Human HEL308 localizes to damaged replication forks and unwinds lagging strand structures

HEL308 is a superfamily II DNA helicase, conserved from archaea through to humans. HEL308 family members were originally isolated by their similarity to the Drosophila melanogaster Mus308 protein, which contributes to the repair of replication-blocking lesions such as DNA interstrand cross-links. Biochemical studies have established that human HEL308 is an ATP-dependent enzyme that unwinds DNA with a 3' to 5' polarity, but little else is know about its mechanism. Here, we show that GFP-tagged HEL308 localizes to replication forks following camptothecin treatment. Moreover, HEL308 colocalizes with two factors involved in the repair of damaged forks by homologous recombination, Rad51 and FANCD2. Purified HEL308 requires a 3' single-stranded DNA region to load and unwind duplex DNA structures. When incubated with substrates that model stalled replication forks, HEL308 preferentially unwinds the parental strands of a structure that models a fork with a nascent lagging strand, and the unwinding action of HEL308 is specifically stimulated by human replication protein A. Finally, we show that HEL308 appears to target and unwind from the junction between single-stranded to double-stranded DNA on model fork structures. Together, our results suggest that one role for HEL308 at sites of blocked replication might be to open up the parental strands to facilitate the loading of subsequent factors required for replication restart.     

急剧弯曲DNA柔韧性的研究进展

基因调控,核小体和病毒的包装行为都会涉及DNA的急剧弯曲成环。DNA分子的环化是研究其本身柔韧性的主要方法。目前已经发展出很多研究DNA环化的模型,其中WLC(worm-likechain)模型较为成熟。近年来,在DNA环化的重要参数、影响因素以及DNA急剧弯曲成环的理论研究等诸多方面都有了新进展。     

Simultaneous assessment of average fragment size and amount in minute samples of degraded DNA

There is currently no method allowing routine characterization of minute amounts of degraded DNA samples such as those encountered in forensic science, archived tissues, ancient DNA, extracellular or stool DNA, and processed food. Here we describe and directly validate such a method based, on the one hand, on a generalized DNA random fragmentation model and, on the other, on two quantitative polymerase chain reaction (PCR) experiments using two different target sizes. The model also makes it possible to determine the minimum sample amount, the minimum mass average fragment size, and the maximum degradation time necessary to obtain a positive PCR.     

Human DNA polymerase beta mutations allowing efficient abasic site bypass

The DNA of every cell in the human body gets damaged more than 50,000 times a day. The most frequent damages are abasic sites. This kind of damage blocks proceeding DNA synthesis by several DNA polymerases that are involved in DNA replication and repair. The mechanistic basis for the incapability of these DNA polymerases to bypass abasic sites is not clarified. To gain insights into the mechanistic basis, we intended to identify amino acid residues that govern for the pausing of DNA polymerase β when incorporating a nucleotide opposite to abasic sites. Human DNA polymerase β was chosen because it is a well characterized DNA polymerase and serves as model enzyme for studies of DNA polymerase mechanisms. Moreover, it acts as the main gap-filling enzyme in base excision repair, and human tumor studies suggest a link between DNA polymerase β and cancer. In this study we employed high throughput screening of a library of more than 11,000 human DNA polymerase β variants. We identified two mutants that have increased ability to incorporate a nucleotide opposite to an abasic site. We found that the substitutions E232K and T233I promote incorporation opposite the lesion. In addition to this feature, the variants have an increased activity and a lower fidelity when processing nondamaged DNA. The mutations described in this work are located in well characterized regions but have not been reported before. A crystallographic structure of one of the mutants was obtained, providing structural insights.     

基于一种紧束缚模型的DNA电性质分析

DNA的电学性质关系到生命信息静态的存储和动态的释放,因此一直备受关注。在一种紧束缚模型的基础上,研究了DNA的电传输性质,并分析了DNA的导电性的生物意义。在特定的传导距离下,可以利用导电性来分辨基因所在的编码区。     

Multiple DNA binding domains mediate the function of the ERCC1-XPF protein in nucleotide excision repair

ERCC1-XPF is a heterodimeric, structure-specific endonuclease that cleaves single-stranded/double-stranded DNA junctions and has roles in nucleotide excision repair (NER), interstrand crosslink (ICL) repair, homologous recombination, and possibly other pathways. In NER, ERCC1-XPF is recruited to DNA lesions by interaction with XPA and incises the DNA 5' to the lesion. We studied the role of the four C-terminal DNA binding domains in mediating NER activity and cleavage of model substrates. We found that mutations in the helix-hairpin-helix domain of ERCC1 and the nuclease domain of XPF abolished cleavage activity on model substrates. Interestingly, mutations in multiple DNA binding domains were needed to significantly diminish NER activity in vitro and in vivo, suggesting that interactions with proteins in the NER incision complex can compensate for some defects in DNA binding. Mutations in DNA binding domains of ERCC1-XPF render cells more sensitive to the crosslinking agent mitomycin C than to ultraviolet radiation, suggesting that the ICL repair function of ERCC1-XPF requires tighter substrate binding than NER. Our studies show that multiple domains of ERCC1-XPF contribute to substrate binding, and are consistent with models of NER suggesting that multiple weak protein-DNA and protein-protein interactions drive progression through the pathway. Our findings are discussed in the context of structural studies of individual domains of ERCC1-XPF and of its role in multiple DNA repair pathways.     

DNA芯片在0-1规划问题中的应用

生物芯片技术和DNA计算分别是近年来生命科学与信息科学的新兴研究领域,对信息高度并行的获取与处理是二者的本质特性.而0-1规划问题作为运筹学中一个重要的问题,到目前为止还没有好的算法.在DNA计算和DNA芯片基础上,提出了基于DNA芯片解决0-1规划问题的DNA计算新模型,与以往DNA计算模型相比,该模型具有高信息量和操作易自动化的优点.同时指出DNA芯片技术有望作为新型生物计算的芯片.     

Synergic and Opposing Activities of Thermophilic RecQ-like Helicase and Topoisomerase 3 Proteins in Holliday Junction Processing and Replication Fork Stabilization

RecQ family helicases and topoisomerase 3 enzymes form evolutionary conserved complexes that play essential functions in DNA replication, recombination, and repair, and in vitro, show coordinate activities on model recombination and replication intermediates. Malfunctioning of these complexes in humans is associated with genomic instability and cancer-prone syndromes. Although both RecQ-like and topoisomerase 3 enzymes are present in archaea, only a few of them have been studied, and no information about their functional interaction is available. We tested the combined activities of the RecQ-like helicase, Hel112, and the topoisomerase 3, SsTop3, from the thermophilic archaeon Sulfolobus solfataricus. Hel112 showed coordinate DNA unwinding and annealing activities, a feature shared by eukaryotic RecQ homologs, which resulted in processing of synthetic Holliday junctions and stabilization of model replication forks. SsTop3 catalyzed DNA relaxation and annealing. When assayed in combination, SsTop3 inhibited the Hel112 helicase activity on Holliday junctions and stimulated formation and stabilization of such structures. In contrast, Hel112 did not affect the SsTop3 DNA relaxation activity. RecQ-topoisomerase 3 complexes show structural similarity with the thermophile-specific enzyme reverse gyrase, which catalyzes positive supercoiling of DNA and was suggested to play a role in genome stability at high temperature. Despite such similarity and the high temperature of reaction, the SsTop3-Hel112 complex does not induce positive supercoiling and is thus likely to play different roles. We propose that the interplay between Hel112 and SsTop3 might regulate the equilibrium between recombination and anti-recombination activities at replication forks.     

Multiple functions of DNA polymerases

The primary role of DNA polymerases is to accurately and efficiently replicate the genome in order to ensure the maintenance of the genetic information and its faithful transmission through generations. This is not a simple task considering the size of the genome and its constant exposure to endogenous and environmental DNA damaging agents. Thus, a number of DNA repair pathways operate in cells to protect the integrity of the genome. In addition to their role in replication, DNA polymerases play a central role in most of these pathways. Given the multitude and the complexity of DNA transactions that depend on DNA polymerase activity, it is not surprising that cells in all organisms contain multiple highly specialized DNA polymerases, the majority of which have only recently been discovered. Five DNA polymerases are now recognized in Escherichia coli, 8 in Saccharomyces cerevisiae, and at least 15 in humans. While polymerases in bacteria, yeast and mammalian cells have been extensively studied much less is known about their counterparts in plants. For example, the plant model organism Arabidopsis thaliana is thought to contain 12 DNA polymerases, whose functions are mostly unknown. Here we review the properties and functions of DNA polymerases focusing on yeast and mammalian cells but paying special attention to the plant enzymes and the special circumstances of replication and repair in plant cells.     

Dissecting the DNA damage response using functional genomics approaches in S. cerevisiae

The faithful transmission of genetic information from a mother to daughter cells can only occur if the integrity of the genome is preserved. DNA transactions within cells are tightly regulated to prevent DNA damage. When events that challenge genome integrity do occur, a complex web of DNA damage response pathways comes into play. Studies in model organisms have contributed significantly to the understanding of these pathways. In the last decade, the development of functional genomics techniques in S.cerevisiae has ushered in systematic approaches for the study of complex cellular processes. These methods have enabled the systematic interrogation of the DNA damage response.     

Methylcytosine and Normal Cytosine Deamination by the Foreign DNA Restriction Enzyme APOBEC3A

Multiple studies have indicated that the TET oxidases and, more controversially, the activation-induced cytidine deaminase/APOBEC deaminases have the capacity to convert genomic DNA 5-methylcytosine (MeC) into altered nucleobases that provoke excision repair and culminate in the replacement of the original MeC with a normal cytosine (C). We show that human APOBEC3A (A3A) efficiently deaminates both MeC to thymine (T) and normal C to uracil (U) in single-stranded DNA substrates. In comparison, the related enzyme APOBEC3G (A3G) has undetectable MeC to T activity and 10-fold less C to U activity. Upon 100-fold induction of endogenous A3A by interferon, the MeC status of bulk chromosomal DNA is unaltered, whereas both MeC and C nucleobases in transfected plasmid DNA substrates are highly susceptible to editing. Knockdown experiments show that endogenous A3A is the source of both of these cellular DNA deaminase activities. This is the first evidence for nonchromosomal DNA MeC to T editing in human cells. These biochemical and cellular data combine to suggest a model in which the expanded substrate versatility of A3A may be an evolutionary adaptation that occurred to fortify its innate immune function in foreign DNA clearance by myeloid lineage cell types.     

The Fanconi anemia/BRCA pathway: a coordinator of cross-link repair

Fanconi anemia (FA) is a rare inherited disease characterized by genomic instability and markedly increased cancer risk. Efforts to elucidate the molecular basis of FA have unearthed a novel DNA damage response pathway, the integrity of which is critical for cellular resistance to DNA cross-linking agents. Despite significant progress in uncovering the molecular events underlying FA, the precise function of this pathway in DNA repair is unknown. This article will review evidence implicating FA proteins in multiple aspects of DNA cross-link repair and propose a model to explain the selectivity of the FA pathway toward DNA cross-linking agents.     

Model for forward polymerization and switching transition between polymerase and exonuclease sites by DNA polymerase molecular motors

Based on the available crystal structure a model is presented for the polymerization activity and switching transition between polymerase and exonuclease sites of a DNA polymerase molecular motor. Using the model, the fast polymerization rate for correctly base-paired DNA and much reduced polymerization rate after an incorporation of a mismatched base can be well explained. The dependences of the polymerization rate and exonuclease rate on mechanical tension acting on the DNA template are studied. The switching rates between the two sites are analyzed. All the results show good quantitative agreement with the available experimental results.     

Mechanisms of activation of the RAW264.7 macrophage cell line by transfected mammalian DNA

Bacterial DNA can stimulate the production of cytokines and nitric oxide (NO), while mammalian DNA can block these responses. If mammalian DNA is transfected into macrophages, however, it can stimulate NO production, without inducing IL-12. To define further this activity, signaling pathways induced by transfected calf thymus (CT) DNA were studied. Using RAW264.7 cells as a model, CT DNA in the transfection agent FuGENE 6 activated cells through the NF-kappaB and MAPKs pathways, similar to bacterial DNA and LPS. The role of these pathways was further investigated using specific inhibitors, with studies indicating that NO production is blocked by inhibitors of NF-kappaB and p38 but not other MAPKs. These data indicate that the immune activity of DNA is influenced by context or intracellular location and that, when transfected into cells, mammalian DNA can activate cells through signaling pathways similar to those of bacterial DNA.     

The repair rate of radiation-induced DNA damage: a stochastic interpretation based on the gamma function

There is a large body of evidence that stress-induced DNA damage may be responsible for cell lethality, cancer proneness and/or immune reaction. However, statistical features of their repair rate remain poorly documented. In order to interpret the shape of the radiation-induced DNA damage repair curves with a minimum of biological assumptions, we introduced the concept of repair probability, specific to any individual radiation-induced DNA damage, whatever its biochemical type. We strengthened the apparent paradox that the repair rate of a population of DNA damage is time-dependent even if the repair rate of the individual DNA damage is constant. Hence, the existing models, based on a dual approach of the DNA repair may be insufficient for describing the DNA repair rate over a large range of repair times. Since the repair probability of DNA damage cannot be assessed individually, the measurement of the DNA repair rate is assumed to consist in determining the instantaneous mean of all repair probabilities. The relevance of this model was examined with different endpoints: cell species, genotypes, radiation type and chromatin condensation. The Euler's Gamma function was shown to provide the distribution the most consistent with such hypotheses. Furthermore, formulas, deduced from the Gamma distribution, were found to be compatible with our previous model, empirically defined but based on a variable repair half-time.     

Bacteriophage lambda terminase: alterations of the high-affinity ATPase affect viral DNA packaging

DNA packaging by large DNA viruses such as the tailed bacteriophages and the herpesviruses involves DNA translocation into a preformed protein shell, called the prohead. Translocation is driven by an ATP hydrolysis-powered DNA packaging motor. The bacteriophages encode a heterodimeric viral DNA packaging protein, called terminase. The terminases have an ATPase center located in the N terminus of the large subunit implicated in DNA translocation. In previous work with phage lambda, lethal mutations that changed ATP-reactive residues 46 and 84 of gpA, the large terminase subunit, were studied. These mutant enzymes retained the terminase endonuclease and helicase activities, but had severe defects in virion assembly, and lacked the terminase high-affinity ATPase activity. Surprisingly, in the work described here, we found that enzymes with the conservative gpA changes Y46F and Y46A had only mild packaging defects. These mild defects contrast with their profound virion assembly defects. Thus, these mutant enzymes have, in addition to the mild DNA packaging defects, a severe post-DNA packaging defect. In contrast, the gpA K84A enzyme had similar virion assembly and DNA packaging defects. The DNA packaging energy budget, i.e. DNA packaged/ATP hydrolyzed, was unchanged for the mutant enzymes, indicating that DNA translocation is tightly coupled to ATP hydrolysis. A model is proposed in which gpA residues 46 and 84 are important for terminase's high-affinity ATPase activity. Assembly of the translocation complex remodels this ATPase so that residues 46 and 84 are not crucial for the activated translocation ATPase. Changing gpA residues 46 and 84 primarily affects assembly, rather than the activity, of the translocation complex.     

A DNA assembly model of sentence generation

Recent results of corpus-based linguistics demonstrate that context-appropriate sentences can be generated by a stochastic constraint satisfaction process. Exploiting the similarity of constraint satisfaction and DNA self-assembly, we explore a DNA assembly model of sentence generation. The words and phrases in a language corpus are encoded as DNA molecules to build a language model of the corpus. Given a seed word, the new sentences are constructed by a parallel DNA assembly process based on the probability distribution of the word and phrase molecules. Here, we present our DNA code word design and report on successful demonstration of their feasibility in wet DNA experiments of a small scale.