Sequence-specific endonucleases in strains of Anabaena and Nostoc

The complements of restriction endonucleases of 12 strains of cyanobacteria were determined in cell-free extracts, and were compared with the complements of restriction activities assessed by measuring the relative efficiencies of plating of cyanophages on those cyanobacteria. The hosts which were susceptible to all of the phages contained endo R · AvaI and endo R · AvaII, and in several cases probably endo R · AvaIII, or isoschizomers of these enzymes. Three hosts which were lysed by only a subset (1 or 3) of the phages contained different restriction endonuclease. Anabaena sp. PCC 7120 showed apparent phenotypic restriction of phage An-22 grown in hosts with (isoschizomers of) AvaI, II and III, but no corresponding endonuclease has yet been detected in vitro. Nostoc sp. ATCC 29131 (PCC 6705) was found to contain a restriction enzyme, NspBII, with hitherot unknown specificity, C(A/C)GC(T/G)G.     

Multi-site-specific endonucleases and the initiation of homologous genetic recombination in yeast

The notion that homologous recombination is a regulated biological process is not a familiar one. In yeasts, homologous recombination and most site-specific ones are initiated by site-specific double-stranded breaks that are introduced within cis-acting elements for the recombination. On the other hand, yeasts have a group of site-specific endonucleases (multi-site-specific endonucleases) that have a number of cleavage sites on each DNA. One of them, Endo.SceI of S. cerevisiae, was shown to introduce double-stranded breaks at a number of welldefined sites on the mitochondrial DNA in vivo. An Endo.SceI-induced double-stranded break was demonstrated to induce homologous recombination in mitochondria. Like the case of homologous recombination of nuclear chromosomes, the double-stranded break induces gene conversion of both genetic markers flanking and in the proximity of the cleavage site, and the cleaved DNA acts as a recipient of genetic information from the uncleaved partner DNA. The 70 kDa-heat-shock protein (HSP70)-subunit of Endo.SceI and a general role of the HSP70 in the regulation of protein-folding suggest the regulation of nucleolytic activity of Endo.SceI.     

Sequence-specific responses of restriction endonucleases to bromodeoxyuridine substitution in mammalian DNA

Substitution of BrdU for dT in mammalian DNA alters the rates of DNA cleavage by restriction endonucleases in a manner that can be related to the specificity of cleavage. A formula is proposed that describes inhibitory and stimulatory contributions arising from the substitution of a Br atom for the CH3 group on T. The larger Br atom is postulated to sterically hinder the nuclease from binding to adjacent groups in the DNA cleavage site, while allowing a tighter binding to itself. The inhibition caused by steric hindrance is predicted to vary inversely with distance from the point of cleavage, whereas the stimulation caused by tighter binding is predicted to be independent of distance. The resultant formula gives a good fit to the data obtained for thirteen different restriction nucleases of known specificity. The parameters in the formula appear to be simple functions of ionic strength. This formula can be used to predict the effect of BrdU substitution on any endonuclease whose specificity of cleavage is known.     

Mitochondrial-encoded endonucleases drive recombination of protein-coding genes in yeast

Mitochondrial recombination in yeast is well recognized, yet the underlying genetic mechanisms are not well understood. Recent progress has suggested that mobile introns in mitochondrial genomes (mitogenomes) can facilitate the recombination of their corresponding intron-containing genes through a mechanism known as intron homing. As many mitochondrial genes lack introns, there is a critical need to determine the extent of recombination and underlying mechanism of intron-lacking genes. This study leverages yeast mitogenomes to address these questions. In Saccharomyces cerevisiae, the 3′-end sequences of at least three intron-lacking mitochondrial genes exhibit elevated nucleotide diversity and recombination hotspots. Each of these 3′-end sequences is immediately adjacent to or even fused as overlapping genes with a stand-alone endonuclease. Our findings suggest that SAEs are responsible for recombination and elevated diversity of adjacent intron-lacking genes. SAEs were also evident to drive recombination of intron-lacking genes in Lachancea kluyveri, a yeast species that diverged from S. cerevisiae more than 100 million years ago. These results suggest SAEs as a common driver in recombination of intron-lacking genes during mitogenome evolution. We postulate that the linkage between intron-lacking gene and its adjacent endonuclease gene is the result of co-evolution.     

tRNA核酸内切酶的研究进展

tRNA在蛋白质合成过程中起着极其重要的作用。在所有的生物体内,tRNA首先以前体形式转录,然后必需经过一系列的加工后才能成为有功能的tRNA分子。tRNaseZ、RNaseP和tRNA剪接内切酶是参与tRNA前体加工的三种主要的核酸内切酶,分别参与tRNA前体3′末端、tRNA前体5′末端和内含子剪接的加工。这三种酶具有不同的结构特征,并且利用完全不同的催化机制水解磷酸二酯键。tRNaseZ和RNaseP都是金属酶,活性中心分别需要Zn^2＋和Mg^2＋的参与;而tRNA剪接内切酶活性中心不需要金属离子,是一个由不同催化亚基上的关键氨基酸残基构成的组合式活性中心。     

Protein-DNA interactions in genetic recombination

The formation of DNA-protein complexes that are capable of interaction with other DNA molecules is necessary for efficient genetic recombination. How do such complexes form, and how are homologous DNA sequences brought into alignment? Physical and biochemical studies of recombination enzymes from bacteria indicate that these proteins provide the structural framework within which the genetic exchanges occur.     

Processing of joint molecule intermediates by structure-selective endonucleases during homologous recombination in eukaryotes

Homologous recombination is required for maintaining genomic integrity by functioning in high-fidelity repair of DNA double-strand breaks and other complex lesions, replication fork support, and meiotic chromosome segregation. Joint DNA molecules are key intermediates in recombination and their differential processing determines whether the genetic outcome is a crossover or non-crossover event. The Holliday model of recombination highlights the resolution of four-way DNA joint molecules, termed Holliday junctions, and the bacterial Holliday junction resolvase RuvC set the paradigm for the mechanism of crossover formation. In eukaryotes, much effort has been invested in identifying the eukaryotic equivalent of bacterial RuvC, leading to the discovery of a number of DNA endonucleases, including Mus81?CMms4/EME1, Slx1?CSlx4/BTBD12/MUS312, XPF?CERCC1, and Yen1/GEN1. These nucleases exert different selectivity for various DNA joint molecules, including Holliday junctions. Their mutant phenotypes and distinct species-specific characteristics expose a surprisingly complex system of joint molecule processing. In an attempt to reconcile the biochemical and genetic data, we propose that nicked junctions constitute important in vivo recombination intermediates whose processing determines the efficiency and outcome (crossover/non-crossover) of homologous recombination.     

RecA-DNA helical filaments in genetic recombination

Paul Howard-Flanders et al proposed a molecular model of RecA-mediated recombination reaction six years ago. How does this model stand at present? In answering this question, we focus on two leading ideas of the original model, namely the proposal of the coaxial arrangement of the aligned DNA molecules within helical RecA filaments and the proposal of the ATP independence of the pairing stage of the recombination reaction. Results obtained after the model was proposed are reviewed and compared with these original assumptions and postulates of the model. EM visualization of recombining DNA molecules, studies of the energetics of the RecA-mediated recombination reaction and biochemical analysis of deproteinized joint molecules are fully consistent with a triple-stranded DNA arrangement during the RecA-mediated recombination reaction and demonstrate the ATP independence of the pairing stage of the reaction.     

AtRAD1, a plant homologue of human and yeast nucleotide excision repair endonucleases, is involved in dark repair of UV damages and recombination

Plants are unique in the obligatory nature of their exposure to sunlight and consequently to ultraviolet (UV) irradiation. However, our understanding of plant DNA repair processes lags far behind the current knowledge of repair mechanisms in microbes, yeast and mammals, especially concerning the universally conserved and versatile dark repair pathway called nucleotide excision repair (NER). Here we report the isolation and functional characterization of Arabidopsis thaliana AtRAD1, which encodes the plant homologue of Saccharomyces cerevisiae RAD1, Schizosaccharomyces pombe RAD16 and human XPF, endonucleolytic enzymes involved in DNA repair and recombination processes. Our results indicate that AtRAD1 is involved in the excision of UV-induced damages, and allow us to assign, for the first time in plants, the dark repair of such DNA lesions to NER. The low efficiency of this repair mechanism, coupled to the fact that AtRAD1 is ubiquitously expressed including tissues that are not accessible to UV light, suggests that plant NER has other roles. Possible 'UV-independent' functions of NER are discussed with respect to features that are particular to plants.     

In vivo biochemistry: Physical monitoring of recombination induced by site-specific endonucleases

The recombinational repair of chromosomal double-strand breaks (DSBs) is of critical importance to all organisms, who devote considerable genetic resources to ensuring such repair is accomplished. In Saccharomyces cerevisiae, DSB-mediated recombination can be initiated synchronously by the conditional expression of two site-specific endonucleases, HO or I-Scel. DNA undergoing recombination can then be extracted at intervals and analyzed. Recombination initiated by meiotic-specific DSBs can be followed in a similar fashion. This type of ‘in vivo biochemistry’ has been used to describe several discrete steps in two different homologous recombination pathways: gene conversion and single-strand annealing. The roles of specific proteins during recombination can be established by examining DNA in strains deleted for the corresponding gene. These same approaches are now becoming available for the study of recombination in both higher plants and animals. Physical monitoring can also be used to analyze nonhomologous recombination events, whose mechanisms appear to be conserved from yeast to mammals.     

Biochemical and genetic properties of site-specific restriction endonucleases in Bacillus globigii

Bacillus globigii contains two site-specific endonucleases, BPGLI AND BglI. A rapid technique for selection of mutants deficient in each of these enzymes was developed using sensitivity to infection by bacteriophage SP50 as an indication of the levels of enzyme. Mutants defective in BglI, BglII, and both BglI and BglII retained the wild-type modification phenotype. Genetic and biochemical studies have established that these enzymes are involved in restriction in vivo. Simplified purification procedures for BglI and BglII using these mutants are described.     

The nature of genetic recombination

The biological evolutionary axiom proposed earlier by the author states that in the absence of genetic recombination the evolution of organic forms would be impossible. In the present paper the literature data are considered, illustrating the role of genetic recombination in evolution. It is urged that a tendency towards an increasing complexity of biological organization results from periodical recombinational combining of the diverged genes as well as the whole genomes of different origin. The alternative mechanism implying the production of duplications from the identical gene copies or whole genomes is considered to be unlikely. According to the biological evolutionary axiom, the origin of life is connected with the appearance of a mode of reparation of crystalline type aggregates--the precursors of DNA by means of exchanges among their constituents. A hypothesis is proposed that in the process of recombination a certain distribution of the 6-amino bases (adenine, cytosine) along the DNA molecule is settled, with respect to the 6-carbonyl bases (guanine, thymine). It is proposed that the relative distribution of the bases mentioned influences electrostatic stability of the DNA molecule as a crystalline associate.     

In vivo selection of engineered homing endonucleases using double-strand break induced homologous recombination

Homing endonucleases, endonucleases capable of recognizing long DNA sequences, have been shown to be a tool of choice for precise and efficient genome engineering. Consequently, the possibility to engineer novel endonucleases with tailored specificities is under strong investigation. In this report, we present a simple and efficient method to select meganucleases from libraries of variants, based on their cleavage properties. The method has the advantage of directly selecting for the ability to induce double-strand break induced homologous recombination in a eukaryotic environment. Model selections demonstrated high levels of enrichments. Moreover, this method compared favorably with phage display for enrichment of active mutants from a mutant library. This approach makes possible the exploration of large sequence spaces and thereby represents a valuable tool for genome engineering.