Type IV pilus of Myxococcus xanthus is a motility apparatus controlled by the frz chemosensory system

Although flagella are the best-understood means of locomotion in bacteria [1], other bacterial motility mechanisms must exist as many diverse groups of bacteria move without the aid of flagella [2-4]. One unusual structure that may contribute to motility is the type IV pilus [5,6]. Genetic evidence indicates that type IV pili are required for social gliding motility (S-motility) in Myxococcus, and twitching motility in Pseudomonas and Neisseria [6,7]. It is thought that type IV pili may retract or rotate to bring about cellular motility [6,8], but there is no direct evidence for the role of pili in cell movements. Here, using a tethering assay, we obtained evidence that the type IV pilus of Myxococcus xanthus functions as a motility apparatus. Pili were required for M. xanthus cells to adhere to solid surfaces and to generate cellular movement using S-motility. Tethered cells were released from the surface at intervals corresponding to the reversal frequency of wild-type cells when gliding on a solid surface. Mutants defective in the control of directional movements and cellular reversals (frz mutants) showed altered patterns of adherence that correlate reversal frequencies with tethering. The behavior of the tethered cells was consistent with a model in which the pili are extruded from one cell pole, adhere to a surface, and then retract, pulling the cell in the direction of the adhering pili. Cellular reversals would result from the sites of pili extrusion switching from one cell pole to another and are controlled by the frz chemosensory system.     

Genetic and Molecular Analysis of cglB, a Gene Essential for Single-Cell Gliding in Myxococcus xanthus

Gliding movements of individual isolated Myxococcus xanthus cells depend on the genes of the A-motility system (agl and cgl genes). Mutants carrying defects in those genes are unable to translocate as isolated cells on solid surfaces. The motility defect of cgl mutants can be transiently restored to wild type by extracellular complementation upon mixing mutant cells with wild-type or other motility mutant cells. To develop a molecular understanding of the function of a Cgl protein in gliding motility, we cloned the cglB wild-type allele by genetic complementation of the mutant phenotype. The nucleotide sequence of a 2.85-kb fragment was determined and shown to encode two complete open reading frames. The CglB protein was determined to be a 416-amino-acid putative lipoprotein with an unusually high cysteine content. The CglB antigen localized to the membrane fraction. The swarming and gliding defects of a constructed DeltacglB mutant were fully restored upon complementation with the cglB wild-type allele. Experiments with a cglB allele encoding a CglB protein with a polyhistidine tag at the C terminus showed that this allele also promoted wild-type levels of swarming and single-cell gliding, but was unable to stimulate DeltacglB cells to move. Possible functions of CglB as a mechanical component or as a signal protein in single cell gliding are discussed.     

PlpA,a PilZ‐like protein,regulates directed motility of the bacterium Myxococcus xanthus

The rod‐shaped bacterium Myxococcus xanthus moves on surfaces along its long cell axis and reverses its moving direction regularly. Current models propose that the asymmetric localization of a Ras‐like GTPase, MglA, to leading cell poles determines the moving direction of cells. However, cells are still motile in the mutants where MglA localizes symmetrically, suggesting the existence of additional regulators that control moving direction. In this study, we identified PlpA, a P ilZ‐l ike p rotein that regulates the direction of motility. PlpA and MglA localize into opposite asymmetric patterns. Deletion of the plpA gene abolishes the asymmetry of MglA localization, increases the frequency of cellular reversals and leads to severe defects in cell motility. By tracking the movements of single motor particles, we demonstrated that PlpA and MglA co‐regulated the direction of gliding motility through direct interactions with the gliding motor. PlpA inhibits the reversal of individual gliding motors while MglA promotes motor reversal. By counteracting MglA near lagging cell poles, PlpA reinforces the polarity axis of MglA and thus stabilizes the direction of motility.     

Biochemical characterization of a mutant of the yeast Pichia anomala derepressed for malic acid utilization in the presence of glucose

Abstract Myxococcus xanthus cells move over surfaces by gliding motility. The frz signal transduction system is used to control the reversal frequency, and thus the overall direction of movement of M. xanthus cells. We analyzed the behavior of wild-type and frz mutant cells in response to prey bacteria ( Escherichia coli ). Wild-type cells of M. xanthus did not respond to microcolonies of E. coli until they made physical contact. Cells which penetrated a colony remained in the colony until all of the prey cells were digested. Cells of frz mutants also penetrated E. coli microcolonies and digested some of the E. coli cells, but they invariably abandoned the microcolony leaving their food source behind. These observations illustrate the importance of the frz system of signal transduction for the feeding behavior of M. xanthus cells.     

MglA and MglB are required for the intramacrophage growth of Francisella novicida

Francisella novicida is a facultative intracellular pathogen capable of growing in macrophages. A spontaneous mutant of F. novicida defective for growth in macrophages was isolated on LB media containing the chromogenic phosphatase substrate 5-bromo-4-chloro-3-indolyl phosphate (X-p) and designated GB2. Using an in cis complementation strategy, four strains were isolated that are restored for growth in macrophages. A locus isolated from one of these strains complements GB2 for both the intracellular growth defect and the colony morphology on LB (X-p) media. The locus consists of an apparent operon of two genes, designated mglAB , for macrophage growth locus. Both mglA and mglB transposon insertion mutants are defective for intracellular growth and have a phenotype similar to GB2 on LB (X-p) media. Sequencing of mglA cloned from GB2 identified a missense mutation, providing evidence that both mglA and mglB are required for the intramacrophage growth of F. novicida. mglB expression in GB2 was confirmed using antiserum against recombinant MglB. Cell fractionation studies revealed several differences in the protein profiles of mgl mutants compared with wild-type F. novicida . The deduced amino acid sequences of mglA and mglB show similarity to the SspA and SspB proteins of Escherichia coli and Haemophilus spp. In E. coli , SspA and/or SspB influence the levels of multiple proteins under conditions of nutritional stress, and SspA can associate with the RNA polymerase holoenzyme. Taken together, these observations suggest that in Francisella MglA and MglB may affect the expression of genes whose products contribute to survival and growth within macrophages.     

Genetics of gliding motility in Myxococcus xanthus (Myxobacterales): Genes controlling movement of single cells

Summary M. xanthus is a gliding bacterium whose motility is subject to intercellular control. Strain DK101 of M. xanthus gives rise to 6 distinct types of nonmotile mutants and transduction of motility between mutants, mediated by the generalized transducing phage Mx8, identifies the gene loci that underlie the six types. Five of the types, B, C, D, E, and F, are contitional mutants that can be stimulated to move by wild-type cells or by cells of a different mutant type. Mutants of each stimulation type lie in separate and distinct loci, cglB, cglC, cglD, cglE and cglF. The sixth mutant type can stimulate any of the five other types to move, never moves itself, and is produced by mutations in at least 17 loci.     

Gliding motility in Myxococcus xanthus: mgl locus, RNA, and predicted protein products.

Mutants of Myxococcus xanthus that had lost the ability to glide were examined to elucidate the mechanism of gliding motility. Nonmotile mutants resulting from a single mutational step were all defective at the same locus, mgl, which implied an important role for the mgl product(s) in gliding. Deletion experiments, transposon insertion mutagenesis, and genetic rescue of mgl mutants mapped the locus to a 1.6-kilobase segment of Myxococcus DNA. Two species of RNA that hybridized with mgl DNA were found both during vegetative growth and during the starvation-induced development of fruiting bodies, which also requires cell movement. The two RNA species, of 1.5 and 1.3 kilobases, had the same 5' to 3' orientation and overlapped extensively. The DNA sequences of mgl+ and of seven mgl mutants were determined. Each mutant differed from mgl+ by a single-base-pair change in the sequence. Two adjacent open reading frames were found in the sequence hybridizing to both species of mgl RNA. Six of the single-base-pair changes, each of which would result in a single-amino-acid change, and an insertion-produced mgl mutation were located in the downstream open reading frame. This open reading frame (of 195 amino acids) is therefore an mgl gene, called mglA. The function of the upstream open reading frame is not known with certainty, although it does contain one of the mgl mutant sites and could be a second mgl gene.     

Gliding motility in bacteria: insights from studies of Myxococcus xanthus.

Gliding motility is observed in a large variety of phylogenetically unrelated bacteria. Gliding provides a means for microbes to travel in environments with a low water content, such as might be found in biofilms, microbial mats, and soil. Gliding is defined as the movement of a cell on a surface in the direction of the long axis of the cell. Because this definition is operational and not mechanistic, the underlying molecular motor(s) may be quite different in diverse microbes. In fact, studies on the gliding bacterium Myxococcus xanthus suggest that two independent gliding machineries, encoded by two multigene systems, operate in this microorganism. One machinery, which allows individual cells to glide on a surface, independent of whether the cells are moving alone or in groups, requires the function of the genes of the A-motility system. More than 37 A-motility genes are known to be required for this form of movement. Depending on an additional phenotype, these genes are divided into two subclasses, the agl and cgl genes. Videomicroscopic studies on gliding movement, as well as ultrastructural observations of two myxobacteria, suggest that the A-system motor may consist of multiple single motor elements that are arrayed along the entire cell body. Each motor element is proposed to be localized to the periplasmic space and to be anchored to the peptidoglycan layer. The force to glide which may be generated here is coupled to adhesion sites that move freely in the outer membrane. These adhesion sites provide a specific contact with the substratum. Based on single-cell observations, similar models have been proposed to operate in the unrelated gliding bacteria Flavobacterium johnsoniae (formerly Cytophaga johnsonae), Cytophaga strain U67, and Flexibacter polymorphus (a filamentous glider). Although this model has not been verified experimentally, M. xanthus seems to be the ideal organism with which to test it, given the genetic tools available. The second gliding motor in M. xanthus controls cell movement in groups (S-motility system). It is dependent on functional type IV pili and is operative only when cells are in close proximity to each other. Type IV pili are known to be involved in another mode of bacterial surface translocation, called twitching motility. S-motility may well represent a variation of twitching motility in M. xanthus. However, twitching differs from gliding since it involves cell movements that are jerky and abrupt and that lack the organization and smoothness observed in gliding. Components of this motor are encoded by genes of the S-system, which appear to be homologs of genes involved in the biosynthesis, assembly, and function of type IV pili in Pseudomonas aeruginosa and Neisseria gonorrhoeae. How type IV pili generate force in S-motility is currently unknown, but it is to be expected that ongoing physiological, genetic, and biochemical studies in M. xanthus, in conjunction with studies on twitching in P. aeruginosa and N. gonorrhoeae, will provide important insights into this microbial motor. The two motility systems of M. xanthus are affected to different degrees by the MglA protein, which shows similarity to a small GTPase. Bacterial chemotaxis-like sensory transduction systems control gliding motility in M. xanthus. The frz genes appear to regulate gliding movement of individual cells and movement by the S-motility system, suggesting that the two motors found in this bacterium can be regulated to result in coordinated multicellular movements. In contrast, the dif genes affect only S-system-dependent swarming.     

MglA,a small GTPase,interacts with a tyrosine kinase to control type IV pili-mediated motility and development of Myxococcus xanthus

The mglA gene encodes a 22 kDa GTPase that is critical for single-cell (A) gliding, type IV pili-mediated (S) gliding and development of Myxococcus xanthus. To identify components that interact with MglA to control these processes, second-site mutations that restore movement to non-motile mglA mutants were sought. An allele-specific extragenic suppressor of mglA8, named mas815 (mglA8 suppressor 15), was obtained. mas815 does not bypass the requirement for MglA, yet it restores type IV pili-mediated motility and starvation-induced development. Single-cell (A) motility is not restored. The suppressing mutation maps to the 3' end of a gene, masK, in an operon immediately upstream of the mglBA operon. masK encodes a protein of the STY kinase family. When the masK gene was used as bait against a library carrying M. xanthus DNA in the yeast two-hybrid system, eight positive, independent clones containing fusions of mglA to GAL4 were obtained, thus confirming the interaction between MglA and MasK. MasK, expressed in Escherichia coli, was shown to phosphorylate at a tyrosine residue(s). The gain-of-function in the masK815 mutant was correlated with increased production of extracellular fibrils, which are required for adhesion, cell-cell contact and sensing phosphatidylethanolamine chemoattractants. These data suggest that the interaction between MasK and MglA is an essential part of a signal transduction pathway controlling motility and development.     

AglZ regulates adventurous (A-) motility in Myxococcus xanthus through its interaction with the cytoplasmic receptor, FrzCD

Myxococcus xanthus moves by gliding motility powered by type IV pili (S-motility) and distributed motor complexes (A-motility). The Frz chemosensory pathway controls reversals for both motility systems. However, it is unclear how the Frz pathway can communicate with these different systems. In this article, we show that FrzCD, the Frz pathway receptor, interacts with AglZ, a protein associated with A-motility. Affinity chromatography and cross-linking experiments showed that the FrzCD–AglZ interaction occurs between the uncharacterized N-terminal region of FrzCD and the N-terminal pseudo-receiver domain of AglZ. Fluorescence microscopy showed AglZ–mCherry and FrzCD–GFP localized in clusters that occupy different positions in cells. To study the role of the Frz system in the regulation of A-motility, we constructed aglZ frzCD double mutants and aglZ frzCD pilA triple mutants. To our surprise, these mutants, predicted to show no A-motility (A^-S⁺) or no motility at all (A^-S^-), respectively, showed restored A-motility. These results indicate that AglZ modulates a FrzCD activity that inhibits A-motility. We hypothesize that AglZ–FrzCD interactions are favoured when cells are isolated and moving by A-motility and inhibited when S-motility predominates and A-motility is reduced.     

Polarity of motility systems in Myxococcus xanthus

Myxococcus xanthus is a gliding bacterium that contains two motility systems: S-motility, powered by polar type IV pili, and A-motility, powered by uncharacterized motors and adhesion complexes. The localization and coordination of the two motility engines is essential for directed motility as cells move forward and reverse. During cell reversals, the polarity and localization of motility proteins are rapidly inverted, rendering this system a fascinating example of dynamic protein localization.     

Defects in contact-stimulated gliding during aggregation by Myxococcus xanthus.

During development, Myxococcus xanthus cells glide toward foci of aggregation and produce compact multicellular mounds. We studied development in strains with defects in contact-stimulated gliding. Contact stimulation involves a mechanism influenced by contacts between neighboring cells which stimulates the gliding motility of single cells (Hodgkin and Kaiser, Proc. Natl. Acad. Sci. USA 74:2938-2942, 1977; Hodgkin and Kaiser, Mol. Gen. Genet. 171:167-176, 1979). Most mutants containing a mutation in a single gene affecting contact stimulation (cgl gene) were able to form foci of aggregation during development. However, the aggregates were diffuse, suggesting that contact stimulation is important for morphogenetic movements during aggregation. A mutant containing a mutation in the cglF3 gene showed a striking delay in aggregation, suggesting that the cglF3 gene affects a mechanism stimulating cells moving to foci or affects a mechanism for coordinating early cell behavior. Mutants containing the cglF3 mutation in combination with a cglB, cglC, cglE, or cglF1 mutation had severe defects in aggregation and failed to recover from the early delay. The severity of the defects in mutants containing two cgl mutations suggests that cgl genes are critical for development. We propose that cgl genes stimulate cell movement or control specific contacts between cells during aggregation.     

Developmental aggregation of Myxococcus xanthus requires frgA, an frz-related gene

Myxococcus xanthus is a gram-negative bacterium which has a complex life cycle that includes multicellular fruiting body formation. Frizzy mutants are characterized by the formation of tangled filaments instead of hemispherical fruiting bodies on fruiting agar. Mutations in the frz genes have been shown to cause defects in directed motility, which is essential for both vegetative swarming and fruiting body formation. In this paper, we report the discovery of a new gene, called frgA (for frz-related gene), which confers a subset of the frizzy phenotype when mutated. The frgA null mutant showed reduced swarming and the formation of frizzy aggregates on fruiting agar. However, this mutant still displayed directed motility in a spatial chemotaxis assay, whereas the majority of frz mutants fail to show directed movements in this assay. Furthermore, the frizzy phenotype of the frgA mutant could be complemented extracellularly by wild-type cells or strains carrying non-frz mutations. The phenotype of the frgA mutant is similar to that of the abcA mutant and suggests that both of these mutants could be defective in the production or export of extracellular signals required for fruiting body formation rather than in the sensing of such extracellular signals. The frgA gene encodes a large protein of 883 amino acids which lacks homologues in the databases. The frgA gene is part of an operon which includes two additional genes, frgB and frgC. The frgB gene encodes a putative histidine protein kinase, and the frgC gene encodes a putative response regulator. The frgB and frgC null mutants, however, formed wild-type fruiting bodies.     

Function of MglA, a 22-kilodalton protein essential for gliding in Myxococcus xanthus.

Single mutations in the mglA gene in Myxococcus xanthus render cells incapable of gliding. The mglA strains are unique in that all other nonmotile strains of M. xanthus isolated are the result of at least two independent mutations in separate motility system genes. Translational fusions of trpE, or of lacZ, to mglA were constructed, and the resulting fusion polypeptides were used to generate antibodies. Antibodies specific to MglA protein were purified. Antibody-tagged MglA was found localized to the cytoplasm of M. xanthus cells both by fractionation of cell extracts and by electron microscopy of thin sections of whole cells. Four of the five mglA missense mutants tested failed to produce detectable levels of the MglA antigen in whole cell extracts. Nonmotile double mutants (A-S-), which have one mutation in a gene of system A and one mutation in a gene of system S, have the same phenotype as null mglA mutants but produce wild-type levels of MglA protein. MglA protein is conserved in all strains of myxobacteria tested. The amino acid sequence of MglA protein includes three sequence motifs characteristic of GDP/GTP-binding proteins. On the basis of its genetic properties, intracellular location, and amino acid sequence, it is argued that MglA protein is a regulator in the sequence of functions leading to cell movement.     

Cloning and characterization of the Flavobacterium johnsoniae gliding-motility genes gldB and gldC

The mechanism of bacterial gliding motility (active movement over surfaces without the aid of flagella) is not known. A large number of mutants of the gliding bacterium Flavobacterium johnsoniae (Cytophaga johnsonae) with defects in gliding motility have been previously isolated, and genetic techniques to analyze these mutants have recently been developed. We complemented a nongliding mutant of F. johnsoniae (UW102-99) with a library of wild-type DNA by using the shuttle cosmid pCP26. The complementing plasmid (pCP200) contained an insert of 26 kb and restored gliding motility to 4 of 50 independently isolated nongliding mutants. A 1.9-kb fragment which encompassed two genes, gldB and gldC, complemented all four mutants. An insertion mutation in gldB was polar on gldC, suggesting that the two genes form an operon. Disruption of the chromosomal copy of gldB in wild-type F. johnsoniae UW101 eliminated gliding motility. Introduction of the gldBC operon, or gldB alone, restored motility. gldB appears to be essential for F. johnsoniae gliding motility. It codes for a membrane protein that does not exhibit strong sequence similarity to other proteins in the databases. gldC is not absolutely required for gliding motility, but cells that do not produce GldC form colonies that spread less well than those of the wild type. GldC is a soluble protein and has weak sequence similarity to the fungal lectin AOL.     

Cloning and Characterization of the Flavobacterium johnsoniae Gliding Motility Genes gldD and gldE

Cells of Flavobacterium johnsoniae move over surfaces by a process known as gliding motility. The mechanism of this form of motility is not known. Cells of F. johnsoniae propel latex spheres along their surfaces, which is thought to be a manifestation of the motility machinery. Three of the genes that are required for F. johnsoniae gliding motility, gldA, gldB, and ftsX, have recently been described. Tn4351 mutagenesis was used to identify another gene, gldD, that is needed for gliding. Tn4351-induced gldD mutants formed nonspreading colonies, and cells failed to glide. They also lacked the ability to propel latex spheres and were resistant to bacteriophages that infect wild-type cells. Introduction of wild-type gldD into the mutants restored motility, ability to propel latex spheres, and sensitivity to bacteriophage infection. gldD codes for a cytoplasmic membrane protein that does not exhibit strong sequence similarity to proteins of known function. gldE, which lies immediately upstream of gldD, encodes another cytoplasmic membrane protein that may be involved in gliding motility. Overexpression of gldE partially suppressed the motility defects of a gldB point mutant, suggesting that GldB and GldE may interact. GldE exhibits sequence similarity to Borrelia burgdorferi TlyC and Salmonella enterica serovar Typhimurium CorC.     

Regulation of dynamic polarity switching in bacteria by a Ras‐like G‐protein and its cognate GAP

The rod‐shaped cells of the bacterium Myxococcus xanthus move uni‐directionally and occasionally undergo reversals during which the leading/lagging polarity axis is inverted. Cellular reversals depend on pole‐to‐pole relocation of motility proteins that localize to the cell poles between reversals. We show that MglA is a Ras‐like G‐protein and acts as a nucleotide‐dependent molecular switch to regulate motility and that MglB represents a novel GTPase‐activating protein (GAP) family and is the cognate GAP of MglA. Between reversals, MglA/GTP is restricted to the leading and MglB to the lagging pole defining the leading/lagging polarity axis. For reversals, the Frz chemosensory system induces the relocation of MglA/GTP to the lagging pole causing an inversion of the leading/lagging polarity axis. MglA/GTP stimulates motility by establishing correct polarity of motility proteins between reversals and reversals by inducing their pole‐to‐pole relocation. Thus, the function of Ras‐like G‐proteins and their GAPs in regulating cell polarity is found not only in eukaryotes, but also conserved in bacteria.     

Phenotypic analyses of frz and dif double mutants of Myxococcus xanthus

Myxococcus xanthus is a Gram-negative gliding bacterium that aggregates and develops into multicellular fruiting bodies in response to starvation. Two chemosensory systems (frz and dif), both of which are homologous to known chemotaxis proteins, were previously identified through characterization of various developmental mutants. This study aims to examine the interaction between these two systems since both of them are required for fruiting body formation of M. xanthus. Through detailed phenotypic analyses of frz and dif double mutants, we found that both frz and dif are involved in cellular reversal and social motility; however, the frz genes are epistatic in controlling cellular reversal, whereas the dif genes are epistatic in controlling social motility. The study suggests that the integration of these two chemotaxis systems may play a central role in controlling the complicated social behaviors of M. xanthus.     

Social motility in Myxococcus xanthus requires FrzS, a protein with an extensive coiled-coil domain

Gliding motility in the developmental bacterium Myxococcus xanthus involves two genetically distinct motility systems, designated adventurous (A) and social (S). Directed motility responses, which facilitate both vegetative swarming and developmental aggregation, additionally require the 'frizzy' (Frz) signal transduction pathway. In this study, we have analysed a new gene (frzS), which is positioned upstream of the frzA-F operon. Insertion mutations in frzS caused both vegetative spreading and developmental defects, including 'frizzy' aggregates in the FB strain background. The 'frizzy' phenotype was previously considered to result only from defective directed motility responses. However, deletion of the frzS gene in an A-S+ motility background demonstrated that FrzS is a new component of the S-motility system, as the A-frzS double mutant was non-spreading (A-S-). Compared with known S-motility mutants, the frzS mutants appear similar to pilT mutants, in that both produce type IV pili, extracellular fibrils and lipopolysaccharide (LPS) O-antigen, and both agglutinate rapidly in a cohesion assay. The FrzS protein has an unusual domain composition for a bacterial protein. The N-terminal domain shows similarity to the receiver domains of the two-component response regulator proteins. The C-terminal domain is composed of up to 38 heptad repeats (a b c d e f g)38, in which residues at positions a and d are predominantly hydrophobic, whereas residues at positions e and g are predominantly charged. This periodic disposition of specific residues suggests that the domain forms a long coiled-coil structure, similar to those found in the alpha-fibrous proteins, such as myosin. Overexpression of this domain in Escherichia coli resulted in the formation of an unusual striated protein lattice that filled the cells. We speculate on the role that this novel protein could play in gliding motility.