Restrictase BamHI, HindII, EcoRI and SmaI mapping of hybrid lambda-phi 80 phages with recombination in the structural gene region

Hybrids lambda H lambda T80 with recombination in the region of structural genes have lambda head and phi 80 tail genes. In this paper the molecular structure of 5 independently isolated hybrids was established using restriction endonucleases. It has been shown that all of them have a recombinant head or tail. A deletion of 4,8% lambda was demonstrated in the immunity region of phi 80vir phage. Co-ordinates of restriction sites for BamHI, HindIII, EcoRI and SmaI restriction endonucleases on phi 80 DNA were calculated.     

SegH and Hef: two novel homing endonucleases whose genes replace the mobC and mobE genes in several T4-related phages

T4 contains two groups of genes with similarity to homing endonucleases, the seg-genes (similarity to endonucleases encoded by group I introns) containing GIY-YIG motifs and the mob-genes (similarity to mobile endonucleases) containing H-N-H motifs. The four seg-genes characterized to date encode homing endonucleases with cleavage sites close to their respective gene loci while none of the mob-genes have been shown to cleave DNA. Of 18 phages screened, only T4 was found to have mobC while mobE genes were found in five additional phages. Interestingly, three phages encoded a seg-like gene (hereby called segH) with a GIY-YIG motif in place of mobC. An additional phage has an unrelated gene called hef (homing endonuclease-like function) in place of the mobE gene. The gene products of both novel genes displayed homing endonuclease activity with cleavage site specificity close to their respective genes. In contrast to intron encoded homing endonucleases, both SegH and Hef can cleave their own DNA as well as DNA from phages without the genes. Both segH and mobE (and most likely hef) can home between phages in mixed infections. We discuss why it might be a selective advantage for phage freestanding homing endonucleases to cleave both HEG-containing and HEG-less genomes.     

Chromosomal loci of genes controlling site-specific restriction endonucleases of Bacillus subtilis

Molecular Genetics and Genomics - We constructed transformants of B. subtilis 168 which acquired genes for site-specific restriction endonucleases. These endonucleases originated from various...     

The MmeI family: type II restriction–modification enzymes that employ single-strand modification for host protection

The type II restriction endonucleases form one of the largest families of biochemically-characterized proteins. These endonucleases typically share little sequence similarity, except among isoschizomers that recognize the same sequence. MmeI is an unusual type II restriction endonuclease that combines endonuclease and methyltransferase activities in a single polypeptide. MmeI cuts DNA 20 bases from its recognition sequence and modifies just one DNA strand for host protection. Using MmeI as query we have identified numerous putative genes highly similar to MmeI in database sequences. We have cloned and characterized 20 of these MmeI homologs. Each cuts DNA at the same distance as MmeI and each modifies a conserved adenine on only one DNA strand for host protection. However each enzyme recognizes a unique DNA sequence, suggesting these enzymes are undergoing rapid evolution of DNA specificity. The MmeI family thus provides a rich source of novel endonucleases while affording an opportunity to observe the evolution of DNA specificity. Because the MmeI family enzymes employ modification of only one DNA strand for host protection, unlike previously described type II systems, we propose that such single-strand modification systems be classified as a new subgroup, the type IIL enzymes, for Lone strand DNA modification.     

Targeted gene therapies: tools, applications, optimization

Many devastating human diseases are caused by mutations in a single gene that prevent a somatic cell from carrying out its essential functions, or by genetic changes acquired as a result of infectious disease or in the course of cell transformation. Targeted gene therapies have emerged as potential strategies for treatment of such diseases. These therapies depend upon rare-cutting endonucleases to cleave at specific sites in or near disease genes. Targeted gene correction provides a template for homology-directed repair, enabling the cell's own repair pathways to erase the mutation and replace it with the correct sequence. Targeted gene disruption ablates the disease gene, disabling its function. Gene targeting can also promote other kinds of genome engineering, including mutation, insertion, or gene deletion. Targeted gene therapies present significant advantages compared to approaches to gene therapy that depend upon delivery of stably expressing transgenes. Recent progress has been fueled by advances in nuclease discovery and design, and by new strategies that maximize efficiency of targeting and minimize off-target damage. Future progress will build on deeper mechanistic understanding of critical factors and pathways.     

BglII and MunI: what a difference a base makes

Restriction endonucleases are resilient to alterations in their DNA-binding specificities. Structures of the BglII and MunI endonucleases bound to their palindromic DNA sites, which differ by only their outer base pairs from the recognition sequences of BamHI and EcoRI, respectively, have recently been determined. A comparison of these complexes reveals surprising differences and similarities in structure, and provides a basis for understanding the immutability of restriction endonucleases.     

抗人CD3单抗重、轻链可变区基因的体外扩增、克隆和序列分析

根据免疫球蛋白重链和轻链可变区基因５’端序列和Ｊ区序列,化学合成适合于体外扩增抗体重、轻链可变区基因的二对引物。从体外培养的ＯＫＴ３杂交瘤细胞中提取总ＲＮＡ,反转录生成ｃＤＮＡ,以ｃＤＮＡ为模板,分别加入合成的重、轻链可变区引物进行ＰＣＲ,扩增出抗体重、轻链可变区基因片段。将扩增产物分别插入ｐＵＣ１９质粒,筛选出阳性克隆,用链终止法进行ＤＮＡ序列测定。所测重链可变区基因全长３５７ｂｐ,编码１１９个氨基酸,轻链可变区基因全长３２１ｂｐ,编码１０７个氨基酸。     

Cloning, sequence analysis, and expression of ansB from Pseudomonas fluorescens, encoding periplasmic glutaminase/asparaginase

A gene (ansB) encoding a class II glutaminase/asparaginase has been cloned from Pseudomonas fluorescens and characterized by DNA sequencing, promoter analysis and heterologous expression in Escherichia coli. We show that ansB is monocistronic and depends on the alternate sigma factor sigma 54 for expression. A second open reading frame located downstream of ansB is highly homologous to a number of bacterial genes that encode secreted endonucleases of unknown function.     

Targeted gene therapies: tools,applications, optimization

Many devastating human diseases are caused by mutations in a single gene that prevent a somatic cell from carrying out its essential functions, or by genetic changes acquired as a result of infectious disease or in the course of cell transformation. Targeted gene therapies have emerged as potential strategies for treatment of such diseases. These therapies depend upon rare-cutting endonucleases to cleave at specific sites in or near disease genes. Targeted gene correction provides a template for homology-directed repair, enabling the cell’s own repair pathways to erase the mutation and replace it with the correct sequence. Targeted gene disruption ablates the disease gene, disabling its function. Gene targeting can also promote other kinds of genome engineering, including mutation, insertion, or gene deletion. Targeted gene therapies present significant advantages compared to approaches to gene therapy that depend upon delivery of stably expressing transgenes. Recent progress has been fueled by advances in nuclease discovery and design, and by new strategies that maximize efficiency of targeting and minimize off-target damage. Future progress will build on deeper mechanistic understanding of critical factors and pathways.     

Cloning, physical mapping and genome organization of mitochondrial DNA from Cyprinus carpio oocytes

Summary The mitochondrial genome from Cyprinus carpio oocytes is a 10.5 megadalton, circular DNA molecule. The carp mitochondrial DNA was cloned in pBR325. Three recombinant plasmids accounted for the entire genome. Mapping of this DNA using 11 different restriction endonucleases is reported here. Both the large and small rRNA genes were then localized using Southern blot analysis. The subunit I of the cytochrome oxidase, the cytochrome b, the tRNA^Glu and the URF 4 genes were localized by nucleotide sequence analysis and homology studies with human mtDNA.Our results suggest that a similar gene order has been maintained in the mitochondrial genomes of Chordata and support the hypothesis of a common ancestor for all vertebrate organelle genomes.This study constitutes the first report on the genome organization of a fish mtDNA and provides information for further investigation in connection with sequence determination, replication, and gene expression in carp mitochondria.This work was supported by proyect RS-82-21 from the Universidad Austral de Chile and Grant N^o 1116 from Fondo Nacional de Desarrollo Cientifico y Tecnologico     

Nonsynonymous single-nucleotide polymorphisms of the human apoptosis-related endonuclease--DNA fragmentation factor beta polypeptide, endonuclease G, and Flap endonuclease-1--genes show a low degree of genetic heterogeneity

DNA fragmentation factor beta (DFFB) polypeptide, endonuclease G (EndoG), and Flap endonuclease-1 (FEN-1) are responsible for DNA fragmentation, a hallmark of apoptosis. Although the human homologs of these genes show three, four, and six nonsynonymous single-nucleotide polymorphisms (SNPs), respectively, data on their genotype distributions in populations worldwide are limited. In this context, the objectives of this study were to elucidate the genetic heterogeneity of all these SNPs in wide-ranging populations, and thereby to clarify the genetic background of these apoptosis-related endonucleases in human populations. We investigated the genotype distribution of their SNPs in 13 different populations of healthy Asians, Africans, and Caucasians using novel genotyping methods. Among the 13 SNPs in the 3 genes, only 3 were found to be polymorphic: R196K and K277R in the DFFB gene, and S12L in the EndoG gene. All 6 SNPs in the FEN-1 gene were entirely monoallelic. Although it remains unclear whether each SNP would exert any effect on endonuclease functions, these genes appear to exhibit low degree of genetic heterogeneity with regard to nonsynonymous SNPs. These findings allow us to conclude that human apoptosis-related endonucleases, similarly to other human DNase genes, revealed previously, are well conserved at the protein level during the course of human evolution.     

Immunoenzymatic Detection of PCR Products for the Identification of Phytoplasmas in Plants

Polymerase chain reaction (PCR, with universal and specific primers designed on rRNA genes) provides a rapid, reliable method of diagnosing phytoplasmas (formerly mycoplasma-like organisms) in plants. However, to attain a better identification of these prokaryotes, it is often necessary to digest the PCR products with restriction endonucleases or to hybridize them with specific probes. The present study compared routine procedures for detecting PCR products against a new system, PCRELISA (Boehringer Mannheim), which enables immunoenzymatic detection of PCR products. The results show that this new system provides fast and highly sensitive detection of several phytoplasmas associated with certain trees and shrubs. Optimization of all parameters involved in the PCR-ELISA procedure and its advantages are reported and discussed.     

Rapid Identification of Rhizobia by Restriction Fragment Length Polymorphism Analysis of PCR-Amplified 16S rRNA Genes

Forty-eight strains representing the eight recognized Rhizobium species, two new Phaseolus bean Rhizobium genomic species, Bradyrhizobium spp., Agrobacterium spp., and unclassified rhizobia from various host plants were examined by restriction fragment length polymorphism (RFLP) analysis of 16S rRNA genes amplified by polymerase chain reaction (PCR). Twenty-one composite genotypes were obtained from the combined data of the RFLP analysis with nine endonucleases. Species assignments were in full agreement with the established taxonomic classification. Estimation from these data of genetic relationships between and within genera and species correlated well with previously published data based on DNA-rRNA hybridizations and sequence analysis of 16S rRNA genes. This PCR-RFLP method provides a rapid tool for the identification of root nodule isolates and the detection of new taxa.     

真菌线粒体cob中Ⅱ型LAGLIDADG归巢内切酶进化分析

以已公布的114种真菌线粒体基因组数据为依据,对cob内含子及其编码的Ⅱ型LAGLIDADG归巢内切酶进行全面分析,以揭示其进化规律。在cob内含子中共发现27个Ⅱ型LAGLIDADG归巢内切酶基因,其中18个位于S433内含子插入位点,其余9个散布在另外8个插入位点。结合Pfam数据,将Ⅱ型LAGLIDADG归巢内切酶分成10个主要类群,其中4个类群存在不同生物界物种间的水平迁移。S433位点的18个归巢内切酶均属于类群1,它们与宿主内含子可能从共同祖先垂直遗传而来,并在传递过程中伴有水平迁移;其他归巢内切酶及宿主内含子则应是水平迁移的结果。类群1中的归巢内切酶可分为两个亚类,两亚类识别的靶序列存在明显差异;保守模体氨基酸序列分析显示它们大多数具有潜在内切酶活性。全面呈现了真菌线粒体cob内含子及其编码的Ⅱ型LAGLIDADG归巢内切酶的存在状态和进化模式,为归巢内切酶的改造和设计提供了新素材。     

Structural and Functional Characteristics of Homing Endonucleases

Mobile genetic elements constitute a remarkably diverse group of nonessential selfish genes that provide no apparent function to the host. These selfish genes have been implicated in host extinction, speciation and architecture of genetic systems. Homing endonucleases, encoded by the open reading frames embedded in introns or inteins of mobile genetic elements, possess double-stranded DNA-specific endonuclease activity. They inflict sequence-specific double-strand breaks at or near the homing site in intron- or intein-less allele. Subsequently, through nonreciprocal exchange the insertion sequence (intron or intein) is transferred from an intein- or intron-containing allele to an intein- or intron-less allele. The components of host double-strand break repair pathway are thought to finish the “homing” process. Several lines of evidence suggest that homing endonucleases are capable of promoting transposition into ectopic sites within or across genomes for their survival as well as dispersal in natural populations. The occurrence of inteins at high frequencies serves as instructive models for understanding the mechanistic aspects of the process of homing and its evolution. This review focuses on genetic, biochemical, structural, and phylogenetic aspects of homing endonucleases, and their comparison with restriction endonucleases.