Identification and characterization of a locus inhibiting extrachromosomal maintenance of the Streptomyces plasmid SLP1

KorSA from the Streptomyces integrative element pSAM2 is a central transcriptional repressor: target genes and binding sites

pSAM2, a 10.9-kb mobile integrative genetic element from Streptomyces ambofaciens, possesses, as do a majority of Streptomyces conjugative plasmids, a kil-kor system associated with its transfer. The kor function of pSAM2 was attributed to the korSA gene, but its direct role remained unclear. The present study was focused on the determination of the KorSA targets. It was shown that KorSA acts as a transcriptional repressor by binding to a conserved 17-nucleotide sequence found upstream of only two genes: its own gene, korSA, and pra, a gene positively controlling pSAM2 replication, integration, and excision. A unique feature of KorSA, compared to Kor proteins from other Streptomyces conjugative plasmids, is that it does not directly regulate pSAM2 transfer. KorSA does not bind to the pSAM2 genes coding for transfer and intramycelial spreading. Through the repression of pra, KorSA is able to negatively regulate pSAM2 functions activated by Pra and, consequently, to maintain pSAM2 integrated in the chromosome.

Regulation of transfer functions by the imp locus of the Streptomyces coelicolor plasmidogenic element SLP1

SLP1(int) is a 17.2-kb genetic element that normally is integrated site specifically into the chromosome of Streptomyces coelicolor A3(2). The imp operon within SLP1(int) represses replication of both chromosomally integrated and extrachromosomal SLP1. During mating with S. lividans, SLP1(int) can excise, delete part of imp, and form a family of autonomously replicating conjugative plasmids. Earlier work has shown that impA and impC gene products act in concert to control plasmid maintenance and regulate their own transcription. Here we report that these imp genes act also on a second promoter, P(opimp) (promoter opposite imp), located adjacent to, and initiating transcription divergent from, imp to regulate loci involved in the intramycelial transfer of SLP1 plasmids. spdB1 and spdB2, two overlapping genes immediately 3' to P(opimp) and directly regulated by imp, are shown by Tn5 mutagenesis to control transfer-associated growth inhibition (i.e., pocking). Additional genes resembling transfer genes of other Streptomyces spp. plasmids and required for SLP1 transfer and/or postconjugal intramycelial spread are located more distally to P(opimp). Expression of impA and impC in an otherwise competent recipient strain prevented SLP1-mediated gene transfer of chromosomal and plasmid genes but not plasmid-independent chromosome-mobilizing activity, suggesting that information transduced to recipients after the formation of mating pairs affects imp activity. Taken together with earlier evidence that the imp operon regulates SLP1 DNA replication, the results reported here implicate imp in the overall regulation of functions related to the extrachromosomal state of SLP1.

Molecular characterization of a Brucella species large DNA fragment deleted in Brucella abortus strains: evidence for a locus involved in the synthesis of a polysaccharide

A Brucella melitensis 16M DNA fragment of 17,119 bp, which contains a large region deleted in B. abortus strains and DNA flanking one side of the deletion, has been characterized. In addition to the previously identified omp31 gene, 14 hypothetical genes have been identified in the B. melitensis fragment, most of them showing homology to genes involved in the synthesis of a polysaccharide. Considering that 10 of the 15 genes are missing in B. abortus and that all the polysaccharides described in the Brucella genus (lipopolysaccharide, native hapten, and polysaccharide B) have been detected in all the species, it seems likely that the genes described here might be part of a cluster for the synthesis of a novel Brucella polysaccharide. Several polysaccharides have been identified as important virulence factors, and the discovery of a novel polysaccharide in the brucellae which is probably not synthesized in B. abortus might be interesting for a better understanding of the pathogenicity and host preference differences observed between the Brucella species. However, the possibility that the genes described in this paper no longer encode the synthesis of a polysaccharide cannot be excluded. Brucellae belong to the alpha-2 subdivision of the class Proteobacteria, which includes other microorganisms living in association with eucaryotic cells, some of them synthesizing extracellular polysaccharides involved in the interaction with the host cell. The genes described in this paper might be a remnant of the common ancestor of the alpha-2 subdivision of the class Proteobacteria, and the brucellae might have lost such extracellular polysaccharide during evolution if it was not necessary for survival or for establishment of the infectious process. Nevertheless, further studies are necessary to identify the entire DNA fragment missing in B. abortus strains and to elucidate the mechanism responsible for such deletion, since only 9,948 bp of the deletion was present in the sequenced B. melitensis DNA fragment.

Role of the imp operon of the Streptomyces coelicolor genetic element SLP1: two imp-encoded proteins interact to autoregulate imp expression and control plasmid maintenance

The Streptomyces coelicolor genetic element SLP1 can exist either integrated into the host chromosome or as an autonomously replicating plasmid. The integrated form of SLP1 includes a locus (imp, for inhibition of plasmid maintenance) that can act both in cis and in trans to prevent propagation of SLP1 as an extrachromosomal replicon (S. R. Grant, S. C. Lee, K. Kendall, and S. N. Cohen, Mol. Gen. Genet. 217:324-331, 1989). We report here that a 1.8-kb Eco47III DNA fragment previously shown to encode the Imp+ phenotype contains two genes (impA and impC) that must be expressed in cis to each other and whose products interact functionally and probably physically to interfere with SLP1 plasmid maintenance and repress expression of the imp operon. Partial repression of the imp promoter (P(imp)), which is located immediately 5' of impA, by the 29.7-kDa ImpA protein is enhanced by the impC gene product. Gel shift analysis indicates that ImpA binds to a 16-bp sequence located within the DNA segment containing P(imp) and that ImpC interferes with this binding. Our data suggest that binding of ImpA to the P(imp) region mediates DNA looping in this region.

Transfer functions of the conjugative integrating element pSAM2 from Streptomyces ambofaciens: characterization of a kil-kor system associated with transfer

pSAM2 is an 11-kb integrating element from Streptomyces ambofaciens. During matings, pSAM2 can be transferred at high frequency, forming pocks, which are zones of growth inhibition of the recipient strain. The nucleotide sequences of the regions involved in pSAM2 transfer, pock formation, and maintenance have been determined. Seven putative open reading frames with the codon usage typical of Streptomyces genes have been identified: traSA (306 amino acids [aa]), orf84 (84 aa), spdA (224 aa), spdB (58 aa), spdC (51 aa), spdD (104 aa), and korSA (259 aa). traSA is essential for pSAM2 intermycelial transfer and pock formation. It could encode a protein with similarities to the major transfer protein, Tra, of pIJ101. TraSA protein contains a possible nucleotide-binding sequence and a transmembrane segment. spdA, spdB, spdC, and spdD influence pock size and transfer efficiency and may be required for intramycelial transfer. A kil-kor system similar to that of pIJ101 is associated with pSAM2 transfer: the korSA (kil-override) gene product could control the expression of the traSA gene, which has lethal effects when unregulated (Kil phenotype). The KorSA protein resembles KorA of pIJ101 and repressor proteins belonging to the GntR family. Thus, the integrating element pSAM2 possesses for transfer general features of nonintegrating Streptomyces plasmids: different genes are involved in the different steps of the intermycelial and intramycelial transfer, and a kil-kor system is associated with transfer. However, some differences in the functional properties, organization, and sizes of the transfer genes compared with those of other Streptomyces plasmids have been found.

Localization and nucleotide sequences of genes mediating site-specific recombination of the SLP1 element in Streptomyces lividans

SLP1 is a 17.2-kbp genetic element indigenous to the Streptomyces coelicolor chromosome. During conjugation, SLP1 can undergo excision and subsequent site-specific integration into the chromosomes of recipient cells. We report here the localization, nucleotide sequences, and initial characterization of the genes mediating these recombination events. A region of SLP1 adjacent to the previously identified site of integration, attP, was found to be sufficient to promote site-specific integration of an unrelated Streptomyces plasmid. Nucleotide sequence analysis of a 2.2-kb segment of this region reveals two open reading frames that are adjacent to and transcribed toward the attP site. One of these, the 1,365-bp int gene of SLP1, encodes a predicted 50.6-kDa basic protein having substantial amino acid sequence similarity to a family of site-specific recombinases that includes the Escherichia coli bacteriophage lambda integrase. A linker insertion in the 5' end of the cloned int gene prevents integration, indicating that Int is essential for promoting integration. An open reading frame (orf61) lying immediately 5' to int encodes a predicted 7.1-kDa basic peptide showing limited sequence similarity to the excisionase (xis) genes of other site-specific recombination systems.

Regulation and function of the Streptomyces plasmid pSN22 genes involved in pock formation and inviability

pSN22 is an 11-kb multicopy plasmid from Streptomyces nigrifaciens which is being studied in Streptomyces lividans. A segment of about 7 kb of pSN22 contains five genes involved in conjugation. Three of them, traA, traB, and traR, are essential for plasmid transfer and for the mobilization of chromosomal markers (fertility), while the remaining two genes, spdA and spdB, merely enhance the efficiency of plasmid transfer, resulting in the formation of larger pocks. In vitro promoter-probing experiments identified a 550-bp BglII-SmaI DNA fragment with promoter activity in both orientations; Northern (RNA blot) hybridization identified corresponding divergent transcripts of 1 and 5.2 kb for traR and the traA-traB-spdB operon, respectively. The traR gene product repressed its own transcription and also the transcription of the traA-traB-spdB operon. Plasmids containing a functional traB gene could not "survive" without traR being present in the same cell either in cis or in trans, presumably because unregulated expression of traB is lethal to the host. Plasmids with a functional traA gene but without traR had a low transformation efficiency and inhibited the growth of host cells.

Five genes involved in self-transmission of pSN22, a Streptomyces plasmid

An 11-kbp multicopy plasmid, pSN22, was isolated from Streptomyces nigrifaciens SN22. pSN22 is self-transmissible (conjugative), is maintained stably in S. lividans, and forms pocks in a wide range of Streptomyces strains. Mutational analyses showed that a fragment of pSN22 contained five genes involved in plasmid transfer and pock formation. traB was essential for plasmid transfer. traA was required for pock formation, but not for plasmid transfer. spdA or spdB were concerned with pock size; mutations in these genes decreased pock size. The fifth gene, traR, could be deleted together with other genes to give nontransmissible plasmids, but plasmids with insertions or deletions only within traR became nonviable. traR is probably needed to counterbalance the lethal effects of another plasmid gene. Transfer of pSN22 promoted the cotransfer of nontransmissible plasmids and enhanced chromosome recombination between the host and recipient strains, suggesting that plasmid transfer accompanies cytoplasmic mixing.

Functional analysis of the Streptomyces ambofaciens element pSAM2

pSAM2 is an 11-kb element integrated in the Streptomyces ambofaciens ATCC23877 genome and found additionally as a free replicon present at several copies per chromosome in strain JI3212, the derivative of ATCC23877 isolated after uv irradiation. In spite of its small size, this element specifies numerous functions including maintenance, site-specific integration, self-transmissibility, pock formation, and mobilization of chromosomal markers. After transfer of the free form of pSAM2 to Streptomyces lividans, the free and the integrated forms coexist. A functional map of pSAM2 was deduced from phenotypes exhibited in S. lividans by numerous deletion or insertion derivatives. In addition to the previously characterized regions sufficient for site-specific integration we have shown that separate regions are involved in either plasmid maintenance as a free molecule, plasmid transfer, and pock formation. Transfer of pSAM2 could depend on its ability to be maintained in a free form, since plasmids deficient in this function are transferred at very low frequency. Deletions of some regions of the plasmid are lethal for the plasmid or the host, but if some other regions are deleted simultaneously, transformants can be obtained.

Characterization of the genetic elements required for site-specific integration of plasmid pSE211 in Saccharopolyspora erythraea

The 18.1-kilobase plasmid pSE211 integrates into the chromosome of Saccharopolyspora erythraea at a specific attB site. Restriction analysis of the integrated plasmid, pSE211int, and adjacent chromosomal sequences allowed identification of attP, the plasmid attachment site. Nucleotide sequencing of attP, attB, attL, and attR revealed a 57-base-pair sequence common to all sites with no duplications of adjacent plasmid or chromosomal sequences in the integrated state, indicating that integration takes place through conservative, reciprocal strand exchange. An analysis of the sequences indicated the presence of a putative gene for Phe-tRNA at attB which is preserved at attL after integration has occurred. A comparison of the attB site for a number of actinomycete plasmids is presented. Integration at attB was also observed when a 2.4-kilobase segment of pSE211 containing attP and the adjacent plasmid sequence was used to transform a pSE211- host. Nucleotide sequencing of this segment revealed the presence of two complete open reading frames (ORFs) and a segment of a third ORF. The ORF adjacent to attP encodes a putative polypeptide 437 amino acids in length that shows similarity, at its C-terminal domain, to sequences of site-specific recombinases of the integrase family. The adjacent ORF encodes a putative 98-amino-acid basic polypeptide that contains a helix-turn-helix motif at its N terminus which corresponds to domains in the Xis proteins of a number of bacteriophages. A proposal for the function of this polypeptide is presented. The deduced amino acid sequence of the third ORF did not reveal similarities to polypeptide sequences in the current data banks.