학술논문

Enhancing Ristomycin A Production by Overexpression of ParB-Like StrR Family Regulators Controlling the Biosynthesis Genes.
Document Type
Article
Source
Applied & Environmental Microbiology. Oct2021, Vol. 87 Issue 19, p1-19. 19p.
Subject
*BIOSYNTHESIS
*REGULATOR genes
*GENE clusters
*GENES
*PROMOTERS (Genetics)
*GENE families
Language
ISSN
0099-2240
Abstract
Amycolatopsis sp. strain TNS106 harbors a ristomycin-biosynthetic gene cluster (asr) in its genome and produces ristomycin A. Deletion of the sole cluster-situated StrR family regulatory gene, asrR, abolished ristomycin A production and the transcription of the asr genes orf5 to orf39. The ristomycin A fermentation titer in Amycolatopsis sp. strain TNS106 was dramatically improved by overexpression of asrR and a heterologous StrR family regulatory gene, bbr, from the balhimycin-biosynthetic gene cluster (BGC) utilizing strong promoters and multiple gene copies. Ristomycin A production was improved by approximately 60-fold, resulting in a fermentation titer of 4.01 g/liter in flask culture, in one of the engineered strains. Overexpression of AsrR and Bbr upregulated transcription of tested asr biosynthetic genes, indicating that these asr genes were positively regulated by AsrR and Bbr. However, only the promoter region of the asrR operon and the intergenic region upstream of orf12 were bound by AsrR and Bbr in gel retardation assays, suggesting that AsrR and Bbr directly regulated the asrR operon and probably orf12 to orf14 but no other asr biosynthetic genes. Further assays with synthetic short probes showed that AsrR and Bbr specifically bound not only probes containing the canonical inverted repeats but also a probe with only one 7-bp element of the inverted repeats in its native context. AsrR and Bbr have an N-terminal ParB-like domain and a central winged helix-turn-helix DNA-binding domain. Site-directed mutations indicated that the N-terminal ParB-like domain was involved in activation of ristomycin A biosynthesis and did not affect the DNA-binding activity of AsrR and Bbr. [ABSTRACT FROM AUTHOR]