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

LuxR-Type SCO6993 Negatively Regulates Antibiotic Production at the Transcriptional Stage by Binding to Promoters of Pathway-Specific Regulatory Genes in Streptomyces coelicolor

SCO6993 (606 amino acids) in Streptomyces coelicolor belongs to the large ATP-binding regulators of the LuxR family regulators having one DNA-binding motif. Our previous findings predicted that SCO6993 may suppress the production of pigmented antibiotics, actinorhodin, and undecylprodigiosin, in S. coelicolor, resulting in the characterization of its properties at the molecular level. SCO6993-disruptant, S. coelicolor ΔSCO6993 produced excess pigments in R2YE plates as early as the third day of culture and showed 9.0-fold and 1.8-fold increased production of actinorhodin and undecylprodigiosin in R2YE broth, respectively, compared with that by the wild strain and S. coelicolor ΔSCO6993/SCO6993⁺. Real-time polymerase chain reaction analysis showed that the transcription of actA and actII-ORF4 in the actinorhodin biosynthetic gene cluster and that of redD and redQ in the undecylprodigiosin biosynthetic gene cluster were significantly increased by SCO6993-disruptant. Electrophoretic mobility shift assay and DNase footprinting analysis confirmed that SCO6993 protein could bind only to the promoters of pathway-specific transcriptional activator genes, actII-ORF4 and redD, and a specific palindromic sequence is essential for SCO6993 binding. Moreover, SCO6993 bound to two palindromic sequences on its promoter region. These results indicate that SCO6993 suppresses the expression of other biosynthetic genes in the cluster by repressing the transcription of actII-ORF4 and redD and consequently negatively regulating antibiotic production.

SCO6992, a Protein with β-Glucuronidase Activity, Complements a Mutation at the absR Locus and Promotes Antibiotic Biosynthesis in Streptomyces coelicolor

Streptomyces coelicolor is a filamentous soil bacterium producing several kinds of antibiotics. S. coelicolor abs8752 is an abs (antibiotic synthesis deficient)-type mutation at the absR locus; it is characterized by an incapacity to produce any of the four antibiotics synthesized by its parental strain J1501. A chromosomal DNA fragment from S. coelicolor J1501, capable of complementing the abs^- phenotype of the abs8752 mutant, was cloned and analyzed. DNA sequencing revealed that two complete ORFs (SCO6992 and SCO6993) were present in opposite directions in the clone. Introduction of SCO6992 in the mutant strain resulted in a remarkable increase in the production of two pigmented antibiotics, actinorhodin and undecylprodigiosin, in S. coelicolor J1501 and abs8752. However, introduction of SCO6993 did not show any significant difference compared to the control, suggesting that SCO6992 is primarily involved in stimulating the biosynthesis of antibiotics in S. coelicolor. In silico analysis of SCO6992 (359 aa, 39.5 kDa) revealed that sequences homologous to SCO6992 were all annotated as hypothetical proteins. Although a metalloprotease domain with a conserved metal-binding motif was found in SCO6992, the recombinant rSCO6992 did not show any protease activity. Instead, it showed very strong β-glucuronidase activity in an API ZYM assay and toward two artificial substrates, p-nitrophenyl-β-D-glucuronide and AS-BI-β-D-glucuronide. The binding between rSCO6992 and Zn²⁺ was confirmed by circular dichroism spectroscopy. We report for the first time that SCO6992 is a novel protein with β-glucuronidase activity, that has a distinct primary structure and physiological role from those of previously reported β-glucuronidases.

Combining transposon mutagenesis and reporter genes to identify novel regulators of the topA promoter in Streptomyces

BACKGROUND

Identifying the regulatory factors that control transcriptional activity is a major challenge of gene expression studies. Here, we describe the application of a novel approach for in vivo identification of regulatory proteins that may directly or indirectly control the transcription of a promoter of interest in Streptomyces.

RESULTS

A method based on the combination of Tn5 minitransposon-driven random mutagenesis and lux reporter genes was applied for the first time for the Streptomyces genus. As a proof of concept, we studied the topA supercoiling-sensitive promoter, whose activity is dependent on unknown regulatory factors. We found that the sco4804 gene product positively influences topA transcription in S. coelicolor, demonstrating SCO4804 as a novel player in the control of chromosome topology in these bacteria.

CONCLUSIONS

Our approach allows the identification of novel Streptomyces regulators that may be critical for the regulation of gene expression in these antibiotic-producing bacteria.

Modulation of Gene Expression in Actinobacteria by Translational Modification of Transcriptional Factors and Secondary Metabolite Biosynthetic Enzymes

Different types of post-translational modifications are present in bacteria that play essential roles in bacterial metabolism modulation. Nevertheless, limited information is available on these types of modifications in actinobacteria, particularly on their effects on secondary metabolite biosynthesis. Recently, phosphorylation, acetylation, or phosphopantetheneylation of transcriptional factors and key enzymes involved in secondary metabolite biosynthesis have been reported. There are two types of phosphorylations involved in the control of transcriptional factors: (1) phosphorylation of sensor kinases and transfer of the phosphate group to the receiver domain of response regulators, which alters the expression of regulator target genes. (2) Phosphorylation systems involving promiscuous serine/threonine/tyrosine kinases that modify proteins at several amino acid residues, e.g., the phosphorylation of the global nitrogen regulator GlnR. Another post-translational modification is the acetylation at the epsilon amino group of lysine residues. The protein acetylation/deacetylation controls the activity of many short and long-chain acyl-CoA synthetases, transcriptional factors, key proteins of bacterial metabolism, and enzymes for the biosynthesis of non-ribosomal peptides, desferrioxamine, streptomycin, or phosphinic acid-derived antibiotics. Acetyltransferases catalyze acetylation reactions showing different specificity for the acyl-CoA donor. Although it functions as acetyltransferase, there are examples of malonylation, crotonylation, succinylation, or in a few cases acylation activities using bulky acyl-CoA derivatives. Substrates activation by nucleoside triphosphates is one of the central reactions inhibited by lysine acetyltransferases. Phosphorylation/dephosphorylation or acylation/deacylation reactions on global regulators like PhoP, GlnR, AfsR, and the carbon catabolite regulator glucokinase strongly affects the expression of genes controlled by these regulators. Finally, a different type of post-translational protein modification is the phosphopantetheinylation, catalized by phosphopantetheinyl transferases (PPTases). This reaction is essential to modify those enzymes requiring phosphopantetheine groups like non-ribosomal peptide synthetases, polyketide synthases, and fatty acid synthases. Up to five PPTases are present in S. tsukubaensis and S. avermitilis. Different PPTases modify substrate proteins in the PCP or ACP domains of tacrolimus biosynthetic enzymes. Directed mutations of genes encoding enzymes involved in the post-translational modification is a promising tool to enhance the production of bioactive metabolites.

The Balance Metabolism Safety Net: Integration of Stress Signals by Interacting Transcriptional Factors in Streptomyces and Related Actinobacteria

Soil dwelling Streptomyces species are faced with large variations in carbon or nitrogen sources, phosphate, oxygen, iron, sulfur, and other nutrients. These drastic changes in key nutrients result in an unbalanced metabolism that have undesirable consequences for growth, cell differentiation, reproduction, and secondary metabolites biosynthesis. In the last decades evidence has accumulated indicating that mechanisms to correct metabolic unbalances in Streptomyces species take place at the transcriptional level, mediated by different transcriptional factors. For example, the master regulator PhoP and the large SARP-type regulator AfsR bind to overlapping sequences in the afsS promoter and, therefore, compete in the integration of signals of phosphate starvation and S-adenosylmethionine (SAM) concentrations. The cross-talk between phosphate control of metabolism, mediated by the PhoR-PhoP system, and the pleiotropic orphan nitrogen regulator GlnR, is very interesting; PhoP represses GlnR and other nitrogen metabolism genes. The mechanisms of control by GlnR of several promoters of ATP binding cassettes (ABC) sugar transporters and carbon metabolism are highly elaborated. Another important cross-talk that governs nitrogen metabolism involves the competition between GlnR and the transcriptional factor MtrA. GlnR and MtrA exert opposite effects on expression of nitrogen metabolism genes. MtrA, under nitrogen rich conditions, represses expression of nitrogen assimilation and regulatory genes, including GlnR, and competes with GlnR for the GlnR binding sites. Strikingly, these sites also bind to PhoP. Novel examples of interacting transcriptional factors, discovered recently, are discussed to provide a broad view of this interactions. Altogether, these findings indicate that cross-talks between the major transcriptional factors protect the cell metabolic balance. A detailed analysis of the transcriptional factors binding sequences suggests that the transcriptional factors interact with specific regions, either by overlapping the recognition sequence of other factors or by binding to adjacent sites in those regions. Additional interactions on the regulatory backbone are provided by sigma factors, highly phosphorylated nucleotides, cyclic dinucleotides, and small ligands that interact with cognate receptor proteins and with TetR-type transcriptional regulators. We propose to define the signal integration DNA regions (so called integrator sites) that assemble responses to different stress, nutritional or environmental signals. These integrator sites constitute nodes recognized by two, three, or more transcriptional factors to compensate the unbalances produced by metabolic stresses. This interplay mechanism acts as a safety net to prevent major damage to the metabolism under extreme nutritional and environmental conditions.

Regulation of antibiotic production in Actinobacteria: new perspectives from the post-genomic era

Covering: 2000 to 2018 The antimicrobial activity of many of their natural products has brought prominence to the Streptomycetaceae, a family of Gram-positive bacteria that inhabit both soil and aquatic sediments. In the natural environment, antimicrobial compounds are likely to limit the growth of competitors, thereby offering a selective advantage to the producer, in particular when nutrients become limited and the developmental programme leading to spores commences. The study of the control of this secondary metabolism continues to offer insights into its integration with a complex lifecycle that takes multiple cues from the environment and primary metabolism. Such information can then be harnessed to devise laboratory screening conditions to discover compounds with new or improved clinical value. Here we provide an update of the review we published in NPR in 2011. Besides providing the essential background, we focus on recent developments in our understanding of the underlying regulatory networks, ecological triggers of natural product biosynthesis, contributions from comparative genomics and approaches to awaken the biosynthesis of otherwise silent or cryptic natural products. In addition, we highlight recent discoveries on the control of antibiotic production in other Actinobacteria, which have gained considerable attention since the start of the genomics revolution. New technologies that have the potential to produce a step change in our understanding of the regulation of secondary metabolism are also described.

The regulation of the secondary metabolism of Streptomyces: new links and experimental advances

Streptomycetes and other actinobacteria are renowned as a rich source of natural products of clinical, agricultural and biotechnological value. They are being mined with renewed vigour, supported by genome sequencing efforts, which have revealed a coding capacity for secondary metabolites in vast excess of expectations that were based on the detection of antibiotic activities under standard laboratory conditions. Here we review what is known about the control of production of so-called secondary metabolites in streptomycetes, with an emphasis on examples where details of the underlying regulatory mechanisms are known. Intriguing links between nutritional regulators, primary and secondary metabolism and morphological development are discussed, and new data are included on the carbon control of development and antibiotic production, and on aspects of the regulation of the biosynthesis of microbial hormones. Given the tide of antibiotic resistance emerging in pathogens, this review is peppered with approaches that may expand the screening of streptomycetes for new antibiotics by awakening expression of cryptic antibiotic biosynthetic genes. New technologies are also described that have potential to greatly further our understanding of gene regulation in what is an area fertile for discovery and exploitation

S-adenosyl-L-methionine activates actinorhodin biosynthesis by increasing autophosphorylation of the Ser/Thr protein kinase AfsK in Streptomyces coelicolor A3(2)

S-Adenosyl-L-methionine (SAM) is one of the major methyl donors in all living organisms. The exogenous treatment with SAM leads to increased actinorhodin production in Streptomyces coelicolor A3(2). In this study, mutants from different stages of the AfsK-AfsR signal transduction cascade were used to test the possible target of SAM. SAM had no significant effect on actinorhodin production in afsK, afsR, afsS, or actII-open reading frame 4 (ORF4) mutant. This confirms that afsK plays a critical role in delivering the signal generated by exogenous SAM. The afsK-pHJL-KN mutant did not respond to SAM, suggesting the involvement of the C-terminal of AfsK in binding with SAM. SAM increased the in vitro autophosphorylation of kinase AfsK in a dose-dependent manner, and also abolished the effect of decreased actinorhodin production by a Ser/Thr kinase inhibitor, K252a. In sum, our results suggest that SAM activates actinorhodin biosynthesis in S. coelicolor M130 by increasing the phosphorylation of protein kinase AfsK.

Genetic regulation of secondary metabolic pathways in Streptomyces

Streptomyces species are (along with the fungi) the best-known antibiotic-producing organisms. Often, they make several different antibiotics. The biosynthesis of each antibiotic is encoded by a complex gene cluster that usually also contains regulatory and resistance genes. Typically, there may be more than one such pathway-specific regulatory gene per cluster. Both activator and repressor genes are known. Some of the regulatory genes for different pathways are related. In S. coelicolor, expression of several such biosynthetic gene clusters also depends on at least 11 globally acting genes, at least one of which is involved in the translation of a rare codon (UUA). A protein phosphorylation cascade also seems to be involved. Gene clusters closely similar to those for the biosynthesis of aromatic polyketide antibiotics determine spore pigment in some species. These genes show different regulation from antibiotic production genes. The evolution of gene clusters for polyketide antibiotics, and the possible adaptive benefits of secondary metabolism, are discussed.

Binding study of AfsK, a Ser/Thr kinase from Streptomyces coelicolor A3(2) and S-adenosyl-L-methionine

Streptomyces coelicolor A3(2) produces an antibiotic, actinorhodin, which belongs to the aromatic polyketides and which can function as an acid/base indicator. Its production results in the death of microorganisms in the vicinity of S. coelicolor A3(2), and this phenomenon can be used in concert with biopesticides. The exogenous addition of S-adenosyl-L-methionine (SAM) to S. coelicolor A3(2) enhances its actinorhodin production and may initiate actinorhodin biosynthesis, with at least four genes being involved. Of these (because afsK initiates the others), AfsK, the protein expressed from afsK, may be interacting with SAM. Although the three-dimensional structure of AfsK has not been determined, the differences between nuclear magnetic resonance (NMR) signals obtained from the free form of SAM and those from a SAM-protein complex can help us to determine whether SAM binds to the C-terminal of AfsK or not. In the present study, NMR data analysis strongly supported the idea that SAM binds to AfsK.

Identification of StiR, the first regulator of secondary metabolite formation in the myxobacterium Cystobacter fuscus Cb f17.1

Myxobacteria are well established as proficient producers of natural products with numerous biological activities. Although some knowledge has been gained regarding the biosynthesis of secondary metabolites in this class of bacteria, almost nothing is known about the underlying regulatory mechanisms. In order to identify regulatory elements, we submitted the argyrin and stigmatellin producer Cystobacter fuscus to a random transposon mutagenesis strategy and screened 1,000 mutants for the occurrence of strains showing remarkably increased or decreased production of these compounds. In addition to the identification of the stigmatellin biosynthetic gene cluster, a novel positive regulator (stiR) of stigmatellin production was identified after transposon recovery. In order to exclude secondary mutagenesis effects, a double cross-over mutagenesis strategy was applied to the strain resulting in the repeated generation of the transposon genotype. This strain was shown to be equally effected in natural product biosynthesis.

Biochemical activities of the absA two-component system of Streptomyces coelicolor

The AbsA1 sensor kinase and its cognate response regulator AbsA2 are important regulators of antibiotic synthesis in Streptomyces coelicolor. While certain point mutations in absA1 reduce or eliminate the synthesis of several antibiotics, null mutations in these genes bring about enhanced antibiotic synthesis. We show here that AbsA1, which is unusual in sequence and structure, is both an AbsA2 kinase and an AbsA2 approximately P phosphatase. The half-life of AbsA2 approximately P in solution is 68.6 min, consistent with a role in maintaining a relatively stable state of transcriptional repression or activation. We find that mutations in the absA locus that enhance antibiotic synthesis impair AbsA2 kinase activity and that mutations that repress antibiotic synthesis impair AbsA2 approximately P phosphatase activity. These results support a model in which the phosphorylation state of AbsA2 is determined by the balance of the kinase and phosphatase activities of AbsA1 and where AbsA2 approximately P represses antibiotic biosynthetic genes either directly or indirectly.

The putative anti-anti-sigma factor BldG is post-translationally modified by phosphorylation in Streptomyces coelicolor

The Streptomyces coelicolor bldG gene encodes a protein showing similarity to the SpoIIAA and RsbV anti-anti-sigma factors of Bacillus subtilis. Purified maltose binding protein-BldG could be phosphorylated in vitro by wild-type S. coelicolor crude extract, and both the phosphorylated and unphosphorylated forms of BldG could be detected in vivo using isoelectric focusing. ATP was shown to serve as the phosphoryl group donor, and phosphorylation of BldG was abolished when the putative phosphorylation site was changed from a serine to an alanine residue. A bldG mutant strain expressing the non-phosphorylatable BldG protein was unable to undergo morphological differentiation or produce antibiotics even after prolonged incubation, suggesting that phosphorylation of BldG is necessary for proper development in S. coelicolor.

AfsR as an integrator of signals that are sensed by multiple serine/threonine kinases in Streptomyces coelicolor A3(2)

The genome sequence of Streptomyces coelicolor A3(2) has revealed the presence of about 40 protein serine/threonine or tyrosine kinases. AfsK, which is able to phosphorylate AfsR, a transcriptional activator with ATPase activity, represents the first instance in which a bacterial Hanks-type protein kinase phosphorylates a specific protein and exerts biologically important functions. The AfsK-AfsR system in S. coelicolor A3(2) globally controls secondary metabolism. The signal transduction pathway so far demonstrated or suggested is as follows: AfsK loosely attached to the membrane autophosphorylates threonine and serine residues, perhaps on sensing some external stimulus, and enhances its kinase activity. The kinase activity is modulated by KbpA, an AfsK-binding protein, by means of protein-protein interactions. The activated AfsK phosphorylates threonine and serine residues of AfsR in the cytoplasm, by which the DNA-binding activity of AfsR is greatly enhanced. In addition to AfsK, other kinases-including PkaG and AfsL-also phosphorylate AfsR, suggesting that AfsR serves as an integrator of multiple signals sensed by these kinases. The phosphorylated AfsR binds the promoter of afsS, which encodes a protein of 63 amino acids, and forms a closed complex with RNA polymerase. The closed complex is then converted to a transcriptionally active open complex by the energy available from ATP hydrolysis by AfsR. AfsS induced in this way activates transcription of pathway-specific transcriptional activators, such as actII-ORF4 for actinorhodin production and redD for undecylprodigiosin, in an as yet unknown manner.

afsS is a target of AfsR, a transcriptional factor with ATPase activity that globally controls secondary metabolism in Streptomyces coelicolor A3(2)

AfsR is a pleiotropic, global regulator that controls the production of actinorhodin, undecylprodigiosin and calcium-dependent antibiotic in Streptomyces coelicolor A3(2). AfsR, with 993 amino acids, is phosphorylated on serine and threonine residues by a protein serine/threonine kinase AfsK and contains an OmpR-like DNA-binding fold at its N-terminal portion and A- and B-type nucleotide-binding motifs in the middle of the protein. The DNA-binding domain, in-dependently of the nucleotide-binding domain, contributed the binding of AfsR to the upstream region of afsS that locates immediately 3' to afsR and encodes a 63-amino-acid protein. No transcription of afsS in the DeltaafsR background and restoration of afsS transcription by afsR on a plasmid in the same genetic background indicated that afsR served as a transcriptional activator for afsS. Interestingly, the AfsR binding site overlapped the promoter of afsS, as determined by DNase I protection assay and high-resolution S1 nuclease mapping. The nucleotide-binding domain contributed distinct ATPase and GTPase activity. The phosphorylation of AfsR by AfsK greatly enhanced the DNA-binding activity and modulated the ATPase activity. The DNA-binding ability of AfsR was independent of the ATPase activity. However, the ATPase activity was essential for transcriptional activation of afsS, probably because the energy available from ATP hydrolysis is required for the isomerization of the closed complex between AfsR and RNA polymerase to a transcriptionally competent open complex. Thus, AfsR turns out to be a unique transcriptional factor, in that it is modular, in which DNA-binding and ATPase activities are physically separable, and the two functions are modulated by phosphorylation on serine and threonine residues.

A polyketide biosynthetic gene cluster from Streptomyces antibioticus includes a LysR-type transcriptional regulator

In the search for Type II polyketide synthases (PKSs) a DNA fragment was isolated from Streptomyces antibioticus ATCC 11891 (a producer of oleandomycin). DNA sequencing of the cloned fragment revealed six complete ORFs whose deduced products showed similarities to those of other genes known to be involved in polyketide biosynthesis. Several S. coelicolor strains mutated in different steps of actinorhodin biosynthesis (actI, actIII, actV(A) and actVII) were complemented by the cloned genes, suggesting that the isolated genes encode an aromatic polyketide of unknown structure and function. The cluster also contains a putative LysR-type transcriptional regulator (ORF0), which controls PKS gene expression in a heterologous host. DNA binding assays and transcriptional analysis suggest that the pathway-specific regulator for actinorhodin biosynthesis (actII-ORF4) is also involved in the expression of the cloned PKS in the host strain.

Autophosphorylation of a bacterial serine/threonine kinase, AfsK, is inhibited by KbpA, an AfsK-binding protein

A protein serine/threonine kinase, AfsK, and its target protein AfsR globally control physiological and morphological differentiation in the bacterial genus Streptomyces. A protein (KbpA) of 252 amino acids encoded by an open reading frame in a region upstream of afsK in Streptomyces coelicolor A3(2) was identified as an AfsK-interacting protein. The interaction site of AfsK was in the N-terminal portion containing the kinase catalytic domain. KbpA bound a nonphosphorylated form of AfsK and inhibited its autophosphorylation at serine and threonine residues. KbpA in the reaction mixture containing AfsK and AfsR also inhibited the phosphorylation of AfsR by AfsK, presumably because KbpA inhibited the conversion from the inactive, nonphosphorylated form of AfsK to the active, phosphorylated form. kbpA was transcribed throughout growth, and the transcription was enhanced when production of actinorhodin had already started. KbpA thus appeared to play an inhibitory role in a negative feedback system in the AfsK-AfsR regulatory pathway. Consistent with these in vitro observations, kbpA served as a repressor for actinorhodin production in S. coelicolor A3(2); disruption of kbpA greatly enhanced actinorhodin production, and overexpression of kbpA reduced the production.

Modulation of actinorhodin biosynthesis in Streptomyces lividans by glucose repression of afsR2 gene transcription

While the biosynthetic gene cluster encoding the pigmented antibiotic actinorhodin (ACT) is present in the two closely related bacterial species, Streptomyces lividans and Streptomyces coelicolor, it normally is expressed only in S. coelicolor-generating the deep-blue colonies responsible for the S. coelicolor name. However, multiple copies of the two regulatory genes, afsR and afsR2, activate ACT production in S. lividans, indicating that this streptomycete encodes a functional ACT biosynthetic pathway. Here we report that the occurrence of ACT biosynthesis in S. lividans is determined conditionally by the carbon source used for culture. We found that the growth of S. lividans on solid media containing glucose prevents ACT production in this species by repressing the synthesis of afsR2 mRNA; a shift to glycerol as the sole carbon source dramatically relieved this repression, leading to extensive ACT synthesis and obliterating this phenotypic distinction between S. lividans and S. coelicolor. Transcription from the afsR2 promoter during growth in glycerol was dependent on afsR gene function and was developmentally regulated, occurring specifically at the time of aerial mycelium formation and coinciding temporally with the onset of ACT production. In liquid media, where morphological differentiation does not occur, ACT production in the absence of glucose increased as S. lividans cells entered stationary phase, but unlike ACT biosynthesis on solid media, occurred by a mechanism that did not require either afsR or afsR2. Our results identify parallel medium-dependent pathways that regulate ACT biosynthesis in S. lividans and further demonstrate that the production of this antibiotic in S. lividans grown on agar can be modulated by carbon source through the regulation of afsR2 mRNA synthesis.

An AfsK/AfsR system involved in the response of aerial mycelium formation to glucose in Streptomyces griseus

In Streptomyces coelicolor A3(2), a protein serine/threonine kinase (AfsK) and its target protein (AfsR) control secondary metabolism. AfsK and AfsR homologues (AfsK-g and AfsR-g) from Streptomyces griseus showed high end-to-end similarity in amino acid sequence with the respective S. coelicolor A3(2) proteins, as determined by cloning and nucleotide sequencing. AfsK-g and a fusion protein between AfsK-g and thioredoxin (TRX-AfsK-g) produced in high yield as inclusion bodies in Escherichia coli were solubilized with urea, purified by column chromatography and then refolded to an active form by dialysis to gradually remove the urea. AfsR-g was also fused to glutathione S-transferase (GST-AfsR-g); the fusion product in the soluble fraction in E. coli was purified. Incubation of AfsK-g or TRX-AfsK-g in the presence of [gamma-32P]ATP yielded autophosphorylated products containing phosphoserine and phosphothreonine residues. In addition, TRX-AfsK-g phosphorylated serine and threonine residues of GST-AfsR-g in the presence of [gamma-32P]ATP. Disruption of chromosomal afsK-g had no effect on A-factor or streptomycin production, irrespective of the culture conditions. The afsK-g disruptants did not form aerial mycelium or spores on media containing glucose at concentrations higher than 1%, but did form spores on mannitol- and glycerol-containing media; this suggests that afsK-g is essential for morphogenesis in the presence of glucose. Introduction of afsK-g restored aerial mycelium formation in the disruptants. The phenotype of afsR-g disruptants was similar to that of afsK-g disruptants; introduction of afsR-g restored the defect in aerial mycelium formation on glucose-containing medium. Thus the AfsK/AfsR system in S. griseus is conditionally needed for morphological differentiation, whereas in S. coelicolor A3(2) it is conditionally involved in secondary metabolism.

Transcriptional regulation of Streptomyces coelicolor pathway-specific antibiotic regulators by the absA and absB loci

The four antibiotics produced by Streptomyces coelicolor are all affected by mutations in the absA and absB loci. The absA locus encodes a putative two-component signal transduction system, and the absB locus encodes a homolog of Escherichia coli RNase III. We assessed whether these loci control synthesis of the antibiotics actinorhodin and undecylprodigiosin by regulating transcript abundance from the biosynthetic and regulatory genes specific for each antibiotic. Strains that were Abs- (for antibiotic synthesis deficient) due to mutations in absA or absB were examined. In the Abs- absA mutant strain, transcripts for the actinorhodin biosynthetic genes actVI-ORF1 and actI, and for the pathway-specific regulatory gene actII-ORF4, were substantially lower in abundance than in the parent strain. The level of the transcript for the undecylprodigiosin pathway-specific regulatory gene redD was similarly reduced in this mutant. Additionally, a strain that exhibits precocious hyperproduction of antibiotics (Pha phenotype) due to disruption of the absA locus contained elevated levels of the actVI-ORF1, actII-ORF4, and redD transcripts. In the absB mutant strain, actVI-ORF1, actI, actII-ORF4, and redD transcript levels were also substantially lower than in the parent strain. These results establish that the abs genes affect production of antibiotics through regulation of expression of the antibiotic-specific regulatory genes in S. coelicolor.

Expression of the Streptomyces coelicolor A3(2) ptpA gene encoding a phosphotyrosine protein phosphatase leads to overproduction of secondary metabolites in S. lividans

A DNA fragment that caused pigment production in Streptomyces lividans was isolated from a gene library of PstI-digested chromosomal fragments of S. coelicolor A3(2). Subcloning and nucleotide sequencing proved the identity of the cloned gene to ptpA encoding a low-molecular-mass phosphotyrosine protein phosphatase. The S. lividans transformant containing ptpA on pIJ41 with a copy number of 3 4 per genome produced large amounts of undecylprodigiosin and A-factor, in addition to the pigmented antibiotic actinorhodin, whereas the transformant containing ptpA on an SCP2* derivative with a copy number of 1-2 did not. The PtpA protein produced as a fusion to the maltose binding protein in Escherichia coli showed phosphatase activity toward o-phosphotyrosine, but not toward o-phosphoserine or a-threonine. Introduction of a mutant ptpA gene encoding an inactive protein with serine instead of the 9th cysteine caused no pigmentation. Disruption of the chromosomal ptpA gene of S. coelicolor A3(2), however, appeared to cause no detectable effect on the production of the pigmented antibiotics or A-factor and the ptpA disruptants developed aerial mycelium and spores normally.

Signal transduction and secondary metabolism: prospects for controlling productivity

Evidence is accumulating that demonstrates the key roles played by diffusible molecules in regulating cellular differentiation, even among prokaryotic microorganisms. This is exemplified by A-factor and its analogues, which act as autoregulators for morphological differentiation and secondary metabolism in Streptomyces. The identification of a specific receptor for A-factor and an A-factor-controlled promoter sequence in S. griseus indicate the close similarity of this system to eukaryotic hormonal control. The involvement of prokaryotic homologues of the eukaryotic Ser/Thr-kinases in the regulation of differentiation processes seems to be another characteristic feature of this group of bacteria. Recent evidence for the presence of these molecular signalling systems in Streptomyces is reviewed, along with the inherent implications.

afsR2: a previously undetected gene encoding a 63-amino-acid protein that stimulates antibiotic production in Streptomyces lividans

Earlier work has shown that the afsR genetic locus promotes formation of the pigmented antibiotics actinorhodin and undecylprodigiosin in Streptomyces lividans and its close relative, Streptomyces coelicolor. A protein designated as AfsR has been implicated in this activity. We report here the existence of a previously unknown gene, afsR2, which is separate from and adjacent to the AfsR-encoding sequence and which, when present at high copy number, (i) stimulates transcription of biosynthetic and regulatory genes in the actinorhodin gene cluster (act), and (ii) stimulates the synthesis of undecylprodigiosin. We show that the effects of afsR2 on actinorhodin synthesis are mediated through transcription of the actII-ORF4 locus, which encodes a transcriptional activator of other genes in the act cluster. Analysis of the cloned afsR2 gene indicates that its activity is the result of the 63-amino-acid protein it specifies.

Phosphorylation of the AfsR protein involved in secondary metabolism in Streptomyces species by a eukaryotic-type protein kinase

A global regulatory protein, AfsR, involved in secondary metabolism, was found to be phosphorylated by a membrane-associated phosphokinase, named AfsK, of Streptomyces coelicolor A3(2) and S. lividans. The N-terminal portion of AfsK, deduced from the nucleotide (nt) sequence of the afsK gene, which was located downstream from the afsR gene, showed significant sequence similarity to the catalytic domain of eukaryotic Ser/Thr protein kinases (PKs). Consistent with this, experiments with AfsK produced by use of an Escherichia coli host-vector system revealed a self-catalyzed phosphate incorporation into both Ser and Tyr residues of AfsK. The recombinant AfsK phosphorylated the purified AfsR at both Ser and Thr residues. Disruption of the chromosomal afsK gene with the phage vector KC515 resulted in significant, but not complete, loss of actinorhodin production. This result implies the involvement of afsK in the regulation of secondary metabolism. The presence of an additional PK able to phosphorylate AfsR is predicted, because the afsK-disrupted strain still contained an activity able to phosphorylate Ser and Thr residues of AfsR. Southern hybridization experiments showed that nt sequences homologous to afsK, as well as afsR, were distributed among many Streptomyces spp. It is thus concluded that a signal transduction system similar to that found in higher organisms is involved in the regulation of secondary metabolism in the bacterial genus Streptomyces.

A-factor and streptomycin biosynthesis in Streptomyces griseus

Accumulating data have shown that the metabolites with a gamma-butyrolactone ring functions as an autoregulatory factor or a microbial hormone for the expression of various phenotypes not only in a variety of Streptomyces spp. but also in the distantly related bacteria. A-factor, as a representative of this type of autoregulators, triggers streptomycin biosynthesis and cellular differentiation in Streptomyces griseus. A model for the A-factor regulatory cascade on the basis of recent work is as follows. At an early step in the A-factor regulatory relay, the positive A-factor signal is first received by an A-factor receptor protein that is comparable in every aspect to eukaryotic hormone receptors, and then, via one or more regulatory steps, transmitted to an A-factor-responsive protein that binds to the upstream activation sequence of the strR gene, a regulatory gene in the streptomycin biosynthetic gene cluster. The StrR protein thus induced appears to activate the other streptomycin biosynthetic genes. This review summarizes the characteristics of A-factor as a microbial hormone and the A-factor regulatory relay leading to streptomycin production.

Genetic control of polyketide biosynthesis in the genus Streptomyces

The genetic control of polyketide metabolite biosynthesis in Streptomyces sp. producing actinorhodin, daunorubicin, erythromycin, spiramycin, tetracenomycin and tylosin is reviewed. Several examples of positively-acting transcriptional regulators of polyketide metabolism are known, including some two-component sensor kinase-response regulator systems. Translational and posttranslational control mechanisms are only briefly mentioned since very little is known about either of these processes. Examples of how enzyme levels and substrate supply affect polyketide metabolism also are discussed.

ATP-dependent protein kinases in bacteria

Protein phosphorylation has been shown to occur in over fifty different bacterial species and, therefore, seems to be a universal device among prokaryotes. Most of the protein kinases responsible for this modification of proteins share the common property of using adenosine triphosphate as phosphoryl donor. However, they differ from one another in a number of structural and functional aspects. Namely, they exhibit a varying acceptor amino acid specificity and can be classified, on this basis, in three main groups: protein-histidine kinases, protein-serine/threonine kinases and protein-tyrosine kinases.

Effects of protein kinase inhibitors on in vitro protein phosphorylation and cellular differentiation of Streptomyces griseus

In vitro phosphorylation reactions using extracts of Streptomyces griseus cells and gamma-[32P]ATP revealed the presence of multiple phosphorylated proteins. Most of the phosphorylations were distinctly inhibited by staurosporine and K-252a which are known to be eukaryotic protein kinase inhibitors. The in vitro experiments also showed that phosphorylation was greatly enhanced by manganese and inhibition of phosphorylation by staurosporine and K-252a was partially circumvented by 10 mM manganese. A calcium-activated protein kinase(s) was little affected by these inhibitors. Herbimycin and radicicol, known to be tyrosine kinase inhibitors, completely inhibited the phosphorylation of one protein. Consistent with their in vitro effects the protein kinase inhibitors inhibited aerial mycelium formation and pigment production by S. griseus. All these data suggest that S. griseus possesses several protein kinases of eukaryotic type which are essential for morphogenesis and secondary metabolism. In vitro phosphorylation of some proteins in a staurosporine-producing Streptomyces sp. was also inhibited by staurosporine, K-252a and herbimycin, which suggests the presence of a mechanism for self-protection in this microorganism.

A putative two-component regulatory system involved in secondary metabolism in Streptomyces spp

A DNA fragment stimulating actinorhodin, undecylprodigiosin, and A-factor production in Streptomyces lividans 66 was cloned from Streptomyces coelicolor A3(2). Nucleotide sequencing revealed the presence of an open reading frame of 225 codons, named afsQ1, that showed great similarity in amino acid sequence to the response regulators of typical prokaryotic two-component regulatory systems responsible for adaptive responses. The termination codon, TGA, of afsQ1 overlapped the initiation codon, GTG, of a second open reading frame, afsQ2, of 535 codons. The afsQ2 gene product showed homology with the sensory histidine protein kinases of two-component systems. In agreement with the assumption that the AfsQ1 and AfsQ2 proteins comprise an aspartate-histidine phosphotransfer system, an amino acid replacement from Asp to Glu at residue 52 of AfsQ1, generated by site-directed mutagenesis, resulted in loss of the protein's ability to stimulate antibiotic production in S. lividans. Primer extension experiments indicated that transcription of the afsQ1 and afsQ2 genes initiates at the translational start codon (GTG) of the afsQ1 gene. The afsQ1 and afsQ2 genes were physically mapped at a chromosomal position near the actinorhodin biosynthetic gene cluster (act) by hybridization to Southern blots of restriction fragments separated by pulsed-field gel electrophoresis. Disruption of either afsQ1 or afsQ2 on the S. coelicolor chromosome by use of phage phi C31KC515 led to no detectable change in secondary metabolite formation or morphogenesis. The afsQ1 gene on pIJ922 suppressed the S. coelicolor absA mutation and caused actinorhodin production but did not suppress the absB mutation. Southern blot hybridization showed that sequences homologous to afsQ1 and afsQ2 are present in almost all of the actinomycetes examined.

Regulation of secondary metabolism and cell differentiation in Streptomyces: A-factor as a microbial hormone and the AfsR protein as a component of a two-component regulatory system

A-factor is a microbial hormone that functions as a key switch for secondary metabolite formation and morphogenesis in Streptomyces griseus. Genetic and biochemical studies on the A-factor-binding protein have implied that the binding protein present in the cytoplasm plays a role in repressing streptomycin (Sm) production and sporulation while the binding of A-factor to the binding protein releases this repression. The A-factor signal is transferred, probably via some additional regulatory proteins in the A-factor-regulatory cascade, to the strR gene, a regulator for Sm biosynthesis. A positive regulatory protein binds about 430-330 bp upstream from the transcription start point of the strR promoter and activates its transcription. The StrR product, in turn, activates the other Sm-biosynthesis genes. A global regulatory gene, afsR, of Streptomyces coelicolor A3(2) encodes a 993-amino acid protein that is phosphorylated by a specific phosphokinase, AfsK, encoded by the region just upstream from the afsR gene. Site-directed mutagenesis of afsR has revealed that phosphorylated AfsR globally stimulates transcription of antibiotic-production genes. It is most likely that AfsR and AfsK compose a two-component regulatory system. Although AfsR shows no significant homology with typical regulators of the two-component systems in other prokaryotes, such as OmpR and PhoB of Escherichia coli, it shows considerable homology with regulatory proteins in antibiotic biosynthetic gene clusters of Streptomyces spp., such as actII ORF4, dnrR1 ORF1 and redD ORF1.(ABSTRACT TRUNCATED AT 250 WORDS)

Secondary metabolites as chemical signals for cellular differentiation

Several microbial secondary metabolites function as essential chemical signals for induction of cellular differentiation in the producing organisms. The role of A-factor and its analogues such as essential autoregulators in actinomycetes is discussed and a review is given of fungal metabolites with hormonal activities. Divergent secondary metabolites with the capability to induce cellular differentiation in other organisms are also discussed as to their possible involvement in a symbiotic relationship in the ecosystem.

Global control in Pseudomonas fluorescens mediating antibiotic synthesis and suppression of black root rot of tobacco

Pseudomonas fluorescens CHA0 colonizes plant roots, produces several secondary metabolites in stationary growth phase, and suppresses a number of plant diseases, including Thielaviopsis basicola-induced black root rot of tobacco. We discovered that mutations in a P. fluorescens gene named gacA (for global antibiotic and cyanide control) pleiotropically block the production of the secondary metabolites 2,4-diacetylphloroglucinol (Phl), HCN, and pyoluteorin. The gacA mutants of strain CHA0 have a drastically reduced ability to suppress black root rot under gnotobiotic conditions, supporting the previous observations that the antibiotic Phl and HCN individually contribute to the suppression of black root rot. The gacA gene is directly followed by a uvrC gene. Double gacA-uvrC mutations render P. fluorescens sensitive to UV irradiation. The gacA-uvrC cluster is homologous to the orf-2 (= uvrY)-uvrC operon of Escherichia coli. The gacA gene specifies a trans-active 24-kDa protein. Sequence data indicate that the GacA protein is a response regulator in the FixJ/DegU family of two-component regulatory systems. Expression of the gacA gene itself was increased in stationary phase. We propose that GacA, perhaps activated by conditions of restricted growth, functions as a global regulator of secondary metabolism in P. fluorescens.

Clusters of genes for the biosynthesis of antibiotics: Regulatory genes and overproduction of pharmaceuticals

In the last decade numerous genes involved in the biosynthesis of antibiotics, pigments, herbicides and other secondary metabolites have been cloned. The genes involved in the biosynthesis of penicillin, cephalosporin and cephamycins are organized in clusters as occurs also with the biosynthetic genes of other antibiotics and secondary metabolites (see review by Martín and Liras [65]). We have cloned genes involved in the biosynthesis of beta-lactam antibiotics from five different beta-lactam producing organisms both eucaryotic (Penicillium chrysogenum, Cephalosporium acremonium (syn. Acremonium chrysogenum) Aspergillus nidulans) and procaryotic (Nocardia lactamdurans, Streptomyces clavuligerus). In P. chrysogenum and A. nidulans the organization of the pcbAB, pcbC and penDE genes for ACV synthetase, IPN synthase and IPN acyltransferase showed a similar arrangement. In A. chrysogenum two different clusters of genes have been cloned. The cluster of early genes encodes ACV synthetase and IPN synthase, whereas the cluster of late genes encodes deacetoxycephalosporin C synthetase/hydroxylase and deacetylcephalosporin C acetyltransferase. In N. lactamdurans and S. clavuligerus a cluster of early cephamycin genes has been fully characterized. It includes the lat (for lysine-6-aminotransferase), pcbAB (for ACV synthase) and pcbC (for IPN synthase) genes. Pathway-specific regulatory genes which act in a positive (or negative) form are associated with clusters of genes involved in antibiotic biosynthesis. In addition, widely acting positive regulatory elements exert a pleiotropic control on secondary metabolism and differentiation of antibiotic producing microorganisms. The application of recombinant DNA techniques will contribute significantly to the improvement of fermentation organisms.

Regulation of secondary metabolism in Streptomyces spp. and overproduction of daunorubicin in Streptomyces peucetius

Two DNA segments, dnrR1 and dnrR2, from the Streptomyces peucetius ATCC 29050 genome were identified by their ability to stimulate secondary metabolite production and resistance. When introduced into the wild-type ATCC 29050 strain, the 2.0-kb dnrR1 segment caused a 10-fold overproduction of epsilon-rhodomycinone, a key intermediate of daunorubicin biosynthesis, whereas the 1.9-kb dnrR2 segment increased production of both epsilon-rhodomycinone and daunorubicin 10- and 2-fold, respectively. In addition, the dnrR2 segment restored high-level daunorubicin resistance to strain H6101, a daunorubicin-sensitive mutant of S. peucetius subsp. caesius ATCC 27952. Analysis of the sequence of the dnrR1 fragment revealed the presence of two closely situated open reading frames, dnrI and dnrJ, whose deduced products exhibit high similarity to the products of several other Streptomyces genes that have been implicated in the regulation of secondary metabolism. Insertional inactivation of dnrI in the ATCC 29050 strain with the Tn5 kanamycin resistance gene abolished epsilon-rhodomycinone and daunorubicin production and markedly decreased resistance to daunorubicin. Sequence comparison between the products of dnrIJ and the products of the Streptomyces coelicolor actII-orf4, afsR, and redD-orf1 genes and of the Streptomyces griseus strS, the Saccharopolyspora erythraea eryC1, and the Bacillus stearothermophilus degT genes reveals two families of putative regulatory genes. The members of the DegT, DnrJ, EryC1, and StrS family exhibit some of the features characteristic of the protein kinase (sensor) component of two-component regulatory systems from other bacteria (even though none of the sequences of these four proteins show a significant overall or regional similarity to such protein kinases) and have a consensus helix-turn-helix motif typical of DNA binding proteins. A helix-turn-helix motif is also present in two of the proteins of the other family, AfsR and RedD-Orf1. Both sets of Streptomyces proteins are likely to be trans-acting factors involved in regulating secondary metabolism.