Introduction of transposon Tn5 into Myxococcus for analysis of developmental and other nonselectable mutants

Inter-laboratory evolution of a model organism and its epistatic effects on mutagenesis screens

In theory, a few naturally occurring evolutionary changes in the genome of a model organism may have little or no observable impact on its wild type phenotype, and yet still substantially impact the phenotypes of mutant strains through epistasis. To see if this is happening in a model organism, we obtained nine different laboratories' wild type Myxococcus xanthus DK1622 "sublines" and sequenced each to determine if they had evolved after their physical separation. Under a common garden experiment, each subline satisfied the phenotypic prerequisites for wild type, but many differed to a significant degree in each of the four quantitative phenotypic traits we measured, with some sublines differing by several-fold. Genome resequencing identified 29 variants between the nine sublines, and eight had at least one unique variant within an Open Reading Frame (ORF). By disrupting the ORF MXAN7041 in two different sublines, we demonstrated substantial epistasis from these naturally occurring variants. The impact of such inter-laboratory wild type evolution is important to any genotype-to-phenotype study; an organism's phenotype may be sensitive to small changes in genetic background, so that results from phenotypic screens and other related experiments might not agree with prior published results or the results from other laboratories.

Understanding the enormous diversity of bacteriophages: the tailed phages that infect the bacterial family Enterobacteriaceae

Bacteriophages are the predominant biological entity on the planet. The recent explosion of sequence information has made estimates of their diversity possible. We describe the genomic comparison of 337 fully sequenced tailed phages isolated on 18 genera and 31 species of bacteria in the Enterobacteriaceae. These phages were largely unambiguously grouped into 56 diverse clusters (32 lytic and 24 temperate) that have syntenic similarity over >50% of the genomes within each cluster, but substantially less sequence similarity between clusters. Most clusters naturally break into sets of more closely related subclusters, 78% of which are correlated with their host genera. The largest groups of related phages are superclusters united by genome synteny to lambda (81 phages) and T7 (51 phages). This study forms a robust framework for understanding diversity and evolutionary relationships of existing tailed phages, for relating newly discovered phages and for determining host/phage relationships.

Developmental cell interactions in Myxococcus xanthus and the spoC locus

The product(s) of the Myxococcus xanthus spoC locus is required for two multicellular activities in fruiting body development, rippling and sporulation. Ripples, which are formed early in development, are spatially separated ridges of cells that move synchronously. Myxospores are heat-resistant resting cells that are formed near the end of the developmental process. To investigate the function of spoC, it was cloned in an Escherichia coli plasmid, then transferred to M. xanthus by specialized transduction with coliphage P1. The plasmid, which cannot replicate in M. xanthus, integrated into the M. xanthus chromosome, producing two copies of the spoC locus in tandem. Cells containing one copy of a mutant allele and one copy of the wild-type allele displayed the wild-type phenotype. Cells containing two different mutant alleles failed to ripple or sporulate, implying that all four independent spoC mutations are in the same gene or unit of transcription. Homozygous mutant duplications arose from constructions in which DNA from a spo(+) donor was transduced into a spoC recipient, or vice versa, at an average frequency of 14%, indicating that gene conversion was a frequent event.

Recombination in the Vicinity of Insertions of Transposon Tn 5 in MYXOCOCCUS XANTHUS

To test genetic recombination in the vicinity of insertions of the transposon Tn5, crosses were performed by transduction between M. xanthus strains carrying different insertions of Tn5. One member of each pair carried resistance to kanamycin (Tn5-Km); the other carried resistance to tetracycline (Tn5-Tc). The distance between each pair of Tn5 insertions was also measured by restriction mapping. The physical distance corresponding to each recombination frequency was calculated from the transductional linkage and compared with distance on the restriction map. A good correspondence between the two measures of distance was obtained for a pair of Tn5 insertions near the cglB locus and for another pair near the mgl locus. Correspondence between the two measurements of distance, the observed allelic behavior of Tn5-Km and Tn5 -Tc at the same locus and the finding of the same frequencies of recombinants in reciprocal crosses implied that recombination in the vicinity of Tn 5 was normal.

Discovery of the autonomously replicating plasmid pMF1 from Myxococcus fulvus and development of a gene cloning system in Myxococcus xanthus

Myxobacteria are very important due to their unique characteristics, such as multicellular social behavior and the production of diverse and novel bioactive secondary metabolites. However, the lack of autonomously replicating plasmids has hindered genetic manipulation of myxobacteria for decades. To determine whether indigenous plasmids are present, we screened about 150 myxobacterial strains, and a circular plasmid designated pMF1 was isolated from Myxococcus fulvus 124B02. Sequence analysis showed that this plasmid was 18,634 bp long and had a G+C content of 68.7%. Twenty-three open reading frames were found in the plasmid, and 14 of them were not homologous to any known sequence. Plasmids containing the gene designated pMF1.14, which encodes a large unknown protein, were shown to transform Myxococcus xanthus DZ1 and DK1622 at high frequencies ( approximately 10(5) CFU/microg DNA), suggesting that the locus is responsible for the autonomous replication of pMF1. Shuttle vectors were constructed for both M. xanthus and Escherichia coli. The pilA gene, which is essential for pilus formation and social motility in M. xanthus, was cloned into the shuttle vectors and introduced into the pilA-deficient mutant DK10410. The transformants subsequently exhibited the ability to form pili and social motility. Autonomously replicating plasmid pMF1 provides a new tool for genetic manipulation in Myxococcus.

Exopolysaccharide biosynthesis genes required for social motility in Myxococcus xanthus

Social (S)-motility in Myxococcus xanthus is a flagellum-independent gliding motility system that allows bacteria to move in groups on solid surfaces. S-motility has been shown to require type IV pili (TFP), exopolysaccharide (EPS; a component of fibrils) and lipopolysaccharide (LPS). Previously, information concerning EPS biogenesis in M. xanthus was lacking. In this study, we screened 5000 randomly mutagenized colonies for defects in S-motility and EPS and identified two genetic regions essential for EPS biogenesis: the EPS synthesis (eps) region and the EPS-associated (eas) region. Mutants with insertions in the eps and eas regions were defective in S-motility and fruiting body formation. These mutants failed to bind the dye calcofluor white, indicating that they lacked EPS; however, they retained normal TFP and LPS. Analysis of the eps locus showed several open reading frames (ORFs) that encode homologues to glycosyltransferases, glucanases and EPS transporters as well as regulatory proteins; the eas locus contains two ORFs: one exhibits homology to hypothetical proteins with a conserved domain of unknown function and the other displays no apparent homology to other proteins in the database. Further genetic mutagenesis analysis indicates that the whole eps region is involved in the biosynthesis of fibrils and fibril EPS. The operon at the proximal end of the eps region was analysed by generating in-frame deletion mutations. These mutants showed varying degrees of defects in the bacterium's ability to produce EPS or perform EPS-related functions, confirming the involvement of these genes in M. xanthus EPS biogenesis.

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.

SdeK, a histidine kinase required for Myxococcus xanthus development

The sdeK gene is essential to the Myxococcus xanthus developmental process. We reported previously, based on sequence analysis (A. G. Garza, J. S. Pollack, B. Z. Harris, A. Lee, I. M. Keseler, E. F. Licking, and M. Singer, J. Bacteriol. 180:4628--4637, 1998), that SdeK appears to be a histidine kinase. In the present study, we have conducted both biochemical and genetic analyses to test the hypothesis that SdeK is a histidine kinase. An SdeK fusion protein containing an N-terminal polyhistidine tag (His-SdeK) displays the biochemical characteristics of a histidine kinase. Furthermore, histidine 286 of SdeK, the putative site of phosphorylation, is required for both in vitro and in vivo protein activity. The results of these assays have led us to conclude that SdeK is indeed a histidine kinase. The developmental phenotype of a Delta sdeK1 strain could not be rescued by codevelopment with wild-type cells, indicating that the defect is not due to the mutant's inability to produce an extracellular signal. Furthermore, the Delta sdeK1 mutant was found to produce both A- and C-signal, based on A-factor and codevelopment assays with a csgA mutant, respectively. The expression patterns of several Tn5lacZ transcriptional fusions were examined in the Delta sdeK1-null background, and we found that all C-signal-dependent fusions assayed also required SdeK for full expression. Our results indicate that SdeK is a histidine kinase that is part of a signal transduction pathway which, in concert with the C-signal transduction pathway, controls the activation of developmental-gene expression required to progress past the aggregation stage.

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.

The stringent response in Myxococcus xanthus is regulated by SocE and the CsgA C-signaling protein

Myxococcus xanthus fruiting body development is induced by amino acid limitation. The decision to grow or develop is established by the RelA-dependent stringent response and A-signaling. We identified two new members of this regulatory hierarchy, socE and the C-signaling gene csgA. SocE depletion arrests growth and induces sporulation under conditions that normally favor growth as well as curtailing DNA and stable RNA synthesis, inhibiting cell elongation, and inducing accumulations of the stringent nucleotides ppGpp and pppGpp [(p)ppGpp]. This system separates C-signaling, which does not occur under these conditions, from CsgA enzyme activity. Amino acid substitutions in the CsgA coenzyme binding pocket or catalytic site eliminate growth arrest. relA mutation also eliminates growth arrest. Eleven pseudorevertants selected for growth following SocE depletion contained mutations in csgA or relA. These results suggest that CsgA induces the stringent response and while SocE inhibits it. Unlike the csgA mutant, wild-type and socE csgA cells maintained high levels of (p)ppGpp throughout development. We suggest that CsgA maintains growth arrest throughout development to divert carbon from A-signaling and other sources into developmental macromolecular synthesis.

The stringent response in Myxococcus xanthus is regulated by SocE and the CsgA C-signaling protein

Myxococcus xanthus fruiting body development is induced by amino acid limitation. The decision to grow or develop is established by the RelA-dependent stringent response and A-signaling. We identified two new members of this regulatory hierarchy, socE and the C-signaling gene csgA. SocE depletion arrests growth and induces sporulation under conditions that normally favor growth as well as curtailing DNA and stable RNA synthesis, inhibiting cell elongation, and inducing accumulations of the stringent nucleotides ppGpp and pppGpp [(p)ppGpp]. This system separates C-signaling, which does not occur under these conditions, from CsgA enzyme activity. Amino acid substitutions in the CsgA coenzyme binding pocket or catalytic site eliminate growth arrest. relA mutation also eliminates growth arrest. Eleven pseudorevertants selected for growth following SocE depletion contained mutations in csgA or relA. These results suggest that CsgA induces the stringent response and while SocE inhibits it. Unlike the csgA mutant, wild-type and socE csgA cells maintained high levels of (p)ppGpp throughout development. We suggest that CsgA maintains growth arrest throughout development to divert carbon from A-signaling and other sources into developmental macromolecular synthesis.

The aadA gene of plasmid R100 confers resistance to spectinomycin and streptomycin in Myxococcus xanthus

Plasmids with the aadA gene from plasmid R100, which confers resistance to the aminoglycosides spectinomycin and streptomycin in Escherchia coli, can be introduced into wild-type Myxococcus xanthus, strain DK1622, by electroporation. Recombinant M. xanthus strains with integrated plasmids carrying the aadA gene acquire resistance to high levels of these antibiotics. Selection for aadA in M. xanthus can be carried out independently of, or simultaneously with, selection for resistance to kanamycin. The kinds and frequencies of recombination events observed between integrative plasmids with aadA and the M. xanthus chromosome are similar to those observed after the transformation of yeast. Cleavage of integrative plasmid DNA at a site adjacent to a region of homology between the plasmid and the M. xanthus genome favors the targeted disruption of M. xanthus genes by allele replacement.

Methylation of FrzCD defines a discrete step in the developmental program of Myxococcus xanthus

Myxococcus xanthus is a gram-negative soil bacterium which undergoes fruiting body formation during starvation. The frz signal transduction system has been found to play an important role in this process. FrzCD, a methyl-accepting taxis protein homologue, shows modulated methylation during cellular aggregation, which is thought to be part of an adaptation response to an aggregation signal. In this study, we assayed FrzCD methylation in many known and newly isolated mutants defective in fruiting body formation to determine a possible relationship between the methylation response and fruiting morphology. The results of our analysis indicated that the developmental mutants could be divided into two groups based on their ability to show normal FrzCD methylation during development. Many mutants blocked early in development, i.e., nonaggregating or abnormally aggregating mutants, showed poor FrzCD methylation. The well-characterized asg, bsg, csg, and esg mutants were found to be of this type. The defects in FrzCD methylation of these signaling mutants could be partially rescued by extracellular complementation with wild-type cells or addition of chemicals which restore their fruiting body formation. Mutants blocked in late development, i.e., translucent mounds, showed normal FrzCD methylation. Surprisingly, some mutants blocked in early development also exhibited a normal level of FrzCD methylation. The characterized mutants in this group were found to be defective in social motility. This indicates that FrzCD methylation defines a discrete step in the development of M. xanthus and that social motility mutants are not blocked in these early developmental steps.

A DnaK homolog in Myxococcus xanthus is involved in social motility and fruiting body formation

Myxococcus xanthus is a gram-negative soil bacterium which exhibits a complex life cycle and social behavior. In this study, two developmental mutants of M. xanthus were isolated through Tn5 transposon mutagenesis. The mutants were found to be defective in cellular aggregation as well as in sporulation. Further phenotypic characterization indicated that the mutants were defective in social motility but normal in directed cell movements. Both mutations were cloned by a transposon-tagging method. Sequence analysis indicated that both insertions occurred in the same gene, which encodes a homolog of DnaK. Unlike the dnaK genes in other bacteria, this M. xanthus homolog appears not to be regulated by temperature or heat shock and is constitutively expressed during vegetative growth and under starvation. The defects of the mutants indicate that this DnaK homolog is important for the social motility and development of M. xanthus.

A new Myxococcus xanthus gene cluster for the biosynthesis of the antibiotic saframycin Mx1 encoding a peptide synthetase

The gene cluster for the biosynthesis of the heterocyclic quinone antibiotic saframycin Mx1 of Myxococcus xanthus DM504/15 was inactivated and tagged by Tn5 insertions. The tagged genes were cloned in Escherichia coli and used to select overlapping cosmid clones spanning 58 kb of the M. xanthus genome. Gene disruption experiments defined a > or = 18 kb contiguous DNA region involved in saframycin biosynthesis. Sequencing of part of this region revealed a large ORF containing two 600-amino-acid domains with similarity to peptide synthetase amino-acid-activating sequences, suggesting that saframycin Mx1 is synthesized by a nonribosomal multienzyme complex, similar to other bioactive peptides.

Use of a phase variation-specific promoter of Myxococcus xanthus in a strategy for isolating a phase-locked mutant

The bacterium Myxococcus xanthus alternates between two colony types distinguished by colony morphology and pigmentation. Because the two phases are interconvertible, this phenomenon has been termed phase variation. In one phase, the colonies are bright yellow, rough, and swarming. In the alternate phase, the colonies are tan and mucoid with smooth edges. During exponential vegetative growth, the populations within a colony reach an equilibrium of approximately 99% yellow and 1% tan cells. Neither the biological function nor the genetic mechanism of phase variation is currently understood. To investigate phase variation, a yellow-phase-specific promoter was identified by Tn5lac mutagenesis. A tan-phase-locked mutant was isolated by a strategy, described in this study, which involved introducing a selectable marker expressed under phase-regulated expression. This was accomplished by a fusion of the cloned yellow-phase-specific promoter to a promoterless kanamycin resistance gene. The defect in the phase-locked mutant, given the designation var-683, caused the rate of switching from the tan to yellow phase to be reduced by at least 10(3)-fold below the wild-type rate of switching. This strain will provide a stable tan population for genetic and biological analysis. Evidence is presented for the existence of a transcriptional regulator which controls the expression of phase-regulated promoters.

Identification of esg, a genetic locus involved in cell-cell signaling during Myxococcus xanthus development

JD258, a Tn5 insertion mutant of Myxococcus xanthus, was shown to have major defects in three development-associated properties: expression of the developmentally regulated tps gene, spore formation, and production of multicellular fruiting bodies. The defects in tps gene expression and sporulation could be substantially corrected, at the phenotypic level, by mixing JD258 with wild-type cells (extracellular complementation). By this criterion, JD258 appeared to be a new member of a group of conditional developmental mutants that were previously characterized and placed in four extracellular complementation groups (A to D) based on the ability of mutants in one group to stimulate development in mutants belonging to a different group (D. C. Hagen, A. P. Bretscher, and D. Kaiser, Dev. Biol. 64:284-296, 1978). Mutants from groups A, B, C, and D all displayed extracellular complementation activity when mixed with JD258. These results, and other aspects of the phenotype of JD258, indicate that this mutant defines a fifth extracellular complementation group, group E. The M. xanthus esg locus identified by the Tn5 insertion in JD258 was cloned in Escherichia coli and used for further genetic analysis of the locus. These studies indicated that the esg locus resides within a 2.5-kb region of the M. xanthus chromosome and that the locus contains at least two genetic complementation groups. Our results are consistent with a model in which the esg locus controls the production of a previously unrecognized extracellular signal that must be transmitted between cells for the completion of M. xanthus development.

Mutation and mapping of genes involved in production of the antibiotic TA in Myxococcus xanthus

Transposition of TnV and Tn5lac into Myxococcus xanthus yielded 8,381 kanamycin-resistant mutants that were tested for antibiotic TA production. Twenty-four of the mutants were nonproducers of TA (less than 0.4 ng/ml), and 3 produced a higher level (2.5 micrograms/ml) than the parent strain (1.5 micrograms/ml). For most of the strains, there was 100% cotransduction between kanamycin resistance and the altered TA phenotype. Southern blot analysis of restriction digests of the mutant DNA indicated that the transposons were inserted at different sites on the M. xanthus chromosome. The TA genes were mapped by cotransduction between pairs of mutants following replacement of the initial insert of one of the pair with the tetracycline resistance transposon Tn5-132. Nine of the 13 nonproducers tested were linked over a 36-kb stretch of the chromosome. There was no linkage between one of the overproducers and any of the nonproducers tested.

Tagging developmental genes in Dictyostelium by restriction enzyme-mediated integration of plasmid DNA

Introduction of restriction enzyme along with linearized plasmid results in integration of plasmid DNA at genomic restriction sites in a high proportion of the resulting transformants. We have found that electroporating BamHI or EcoRI together with pyr5-6 plasmids cut with the same enzyme stimulates the efficiency of transformation in Dictyostelium discoideum more than 20-fold over the rate seen when plasmid DNA alone is introduced. Restriction enzyme-mediated integration generates insertions into genomic restriction sites in an apparently random manner, some of which cause mutations. About 1 in 400 of the Dictyostelium transformants displayed arrested or aberrant development. The integrated plasmid, along with flanking genomic DNA, was excised from some of these mutants, cloned in Escherichia coli, and used to transform other Dictyostelium cells. Homologous recombination within the flanking sequences resulted in the same phenotypes displayed by the original mutants, directly demonstrating that the affected genes were responsible for the specific morphological phenotypes. This method of insertional mutagenesis should be useful for tagging, and subsequent cloning, of many developmentally important genes that can be identified by their mutant phenotypes.

Sensory transduction in the gliding bacterium Myxococcus xanthus

Sensory transduction in the gliding bacterium Myxococcus xanthus is mediated by the frz genes. These genes are homologous to the chemotaxis genes of enteric bacteria and control the rate of cell reversal during gliding. Sensory transduction is hypothesized to involve the recognition of substances present in the medium at the cell surface and the subsequent stimulation of a cytoplasmic methyl-accepting protein, FrzCD. Phosphorylation of FrzE is also involved in the sensory transduction pathway. Despite the similarities between the chemotaxis proteins of enteric bacteria and M. xanthus Frz proteins, fundamental differences exist between these different bacteria in terms of the ability of cells to recognize and respond to substances in their environment. The mechanism of directional switching and the nature of the gliding motor remain obscure. It is hoped that the study of the interaction of the Frz proteins will allow greater understanding of these problems.

Low-temperature induction of Myxococcus xanthus developmental gene expression in wild-type and csgA suppressor cells

The csgA gene encodes an extracellular protein that plays an essential role in the regulation of fruiting-body formation and sporulation of Myxococcus xanthus. The csgA suppressor allele soc-500 (formerly referred to as csp-500) was selected based on its ability to restore sporulation to csgA cells under developmental conditions at 32 degrees C. The soc-500 allele was subsequently found to induce sporulation of csgA+ or csgA cells simply by shifting the temperature of vegetatively growing cells to 15 degrees C. Low-temperature-induced sporulation of soc-500 strains occurred in the absence of two requirements for fruiting-body sporulation: low nutrient levels and a high temperature. Low temperature alone caused the expression of many developmentally regulated genes but did not support the development of wild-type cells. The soc-500 allele appears to activate genes involved with sensing nutritional stress. At low temperature on a nutritionally rich medium, soc-500 induced expression of the tps gene which is normally expressed following nutritional shiftdown. The soc-500 allele was cloned and integrated into the wild-type chromosome by site-specific recombination. It was dominant over the wild-type allele in merodiploids and is contained on a 3-kbp DraI-ClaI restriction fragment. The soc-500 transcriptional unit spans a 300-bp PstI-PstI restriction fragment, since deletion of the PstI restriction fragment inhibits both csgA suppression and low-temperature induction. These results suggest that the soc-500 mutation lies in a gene that is involved in nutrient sensing.

Physical map of the Myxococcus xanthus chromosome

The genome of Myxococcus xanthus, which is 9,454 kbp, is one of the largest bacterial genomes. The organization of the DNA and the distribution of genes encoding social and developmental behaviors were examined by using pulsed field gel electrophoresis. Intact genomic DNA was digested with AseI into 16 restriction fragments, which were separated by contour-clamped homogeneous electric field electrophoresis, purified, and radiolabeled. Each AseI fragment was hybridized to SpeI-digested DNA and to an M. xanthus genomic library contained in yeast artificial chromosomes. Some SpeI restriction fragments and yeast artificial chromosome clones contained AseI sites and hybridized with two different AseI restriction fragments, providing evidence for the juxtaposition of these AseI restriction fragments in the chromosome. The deduced AseI physical map is circular, suggesting that this bacterium contains a single, circular chromosome. Transposable elements shown by transduction to be in or near genes of interest were located on specific AseI restriction fragments by restriction analysis and Southern hybridization. Most AseI restriction fragments contained genes involved in social and developmental behaviors.

Suppressors that permit A-signal-independent developmental gene expression in Myxococcus xanthus

Progression through the early stages of Myxococcus xanthus fruiting body development requires the cell-to-cell transmission of soluble material called A signal. During these early stages, expression from the gene identified by Tn5 lac insertion omega 4521 increases. A DNA probe of the omega 4521 gene was constructed. Use of this probe showed that accumulation of mRNA corresponding to the omega 4521 gene depends upon A signal. A-signal-deficient (asg) mutants fail to accumulate this RNA, and the external addition of A signal restores accumulation. To identify links between A signal and its responsive gene, omega 4521, suppressors of an asg mutation were generated. All of the suppressor alleles restored lacZ expression from omega 4521 in the absence of A signal, and they were demonstrated to be neither reversions of the asgB mutation nor mutations in the promoter of omega 4521. Fifteen suppressor mutations map to two loci, sasA and sasB (for suppressor of asg). sasA and sasB mutants differ phenotypically during growth and development. Mid-logarithmic-phase sasA asgB double mutants, like sas+ asg+ strains, express low levels of lacZ, whereas sasB asgB double mutants express high levels. sasA asg+ mutants form abnormal colonies, are less cohesive than wild type, and are defective in fruiting body formation and sporulation. In contrast, sasB asg+ mutants form normal colonies, are as cohesive as wild type, and appear to develop normally. The characteristics of sasA suppressors implicate the sasA+ product as a negative regulator in the A-signal-dependent regulation of omega 4521.

Genetic analysis of tag mutants of Myxococcus xanthus provides evidence for two developmental aggregation systems

Temperature-dependent aggregation mutants (tag) of the myxobacterium Myxococcus xanthus aggregated into mounds and developed into fruiting bodies normally at 28 degrees C; however, they failed to form mounds at 34 degrees C. The timing of sporulation was unaffected by the mutations, and normal numbers of spores were produced at both permissive and restrictive temperatures. This class of mutations was originally identified through screening of ethyl methanesulfonate (EMS)-generated mutations. Subsequent work identified a linked insertion of transposon Tn5, which was used to map the EMS-generated mutations to four loci. In this paper, we describe the cloning of the tag loci and the use of transposon mutagenesis to further analyze the tag loci. Nine tag complementation groups spanning 8.5 kilobase pairs of DNA were identified through mapping of 28 independent Tn5 insertions. All insertion and deletion mutants had the same phenotype as the EMS mutants: they were temperature sensitive for mound formation. This result suggests that M. xanthus has at least two sets of genes for developmental aggregation. The tag genes constitute one set of these genes; they are required for normal development at 34 degrees C but are not required for normal development at 28 degrees C.

asgB, a gene required early for developmental signalling, aggregation, and sporulation of Myxococcus xanthus

The asgB genetic locus of Myxococcus xanthus specifies a function which is required early in the developmental pathway leading to aggregation and sporulation in fruiting bodies. The developmental defect of asgB mutants can be compensated by extracellular complementation using either intact wild-type cells or cell-free supernatants conditioned by developing wild-type cells. A Tn5 insertion was isolated closely linked to asgB480 and facilitated the cloning of both the wild-type (asgB+) and the mutant (asgB480) alleles in Escherichia coli plasmid. Tandem duplications of the asgB locus were constructed in M. xanthus; the completely wild-type phenotype of asgB+/asgB480 partial diploids implies that the asgB480 allele is recessive. This finding, along with extracellular complementation by wild-type cells, is consistent with the hypothesis that the asgB+ locus is required to produce a substance with an intercellular signalling function. At least part of the asgB gene was found to lie within a 1.2 kb SmaI DNA fragment. This 1.2 kb fragment, as well as smaller fragments derived from it, were used as DNA probes in RNA/DNA hybrid analyses of transcription in the asgB region. Two small mRNA species were detected, one about 650 bp long, and the other about 500 bp; the two species of mRNAs apparently overlap. Both mRNAs are present in low, but approximately equal amounts, in vegetatively growing cells. This is consistent with the observation that asg mutants display a mutant vegetative phenotype (a change in colony color and spreading behavior) as well as defective development.

dsg, a gene required for cell-cell interaction early in Myxococcus development

dsg mutants of Myxococcus xanthus are conditionally defective in fruiting body development, including sporulation. Unable to develop on their own, these mutants can assemble fruiting bodies with spores if they are mixed with wild-type cells. To elucidate the developmental defect in dsg mutants by close comparison with wild type, such mutants have been backcrossed by transduction, using a closely linked insertion of transposon Tn5 for selection. Backcrossed dsg mutants form aggregates that are larger, less compact, and less symmetrical than dsg+ fruiting bodies. Also, the starvation-induced sporulation in dsg aggregates is delayed and reduced. However, dsg mutants can be induced by glycerol or dimethyl sulfoxide to sporulate at levels approaching those of wild type. dsg mutants may thus have a primary defect early in development which diminishes their capacity to aggregate and which indirectly decreases the number of fruiting body spores. The linked insertion of Tn5 also facilitated cloning the dsg gene. The cloned dsg+ allele was shown to be dominant to both the dsg-429 and dsg-439 alleles, and both mutant alleles were shown to belong to the same genetic complementation group. Subcloning of restriction fragments, deletions, and insertions of transposon Tn5 agree in locating the dsg gene to an 850-base-pair segment of the cloned region.

Developmental bypass suppression of Myxococcus xanthus csgA mutations

The csgA mutations of Myxococcus xanthus (formerly known as spoC) inhibit sporulation as well as rippling, which involves ridges of cells moving in waves. Sporulating revertants of CsgA cells were isolated by direct selection, since spores are much more resistant to heat and ultrasonic treatment than are vegetative cells. The revertants fell into seven groups on the basis of phenotype and the chromosomal location of the suppressor alleles. Group 1 contained one allele that was a back mutation of the original csgA mutation. Group 2 contained two linked alleles that were unlinked to the csgA locus and restored fruiting-body formation, sporulation, and rippling. Group 3 revertants regained the ability to sporulate in fruiting bodies but not the ability to ripple. Revertants in groups 4 to 7 were able to sporulate but unable to form fruiting bodies or ripples. The suppressors were all found to be bypass suppressors even though they were not selected as such in most cases. The csgA mutation prevented expression of several developmentally regulated promoters, each fused to a lacZ reporter gene and assayed by beta-galactosidase production. In four of five suppressor groups (groups 4 to 7), expression of each of these csgA-dependent fusions was restored, which suggests that bypass suppression restores developmental gene expression near the point at which expression is disrupted in CsgA mutants. Bypass suppression did not restore production of C factor, and morphological manifestations of development such as rippling and fruiting-body formation were usually abnormal. One interpretation of these results is that C factor has multiple functions and few suppressors can compensate for all of them.

Genes required for developmental signalling in Myxococcus xanthus: three asg loci

asg-carrying strains of Myxococcus xanthus arose in a selection for mutants defective in cell-cell signalling during fruiting body development. All 15 asg mutations examined were found to lie in one of three genetic loci, asgA, asgB, or asgC. The loci were defined by linkage to different insertions of transposon Tn5 and molecular cloning of asgA. asg mutants of all three types were deficient in the aggregation of cells into mounds of the sort that normally give rise to fruiting bodies. asg mutants were also deficient in spore formation; sporulation is normally one of the last steps in fruiting body development. Consistent with a requirement for cell-to-cell signalling, at 1 to 2 h asg+-carrying cells release a material called A-factor that can rescue development of asg mutants. asgA, asgB, and asgC mutants released 5% or less of the asg+ level of A-factor, as measured by bioassay. The experimental results are consistent with the hypothesis that a deficiency in A-factor production or release is the primary developmental defect in asg mutants and that aggregation and sporulation depend on A-factor. asg mutations at all three loci also changed the color and morphology of growing colonies, and failure to release A-factor may itself arise from a defect in growing cells.

Movement of multiple DNA units between Myxococcus xanthus cells

Myxococcus xanthus YS produces particles (Mx alpha particles) that transmit genetic information between cells. Mx alpha particles might be viruses, although no host able to sustain lytic growth of Mx alpha has been discovered. The particles could be detected by their ability to transduce a Tn5 transposon tag to recipient bacteria. DNA from purified particles hybridized to a limited number of DNA restriction fragments of strain YS, suggesting that Mx alpha particles contain only specific DNA sequences. A set of Tn5 insertions residing in the transducible region provided genetic markers for cloning cellular DNA packaged by Mx alpha. A map of this region showed that transducible DNA comprised multiple units of approximately 80 kilobases each. Individual units share DNA homology but are divergent in the location of restriction sites. Other wild-type isolates of Myxococcus species contained DNA sequences with homology to Mx alpha DNA, indicating that Mx alpha DNA is widespread in nature. Experiments on the transfer of Mx alpha DNA in strain YS suggested that DNA transfer is enhanced during the developmental cycle.

Isolation of cell surface antigen mutants of Myxococcus xanthus by use of monoclonal antibodies

Monoclonal antibodies (MAbs) with affinities for molecules on the cell surface of the procaryote Myxococcus xanthus were used in a screening strategy for the isolation of mutants lacking particular cell surface molecules. From a large library of independent mutants created by Tn5 transposon mutagenesis, mutants were isolated which lacked reactivities with MAb 1604 (a MAb specific for a cell surface protein) and MAbs 2600, 1733, 1514, 1412, and 783 (MAbs specific for carbohydrate epitopes on the O antigen of lipopolysaccharide [LPS]). The defect in antibody recognition was shown by genetic crosses and DNA hybridization experiments to be caused by the Tn5 transposon acting as a mutation at a single locus. Quantitative enzyme-linked immunosorbent assays showed that particular mutant strains had no detectable affinity for the specific MAb probe. LPS mutants were resistant to myxophage Mx8, and this provided a selection method for isolating a large number of new LPS mutants. A class of Mx8-resistant mutants lacked reactivity with MAb 1514 and therefore was defective in the O antigen of LPS. A class of Mx1-resistant mutants lacked reactivity with MAb 2254, a MAb specific for a carbohydrate epitope on the core of LPS. A comparison of MAb binding to different mutant strains revealed a principle for mapping epitopes and showed that MAbs 1514 and 2254 recognize side-chain carbohydrates rather than backbone carbohydrates within the LPS molecule.

Genetic identification and cloning of a gene required for developmental cell interactions in Myxococcus xanthus

Developmental mutants of Myxococcus xanthus have been previously described which appear to be defective in required cell-cell interactions. These mutants fall into four phenotypic classes, Asg, Bsg, Csg, and Dsg, each of which is unable to differentiate into spores but can be rescued by extracellular complementation by wild-type cells or by mutants of a different class. We report the identification of one of the loci in which mutations result in a Bsg phenotype. The cloned locus was contained on a 12-kilobase EcoRI fragment and then localized by subcloning and a combination of in vitro and transposon mutagenesis. All mutations in this locus behave as a single complementation group, which we designate bsgA (formerly ssbA). Each of the bsgA mutations results in a nonsporulating phenotype, which can be rescued by extracellular complementation. Furthermore, we report that the bsgA mutants have a distinctive interaction with wild-type cells when vegetatively growing, swarming colonies converge.

Expression of many developmentally regulated genes in Myxococcus depends on a sequence of cell interactions

Certain developmental mutants of Myxococcus xanthus can be complemented extracellularly by wild-type cells. These mutants behave as if they are defective in cell-cell interactions that are required for development. There may be several different interactions because the mutants belong to four extracellular complementation groups (A, B, C, and D). We report here that B- and C- mutations change the pattern of gene expression during Myxococcus development as detected by transcriptional fusions to lacZ mediated by Tn5 lac. The mutant C locus reduced or abolished developmental beta-galactosidase expression from 15 lac fusions that normally begin to be expressed in wild-type cells after 6 hr of development. Expression of these C-dependent lac fusions was restored to C- mutants by adding wild-type cells. The C- mutation did not affect the expression of 10 lac fusions that normally begin to be expressed before 6 hr of development, indicating that the C-mediated cell-cell interaction is required beginning at about 6 hr of development. Cells require the B+ function very early in development because a B- mutation reduced or abolished developmental beta-galactosidase expression from all 26 lac fusions tested, including some that normally begin to be expressed at the onset of development. In a C- mutant and in a B- mutant, some lac fusions responded with reduced beta-galactosidase expression, whereas other fusions, which would normally begin beta-galactosidase expression at about the same time during development, expressed no beta-galactosidase, indicating that developmental genes within a given temporal class display different sensitivities to the absence of cell-cell interactions. Requirements for B+ and C+ function, as well as the previously described A+ function, appear to lie on the same developmental pathway.

Cloning of genes from members of the family Enterobacteriaceae with mini-Mu bacteriophage containing plasmid replicons

An in vivo cloning system that uses derivatives of the Escherichia coli bacteriophage Mu with plasmid replicons has been extended to five different species of the family Enterobacteriaceae. Mu and these mini-Mu replicon elements were introduced into strains of E. coli, Shigella flexneri, Salmonella typhimurium, Citrobacter freundii, and Proteus mirabilis by infection, by transformation, or by conjugation with newly constructed broad-host-range plasmids containing insertions of these elements. Lysates from these cells, lysogenic for Mu and mini-Mu elements, were used to infect sensitive recipient strains of E. coli, S. typhimurium, and C. freundii. Drug-resistant transductants had mini-Mu replicon elements with inserts of different DNA sequences. All of the lysogens made could be induced to yield high phage titers, including those coming from strains that were resistant to Mu and Mu derivatives. Clones of 10 particular genes were isolated by their ability to complement specific mutations in the recipient strains, even in the presence of the E. coli K-12 restriction system. Some of the mini-Mu replicon elements used contained lac gene fusing segments and resulted in fusions of the lac operon to control regions in the cloned sequences.

Control of morphogenesis in myxobacteria

The myxobacteria are Gram-negative soil bacteria that live in large communities known as swarms. The most remarkable characteristic of myxobacteria is their ability to form fruiting bodies that have a species-specific shape and color. Fruiting body formation requires the concerted effort of hundreds of thousands of cells. Development is initiated only when two conditions are satisfied. The cells must be nutritionally deprived (environmental signal) and there must be many other cells in the vicinity (intercellular signal). The development of one species, Myxococcus xanthus, has been studied in the most detail. M. xanthus uses amino acids as its primary carbon, nitrogen, and energy source. Starvation for a single amino acid, or for inorganic phosphate, serves as the environmental signal. A variety of intercellular signals appear to control the initiation of development and the timing of subsequent developmental events.

Role of cell cohesion in Myxococcus xanthus fruiting body formation

Dsp mutants of Myxococcus xanthus have a complex phenotype with abnormal cell cohesion, social motility, and development. All three defects are the result of a single mutation in the dsp locus, a region of DNA about 14 kilobases long. Cohesion appears to play a central role in social motility, since nonsocial mutants exhibit weak agglutination or, in the case of Dsp cells, no agglutination (L. J. Shimkets, J. Bacteriol. 166:837-841, 1986). However, Dsp cells can be agglutinated by cohesive strains of M. xanthus. This provided the opportunity to examine the role of cohesion during development by comparing the developmental phenotype of Dsp cells with that of Dsp cells mixed with cohesive strains. Dsp mutants were unable to complete any of the developmental behaviors: aggregation, fruiting body formation, developmental autolysis, and sporulation. Contact with cohesive strains seemed to restore some developmental characteristics to the Dsp cells. When allowed to develop with wild-type cells, Dsp cells accumulated in fruiting bodies and underwent developmental autolysis, but did not form a significant portion of the spore population. Igl mutants, which may be similar to the previously described frizzy mutants, are cohesive strains that are unable to form fruiting bodies. Mixing Igl cells with Dsp cells under developmental conditions resulted in fruiting body formation, although the Dsp cells were unable to form significant levels of myxospores. In spite of their inability to sporulate under developmental conditions, Dsp mutants did not appear to be defective in the sporulation process. In fact, they formed normal levels of myxospores in response to the chemical inducer glycerol.

"Frizzy" genes of Myxococcus xanthus are involved in control of frequency of reversal of gliding motility

Myxococcus xanthus, a Gram-negative bacterium, has a complex life cycle that includes fruiting body formation. Frizzy (frz) mutants are unable to aggregate normally, instead forming frizzy filamentous aggregates. We have found that these mutants are defective in the control of cell reversal during gliding motility. Wild-type cells reverse their direction of gliding about every 6.8 min; net movement occurs since the interval between reversals can vary widely. The frzA-C, -E and -F mutants reverse their direction of movement very rarely, about once every 2 hr. These mutants cannot aggregate normally and give rise to frizzy filamentous colonies on fruiting agar or motility agar. In contrast, frzD mutants reverse their direction of movement very frequently, about once every 2.2 min; individual cells show little net movement and form smooth-edged "nonmotile" type colonies. Genetic analysis of the frzD locus shows that mutations in this locus can be dominant to the wild-type allele and that its gene product(s) must interact with the other frz gene products. Our results suggest that the frz genes are part of a system responsible for directed movement of this organism.

Transposon tagging to detect a latent virus in Myxococcus xanthus

Transposon mutagenesis of the bacterium Myxococcus xanthus with the transposon Tn5 revealed a special class of bacterial mutants that transduced the transposon through culture supernatant fluids. Virus-like particles copurified with transducing activity. Transposon tagging for detecting these virus-like particles may be generally useful in isolating endogenous viral agents capable of transferring genetic information between cells.

Cell interactions in myxobacterial growth and development

During their complex life cycle, myxobacteria manifest a number of cell interactions. These include contact-mediated interactions as well as those mediated by soluble extracellular signals. Some of these interactions are well-defined; in addition, the tools for molecular and genetic analysis of these interactions in Myxococcus xanthus are now available.

Novel one-step cloning vector with a transposable element: application to the Myxococcus xanthus genome

A new strategy was developed for rapid cloning of genes with a transposon mutation library. We constructed a transposon designated TnV that was derived from Tn5 and consists of the gene coding for neomycin phosphotransferase II as well as the replication origin of an Escherichia coli plasmid, pSC101, flanked by Tn5 inverted repeats (IS50L and IS50R). TnV can transpose to many different sites of DNA in E. coli and Myxococcus xanthus and confers kanamycin resistance (Kmr) to the cells. From the Kmr cells, one-step cloning of a gene which is mutated as a result of TnV insertion can be achieved as follows. Chromosomal DNA isolated from TnV-mutagenized cells is digested with an appropriate restriction enzyme, ligated, and transformed into E. coli cells with selection for Kmr. The plasmids isolated contain TnV in the target gene. The plasmid DNA can then be used as a probe for characterization of the gene and screening of clones from a genomic library. We used this vector to clone DNA fragments containing genes involved in the development of M. xanthus.

Vectors for transposon mutagenesis of non-enteric bacteria

We have constructed a series of transposon delivery vectors derived from pRK2013. Since pRK2013 has a broad host range transfer system and a ColE1 replicon, it can be transferred to, but not replicated in, many non-enteric gram-negative bacteria. Thus pRK2013 provides an effective mechanism for the transient introduction of a transposon. Delivery vectors containing Tn7 (tmp str), Tn10 (tet), Tn10 HH104 (tet), or Tn5-132 (tet) have been constructed. When transposition in Caulobacter crescentus was examined, both Tn7 and Tn5-132 were found to transpose efficiently. In contrast, although the antibiotic resistances of Tn10 and Tn501 (mer) were expressed in C. crescentus, no transposition was observed with either transposon. However, transposition of Tn10 from the Tn10 vectors did occur in Acinetobacter calcoaceticus, and transposition of Tn501 from pMD100 has been demonstrated in Rhizobium japonicum (Bullerjahn and Benzinger 1984). Thus, transposon-host interactions play an important role in the determination of whether a particular transposon can transpose in a given host. Furthermore, the results with C. crescentus indicate that there must be different requirements for host interactions for Tn10 and Tn501 than for Tn5 and Tn7.

Transpositional Mutagenesis of Thiobacillus novellus and Thiobacillus versutus

Transpositional mutagenesis of Thiobacillus novellus by Tn 501 was achieved by means of the incompatibility of IncP plasmids. Tn 501 insertion caused three types of mutant phenotypes: isoleucine auxotrophy, lysine auxotrophy, and a reduced ability to oxidize reduced sulfur compounds and to fix CO 2 . Oxidation rates for elemental sulfur (S 0 ), thiosulfate (S 2 O 3 2− ), and tetrathionate (S 4 O 6 2− ) in mutants of the latter type were reduced relative to those of the nonmutant control strain. Incorporation of labeled bicarbonate (H 14 CO 3 − ) was also significantly impaired. Although suicide vehicles were not useful for the introduction of transposons into T. novellus , this method was effective for the Tn 1721 -induced mutagenesis of Thiobacillus versutus. Tn 1721 insertions resulted in the loss of the natural resistance of T. versutus to arsenate and gentamicin and in auxotrophies for isoleucine-valine, arginine, phenylalanine, valine, and panthothenate. Transpositional mutagenesis by either method should prove to be a useful tool for further study of these and other members of the genus Thiobacillus.

Cloning and complementation analysis of the "Frizzy" genes of Myxococcus xanthus

Fruiting-body formation in Myxococcus xanthus involves the aggregation of cells into raised mounds, where they sporulate. "Frizzy" mutants fail to aggregate into mounds, but rather aggregate into "frizzy" filaments (D.R. Zusman 1982). The frizzy mutations (frz) were found to be genetically linked. The region of DNA carrying the frz genes was cloned in Escherichia coli by selecting for the kanamycin resistance element present on a transposon Tn5 insertion linked to the frz genes. Phage P1 mediated transduction of the cloned DNA into M. xanthus frizzy mutants showed that the cloned DNA could complement the frz mutations. The cloned DNA was analyzed by isolating and characterizing new Tn5 insertions at short intervals within the M. xanthus DNA and by constructing in vitro deletions. The mutated DNA was then transduced into M. xanthus where the cloned DNA became integrated into the bacterial chromosome as gene replacements or as merodiploids. The gene replacement strains allowed us to define the limits of the frz region, since Tn5 insertions in the frz genes resulted in the frizzy phenotype. The merodiploid strains allowed us to perform complementation analyses. Using appropriate crosses, we were able to identify 5-6 frz complementation groups on 7.5 kb of cloned DNA. One of the complementation groups was separated from the others by 1.4 kb of DNA, whereas the others were contiguous. The different frz loci behave as separate transcriptional groups although interactions between some of the gene products are indicated.