NepA is a structural cell wall protein involved in maintenance of spore dormancy in Streptomyces coelicolor

Streptomycetes have a complex morphogenetic programme culminating in the formation of aerial hyphae that develop into chains of spores. After spore dispersal, environmental signals trigger dormant spores to germinate to establish a new colony. We here compared whole genome expression of a wild-type colony of Streptomyces coelicolor forming aerial hyphae and spores with that of the chp null mutant that forms few aerial structures. This revealed that expression of 244 genes was significantly altered, among which genes known to be involved in development. One of the genes that was no longer expressed in the Δ chpABCDEFGH mutant was nepA , which was previously shown to be expressed in a compartment connecting the substrate mycelium with the sporulating parts of the aerial mycelium. We here show that expression is also detected in developing spore chains, where NepA is secreted to end up as a highly insoluble protein in the cell wall. Germination of spores of a nepA deletion mutant was faster and more synchronous, resulting in colonies with an accelerated morphogenetic programme. Crucially, spores of the Δ nepA mutant also germinated in water, unlike those of the wild-type strain. Taken together, NepA is the first bacterial structural cell wall protein that is important for maintenance of spore dormancy under unfavourable environmental conditions.     

Different alleles of the response regulator gene bldM arrest Streptomyces coelicolor development at distinct stages

whiK was one of five new whi loci identified in a recent screen of NTG-induced whi mutants and was defined by three mutants, R273, R318 and R655. R273 and R318 produce long, tightly coiled aerial hyphae with frequent septation. In contrast, R655 shows a more severe phenotype; it produces straight, undifferentiated aerial hyphae with very rare short chains of spores. Subcloning and sequencing showed that whiK encodes a member of the FixJ subfamily of response regulators, with a C-terminal helix-turn-helix DNA-binding domain and an apparently typical N-terminal phosphorylation pocket. Unexpectedly, a constructed whiK null mutant failed to form aerial mycelium, showing that different alleles of this locus can arrest Streptomyces coelicolor development at very distinct stages. As a consequence of the null mutant phenotype, whiK was renamed bldM. The bldM null mutant fits into the extracellular signalling cascade proposed for S. coelicolor and is a member of the bldD extracellular complementation group. The three original NTG-induced mutations that defined the whiK/bldM locus each affected the putative phosphorylation pocket. The mutations in R273 and in R318 were the same, replacing a highly conserved glycine (G-62) with aspartate. The more severe mutant, R655, carried a C-7Y substitution adjacent to the highly conserved DD motif at positions 8-9. However, although bldM has all the highly conserved residues associated with the phosphorylation pocket of conventional response regulators, aspartate-54, the putative site of phosphorylation, is not required for bldM function. Constructed mutant alleles carrying either D-54N or D-54A substitutions complemented the bldM null mutant in single copy in trans, and strains carrying the D-54N or the D-54A substitution at the native chromosomal bldM locus sporulated normally. bldM was not phosphorylated in vitro with either of the small-molecule phosphodonors acetyl phosphate or carbamoyl phosphate under conditions in which a control response regulator protein, NtrC, was labelled efficiently.     

Disruption of a sigma factor gene, sigF, affects an intermediate stage of spore pigment production in Streptomyces aureofaciens

The Streptomyces aureofaciens sigF gene encodes a sigma factor. By integrative transformation, via double cross-over, a stable null mutant of sigF gene was obtained. This mutation appeared to have no obvious effect on vegetative growth, but affected the late stage of spore maturation. Microscopic examination showed that spores were deformed, and spore wall was thinner, compared with the wild-type spores. The spore pigment of sigF mutant was green, compared to wild-type grey-pink spore pigmentation. The plasmid-born wild-type sigF gene complemented the mutation after transformation of the mutant strain.     

GAS2 and GAS4, a pair of developmentally regulated genes required for spore wall assembly in Saccharomyces cerevisiae

The GAS multigene family of Saccharomyces cerevisiae is composed of five paralogs (GAS1 to GAS5). GAS1 is the only one of these genes that has been characterized to date. It encodes a glycosylphosphatidylinositol-anchored protein functioning as a beta(1,3)-glucan elongase and required for proper cell wall assembly during vegetative growth. In this study, we characterize the roles of the GAS2 and GAS4 genes. These genes are expressed exclusively during sporulation. Their mRNA levels showed a peak at 7 h from induction of sporulation and then decreased. Gas2 and Gas4 proteins were detected and reached maximum levels between 8 and 10 h from induction of sporulation, a time roughly coincident with spore wall assembly. The double null gas2 gas4 diploid mutant showed a severe reduction in the efficiency of sporulation, an increased permeability of the spores to exogenous substances, and production of inviable spores, whereas the single gas2 and gas4 null diploids were similar to the parental strain. An analysis of spore ultrastructure indicated that the loss of Gas2 and Gas4 proteins affected the proper attachment of the glucan to the chitosan layer, probably as a consequence of the lack of coherence of the glucan layer. The ectopic expression of GAS2 and GAS4 genes in a gas1 null mutant revealed that these proteins are redundant versions of Gas1p specialized to function in a compartment at a pH value close to neutral.     

Colony development in Streptomyces carpinensis: a streptomycete with substrate mycelium spores

In this paper we present an ultrastructural study of spore formation in aerial vs. substrate mycelia of Streptomyces carpinensis. Both mycelia initiated spore formation at nearly the same time of colony development but exhibited different patterns of spatial localization of sporulation: spore formation took place throughout the aerial mycelium whereas in the substrate mycelium was confined to a narrow zone at the bottom of the colony. The ultrastructural changes leading to spore formation, however, were quite similar in both mycelia, differing only with respect to the outer components of the sporal wall. Spores formed in the aerial mycelium were covered by a thin sheath whereas the spores formed in the substrate mycelium were covered by an amorphous electron-dense material.