The corrected nucleotide sequences of the TaqI restriction and modification enzymes reveal a thirteen-codon overlap.

The nucleotide sequence of the genes encoding methyltransferase TaqI (M.TaqI) and restriction endonuclease TaqI (R.TaqI) with the recognition sequence, TCGA, were analyzed in clones isolated from independent libraries. The genes, originally reported as 363 and 236 codons long [Slatko et al., Nucleic Acids Res. 15 (1987) 9781-9796] were redetermined as 421 and 263 codons long, respectively. The C terminus of the taqIM gene overlaps the N terminus of the taqIR gene by 13 codons, as observed with the isoschizomeric TthHB8I restriction-modification system [Barany et al., Gene 112 (1992) 13-20]. Removal of the overlapping codons did not interfere with in vivo M.TaqI activity. We postulate the overlap plays a role in regulating taqIR expression.     

异源D-海因酶和N-氨甲酰水解酶共表达重组枯草芽孢杆菌的构建

【目的】构建异源D-海因酶和N-氨甲酰水解酶共表达的重组枯草芽孢杆菌,探讨其作为全细胞催化剂合成D-对羟基苯甘氨酸的可行性。【方法】采用P_(aco)表达盒表达D-海因酶基因hyd或sd1,采用P_(AE)表达盒表达N-氨甲酰水解酶基因adc。分别以质粒pHP13和pUB110为载体,构建D-海因酶和N-氨甲酰水解酶共表达质粒pHCS、pHCY和pUCS。在受体菌中整合表达了acoR和sigL基因,敲除了skf和sdp基因。将共表达质粒分别转化不同的受体菌,通过测定全细胞催化活性,表征D-海因酶和N-氨甲酰水解酶共表达的效果。【结果】带有质粒pHCY和pHCS的重组菌,全细胞催化活性分别为0.21 U/mL和0.31 U/mL。整合表达acoR和sigL基因以及高拷贝质粒pUCS,使全细胞催化活性达到1.0 U/mL。【结论】异源D-海因酶和N-氨甲酰水解酶在枯草芽孢杆菌中能够正确表达。基因拷贝数、acoR和sigL基因表达水平,及skf和sdp基因缺失对重组菌的催化活性具有显著影响。     

BstNI同功酶限制—修饰系统基因的表达检测和定位分析

鉴定了Ｅ．ｃｏｌｉ ＨＢ１０１和ＪＭ１１０的部分遗传标记,作为受体菌分别用于ＢｓｔＮＩ同功酶限制－修饰系统中限制性内切酶（Ｒ）基因和甲基化酶（Ｍ）基因表达的检测。用外切酶Ⅲ单向删切含Ｒ－Ｍ基因的ＤＮＡ片段,获得２３个缺失突变亚克隆。通过检测各亚克隆表达的Ｒ酶和Ｍ酶活性,将Ｒ和Ｍ基因分别定位在距克隆位点ＰｓｔＩ和０．２→１．４ｋｂ和１．５→３．３ｋｂ范围内。分析表明：该系统属于Ⅱ类限制－修饰系统,两     

Cloning and characterization of genes for the PvuI restriction and modification system.

The genes encoding the endonuclease and the methylase of the PvuI restriction and modification system were cloned in E.coli and characterized. The genes were adjacent in tandem orientation spanning a distance of 2200 bases. The PvuI endonuclease was a single polypeptide with a calculated molecular weight of 27,950 daltons. The endonuclease was easily detectable when the gene was expressed from its endogenous promotor and present on a low copy plasmid, but expression was considerably enhanced when the endonuclease gene was placed under the control of a strong promoter on a high copy plasmid. The methylase did not completely protect plasmid DNA from R.PvuI digestion until the methylase gene was placed under lac promotor control in a multicopy plasmid. In the absence of the M.PvuI methylase, expression of the R.PvuI endonuclease from the lac promotor on a multicopy plasmid was not lethal to wild type E.coli, but was lethal in a temperature-sensitive ligase mutant at the non-permissive temperature. Moreover, induction of the R.PvuI endonuclease under lambda pL promotor control resulted in complete digestion of the E.coli chromosome by R.PvuI.     

Cloning the modification methylase gene of Bacillus sphaericus R in Escherichia coli

The gene coding for the sequence-specific modification methylase methM . BspI of Bacillus sphaericus R has been cloned in Escherichia coli by means of plasmid pBR322. The selection was based on the expression of the cloned gene which rendered the recombinant plasmid resistant to BspI restriction endonuclease cleavage. The gene is carried by a 9 kb BamHI fragment and by a smaller 2.5 kb EcoRI fragment derived from the BamHI fragment. The Bsp-specific methylase level was found to be higher in the recombinant clones than in the parental strain. The methylase gene is probably located on the Bacillus sphaericus chromosome, and not on a plasmid known to be carried by this strain. The recombinant clones do not exhibit an BspI restriction endonuclease activity.     

Overproduction, purification and crystallization of TaqI restriction endonuclease

Under phoA promoter control, TaqI endonuclease was overproduced to 5% of Escherichia coli cellular proteins. This was achieved by fusing the endonuclease gene to the first four codons of the alkaline phosphatase signal sequence. For maximal overproduction (30% of cellular proteins), a putative 14-bp hairpin within the endonuclease coding sequence was replaced with degenerate codons. In addition, TaqI methylase was required to protect host DNA. The endonuclease was purified in sufficient amounts for crystallization.     

Characterization of the cloned BamHI restriction modification system: its nucleotide sequence, properties of the methylase, and expression in heterologous hosts.

The BamHI restriction modification system was previously cloned into E. coli and maintained with an extra copy of the methylase gene on a high copy vector (Brooks et al., (1989) Nucl. Acids Res. 17, 979-997). The nucleotide sequence of a 3014 bp region containing the endonuclease (R) and methylase (M) genes has now been determined. The sequence predicts a methylase protein of 423 amino acids, Mr 49,527, and an endonuclease protein of 213 amino acids, Mr 24,570. Between the two genes is a small open reading frame capable of encoding a 102 amino acid protein, Mr 13,351. The M. BamHI enzyme has been purified from a high expression clone, its amino terminal sequence determined, and the nature of its substrate modification studied. The BamHI methylase modifies the internal C within its recognition sequence at the N4 position. Comparisons of the deduced amino acid sequence of M. BamHI have been made with those available for other DNA methylases: among them, several contain five distinct regions, 12 to 22 amino acids in length, of pronounced sequence similarity. Finally, stability and expression of the BamHI system in both E. coli and B. subtilis have been studied. The results suggest R and M expression are carefully regulated in a 'natural' host like B. subtilis.     

Molecular cloning and expression in Escherichia coli of two modification methylase genes of Bacillus subtilis

Two modification methylase genes of Bacillus subtilis R were cloned in Escherichia coli by using a selection procedure which is based on the expression of these genes. Both genes code for DNA-methyltransferases which render the DNA of the cloning host E. coli HB101 insensitive to the BspRI (5'-GGCC) endonuclease of Bacillus sphaericus R. One of the cloned genes is part of the restriction-modification (RM) system BsuRI of B. subtilis R with specificity for 5'-GGCC. The other one is associated with the lysogenizing phage SP beta B and produces the methylase M.BsuP beta BI with specificity for 5'-GGCC. The fragment carrying the SP beta B-derived gene also directs the synthesis in E. coli of a third methylase activity (M.BsuP beta BII), which protects the host DNA against HpaII and MspI cleavage within the sequence 5'-CCGG. Indirect evidence suggests that the two SP beta B modification activities are encoded by the same gene. No cross-hybridization was detected either between the M.BsuRI and M.BsuP beta B genes or between these and the modification methylase gene of B. sphaericus R, which codes for the enzyme M.BspRI with 5'-GGCC specificity.     

Cloning and sequence analysis of the StsI restriction-modification gene: presence of homology to FokI restriction-modification enzymes.

StsI endonuclease (R.StsI), a type IIs restriction endonuclease found in Streptococcus sanguis 54, recognizes the same sequence as FokI but cleaves at different positions. A DNA fragment that carried the genes for R.StsI and StsI methylase (M.StsI) was cloned from the chromosomal DNA of S.sanguis 54, and its nucleotide sequence was analyzed. The endonuclease gene was 1,806 bp long, corresponding to a protein of 602 amino acid residues (M(r) = 68,388), and the methylase gene was 1,959 bp long, corresponding to a protein of 653 amino acid residues (M(r) = 76,064). The assignment of the endonuclease gene was confirmed by analysis of the N-terminal amino acid sequence. Genes for the two proteins were in a tail-to-tail orientation, separated by a 131-nucleotide intercistronic region. The predicted amino acid sequences between the StsI system and the FokI system showed a 49% identity between the methylases and a 30% identity between the endonucleases. The sequence comparison of M.StsI with various methylases showed that the N-terminal half of M.StsI matches M.NIaIII, and the C-terminal half matches adenine methylases that recognize GATC and GATATC.     

Cloning and expression of a new site-specific methyltransferase M.SscL1I from Staphylococcus sp. L1

The gene of the new site-specific methyltransferase M.SscL1I belonging to the same modification-restriction system as the previously described by us site-specific endonuclease SscL1I has been cloned from the natural strain Staphylococcus sp. L1. A plasmid to express the methylase gene under control of the T7 phage-specific promotor has been constructed. Conditions were found to express the recombinant methylase M.SscL1I and to purify it to near homogeneity. It is shown that the methylase modifies the adenine base in the recognition site 5;-GANTC-3;.     

An alternative approach for screening active bam HI variants: overexpression in T-7 RNA polymerase based system

The type II restriction endonuclease, Bam HI, has been overexpressed in E. coli by cloning the Bam HI gene in frame with an E. coli Ribosome Binding Site (RBS) under the T7 promoter of an E. coli expression vector pRSET A. The expression level of Bam HI endonuclease using this construct was found to be higher than that reported of the overexpressing clone pAEK14. Our overexpressing clone, pAABRw in BL21 cells in presence of Bam HI methylase in pMAP6 following induction with IPTG yields about 9.2 x 10(6) units per gram wet cell paste. In vivo activity of the recombinant endonuclease could be confirmed by the SOS induction assay in JH139 cells even in the absence of T7 polymerase and cognate Bam HI methylase because of leaky expression in E. coli. This provides an alternate way to screen the active endonuclease and its variants.     

Site-specific methylases induce the SOS DNA repair response in Escherichia coli.

Expression of the site-specific adenine methylase HhaII (GmeANTC, where me is methyl) or PstI (CTGCmeAG) induced the SOS DNA repair response in Escherichia coli. In contrast, expression of methylases indigenous to E. coli either did not induce SOS (EcoRI [GAmeATTC] or induced SOS to a lesser extent (dam [GmeATC]). Recognition of adenine-methylated DNA required the product of a previously undescribed gene, which we named mrr (methylated adenine recognition and restriction). We suggest that mrr encodes an endonuclease that cleaves DNA containing N6-methyladenine and that DNA double-strand breaks induce the SOS response. Cytosine methylases foreign to E. coli (MspI [meCCGG], HaeIII [GGmeCC], BamHI [GGATmeCC], HhaI [GmeCGC], BsuRI [GGmeCC], and M.Spr) also induced SOS, whereas one indigenous to E. coli (EcoRII [CmeCA/TGG]) did not. SOS induction by cytosine methylation required the rglB locus, which encodes an endonuclease that cleaves DNA containing 5-hydroxymethyl- or 5-methylcytosine (E. A. Raleigh and G. Wilson, Proc. Natl. Acad. Sci. USA 83:9070-9074, 1986).     

Two-step cloning and expression in Escherichia coli of the DNA restriction-modification system StyLTI of Salmonella typhimurium.

The StyLTI restriction-modification system is common to most strains of the genus Salmonella, including Salmonella typhimurium. We report here the two-step cloning of the genes controlling the StyLTI system. The StyLTI methylase gene (mod) was cloned first. Then, the companion endonuclease gene (res) was introduced on a compatible vector. A strain of S. typhimurium sensitive to the coliphage lambda was constructed and used to select self-modifying recombinant phages from a Res- Mod+ S. typhimurium genomic library in the lambda EMBL4 cloning vector. The methylase gene of one of these phages was then subcloned in pBR328 and transferred into Escherichia coli. In the second step, the closely linked endonuclease and methylase genes were cloned together on a single DNA fragment inserted in pACYC184 and introduced into the Mod+ E. coli strain obtained in the first step. Attempts to transform Mod- E. coli or S. typhimurium strains with this Res+ Mod+ plasmid were unsuccessful, whereas transformation of Mod+ strains occurred at a normal frequency. This can be understood if the introduction of the StyLTI genes into naive hosts is lethal because of degradation of host DNA by restriction activity; in contrast to most restriction-modification systems, StyLTI could not be transferred into naive hosts without killing them. In addition, it was found that strains containing only the res gene are viable and lack restriction activity in the absence of the companion mod gene. This suggests that expression of the StyLTI endonuclease activity requires at least one polypeptide involved in the methylation activity, as is the case for types I and III restriction-modification systems but not for type II systems.     

Purification and properties of the Eco57I restriction endonuclease and methylase--prototypes of a new class (type IV).

The Eco57I restriction endonuclease and methylase were purified to homogeneity from the E.coli RR1 strain carrying the eco57IRM genes on a recombinant plasmid. The molecular weight of the denaturated methylase is 63 kDa. The restriction endonuclease exists in a monomeric form with an apparent molecular weight of 104-108 kDa. R.Eco57I also possesses methylase activity. The methylation activities of both enzymes modify the outer A residue in the target sequence 5'CTGAAG yielding N6-methyladenine. M.Eco57I modifies both strands of the substrate while R.Eco57I modifies only one. Only the methylase enzyme is stimulated by Ca2+. The restriction endonuclease shows an absolute requirement for Mg2+ and is stimulated by AdoMet. ATP has no influence on either activity of the enzymes. The subunit structure and enzymatic properties of the Eco57I enzymes distinguish them from all other restriction-modification enzymes that have been described previously. Therefore, RM.Eco57I may be regarded as a representative of a novel class of restriction-modification systems, and we propose to classify it as type IV.     

Cloning and sequence analysis of the genes coding for Eco57I type IV restriction-modification enzymes.

A 6.3 kb fragment of E.coli RFL57 DNA coding for the type IV restriction-modification system Eco57I was cloned and expressed in E.coli RR1. A 5775 bp region of the cloned fragment was sequenced which contains three open reading frames (ORF). The methylase gene is 1623 bp long, corresponding to a protein of 543 amino acids (62 kDa); the endonuclease gene is 2991 bp in length (997 amino acids, 117 kDa). The two genes are transcribed convergently from different strands with their 3'-ends separated by 69 bp. The third short open reading frame (186 bp, 62 amino acids) has been identified, that precedes and overlaps by 7 nucleotides the ORF encoding the methylase. Comparison of the deduced Eco57I endonuclease and methylase amino acid sequences revealed three regions of significant similarity. Two of them resemble the conserved sequence motifs characteristic of the DNA[adenine-N6] methylases. The third one shares similarity with corresponding regions of the PaeR7I, TaqI, CviBIII, PstI, BamHI and HincII methylases. Homologs of this sequence are also found within the sequences of the PaeR7I, PstI and BamHI restriction endonucleases. This is the first example of a family of cognate restriction endonucleases and methylases sharing homologous regions. Analysis of the structural relationship suggests that the type IV enzymes represent an intermediate in the evolutionary pathway between the type III and type II enzymes.     

Nucleotide sequence of the EcoRII restriction endonuclease gene

The nucleotide sequence of a 1394 basepair (bp) DNA fragment containing the EcoRII restriction endonuclease (R.EcoRII) gene was determined. The endonuclease gene is 1206 bp in length (predicted 402 amino acids (aa) and Mr = 45 178) and is separated by 33 bp from the EcoRII modification methylase (M.EcoRII) gene. The EcoRII restriction-modification system has a tail-to-tail organization of the two genes.     

Regulation of the BamHI restriction-modification system by a small intergenic open reading frame, bamHIC, in both Escherichia coli and Bacillus subtilis.

BamHI, from Bacillus amyloliquefaciens H, is a type II restriction-modification system recognizing and cleaving the sequence G--GATCC. The BamHI restriction-modification system contains divergently transcribed endonuclease and methylase genes along with a small open reading frame oriented in the direction of the endonuclease gene. The small open reading frame has been designated bamHIC (for BamHI controlling element). It acts as both a positive activator of endonuclease expression and a negative repressor of methylase expression of BamHI clones in Escherichia coli. Methylase activity increased 15-fold and endonuclease activity decreased 100-fold when bamHIC was inactivated. The normal levels of activity for both methylase and endonuclease were restored by supplying bamHIC in trans. The BamHI restriction-modification system was transferred into Bacillus subtilis, where bamHIC also regulated endonuclease expression when present on multicopy plasmid vectors or integrated into the chromosome. In B. subtilis, disruption of bamHIC caused at least a 1,000-fold decrease in endonuclease activity; activity was partially restored by supplying bamHIC in trans.     

Cloning and characterization of the MboII restriction-modification system

The two genes encoding the class IIS restriction-modification system MboII from Moraxella bovis were cloned separately in two compatible plasmids and expressed in E. coli RR1 delta M15. The nucleotide sequences of the MboII endonuclease (R.MboII) and methylase (M.MboII) genes were determined and the putative start codon of R.MboII was confirmed by amino acid sequence analysis. The mboIIR gene specifies a protein of 416 amino acids (MW: 48,617) while the mboIIM gene codes for a putative 260-residue polypeptide (MW: 30,077). Both genes are aligned in the same orientation. The coding region of the methylase gene ends 11 bp upstream of the start codon of the restrictase gene. Comparing the amino acid sequence of M.MboII with sequences of other N6-adenine methyltransferases reveals a significant homology to M.RsrI, M.HinfI and M.DpnA. Furthermore, M.MboII shows homology to the N4-cytosine methyltransferase BamHI.