In Streptomyces coelicolor, AtrA is an activator of transcription of the actinorhodin cluster-situated regulator gene actII-ORF4. In previous work, we showed that S. coelicolor AtrA binds in vitro to the promoter of S. griseus strR, the streptomycin cluster-situated regulator. We show here that S. griseus carries a single close homologue of atrA and that expression of S. coelicolor AtrA in S. griseus causes a DNA binding-dependent reduction in streptomycin production and in the mRNA levels of strR and genes of streptomycin biosynthesis. However, there is no effect on the level of the mRNA of adpA, which is the only transcription factor that has so far been characterised for strR. The adpA gene is directly regulated by ArpA, the receptor protein for the gamma-butyrolactone signalling molecule A-factor. Therefore, to our knowledge, our results provide the first in vivo evidence that A-factor-ArpA-AdpA-StrR regulatory cascade represents only part of the full complexity of regulation of streptomycin biosynthesis in S. griseus. The potential biotechnological application of our findings is discussed.
Bacterial conjugation is a genetic transfer that involves cell-to-cell between donor and recipient cells. With the current method used to teach students in genetic courses at the undergraduate level, the transconjugants are identified using bacterial physiology and/or antibiotic resistance. Using physiology, however, is difficult for both first-year undergraduates and special science students at the high school levels, who do not have the basic knowledge. We have developed a laboratory exercise that comprises a simple and rapid technique for transferring bacterial DNA by conjugation and examining the transconjuants using only antibiotic resistance on agar. The identity of the right transconjuants is confirmed by agarose gel electrophoresis. This exercise is designed to help students understand how horizontal gene transfer occurs in bacteria by conjugation using Escherichia coli as a hands-on learning model. Students should be able to draw concept maps of three DNA transfer methods on their own after carrying out the experiment and getting some additional information.
Aims: To develop an intergeneric conjugation system for rimocidin‐producing Streptomyces rimosus. Methods and Results: High efficiencies of conjugation [10−2–10−3 transconjugants/recipient colony forming units (CFU)] were obtained when spores of S. rimosus were heat treated at 40°C for 10 min prior to mixing with E. coli ET12567(pUZ8002/pIJ8600) as donor. Mycelium from liquid grown cultures of S. rimosus could also be used as recipient instead of spores, with 24‐h cultures giving optimal results. TSA (Oxoid) medium containing 10 m mol l−1 MgCl2 was the preferred medium for conjugation. Southern hybridization was used to confirm that transconjugants of S. rimosus contained a single copy of pIJ8600 integrated at a unique chromosomal attachment site (attB). The transconjugants exhibited a high stability of plasmid integration and showed strong expression of green fluorescent protein when using pIJ8655 as the conjugative vector. Conclusion: Intergeneric conjugation between E. coli and S. rimosus was achieved at high efficiency using both spores and mycelium. Significance and Impact of the Study: The conjugation system developed provides a convenient gene expression system for S. rimosus R7 and will enable the genetic manipulation of the rimocidin gene cluster.
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