Two novel human and mouse DNA polymerases of the polX family

Immunoglobulin kappa light chain gene rearrangement is impaired in mice deficient for DNA polymerase mu

DNA polymerase mu (pol mu) is a template-dependent polymerase closely related to the lymphoid-specific enzyme terminal deoxynucleotidyl transferase (TdT). We report here the phenotype of pol mu-deficient mice. Such animals display an abnormal B cell differentiation, with a specific alteration in the IgM- to IgM+ transition in bone marrow. In all mice, Ig light chain gene rearrangement is impaired at the level of the Vkappa-Jkappa and Vlambda-Jlambda junctions, which show extensive nibbling of both coding extremities. These alterations lead to a profound defect in the peripheral B cell compartment which, although variable between animals, results in an average 40% reduction in the splenic B cell fraction. Pol mu appears, therefore, as a key element contributing to the relative homogeneity in size of light chain CDR3 and taking part in Ig gene rearrangement at a stage where TdT is no longer expressed.

The absence of DNA polymerase kappa does not affect somatic hypermutation of the mouse immunoglobulin heavy chain gene

During the immune response to T cell-dependent antigen, somatic hypermutation (SHM) is introduced into immunoglobulin (Ig) genes. The variable region is the target for SHM and it is here that DNA lesions are introduced and mutations are generated. It has been suggested that error-prone DNA polymerase(s) may play an important role in this mutagenesis phase. Recently, DNA polymerase kappa (Polkappa), which belongs to the Y-family of DNA polymerases, was identified. Since a hot spot of SHMs (RGYW motif) is also a hot spot of mutations by human Polkappa, this enzyme was suggested to be an SHM instigator. In order to address the question whether Polkappa is involved in SHM, we immunized Polkappa-deficient mice and analyzed the SHM of the Ig heavy chain gene. We found that the SHM frequency and spectrum were indistinguishable between the Polkappa knockout mice and control mice. These results suggested that Polkappa is not essential for this process.

Human DNA polymerase lambda possesses terminal deoxyribonucleotidyl transferase activity and can elongate RNA primers: implications for novel functions

DNA polymerase lambda is a novel enzyme of the family X of DNA polymerases. The recent demonstration of an intrinsic 5'-deoxyribose-5'-phosphate lyase activity, a template/primer dependent polymerase activity, a distributive manner of DNA synthesis and sequence similarity to DNA polymerase beta suggested a novel beta-like enzyme. All these properties support a role of DNA polymerase lambda in base excision repair. On the other hand, the biochemical properties of the polymerisation activity of DNA polymerase lambda are still largely unknown. Here we give evidence that human DNA polymerase lambda has an intrinsic terminal deoxyribonucleotidyl transferase activity that preferentially adds pyrimidines onto 3'OH ends of DNA oligonucleotides. Furthermore, human DNA polymerase lambda efficiently elongates an RNA primer hybridized to a DNA template. These two novel properties of human DNA polymerase lambda might suggest additional roles for this enzyme in DNA replication and repair processes.

Polymerase mu is a DNA-directed DNA/RNA polymerase

DNA polymerases are defined as such because they use deoxynucleotides instead of ribonucleotides with high specificity. We show here that polymerase mu (pol mu), implicated in the nonhomologous end-joining pathway for repair of DNA double-strand breaks, incorporates both ribonucleotides and deoxynucleotides in a template-directed manner. pol mu has an approximately 1,000-fold-reduced ability to discriminate against ribonucleotides compared to that of the related pol beta, although pol mu's substrate specificity is similar to that of pol beta in most other respects. Moreover, pol mu more frequently incorporates ribonucleotides when presented with nucleotide concentrations that approximate cellular pools. We therefore addressed the impact of ribonucleotide incorporation on the activities of factors required for double-strand break repair by nonhomologous end joining. We determined that the ligase required for this pathway readily joined strand breaks with terminal ribonucleotides. Most significantly, pol mu frequently introduced ribonucleotides into the repair junctions of an in vitro nonhomologous end-joining reaction, an activity that would be expected to have important consequences in the context of cellular double-strand break repair.

Functions of eukaryotic DNA polymerases

A major function of DNA polymerases is to accurately replicate the six billion nucleotides that constitute the human genome. This task is complicated by the fact that the genome is constantly challenged by a variety of endogenous and exogenous DNA-damaging agents. DNA damage can block DNA replication or alter base coding potential, resulting in mutations. In addition, the accumulation of damage in nonreplicating DNA can affect gene expression, which leads to the malfunction of many cellular processes. A number of DNA repair systems operate in cells to remove DNA lesions, and several DNA polymerases are known to be the key components of these repair systems. In the past few years, a number of novel DNA polymerases have been discovered that likely function in replicative bypass of DNA damage missed by DNA repair enzymes or in specialized forms of repair. Furthermore, DNA polymerases can act as sensors in cell cycle checkpoint pathways that prevent entry into mitosis until damaged DNA is repaired and replication is completed. The list of DNA template-dependent eukaryotic DNA polymerases now consists of 14 enzymes with amazingly different properties. In this review, we discuss the possible functions of these polymerases in DNA damage repair, the replication of intact and damaged chromosomes, and cell cycle checkpoints.

Damage repair DNA polymerases Y

The newly found Y-family DNA polymerases are characterized by low fidelity replication using an undamaged template and the ability to carry out translesion DNA synthesis. The crystal structures of three Y-family polymerases, alone or complexed with DNA and nucleotide substrate, reveal a conventional right-hand-like catalytic core consisting of finger, thumb and palm domains. The finger and thumb domains are unusually small resulting in an open and spacious active site, which can accommodate mismatched base pairs as well as various DNA lesions. Although devoid of a 3'-->5' exonuclease activity, the Y-family polymerases possess a unique "little finger" domain that facilitates DNA association, catalytic efficiency and interactions with auxiliary factors. Expression of Y-family polymerases is often induced by DNA damage, and their recruitment to the replication fork is mediated by beta-clamp, clamp loader, single-strand-DNA-binding protein and RecA in Escherichia coli, and by ubiquitin-modified proliferating cell nuclear antigen in yeast.

Constitutive and regulated expression of the mouse Dinb (Polkappa) gene encoding DNA polymerase kappa

A recently discovered group of novel polymerases are characterized by significantly reduced fidelity of DNA synthesis in vitro. This feature is consistent with the relaxed fidelity required for the replicative bypass of various types of base damage that frequently block high fidelity replicative polymerases. The present studies demonstrate that the specialized DNA polymerase kappa (polkappa) is uniquely and preferentially expressed in the adrenal cortex and testis of the mouse, as well as in a variety of other tissues. The adrenal cortex is the sole site of detectable expression of the Polkappa gene in mouse embryos. This adrenal expression pattern is consistent with a requirement for polkappa for the replicative bypass of DNA base damage generated during steroid biosynthesis. The expression pattern of polkappa in the testis is specific for particular stages of spermatogenesis and is distinct from the expression pattern of several other low fidelity DNA polymerases that are also expressed during spermatogenesis. The mouse (but not the human) Polkappa gene is primarily regulated by the p53 gene and is upregulated in response to exposure to various DNA-damaging agents in a p53-dependent manner.

Human DNA polymerase lambda functionally and physically interacts with proliferating cell nuclear antigen in normal and translesion DNA synthesis

Proliferating cell nuclear antigen (PCNA) has been shown to interact with a variety of DNA polymerases (pol) such as pol delta, pol epsilon, pol iota, pol kappa, pol eta, and pol beta. Here we show that PCNA directly interacts with the newly discovered pol lambda cloned from human cells. This interaction stabilizes the binding of pol lambda to the primer template, thus increasing its affinity for the hydroxyl primer and its processivity in DNA synthesis. However, no effect of PCNA was detected on the rate of nucleotide incorporation or discrimination efficiency by pol lambda. PCNA was found to stimulate efficient synthesis by pol lambda across an abasic (AP) site. When compared with pol delta, human pol lambda showed the ability to incorporate a nucleotide in front of the lesion. Addition of PCNA led to efficient elongation past the AP site by pol lambda but not by pol delta. However, when tested on a template containing a bulky DNA lesion, such as the major cisplatin Pt-d(GpG) adduct, PCNA could not allow translesion synthesis by pol lambda. Our results suggest that the complex between PCNA and pol lambda may play an important role in the bypass of abasic sites in human cells.

Error-prone repair DNA polymerases in prokaryotes and eukaryotes

DNA repair is crucial to the well-being of all organisms from unicellular life forms to humans. A rich tapestry of mechanistic studies on DNA repair has emerged thanks to the recent discovery of Y-family DNA polymerases. Many Y-family members carry out aberrant DNA synthesis-poor replication accuracy, the favored formation of non-Watson-Crick base pairs, efficient mismatch extension, and most importantly, an ability to replicate through DNA damage. This review is devoted primarily to a discussion of Y-family polymerase members that exhibit error-prone behavior. Roles for these remarkable enzymes occur in widely disparate DNA repair pathways, such as UV-induced mutagenesis, adaptive mutation, avoidance of skin cancer, and induction of somatic cell hypermutation of immunoglobulin genes. Individual polymerases engaged in multiple repair pathways pose challenging questions about their roles in targeting and trafficking. Macromolecular assemblies of replication-repair "factories" could enable a cell to handle the complex logistics governing the rapid migration and exchange of polymerases.

Eukaryotic DNA polymerases

Any living cell is faced with the fundamental task of keeping the genome intact in order to develop in an organized manner, to function in a complex environment, to divide at the right time, and to die when it is appropriate. To achieve this goal, an efficient machinery is required to maintain the genetic information encoded in DNA during cell division, DNA repair, DNA recombination, and the bypassing of damage in DNA. DNA polymerases (pols) alpha, beta, gamma, delta, and epsilon are the key enzymes required to maintain the integrity of the genome under all these circumstances. In the last few years the number of known pols, including terminal transferase and telomerase, has increased to at least 19. A particular pol might have more than one functional task in a cell and a particular DNA synthetic event may require more than one pol, which suggests that nature has provided various safety mechanisms. This multi-functional feature is especially valid for the variety of novel pols identified in the last three years. These are the lesion-replicating enzymes pol zeta, pol eta, pol iota, pol kappa, and Rev1, and a group of pols called pol theta;, pol lambda, pol micro, pol sigma, and pol phi that fulfill a variety of other tasks.

A physical and functional interaction between yeast Pol4 and Dnl4-Lif1 links DNA synthesis and ligation in nonhomologous end joining

Genetic studies have implicated the Saccharomyces cerevisiae POL4 gene product in the repair of DNA double-strand breaks by nonhomologous end joining. Here we show that Pol4 preferentially catalyzes DNA synthesis on small gaps formed by the alignment of linear duplex DNA molecules with complementary ends, a DNA substrate specificity that is compatible with its predicted role in the repair of DNA double-strand breaks. Pol4 also interacts directly with the Dnl4 subunit of the Dnl4-Lif1 complex via its N-terminal BRCT domain. This interaction stimulates the DNA synthesis activity of Pol4 and, to a lesser extent, the DNA joining activity of Dnl4-Lif1. Notably, the joining of DNA substrates that require the combined action of Pol4 and Dnl4-Lif1 is much more efficient than the joining of similar DNA substrates that require only ligation. Thus, the physical and functional interactions between Pol4 and Dnl4-Lif1 provide a molecular mechanism for both the recruitment of Pol4 to in vivo DNA double-strand breaks and the coupling of the gap filling DNA synthesis and DNA joining reactions that complete the microhomology-mediated pathway of nonhomologous end joining.

Lesion bypass activities of human DNA polymerase mu

DNA polymerase mu (Polmu) is a newly discovered member of the polymerase X family with unknown cellular function. The understanding of Polmu function should be facilitated by an understanding of its biochemical activities. By using purified human Polmu for biochemical analyses, we discovered the lesion bypass activities of this polymerase in response to several types of DNA damage. When it encountered a template 8-oxoguanine, abasic site, or 1,N(6)-ethenoadenine, purified human Polmu efficiently bypassed the lesion. Even bulky DNA adducts such as N-2-acetylaminofluorene-adducted guanine, (+)- and (-)-trans-anti-benzo[a]pyrene-N(2)-dG were unable to block the polymerase activity of human Polmu. Bypass of these simple base damage and bulky adducts was predominantly achieved by human Polmu through a deletion mechanism. The Polmu specificity of nucleotide incorporation indicates that the deletion resulted from primer realignment before translesion synthesis. Purified human Polmu also effectively bypassed a template cis-syn TT dimer. However, this bypass was achieved in a mainly error-free manner with AA incorporation opposite the TT dimer. These results provide new insights into the biochemistry of human Polmu and show that efficient translesion synthesis activity is not strictly confined to the Y family polymerases.

DNA polymerase mu gene expression in B-cell non-Hodgkin's lymphomas: an analysis utilizing in situ hybridization

DNA polymerase mu (pol mu) is a novel error-prone DNA repair enzyme bearing significant structural homology with terminal deoxynucleotidyltransferase. Whereas other human error-prone DNA polymerases identified thus far show no preferential lymphoid tissue distribution, the highest levels of pol mu mRNA have been detected in peripheral lymphoid tissues, particularly germinal center B cells. Conceivably, up-regulation of the pol mu gene may be biologically significant in lymphomagenesis, especially in the development of B-cell non-Hodgkin's lymphomas (B-NHLs), because of enhanced error-prone DNA repair activities. To explore this possibility, we generated a digoxigenin-labeled riboprobe to pol mu mRNA and used the probe and in situ hybridization to examine the expression pattern of the pol mu gene in formalin-fixed, paraffin-embedded tissue sections of 37 B-NHLs. This included eight chronic lymphocytic leukemia/small lymphocytic lymphomas, six mantle cell lymphomas, seven follicular lymphomas, nine diffuse large B-cell lymphomas, three splenic marginal zone lymphomas, two Burkitt's lymphomas, and two precursor B-lymphoblastic lymphomas. We also correlated the pol mu mRNA expression levels with the tumor proliferation index, which was assessed in each case by image analysis of Ki-67 immunostained slides. Nineteen of 21 (90%) B-NHLs arising from postgerminal center B cells (follicular lymphomas, diffuse large B-cell lymphomas, splenic marginal zone lymphomas, and Burkitt's lymphomas) exhibited high expression of pol mu mRNA. In contrast, only 2 of 16 (13%) B-NHLs arising from pregerminal center B cells (chronic lymphocytic leukemia/small lymphocytic lymphomas, mantle cell lymphomas, and precursor B-lymphoblastic lymphomas) expressed significant levels of pol mu mRNA. Pol mu gene expression did not seem to correlate with the proliferation index, especially because a significant level of pol mu mRNA was not detected in either case of precursor B-lymphoblastic lymphomas. In conclusion, pol mu gene expression is highly associated with B-NHLs of postgerminal center B-cell derivation. Furthermore, the expression level is independent of the proliferation rate and thus is unrelated to the biological aggressiveness of the tumors. These findings, along with the error-prone nature of the enzyme, suggest that up-regulation of pol mu gene expression may be a contributing factor to the pathogenesis of a subset of B-NHLs through DNA repair-associated genomic instability.

AID-dependent somatic hypermutation occurs as a DNA single-strand event in the BL2 cell line

Immunoglobulin (Ig) gene hypermutation can be induced in the BL2 Burkitt's lymphoma cell line by IgM cross-linking and coculture with normal or transformed T helper clones. We describe here a T cell#150;independent in vitro induction assay, by which hypermutation is induced in BL2 cells through simultaneous aggregation of three surface receptors: IgM, CD19 and CD21. The mutations arise as a post-transcriptional event within 90 min. They are stably introduced in the G1 phase of the cell cycle, occurring in one of the two variable gene DNA strands, and eventually become fixed by replication in one of the daughter cells. Inactivation of AID (activation-induced cytidine deaminase) by homologous recombination in BL2 cells completely inhibits the process, thus validating this induction procedure as a model for the in vivo mechanism.

Simplified normal mode analysis of conformational transitions in DNA-dependent polymerases: the elastic network model

The Elastic Network Model is used to investigate the open/closed transition in all DNA-dependent polymerases whose structure is known in both forms. For each structure the model accounts well for experimental crystallographic B-factors. It is found in all cases that the transition can be well described with just a handful of the normal modes. Usually, only the lowest and/or the second lowest frequency normal modes deduced from the open form give rise to calculated displacement vectors that have a correlation coefficient larger than 0.50 with the observed difference vectors between the two forms. This is true for every structural class of DNA-dependent polymerases where a direct comparison with experimental structural data is available. In cases where only one form has been observed by X-ray crystallography, it is possible to make predictions concerning the possible existence of another form in solution by carefully examining the vector displacements predicted for the lowest frequency normal modes. This simple model, which has the advantage to be computationally inexpensive, could be used to design novel kind of drugs directed against polymerases, namely drugs preventing the open/closed transition from occurring in bacterial or viral DNA-dependent polymerases.

Association of DNA polymerase mu (pol mu) with Ku and ligase IV: role for pol mu in end-joining double-strand break repair

Mammalian DNA polymerase mu (pol mu) is related to terminal deoxynucleotidyl transferase, but its biological role is not yet clear. We show here that after exposure of cells to ionizing radiation (IR), levels of pol mu protein increase. pol mu also forms discrete nuclear foci after IR, and these foci are largely coincident with IR-induced foci of gammaH2AX, a previously characterized marker of sites of DNA double-strand breaks. pol mu is thus part of the cellular response to DNA double-strand breaks. pol mu also associates in cell extracts with the nonhomologous end-joining repair factor Ku and requires both Ku and another end-joining factor, XRCC4-ligase IV, to form a stable complex on DNA in vitro. pol mu in turn facilitates both stable recruitment of XRCC4-ligase IV to Ku-bound DNA and ligase IV-dependent end joining. In contrast, the related mammalian DNA polymerase beta does not form a complex with Ku and XRCC4-ligase IV and is less effective than pol mu in facilitating joining mediated by these factors. Our data thus support an important role for pol mu in the end-joining pathway for repair of double-strand breaks.

Over-expression of human DNA polymerase lambda in E. coli and characterization of the recombinant enzyme

BACKGROUND

DNA polymerase lambda (Pol lambda) was recently identified as a new member of the family X of DNA polymerases in eukaryotic cells. Pol lambda contains a nuclear localization signal (NLS), a BRCA1-C terminal (BRCT) domain, a proline-rich region, helix-hairpin-helix (HhH) and pol X motifs. Since the amino acid sequence for Pol lambda shares a high degree of homology to Pol beta, Pol lambda is considered to have a similar enzymatic nature to Pol beta.

RESULTS

Recombinant human Pol lambda was shown to possess template-directed DNA polymerase activity in its monomeric form. Pol lambda required either Mn2+ or Mg2+ as a metal co-factor to catalyse this activity, and optimal activity was detected at pH 8.5-9.0. Pol lambda was insensitive to aphidicolin, but was sensitive to dideoxynucleoside triphosphates or N-ethylmaleimide. By constructing the truncated Pol lambda, the proline rich region was shown to act in a suppression of its polymerization activity. A chimeric enzyme comprised of the Pol lambda N-terminal region and Pol beta also showed a reduced Pol beta activity. Proliferating cell nuclear antigen (PCNA) directly interacts with Pol lambda through its Pol beta like region in vitro.

CONCLUSIONS

Pol lambda possesses similar enzymatic nature to Pol beta; requirements of cations and optimal conditions for pH and NaCl concentration, aside from sensitivity to N-ethylmaleimide and template preference. The proline rich region of Pol lambda functions as a suppressor domain for its polymerization activity (SDPA). Pol lambda interacts directly with PCNA through its Pol beta like region. The functional consequence of this interaction is the negative regulation of Pol lambda activity.

Human DNA polymerase mu (Pol mu) exhibits an unusual replication slippage ability at AAF lesion

We analyzed the ability of various cell extracts to extend a radiolabeled primer past an N-2-acetylaminofluorene (AAF) adduct located on a primed single-stranded template. When the 3' end of the primer is located opposite the lesion, partially fractionated human primary fibroblast extracts efficiently catalyzed primer-terminus extension by adding a ladder of about 15 dGMPs, in an apparently non-templated reaction. This activity was not detected in SV40-transformed fibroblasts or in HeLa cell extracts unless purified human DNA polymerase mu (Pol mu) was added. In contrast, purified human Pol mu alone could only add three dGMPs as predicted from the sequence of the template. These results suggest that a cofactor(s) present in cellular extracts modifies Pol mu activity. The production of the dGMP ladder at the primer terminus located opposite the AAF adduct reveals an unusual ability of Pol mu (in conjunction with its cofactor) to perform DNA synthesis from a slipped intermediate containing several unpaired bases.

Epistatic analysis of the roles of the RAD27 and POL4 gene products in DNA base excision repair in S. cerevisiae

The cellular role of the DNA polymerase encoded by the Saccharomyces cerevisiae POL4 gene is unclear. We have used an epistasis analysis to investigate whether the proteins encoded by the POL4 and RAD27 genes participate in alternative, non-redundant subpathways of DNA base excision repair (BER). We constructed strains in which the genes were deleted singly or in combination and have examined their sensitivity to DNA damaging agents as well as spontaneous mutation frequency. The double deletion strain is no more sensitive to damaging agents and has no higher spontaneous mutation frequency than the most sensitive single mutant. These data indicate that the protein encoded by the POL4 gene does not participate in a non-redundant subpathway of base excision repair under these conditions. We discuss the implications of these results in light of the recent classification of the POL4 gene product as a member of the DNA polymerase lambda family.

Cutting edge: DNA polymerases mu and lambda are dispensable for Ig gene hypermutation

Mutations arising in Ig V genes during an immune response are most likely introduced by one or several error-prone DNA polymerases. Many of the recently described nonreplicative DNA polymerases have an intrinsic fidelity compatible with such an activity, the strongest candidates being polymerase (pol) eta, pol iota, pol zeta, and pol mu. We report in this work that mice inactivated for either of the two polymerases related to pol beta (i.e., pol mu and pol lambda) are viable and fertile and display a normal hypermutation pattern.

DNA polymerase lambda, a novel DNA repair enzyme in human cells

DNA polymerase lambda (pol lambda) is a novel family X DNA polymerase that has been suggested to play a role in meiotic recombination and DNA repair. The recent demonstration of an intrinsic 5'-deoxyribose-5-phosphate lyase activity in pol lambda supports a function of this enzyme in base excision repair. However, the biochemical properties of the polymerization activity of this enzyme are still largely unknown. We have cloned and purified human pol lambda to homogeneity in a soluble and active form, and we present here a biochemical description of its polymerization features. In support of a role in DNA repair, pol lambda inserts nucleotides in a DNA template-dependent manner and is processive in small gaps containing a 5'-phosphate group. These properties, together with its nucleotide insertion fidelity parameters and lack of proofreading activity, indicate that pol lambda is a novel beta-like DNA polymerase. However, the high affinity of pol lambda for dNTPs (37-fold over pol beta) is consistent with its possible involvement in DNA transactions occurring under low cellular levels of dNTPs. This suggests that, despite their similarities, pol beta and pol lambda have nonredundant in vivo functions.

Hydrocephalus, situs inversus, chronic sinusitis, and male infertility in DNA polymerase lambda-deficient mice: possible implication for the pathogenesis of immotile cilia syndrome

A growing number of DNA polymerases have been identified, although their physiological function and relation to human disease remain mostly unknown. DNA polymerase lambda (Pol lambda; also known as Pol beta2) has recently been identified as a member of the X family of DNA polymerases and shares 32% amino acid sequence identity with DNA Pol beta within the polymerase domain. With the use of homologous recombination, we generated Pol lambda(-/-) mice. Pol lambda(-/-) mice develop hydrocephalus with marked dilation of the lateral ventricles and exhibit a high rate of mortality after birth, although embryonic development appears normal. Pol lambda(-/-) mice also show situs inversus totalis and chronic suppurative sinusitis. The surviving male, but not female, Pol lambda(-/-) mice are sterile as a result of spermatozoal immobility. Microinjection of sperm from male Pol lambda(-/-) mice into oocytes gives rise to normal offspring, suggesting that the meiotic process is not impaired. Ultrastructural analysis reveals that inner dynein arms of cilia from both the ependymal cell layer and respiratory epithelium are defective, which may underlie the pathogenesis of hydrocephalus, situs inversus totalis, chronic sinusitis, and male infertility. Sensitivity of Pol lambda(-/-) cells to various kinds of DNA damage is indistinguishable from that of Pol lambda(+/+) cells. Collectively, Pol lambda(-/-) mice may provide a useful model for clarifying the pathogenesis of immotile cilia syndrome.

Crystal structures of a template-independent DNA polymerase: murine terminal deoxynucleotidyltransferase

The crystal structure of the catalytic core of murine terminal deoxynucleotidyltransferase (TdT) at 2.35 A resolution reveals a typical DNA polymerase beta-like fold locked in a closed form. In addition, the structures of two different binary complexes, one with an oligonucleotide primer and the other with an incoming ddATP-Co(2+) complex, show that the substrates and the two divalent ions in the catalytic site are positioned in TdT in a manner similar to that described for the human DNA polymerase beta ternary complex, suggesting a common two metal ions mechanism of nucleotidyl transfer in these two proteins. The inability of TdT to accommodate a template strand can be explained by steric hindrance at the catalytic site caused by a long lariat-like loop, which is absent in DNA polymerase beta. However, displacement of this discriminating loop would be sufficient to unmask a number of evolutionarily conserved residues, which could then interact with a template DNA strand. The present structure can be used to model the recently discovered human polymerase mu, with which it shares 43% sequence identity.

A plant phytotoxin, solanapyrone A, is an inhibitor of DNA polymerase beta and lambda

Solanapyrone A, a phytotoxin and enzyme inhibitor isolated from a fungus (SUT 01B1-2) selectively inhibits the activities of mammalian DNA polymerase beta and lambda (pol beta and lambda) in vitro. The IC50 values of the compound were 30 microm for pol beta and 37 microm for pol lambda. Because pol beta and lambda are in a family and their three-dimensional structures are thought to be highly similar to each other, we used pol beta to analyze the biochemical relationship with solanapyrone A. On pol beta, solanapyrone A antagonistically competed with both the DNA template and the nucleotide substrate. BIAcore analysis demonstrated that solanapyrone A bound selectively to the N-terminal 8-kDa domain of pol beta. This domain is known to bind single-stranded DNA, provide 5'-phosphate recognition of gapped DNA, and cleave the sugar-phosphate bond 3' to an intact apurinic/apyrimidinic (AP) site (i.e. AP lyase activity) including 5'-deoxyribose phosphate lyase activity. Solanapyrone A inhibited the single-stranded DNA-binding activity but did not influence the activities of the 5'-phosphate recognition in gapped DNA structures and the AP lyase. Based on these results, the inhibitory mechanism of solanapyrone A is discussed.

Emerging links between hypermutation of antibody genes and DNA polymerases

Substantial antibody variability is created when nucleotide substitutions are introduced into immunoglobulin variable genes by a controlled process of hypermutation. Evidence points to a mechanism involving DNA repair events at sites of targeted breaks. In vertebrate cells, there are many recently identified DNA polymerases that inaccurately copy templates. Some of these are candidates for enzymes that introduce base changes during hypermutation. Recent research has focused on possible roles for DNA polymerases zeta (POLZ), eta (POLH), iota (POLI), and mu (POLM) in the process.

Highly frequent frameshift DNA synthesis by human DNA polymerase mu

DNA polymerase mu (Polmu) is a newly identified member of the polymerase X family. The biological function of Polmu is not known, although it has been speculated that human Polmu may be a somatic hypermutation polymerase. To help understand the in vivo function of human Polmu, we have performed in vitro biochemical analyses of the purified polymerase. Unlike any other DNA polymerases studied thus far, human Polmu catalyzed frameshift DNA synthesis with an unprecedentedly high frequency. In the sequence contexts examined, -1 deletion occurred as the predominant DNA synthesis mechanism opposite the single-nucleotide repeat sequences AA, GG, TT, and CC in the template. Thus, the fidelity of DNA synthesis by human Polmu was largely dictated by the sequence context. Human Polmu was able to efficiently extend mismatched bases mainly by a frameshift synthesis mechanism. With the primer ends, containing up to four mismatches, examined, human Polmu effectively realigned the primer to achieve annealing with a microhomology region in the template several nucleotides downstream. As a result, human Polmu promoted microhomology search and microhomology pairing between the primer and the template strands of DNA. These results show that human Polmu is much more prone to cause frameshift mutations than base substitutions. The biochemical properties of human Polmu suggest a function in nonhomologous end joining and V(D)J recombination through its microhomology searching and pairing activities but do not support a function in somatic hypermutation.

Identification of an intrinsic 5'-deoxyribose-5-phosphate lyase activity in human DNA polymerase lambda: a possible role in base excision repair

Base excision repair (BER) is a major repair pathway in eukaryotic cells responsible for repair of lesions that give rise to abasic (AP) sites in DNA. Pivotal to this process is the 5'-deoxyribose-5-phosphate lyase (dRP lyase) activity of DNA polymerase beta (Pol beta). DNA polymerase lambda (Pol lambda) is a recently identified eukaryotic DNA polymerase that is homologous to Pol beta. We show here that human Pol lambda exhibits dRP lyase, but not AP lyase, activity in vitro and that this activity is consistent with a beta-elimination mechanism. Accordingly, a single amino acid substitution (K310A) eliminated more than 90% of the wild-type dRP lyase activity, thus suggesting that Lys(310) of Pol lambda is the main nucleophile involved in the reaction. The dRP lyase activity of Pol lambda, in coordination with its polymerization activity, efficiently repaired uracil-containing DNA in an in vitro reconstituted BER reaction. These results suggest that Pol lambda may participate in "single-nucleotide" base excision repair in mammalian cells.

Human DNA polymerase iota promiscuous mismatch extension

Human DNA polymerase iota is a low-fidelity template copier that preferentially catalyzes the incorporation of the wobble base G, rather than the Watson-Crick base A, opposite template T (Tissier, A., McDonald, J. P., Frank, E. G., and Woodgate, R. (2000) Genes Dev. 14, 1642-1650; Johnson, R. E., Washington, M. T., Haracska, L., Prakash, S., and Prakash, L. (2000) Nature 406, 1015-1019; Zhang, Y., Yuan, F., Wu, X., and Wang, Z. (2000) Mol. Cell. Biol. 20, 7099-7108). Here, we report on its ability to extend all 12 possible mispairs and 4 correct pairs in different sequence contexts. Extension from both matched and mismatched primer termini is generally most efficient and accurate when A is the next template base. In contrast, extension occurs less efficiently and accurately when T is the target template base. A striking exception occurs during extension of a G:T mispair, where the enzyme switches specificity, "preferring" to make a correct A:T base pair immediately downstream from an originally favored G:T mispair. Polymerase iota generates a variety of single and tandem mispairs with high frequency, implying that it may act as a strong mutator when copying undamaged DNA templates in vivo. Even so, its limited ability to catalyze extension from a relatively stable primer/template containing a "buried" mismatch suggests that polymerase iota-catalyzed errors are confined to short template regions.

The translesion DNA polymerase zeta plays a major role in Ig and bcl-6 somatic hypermutation

Ig somatic mutations would be introduced by a polymerase (pol) while repairing DNA outside main DNA replication. We show that human B cells constitutively express the translesion pol zeta, which effectively extends DNA past mismatched bases (mispair extender), and pol eta, which bypasses DNA lesions in an error-free fashion. Upon B cell receptor (BCR) engagement and coculture with activated CD4+ T cells, these lymphocytes upregulated pol zeta, downregulated pol eta, and mutated the Ig and bcl-6 genes. Inhibition of the pol zeta REV3 catalytic subunit by specific phosphorothioate-modified oligonucleotides impaired Ig and bcl-6 hypermutation and UV damage-induced DNA mutagenesis, without affecting cell cycle or viability. Thus, pol zeta plays a critical role in Ig and bcl-6 hypermutation, perhaps facilitated by the downregulation of pol eta.

Managing DNA polymerases: coordinating DNA replication, DNA repair, and DNA recombination

Two important and timely questions with respect to DNA replication, DNA recombination, and DNA repair are: (i) what controls which DNA polymerase gains access to a particular primer-terminus, and (ii) what determines whether a DNA polymerase hands off its DNA substrate to either a different DNA polymerase or to a different protein(s) for the completion of the specific biological process? These questions have taken on added importance in light of the fact that the number of known template-dependent DNA polymerases in both eukaryotes and in prokaryotes has grown tremendously in the past two years. Most notably, the current list now includes a completely new family of enzymes that are capable of replicating imperfect DNA templates. This UmuC-DinB-Rad30-Rev1 superfamily of DNA polymerases has members in all three kingdoms of life. Members of this family have recently received a great deal of attention due to the roles they play in translesion DNA synthesis (TLS), the potentially mutagenic replication over DNA lesions that act as potent blocks to continued replication catalyzed by replicative DNA polymerases. Here, we have attempted to summarize our current understanding of the regulation of action of DNA polymerases with respect to their roles in DNA replication, TLS, DNA repair, DNA recombination, and cell cycle progression. In particular, we discuss these issues in the context of the Gram-negative bacterium, Escherichia coli, that contains a DNA polymerase (Pol V) known to participate in most, if not all, of these processes.

DNA polymerase eta is an A-T mutator in somatic hypermutation of immunoglobulin variable genes

To determine whether DNA polymerase eta plays a role in the hypermutation of immunoglobulin variable genes, we examined the frequency and pattern of substitutions in variable VH6 genes from the peripheral blood lymphocytes of three patients with xeroderma pigmentosum variant disease, whose polymerase eta had genetic defects. The frequency of mutation was normal but the types of base changes were different: there was a decrease in mutations at A and T and a concomitant rise in mutations at G and C. We propose that more than one polymerase contributes to hypermutation and that if one is absent, others compensate. The data indicate that polymerase eta is involved in generating errors that occur predominantly at A and T and that another polymerase(s) may preferentially generate errors opposite G and C.

Transcription, beta-like DNA polymerases and hypermutation

This paper discusses two aspects of immunoglobulin (Ig) gene hypermutation. In the first approach, a transcription termination signal is introduced in an Ig light chain transgene acting as a mutation substrate, and transgenic lines are generated with control and mutant transgenes integrated in tandem. Analysis of transcription levels and mutation frequencies between mutant and control transgenes clearly dissociates transcription elongation and mutation, and therefore argues against models whereby specific pausing of the RNA polymerase during V gene transcription would trigger an error-prone repair process. The second part reports the identification of two novel beta-like DNA polymerases named Pol lambda and Pol mu, one of which (Pol mu) represents a good candidate for the Ig mutase due to its higher lymphoid expression and its similarity with the lymphoid enzyme terminal deoxynucleotidyl transferase. Peculiar features of the expression of this gene, including an unusual splicing variability and a splicing inhibition in response to DNA-damaging agents, are discussed.

Why do cells have multiple error-prone DNA polymerases?

Recent years have witnessed the emergence of a plethora of so-called novel DNA polymerases in both eukaryotic and prokaryotic cells. Many of these DNA polymerases are characterized by poor replicational fidelity and low processivity, and are devoid of 3' --> 5' exonuclease activity. This article describes the discovery of these error-prone polymerases and what is known about their biological function.

Human DNA repair genes

DNA repair systems are essential for the maintenance of genome integrity. Consequently, the disregulation of repair genes can be expected to be associated with significant, detrimental health effects, which can include an increased prevalence of birth defects, an enhancement of cancer risk, and an accelerated rate of aging. Although original insights into DNA repair and the genes responsible were largely derived from studies in bacteria and yeast, well over 125 genes directly involved in DNA repair have now been identified in humans, and their cDNA sequence established. These genes function in a diverse set of pathways that involve the recognition and removal of DNA lesions, tolerance to DNA damage, and protection from errors of incorporation made during DNA replication or DNA repair. Additional genes indirectly affect DNA repair, by regulating the cell cycle, ostensibly to provide an opportunity for repair or to direct the cell to apoptosis. For about 70 of the DNA repair genes listed in Table I, both the genomic DNA sequence and the cDNA sequence and chromosomal location have been elucidated. In 45 cases single-nucleotide polymorphisms have been identified and, in some cases, genetic variants have been associated with specific disorders. With the accelerating rate of gene discovery, the number of identified DNA repair genes and sequence variants is quickly rising. This report tabulates the current status of what is known about these genes. The report is limited to genes whose function is directly related to DNA repair.