ALBERT

Notes: The chaperone-like protein of the main terminal branch of the general secretory pathway from Klebsiella oxytoca, the outer membrane lipoprotein PulS, protects the multimeric secretin PulD from degradation and promotes its correct localization to the outer membrane. To determine whether these are separable functions, or whether resistance to proteolysis results simply from correct localization of PulD, we replaced the lipoprotein-type signal peptide of PulS by the signal peptide of periplasmic maltose-binding protein. The resulting periplasmic PulS retained its ability to protect PulD, but not its ability to localize PulD to the outer membrane and to function in pullulanase secretion. Periplasmic PulS competed with wild-type PulS to prevent pullulanase secretion, presumably again by causing mislocalization of PulD. A hybrid protein comprising the mature part of PulS fused to the C-terminus of full-length maltose-binding protein (MalE–PulS) had similar properties to the periplasmic PulS protein. Moreover, MalE–PulS was shown to associate with PulD by amylose-affinity chromatography. The MalE–PulS hybrid was rendered completely functional (i.e. it restored pullulanase secretion in a pulS mutant) by replacing its signal peptide with a lipoprotein-type signal peptide. However, this fatty-acylated hybrid protein was only functional if it also carried a lipoprotein sorting signal that targeted it to the outer membrane. Thus, the two functions of PulS are separate and fully dissociable. Incorrect localization, rather than proteolysis, of PulD in the absence of PulS was shown to be the factor that causes high-level induction of the phage shock response. The Erwinia chrysanthemi PulS homologue, OutS, can substitute for PulS, and PulS can protect the secretin OutD from proteolysis in Escherichia coli, indicating the possible existence of a family of PulS-like chaperone proteins.

Notes: Because the ferric uptake regulator (fur ) appears to be an essential gene in Pseudomonas aeruginosa, resistance to manganese was used as an enrichment to isolate strains carrying point mutations in the fur gene in order to assess its role in the co-ordinate expression of siderophores and exotoxin A (ETA). This report describes a detailed molecular and phenotypic characterization of four mutants and one revertant, which carry point mutations in the fur gene. Two parental strains were used in this study. Three mutants were isolated from the widely used strain, PAO1. One of these, CS (cold sensitive), has a mutation in the 5′ non-coding region of the fur gene while the two other mutants derived from this parent have mutations resulting in the following deduced changes in Fur: mutant A2, H86 → R; mutant A4, H86 → Y. The other mutant (C6) and its revertant (C6Rv) were derived from PAO6261, a mutant of PAO1 with a deletion in the anr gene (anaerobic regulation of arginine deiminase and nitrate reduction) that controls anaerobic respiration in P. aeruginosa. Fur from the C6 mutant has an A10 → G mutation while in the C6Rv spontaneous revertant the mutant Gly residue has been changed to Ser at this position. All mutants were examined for alterations in the iron-regulated expression of siderophores and ETA. The A2 and A4 mutants expressed higher levels of siderophores in iron-deficient media and in iron-replete media. The CS mutant constitutively expressed siderophores at 25°C. At 42°C siderophore biosynthesis was iron repressed as in the parental strain PAO1. The deletion of anr in PAO6261 had no apparent effect on the iron-mediated regulation of siderophore synthesis, but the C6 mutant derived from this strain produces siderophores constitutively. The iron-regulated production of siderophores by C6Rv was similar to the parental strain PAO6261 and PAO1. Because one of the parental strains used in this study is an Anr mutant, regulation of ETA production was assessed under aerobic and microaerobic conditions. Iron-dependent repression of ETA synthesis in both parental strains and A2 and A4 mutants was found to be 50–100-fold under aerobic and microaerobic conditions, as assayed by quantitative Western dot-blot assays. By contrast in the CS and C6 mutants, while iron-dependent repression of ETA synthesis was similar to both parental strains under aerobic conditions, ETA production in these mutants was constitutive in a microaerobic environment. RNase protection analysis of toxA and regAB transcription in PAO1, PAO6261 and the C6 mutant corroborated the results of quantitative dot-blot assays of ETA. The mutant Fur proteins were purified and examined for their ability to bind to the promoter of a gene (pvdS ) that positively regulates the expression of siderophores and ETA. Fur from the A2 and A4 mutants and from the C6Rv revertant was able to bind to the target DNA, but with reduced affinity by comparison to wild-type Fur. Fur from the C6 mutant in DNase I footprint experiments failed to protect the promoter region of the pvdS gene, but it retained some weak binding activity in gel mobility shift assays. The data presented in this study not only furnish some additional insights into the structure–function relationships of Fur, but also afford novel perspectives with regard to Fur and the iron-dependent regulation of virulence factors in P. aeruginosa under environmental conditions that have not previously been considered.

Notes: During endospore formation in Bacillus subtilis an asymmetric division produces two cells, forespore and mother cell, which follow different developmental paths. Commitment to the forespore-specific developmental path is controlled in part by the activation of the forespore-specific RNA polymerase sigma factor, σF. Activity of σF is inhibited in the mother cell by the anti-sigma factor SpoIIAB. In the forespore, σF directs transcription of the structural gene for σG. However, σG does not become active until after engulfment of the forespore is complete. This σG activity is dependent upon the products of the spoIIIA operon. We showed that σG is present but mostly inactive in a spoIIIA mutant. We also demonstrated that the anti-sigma factor SpoIIAB can bind to σGin vitro. Moreover, a mutant form of σG that binds SpoIIAB inefficiently in vitro was shown to function independently of SpoIIIA during sporulation. These and previously reported results support a model in which SpoIIAB functions as an inhibitor of σG activity during sporulation. Therefore, we propose that the anti-sigma factor SpoIIAB antagonizes both σF and σG activities, and that this antagonism is relieved in the forespore in two stages. In the first stage, which follows septation, a SpoIIAA-dependent mechanism partially relieves SpoIIAB inhibition of σF activity in the forespore. In the second stage, which follows forespore engulfment, a SpoIIIA-dependent process inactivates SpoIIAB in the forespore, resulting in the activation of σG.

Notes: The Ty virus-like particles (VLPs) are functionally analogous to retroviral particles. They package the enzymes and the RNA necessary for retrotransposition, and mediate the integration of the reverse-transcription product into the genome of the host cell. Here we map three structural determinants of particle assembly in the subunit protein. We have also identified key residues in these regions that seem to be involved in subunit interaction and particle morphology. In particular, two point mutations in putative amphipathic helices have remarkable effects on VLP morphology, increasing the diameter as much as eightfold.

Notes: Two new yeast genes, named ASN1 and ASN2, were isolated by complementation of the growth defect of an asparagine auxotrophic mutant. Genetical analysis indicates that these two genes are allelic to the asnA and asnB loci described previously. Simultaneous disruption of both genes leads to a total asparagine auxotrophy, while disruption of asn1 or asn2 alone has no effect on growth under tested conditions. Nucleotide sequences of ASN1 and ASN2 revealed striking similarities with genes encoding asparagine synthetase (AS) from other organisms. Regulation of ASN1 and ASN2 expression was studied using lacZ fusions and both genes were found to be several times less expressed in the absence of the transcription activator Gcn4p. The HAP complex, another transcription factor that binds to CCAAT-box sequences, was shown to specifically affect ASN1 expression. Hap2p and Hap3p subunits of the HAP complex are required for optimal expression of ASN1, while the Hap4p regulatory subunit, which is required for regulation by the carbon source, plays a minor role in this process. Consistent with the weak effect of Hap4p, the carbon source does not significantly affect expression of ASN1. Our results show that the role of the HAP complex is not limited to activation of genes required for respiratory metabolism.

Notes: During infection of their hosts, salmonellae enter intestinal epithelial cells. It has been proposed that when Salmonellatyphimurium is present in the intestinal lumen, several environmental and regulatory conditions modulate the expression of invasion factors required for bacterial entry into host cells. We report here that the expression of six different S. typhimurium invasion genes encoded on SPI1 (Salmonella pathogenicity island 1) is co-ordinately regulated by oxygen, osmolarity, pH, PhoPQ, and HilA. HilA is a transcriptional activator of the OmpR/ToxR family that is also encoded on SPI1. We have found that HilA plays a central role in the co-ordinate regulation of invasion genes by environmental and regulatory conditions. HilA can activate the expression of two invasion gene–lacZY fusions on reporter plasmids in Escherichia coli, suggesting that HilA acts directly at invasion-gene promoters in S. typhimurium. We have found that the regulation of invasion genes by oxygen, osmolarity, pH, and PhoPQ is indirect and is mediated by regulation of hilA expression by these environmental and regulatory factors. We hypothesize that the complex and co-ordinate regulation of invasion genes by HilA is an important feature of salmonella pathogenesis and allows salmonellae to enter intestinal epithelial cells.

Notes: The PrfA protein, which is a member of the Crp/Fnr family of prokaryotic transcription activators, regulates the virulence genes of Listeria monocytogenes. In this work, specific binding of PrfA to its target DNA was determined by electrophoretic mobility-shift assays (EMSAs) using cell-free extracts from the two L. monocytogenes strains EGD and NCTC 7973. PrfA-specific binding differs between the two strains, even when the concentration of PrfA was adjusted to similar levels. Both strains exhibited increased PrfA-specific binding after a shift into minimal essential medium (MEM) without showing a significant change in the amount of PrfA protein, relative to extracts from bacteria grown in brain–heart infusion (BHI). The purified PrfA protein from strain EGD produced in Escherichia coli did not exhibit specific binding to the target DNA but did so upon addition of PrfA-free extracts from various Listeria species and Bacillus subtilis. The observed activation of PrfA seems to be caused by a PrfA-activating factor (Paf), which is probably a protein since elevated temperature, but not RNase treatment, destroyed the activation potential of such PrfA-free extracts. Moreover, fractionation of these extracts by sucrose gradient centrifugation yielded the Paf activity in a fraction sedimenting at 3.2 S. Specific binding of PrfA-containing extracts from strain EGD to the hly and actA promoter sequences was strongly inhibited by iron, whereas that of extracts from strain NCTC 7973 was only slightly reduced. The iron effect seems to be mediated by Paf rather than by PrfA itself.

Notes: Mutation fixation at an ethenocytosine (εC) residue borne on transfected M13 single-stranded DNA is significantly enhanced in response to pretreatment of Escherichia coli cells with UV, alkylating agents or hydrogen peroxide, a phenomenon that we have called UVM for UV modulation of mutagenesis. The UVM response does not require the E. coli SOS or adaptive responses, and is observed in cells defective for oxyR, an oxidative DNA damage-responsive regulatory gene. UVM may represent either a novel DNA-repair phenomenon, or an unrecognized feature of DNA replication in damaged cells that affects a specific class of non-coding DNA lesions. To explore the range of DNA lesions subject to the UVM effect, we have examined mutation fixation at 3,N 4-ethenocytosine and 1,N 6-ethenoadenine, as well as at O6-methylguanine (O6mG). M13 viral single-stranded DNA constructs bearing a single mutagenic lesion at a specific site were transfected into cells pretreated with UV or 1-methyl-3-nitro-1-nitrosoguanidine (MNNG). Survival of transfected viral DNA was measured as transfection efficiency, and mutagenesis at the lesion site was analysed by a quantitative multiplex sequence analysis technology. The results suggest that the UVM effect modulates mutagenesis at the two etheno lesions, but does not appear to significantly affect mutagenesis at O6mG. Because the modulation of mutagenesis is observed in cells incapable of the SOS response, these data are consistent with the notion that UVM may represent a previously unrecognized DNA damage-inducible response that affects the fidelity of DNA replication at certain mutagenic lesions in Escherichia coli.

Notes: The ATP-binding-cassette (ABC) protein LacK of Agro-bacterium radiobacter displays high sequence similarity to the MalK subunit of the Salmonella typhimurium maltose-transport system (MalFGK2). We have used LacK as a tool to identify sites of interaction of MalK with the membrane-integral components MalF and MalG. Small amounts of LacK, resulting from the expression of the plasmid-borne lacK gene, proved to be sufficient for partial restoration of growth of a malK strain of S. typhimurium on maltose. LacK failed to substitute for MalK in regulating the expression of maltose-inducible genes but the hybrid complex MalFGLacK2 was sensitive to inducer exclusion. The lacK gene also complemented a ugpC mutant of Escherichia coli to growth on sn-glycerol-3-phosphate as the phosphate source. Partially purified LacK exhibited a spontaneous ATPase activity comparable to that of MalK. A MalK′–′LacK chimeric protein was isolated (by in vivo recombination) in which the N-terminal 140 amino acids of MalK are fused to residues 141–363 of LacK. The protein substituted for MalK in maltose transport considerably better than LacK. Furthermore, random mutagenesis of the plasmid-borne lacK gene yielded three clones that were superior to wild-type lacK in complementing a malK mutation. Single mutations (V114M or L123F) substantially improved the growth of a malK strain on maltose, whereas a double mutation (L123F, S295N) resulted in growth and transport rates that were indistinguishable from those obtained with MalK. In contrast, the introduction of the single change S295N into LacK had no effect but combination with the V114M mutation led to a further twofold increase in transport activity. These results indicate that a putative helical domain in MalK, encompassing residues 89–140, is crucial for a functional, high-affinity interaction with MalF and MalG.

Notes: The Escherichia coli RfaH protein is required for the expression of operons directing synthesis and export of the toxin haemolysin, the lipopolysaccharide core, and the F-factor sex pilus. Mutation of rfaH increases transcriptional polarity along all three operons. By demonstrating strong RfaH-dependent suppression of transcription polarity in vitro, we have established RfaH as a novel transcriptional activator, and we reveal that RfaH is a homologue of the essential protein NusG that modulates general transcriptional pausing and termination in prokaryotes. Full transcription of the distal genes from an upstream promoter required RfaH and the 5′ cis-acting ops element, both in vivo and in vitro. In vivo the requirement for the ops element was suppressed by overexpressing RfaH, and in vitro the presence of ops lowered the concentration of RfaH required to stimulate transcript elongation. We suggest that RfaH directs transcript elongation in an analogous way to NusG, but does so in a subset of bacterial operons primarily engaged in the production of extracellular components required for virulence and fertility.