Ekaterina G. Frank

Misinsertion and bypass of thymine–thymine dimers by human DNA polymerase ι

Human DNA polymerase ι (polι) is a recently discovered enzyme that exhibits extremely low fidelity on undamaged DNA templates. Here, we show that polι is able to facilitate limited translesion replication of a thymine–thymine cyclobutane pyrimidine dimer (CPD). More importantly, however, the bypass event is highly erroneous. Gel kinetic assays reveal that polι misinserts T or G opposite the 3′ T of the CPD ∼1.5 times more frequently than the correct base, A. While polι is unable to extend the T·T mispair significantly, the G·T mispair is extended and the lesion completely bypassed, with the same efficiency as that of the correctly paired A·T base pair. By comparison, polι readily misinserts two bases opposite a 6‐4 thymine–thymine pyrimidine–pyrimidone photoproduct (6‐4PP), but complete lesion bypass is only a fraction of that observed with the CPD. Our data indicate, therefore, that polι possesses the ability to insert nucleotides opposite UV photoproducts as well as to perform unassisted translesion replication that is likely to be highly mutagenic.

129-derived Strains of Mice Are Deficient in DNA Polymerase ι and Have Normal Immunoglobulin Hypermutation

Recent studies suggest that DNA polymerase η (polη) and DNA polymerase ι (polι) are involved in somatic hypermutation of immunoglobulin variable genes. To test the role of polι in generating mutations in an animal model, we first characterized the biochemical properties of murine polι. Like its human counterpart, murine polι is extremely error-prone when catalyzing synthesis on a variety of DNA templates in vitro. Interestingly, when filling in a 1 base-pair gap, DNA synthesis and subsequent strand displacement was greatest in the presence of both pols ι and η. Genomic sequence analysis of Poli led to the serendipitous discovery that 129-derived strains of mice have a nonsense codon mutation in exon 2 that abrogates production of polι. Analysis of hypermutation in variable genes from 129/SvJ (Poli −/−) and C57BL/6J (Poli +/+) mice revealed that the overall frequency and spectrum of mutation were normal in polι-deficient mice. Thus, either polι does not participate in hypermutation, or its role is nonessential and can be readily assumed by another low-fidelity polymerase.

Increased Catalytic Activity and Altered Fidelity of Human DNA Polymerase ι in the Presence of Manganese

All DNA polymerases require a divalent cation for catalytic activity. It is generally assumed that Mg2+ is the physiological cofactor for replicative DNA polymerases in vivo. However, recent studies suggest that certain repair polymerases, such as pol λ, may preferentially utilize Mn2+ in vitro. Here we report on the effects of Mn2+ and Mg2+ on the enzymatic properties of human DNA polymerase ι (pol ι). pol ι exhibited the greatest activity in the presence of low levels of Mn2+ (0.05–0.25 mm). Peak activity in the presence of Mg2+ was observed in the range of 0.1–0.5 mm and was significantly reduced at concentrations >2 mm. Steady-state kinetic analyses revealed that Mn2+ increases the catalytic activity of pol ι by ∼30–60,000-fold through a dramatic decrease in the Km value for nucleotide incorporation. Interestingly, whereas pol ι preferentially misinserts G opposite T by a factor of ∼1.4–2.5-fold over the correct base A in the presence of 0.25 and 5 mm Mg2+, respectively, the correct insertion of A is actually favored 2-fold over the misincorporation of G in the presence of 0.075 mm Mn2+. Low levels of Mn2+ also dramatically increased the ability of pol ι to traverse a variety of DNA lesions in vitro. Titration experiments revealed a strong preference of pol ι for Mn2+ even when Mg2+ is present in a >10-fold excess. Our observations therefore raise the intriguing possibility that the cation utilized by pol ι in vivo may actually be Mn2+ rather than Mg2+, as tacitly assumed.

Altered nucleotide misinsertion fidelity associated with polι‐dependent replication at the end of a DNA template

A hallmark of human DNA polymerase ι (polι) is the asymmetric fidelity of replication at template A and T when the enzyme extends primers annealed to a single‐stranded template. Here, we report on the efficiency and accuracy of polι‐dependent replication at a nick, a gap, the very end of a template and from a mispaired primer. Polι cannot initiate synthesis on a nicked DNA substrate, but fills short gaps efficiently. Surprisingly, polιs ability to blunt‐end a 1 bp recessed terminus is dependent upon the template nucleotide encountered and is highly erroneous. At template G, both C and T are inserted with roughly equal efficiency, whilst at template C, C and A are misinserted 8‐ and 3‐fold more often than the correct base, G. Using substrates containing mispaired primer termini, we show that polι can extend all 12 mispairs, but with differing efficiencies. Polι can also extend a tandem mispair, especially when it is located within a short gap. The enzymatic properties of polι appear consistent with that of a somatic hypermutase and suggest that polι may be one of the low‐fidelity DNA polymerases hypothesized to participate in the hypermutation of immunoglobulin variable genes in vivo.

Eukaryotic Y-family polymerases bypass a 3-methyl-2′-deoxyadenosine analog in vitro and methyl methanesulfonate-induced DNA damage in vivo

N3-methyl-adenine (3MeA) is the major cytotoxic lesion formed in DNA by SN2 methylating agents. The lesion presumably blocks progression of cellular replicases because the N3-methyl group hinders interactions between the polymerase and the minor groove of DNA. However, this hypothesis has yet to be rigorously proven, as 3MeA is intrinsically unstable and is converted to an abasic site, which itself is a blocking lesion. To circumvent these problems, we have chemically synthesized a 3-deaza analog of 3MeA (3dMeA) as a stable phosphoramidite and have incorporated the analog into synthetic oligonucleotides that have been used in vitro as templates for DNA replication. As expected, the 3dMeA lesion blocked both human DNA polymerases α and δ. In contrast, human polymerases η, ι and κ, as well as Saccharomyces cerevisiae polη were able to bypass the lesion, albeit with varying efficiencies and accuracy. To confirm the physiological relevance of our findings, we show that in S. cerevisiae lacking Mag1-dependent 3MeA repair, polη (Rad30) contributes to the survival of cells exposed to methyl methanesulfonate (MMS) and in the absence of Mag1, Rad30 and Rev3, human polymerases η, ι and κ are capable of restoring MMS-resistance to the normally MMS-sensitive strain.

A strategy for the expression of recombinant proteins traditionally hard to purify.

We have developed a series of plasmid vectors for the soluble expression and subsequent purification of recombinant proteins that have historically proven to be extremely difficult to purify from Escherichia coli. Instead of dramatically overproducing the target protein, it is expressed at a low basal level that facilitates the correct folding of the recombinant protein and increases its solubility. Highly active recombinant proteins that are traditionally difficult to purify are readily purified using standard affinity tags and conventional chromatography. To demonstrate the utility of these vectors, we have expressed and purified full-length human DNA polymerases η, ι, and ν from E. coli and show that the purified DNA polymerases are catalytically active in vitro.

The structure and duplex context of DNA interstrand crosslinks affects the activity of DNA polymerase η

Several important anti-tumor agents form DNA interstrand crosslinks (ICLs), but their clinical efficiency is counteracted by multiple complex DNA repair pathways. All of these pathways require unhooking of the ICL from one strand of a DNA duplex by nucleases, followed by bypass of the unhooked ICL by translesion synthesis (TLS) polymerases. The structures of the unhooked ICLs remain unknown, yet the position of incisions and processing of the unhooked ICLs significantly influence the efficiency and fidelity of bypass by TLS polymerases. We have synthesized a panel of model unhooked nitrogen mustard ICLs to systematically investigate how the state of an unhooked ICL affects pol η activity. We find that duplex distortion induced by a crosslink plays a crucial role in translesion synthesis, and length of the duplex surrounding an unhooked ICL critically affects polymerase efficiency. We report the synthesis of a putative ICL repair intermediate that mimics the complete processing of an unhooked ICL to a single crosslinked nucleotide, and find that it provides only a minimal obstacle for DNA polymerases. Our results raise the possibility that, depending on the structure and extent of processing of an ICL, its bypass may not absolutely require TLS polymerases.

Arrested DNA replication in Xenopus and release by Escherichia coli mutagenesis proteins

Xenopus oocytes and oocyte nuclear extracts repair ultraviolet photoproducts on double-stranded (ds) DNA and replicate single-stranded (ss) to ds DNA. M13 ss DNA molecules containing cyclobutane pyrimidine dimers were maintained but not replicated in Xenopus oocytes, yet were replicated in progesterone-matured oocytes. The replication arrest functioned only in cis. The replication arrest was alleviated by injection into oocytes of messenger RNAs encoding the prokaryotic mutagenesis proteins UmuD′C or MucA′B. These results may help explain how cells stabilize repair or replication events on DNA with unrepairable lesions.

DNA polymerase ι functions in the generation of tandem mutations during somatic hypermutation of antibody genes

Gearhart and collaborators address the long-standing question of the roles of error-prone DNA polymerases in somatic hypermutation of antibody genes.

Posttranslational Regulation of Human DNA Polymerase ι

Background: Many proteins are subject to posttranslational regulation, such as ubiquitination. Results: Human DNA polymerase ι (polι) can be monoubiquitinated at >27 unique sites, and exposure to naphthoquinones results in polyubiquitination of polι. Conclusion: Ubiquitination sites are located across the entire polι polypeptide as well as various structural motifs. Significance: Ubiquitination at these sites is likely to alter cellular functions of polι in vivo. Human DNA polymerases (pols) η and ι are Y-family DNA polymerase paralogs that facilitate translesion synthesis past damaged DNA. Both polη and polι can be monoubiquitinated in vivo. Polη has been shown to be ubiquitinated at one primary site. When this site is unavailable, three nearby lysines may become ubiquitinated. In contrast, mass spectrometry analysis of monoubiquitinated polι revealed that it is ubiquitinated at over 27 unique sites. Many of these sites are localized in different functional domains of the protein, including the catalytic polymerase domain, the proliferating cell nuclear antigen-interacting region, the Rev1-interacting region, and its ubiquitin binding motifs UBM1 and UBM2. Polι monoubiquitination remains unchanged after cells are exposed to DNA-damaging agents such as UV light (generating UV photoproducts), ethyl methanesulfonate (generating alkylation damage), mitomycin C (generating interstrand cross-links), or potassium bromate (generating direct oxidative DNA damage). However, when exposed to naphthoquinones, such as menadione and plumbagin, which cause indirect oxidative damage through mitochondrial dysfunction, polι becomes transiently polyubiquitinated via Lys11- and Lys48-linked chains of ubiquitin and subsequently targeted for degradation. Polyubiquitination does not occur as a direct result of the perturbation of the redox cycle as no polyubiquitination was observed after treatment with rotenone or antimycin A, which both inhibit mitochondrial electron transport. Interestingly, polyubiquitination was observed after the inhibition of the lysine acetyltransferase KATB3/p300. We hypothesize that the formation of polyubiquitination chains attached to polι occurs via the interplay between lysine acetylation and ubiquitination of ubiquitin itself at Lys11 and Lys48 rather than oxidative damage per se.