A simple and rapid method for screening bacteria for type II restriction endonucleases: enzymes in Aphanothece halophytica

A method is described which allows a large number of bacterial strains to be rapidly and easily screened for the presence of site-specific endonucleases. The method involves selective permeabilization of the bacterial cell and analysis of the exuded material. Type II restriction endonucleases from cyanobacteria and Gram-negative eubacteria have been detected and new enzymes have been found. The method should be widely applicable and easy to modify for use in genera other than those tested. Three-site-specific endonuclease activities, detected by this method in Aphanothece halophytica PCC 7412, were purified and their recognition and cleavage specificities were determined AhaI and AhaII recognise and cleave the same DNA sequences as CauII and AcyI respectively; the specificity of AhaIII (TTTAAA) has been reported previously (Whitehead and Brown, 1982, FEBS Letters 143:296–300).Abbreviations Brij-58 20 cetyl ether - Pu purine nucleoside - Py pyrimidine nucleoside     

Transposon-like structure of a new plasmid-encoded restriction-modification system in Rhizobium leguminosarum VF39SM

Total DNA isolated from Rhizobium leguminosarum VF39SM cells is resistant to cleavage by the restriction endonuclease PstI. Plasmid curing and transfer studies localized this phenotype to pRleVF39b, the second smallest of six plasmids found in this bacterium. In vitro selection for vector modification was employed to isolate a presumptive methylase gene (M.Rle39BI) from a plasmid gene library. Total and plasmid DNAs isolated from E. coli containing M.RleBI were resistant to digestion by PstI. Sequence data suggested that a putative restriction endonuclease (R.Rle39BI) was also encoded on the same fragment. The two genes were flanked by identical copies of a putative insertion sequence, which was also present in several copies elsewhere in the VF39SM genome. The presence of this element in other strains examined suggested that this element is indeed an insertion sequence. The differences in G/C content between the DNA coding for the R/M system and that of the IS element suggest that this DNA region may have been acquired by horizontal transfer. Received: 28 January 1997 / Accepted: 3 June 1997     

Cellular localization of Type I restriction-modification enzymes is family dependent

Cellular localization of Type I restriction-modification enzymes EcoKI, EcoAI, and EcoR124I-the most frequently studied representatives of IA, IB, and IC families-was analyzed by immunoblotting of subcellular fractions isolated from Escherichia coli strains harboring the corresponding hsd genes. EcoR124I shows characteristics similar to those of EcoKI. The complex enzymes are associated with the cytoplasmic membrane via DNA interaction as documented by the release of the Hsd subunits from the membrane into the soluble fraction following benzonase treatment. HsdR subunits of the membrane-bound enzymes EcoKI and EcoR124I are accessible, though to a different extent, at the external surface of cytoplasmic membrane as shown by trypsinization of intact spheroplasts. EcoAI strongly differs from EcoKI and EcoR124I, since neither benzonase nor trypsin affects its association with the cytoplasmic membrane. Possible reasons for such a different organization are discussed in relation of the control of the restriction-modification activities in vivo.     

Restriction-modification system in bacteriophage MB78

Restriction-modification system is present in bacteria to protect the cells against phage infection. Interestingly, the bacteriophage MB78, a virulent phage of Salmonella typhimurium possesses restriction-modification system. Permissive host transformed with plasmid having the genomic fragment of MB78 carrying the putative restriction-modification genes severely restrict the growth of the phage 9NA. Growth of phage MB78 is also restricted to some extent. However, the temperate phage P22 is not restricted at all. Cloning of the the putative restriction-modification genes has been done in both orientations in different vectors. The clones carrying the genes in the same orientation as that of the lacZ in pUC19 are mostly unstable. However, those are stable when cloned in opposite orientation. Viability of the transformants is strain-, orientation-, and medium-dependent. The two genes have also been cloned individually/separately. Hosts carrying only the modification gene do not restrict growth of phages while the hosts carrying only the restriction gene do. The former produces stable transformants while the latter produces very unstable transformants which were viable only upto 36 h or so. The colonies carrying modification gene were normal looking while those carrying the restriction gene were tiny, flat, and looked distressed resembling very much the clones carrying bacterial restriction-modification system. Amplification of the genes and subsequent cloning in expression vector will be carried out for characterization of the enzymes.     

Transformation using in vivo and in vitro methylation in Streptomyces griseus

Streptomyces griseus does not readily take up foreign DNA isolated from other Streptomyces species or Escherichia coli, presumably due to its unique restriction-modification systems that function as a barrier for interspecific DNA transfer. To efficiently transform S. griseus by avoiding the restriction barriers, we methylated incoming DNA in vivo and in vitro and treated protoplasts with heat prior to transformation. Whereas heat treatment of protoplasts or methylation of the E. coli-Streptomyces shuttle vectors (pXE4 and pKK1443) did not prominently improve the transformation efficiency, HpaII methylation of the vectors from any E. coli strains tested in this study highly increased the transformation efficiency. The highest transformation efficiency was observed when the shuttle vectors were isolated from the dam, hsd strain of E. coli (GM161) and methylated by AluI and HpaII methyltransferases, and the efficiency was approximately the same as that of the vectors from S. griseus. We identified several restriction-modification systems that decrease the transformation efficiency. This research also led us to understand methylation profiles and restriction-modification systems in S. griseus.     

Reduced but accurate translation from a mutant AUA initiation codon in the mitochondrial COX2 mRNA of Saccharomyces cerevisiae

The gene encoding the XorII methyltransferase (M · XorII) was cloned from Xanthomonas oryzae pv. oryzae and characterized in Escherichia coli. The M · XorII activity was localized to a 3.1 kb BamHI-BstXI fragment, which contained two open reading frames (ORFs) of 1272 nucleotides (424 amino acids) and 408 nucleotides (136 amino acids). Ten polypeptide domains conserved in other M⁵ cytosine methyltransferases (MTases) were identified in the deduced amino acid sequence of the 1272 ORF. E. coli Mrr⁺ strains were transformed poorly by plasmids containing the XorII MTase gene, indicating the presence of at least one ^MCG in the recognition sequence for M · XorII (CGATCG). The 408 nucleotide ORF was 36% identical at the amino acid level to sequences of the E. coli dcm-vsr gene, which is required for very short patch repair. X. oryzae pv. oryzae genomic DNA that is resistant to digestion by Pvul and XorII hybridizes with a 7.0 kb fragment containing the XorII MTase gene and vsr homolog, whereas DNA from strains that lack M · XorII activity do not hybridize with the fragment.The sequence presented in this paper has been submitted to NCBI; the accession number is U06424     

Structural plasmid evolution as a result of coupled recombinations at<Emphasis Type="Italic"> bom</Emphasis> and<Emphasis Type="Italic"> cer</Emphasis> sites

We have studied the recombination of plasmids bearing bom and cer sites. The bom (basis of mobilization) site is required for conjugative transfer, while the cer (ColE1 resolution) site is involved in the resolution of plasmid multimers, which increases plasmid stability. We constructed a pair of parent plasmids in such a way as to allow us select clones containing recombinant plasmids directly. Clone selection was based on the McrA sensitivity of recipient host DNA modified by M. Ecl18kI, which is encoded by one of the parent plasmids. The recombinant plasmid contains segments originating from both parental DNAs, which are bounded by bom and cer sites. Its structure is in accordance with our previously proposed model for recombination mediated by bom and cer sequences. The frequency of recombinant plasmid formation coincided with the frequency of recombination at the bom site. We also show that bom-mediated recombination in trans, unlike in cis, is independent of other genetic determinants on the conjugative plasmids.Communicated by W. Goebel     

Methylation-dependent DNA restriction in Bacillus anthracis

Bacillus anthracis, the causative agent of anthrax, is poorly transformed with DNA that is methylated on adenine or cytosine. Here we characterize three genetic loci encoding type IV methylation-dependent restriction enzymes that target DNA containing C5-methylcytosine (m5C). Strains in which these genes were inactivated, either singly or collectively, showed increased transformation by methylated DNA. Additionally, a triple mutant with an ~ 30-kb genomic deletion could be transformed by DNA obtained from Dam⁺Dcm⁺E. coli, although at a low frequency of ~ 10^− 3 transformants/10⁶ cfu. This strain of B. anthracis can potentially serve as a preferred host for shuttle vectors that express recombinant proteins, including proteins to be used in vaccines. The gene(s) responsible for the restriction of m6A-containing DNA in B. anthracis remain unidentified, and we suggest that poor transformation by such DNA could in part be a consequence of the inefficient replication of hemimethylated DNA in B. anthracis.