Randy M. Morgenstein

Regulation of gene expression during swarmer cell differentiation in Proteus mirabilis.

The gram-negative bacterium Proteus mirabilis can exist in either of two cell types, a vegetative cell characterized as a short rod and a highly elongated and hyperflagellated swarmer cell. This differentiation is triggered by growth on solid surfaces and multiple inputs are sensed by the cell to initiate the differentiation process. These include the inhibition of flagellar rotation, the accumulation of extracellular putrescine and O-antigen interactions with a surface. A key event in the differentiation process is the upregulation of FlhD(2)C(2), which activates the flagellar regulon and additional genes required for differentiation. There are a number of genes that influence FlhD(2)C(2) expression and the function of these genes, if known, will be discussed in this review. Additional genes that have been shown to regulate gene expression during swarming will also be reviewed. Although P. mirabilis represents an excellent system to study microbial differentiation, it is largely understudied relative to other systems. Therefore, this review will also discuss some of the unanswered questions that are central to understanding this process in P. mirabilis.

Loss of the WaaL O-Antigen Ligase Prevents Surface Activation of the Flagellar Gene Cascade in Proteus mirabilis

Proteus mirabilis is a Gram-negative bacterium that undergoes a physical and biochemical change from a vegetative swimmer cell (a typical Gram-negative rod) to an elongated swarmer cell when grown on a solid surface. In this study, we report that a transposon insertion in the waaL gene, encoding O-antigen ligase, blocked swarming motility on solid surfaces but had little effect on swimming motility in soft agar. The waaL mutant was unable to differentiate into a swarmer cell. Differentiation was also prevented by a mutation in wzz, encoding a chain length determinant for O antigen, but not by a mutation in wzyE, encoding an enzyme that polymerizes enterobacterial common antigen, a surface polysaccharide different from the lipid A::core. In wild-type P. mirabilis, increased expression of the flhDC operon occurs after growth on solid surfaces and is required for the high-level expression of flagellin that is characteristic of swarmer cells. However, in both the waaL and the wzz mutants, the flhDC operon was not activated during growth on agar. A loss-of-function mutation in the rcsB response regulator or overexpression of flhDC restored swarming to the waaL mutant, despite the absence of O antigen. Therefore, although O antigen may serve a role in swarming by promoting wettability, the loss of O antigen blocks a regulatory pathway that links surface contact with the upregulation of flhDC expression.

RodZ links MreB to cell wall synthesis to mediate MreB rotation and robust morphogenesis

Significance The bacterial actin homolog, MreB, is a key determinant of rod-cell shape but the mechanism by which it functions has remained a topic of much debate. Recently it was shown that MreB exists as small polymers that actively rotate around the cell circumference. This rotation is widely conserved, yet its mechanism and function have remained unknown. Here we show that MreB rotates because cytoplasmic MreB filaments are coupled to periplasmic cell wall synthesis through the transmembrane protein RodZ, which acts as a transmembrane linker. Furthermore, by genetically uncoupling MreB rotation from growth we establish MreB rotation acts as a robustness mechanism for rod-like shape determination. This work thus explains the mystery of MreB rotation and suggests a new model for bacterial cell shape maintenance. The rod shape of most bacteria requires the actin homolog, MreB. Whereas MreB was initially thought to statically define rod shape, recent studies found that MreB dynamically rotates around the cell circumference dependent on cell wall synthesis. However, the mechanism by which cytoplasmic MreB is linked to extracytoplasmic cell wall synthesis and the function of this linkage for morphogenesis has remained unclear. Here we demonstrate that the transmembrane protein RodZ mediates MreB rotation by directly or indirectly coupling MreB to cell wall synthesis enzymes. Furthermore, we map the RodZ domains that link MreB to cell wall synthesis and identify mreB mutants that suppress the shape defect of ΔrodZ without restoring rotation, uncoupling rotation from rod-like growth. Surprisingly, MreB rotation is dispensable for rod-like shape determination under standard laboratory conditions but is required for the robustness of rod shape and growth under conditions of cell wall stress.

Role of the Umo Proteins and the Rcs Phosphorelay in the Swarming Motility of the Wild Type and an O-Antigen (waaL) Mutant of Proteus mirabilis

Proteus mirabilis is a Gram-negative bacterium that exists as a short rod when grown in liquid medium, but during growth on surfaces it undergoes a distinct physical and biochemical change that culminates in the formation of a swarmer cell. How P. mirabilis senses a surface is not fully understood; however, the inhibition of flagellar rotation and accumulation of putrescine have been proposed to be sensory mechanisms. Our lab recently isolated a transposon insertion in waaL, encoding O-antigen ligase, that resulted in a loss of swarming but not swimming motility. The waaL mutant failed to activate flhDC, the class 1 activator of the flagellar gene cascade, when grown on solid surfaces. Swarming in the waaL mutant was restored by overexpression of flhDC in trans or by a mutation in the response regulator rcsB. To further investigate the role of the Rcs signal transduction pathway and its possible relationship with O-antigen surface sensing, mutations were made in the rcsC, rcsB, rcsF, umoB (igaA), and umoD genes in wild-type and waaL backgrounds. Comparison of the swarming phenotypes of the single and double mutants and of strains overexpressing combinations of the UmoB, UmoD, and RcsF proteins demonstrated the following: (i) there is a differential effect of RcsF and UmoB on swarming in wild-type and waaL backgrounds, (ii) RcsF inhibits UmoB activity but not UmoD activity in a wild-type background, and (iii) UmoD is able to modulate activity of the Rcs system.

Lack of the GTPase RHO-4 in Neurospora crassa causes a reduction in numbers and aberrant stabilization of microtubules at hyphal tips.

The multinucleate hyphae of the filamentous ascomycete fungus Neurospora crassa grow by polarized hyphal tip extension. Both the actin and microtubule cytoskeleton are required for maximum hyphal extension, in addition to other vital processes. Previously, we have shown that the monomeric GTPase encoded by the N. crassa rho-4 locus is required for actin ring formation during the process of septation; rho-4 mutants lack septa. However, other phenotypic aspects of the rho-4 mutant, such as slow growth and cytoplasmic bleeding, led us to examine the hypothesis that the microtubule (MT) cytoskeleton of the rho-4 mutant was affected in morphology and dynamics. Unlike a wild-type strain, the rho-4 mutant had few MTs and these few MTs originated from nuclear spindle pole bodies. rho-4 mutants and rho-4 strains containing a GTP-locked (activated) rho-4 allele showed a reduction in numbers of cytoplasmic MTs and microtubule stabilization at hyphal tips. Strains containing a GDP-biased (negative) allele of rho-4 showed normal numbers of MTs and minor effects on microtubule stabilization. An examination of nuclear dynamics revealed that rho-4 mutants have large, and often, stretched or broken nuclei. These observations indicate that RHO-4 plays important roles in regulating both the actin and MT cytoskeleton, which are essential for optimal hyphal tip growth and in nuclear distribution and morphology.

MreB polymers and curvature localization are enhanced by RodZ and predict E. coli' s cylindrical uniformity

The actin-like protein MreB has been proposed to coordinate the synthesis of the cell wall to determine cell shape in bacteria. MreB is preferentially localized to areas of the cell with specific curved geometries, avoiding the cell poles. It remains unclear whether MreB’s curvature preference is regulated by additional factors, and which specific features of MreB promote specific features of rod shape growth. Here, we show that the transmembrane protein RodZ modulates MreB curvature preference and polymer number in E. coli, properties which are regulated independently. An unbiased machine learning analysis shows that MreB polymer number, the total length of MreB polymers, and MreB curvature preference are key correlates of cylindrical uniformity, the variability in radius within a single cell. Changes in the values of these parameters are highly predictive of the resulting changes in cell shape (r2 = 0.93). Our data thus suggest RodZ promotes the assembly of geometrically-localized MreB polymers that lead to the growth of uniform cylinders.The actin-like protein MreB coordinates the synthesis of the cell wall, which determines cell shape in bacteria. Here, Bratton et al. show that the transmembrane protein RodZ modulates MreB polymer number and curvature preference, contributing to the cylindrical uniform shape of E. coli cells.