Nucleotide sequence of the chi recombinational hot spot chi +D in bacteriophage lambda.

Chi sites in bacteriophage lambda stimulate recombination promoted by the RecBC pathway of Escherichia coli. Mutations which create these sites occur at four widely separated loci in lambda. We report here the nucleotide sequence surrounding the site of one of these loci, chi D, located near the S gene. The mutations creating the active Chi site, designated chi +D, are transversions from CG to AT. This mutation, like the chi +B and chi +C mutations previously analyzed, leads to a nucleotide sequence common to all three active chi sites.     

General recombination in Escherichia coli K-12: in vivo role of RecBC enzyme.

Heterozygous lacZ- merodiploids of Escherichia coli K-12 have been used to study the role of the RecBC enzyme in general recombination. The transcribable intermediate assay detects the product of early steps in recombination without requiring the formation of viable recombinant colonies. Recombination is initiated by infection with lambda precA+. We have found that transcribable intermediate formation in crosses between F42 lac and chromosomal lac is dependent on F fertility functions and an active RecBC enzyme. Thus, the products of the recB and recC genes are required in early steps of recombination between these two substrates. Introduction of the F42 lac donor DNA by conjugation immediately after infection with lambda precA+ abolishes the requirement for an active RecBC enzyme.     

Recombination Pathway Specificity of Chi

Chi in phage lambda is a genetic element increasing the rate of recombination in its vicinity. Chi activity requires the wild-type functions of both the recA and the recB genes of E. coli. In terms of the pathway concept for recombination, Chi is active in the RecBC pathway and inactive in the Red, RecE., and RecF pathways.     

Cutting of chi-like sequences by the RecBCD enzyme of Escherichia coli

Chi, 5' G-C-T-G-G-T-G-G 3', stimulates coliphage lambda recombination mediated by the major recombination pathway of Escherichia coli, the RecBC pathway. Purified RecBCD enzyme makes a single strand endonuclease cleavage four to six nucleotides to the 3' side of the chi sequence. Three sequences similar to chi, 5' A-C-T-G-G-T-G-G 3', 5' G-T-T-G-G-T-G-G 3' and 5' G-C-T-A-G-T-G-G 3', have partial recombinational hotspot activity in genetic crosses. We report here that purified RecBCD enzyme preferentially cuts four nucleotides to the right of the two most active chi-like octamers. The degree of cutting correlated with the genetic activities of these sequences; this result indicates that these cleavages are essential to the genetic activity of chi and chi-like sequences.     

Escherichia coli RecBC pseudorevertants lacking chi recombinational hotspot activity

Pseudorevertants of an Escherichia coli exonuclease V (RecBC enzyme)-negative mutant have been isolated after ethyl methane sulfonate mutagenesis of a recC73 (presumed missense) mutant. The remedial mutations in each of the four pseudorevertants studied in detail map and complement as recC mutations. By several criteria, such as recombination proficiency, support of phage growth, RecBC nuclease activity, and cell viability, the pseudorevertants appear to have regained partially or completely various aspects of RecBC activity. However, chi recombinational hotspots, which stimulate exclusively the RecBC pathway of recombination, have no detectable activity in lambda vegetative crosses in the pseudorevertants. The properties of these mutants, in which the RecBC pathway of recombination is active yet in which chi is not active, are consistent with the hypothesis that wild-type RecBC enzyme directly interacts with chi sites; alternatively, the mutants may block or bypass the productive interaction of another recombinational enzyme with chi.     

Recombinational hotspot activity of Chi-like sequences

Chi sites, consisting of the nucleotide octamer 5' G-C-T-G-G-T-G-G 3', stimulate coliphage lambda recombination mediated by the Escherichia coli RecBC recombination pathway. In a sensitive genetic assay using phage lambda crosses, three of four Chi-like sequences tested, namely 5' A-C-T-G-G-T-G-G 3', 5' G-T-T-G-G-T-G-G 3' and 5' G-C-T-A-G-T-G-G 3', had about 6%, 11% and 38% of full Chi activity, respectively. We conclude that certain Chi-like sequences manifest a spectrum of recombinational hotspot activities and may account for RecBC-mediated generalized recombination of lambda lacking Chi sites.     

Genetic Functions Promoting Homologous Recombination in Escherichia coli: A Study of Inversions in Phage λ

We have studied homologous recombination in a derivative of phage lambda containing two 1.4-kb repeats in inverted orientation. Inversion of the intervening 2.5-kb segment occurred efficiently by the Escherichia coli RecBC pathway but markedly less efficiently by the lambda Red pathway or the E. coli RecE or RecF pathways. Inversion by the RecBCD pathway was stimulated by Chi sites located to the right of the invertible segment; this stimulation decreased exponentially by a factor of about 2 for each 2.2 kb between the invertible segment and the Chi site. In addition to RecA protein and RecBCD enzyme, inversion by the RecBC pathway required single-stranded DNA binding protein, DNA gyrase, DNA polymerase I and DNA ligase. Inversion appeared to occur either intra- or intermolecularly. These results are discussed in the framework of a current molecular model for the RecBC pathway of homologous recombination.     

Chi-dependent DNA strand cleavage by RecBC enzyme

Chi sites enhance in their vicinity homologous recombination by the E. coli RecBC pathway. We report here that RecBC enzyme catalyzes Chi-dependent cleavage of one DNA strand, that containing the Chi sequence 5'G-C-T-G-G-T-G-G3'. Chi-specific cleavage is greatly reduced by single base pair changes within the Chi sequence and by mutations within the E. coli recC gene, coding for a RecBC enzyme subunit. Although cleavage occurs preferentially with double-stranded DNA, the product of the reaction is single-stranded DNA. These results demonstrate the direct interaction of RecBC enzyme with Chi sites that was inferred from the genetic properties of Chi and recBC, and they support models of recombination in which Chi acts before the initiation of strand exchange.     

Chi Mutation in a Transposon and the Orientation-Dependence of Chi Phenotype

Chi, an element that stimulates recombination via the E. coli RecBC pathway, can arise by spontaneous mutation in the transposon Tn5. When in phage lambda in one orientation, the mutant transposon confers Chi+ phenotype (large plaque and a high rate of exchange near the transposon). In the other orientation, however, the transposon does not confer Chi+ phenotype. The mobility of the transposon allows us to show that the Chi+ orientation of the mutant Tn5 is the same at different locations in lambda. These include a site near gene J, one in gam at 69, one to the right of gam at 73 and several to the right of R between 95.7 and 99.5. To the right of R, the mutant transposon could be found in only one orientation, that which confers Chi+ phenotype. We speculate that the other orientation of Tn5 in that locale is lethal to lambda. The orientation-dependence of Chi+ phenotype also revealed that Tn5 flip-flops in lambda.     

Does Chi Give or Take?

In lytic cycle crosses with Red-Gam-lambda phage, particles were examined that had undergone an Int-mediated exchange. It was assumed that this exchange dimerized the circular lambda, making it packageable. Among these Int-mediated recombinants, particles were identified that had, in addition, enjoyed a close double exchange mediated by the RecBC pathway. Such close double exchanges indicate localized negative interference and are analogous to eukaryotic conversions that have retained parental configuration of flanking markers. These events are stimulated by Chi, a recombinator specific to the RecBC pathway. When Chi is present in only one parent in the cross, the complementary double exchange recombinants are Chi stimulated to the same degree. This behavior of Chi contrasts with that of characterized eukaryotic recombinators.     

Activation of Chi recombinational hotspots by RecBCD-like enzymes from enteric bacteria

Chi sites, 5'G-C-T-G-G-T-G-G-3', enhance homologous recombination in Escherichia coli and are activated by the RecBCD enzyme. To test the ability of Chi to be activated by analogous enzymes from other bacteria, we cloned recBCD-like genes from diverse bacteria into an E. coli recBCD deletion mutant. Clones from seven species of enteric bacteria conferred to this deletion mutant recombination proficiency, Chi hotspot activity in lambda Red- Gam- vegetative crosses, and RecBCD enzyme activities, including Chi-dependent DNA strand cleavage. Three clones from Pseudomonas aeruginosa and Ps. putida conferred recombination proficiency and ATP-dependent nuclease activity, but neither Chi hotspot activity nor Chi-dependent DNA cleavage. These results imply that Chi has been conserved as a recombination-promoting signal for RecBCD-like enzymes in enteric bacteria but not in more distantly related bacteria such as Pseudomonas spp. We discuss the possibility that other, presently unknown, nucleotide sequences serve the same function as Chi in Pseudomonas spp.     

Two-step cloning and expression in Escherichia coli of the DNA restriction-modification system StyLTI of Salmonella typhimurium.

The StyLTI restriction-modification system is common to most strains of the genus Salmonella, including Salmonella typhimurium. We report here the two-step cloning of the genes controlling the StyLTI system. The StyLTI methylase gene (mod) was cloned first. Then, the companion endonuclease gene (res) was introduced on a compatible vector. A strain of S. typhimurium sensitive to the coliphage lambda was constructed and used to select self-modifying recombinant phages from a Res- Mod+ S. typhimurium genomic library in the lambda EMBL4 cloning vector. The methylase gene of one of these phages was then subcloned in pBR328 and transferred into Escherichia coli. In the second step, the closely linked endonuclease and methylase genes were cloned together on a single DNA fragment inserted in pACYC184 and introduced into the Mod+ E. coli strain obtained in the first step. Attempts to transform Mod- E. coli or S. typhimurium strains with this Res+ Mod+ plasmid were unsuccessful, whereas transformation of Mod+ strains occurred at a normal frequency. This can be understood if the introduction of the StyLTI genes into naive hosts is lethal because of degradation of host DNA by restriction activity; in contrast to most restriction-modification systems, StyLTI could not be transferred into naive hosts without killing them. In addition, it was found that strains containing only the res gene are viable and lack restriction activity in the absence of the companion mod gene. This suggests that expression of the StyLTI endonuclease activity requires at least one polypeptide involved in the methylation activity, as is the case for types I and III restriction-modification systems but not for type II systems.     

Salmonella typhimurium newD and Escherichia coli leuC genes code for a functional isopropylmalate isomerase in Salmonella typhimurium-Escherichia coli hybrids.

The supQ newD gene substitution system in Salmonella typhimurium restores leucine prototrophy to leuD mutants by providing the newD gene product which is capable of replacing the missing leuD polypeptide in the isopropylmalate isomerase, a complex of the leuC and leuD gene product. Mutations in the supQ gene are required to make the newD protein available. An Escherichia coli F' factor was constructed which carried supQ- newD+ from S. typhimurium on a P22-specialized transducing genome. This F' pro lac (P22dsupQ394newD) episome was transferred into S. typhimurium strains containing th leuD798-ara deletion; the resulting merodiploid strains had a Leu+ phenotype, indicating that supQ- newD+ is dominant over supQ+ newD+, and eliminating the possibility that the supQ gene codes for a repressor of the newD gene. Furthermore, transfer of the F' pro lac (P22dsupQ39newD) into E. coli leuD deletion strains restored leucine prototrophy, showing that the S. typhimurium newD gene can complment the E. coli leuC gene. Growth rates of the S. typhimurium-E coli hybrid strains indicated that the mutant isopropylmalate isomerase in these strains does not induce a leucine limitation, as it does in S. typhimurium leuD supQ mutants. In vitro activity of the mutant isopropylmalate isomerase was demonstrated; the Km values for alpha-isopropylmalate of both the S. typhimurium leuC-newD isomerase and the S. typhimurium-E. coli hybrid isomerase were as much as 100 times higher than the Km values for alpha-isopropylmalate of the wild-type enzyme, which was 3 x 10(-4) M. Mutagenesis of E. coli leuD deletion strains failed to restore leucine prototrophy, indicating that E. coli does not have genes analogous to the S. typhimurium supQ newD genes, of that, if present, activation of a newD is a rare event or is lethal to the cell.     

Characterization of recombinant diaminopropionate ammonia-lyase from Escherichia coli and Salmonella typhimurium

Diaminopropionate ammonia-lyase gene from Escherichia coli and Salmonella typhimurium was cloned and the overexpressed enzymes were purified to homogeneity. The k(cat) values, determined for the recombinant enzymes with DL-DAP, D-serine, and L-serine as substrates, showed that the enzyme from S. typhimurium was more active than that from E. coli and the K(m) values were found to be similar. The purified enzymes had an absorption maximum (lambda(max)) at 412 nm, typical of PLP dependent enzymes. A red shift in lambda(max) was observed immediately after the addition of 10mM DL-DAP, which returned to the original lambda(max) of 412 nm in about 4 min. This red shift might reflect the formation of an external aldimine and/or other transient intermediates of the reaction. The apoenzyme of E. coli and S. typhimurium prepared by treatment with L-cysteine could be partially (60%) reconstituted by the addition of PLP. The holo, apo, and the reconstituted enzymes were shown to be present as homo dimers by size exclusion chromatography.     

Chi hotspot activity in Escherichia coli without RecBCD exonuclease activity: implications for the mechanism of recombination

The major pathway of genetic recombination and DNA break repair in Escherichia coli requires RecBCD enzyme, a complex nuclease and DNA helicase regulated by Chi sites (5'-GCTGGTGG-3'). During its unwinding of DNA containing Chi, purified RecBCD enzyme has two alternative nucleolytic reactions, depending on the reaction conditions: simple nicking of the Chi-containing strand at Chi or switching of nucleolytic degradation from the Chi-containing strand to its complement at Chi. We describe a set of recC mutants with a novel intracellular phenotype: retention of Chi hotspot activity in genetic crosses but loss of detectable nucleolytic degradation as judged by the growth of mutant T4 and lambda phages and by assay of cell-free extracts. We conclude that RecBCD enzyme's nucleolytic degradation of DNA is not necessary for intracellular Chi hotspot activity and that nicking of DNA by RecBCD enzyme at Chi is sufficient. We discuss the bearing of these results on current models of RecBCD pathway recombination.     

Interaction of lambda Gam protein with the RecD subunit of RecBCD enzyme increases radioresistance of the wild-type Escherichia coli.

By making use of the gam(+)-plasmid, the so-called gam-dependent radioresistance was studied. This resistance is the result of the interaction between Gam protein (encoded by the gam gene of lambda) and RecBCD enzyme of Escherichia coli. gam-dependent radioresistance is observed in recB+ recC+ recD+ but not in recB+ recC+ recD- cells. It is suggested that Gam protein interacts specifically with the RecD subunit of RecBCD enzyme; the RecBC complex probably retains its activity in the presence of this viral protein.     

Host/vector interactions which affect the viability of recombinant phage lambda clones

A class of recombinant phage lambda clones are recovered from human genomic libraries on Escherichia coli recB21 recC22 sbcB15 cells, which fail to form plaques on wild-type cells. We report experiments which address the mechanism of this inhibition. The introduction of the recombination-stimulating sequence chi into one such clone allows growth of this phage on Rec+ cells. In addition, the insertion of lambda gam+ gene into a rec+-inhibited clone results in the ability of the phage to form plaques on wild-type cells. Since lambda Gam protein is an inhibitor of host RecBC enzyme, we tested a collection of such phage for growth on a variety of hosts altered in RecBC function. Host permissiveness correlated with the inactivation of the RecBC nucleolytic activities and not with the recombinational activities. These observations suggest that the inserted DNA sequences of these phage limit the production of packageable chromosomes. This conclusion is easily reconciled with our current knowledge of the interaction of the host recombination systems with lambda replication and encapsidation. Based on these experiments we have constructed strains, both recombination-proficient and recombination-deficient, which serve as improved hosts for the recovery of genomic sequences which are otherwise inhibitory to the growth of phage lambda.     

Salmonella recD mutations increase recombination in a short sequence transduction assay.

We have identified recD mutants of Salmonella typhimurium by their ability to support growth of phage P22 abc (anti-RecBCD) mutants, whose growth is prevented by normal host RecBCD function. As in Escherichia coli, the recD gene of S. typhimurium lies between the recB and argA genes at min 61 of the genetic map. Plasmids carrying the Salmonella recBCD+ genes restore ATP-dependent exonuclease V activity to an E. coli recBCD deletion mutant. The new Salmonella recD mutations (placed on this plasmid) eliminate the exonuclease activity and enable the plasmid-bearing E. coli deletion mutant to support growth of phage T4 gene 2 mutants. The Salmonella recD mutations caused a 3- to 61-fold increase in the ability of a recipient strain to inherit (by transduction) a large inserted element (MudA prophage; 38 kb). In this cross, recombination events must occur in the short (3-kb) sequences that flank the element in the 44-kb transduced fragment. The effect of the recD mutation depends on the nature of the flanking sequences and is likely to be greatest when those sequences lack a Chi site. The recD mutation appears to minimize fragment degradation and/or cause RecBC-dependent recombination events to occur closer to the ends of the transduced fragment. The effect of a recipient recD mutation was eliminated if the donor P22 phage expressed its Abc (anti-RecBC) function. We hypothesize that in standard (high multiplicity of infection) P22-mediated transduction crosses, recombination is stimulated both by Chi sequences (when present in the transduced fragment) and by the phage-encoded Abc protein which inhibits the host RecBCD exonuclease.     

Conservation of Chi cutting activity in terrestrial and marine enteric bacteria

Homologous recombination in Escherichia coli occurs at increased frequency near Chi sites, 5'G-C-T-G-G-T-G-G3'. Cutting of DNA close to the Chi sequence by the E. coli RecBC enzyme is essential to Chi's stimulation of recombination. We have detected Chi-dependent cutting activity in extracts of several genera of terrestrial enteric bacteria (family Enterobacteriaceae) and of two genera of marine enteric bacteria (family Vibrionaceae). More distantly related bacteria had no detectable Chi-dependent cutting activity. These results support the view that recognition of this specific nucleotide sequence as a signal activating recombination has been maintained during the evolution of certain groups of bacteria. We discuss the possibility that other sequences play a similar role in other groups of bacteria.