The adpA-like regulatory gene from Actinoplanes teichomyceticus: in silico analysis and heterologous expression.

Analysis of the draft sequence of the genome of teicoplanin producer Actinoplanes teichomyceticus (NRRL-B16726) led to identification of several genes encoding AraC-family regulators that resemble AdpA, master regulator of transcription in Streptomyces. We elucidated possible regulatory functions of one of the identified genes, adpA19(at), most similar to archetypal adpA from model Streptomyces species, in a series of expression experiments. Introduction of adpA19 at under control of its own promoter on moderate copy number vector pKC1139 into NRRL-B16726 had no influence on antibiotic production and sporulation. Introduction of adpA19 at into Streptomyces coelicolor M145 and several S. ghanaensis strains had major influence on antibiotic production by these bacteria. Finally, adpA19 at expression in a set of soil actinomycete isolates led to induction of synthesis of antibiotic compounds. Our data point to pleiotropic regulatory role of adpA19(at), warranting its use as a tool to manipulate secondary metabolome of actinomycetes.

Manipulating the regulatory genes for teicoplanin production in Actinoplanes teichomyceticus.

Actinoplanes teichomyceticus produces the lipoglycopeptide antibiotic teicoplanin, which is considered a last line of defense against multidrug resistant Gram-positive cocci. Different strategies have been employed to generate industrial producers of teicoplanin, however they do not include manipulations of teicoplanin biosynthetic genes due to a poorly developed genetic "toolkit" for this strain. Through this work, we extend the choice of vectors that can be conjugally transferred and maintained in A. teichomyceticus. Antibiotic producing properties and stability of the transconjugants have been examined. As an illustration of the utility of pSG5-based vector pKC1139, we improved teicoplanin production by the wild type strain via manipulations of two regulatory genes from the teicoplanin biosynthetic cluster, tcp28 and tcp29.