Rutger H. A. Folmer

Floating stereospecific assignment revisited: Application to an 18 kDa protein and comparison with J-coupling data

We report a floating chirality procedure to treat nonstereospecifically assigned methylene orisopropyl groups in the calculation of protein structures from NMR data using restrainedmolecular dynamics and simulated annealing. The protocol makes use of two strategies toinduce the proper conformation of the prochiral centres: explicit atom ‘swapping’ followingan evaluation of the NOE energy term, and atom ‘floating’ by reducing the angle andimproper force constants that enforce a defined chirality at the prochiral centre. The individualcontributions of both approaches have been investigated. In addition, the effects of accuracyand precision of the interproton distance restraints were studied. The model system employedis the 18 kDa single-stranded DNA binding protein encoded by Pseudomonas bacteriophagePf3. Floating chirality was applied to all methylene and isopropyl groups that give rise to non-degenerate NMR signals, and the results for 34 of these groups were compared to J-couplingdata. We conclude that floating stereospecific assignment is a reliable tool in protein structurecalculation. Its use is beneficial because it allows the distance restraints to be extracteddirectly from the measured peak volumes without the need for averaging or addingpseudoatom corrections. As a result, the calculated structures are of a quality almostcomparable to that obtained with stereospecific assignments. As floating chirality furthermoreis the only approach treating prochiral centres that ensures a consistent assignment of the twoproton frequencies in a single structure, it seems to be preferable over using pseudoatoms or(R-6) averaging.

A 13C double-filtered NOESY with strongly reduced artefacts and improved sensitivity

SummaryA 1H NOESY experiment with two 13C half-filters is described which has, compared to previously reported versions, an enhanced overall sensitivity and strongly reduced intramolecular cross peaks in any part of the spectrum edited for intermolecular NOEs. By adding a shaped 13C pulse to the half-filter which selectively inverts the aromatic resonances, the filter can be tuned separately and simultaneously for the aliphatic and aromatic regions. Contrary to recently proposed schemes, no magnetization is destroyed, so that full sensitivity is retained for symmetric systems such as homodimers. Furthermore, by replacing the rectangular 180° 13C pulses by high-power hyperbolic secant pulses for inversion of the complete 13C spectral range, offset effects (which are another source of signal loss and artefacts) are eliminated. The spectra edited for intermolecular NOEs clearly demonstrate that residual artefacts are considerably smaller than in the original version of the experiment.

Single-stranded DNA binding protein encoded by the filamentous bacteriophage M13: structural and functional characteristics

The single-stranded DNA binding protein, or gene V protein (gVp), encoded by gene V of the filamentous bacteriophage M13 is a multifunctional protein that not only regulates viral DNA replication but also gene expression at the level of mRNA translation. It furthermore is implicated as a scaffolding and/or chaperone protein during the phage assembly process at the hostcell membrane. The protein is 87 amino acids long and its biological functional entity is a homodimer. In this manuscript a short description of the life cycle of filamentous phages is presented and our current knowledge of the major functional and structural properties and characteristics of gene V protein are reviewed. In addition models of the superhelical complexes gVp forms with ssDNA are described and their (possible) biological meaning in the infection process are discussed. Finally it is described that the ‘DNA binding loop’ of gVp is a recurring motif in many ssDNA binding proteins and that the fold of gVp is shared by a large family of evolutionarily conserved gene regulatory proteins.

Refined Solution Structure of the Tyr41-]His Mutant of the M13 Gene-V Protein - a Comparison with the Crystal-Structure

The three-dimensional solution structure of mutant Tyr41?His of the single-stranded DNA binding protein encoded by gene V of the filamentous bacteriophage M13 has been refined in two stages. The first stage involved the collection of additional NOE-based distance constraints, which were then used in eight cycles of back-calculations and structure calculations. The structures of the gene V protein dimers were calculated using simulated annealing, employing restrained molecular dynamics with a geometric force field. In the second stage of the refinement procedure, solvent was explicitly included during the dynamic calculations. A total of 30 structures was calculated for the protein, representing its solution structure in water. The first calculation step significantly improved the convergence of the structures, whereas the subsequent simulations in water made the structures physically more realistic. This is, for instance, illustrated by the number of hydrogen bonds formed in the molecule, which increased considerably upon going to aqueous solution. It is shown that the solution structure of the mutant gene V protein is nearly identical to the crystal structure of the wild-type molecule, except for the DNA-binding loop (residues 16-28). This antiparallel s-hairpin is twisted and partially folded back towards the core of the protein in the NMR structure, whereas it is more extended and points away from the rest of the molecule in the X-ray structure. Unrestrained molecular dynamics calculations suggest that this latter conformation is energetically unstable in solution.

Refined Solution Structure of the Tyr41→His Mutant of the M13 Gene V Protein

The three-dimensional solution structure of mutant Tyr41-->His of the single-stranded DNA binding protein encoded by gene V of the filamentous bacteriophage M13 has been refined in two stages. The first stage involved the collection of additional NOE-based distance constraints, which were then used in eight cycles of back-calculations and structure calculations. The structures of the gene V protein dimers were calculated using simulated annealing, employing restrained molecular dynamics with a geometric force field. In the second stage of the refinement procedure, solvent was explicitly included during the dynamic calculations. A total of 30 structures was calculated for the protein, representing its solution structure in water. The first calculation step significantly improved the convergence of the structures, whereas the subsequent simulations in water made the structures physically more realistic. This is, for instance, illustrated by the number of hydrogen bonds formed in the molecule, which increased considerably upon going to aqueous solution. It is shown that the solution structure of the mutant gene V protein is nearly identical to the crystal structure of the wild-type molecule, except for the DNA-binding loop (residues 16-28). This antiparallel beta-hairpin is twisted and partially folded back towards the core of the protein in the NMR structure, whereas it is more extended and points away from the rest of the molecule in the X-ray structure. Unrestrained molecular dynamics calculations suggest that this latter conformation is energetically unstable in solution.