Hydrophobic and charged residues in the C-terminal arm of hepatitis C virus RNA-dependent RNA polymerase regulate initiation and elongation.

UNLABELLED: The RNA-dependent RNA polymerase (RdRp) of hepatitis C virus (HCV) is essential for viral genome replication. Crystal structures of the HCV RdRp reveal two C-terminal features, a ß-loop and a C-terminal arm, suitably located for involvement in positioning components of the initiation complex. Here we show that these two elements intimately regulate template and nucleotide binding, initiation, and elongation. We constructed a series of ß-loop and C-terminal arm mutants, which were used for in vitro analysis of RdRp de novo initiation and primer extension activities. All mutants showed a substantial decrease in initiation activities but a marked increase in primer extension activities, indicating an ability to form more stable elongation complexes with long primer-template RNAs. Structural studies of the mutants indicated that these enzyme properties might be attributed to an increased flexibility in the C-terminal features resulting in a more open polymerase cleft, which likely favors the elongation process but hampers the initiation steps. A UTP cocrystal structure of one mutant shows, in contrast to the wild-type protein, several alternate conformations of the substrate, confirming that even subtle changes in the C-terminal arm result in a more loosely organized active site and flexible binding modes of the nucleotide. We used a subgenomic replicon system to assess the effects of the same mutations on viral replication in cells. Even the subtlest mutations either severely impaired or completely abolished the ability of the replicon to replicate, further supporting the concept that the correct positioning of both the ß-loop and C-terminal arm plays an essential role during initiation and in HCV replication in general. IMPORTANCE: HCV RNA polymerase is a key target for the development of directly acting agents to cure HCV infections, which necessitates a thorough understanding of the functional roles of the various structural features of the RdRp. Here we show that even highly conservative changes, e.g., Tyr→Phe or Asp→Glu, in these seemingly peripheral structural features have profound effects on the initiation and elongation properties of the HCV polymerase.

Residues Arg283, Arg285, and Ile287 in the nucleotide binding pocket of bovine viral diarrhea virus NS5B RNA polymerase affect catalysis and fidelity.

Residues Arg283, Arg285, and Ile287 are highly conserved amino acids in bovine viral diarrhea virus RNA polymerase (BVDV RdRp) and RdRps from related positive-strand RNA viruses. This motif is an important part of the binding pocket for the nascent RNA base pair during initiation and elongation. We found that replacement of the arginines with alanines or more conserved lysines or replacement of isoleucine with alanine or valine alters the ability of the mutant RdRps to incorporate ribonucleotides efficiently. The reduced RdRp activity stems from both decreased ribonucleotide binding and decreased catalytic efficiency in both primer-dependent and de novo initiation, as shown by kinetic studies. In line with other studies on flaviviral RdRps, our data suggest that Arg283 and Ile287 may be implicated in ribonucleotide binding and positioning of the template base in the active site. Arg285 appears to be involved directly in the selection of cognate nucleotide. The findings for Arg285 and Ile287 mutants also agree with similar data from picornavirus RdRps.

Structural changes in the hydrophobic hinge region adversely affect the activity and fidelity of the I260Q mutator DNA polymerase ß.

The I260Q variant of DNA polymerase ß is an efficient mutator polymerase with fairly indiscriminate misincorporation activities opposite all template bases. Previous modeling studies have suggested that I260Q harbors structural variations in its hinge region. Here, we present the crystal structures of wild type and I260Q rat polymerase ß in the presence and absence of substrates. Both the I260Q apoenzyme structure and the closed ternary complex with double-stranded DNA and ddTTP show ordered water molecules in the hydrophobic hinge near Gln260, whereas this is not the case in the wild type polymerase. Compared to wild type polymerase ß ternary complexes, there are subtle movements around residues 260, 272, 295, and 296 in the mutant. The rearrangements in this region, coupled with side chain movements in the immediate neighborhood of the dNTP-binding pocket, namely, residues 258 and 272, provide an explanation for the altered activity and fidelity profiles observed in the I260Q mutator polymerase.

Colon cancer-associated DNA polymerase ß variant induces genomic instability and cellular transformation.

Rapidly advancing technology has resulted in the generation of the genomic sequences of several human tumors. We have identified several mutations of the DNA polymerase ß (pol ß) gene in human colorectal cancer. We have demonstrated that the expression of the pol ß G231D variant increased chromosomal aberrations and induced cellular transformation. The transformed phenotype persisted in the cells even once the expression of G231D was extinguished, suggesting that it resulted as a consequence of genomic instability. Biochemical analysis revealed that its catalytic rate was 140-fold slower than WT pol ß, and this was a result of the decreased binding affinity of nucleotides by G231D. Residue 231 of pol ß lies in close proximity to the template strand of the DNA. Molecular modeling demonstrated that the change from a small and nonpolar glycine to a negatively charged aspartate resulted in a repulsion between the template and residue 231 leading to the distortion of the dNTP binding pocket. In addition, expression of G231D was insufficient to rescue pol ß-deficient cells treated with chemotherapeutic agents suggesting that these agents may be effectively used to treat tumors harboring this mutation. More importantly, this suggests that the G231D variant has impaired base excision repair. Together, these data indicate that the G231D variant plays a role in driving cancer.

The E288K colon tumor variant of DNA polymerase ß is a sequence specific mutator.

DNA polymerase ß (pol ß) is the main polymerase involved in base excision repair (BER), which is a pathway responsible for the repair of tens of thousands of DNA lesions per cell per day. Our recent efforts in sequencing colon tumors showed that 40% of the tumors sequenced possessed a variant in the coding region of the POLB gene; one of these variants is E288K. Expression of the E288K variant in cells leads to an increase in the frequency of mutations at AT base pairs. In vitro, the E288K variant is as active as and binds one-base-gapped DNA with the same affinity as wild-type pol ß. Single-turnover kinetic data for the E288K variant show that its mutator phenotype is specific for misincorporating opposite template A up to 6-fold more than the wild-type enzyme and that this is due to a decrease in the degree of discrimination in nucleotide binding. Molecular modeling suggests that the substitution of Lys at position 288 causes the polymerase to adopt a more open conformation, which may be disrupting the nucleotide binding pocket. This may explain the reduced degree of discrimination at the level of nucleotide binding. The enhanced mutagenesis of the E288K variant could lead to genomic instability and ultimately a malignant tumor phenotype.

Unfavorable electrostatic and steric interactions in DNA polymerase ß E295K mutant interfere with the enzyme's pathway.

Mutations in DNA polymerase ß (pol ß) have been associated with approximately 30% of human tumors. The E295K mutation of pol ß has been linked to gastric carcinoma via interference with base excision repair. To interpret the different behavior of E295K as compared to wild-type pol ß in atomic and energetic detail, we resolve a binary crystal complex of E295K at 2.5 Å and apply transition path sampling (TPS) to delineate the closing pathway of the E295K pol ß mutant. Conformational changes are important components in the enzymatic pathway that lead to and ready the enzyme for the chemical reaction. Our analyses show that the closing pathway of E295K mutant differs from the wild-type pol ß in terms of the individual transition states along the pathway, associated energies, and the active site conformation in the final closed form of the mutant. In particular, the closed state of E295K has a more distorted active site than the active site in the wild-type pol ß. In addition, the total energy barrier in the conformational closing pathway is 65 ± 11 kJ/mol, much higher than that estimated for both correct (e.g., G:C) and incorrect (e.g., G:A) wild-type pol ß systems (42 ± 8 and 45 ± 7 kJ/mol, respectively). In particular, the rotation of Arg258 is the rate-limiting step in the conformational pathway of E295K due to unfavorable electrostatic and steric interactions. The distorted active site in the closed relative to open state and the high energy barrier in the conformational pathway may explain in part why the E295K mutant is observed to be inactive. Interestingly, however, following the closing of the thumb but prior to the rotation of Arg258, the E295K mutant complex has a similar energy level as compared to the wild-type pol ß. This suggests that the E295K mutant may associate with DNA with similar affinity, but it may be hampered in continuing the process of chemistry. Supporting experimental data come from the observation that the catalytic activity of wild-type pol ß is hampered when E295K is present: this may arise from the competition between E295K and wild-type enzyme for the DNA. These combined results suggest that the low insertion efficiency of E295K mutant as compared to wild-type pol ß may be related to a closed form distorted by unfavorable electrostatic and steric interactions between Arg258 and other key residues. The active site is thus less competent for proceeding to the chemical reaction, which may also involve a higher reaction barrier than the wild-type or may not be possible in this mutant. Our analysis also suggests further experiments for other mutants to test the above hypothesis and dissect the roles of steric and electrostatic factors on enzyme behavior.

A triad interaction in the fingers subdomain of DNA polymerase beta controls polymerase activity.

DNA polymerase beta (pol beta) is the main polymerase involved in the base excision repair pathway responsible for repairing damaged bases in the DNA. Previous studies on the H285D mutant of pol beta suggested that the C-terminal region of the polymerase is important for polymerase function. In this study, the C-terminal region of pol beta was mutated to assess its role in polymerization. Kinetic experiments showed that the C-terminal region is required for wild-type polymerase activity. Additionally, an interaction between the fingers and palm subdomain revealed itself to be required for polymerase activity. The E316R mutant of pol beta was shown to have a 29,000-fold reduction in polymerization rate with no reduction in nucleotide binding, suggesting that there exists a noncovalent mechanistic step between nucleotide binding and nucleophilic attack of the primer 3'-hydroxyl group on the α-PO(4) of the nucleotide. Molecular modeling studies of the E316R mutant demonstrate that disrupting the interaction between Arg182 and Glu316 disrupts the packing of side chains in the hydrophobic hinge region and may be hampering the conformational change during polymerization. Taken together, these data demonstrate that the triad interaction of Arg182, Glu316, and Arg333 is crucial for polymerase function.

Hinge residue I174 is critical for proper dNTP selection by DNA polymerase beta.

DNA polymerase beta (pol beta) is the key gap-filling polymerase in base excision repair, the DNA repair pathway responsible for repairing up to 20000 endogenous lesions per cell per day. Pol beta is also widely used as a model polymerase for structure and function studies, and several structural regions have been identified as being critical for the fidelity of the enzyme. One of these regions is the hydrophobic hinge, a network of hydrophobic residues located between the palm and fingers subdomains. Previous work by our lab has shown that hinge residues Y265, I260, and F272 are critical for polymerase fidelity by functioning in discrimination of the correct from incorrect dNTP during ground state binding. Our work aimed to elucidate the role of hinge residue I174 in polymerase fidelity. To study this residue, we conducted a genetic screen to identify mutants with a substitution at residue I174 that resulted in a mutator polymerase. We then chose the mutator mutant I174S for further study and found that it follows the same general kinetic pathway as and has an overall protein folding similar to that of wild-type (WT) pol beta. Using single-turnover kinetic analysis, we found that I174S exhibits decreased fidelity when inserting a nucleotide opposite a template base G, and this loss of fidelity is due primarily to a loss of discrimination during ground state dNTP binding. Molecular dynamics simulations show that mutation of residue I174 to serine results in an overall tightening of the hinge region, resulting in aberrant protein dynamics and fidelity. These results point to the hinge region as being critical in the maintenance of the proper geometry of the dNTP binding pocket.

Loop II of DNA polymerase beta is important for discrimination during substrate binding.

Loop II of DNA polymerase beta (pol beta) consists of 14 amino acid residues and is highly flexible and solvent exposed. Previous research from our laboratory has shown that this loop is important for polymerase activity and fidelity. In the study presented here, we demonstrate that a shortened five amino acid residue loop compromises the fidelity of pol beta. This five-residue loop, termed ENEYP, induces one base frameshift errors and A-C transversions within a specific sequence context. We demonstrate that ENEYP misincorporates dGTP opposite template A at higher efficiencies than wild-type pol beta. The kinetic basis for misincorporation is a defect in discrimination of the correct from incorrect dNTP substrate at the level of ground-state binding. Our results are consistent with the idea that loop II of pol beta functions to maintain accurate DNA synthesis by a direct or indirect influence on the nucleotide binding pocket.

The Leu22Pro tumor-associated variant of DNA polymerase beta is dRP lyase deficient.

Approximately 30% of human tumors characterized to date express DNA polymerase beta (pol beta) variant proteins. Two of the polymerase beta cancer-associated variants are sequence-specific mutators, and one of them binds to DNA but has no polymerase activity. The Leu22Pro (L22P) DNA polymerase beta variant was identified in a gastric carcinoma. Leu22 resides within the 8 kDa amino terminal domain of DNA polymerase beta, which exhibits dRP lyase activity. This domain catalyzes the removal of deoxyribose phosphate during short patch base excision repair. We show that this cancer-associated variant has very little dRP lyase activity but retains its polymerase activity. Although residue 22 has no direct contact with the DNA, we report here that the L22P variant has reduced DNA-binding affinity. The L22P variant protein is deficient in base excision repair. Molecular dynamics calculations suggest that alteration of Leu22 to Pro changes the local packing, the loop connecting helices 1 and 2 and the overall juxtaposition of the helices within the N-terminal domain. This in turn affects the shape of the binding pocket that is required for efficient dRP lyase catalysis.

Loop II of DNA polymerase beta is important for polymerization activity and fidelity.

The accurate replication and transmission of genetic information is critical in the life of an organism. During its entire lifespan, the genetic information is constantly under attack from endogenous and exogenous sources of damage. To ensure that the content of its genetic information is faithfully preserved for synthesis and transmission, eukaryotic cells have developed a complex system of genomic quality control. Key players in this process are DNA polymerases, the enzymes responsible for synthesizing the DNA, because errors introduced into the genome by polymerase can result in mutations. We use DNA polymerase beta (pol beta) as a model system to investigate mechanisms of preserving fidelity during nucleotide incorporation. In the study described here, we characterized the role that loop II of pol beta plays in maintaining the activity and fidelity of pol beta. We report here that the absence or shortening of loop II compromises the catalytic activity of pol beta. Our data also show that loop variants of a specific length have a lower fidelity when compared to the wild-type polymerase. Taken together, our results indicate that loop II is important for the catalytic activity and fidelity of pol beta.

The I260Q variant of DNA polymerase beta extends mispaired primer termini due to its increased affinity for deoxynucleotide triphosphate substrates.

DNA polymerase beta plays a key role in base excision repair. We have previously shown that the hydrophobic hinge region of polymerase beta, which is distant from its active site, plays a critical role in the fidelity of DNA synthesis by this enzyme. The I260Q hinge variant of polymerase beta misincorporates nucleotides with a significantly higher catalytic efficiency than the wild-type enzyme. In the study described here, we show that I260Q extends mispaired primer termini. The kinetic basis for extension of mispairs is defective discrimination by I260Q at the level of ground-state binding of the dNTP substrate. Our results suggest that the hydrophobic hinge region influences the geometry of the dNTP binding pocket exclusively. Because the DNA forms part of the binding pocket, our data are also consistent with the interpretation that the mispaired primer terminus affects the geometry of the dNTP binding pocket such that the I260Q variant has a higher affinity for the incoming dNTP than wild-type polymerase beta.

The Asp285 variant of DNA polymerase beta extends mispaired primer termini via increased nucleotide binding.

Endogenous DNA damage occurs at a rate of at least 20,000 lesions per cell per day. Base excision repair (BER) is a key pathway for maintaining genome stability. Several pol beta variants were identified as conferring resistance to 3'-azido-3'-deoxythymidine (AZT) in Escherichia coli (Kosa et al. (1999) J. Biol. Chem. 274, 3851-3858). Detailed biochemical studies on one of these AZT-resistant variants, His285 to Asp, have shown that the H285D variant of pol beta possesses pre-steady-state kinetics that are similar to the wild-type polymerase. In gap filling assays with 5-bp gapped DNA, H285D showed a slight mutator phenotype. In depth single turnover kinetic analysis revealed that H285D is much more efficient than wild-type pol beta at extending mispaired primer termini. This mispair extension property of H285D is attributed to a greatly increased binding to the next correct nucleotide in the presence of a mispair. This change in K d(dNTP),app is not accompanied by a change in k pol; values for k pol are the same for both H285D and wild-type. Close examination of available structural data, as well as molecular modeling, has shown that residue 285 is able to make several stabilizing contacts in the fingers domain of the polymerase, and the introduction of a negatively charged side chain could have important effects on the enzyme. It is postulated that the loss of the contact between His285, Lys289, and Ile323 is responsible for the ability of H285D to extend mispairs through disruption of contacts near the C-terminal end of pol beta and propagation into the nucleotide binding pocket.

Co-translational myristoylation alters the quaternary structure of HIV-1 Nef in solution.

We have studied the solution properties of Nef, a 24-kDa cotranslationally myristoylated protein produced by HIV-1 and other primate lentiviruses. Nef is found in the cytosol and also in association with cytoplasmic membranes, the latter, mediated in part by the myristoyl group attached to the N-terminal glycine. Recombinant Nef was coexpressed in Escherichia coli in tandem with N-myristoyl-transferase and is fully myristoylated. Analysis by circular dichroism showed the myristoylated form to contain a greater alpha-helical content than the nonmyristoylated form. Analysis of modified and unmodified Nef in solution using small angle X-ray scattering, dynamic laser light scattering and analytical ultracentrifugation consistently showed differences in the oligomeric states of the two forms of Nef. Myristoylated Nef is predominantly monomeric and small oligomers which are also present, can be converted to the monomeric form under reducing conditions. By contrast, the nonmyristoylated form exists as a stable hexadecamer in solution which disassociates into tetramers upon addition of reducing agents. Shape reconstructions from small angle scattering curves of nonmyristoylated Nef are compatible with a large disc-like structure in the hexadecameric oligomer consisting of four Nef tetramers. From these findings, we hypothesize that Nef undergoes a substantial conformational change from an "open" into a "closed" form whereby the myristate group is sequestered in a hydrophobic pocket. The myristoylated protein can switch to the open conformation by association of the N-terminal region of molecule with membranes. These changes would allow Nef to carry out various functions depending on the conformational and oligomeric states.

The p7 protein of hepatitis C virus forms an ion channel that is blocked by the antiviral drug, Amantadine.

Hepatitis C virus (HCV) cannot be grown in vitro, making biochemical identification of new drug targets especially important. HCV p7 is a small hydrophobic protein of unknown function, yet necessary for particle infectivity in related viruses [Harada, T. et al., (2000) J. Virol. 74, 9498-9506]. We show that p7 can be cross-linked in vivo as hexamers. Escherichia coli expressed p7 fusion proteins also form hexamers in vitro. These and HIS-tagged p7 function as calcium ion channels in black lipid membranes. This activity is abrogated by Amantadine, a compound that inhibits ion channels of influenza [Hay, A.J. et al. (1985) EMBO J. 4, 3021-3024; Duff, K.C. and Ashley, R.H. (1992) Virology 190, 485-489] and has recently been shown to be active in combination with current HCV therapies.

Hand-holding for retrohoming in a molecular diversity dance.

In bacterial systems, adaptive protein sequence changes can be mediated by diversity-generating retroelements in a process known as retrohoming. An accessory variability determinant (Avd), together with a reverse transcriptase (RT), is critically involved in this process. In this issue of Structure, Alayyoubi and colleagues describe the structure of Avd as a basis for interactions with RT that promote retrohoming.

Point mutations in the West Nile virus (Flaviviridae; Flavivirus) RNA-dependent RNA polymerase alter viral fitness in a host-dependent manner in vitro and in vivo.

The West Nile virus (WNV) genome contains a single RNA-dependent RNA polymerase (RdRp) gene, which is responsible for replication of the viral genome and, as such, is an important target for antiviral therapy. Viral RdRps are known to lack proofreading capabilities and as a result viruses such as WNV exist as a mixture of viral genotypes within an infection, enabling the virus to readily emerge and adapt to new host environments. To test the consequences of subtle structural alterations remote from the RdRp active-site, the following single point mutations were engineered in the WNV NS5 RdRp coding region: T363N, A365N, and T537I; these mutations were selected in an effort to stabilize the secondary structural elements near the rNTP binding pocket of the RdRp. Mutant viruses were tested in vitro on Vero, C6/36, Culex tarsalis and DF-1 cell types and in vivo in one day old chickens and Culex pipiens mosquitoes. Plaque morphology was affected by each mutation and growth and RNA replication kinetics were altered as well. Our results demonstrate that subtle alteration of the RdRp protein away from the active site can have a significant overall biological effect on WNV fitness, and that this effect can be host-dependent.

Biochemical and pre-steady-state kinetic characterization of the hepatitis C virus RNA polymerase (NS5BDelta21, HC-J4).

Here we report a detailed characterization of the biochemical and kinetic properties of the hepatitis C virus (HCV, genotype-1b, J4 consensus) RNA-dependent RNA polymerase NS5B, by performing comprehensive RNA binding, nucleotide incorporation, and protein/protein oligomerization studies. By applying equilibrium fluorescence titrations, we determined a surprisingly high dissociation constant (K(d)) of approximately 250 nM for single-stranded as well as for partially double-stranded RNA. A detailed analysis of the nucleic acid binding mechanism using pre-steady-state techniques revealed the association reaction to be nearly diffusion controlled. It occurs in a single step with a second-order rate constant (k(on)) of 0.273 nM(-)(1) s(-)(1). The dissociation of the nucleic acid-polymerase complex is fast with a dissociation rate constant (k(off)) of 59.3 s(-)(1). With short, partially double-stranded RNAs, no nucleotide incorporation could be observed, while de novo RNA synthesis with short RNA templates showed nucleotide incorporation and end-to-end template switching events. Single-turnover, single-nucleotide incorporation studies (representing here the initiation and not processive polymerization) using dinucleotide primers revealed a very slow incorporation rate (k(pol)) of 0.0007 s(-)(1) and a K(d) of the binary enzyme-nucleic acid complex for the incoming ATP of 27.7 microM. Using dynamic laser light scattering, it could be shown for the first time that oligomerization of HCV NS5B is a dynamic and monovalent salt concentration dependent process. While NS5B is highly oligomeric at low salt concentrations, monomers were only observed at NaCl concentrations above 300 mM. Binding of short RNA substrates led to a further increase in oligomerization, whereas GTP did not show any effect on protein/protein interactions. Furthermore, nucleotide incorporation studies indicate the oligomerization state does not correlate with enzymatic activities as previously proposed.

The hydrophobic hinge region of rat DNA polymerase beta is critical for substrate binding pocket geometry.

The hydrophobic hinge of DNA polymerase beta facilitates closing and stabilization of the enzyme once the nucleotide substrate has bound. Alteration of the hydrophobic nature of the hinge by the introduction of a hydrophilic glutamine residue in place of isoleucine 260 results in an inaccurate polymerase. The kinetic basis of infidelity is lack of discrimination during the binding of substrate. The I260Q polymerase beta variant has lower affinity than wild type enzyme for the correct substrate and much higher affinity for the incorrect substrate. Our results demonstrate that the hinge is important for formation of the substrate binding pocket. Our results are also consistent with the interpretation that DNA polymerase beta discriminates the correct from incorrect substrate during the binding step.