ALBERT

Notes: Abstract Ethylene regulates a multitude of plant processes, ranging from seed germination to organ senescence. Of particular economic importance is the role of ethylene as an inducer of fruit ripening. Ethylene is synthesized from S-adenosyl-L-methionine via 1-aminocyclopropane-1-carboxylic acid (ACC). The enzymes catalyzing the two reactions in this pathway are ACC synthase and ACC oxidase. Environmental and endogenous signals regulate ethylene biosynthesis primarily through differential expression of ACC synthase genes. Components of the ethylene signal transduction pathway have been identified by characterization of ethylene-response mutants in Arabidopsis thaliana. One class of mutations, exemplified by etr1, led to the identification of the ethylene receptors, which turned out to be related to bacterial two-component signaling systems. Mutations that eliminate ethylene binding to the receptor yield a dominant, ethylene-insensitive phenotype. CTR1 encodes a Raf-like Ser/Thr protein kinase that acts downstream from the ethylene receptor and may be part of a MAP kinase cascade. Mutants in CTR1 exhibit a constitutive ethylene-response phenotype. Both the ethylene receptors and CTR1 are negative regulators of ethylene responses. EIN2 and EIN3 are epistatic to CTR1, and mutations in either gene lead to ethylene insensitivity. Whereas the function of EIN2 in ethylene transduction is not known, EIN3 is a putative transcription factor involved in regulating expression of ethylene-responsive genes. Biotechnological modifications of ethylene synthesis and of sensitivity to ethylene are promising methods to prevent spoilage of agricultural products such as fruits, whose ripening is induced by ethylene.

Notes: Abstract Chemical synaptic transmission serves as the main form of cell to cell communication in the nervous system. Neurotransmitter release occurs through the process of regulated exocytosis, in which a synaptic vesicle releases its contents in response to an increase in calcium. The use of genetic, biochemical, structural, and functional studies has led to the identification of factors important in the synaptic vesicle life cycle. Here we focus on the prominent role of SNARE (soluble NSF attachment protein receptor) proteins during membrane fusion and the regulation of SNARE function by Rab3a, nSec1, and NSF. Many of the proteins important for transmitter release have homologs involved in intracellular vesicle transport, and all forms of vesicle trafficking share common basic principles. Finally, modifications to the synaptic exocytosis pathway are very likely to underlie certain forms of synaptic plasticity and therefore contribute to learning and memory.

Notes: Abstract The ezrin-radixin-moesin (ERM) family of proteins have emerged as key regulatory molecules in linking F-actin to specific membrane proteins, especially in cell surface structures. Merlin, the product of the NF2 tumor suppressor gene, has sequence similarity to ERM proteins and binds to some of the same membrane proteins, but lacks a C-terminal F-actin binding site. In this review we discuss how ERM proteins and merlin are negatively regulated by an intramolecular association between their N- and C-terminal domains. Activation of at least ERM proteins can be accomplished by C-terminal phosphorylation in the presence of PIP2. We also discuss membrane proteins to which ERM and merlin bind, including those making an indirect linkage through the PDZ-containing adaptor molecules EBP50 and E3KARP. Finally, the function of these proteins in cortical structure, endocytic traffic, signal transduction, and growth control is discussed.

Notes: Abstract Adipogenesis, or the development of fat cells from preadipocytes, has been one of the most intensely studied models of cellular differentiation. In part this has been because of the availability of in vitro models that faithfully recapitulate most of the critical aspects of fat cell formation in vivo. More recently, studies of adipogenesis have proceeded with the hope that manipulation of this process in humans might one day lead to a reduction in the burden of obesity and diabetes. This review explores some of the highlights of a large and burgeoning literature devoted to understanding adipogenesis at the molecular level. The hormonal and transcriptional control of adipogenesis is reviewed, as well as studies on a less well known type of fat cell, the brown adipocyte. Emphasis is placed, where possible, on in vivo studies with the hope that the results discussed may one day shed light on basic questions of cellular growth and differentiation in addition to possible benefits in human health.

Notes: Abstract Enteropathogenic Escherichia coli (EPEC) is a gram-negative bacterial pathogen that adheres to human intestinal epithelial cells, resulting in watery, persistent diarrhea. It subverts the host cell cytoskeleton, causing a rearrangement of cytoskeletal components into a characteristic pedestal structure underneath adherent bacteria. In contrast to other intracellular pathogens that affect the actin cytoskeleton from inside the host cytoplasm, EPEC remains extracellular and transmits signals through the host cell plasma membrane via direct injection of virulence factors by a "molecular syringe," the bacterial type III secretion system. One injected factor is Tir, which functions as the plasma membrane receptor for EPEC adherence. Tir directly links extracellular EPEC through the epithelial membrane and firmly anchors it to the host cell actin cytoskeleton, thereby initiating pedestal formation. In addition to stimulating actin nucleation and polymerization in the host cell, EPEC activates several other signaling pathways that lead to tight junction disruption, inhibition of phagocytosis, altered ion secretion, and immune responses. This review summarizes recent developments in our understanding of EPEC pathogenesis and discusses similarities and differences between EPEC pedestals, focal contacts, and Listeria monocytogenes actin tails.

Notes: Abstract Early development of the vertebrate skeleton depends on genes that pattern the distribution and proliferation of cells from cranial neural crest, sclerotomes, and lateral plate mesoderm into mesenchymal condensations at sites of future skeletal elements. Within these condensations, cells differentiate to chondrocytes or osteoblasts and form cartilages and bones under the control of various transcription factors. In most of the skeleton, organogenesis results in cartilage models of future bones; in these models cartilage is replaced by bone by the process of endochondral ossification. Lastly, through a controlled process of bone growth and remodeling the final skeleton is shaped and molded. Significant and exciting insights into all aspects of vertebrate skeletal development have been obtained through molecular and genetic studies of animal models and humans with inherited disorders of skeletal morphogenesis, organogenesis, and growth.

Notes: Abstract Stomatal guard cells are unique as a plant cell model and, because of the depth of present knowledge on ion transport and its regulation, offer a first look at signal integration in higher plants. A large body of data indicates that Ca2+ and H+ act independently, integrating with protein kinases and phosphatases, to control the gating of the K+ and Cl- channels that mediate solute flux for stomatal movements. Oscillations in the cytosolic-free concentration of Ca2+ contribute to a signaling cassette, integrated within these events through an unusual coupling with membrane voltage for solute homeostasis. Similar cassettes are anticipated to include control pathways linked to cytosolic pH. Additional developments during the last two years point to events in membrane traffic that play equally important roles in stomatal control. Research in these areas is now adding entirely new dimensions to our understanding of guard cell signaling.

Notes: Abstract During the past decade, much progress has been made in understanding how the adult fly is built. Some old concepts such as those of compartments and selector genes have been revitalized. In addition, recent work suggests the existence of genes involved in the regionalization of the adult that do not have all the features of selector genes. Nevertheless, they generate morphological distinctions within the body plan. Here we re-examine some of the defining criteria of selector genes and suggest that these newly characterized genes fulfill many, but not all, of these criteria. Further, we propose that these genes can be classified according to the domains in which they function. Finally, we discuss experiments that address the molecular mechanisms by which selector and selector-like gene products function in the fly.

Notes: Abstract Cajal bodies are small nuclear organelles first described nearly 100 years ago by Ramon y Cajal in vertebrate neural tissues. They have since been found in a variety of animal and plant nuclei, suggesting that they are involved in basic cellular processes. Cajal bodies contain a marker protein of unknown function, p80-coilin, and many components involved in transcription and processing of nuclear RNAs. Among these are the three eukaryotic RNA polymerases and factors required for transcribing and processing their respective nuclear transcripts: mRNA, rRNA, and pol III transcripts. A model is discussed in which Cajal bodies are the sites for preassembly of transcriptosomes, unitary particles involved in transcription and processing of RNA. A parallel is drawn to the nucleolus and the preassembly of ribosomes, which are unitary particles involved in translation of proteins.

Notes: Abstract M cells are distinctive epithelial cells that occur only in the follicle-associated epithelia that overlie organized mucosa-associated lymphoid tissues. They are structurally and functionally specialized for transepithelial transport, delivering foreign antigens and microorganisms to organized lymphoid tissues within the mucosae of the small and large intestines, tonsils and adenoids, and airways. M cell transport is a double-edged sword: Certain pathogens exploit the features of M cells that are intended to promote uptake for the purpose of immunological sampling. Eludication of the molecular architecture of M cell apical surfaces is important for understanding the strategies that pathogens use to exploit this pathway and for utilizing M cell transport for delivery of vaccines to the mucosal immune system. This article reviews the functional and biochemical features that distinguish M cells from other intestinal cell types. In addition it synthesizes the available information on development and differentiation of organized lymphoid tissues and the specialized epithelium associated with these immune inductive sites.

Notes: Abstract Dynamin, a 100-kDa GTPase, is an essential component of vesicle formation in receptor-mediated endocytosis, synaptic vesicle recycling, caveolae internalization, and possibly vesicle trafficking in and out of the Golgi. In addition to the GTPase domain, dynamin also contains a pleckstrin homology domain (PH) implicated in membrane binding, a GTPase effector domain (GED) shown to be essential for self-assembly and stimulated GTPase activity, and a C-terminal proline-rich domain (PRD), which contains several SH3-binding sites. Dynamin partners bind to the PRD and may either stimulate dynamin's GTPase activity or target dynamin to the plasma membrane. Purified dynamin readily self-assembles into rings or spirals. This striking structural property supports the hypothesis that dynamin wraps around the necks of budding vesicles where it plays a key role in membrane fission. The focus of this review is on the relationship between the GTPase and self-assembly properties of dynamin and its cellular function.

Notes: Abstract Cholesterol balance is maintained by a series of regulatory pathways that control the acquisition of cholesterol from endogenous and exogenous sources and the elimination of cholesterol, facilitated by its conversion to bile acids. Over the past decade, investigators have discovered that a family of membrane-bound transcription factors, sterol regulatory element-binding proteins (SREBPs), mediate the end-product repression of key enzymes of cholesterol biosynthesis. Recently orphan members of another family of transcription factors, the nuclear hormone receptors, have been found to regulate key pathways in bile acid metabolism, thereby controlling cholesterol elimination. The study of these orphan nuclear receptors suggests their potential as targets for new drug therapies.

Notes: Abstract Voltage-gated Ca2+ channels mediate Ca2+ entry into cells in response to membrane depolarization. Electrophysiological studies reveal different Ca2+ currents designated L-, N-, P-, Q-, R-, and T-type. The high-voltage-activated Ca2+ channels that have been characterized biochemically are complexes of a pore-forming alpha1 subunit of ~190-250 kDa; a transmembrane, disulfide-linked complex of alpha2 and delta subunits; an intracellular beta subunit; and in some cases a transmembrane gamma subunit. Ten alpha1 subunits, four alpha2delta complexes, four beta subunits, and two gamma subunits are known. The Cav1 family of alpha1 subunits conduct L-type Ca2+ currents, which initiate muscle contraction, endocrine secretion, and gene transcription, and are regulated primarily by second messenger-activated protein phosphorylation pathways. The Cav2 family of alpha1 subunits conduct N-type, P/Q-type, and R-type Ca2+ currents, which initiate rapid synaptic transmission and are regulated primarily by direct interaction with G proteins and SNARE proteins and secondarily by protein phosphorylation. The Cav3 family of alpha1 subunits conduct T-type Ca2+ currents, which are activated and inactivated more rapidly and at more negative membrane potentials than other Ca2+ current types. The distinct structures and patterns of regulation of these three families of Ca2+ channels provide a flexible array of Ca2+ entry pathways in response to changes in membrane potential and a range of possibilities for regulation of Ca2+ entry by second messenger pathways and interacting proteins.

Notes: Abstract Green fluorescent protein chimerae acting as reporters for protein localization and trafficking within the secretory membrane system of living cells have been used in a wide variety of applications, including time-lapse imaging, double-labeling, energy transfer, quantitation, and photobleaching experiments. Results from this work are clarifying the steps involved in the formation, translocation, and fusion of transport intermediates; the organization and biogenesis of organelles; and the mechanisms of protein retention, sorting, and recycling in the secretory pathway. In so doing, they are broadening our thinking about the temporal and spatial relationships among secretory organelles and the membrane trafficking pathways that operate between them.

Notes: Abstract SUMO (small ubiquitin-related modifier) is the best-characterized member of a growing family of ubiquitin-related proteins. It resembles ubiquitin in its structure, its ability to be ligated to other proteins, as well as in the mechanism of ligation. However, in contrast to ubiquitination-often the first step on a one-way road to protein degradation-SUMOlation does not seem to mark proteins for degradation. In fact, SUMO may even function as an antagonist of ubiquitin in the degradation of selected proteins. While most SUMO targets are still at large, available data provide compelling evidence for a role of SUMO in the regulation of protein-protein interactions and/or subcellular localization.

Notes: Abstract Because many viruses replicate in the nucleus of their host cells, they must have ways of transporting their genome and other components into and out of this compartment. For the incoming virus particle, nuclear entry is often one of the final steps in a complex transport and uncoating program. Typically, it involves recognition by importins (karyopherins), transport to the nucleus, and binding to nuclear pore complexes. Although all viruses take advantage of cellular signals and factors, viruses and viral capsids vary considerably in size, structure, and in how they interact with the nuclear import machinery. Influenza and adenoviruses undergo extensive disassembly prior to genome import; herpesviruses release their genome into the nucleus without immediate capsid disassembly. Polyoma viruses, parvoviruses, and lentivirus preintegration complexes are thought to enter in intact form, whereas the corresponding complexes of onco-retroviruses have to wait for mitosis because they cannot infect interphase nuclei.

Notes: Abstract The Myc/Max/Mad network comprises a group of transcription factors whose distinct interactions result in gene-specific transcriptional activation or repression. A great deal of research indicates that the functions of the network play roles in cell proliferation, differentiation, and death. In this review we focus on the Myc and Mad protein families and attempt to relate their biological functions to their transcriptional activities and gene targets. Both Myc and Mad, as well as the more recently described Mnt and Mga proteins, form heterodimers with Max, permitting binding to specific DNA sequences. These DNA-bound heterodimers recruit coactivator or corepressor complexes that generate alterations in chromatin structure, which in turn modulate transcription. Initial identification of target genes suggests that the network regulates genes involved in the cell cycle, growth, life span, and morphology. Because Myc and Mad proteins are expressed in response to diverse signaling pathways, the network can be viewed as a functional module which acts to convert environmental signals into specific gene-regulatory programs.

Notes: Abstract The inner membranes of eubacteria and mitochondria, as well as the chloroplast thylakoid membrane, contain essential proteins that function in oxidative phosphorylation and electron transport processes or in photosynthesis. Because most of the organellar proteins are nuclear encoded, they are synthesized in the cytoplasm and subsequently imported into the organelle before they are inserted into the membrane. This review focuses on the pathways of protein insertion into the inner membrane of eubacteria and mitochondria and into the chloroplast thylakoid membrane. In many respects, insertion of proteins into the inner membrane of bacteria is a process similar to that used by proteins of the thylakoid membrane. In both of these systems a signal recognition particle (SRP) and a SecYE-translocase are involved, as in translocation into the endoplasmic reticulum. The pathway of proteins into the mitochondrial membranes appears to be different in that it involves no SecYE-like components. A conservative pathway, recently identified in mitochondria, involves the Oxa1 protein for the insertion of proteins from the matrix. The presence of Oxa1 homologues in eubacteria and chloroplasts suggests that this pathway is evolutionarily conserved.

Notes: Abstract The microtubule cytoskeleton is a highly regulated system. At different times in the cell cycle and positions within the organism, microtubules can be very stable or highly dynamic. Stability and dynamics are regulated by interaction with a large number of proteins that themselves may change at specific points in the cell cycle. Exogenous ligands can disrupt the normal processes by either increasing or decreasing microtubule stability and inhibiting their dynamic behavior. The recent determination of the structure of tubulin, the main component of microtubules, makes it possible now to begin to understand the details of these interactions. We review here the structure of the tubulin dimer, with particular regard to how proteins and drugs may bind and modulate microtubule dynamics.

Notes: Abstract Many bisexual flowering plants possess a reproductive strategy called self-incompatibility (SI) that enables the female tissue (the pistil) to reject self but accept non-self pollen for fertilization. Three different SI mechanisms are discussed, each controlled by two separate, highly polymorphic genes at the S-locus. For the Solanaceae and Papaveraceae types, the genes controlling female function in SI, the S-RNase gene and the S-gene, respectively, have been identified. For the Brassicaceae type, the gene controlling male function, SCR/SP11, and the gene controlling female function, SRK, have been identified. The S-RNase based mechanism involves degradation of RNA of self-pollen tubes; the S-protein based mechanism involves a signal transduction cascade in pollen, including a transient rise in [Ca2+]i and subsequent protein phosphorylation/dephosphorylation; and the SRK (a receptor kinase) based mechanism involves interaction of a pollen ligand, SCR/SP11, with SRK, followed by a signal transduction cascade in the stigmatic surface cell.

Notes: Abstract Retinylidene proteins, containing seven membrane-embedded alpha-helices that form an internal pocket in which the chromophore retinal is bound, are ubiquitous in photoreceptor cells in eyes throughout the animal kingdom. They are also present in a diverse range of other organisms and locations, such as archaeal prokaryotes, unicellular eukaryotic microbes, the dermal tissue of frogs, the pineal glands of lizards and birds, the hypothalamus of toads, and the human brain. Their functions include light-driven ion transport and phototaxis signaling in microorganisms, and retinal isomerization and various types of photosignal transduction in higher animals. The aims of this review are to examine this group of photoactive proteins as a whole, to summarize our current understanding of structure/function relationships in the best-studied examples, and to report recent new developments.

Notes: Abstract Cell walls separate individual plant cells. To enable essential intercellular communication, plants have evolved membrane-lined channels, termed plasmodesmata, that interconnect the cytoplasm between neighboring cells. Historically, plasmodesmata were viewed as facilitating traffic of low-molecular weight growth regulators and nutrients critical to growth. Evidence for macromolecular transport via plasmodesmata was solely based on the exploitation of plasmodesmata by plant viruses during infectious spread. Now plasmodesmata are revealed to transport endogenous proteins, including transcription factors important for development. Two general types of proteins, non-targeted and plasmodesmata-targeted, traffic plasmodesmata channels. Size and subcellular location influence non-targeted protein transportability. Superimposed on cargo-specific parameters, plasmodesmata themselves fluctuate in aperture between closed, open, and dilated. Furthermore, plasmodesmata alter their transport capacity temporally during development and spatially in different regions of the plant. Plasmodesmata are exposed as major gatekeepers of signaling molecules that facilitate or regulate developmental programs, maintain physiological status, and respond to pathogens.

Notes: Abstract The closely related bacterial pathogens Neisseria gonorrhoeae (gonococci, GC) and N. meningitidis (meningococci, MC) initiate infection at human mucosal epithelia. Colonization begins at apical epithelial surfaces with a multistep adhesion cascade, followed by invasion of the host cell, intracellular persistence, transcytosis, and exit. These activities are modulated by the interaction of a panoply of virulence factors with their cognate host cell receptors, and signals are sent from pathogen to host and host to pathogen at multiple stages of the adhesion cascade. Recent advances place us on the verge of understanding the colonization process at a molecular level of detail. In this review we describe the Neisseria virulence factors in the context of epithelial cell biology, placing special emphasis on the signaling functions of type IV pili, pilus-based twitching motility, and the Opa and Opc outermembrane adhesin/invasin proteins. We also summarize what is known about bacterial intracellular trafficking and growth. With the accelerated integration of tools from cell biology, biochemistry, biophysics, and genomics, experimentation in the next few years should bring unprecedented insights into the interactions of Neisseriae with their host.

Notes: Five human teratoma cell lines have been characterized for the presence of a certain number of marker antigens whose presence or absence has been shown to be characteristic of mouse embryonal carcinoma (EC) cells. Four out of the five lines have been shown to respond to at least some of the criteria associated with murine EC cells even though only limited in vitro differentiation could be demonstrated. The significance of certain unusual marker antigen combinations present on the cell line Tera I and its clones and so far unobserved for the murine model is discussed. The observation in Tera I populations of cells carrying simultaneously both the F9 and β2-microglobulin or HLA antigens, suggest that the human cell lines may represent a novel material for the study of mammalian differentiation.

Notes: Principles of Gene Manipulation. Studies in Microbiology

Notes: Anabaena strain 90 produces three hepatotoxic heptapeptides (microcystins), two seven-residue depsipeptides called anabaenopeptilide 90A and 90B, and three six-residue peptides called anabaenopeptins. The anabaenopeptilides belong to a group of cyanobacterial depsipeptides that share the structure of a six-amino-acid ring with a side-chain. Despite their similarity to known cyclic peptide toxins, no function has been assigned to the anabaenopeptilides. Degenerate oligonucleotide primers based on the conserved amino acid sequences of other peptide synthetases were used to amplify DNA from Anabaena 90, and the resulting polymerase chain reaction (PCR) products were used to identify a peptide synthetase gene cluster. Four genes encoding putative anabaenopeptilide synthetase domains were characterized. Three genes, apdA, apdB and apdD, contain two, four and one module, respectively, encoding a total of seven modules for activation and peptide bond formation of seven l-amino acids. Modules five and six also carry methyltransferase-like domains. Before the first module, there is a region similar in amino acid sequence to formyltransferases. A fourth gene (apdC), between modules six and seven, is similar in sequence to halogenase genes. Thus, the order of domains is co-linear with the positions of amino acid residues in the finished peptide. A mutant of Anabaena 90 was made by inserting a chloramphenicol resistance gene into the apdA gene. DNA amplification by PCR confirmed the insertion. Mass spectrometry analysis showed that anabaenopeptilides are not made in the mutant strain, but other peptides, such as microcystins and anabaenopeptins, are still produced by the mutant.

Notes: Salmonella pathogenesis is a complex and multifactorial phenomenon. Many genes required for full virulence in mice have been identified, but only a few of these have been shown to be necessary for the induction of enteritis. Likewise, at least some of the Salmonella virulence factors affecting enteritis do not appear to be required for infection of systemic sites in mice. This suggests that subsets of virulence genes influence distinct aspects of Salmonella pathogenesis. Recently, considerable progress has been made in characterizing the virulence mechanisms influencing enteritis caused by non-typhoid Salmonella spp. The Salmonella pathogenicity island-1-encoded type III secretion system mediates the translocation of secreted effector proteins into target epithelial cells. These effector proteins are key virulence factors required for Salmonella intestinal invasion and the induction of fluid secretion and inflammatory responses.

Notes: The recent emergence of food-borne pathogens, such as Salmonella enterica serotype Enteritidis (S. enteritidis) and Escherichia coli O157:H7, has generated increasing interest in how infectious diseases can invade, persist and spread within new host populations. To alter their host range pathogens require adaptations, which ensure their circulation in a new animal population. Adaptations for circulation in different populations of vertebrate hosts seem to have been acquired multiple times within the genus Salmonella because extant Salmonella serotypes differ greatly with regard to host range. In this article, mechanisms involved in host adaptation are deduced by considering the influence of the host immune response on circulation of Salmonella serotypes within populations of vertebrate animals. This approach contributes to the identification of genes involved in host adaptation and provides new insights into the emergence of food-borne pathogens.

Notes: Transcription from the bop promoter in the haloarchaeon Halobacterium NRC-1, is highly induced under oxygen-limiting conditions. A DNA gyrase inhibitor, novobiocin, was previously shown to block bop gene induction and suggested that DNA supercoiling mediates transcriptional induction. A region of non-B structure was found 3′ to the TATA box within an 11 bp alternating purine–pyrimidine sequence (RY box), which correlated to both increased DNA supercoiling and transcriptional induction. Here, saturation mutagenesis of the RY box region has been used to show that single-base substitutions of A(r)G either 23 or 19 bp 5′ to the transcription start site temper the effect of DNA supercoiling based on novobiocin insensitivity of transcription. Mutagenesis of the region 5′ to the TATA box showed its involvement in DNA supercoiling modulation of transcription, defined the 3′ end of the upstream activator sequence (UAS) regulatory element, and ruled out the requirement for a TFB (TFIIB) Recognition Element. Spacing between the TATA box and UAS was found to be critical for promoter activity because insertion of partial or whole helical turns between the two elements completely inhibited transcription indicating that the UAS element does not function as a transcriptional enhancer. The results are discussed in the context of DNA melting and flexibility around the TATA box region and the involvement of multiple regulatory and transcription factors in bop promoter activity.

Notes: We investigated the transcription of the urease gene cluster ureABIEFGH in Helicobacter pylori to determine the regulation of gene expression of the highly produced enzyme urease. Northern blot hybridization analysis demonstrated that cells of the wild-type strain grown in an ordinary broth had transcripts of ureAB, ureABI, ureI, ureIE′ and ure′FGH, but cells of a ureI-disrupted mutant had only the ureAB transcript. When the wild-type cells were exposed to pH 8 for 30 min, very little mRNA was detected. However, when exposed to pH 6, a large amount of the ureIE′′ transcript, which was longer than the ureIE′ transcript, together with the additional transcripts ureABIEFGH and ure′EFGH were detected. Rifampicin addition experiments demonstrated that urease mRNAs, and the ureIE′ transcripts in particular, are more stable at pH 5.5 than at pH 7. In accord with these results, urease activity in the crude cell extract of the pH 5.5 culture was twice as much as that of the pH 7 culture, although the amounts of UreA and UreB detected by immunoblot analysis were similar. The transcription start point of ureI was identified by primer extension using a ureA promoter-deleted mutant, and a consensus sequence of RpoD-RNA polymerase was found in the ureI promoter. The 3′ end of the ureIE′′ mRNA, determined using S1 nuclease mapping, revealed that the transcript is able to cover the majority of the ureE open reading frame (ORF) that might be sufficient for UreE activity. Based on the above results, we conclude that the urease gene cluster of H. pylori consists of two operons, ureAB and ureIEFGH, and that primary transcripts of the latter as well as the read-through transcript, ureABIEFGH, are cleaved to produce several species of mRNA. It has been suggested that the ureIEFGH operon is regulated post-transcriptionally by mRNA decay in response to environmental pH. We are tempted to speculate that the ureE′′ transcript present in acidic pH may contribute to produce an active product that can proceed the nickel incorporation to the active centre, the final step of urease biosynthesis.

Notes: Systemic infections by Salmonella enterica, such as typhoid fever, are a significant threat to human health. Recent studies indicate that the function of a type III secretion system encoded by Salmonella Pathogenicity Island 2 (SPI2) is central for the ability of S. enterica to cause systemic infections and for intracellular pathogenesis. This review summarizes approaches leading to the identification of SPI2, the molecular genetics and evolution of SPI2, and the current understanding of the regulation of gene expression. Recent studies have indicated that SPI2 is used by intracellular Salmonella to actively modify functions of the host cells. The role of SPI2 during pathogenesis of salmonellosis and current models regarding function will be discussed.

Notes: Natural sequence variation was investigated among serogroup A subgroup IV-1 Neisseria meningitidis isolated from diseased patients and healthy carriers in The Gambia, West Africa. The frequencies of DNA import were analysed by sequencing fragments of four linked genes encoding the immunogenic outer membrane proteins TbpB (transferrin binding protein B) and OpaA (an adhesin) plus two housekeeping enzymes. Seventeen foreign tbpB alleles were independently imported into the 98 strains tested, apparently due to immune selection. The median size of the imported DNA fragments was 5 kb, resulting in the occasional concurrent import of linked housekeeping genes by hitchhiking. Sequences of tbpB from other strains of N. meningitidis as well as commensal Neisseria lactamica and Neisseria spp. isolated from the same geographical area revealed that these species share a common tbpB gene pool and identified several examples of interspecific genetic exchange. These observations indicate that recombination can be more frequent between related species than within a species and indicate that effective vaccination against serogroup B meningococcal disease may be difficult to achieve.

Notes: Antirepressors have been identified as proteins interacting with transcriptional repressors leading to expression of the repressed genes. The defective satellite phage/plasmid P4 has the capacity to derepress the unrelated prophage P2 after infection, thereby getting access to the late functions of the helper that are required for P4 lytic growth. The derepression of prophage P2 is mediated by the P4 E protein that function as an antirepressor by binding to the P2 immunity repressor C. A P2 mutant, sos, has been isolated that is insensitive to the action of the P4 E protein. In the present study, we show that sos is a point mutation in the P2 immunity repressor gene C and that it makes P4 E unable to turn the transcriptional switch of P2 from the lysogenic state to the lytic mode in a two plasmid reporter system. Furthermore, the interaction between C and E, when analysed in the yeast two-hybrid system, is blocked by the sos mutation. An analysis of C mutants indicates that the dimerization function of C is located in the C-terminal part of the protein and the dimerization defective mutants are unable to bind to their operator DNA. The sos mutation does not affect the capacity of the protein to dimerize. Using the yeast two-hybrid system, compensatory E mutants have been isolated that can interact with Sos, but they are unable to turn the transcriptional switch controlled by the Sos repressor. However, one point mutation in the E protein is shown to be unable to turn the transcriptional switch controlled by the wild-type C repressor.

Notes: CAP1 encodes a basic region-leucine zipper (bZip) transcriptional regulatory protein that is required for oxidative stress tolerance in Candida albicans. Cap1p is a homologue of a Saccharomyces cerevisiae bZip transcription factor designated Yap1p that is both required for oxidative stress tolerance and localized to the nucleus in response to the presence of oxidants. Oxidant-regulated localization of Yap1p to the nucleus requires the presence of a carboxy-terminal cysteine residue (C629) that is conserved in Cap1p as C477. To examine the role of this conserved cysteine residue, C477 was replaced with an alanine residue. This mutant protein, C477A Cap1p, was analysed for its behaviour both in S. cerevisiae and C. albicans. Wild type and C477A Cap1p were able to complement the oxidant hypersensitivity of a Δyap1 S. cerevisiae strain. Whereas a Yap1p-responsive lacZ fusion gene was oxidant inducible in the presence of YAP1, the C. albicans Cap1p derivatives were not oxidant responsive in S. cerevisiae. Introduction of wild type and C477A Cap1p-expressing plasmids into C. albicans produced differential resistance to oxidants. Glutathione reductase activity was found to be inducible by oxidants in the presence of Cap1p but was constitutively elevated in the presence of C477A Cap1p. Western blot assays indicate Cap1p is post-translationally regulated by oxidants. Green fluorescent protein fusions to CAP1 showed that this protein is localized to the nucleus only in the presence of oxidants while C477A Cap1p is constitutively nuclear localized. Directly analogous to S. cerevisiae Yap1p, regulated nuclear localization of C. albicans Cap1p is crucial for its normal function.

Notes: The DNA-binding domain of the Escherichia coli DnaA protein is represented by the 94 C-terminal amino acids (domain 4, aa 374–467). The isolated DNA-binding domain acts as a functional repressor in vivo, as monitored with a mioC::lacZ translational fusion integrated into the chromosome of the indicator strain. In order to identify residues required for specific DNA binding, site-directed and random PCR mutagenesis were performed, using the mioC::lacZ construct for selection. Mutations defective in DNA binding were found all over the DNA-binding domain with some clustering in the basic loop region, within presumptive helix B and in a highly conserved region at the N-terminus of presumptive helix C. Surface plasmon resonance (SPR) analysis revealed different binding classes of mutant proteins. No or severely reduced binding activity was demonstrated for amino acid substitutions at positions R399, R407, Q408, H434, T435, T436 and A440. Altered binding specificity was found for mutations in a 12 residue region close to the N-terminus of helix C. The defects of the classical temperature sensitive mutants dnaA204, dnaA205 and dnaA211 result from instability of the proteins at higher temperatures. dnaX suppressors dnaA71 and dnaA721 map to the region close to helix C and bind DNA non-specifically.

Notes: The integrase (Int) proteins encoded by bacteriophages HK022 and λ catalyse similar site-specific integration and excision reactions between specific DNA regions known as attachment (att) sites. However, the Int proteins of HK022 and λ are unable to catalyse recombination between non-cognate att sites. The att sites of both phages contain weak binding sites for Int, known as ‘core-type’ sites. Negatively acting nucleotide determinants associated with specific core sites (λ B′, HK022 B′, HK022 C) are responsible for the barrier to non-cognate recombination. In this study, we used challenge phages to demonstrate that the λ and HK022 Ints cannot bind to core sites containing non-cognate specificity determinants in vivo. We isolated mutants of the HK022 Int, which bind the λ B′ core site. Two mutants, D99N and D99A, have changed a residue in the core-binding (CB) domain, which may be directly contacting the core site DNA. We suggest that binding to the λ B′ site was accomplished by removing the negatively charged aspartate residue, which normally participates in a conflicting interaction with the G4 nucleotide of the λ B′ site. We showed that, although our mutants retain the ability to recombine their cognate att sites, they are unable to recombine λatt sites.

Notes: The fim switch of Escherichia coli is responsible for phase-variable expression of type 1 fimbriae. Switching in the ON-to-OFF and OFF-to-ON directions is promoted by the FimB recombinase, while the FimE recombinase directs switching predominantly in the ON-to-OFF direction. The effects of local promoter activity and the H-NS nucleoid-associated protein on inversion of the switch were assessed. In contrast to FimB-mediated inversion, inversion of the switch by the FimE recombinase was unaffected by the H-NS status of the cell. Transcription towards the switch from within a translationally inactivated fimE gene was found to bias the switch strongly in the OFF direction, creating a FimE+-like phenotype in the absence of the FimE protein. This biasing was H-NS dependent and was also contingent on transcription from within the switch. These data show that local transcription and a nucleoid-associated protein both contribute to the modulation of a site-specific recombination event on the bacterial chromosome.

Notes: The fnrN gene from Rhizobium leguminosarum UPM791 controls microaerobic expression of both nitrogen fixation and hydrogenase activities in symbiotic cells. Two copies of fnrN are present in this strain, one chromosomal (fnrN1) and the other located in the symbiotic plasmid (fnrN2). Their expression was studied by cloning the regulatory regions in lacZ promoter-probe vectors. The fnrN genes were found to be autoregulated: they are expressed only at basal levels under aerobic conditions; they are highly expressed under microaerobic conditions; and they are expressed at basal levels in the double mutant DG2 (fnrN1 fnrN2) under any condition. The promoters of both genes contain two FnrN-binding sequences (anaeroboxes), centred at positions −12.5 (proximal anaerobox) and −44.5 (distal anaerobox). Expression analysis and gel retardation experiments with fnrN1-derivative promoter mutants altered in key bases of the anaerobox sequences demonstrated that binding of FnrN1 to the distal anaerobox is necessary for microaerobic activation of transcription, and that binding of FnrN1 to the proximal anaerobox results in transcriptional repression. The apparent affinity of FnrN1 for the proximal anaerobox was fivefold lower than for the distal anaerobox, resulting in repression of transcription of fnrN1 only at high-FnrN1 concentrations. This positive and negative autoregulation mechanism ensures an equilibrated expression of fnrN in response to microaerobic conditions.

Notes: Listeria monocytogenes is capable of growth within the cytoplasm of infected host cells. Escape from the host cell phagosome is mediated primarily through secretion of listeriolysin, a haemolytic factor which functions to actively lyse the phagosomal membrane. Listeriolysin negative mutants of L. monocytogenes are non-haemolytic on blood agar plates and demonstrate a significant reduction of virulence in the mouse model of infection. We have developed a system for the identification of in vivo induced genes in L. monocytogenes which utilizes the listeriolysin gene, hly, as both a reporter of gene expression and as a means of selection of promoter elements expressed in vivo. The system is analogous to in vivo expression technology (IVET) first reported for Salmonella, however, as listeriolysin functions in the environment of the host phagosome the loci identified in this study are most likely expressed during residence in the phagosome. The system was successfully tested using the promoter of the inducible virulence gene plcA. A bank was created by fusing a promoterless copy of hly to random promoter elements in a listeriolysin negative IVET host. Sequential inoculations of mice with this bank resulted in the isolation of clones with increased survival potential in the mouse model relative to a negative control, but which remained haemolysin negative on blood agar plates. Nine in vivo induced loci were identified including genes encoding a DNA topoisomerase III, a cellobiose transporter and a fumarase. Two isolates represented fusions to proteins of unknown function and three isolates contained no significant homologues in the database. A mutant in the fumarase gene demonstrated reduced virulence for mice and an inability to grow in cultured mouse phagocytes.

Notes: Saccharomyces cerevisiae Ste12p plays a key role in coupling signal transduction through MAP kinase modules to cell-specific or morphogenesis-specific gene expression required for mating and pseudohyphal (PH)/filamentous growth (FG). Ste12p homologues in the pathogenic yeasts Candida albicans and Filobasidiela neoformans apparently play similar roles during dimorphic transitions. Here we report the isolation and characterization of the first Ste12 protein from a true filamentous fungus. Aspergillus nidulans steA encodes a protein with a homeodomain 63–75% identical to those of other Ste12 proteins, with greatest similarity to FnSte12αp. SteAp and Ste12αp lack the pheromone induction domain found in budding yeast Ste12p, but have C-terminal C2/H2-Zn+2 finger domains not present in the other Ste12 proteins. A ΔsteA strain is sterile and differentiates neither ascogenous tissue nor fruiting bodies (cleistothecia). However, the development of sexual cycle-specific Hülle cells is unaffected. Filamentous growth, conidiation and the differentiation of PH-like asexual reproductive cells (metulae and phialides) are normal in the deletion strain. Northern analysis of key regulators of the asexual and sexual reproductive cycles support the observation that although SteAp function is restricted to the sexual cycle, cross regulation between the two developmental pathways exists. Our results further suggest that while several classes of related proteins control similar morphogenetic events in A. nidulans and the dimorphic yeasts, significant differences must exist in the regulatory circuitry.

Notes: The two glyceraldehyde-3-phosphate dehydrogenase-encoding genes (gap) of Synechocystis were shown to be expressed as monocistronic transcripts. Whereas gap1 expression is slow and weak, gap2 gene induction is rapid and strong. Transcription of the gap2 gene was shown to depend on functional photosynthetic electron transport and on active carbon metabolism. The basal promoter of gap2 (P, −45 to +34, relative to the transcription start site) is controlled by three cis-acting elements designated A (−443 to −45), B (+34 to +50, in the untranslated leader region) and C (+50 to +167, in the coding region) that, together, promote a 100-fold stimulation of P activity. Element B was found to behave as a transcriptional enhancer, in that it was active regardless of its position, orientation and distance relative to P. All three cis-acting stimulatory elements exhibit a common 5′-agaTYAACg-3′ nucleotide motif that appears to be conserved in cyanobacteria and may be the target for a transcriptional enhancer. We also report that gap2 transcription depends on a Gram-positive-like −16 promoter box (5′-TRTG-3′) that was obviously conserved throughout the evolution of chloroplasts. This is the first report on the occurrence of a −16 promoter element in photoautotrophic organisms.

Notes: Apicomplexan protozoa possess a family of micronemal and cell surface-associated proteins, each comprised a combination of cell-adhesive vertebrate von Willebrand factor (vWF)-like A domains and thrombospondin (TSP) type 1-like domains. The human malaria parasite Plasmodium falciparum has in the extracellular portion of the CS protein TRAP-related protein (CTRP) six tandemly arrayed A domains followed by seven TSP type 1-like domains, whereas a second member of this family, thrombospondin-related anonymous protein (TRAP), contains a single vWF-like A domain and a single TSP type 1-like domain. Here we show that CTRP transcripts are present within the infected mosquito midgut and that CTRP protein is expressed with a punctate distribution and a predominance at the apical end of mosquito midgut-stage ookinetes. This expression pattern is analogous to micronemal expression of TRAP in Plasmodium sporozoites. Disruption of the CTRP gene by homologous recombination in cultures of the human malaria parasite P. falciparum demonstrates that CTRP is essential for mosquito midgut development. Oocyst formation was never observed following membrane feeds of CTRP disruptant lines to Anopheline mosquitoes, despite the development of mature ookinetes. We propose that CTRP is involved in essential recognition or motility processes at the ookinete cell surface within the mosquito midgut.

Notes: The rncS gene of Bacillus subtilis encodes Bs-RNase III, a narrow-specificity endoribonuclease. Previous attempts to disrupt rncS were unsuccessful. Here, a strain was constructed in which Bs-RNase III expression was dependent upon transcription of rncS from a temperature-sensitive plasmid. Growth of this strain at the non-permissive temperature resulted in 90–95% cell death, and virtually all the cells that survived retained the rncS-expressing plasmid. Thus, we conclude that rncS is essential in B. subtilis. The rncS conditional strain also revealed that Bs-RNase III participates in the processing of ribosomal RNA, in addition to processing small cytoplasmic RNA, a member of the signal recognition particle RNA family. Most significantly, a rare rncS null strain was isolated that will aid further study of the critical role Bs-RNase III plays in B. subtilis.

Notes: The dnaK operon of Streptomyces coelicolor encodes the DnaK chaperone machine and HspR, the transcriptional repressor of the operon; HspR confers repression by binding to several inverted repeat sequences in the promoter region, dnaKp. Here, we demonstrate that HspR specifically requires the presence of DnaK protein to retard a dnaKp fragment in gel-shift assays. This requirement is independent of the co-chaperones, DnaJ and GrpE, and it is ATP independent. Furthermore the retarded protein–DNA complex can be ‘supershifted’ by anti-DnaK monoclonal antibody, demonstrating that DnaK forms an integral component of the complex. It was shown in DNase I footprinting experiments that refolding and specific binding of HspR to its DNA target does not require DnaK. We conclude that the formation of the stable DnaK–HspR–DNA ternary complex does not depend on the chaperoning activity of DnaK. In affinity chromatography experiments using whole-cell extracts, DnaK was shown to co-purify with HspR, providing additional evidence that the two proteins interact in vivo; it was not possible to purify HspR away from DnaK in any experiments unless a powerful denaturant was used. The level of heat shock induction of chromosomal DnaK could be partially suppressed by expressing dnaK extrachromosomally from a heterologous promoter. In addition, it is shown that DnaK confers enhanced HspR-mediated repression of transcription in vitro. Taken together, these results suggest that DnaK functions as a transcriptional co-repressor by binding to HspR at its operator sites. In this model, the DnaK–HspR system would represent a novel example of feedback regulation of gene expression by a molecular chaperone, in which DnaK directly activates a repressor, rather than inactivates an activator (as is the case in the DnaK–σ32 and Hsp70–HSF systems of other organisms).

Notes: In vivo and in vitro studies have suggested that the bacterial version of the mammalian signal recognition particle (SRP) system plays an essential and selective role in protein biogenesis. The bacterial SRP system consists of at least two proteins and an RNA molecule (termed Ffh, FtsY and 4.5S RNA, respectively, in Escherichia coli). Recent evidence suggests that other putative bacterial-specific SRP components may also exist. In vitro experiments confirmed the expected basic features of the bacterial SRP system by demonstrating interactions among the SRP components themselves, between them and ribosomes, ribosome-linked hydrophobic nascent polypeptides or inner membranes. The availability of a conserved (and essential) bacterial SRP version has facilitated the implementation of powerful genetic and biochemical approaches for studying the cascade of events during the SRP-mediated targeting process in vivo and in vitro as well as the three-dimensional structures and the properties of each SRP component and complex.

Notes: Cryptococcus neoformans is an important human pathogenic fungus with a defined sexual cycle and well-developed molecular and genetic approaches. C. neoformans is predominantly haploid and has two mating types, MATa and MATα. Mating is known to be regulated by nutritional limitation and thought also to be regulated by pheromones. Previously, a portion of the MATα locus was cloned, and a presumptive pheromone gene, MFα1, was identified by its ability to induce conjugation tube-like filaments when introduced by transformation into MATa cells. Here, the ability of the MFα1 gene to induce these morphological changes in MATa cells was used as a phenotypic assay to perform a structure–function analysis of the gene. We show that the MFα1 open reading frame is required for the morphological response of MATa cells. We also find that the cysteine residue of the C-terminal CAAX motif is required for activity of the MFα1 pheromone. In addition, we use a reporter system to measure the expression levels of the MFα1 pheromone gene and find that two signals, nutrient starvation and the presence of factors secreted by mating partner cells, impinge on this promoter and regulate MFα1 expression. We identify a second pheromone gene, MFα2, and show phenotypically that this gene is also expressed. Finally, we have synthesized the MFα1 pheromone and show that only the predicted mature modified form of the α-factor peptide triggers morphological responses in MATa cells.

Notes: The Escherichia coli cydAB operon, encoding the subunits of the high-affinity cytochrome d oxidase, is maximally transcribed in microaerobiosis as a result of the combined action of the oxygen-responsive regulators Fnr and ArcA. Here, we report that the histone-like protein H-NS is an aerobic repressor of cydAB expression. ArcA is shown to antagonize H-NS action to render cydAB expression insensitive to H-NS repression in anaerobiosis. The targets for H-NS-mediated aerobic repression are the four oxygen-regulated promoters, designated P1, P2, P3 and P4. H-NS control is the result of H-NS binding to an extended region within the cydAB promoter element, including sequences upstream from and overlapping the four regulated promoters. We propose a regulatory model in which oxygen control of cydAB transcription is mediated by three alternative protein–DNA complexes that are assembled sequentially on the promoter region as the cells are shifted from aerobic to microaerobic and to anaerobic conditions. According to this model, ArcA-P plays a central role in cydAB regulation by antagonizing H-NS repression of cydAB transcription when oxygen becomes limiting. This allows peak gene expression and subsequent repression by Fnr under fully anaerobic conditions.

Notes: The KdpD sensor kinase and the KdpE response regulator control the expression of the kdpFABC operon, encoding the KdpFABC high-affinity K+ transport system of Escherichia coli. Low turgor pressure has been postulated to be the environmental stimulus to express KdpFABC. KdpD has autokinase, phosphotransferase and, like many sensor kinases, response regulator (phospho-KdpE) specific phosphatase activity. To determine which of these activities are altered in response to the environmental stimulus, we isolated and analysed six kdpD mutants that cause constitutive expression of KdpFABC. In three of the mutants, phosphatase activity was undetectable and, in two, phosphatase was reduced. Kinase activity was unaffected in four of the mutants, but elevated in one. In one mutant, a pseudorevertant of a kdpD null mutation, kinase and phosphatase were both reduced to 20% of the wild-type level. These findings suggest that initiation of signal transduction by KdpD is mediated by the inhibition of the phospho-KdpE-specific phosphatase activity of KdpD, leading to an accumulation of phospho-KdpE, which in turn activates the expression of the KdpFABC system. The data also suggest that levels of activity in vitro may differ from what occurs in vivo, because in vitro conditions cannot replicate those in vivo.

Notes: DsrA is an 87 nucleotide Escherichia coli RNA with extraordinary regulatory properties. The profound impact of its actions stems from DsrA regulating translation of two global transcription regulators, H-NS and RpoS (σs), by sequence-specific RNA–RNA interactions. H-NS is a major nucleoid-structuring and global repressor protein, and RpoS is the stationary phase and stress response sigma factor of RNA polymerase. DsrA changes its conformation to bind to these two different mRNA targets and thereby inhibits H-NS translation, while stimulating that of RpoS in a mechanistically distinct fashion. DsrA apparently binds both the start and the stop codons of hns mRNA and sharply decreases the mRNA half-life. DsrA also binds sequences in the 5′-untranslated leader region of rpoS mRNA, enhancing rpoS mRNA stability and RpoS translation. A cohort of genes, governed by H-NS repression and RpoS activation, are thus regulated. Low temperatures increase the levels of DsrA, with differential effects on H-NS and RpoS. Additionally, the RNA chaperone protein Hfq is involved with DsrA regulation, as well as with other small RNAs that also act on RpoS to co-ordinate stress responses. We address the possible functions of this genetic regulatory mechanism, as well as the advantages of using small RNAs as global regulators to orchestrate gene expression.

Notes: Enteropathogenic Escherichia coli (EPEC) produces attaching and effacing lesions (AE) on epithelial cells. The genes involved in the formation of the AE lesions are contained within a pathogenicity island named the locus of enterocyte effacement (LEE). The LEE comprises 41 open reading frames organized in five major operons: LEE1, LEE2, LEE3, LEE4 and tir. The first gene of the LEE1 operon encodes a transcription activator of the other LEE operons that is called the LEE-encoded regulator (Ler). The LEE2 and LEE3 operons are divergently transcribed with overlapping −10 promoter regions, and gene fusion studies have shown that they are both activated by Ler. Deletion analysis, using lacZ reporter fusions, of the LEE2 and LEE3 promoters demonstrated that deletions extending closer to the LEE2 transcription start site than −247 bp lead to loss of activation by Ler, whereas only 70 bp upstream of the LEE3 transcription start site is required for Ler-mediated activation. We have purified Ler as a His-tagged protein and used it to perform DNA-binding assays with LEE2 and LEE3. We observed that Ler bound to a DNA fragment containing the −300 to +1 region of LEE2; however, it failed to bind to a DNA fragment containing the −300 to +1 region of LEE3, suggesting that Ler activates both operons by only binding to the regulatory region upstream of LEE2. The Ler-activatable LEE3::lacZ fusions extended to what would be −246 bp of the LEE2 operon. A lacZ fusion from the −300 to +1 region of LEE3 failed to be activated by Ler, consistent with our hypothesis that Ler activates the expression of LEE2 and LEE3 by binding to a region located downstream of the LEE3 transcription start site. DNase I footprinting revealed that Ler protected a region of 121 bp upstream of LEE2. Purified Ler mutated in the coiled-coil domain was unable to activate transcription and to bind to the LEE2 regulatory region. These data indicate that Ler may bind as a multimer to LEE2 and activate both divergent operons by a novel mechanism potentially involving changes in the DNA structure.

Notes: The quorum-sensing system in bacteria is a well-known regulatory system that controls gene expression in a cell density-dependent manner. A transcriptional regulator (LuxR homologue), signal synthase (LuxI homologue) and autoinducer (acyl homoserine lactone) are indispensable for this system in most Gram-negative bacteria. In this study, we found that SdiA, an Escherichia coli LuxR homologue, is a negative regulator of the expression of virulence factors EspD and intimin in enterohaemorrhagic E. coli (EHEC) O157:H7. The expression of EspD and intimin was inhibited at the RNA level upon SdiA overexpression. SdiA has a DNA-binding motif in its C-terminal part and can bind to the promoter regions of the esp and eae genes in vitro. Extracellular factors, which accumulate in culture supernatants of O157:H7 at the stationary phase of growth and inhibit EspD and intimin synthesis, bind to the N-terminal part of SdiA in vivo and in vitro. O157:H7 overproducing the N-terminal part of SdiA exhibited hypertranscription of EspD and intimin, suggesting that the overproduced N-terminal part had inhibited the activity of intact SdiA through titration of the extracellular factors. These results indicate that a quorum-sensing system including the SdiA protein controls colonization by O157:H7.

Notes: In Escherichia coli, the anaerobic expression of genes encoding the nitrate (narGHJI) and dimethyl sulphoxide (dmsABC) terminal reductases is stimulated by the global anaerobic regulator FNR. The ability of FNR to activate transcription initiation has been proposed to be dependent on protein–protein interactions between RNA polymerase and two activating regions (AR) of FNR, FNR-AR1 and FNR-AR3. To further our understanding of the role of FNR-AR1 and FNR-AR3 in transcription activation, we measured the effects of FNR-AR mutants on expression of the narG and dmsA promoters, PnarG and PdmsA. All the FNR-AR1 (FNR-S73F, FNR-T118A, FNR-S187P), FNR-AR3 (FNR-G85A) and FNR-AR1-AR3 (FNR-G85A-S187P) mutants that were tested decreased expression from PnarG and PdmsAin vivo. Transcription assays of PdmsA also showed that the FNR-AR mutant proteins impaired transcription activation in vitro. Furthermore, DNase I footprinting analysis confirmed that this transcription defect was not a result of altered DNA-binding properties. The function of FNR-S187P and FNR-G85A was also measured in strains containing σ70 mutants (σ70-K593A, σ70-R596A and σ70-K597A) known to be impaired in FNR-dependent transcription activation. Of all of the combinations analysed, only FNR-G85 and σ70-K597 showed a genetic interaction, supporting the notion that FNR-AR3 and σ70 interact functionally in the process of transcription activation. Lastly, the transcription activation defect of the FNR-AR1 and FNR-AR3 mutants was greatly reduced when expression of PnarG was assayed in the presence of nitrate. As these growth conditions promote maximal activity of PnarG as a result of the combined function of NarL, IHF and FNR, these results suggest that the requirements for FNR-AR1 and FNR-AR3 are altered in the presence of additional activators.

Notes: The class B M1-V577 penicillin-binding protein (PBP) 3 of Escherichia coli consists of a M1–L39 membrane anchor (bearing a cytosolic tail) that is linked via a G40–S70 intervening peptide to an R71–I236 non-catalytic module (containing the conserved motifs 1–3) itself linked via motif 4 to a D237–V577 catalytic module (containing the conserved motifs 5–7 of the penicilloyl serine transferases superfamily). It has been proposed that during cell septation the peptidoglycan crosslinking activity of the acyl transferase module of PBP3 is regulated by the associated M1–I236 polypeptide itself in interaction with other components of the divisome. The fold adopted by the R71–V577 polypeptide of PBP3 has been modelled by reference to the corresponding R76–S634 polypeptide of the class B Streptococcus pneumoniae PBP2x. Based on these data and the results of site-directed mutagenesis of motifs 1–3 and of peptide segments of high amphiphilicity (identified from hydrophobic moment plots), the M1–I236 polypeptide of PBP3 appears to be precisely designed to work in the way proposed. The membrane anchor and the G40–S70 sequence (containing the G57–Q66 peptide segment) upstream from the non-catalytic module have the information ensuring that PBP3 undergoes proper insertion within the divisome at the cell septation site. Motif 1 and the I74–L82 overlapping peptide segment, motif 2 and the H160–G172 overlapping peptide segment, and the G188–D197 motif 3 are located at or close to the intermodule junction. They contain the information ensuring that PBP3 folds correctly and the acyl transferase catalytic centre adopts the active configuration. The E206–V217 peptide segment is exposed at the surface of the non-catalytic module. It has the information ensuring that PBP3 fulfils its cell septation activity within the fully complemented divisome.

Notes: Helicobacter pylori cells are naturally competent for the uptake of both plasmid and chromosomal DNA. However, we demonstrate that there are strong barriers to transformation of H. pylori strains by plasmids derived from unrelated strains. We sought to determine the molecular mechanisms underlying these barriers. Transformation efficiency was assessed using pHP1, an Escherichia coli–H. pylori shuttle vector conferring kanamycin resistance. Transformation of 33 H. pylori strains was attempted with pHP1 purified from either E. coli or H. pylori, and was successfully introduced into only 11 strains. Digestion of H. pylori chromosomes with different restriction endonucleases (REs) showed that DNA methylation patterns vary substantially among strains. The strain most easily transformed, JP26, was found to have extremely low endogenous RE activity and to lack a restriction–modification (R–M) system, homologous to MboI, which is highly conserved among H. pylori strains. When we introduced this system to JP26, pHP1 from MboI.M+ JP26, but not from wild-type JP26, transformed MboI R−M+ JP26 and heterologous MboI R−M+ wild-type H. pylori strains. Parallel studies with pHP1 from dam+ and dam−E. coli strains confirmed these findings. These data indicate that the endogenous REs of H. pylori strains represent a critical barrier to interstrain plasmid transfer among H. pylori.

Notes: The pilus of Neisseria gonorrhoeae (the gonococcus Gc), the causative agent of gonorrhoea, promotes attachment of the gonococcus to the host epithelium and is essential for the establishment of disease. The ability of N. gonorrhoeae to infect previously exposed individuals is partially due to pilus antigenic variation. In addition, variation of the pilus has been proposed to function in the adaptation of the gonococcus to host environments. Previously, we described the development of a competitive reverse transcriptase (RT)-PCR assay that quantifies the frequency of pilin antigenic variation within a gonococcal population. Using this assay, the effect of different biologically relevant environmental conditions on the frequency of pilin antigenic variation was tested. Of the environmental conditions examined in vitro, only limited iron affected a significant change in the frequency of antigenic variation. Further investigation revealed that an observed increase in pilin antigenic variation reflected an increase in other DNA recombination and DNA repair processes within iron-starved cultures. In addition, this low iron-induced increase was determined to be independent of changes in RecA expression and was observed in a Fur mutant strain. As gonococci encounter conditions of low iron during infection, these data suggest that iron-limitation signals for increased recombinational events that are important for gonococcal pathogenesis.

Notes: IHF (integration host factor) mutants exhibit asynchronous initiation of chromosome replication from oriC as determined from flow cytometric analysis of cultures where RNA synthesis was inhibited with rifampicin. However, the run-out kinetics of chromosome replication in ihf mutants shows that they continue to produce oriCs for some time in the absence of RNA synthesis resulting in a twofold increase in the oriC per mass ratio. An ihf dnaA double mutant did not exhibit this continued increase of the oriC per mass ratio. This indicates that ihf mutants can initiate replication from oriC in a rifampicin-resistant initiation mode but requires fully functional DnaA protein. The origin per mass ratio, determined by a quantitative Southern blotting technique, showed that the ihf mutants had an origin per mass ratio that was 60% of the wild type although it had a normal DnaA protein concentration. This shows that the initiation mass was substantially higher in the ihf mutants. The oriC per terminus ratio, which was also determined by Southern blotting, was very low in the ihf mutant, although it grew with the same doubling times as the wild-type strain. This indicates that cells lacking IHF replicate their chromosome(s) very fast.

Notes: Several strains of the human opportunistic pathogen Pseudomonas aeruginosa infect plants, nematodes and insects. Our laboratory has developed a multihost pathogenesis system based on the P. aeruginosa clinical isolate PA14, in which non-mammalian hosts are used to screen directly for virulence-attenuated mutants. The majority of PA14 mutants isolated using non-mammalian hosts also displayed reduced virulence in a burned mouse model. Surprisingly, only a few host-specific virulence factors were identified, and many of the P. aeruginosa mutants were attenuated in virulence in all the hosts. These studies illustrate the extensive conservation in the virulence mechanisms used by P. aeruginosa to infect evolutionarily diverged hosts, and validate the multihost method of screening for virulence factors relevant to mammalian pathogenesis. Through the use of genetically tractable hosts, the multihost pathogenesis model also provides tools for elucidating host responses and dissecting the fundamental molecular interactions that underlie bacterial pathogenesis.

Notes: A meningococcal genomic expression library was screened for potent CD4+ T-cell antigens, using patients' peripheral blood lymphocytes (PBLs). One of the most promising positive clones was fully characterized. The recombinant meningococcal DNA contained a single, incomplete, open reading frame (ORF), which was fully reconstructed with reference to available genomic sequence data. The gene was designated autA (auto-transporter A) as its peptide sequence shares molecular characteristics of the auto-transporter family of proteins. Only a single copy of this gene was detected in the meningococcal, and none in the gonococcal, genomic sequence databases. The complete autA gene, when cloned into an expression vector, expressed a protein of approximately 68 kDa. Purified rAutA recalled strong secondary T-cell responses in PBLs of patients and some healthy donors, and induced strong primary T-cell responses in healthy donors. The human B-cell immunogenicity and cross-reactivity of AutA, purified under native conditions, was confirmed in dot immunoblot experiments. Immunoblots with rabbit polyclonal antibodies to rAutA demonstrated the conserved nature, antigenicity and cross-reactivity of AutA amongst meningococci of different serogroups and strains representing different hypervirulent lineages. AutA showed homology with another meningococcal and gonococcal ORF (designated AutB). AutB was cloned and expressed and used to raise an autB-specific antiserum. Immunoblot experiments indicated that AutB is not expressed in meningococci and does not cross-react with AutA. Thus, AutA, being a potent CD4+ T-cell and B-cell-stimulating antigen, which is highly conserved, deserves further investigation as a potential vaccine candidate.

Notes: A number of well-known bacterial toxins ADP-ribosylate and thereby inactivate target proteins in their animal hosts. Recently, several vertebrate ecto-enzymes (ART1–ART7) with activities similar to bacterial toxins have also been cloned. We show here that psiblast, a position-specific-iterative database search program, faithfully connects all known vertebrate ecto-mono(ADP-ribosyl)transferases (mADPRTs) with most of the known bacterial mADPRTs. Intriguingly, no matches were found in the available public genome sequences of archaeabacteria, the yeast Saccharomyces cerevisiae or the nematode Caenorhabditis elegans. Significant new matches detected by psiblast from the public sequence data bases included only one open reading frame (ORF) of previously unknown function: the spvB gene contained in the virulence plasmids of Salmonella enterica. Structure predictions of SpvB indicated that it is composed of a C-terminal ADP-ribosyltransferase domain fused via a poly proline stretch to a N-domain resembling the N-domain of the secretory toxin TcaC from nematode-infecting enterobacteria. We produced the predicted catalytic domain of SpvB as a recombinant fusion protein and demonstrate that it, indeed, acts as an ADP-ribosyltransferase. Our findings underscore the power of the psiblast program for the discovery of new family members in genome databases. Moreover, they open a new avenue of investigation regarding salmonella pathogenesis.

Notes: Expression of the Saccharomyces cerevisiae nuclear gene CYB2 encoding the mitochondrial enzyme l-(+)-lactate–cytochrome c oxidoreductase (EC 1.2.2.3) is subject to several strict metabolic controls at the transcriptional level: repression due to glucose fermentation, derepression by ethanol, induction by lactate and inhibition under anaerobic conditions or in response to deficiency of haem biosynthesis. In this respect, the data obtained from the transcriptional analysis of the CYB2 gene contribute to a better understanding of the control of mitochondrial biogenesis. In this study, we show that Hap1p is the main transcriptional activator involved in the control of CYB2 transcription. We found that Hap1p activity, known to be oxygen dependent, is effected by DNA–protein interaction with two binding sites present in the CYB2 promoter. Control is moreover dependent on carbon sources. This regulation by the carbon substrates is subordinate to the activity of the complex Hap2/3/4/5p, which counteracts the negative effect of the URS1 element. Finally, our results suggest that the Adr1p transcriptional activator is also required in CYB2 transcription control. This work provides new data which allows a better understanding of the molecular mechanisms implicated in the co-regulation at the transcriptional level of the genes encoding proteins involved in various aspects of oxidative metabolism.

Notes: Salmonella species translocate effector proteins into the host cell cytoplasm using a type III secretion system (TTSS). The translocation machinery probably contacts the eukaryotic cell plasma membrane to effect protein transfer. Data presented here demonstrate that both SspB and SspC, components of the translocation apparatus, are inserted into the epithelial cell plasma membrane 15 min after Salmonella typhimurium infection. In addition, a yeast two-hybrid interaction between SspC and an eukaryotic intermediate filament protein was identified. Three individual carboxyl-terminal point mutations within SspC that disrupt the yeast two-hybrid interaction were isolated. Strains expressing the mutant SspC alleles were defective for invasion, translocation of effector molecules and membrane localization of SspC. These data indicate that insertion of SspC into the plasma membrane of target cells is required for invasion and effector molecule translocation and that the carboxyl terminus of SspC is essential for these functions.

Notes: The pilus antigenic variation (Av) system of Neisseria gonorrhoeae is one of several high-frequency variation systems that utilize gene conversion to switch between numerous forms of an antigen on the cell surface. We have tested three predictions of the first models that explain the movement of DNA during pilin Av: (i) Av requires two recombinations at short regions of identity, (ii) circular intermediates exist that carry pilE/pilS hybrid loci and (iii) these pilE/pilS hybrid loci target the pilS sequences to a recipient pilE gene. We confirm that normal pilin Av utilizes recombination at very short regions of DNA sequence identity and that these recombination events can occur independent of homologous recombination functions. We have isolated covalently closed circular DNA molecules carrying hybrid pilin loci, but propose that an alternative hybrid molecule is the intermediate of pilin Av. Our most striking finding is that transformation of isolated pilE/pilS hybrid loci targets the pilS sequences of the hybrid to a recipient pilE at frequencies much higher than normal recombination frequencies. These results show that the different steps of a model that explains pilin Av can be separately tested to support the validity of these novel models that account for the high-frequency gene conversions that mediate pilin Av.

Notes: In Bacillus subtilis, the ComQXPA quorum-sensing system controls cell density-dependent phenotypes such as the production of degradative enzymes and antibiotics and the development of genetic competence. Bacillus subtilis (natto) NAF12, a mutant defective in poly-γ-glutamate (γ-PGA) production, was derived from B. subtilis (natto) NAF4 by Tn917-LTV1 insertional mutagenesis. Determination of the mutant DNA sequences flanking the Tn917-LTV1 insert revealed that the insertion had inactivated comP in this mutant, indicating that γ-PGA synthesis in B. subtilis (natto) is under the control of the ComP–ComA signal transduction system. A comparison of the amino acid sequences revealed striking variation in the primary structures of ComQ (44% identity), ComX (26%) and the sensor domain of ComP (36%) between B. subtilis (natto) NAF4 and B. subtilis 168. In contrast, the amino acid and nucleotide sequences of the kinase domains of ComP and of the ComA response regulator share 95% and 100% identity respectively. The comP genes of NAF4 and 168 restored the impaired competence of B. subtilis BD1658 (comP::cat) and γ-PGA production of B. subtilis (natto) NAF12 (comP::Tn917-LTV1) to only 15% of the level achieved by the respective parent comP genes. However, when introduced together with the cognate comQ and comX genes, the comP genes restored the relevant defect of the heterologous comP mutants nearly to wild-type levels. Analogous to the comCDE system of Streptococcus strains and the agrBCDE system of Staphylococcus aureus, the concerted variation in the comQXP genes appears to establish specific intercellular communication between B. subtilis strains sharing the same pheromone system.

Notes: The spo0A genes of Clostridium beijerinckii NCIMB 8052 and Clostridium cellulolyticum ATCC 35319 were isolated and characterized. The C-terminal DNA-binding domains of the predicted products of spo0A from these two organisms, as well as 16 other taxonomically diverse species of Bacillus and Clostridium, show extensive amino acid sequence conservation (56% identity, 65% similarity over 104 residues). A 12-amino-acid motif (SRVERAIRHAIE) that forms the putative DNA recognition helix is particularly highly conserved, suggesting a common DNA target. Insertional inactivation of spo0A in C. beijerinckii blocked the formation of solvents (as well as spores and granulose). Sequences resembling Spo0A-binding motifs (TGNCGAA) are found in the promoter regions of several of the genes whose expression is modulated at the onset of solventogenesis in Clostridium acetobutylicum and C. beijerinckii. These include the upregulated adc gene, encoding acetoacetate decarboxylase (EC 4.1.1.4), and the downregulated ptb gene, encoding phosphotransbutyrylase (EC 2.3.1.c). In vitro gel retardation experiments using C. acetobutylicum adc and C. beijerinckii ptb promoter fragments and recombinant Bacillus subtilis and C. beijerinckii Spo0A suggested that adc and ptb are directly controlled by Spo0A. The binding affinity was reduced when the 0A boxes were destroyed, and enhanced when they were modified to conform precisely to the consensus sequence. In vivo analysis of wild-type and mutagenized promoters transcriptionally fused to the gusA reporter gene in C. beijerinckii validated this hypothesis. Post-exponential phase expression from the mutagenized adc promoter was substantially reduced, whereas expression from the mutagenized ptb promoter was not shut down at the end of exponential growth.

Notes: The Cpx envelope stress response of Escherichia coli is controlled by a two-component regulatory system that senses misfolded proteins in extracytoplasmic compartments and responds by inducing the expression of envelope protein folding and degrading factors. We have proposed that in the absence of envelope stress the pathway is maintained in a downregulated state, in part through interactions between the periplasmic inhibitor molecule CpxP and the sensing domain of the histidine kinase CpxA. In this study, we show that depletion of the periplasmic contents of the cell by spheroplast formation does indeed lead to induction of the Cpx envelope stress response. Further, removal of CpxP is an important component of this induction because tethering an MBP–CpxP fusion protein to the spheroplast inner membranes prevents full activation by this treatment. Spheroplast formation has previously been demonstrated to induce the expression of a periplasmic protein of unknown function, Spy. Analysis of spy expression in response to spheroplast formation by Western blot analysis and by lacZ operon fusion in various cpx mutant backgrounds demonstrated that spy is a member of the Cpx regulon. Interestingly, although the only known spy homologue is cpxP, Spy does not appear to perform the same function as CpxP as it is not involved in inhibiting the Cpx envelope stress response. Rather, deletion of spy leads to activation of the σE stress response. Because the σE response is specifically affected by alterations in outer membrane protein biogenesis, we think it possible that Spy may be involved in this process.

Notes: The two-component regulatory proteins ResD and ResE are required for anaerobic nitrate respiration in Bacillus subtilis. ResD, when it undergoes ResE-dependent phosphorylation, is thought to activate transcriptionally anaerobically induced genes such as fnr, hmp and nasD. In this report, deletion analysis of the fnr, hmp and nasD promoter regions was carried out to identify cis-acting sequences required for ResDE-dependent transcription. The results suggest that the hmp and nasD promoters have multiple target sequences for ResDE-dependent regulation and that fnr has a single target site. Gel mobility shift assays and DNase I footprinting analyses were performed to determine whether ResD interacts directly with the regulatory regions of the three genes. Our results indicate that ResD specifically binds to sequences residing upstream of the hmp and nasD promoters and that phosphorylation of ResD significantly stimulates this binding. In contrast, a higher concentration of ResD is required for binding to the fnr promoter region and no stimulation of the binding by ResD phosphorylation was observed. Taken together, these results suggest that ResD activates transcription of fnr, hmp and nasD by interacting with DNA upstream of these promoters. Our results suggest that phosphorylation of ResD stimulates binding to multiple ResD binding sites, but is much less stimulatory if only a single binding site exists.

Notes: A two-component signal transduction system composed of a sensor kinase, ResE, and a response regulator, ResD, encoded by resD and resE genes of the res operon (resABCDE), has a regulatory role in both aerobic and anaerobic respiration. In terms of aerobic respiration, resD functions upstream of ctaA, a gene required for haem A biogenesis and hence for the synthesis of haem A-containing cytochrome terminal oxidases. Although ResD is probably a transcription factor, there was no direct evidence that ResD protein, either phosphorylated or unphosphorylated, interacts directly with regulatory regions of ResD-controlled genes. Here, we report the overexpression and purification of ResD and ResE and their role in gene activation. ResD can be phosphorylated by ResE in vitro and is a monomer in solution in either the phosphorylated or unphosphorylated state. The binding activity of ResD to the ctaA promoter was examined by gel shift assays and DNase I footprinting assays. DNase I footprinting showed both unphosphorylated and phosphorylated ResD binding to the ctaA promoter and showed that there are three binding sites (A1, A2 and A3), two (A1 and A2) upstream of the −35 promoter region and one (A3) downstream of the −10 of the promoter. The role of each site in ctaA promoter activity and ResD binding was characterized using deletion analysis, followed by the DNase I footprinting and in vivo transcription assays of promoter–lacZ fusions. Our results showed that the concentration of ResD required to bind at each site is different and that ResD binding at the A1 site is independent of the other two ResD binding sites, but that the concentration of ResD∼P required to protect site A2 is reduced when site A3 is present. In vivo transcription assays from promoter–lacZ fusion constructs showed that DNA containing ResD-binding site A2 was essential for promoter activity and that promoter constructs containing both binding sites A2 and A3 were sufficient for full promoter activity.

Notes: The flhDC operon of Salmonella typhimurium is the master control operon required for the expression of the entire flagellar regulon. The flagellar master operon was placed under the tetracycline-inducible promoter PtetA using the T-POP transposon. Cells containing this construct are motile in the presence of tetracycline and non-motile without inducer present. No flagella were visible under the electron microscope when cells were grown without inducer. The class 1, class 2 and class 3 promoters of the flagellar regulon are temporally regulated. After addition of tetracycline, the class 1 flhDC operon was transcribed immediately. Transcription of flgM (which is transcribed from both class 2 and class 3 promoters) began 15 min after induction. At 20 min after induction, the class 2 fliA promoter became active and intracellular FliA protein levels increased; at 30 min after induction, the class 3 fliC promoter was activated. Induction of fliC gene expression coincides with the appearance of FlgM anti-sigma factor in the growth medium. This also coincides with the completion of hook–basal body structures. Rolling cells first appeared 35 min after induction, and excess hook protein (FlgE) was also found in the growth medium at this time. At 45 min after induction, nascent flagellar filaments became visible in electron micrographs and over 40% of the cells exhibited some swimming behaviour. Multiple flagella assemble and grow on individual cells after induction of the master operon. These results confirm that the flagellar regulatory hierarchy of S. typhimurium is temporally regulated after induction. Both FlgM secretion and class 3 gene expression occur upon completion of the hook–basal body structure.

Notes: Nitrogen metabolism in Aspergillus nidulans is regulated by AREA, a member of the GATA family of transcription factors. One mechanism that modulates AREA activity involves the rapid degradation of the areA transcript when sufficient NH4+ or Gln are available. This signalling mechanism has been shown to require a region of 218 nucleotides within the 3′ untranslated region of areA mRNA. We demonstrate that this region functions independently in a heterologous transcript and acts to accelerate degradation of the poly(A) tail, which in turn leads to rapid transcript degradation in response to the addition of NH4+ or Gln to the growth medium. areA transcript degradation is inhibited by cycloheximide, but this is not a general consequence of translational inhibition. We believe that this is the first reported example in which specific physiological signals, acting through a defined sequence within a transcript, have been shown to promote accelerated poly(A) degradation, which in turn triggers transcript degradation.

Notes: Many strains of the important human pathogen Streptococcus pyogenes form aggregates when grown in vitro in liquid medium. The present studies demonstrate that this property is crucial for the adherence, the resistance to phagocytosis and the virulence of S. pyogenes. A conserved sequence of 19 amino acid residues (designated AHP) was identified in surface proteins of common S. pyogenes serotypes. This sequence was found to promote bacterial aggregation through homophilic protein–protein interactions between AHP-containing surface proteins of neighbouring bacteria. A synthetic AHP peptide inhibited S. pyogenes aggregation, reduced the survival of S. pyogenes in human blood and attenuated its virulence in mice. In contrast, mutant bacteria devoid of surface proteins containing AHP-related sequences did not aggregate or adhere to epithelial cells. These bacteria are also rapidly killed in human blood and show reduced virulence in mice, underlining the pathogenic significance of the AHP sequence and S. pyogenes aggregation.

Notes: Transcription of the type IV pilus subunit gene of Pseudomonas aeruginosa is controlled by a two-component signal transduction system. PilS, the histidine kinase, is membrane bound and PilR, its cognate response regulator, is cytoplasmic. The signal that activates PilS is unknown. PilS has three domains: (i) The N-terminus, predicted to form six transmembrane (TM) helices; (ii) a central linker domain; and (iii) the C-terminal transmitter domain containing all the conserved residues of sensor kinases. A translational fusion of the gfp gene (green fluorescent protein) to the 3′ end of pilS was used to determine the position of PilS in the bacterial cell. Epifluorescence microscopy revealed that PilS is retained to the poles of P. aeruginosa but is distributed evenly about the membrane of Escherichia coli. Deletions of the PilS–GFP fusion revealed that the TM domain was sufficient and necessary to bring GFP to the membrane of P. aeruginosa and E. coli but was not sufficient to confine GFP to the poles. Retention to the poles of P. aeruginosa required both the TM and linker domains. Replacement of the PilS TM domain with an E. coli membrane protein, MalG, still allowed polar localization. Therefore, the PilS TM domain positions the linker domain close to the membrane allowing it to interact with the putative polar anchor which is specific to P. aeruginosa.

Notes: NC2 (Dr1/DRAP1) and Mot1p are global repressors of transcription that have been isolated in both Saccharomyces cerevisiae and humans. NC2 is a dimeric histone-fold complex that represses RNA polymerase II transcription through binding to TBP and inhibition of TFIIA and TFIIB. Mot1p is an ATPase that removes DNA-bound TBP upon ATP hydrolysis. In this work, we studied the core promoter specificity of NC2 in vivo using a strain that carries mutated NC2β activity. We show that NC2, like Mot1p, is required for transcription of the HIS3 and HIS4 TATA-less core promoters. Furthermore, whereas neither Mot1p nor NC2 appear to function as repressors of the HIS3 gene in cells growing exponentially in glucose, we find that both are required for repression of the HIS3 TATA promoter when cells go through the diauxic shift. Thus, the activity of these factors is similarly regulated depending upon the physiological conditions, and it appears that core promoters activated or repressed by them in vivo might be distinguishable by whether or not they contain a canonical TATA sequence. Finally, although NC2 is an essential factor for yeast viability, we isolated a mutation in a non-essential component of the holoenzyme, Sin4p, that bypasses the requirement for NC2.

Notes: Screening of an Aspergillus niger differential cDNA library, constructed by subtracting cDNA fragments of a xlnR loss-of-function mutant from wild-type cDNA fragments, resulted in the cloning of the gene encoding d-xylose reductase (xyrA). Northern blot analysis using an A. niger wild-type strain, a xlnR multiple-copy strain and a xlnR loss-of-function mutant confirmed that the xyrA gene is regulated by XlnR, the transcriptional activator of the xylanolytic enzyme system in A. niger. d-xylose reductase catalyses the NADPH-dependent reduction of d-xylose to xylitol, which is the first step in d-xylose catabolism in fungi. Until now, XlnR was shown to control the transcription of genes encoding extracellular hydrolytic enzymes involved in cellulose and xylan degradation. In the present study, we show that A. niger is able to harmonize its sugar metabolism and extracellular xylan degradation via XlnR by regulating the expression of XyrA.

Notes: The Escherichia coli MelR protein is a transcription activator that, in the presence of melibiose, activates expression of the melAB operon by binding to four sites located just upstream of the melAB promoter. MelR is encoded by the melR gene, which is expressed from a divergent transcript that starts 237 bp upstream of the melAB promoter transcript start point. In a recent study, we have identified a fifth DNA site for MelR that overlaps the melR promoter transcript start and −10 region. Here we show that MelR binding to this site can downregulate expression from the melR promoter; thus, MelR autoregulates its own expression. Optimal repression of the melR promoter is observed in the absence of melibiose and requires one of the four other DNA sites for MelR at the melAB promoter. The two MelR binding sites required for this optimal repression are separated by 177 bp. We suggest that, in the absence of melibiose, MelR forms a loop between these two sites. We argue that, in the presence of melibiose, this loop is broken as the melAB promoter is activated. However, in the presence of melibiose, the melR promoter can still be partially repressed by MelR binding to the site that overlaps the transcript start and −10 region. Parallels with the Escherichia coli araC–araBAD regulatory region are discussed.

Notes: The Rab/Ypt small G proteins are essential for intracellular vesicle trafficking in mammals and yeast. The vesicle-docking process requires that Ypt proteins are located in the vesicle membrane. C-terminal geranylgeranyl anchors mediate the membrane attachment of these proteins. The Rab escort protein (REP) is essential for the recognition of Rab/Ypt small G proteins by geranylgeranyltransferase II (GGTase II) and for their delivery to acceptor membranes. What effect an alteration in the levels of prenylated Rab/Ypt proteins has on vesicle transport or other cellular processes is so far unknown. Here, we report the characterization of a yeast REP mutant, mrs6-2, in which reduced prenylation of Ypt proteins occurs even at the permissive temperature. A shift to the restrictive temperature does not alter exponential growth during the first 3 h. The amount of Sec4p, but not Ypt1p, bound to vesicle membranes is reduced 2.5 h after the shift compared with wild-type or mrs6-2 cells incubated at 25°C. In addition, vesicles fail to be polarized towards the bud and small budded binucleate cells accumulate at this time point. Growth in 1 M sorbitol or overexpression of MLC1, encoding a myosin light chain able to bind the unconventional type V myosin Myo2, or of genes involved in cell wall maintenance, such as SLG1, GFA1 and LRE1, suppresses mrs6-2 thermosensitivity. Our data suggest that, at least at high temperature, a critical minimal level of Ypt protein prenylation is required for maintaining vesicle polarization.

Notes: Using a combined in vivo and in vitro approach, we demonstrated that the transposition products generated by IS911 from a dimeric donor plasmid are different from those generated from a plasmid monomer. When carried by a monomeric plasmid donor, free IS911 transposon circles are generated by intra-IS recombination in which one IS end undergoes attack by the other. These represent transposition intermediates that undergo integration using the abutted left (IRL) and right (IRR) ends of the element, the active IRR–IRL junction, to generate simple insertions. In contrast, the two IS911 copies carried by a dimeric donor plasmid not only underwent intra-IS recombination to generate transposon circles but additionally participated in inter-IS recombination. This also creates an active IRR–IRL junction by generating a head-to-tail IS tandem dimer ([IS]2) in which one of the original plasmid backbone copies is eliminated in the formation of the junction. Both transposon circles and IS tandem dimers are generated from an intermediate in which two transposon ends are retained by a single strand joint to generate a figure 8 molecule. Inter-IS figure 8 molecules generated in vitro could be resolved into the [IS]2 form following introduction into a host strain by transformation. Resolution did not require IS911 transposase. The [IS]2 structure was stable in the absence of transposase but was highly unstable in its presence both in vivo and in vitro. Previous studies had demonstrated that the IRR–IRL junction promotes efficient intermolecular integration and intramolecular deletions both in vivo and in vitro. Integration of the [IS]2 derivative would result in a product that resembles a co-integrate structure. It is also shown here that the IRR–IRL junction of the [IS]2 form and derivative structures can specifically target one of the other ends in an intramolecular transposition reaction to generate transposon circles in vitro. These results not only demonstrate that IS911 (and presumably other members of the IS3 family) is capable of generating a range of transposition products, it also provides a mechanistic framework which explains the formation and activity of such structures previously observed for several other unrelated IS elements. This behaviour is probably characteristic of a large number of IS elements.

Notes: Lateral gene transfer (LGT) is a major force in microbial genome evolution. Here, we present an overview of lateral transfers affecting genes involved in isopentenyl diphosphate (IPP) synthesis. Two alternative metabolic pathways can synthesize this universal precursor of isoprenoids, the 1-deoxy-d-xylulose 5-phosphate (DOXP) pathway and the mevalonate (MVA) pathway. We have surveyed recent genomic data and the biochemical literature to determine the distribution of the genes composing these pathways within the bacterial domain. The scattered distribution observed is incompatible with a simple scheme of vertical transmission. LGT (among and between bacteria, archaea and eukaryotes) more parsimoniously explains many features of this pattern. This alternative scenario is supported by phylogenetic analyses, which unambiguously confirm several cases of lateral transfer. Available biochemical data allow the formulation of hypotheses about selective pressures favouring transfer. The phylogenetic diversity of the organisms involved and the range of possible causes and effects of these transfer events make the IPP biosynthetic pathways an ideal system for studying the evolutionary role of LGT.

Notes: The commercially important bacterium Lactococcus lactis contains two FNR-like proteins (FlpA and FlpB) which have a high degree of identity to each other and to the FLP of Lactobacillus casei. FlpA was isolated from a GST–FlpA fusion protein produced in Escherichia coli. Like FLP, isolated FlpA is a homodimeric protein containing both Zn and Cu. However, the properties of FlpA were more like those of the E. coli oxygen-responsive transcription factor FNR than the FLP of L. casei. As prepared FlpA recognized an FNR site (TTGAT-N4-ATCAA) but not an FLP site (CCTGA-N4-TCAGG) in band-shift assays. In contrast to FLP, DNA binding by FlpA did not require the formation of an intramolecular disulphide bond. However, despite containing only two cysteine residues per monomer, FlpA was able to acquire an FNR-like, oxygen-labile [4Fe 4S] cluster. But, whereas the incorporation of a [4Fe 4S] cluster into FNR enhances interaction with target DNA, it abolished DNA binding by FlpA. An FlpA variant (FlpA′) with an N-terminal region designed to be more FLP-like failed to incorporate an iron–sulphur cluster but could now form an intramolecular disulphide. This simple example of protein engineering, converting an oxygen-labile [4Fe 4S] containing FNR-like protein into a dithiol–disulphide FLP-like redox sensor demonstrates the versatility of the basic CRP structure. Attempts to demonstrate an FlpA-based aerobic–anaerobic switch in the heterologous host E. coli were unsuccessful. However, studies with a series of FNR-dependent lac reporter fusions in strains of E. coli expressing flpA or flpB revealed that both homologues were able to activate expression of FNR-dependent promoters in vivo but only when positioned 61 base pairs upstream of the transcription start.

Notes: MarR, the negative regulator of the Escherichia coli multiple antibiotic resistance (marRAB) operon, is a member of a newly recognized family of regulatory proteins. The amino acid sequences of these proteins do not display any apparent homologies to the DNA binding domains of prokaryotic transcription regulators and a DNA binding motif for any one of the MarR homologues is currently unknown. In order to define regions of MarR required for DNA binding, mutant repressors, selected based on their ability to interfere with (negatively complement) the activity of wild-type MarR, were isolated. As determined using gel mobility shift assays, 13 out of 14 negative complementing mutants tested were unable to bind DNA in vitro. Three negative complementing alleles presumably specify truncated repressors and one of these proteins, a 120 residue MarR, can bind DNA in vitro. Most of the negative complementing mutations were clustered within two areas of MarR with features related to a helix–turn–helix DNA binding motif. These regions are presumed to be required for the DNA binding activity of the repressor.

Notes: Saccharomyces cerevisiae PAU genes constitute the largest multigene family in yeast, with 23 members located mainly in subtelomeric regions. The role and regulation of these genes were previously unknown. We detected PAU gene expression during alcoholic fermentation. An analysis of PAU gene regulation using PAU–lacZ fusions and Northern analyses revealed that they were regulated by anaerobiosis. PAU genes display, however, different abilities to be induced by anaerobiosis and this appears to be related to their chromosomal localization; two subtelomeric copies are more weakly inducible than an interstitial one. We show that PAU genes are negatively regulated by oxygen and repressed by haem. Examination of PAU gene expression in rox1Δ and tup1Δ strains indicates that PAU repression by oxygen is mediated by an unknown, haem-dependent pathway, which does not involve the Rox1p anaerobic repressor but requires Tup1p. Given the size of the gene family, PAU genes could be expected to be important during yeast life and some of them probably help the yeast to cope with anaerobiosis.

Notes: Agrobacterium rhizogenes transfers DNA (T-DNA) from its Ri plasmid to plant cells. All T-DNA genes are expressed in plant cells. The rolA gene is the only T-DNA gene that contains an intron in the untranslated leader region of its mRNA. This paper shows that (i) the rolA gene is also transcribed in bacteria; (ii) the 85 bp corresponding to the spliceosomal intron drives prokaryotic gene expression in agrobacteria, in free-living rhizobia and in bacteroids within root nodules; and (iii) promoter activity is abolished by the deletion of 63 bp from its 5′ end and is reduced by mutations changing its sequence near the putative −10 region. The expression pattern of a chimeric reporter gene shows that, in free-living bacteria, gene expression takes place during the exponential phase of growth and increases at the onset of the stationary phase. Within root nodules, reporter gene expression occurs in the invasion, nitrogen fixing and senescent zones.

Notes: Antisense RNAs regulate plasmid replication by several different mechanisms. One of these mechanisms, transcriptional attenuation, was first described for the staphylococcal plasmid pT181, and later for the streptococcal plasmids pIP501 and pAMβ1. Previously, we performed detailed in vitro and in vivo analyses of the pIP501 system. Here, we present an in vitro analysis of the antisense system of plasmid pT181. The secondary structures of antisense and sense RNA species of different lengths were determined. Binding rate constants for sense/antisense RNA pairs were measured, and functional segments required for complex formation were determined. A single-round transcription assay was used for in vitro analysis of transcriptional attenuation. A comparison between pT181 and pIP501 revealed several differences; whereas a truncated derivative of pIP501 antisense RNA was sufficient for stable complex formation, both stem–loop structures of pT181-RNAI were required. In contrast to the sense RNA of pIP501, which showed an intrinsic propensity to terminate (30–50% in the absence of antisense RNA), the sense RNA of pT181 required antisense RNA for induced termination. Rate constants of formation of pT181 sense–antisense RNA complexes were similar to inhibition rate constants, in striking contrast to pIP501, in which inhibition occurred at least 10-fold faster than stable binding.

Notes: Haemophilus influenzae haemagglutinating pili are surface appendages that promote attachment to host cells and facilitate respiratory tract colonization, an essential step in the pathogenesis of disease. In contrast to other well-characterized forms of pili, H. influenzae haemagglutinating pili are two-stranded helical structures. Nevertheless, haemagglutinating pili are assembled by a pathway that involves a periplasmic chaperone and an outer membrane usher, analogous to the prototype pathway involved in the biogenesis of Escherichia coli P pili. In this study, we performed site-directed mutagenesis of the H. influenzae HifB chaperone and HifA major pilus subunit at positions homologous to sites important for chaperone–subunit interactions and subunit oligomerization in P pili. Mutations at putative subunit binding pocket residues in HifB or at the penultimate tyrosine in HifA abolished formation of HifB–HifA periplasmic complexes, whereas mutations at the −14 glycine in HifA had no effect on HifB–HifA interactions but abrogated HifA oligomerization. To define further the constraints of the interaction between HifA and HifB, we examined the interchangeability of pilus gene cluster components from H. influenzae type b strain Eagan (hifA-hifEEag) and the related H. influenzae biogroup aegyptius strain F3031 (hifA-hifEF3031). Functional pili were assembled both with HifAEag and the strain F3031 gene cluster and with HifAF3031 and the strain Eagan gene cluster, underscoring the flexibility of the H. influenzae chaperone/usher pathway in incorporating HifA subunits with significant sequence diversity. To gain additional insight into the interactive surfaces of HifA and HifB, we aligned HifA sequences from 20 different strains and then modelled the HifA structure based on the recently crystallized PapD–PapK complex. Analysis of the resulting structure revealed high levels of sequence conservation in regions predicted to interact with HifB, and maximal sequence diversity in regions potentially exposed on the surface of assembled pili. These results suggest broad applicability of structure–function relationships identified in studies of P pili, including the concepts of donor strand complementation and donor strand exchange. In addition, they provide insight into the structure of HifA and suggest a basis for antigenic variation in H. influenzae haemagglutinating pili.

Notes: Helicobacter pylori NCTC11637 expresses a lipopolysaccharide (LPS) that comprises an O antigen side-chain with structural homology to the human blood group antigen Lewis X (Lex). The role of this molecule in adhesion of H. pylori to gastric epithelial cells was investigated. Mutants expressing truncated LPS structures were generated through insertional mutagenesis of rfbM and galE; genes encode GDP mannose pyrophosphorylase and galactose epimerase respectively. Compositional and structural analysis revealed that the galE mutant expressed a rough LPS that lacked an O antigen side-chain. In contrast, an O antigen side-chain was still synthesized by the rfbM mutant, but it lacked fucose and no longer reacted with anti-Lex monoclonal antibodies (Mabs). The ability of these mutants to bind to paraffin-embedded sections from the antrum region of a human stomach was assessed. Adhesion of the wild type was characterized by tropic binding to the apical surface of mucosal epithelial cells and cells lining gastric pits. In contrast, both the rfbM and galE mutants failed to demonstrate tropic binding and adhered to the tissue surface in a haphazard manner. These results indicate that LPS and, more specifically, LeX structures in the O antigen side-chain play an important role in targeting H. pylori to specific cell lineages within the gastric mucosa. The role of LeX in this interaction was confirmed by the tropic binding of synthetic Lex, conjugated to latex beads, to gastric tissue. The observed pattern of adhesion was indistinguishable from that of wild-type H. pylori.

Notes: Exposure of Escherichia coli to a variety of DNA-damaging agents results in the induction of the global ‘SOS response’. Expression of many of the genes in the SOS regulon are controlled by the LexA protein. LexA acts as a transcriptional repressor of these unlinked genes by binding to specific sequences (LexA boxes) located within the promoter region of each LexA-regulated gene. Alignment of 20 LexA binding sites found in the E. coli chromosome reveals a consensus of 5′-TACTG(TA)5CAGTA-3′. DNA sequences that exhibit a close match to the consensus are said to have a low heterology index and bind LexA tightly, whereas those that are more diverged have a high heterology index and are not expected to bind LexA. By using this heterology index, together with other search criteria, such as the location of the putative LexA box relative to a gene or to promoter elements, we have performed computational searches of the entire E. coli genome to identify novel LexA-regulated genes. These searches identified a total of 69 potential LexA-regulated genes/operons with a heterology index of 〈 15 and included all previously characterized LexA-regulated genes. Probes were made to the remaining genes, and these were screened by Northern analysis for damage-inducible gene expression in a wild-type lexA+ cell, constitutive expression in a lexA(Def) cell and basal expression in a non-inducible lexA(Ind−) cell. These experiments have allowed us to identify seven new LexA-regulated genes, thus bringing the present number of genes in the E. coli LexA regulon to 31. The potential function of each newly identified LexA-regulated gene is discussed.

Notes: We identified an exported protease in Lactococcus lactis ssp. lactis strain IL1403 belonging to the HtrA/DegP family. Inactivation of the chromosomal gene (htrALl) encoding this protease (HtrALl) results in growth thermo-sensitivity at very high temperatures (above 37°C for L. lactis). The role of htrALl in extracellular proteolysis under normal growth conditions was examined by testing the stability of different exported proteins (i.e. fusions, a heterologous pre-pro-protein or a native protein containing repeats), having different locations. In the wild-type (wt) strain, degradation products, including the C-terminal protein ends, were present in the medium, indicating that proteolysis occurs during or after export to the cell surface; in one case, degradation was nearly total. In contrast, proteolysis was totally abolished in the htrA strain for all five proteins tested, and the yield of full-length products was significantly increased. These results suggest that HtrALl is the sole extracellular protease that degrades abnormal exported proteins. In addition, our results reveal that HtrALl is needed for the pro-peptide processing of a natural pro-protein and for maturation of a native protein. We propose that in lactococci, and possibly in other Gram-positive organisms with small sized-genomes, a single surface protease, HtrA, is totally responsible for the housekeeping of exported proteins.

Notes: In the disease course of bacillary dysentery, pathogenic Shigella flexneri invade colonic epithelial cells and spread both within and between host cells. The ability to spread intercellularly allows the organism to infect an entire epithelial layer without significant contact with the extracellular milieu. Using fluorescence activated cell sorter (FACS)-based technology, we developed a rapid and powerful selection strategy for the isolation of S. flexneri mutants that are unable to spread from cell to cell. The majority of mutants identified using this strategy harbour mutations that affect the structure of their lipopolysaccharide or the ability of the bacteria to move intracellularly via actin-based motility; both factors have previously been shown to be essential for cell-to-cell spread. However, using a modified strategy that eliminated both of these types of mutants, we identified several mutants that provide us with evidence that bacterial proteins of the type III secretion system, which are essential for bacterial entry into host cells, also play a role in cell-to-cell spread.

Notes: Using PCR, reverse transcription-PCR (RT-PCR) and colony hybridization in a genomic library, we isolated six genes which encode type II P-type ATPases in Neurospora crassa. The six full-length cDNAs were cloned in a yeast expression vector and transformed into Saccharomyces cerevisiae null Ca2+- or Na+-ATPase mutants. Three cDNAs suppressed the defect of the Ca2+ mutant and two of these protected from Mn2+ toxicity. One cDNA suppressed the defect of the Na+ mutant and two cDNAs were not functional in S. cerevisiae. The expression of the transcripts of the six genes in the presence of Ca2+, Na+, high pH or supporting an osmotic shock indicated that, with the exception of one of the Ca2+-ATPases, the main function of the cloned ATPases is the adaptation to stress conditions. The relationship between the cloned fungal Ca2+- and Na+-ATPases and plant type II P-ATPases is discussed.

Notes: The chromosomal DpnII gene cassette of Streptococcus pneumoniae encodes two methyltransferases and an endonuclease. One methyltransferase acts on double-stranded and the other on single-stranded DNA. Two mRNAs are transcribed from the cassette. One, a SigA promoter transcript, includes all three genes; the other includes a truncated form of the second methyltransferase gene (dpnA) and the endonuclease gene. The truncated dpnA, which is translated from the second start codon in the full gene, was shown to produce active enzyme. A promoter reporter plasmid for S. pneumoniae was devised to characterize the promoter for the second mRNA. This transcript was found to depend on a promoter that responded to the induction of competence for genetic transformation. The promoter contains the combox sequence recognized by a SigH-containing RNA polymerase. As part of the competence regulon, the dpnA gene makes a product able to methylate incoming plasmid strands to protect them from the endonuclease and allow plasmid establishment. Its function differs from most genes in the regulon, which are involved in DNA uptake. Comparison of R6 and Rx strains of S. pneumoniae showed the temperature dependence of transformation in R6 to result from temperature sensitivity of the uptake apparatus and not the development of competence.

Notes: The Saccharomyces cerevisiae nuclear gene OXA1, which is conserved from prokaryotes to human, was shown to be essential for cytochrome c oxidase and F1F0–ATP synthase biogenesis. We have searched for an orthologue of OXA1 in Schizosaccharomyces pombe, another yeast that is highly diverged from S. cerevisiae and which could more closely model higher eukaryotes. In particular, S. pombe exhibits a limited growth under anaerobic conditions and is petite negative, that is it does not tolerate large deletions of its mitochondrial DNA. Surprisingly, two S. pombe cDNAs able to complement an S. cerevisiae oxa1 mutation were isolated. The corresponding genes have different chromosomal locations and intron contents. They encode distinct proteins, both sharing a weak sequence identity one with the other and with Oxa1p. A phenotypic analysis of both single inactivations demonstrates that only one gene is essential for respiration in S. pombe. However, the double inactivation is lethal. This work gives new insight into the dependence of S. pombe viability upon oxa1 function, providing evidence of a connection between petite negativity, a functional respiratory chain and F1F0–ATP synthase complex in S. pombe.

Notes: The outer membrane protects Gram-negative bacteria against a harsh environment. At the same time, the embedded proteins fulfil a number of tasks that are crucial to the bacterial cell, such as solute and protein translocation, as well as signal transduction. Unlike membrane proteins from all other sources, integral outer membrane proteins do not consist of transmembrane α-helices, but instead fold into antiparallel β-barrels. Over recent years, the atomic structures of several outer membrane proteins, belonging to six families, have been determined. They include the OmpA membrane domain, the OmpX protein, phospholipase A, general porins (OmpF, PhoE), substrate-specific porins (LamB, ScrY) and the TonB-dependent iron siderophore transporters FhuA and FepA. These crystallographic studies have yielded invaluable insight into and decisively advanced the understanding of the functions of these intriguing proteins. Our review is aimed at discussing their common principles and peculiarities as well as open questions associated with them.

Notes: ExoS is a type III cytotoxin of Pseudomonas aeruginosa, which modulates two eukaryotic signalling pathways. The N-terminus (residues 1–234) is a GTPase activating protein (GAP) for RhoGTPases, while the C-terminus (residues 232–453) encodes an ADP-ribosyltransferase. Utilizing a series of N-terminal deletion peptides of ExoS and an epitope-tagged full-length ExoS, two independent domains have been identified within the N-terminus of ExoS that are involved in intracellular localization and expression of GAP activity. N-terminal peptides of ExoS localized to the perinuclear region of CHO cells, and a membrane localization domain was localized between residues 36 and 78 of ExoS. The capacity to elicit CHO cell rounding and express GAP activity resided within residues 90–234 of ExoS, which showed that membrane localization was not required to elicit actin reorganization. ExoS was present in CHO cells as a full-length form, which fractionated with membranes, and as an N-terminally processed fragment, which localized to the cytosol. Thus, ExoS localizes in eukaryotic cells to the perinuclear region and is processed to a soluble fragment, which possesses both the GAP and ADP-ribosyltransferase activities.

Notes: The genome sequence of Helicobacter pylori suggests that this bacterium possesses several Fe acquisition systems, including both Fe2+- and Fe3+-citrate transporters. The role of these transporters was investigated by generating insertion mutants in feoB, tonB, fecA1 and fecDE. Fe transport in the feoB mutant was ≈ 10-fold lower than in the wild type (with 0.5 μM Fe), irrespective of whether Fe was supplied in the Fe2+ or Fe3+ form. In contrast, transport rates were unaffected by the other mutations. Complementation of the feoB mutation fully restored both Fe2+ and Fe3+ transport. The growth inhibition exhibited by the feoB mutant in Fe-deficient media was relieved by human holo-transferrin, holo-lactoferrin and Fe3+-dicitrate, but not by FeSO4. The feoB mutant had less cellular Fe and was more sensitive to growth inhibition by transition metals in comparison with the wild type. Biphasic kinetics of Fe2+ transport in the wild type suggested the presence of high- and low-affinity uptake systems. The high-affinity system (apparent Ks = 0.54 μM) is absent in the feoB mutant. Transport via FeoB is highly specific for Fe2+ and was inhibited by FCCP, DCCD and vanadate, indicating an active process energized by ATP. Ferrozine inhibition of Fe2+ and Fe3+ uptake implied the concerted involvement of both an Fe3+ reductase and FeoB in the uptake of Fe supplied as Fe3+. Taken together, the results are consistent with FeoB-mediated Fe2+ uptake being a major pathway for H. pylori Fe acquisition. feoB mutants were unable to colonize the gastric mucosa of mice, indicating that FeoB makes an important contribution to Fe acquisition by H. pylori in the low-pH, low-O2 environment of the stomach.

Notes: The location of the cis-acting regulatory region for histidine-dependent antitermination of the Bacillus subtilis hut operon was determined. A secondary structure, whose sequences partially overlap with the downstream terminator, was found in the regulatory region of the hut transcript. Mutational analysis of the regulatory region showed that the secondary structure was required for histidine-dependent antitermination. An electrophoretic mobility-shift assay demonstrated that, in response to the presence of histidine and Mg2+, purified HutP bound hut RNA bearing putative secondary structure but not RNA lacking the potential to form putative secondary structure. Native gel electrophoresis showed that HutP existed as a hexamer. A filter-binding assay revealed that the concentration of histidine required for half-maximal binding of HutP to RNA was 3.1 mM and that the Kd for binding of HutP to RNA was ≈ 0.56 µM in the presence of histidine. These results suggested that putative secondary structure in the regulatory region of hut mRNA could function as an antiterminator to inhibit the formation of the terminator structure and that HutP causes expression of the hut structural genes by binding to the putative antiterminator structure in response to the presence of histidine.

Notes: Rad6p plays important roles in post-replication DNA repair, chromatin organization, gene silencing and meiosis. In this study, we show that Rad6p also regulates yeast-hypha morphogenesis in the human pathogen Candida albicans. CaRAD6 gene and cDNAs were isolated and characterized revealing that the gene carries two 5′-proximal introns. CaRad6p shows a high degree of sequence similarity to Rad6 proteins from fungi to man (60–83% identity), and it suppresses the UV sensitivity and lack of induced mutagenesis displayed by a Saccharomyces cerevisiae rad6 mutant. In C. albicans, CaRAD6 expression is induced in response to UV, and CaRad6p depletion confers UV sensitivity, confirming that Rad6p serves a role in protecting this fungus against UV damage. CaRAD6 overexpression inhibits hyphal development, whereas CaRad6p depletion enhances hyphal growth. Also, CaRAD6 mRNA levels decrease during the yeast-hypha transition. These effects are dependent on Efg1p, but not Cph1p, indicating that CaRad6p acts specifically through the Efg1p morphogenetic signalling pathway to repress yeast-hypha morphogenesis.

Notes: Control of transcription in prokaryotes often involves direct contact of regulatory proteins with RNA polymerase. For the σ54 RNA polymerase, regulatory proteins bound to distally located enhancers engage the polymerase via DNA looping. The σ54-dependent nifA promoter of Herbaspirillum seropedicae (Hs) is activated under nitrogen-limiting growth conditions. Potential enhancers for the nitrogen control activators NTRC and NIFA and binding sites for integration host factor (IHF) and σ54-holoenzyme were identified. DNA footprinting experiments showed that these sites functioned for protein binding. Their involvement in the promoter regulation was explored. In vitro, activation of the Hs nifA promoter by NTRC is stimulated by the DNA bending protein IHF. In marked contrast, activation by NIFA is greatly reduced by IHF, thus diminishing potentially destabilizing autoactivation of the nifA promoter by NIFA. Additionally, high levels of NIFA appear to limit NTRC-dependent activation. This inhibition is IHF dependent. Therefore, IHF acts positively and negatively at the nifA promoter to restrict transcription activation to NTRC and one signal transduction pathway.

Notes: LamB of Escherichia coli K12, also called maltoporin, is an outer membrane protein, which specifically facilitates the diffusion of maltose and maltodextrin through the bacterial outer membrane. Each monomer is composed of an 18-stranded antiparallel β-barrel. In the present work, on the basis of the known X-ray structure of LamB, the effects of modifications of the β-barrel domain of maltoporin were studied in vivo and in vitro. We show that: (i) the substitution of the pair of strands β13–β14 of the E. coli maltoporin with the corresponding pair of strands from the functionally related maltoporin of Salmonella typhimurium yielded a protein active in vivo and in vitro; and (ii) the removal of one pair of β-strands (deletion β13–β14) from the E. coli maltoporin, or its replacement by a pair of strands from the general porin OmpF of E. coli, leads to recombinant proteins that lost in vivo maltoporin activities but still kept channel formation and carbohydrate binding in vitro. We also inserted into deletion β13–β14 the portion of the E. coli LamB protein comprising strands β13 to β16. This resulted in a protein expected to have 20 β-strands and which completely lost all LamB-specific activities in vivo and in vitro.

Notes: In response to starvation, Myxococcus xanthus undergoes a multicellular developmental process that produces a dome-shaped fruiting body structure filled with differentiated cells called myxospores. Two insertion mutants that block the final stages of fruiting body morphogenesis and reduce sporulation efficiency were isolated and characterized. DNA sequence analysis revealed that the chromosomal insertions are located in open reading frames ORF2 and asgE, which are separated by 68 bp. The sporulation defect of cells carrying the asgE insertion can be rescued phenotypically when co-developed with wild-type cells, whereas the sporulation efficiency of cells carrying the ORF2 insertion was not improved when mixed with wild-type cells. Thus, the asgE insertion mutant appears to belong to a class of developmental mutants that are unable to produce cell–cell signals required for M. xanthus development, but they retain the ability to respond to them when they are provided by wild-type cells. Several lines of evidence indicate that asgE cells fail to produce normal levels of A-factor, a cell density signal. A-factor consists of a mixture of heat-stable amino acids and peptides, and at least two heat-labile extracellular proteases. The asgE mutant yielded about 10-fold less heat-labile A-factor and about twofold less heat-stable A-factor than wild-type cells, suggesting that the primary defect of asgE cells is in the production or release of heat-labile A-factor.