Zucai Suo

Snapshots of a Y-Family DNA Polymerase in Replication: Substrate-induced Conformational Transitions and Implications for Fidelity of Dpo4

Y-family DNA polymerases catalyze translesion DNA synthesis over damaged DNA. Each Y-family polymerase has a polymerase core consisting of a palm, finger and thumb domain in addition to a fourth domain known as a little finger domain. It is unclear how each domain moves during nucleotide incorporation and what type of conformational changes corresponds to the rate-limiting step previously reported in kinetic studies. Here, we present three crystal structures of the prototype Y-family polymerase: apo-Dpo4 at 1.9 A resolution, Dpo4-DNA binary complex and Dpo4-DNA-dTMP ternary complex at 2.2 A resolution. Dpo4 undergoes dramatic conformational changes from the apo to the binary structures with a 131 degrees rotation of the little finger domain relative to the polymerase core upon DNA binding. This DNA-induced conformational change is verified in solution by our tryptophan fluorescence studies. In contrast, the polymerase core retains the same conformation in all three conformationally distinct states. Particularly, the finger domain which is responsible for checking base pairing between the template base and an incoming nucleotide retains a rigid conformation. The inflexibility of the polymerase core likely contributes to the low fidelity of Dpo4, in addition to its loose and solvent-accessible active site. Interestingly, while the binary and ternary complexes of Dpo4 retain an identical global conformation, the aromatic side chains of two conserved tyrosines at the nucleotide-binding site change orientations between the binary and ternary structures. Such local conformational changes may correspond to the rate-limiting step in the mechanism of nucleotide incorporation. Together, the global and local conformational transitions observed in our study provide a structural basis for the distinct kinetic steps of a catalytic cycle of DNA polymerization performed by a Y-family polymerase.

Mechanism of Abasic Lesion Bypass Catalyzed by a Y-family DNA Polymerase

The 3 million-base pair genome of Sulfolobus solfataricus likely undergoes depurination/depyrimidination frequently in vivo. These unrepaired abasic lesions are expected to be bypassed by Dpo4, the only Y-family DNA polymerase from S. solfataricus. Interestingly, these error-prone Y-family enzymes have been shown to be physiologically vital in reducing the potentially negative consequences of DNA damage while paradoxically promoting carcinogenesis. Here we used Dpo4 as a model Y-family polymerase to establish the mechanistic basis for DNA lesion bypass. While showing efficient bypass, Dpo4 paused when incorporating nucleotides directly opposite and one position downstream from an abasic lesion because of a drop of several orders of magnitude in catalytic efficiency. Moreover, in disagreement with a previous structural report, Dpo4-catalyzed abasic bypass involves robust competition between the A-rule and the lesion loop-out mechanism and is governed by the local DNA sequence. Analysis of the strong pause sites revealed biphasic kinetics for incorporation indicating that Dpo4 primarily formed a nonproductive complex with DNA that converted slowly to a productive complex. These strong pause sites are mutational hot spots with the embedded lesion even affecting the efficiency of five to six downstream incorporations. Our results suggest that abasic lesion bypass requires tight regulation to maintain genomic stability.

Global Conformational Dynamics of a Y-Family DNA Polymerase during Catalysis

High-resolution analysis of protein, and DNA conformational changes during DNA polymerization, established relationships between the enzymatic function and conformational dynamics of individual domains for a DNA polymerase.

Up-regulation of the Fidelity of Human DNA Polymerase λ by Its Non-enzymatic Proline-rich Domain

DNA repair pathways are essential for maintaining genome stability. DNA polymerase β plays a critical role in base-excision repair in vivo. DNA polymerase λ, a recently identified X-family homolog of DNA polymerase β, is hypothesized to be a second polymerase involved in base-excision repair. The full-length DNA polymerase λ is comprised of three domains: a C-terminal DNA polymerase β-like domain, an N-terminal BRCA1 C-terminal domain, and a previously uncharacterized proline-rich domain. Strikingly, pre-steady-state kinetic analyses reveal that, although human DNA polymerase λ has almost identical fidelity to human DNA polymerase β, the C-terminal DNA polymerase β-like domain alone displays a dramatic, up to 100-fold loss in fidelity. We further demonstrate that the non-enzymatic proline-rich domain confers the increase in fidelity of DNA polymerase λ by significantly lowering incorporation rate constants of incorrect nucleotides. Our studies illustrate a novel mechanism, in which the DNA polymerase fidelity is controlled not by an accessory protein or a proofreading exonuclease domain but by an internal regulatory domain.

Sloppy Bypass of an Abasic Lesion Catalyzed by a Y-family DNA Polymerase

DNA damage that eludes cellular repair pathways can arrest the replication machinery and stall the cell cycle. However, this damage can be bypassed by the Y-family DNA polymerases. Here, Dpo4, an archetypal Y-family member from the thermophilic Sulfolobus solfataricus, was used to extend our kinetic studies of the bypass of an abasic site, one of the most mutagenic and ubiquitous cellular lesions. A short oligonucleotide sequencing assay is developed to directly sequence DNA bypass products synthesized by Dpo4. Our results show that incorporation upstream of the abasic lesion is replicated error-free; yet dramatically, once Dpo4 encounters the lesion, synthesis became sloppy, with bypass products containing a myriad of mutagenic events. Incorporation of dAMP (29%) and dCMP (53%) opposite the abasic lesion at 37 °C correlates exceptionally well with our kinetic results and demonstrates two dominant bypass pathways via the A-rule and the lesion loop-out mechanism. Interestingly, the percentage of overall frameshift mutations increased from 71 (37 °C) to 87% (75 °C). Further analysis indicates that lesion bypass via the A-rule is strongly preferred over the lesion loop-out mechanism at higher temperatures and concomitantly reduces the occurrence of “-1 deletion” mutations observed opposite the lesion at lower temperatures. The bypass percentage via the latter pathway is confirmed by an enzymatic digestion assay, verifying the reliability of our sequencing assay. Our results demonstrate that an abasic lesion causes Dpo4 and possibly all Y-family members to switch from a normal to a very mutagenic mode of replication.

EFFECT OF RNA SECONDARY STRUCTURE ON RNA CLEAVAGE CATALYZED BY HIV-1 REVERSE TRANSCRIPTASE

Using a synthetic 66 nucleotide RNA template containing a stable hairpin structure derived from the HIV-1 genome, six predominant RNA cleavage products are found during DNA synthesis catalyzed by HIV-1 RT. These major RNA cleavage sites correlate well with the pause sites seen during primer elongation [Suo, Z., & Johnson, K. A. (1997) Biochemistry (manuscript submitted for publication)]. Thus, the RNase H and polymerase activities of RT are coupled as RT reads through the RNA secondary structure. The distance between the two active sites of HIV-1 RT is 19-20 base pairs of DNA/RNA heteroduplex when the next template base is not paired. The heteroduplex region was enlarged by 2-3 base pairs once RT encounters the template hairpin. A model for this change is presented. At the pause sites, the burst amplitudes of RNA cleavage are larger than the corresponding reaction amplitudes of next nucleotide incorporation at the polymerase site. Measurement of the steady state rates of RNA cleavage confirms that all substrates dissociate slowly from RT. These results suggest that while substrates are bound nonproductively at the polymerase site, they are still bound productively at the RNase H active site of RT. Characterization of an RNase H-deficient RT mutant (D443N) shows that RNase H activity is not critical for RT to read through the RNA secondary structure. HIV-1 nucleocapsid does not increase the processivity of HIV-1 RT but inhibits DNA elongation by blocking the binding of RT to DNA substrates.

Human DNA Polymerase ϵ Is Able to Efficiently Extend from Multiple Consecutive Ribonucleotides

Background: Ribonucleotides in DNA are associated with genome instability. Results: Human DNA polymerase ϵ catalyzes efficient incorporation of ribonucleotides and extension from primers terminating in multiple consecutive ribonucleotides. Conclusion: Human DNA polymerase ϵ is able to extend ribonucleotide-terminal primers through a reduction in its proofreading activity. Significance: Leading strand replication may have a unique relationship to ribonucleotides, RNA, and genome stability. Replicative DNA polymerases (Pols) help to maintain the high fidelity of replication in large part through their strong selectivity against mispaired deoxyribonucleotides. It has recently been demonstrated that several replicative Pols from yeast have surprisingly low selectivity for deoxyribonucleotides over their analogous ribonucleotides. In human cells, ribonucleotides are found in great abundance over deoxyribonucleotides, raising the possibility that ribonucleotides are incorporated in the human genome at significant levels during normal cellular functions. To address this possibility, the ability of human DNA polymerase ϵ to incorporate ribonucleotides was tested. At physiological concentrations of nucleotides, human Pol ϵ readily inserts and extends from incorporated ribonucleotides. Almost half of inserted ribonucleotides escape proofreading by 3′ → 5′ exonuclease-proficient Pol ϵ, indicating that ribonucleotide incorporation by Pol ϵ is likely a significant event in human cells. Human Pol ϵ is also efficient at extending from primers terminating in up to five consecutive ribonucleotides. This efficient extension appears to result from reduced exonuclease activity on primers containing consecutive 3′-terminal ribonucleotides. These biochemical properties suggest that Pol ϵ is a likely source of ribonucleotides in human genomic DNA.

Structural insight into dynamic bypass of the major cisplatin-DNA adduct by Y-family polymerase Dpo4.

Y‐family DNA polymerases bypass Pt‐GG, the cisplatin‐DNA double‐base lesion, contributing to the cisplatin resistance in tumour cells. To reveal the mechanism, we determined three structures of the Y‐family DNA polymerase, Dpo4, in complex with Pt‐GG DNA. The crystallographic snapshots show three stages of lesion bypass: the nucleotide insertions opposite the 3′G (first insertion) and 5′G (second insertion) of Pt‐GG, and the primer extension beyond the lesion site. We observed a dynamic process, in which the lesion was converted from an open and angular conformation at the first insertion to a depressed and nearly parallel conformation at the subsequent reaction stages to fit into the active site of Dpo4. The DNA translocation‐coupled conformational change may account for additional inhibition on the second insertion reaction. The structures illustrate that Pt‐GG disturbs the replicating base pair in the active site, which reduces the catalytic efficiency and fidelity. The in vivo relevance of Dpo4‐mediated Pt‐GG bypass was addressed by a dpo‐4 knockout strain of Sulfolobus solfataricus, which exhibits enhanced sensitivity to cisplatin and proteomic alterations consistent with genomic stress.

Recent insight into the kinetic mechanisms and conformational dynamics of Y-Family DNA polymerases.

The kinetic mechanisms by which DNA polymerases catalyze DNA replication and repair have long been areas of active research. Recently discovered Y-family DNA polymerases catalyze the bypass of damaged DNA bases that would otherwise block replicative DNA polymerases and stall replication forks. Unlike DNA polymerases from the five other families, the Y-family DNA polymerases have flexible, solvent-accessible active sites that are able to tolerate various types of damaged template bases and allow for efficient lesion bypass. Their promiscuous active sites, however, also lead to fidelities that are much lower than those observed for other DNA polymerases and give rise to interesting mechanistic properties. Additionally, the Y-family DNA polymerases have several other unique structural features and undergo a set of conformational changes during substrate binding and catalysis different from those observed for replicative DNA polymerases. In recent years, pre-steady-state kinetic methods have been extensively employed to reveal a wealth of information about the catalytic properties of these fascinating noncanonical DNA polymerases. Here, we review many of the recent findings on the kinetic mechanisms of DNA polymerization with undamaged and damaged DNA substrates by the Y-family DNA polymerases, and the conformational dynamics employed by these error-prone enzymes during catalysis.

Kinetic investigation of the inhibitory effect of gemcitabine on DNA polymerization catalyzed by human mitochondrial DNA polymerase

Gemcitabine, 2′-deoxy-2′, 2′-difluorocytidine (dFdC), is a drug approved for use against various solid tumors. Clinically, this moderately toxic nucleoside analog causes peripheral neuropathy, hematological dysfunction, and pulmonary toxicity in cancer patients. Although these side effects closely mimic symptoms of mitochondrial dysfunction, there is no direct evidence to show gemcitabine interferes with mitochondrial DNA replication catalyzed by human DNA polymerase γ. Here we employed presteady state kinetic methods to directly investigate the incorporation of the 5′-triphosphorylated form of gemcitabine (dFdCTP), the excision of the incorporated monophosphorylated form (dFdCMP), and the bypass of template base dFdC catalyzed by human DNA polymerase γ. Opposite template base dG, dFdCTP was incorporated with a 432-fold lower efficiency than dCTP. Although dFdC is not a chain terminator, the incorporated dFdCMP decreased the incorporation efficiency of the next 2 correct nucleotides by 214- and 7-fold, respectively. Moreover, the primer 3′-dFdCMP was excised with a 50-fold slower rate than the matched 3′-dCMP. When dFdC was encountered as a template base, DNA polymerase γ paused at the lesion and one downstream position but eventually elongated the primer to full-length product. These pauses were because of a 1,000-fold decrease in nucleotide incorporation efficiency. Interestingly, the polymerase fidelity at these pause sites decreased by 2 orders of magnitude. Thus, our pre-steady state kinetic studies provide direct evidence demonstrating the inhibitory effect of gemcitabine on the activity of human mitochondrial DNA polymerase.