Analysis of the SOS response in Salmonella enterica serovar typhimurium using RNA fingerprinting by arbitrarily primed PCR.

We report an analysis of a sample of the SOS response of Salmonella enterica serovar Typhimurium using the differential display of RNA fingerprinting gels of arbitrarily primed PCR products. The SOS response was induced by the addition of mitomycin C to an exponentially growing culture of serovar Typhimurium, and the RNA population was sampled during the following 2 h. These experiments revealed 21 differentially expressed PCR fragments representing mRNA transcripts. These 21 fragments correspond to 20 distinct genes. All of these transcripts were positively regulated, with the observed induction starting 10 to 120 min after addition of mitomycin C. Fifteen of the 21 transcripts have no homologue in the public sequence data banks and are therefore classified as novel. The remaining six transcripts corresponded to the recE, stpA, sulA, and umuC genes, and to a gene encoding a hypothetical protein in the Escherichia coli lysU-cadA intergenic region; the recE gene was represented twice by nonoverlapping fragments. In order to determine if the induction of these 20 transcripts constitutes part of a classical SOS regulon, we assessed the induction of these genes in a recA mutant. With one exception, the increased expression of these genes in response to mitomycin C was dependent on the presence of a functional recA allele. The exception was fivefold induced in the absence of a functional RecA protein, suggesting another layer of regulation in response to mitomycin C, in addition to the RecA-LexA pathway of SOS induction. Our data reveal several genes belonging to operons known to be directly involved in pathogenesis. In addition, we have found several phage-like sequences, some of which may be landmarks of pathogenicity determinants. On the basis of these observations, we propose that the general use of DNA-damaging agents coupled with differential gene expression analysis may be a useful and easy method for identifying pathogenicity determinants in diverse organisms.

Sample sequencing of a Salmonella typhimurium LT2 lambda library: comparison to the Escherichia coli K12 genome.

As part of the ongoing sequencing of the complete Salmonella typhimurium LT2 genome, a partly ordered set of 416 lambda clones has been developed, representing over 90% of the genome. The average insert size is 17 kb. Sequences were obtained from both ends of each clone in this set. A total of over 600 kb of sequence has been deposited in the genome survey sequence section of GenBank. This resource of clones is available from the Salmonella Genome Stock Center. A preliminary comparison with the Escherichia coli K12 genome indicates that there are likely to be many hundred insertion deletion events, encompassing more than one gene, that distinguish these genomes. Fully 30% of the S. typhimurium sequences have no close homologs in the GenBank database.

A Salmonella phage-P22 mutant defective in abortive transduction.

In the course of a lytic infection the Salmonella phage P22 occasionally encapsulates bacterial DNA instead of phage DNA. Thus, phage lysates include two classes of viral particles. Phage particles carrying bacterial DNA are referred to as transducing particles and deliver this DNA to a host as efficiently as particles carrying phase DNA. Once injected, the transduced DNA can either recombine with the recipient chromosome to form a "complete" transductant, or it can establish itself as an expressible, nonreplicating genetic element and form an "abortive" transductant. In this work, we describe a P22-phage mutant with reduced ability to form abortive transductants. The mutation responsible for this phenotype, called tdx-1, was found as one of two mutations contributing to the high-transducing pheno-type of the P22-mutant HT12/4. In addition, the tdx-1 mutation is lethal when combined with an erf am mutation. The tdx-1 mutation has been mapped to a region of the P22 genome that encodes several injected proteins and may involve more than one mutant locus. The phenotypes of the tdx-l mutation suggest that the Tdx protein(s) normally assist in the circularization of the P22 genome and also contribute to the formation of DNA circles thought to be required for abortive transduction.

Suppressors of recB mutations in Salmonella typhimurium.

Using a screen that directly assesses transductional proficiency, we have isolated suppressors of recB mutations in Salmonella typhimurium. The alleles of sbcB reported here are phenotypically distinct from those isolated in Escherichia coli in that they restore recombination proficiency (Rec+), resistance to ultraviolet light (UVR), and mitomycin C resistance (MCR) in the absence of an accompanying sbcCD mutation. In addition the sbcB alleles reported here are co-dominant to sbcB+. We have also isolated insertion and deletion mutants of the sbcB locus. These null mutations suppress only the UVS phenotype of recB mutants. We have also isolated sbcCD mutations, which map near proC. These sbcCD mutations increase the viability, recombination proficiency and MCR of both the transductional recombination suppressors (sbcB1 & sbcB6) and the sbcB null mutations. S. typhimurium recB sbcB1 sbcCD8 strains are 15-fold more recombination proficient than wild-type strains. The increase in transductants in these strains is accompanied by a loss of abortive transductants suggesting that these fragments are accessible to the mutant recombination apparatus. Using tandem duplications, we have constructed sbcB merodiploids and found that, in a recB mutant sbcCD+ genetic background, the sbcB+ allele is dominant to sbcB1 for transductional recombination but co-dominant for UVR and MCR. However, in a recB sbcCD8 genetic background, the sbcB1 mutation is co-dominant to sbcB+ for all phenotypes. Our results lead us to suggest that the SbcB and SbcCD proteins have roles in RecBCD-dependent recombination.

Rapid mapping in Salmonella typhimurium with Mud-P22 prophages.

A new method for mapping mutations in the Salmonella typhimurium chromosome is described and applied to the localization of novel regulatory mutations affecting expression of the nirB (nitrite reductase) gene. The mapping technique is also illustrated by the mapping of mutations in genes affecting carbohydrate catabolism and biosynthetic pathways. The new mapping method involves use of the hybrid phage MudP and MudQ (together referred to as Mud-P22), originally constructed by Youderian et al. (Genetics 118:581-592, 1988). This report describes a set of Mud-P22 lysogens, each member of the set containing a different Mud-P22 insertion. The insertions are scattered along the entire Salmonella genome. These lysogens, when induced by mitomycin C, generate transducing lysates that are enriched (45- to 1,400-fold over the background, generalized transducing particle population) for transducing particles containing bacterial DNA that flanks one side of the insertion. We demonstrate that within the set of lysogens there can be found at least one Mud-P22 insertion that enriches for any particular region of the Salmonella chromosome and that, therefore, all regions of the chromosome are discretely enriched and represented by the collection as a whole. We describe a technique that allows the rapid and facile determination of which lysate contains enriched sequences for the repair of a mutant locus, thereby allowing the determination of the map position of the locus. This technique is applicable to those mutations for which the wild-type allele is selectable. We also describe a procedure whereby any Tn10 insertion can be mapped by selecting for the loss of Tetr.

Affinity labeling the ribosome with eukaryotic-specific antibiotics: (bromoacetyl)trichodermin.

Trichodermin, a eukaryotic-specific antibiotic, inhibits protein synthesis in Drosophila cells. We have synthesized a 14C-labeled bromoacetyl derivative of trichodermin that binds to Drosophila 80S ribosomes and once bound reacts covalently with ribosomal proteins. It does not react with rRNA. Three large-subunit proteins (L1, L3, and L24) and three small-subunit proteins (S3/S5, 2/3S, and S8) are labeled by [14C] (bromoacetyl)trichodermin. Reaction with each of these proteins can be competed by an excess of unmodified trichodermin, indicating that the labeling has occurred from the native binding site of the parent drug. One of the (bromoacetyl)trichodermin-labeled proteins (S8) is also labeled by photoactivated puromycin in the A site. A second protein (S3/S5) is found to be labeled by a P-site affinity reagent. The results suggest that the trichodermin binding site spans both the small and large subunits and portions of both the A and P sites. These data combined with previous studies on the A and P sites of Drosophila ribosomes have allowed us to construct a model of the protein locations in this important active site.