Genetic population structure of the soil bacterium Myxococcus xanthus at the centimeter scale

Myxococcus xanthus is a gram-negative soil bacterium best known for its remarkable life history of social swarming, social predation, and multicellular fruiting body formation. Very little is known about genetic diversity within this species or how social strategies might vary among neighboring strains at small spatial scales. To investigate the small-scale population structure of M. xanthus, 78 clones were isolated from a patch of soil (16 by 16 cm) in Tübingen, Germany. Among these isolates, 21 genotypes could be distinguished from a concatemer of three gene fragments: csgA (developmental C signal), fibA (extracellular matrix-associated zinc metalloprotease), and pilA (the pilin subunit of type IV pili). Accumulation curves showed that most of the diversity present at this scale was sampled. The pilA gene contains both conserved and highly variable regions, and two frequency-distribution tests provide evidence for balancing selection on this gene. The functional domains in the csgA gene were found to be conserved. Three instances of lateral gene transfer could be inferred from a comparison of individual gene phylogenies, but no evidence was found for linkage equilibrium, supporting the view that M. xanthus evolution is largely clonal. This study shows that M. xanthus is surrounded by a variety of distinct conspecifics in its natural soil habitat at a spatial scale at which encounters among genotypes are likely.     

Spatial organization of Myxococcus xanthus during fruiting body formation

Microcinematography was used to examine fruiting body development of Myxococcus xanthus. Wild-type cells progress through three distinct phases: a quiescent phase with some motility but little aggregation (0 to 8 h), a period of vigorous motility leading to raised fruiting bodies (8 to 16 h), and a period of maturation during which sporulation is initiated (16 to 48 h). Fruiting bodies are extended vertically in a series of tiers, each involving the addition of a cell monolayer on top of the uppermost layer. A pilA (MXAN_5783) mutant produced less extracellular matrix material and thus allowed closer examination of tiered aggregate formation. A csgA (MXAN_1294) mutant exhibited no quiescent phase, aberrant aggregation in phase 2, and disintegration of the fruiting bodies in the third phase.     

Type IV‐pili dependent motility is co‐regulated by PilSR and PilS2R2 two‐component systems via distinct pathways in Myxococcus xanthus

Myxococcus xanthus is an environmental bacterium with two forms of motility. One type, known as social motility, is dependent on extension and retraction of Type‐IV pili (T4P) and production of extracellular polysaccharides (EPS). Several signaling systems have been linked to regulation of T4P‐dependent motility. In particular, expression of the pilin subunit pilA requires the PilSR two‐component signaling system (TCS). A second TCS, PilS2R2, encoded within the same locus that encodes PilSR, has also been linked to M. xanthus T4P‐dependent motility. We demonstrate that PilSR and PilS2R2 regulate M. xanthus T4P‐dependent motility through distinct pathways. Consistent with known roles of PilSR, our results indicate that the primary function of PilSR is to regulate expression of pilA. In contrast, PilS2 and PilR2 have little to no affect on PilA protein levels. However, deletion of pilR2 resulted in a reduction of assembled pili, significant decreases in EPS production and loss of T4P‐dependent motility. Furthermore, the pilR2 mutation led to increased production of outer membrane vesicles (OMV). Collectively, we propose that PilS2R2 is required for proper assembly of T4P and regulation of OMV production, and hypothesize that production of these vesicles is related to M. xanthus motility.     

A Chaperone in the HSP70 Family Controls Production of Extracellular Fibrils in Myxococcus xanthus

Three independent Tn5-lac insertions in the S1 locus of Myxococcus xanthus inactivate the sglK gene, which is nonessential for growth but required for social motility and multicellular development. The sequence of sglK reveals that it encodes a homologue of the chaperone HSP70 (DnaK). The sglK gene is cotranscribed with the upstream grpS gene, which encodes a GrpE homologue. Unlike sglK, grpS is not required for social motility or development. Wild-type M. xanthus is encased in extracellular polysaccharide filaments associated with the multimeric fibrillin protein. Mutations in sglK inhibit cell cohesion, the binding of Congo red, and the synthesis or secretion of fibrillin, indicating that sglK mutants do not make fibrils. The fibR gene, located immediately upstream of the grpS-sglK operon, encodes a product which is predicted to have a sequence similar to those of the repressors of alginate biosynthesis in Pseudomonas aeruginosa and Pseudomonas putida. Inactivation of fibR leads to the overproduction of fibrillin, suggesting that M. xanthus fibril production and Pseudomonas alginate production are regulated in analogous ways. M. xanthus and Pseudomonas exopolysaccharides may play similar roles in a mechanism of social motility conserved in these gram-negative bacteria.     

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.     

Inhibition of Development of Myxococcus xanthus by Eukaryotic Protein Kinase Inhibitors

Myxococcus xanthus is a social bacterium that lives in the soil and undergoes spectacular development to form multicellular fruiting bodies. It contains a large family of eukaryote-like serine/threonine protein kinases. We found that a number of inhibitors for eukaryotic protein serine, threonine, and tyrosine kinases could inhibit the development and sporulation of M. xanthus to various degrees. These results suggest that serine/threonine and tyrosine phosphorylation may be involved in development of M. xanthus. None of the inhibitors tested had any effect on vegetative growth of M. xanthus. Most of them seemed to act during the early stages of development. However, the expression of a very early development-specific gene, Ω4521, was not significantly affected by the inhibitors. The patterns of protein phosphorylation during development were also not significantly altered by the inhibitors, suggesting that the targets of the inhibitors are minor or unstable phosphoproteins but play key roles in fruiting-body formation in M. xanthus.     

Microbial Diversity and PAH Catabolic Genes Tracking Spatial Heterogeneity of PAH Concentrations

We analyzed the within-site spatial heterogeneity of microbial community diversity, polyaromatic hydrocarbon (PAH) catabolic genotypes, and physiochemical soil properties at a creosote contaminated site. Genetic diversity and community structure were evaluated from an analysis of denaturant gradient gel electrophoresis (DGGE) of polymerase chain reaction (PCR)-amplified sequences of 16S rRNA gene. The potential PAH degradation capability was determined from PCR amplification of a suit of aromatic dioxygenase genes. Microbial diversity, evenness, and PAH genotypes were patchily distributed, and hot and cold spots of their distribution coincided with hot and cold spots of the PAH distribution. The analyses revealed a positive covariation between microbial diversity, biomass, evenness, and PAH concentration, implying that the creosote contamination at this site promotes diversity and abundance. Three patchily distributed PAH-degrading genotypes, NAH, phnA, and pdo1, were identified, and their abundances were positively correlated with the PAH concentration and the fraction of soil organic carbon. The covariation of the PAH concentration with the number and spatial distribution of catabolic genotypes suggests that a field site capacity to degrade PAHs may vary with the extent of contamination.     

Chimaeric load among sympatric social bacteria increases with genotype richness

The total productivity of social groups can be determined by interactions among their constituents. Chimaeric load—the reduction of group productivity caused by antagonistic within-group heterogeneity—may be common in heterogeneous microbial groups due to dysfunctional behavioural interactions between distinct individuals. However, some instances of chimaerism in social microbes can increase group productivity, thus making a general relationship between chimaerism and group-level performance non-obvious. Using genetically similar strains of the soil bacterium Myxococcus xanthus that were isolated from a single centimetre-scale patch of soil, we tested for a relationship between degree of chimaerism (genotype richness) and total group performance at social behaviours displayed by this species. Within-group genotype richness was found to correlate negatively with total group performance at most traits examined, including swarming in both predatory and prey-free environments and spore production during development. These results suggest that interactions between such neighbouring strains in the wild will tend to be mutually antagonistic. Negative correlations between group performance and average genetic distance among group constituents at three known social genes were not found, suggesting that divergence at other loci that govern social interaction phenotypes is responsible for the observed chimaeric load. The potential for chimaeric load to result from co-aggregation among even closely related neighbours may promote the maintenance and strengthening of kin discrimination mechanisms, such as colony-merger incompatibilities observed in M. xanthus. The findings reported here may thus have implications for understanding the evolution and maintenance of diversity in structured populations of soil microbes.     

Bacillaene and Sporulation Protect Bacillus subtilis from Predation by Myxococcus xanthus

Myxococcus xanthus and Bacillus subtilis are common soil-dwelling bacteria that produce a wide range of secondary metabolites and sporulate under nutrient-limiting conditions. Both organisms affect the composition and dynamics of microbial communities in the soil. However, M. xanthus is known to be a predator, while B. subtilis is not. A screen of various prey led to the finding that M. xanthus is capable of consuming laboratory strains of B. subtilis, while the ancestral strain, NCIB3610, was resistant to predation. Based in part on recent characterization of several strains of B. subtilis, we were able to determine that the pks gene cluster, which is required for production of bacillaene, is the major factor allowing B. subtilis NCIB3610 cells to resist predation by M. xanthus. Furthermore, purified bacillaene was added exogenously to domesticated strains, resulting in resistance to predation. Lastly, we found that M. xanthus is incapable of consuming B. subtilis spores even from laboratory strains, indicating the evolutionary fitness of sporulation as a survival strategy. Together, the results suggest that bacillaene inhibits M. xanthus predation, allowing sufficient time for development of B. subtilis spores.     

Parallel emergence of negative epistasis across experimental lineages

Epistatic interactions can greatly impact evolutionary phenomena, particularly the process of adaptation. Here, we leverage four parallel experimentally evolved lineages to study the emergence and trajectories of epistatic interactions in the social bacterium Myxococcus xanthus. A social gene (pilA) necessary for effective group swarming on soft agar had been deleted from the common ancestor of these lineages. During selection for competitiveness at the leading edge of growing colonies, two lineages evolved qualitatively novel mechanisms for greatly increased swarming on soft agar, whereas the other two lineages evolved relatively small increases in swarming. By reintroducing pilA into different genetic backgrounds along the four lineages, we tested whether parallel lineages showed similar patterns of epistasis. In particular, we tested whether a pattern of negative epistasis between accumulating mutations and pilA previously found in the fastest lineage would be found only in the two evolved lineages with the fastest and most striking swarming phenotypes, or rather was due to common epistatic structure across all lineages arising from the generic fixation of adaptive mutations. Our analysis reveals the emergence of negative epistasis across all four independent lineages. Further, we present results showing that the observed negative epistasis is not due exclusively to evolving populations approaching a maximum phenotypic value that inherently limits positive effects of pilA reintroduction, but rather involves direct antagonistic interactions between accumulating mutations and the reintroduced social gene.     

Kin discrimination and outer membrane exchange in Myxococcus xanthus: A comparative analysis among natural isolates

Genetically similar cells of the soil bacterium Myxococcus xanthus cooperate at multiple social behaviours, including motility and multicellular development. Another social interaction in this species is outer membrane exchange (OME), a behaviour of unknown primary benefit in which cells displaying closely related variants of the outer membrane protein TraA transiently fuse and exchange membrane contents. Functionally incompatible TraA variants do not mediate OME, which led to the proposal that TraA incompatibilities determine patterns of intercellular cooperation in nature, but how this might occur remains unclear. Using natural isolates from a centimetre‐scale patch of soil, we analyse patterns of TraA diversity and ask whether relatedness at TraA is causally related to patterns of kin discrimination in the form of both colony‐merger incompatibilities (CMIs) and interstrain antagonisms. A large proportion of TraA functional diversity documented among global isolates is predicted to be contained within this cm‐scale population. We find evidence of balancing selection on the highly variable PA14‐portion of TraA and extensive transfer of traA alleles across genomic backgrounds. CMIs are shown to be common among strains identical at TraA, suggesting that CMIs are not generally caused by TraA dissimilarity. Finally, it has been proposed that interstrain antagonisms might be caused by OME‐mediated toxin transfer. However, we predict that most strain pairs previously shown to exhibit strong antagonisms are incapable of OME due to TraA dissimilarity. Overall, our results suggest that most documented patterns of kin discrimination in a natural population of M. xanthus are not causally related to the TraA sequences of interactants.     

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.     

Contribution of pilA to Competitive Colonization of the Squid Euprymna scolopes by Vibrio fischeri

Vibrio fischeri colonizes the squid Euprymna scolopes in a mutualistic symbiosis. Hatchling squid lack these bacterial symbionts, and V. fischeri strains must compete to occupy this privileged niche. We cloned a V. fischeri gene, designated pilA, that contributes to colonization competitiveness and encodes a protein similar to type IV-A pilins. Unlike its closest known relatives, Vibrio cholerae mshA and vcfA, pilA is monocistronic and not clustered with genes associated with pilin export or assembly. Using wild-type strain ES114 as the parent, we generated an in-frame pilA deletion mutant, as well as pilA mutants marked with a kanamycin resistance gene. In mixed inocula, marked mutants were repeatedly outcompeted by ES114 (P < 0.05) but not by an unmarked pilA mutant, for squid colonization. In contrast, the ratio of mutant to ES114 CFUs did not change during 70 generations of coculturing. The competitive defect of pilA mutants ranged from 1.7- to 10-fold and was more pronounced when inocula were within the range estimated for V. fischeri populations in Hawaiian seawater (200 to 2,000 cells/ml) than when higher densities were used. ES114 also outcompeted a pilA mutant by an average of twofold at lower inoculum densities, when only a fraction of the squid became infected, most by only one strain. V. fischeri strain ET101, which was isolated from Euprymna tasmanica and is outcompeted by ES114, lacks pilA; however, 11 other diverse V. fischeri isolates apparently possess pilA. The competitive defect of pilA mutants suggests that cell surface molecules may play important roles in the initiation of beneficial symbioses in which animals must acquire symbionts from a mixed community of environmental bacteria.     

Spatial Variation in <Emphasis Type="Italic">Streptomyces</Emphasis> Genetic Composition and Diversity in a Prairie Soil

Understanding how microbial genotypes are arrayed in space is crucial for identifying local factors that may influence the spatial distribution of genetic diversity. In this study we investigated variation in 16S rDNA sequences and rep-PCR fingerprints of Streptomyces stains isolated from prairie soil among three locations and four soil depths. Substantial variation in Streptomyces OTU (operational taxonomic unit) and BOX-PCR fingerprint diversity was found among locations within a limited spatial area (1 m²). Further, phylogenetic lineages at each location were distinct. However, there was little variation in genetic diversity among isolates from different soil depths and similar phylogenetic lineages were found at each depth. Some clones were found at a localized scale while other clones had a relatively widespread distribution. There was poor correspondence between 16S rDNA groupings and rep-PCR fingerprint groupings. The finding of distinct phylogenetic lineages and the variation in spatial distribution of clones suggests that selection pressures may vary over the soil landscape.     

The biogeography of kin discrimination across microbial neighbourhoods

The spatial distribution of potential interactants is critical to social evolution in all cooperative organisms. Yet the biogeography of microbial kin discrimination at the scales most relevant to social interactions is poorly understood. Here we resolve the microbiogeography of social identity and genetic relatedness in local populations of the model cooperative bacterium Myxococcus xanthus at small spatial scales, across which the potential for dispersal is high. Using two criteria of relatedness—colony‐merger compatibility during cooperative motility and DNA‐sequence similarity at highly polymorphic loci—we find that relatedness decreases greatly with spatial distance even across the smallest scale transition. Both social relatedness and genetic relatedness are maximal within individual fruiting bodies at the micrometre scale but are much lower already across adjacent fruiting bodies at the millimetre scale. Genetic relatedness was found to be yet lower among centimetre‐scale samples, whereas social allotype relatedness decreased further only at the metre scale, at and beyond which the probability of social or genetic identity among randomly sampled isolates is effectively zero. Thus, in M. xanthus, high‐relatedness patches form a rich mosaic of diverse social allotypes across fruiting body neighbourhoods at the millimetre scale and beyond. Individuals that migrate even short distances across adjacent groups will frequently encounter allotypic conspecifics and territorial kin discrimination may profoundly influence the spatial dynamics of local migration. Finally, we also found that the phylogenetic scope of intraspecific biogeographic analysis can affect the detection of spatial structure, as some patterns evident in clade‐specific analysis were masked by simultaneous analysis of all strains.     

Type IV Pilus Proteins Form an Integrated Structure Extending from the Cytoplasm to the Outer Membrane

The bacterial type IV pilus (T4P) is the strongest biological motor known to date as its retraction can generate forces well over 100 pN. Myxococcus xanthus, a δ-proteobacterium, provides a good model for T4P investigations because its social (S) gliding motility is powered by T4P. In this study, the interactions among M. xanthus T4P proteins were investigated using genetics and the yeast two-hybrid (Y2H) system. Our genetic analysis suggests that there is an integrated T4P structure that crosses the inner membrane (IM), periplasm and the outer membrane (OM). Moreover, this structure exists in the absence of the pilus filament. A systematic Y2H survey provided evidence for direct interactions among IM and OM proteins exposed to the periplasm. For example, the IM lipoprotein PilP interacted with its cognate OM protein PilQ. In addition, interactions among T4P proteins from the thermophile Thermus thermophilus were investigated by Y2H. The results indicated similar protein-protein interactions in the T4P system of this non-proteobacterium despite significant sequence divergence between T4P proteins in T. thermophilus and M. xanthus. The observations here support the model of an integrated T4P structure in the absence of a pilus in diverse bacterial species.     

Genome evolution and the emergence of fruiting body development in Myxococcus xanthus

Background

Lateral gene transfer (LGT) is thought to promote speciation in bacteria, though well-defined examples have not been put forward.

Methodology/Principle Findings

We examined the evolutionary history of the genes essential for a trait that defines a phylogenetic order, namely fruiting body development of the Myxococcales. Seventy-eight genes that are essential for Myxococcus xanthus development were examined for LGT. About 73% of the genes exhibit a phylogeny similar to that of the 16S rDNA gene and a codon bias consistent with other M. xanthus genes suggesting vertical transmission. About 22% have an altered codon bias and/or phylogeny suggestive of LGT. The remaining 5% are unique. Genes encoding signal production and sensory transduction were more likely to be transmitted vertically with clear examples of duplication and divergence into multigene families. Genes encoding metabolic enzymes were frequently acquired by LGT. Myxobacteria exhibit aerobic respiration unlike most of the δ Proteobacteria. M. xanthus contains a unique electron transport pathway shaped by LGT of genes for succinate dehydrogenase and three cytochrome oxidase complexes.

Conclusions/Significance

Fruiting body development depends on genes acquired by LGT, particularly those involved in polysaccharide production. We suggest that aerobic growth fostered innovation necessary for development by allowing myxobacteria access to a different gene pool from anaerobic members of the δ Proteobacteria. Habitat destruction and loss of species diversity could restrict the evolution of new bacterial groups by limiting the size of the prospective gene pool.     

Heterologous Expression of the Oxytetracycline Biosynthetic Pathway in Myxococcus xanthus

New natural products for drug discovery may be accessed by heterologous expression of bacterial biosynthetic pathways in metagenomic DNA libraries. However, a “universal” host is needed for this experiment. Herein, we show that Myxococcus xanthus is a potential “universal” host for heterologous expression of polyketide biosynthetic gene clusters.Bacterial natural products are excellent lead compounds for drug discovery and have played major roles in the development of pharmaceutical agents in nearly all therapeutic areas (1, 7, 9). Unfortunately, the rate of discovery of new bacterial natural products has decreased, due in part to frequent rediscovery of known compounds (7). An enormous and currently inaccessible reservoir of new natural products is located in the biosynthetic pathways found in the genomes of uncultivated bacteria (18). Heterologous expression of these biosynthetic gene clusters represents a powerful tool for discovering new natural products (20, 21). Herein, we demonstrate that the deltaproteobacterium Myxococcus xanthus is an effective host for heterologous expression of aromatic polyketide biosynthetic pathways. This work expands the scope of polyketide biosynthetic pathways which can be heterologously expressed in M. xanthus and suggests that M. xanthus may be a suitable general host for heterologous expression.Molecular phylogenetic studies have shown that bacterial diversity is enormous, and the vast majority of the diversity is found in uncultivated bacterial species (18). Estimates suggest that 99% of bacteria from the environment are uncultivatable using standard techniques (2, 15, 16). Culture-independent analyses of metagenomic DNA libraries from soil and marine environments indicate that there is a wealth of natural product diversity in these uncultivated strains. For example, analysis of a soil metagenome for a highly conserved region of polyketide synthase genes showed that none of the sequences found were present in the known public databases (5). Polyketide synthases are key enzymes responsible for the production of the polyketide family of natural products in proteobacteria, actinobacteria, and “low-G+C Gram-positive bacteria” (4, 12, 19). Polyketide natural products have been developed into antibiotic, anticancer, and immunosuppressant clinical agents (1, 6, 8). Based on these observations, metagenomic DNA libraries are expected to possess a large number of new polyketide biosynthetic pathways, representing substantial new chemical diversity for drug discovery.Heterologous expression of biosynthetic pathways can play a major role in interrogating metagenomic DNA libraries for new polyketide biosynthetic pathways. Heterologous production of polyketides in hosts such as Streptomyces coelicolor and Streptomyces lividans is an important tool in the identification and characterization of these pathways (6, 8, 17). Results from these studies have shown that Streptomyces strains are good hosts for heterologous production of many polyketides, particularly those from actinomycetes. However, Streptomyces strains have proved to be poor hosts for expression of deltaproteobacterial polyketide biosynthetic pathways, such as those in myxobacteria (10, 17). As polyketide biosynthetic pathways in metagenomic DNA libraries contain both actinomycete- and deltaproteobacterium-derived pathways, a heterologous expression host competent to express pathways of both origins is needed.We examined the ability of the deltaproteobacterium M. xanthus to act as a general heterologous expression host. M. xanthus is a predatory bacterium that undergoes multicellular development in response to nutrient starvation. During development, M. xanthus is known to be an effective host for the heterologous expression of the deltaproteobacterium-derived epothilone D biosynthetic pathway and has been used for the production of epothilone D for clinical trials (17). M. xanthus has also been shown to be an excellent host for the heterologous expression of several other myxobacterial metabolites, including myxothiazol and myxochromide S (3, 11, 22). We demonstrate that M. xanthus can also heterologously express the Streptomyces rimosus oxytetracycline biosynthetic pathway, producing oxytetracycline. This is the first example of a polyketide from a nonmyxobacterial species heterologously expressed in a myxobacterium.To generate an M. xanthus strain capable of heterologously expressing oxytetracycline, the Streptomyces rimosus oxytetracycline biosynthetic pathway (Fig. ​(Fig.1)1) was inserted via homologous recombination into the asgE locus of M. xanthus. The asgE locus of M. xanthus was amplified and inserted into the BglII site of pET28b (Novagen) to produce pMRH02. The oligonucleotides used for the amplification of the asgE locus were 5′-GACGAGATCTGTTGGAAGGTCGGCAACTGG-3′ and 5′-CTTAAGATCTTCCGTGAAGTACTGGCGCAC-3′. The asgE locus provides a chromosomal region for single-crossover homologous recombination into the M. xanthus chromosome. The 32-kb oxytetracycline pathway in S. rimosus was excised from pYT264 (24) and cloned into the EcoRI site of pMRH02 to produce pMRH08. M. xanthus DK1622 was electroporated under standard conditions (13) with pMRH08 to provide an M. xanthus ΔasgE Kan^r mutant. Positive selection for the chromosomal insertion was maintained throughout all experiments by use of kanamycin supplementation (40 μg/ml). This large genomic insertion significantly increased the doubling time for the strain (doubling time, ≈10 h).Open in a separate windowFIG. 1.Oxytetracycline biosynthetic pathway. (A) Enzymatic pathway responsible for formation of oxytetracycline. (B) Oxytetracycline biosynthesis gene cluster from S. rimosus.Oxytetracycline was heterologously produced in M. xanthus under standard rich medium culture conditions and detected in culture broth by liquid chromatography-mass spectrometry (LC-MS). A liquid culture of the mutant strain containing the oxytetracycline gene cluster was cultured for 10 days at 33°C in CTTYE (1.0% Casitone, 0.5% yeast extract, 10.0 mM Tris-HCl, 1.0 mM KH₂PO₄, and 8.0 mM MgSO₄; 100 ml). Acetone (10%, vol/vol) was added to the culture and vigorously mixed. The resulting mixture was extracted with 3 volumes of ethyl acetate to remove the organic soluble materials, including oxytetracycline. The organic extracts were concentrated in vacuo and resuspended in methanol (100 μl). LC-MS analyses were carried out using an Altima Hypersil C₁₈ column (3-μm particle size; 150 mm by 2.1 mm) with a linear gradient of water-acetonitrile (5 to 95%) with 0.05% formic acid over 90 min (0.20 ml/min), followed by positive-ion electrospray ionization (5,500 V) and analysis with a Shimadzu 2010A single quadrupole mass spectrometer. LC-MS analysis indicated that oxytetracycline was present in the fermentation broth (Fig. ​(Fig.2).2). The titer of oxytetracycline was determined to be approximately 10 mg per liter of fermentation broth. Quantification was performed in triplicate by LC-MS analysis using a standard curve generated from commercial oxytetracycline. Negative controls of M. xanthus DK1622 cultures processed under identical conditions did not contain detectable levels of oxytetracycline.Open in a separate windowFIG. 2.LC-MS ion extraction analysis of the molecular ion [M+H]⁺ of standard and culture extracts. (A) Oxytetracycline standard. (B) M. xanthus ΔasgE Kan^r mutant containing the oxytetracycline biosynthetic pathway. (C) Wild-type M. xanthus DK1622.These data indicate that M. xanthus can heterologously express the oxytetracycline polyketide synthase biosynthetic pathway in S. rimosus. Several factors affect the successful heterologous production of polyketide synthase pathways, including codon usage, mRNA stability, functionality of regulatory elements, and the presence of all necessary starter and extender units (14). As codon usages between M. xanthus and the genus Streptomyces are very similar and myxobacteria are known to produce polyketide products requiring a wide diversity of starter and extender units, neither codon usage nor starter and extender unit availability was considered likely to affect the ability of M. xanthus to heterologously express streptomycete biosynthetic pathways. As Streptomyces strains do not appear to be effective at heterologous expression of myxobacterial biosynthetic pathways, we were concerned that Myxococcus and Streptomyces strains may possess substantially different regulatory elements. Our data indicate that the regulatory elements present in streptomycete-derived biosynthetic pathways are sufficient to enable expression of the biosynthetic genes in M. xanthus. Further work exploring the regulatory elements present in myxobacterial polyketide biosynthetic gene clusters is needed to evaluate this hypothesis.This study demonstrates that M. xanthus can heterologously express streptomycete-derived polyketide biosynthetic pathways in addition to myxobacterial polyketide biosynthetic pathways. The observed titer of 10 mg/liter of culture broth is comparable to titers reported for the heterologous expression of myxobacterial polyketide biosynthetic pathways in myxobacteria (11) and streptomycete-derived polyketide biosynthetic pathways in Streptomyces (14, 23) and is sufficient for characterization of the polyketide product. Pseudomonas putida, which has a more favorable growth profile, has been shown to be a good host for heterologous expression of myxobacterial polyketide biosynthetic pathways, with product titers in the range of 0.6 to 40 mg/liter of culture broth (14, 21, 23). The observed breadth of polyketide pathways accessible and the titers of the polyketide products produced make M. xanthus an attractive potential candidate for a “universal” host for facilitating heterologous expression of polyketide biosynthetic pathways derived from environmental samples of metagenomic DNA.     

Grassland Management Regimens Reduce Small-Scale Heterogeneity and Species Diversity of β-Proteobacterial Ammonia Oxidizer Populations

The impact of soil management practices on ammonia oxidizer diversity and spatial heterogeneity was determined in improved (addition of N fertilizer), unimproved (no additions), and semi-improved (intermediate management) grassland pastures at the Sourhope Research Station in Scotland. Ammonia oxidizer diversity within each grassland soil was assessed by PCR amplification of microbial community DNA with both ammonia oxidizer-specific, 16S rRNA gene (rDNA) and functional, amoA, gene primers. PCR products were analysed by denaturing gradient gel electrophoresis, phylogenetic analysis of partial 16S rDNA and amoA sequences, and hybridization with ammonia oxidizer-specific oligonucleotide probes. Ammonia oxidizer populations in unimproved soils were more diverse than those in improved soils and were dominated by organisms representing Nitrosospira clusters 1 and 3 and Nitrosomonas cluster 7 (closely related phylogenetically to Nitrosomonas europaea). Improved soils were only dominated by Nitrosospira cluster 3 and Nitrosomonas cluster 7. These differences were also reflected in functional gene (amoA) diversity, with amoA gene sequences of both Nitrosomonas and Nitrosospira species detected. Replicate 0.5-g samples of unimproved soil demonstrated significant spatial heterogeneity in 16S rDNA-defined ammonia oxidizer clusters, which was reflected in heterogeneity in ammonium concentration and pH. Heterogeneity in soil characteristics and ammonia oxidizer diversity were lower in improved soils. The results therefore demonstrate significant effects of soil management on diversity and heterogeneity of ammonia oxidizer populations that are related to similar changes in relevant soil characteristics.