Proteomics-driven identification of putative AfsR2-target proteins stimulating antibiotic biosynthesis inStreptomyces lividans

AfsR2, originally identified fromStreptomyces lividans, is a global regulatory protein which stimulates antibiotic biosynthesis. Through its stable chromosomal integration, the high level of gene expression ofafsR2 significantly induced antibiotic production as well as the sporulation ofS. lividans, implying the presence of yet-uncharacterized AfsR2-target proteins. To identify and evaluate the putative AfsR2-target proteins involved in antibiotic regulation, the proteomics-driven approach was applied to the wild-typeS. lividans and theafsR2-integrated actinorhodin overproducing strain. The 2D gel-electrophoresis gave approximately 340 protein spots showing different protein expression patterns between these twoS. lividans strains. Further MALDI-TOF analysis revealed several AfsR2-target proteins, including glyceraldehyde-3-phosphate dehydrogenase, putative phosphate transport system regulator, guanosine pentaphosphate synthetase/polyribonucleotide nucleotidyltransferase, and superoxide dismutase, which suggests that the AfsR2 should be a pleiotropic regulatory protein which controls differential expressions of various kinds of genes inStreptomyces species.     

Cross-regulation among disparate antibiotic biosynthetic pathways of Streptomyces coelicolor

A complex programme of regulation governs gene expression during development of the morphologically and biochemically complex eubacterial genus Streptomyces. Earlier work has suggested a model in which 'higher level' pleiotropic regulators activate 'pathway-specific' regulators located within chromosomal gene clusters encoding biosynthesis of individual antibiotics. We used mutational analysis and adventitious overexpression of key Streptomyces coelicolor regulators to investigate functional interactions among them. We report here that cluster-situated regulators (CSRs) thought to be pathway-specific can also control other antibiotic biosynthetic gene clusters, and thus have pleiotropic actions. Surprisingly, we also find that CSRs exhibit growth-phase-dependent control over afsR2/afsS, a 'higher level' pleiotropic regulatory locus not located within any of the chromosomal gene clusters it targets, and further demonstrate that cross-regulation by CSRs is modulated globally and differentially during the S. coelicolor growth cycle by the RNaseIII homologue AbsB. Our results, which reveal a network of functional interactions among regulators that govern production of antibiotics and other secondary metabolites in S. coelicolor, suggest that revision of the currently prevalent view of higher-level versus pathway-specific regulation of secondary metabolism in Streptomyces species is warranted.     

Functional analysis of relA and rshA, two relA/spoT homologues of Streptomyces coelicolor A3(2)

Deletion of the (p)ppGpp synthetase gene, relA, of Streptomyces coelicolor A3(2) results in loss of production of the antibiotics actinorhodin (Act) and undecylprodigiosin (Red) and delayed morphological differentiation when the mutant is grown under conditions of nitrogen limitation. To analyze the role of (p)ppGpp as an intracellular signaling molecule for the initiation of antibiotic production, several C-terminally deleted derivatives of S. coelicolor relA that could potentially function in the absence of ribosome activation were placed under the control of the thiostrepton-inducible tipA promoter. While 0.82- and 1.28-kb N-terminal segments failed to restore (p)ppGpp and antibiotic production upon induction in a relA null mutant, 1.46- and 2.07-kb segments did. Under conditions of phosphate limitation, deletion of relA had little or no effect on Act or Red synthesis, potentially reflecting an alternative mechanism for ppGpp synthesis. A second S. coelicolor RelA homologue (RshA, with 42% identity to S. coelicolor RelA) was identified in the genome sequence. However, deletion of rshA had no effect on the ability of the relA mutant to make Act and Red when grown under conditions of phosphate limitation. While high-level induction of tipAp::rshA in the relA mutant resulted in growth inhibition, low-level induction restored antibiotic production and sporulation. In neither case, nor in the relA mutant that was grown under phosphate limitation and producing Act and Red, could (p)ppGpp synthesis be detected. Thus, a ppGpp-independent mechanism exists to activate antibiotic production under conditions of phosphate limitation that can be mimicked by overexpression of rshA.     

Phosphorylation of the AfsR product, a global regulatory protein for secondary-metabolite formation in Streptomyces coelicolor A3(2).

The AfsR protein is essential for the biosynthesis at the wild-type level of A-factor, actinorhodin, and undecylprodigiosin in Streptomyces coelicolor A3(2) and Streptomyces lividans. Because overexpression of the afsR gene caused some deleterious effect on these strains, a multicopy plasmid carrying the whole afsR gene was introduced into Streptomyces griseus, from which a crude cell lysate was prepared as a protein source. The AfsR protein was purified to homogeneity from the cytoplasmic fraction through several steps of chromatography, including affinity column chromatography with ATP-agarose and use of anti-AfsR antibody for its detection. The molecular weight of AfsR was estimated by sodium dodecyl sulfate-polyacrylamide gel electrophoresis and by gel filtration to be 105,300, which is in good agreement with that deduced from the nucleotide sequence of afsR. The purified AfsR protein was found to be phosphorylated through the transfer of the gamma-phosphate group of ATP in the presence of the cell extracts of S. coelicolor A3(2) and S. lividans. This phosphorylation proceeded very rapidly, and no competition was observed with CTP, GTP, UTP, or cyclic AMP. In the cell extract of S. griseus, no activity phosphorylating the AfsR protein was detected, suggesting that this activity is not generally present in Streptomyces spp. but is specific to certain species. It is conceivable that the extent of phosphorylation of the AfsR protein modulates its regulatory activity which, in turn, regulates expression of some target gene(s) involved in the secondary-metabolite formation in S. coelicolor A3(2).     

cmdABCDEF, a cluster of genes encoding membrane proteins for differentiation and antibiotic production in Streptomyces coelicolor A3(2)

Background  

Streptomyces coelicolor is the most studied Streptomyces species and an excellent model for studying differentiation and antibiotic production. To date, many genes have been identified to be required for its differentiation (e.g. bld genes for aerial growth and whi genes for sporulation) and antibiotics production (including actII-orf4, redD, cdaR as pathway-specific regulatory genes and afsR, absA1/A2 as pleiotropic regulatory genes).     

Overlapping binding of PhoP and AfsR to the promoter region of glnR in Streptomyces coelicolor

Growth of soil bacteria is often limited by the availability of essential nutrients such as carbon, nitrogen and phosphate. The reaction to a specific nutrient starvation triggers interconnected responses to equilibrate the metabolism. It is known that PhoP (response regulator involved in phosphate control) specifically binds to several promoters of genes involved in nitrogen metabolism which are also regulated by GlnR (regulator involved in nitrogen control). In this article we report a novel cross-talk between GlnR and the SARP-like regulator, AfsR. AfsR binds to some PhoP-regulated promoters including those of afsS (a small regulatory protein of secondary metabolism), pstS (a component of the phosphate transport system) and phoRP (encoding the two component system itself). We have characterized the regulation exerted upon the nitrogen regulator glnR gene by AfsR, using EMSA and DNase I footprinting assays as well as in vivo expression studies with ΔphoP, ΔafsR and ΔafsR-ΔphoP mutants. Both PhoP and AfsR proteins are able to bind to overlapping regions within the glnR promoter producing different effects. This work demonstrates a cross-talk of three different regulators of both primary and secondary metabolism.