Two type I restriction enzymes from Salmonella species. Purification and DNA recognition sequences.

We have purified the type I restriction enzymes SB and SP from Salmonella typhimurium and S. potsdam, respectively, and determined the DNA sequences that they recognize. These sequences resemble those previously determined for the type I enzymes, EcoB, EcoK and EcoA, in that the specific part of the sequence is divided into two domains by a spacer of non-specific sequence that has a fixed length for each enzyme. Two main differences from the previously determined sequences are seen. Both of the new sequences are degenerate and one of them, SB, has one trinucleotide and one pentanucleotide-specific domain rather than the trinucleotide and tetranucleotide domains seen for all of the other enzymes. The only conserved features of the recognition sequences are the adenosyl residues that are methylated in the modification reaction. For all of the enzymes these are situated ten or 11 base-pairs apart, one on each strand of the DNA. This suggests that the enzymes bind to DNA along one face of the double helix making protein-DNA interaction in two successive major grooves with most of the non-specific spacer sequence in the intervening minor groove.

Type III DNA restriction and modification systems EcoP1 and EcoP15. Nucleotide sequence of the EcoP1 operon, the EcoP15 mod gene and some EcoP1 mod mutants.

This paper presents the nucleotide sequence of the mod-res operon of phage P1, which encodes the two structural genes for the EcoP1 type III restriction and modification system. We have also sequenced the mod gene of the allelic EcoP15 system. The mod gene product is responsible for binding the system-specific DNA recognition sequences in both restriction and modification; it also catalyses the modification reaction. A comparison of the two mod gene product sequences shows that they have conserved amino and carboxyl ends but have completely different sequences in the middle of the molecules. Two alleles of the EcoP1 mod gene that are defective in modification but not in restriction were also sequenced. The mutations in both alleles lie within the non-conserved regions.

EcoR124 and EcoR124/3: the first members of a new family of type I restriction and modification systems.

We have purified the EcoR124 and EcoR124/3 restriction enzymes and shown that they are type I enzymes by several criteria: subunit composition, DNA and S-adenosylmethionine-dependent ATPase activity, and site-specific DNA methylase activity. By immunochemical criteria these enzymes are related to each other but are unrelated to the two previously investigated families of type I restriction enzymes. They form therefore a new family which we call type IC. The arrangement of the structural genes coding for these enzymes and their transcriptional organisation have been determined. These are different from the common arrangement found for the other two families of type I enzymes.

A mutational analysis of the bacteriophage P1 cin recombinase gene: intragenic complementation.

Bacteriophage P1 encodes a site-specific recombinase, Cin, which regulates the alternate expression of tail fibre genes by inverting a DNA segment. To define regions of Cin important for the recombination process, we have isolated and characterised 24 different mutations of the cin gene. Most of these mutations affected amino acids that are highly conserved in other related recombinases. Some of these mutants complement each other in vivo. This intragenic complementation could be due to the assembly of heteromers containing both mutant proteins, suggesting that the active enzyme is at least a dimer.