Differential expression of protein S genes during Myxococcus xanthus development

Protein S, the most abundant protein synthesized during development of the fruiting bacterium Myxococcus xanthus, is coded by two highly homologous genes called protein S gene 1 (ops) and protein S gene 2 (tps). The expression of these genes was studied with fusions of the protein S genes to the lacZ gene of Escherichia coli. The gene fusions were constructed so that expression of beta-galactosidase activity was dependent on protein S gene regulatory sequences. Both the gene 1-lacZ fusion and the gene 2-lacZ fusion were expressed exclusively during fruiting body formation (development) in M. xanthus. However, distinct patterns of induction of fusion protein activity were observed for the two genes. Gene 2 fusion activity was detected early during development on an agar surface and could also be observed during nutritional downshift in dispersed liquid culture. Gene 1 fusion activity was not detected until much later in development and was not observed after downshift in liquid culture. The time of induction of gene 1 fusion activity was correlated with the onset of sporulation, and most of the activity was spore associated. This gene fusion was expressed during glycerol-induced sporulation when gene 2 fusion activity could not be detected. The protein S genes appear to be members of distinct regulatory classes of developmental genes in M. xanthus.     

Effects of deletion of the gene for the development-specific protein S on differentiation in Myxococcus xanthus

A deletion mutation of the gene for protein S (tps), a development-specific protein of Myxococcus xanthus, was constructed. No significant differences in the process of fruiting body formation or the yield of myxospores were observed between mutant and wild-type cells. On the other hand, when the tps gene was deleted together with a 2.0-kilobase sequence including the ops gene immediately upstream of the tps gene, fruiting body formation was substantially delayed, and the yield of myxospores was reduced. These results indicate that protein S is not essential for differentiation of M. xanthus, whereas a gene product(s) coded from the sequence upstream of the tps gene appears to be required for normal fruiting body formation.     

Two homologous genes coding for spore-specific proteins are expressed at different times during development of Myxococcus xanthus.

The ops and tps genes of Myxococcus xanthus have ca. 90% DNA and amino acid sequence homology and are in the same orientation separated by a spacer region of only 1.4 kilobases. The products of the two genes were found to cross-react immunologically, and both were capable of Ca2+-dependent self-assembly on the surface of myxospores. However, the ops and tps genes were expressed very differently during the developmental cycle of M. xanthus. The tps gene is induced early during fruiting body formation on a solid surface, and its product, protein S, is made in large quantities (up to 15% of total protein synthesis). When the cells turn into myxospores, protein S is assembled on the outer surface of the spore. We have now also found it in much smaller quantities inside the spores. The ops gene, on the other hand, appears to be induced later in development, after the cells have sporulated, since the ops gene product was found only inside the spores. When an ops gene under the control of a tps gene promoter was inserted into a wild-type strain, the ops gene product was synthesized at the same time as protein S and assembled onto the spore surface.     

Changes in cell surface hydrophobicity of Myxococcus xanthus are correlated with sporulation-related events in the developmental program.

Cell surface hydrophobicity was measured in the bacterium Myxococcus xanthus during vegetative growth, fruiting body formation, and glycerol-induced spore formation by the method of Rosenberg et al. (FEMS Microbiol. Lett. 9:29-33, 1980). A significant decrease in cell surface hydrophobicity was observed 12 to 36 h after fruiting body formation and 60 to 120 min after glycerol-induced sporulation. The hydrophilic shift was correlated with the ability of the cells to sporulate but not with their ability to aggregate. Sucrose gradient purification removed the hydrophilic substance from the fruiting body spores but not from the glycerol-induced spores. The change in cell surface hydrophobicity in M. xanthus should be a useful developmental marker.     

Acceleration of starvation- and glycerol-induced myxospore formation by prior heat shock in Myxococcus xanthus.

The effect of heat shock on Myxococcus xanthus was investigated during both glycerol- and starvation-induced development. Cells heat shocked at 40 degrees C for 1 h prior to a development-inducing signal displayed an accelerated rate of myxospore formation at 30 degrees C. Additionally, M. xanthus cells heat shocked prior to glycerol induction formed a greater total number of myxospores when sporulation was complete than did control cells maintained at 30 degrees C. However, in starvation-induced fruiting cells the total number of myxospores in control and heat-shocked populations was about equal when fruiting body and myxospore formation was complete. When extended heat shock (3 h) was applied to cells prior to development, no acceleration of myxospore formation was observed. Heat shock elicited the premature expression of many developmentally regulated proteins. Cell fractionation and analysis by sodium dodecyl sulfate-polyacrylamide gel electrophoresis and fluorography revealed the subcellular location and molecular weights of the 18 glycerol-induced and 9 starvation-induced developmental proteins. Comparison with previously identified M. xanthus heat shock proteins showed that nine of the developmental proteins found in glycerol-induced cells and three of the developmental proteins found in starvation-induced cells were heat shock proteins. Furthermore, heat shock increased the activity of alkaline phosphatase, a developmentally regulated enzyme, in vegetative cells, glycerol-induced cells, and starvation-induced cells.     

Gene expression during development of Myxococcus xanthus. Analysis of the genes for protein S

Protein S is an abundant spore coat protein produced during fruiting body formation (development) of the bacterium Myxococcus xanthus. We have cloned the DNA which codes for protein S and have found that this DNA hybridizes to three protein S RNA species from developmental cells but does not hybridize to RNA from vegetative cells. The half-life of protein S RNA was found to be unusually long, about 38 minutes, which, at least in part, accounts for the high level of protein S synthesis observed during development. Hybridization of restriction fragments from cloned M. xanthus DNA to the developmental RNAs enabled us to show that M. xanthus has two directly repeated genes for protein S (gene 1 and gene 2) which are separated by about 10(3) base-pairs on the bacterial chromosome. To study the expression of the protein S genes in M. xanthus, eight M. xanthus strains were isolated with Tn5 insertions at various positions in the DNA which codes for protein S. The strains which contained insertions in gene 1 or between gene 1 and gene 2 synthesized all three protein S RNA species and exhibited normal levels of protein S on spores. In contrast, M. xanthus strains exhibited normal levels of protein S on spores. In contrast, M. xanthus strains with insertions in gene 2 had no detectable protein S on spores and lacked protein S RNA. Thus, gene 2 is responsible for most if not all of the production of protein S during M. xanthus development. M. xanthus strains containing insertions in gene 1, gene 2 or both genes, were found to aggregate and sporulate normally even though strains bearing insertions in gene 2 contained no detectable protein S. We examined the expression of gene 1 in more detail by constructing a fusion between the lacZ gene of Escherichia coli and the N-terminal portion of protein S gene 1 of M. xanthus. The expression of beta-galactosidase activity in an M. xanthus strain containing the gene fusion was shown to be under developmental control. This result suggests that gene 1 is also expressed during development although apparently at a much lower level than gene 2.     

Structure of the gene for CAD, the multifunctional protein that initiates UMP synthesis in Syrian hamster cells.

Two adjacent fragments of genomic DNA spanning the gene for CAD, which encodes the first three enzymes of UMP biosynthesis, were cloned from a mutant Syrian hamster cell line containing multiple copies of this gene. The mutant was selected for resistance to N-(phosphonacetyl)-L-aspartate, a potent and specific inhibitor of aspartate transcarbamylase, the second enzyme in the pathway. The sizes and positions of about 37 intervening sequences within the 25-kilobase CAD gene were mapped by electron microscopy, and the locations of the 5' and 3' ends of the 7.9-kilobase CAD mRNA were established by electron microscopy and by other hybridization methods. The coding sequences are small (100 to 400 bases), as are most of the intervening sequences (50 to 300 bases). However, there are also several large intervening sequences of up to 5,000 bases each. Two small cytoplasmic polyadenylated RNAs are transcribed from a region just beyond the 5' end of the CAD gene, and their abundance reflects the degree of gene amplification.     

Sporulation timing in Myxococcus xanthus is controlled by the espAB locus

The fruiting body development of Myxococcus xanthus consists of two separate but interacting pathways: one for aggregation of many cells to form raised mounds and the other for sporulation of individual cells into myxospores. Sporulation of individual cells normally occurs after mound formation, and is delayed at least 30 h after starvation under our laboratory conditions. This suggests that M. xanthus has a mechanism that monitors progress towards aggregation prior to triggering sporulation. A null mutation in a newly identified gene, espA (early sporulation), causes sporulation to occur much earlier compared with the wild type (16 h earlier). In contrast, a null mutation in an adjacent gene, espB, delays sporulation by about 16 h compared with the wild type. Interestingly, it appears that the espA mutant does not require raised mounds for sporulation. Many mutant cells sporulate outside the fruiting bodies. In addition, the mutant can sporulate, without aggregation into raised mounds, under some conditions in which cells normally do not form fruiting bodies. Based on these observations, it is hypothesized that EspA functions as an inhibitor of sporulation during early fruiting body development while cells are aggregating into raised mounds. The aggregation-independent sporulation of the espA mutant still requires starvation and high cell density. The espA and espB genes are expressed as an operon and their translations appear to be coupled. Expression occurs only under developmental conditions and does not occur during vegetative growth or during glycerol-induced sporulation. Sequence analysis of EspA indicates that it is a histidine protein kinase with a fork head-associated (FHA) domain at the N-terminus and a receiver domain at the C-terminus. This suggests that EspA is part of a two-component signal transduction system that regulates the timing of sporulation initiation.     

Synthesis and salvage of purines during cellular morphogenesis of Myxococcus xanthus.

Intact cells of Myxococcus xanthus were examined for de novo purine synthesis and salvage utilization. The cellular uptake rates of radioactive glycine (de novo purine precursor), adenine, and guanine were measured, and thin-layer chromatography and radioautography were used to examine cell extracts for de novo synthesized purine nucleotides. Intact vegatative cells, glycerol-induced myxospores, and germinating cells of M. xanthus CW-1 were able to carry out de novo purine and salvage synthesis. Germinating cells and glycerol-induced myxospores were metabolically more active or as active as vegetative cells with respect to purine anabolism. We conclude that M. xanthus is capable of synthesizing purine nucleotides and salvaging purines throughout the glycerol version of its life cycle.     

The peptidoglycan sacculus of Myxococcus xanthus has unusual structural features and is degraded during glycerol-induced myxospore development

Upon nutrient limitation cells of the swarming soil bacterium Myxococcus xanthus form a multicellular fruiting body in which a fraction of the cells develop into myxospores. Spore development includes the transition from a rod-shaped vegetative cell to a spherical myxospore and so is expected to be accompanied by changes in the bacterial cell envelope. Peptidoglycan is the shape-determining structure in the cell envelope of most bacteria, including myxobacteria. We analyzed the composition of peptidoglycan isolated from M. xanthus. While the basic structural elements of peptidoglycan in myxobacteria were identical to those in other gram-negative bacteria, the peptidoglycan of M. xanthus had unique structural features. meso- or LL-diaminopimelic acid was present in the stem peptides, and a new modification of N-acetylmuramic acid was detected in a fraction of the muropeptides. Peptidoglycan formed a continuous, bag-shaped sacculus in vegetative cells. The sacculus was degraded during the transition from vegetative cells to glycerol-induced myxospores. The spherical, bag-shaped coats isolated from glycerol-induced spores contained no detectable muropeptides, but they contained small amounts of N-acetylmuramic acid and meso-diaminopimelic acid.     

Studies on the nature and role of polyadenylated RNA in spore development of Bacillus subtilis

Summary cDNA probes synthesized on poly(A)RNAs isolated from sporulating cells of Bacillus subtilis were used for hybridization studies with RNAs derived from cells at different stages of growth and sporulation. It was shown that these cDNAs hybridized only to RNA from sporulating cells. No hybridization was observed if total RNA isolated from vegetative cells or from stationary phase cells of a zero stage asporogenic mutant was used. The hybridization studies also indicate that at each sporulation stage different poly(A)RNA species are synthesized. Furthermore, the hybridization kinetics have clearly demonstrated the existence of three distinct abundance classes of poly(A)RNA similar to those observed in eukaryotic cells. BamHI endonuclease restriction fragments of B. subtilis DNA that were found to hybridize to labeled poly(A)RNA were ligated to the pHV33 vector and hybrid clones that hybridized efficiently to poly(A)RNA were selected. Among these, three have been found to carry the spoOB gene.These results strongly suggest that the appearance of poly(A)RNA can be correlated to the expression of spore genes.