Replication protein A (RPA) hampers the processive action of APOBEC3G cytosine deaminase on single-stranded DNA

BACKGROUND: Editing deaminases have a pivotal role in cellular physiology. A notable member of this superfamily, APOBEC3G (A3G), restricts retroviruses, and Activation Induced Deaminase (AID) generates antibody diversity by localized deamination of cytosines in DNA. Unconstrained deaminase activity can cause genome-wide mutagenesis and cancer. The mechanisms that protect the genomic DNA from the undesired action of deaminases are unknown. Using the in vitro deamination assays and expression of A3G in yeast, we show that replication protein A (RPA), the eukaryotic single-stranded DNA (ssDNA) binding protein, severely inhibits the deamination activity and processivity of A3G. PRINCIPAL FINDINGS/METHODOLOGY: We found that mutations induced by A3G in the yeast genomic reporter are changes of a single nucleotide. This is unexpected because of the known property of A3G to catalyze multiple deaminations upon one substrate encounter event in vitro. The addition of recombinant RPA to the oligonucleotide deamination assay severely inhibited A3G activity. Additionally, we reveal the inverse correlation between RPA concentration and the number of deaminations induced by A3G in vitro on long ssDNA regions. This resembles the "hit and run" single base substitution events observed in yeast. SIGNIFICANCE: Our data suggest that RPA is a plausible antimutator factor limiting the activity and processivity of editing deaminases in the model yeast system. Because of the similar antagonism of yeast RPA and human RPA with A3G in vitro, we propose that RPA plays a role in the protection of the human genome cell from A3G and other deaminases when they are inadvertently diverged from their natural targets. We propose a model where RPA serves as one of the guardians of the genome that protects ssDNA from the destructive processive activity of deaminases by non-specific steric hindrance.     

Sequence-dependent enhancement of hydrolytic deamination of cytosines in DNA by the restriction enzyme PspGI

Hydrolytic deamination of cytosines in DNA creates uracil and, if unrepaired, these lesions result in C to T mutations. We have suggested previously that a possible way in which cells may prevent or reduce this chemical reaction is through the binding of proteins to DNA. We use a genetic reversion assay to show that a restriction enzyme, PspGI, protects cytosines within its cognate site, 5′-CCWGG (W is A or T), against deamination under conditions where no DNA cleavage can occur. It decreases the rate of cytosine deamination to uracil by 7-fold. However, the same protein dramatically increases the rate of deaminations within the site 5′-CCSGG (S is C or G) by ~15-fold. Furthermore, a similar increase in cytosine deaminations is also seen with a catalytically inactive mutant of the enzyme showing that endonucleolytic ability of the protein is dispensable for its mutagenic action. The sequences of the mutants generated in the presence of PspGI show that only one of the cytosines in CCSGG is predominantly converted to thymine. Our results are consistent with PspGI ‘sensitizing’ the cytosine in the central base pair in CCSGG for deamination. Remarkably, PspGI sensitizes this base for damage despite its inability to form stable complexes at CCSGG sites. These results can be explained if the enzyme has a transient interaction with this sequence during which it flips the central cytosine out of the helix. This prediction was validated by modeling the structure of PspGI–DNA complex based on the structure of the related enzyme Ecl18kI which is known to cause base-flipping.     

APOBEC3G DNA deaminase acts processively 3' --> 5' on single-stranded DNA

Akin to a 'Trojan horse,' APOBEC3G DNA deaminase is encapsulated by the HIV virion. APOBEC3G facilitates restriction of HIV-1 infection in T cells by deaminating cytosines in nascent minus-strand complementary DNA. Here, we investigate the biochemical basis for C --> U targeting. We observe that APOBEC3G binds randomly to single-stranded DNA, then jumps and slides processively to deaminate target motifs. When confronting partially double-stranded DNA, to which APOBEC3G cannot bind, sliding is lost but jumping is retained. APOBEC3G shows catalytic orientational specificity such that deamination occurs predominantly 3' --> 5' without requiring hydrolysis of a nucleotide cofactor. Our data suggest that the G --> A mutational gradient generated in viral genomic DNA in vivo could result from an intrinsic processive directional attack by APOBEC3G on single-stranded cDNA.     

An oligomeric form of E. coli UvrD is required for optimal helicase activity.

Pre-steady-state chemical quenched-flow techniques were used to study DNA unwinding catalyzed by Escherichia coli UvrD helicase (helicase II), a member of the SF1 helicase superfamily. Single turnover experiments, with respect to unwinding of a DNA oligonucleotide, were used to examine the DNA substrate and UvrD concentration requirements for rapid DNA unwinding by pre-bound UvrD helicase. In excess UvrD at low DNA concentrations (1 nM), the bulk of the DNA is unwound rapidly by pre-bound UvrD complexes upon addition of ATP, but with time-courses that display a distinct lag phase for formation of fully unwound DNA, indicating that unwinding occurs in discrete steps, with a "step size" of four to five base-pairs as previously reported. Optimum unwinding by pre-bound UvrD-DNA complexes requires a 3' single-stranded (ss) DNA tail of 36-40 nt, whereas productive complexes do not form readily on DNA with 3'-tail lengths 相似文献   

Bacillus subtilis bacteriophage SPP1 G40P helicase lacking the n-terminal domain unwinds DNA bidirectionally

Bacillus subtilis bacteriophage SPP1 G40P hexameric replicative DNA helicase unidirectionally translocates with a 5'-->3' polarity while separating the DNA strands. A G40P mutant derivative lacking the N-terminal domain (containing amino acid residues 110-442 from G40P, G40PDeltaN109) was purified and characterized. G40PDeltaN109 showed an ATPase activity that was dependent on the presence of single-stranded (ss) DNA. Unlike G40P, G40PDeltaN109 was shown to bind with similar affinity both ssDNA arms of forked structures by nuclease protection assays. In a pH-dependent manner, G40PDeltaN109 unwound a branched double-arm substrate preferentially with a 3'-->5' polarity. Our results show that the linker region and the C-terminal domain of G40P are sufficient to render an enzyme capable of encircling the ssDNA tails of the forked DNA and to unwind DNA with both 5'-->3' and 3'-->5' polarity. The presence of the N-terminal domain, which does not play an essential role in helicase action, might be required indirectly for strand discrimination and polarity of translocation.     

Single-stranded DNA scanning and deamination by APOBEC3G cytidine deaminase at single molecule resolution

APOBEC3G (Apo3G) is a single-stranded (ss)DNA cytosine deaminase that eliminates HIV-1 infectivity by converting C → U in numerous small target motifs on the minus viral cDNA. Apo3G deaminates linear ssDNA in vitro with pronounced spatial asymmetry favoring the 3′ → 5′ direction. A similar polarity observed in vivo is believed responsible for initiating localized C → T mutational gradients that inactivate the virus. When compared with double-stranded (ds)DNA scanning enzymes, e.g. DNA glycosylases that excise rare aberrant bases, there is a paucity of mechanistic studies on ssDNA scanning enzymes. Here, we investigate ssDNA scanning and motif-targeting mechanisms for Apo3G using single molecule Förster resonance energy transfer. We address the specific issue of deamination asymmetry within the general context of ssDNA scanning mechanisms and show that Apo3G scanning trajectories, ssDNA contraction, and deamination efficiencies depend on motif sequence, location, and ionic strength. Notably, we observe the presence of bidirectional quasi-localized scanning of Apo3G occurring proximal to a 5′ hot motif, a motif-dependent DNA contraction greatest for 5′ hot > 3′ hot > 5′ cold motifs, and diminished mobility at low salt. We discuss the single molecule Förster resonance energy transfer data in terms of a model in which deamination polarity occurs as a consequence of Apo3G binding to ssDNA in two orientations, one that is catalytically favorable, with the other disfavorable.     

Indirect readout of DNA sequence at the primary-kink site in the CAP-DNA complex: alteration of DNA binding specificity through alteration of DNA kinking.

The catabolite activator protein (CAP) sharply bends DNA in the CAP-DNA complex, introducing a DNA kink, with a roll angle of approximately 40 degrees and a twist angle of approximately 20 degrees, between positions 6 and 7 of the DNA half-site, 5'-A(1)A(2)A(3)T(4)G(5)T(6)G(7)A(8)T(9)C(10)T(11)-3' ("primary kink"). CAP recognizes the base-pair immediately 5' to the primary-kink site, T:A(6), through an "indirect-readout" mechanism involving sequence effects on the energetics of primary-kink formation. CAP recognizes the base-pair immediately 3' to the primary-kink site, G:C(7), through a "direct-readout" mechanism involving formation of a hydrogen bond between Glu181 of CAP and G:C(7). Here, we report that substitution of the carboxylate side-chain of Glu181 of CAP by the one-methylene-group-shorter carboxylate side-chain of Asp changes DNA binding specificity at position 6 of the DNA half site, changing specificity for T:A(6) to specificity for C:G(6), and we report a crystallographic analysis defining the structural basis of the change in specificity. The Glu181-->Asp substitution eliminates the primary kink and thus eliminates indirect-readout-based specificity for T:A(6). The Glu181-->Asp substitution does not eliminate hydrogen-bond formation with G:C(7), and thus does not eliminate direct-readout-based specificity for G:C(7).     

The 3' --> 5' exonuclease of T4 DNA polymerase removes premutagenic alkyl mispairs and contributes to futile cycling at O6-methylguanine lesions

We have studied the processing of O(6)-methylguanine (m6G)-containing oligonucleotides and N-methyl-N-nitrosourea (MNU)-treated DNA templates by the 3' --> 5' exonuclease of T4 DNA polymerase. In vitro biochemical analyses demonstrate that the exonuclease can remove bases opposite a defined m6G lesion. The efficiency of excision of a terminal m6G.T was similar to that of m6G.C, and both were excised as efficiently as a G.T substrate. Partitioning assays between the polymerase and exonuclease activities, performed in the presence of dNTPs, resulted in repeated incorporation and excision events opposite the m6G lesion. This idling produces dramatically less full-length product, relative to natural substrates, indicating that the 3' --> 5' exonuclease may contribute to DNA synthesis inhibition by alkylating agents. Genetic data obtained using an in vitro herpes simplex virus-thymidine kinase assay support the inefficiency of the exonuclease as a "proofreading" activity for m6G, since virtually all mutations produced by the native enzyme using MNU-treated templates were G --> A transitions. Comparison of MNU dose-response curves for exonuclease-proficient and -deficient forms of T4 polymerase reveals that the exonuclease efficiently removes 50-86% of total premutagenic alkyl mispairs. We propose that idling of exonuclease-proficient polymerases at m6G lesions during repair DNA synthesis provides the biochemical explanation for cellular cytotoxicity of methylating agents.     

Reviving a dead enzyme: cytosine deaminations promoted by an inactive DNA methyltransferase and an S-adenosylmethionine analogue

The enzymes that transfer a methyl group to C5 of cytosine within specific sequences (C5 Mtases) deaminate the target cytosine to uracil if the methyl donor S-adenosylmethionine (SAM) is omitted from the reaction. Recently, it was shown that cytosine deamination caused by C5 Mtases M.HpaII, M.SssI and M.MspI is enhanced in the presence of several analogues of SAM, and a mechanism for this analogue-promoted deamination was proposed. According to this mechanism, the analogues protonate C5 of the target cytosine, creating a dihydrocytosine intermediate that is susceptible to deamination. We show here that one of these analogues, 5'-aminoadenosine (AA), enhances cytosine deamination by the Mtase M. EcoRII, but it does so without enhancing protonation of C5. Further, we show that uracil is an intermediate in the mutational pathway and propose an alternate mechanism for the analogue-promoted deamination. The new mechanism involves a facilitated water attack at C4 but does not require attack at C6 by the enzyme. The latter feature of the mechanism was tested by using M.EcoRII mutants defective in the nucleophilic attack at C6 in the deamination assay. We find that although these proteins are defective in methyl transfer and cytosine deamination, they cause cytosine deaminations in the presence of AA in the reaction. Our results point to a possible connection between the catalytic mechanism of C5 Mtases and of enzymes that transfer methyl groups to N(4) of cytosine. Further, they provide an unusual example where a coenzyme activates an otherwise "dead" enzyme to perform catalysis by a new reaction pathway.     

Abasic sites from cytosine as termination signals for DNA synthesis.

DNA with abasic sites has been prepared by deamination of cytosine followed by treatment of the product with uracil N-glycosylase. Termination in vitro on such templates does not occur until treatment with uracil N-glycosylase. DNA terminated one base before abasic sites created from C's has been used as a template in "second stage" reactions. With enzymes devoid or deficient in 3' greater than 5' exonuclease activity purines, particularly adenine, are preferentially added opposite the putative abasic site. 2-Aminopurine behaves more like adenine than like guanine in these experiments. Polymerase beta preferentially incorporates A opposite abasic sites produced from T, and G opposite abasic sites produced from C. We have eliminated an obvious artefact (e.g. strand switching) which might account for this observation.     

HIV-1 Viral Infectivity Factor (Vif) Alters Processive Single-stranded DNA Scanning of the Retroviral Restriction Factor APOBEC3G

APOBEC3G is a retroviral restriction factor that can inhibit the replication of human immunodeficiency virus, type 1 (HIV-1) in the absence of the viral infectivity factor (Vif) protein. Virion-encapsidated APOBEC3G can deaminate cytosine to uracil in viral (−)DNA, which leads to hypermutation and inactivation of the provirus. APOBEC3G catalyzes these deaminations processively on single-stranded DNA using sliding and jumping movements. Vif is thought to primarily overcome APOBEC3G through an interaction that mediates APOBEC3G ubiquitination and results in its proteasomal degradation. However, Vif may also inhibit APOBEC3G mRNA translation, virion encapsidation, and deamination activity. Here we investigated the molecular mechanism of Vif_IIIB- and Vif_HXB2-mediated inhibition of APOBEC3G deamination activity. Biochemical assays using a model HIV-1 replication assay and synthetic single-stranded or partially double-stranded DNA substrates demonstrated that APOBEC3G has an altered processive mechanism in the presence of Vif. Specifically, Vif_HXB2 inhibited the jumping and Vif_IIIB inhibited the sliding movements of APOBEC3G. The absence of such an effect by Vif on degradation-resistant APOBEC3G D128K indicates that a Vif-APOBEC3G interaction mediates this effect. That the partially processive APOBEC3G was less effective at inducing mutagenesis in a model HIV-1 replication assay suggests that Vif co-encapsidation with APOBEC3G can promote sublethal mutagenesis of HIV-1 proviral DNA.     

Deamination of 5-methylcytosines within cyclobutane pyrimidine dimers is an important component of UVB mutagenesis

UVB mutagenesis is characterized by an abundance of C --> T and 5-methylcytosine --> T transitions at dipyrimidine sequences. It is not known how these mutations might arise. One hypothesis is that UV-induced mutations occur only after deamination of the cytosine or 5-methylcytosine within the pyrimidine dimer. It is not clear how methylation of cytosines at the 5-position influences deamination and how this affects mutagenesis. We have now conducted experiments with a CpG-methylated supF shuttle vector that was irradiated with UVB and then incubated at 37 degrees C to allow time for deamination before passage through a human cell line to establish mutations. This led to a significantly increased frequency of CC --> TT mutations and of transition mutations at 5'-PymCG-3' sequences. A spectrum of deaminated cis-syn cyclobutane pyrimidine dimers in the supF gene was determined using the mismatch glycosylase activities of MBD4 protein in combination with ligation-mediated PCR. Methylation at the C-5 position promoted the deamination of cytosines within cis-syn cyclobutane pyrimidine dimers, and these two events combined led to a significantly increased frequency of UVB-induced transition mutations at 5'-PymCG-3' sequences. Under these conditions, the majority of all supF mutations were transition mutations at 5'-PymCG-3', and they clustered at several mutational hot spots. Exactly these types of mutations are frequently observed in the p53 gene of nonmelanoma skin tumors. This particular mutagenic pathway may become prevalent under conditions of inefficient DNA repair and slow proliferation of cells in the human epidermis.