Cloning and sequences of the genes encoding the CfrBI restriction-modification system from Citrobacter freundii

An alternative approach to study the enzymatic specificities of the CfrBI restriction-modification system

Restriction–modification systems (RMS) are the main gene-engineering tools and a suitable model to study the molecular mechanisms of catalysis and DNA–protein interactions. Research into the catalytic properties of these enzymes, determination of hydrolysis and DNA-methylation sites remain topical. In our previous work we have cloned and sequenced the CfrBI restriction–modification system (strain Citrobacter freundii), which recognizes the nucleotide sequence 5′-CCWWGG-3′.

In this article we describe the cloning of the methyltransferase and restriction endonuclease genes (gene encoding CfrBI DNA methyltransferase (cfrBIM) and gene encoding CfrBI restriction endonuclease (cfrBIR)) separately to obtain strains overproducing the enzymes of this system. His₆-CfrBI, which had been purified to homogeneity, was used to establish the DNA-hydrolysis point in its recognition site. CfrBI was shown to cleave DNA after just the first 5′C within the recognition site and then to generate 4-nt 3′ cohesive ends (5′-C/CWWGG-3′).

To map the site of methylation by M.CfrBI, we exploited the fact that the CfrBI site partially overlaps with the recognition sites of the well-documented enzymes KpnI and ApaI. The M.CfrBI- induced hemimethylation of the internal C residue of the ApaI recognition sequence (GGGC^N4mCC) was observed to block cleavage by ApaI. In contrast, KpnI was able to digest its M.CfrBI-hemimethylated site (GGTA^N4mCC).

KpnI was used to restrict a fragment of DNA harbouring the CfrBI and KpnI sites, in which the CfrBI site was methylated in vitro by His₆-M.CfrBI using [³H]-SAM.

The subsequent separation of hydrolysis products by electrophoresis and the enumeration of incorporated [H3]-methyl groups in each of the fragments made it possible to determine that external cytosine undergoes modification in the recognition site.

Regulation of RNA polymerase promoter selectivity by covalent modification of DNA

Expression of genes encoding type II restriction/modification (R/M) systems, which are widely spread in eubacteria, must be tightly regulated to ensure that host DNA is protected from restriction endonucleases at all times. Examples of coordinated expression of R/M genes that rely on the action of regulatory factors or the ability of methyl transferases to repress their own synthesis by interacting with the promoter DNA have been described. Here, we characterize the molecular mechanism of factor-independent regulation in the CfrBI R/M system. Regulation of the cfrBIM gene transcription occurs through CfrBIM-catalyzed methylation of a cytosine residue in the cfrBIM promoter. The covalent modification inhibits cfrB1M promoter complex formation by interfering with the RNA polymerase sigma(70) subunit region 4.2 recognition of the -35 promoter element. The decrease in the cfrBIM promoter complex formation leads to increase in the activity of overlapping cfrBIR promoters. This elegant factor-independent regulatory system ensures coordinated expression of the cfrBI genes.

DNA methylation at the CfrBI site is involved in expression control in the CfrBI restriction-modification system

We have previously found that genes of the CFR:BI restriction-modification (R-M) system from Citrobacter freundii are oriented divergently and that their promoter regions overlap. The overlapping promoters suggest regulation of gene expression at the transcriptional level. In this study the transcription regulation of CFR:BI R-M genes was analyzed in vivo and in vitro in Escherichia coli. It was shown that in the presence of CFR:BI methyltransferase (M.CFR:BI), cell galactokinase activity decreases 10-fold when the galactokinase gene (galK) is under the control of the cfrBIM promoter and increases 20-fold when galK is under the control of the cfrBIR promoter. The CFR:BI site, proven to be unique for the entire CFR:BI R-M gene sequence, is located in the -35 cfrBIM promoter region and is in close vicinity of the -10 cfrBIR promoter region. A comparison of the cfrBIM and the cfrBIR promoter activities in the in vitro transcription system using methylated and unmethylated DNA fragments as templates demonstrated that the efficiency of CFR:BI R-M gene transcription is regulated by enzymatic modification at the N-4-position of cytosine bases of the CFR:BI site by M.CFR:BI. From the results of the in vivo and in vitro experiments we suggest a new model of gene expression regulation in type II R-M systems.

Rapid, sensitive, microbial detection by gene amplification using restriction endonuclease target sequences

The use of primers synthesized to eight class II restriction endonuclease target sequences, from Haemophilus parainfluenzae, Escherichia coli, Staphylococcus aureus, Salmonella infantis, Rhodobacter sphaeroides, Klebsiella pneumoniae, Bacillus amyloliquefaciens and Proteus vulgaris for single and multiplex PCR identification of the organisms is discussed. Results indicate that the method is sensitive and specific enough to detect single cells and attogram amounts of target DNA. It has also been demonstrated that the primers can be used in whole cell PCR for identification and whole cell PCR product recovery could be enhanced by the addition of gelatin or DMSO to PCR reaction mixtures. Other results have indicated that the method can be used for the definite identification of specific individuals present in mixed cultures or suspensions of organisms. The applicability of the method for detection of a specific strain within a group of closely related organisms has also been investigated and for that sequence/organism the results suggest that the proposed method is indeed very specific and discriminative. It is suggested that as more information becomes available regarding such sequences and their distribution, this approach could form the basis of a widescale, rapid, simple and cheap identification and/or typing system for bacteria.

REBASE--restriction enzymes and methylases

REBASE is a comprehensive database of information about restriction enzymes and their associated methylases, including their recognition and cleavage sites and their commercial availability. Information from REBASE is available via monthly electronic mailings as well as via WAIS and anonymous ftp. Specialized files are available that can be used directly by many software packages.