Purification of cohesive-end-producing restriction endonuclease from Bacillus subtilis G.

A new restriction endonuclease was partially purified from Bacillus subtilis G (IAM1247). This restriction endonuclease (endonuclease RBsuG) seems to produce cohesive ends at its cleavage site.     

A general method for inserting specific DNA sequences into cloning vehicles

A general method has been developed to introduce any double-stranded DNA molecule into cloning vehicles at different restriction endonuclease sites. In this method a chemically synthesized decadeoxyribonucleotide duplex, containing a specific restriction endonuclease sequence, is joinlex DNA is cut by the same restriction endonuclease to generate the cohesive ends. It is then inserted into the restriction endonuclease cleavage site of the cloning vehicle. To demonstrate the feasibility of this new method, we have inserted separately the synthetic lac operator DNA at the Bam I and HindIII cleavage sites of the plasmid pMB9 DNA.     

Restriction endonuclease DNA analysis of antigenic variants of leptospires selected by monoclonal antibodies

The genome of antigenic variant CV (CT3)-1 derived from Leptospira interrogans serovar canicola was compared by cleavage with restriction endonucleases with the parent and serovar bafani, to which the variant was serologically most closely related. No differences were observed between the parent and variant in DNA restriction endonuclease patterns using eight restriction endonucleases. Serovar bafani was different in the patterns from the parent and antigenic variant CV (CT3)-1. The two antigenic variants derived from serovar hebdomadis, HV (H16)-1 and HV (H19)-1 which belonged serologically to serovars jules and hebdomadis, respectively, were compared by restriction endonuclease DNA analysis with the parent and serovar jules. No differences were observed between the parent and variants in DNA restriction endonuclease patterns using the same enzymes. But some differences were observed in DNA restriction endonuclease patterns between HV (H16)-1 and serovar jules. Thus, the antigenic variant selected from the parent by the anti-parent monoclonal antibody and serologically different from the parent, being identified either as a new serovar or as a known one, was found to be similar to the parent by the restriction endonuclease DNA analysis.     

Netropsin, distamycin A, bis-netropsins as selective inhibitors of restrictases and DNAse I

The simultaneous analysis of DNAase I "footprinting" data and restriction endonucleases inhibition data was performed on the same DNA end-labelled fragment. The inhibition induced by netropsin, a number of bis-netropsins and distamycin A was investigated. These experiments led us to the following conclusions. The restriction endonucleases inhibition by the ligands is caused by the ligand molecules binding in the close vicinity to the restriction endonuclease recognition sequence. The zone of +/- 4 bp from the center of the restriction endonuclease recognition sequence can be defined as the zone of the influence of the bounded ligand on the restriction endonuclease. But in this case the intersection of recognition sequence and the binding site occupied by a single ligand molecule is not sufficient for the inhibition to occur. Restriction endonuclease cutting sites protected by netropsin can be predicted basing upon known nucleotide sequence specificity of netropsin. Netropsin and bis-netropsins show different nucleotide sequence specificity. This fact can be used for selective inhibition of restriction endonucleases.     

Physical map of the bacteriophage T5 genome based on the cleavage products of the restriction endonucleases SalI, SmaI, BamI, and HpaI.

A physical map of the bacteriophage T5 genome was constructed by ordering the fragments produced by cleavage of T5 DNA with the restriction endonucleases SalI (4 fragments), SmaI (4 fragments), BamI (5 fragments), and HpaI (28 fragments). The following techniques were used to order the fragments. (i) Digestion of DNA from T5 heat-stable deletion mutants was used to identify fragments located in the deletable region. (ii) Fragments near the ends of the T5 DNA molecule were located by treating T5 DNA with lambda exonuclease before restriction endonuclease cleavage. (iii) Fragments spanning other restriction endonuclease cleavage sites were identified by combined digestion of T5 DNA with two restriction endonucleases. (iv) The general location of some fragments was determined by isolating individual restriction fragments from agarose gels and redigesting the isolated fragments with a second restriction enzyme. (v) Treatment of restriction digests with lambda exonuclease before digestion with a second restriction enzyme was used to identify fragments near, but not spanning, restriction cleavage sites. (vi) Exonucleases III treatment of T5 DNA before restriction endonuclease cleavage was used to locate fragments spanning or near the natural T5 single-chain interruptions. (vii) Analysis of the products of incomplete restriction endonuclease cleavage was used to identify adjacent fragments.     

Restriction endonuclease map of Euglena gracilis chloroplast DNA.

A physical map of the Euglena gracilis chloroplast genome has been constructed, based on cleavage sites of Euglena gracilis chloroplast DNA treated with bacterial restriction endonucleases. Covalently close, circular chloroplast DNA is cleaved by restriction endonuclease SalI into three fragments and by restriction endonuclease BamHI into six fragments. These nine cleavage sites have been ordered by fragment molecular weight analysis, double digestions, partial digestions, and by digestion studies of isolated DNA fragments. A fragment pattern of the products of EcoRI restriction endonuclease digestion of Euglena chloroplast DNA is also described. One of these fragments has been located on the cleavage site map.     

A rapid procedure for purification of EcoRI endonuclease.

A convenient and rapid procedure has been developed to purify restriction endonuclease Eco RI. The method involves sonication of cells at low ionic strength, precipitation of the endonuclease with Polymin P (a polyethyleneimine), elution of the enzyme from the Polymin P precipitate, ammonium sulfate precipitation and chromatography on phosphocellulose. The purified restriction endonuclease is free of exonuclease and other endonucleases.     

Detection of aquatic microorganisms from the Black Sea--producers of restriction endonucleases

300 clones of microorganisms isolated at different stations and from different depths in the Black Sea were screened for restriction endonucleases production. The production of restriction endonucleases was found in 17 clones screened. Three of them were identified to be Alteromonas haloplanktis B1. Restriction endonuclease AhaB1 is an isoshizomer of Sau961. An identified Alteromonas haloplanktis clone B8 produces AhaB8I restriction endonuclease the prototype to which is KpnI. Of the clones isolated three are Moraxella species B4 producing MapB4I restriction endonuclease analogous to BanI, three are Bacillus species producing BspB2I and one is Micrococcus lylae 113 producing Mly1131 analogue of NarI, six Moraxella species B6 produce MspB6I. The isolated producer strains may be used for isolation of above mentioned restriction endonucleases.     

Cloning and molecular characterization of the HgiCI restriction/modification system from Herpetosiphon giganteus Hpg9 reveals high similarity to BanI.

The genes coding for the GGYRCC specific restriction/modification system HgiCI from Herpetosiphon giganteus Hpg9 have been cloned in Escherichia coli in three steps. As an initial step, the methyltransferase gene could be obtained after heterologous in vitro selection of a plasmid gene bank by cleavage with the isoschizomeric restriction endonuclease BanI. The adjacent endonuclease gene was cloned following Southern blot analysis of flanking genomic regions. The two genes code for polypeptides of 420 amino acids (M.HgiCI) and 345 amino acids (R.HgiCI). Establishing a functional endonuclease gene could only be achieved using a tightly regulated expression system or by methylation of the genomic DNA prior to transformation of the endonuclease gene. The methyltransferase M.HgiCI shows significant similarities to the family of 5-methylcytidine methyltransferases. Striking similarities could be found with both the isoschizomeric endonuclease and methyltransferase of the BanI restriction/modification system from Bacillus aneurinolyticus.     

BsiI--a new unusual restriction endonuclease

The restriction endonuclease BsiI from Bacillus sphaericus was isolated. The recognition sequence and cleavage point of enzyme BsiI have been determined as (sequence: see text). This restriction endonuclease is not an isoschizomer of any known restriction endonucleases and differs from other enzymes: it hydrolyses DNA into unsymmetrical recognition sequence.     

The bacteriophage P1 restriction endonuclease

The bacteriophage P1 restriction endonuclease has been purified from Escherichia coli lysogenic for P1. This restriction endonuclease P has a sedimentation coefficient of 9.3 S. Unlike the E. coli K restriction endonuclease, endonuclease P does not require S-adenosylmethionine for breakage of DNA. S-adenosylmethionine does, however, stimulate the rate of double-strand breakage of DNA by endonuclease P. Hydrolysis of ATP by endonuclease P could not be detected under conditions in which the K restriction endonuclease massively degrades ATP.The enzyme makes a limited number of double-strand breaks in unmodified or heterologously modified λ DNA. In the presence of S-adenosylmethionine, it does not cut every DNA molecule to the same extent. Incubation of λ DNA with excess amounts of enzyme in the presence of S-adenosylmethionine results in less breakage of the DNA than with smaller amounts of enzyme. This effect is not seen in the absence of S-adenosylmethionine. The maximum amount of cutting in the absence of S-adenosylmethionine appears to be greater than the maximum amount of cutting in its presence. This is most likely due to the modification methylase activity of P1 restriction endonuclease.     

WebFARM: web server for finite automated restriction mapping

Restriction endonucleases are indispensable tools in molecular biology and biotechnology. Type II restriction endonucleases are part of restriction modification systems. DNA fragment extraction and restriction mapping are the basis for several biotechnological activities. WebFARM is a server application for identifying restriction endonuclease recognition sites and to give information regarding restriction mapping for given nucleotide sequences. WebFARM analyses given nucleotide sequence and identify restriction site for selected restriction endonucleases. It will also provide frequency of restriction for each restriction endonuclease. AVAILABILITY: http://webfarm.bioinfoindia.org/     

Host-controlled Restriction of T-even Bacteriophages: Relation of Endonuclease I and T-even-induced Nucleases to Restriction

Restriction of nonglucosylated T2 phage (T(*)2) as a function of bacterial growth state was the same for endonuclease I-containing and endonuclease I-deficient strains of Escherichia coli B. Furthermore, E. coli strains with various levels of restriction for T2 had comparable endonuclease I activities. It was also found that a T4 mutant temperature-sensitive for gene 46 and 47 functions was fully restricted at 42 C. It therefore appears that neither endonuclease I nor the phage-induced nucleases whose activities are blocked by mutations in genes 46 and 47 catalyze the initial event in restriction of nonglucosylated T-even phages.     

Evolutionary relationship between different subgroups of restriction endonucleases

The type II restriction endonuclease SsoII shows sequence similarity with 10 other restriction endonucleases, among them the type IIE restriction endonuclease EcoRII, which requires binding to an effector site for efficient DNA cleavage, and the type IIF restriction endonuclease NgoMIV, which is active as a homotetramer and cleaves DNA with two recognition sites in a concerted reaction. We show here that SsoII is an orthodox type II enzyme, which is active as a homodimer and does not require activation by binding to an effector site. Nevertheless, it shares with EcoRII and NgoMIV a very similar DNA-binding site and catalytic center as shown here by a mutational analysis, indicative of an evolutionary relationship between these three enzymes. We suggest that a similar relationship exists between other orthodox type II, type IIE, and type IIF restriction endonucleases. This may explain why similarities may be more pronounced between members of different subtypes of restriction enzymes than among the members of a given subtype.     

Restriction endonuclease DNA analysis of Leptospira interrogans serovars Icterohaemorrhagiae and Copenhageni

Leptospira interrogans serovar icterohaemorrhagiae strains Ictero No. I and RGA and serovar copenhageni strains M20, Shiromizu and Shibaura were examined by restriction endonuclease DNA analysis. Fifteen endonucleases (AluI, BamHI, BglII, EcoRI, HaeIII, HhaI, HindIII, KpnI, PstI, SacI, SalI, SmaI, StyI, XbaI and XhoI) were used as the digesting enzymes. Strain Ictero No. I showed endonuclease cleavage patterns which differed from those of the other four strains only when it was digested with enzymes KpnI and HindIII. When digested with KpnI, an extra band of about 5.4 kb was clearly produced, and when digested with HindIII, an extra band of about 25 kb was produced. When the other 13 enzymes were used, no differences were found between the endonuclease cleavage patterns among the five strains. Moreover, strains RGA, M20, Shiromizu and Shibaura could not be distinguished by the restriction endonuclease DNA analysis using all 15 endonucleases. In addition, six newly isolated leptospires from patients with leptospirosis and from Rattus norvegicus were compared with the Ictero No. I and M20 strains, by restriction endonuclease DNA analysis using enzymes KpnI and HindIII. Three leptospires belonging to serovar icterohaemorrhagiae showed the same endonuclease cleavage patterns as the M20 strain. The other three strains, which belong to serovar copenhageni, showed almost the same endonuclease cleavage patterns as the M20 strain; only the Kai ima 702 strain produced an extra band which was not identical to the Ictero No. I-specific extra band when digested with HindIII. The leptospiral restriction endonuclease DNA analysis has revealed taxonomic structures that are unrecognized by serology alone.     

Cloning and complete nucleotide sequences of the type II restriction-modification genes of Salmonella infantis.

The complete type II restriction-modification system of Salmonella infantis was cloned in Escherichia coli as an R . Sau3AI fragment of 3,430 base pairs. The clone was shown to express the restriction endonuclease as well as the modification methylase. The nucleotide sequence of the above fragment showed two open reading frames of 461 and 230 codons in tail-to-tail orientation. These were shown to represent the modification methylase M . SinI and the restriction endonuclease R . SinI, respectively. The methylase M . SinI amino acid sequence revealed a considerable similarity to those of other deoxycytidylate methylases. In contrast, endonuclease R . SinI did not exhibit such a similarity to other restriction enzymes.     

Temporal dynamics of methyltransferase and restriction endonuclease accumulation in individual cells after introducing a restriction-modification system

Type II restriction-modification (R-M) systems encode a restriction endonuclease that cleaves DNA at specific sites, and a methyltransferase that modifies same sites protecting them from restriction endonuclease cleavage. Type II R-M systems benefit bacteria by protecting them from bacteriophages. Many type II R-M systems are plasmid-based and thus capable of horizontal transfer. Upon the entry of such plasmids into a naïve host with unmodified genomic recognition sites, methyltransferase should be synthesized first and given sufficient time to methylate recognition sites in the bacterial genome before the toxic restriction endonuclease activity appears. Here, we directly demonstrate a delay in restriction endonuclease synthesis after transformation of Escherichia coli cells with a plasmid carrying the Esp1396I type II R-M system, using single-cell microscopy. We further demonstrate that before the appearance of the Esp1396I restriction endonuclease the intracellular concentration of Esp1396I methyltransferase undergoes a sharp peak, which should allow rapid methylation of host genome recognition sites. A mathematical model that satisfactorily describes the observed dynamics of both Esp1396I enzymes is presented. The results reported here were obtained using a functional Esp1396I type II R-M system encoding both enzymes fused to fluorescent proteins. Similar approaches should be applicable to the studies of other R-M systems at single-cell level.     

Restriction endonuclease mapping of pSC101 and pMB9

Summary A restriction endonuclease analysis of the plasmids pSC101 and pMB9 has allowed a determination of the alterations that occurred in the tetracycline resistance locus during the construction of pMB9 from pSC101. The genes for four of the polypeptides involved in tetracycline resistance have been positioned on the restriction endonuclease map of pSC101.     

Purification of the HhaII restriction endonuclease from an overproducer Escherichia coli clone

An Escherichia coli K12 strain carrying the HhaII methylase and restriction genes on two separate compatible plasmids, pSK5 and pSK7, is used to overproduce the restriction endonuclease. Plasmid pSK5 expresses the methylase gene constitutively from its chloramphenicol resistance gene promoter, and plasmid pSK7 expresses the restriction endonuclease under control of the lacUV5 promoter. Induction of the two-plasmid clone with 1 mM isopropyl-1-thio-beta-D-galactopyranoside results in a 15-fold increase in HhaII endonuclease activity. The enzyme has been purified to apparent homogeneity. It migrates as a 23-kilodalton polypeptide on denaturing sodium dodecyl sulfate-polyacrylamide electrophoretic gels and as a 52-kilo-dalton native protein dimer on a high pressure liquid chromatography sizing column.