The esg locus of Myxococcus xanthus encodes the E1α and E1β subunits of a branched-chain keto acid dehydrogenase

The esg locus of Myxococcus xanthus appears to control the production of a signal that must be transmitted between cells for the completion of multicellular development DNA sequence analysis suggested that the esg locus encodes the E1 decarboxylase (composed of E1α and E1β subunits) of a branched-chain keto acid dehydrogenase (BCKAD) that is involved in branched-chain amino acid (BCAA) metabolism. The properties of an esg ::Tn5 insertion mutant supported this conclusion. These properties include: (i) the growth yield of the mutant was reduced with increasing concentrations of the BCAAs in the medium while the growth yield of wild-type cells increased, (ii) mutant extracts were deficient in BCKAD activity, and (iii) growth of the mutant in media with short branched-chain fatty acids related to the expected products of the BCKAD helped to correct the mutant defects in growth, pigmentation and development. The esg BCKAD appears to be involved in the synthesis of long branched-chain fatty acids since the mutant contained reduced levels of this class of compounds. Our results are consistent with a model in which the esg-encoded enzyme is involved in the synthesis of branched-chain fatty acids during vegetative growth, and these compounds are used later in cell-cell signalling during development.     

Cyclic nucleotides and development ofMyxococcus xanthus: Analysis of mutants

Approximately 60 developmental mutants ofMyxococcus xanthus M300 were obtained through nitrosoguanidine mutagenesis and placed into three operationally defined categories. Type-I strains exhibited no aggregation or sporulation. Type-II strains were able to aggregate but did not sporulate. A strain classed as a type-III strain was a low-capacity fruiter. Each category displayed defects in cyclic nucleotide behavior that could be predicted from the current model. Most significantly, several aggregationless (type I) mutants lacking cGMP phosphodiesterase aggregated in the presence of externally applied phosphodiesterase. A requirement for cell-cell contact in sporulation has been confirmed. Evidence is presented that suggests the involvement of cAMP phosphodiesterase in sporulation and that sporulation may be a developmental pathway independent of aggregation. These results support a previously published hypothesis of the role of cyclic nucleotides in the development ofM. xanthus.     

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.     

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.     

Propionyl-CoA carboxylase of Myxococcus xanthus: catalytic properties and function in developing cells

An acyl-coenzyme A carboxylase that carboxylates acetyl-CoA, butyryl-CoA, propionyl-CoA, and succinyl-CoA was purified from Myxococcus xanthus. Since the enzyme showed maximal rates of carboxylation with propionyl-CoA, the enzyme is thought to be propionyl-CoA carboxylase. The apparent K _m values for acetyl-CoA, butyryl-CoA, propionyl-CoA, and succinyl-CoA were found to be 0.2, 0.2, 0.03, and 1.0 mM, respectively. The native enzyme has a molecular mass of 605–615 kDa and is composed of nonidentical subunits (α and β) with molecular masses of 53 and 56 kDa, respectively. The enzyme showed maximal activity at pH 7.0–7.5 and at 25–30°C, and was affected by variation in concentrations of ATP and Mg²⁺. During development of M. xanthus, the propionyl-CoA carboxylase activity increased gradually, with maximum activity observed during the sporulation stage. Previous work has shown that a propionyl-CoA-carboxylase-deficient mutant of M. xanthus reduces levels of long-chain fatty acids. These results suggest that the propionyl-CoA carboxylase is also responsible for the carboxylation of acetyl-CoA to malonyl-CoA used for the synthesis of long-chain fatty acids during development. Received: 24 February 1998 / Accepted: 25 May 1998     

Mutants of the fission yeast Schizosaccharomyces pombe which alter the shift between cell proliferation and sporulation

Summary Mutants of S. pombe have been isolated which undergo conjugation and sporulation in rich medium, conditions which are normally inhibitory for these processes. Two of these mutants are also able to sporulate from the haploid state in the absence of heterozygosity at the mating type locus. These recessive mutants define a single nuclear gene called ran1 which is unlinked to mating type. It is proposed that the ran1 gene codes for an inhibitor in the control of the initiation of conjugation and sporulation. In wild type cells the inhibitory effect is released by nutritional starvation and heterozygosity at the mating type locus. This allows the cells to proceed to sporulation. The ran1 mutants are unusual in that they attempt to undergo a reductional meiotic division from the haploid state. They are also genetically unstable and generate extragenic suppressors at high frequency.     

Autocides and a paracide,antibiotic TA,produced byMyxococcus xanthus

Myxococcus xanthus produces two categories of low molecular weight antibacterial materials, autocides and paracides, that have diametrically opposite host ranges. Low concentrations of autocides lyseM. xanthus, the producing organism, whereas paracides exert their effects on other bacteria. Antibiotic TA (a paracide) kills all growing bacteria tested that have a peptidoglycan cell wall exceptM. xanthus. It is a macrocyclic polyketide with a molecular weight of 623. The two major autocides produced byM. xanthus are phosphatidylethanolamine and a mixture of fatty acids. The modes of action, host ranges and biosynthesis of antibiotic TA and the autocides are presented, and then an attempt is made to explain their role in the complex life cycle ofM. xanthus. In addition, the remarkable adhesion properties of antibiotic TA and a new semisynthetic derivative of it, focusin, are presented.     

Neutral and Phospholipids of the Myxococcus xanthus Lipodome during Fruiting Body Formation and Germination

Myxobacteria are well-known for their complex life cycle, including the formation of spore-filled fruiting bodies. The model organism Myxococcus xanthus exhibits a highly complex composition of neutral and phospholipids, including triacylglycerols (TAGs), diacylglycerols (DAGs), phosphatidylethanolamines (PEs), phosphatidylglycerols (PGs), cardiolipins (CLs), and sphingolipids, including ceramides (Cers) and ceramide phosphoinositols (Cer-PIs). In addition, ether lipids have been shown to be involved in development and signaling. In this work, we describe the lipid profile of M. xanthus during its entire life cycle, including spore germination. PEs, representing one of the major components of the bacterial membrane, decreased by about 85% during development from vegetative rods to round myxospores, while TAGs first accumulated up to 2-fold before they declined 48 h after the induction of sporulation. Presumably, membrane lipids are incorporated into TAG-containing lipid bodies, serving as an intermediary energy source for myxospore formation. The ceramides Cer(d-19:0/iso-17:0) and Cer(d-19:0/16:0) accumulated 6-fold and 3-fold, respectively, after 24 h of development, identifying them to be novel putative biomarkers for M. xanthus sporulation. The most abundant ether lipid, 1-iso-15:0-alkyl-2,3-di-iso-15:0-acyl glycerol (TG1), exhibited a lipid profile different from that of all TAGs during sporulation, reinforcing its signaling character. The absence of all these lipid profile changes in mutants during development supports the importance of lipids in myxobacterial development. During germination of myxospores, only the de novo biosynthesis of new cell membrane fatty acids was observed. The unexpected accumulation of TAGs also during germination might indicate a function of TAGs as intermediary storage lipids during this part of the life cycle as well.     

Properties of Bacillus acidocaldarius mutants deficient in ω-cyclohexyl fatty acid biosynthesis

Mutants of the thermoacidophilic Bacillus acidocaldarius, auxotrophic for shikimate or cyclohyxyl-carboxylate, were isolated and characterized. The cyclohexylcarboxylate auxotrophs could be divided by crossfeeding experiments into two groups according to their genetic block. The cyclohexylcarboxylate auxotrophs were deficient in -cyclohexyl fatty acid biosynthesis. If the mutants were fed with branched-chain amino acids or short branched-chain fatty acids instead of cyclohexylcarboxylate they form a fatty acid pattern consisting of branched-chain fatty acids. In the high temperature/low pH range the growth yield of cells with this fatty acid pattern is lower as compared to wild type cells or mutants fed with cyclohexylcarboxylate. The same cells are also more sensitive to heat shocks and ethanol. The transport systems for lysine, glutamate and glucose are severely altered by the fatty acid pattern. It was also shown that the density of the lipids containing -cyclohexyl fatty acids is higher compared to cells with branched-chain fatty acids. Thus it could be supposed that this alteration influences transport systmes in a direct manner or via energization of the cytoplasmic membrane.     

Endocellular fatty acid composition during batch growth and sporulation of Bacillus thuringiensis kurstaki

Bacillus thuringiensis kurstaki (HD-1) was grown on two different complex media to study its fatty acid composition during vegetative growth and sporulation. In contrast to literature results, iso-even branched-chain fatty acids were found to predominate after early vegetative growth and throughout sporulation.     

Genetics of gliding motility and development inMyxococcus xanthus

Successful development in multicellular eukaryotes requires cell-cell communication and the coordinated spatial and temporal movements of cells. The complex array of networks required to bring eukaryotic development to fruition can be modeled by the development of the simpler prokaryoteMyxococcus xanthus. As part of its life cycle,M. xanthus forms multicellular fruiting bodies containing differentiated cells. Analysis of the genes essential forM. xanthus development is possible because strains with mutations that block development can be maintained in the vegetative state. Development inM. xanthus is induced by starvation, and early events in development suggest that signaling, stages have evolved to monitor the metabolic state of the developing cell. In the absence of these signals, which include amino acids, α-keto acids, and other intermediary metabolites, the ability of cells to differentiate into myxospores is impaired. Mutations that block genes controlling gliding, motility disrupt the morphogenesis of fruiting bodies and sporogenesis in surprising ways. In this review, we present data that encourage future genetic and biochemical studies of the relationships between motility, cell-cell signaling, and development inM. xanthus.     

Genetics of gliding motility in Myxococcus xanthus: Molecular cloning of the mgl locus

Summary Wild-type Myxococcus xanthus cells move across solid surfaces by gliding. However no locomotory organelles for gliding have as yet been identified. Two sets of genes are required for gliding in M. xanthus: Gene System A is necessary for the gliding of isolated cells and Gene System S comes into play when cells are close together. The product of the mgl locus is required for both types of gliding and therefore may be a structural component of the gliding organelle. To begin to investigate the function of mgl in gliding a 12 kb segment of M. xanthus DNA containing the locus was cloned in Escherichia coli and returned to Myxococcus by specialized transduction with coliphage P1. In M. xanthus the chimeric plasmid integrates into the chromosome by recombination between the cloned segment and its homolog in the recipient chromosome forming a tandem duplication of the cloned segment with the vector sequences at the novel joint. The construction of partial diploids in this manner facilitated dominance tests and interallelic crosses with ten mgl alleles. We also describe a method for the analysis of tandem duplications that precisely maps alleles to a specific copy of the duplicated sequences. This method provides evidence for the dominance of mgl ⁺ over the mgl ^- alleles. It also reveals what appears to be gene conversion at this locus during recombination between a cloned mgl sequence and its homolog in the chromosome.     

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.     

The Myxococcus xanthus developmental program can be delayed by inhibition of DNA replication

Under conditions of nutrient deprivation, Myxococcus xanthus undergoes a developmental process that results in the formation of a fruiting body containing environmentally resistant myxospores. We have shown that myxospores contain two copies of the genome, suggesting that cells must replicate the genome prior to or during development. To further investigate the role of DNA replication in development, a temperature-sensitive dnaB mutant, DnaB^A116V, was isolated from M. xanthus. Unlike what happens in Escherichia coli dnaB mutants, where DNA replication immediately halts upon a shift to a nonpermissive temperature, growth and DNA replication of the M. xanthus mutant ceased after one cell doubling at a nonpermissive temperature, 37°C. We demonstrated that at the nonpermissive temperature the DnaB^A116V mutant arrested as a population of 1n cells, implying that these cells could complete one round of the cell cycle but did not initiate new rounds of DNA replication. In developmental assays, the DnaB^A116V mutant was unable to develop into fruiting bodies and produced fewer myxospores than the wild type at the nonpermissive temperature. However, the mutant was able to undergo development when it was shifted to a permissive temperature, suggesting that cells had the capacity to undergo DNA replication during development and to allow the formation of myxospores.     

Poly(3‐hydroxybutyrate) fuels the tricarboxylic acid cycle and de novo lipid biosynthesis during Bacillus anthracis sporulation

Numerous bacteria accumulate poly(3‐hydroxybutyrate) (PHB) as an intracellular reservoir of carbon and energy in response to imbalanced nutritional conditions. In Bacillus spp., where PHB biosynthesis precedes the formation of the dormant cell type called the spore (sporulation), the direct link between PHB accumulation and efficiency of sporulation was observed in multiple studies. Although the idea of PHB as an intracellular carbon and energy source fueling sporulation was proposed several decades ago, the mechanisms underlying PHB contribution to sporulation have not been defined. Here, we demonstrate that PHB deficiency impairs Bacillus anthracis sporulation through diminishing the energy status of the cells and by reducing carbon flux into the tricarboxylic acid (TCA) cycle and de novo lipid biosynthesis. Consequently, this metabolic imbalance decreased biosynthesis of the critical components required for spore integrity and resistance, such as dipicolinic acid (DPA) and the spore's inner membrane. Supplementation of the PHB deficient mutant with exogenous fatty acids overcame these sporulation defects, highlighting the importance of the TCA cycle and lipid biosynthesis during sporulation. Combined, the results of this work reveal the molecular mechanisms of PHB contribution to B. anthracis sporulation and provide valuable insight into the metabolic requirements for this developmental process in Bacillus species.     

Exopolysaccharides promote Myxococcus xanthus social motility by inhibiting cellular reversals

The biofilm‐forming bacterium Myxococcus xanthus moves on surfaces as structured swarms utilizing type IV pili‐dependent social (S) motility. In contrast to isolated cells that reverse their moving direction frequently, individual cells within swarms rarely reverse. The regulatory mechanisms that inhibit cellular reversal and promote the formation of swarms are not well understood. Here we show that exopolysaccharides (EPS), the major extracellular components of M. xanthus swarms, inhibit cellular reversal in a concentration‐dependent manner. Thus, individual wild‐type cells reverse less frequently in swarms due to high local EPS concentrations. In contrast, cells defective in EPS production hyper‐reverse their moving direction and show severe defects in S‐motility. Surprisingly, S‐motility and wild‐type reversal frequency are restored in double mutants that are defective in both EPS production and the Frz chemosensory system, indicating that EPS regulates cellular reversal in parallel to the Frz pathway. Here we clarify that besides functioning as the structural scaffold in biofilms, EPS is a self‐produced signal that coordinates the group motion of the social bacterium M. xanthus.