AID-initiated purposeful mutations in immunoglobulin genes

Exposure brings risk to all living organisms. Using a remarkably effective strategy, higher vertebrates mitigate risk by mounting a complex and sophisticated immune response to counter the potentially toxic invasion by a virtually limitless army of chemical and biological antagonists. Mutations are almost always deleterious, but in the case of antibody diversification there are mutations occurring at hugely elevated rates within the variable (V) and switch regions (SR) of the immunoglobulin (Ig) genes that are responsible for binding to and neutralizing foreign antigens throughout the body. These mutations are truly purposeful. This chapter is centered on activation-induced cytidine deaminase (AID). AID is required for initiating somatic hypermutation (SHM) in the V regions and class switch recombination (CSR) in the SR portions of Ig genes. By converting C --> U, while transcription takes place, AID instigates a cascade of mutational events involving error-prone DNA polymerases, base excision and mismatch repair enzymes, and recombination pathways. Together, these processes culminate in highly mutated antibody genes and the B cells expressing antibodies that have achieved optimal antigenic binding undergo positive selection in germinal centers. We will discuss the biological role of AID in this complex process, primarily in terms of its biochemical properties in relation to SHM in vivo. The chapter also discusses recent advances in experimental methods to characterize antibody dynamics as a function of SHM to help elucidate the role that the AID-induced mutations play in tailoring molecular recognition. The emerging experimental techniques help to address long-standing conundrums concerning evolution-imposed constraints on antibody structure and function.

The APOBEC-2 crystal structure and functional implications for the deaminase AID

APOBEC-2 (APO2) belongs to the family of apolipoprotein B messenger RNA-editing enzyme catalytic (APOBEC) polypeptides, which deaminates mRNA and single-stranded DNA. Different APOBEC members use the same deamination activity to achieve diverse human biological functions. Deamination by an APOBEC protein called activation-induced cytidine deaminase (AID) is critical for generating high-affinity antibodies, and deamination by APOBEC-3 proteins can inhibit retrotransposons and the replication of retroviruses such as human immunodeficiency virus and hepatitis B virus. Here we report the crystal structure of APO2. APO2 forms a rod-shaped tetramer that differs markedly from the square-shaped tetramer of the free nucleotide cytidine deaminase, with which APOBEC proteins share considerable sequence homology. In APO2, two long alpha-helices of a monomer structure prevent the formation of a square-shaped tetramer and facilitate formation of the rod-shaped tetramer via head-to-head interactions of two APO2 dimers. Extensive sequence homology among APOBEC family members allows us to test APO2 structure-based predictions using AID. We show that AID deamination activity is impaired by mutations predicted to interfere with oligomerization and substrate access. The structure suggests how mutations in patients with hyper-IgM-2 syndrome inactivate AID, resulting in defective antibody maturation.

RecA acts in trans to allow replication of damaged DNA by DNA polymerase V

The DNA polymerase V (pol V) and RecA proteins are essential components of a mutagenic translesion synthesis pathway in Escherichia coli designed to cope with DNA damage. Previously, it has been assumed that RecA binds to the DNA template strand being copied. Here we show, however, that pol-V-catalysed translesion synthesis, in the presence or absence of the beta-processivity-clamp, occurs only when RecA nucleoprotein filaments assemble or RecA protomers bind on separate single-stranded (ss)DNA molecules in trans. A 3'-proximal RecA filament end on trans DNA is essential for stimulation; however, synthesis is strengthened by further pol V-RecA interactions occurring elsewhere along a trans nucleoprotein filament. We suggest that trans-stimulation of pol V by RecA bound to ssDNA reflects a distinctive regulatory mechanism of mutation that resolves the paradox of RecA filaments assembled in cis on a damaged template strand obstructing translesion DNA synthesis despite the absolute requirement of RecA for SOS mutagenesis.

Simulating the effect of DNA polymerase mutations on transition-state energetics and fidelity: evaluating amino acid group contribution and allosteric coupling for ionized residues in human pol beta

The control of the catalytic power and fidelity of DNA polymerases involves the complex combined effect of the protein residues, the Mg2+ ions, and the interaction between the DNA bases. In an attempt to advance the understanding of catalytic control, we analyze the effect of the protein residues, taking human DNA polymerase beta as a model system. Specifically, we examine the ability of different theoretical models to reproduce the effect of ionized residues on the transition state (TS) binding energy and the corresponding k(pol)/KD. We also explore the role of the Mg2+ ions in the binding and catalysis processes. The application of the microscopic linear response approximation (LRA) and the semimacroscopic PDLD/S-LRA methods to a benchmark of mutational studies produces a semiquantitative correlation and indicates that these methods can provide predictive power. However, pre-steady-state and steady-state kinetic studies currently available do not give a unique benchmark, owing principally to widely varying experimental conditions. We believe that a more uniform experimental benchmark is needed for further refinement of the theoretical models. The analysis of the correlation between the results obtained by a rigorous thermodynamic cycle and by simpler approximations indicates that the protein reorganization between the open, i.e., unbound, form and the closed form does not change the magnitude of the calculated mutational effects in a major way for the experimental data used in this study. The use of the PDLD/S-LRA group contributions allows us to construct energy-based correlation diagrams that can help toward understanding the coupling, i.e., transfer of information, between the base-binding and catalytic sites and to gain a deeper insight into the molecular basis of DNA replication fidelity. Our analysis suggests that the allosteric matrix obtained by subtracting the correlation matrix of the correct and incorrect base pairs should prove useful in exploring the information transfer occurring between the base-binding and catalytic sites. This type of treatment should be especially effective when coupled with structural studies of polymerase-DNA-base mispair ternary complexes and studies using polymerase double mutants. We discuss the potential of direct calculations of binding energy of the TS in a rational design of TS analogues and in drug design.

Replication of an oxidized abasic site in Escherichia coli by a dNTP-stabilized misalignment mechanism that reads upstream and downstream nucleotides

Abasic sites (AP) and oxidized abasic lesions are often referred to as noninstructive lesions because they cannot participate in Watson-Crick base pairing. The aptness of the term noninstructive for describing AP site replication has been called into question by recent investigations in E. coli using single-stranded shuttle vectors. These studies revealed that the replication of templates containing AP sites or the oxidized abasic lesions resulting from C1'- (L) and C4'-oxidation (C4-AP) are distinct from one another, suggesting that structural features other than Watson-Crick hydrogen bonds contribute to controlling replication. The first description of the replication of the abasic site resulting from formal C2'-oxidation (C2-AP) is presented here. Full-length and single-nucleotide deletion products are observed when templates containing C2-AP are replicated in E. coli. Single nucleotide deletion formation is largely dependent upon the concerted effort of pol II and pol IV, whereas pol V suppresses frameshift product formation. Pol V utilizes the A-rule when bypassing C2-AP. In contrast, pol II and pol IV utilize a dNTP-stabilized misalignment mechanism to read the upstream and downstream nucleotides when bypassing C2-AP. This is the first example in which the identity of the 3'-adjacent nucleotide is read during the replication of a DNA lesion. The results raise further questions as to whether abasic lesions are noninstructive lesions. We suggest that abasic site bypass is affected by the local biopolymer structure in addition to the structure of the lesion.

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.

Lyase activities intrinsic to Escherichia coli polymerases IV and V

Escherichia coli DNA polymerase IV and V (pol IV and pol V) are error-prone DNA polymerases that are induced as part of the SOS regulon in response to DNA damage. Both are members of the Y-family of DNA polymerases. Their principal biological roles appear to involve translesion synthesis (TLS) and the generation of mutational diversity to cope with stress. Although neither enzyme is known to be involved in base excision repair (BER), we have nevertheless observed apurinic/apyrimidinic 5'-deoxyribose phosphate (AP/5'-dRP) lyase activities intrinsic to each polymerase. Pols IV and V catalyze cleavage of the phosphodiester backbone at the 3'-side of an apurinic/apyrimidinic (AP) site as well as the removal of a 5'-deoxyribose phosphate (dRP) at a preincised AP site. The specific activities of the two error-prone polymerase-associated lyases are approximately 80-fold less than the associated lyase activity of human DNA polymerase beta, which is a key enzyme used in short patch BER. Pol IV forms a covalent Schiff's base intermediate with substrate DNA that is trapped by sodium borohydride, as proscribed by a beta-elimination mechanism. In contrast, a NaBH(4) trapped intermediate is not observed for pol V, even though the lyase specific activity of pol V is slightly higher than that of pol IV. Incubation of pol V (UmuD'(2)C) with a molar excess of UmuD drives an exchange of subunits to form UmuD'D+insoluble UmuC causing inactivation of polymerase and lyase activities. The concomitant loss of both activities is strong evidence that pol V contains a bona fide lyase activity.

A Sliding-Clamp Toolbelt Binds High- and Low-Fidelity DNA Polymerases Simultaneously

This report demonstrates that the beta sliding clamp of E. coli binds two different DNA polymerases at the same time. One is the high-fidelity Pol III chromosomal replicase and the other is Pol IV, a low-fidelity lesion bypass Y family polymerase. Further, polymerase switching on the primed template junction is regulated in a fashion that limits the action of the low-fidelity Pol IV. Under conditions that cause Pol III to stall on DNA, Pol IV takes control of the primed template. After the stall is relieved, Pol III rapidly regains control of the primed template junction from Pol IV and retains it while it is moving, becoming resistant to further Pol IV takeover events. These polymerase dynamics within the beta toolbelt complex restrict the action of the error-prone Pol IV to only the area on DNA where it is required.

AID binds to transcription-induced structures in c-MYC that map to regions associated with translocation and hypermutation

Translocation and aberrant hypermutation of c-MYC are common in B-cell lymphomas. Activation-induced Cytidine Deaminase (AID) initiates switch recombination and somatic hypermutation in B cells by targeted deamination of transcribed genes. We show that transcription of the immunoglobulin S regions and c-MYC results in formation of similar DNA structures, 'G-loops', which contain a cotranscriptional RNA: DNA hybrid on the C-rich strand and single-stranded regions and G4 DNA on the G-rich strand. AID binds specifically to G-loops within transcribed S regions and c-MYC, and G-loops in c-MYC map to the regions associated with translocation breakpoints and aberrant hypermutation in B-cell lymphomas. Aberrant targeting of AID to DNA structures formed upon c-MYC transcription may therefore contribute to the genetic instability of c-MYC in B-cell malignancies.

Computer simulations of protein functions: searching for the molecular origin of the replication fidelity of DNA polymerases

The use of computers to simulate the functions of complex biological macromolecules is essential to achieve a microscopic description of biological processes and to model and interpret experimental data. Here we apply theoretical computational approaches to investigate the fidelity of T7 DNA polymerase, divided into discrete steps that include contributions from substrate binding, pK(a) shifts, and rate constants for the PO bond-breaking and bond-making processes. We begin by defining the discrimination between right and wrong nucleotides in terms of the free energy landscape for the dNMP incorporation reaction. We then use the linear response approximation and the empirical valence bond methods to obtain converging results for the contribution of the binding and chemical steps to the overall fidelity. These approaches are successful in reproducing general trends in the observed polymerase incorporation fidelity. The calculations demonstrate the potential for further integration of theoretical and experimental studies to analyze high- and low-fidelity DNA polymerases.

Methylation protects cytidines from AID-mediated deamination

Somatic hypermutation (SHM), class switch recombination (CSR), and gene conversion of immunoglobulin genes require activation-induced cytidine deaminase (AID). AID initiates these events by deaminating cytidines within antibody variable and switch regions. The mechanism that restricts mutation to antibody genes is not known. Although genes other than antibody genes have been found to mutate, not all highly transcribed genes mutate. Thus, somatic hypermutation does not target all genes and suggests a mechanism that either recruits AID to genes for mutation, and/or one that protects genes from promiscuous AID activity. Recent evidence suggests that AID deaminates methyl cytidines inefficiently. Methylation of cytidines could thus represent a means to protect the genome from potentially harmful AID activity that occurs outside of the immunoglobulin loci. To test this premise, we examined whether AID could deaminate methylated-CpG motifs in different sequence contexts. In agreement with a report that suggests that AID has processive-like properties in vitro, we found that AID could completely deaminate single-stranded DNA tracks in plasmid substrates that were greater than 300 nucleotides in length. In addition, methylated-CpG motifs, but not their unmethylated counterparts, were protected from AID-mediated deamination. However, methylation did not protect cytidines that neighbored CpG motifs indicating that methylation per se does not provide a more global safeguard against AID-mediated activity. These data also suggest that AID, and possibly other related cytidine deaminases, might represent a more rapid alternative to bisulfite sequencing for identifying methylated-CpG motifs.

Reward versus risk: DNA cytidine deaminases triggering immunity and disease

The enzymatic deamination of cytosine to uracil, using the free base C, its nucleosides, and nucleotides as substrates, is an essential feature of nucleotide metabolism. However, the deamination of C and, especially, 5 methyl C on DNA is typically detrimental, causing mutations leading to serious human disease. Recently, a family of enzymes has been discovered that catalyzes the conversion of C to U on DNA and RNA, generating favorable mutations that are essential for human survival. Members of the Apobec family of nucleic acid-dependent cytidine deaminases include activation-induced cytidine deaminase (AID) and Apobec3G. AID is required for B cells to undergo somatic hypermutation (SHM) and class switch recombination (CSR), two processes that are needed to produce high-affinity antibodies of all isotypes. Apobec3G is responsible for protection against HIV infection. Recent advances in the biochemical and structural analyses of nucleic acid cytidine deaminases will be discussed in relation to their programmed roles in ensuring antibody diversification and in imposing innate resistance against retroviral infection. The serious negative consequences of expressing Apobec deaminases in the wrong place at the wrong time to catalyze aberrant deamination in "at risk" sequences will be discussed in terms of causing genomic instability and disease.

DNA polymerase V and RecA protein, a minimal mutasome

A hallmark of the Escherichia coli SOS response is the large increase in mutations caused by translesion synthesis (TLS). TLS requires DNA polymerase V (UmuD'2C) and RecA. Here, we show that pol V and RecA interact by two distinct mechanisms. First, pol V binds to RecA in the absence of DNA and ATP and second, through its UmuD' subunit, requiring DNA and ATP without ATP hydrolysis. TLS occurs in the absence of a RecA nucleoprotein filament but is inhibited in its presence. Therefore, a RecA nucleoprotein filament is unlikely to be required for SOS mutagenesis. Pol V activity is severely diminished in the absence of RecA or in the presence of RecA1730, a mutant defective for pol V mutagenesis in vivo. Pol V activity is strongly enhanced with RecA mutants constitutive for mutagenesis in vivo, suggesting that RecA is an obligate accessory factor that activates pol V for SOS mutagenesis.

Identifying protein-protein interactions in somatic hypermutation

Somatic hypermutation (SHM) in immunoglobulin genes is required for high affinity antibody–antigen binding. Cultured cell systems, mouse model systems, and human genetic deficiencies have been the key players in identifying likely SHM pathways, whereas “pure” biochemical approaches have been far less prominent, but change appears imminent. Here we comment on how, when, and why biochemistry is likely to emerge from the shadows and into the spotlight to elucidate how the somatic mutation of antibody variable (V) regions is generated.

A biochemically defined system for mammalian nonhomologous DNA end joining

Nonhomologous end joining (NHEJ) is a major pathway in multicellular eukaryotes for repairing double-strand DNA breaks (DSBs). Here, the NHEJ reactions have been reconstituted in vitro by using purified Ku, DNA-PK(cs), Artemis, and XRCC4:DNA ligase IV proteins to join incompatible ends to yield diverse junctions. Purified DNA polymerase (pol) X family members (pol mu, pol lambda, and TdT, but not pol beta) contribute to junctional additions in ways that are consistent with corresponding data from genetic knockout mice. The pol lambda and pol mu contributions require their BRCT domains and are both physically and functionally dependent on Ku. This indicates a specific biochemical function for Ku in NHEJ at incompatible DNA ends. The XRCC4:DNA ligase IV complex is able to ligate one strand that has only minimal base pairing with the antiparallel strand. This important aspect of the ligation leads to an iterative strand-processing model for the steps of NHEJ.

Biochemical Analysis of Hypermutational Targeting by Wild Type and Mutant Activation-induced Cytidine Deaminase

The synthesis of high affinity antibodies requires activation-induced cytidine deaminase (AID) to initiate somatic hypermutation and class-switch recombination. Here we investigate AID-catalyzed deamination of C --> U on single-stranded DNA and on actively transcribed closed circular double-stranded DNA. Mutations are initially favored at canonical WRC (W = A or T, R = A or G) somatic hypermutation hot spot motifs, but over time mutations at neighboring non-hot spot sites increase creating random clusters of mutated regions in a seemingly processive manner. N-terminal AID mutants R35E and R35E/R36D appear less processive and have altered mutational specificity compared with wild type AID. In contrast, a C-terminal deletion mutant defective in CSR in vivo closely resembles wild type AID. A mutational spectrum generated during transcription of closed circular double-stranded DNA indicates that wild type AID retains its specificity for WRC hot spot motifs within the confines of a moving transcription bubble while introducing clusters of multiple deaminations predominantly on the nontranscribed strand.

Effects of the C4'-oxidized abasic site on replication in Escherichia coli. An unusually large deletion is induced by a small lesion

The C4'-oxidized abasic site (C4-AP) is produced in DNA as a result of oxidative stress by a variety of agents. For instance, the lesion accounts for approximately 40% of the DNA damage produced by the antitumor antibiotic bleomycin. The effect of C4-AP on DNA replication in Escherichia coli was determined using the restriction endonuclease and postlabeling (REAP) method. Three-nucleotide deletion products are the sole products observed following replication of plasmids containing C4-AP under SOS conditions in wild-type cells. Full-length products are formed in varying amounts depending upon the local sequence in wild-type cells under non-SOS-induced conditions. The "A-rule" is followed for the formation of substitution products. C4-AP is the first example of a DNA lesion that produces significant levels of three-nucleotide deletions in a variety of sequence contexts. Experiments carried out in cells lacking specific polymerases reveal that formation of three-nucleotide deletion products results from a coordinated effort involving pol II and pol IV. This is the first example in which these SOS inducible polymerases are shown to work in concert during lesion bypass. Three-nucleotide deletions are not observed during the replication of other abasic lesions, and are rarely produced by bulky adducts. The effect of C4-AP on DNA replication suggests a significant role for this lesion in the cytotoxicity of bleomycin. Formation of the C4-AP lesion may also be responsible for the formation of mutant proteins containing single-amino acid deletions that exhibit altered phenotypes.

A comprehensive comparison of DNA replication past 2-deoxyribose and its tetrahydrofuran analog in Escherichia coli

Apurinic/apyrimidinic (AP) sites are alkali labile lesions that, when encountered during DNA replication, can block polymerases or potentially result in mutagenic events. Owing to the instability of 2-deoxyribose lesions (AP), a chemically stable tetrahydrofuran analog (F) is often used as a model of abasic sites. A comparison of the two lesions in Saccharomyces cerevisiae revealed that the model lesion and 2-deoxyribose have distinct in vivo effects. Comprehensive comparative analyses of F and AP have not been carried out in Escherichia coli. We conducted a side-by-side investigation of F and AP in E.coli to compare their biological effects and interactions with SOS polymerases. Both lesions were examined in SOS-induced and uninduced cells. Our studies reveal that in uninduced E.coli the effects of individual polymerases in the replication of plasmids containing F or AP are distinct. However, when cells are SOS-induced, the biological effects of F and AP are similar.

To slip or skip, visualizing frameshift mutation dynamics for error-prone DNA polymerases

Three models describing frameshift mutations are "classical" Streisinger slippage, proposed for repetitive DNA, and "misincorporatation misalignment" and "dNTP-stabilized misalignment," proposed for non-repetitive DNA. We distinguish between models using pre-steady state fluorescence kinetics to visualize transiently misaligned DNA intermediates and nucleotide incorporation products formed by DNA polymerases adept at making small frameshift mutations in vivo. Human polymerase (pol) mu catalyzes Streisinger slippage exclusively in repetitive DNA, requiring as little as a dinucleotide repeat. Escherichia coli pol IV uses dNTP-stabilized misalignment in identical repetitive DNA sequences, revealing that pol mu and pol IV use different mechanisms in repetitive DNA to achieve the same mutational end point. In non-repeat sequences, pol mu switches to dNTP-stabilized misalignment. pol beta generates -1 frameshifts in "long" repeats and base substitutions in "short" repeats. Thus, two polymerases can use two different frameshift mechanisms on identical sequences, whereas one polymerase can alternate between frameshift mechanisms to process different sequences.

Mutagenic effects of 2-deoxyribonolactone in Escherichia coli. An abasic lesion that disobeys the A-rule

Abasic sites are often referred to as noninstructive lesions. The C1'-oxidized abasic site (2-deoxyribonolactone, L) is produced by several DNA damaging agents, including gamma-radiolysis and the neocarzinostatin chromophore (NCS). The effects of a C1'-oxidized abasic site incorporated at a defined site in single-stranded plasmid were examined in SOS polymerase-proficient and -deficient Escherichia coli. For comparison, experiments utilizing plasmids containing an abasic site (AP) were carried out side by side. In contrast to plasmid containing AP, dA and dG were incorporated most often when plasmid containing L was replicated. The ratio of dG:dA incorporation depended upon local sequence and varied from 0.9 to 2.2. High levels of translesion incorporation of dA are consistent with previous observations that treatment of DNA with the neocarzinostatin chromophore resulted in large amounts of G.C --> A.T transitions [Povirk and Goldberg (1986) Nucleic Acids Res. 14, 1417] and support the proposal that L is the source of these mutations. Both abasic lesions were 100% lethal in triple knockout cells lacking pol II, pol IV, and pol V. Analysis of translesion synthesis in repair-deficient cells revealed that pol V played a significant role in replication of L and AP. Significant levels of -1 frameshifts were formed in 5'-d(CL) sequences in the presence of pol V and were the exclusive product in pol V-deficient cells. Frameshift products were not formed when the nucleotide on the 5'-side of L was either dT or dG. Deleting pol II or pol IV had only modest effects on replication of L-containing plasmid but significantly decreased the amount of -1 frameshift product formed from an AP lesion. Experiments carried out side by side using otherwise identical plasmids containing an AP site illustrate the distinct properties of these two abasic lesions and that neither should be thought of as noninstructive.

In vitro effects of a C4'-oxidized abasic site on DNA polymerases

Oxidative damage to DNA produces abasic sites resulting from the formal hydrolysis of the nucleotides' glycosidic bonds, along with a variety of oxidized abasic sites. The C4'-oxidized abasic site (C4-AP) is produced by several DNA-damaging agents. This lesion accounts for approximately 40% of the DNA damage produced by bleomycin. The effect of a C4'-oxidized abasic site incorporated at a defined site in a template was examined on Klenow fragments with and without 3' --> 5' exonuclease activity. Both enzymes preferentially incorporated dA > dG >> dC, T opposite C4-AP. Neither enzyme is able to extend the primer past the lesion. Experiments with regular AP sites in an otherwise identical template indicate that Klenow does not differentiate between these two disparate abasic sites. Extension of the primer by alternative polymerases pol II, pol II exo(-), pol IV, and pol V was examined. Pol II exo(-) was most efficient. Qualitative translesion synthesis experiments showed that pol II exo(-) preferentially incorporates T opposite C4-AP, followed in order by dG, dA, and dC. Thymidine incorporation opposite C4'-AP is distinct from the pol II exonuclease interaction with a regular AP site in an otherwise identical template. These in vitro experiments suggest that bypass polymerases may play a crucial role in survival of cells in which C4-AP is produced, and unlike a typical AP site, the C4-AP lesion may not follow the "A-rule". The interaction between bypass polymerases and a C4-AP lesion could explain the high levels of G:C --> T:A transversions in cells treated with bleomycin.

Increased dNTP binding affinity reveals a nonprocessive role for Escherichia coli beta clamp with DNA polymerase IV

Replication forks often stall at undamaged or damaged template sites in Escherichia coli. Subsequent resumption of DNA synthesis occurs by replacing DNA polymerase III, which is bound to DNA by the beta-sliding clamp, with one of three damage-induced DNA polymerases II, IV, or V. The principal role of the beta clamp is to tether the normally weakly bound polmerases to DNA thereby increasing their processivities. DNA polymerase IV binds dNTP substrates with about 10-fold lower affinity compared with the other E. coli polymerases, which if left unchecked could hinder its ability to synthesize DNA in vivo. Here we report a new property for the beta clamp, which when bound to DNA polymerase IV results in a large increase in dNTP binding affinity that concomitantly increases the efficiency of nucleotide incorporation at normal and transiently slipped mispaired primer/template ends. Primer-template DNA slippage resulting in single nucleotide deletions is a biological hallmark of DNA polymerase IV infidelity responsible for enhancing cell fitness in response to stress. We show that the increased DNA polymerase IV-dNTP binding affinity is an intrinsic property of the DNA polymerase IV-beta clamp interaction and not an indirect consequence of an increased binding of DNA polymerase IV to DNA.