Regulation of gene expression in type II restriction-modification system

Type II restriction-modification systems are comprised of a restriction endonuclease and methyltransferase. The enzymes are coded by individual genes and recognize the same DNA sequence. Endonuclease makes a double-stranded break in the recognition site, and methyltransferase covalently modifies the DNA bases within the recognition site, thereby down-regulating endonuclease activity. Coordinated action of these enzymes plays a role of primitive immune system and protects bacterial host cell from the invasion of foreign (for example, viral) DNA. However, uncontrolled expression of the restriction-modification system genes can result in the death of bacterial host cell because of the endonuclease cleavage of host DNA. In the present review, the data on the expression regulation of the type II restriction-modification enzymes are discussed.     

Regulation of gene expression in a type II restriction-modification system

Type II restriction-modification systems are comprised of a restriction endonuclease and methyltransferase. The enzymes are coded by individual genes and recognize the same DNA sequence. Endonuclease makes a double-stranded break in the recognition site, and methyltransferase covalently modifies DNA bases within the recognition site, thereby preventing cleavage by the endonuclease. The concerted action of these enzymes plays the role of a primitive immune system and protects the bacterial host cell from invasion by foreign (for example, viral) DNA. However, uncontrolled expression of restriction-modification system genes can result in the death of a bacterial host cell because of endonuclease cleavage of the host DNA. In the present review, data on the regulation of expression of the type II restriction-modification enzymes genes are discussed.     

Cloning, nucleotide sequence, and expression of the HincII restriction-modification system.

Two genes, coding for the HincII from Haemophilus influenzae Rc restriction-modification system, were cloned and expressed in Escherichia coli RR1. Their DNA sequences were determined. The HincII methylase (M.HincII) gene was 1,506 base pairs (bp) long, corresponding to a protein of 502 amino acid residues (Mr = 55,330). The HincII endonuclease (R.HincII) gene was 774 bp long, corresponding to a protein of 258 amino acid residues (Mr = 28,490). The amino acid residues predicted from the R.HincII and the N-terminal amino acid sequence of the enzyme found by analysis were identical. These methylase and endonuclease genes overlapped by 1 bp on the H. influenzae Rc chromosomal DNA. The clone, named E. coli RR1-Hinc, overproduced R.HincII. The R.HincII activity of this clone was 1,000-fold that from H. influenzae Rc. The amino acid sequence of M.HincII was compared with the sequences of four other adenine-specific type II methylases. Important homology was found between tne M.HincII and these other methylases.     

Nucleotide sequence of the DdeI restriction-modification system and characterization of the methylase protein.

The DdeI restriction-modification system was previously cloned and has been maintained in E. coli on two separate and compatible plasmids (1). The nucleotide sequence of the endonuclease and methylase genes has now been determined; it predicts proteins of 240 amino acids, Mr = 27,808, and 415 amino acids, Mr = 47,081, respectively. Inspection of the DNA sequence shows that the 3' end of the methylase gene had been deleted during cloning. The clone containing the complete methylase gene was made and compared to that containing the truncated gene; only clones containing the truncated form support the endonuclease gene in E. coli. Bal-31 deletion studies show that methylase expression in the Dde clones is also dependent upon orientation of the gene with respect to pBR322. The truncated and complete forms of the methylase protein were purified and compared; the truncated form appears to be more stable and active in vitro. Finally, comparison of the deduced amino acid sequence of M. DdeI with that of other known cytosine methylases shows significant regions of homology.     

The unique FauI restriction-modification system: cloning and comparative analysis of protein structure

The nucleotide sequence was established for the full-length Flavobacterium aquatile operon coding for the FauI restriction-modification system. The operon is unusual in structure and has the gene order control protein gene-DNA methyltransferase A gene-restriction endonuclease gene-DNA methyltransferase B gene, other than in the known analogs. The genes are similarly oriented and overlap. On evidence of sequence analysis, both methyltransferases are C5 enzymes, the control protein is similar to that of other restriction-modification systems, and restriction endonuclease is low-homologous to other enzymes cleaving the DNA upper strand in position 4 or 5 relative to the recognition site.     

IS-linked movement of a restriction-modification system

Potential mobility of restriction-modification systems has been suggested by evolutionary/bioinformatic analysis of prokaryotic genomes. Here we demonstrate in vivo movement of a restriction-modification system within a genome under a laboratory condition. After blocking replication of a temperature-sensitive plasmid carrying a PaeR7I restriction-modification system in Escherichia coli cells, the plasmid was found integrated into the chromosome of the surviving cells. Sequence analysis revealed that, in the majority of products, the restriction-modification system was linked to chromosomal insertion sequences (ISs). Three types of products were: (I) apparent co-integration of the plasmid and the chromosome at a chromosomal IS1 or IS5 copy (24/28 analyzed); (II) de novo insertion of IS1 with the entire plasmid except for a 1-3 bp terminal deletion (2/28); and (III) reciprocal crossing-over between the plasmid and the chromosome involving 1-3 bp of sequence identity (2/28). An R-negative mutation apparently decreased the efficiency of successful integration by two orders of magnitude. Reconstruction experiments demonstrated that the restriction-dependence was mainly due to selection against cells without proper integration: their growth was inhibited by the restriction enzyme action. These results demonstrate collaboration of a mobile element and a restriction-modification system for successful joint migration. This collaboration may have promoted the spread and, therefore, the long-term persistence of these complexes and restriction-modification systems in a wide range of prokaryotes.     

Cloning and expression of the HpaI restriction-modification genes.

The genes from Haemophilus parainfluenzae encoding the HpaI restriction-modification system were cloned and expressed in Escherichia coli. From the DNA sequence, we predicted the HpaI endonuclease (R.HpaI) to have 254 amino acid residues (Mr 29,630) and the HpaI methyltransferase (M.HpaI) to have 314 amino acid residues (37,390). The R.HpaI and M.HpaI genes overlapped by 16 base pairs on the chromosomal DNA. The genes had the same orientation. The clone, named E. coli HB101-HPA2, overproduced R.HpaI. R.HpaI activity from the clone was 100-fold that from H. parainfluenzae. The amino acid sequence of M.HpaI was compared with those of other type II methyltransferases.     

DNA restriction dependent on two recognition sites: activities of the SfiI restriction-modification system in Escherichia coli

In contrast to many type II restriction enzymes, dimeric proteins that cleave DNA at individual recognition sites 4-6 bp long, the SfiI endonuclease is a tetrameric protein that binds to two copies of an elongated sequence before cutting the DNA at both sites. The mode of action of the SfiI endonuclease thus seems more appropriate for DNA rearrangements than for restriction. To elucidate its biological function, strains of Escherichia coli expressing the SfiI restriction-modification system were transformed with plasmids carrying SfiI sites. The SfiI system often failed to restrict the survival of a plasmid with one SfiI site, but plasmids with two or more sites were restricted efficiently. Plasmids containing methylated SfI sites were not restricted. No rearrangements of the plasmids carrying SfiI sites were detected among the transformants. Hence, provided the target DNA contains at least two recognition sites, SfiI displays all of the hallmarks of a restriction-modification system as opposed to a recombination system in E. coli cells. The properties of the system in vivo match those of the enzyme in vitro. For both restriction in vivo and DNA cleavage in vitro, SfiI operates best with two recognition sites on the same DNA.     

Mycoplasma restriction-modification system MunI and its possible role in pathogenesis processes]

The restriction-modification system, named RMMunI, has been purified and characterised from Friend murine erythroleukemia cells. The site-specific endonuclease recognizes and cleaves the 5'C1AATTG nucleotide sequence. RMunI is an isoschizomer of RMfeI from Mycoplasma fermentans. Site-specific methylase modifies the second adenine residue in the same sequence (5'Cam6ATTG). It was established that the discovered enzymatic system is from mycoplasma which contaminates cell lines. Mycoplasma's DNA hybridizes with species-specific DNA probed for Mycoplasma fermentans and Mycoplasma arginini. The possible role of mycoplasmic restriction-modification enzymes in the process of acquired immune deficiency syndrome are discussed.     

MmeI: a minimal Type II restriction-modification system that only modifies one DNA strand for host protection

MmeI is an unusual Type II restriction enzyme that is useful for generating long sequence tags. We have cloned the MmeI restriction-modification (R-M) system and found it to consist of a single protein having both endonuclease and DNA methyltransferase activities. The protein comprises an amino-terminal endonuclease domain, a central DNA methyltransferase domain and C-terminal DNA recognition domain. The endonuclease cuts the two DNA strands at one site simultaneously, with enzyme bound at two sites interacting to accomplish scission. Cleavage occurs more rapidly than methyl transfer on unmodified DNA. MmeI modifies only the adenine in the top strand, 5′-TCCRAC-3′. MmeI endonuclease activity is blocked by this top strand adenine methylation and is unaffected by methylation of the adenine in the complementary strand, 5′-GTYGGA-3′. There is no additional DNA modification associated with the MmeI R-M system, as is required for previously characterized Type IIG R-M systems. The MmeI R-M system thus uses modification on only one of the two DNA strands for host protection. The MmeI architecture represents a minimal approach to assembling a restriction-modification system wherein a single DNA recognition domain targets both the endonuclease and DNA methyltransferase activities.     

Comparative study of the M.Bstf5I-1 and M.BstF5I-3 DNA methyltransferases from the Bacillus stearothermophilus F5 restriction-modification system

The BstF5I restriction-modification system from Bacillus stearothermophilus F5, unlike all known restriction-modification systems, contains three genes encoding DNA methyltransferases. In addition to revealing two DNA methylases responsible for modification of adenine in different DNA strands, it has been first shown that one bacterial cell has two DNA methylases, M.BstF5I-1 and M.BstF5I-3, with similar substrate specificity. The boundaries of the gene for DNA methyltransferase M.BstF5I-1 have been verified. The bstF5IM-1 gene was cloned in pJW and expressed in Escherichia coli. Homogeneous samples of M.BstF5I-1 and M.BstF5I-3 were obtained by chromatography with different sorbents. The main kinetic parameters have been determined for M.BstF5I-1 and M.BstF5I-3, both modifying adenine in the recognition site 5'-GGATG-3'.     

Mobility of a restriction-modification system revealed by its genetic contexts in three hosts

The flow of genes among prokaryotes plays a fundamental role in shaping bacterial evolution, and restriction-modification systems can modulate this flow. However, relatively little is known about the distribution and movement of restriction-modification systems themselves. We have isolated and characterized the genes for restriction-modification systems from two species of Salmonella, S. enterica serovar Paratyphi A and S. enterica serovar Bareilly. Both systems are closely related to the PvuII restriction-modification system and share its target specificity. In the case of S. enterica serovar Paratyphi A, the restriction endonuclease is inactive, apparently due to a mutation in the subunit interface region. Unlike the chromosomally located Salmonella systems, the PvuII system is plasmid borne. We have completed the sequence characterization of the PvuII plasmid pPvu1, originally from Proteus vulgaris, making this the first completely sequenced plasmid from the genus Proteus. Despite the pronounced similarity of the three restriction-modification systems, the flanking sequences in Proteus and Salmonella are completely different. The SptAI and SbaI genes lie between an equivalent pair of bacteriophage P4-related open reading frames, one of which is a putative integrase gene, while the PvuII genes are adjacent to a mob operon and a XerCD recombination (cer) site.     

Cytosine methylation by the SuaI restriction-modification system: implications for genetic fidelity in a hyperthermophilic archaeon

5-methylcytosine in chromosomal DNA represents a potential source of frequent spontaneous mutation for hyperthermophiles. To determine the relevance of this threat for the archaeon Sulfolobus acidocaldarius, the mode of GGCC methylation by its restriction-modification system, SuaI, was investigated. Distinct isoschizomers of the SuaI endonuclease were used to probe the methylation state of GGCC in native S. acidocaldarius DNA. In addition, the methylation sensitivity of the SuaI endonuclease was determined with synthetic oligonucleotide substrates and modified natural DNAs. The results show that the SuaI system uses N(4) methylation to block cleavage of its recognition site, thereby avoiding the creation of G. T mismatches by spontaneous deamination at extremely high temperature.     

Structure and evolution of the XcyI restriction-modification system.

The XcyI restriction-modification system from Xanthomonas cyanopsidis recognizes the sequence, CCCGGG. The XcyI endonuclease and methylase genes have been cloned and sequenced and were found to be aligned in a head to tail orientation with the methylase preceding and overlapping the endonuclease by one base pair. The nucleotide sequence codes for an N4 cytosine methyltransferase with a predicted molecular weight of 33,500 and an endonuclease comprised of 333 codons and a molecular weight of 36,600. Sequence comparisons revealed significant similarity between the XcyI, CfrI and SmaI methylisomers. In contrast, no similarity was detected between the primary structures of the XcyI and SmaI endonucleases. The XcyI restriction-modification system is highly homologous to the XmaI genes, although the DNA sequences flanking the genes rapidly diverge. The sequence of the XcyI endonuclease contains two motifs which have recently been identified as essential to the activity of the EcoRV endonuclease.     

Cloning and expression of the BalI restriction-modification system.

BalI, a type II restriction-modification (R-M) system from the bacterium, Brevibacterium albidum, recognizes the DNA sequence 5'-TGGCCA-3'. We cloned the genes encoding the BalI restriction endonuclease and methyltransferase and expressed them in Escherichia coli. The two genes were aligned tail-to-tail and their termination codons overlapped. BalI restriction endonuclease and methyltransferase comprise 260 and 280 amino acids, respectively, and have molecular weights of 29 043 and 31 999 Da. The amino acid sequence of BalI methyltransferase is similar to that of other m6A MTases, although it has been categorized as a m5C methyltransferase. A high expression system for the BalI restriction endonuclease was constructed in E. coli for the production of large quantities of enzyme.     

Characterization of a novel unique restriction-modification system from Yersinia enterocolitica O:8 1B

Genetic manipulations with enteropathogenic Yersinia enterocolitica O:8 are complicated by the presence of an efficient PstI-like YenI restriction-modification (R-M) system. We have characterized the YenI R-M system in Y. enterocolitica O:8, biotype 1B. A 5039 bp DNA fragment of the pSAK2 recombinant plasmid carrying the yenI locus was used to determine the nucleotide sequence. DNA sequence analysis identified a single 2481 bp open reading frame (ORF) that encodes an 826 amino acid large polypeptide having an apparent molecular mass of 93 kDa. The N-terminal part of the YenI ORF has 45 and 40% identity to PstI and BsuI methyltransferases (MTases), respectively; while the C-terminal part depicts 55 and 45% identity to endonucleases (ENases) of both isoschyzomeric enzymes. The yenI gene was cloned into pT7-5 plasmid and has been shown to encode a single polypeptide of expected molecular mass. A specific recognition sequence, typical to the type II R-M systems and single peptide organization, typical to type IV R-M systems, make YenI unique among known restriction-modification systems. We have constructed a truncated recombinant variant of YenI enzyme, which conserved only MTase activity, and that can be applied to YenI methylation of the DNA to be transformed into Y. enterocolitica O:8 biotype 1B strains.     

The SalI (SalGI) restriction-modification system of Streptomyces albus G

The salIR and salM genes of Streptomyces albus G specify the SalGI (SalI) restriction enzyme and its cognate methyltransferase, respectively. These enzymes are responsible for restriction and modification of bacteriophages. Some phages carry genes that interfere with SalI-specific modification. The sal genes have been cloned in a Streptomyces host-vector system. Use of the cloned DNA as a hybridization probe reveals that sal mutants frequently arise from transposition of a DNA segment of approx. 1 kb into the sal genes. Some, but not all, other bacteria that produce SalGI isoschizomers contain nucleotide sequences that hybridize with sal DNA.     

Substrate specificity and biochemical properties of M3.BstF5I DNA methyltransferase from the BstF5I restriction-modification system

Optimal conditions for DNA methylation by the M3.BstF5I enzyme from Bacillus stearothermophilus and kinetic parameters of λ phage DNA modification and that of a number of oligonucleotide substrates are established. Comparison of M1.BstF5I and M3.BstF5I kinetic parameters revealed that with similar temperature optima and affinity for DNA, M3.BstF5I has nearly fourfold lower turnover number (0.24 min⁻¹) and modifies the hemimethylated recognition site with lower efficiency under optimal conditions than the unmethylated one. In contrast to another three methylases of the BstF5I restriction-modification system, the M3.BstF5I enzyme is able to optionally modify the noncanonical 5′-GGATC-3′ DNA sequence with a rate more than one order of magnitude lower than the methylation rate of the canonical 5′-GGATG-3′ recognition site.