The act operon controls the level and time of C-signal production for Myxococcus xanthus development

The C-signal is a morphogen that controls the assembly of fruiting bodies and the differentiation of myxospores. Production of this signal, which is encoded by the csgA gene, is regulated by the act operon of four genes that are co-transcribed from the same start site. The act A and act B genes regulate the maximum level of the C-signal, which never rises above one-quarter of the maximum wild-type level of CsgA protein in null mutants of either gene. The act A and act B mutants have the same developmental phenotype: both aggregate, neither sporulates, both prolong rippling. By sequence homology, act A encodes a response regulator, and act B encodes a sigma-54 activator protein of the NTRC class. The similar phenotypes of act A and act B deletion mutants suggest that the two gene products are part of the same signal transduction pathway. That pathway responds to C-signal and also regulates the production of CsgA protein, thus creating a positive feedback loop. The act C and act D genes regulate the time pattern of CsgA production, while achieving the same maximum level. An act C null mutant raises CsgA production 15 h earlier than the wild type, whereas an act D null mutant does so 6 h later than wild type. The loop explains how the C-signal rises continuously from early development to a peak at the time of sporulation, and the act genes govern the time course of that rise.     

C-factor: a cell-cell signaling protein required for fruiting body morphogenesis of M. xanthus

During fruiting body development, the product of the csgA gene is necessary for cellular aggregation, for spore differentiation, and for gene expression that is initiated after 6 hr of starvation. From nascent wild-type fruiting bodies we have purified a polypeptide of 17 kd called C-factor, which, at approximately 1 to 2 nM, restores normal development to csgA mutant cells. C-factor activity is not recovered from extracts of unstarved, growing cells or csgA mutant cells. The amino acid sequence from purified C-factor demonstrates that it is the product of the csgA gene. C-factor is active over a narrow range of concentration and has properties of a morphogenetic paracrine signal.     

C-signal: a cell surface-associated morphogen that induces and co-ordinates multicellular fruiting body morphogenesis and sporulation in Myxococcus xanthus

In Myxococcus xanthus, morphogenesis of multicellular fruiting bodies and sporulation are co-ordinated temporally and spatially. csgA mutants fail to synthesize the cell surface-associated C-signal and are unable to aggregate and sporulate. We report that csgA encodes two proteins, a 25 kDa species corresponding to full-length CsgA protein and a 17 kDa species similar in size to C-factor protein, which has been shown previously to have C-signal activity. By systematically varying the accumulation of the csgA proteins, we show that overproduction of the csgA proteins results in premature aggregation and sporulation, uncoupling of the two events and the formation of small fruiting bodies, whereas reduced synthesis of the csgA proteins causes delayed aggregation, reduced sporulation and the formation of large fruiting bodies. These results show that C-signal induces aggregation as well as sporulation, and that an ordered increase in the level of C-signalling during development is essential for the spatial co-ordination of these events. The results support a quantitative model, in which aggregation and sporulation are induced at distinct threshold levels of C-signalling. In this model, the two events are temporally co-ordinated by the regulated increase in C-signalling levels during development. The contact-dependent C-signal transmission mechanism allows the spatial co-ordination of aggregation and sporulation by coupling cell position and signalling levels.     

Cloning and characterization of the socA locus which restores development to Myxococcus xanthus C-signaling mutants.

The csgA gene produces an intercellular signal during fruiting body formation of the myxobacterium Myxococcus xanthus. Sporulating pseudorevertants were isolated to allow us to understand the mechanism by which CsgA is perceived by cells and used to regulate developmental gene expression. Two strains, LS559 and LS560, which have closely linked transposon insertions, soc-559 (formerly csp-559) and soc-560 (formerly csp-560), respectively, regained all the developmental behaviors lost by the csgA mutation including the ability to ripple, form fruiting bodies, and sporulate. The sequence analysis of the socA locus revealed that there are three putative protein-coding regions, designated socA1, socA2, and socA3. The deduced amino acid sequence of socA1 exhibits characteristics of the short-chain alcohol dehydrogenase family. The deduced amino acid sequence of socA2 shares 48% identity with the frdD gene product of the frd operon in Proteus vulgaris which anchors fumarate reductase to the membrane. The deduced amino acid sequence of socA3 does not show homology to any known proteins. Genotypic complementation, Northern (RNA) blotting, DNA sequence analysis, and the pattern of gene expression all suggest that these three genes are polycistronic. Since the socA mutations effectively bypass CsgA, the question of why csgA is maintained in M. xanthus was examined by studying the long-term stability of socA spores. Unlike the wild type, socA mutant spores germinated on starvation agar. Transmission electron micrographs of spore thin sections revealed that germination is not due to an obvious structural deficiency of the socA spores. These results suggest that the ability of socA myxospores to survive long periods under unfavorable environmental conditions is severely comprised. Therefore, soxA appears to be essential for the development of M. xanthus.     

Effect of dsp mutations on the cell-to-cell transmission of CsgA in Myxococcus xanthus.

The dsp locus contains genes involved in the subunit synthesis and/or assembly of fibrils that radiate outward from the Myxococcus xanthus cell surface and attach to other cells. The csgA gene encodes an extracellular protein morphogen which is essential for fruiting body development. The question of whether fibrils are involved in the transmission of CsgA to adjacent cells was investigated in three ways. First, the dsp and csgA mutants were mixed in a ratio of 1:1 and allowed to develop; fruiting bodies containing spores derived from the csgA mutant were formed, suggesting efficient CsgA transfer. Second, the csgA mutation affected expression of many developmentally regulated genes differently from the way dsp affected their expression. Third, the expression of one developmentally regulated gene, which was partially expressed in csgA and dsp backgrounds, was almost completely inhibited in the presence of both mutations, suggesting that its promoter is regulated independently by two distinct stimuli, one that is csgA dependent and one that is dsp dependent. Together these results argue that fibrils are not necessary for cell-to-cell transmission or perception of CsgA, and their precise function remains unknown.     

Mutational analysis of the Myxococcus xanthus Omega4400 promoter region provides insight into developmental gene regulation by C signaling

Myxococcus xanthus utilizes extracellular signals during development to coordinate cell movement, differentiation, and changes in gene expression. One of these signals, the C signal, regulates the expression of many genes, including Omega4400, a gene identified by an insertion of Tn5 lac into the chromosome. Expression of Tn5 lac Omega4400 is reduced in csgA mutant cells, which fail to perform C signaling, and the promoter region has several sequences similar to sequences found in the regulatory regions of other C-signal-dependent genes. One such gene, Omega4403, depends absolutely on the C signal for expression, and its promoter region has been characterized previously by mutational analysis. To determine if the similar sequences within the Omega4400 and Omega4403 regulatory regions function in the same way, deletion analysis and site-directed mutagenesis of the Omega4400 promoter region were performed. A 7-bp sequence centered at -49 bp, termed a C box, is identical in the Omega4400 and Omega4403 promoter regions, yet mutations in the individual base pairs affected expression from the two promoters very differently. Also, a single-base-pair change within a similar 5-bp element, which is centered at -61 bp in both promoter regions, had very different effects on the activities of the two promoters. Further mutational analysis showed that two regions are important for Omega4400 expression; one region, from -63 to -31 bp, is required for Omega4400 expression, and the other, from -86 to -81 bp, exerts a two- to fourfold effect on expression and is at least partially responsible for the C signal dependence of the Omega4400 promoter. Mutations in sigD and sigE, which are genes that encode sigma factors, abolished and reduced Omega4400 expression, respectively. Expression of Omega4400 in actB or actC mutants correlated well with the altered levels of C signal produced in these mutants. Our results provide the first detailed analysis of an M. xanthus regulatory region that depends partially on C signaling for expression and indicate that similar DNA sequences in the Omega4400 and Omega4403 promoter regions function differently.     

Both vegetative and reproductive actin isovariants complement the stunted root hair phenotype of the Arabidopsis act2-1 mutation

The ACT2 gene, encoding one of eight actin isovariants in Arabidopsis, is the most strongly expressed actin gene in vegetative tissues. A search was conducted for physical defects in act2-1 mutant plants to account for their reduced fitness compared with wild type in population studies. The act2-1 insertion fully disrupted expression of ACT2 RNA and significantly lowered the level of total actin protein in vegetative organs. The root hairs of the act2-1 mutants were 10% to 70% the length of wild-type root hairs, and they bulged severely at the base. The length of the mutant root hairs and degree of bulging at the base were affected by adjusting the osmolarity and gelling agent of the growth medium. The act2-1 mutant phenotypes were fully rescued by an ACT2 genomic transgene. When the act2-1 mutation was combined with another vegetative actin mutation, act7-1, the resulting double mutant exhibited extensive synergistic phenotypes ranging from developmental lethality to severe dwarfism. Transgenic overexpression of the ACT7 vegetative isovariant and ectopic expression of the ACT1 reproductive actin isovariant also rescued the root hair elongation defects of the act2-1 mutant. These results suggest normal ACT2 gene regulation is essential to proper root hair elongation and that even minor differences may cause root defects. However, differences in the actin protein isovariant are not significant to root hair elongation, in sharp contrast to recent reports on the functional nonequivalency of plant actin isovariants. Impairment of root hair functions such as nutrient mining, water uptake, and physical anchoring are the likely cause of the reduced fitness seen for act2-1 mutants in multigenerational studies.     

Genetic variability of the tumorous-head maternal effect in Drosophila melanogaster

Summary The tumorous-head maternal effect in Drosophila melanogaster is produced by a recessive gene (tuh-1) in chromosome 1. Polymorphism exists at this locus. This maternal effect, which is part of the normal variation found in this species, is detected with the aid of a mutant gene. In the presence of the maternal effect, a semi-dominant mutant gene (tuh-3) causes homoeotic changes in the eye-antennal imaginal discs. The phenotype in the adult is known as the tumorous-head abnormality. The mutant gene, which is located in the right arm of chromosome 3, is characterized by reduced penetrance. Using the penetrance of the mutant gene as the criterion, the results of these experiments show that the level of the maternal effect activity is influenced remarkably by modifiers present in wild type strains. The assay is to mate females homozygous for tuh-1 with males homozygous for tuh-3 and to determine the percent of the offspring showing the tumorous head abnormality. Using this procedure, it was observed that parental females with various combinations of chromosomes 1 and 3 from Lausanne and Stephenville wild type strains show great variability in the level of maternal effect activity. Modifiers in chromosome 1 and 3 from the Stephenville strain increase the level of the maternal effect activity. The level is reduced if these chromosomes are replaced by those from the Lausanne strain. A major locus in chromosome 3 is in the same region occupied by clusters of functionally related genes with regulating action. These results demonstrate that the penetrance of a mutant gene, which acts during embryogenesis, is influenced by modifiers which act during oogenesis.This investigation was supported by Public Health Service Research Grant GM 18664 to Arizona State University from the National Institute of General Medical Sciences     

The Zrc1 is involved in zinc transport system between vacuole and cytosol in Saccharomyces cerevisiae

The ZRC1 gene encodes a multicopy suppressor of zinc toxicity in Saccharomyces cerevisiae; however, previously we found that the expression of ZRC1 was induced when the intracellular zinc level was decreased. Zrc1 has six putative transmembrane domains and we determined that a Zrc1-GFP fusion protein was localized to the vacuolar membrane. The steady state level of intracellular zinc in a zrc1Delta mutant cultured in the zinc-abundant medium was lower than that in wild type. No distinct difference was observed in the basal activity of glyoxalase I, which is a cytosolic enzyme requiring zinc for catalytic function and is used here as a marker for cytosolic zinc-availability, between wild type and zrc1Delta mutant, although the activity was decreased much greater extent in the zrc1Delta mutant if the cells were exposed to the metal-limited medium. Similarly, the basal expression level of ZRC1-lacZ reporter gene in zrc1Delta mutant was the same as that in wild type; however, the fold of induction of ZRC1-lacZ expression in zrc1Delta mutant under the zinc-limited conditions was higher than that in the wild type. Based on these results, we present a tentative model for the function of Zrc1 as a mechanism to maintain the zinc homeostasis in yeast.     

Site-specific integration and expression of a developmental promoter in Myxococcus xanthus.

A series of intercellular signals are involved in the regulation of gene expression during fruiting body formation of Myxococcus xanthus. Mutations which block cell interactions, such as csgA (formerly known as spoC), also prevent expression of certain developmentally regulated promoters. csgA+ cells containing Tn5 lac omega DK4435, a developmentally regulated promoter fused to lacZ, began synthesizing lacZ mRNA 12 to 18 h into the developmental cycle. beta-Galactosidase specific activity increased about 12 h later. Neither lacZ mRNA nor beta-galactosidase activity was detected in a developing csgA mutant containing omega DK4435. The developmental promoter and its fused lacZ reporter gene were cloned into a pBR322-derived plasmid vector containing a portion of bacteriophage Mx8. These plasmids preferentially integrated into the M. xanthus chromosome by site-specific recombination at the bacteriophage Mx8 attachment site and maintained a copy number of 1 per chromosome. The integrated plasmids were relatively stable, segregating at a frequency of 0.0007% per generation in the absence of selection. The cloned and integrated promoter behaved like the native promoter, expressing beta-galactosidase at the proper time during wild-type development and failing to express the enzyme during development of a csgA mutant. The overall level of beta-galactosidase expression in merodiploid cells containing one native promoter and one promoter fused to lacZ was about half that of cells containing a single promoter fused to lacZ. These results suggest that the timing of developmentally regulated gene expression is largely independent of the location of this gene within the chromosome. Furthermore, they show that site-specific recombination can be a useful tool for establishing assays for promoter or gene function in M. xanthus.