Polymerase Active Site Research Articles

Construction of A Preliminary Three-Dimensional Structure Simian betaretrovirus Serotype-2 (SRV-2) Reverse Transcriptase Isolated from Indonesian Cynomolgus Monkey.

Simian betaretrovirus serotype-2 (SRV-2) is an important pathogenic agent in Asian macaques. It is a potential confounding variable in biomedical research. SRV-2 also provides a valuable viral model compared to other retroviruses which can be used for understanding many aspects of retroviral-host interactions and immunosuppression, infection mechanism, retroviral structure, antiretroviral and vaccine development. In this study, we isolated the gene encoding reverse transcriptase enzyme (RT) of SRV-2 that infected Indonesian cynomolgus monkey (Mf ET1006) and predicted the three dimensional structure model using the iterative threading assembly refinement (I-TASSER) computational programme. This SRV-2 RT Mf ET1006 consisted of 547 amino acids at nucleotide position 3284–4925 of whole genome SRV-2. The polymerase active site located in the finger/palm subdomain characterised by three conserved catalytic aspartates (Asp90, Asp165, Asp166), and has a highly conserved YMDD motif as Tyr163, Met164, Asp165 and Asp166. We estimated that this SRV-2 RT Mf ET1006 structure has the accuracy of template modelling score (TM-score 0.90 ± 0.06) and root mean square deviation (RMSD) 4.7 ± 3.1Å, indicating that this model can be trusted and the accuracy can be seen from the appearance of protein folding in tertiary structure. The superpositionings between SRV-2 RT Mf ET1006 and Human Immunodeficiency Virus-1 (HIV-1) RT were performed to predict the structural in details and to optimise the best fits for illustrations. This SRV-2 RT Mf ET1006 structure model has the highest homology to HIV-1 RT (2B6A.pdb) with estimated accuracy at TM-score 0.911, RMSD 1.85 Å, and coverage of 0.953. This preliminary study of SRV-2 RT Mf ET1006 structure modelling is intriguing and provide some information to explore the molecular characteristic and biochemical mechanism of this enzyme.

Replication of the Aristolochic Acid I Adenine Adduct (ALI-N6-A) by a Model Translesion Synthesis DNA Polymerase: Structural Insights on the Induction of Transversion Mutations from Molecular Dynamics Simulations.

Exposure to aristolochic acid I and II (AAI and AAII) has been implicated in aristolochic acid nephropathy and urothelial carcinoma. The toxicological effects of AAs are attributed to their ability to form aristolacatam (AL)-purine DNA adducts. Among these lesions, the AL-adenine (ALI-N6-A and ALII-N6-A) adducts cause the "signature" A → T transversion mutations associated with AA genotoxicity. To provide the currently missing structural basis for the induction of these signature mutations, the present work uses classical all-atom molecular dynamics simulations to examine different (i.e., preinsertion, insertion, and postextension) stages of replication past the most abundant AA adduct (ALI-N6-A) by a representative lesion-bypass DNA polymerase (Dpo4). Our analysis reveals that, before dNTP incorporation (i.e., preinsertion step), ALI-N6-A adopts a nearly planar conformation at the N6-linkage and the ALI moiety intercalates within the DNA helix. Since this conformation occupies the dNTP binding site, the same planar lesion conformation results in a significant distortion of the polymerase active site at the insertion step and therefore replication will likely not be successful. However, if ALI-N6-A undergoes a small conformational change to introduce non-planarity at the N6-linkage during the insertion step, minimal distortion occurs in the Dpo4 active site upon incorporation of dATP. This insertion and subsequent extension would initially lead to A:A mismatches and then result in A → T transversion mutations during the second round of replication. In contrast, if a large conformation flip of the ALI moiety occurs at the insertion step to reorient the bulky moiety from an intercalated position into the major groove, dTTP (non-mutagenic) incorporation will be favored. Molecular dynamics (MD) simulations on postextension complexes reveal that damaged DNA will likely further rearrange during later replication steps to acquire a base-displaced intercalated conformation that is similar to that previously reported for (unbound) ALI-N6-A adducted DNA, with the exception of slight non-planarity at the lesion site. Overall, our results provide a structural explanation for both the successful non-mutagenic lesion bypass and the preferential misincorporation of dATP opposite ALI-N6-A and thereby rationalize the previously reported induction of A → T signature transversion mutations associated with AAs. This work should thereby inspire future biochemical experiments and modeling studies on the replication of this important class of DNA lesions by related human translesion synthesis polymerases.

Checkpoint-Mediated DNA Polymerase ε Exonuclease Activity Curbing Counteracts Resection-Driven Fork Collapse

DNA polymerase epsilon (Pole) carries out leading strand synthesis with high fidelity owing to its exonuclease activity. Pole polymerase and exonuclease activities are balanced, due to partitioning of nascent DNA strands between catalytic sites, so that net resection occurs when synthesis is impaired. In vivo, DNA synthesis stalling activates replication checkpoint kinases, which act to preserve the functional integrity of replication forks. Here we show that stalled Pole drives nascent strand resection causing fork functional collapse, averted via checkpoint-dependent phosphorylation. Pole catalytic subunit Pol2 is phosphorylated on serine 430, which influences partitioning between polymerase and exonuclease active sites. A phosphormimetic S430D change reduces exonucleolysis in vitro and counteracts fork functional collapse. Conversely, non-phosphorylatable pol2-S430A expression results in resection-driven collapse of stressed forks. Our findings reveal that checkpoint kinases switch Pole to an exonuclease-safe mode preventing nascent strand resection and stabilizing stalled replication forks. Elective partitioning suppression has implications for the diverse Pole roles in genome integrity maintenance.

Inactivating Mutations in Exonuclease and Polymerase Domains in DNA Polymerase Delta Alter Sensitivities to Inhibitors of dNTP Synthesis.

POLD1 encodes the catalytic subunit of DNA polymerase delta (Polδ), the major lagging strand polymerase, which also participates in DNA repair. Mutations affecting the exonuclease domain increase the risk of various cancers, while mutations that change the polymerase active site cause a progeroid syndrome called mandibular hypoplasia, deafness, progeroid features, and lipodystrophy (MDPL) syndrome. We generated a set of catalytic subunit of human telomerase (hTERT)-immortalized human fibroblasts expressing wild-type or mutant POLD1 using the retroviral LXSN vector system. In the resulting cell lines, expression of endogenous POLD1 was suppressed in favor of the recombinant POLD1. The siRNA screening of DNA damage-related genes revealed that fibroblasts expressing D316H and S605del POLD1 were more sensitive to knockdowns of ribonuclease reductase (RNR) components, RRM1 and RRM2 in the presence of hydroxyurea (HU), an RNR inhibitor. On the contrary, SAMHD1 siRNA, which increases the concentration of dNTPs, increased growth of wild type, D316H, and S605del POLD1 fibroblasts. Hypersensitivity to dNTP synthesis inhibition in POLD1 mutant lines was confirmed using gemcitabine. Our finding is consistent with the notion that reduced dNTP concentration negatively affects the cell growth of hTERT fibroblasts expressing exonuclease and polymerase mutant POLD1.

Structural Basis of HIV-1 Inhibition by Nucleotide-Competing Reverse Transcriptase Inhibitor INDOPY-1.

HIV-1 reverse transcriptase (RT) is an essential enzyme, targeting half of approved anti-AIDS drugs. While nucleoside RT inhibitors (NRTIs) are DNA chain terminators, the nucleotide-competing RT inhibitor (NcRTI) INDOPY-1 blocks dNTP binding to RT. Lack of structural information hindered INDOPY-1 improvement. Here we report the HIV-1 RT/DNA/INDOPY-1 crystal structure, revealing a unique mode of inhibitor binding at the polymerase active site without involving catalytic metal ions. The structure may enable new strategies for developing NcRTIs.

Transcriptional Bypass of DNA-Protein and DNA-Peptide Conjugates by T7 RNA Polymerase.

DNA-protein cross-links (DPCs) are unusually bulky DNA adducts that block the access of proteins to DNA and interfere with gene expression, replication, and repair. We previously described DPC formation at the N7-guanine position of DNA in human cells treated with antitumor nitrogen mustards and platinum compounds and have shown that DPCs can form endogenously at DNA epigenetic mark 5-formyl-dC. However, insufficient information is available about the effects of these structurally distinct DPCs on transcription. In the present work, we employ a combination of in vitro assays, mass spectrometry, and molecular dynamics simulations to examine the ability of phage T7 RNA polymerase to bypass DPCs conjugated to the C7 position of 7-deaza-dG and the C5 position of dC. These model adducts represent endogenous DPCs induced by exposure to antitumor drugs and formed at epigenetics DNA marks, respectively. Our results reveal that DPCs containing full-length proteins significantly inhibit in vitro transcription by T7 RNA polymerase, while short DNA-peptide cross-links (DpCs) are bypassed. DpCs conjugated to the C7 position of 7-deaza-dG are transcribed with high fidelity, while the same polypeptides attached to the C5 position of dC induce transcription errors. Molecular dynamics simulations of DpCs conjugated either to the C5 atom of dC or the C7 position of 7-deaza-dG on the template strand in T7 RNA polymerase explain how the conjugated peptide can be accommodated in the narrow major groove of the DNA-RNA hybrid and how the modified dC can form a stable mismatch with the incoming ATP in the polymerase active site, allowing for transcriptional mutagenesis.

Ribonucleoside triphosphates promote T7 DNA replication and the lysis of T7-Infected Escherichia coli

rNTPs are structurally similar to dNTPs, but their concentrations are much higher than those of dNTPs in cells. rNTPs in solutions or rNMP at the primer terminus or embedded in template always inhibit or block DNA replication, due to the reduced Mg2+ apparent concentration, competition of rNTPs with dNTPs, and the extra repulsive interaction of rNTP or rNMP with polymerase active site. In this work, unexpectedly, we found rNTPs can promote T7 DNA replication with the maximal promotion at rNTPs/dNTPs concentration ratio of 20. This promotion was not due to the optimized Mg2+ apparent concentration or the direct incorporation of extra rNMPs into DNA. This promotion was dependent on the concentrations and types of rNTPs. Kinetic analysis showed that this promotion was originated from the increased fraction of polymerase-DNA productive complex and the accelerated DNA polymerization. Further evidence showed that more polymerase-DNA complex was formed and their binding affinity was also enhanced in the presence of extra rNTPs. Moreover, this promotion in T7 DNA replication also accelerated the lysis of T7-infected host Escherichia coli. This work discovered that rNTPs could promote DNA replication, completely different from the traditional concept that rNTPs always inhibit DNA replication.

Networked Communication between Polymerase and Exonuclease Active Sites in Human Mitochondrial DNA Polymerase.

High fidelity human mitochondrial DNA polymerase (Pol γ) contains two active sites, a DNA polymerization site (pol) and a 3'-5' exonuclease site (exo) for proofreading. Although separated by 35 Å, coordination between the pol and exo sites is crucial to high fidelity replication. The biophysical mechanisms for this coordination are not completely understood. To understand the communication between the two active sites, we used a statistical-mechanical model of the protein ensemble to calculate the energetic landscape and local stability. We compared a series of structures of Pol γ, complexed with primer/template DNA, and either a nucleotide substrate or a series of nucleotide analogues, which are differentially incorporated and excised by pol and exo activity. Despite the nucleotide or its analogues being bound in the pol, Pol γ residue stability varied across the protein, particularly in the exo domain. This suggests that substrate presence in the pol can be "sensed" in the exo domain. Consistent with this hypothesis, in silico mutations made in one active site mutually perturbed the energetics of the other. To identify specific regions of the polymerase that contributed to this communication, we constructed an allosteric network connectivity map that further demonstrates specific pol-exo cooperativity. Thus, a cooperative network underlies energetic connectivity. We propose that Pol γ and other dual-function polymerases exploit an energetic coupling network that facilitates domain-domain communication to enhance discrimination between correct and incorrect nucleotides.

Structural snapshots of actively transcribing influenza polymerase

Influenza virus RNA-dependent RNA polymerase uses unique mechanisms to transcribe its single-stranded genomic vRNA into mRNA. The polymerase is initially bound to a promoter comprising the partially base-paired 3′ and 5′ extremities of the vRNA. A short, capped primer, ′cap-snatched′ from a nascent host polymerase II transcript, is directed towards the polymerase active site to initiate RNA synthesis. Here we present structural snapshots, determined by X-ray crystallography and cryo-electron microscopy, of actively initiating influenza polymerase as it transitions towards processive elongation. Unexpected conformational changes unblock the active site cavity to allow establishment of a nine base-pair template-product RNA duplex before the strands separate into distinct exit channels. Concomitantly, as the template translocates, the promoter base-pairs are broken and the template entry region is remodelled. These structures reveal new details of the influenza polymerase active site that will help optimize nucleoside analogs or other compounds that directly inhibit viral RNA synthesis.

Two Coselected Distal Mutations in HIV-1 Reverse Transcriptase (RT) Alter Susceptibility to Nonnucleoside RT Inhibitors and Nucleoside Analogs.

Two mutations, G112D and M230I, were selected in the reverse transcriptase (RT) of human immunodeficiency virus type 1 (HIV-1) by a novel nonnucleoside reverse transcriptase inhibitor (NNRTI). G112D is located near the HIV-1 polymerase active site; M230I is located near the hydrophobic region where NNRTIs bind. Thus, M230I could directly interfere with NNRTI binding but G112D could not. Biochemical and virological assays were performed to analyze the effects of these mutations individually and in combination. M230I alone caused a reduction in susceptibility to NNRTIs, while G112D alone did not. The G112D/M230I double mutant was less susceptible to NNRTIs than was M230I alone. In contrast, both mutations affected the ability of RT to incorporate nucleoside analogs. We suggest that the mutations interact with each other via the bound nucleic acid substrate; the nucleic acid forms part of the polymerase active site, which is near G112D. The positioning of the nucleic acid is influenced by its interactions with the "primer grip" region and could be influenced by the M230I mutation.IMPORTANCE Although antiretroviral therapy (ART) is highly successful, drug-resistant variants can arise that blunt the efficacy of ART. New inhibitors that are broadly effective against known drug-resistant variants are needed, although such compounds might select for novel resistance mutations that affect the sensitivity of the virus to other compounds. Compound 13 selects for resistance mutations that differ from traditional NNRTI resistance mutations. These mutations cause increased sensitivity to NRTIs, such as AZT.

Molecular basis for the faithful replication of 5-methylcytosine and its oxidized forms by DNA polymerase β

DNA methylation is an epigenetic mark that regulates gene expression in mammals. One method of methylation removal is through ten-eleven translocation-catalyzed oxidation and the base excision repair pathway. The iterative oxidation of 5-methylcytosine catalyzed by ten-eleven translocation enzymes produces three oxidized forms of cytosine: 5-hydroxmethylcytosine, 5-formylcytosine, and 5-carboxycytosine. The effect these modifications have on the efficiency and fidelity of the base excision repair pathway during the repair of opposing base damage, and in particular DNA polymerization, remains to be elucidated. Using kinetic assays, we show that the catalytic efficiency for the incorporation of dGTP catalyzed by human DNA polymerase β is not affected when 5-methylcytosine, 5-hydroxmethylcytosine, and 5-formylcytosine are in the DNA template. In contrast, the catalytic efficiency of dGTP insertion decreases ∼20-fold when 5-carboxycytosine is in the templating position, as compared with unmodified cytosine. However, DNA polymerase fidelity is unaltered when these modifications are in the templating position. Structural analysis reveals that the methyl, hydroxymethyl, and formyl modifications are easily accommodated within the polymerase active site. However, to accommodate the carboxyl modification, the phosphate backbone on the templating nucleotide shifts ∼2.5 Å to avoid a potential steric/repulsive clash. This altered conformation is stabilized by lysine 280, which makes a direct interaction with the carboxyl modification and the phosphate backbone of the templating strand. This work provides the molecular basis for the accommodation of epigenetic base modifications in a polymerase active site and suggests that these modifications are not mutagenically copied during base excision repair.

Insights into DNA polymerase δ's mechanism for accurate DNA replication.

Our study examines the mechanisms by which DNA polymerase (pol) δ faithfully replicates DNA. To better understand this process, we have performed all-atom molecular dynamics simulations of several DNA pol δ systems to identify conformational changes occurring prior to chemistry and investigate mechanisms by which mutations in the fingers domain (R696W and A699Q) lower fidelity. Our results indicate that, without the incoming nucleotide, a distinct open conformation occurs defined by a rotation in the fingers. The closed form, adopted when the correct nucleotide is bound, appears best organized for chemistry when three magnesium ions coordinate protein and DNA residues in the active site. Removing an unusual third metal ion from the polymerase active site causes shifting in the fingers and thumb as well as stimulating specific exonuclease β-hairpin-DNA interactions that fray the primer terminus base pair. These changes suggest that dissociation of the third divalent ion (metal ion 'C') signals a transfer of the DNA primer from the polymerase to the exonuclease active site and implies a role for the β-hairpin in DNA switching. Analysis of β-hairpin movement in several systems reveals a dependence on active-site changes and suggests how Lys444 and Tyr446 present in the β-hairpin can affect proofreading. Analysis of A699Q and R696W pol δ mutant systems reveal marked differences in the open-to-closed transition as well as β-hairpin repositioning that explain reduced nucleotide selectivity and higher error rates.

Adduct Fluorescence as a Tool to Decipher Sequence Impact on Frameshift Mutations Mediated by a C-Linked C8-Biphenyl-Guanine Lesion.

Aromatic chemicals can undergo metabolic activation to afford electrophilic species that react at the C8-site of 2'-deoxyguanosine (dG) to generate bulky C8-dG adducts as a basis of initiating carcinogenesis. These DNA lesions have served as models to understand the mechanism of frameshift mutagenesis, especially within CG-dinucleotide repeat sequences, such as NarI (5'-GGCXCC-3', where X = C8-dG adduct), however there is still limited capacity to predict the likelihood of mutation arising within particular contexts, and hence chemistry-based strategies are needed for probing relationships between nucleic acid sequence and structure with replication errors. In the NarI sequence, certain C8-dG adducts may trigger in the course of DNA synthesis the formation of a slipped mutagenic intermediate (SMI) that contains a two nucleotide (XC) bulge in the template strand that can form upstream of the polymerase active site. This distortion facilitates polymerization but affords a GC dinucleotide deletion product (-2 frameshift mutation). In the current study, incorporating the fluorescent C-linked 4-fluorobiphenyl-dG (FBP-dG) adduct into two 22-mer templates containing CG-dinucleotide repeats ( NarI: 3'-CXCGGC-5' and CG3: 3'-CXCGCG-5', X = FBP-dG) and performing primer extension reactions using DNA polymerase I, Klenow fragment exo- (Kf-) revealed a dramatic sequence-based difference in polymerase bypass efficiency. Primer extension past FBP-dG within the NarI sequence was strongly blocked, whereas Kf- extended the primer past FBP-dG within a CG3 template to afford a full-length product and the GC dinucleotide deletion. To model the nucleotide insertion steps in the fully paired (FP) versus the slipped mutagenic (SM) translesion pathways, adducted template:primer duplexes were constructed and characterized by UV thermal denaturation and fluorescence spectroscopy. The emission intensity of the FBP-dG lesion exhibits sensitivity to SMI formation (turn-on) versus a FP duplex (turn-off), permitting insight into adduct base-pairing within the template:primer duplexes. This fluorescence sensitivity provides a rationale for sequence impact on -2 frameshift mutations mediated by the C-linked FBP-dG lesion.

Tfiih Generates a Six-Base-Pair Open Complex during Eukaryotic Transcription Initiation

The initiation of messenger RNA transcription in Eukaryotes is directed by the formation of a megaDalton-sized multi-protein complex known as the pre-initiation complex (PIC). After PIC formation, double-stranded DNA is unwound to form a single-stranded DNA bubble and the template strand is loaded into the polymerase active site. Initial DNA opening is ATP-dependent and is catalyzed by Ssl2/XPB, a dsDNA translocase subunit of the basal transcription factor TFIIH. In yeast, transcription initiation proceeds through a scanning phase where downstream DNA is searched for optimal start-sites. Here, to test different models for initial DNA opening and start-site scanning, we measure the size of the DNA bubble formed by Saccharomyces cerevisiae PICs in real time using a single-molecule magnetic tweezers assay. We show that ATP hydrolysis by Ssl2 leads to the opening of a 6 base-pair (bp) DNA bubble that is expanded to 13 bp in the presence of NTPs. These observations support a two-step DNA opening model wherein ATP-dependent Ssl2 translocation leads to a 6 bp open complex which RNA polymerase II expands via NTP-dependent RNA transcription.

A guardian residue hinders insertion of a Fapy•dGTP analog by modulating the open-closed DNA polymerase transition.

4,6-Diamino-5-formamidopyrimidine (Fapy•dG) is an abundant form of oxidative DNA damage that is mutagenic and contributes to the pathogenesis of human disease. When Fapy•dG is in its nucleotide triphosphate form, Fapy•dGTP, it is inefficiently cleansed from the nucleotide pool by the responsible enzyme in Escherichia coli MutT and its mammalian homolog MTH1. Therefore, under oxidative stress conditions, Fapy•dGTP could become a pro-mutagenic substrate for insertion into the genome by DNA polymerases. Here, we evaluated insertion kinetics and high-resolution ternary complex crystal structures of a configurationally stable Fapy•dGTP analog, β-C-Fapy•dGTP, with DNA polymerase β. The crystallographic snapshots and kinetic data indicate that binding of β-C-Fapy•dGTP impedes enzyme closure, thus hindering insertion. The structures reveal that an active site residue, Asp276, positions β-C-Fapy•dGTP so that it distorts the geometry of critical catalytic atoms. Removal of this guardian side chain permits enzyme closure and increases the efficiency of β-C-Fapy•dG insertion opposite dC. These results highlight the stringent requirements necessary to achieve a closed DNA polymerase active site poised for efficient nucleotide incorporation and illustrate how DNA polymerase β has evolved to hinder Fapy•dGTP insertion.

Unbinding Dynamics of Non-Nucleoside Inhibitors from HIV-1 Reverse Transcriptase.

Non-nucleoside inhibitors of HIV-1 reverse transcriptase (NNRTIs), which bind to an allosteric site 10-15 Å from the polymerase active site, play a central role in anti-HIV chemotherapy. Though NNRTIs have been known for 30 years, the pathways by which they bind and unbind from HIV-RT have not been characterized. In crystal structures for complexes, three channels are found to extend from the NNRTI binding site to the exterior of the protein, while added mystery comes from the fact that the binding site is collapsed in the unliganded protein. To address this issue, metadynamics simulations have been performed to elucidate the unbinding of four NNRTIs from HIV-RT. A general and transferable collective variable defined by the distance between the center-of-mass (COM) of the binding pocket and COM of the ligand is used to follow the dynamics while minimizing the bias. The metadynamics also allows computation of the barriers to unbinding, which are compared with the observed potencies of the compounds in an antiviral assay.

Unnatural Cytosine Bases Recognized as Thymines by DNA Polymerases by the Formation of the Watson-Crick Geometry.

The emergence of unnatural DNA bases provides opportunities to demystify the mechanisms by which DNA polymerases faithfully decode chemical information on the template. It was previously shown that two unnatural cytosine bases (termed "M-fC" and "I-fC"), which are chemical labeling adducts of the epigenetic base 5-formylcytosine, can induce C-to-T transition during DNA amplification. However, how DNA polymerases recognize such unnatural cytosine bases remains enigmatic. Herein, crystal structures of unnatural cytosine bases pairing to dA/dG in the KlenTaq polymerase-host-guest complex system and pairing to dATP in the KlenTaq polymerase active site were determined. Both M-fC and I-fC base pair with dA/dATP, but not with dG, in a Watson-Crick geometry. This study reveals that the formation of the Watson-Crick geometry, which may be enabled by the A-rule, is important for the recognition of unnatural cytosines.

Unnatural Cytosine Bases Recognized as Thymines by DNA Polymerases by the Formation of the Watson–Crick Geometry

AbstractThe emergence of unnatural DNA bases provides opportunities to demystify the mechanisms by which DNA polymerases faithfully decode chemical information on the template. It was previously shown that two unnatural cytosine bases (termed “M‐fC” and “I‐fC”), which are chemical labeling adducts of the epigenetic base 5‐formylcytosine, can induce C‐to‐T transition during DNA amplification. However, how DNA polymerases recognize such unnatural cytosine bases remains enigmatic. Herein, crystal structures of unnatural cytosine bases pairing to dA/dG in the KlenTaq polymerase‐host–guest complex system and pairing to dATP in the KlenTaq polymerase active site were determined. Both M‐fC and I‐fC base pair with dA/dATP, but not with dG, in a Watson–Crick geometry. This study reveals that the formation of the Watson–Crick geometry, which may be enabled by the A‐rule, is important for the recognition of unnatural cytosines.

"Multi-subunit RNA Polymerases of Bacteria: An insight into their Active Sites and Catalytic Mechanism"

Objectives: To analyze the Multi-Subunit (MSU) DNA dependent RNA polymerases of eubacteria and identify conserved motifs, active site regions among them and propose a plausible mechanism of action for these enzymes, using the E. coli RNA polymerase as a model system. Methods: The advanced version of Clustal Omega was used for protein sequence analysis of the MSU DNA dependent RNA polymerases from eubacteria. Along with the conserved motifs identified by the bioinformatics analysis, the data already available from biochemical and Site-Directed Mutagenesis (SDM) experiments and X-ray crystallographic analysis on these enzymes were used to confirm the possible amino acids involved in the active sites and catalysis. Findings: Multiple Sequence Alignment (MSA) of eubacterial RNA polymerases from different bacterial sources showed only a very few highly conserved motifs among them. Possible catalytic regions in the catalytic subunits β and β‘ (in eubacteria) consist of an absolutely conserved amino acid R, in contrast to a K that is reported for DNA polymerases and single subunit (SSU)DNA dependent RNA polymerases. In addition to, the invariant ‘gatekeeper/DNA template binding’ YG pair is also found in all the MSU RNA polymerases as found in all the SSU RNA polymerases and DNA polymerases. The eubacterial βsubunits are very similar in theiractive sites, catalytic regions and distance conservations between the template binding YG pair and the catalytic R, i.e., they are placed at 7 amino acids length. An invariant R is placed here at -6th position from the catalytic R, similar to SSU RNA polymerases and DNA polymerases which is proposed to play an important role in NTP selection. In the eubacterial β’ catalytic subunits, the proposed catalytic R is placed double the distance, i.e., -16 amino acids downstream from the YG pair unlike in the SSU RNA polymerasesand DNA polymerases where the distance is only 8th amino acids downstream from the YG pair. The two Ds in the completely conserved metal binding region could act as the charge shielder and orient the α-phosphates of incoming NTPs for reaction at the 3’-OH growing end. Based on the sequence analysis, a model is proposed for the initiation and elongation steps in the transcription process and a plausible mechanism of action. Applications: A comparative analysis of the bacterial and human RNA polymerases for their transcription mechanism will pave way for design new and effective drugs for many bacterial infections, including the antibiotic resistance. Keywords: Bacterial RNA Polymerases, Clustal Omega, Conserved Motifs, Multi-Subunit RNA Polymerases, Polymerase Active Sites, Polymerization Mechanism, Proofreading

5-Formylcytosine mediated DNA–protein cross-links block DNA replication and induce mutations in human cells

5-Formylcytosine (5fC) is an epigenetic DNA modification introduced via TET protein-mediated oxidation of 5-methyl-dC. We recently reported that 5fC form reversible DNA–protein conjugates (DPCs) with histone proteins in living cells (Ji et al. (2017) Angew. Chem. Int. Ed., 56:14130–14134). We now examined the effects of 5fC mediated DPCs on DNA replication. Synthetic DNA duplexes containing site-specific DPCs between 5fC and lysine-containing proteins and peptides were subjected to primer extension experiments in the presence of human translesion synthesis DNA polymerases η and κ. We found that DPCs containing histones H2A or H4 completely inhibited DNA replication, but the replication block was removed when the proteins were subjected to proteolytic digestion. Cross-links to 11-mer or 31-mer peptides were bypassed by both polymerases in an error-prone manner, inducing targeted C→T transitions and –1 deletions. Similar types of mutations were observed when plasmids containing 5fC-peptide cross-links were replicated in human embryonic kidney (HEK) 293T cells. Molecular simulations of the 11-mer peptide-dC cross-links bound to human polymerases η and κ revealed that the peptide fits well on the DNA major groove side, and the modified dC forms a stable mismatch with incoming dATP via wobble base pairing in the polymerase active site.