Site-specific cleavage of DNA at 8-, 9-, and 10-bp sequences

The use of prokaryotic DNA methyltransferases as experimental and analytical tools in modern biology

Prokaryotic DNA methyltransferases (MTases) are used as experimental and research tools in molecular biology and molecular genetics due to their ability to recognize and transfer methyl groups to target bases in specific DNA sequences. As a practical tool, prokaryotic DNA MTases can be used in recombinant DNA technology for in vitro alteration and enhancing of cleavage specificity of restriction endonucleases. The ability of prokaryotic DNA MTases to methylate cytosine residues in specific sequences, which are also methylated in eukaryotic DNA, makes it possible to use them as analytical reagent for determination of the site-specific level of methylation in eukaryotic DNA. In vivo DNA methylation by prokaryotic DNA MTases is used in different techniques for probing chromatin structure and protein-DNA interactions. Additional prospects are opened by development of the methods of DNA methylation targeted to predetermined DNA sequences by fusion of DNA MTases to DNA binding proteins. This review will discuss the application of prokaryotic DNA MTases of Type II in the methods and approaches mentioned above.

Selective cleavage of human DNA: RecA-assisted restriction endonuclease (RARE) cleavage

Current methods for sequence-specific cleavage of large segments of DNA are severely limited because of the paucity of possible cleavage sites. A method is described whereby any Eco RI site can be targeted for specific cleavage. The technique is based on the ability of RecA protein from Escherichia coli to pair an oligonucleotide to its homologous sequence in duplex DNA and to form a three-stranded complex. This complex is protected from Eco RI methylase; after methylation and RecA protein removal, Eco RI restriction enzyme cleavage was limited to the site previously protected from methylation. When pairs of oligonucleotides are used, a specific fragment can be cleaved out of genomes. The method was tested on lambda phage, Escherichia coli, and human DNA. Fragments exceeding 500 kilobases in length and yields exceeding 80 percent could be obtained.

Cleaving yeast and Escherichia coli genomes at a single site

The 15-megabase pair Saccharomyces cerevisiae and the 4.7-megabase pair Escherichia coli genomes were completely cleaved at a single predetermined site by means of the Achilles' heel cleavage (AC) procedure. The symmetric lac operator (lacOs) was introduced into the circular Escherichia coli genome and into one of the 16 yeast chromosomes. Intact chromosomes from the resulting strains were prepared in agarose microbeads and methylated with Hha I (5'-GCGC) methyltransferase (M.Hha I) in the presence of lac repressor (LacI). All Hae II sites (5'-[sequence: see text]) with the exception of the one in lacOs, which was protected by LacI, were modified and thus no longer recognized by Hae II. After inactivation of M.Hha I and LacI, Hae II was used to completely cleave the chromosomes specifically at the inserted lacOs. These experiments demonstrate the feasibility of using the AC approach to efficiently extend the specificity of naturally occurring restriction enzymes and create new tools for the mapping and precise molecular dissection of multimegabase genomes.

Genetic transfer systems in Bacteroides: cloning and mapping of the transferable tetracycline-resistance locus

Conjugation systems that transfer antibiotic resistance in the absence of detectable plasmids are common in Bacteroides, but the mechanism of transfer is poorly understood. We found that linked transfer of tetracycline (TcR) and clindamycin (ClR) resistance by Bacteroides fragilis strain 1126 is induced by growth in either Tc or Cl. We cloned the transferable TcR locus as a 13 kb fragment on the shuttle vector pPH6 in Escherichia coli and showed that this region expresses TcR in Bacteroides but not E. coli. The TcR gene was mapped to a 3 kb region and the ClR gene was shown not to be present in the 13 kb insert. Homologous TcR genes are found in B. fragilis V479 and 1792. Using pulsed-field electrophoresis, the transferable TcR gene was shown to be physically associated with high molecular-weight DNA, suggesting that it is located on the chromosome. A new TcR shuttle vector, pPH7 delta 1.1, was constructed to facilitate use of this selective marker in Bacteroides genetics.

Enzymatic cleavage of a bacterial genome at a 10-base-pair recognition site

The circular genome of Staphylococcus aureus was cut into two fragments by a simple enzymatic method that cleaves a 10-base-pair site. The recognition sequence, A-T-C-G-mA decreases T-C-G-mA-T, was created by the combined use of the methylase M.Cla I (A-T-C-G-mA-T) and the restriction endonuclease Dpn I (G-mA decreases T-C). This technique is insensitive to CpG methylation and in human DNA is predicted to produce fragments that, on average, are greater than five million base pairs. The ability to create such long pieces of DNA should facilitate mapping of large, complex chromosomes.

The 5'-GGATCC-3' cleavage specificity of BamHI is increased to 5'-CCGGATCCGG-3' by sequential double methylation with M.HpaII and M.BamHI

Site-specific DNA methylation is known to block cleavage by a number of restriction endonucleases. We show that methylation at 'non-canonical' DNA modification sites can also block methylation by five of 13 DNA methyltransferases (MTases) tested. Furthermore, MTases and endonucleases that recognize the same nucleotide sequence can differ in their sensitivity to non-canonical methylation. In particular, BamHI endonuclease can cut 5'-GGATCm5C efficiently, whereas M.BamHI cannot methylate this modified sequence. Methyltransferase/endonuclease pairs which differ in their sensitivity to non-canonical methylation can be exploited to generate rare DNA cleavage sites. For example, we show that M.HpaII, M.BamHI, and BamHI can be used sequentially in a three-step procedure to specifically cleave DNA at the 10-bp sequence 5'-CCGGATCCGG. Several highly selective DNA cutting strategies are made possible by these sequential double methylation-blocking reactions.