A missense mutation in ftsZ differentially affects vegetative and developmentally controlled cell division in Streptomyces coelicolor A3(2)

Streptomyces coelicolor A3(2) undergoes at least two kinds of cell division: vegetative septation leading to cross-walls in the substrate mycelium; and developmentally regulated sporulation septation in aerial hyphae. By isolation and characterization of a non-sporulating ftsZ mutant, we demonstrate a difference between the two types of septation. The ftsZ17(Spo) allele gave rise to a classical white phenotype. The mutant grew as well as the parent on plates, and formed apparently normal hyphal cross-walls, although with a small reduction in frequency. In contrast, sporulation septation was almost completely abolished, resulting in a phenotype reminiscent of whiH and ftsZdelta2p mutants. The ftsZ17(Spo) allele was partially dominant and had no detectable effect on the cellular FtsZ content. As judged from both immunofluorescence microscopy of FtsZ and translational fusion of ftsZ to egfp, the mutation prevented correct temporal and spatial assembly of Z rings in sporulating hyphae. Homology modelling of S. coelicolor FtsZ indicated that the mutation, an A249T change in the C-terminal domain, would be expected to alter the protein on the lateral face of FtsZ protofilaments. The results suggest that cytokinesis may be developmentally controlled at the level of Z-ring assembly during sporulation of S. coelicolor A3(2).     

WhiA, a protein of unknown function conserved among gram-positive bacteria, is essential for sporulation in Streptomyces coelicolor A3(2)

The whiA sporulation gene of Streptomyces coelicolor A3(2), which plays a key role in switching aerial hyphae away from continued extension growth and toward sporulation septation, was cloned by complementation of whiA mutants. DNA sequencing of the wild-type allele and five whiA mutations verified that whiA is a gene encoding a protein with homologues in all gram-positive bacteria whose genome sequence is known, whether of high or low G+C content. No function has been attributed to any of these WhiA-like proteins. In most cases, as in S. coelicolor, the whiA-like gene is downstream of other conserved genes in an operon-like cluster. Phenotypic analysis of a constructed disruption mutant confirmed that whiA is essential for sporulation. whiA is transcribed from at least two promoters, the most downstream of which is located within the preceding gene and is strongly up-regulated when colonies are undergoing sporulation. The up-regulation depends on a functional whiA gene, suggesting positive autoregulation, although it is not known whether this is direct or indirect. Unlike the promoters of some other sporulation-regulatory genes, the whiA promoter does not depend on the sporulation-specific sigma factor encoded by whiG.     

Structure and function ofsawB, a gene involved in differentiation ofStreptomyces ansochromogenes

A partial DNA library of Streptomyces ansochromogenes 7100 was constructed by using plasmid plJ702 as vector and white mutant W19 as recipient. About 3 000 clones were obtained, two of which gave rise to the grey phenotype as wild type 7100. The plasmids were isolated from two transformants. The result indicated that the 5.2 kb and 5.8 kb DNA fragments were inserted into plJ702. The resulting recombinant plasmids were designated as pNL-1 and pNL-2 respectively. The 1.25 kb Pstl l-Apa l DNA fragment from pNL-1 was recognized as its complementarity to W19 strain. The nucleotide sequence of the 3.0 kb Pst I DNA fragment including 1.25 kb was determined and analyzed. The result indicated that this DNA fragment contains one complete open reading frame (ORF1) which encodes a protein with 295 amino acid residues, and this gene was designated as sawB. The deduced protein has 81% amino acid identities in comparison with that encoded by whiH in Streptomyces coelicolor. The function of sawB gene was studied by usi     

Implication of stringent response in the increase of mutability of the whiG and whiH genes during Streptomyces coelicolor development

In Streptomyces ambofaciens, genetic instability occurring during aerial mycelium development gives rise to white mutant papillae on colonies. Pig-pap mutants deriving from such papillae are unable to sporulate and devoid of the large genome rearrangement usually observed in the other Streptomyces mutants that genetic instability generated. Pig-pap mutants frequently harboured discrete mutations affecting the whiG gene. Furthermore, it has been established that the production of papillae dramatically increased when S. ambofaciens was grown under an amino acid limitation. In this work, we tested the implication of the stringent response, induced during an amino acid limitation, in the production of white papillae in Streptomyces coelicolor, a species which is phylogenetically close to S. ambofaciens. First, we showed that S. coelicolor produced mutant papillae and that this production was increased under an amino acid limitation. Secondly, we showed that the Pig-pap mutants generated both with and without amino acid limitation frequently exhibited mutations in whiH or whiG genes. Finally, we observed that a relA mutant of S. coelicolor, which was unable to elicit the stringent response under an amino acid limitation, was also unable to produce papillae. The restoration of the ability to elicit the stringent response also restored the papillae production. These papillae gave rise to Pig-pap mutants displaying the same characteristics as Pig-pap mutants spontaneously appearing on wild-type colonies. Altogether, these results show that whatever the underlying mechanism, the stringent response is involved in the production of white papillae in S. coelicolor.     

The product of a developmental gene, crgA, that coordinates reproductive growth in Streptomyces belongs to a novel family of small actinomycete-specific proteins

On solid media, the reproductive growth of Streptomyces involves antibiotic biosynthesis coincident with the erection of filamentous aerial hyphae. Following cessation of growth of an aerial hypha, multiple septation occurs at the tip to form a chain of unigenomic spores. A gene, crgA, that coordinates several aspects of this reproductive growth is described. The gene product is representative of a well-conserved family of small actinomycete proteins with two C-terminal hydrophobic-potential membrane-spanning segments. In Streptomyces avermitilis, crgA is required for sporulation, and inactivation of the gene abolished most sporulation septation in aerial hyphae. Disruption of the orthologous gene in Streptomyces coelicolor indicates that whereas CrgA is not essential for sporulation in this species, during growth on glucose-containing media, it influences the timing of the onset of reproductive growth, with precocious erection of aerial hyphae and antibiotic production by the mutant. Moreover, CrgA subsequently acts to inhibit sporulation septation prior to growth arrest of aerial hyphae. Overexpression of CrgA in S. coelicolor, uncoupling any nutritional and growth phase-dependent regulation, results in growth of nonseptated aerial hyphae on all media tested, consistent with a role for the protein in inhibiting sporulation septation.     

New Sporulation Loci in Streptomyces coelicolor A3(2)

Sporulation mutants of Streptomyces coelicolor appear white because they are defective in the synthesis of the grey polyketide spore pigment, and such white (whi) mutants had been used to define eight sporulation loci, whiA, whiB, whiD, whiE, whiG, whiH, whiI, and whiJ (K. F. Chater, J. Gen. Microbiol. 72:9-28, 1972; N. J. Ryding, Ph.D. thesis, University of East Anglia, 1995). In an attempt to identify new whi loci, we mutagenized S. coelicolor M145 spores with nitrosoguanidine and identified 770 mutants with colonies ranging from white to medium grey. After excluding unstable strains, we examined the isolates by phase-contrast microscopy and chose 115 whi mutants with clear morphological phenotypes for further study. To exclude mutants representing cloned whi genes, self-transmissible SCP2*-derived plasmids carrying whiA, whiB, whiG, whiH, or whiJ (but not whiD, whiE, or whiI) were introduced into each mutant by conjugation, and strains in which the wild-type phenotype was restored either partially or completely by any of these plasmids were excluded from further analysis. In an attempt to complement some of the remaining 31 whi mutants, an SCP2* library of wild-type S. coelicolor chromosomal DNA was introduced into 19 of the mutants by conjugation. Clones restoring the wild-type phenotype to 12 of the 19 strains were isolated and found to represent five distinct loci, designated whiK, whiL, whiM, whiN, and whiO. Each of the five loci was located on the ordered cosmid library: whiL, whiM, whiN, and whiO occupied positions distinct from previously cloned whi genes; whiK was located on the same cosmid overlap as whiD, but the two loci were shown by complementation to be distinct. The phenotypes resulting from mutations at each of these new loci are described.     

A new RNA polymerase sigma factor, σF is required for the late stages of morphological differentiation in Streptomyces spp.

A gene ( sigF ) encoding a new sigma factor was isolated from Streptomyces aureofaciens using a degenerate oligonucleotide probe designed from the GLI(KDNE)A motif lying within the well-conserved region 2.2 of the eubacterial σ⁷⁰ family. Homologues were present in other Streptomyces spp., and that of the genetically well-studied Streptomyces coelicolor A3(2) was also cloned. The nucleotide sequences of the two sigF genes were determined and shown to encode primary translation products of 287 ( S. coelicolor ) and 295 ( S. aureofaciens ) amino acid residues, both showing greatest similarity to σ^B of Bacillus subtilis . However, while σ^B is involved in stationary-phase gene expression and in the general stress response in B. subtilis , σ^F affects morphological differentiation in Streptomyces , Disruption of sigF did not affect vegetative growth but did cause a whi mutant phenotype. Microscopic examination showed that the sigF mutant produced spores that were smaller and deformed compared with those of the wild type, that the spore walls were thinner and sensitive to detergents and that in sigF mutant spores the chromosome failed to condense. σ^F is proposed to control the late stages of spore development in Streptomyces .