We have constructed Escherichia coli-Streptomyces shuttle plasmids which are capable of conjugal transfer from E. coli to Streptomyces spp. These plasmids contained the pBR322 and pUJlOl origins of replication and the RK2 (IncP) origin of transfer. The transfer of plasmid was specifically dependent the presence of a 760-base-pair, cis-acting, oriT-containing fragment and on RP4 (IncP) functions supplied in trans. Conditions of mating and selection of exconjugants were analyzed with Streptomyces lividans as recipient. Plasmid transfer to other Streptomyces species was also demonstrated.It was long assumed that plasmids could not be naturally transferred between gram-negative and gram-positive bacteria. 14) Fig. 1. Both plasmids contain the pBR322 replicon and a 760-base-pair fragment containing oriT of RK2. pPM801 contains the entire pIJlOl replicon, which includes streptomycete spread and transfer functions (6). pPM803 was constructed from the streptomycete vector pIJ699 (7). pIJ699 is a pIJlOl-derived vector which is defective for transfer in streptomycetes. To avoid an instability problem often encountered in E. coli-Streptomyces shuttle vectors, transcriptional terminator sequences between the two replicons were incorporated into pIJ699.Intergeneric conjugation. The natural resistance of many streptomycetes to nalidixic acid was used to counterselect the sensitive E. coli donor.
The DNA sequence of the region located downstream from the kanamycin resistance gene of Tn5 up to the right inverted repeat IS50R has been determined. This completes the determination of the sequence of Tn5 which is 5818 bp long. The 2.7 Kb central region contains three resistance genes: the kanamycin-neomycin resistance gene, a gene coding for resistance to CL990 an antimitotic-antibiotic compound of the bleomycin family and a third gene that confers streptomycin resistance in some bacterial species but is cryptic in E. coli. A Tn5* mutant able to express streptomycin resistance in E. coli was isolated. With this mutant, it was demonstrated that in E. coli the expression of the three resistance genes is coordinated in a single operon.
SummaryThe clpB gene of Streptomyces albus was cloned by polymerase chain reaction (PCR) using degenerate oligonucleotides. Transcriptional analysis showed that the clpB gene was heat induced. Primer extension identified a transcription start site preceded by typical vegetative ¹10 and ¹35 hexamer sequences. The Streptomyces HspR repressor is known to bind to three inverted repeat motifs (IR1, IR2, IR3) upstream from the S. coelicolor dnaK operon. We identified an inverted repeat motif identical to IR3 upstream from the S. albus clpB gene. DNA-binding experiments showed that HspR regulates clpB transcription by interacting directly with this motif. Streptomyces albus is the first Gram-positive organism for which the co-regulation of DnaK and ClpB has been described. Such co-regulation suggests that there is a physiological relationship between these two proteins in this bacterium. Genes similar to hspR were also identified in Mycobacterium leprae, M. tuberculosis and in bacteria unrelated to the actinomycetales order, such as Helicobacter pylori and Aquifex aeolicus. HspR binding sites were found in these bacteria upstream from various heat shock genes, suggesting that these genes are regulated by HspR. The HspR binding site, here called HAIR (H spR associated inverted repeat), has the consensus sequence CTTGAGT N7 ACTCAAG.
SummaryThe genes of Streptomyces coelicolor A3(2) encoding catalytic subunits (ClpP) and regulatory subunits (ClpX and ClpC) of the ATP-dependent protease family Clp were cloned, mapped and characterized. S. coelicolor contains at least two clpP genes, clpP1 and clpP2, located in tandem upstream from the clpX gene, and at least two unlinked clpC genes. Disruption of the clpP1 gene in S. lividans and S. coelicolor blocks differentiation at the substrate mycelium step. Overexpression of clpP1 and clpP2 accelerates aerial mycelium formation in S. lividans, S. albus and S. coelicolor.
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