Retroviral DNA integration and the DNA damage response

Retroviral DNA integration creates a discontinuity in the host cell chromatin and repair of this damage is required to complete the integration process. As integration and repair are essential for both viral replication and cell survival, it is possible that specific interactions with the host DNA repair systems might provide new cellular targets for human immunodeficiency virus therapy. Various genetic, pharmacological, and biochemical studies have provided strong evidence that postintegration DNA repair depends on components of the nonhomologous end-joining (NHEJ) pathway (DNA-PK (DNA-dependent protein kinase), Ku, Xrcc4, DNA ligase IV) and DNA damage-sensing pathways (Atr (Atm and Rad related), gamma-H2AX). Furthermore, deficiencies in NHEJ components result in susceptibility to apoptotic cell death following retroviral infection. Here, we review these findings and discuss other ways that retroviral DNA intermediates may interact with the host DNA damage signaling and repair pathways.     

DNA Polymerases that Propagate the Eukaryotic DNA Replication Fork

Abstract

Three DNA polymerases are thought to function at the eukaryotic DNA replication fork. Currently, a coherent model has been derived for the composition and activities of the lagging strand machinery. RNA-DNA primers are initiated by DNA polymerase α -primase. Loading of the proliferating cell nuclear antigen, PCNA, dissociates DNA polymerase α and recruits DNA polymerase δ and the flap endonuclease FEN1 for elongation and in preparation for its requirement during maturation, respectively. Nick translation by the strand displacement action of DNA polymerase δ, coupled with the nuclease action of FEN1, results in processive RNA degradation until a proper DNA nick is reached for closure by DNA ligase I. In the event of excessive strand displacement synthesis, other factors, such as the Dna2 nuclease/helicase, are required to trim excess flaps. Paradoxically, the composition and activity of the much simpler leading strand machinery has not been clearly established. The burden of evidence suggests that DNA polymerase ε normally replicates this strand, but under conditions of dysfunction, DNA polymerase δ may substitute.     

DNA ligases in the repair and replication of DNA

DNA ligases are critical enzymes of DNA metabolism. The reaction they catalyse (the joining of nicked DNA) is required in DNA replication and in DNA repair pathways that require the re-synthesis of DNA.Most organisms express DNA ligases powered by ATP, but eubacteria appear to be unique in having ligases driven by NAD(+). Interestingly, despite protein sequence and biochemical differences between the two classes of ligase, the structure of the adenylation domain is remarkably similar. Higher organisms express a variety of different ligases, which appear to be targetted to specific functions. DNA ligase I is required for Okazaki fragment joining and some repair pathways; DNA ligase II appears to be a degradation product of ligase III; DNA ligase III has several isoforms, which are involved in repair and recombination and DNA ligase IV is necessary for V(D)J recombination and non-homologous end-joining. Sequence and structural analysis of DNA ligases has shown that these enzymes are built around a common catalytic core, which is likely to be similar in three-dimensional structure to that of T7-bacteriophage ligase. The differences between the various ligases are likely to be mediated by regions outside of this common core, the structures of which are not known. Therefore, the determination of these structures, along with the structures of ligases bound to substrate DNAs and partner proteins ought to be seen as a priority.     

Locking the DNA gate of DNA gyrase: investigating the effects on DNA cleavage and ATP hydrolysis

Supercoiling by DNA gyrase involves the passage of one segment of double-stranded DNA through another. This requires a DNA duplex to be cleaved and the broken ends separated by at least 20 A. This is accomplished by the opening of a dimer interface, termed the DNA gate, which is covalently attached to the broken ends of the DNA. After strand passage, the DNA gate closes allowing the reunion of the broken ends. We have cross-linked the DNA gate of gyrase using cysteine cross-linking to block gate opening. We show that this locked gate mutant can bind quinolone drugs and perform DNA cleavage. However, locking the DNA gate prevents strand passage and the ability of DNA to stimulate ATP hydrolysis. We discuss the mechanistic implications of these results.     

Sequence-specific DNA binding by the MspI DNA methyltransferase.

The MspI methyltransferase (M.MspI) recognizes the sequence CCGG and catalyzes the formation of 5-methylcytosine at the fist C-residue. We have investigated the sequence-specific DNA-binding properties of M.MspI under equilibrium conditions, using gel-mobility shift assays and DNasel footprinting. M.MspI binds to DNA in a sequence-specific manner either alone or in the presence of the normal methyl donor S-adenosyl-L-methionine as well as the analogues, sinefungin and S-adenosyl-L-homocysteine. In the presence of S-adenosyl-L-homocysteine, M.MspI shows the highest binding affinity to DNA containing a hemimethylated recognition sequence (Kd = 3.6 x 10(-7) M), but binds less well to unmethylated DNA (Kd = 8.3 x 10(-7) M). Surprisingly it shows specific, although poor, binding to fully methylated DNA (Kd = 4.2 x 10(-6) M). M.MspI binds approximately 5-fold more tightly to DNA containing its recognition sequence, CCGG, than to nonspecific sequences in the absence of cofactors. In the presence of S-adenosyl-L-methionine, S-adenosyl-L-homocysteine or sinefungin the discrimination between specific and non-specific sequences increases up to 100-fold. DNasel footprinting studies indicate that 16 base pairs of DNA are covered by M.MspI, with the recognition sequence CCGG located asymmetrically within the footprint.     

DNA polymerases that propagate the eukaryotic DNA replication fork

Three DNA polymerases are thought to function at the eukaryotic DNA replication fork. Currently, a coherent model has been derived for the composition and activities of the lagging strand machinery. RNA-DNA primers are initiated by DNA polymerase ot-primase. Loading of the proliferating cell nuclear antigen, PCNA, dissociates DNA polymerase ca and recruits DNA polymerase S and the flap endonuclease FEN1 for elongation and in preparation for its requirement during maturation, respectively. Nick translation by the strand displacement action of DNA polymerase 8, coupled with the nuclease action of FEN1, results in processive RNA degradation until a proper DNA nick is reached for closure by DNA ligase I. In the event of excessive strand displacement synthesis, other factors, such as the Dna2 nuclease/helicase, are required to trim excess flaps. Paradoxically, the composition and activity of the much simpler leading strand machinery has not been clearly established. The burden of evidence suggests that DNA polymerase E normally replicates this strand,but under conditions of dysfunction, DNA polymerase 8 may substitute.     

DNA–DNA kissing complexes as a new tool for the assembly of DNA nanostructures

Kissing-loop annealing of nucleic acids occurs in nature in several viruses and in prokaryotic replication, among other circumstances. Nucleobases of two nucleic acid strands (loops) interact with each other, although the two strands cannot wrap around each other completely because of the adjacent double-stranded regions (stems). In this study, we exploited DNA kissing-loop interaction for nanotechnological application. We functionalized the vertices of DNA tetrahedrons with DNA stem-loop sequences. The complementary loop sequence design allowed the hybridization of different tetrahedrons via kissing-loop interaction, which might be further exploited for nanotechnology applications like cargo transport and logical elements. Importantly, we were able to manipulate the stability of those kissing-loop complexes based on the choice and concentration of cations, the temperature and the number of complementary loops per tetrahedron either at the same or at different vertices. Moreover, variations in loop sequences allowed the characterization of necessary sequences within the loop as well as additional stability control of the kissing complexes. Therefore, the properties of the presented nanostructures make them an important tool for DNA nanotechnology.     

DNA gyrase-mediated wrapping of the DNA strand is required for the replication fork arrest by the DNA gyrase-quinolone-DNA ternary complex

The ability of DNA gyrase (Gyr) to wrap the DNA strand around itself allows Gyr to introduce negative supercoils into DNA molecules. It has been demonstrated that the deletion of the C-terminal DNA-binding domain of the GyrA subunit abolishes the ability of Gyr to wrap the DNA strand and catalyze the supercoiling reaction (Kampranis, S. C., and Maxwell, A. (1996) Proc. Natl. Acad. Sci. U. S. A. 93, 14416-14421). By using this mutant Gyr, Gyr (A59), we have studied effects of Gyr-mediated wrapping of the DNA strand on its replicative function and its interaction with the quinolone antibacterial drugs. We find that Gyr (A59) can support oriC DNA replication in vitro. However, Gyr (A59)-catalyzed decatenation activity is not efficient enough to complete the decatenation of replicating daughter DNA molecules. As is the case with topoisomerase IV, the active cleavage and reunion activity of Gyr is required for the formation of the ternary complex that can arrest replication fork progression in vitro. Although the quinolone drugs stimulate the covalent Gyr (A59)-DNA complex formation, the Gyr (A59)-quinolone-DNA ternary complexes do not arrest the progression of replication forks. Thus, the quinolone-induced covalent topoisomerase-DNA complex formation is necessary but not sufficient to cause the inhibition of DNA replication. We also assess the stability of ternary complexes formed with Gyr (A59), the wild type Gyr, or topoisomerase IV. The ternary complexes formed with Gyr (A59) are more sensitive to salt than those formed with either the wild type Gyr or topoisomerase IV. Furthermore, a competition experiment demonstrates that the ternary complexes formed with Gyr (A59) readily disassociate from the DNA, whereas the ternary complexes formed with either the wild type Gyr or topoisomerase IV remain stably bound. Thus, Gyr-mediated wrapping of the DNA strand is required for the formation of the stable Gyr-quinolone-DNA ternary complex that can arrest replication fork progression.     

DNA Motion Capture Reveals the Mechanical Properties of DNA at the Mesoscale

Single-molecule studies probing the end-to-end extension of long DNAs have established that the mechanical properties of DNA are well described by a wormlike chain force law, a polymer model where persistence length is the only adjustable parameter. We present a DNA motion-capture technique in which DNA molecules are labeled with fluorescent quantum dots at specific sites along the DNA contour and their positions are imaged. Tracking these positions in time allows us to characterize how segments within a long DNA are extended by flow and how fluctuations within the molecule are correlated. Utilizing a linear response theory of small fluctuations, we extract elastic forces for the different, ∼2-μm-long segments along the DNA backbone. We find that the average force-extension behavior of the segments can be well described by a wormlike chain force law with an anomalously small persistence length.     

Mechanistic details of the DNA recognition by the Dnmt1 DNA methyltransferase

A recently solved Dnmt1-DNA crystal structure revealed several enzyme-DNA contacts and large structural rearrangements of the DNA at the target site, including the flipping of the non-target strand base of the base pair flanking the CpG site and formation of a non-canonical base pair between the non-target strand Gua and the flanking base pair. Here, we show that the contacts of the enzyme to the target base and the Gua:5mC base pair that are observed in the structure are very important for catalytic activity. The contacts to the non-target strand Gua are not important since its exchange by Ade stimulated activity. Except target base flipping, we could not find evidence that the DNA rearrangements have a functional role.     

DNA:DNA hybridization studies on the pink-pigmented facultative methylotrophs

The genomic relatedness among 36 strains of pink-pigmented facultatively methylotrophic bacteria (PPFMs) was estimated by determination of DNA base composition and by DNA:DNA hybridization studies. A reproducible hybridization system was developed for the rapid analysis of multiple DNA samples. Results indicated that the PPFMs comprise four major and several minor homology groups, and that they should remain grouped in a single genus, Methylobacterium.     

Fidelity of DNA synthesis by the Thermus aquaticus DNA polymerase

We have determined the fidelity of in vitro DNA synthesis catalyzed at high temperature by the DNA polymerase from the thermophilic bacterium Thermus aquaticus. Using a DNA substrate that contains a 3'-OH terminal mismatch, we demonstrate that the purified polymerase lacks detectable exonucleolytic proofreading activity. The fidelity of the Taq polymerase was measured by two assays which score errors produced during in vitro DNA synthesis of the lacZ alpha complementation gene in M13mp2 DNA. In both assays, the Taq polymerase produces single-base substitution errors at a rate of 1 for each 9000 nucleotides polymerized. Frameshift errors are also produced, at a frequency of 1/41,000. These results are discussed in relation to the effects of high temperature on fidelity and the use of the Taq DNA polymerase as a reagent for the in vitro amplification of DNA by the polymerase chain reaction.     

DNA methylation reprogramming and DNA repair in the mouse zygote

Here, we summarize current knowledge about epigenetic reprogramming during mammalian preimplantation development, as well as the potential mechanisms driving these processes. We will particularly focus on changes taking place in the zygote, where the paternally derived DNA and chromatin undergo the most striking alterations, such as replacement of protamines by histones, histone modifications and active DNA demethylation. The putative mechanisms of active paternal DNA demethylation have been studied for over a decade, accumulating a lot of circumstantial evidence for enzymatic activities provided by the oocyte, protection of the maternal genome against such activities and possible involvement of DNA repair. We will discuss the various facets of dynamic epigenetic changes related to DNA methylation with an emphasis on the putative involvement of DNA repair in DNA demethylation.     

The DNA dependence of the ATPase activity of DNA gyrase

We have studied the ATPase activity of DNA gyrase both in the absence and presence of DNA. In the absence of DNA we show that the gyrase B protein alone has a very low level of ATPase activity which can be increased many-fold by pretreatment of the B protein with heat or urea. When both the gyrase A protein and linear DNA are also present, the ATPase activity of the untreated B protein is greatly stimulated. We find that the extent of stimulation is dependent upon the length of the DNA but largely independent of DNA sequence. DNA molecules greater than 100 base pairs in length are much more effective in stimulating the gyrase ATPase than those of 70 base pairs or less, although short DNA molecules will stimulate the ATPase at high concentrations. The behavior of long and short DNA molecules with respect to ATPase stimulation is also reflected in their abilities to bind DNA gyrase. To account for these data we propose a model for the interaction of gyrase with ATP and DNA in which ATP hydrolysis requires the binding of DNA to two sites on the enzyme.