Structure,Function, and Mechanism of HhaI DNA Methyltransferases

A vast amount of literature has accumulated on the characterization of DNA methyltransferases. The HhaI DNA methyltransferase, a C5-cytosine methyltransferase, has been the subject of investigation for the last 2 decades. Biochemical and kinetic characterization have led to an understanding of the catalytic and kinetic mechanism of the methyltransfer reaction. The HhaI methyltransferase has also been subjected to extensive structural analysis, with the availability of 12 structures with or without a cofactor and a variety of DNA substrates. The mechanism of base flipping, first described for the HhaI methyltransferase, is conserved among all DNA methyltransferases and is also found to occur in numerous DNA repair enzymes. Studies with other methyltransferase reveal a significant structural and functional similarity among different types of methyltransferases. This review aims to summarize the available information on the HhaI DNA methyltransferase.     

大肠杆菌细胞DNA复制、修复和重组途径的衔接

以大肠杆菌为例围绕相关领域的研究动态进行分析和总结.DNA复制、损伤修复和重组过程的相互作用关系研究是当今生命科学研究的前沿和热点之一.越来越多的研究表明,在分子水平上,DNA复制、损伤修复和重组过程既彼此独立,又相互依存.上述途径可以通过许多关键蛋白质之间的相互作用加以协调和整合,并籍此使遗传物质DNA得到有效的维护和忠实的传递.需要指出的是,基于许多细胞内关键蛋白及其功能在生物界中普遍保守性的事实,相信来自大肠杆菌有关DNA复制、修复和重组之间的研究成果也会对相关真核生物的研究提供借鉴.     

The alpha/beta fold uracil DNA glycosylases: a common origin with diverse fates

Background  

Uracil DNA glycosylases (UDGs) are major repair enzymes that protect DNA from mutational damage caused by uracil incorporated as a result of a polymerase error or deamination of cytosine. Four distinct families of UDGs have been identified, which show very limited sequence similarity to each other, although two of them have been shown to possess the same structural fold. The structural and evolutionary relationships between the rest of the UDGs remain uncertain.     

Instability of inhibited replication forks in E. coli

Inhibiting the progress of replication forks in E. coli makes them susceptible to breakage. Broken replication forks are evidently reassembled by the RecBCD recombinational repair pathway. These findings explain a particular pattern of DNA degradation during inhibition of chromosomal replication, the role of recombination in the viability of mutants with displaced replication origin, and hyper-recombination observed in the Terminus of the E. coli chromosome in rnh mutants. Breakage and repair of inhibited replication forks could be the reason for the recombination-dependence of inducible stable DNA replication. A mechanism by which RecABCD-dependent recombination between very short inverted repeats may help E. coli to invert an operon, transcribed in the direction opposite to that of DNA replication, is discussed.     

Enzymes involved in DNA ligation and end-healing in the radioresistant bacterium <Emphasis Type="Italic">Deinococcus radiodurans</Emphasis>

Background  

Enzymes involved in DNA metabolic events of the highly radioresistant bacterium Deinococcus radiodurans are currently examined to understand the mechanisms that protect and repair the Deinococcus radiodurans genome after extremely high doses of γ-irradiation. Although several Deinococcus radiodurans DNA repair enzymes have been characterised, no biochemical data is available for DNA ligation and DNA endhealing enzymes of Deinococcus radiodurans so far. DNA ligases are necessary to seal broken DNA backbones during replication, repair and recombination. In addition, ionizing radiation frequently leaves DNA strand-breaks that are not feasible for ligation and thus require end-healing by a 5'-polynucleotide kinase or a 3'-phosphatase. We expect that DNA ligases and end-processing enzymes play an important role in Deinococcus radiodurans DNA strand-break repair.     

Lambda Red Mediated Gap Repair Utilizes a Novel Replicative Intermediate in Escherichia coli

The lambda phage Red recombination system can mediate efficient homologous recombination in Escherichia coli, which is the basis of the DNA engineering technique termed recombineering. Red mediated insertion of DNA requires DNA replication, involves a single-stranded DNA intermediate and is more efficient on the lagging strand of the replication fork. Lagging strand recombination has also been postulated to explain the Red mediated repair of gapped plasmids by an Okazaki fragment gap filling model. Here, we demonstrate that gap repair involves a different strand independent mechanism. Gap repair assays examining the strand asymmetry of recombination did not show a lagging strand bias. Directly testing an ssDNA plasmid showed lagging strand recombination is possible but dsDNA plasmids did not employ this mechanism. Insertional recombination combined with gap repair also did not demonstrate preferential lagging strand bias, supporting a different gap repair mechanism. The predominant recombination route involved concerted insertion and subcloning though other routes also operated at lower frequencies. Simultaneous insertion of DNA resulted in modification of both strands and was unaffected by mutations to DNA polymerase I, responsible for Okazaki fragment maturation. The lower efficiency of an alternate Red mediated ends-in recombination pathway and the apparent lack of a Holliday junction intermediate suggested that gap repair does not involve a different Red recombination pathway. Our results may be explained by a novel replicative intermediate in gap repair that does not involve a replication fork. We exploited these observations by developing a new recombineering application based on concerted insertion and gap repair, termed SPI (subcloning plus insertion). SPI selected against empty vector background and selected for correct gap repair recombinants. We used SPI to simultaneously insert up to four different gene cassettes in a single recombineering reaction. Consequently, our findings have important implications for the understanding of E. coli replication and Red recombination.     

Reconstitution of the DNA base excision—repair pathway

Background: The base excision–repair pathway is the major cellular defence mechanism against spontaneous DNA damage. The enzymes involved have been highly conserved during evolution. Base excision–repair has been reproduced previously with crude cell-free extracts of bacterial or human origin. To further our understanding of base excision–repair, we have attempted to reconstitute the pathway in vitro using purified enzymes.Results We report here the successful reconstitution of the base excision–repair pathway with five purified enzymes from Escherichia coli: uracil-DNA glycosylase, a representative of the DNA glycosylases that remove various lesions from DNA; the AP endonuclease IV that specifically cleaves at abasic sites; RecJ protein which excises a 5′ terminal deoxyribose-phosphate residue; DNA polymerase I; and DNA ligase. The reaction proceeds with high efficiency in the absence of additional factors in the reconstituted system. Four of the enzymes are absolutely required for completion of the repair reaction. An unusual feature we have discovered is that the pathway branches after enzymatic incision at an abasic DNA site. RecJ protein is required for the major reaction, which involves replacement of only a single nucleotide at the damaged site; in its absence, an alternative pathway is observed, with generation of longer repair patches by the 5′ nuclease function of DNA polymerase I.Conclusion Repair of uracil in DNA is achieved by a very short-patch excision–repair process involving five different enzymes. No additional protein factors seem to be required. There is a minor, back-up pathway that uses replication factors to generate longer repair patches.     

Multiplex Gene Disruption by Targeted Base Editing of Yarrowia lipolytica Genome Using Cytidine Deaminase Combined with the CRISPR/Cas9 System

The oleaginous yeast Yarrowia lipolytica has a tendency to use the non‐homologous end joining repair (NHEJ) over the homology directed recombination as double‐strand breaks (DSB) repair system, making it difficult to edit the genome using homologous recombination. A recently developed Target‐AID (activation‐induced cytidine deaminase) base editor, designed to recruit cytidine deaminase (CDA) to the target DNA locus via the CRISPR/Cas9 system, can directly induce C to T mutation without DSB and donor DNA. In this study, this system is adopted in Y. lipolytica for multiplex gene disruption. Target‐specific gRNA(s) and a fusion protein consisting of a nickase Cas9, pmCDA1, and uracil DNA glycosylase inhibitor are expressed from a single plasmid to disrupt target genes by introducing a stop codon via C to T mutation within the mutational window. Deletion of the KU70 gene involved in the NHEJ prevents the generation of indels by base excision repair following cytidine deamination, increasing the accuracy of genome editing. Using this Target‐AID system with optimized expression levels of the base editor, single gene disruption and simultaneous double gene disruption are achieved with the efficiencies up to 94% and 31%, respectively, demonstrating this base editing system as a convenient genome editing tool in Y. lipolytica.     

Mismatch repair in mammalian cells

A vital process in maintaining a low genetic error rate is the removal of mismatched bases in DNA. The importance of this process in E. coli is demonstrated by the 100–1000 fold increase in mutation frequency observed in cells deficient in this repair system⁽¹⁾. Mismatches can arise as a consequence of recombination, errors in replication and as a result of spontaneous chemical deamination, the latter process resulting in an estimated twelve T:G mismatches per genome per day in mammalian cells⁽²⁾. Recent studies, discussed here, provide evidence for the existence of specific mismatch repair systems in mammalian and human cells.     

Mammalian DNA ligases

DNA joining enzymes play an essential role in the maintenance of genomic integrity and stability. Three mammalian genes encoding DNA ligases, LIG1, LIG3 and LIG4, have been identified. Since DNA ligase II appears to be derived from DNA ligase III by a proteolytic mechanism, the three LIG genes can account for the four biochemically distinct DNA ligase activities, DNA ligases I, II, III and IV, that have been purified from mammalian cell extracts. It is probable that the specific cellular roles of these enzymes are determined by the proteins with which they interact. The specific involvement of DNA ligase I in DNA replication is mediated by the non-catalytic amino-terminal domain of this enzyme. Furthermore, DNA ligase I participates in DNA base excision repair as a component of a multiprotein complex. Two forms of DNA ligase III are produced by an alternative splicing mechanism. The ubiqitously expressed DNA ligase III-α forms a complex with the DNA single-strand break repair protein XRCC1. In contrast, DNA ligase III-β, which does not interact with XRCC1, is only expressed in male meiotic germ cells, suggesting a role for this isoform in meiotic recombination. At present, there is very little information about the cellular functions of DNA ligase IV.     

DNA helicase mutants of bacteriophage T4 that are defective in DNA recombination

We previously isolated a plasmid-borne, recombination-deficient mutant derivative of the bacteriophage T4 DNA helicase gene 41. We have now transferred this 41rrh1 mutation into the phage genome in order to characterize its mutational effects further. The mutation impairs a recombination pathway that is distinct from the pathway involving uvsX, which is essential for strand transfer, and it also eliminates most homologous recombination between a plasmid and the T4 genome. Although 41rrh1 does not affect T4 DNA replication from some origins, it does inactivate plasmid replication that is dependent on ori(uvsY) and ori(34), as well as recombination-dependent DNA replication. Combination of 41rrh1 with some uvsX alleles is lethal. Based on these results, we propose that gene 41 contributes to DNA recombination through its role in DNA replication. Received: 3 February 1999 / Accepted: 20 July 1999     

Presynaptic filament dynamics in homologous recombination and DNA repair

Homologous recombination (HR) is an essential genome stability mechanism used for high-fidelity repair of DNA double-strand breaks and for the recovery of stalled or collapsed DNA replication forks. The crucial homology search and DNA strand exchange steps of HR are catalyzed by presynaptic filaments—helical filaments of a recombinase enzyme bound to single-stranded DNA (ssDNA). Presynaptic filaments are fundamentally dynamic structures, the assembly, catalytic turnover, and disassembly of which must be closely coordinated with other elements of the DNA recombination, repair, and replication machinery in order for genome maintenance functions to be effective. Here, we reviewed the major dynamic elements controlling the assembly, activity, and disassembly of presynaptic filaments; some intrinsic such as recombinase ATP-binding and hydrolytic activities, others extrinsic such as ssDNA-binding proteins, mediator proteins, and DNA motor proteins. We examined dynamic behavior on multiple levels, including atomic- and filament-level structural changes associated with ATP binding and hydrolysis as evidenced in crystal structures, as well as subunit binding and dissociation events driven by intrinsic and extrinsic factors. We examined the biochemical properties of recombination proteins from four model systems (T4 phage, Escherichia coli, Saccharomyces cerevisiae, and Homo sapiens), demonstrating how their properties are tailored for the context-specific requirements in these diverse species. We proposed that the presynaptic filament has evolved to rely on multiple external factors for increased multilevel regulation of HR processes in genomes with greater structural and sequence complexity.     

Mutational bias suggests that replication termination occurs near the dif site, not at Ter sites

In bacteria, Ter sites bound to Tus/Rtp proteins halt replication forks moving only in one direction, providing a convenient mechanism to terminate them once the chromosome had been replicated. Considering the importance of replication termination and its position as a checkpoint in cell division, the accumulated knowledge on these systems has not dispelled fundamental questions regarding its role in cell biology: why are there so many copies of Ter, why are they distributed over such a large portion of the chromosome, why is the tus gene not conserved among bacteria, and why do tus mutants lack measurable phenotypes? Here we examine bacterial genomes using bioinformatics techniques to identify the region(s) where DNA polymerase III‐mediated replication has historically been terminated. We find that in both Escherichia coli and Bacillus subtilis, changes in mutational bias patterns indicate that replication termination most likely occurs at or near the dif site. More importantly, there is no evidence from mutational bias signatures that replication forks originating at oriC have terminated at Ter sites. We propose that Ter sites participate in halting replication forks originating from DNA repair events, and not those originating at the chromosomal origin of replication.