ALBERT

Notes: Abstract A high-quality NMR solution structure of the chimeric hybrid duplex r(gcaguggc)⋅r(gcca)d(CTGC) was determined using the program DYANA with its recently implemented new module FOUND, which performs exhaustive conformational grid searches for dinucleotides. To ensure conservative data interpretation, the use of 1H-1H lower distance limit constraints was avoided. The duplex comprises the tRNA–DNA junction formed during the initiation of HIV-1 reverse transcription. It forms an A-type double helix that exhibits distinct structural deviations from a standard A-conformation. In particular, the minor groove is remarkably narrow, and its width decreases from about 7.5 Å in the RNA/RNA stem to about 4.5 Å in the RNA/DNA segment. This is unexpected, since minor groove widths for A-RNA and RNA/DNA hybrid duplexes of ∼11 Å and ∼8.5 Å, respectively, were previously reported. The present, new structure supports that reverse transcriptase-associated RNaseH specificity is related primarily to conformational adaptability of the nucleic acid in 'induced-fit'-type interactions, rather than the minor groove width of a predominantly static nucleic acid duplex.

Notes: Summary The program GARANT (General Algorithm for Resonance AssignmeNT) for automated sequence-specific NMR assignment of proteins is based on the mapping of peaks predicted from the amino acid sequence onto the peaks observed in multidimensional spectra [C. Bartels, P. Güntert, M. Billeter and K. Wüthrich (1996) J. Comput. Chem., manuscript submitted for publication]. In this paper we demonstrate the potential of GARANT for the assignment of homologous proteins when either the three-dimensional structure or the chemical shifts of the parent protein are known. In these applications, GARANT utilizes supplementary information either in the form of interatomic distances derived from the three-dimensional structure, in order to add nuclear Overhauser effects reflecting the tertiary structure to the list of expected peaks, or in the form of the chemical shifts of the parent protein, in order to obtain a better estimate of the positions of the expected peaks. The procedure is illustrated with three different proteins: (i) a mutant form of Tendamistat (74 residues), using homonuclear 2D 1H NMR spectra and either the three-dimensional structure or the chemical shifts of the wild-type protein; (ii) the mutant Antp(C39S, W56S) homeodomain (68 residues), using homonuclear 2D 1H NMR spectra and the three-dimensional structure of the Antp(C39S) homeodomain; and (iii) free cyclophilin A (165 residues), using heteronuclear 3D NMR spectra and the three-dimensional structure of a cyclophilin A-cyclosporin A complex. In these three systems nearly complete assignment of the polypeptide backbone resonances and assignment of over 80% of the amino acid side-chain resonances was obtained without manual intervention.

Notes: Abstract The new computer algorithm FOUND, which is implemented as an integrated module of the DYANA structure calculation program, is capable of performing systematic local conformation analyses by exhaustive grid searches for arbitrary contiguous fragments of proteins and nucleic acids. It uses torsion angles as the only degrees of freedom to identify all conformations that fulfill the steric and NMR-derived conformational restraints within a contiguous molecular fragment, as defined either by limits on the maximal restraint violations or by the fragment-based DYANA target function value. Sets of mutually dependent torsion angles, for example in ribose rings, are treated as a single degree of freedom. The results of the local conformation analysis include allowed torsion angle ranges and stereospecific assignments for diastereotopic substituents, which are then included in the input of a subsequent structure calculation. FOUND can be used for grid searches comprising up to 13 torsion angles, such as the backbone of a complete α-helical turn or dinucleotide fragments in nucleic acids, and yields a significantly higher number of stereospecific assignments than the precursor grid search algorithm HABAS.

Notes: Summary Improved experimental schemes for the recently introduced J-modulated [15N,1H]-correlation experiment for measurements of the homonuclear amide proton-Cα proton vicinal coupling constants.3JHNα, in uniformly15N-labeled proteins are described, and a nonlinear fit procedure is presented for quantitative evaluation of3JHNα. The method was first tested with the N-terminal DNA-binding domain of the 434 repressor (M=7.3 kDa), where at 13 C precise values of3JHNα in the range 2.0–9.5 Hz were obtained for all residues with resolved15N-1H cross peaks. It was then applied to theAntennapedia homeodomain complexed to a synthetic 14-base pair DNA fragment (molecular weight of the complex ∼ 18 kDa). The3JHNα values measured were found to be in excellent agreement with those predicted from the secondary structure of this protein in the complex.

Notes: Summary A new program package, XEASY, was written for interactive computer support of the analysis of NMR spectra for three-dimensional structure determination of biological macromolecules. XEASY was developed for work with 2D, 3D and 4D NMR data sets. It includes all the functions performed by the precursor program EASY, which was designed for the analysis of 2D NMR spectra, i.e., peak picking and support of sequence-specific resonance assignments, cross-peak assignments, cross-peak integration and rate constant determination for dynamic processes. Since the program utilizes the X-window system and the Motif widget set, it is portable on a wide range of UNIX workstations. The design objective was to provide maximal computer support for the analysis of spectra, while providing the user with complete control over the final resonance assignments. Technically important features of XEASY are the use and flexible visual display of ‘strips’, i.e., two-dimensional spectral regions that contain the relevant parts of 3D or 4D NMR spectra, automated sorting routines to narrow down the selection of strips that need to be interactively considered in a particular assignment step, a protocol of resonance assignments that can be used for reliable bookkeeping, independent of the assignment strategy used, and capabilities for proper treatment of spectral folding and efficient transfer of resonance assignments between spectra of different types and different dimensionality, including projected, reduced-dimensionality triple-resonance experiments.

Notes: Why Pentose- and Not Hexose-Nucleid Acids? Part IV . ‘Homo-DNA’: 1H-, 13C-, 31P-, and 15N-NMR-Spectroscopic Investigation of ddGlc(A-A-A-A-A-T-T-T-T-T) in Aqueous SolutionFrom a comprehensive NMR structure analysis, it is concluded that the ‘homo-DNA’ oligonucleotide ddGlc(A-A-A-A-A-T-T-T-T-T) in 3 mM D2O solution (100 mM NaCl, 50 mM phosphate buffer, pH 7.0, T = 50°) forms a duplex of C2-symmetry, with its self-complementary oligonucleotide strands in antiparallel orientation. The 2′,3′-dideoxy-β-D-glucopyranosyl rings are in their most stable chair conformation, with all three substituents equatorial and with the adenine as well as the thymine bases in the anti-conformation. The base pairing is of the Watson-Crick type; this pairing mode (as opposed to the reverse-Hoogsteen mode) was deduced from the observation of inter strand NOEs between the adenine protons H—C(2) and the pyranose protons Hα-C(2′) of the sequentially succeeding thymidine nucleotides of the opposite strand, a correlation which discriminates between the Watson-Crick and the reverse-Hoogsteen pairing mode. The NOEs of the NH protons with either the adenine protons H—C(2) or H—C(8), that are normally used to identify the pairing mode in DNA duplexes, cannot be observed here, because the NH signals are very broad. This line broadening is primarily due to the fact that the exchange of the imino protons with the solvent is faster than for corresponding DNA duplexes.Computer-assisted modeling of the [ddGlc(A5-T5)]2 duplex with the program CONFOR [23], using the linear (idealized) homo-DNA single-strand conformation (α = -60°, β = 180°, γ = 60°, δ = 60°, ∊ = 180°, ζ = -60°, see [1] [3]) as the starting structure, resulted in two duplex models A and B (see Figs. 27-32, Scheme 9, and Table 4) which both contain quasi-linear double strands with the base-pairing axis inclined relative to the strand axes by ca. 60° and 45°, respectively, and with base-pair stacking distances of ca. 4.5 Å. While neither of the two models, taken separately, can satisfy all of the NMR constraints, the NMR data can be rationalized by the assumption that the observed duplex structure represents a dynamic equilibrium among conformers which relate to models A and B as their limiting structure. The required rapid equilibrium appears feasible, since the models A and B are interconvertible by two complementary 120° counter rotations around the α-axis and the γ-axis, respectively, of the phosphodiester backbone. The models A and B correspond to the two types of linear (idealized) single-strand backbone conformation derived previously by qualitative conformational analysis without and with allowance for gauche-trans-phosphodiester conformations, respectively [1] [3]. Refinement of the models A and B with the use of the program AMBER [27] by energy minimization in a water bath and molecular-dynamics simulations (2 ps, 300° K) resulted in two dynamic structures (Figs. 33 and 34, Table 4). These have roughly the same energy, closely resemble the starting structures A and B, and satisfy - as an ensemble - all of the NMR constraints without violating any van der Waals distances by more than 0.2 Å. Extensive fluctuations in base-pair distance and deviations from base-pair coplanarity, as well as the presence of water molecules in the cavities between some of the base pairs, were observed in both dynamic structures A and B, which, on the other hand, did not mutually interconvert within the short simulation time period used. These model properties, together with the conjectured equilibrium between the two structure types A and B, lead to the hypothesis of a homo-DNA duplex containing a ‘partially molten’ pairing core. This proposal could qualitatively account for a high rate of the NH exchange, as well as for part of the previously established [3] deficits in both enthalpic stabilization and entropic destabilization of homo-DNA duplexes relative to corresponding DNA duplexes. The phenomenon of the higher overall stability of homo-DNA duplexes vs. DNA duplexes (e.g, [ddGlc(A5-T5)]2, Tm = 59° vs. [d(A5-T5)]2, Tm = 33°, both at c ≈ 50 μM [3]) can then be seen as the result not only of a higher degree of conformational preorganization of the homo-DNA single strand toward the conformation of the duplex backbone [1] [3], but also of the entropic benefit of greater disorder in the central pairing zone of the homo-DNA duplex. This view of the structure of a homo-DNA duplex relates its characteristic properties to a central structural feature: the average base-pair distance in the models of homo-DNA is too large for regular base stacking (ca. 4.5 Å vs. ca. 3.5 Å in DNA). This difference in the distances between adjacent base pairs is a direct consequence of the quasi-linearity of the homo-DNA double strand as opposed to the right-handed twist of the helical DNA duplexes [1] [3], which is directly related to the specific conformational properties of pyranose rings as opposed to furanose rings [1]. Thus, the structural hypothesis derived from the NMR analysis of [ddGlc(A5-T5)]2 relates the conformational differences between homo-DNA and DNA directly to the sugar ring size, which is the essential constitutional difference between the two types of structure.The English footnotes to Figs. 1-34, Schemes 1-9, and Tables 1-4 provide an extension of this summary.

Notes: A new program for automatic resonance assignment of nuclear magnetic resonance (NMR) spectra of proteins, GARANT (General Algorithm for Resonance Assignment), is introduced. Three principal elements used in this approach are: (a) representation of resonance assignments as an optimal match of two graphs describing, respectively, peaks expected from combined knowledge of the primary structure and the magnetization transfer pathways in the spectra used, and experimentally observed peaks; (b) a scoring scheme able to distinguish between correct and incorrect resonance assignments; and (c) combination of an evolutionary algorithm with a local optimization routine. The score that evaluates the match of expected peaks to observed peaks relies on the agreement of the information available about these peaks, most prominently, but not exclusively, the chemical shifts. Tests show that the combination of an evolutionary algorithm and a local optimization routine yields results that are clearly superior to those obtained when using either of the two techniques separately in the search for the correct assignments. GARANT is laid out for assignment problems involving peaks observed in two- and three-dimensional homonuclear and heteronuclear NMR spectra of proteins. © 1997 by John Wiley & Sons, Inc.