Discovery and distribution of super-integrons among pseudomonads.

Until recently, integrons (systems for acquisition and expression of new genetic materials) have been associated generally with antibiotic resistance gene cassettes. The discovery of 'super-integrons' in Vibrionaceae suggests a greater impact of this gene acquisition mechanism on bacterial genome evolution than initially believed. Super-integrons may contain more than 100 gene cassettes and may encode other determinants, including biochemical functions or virulence factors. Here, we report the genetic organization of a super-integron from Pseudomonas alcaligenes ATCC 55044. This is the first evidence of a super-integron in a non-pathogenic bacterium, one which is widely distributed in a great number of ecological niches such as soil and aquatic habitats. Here, the sequence composition, open reading frame (ORF) content and organization of In55044 are described and found to have features intermediate between the multidrug-resistant integrons and the Vibrio cholerae super-integron. Similar structures are inferred to be present in several Pseudomonas species, based on polymerase chain reaction (PCR) experiments.

Methyl-specific DNA binding by McrBC, a modification-dependent restriction enzyme.

McrBC, a GTP-requiring, modification-dependent endonuclease of Escherichia coli K-12, specifically recognizes DNA sites of the form 5' R(m)C 3'. DNA cleavage normally requires translocation-mediated coordination between two such recognition elements at distinct sites. We have investigated assembly of the cleavage-competent complex with gel-shift and DNase I footprint analysis. In the gel-shift system, McrB(L) binding resulted in a fast-migrating specific shifted band, in a manner requiring both GTP and Mg(2+). The binding was specific for methylated DNA and responded to local sequence changes in the same way that cleavage does. Single-stranded DNA competed for McrB(L)-binding in a modification and sequence-specific fashion. A supershifted species was formed in the presence of McrC and GTPgammaS. DNase I footprint analysis showed modest cooperativity in binding to two sites, and a two-site substrate displayed protection in non-specific spacer DNA in addition to the recognition elements. The addition of McrC did not affect the footprint obtained. We propose that McrC effects a conformational change in the complex rather than a reorganization of the DNA:protein interface.

A simple in vitro Tn7-based transposition system with low target site selectivity for genome and gene analysis.

A robust Tn7-based in vitro transposition system is described that displays little target site selectivity, allowing the efficient recovery of many different transposon insertions in target DNAs ranging from small plasmids to cosmids to whole genomes. Two miniTn7 derivatives are described that are useful for the analysis of genes: one a derivative for making translational and transcriptional target gene fusions and the other a derivative that can generate 15 bp (5 amino acid) insertions in target DNAs (proteins).

Molecular evolution of the Escherichia coli chromosome. V. Recombination patterns among strains of diverse origin.

Incorporation patterns of donor DNA into recipient chromosomes following transduction or conjugation have been studied in the progeny of a variety of Escherichia coli crosses in which donor and recipient nucleotide sequences differ by 1-3%. Series of contiguous or variously spaced PCR fragments have been amplified from each recombinant chromosome and digested with a commercial restriction endonuclease previously shown to distinguish the respective parents in a given fragment. We conclude that entering donor DNA fragments are frequently abridged (cut and shortened) before incorporation, the cutting being due to restriction systems, and the shortening presumably due to exonuclease activity. Analysis of several backcrosses confirms, and extends to conjugation, the importance of restriction in E. coli recombination in nature. The transmission patterns in conjugation are similar to those of transduction, but (as expected) on a much larger scale. Asymmetric results of reciprocal crosses imply that mismatch frequency is not a major factor. Marked differences among the results of simple crosses according to parental strain combinations are consistent with observations that E. coli strains in nature vary dramatically in their restriction-modification systems.

The McrBC endonuclease translocates DNA in a reaction dependent on GTP hydrolysis.

McrBC specifically recognizes and cleaves methylated DNA in a reaction dependent on GTP hydrolysis. DNA cleavage requires at least two recognition sites that are optimally separated by 40-80 bp, but can be spaced as far as 3 kb apart. The nature of the communication between two recognition sites was analyzed on DNA substrates containing one or two recognition sites. DNA cleavage of circular DNA required only one methylated recognition site, whereas the linearized form of this substrate was not cleaved. However, the linearized substrate was cleaved if a Lac repressor was bound adjacent to the recognition site. These results suggest a model in which communication between two remote sites is accomplished by DNA translocation rather than looping. A mutant protein with defective GTPase activity cleaved substrates with closely spaced recognition sites, but not substrates where the sites were further apart. This indicates that McrBC translocates DNA in a reaction dependent on GTP hydrolysis. We suggest that DNA cleavage occurs by the encounter of two DNA-translocating McrBC complexes, or can be triggered by non-specific physical obstacles like the Lac repressor bound on the enzyme's path along DNA. Our results indicate that McrBC belongs to the general class of DNA "motor proteins", which use the free energy associated with nucleoside 5'-triphosphate hydrolysis to translocate along DNA.

McrBs, a modulator peptide for McrBC activity.

McrBC is a methylation-dependent endonuclease from Escherichia coli K-12. The enzyme recognizes DNA with modified cytosines preceded by a purine. McrBC restricts DNA that contains at least two methylated recognition sites separated by 40-80 bp. Two gene products, McrBL and McrBs, are produced from the mcrB gene and one, McrC, from the mcrC gene. DNA cleavage in vitro requires McrBL, McrC, GTP and Mg2+. We found that DNA cleavage was optimal at a ratio of 3-5 McrBL per molecule of McrC, suggesting that formation of a multisubunit complex with several molecules of McrBL is required for cleavage. To understand the role of McrBs, we have purified the protein and analyzed its role in vitro. At the optimal ratio of 3-5 McrBL per molecule of McrC, McrBs acted as an inhibitor of DNA cleavage. Inhibition was due to sequestration of McrC and required the presence of GTP, suggesting that the interaction is GTP dependent. If McrC was in excess, a condition resulting in suboptimal DNA cleavage, addition of McrBs enhanced DNA cleavage, presumably due to sequestration of excess McrC. We suggest that the role of McrBs is to modulate McrBC activity by binding to McrC.

Dependence of McrBC cleavage on distance between recognition elements.

DNA cleavage by the modification-dependent restriction enzyme McrBC requires the presence of two suitably modified recognition elements appropriately spaced in the substrate. To characterize the spacing requirement in more detail, we have constructed a plasmid with a single McrBC cleavage site, in which the distance between recognition elements could be systematically varied while preserving the local sequence surrounding the recognition elements. Optimal separation between elements was 55-103 basepairs, with detectable cleavage observed at spacing of 32 bp to 2 kb; no cleavage was seen with spacing of 22 bp or less or with 3 kb between elements. Changing the spacing by 4 basepairs within the optimal range had little effect on the efficiency of cleavage, suggesting that the recognition elements need not lie on the same face of the DNA helix.

On the regulation and diversity of restriction in Escherichia coli.

The effect of UV irradiation on restriction mediated by four endogenous restriction systems of E. coli K-12 was investigated using a uniform testing method. Restriction by all four systems was reduced when treated cells were separately challenged with lambda phage carrying modification patterns that elicit restriction by each system. The response of each system was genetically and physiologically distinct.

Response to UV damage by four Escherichia coli K-12 restriction systems.

To understand the role of restriction in regulating gene flow in bacterial populations, we would like to understand the regulation of restriction enzyme activity. Several antirestriction (restriction alleviation) systems are known that reduce the activity of type I restriction enzymes like EcoKI in vivo. Most of these do not act on type II or type III enzymes, but little information is available for the unclassified modification-dependent systems, of which there are three in E. coli K-12. Of particular interest are two physiological controls on type I enzymes: EcoKI restriction is reduced 2 to 3 orders of magnitude following DNA damage, and a similar effect is seen constitutively in Dam- cells. We used the behavior of EcoKI as a control for testing the response to UV treatment of the three endogenous modification-dependent restriction systems of K-12, McrA, McrBC, and Mrr. Two of these were also tested for response to Dam status. We find that all four resident restriction systems show reduced activity following UV treatment, but not in a unified fashion; each response was genetically and physiologically distinct. Possible mechanisms are discussed.

Organization and function of the mcrBC genes of Escherichia coli K-12.

Many natural DNA sequences are restricted in Escherichia coli K-12, not only by the classic Type I restriction system EcoK, but also by one of three modification-specific restriction systems found in K-12. The McrBC system is the best studied of these. We infer from the base composition of the mcrBC genes that they were imported from an evolutionarily distant source. The genes are located in a hypervariable cluster of restriction genes that may play a significant role in generation of species identity in enteric bacteria. Restriction activity requires the products of two genes for activity both in vivo and in vitro. The mcrB gene elaborates two protein products, only one of which is required for activity in vitro, but both of which contain a conserved amino acid sequence motif identified as a possible GTP-binding site. The mcrC gene product contains a leucine heptad repeat that could play a role in protein-protein interactions. McrBC activity in vivo and in vitro depends on the presence of modified cytosine in a specific sequence context; three different modifications are recognized. The in vitro activity of this novel multi-subunit restriction enzyme displays an absolute requirement for GTP as a cofactor.

McrBC: a multisubunit GTP-dependent restriction endonuclease.

McrBC-mediated restriction of modified DNA has been studied extensively by genetic methods, but little is known of its molecular action. We have used overproducing plasmid constructs to facilitate purification of the McrBL and McrC proteins, and report preliminary characterization of the activity of the complex. Both proteins are required for cleavage of appropriately modified DNA in vitro, in a reaction absolutely dependent on GTP. ATP inhibits the reaction. The sequence and modification requirements for cleavage of the substrate reflect those seen in vivo. The position of cleavage was examined at the nucleotide level, revealing that cleavage occurs at multiple positions in a small region. Based upon these observations, and upon cleavage of model oligonucleotide substrates, it is proposed that the recognition site for this enzyme consists of the motif RmC(N40-80)RmC, with cleavage occurring at multiple positions on both strands, between the modified C residues. In subunit composition, cofactor requirement, and relation between cleavage and recognition site, McrBC does not fit into any of the classes (types I to IV) of restriction enzyme so far described.

A novel activity in Escherichia coli K-12 that directs restriction of DNA modified at CG dinucleotides.

The restriction systems McrA and McrB of Escherichia coli K-12 are known to attack DNA containing modified cytosine. In strains lacking both activities, however, we observed that DNA methylated at CG dinucleotides (as is mammalian DNA) was still significantly restricted. We show that this substantial barrier to the acceptance of 5-methylcytosine-containing DNA is attributable to a hitherto unknown activity of the Mrr restriction system. Strikingly, the multiple systems used by this gut inhabitant to determine the fate of invading DNA will all limit genetic exchange with its mammalian host(s), reinforcing the idea that one role of DNA methylation is to serve as a "molecular passport" (E. A. Raleigh, R. Trimarchi, and H. Revel, Genetics 122:279-296, 1989).

Nomenclature relating to restriction of modified DNA in Escherichia coli.

At least three restriction systems that attack DNA containing naturally modified bases have been found in common Escherichia coli K-12 strains. These systems are McrA, McrBC, and Mrr. A brief summary of the genetic and phenotypic properties so far observed in laboratory strains is set forth, together with a proposed nomenclature for describing these properties.

Genetic and sequence organization of the mcrBC locus of Escherichia coli K-12.

The mcrB (rglB) locus of Escherichia coli K-12 mediates sequence-specific restriction of cytosine-modified DNA. Genetic and sequence analysis shows that the locus actually comprises two genes, mcrB and mcrC. We show here that in vivo, McrC modifies the specificity of McrB restriction by expanding the range of modified sequences restricted. That is, the sequences sensitive to McrB(+)-dependent restriction can be divided into two sets: some modified sequences containing 5-methylcytosine are restricted by McrB+ cells even when McrC-, but most such sequences are restricted in vivo only by McrB+ McrC+ cells. The sequences restricted only by McrB+C+ include T-even bacteriophage containing 5-hydroxymethylcytosine (restriction of this phage is the RglB+ phenotype), some sequences containing N4-methylcytosine, and some sequences containing 5-methylcytosine. The sequence codes for two polypeptides of 54 (McrB) and 42 (McrC) kilodaltons, whereas in vitro translation yields four products, of approximately 29 and approximately 49 (McrB) and of approximately 38 and approximately 40 (McrC) kilodaltons. The McrB polypeptide sequence contains a potential GTP-binding motif, so this protein presumably binds the nucleotide cofactor. The deduced McrC polypeptide is somewhat basic and may bind to DNA, consistent with its genetic activity as a modulator of the specificity of McrB. At the nucleotide sequence level, the G+C content of mcrBC is very low for E. coli, suggesting that the genes may have been acquired recently during the evolution of the species.

Genetic and physical mapping of the mcrA (rglA) and mcrB (rglB) loci of Escherichia coli K-12.

We have genetically analyzed, cloned and physically mapped the modified cytosine-specific restriction determinants mcrA (rglA) and mcrB (rglB) of Escherichia coli K-12. The independently discovered Rgl and Mcr restriction systems are shown to be identical by three criteria: 1) mutants with the RglA- or RglB- phenotypes display the corresponding McrA- or McrB- phenotypes, and vice versa; 2) the gene(s) for RglA and McrA reside together at one locus, while gene(s) for RglB and McrB are coincident at a different locus; and 3) RglA+ and RglB+ recombinant clones complement for the corresponding Mcr-deficient lesions. The mcrA (rglA) gene(s) is on the excisable element e14, just clockwise of purB at 25 min. The mcrB (rglB) gene(s), at 99 min, is in a cluster of restriction functions that includes hsd and mrr, determinants of host-specific restriction (EcoK) and methyladenine-specific restriction respectively. Gene order is mcrB-hsdS-hsdM-hsdR-mrr-serB. Possible models for the acqusition of these restriction determinants by enteric bacteria are discussed.

McrA and McrB restriction phenotypes of some E. coli strains and implications for gene cloning.

The McrA and McrB (modified cytosine restriction) systems of E. coli interfere with incoming DNA containing methylcytosine. DNA from many organisms, including all mammalian and plant DNA, is expected to be sensitive, and this could interfere with cloning experiments. The McrA and B phenotypes of a few strains have been reported previously (1-4). The Mcr phenotypes of 94 strains, primarily derived from E. coli K12, are tabulated here. We briefly review some evidence suggesting that McrB restriction of mouse-modified DNA does occur in vivo and does in fact interfere with cloning of specific mouse sequences.

Physical analysis of Tn10- and IS10-promoted transpositions and rearrangements.

We have investigated by Southern blot hybridization the rate of IS10 transposition and other Tn10/IS10-promoted rearrangements in Escherichia coli and Salmonella strains bearing single chromosomal insertions of Tn10 or a related Tn10 derivative. We present evidence for three primary conclusions. First, the rate of IS10 transposition is approximately 10(-4) per cell per bacterial generation when overnight cultures are grown and plated on minimal media and is at least ten times more frequent than any other Tn10/IS10-promoted DNA alteration. Second, all of the chromosomal rearrangements observed can be accounted for by two previously characterized Tn10-promoted rearrangements: deletion/inversions and deletions. Together these rearrangements occur at about 10% the rate of IS10 transposition. Third, the data suggest that intramolecular Tn10-promoted rearrangements preferentially use nearby target sites, while the target sites for IS10 transposition events are scattered randomly around the chromosome.