Janice D. Pata

Crystal structure of a DinB lesion bypass DNA polymerase catalytic fragment reveals a classic polymerase catalytic domain.

The UmuC/DinB family of bypass polymerases is responsible for translesion DNA synthesis and includes the human polymerases eta, iota, and kappa. We determined the 2.3 A resolution crystal structure of a catalytic fragment of the DinB homolog (Dbh) polymerase from Sulfolobus solfataricus and show that it is nonprocessive and can bypass an abasic site. The structure of the catalytic domain is nearly identical to those of most other polymerase families. Homology modeling suggests that there is minimal contact between protein and DNA, that the nascent base pair binding pocket is quite accessible, and that the enzyme is already in a closed conformation characteristic of ternary polymerase complexes. These observations afford insights into the sources of low fidelity and low processivity of the UmuC/DinB polymerases.

Structure of PolC reveals unique DNA binding and fidelity determinants

PolC is the polymerase responsible for genome duplication in many Gram-positive bacteria and represents an attractive target for antibacterial development. We have determined the 2.4-Å resolution crystal structure of Geobacillus kaustophilus PolC in a ternary complex with DNA and dGTP. The structure reveals nascent base pair interactions that lead to highly accurate nucleotide incorporation. A unique β-strand motif in the PolC thumb domain contacts the minor groove, allowing replication errors to be sensed up to 8 nt upstream of the active site. PolC exhibits the potential for large-scale conformational flexibility, which could encompass the catalytic residues. The structure suggests a mechanism by which the active site can communicate with the rest of the replisome to trigger proofreading after nucleotide misincorporation, leading to an integrated model for controlling the dynamic switch between replicative and repair polymerases. This ternary complex of a cellular replicative polymerase affords insights into polymerase fidelity, evolution, and structural diversity.

Structural diversity of the Y-family DNA polymerases

The Y-family translesion DNA polymerases enable cells to tolerate many forms of DNA damage, yet these enzymes have the potential to create genetic mutations at high rates. Although this polymerase family was defined less than a decade ago, more than 90 structures have already been determined so far. These structures show that the individual family members bypass damage and replicate DNA with either error-free or mutagenic outcomes, depending on the polymerase, the lesion and the sequence context. Here, these structures are reviewed and implications for polymerase function are discussed.

Getting a grip: polymerases and their substrate complexes

Underpinned by a database of more than a dozen different crystal structures, an increasingly complete and coherent picture of polymerase structure and function is emerging. Recently determined structures of DNA and RNA polymerases have revealed some of the molecular features and structural changes governing catalysis, oligomerization, processivity and fidelity. Despite having minimal similarities in sequence and protein topology, the polymerases all display a functionally analogous set of subdomains that bind the primer, template and nucleotide substrates in similar though not identical fashions. The two-metal-ion mechanism for nucleotide incorporation, however, is shared even by nonhomologous polymerases.

Structural Insights into the Generation of Single-Base Deletions by the Y Family DNA Polymerase Dbh

Dbh is a Y family translesion DNA polymerase that accurately bypasses some damaged forms of deoxyguanosine, but also generates single-base deletion errors at frequencies of up to 50%, in specific hot spot sequences. We describe preinsertion binary, insertion ternary, and postinsertion binary crystal structures of Dbh synthesizing DNA after making a single-base deletion. The skipped template base adopts an extrahelical conformation stabilized by interactions with the C-terminal domain of the enzyme. DNA translocation and positioning of the next templating base at the active site, with space opposite to accommodate incoming nucleotide, occur independently of nucleotide binding, incorporation, and pyrophosphate release. We also show that Dbh creates single-base deletions more rapidly when the skipped base is located two or three bases upstream of the nascent base pair than when it is directly adjacent to the templating base, indicating that Dbh predominantly creates single-base deletions by template slippage rather than by dNTP-stabilized misalignment.

Partial N-terminal amino acid sequences of three nonstructural proteins of two flaviviruses

Partial N-terminal amino acid sequences for the three largest nonstructural proteins of two flaviviruses, yellow fever virus and St. Louis encephalitis virus, have been obtained. The determined sequences of these proteins exhibit significant amino acid sequence homology, and allow the positioning of these three nonstructural proteins in the polyprotein sequence deduced from the nucleotide sequence of yellow fever virus (C. M. Rice, E. M. Lenches, S. R. Eddy, S. J. Shin, R. L. Sheets, and J. H. Strauss, 1985, Science 229, 726-733.) The deduced start points support the hypothesis that the N terminus of nonstructural glycoprotein NS1 results from cleavage by signalase, whereas the N termini of NS3 and NS5 result from cleavages following double basic residues that are flanked by amino acids with short side chains.

Human polymerase kappa uses a template-slippage deletion mechanism, but can realign the slipped strands to favour base substitution mutations over deletions

Polymerases belonging to the DinB class of the Y-family translesion synthesis DNA polymerases have a preference for accurately and efficiently bypassing damaged guanosines. These DinB polymerases also generate single-base (−1) deletions at high frequencies with most occurring on repetitive ‘deletion hotspot’ sequences. Human DNA polymerase kappa (hPolκ), the eukaryotic DinB homologue, displays an unusual efficiency for to extend from mispaired primer termini, either by extending directly from the mispair or by primer-template misalignment. This latter property explains how hPolκ creates single-base deletions in non-repetitive sequences, but does not address how deletions occur in repetitive deletion hotspots. Here, we show that hPolκ uses a classical Streisinger template-slippage mechanism to generate −1 deletions in repetitive sequences, as do the bacterial and archaeal homologues. After the first nucleotide is added by template slippage, however, hPolκ can efficiently realign the primer-template duplex before continuing DNA synthesis. Strand realignment results in a base-substitution mutation, minimizing generation of more deleterious frameshift mutations. On non-repetitive sequences, we find that nucleotide misincorporation is slower if the incoming nucleotide can correctly basepair with the nucleotide immediately 5′ to the templating base, thereby competing against the mispairing with the templating base.

Both conserved and non-conserved regions of Spo11 are essential for meiotic recombination initiation in yeast

DNA double-strand breaks (DSBs) are the initiators of most meiotic recombination events. In Saccharomyces cerevisiae, at least ten genes are necessary for meiotic DSB formation. However, the molecular roles of these proteins are not clearly understood. The meiosis-specific Spo11 protein, which shows sequence similarity with a subunit of an archaeal topoisomerase, is believed to catalyze the meiotic DSB formation. Spo11 is also required for induction of meiotic DSBs at long inverted repeats and at large trinucleotide repeat tracts. Here we report the isolation and characterization of temperature-sensitive spo11-mutant alleles to better understand how Spo11 functions, and how meiotic DSBs are generated at various recombination hotspots. Analysis of mutation sites of isolated spo11-mutant alleles indicated that both N-terminal and C-terminal non-conserved residues of Spo11 are essential for the protein’s function, possibly for interaction with other meiotic DSB enzymes. Several of the mutation sites within the conserved region are predicted to lie on the surface of the protein, suggesting that this region is required for activation of the meiotic initiation complex via protein-protein interaction. In addition to the conditional mutants, we isolated partially recombination-defective mutants; analysis of one of these mutants indicated that Ski8, as observed previously, interacts with Spo11 via the latter’s C-terminal residues.

Mutagen resistance and mutation restriction of St. Louis encephalitis virus

The error rate of the RNA-dependent RNA polymerase (RdRp) of RNA viruses is important in maintaining genetic diversity for viral adaptation and fitness. Numerous studies have shown that mutagen-resistant RNA virus variants display amino acid mutations in the RdRp and other replicase subunits, which in turn exhibit an altered fidelity phenotype affecting viral fitness, adaptability and pathogenicity. St. Louis encephalitis virus (SLEV), like its close relative West Nile virus, is a mosquito-borne flavivirus that has the ability to cause neuroinvasive disease in humans. Here, we describe the successful generation of multiple ribavirin-resistant populations containing a shared amino acid mutation in the SLEV RdRp (E416K). These E416K mutants also displayed resistance to the antiviral T-1106, an RNA mutagen similar to ribavirin. Structural modelling of the E416K polymerase mutation indicated its location in the pinky finger domain of the RdRp, distant from the active site. Deep sequencing of the E416K mutant revealed lower genetic diversity than wild-type SLEV after growth in both vertebrate and invertebrate cells. Phenotypic characterization showed that E416K mutants displayed similar or increased replication in mammalian cells, as well as modest attenuation in mosquito cells, consistent with previous work with West Nile virus high-fidelity variants. In addition, attenuation was limited to mosquito cells with a functional RNA interference response, suggesting an impaired capacity to escape RNA interference could contribute to attenuation of high-fidelity variants. Our results provide increased evidence that RNA mutagen resistance arises through modulation of the RdRp and give further insight into the consequences of altered fidelity of flaviviruses.The error rate of the RNA-dependent RNA polymerase (RdRp) of RNA viruses is important in maintaining genetic diversity for viral adaptation and fitness. Numerous studies have shown that mutagen-resistant RNA virus variants display amino acid mutations in the RdRp and other replicase subunits, which in turn exhibit an altered fidelity phenotype affecting viral fitness, adaptability, and pathogenicity. St. Louis encephalitis virus (SLEV), like its close relative West Nile virus (WNV), is a mosquito-borne flavivirus which has the ability to cause neuroinvasive disease in humans. Here, we describe the successful generation of multiple ribavirin-resistant populations containing a shared amino acid mutation in the SLEV RdRp (E416K). These E416K mutants also displayed resistance to the antiviral T-1106, an RNA mutagen similar to ribavirin. Structural modeling of the E416K polymerase mutation indicate its location in the pinky finger domain of the RdRp, distant from the active site. Deep-sequencing of the E416K mutant revealed lower genetic diversity than wildtype SLEV after growth in both vertebrate and invertebrate cells. Phenotypic characterization showed E416K mutants displayed similar or increased replication in mammalian cells, as well as modest attenuation in mosquito cells, consistent with previous work with WNV high-fidelity variants. In addition, attenuation was limited to mosquito cells with a functional RNA interference (RNAi) response, suggesting an impaired capacity to escape RNAi could contribute to attenuation of high-fidelity variants. Our results provide increased evidence that RNA mutagen resistance arises through modulation of the RdRp and gives further insight into the consequences of altered fidelity of flaviviruses.

Differential Gene Regulation in Yersinia pestis versus Yersinia pseudotuberculosis: Effects of Hypoxia and Potential Role of a Plasmid Regulator

The molecular basis of the biological differences between Yersinia pestis and Yersinia pseudotuberculosis remains largely unknown, and relatively little is known about environmental regulation of gene expression in these bacteria. We used a proteomic approach to explore the regulatory response of each bacterium to carbon dioxide-supplemented hypoxic conditions. Both organisms responded similarly and the magnitude of their responses was similar to what was observed in low iron conditions. We also identified proteins that were expressed at different levels in Y. pestis and Y. pseudotuberculosis, and found that SodB is expressed more strongly at both the protein and RNA levels in Y. pseudotuberculosis than in Y. pestis. Enzyme activity did not directly correlate with levels of protein expression, and we propose that an amino acid change difference between these orthologous proteins has the potential to affect catalytic activity. In addition, the upstream regulatory regions of several chromosomal genes were found to exhibit specific binding with a putative transcription factor, CDS4, from the Y. pestis-specific pPCPI plasmid. The potential role of this protein in modulating Y. pestis- specific gene regulation warrants further investigation.