Juhani E. Syväoja

The intrinsically disordered amino-terminal region of human RecQL4: multiple DNA-binding domains confer annealing, strand exchange and G4 DNA binding

Human RecQL4 belongs to the ubiquitous RecQ helicase family. Its N-terminal region represents the only homologue of the essential DNA replication initiation factor Sld2 of Saccharomyces cerevisiae, and also participates in the vertebrate initiation of DNA replication. Here, we utilized a random screen to identify N-terminal fragments of human RecQL4 that could be stably expressed in and purified from Escherichia coli. Biophysical characterization of these fragments revealed that the Sld2 homologous RecQL4 N-terminal domain carries large intrinsically disordered regions. The N-terminal fragments were sufficient for the strong annealing activity of RecQL4. Moreover, this activity appeared to be the basis for an ATP-independent strand exchange activity. Both activities relied on multiple DNA-binding sites with affinities to single-stranded, double-stranded and Y-structured DNA. Finally, we found a remarkable affinity of the N-terminus for guanine quadruplex (G4) DNA, exceeding the affinities for other DNA structures by at least 60-fold. Together, these findings suggest that the DNA interactions mediated by the N-terminal region of human RecQL4 represent a central function at the replication fork. The presented data may also provide a mechanistic explanation for the role of elements with a G4-forming propensity identified in the vicinity of vertebrate origins of DNA replication.

Segregation of Replicative DNA Polymerases during S Phase: DNA POLYMERASE ε, BUT NOT DNA POLYMERASES α/δ, ARE ASSOCIATED WITH LAMINS THROUGHOUT S PHASE IN HUMAN CELLS

Background: Replicative DNA polymerases δ and ϵ are believed to synthesize lagging and leading strands, respectively. Results: Human DNA polymerases α/δ and ϵ segregate during S phase and DNA polymerase ϵ alone remains bound to lamins. Conclusion: DNA polymerases δ and ϵ act independently in late S phase Significance: Human cell DNA replication may mechanistically differ from prokaryotic replication. DNA polymerases (Pol) α, δ, and ϵ replicate the bulk of chromosomal DNA in eukaryotic cells, Pol ϵ being the main leading strand and Pol δ the lagging strand DNA polymerase. By applying chromatin immunoprecipitation (ChIP) and quantitative PCR we found that at G1/S arrest, all three DNA polymerases were enriched with DNA containing the early firing lamin B2 origin of replication and, 2 h after release from the block, with DNA containing the origin at the upstream promoter region of the MCM4 gene. Pol α, δ, and ϵ were released from these origins upon firing. All three DNA polymerases, Mcm3 and Cdc45, but not Orc2, still formed complexes in late S phase. Reciprocal ChIP of the three DNA polymerases revealed that at G1/S arrest and early in S phase, Pol α, δ, and ϵ were associated with the same nucleoprotein complexes, whereas in late S phase Pol ϵ and Pol α/δ were largely associated with distinct complexes. At G1/S arrest, the replicative DNA polymerases were associated with lamins, but in late S phase only Pol ϵ, not Pol α/δ, remained associated with lamins. Consistently, Pol ϵ, but not Pol δ, was found in nuclear matrix fraction throughout the cell cycle. Therefore, Pol ϵ and Pol α/δ seem to pursue their functions at least in part independently in late S phase, either by physical uncoupling of lagging strand maturation from the fork progression, or by recruitment of Pol δ, but not Pol ϵ, to post-replicative processes such as translesion synthesis or post-replicative repair.

The Human Tim-Tipin Complex Interacts Directly with DNA Polymerase ϵ and Stimulates Its Synthetic Activity

Background: The Tim-Tipin complex plays a critical role in the S phase checkpoint and replication fork stability by a molecular mechanism not yet elucidated. Results: The human Tim-Tipin complex specifically enhances the synthetic activity of DNA polymerase ϵ. Conclusion: The Tim-Tipin complex could modulate the DNA polymerase ϵ function at the replication fork. Significance: These findings further our understanding of the replication fork dynamics in metazoans. The Tim-Tipin complex plays an important role in the S phase checkpoint and replication fork stability in metazoans, but the molecular mechanism underlying its biological function is poorly understood. Here, we present evidence that the recombinant human Tim-Tipin complex (and Tim alone) markedly enhances the synthetic activity of DNA polymerase ϵ. In contrast, no significant effect on the synthetic ability of human DNA polymerase α and δ by Tim-Tipin was observed. Surface plasmon resonance measurements and co-immunoprecipitation experiments revealed that recombinant DNA polymerase ϵ directly interacts with either Tim or Tipin. In addition, the results of DNA band shift assays suggest that the Tim-Tipin complex (or Tim alone) is able to associate with DNA polymerase ϵ bound to a 40-/80-mer DNA ligand. Our results are discussed in view of the molecular dynamics at the human DNA replication fork.

The Human Tim/Tipin Complex Directly Interacts with DNA Polymerase ϵ and Stimulates its Synthetic Activity*

Background: The Tim-Tipin complex plays a critical role in the S phase checkpoint and replication fork stability by a molecular mechanism not yet elucidated. Results: The human Tim-Tipin complex specifically enhances the synthetic activity of DNA polymerase ϵ. Conclusion: The Tim-Tipin complex could modulate the DNA polymerase ϵ function at the replication fork. Significance: These findings further our understanding of the replication fork dynamics in metazoans. The Tim-Tipin complex plays an important role in the S phase checkpoint and replication fork stability in metazoans, but the molecular mechanism underlying its biological function is poorly understood. Here, we present evidence that the recombinant human Tim-Tipin complex (and Tim alone) markedly enhances the synthetic activity of DNA polymerase ϵ. In contrast, no significant effect on the synthetic ability of human DNA polymerase α and δ by Tim-Tipin was observed. Surface plasmon resonance measurements and co-immunoprecipitation experiments revealed that recombinant DNA polymerase ϵ directly interacts with either Tim or Tipin. In addition, the results of DNA band shift assays suggest that the Tim-Tipin complex (or Tim alone) is able to associate with DNA polymerase ϵ bound to a 40-/80-mer DNA ligand. Our results are discussed in view of the molecular dynamics at the human DNA replication fork.

Effect of 8-oxoguanine and abasic site DNA lesions on in vitro elongation by human DNA polymerase in the presence of replication protein A and proliferating-cell nuclear antigen.

DNA pol (polymerase) is thought to be the leading strand replicase in eukaryotes. In the present paper, we show that human DNA pol can efficiently bypass an 8-oxo-G (7,8-dihydro-8-oxoguanine) lesion on the template strand by inserting either dCMP or dAMP opposite to it, but it cannot bypass an abasic site. During replication, DNA pols associate with accessory proteins that may alter their bypass ability. We investigated the role of the human DNA sliding clamp PCNA (proliferating-cell nuclear antigen) and of the human single-stranded DNA-binding protein RPA (replication protein A) in the modulation of the DNA synthesis and translesion capacity of DNA pol . RPA inhibited the elongation by human DNA pol on templates annealed to short primers. PCNA did not influence the elongation by DNA pol and had no effect on inhibition of elongation caused by RPA. RPA inhibition was considerably reduced when the length of the primers was increased. On templates bearing the 8-oxo-G lesion, this inhibitory effect was more pronounced on DNA replication beyond the lesion, suggesting that RPA may prevent extension by DNA pol after incorporation opposite an 8-oxo-G. Neither PCNA nor RPA had any effect on the inability of DNA pol to replicate past the AP site, independent of the primer length.

Modification of p21 level and cell cycle distribution by 50 Hz magnetic fields in human SH-SY5Y neuroblastoma cells

Abstract Purpose: In our previous studies, exposure to extremely low frequency (ELF) magnetic fields (MF) altered responses to DNA damage caused by menadione. The aim of this study was to evaluate possible ELF MF induced changes in proteins involved in DNA damage responses and in cell cycle distribution. Materials and methods: Based on our previous studies, the exposure protocol included pre-exposure of human SH-SY5Y neuroblastoma cells to a 50 Hz, 100 μT MF for 24 h prior to a 3-h menadione treatment. As DNA damage responses are relatively fast processes, a 1-h menadione treatment was also included in the experiments. The menadione concentrations used were 1, 10, 15, 20, and 25 μM. Immunoblotting was used to assess the levels of DNA damage response-related proteins (γ-H2AX, Chk1, phospho-Chk1, p21, p27, and p53), while the level of DNA damage was assessed by the alkaline Comet assay. Cell cycle distribution was assayed by SYTOX Green staining followed by flow cytometry analysis. Results: The main findings in MF-exposed cells were decreased p21 protein level after the 1-h menadione treatment, as well as increased proportion of cells in the G1 phase and decreased proportion of S phase cells after the 3-h menadione treatment. These effects were detectable also in the absence of menadione. Conclusions: The results indicate that MF exposure can alter the G1 checkpoint response and that the p21 protein may be involved in early responses to MF exposure.

High levels of TopBP1 induce ATR-dependent shut-down of rRNA transcription and nucleolar segregation

Nucleoli are not only organelles that produce ribosomal subunits. They are also overarching sensors of different stress conditions and they control specific nucleolar stress pathways leading to stabilization of p53. During DNA replication, ATR and its activator TopBP1 initiate DNA damage response upon DNA damage and replication stress. We found that a basal level of TopBP1 protein associates with ribosomal DNA repeat. When upregulated, TopBP1 concentrates at the ribosomal chromatin and initiates segregation of nucleolar components—the hallmark of nucleolar stress response. TopBP1-induced nucleolar segregation is coupled to shut-down of ribosomal RNA transcription in an ATR-dependent manner. Nucleolar segregation induced by TopBP1 leads to a moderate elevation of p53 protein levels and to localization of activated p53 to nucleolar caps containing TopBP1, UBF and RNA polymerase I. Our findings demonstrate that TopBP1 and ATR are able to inhibit the synthesis of rRNA and to activate nucleolar stress pathway; yet the p53-mediated cell cycle arrest is thwarted in cells expressing high levels of TopBP1. We suggest that inhibition of rRNA transcription by different stress regulators is a general mechanism for cells to initiate nucleolar stress pathway.

Human DNA polymerase α interacts with mismatch repair proteins MSH2 and MSH6

High fidelity of genome duplication is ensured by cooperation of polymerase proofreading and mismatch repair (MMR) activities. Here, we show that human mismatch recognizing proteins MutS homolog 2 (MSH2) and MSH6 copurify and interact with replicative Pol α. This enzyme also is the replicative primase and replicates DNA with poor fidelity. We show that MSH2 associates with known human replication origins with different dynamics than DNA polymerase (Pol α). Furthermore, we explored the potential functional role of Pol α in the mismatch repair reaction using an in vitro mismatch repair assay and observed that Pol α promotes mismatch repair. Taken together, we show that human Pol α interacts with MSH2‐MSH6 complex and propose that this interaction occurs during the mismatch repair reaction.

Gap-Directed Translesion DNA Synthesis of an Abasic Site on Circular DNA Templates by a Human Replication Complex

DNA polymerase ε (pol ε) is believed to be the leading strand replicase in eukaryotes whereas pols λ and β are thought to be mainly involved in re-synthesis steps of DNA repair. DNA elongation by the human pol ε is halted by an abasic site (apurinic/apyrimidinic (AP) site). We have previously reported that human pols λ, β and η can perform translesion synthesis (TLS) of an AP site in the presence of pol ε. In the case of pol λ and β, this TLS requires the presence of a gap downstream from the product synthetized by the ε replicase. However, since these studies were conducted exclusively with a linear DNA template, we decided to test whether the structure of the template could influence the capacity of the pols ε, λ, β and η to perform TLS of an AP site. Therefore, we have investigated the replication of damaged “minicircle” DNA templates. In addition, replication of circular DNA requires, beyond DNA pols, the processivity clamp PCNA, the clamp loader replication factor C (RFC), and the accessory proteins replication protein A (RPA). Finally we have compared the capacity of unmodified versus monoubiquitinated PCNA in sustaining TLS by pols λ and η on a circular template. Our results indicate that in vitro gap-directed TLS synthesis by pols λ and β in the presence of pol ε, RPA and PCNA is unaffected by the structure of the DNA template. Moreover, monoubiquitination of PCNA does not affect TLS by pol λ while it appears to slightly stimulate TLS by pol η.

Efficient long DNA gap-filling in a mammalian cell-free system: A potential new in vitro DNA replication assay

In vitro assay of mammalian DNA replication has been variously approached. Using gapped circular duplex substrates containing a 500-base single-stranded DNA region, we have constructed a mammalian cell-free system in which physiological DNA replication may be reproduced. Reaction of the gapped plasmid substrate with crude extracts of human HeLaS3 cells induces efficient DNA synthesis in vitro. The induced synthesis was strongly inhibited by aphidicolin and completely depended on dNTP added to the system. In cell extracts in which PCNA was depleted step-wise by immunoprecipitation, DNA synthesis was accordingly reduced. These data suggest that replicative DNA polymerases, particularly pol delta, may chiefly function in this system. Furthermore, DNA synthesis is made quantifiable in this system, which enables us to evaluate the efficiency of DNA replication induced. Our system sensitively and quantitatively detected the reduction of the DNA replication efficiency in the DNA substrates damaged by oxidation or UV cross-linking and in the presence of a potent chain terminator, ara-CTP. The quantitative assessment of mammalian DNA replication may provide various advantages not only in basic research but also in drug development.