Cell-cell interactions that direct fruiting body development in Myxococcus xanthus

Two-Component Signal Transduction Systems That Regulate the Temporal and Spatial Expression of Myxococcus xanthus Sporulation Genes

When starved for nutrients, Myxococcus xanthus produces a biofilm that contains a mat of rod-shaped cells, known as peripheral rods, and aerial structures called fruiting bodies, which house thousands of dormant and stress-resistant spherical spores. Because rod-shaped cells differentiate into spherical, stress-resistant spores and spore differentiation occurs only in nascent fruiting bodies, many genes and multiple levels of regulation are required. Over the past 2 decades, many regulators of the temporal and spatial expression of M. xanthus sporulation genes have been uncovered. Of these sporulation gene regulators, two-component signal transduction circuits, which typically contain a histidine kinase sensor protein and a transcriptional regulator known as response regulator, are among the best characterized. In this review, we discuss prototypical two-component systems (Nla6S/Nla6 and Nla28S/Nla28) that regulate an early, preaggregation phase of sporulation gene expression during fruiting body development. We also discuss orphan response regulators (ActB and FruA) that regulate a later phase of sporulation gene expression, which begins during the aggregation stage of fruiting body development. In addition, we summarize the research on a complex two-component system (Esp) that is important for the spatial regulation of sporulation.

Characterization of bcsA mutations that bypass two distinct signaling requirements for Myxococcus xanthus development

The BsgA protease is required for starvation-induced development in Myxococcus xanthus. Bypass suppressors of a bsgA mutant were isolated to identify genes that may encode additional components of BsgA protease-dependent regulation of development. Strain M951 was isolated following Tn5 mutagenesis of a bsgA mutant and was capable of forming fruiting bodies and viable spores in the absence of the BsgA protease. The Tn5Omega951 insertion was localized to a gene, bcsA, that encodes a protein that has significant amino acid similarity to a group of recently described flavin-containing monooxygenases involved in styrene catabolism. Mutations in bcsA bypassed the developmental requirements for both extracellular B and C signaling but did not bypass the requirement for A signaling. Bypass of the B-signaling requirement by the bcsA mutation was accompanied by restored expression of a subset of developmentally induced lacZ fusions to the BsgA protease-deficient strain. bcsA mutant cells developed considerably faster than wild-type cells at low cell density and altered transcriptional levels of a developmentally induced, cell-density-regulated gene (Omega4427), suggesting that the bcsA gene product may normally act to inhibit development in a cell-density-regulated fashion. Bypass of the requirements for both B and C signaling by bcsA mutations suggests a possible link between these two genetically, biochemically, and temporally distinct signaling requirements.

Identification and characterization of spdR mutations that bypass the BsgA protease-dependent regulation of developmental gene expression in Myxococcus xanthus

The BsgA protease of Myxococcus xanthus is an intracellular protease closely related to the Lon protease of Escherichia coli. BsgA is required for normal levels of developmentally induced gene expression. In this report, we describe the identification of mutations that suppress the developmental defect of bsgA mutants. These mutations localized to the spdR gene (suppressor protease deficiency regulator) that appears to play a role in the regulation of early developmental gene expression. Mutations in spdR fully restored the ability of a bsgA mutant to form fruiting bodies and spores and, with one exception, restored the expression of several development-specific lacZ fusions. spdR mutants exhibited characteristic phenotypic properties including increased expression of the development-specific tps gene during vegetative growth, formation of fruiting bodies and spores on semi-rich nutrient medium and completion of starvation-induced development in a shorter time period than wild-type strains. The spdR locus was cloned and sequenced and found to encode a member of the NtrC family of two-component transcriptional regulators. One interpretation of these data is that SpdR acts, directly or otherwise, to regulate developmental gene expression negatively and that the BsgA protease is required to relieve this inhibitory effect at the onset of development. However, Western immunoblot analysis indicated that SpdR is present at a relatively constant level during growth and early development in both wild-type and BsgA protease-deficient cells. This finding suggests that BsgA does not function to degrade SpdR at the onset of development.

Not being the wrong size

Size regulation is a never-ending problem. Many of us worry that parts of ourselves are too big whereas other parts are too small. How organisms--and their tissues--are programmed to be a specific size, how this size is maintained, and what might cause something to become the wrong size, are key problems in developmental biology. But what are the mechanisms that regulate the size of multicellular structures?