Analysis of a gene that suppresses the morphological defect of bald mutants of Streptomyces griseus

DNA microarray analysis of global gene regulation by A-factor in Streptomyces griseus

A-factor (2-isocapryloyl-3R-hydroxymethyl-gamma-butyrolactone) is a microbial hormone that triggers morphological differentiation and secondary metabolism in Streptomyces griseus. The effects of A-factor on global gene expression were determined by DNA microarray analysis of transcriptomes obtained with the A-factor-deficient mutant DeltaafsA. A-factor was added at a concentration of 25 ng ml(-1) to mutant DeltaafsA at the middle of the exponential growth phase, and RNA samples were prepared from the cells grown after A-factor addition for a further 5, 15 and 30 min, and 1, 2, 4, 8 and 12 h. The effects of A-factor on transcription of all protein-coding genes of S. griseus were evaluated by comparison of the transcriptomes with those obtained from cells grown in the absence of A-factor. Analysis of variance among the transcriptomes revealed that 477 genes, which were dispersed throughout the chromosome, were differentially expressed during the 12 h after addition of A-factor, when evaluated by specific criteria. Quality threshold clustering analysis with regard to putative polycistronic transcriptional units and levels of upregulation predicted that 152 genes belonging to 74 transcriptional units were probable A-factor-inducible genes. Competitive electrophoretic mobility shift assays using DNA fragments including putative promoter regions of these 74 transcriptional units suggested that AdpA bound 37 regions to activate 72 genes in total. Many of these A-factor-inducible genes encoded proteins of unknown function, suggesting that the A-factor regulatory cascade of S. griseus affects gene expression at a specific time point more profoundly than expected.

Identification of a gene negatively affecting antibiotic production and morphological differentiation in Streptomyces coelicolor A3(2)

SC7A1 is a cosmid with an insert of chromosomal DNA from Streptomyces coelicolor A3(2). Its insertion into the chromosome of S. coelicolor strains caused a duplication of a segment of ca. 40 kb and delayed actinorhodin antibiotic production and sporulation, implying that SC7A1 carried a gene negatively affecting these processes. The subcloning of SC7A1 insert DNA resulted in the identification of the open reading frame SCO5582 as nsdA, a gene negatively affecting Streptomyces differentiation. The disruption of chromosomal nsdA caused the overproduction of spores and of three of four known S. coelicolor antibiotics of quite different chemical types. In at least one case (that of actinorhodin), this was correlated with premature expression of a pathway-specific regulatory gene (actII-orf4), implying that nsdA in the wild-type strain indirectly repressed the expression of the actinorhodin biosynthesis cluster. nsdA expression was up-regulated upon aerial mycelium initiation and was strongest in the aerial mycelium. NsdA has DUF921, a Streptomyces protein domain of unknown function and a conserved SXR site. A site-directed mutation (S458A) in this site in NsdA abolished its function. Blast searching showed that NsdA homologues are present in some Streptomyces genomes. Outside of streptomycetes, NsdA-like proteins have been found in several actinomycetes. The disruption of the nsdA-like gene SCO4114 had no obvious phenotypic effects on S. coelicolor. The nsdA orthologue SAV2652 in S. avermitilis could complement the S. coelicolor nsdA-null mutant phenotype.

Differential regulation of ftsZ transcription during septation of Streptomyces griseus

Streptomyces has been known to form two types of septa. The data in this research demonstrated that Streptomyces griseus forms another type of septum near the base of sporogenic hyphae (basal septum). To understand the regulation of the septation machinery in S. griseus, we investigated the expression of the ftsZ gene. S1 nuclease protection assays revealed that four ftsZ transcripts were differentially expressed during morphological differentiation. The vegetative transcript (emanating from P(veg)) is present at a moderate level during vegetative growth, but is switched off within the first 2 h of sporulation. Two sporulation-specific transcripts predominantly accumulated, and the levels increased by approximately fivefold together shortly before sporulation septa begin to form. Consistently, the sporulation-specific transcripts were expressed much earlier and more abundantly in a group of nonsporulating mutants that form their sporulation septa prematurely. Promoter-probe studies with two different reporter systems confirmed the activities of the putative promoters identified from the 5' end point of the transcripts. The levels and expression timing of promoter activities were consistent with the results of nuclease protection assays. The aseptate phenotype of the P(spo) mutant indicated that the increased transcription from P(spo) is required for sporulation septation, but not for vegetative or basal septum formation.

Initiation of aerial mycelium formation in Streptomyces

In the past two years, the isolation of extracellular factors involved in the initiation of aerial mycelium formation, the identification of metabolic defects in certain developmental mutants, and the characterisation of three further bld genes and several gamma-butyrolactone receptor genes have led to new ideas about the mechanisms that initiate aerial mycelium formation in Streptomyces. The emerging picture suggests the integration of numerous signals from both inside and outside the cell.

Taking a genetic scalpel to the Streptomyces colony

1997 Fred Griffith Review Lecture

(Delivered at the 138th Meeting of the Society for General Microbiology, 2 September 1977)

Bald mutants of Streptomyces griseus that prematurely undergo key events of sporulation

To identify the structural defects of nonsporulating mutants of Streptomyces griseus, the wild-type strain and class III bald mutants were examined by using transmission electron microscopy, ultrasonic treatment, and fluorescence microscopy after the induction of submerged sporulation by phosphate starvation. In the wild-type strain, submerged sporulation was marked by the relatively synchronous formation of sporogenic hyphae, nucleoid segregation, deposition of sporulation septa, and subsequent thickening of the spore walls during maturation. All of the class III mutants prematurely synthesized sporulation septa and thick spore walls. The class IIIA and C mutants formed sporogenic hyphae earlier than the wild-type strain and underwent nucleoid segregation in parallel with sporulation septum formation. In the class IIIB (bld4) mutant, DNA segregation appeared to be uncoupled from septum formation. The results indicate that the class III mutants are defective in loci that are involved in the regulation of key events of Streptomyces morphogenesis.