The quorum-sensing system in a plant bacterium Mesorhizobium huakuii affects growth rate and symbiotic nodulation

Mesorhizobium huakuii is a free-living bacterium which is capable of establishing a specific symbiotic relationship with Astragalus sinicus, an important winter green manure widely used in Eastern Asia, allowing for nitrogen fixing during this process. Previous studies demonstrate that M.␣huakuii produces quorum-sensing molecules at high cell density and quorum sensing plays a role in biofilm formations. In this study, we isolated and characterized two quorum-sensing deficient mutants in M. huakuii. Analysis of the flanking region of transposon insertions indicated that autoinducer synthase related genes are not homologous to acyl homoserine lactone (AHL) synthase genes that are shared among many Gram-negative bacteria, but related to peptide synthesis, indicating that M. huakuii quorum-sensing signals are distinct from AHLs. Compared with the wild-type strains, these quorum-sensing deficient mutants promoted their growth rate and were defective in nodule formation on host plants, indicative of a critical role of quorum sensing in M.␣huakuii during the host–bacterium symbiotic interaction.Yijing Gao and Zengtao Zhong contributed equally to this work.     

Exopolysaccharide biosynthesis is important for <Emphasis Type="Italic">Mesorhizobium tianshanense</Emphasis>: plant host interaction

Mesorhizobium tianshanense is a nitrogen-fixing bacterium that can establish symbiotic associations with Glycyrrhiza uralensis in the form of root nodules. Nodule formation in rhizobia often requires various secreted carbohydrates. To investigate exopolysaccharide (EPS) production and function in M. tianshanense, we performed a genome-wide screen using transposon mutagenesis to identify genes involved in EPS production. We identified seven mutants that produced significantly lower amounts of EPS as well as a two-component sensor kinase/response regulator system that is involved in the activation of EPS synthesis. EPS mutants formed significantly less biofilm and displayed severely reduced nodulation capacity than wild type bacteria, suggesting that EPS synthesis can play important roles in the symbiosis process. Peng Wang, Zengtao Zhong and Jing Zhou have contributed equally to this work.     

Biodiversity of populations of phosphate solubilizing rhizobia that nodulates chickpea in different Spanish soils

Within rhizobia, two species nodulating chickpea, Mesorhizobium ciceri and Mesorhizobium mediterraneum, are known as good phosphate solubilizers. For this reason, we have analysed the ability to solubilize phosphate of a wide number of strains isolated from Cicer arietinum growing in several soils in Spain. The aim of this work was to analyse microbial populations nodulating chickpea, that are able to solubilize phosphates, using molecular techniques. In the present work we analyzed 19 strains isolated from effective nodules of C. arietinum growing in three soils from the North of Spain. Nineteen strains showed ability to solubilize phosphate in YED-P medium. These strains were separated into 4 groups according to the results obtained by 879F-RAPD fingerprinting. The 16S rDNA sequencing of a representative strain from each group allowed the identification of strains as belonging to the genus Mesorhizobium. Strains from groups I and II showed a 99.4% and 99.2% similarity with M. mediterraneum UPM-CA142^T, respectively. The strains from group III were related to M. tianshanense USDA 3592^T at a 99.4% similarity level. Finally, the strain from group IV was related to M. ciceri USDA 3383^T with a 99.3% similarity. The LMW RNA profiles confirmed these results. Strains from groups I and II showed an identical LMW RNA profile to that of M. mediterraneum UPM-CA142^T; the profile of strains from group III was identical to that of M.␣tianshanense USDA 3592^T and the profile of strains from group IV was identical to that of M. ciceri USDA 3383^T. Different 879F-RAPD patterns were obtained for strains of the group I, group II and the M.␣mediterraneum type strain (UPM-CA142^T). The 879-RAPD patterns obtained for group III also differed from the pattern shown by M. tianshanense USDA 3592^T. Finally, the patterns between group IV and M. ciceri USDA 3383^T were also different. These results suggest that groups I and II may be subspecies of M. mediterraneum, group III a subspecies of M. tianshanense and group IV a subspecies of M. ciceri. Nevertheless, more studies are needed to establish the taxonomic status of strains isolated in this study.     

Heterologous overexpression of quorum-sensing regulators to study cell-density-dependent phenotypes in a symbiotic plant bacterium <Emphasis Type="Italic">Mesorhizobium huakuii</Emphasis>

Quorum-sensing is widespread among many prokaryotic lineages. In order to investigate quorum regulation in the plant bacterium Mesorhizobium huakuii which produces an N-acyl homoserine lactone (AHL) quorum signal, the Agrobacterium quorum-sensing regulator TraR was heterologously expressed in this bacterium. The resulting strains showed reduced AHL production in the supernatant compared to wild-type, but similar intracellular levels of AHLs were detected, suggesting that M. huakuii AHLs can be bound to intracellular TraR proteins and thus become unavailable for its own quorum systems. M. huakuii overexpressing TraR formed thinner biofilms than the wild-type, suggesting a role played by quorum-sensing in biofilm formation.Hui Wang and Zengtao Zhong contributed equally to this work.     

Quorum-sensing in Rhizobium

Quorum-sensing signals are found in many species of legume-nodulating rhizobia. In a well-characterized strain of R. leguminosarum biovar viciae, a variety of autoinducers are synthesised, and all have been identified as N-acyl-homoserine lactones. One of these N-acyl-homoserine lactones, is N-(3-hydroxy-7-cis-tetradecenoyl)-L-homoserine lactone, previously known as small bacteriocin, which inhibits the growth of several R. leguminosarum strains. The cinRI locus is responsible for the production of small bacteriocin. CinR induces cinI in response to the AHL made by CinI, thus forming a positive autoregulatory induction loop. A complex cascade of quorum-sensing loops was characterized, in which the cinIR locus appears to be the master control for three other AHL-dependent quorum-sensing control systems. These systems include the raiI/raiR, traI/triR and rhiI/rhiR. Other rhizobial strains appear to share some of these quorum sensing loci, but not all loci are found in all strains. Small bacteriocin along with the other N-acyl-homoserine lactones produced by these three AHL-based control systems regulate (i) growth inhibition of sensitive strains, (ii) transfer of the symbiotic plasmid pRL1JI, and (iii) expression of the rhizosphere-expressed (rhi) genes that influence nodulation. Some of the genes regulated by these systems have been identified. While the functions of some, such as the trb operon regulated by triR are clear, several of the regulated genes have no homologues of known function. It is anticipated that several other genes regulated by these systems have yet to be identified. Therefore, despite the regulation of one of the most complex quorum-sensing cascade being understood, several of the functions regulated by the quorum-sensing genes remain to be elucidated. This revised version was published online in August 2006 with corrections to the Cover Date.     

Nodule Symbiosis of Invasive <Emphasis Type="Italic">Mimosa pigra</Emphasis> in Australia and in Ancestral Habitats: A Comparative Analysis

Ninety isolates of root nodule bacteria from an invasive Mimosa pigra population in Australia were characterized by PCR assays and by sequencing of ribosomal genes. All isolates belonged to the same bacterial genus (Burkholderia) that predominates on M. pigra in its native geographic range in tropical America. However, the Australian Burkholderia strains represented several divergent lineages, none of which had a close relationship to currently known Burkholderia strains in American M. pigra populations. Inoculation of M. pigra with Australian strains resulted in equal or higher plant growth and nodule nitrogenase activity (measured by acetylene reduction assays) relative to outcomes with bacteria from M. pigra’s native geographic region. The main difference in symbiotic phenotype for bacteria from the two regions involved responses to an alternate Mimosa host species: Central American strains failed to fix nitrogen in association with Mimosa pudica, while most Australian Burkholderia isolates tested had high nodule nitrogenase activity in association with both Mimosa species. Invasive M. pigra populations in Australia have therefore acquired a diverse assemblage of nodule bacteria that are effective nitrogen-fixing symbionts, despite having a broader host range and a distant genetic relationship to bacterial strains found in the plant’s ancestral region.     

Diversity of DNA methylation pattern and total DNA restriction pattern in symbiotic Nostoc

Attempts were made to use total DNA restriction patterns and the response of purified DNA to treatment with restriction endonucleases to characterize several symbiotic Nostoc strains which had been isolated from different host plants cultivated in Italy. Among 27 restriction endonucleases tested, several did not cut any DNA and no significant variation in the susceptibility of the genomes to DNA restriction was seen among the strains. Therefore the Nostoc strains could not be separated into groups based on their different susceptibilities to the action of restriction endonucleases. However, in studies of total DNA restriction patterns, the restriction endonucleases BfrI and HpaI gave unique band patterns for each cyanobacterial isolate. Different profiles were even found in strains isolated from host plants belonging to the same species. The results do not support any definition of symbiotic Nostoc genomic groups or species and show that a tight specificity between the host plant and the cyanobacterium might not exist in the symbiotic associations involving Nostoc.     

Chemical identification of<Emphasis Type="Italic"> N</Emphasis>-acyl homoserine lactone quorum-sensing signals produced by<Emphasis Type="Italic"> Sinorhizobium meliloti</Emphasis> strains in defined medium

The N-acyl homoserine lactone (AHL) quorum-sensing signals produced by Sinorhizobium meliloti strains AK631 and 1021 when cultured in a defined glucose-nitrate medium were identified by gas chromatography/mass spectrometry (GC/MS) and electrospray ionization tandem mass spectrometry (ESI MS/MS). Both strains synthesized several long-chain AHLs. Defined medium cultures of strain AK631 synthesized a complex mixture of AHLs with short acyl side chains. Strain 1021 produced no short-chain AHLs when grown on defined medium and made a somewhat different set of long-chain AHLs than previously reported for cultures in rich medium. While the two strains produced several AHLs in common, the differences in AHLs produced suggest that there may be significant differences in their patterns of quorum-sensing regulation.     

Phylogeny of symbiotic cyanobacteria within the genus <Emphasis Type="Italic">Nostoc</Emphasis> based on 16S rDNA sequence analyses

A phylogenetic analysis of selected symbiotic Nostoc strain sequences and available database 16S rDNA sequences of both symbiotic and free-living cyanobacteria was carried out using maximum likelihood and Bayesian inference techniques. Most of the symbiotic strains fell into well separated clades. One clade consisted of a mixture of symbiotic and free-living isolates. This clade includes Nostoc sp. strain PCC 73102, the reference strain proposed for Nostoc punctiforme. A separate symbiotic clade with isolates exclusively from Gunnera species was also obtained, suggesting that not all symbiotic Nostoc species can be assigned to N. punctiforme. Moreover, isolates from Azolla filiculoides and one from Gunnera dentata were well nested within a clade comprising most of the Anabaena sequences. This result supports the affiliation of the Azolla isolates with the genus Anabaena and shows that strains within this genus can form symbioses with additional hosts. Furthermore, these symbiotic strains produced hormogonia, thereby verifying that hormogonia formation is not absent in Anabaena and cannot be used as a criterion to distinguish it from Nostoc.The GenBank accession numbers for the cyanobacterial 16S rRNA gene sequences determined in this study are AY742447-AY742454.     

Analysis of N-acyl homoserine-lactone quorum-sensing molecules made by different strains and biovars of Rhizobium leguminosarum containing different symbiotic plasmids

Strains of Rhizobium leguminosarum use a cell density-dependent gene regulatory system to assess their population density. This is achieved by the accumulation of N-acyl-homoserine lactones (AHLs) in the environment during growth of the bacteria and these AHLs stimulate the induction of various bacterial genes that are up-regulated in the late-exponential and stationary phases of growth. A genetically well-characterised strain of R. leguminosarum biovar viciae was found to have four genes, whose products synthesise different AHLs. We have analysed AHL production by four genetically distinct isolates of R. leguminosarum, three of bv. viciae and one of bv. phaseoli. Distinct differences were seen in the pattern of AHLs produced by the bv. viciae strains compared with bv. phaseoli and the increased levels and diversity of AHLs found in bv. viciae strains can be attributed to the rhiI gene, which is located on the symbiotic (Sym) plasmid and is up-regulated when the bacteria are grown in the rhizosphere. Additional complexity to the profile of AHLs is found to be associated with highly transmissible plasmid pRL1JI of R. leguminosarum bv. viciae, but this is not observed with some other strains, including those carrying different transmissible plasmids. In addition to AHLs produced by the products of genes on the symbiotic plasmid, there is clear evidence for the presence of other AHL production loci. Expression levels and patterns of AHLs can change markedly in different growth media. These results indicate that there is a network of quorum-sensing loci in different strains of R. leguminosarum and these loci may play a role in adapting to rhizosphere growth and plasmid transfer.     

The analysis of core and symbiotic genes of rhizobia nodulating Vicia from different continents reveals their common phylogenetic origin and suggests the distribution of Rhizobium leguminosarum strains together with Vicia seeds

In this work, we analysed the core and symbiotic genes of rhizobial strains isolated from Vicia sativa in three soils from the Northwest of Spain, and compared them with other Vicia endosymbionts isolated in other geographical locations. The analysis of rrs, recA and atpD genes and 16S–23S rRNA intergenic spacer showed that the Spanish strains nodulating V. sativa are phylogenetically close to those isolated from V. sativa and V. faba in different European, American and Asian countries forming a group related to Rhizobium leguminosarum. The analysis of the nodC gene of strains nodulating V. sativa and V. faba in different continents showed they belong to a phylogenetically compact group indicating that these legumes are restrictive hosts. The results of the nodC gene analysis allow the delineation of the biovar viciae showing a common phylogenetic origin of V. sativa and V. faba endosymbionts in several continents. Since these two legume species are indigenous from Europe, our results suggest a world distribution of strains from R. leguminosarum together with the V. sativa and V. faba seeds and a close coevolution among chromosome, symbiotic genes and legume host in this Rhizobium–Vicia symbiosis.     

Molecular analysis of actinorhizal symbiotic systems: Progress to date

The application of molecular tools to questions related to the genetics, ecology and evolution of actinorhizal symbiotic systems has been especially fruitful during the past two years. Host plant phylogenies based on molecular data have revealed markedly different relationships among host plants than have previously been suspected and have contributed to the development of new hypotheses on the origin and evolution of actinorhizal symbiotic systems. Molecular analyses of host plant gene expression in developing nodules have confirmed the occurrence of nodulin proteins and in situ hybridization techniques have been successfully adapted to permit the study of the spatial and temporal patterns of gene expression within actinorhizal nodules. The use of heterologous probes in combination with nucleotide sequence analysis have allowed a number of nif genes to be mapped on the Frankia chromosome which will ultimately contribute to the development of hypotheses related to nif gene regulation in Frankia. The use of both 16S and 23S rDNA nucleotide sequences has allowed the construction of phylogenetic trees that can be tested for congruence with symbiotic characters. In addition the development of Frankia-specific gene probes and amplification primers have contributed to studies on the genetic diversity and distribution of Frankia in the soil.     

Temperature influences the expression of fimbriae and flagella in <Emphasis Type="Italic">Hafnia alvei</Emphasis> strains: an immunofluorescence study

Hafnia alvei, a Gram negative bacillus related to the Enterobacteriaceae family, is considered an opportunistic pathogen of several animal species and humans. In this communication, we describe fimbrial-like structures from different strains of H. alvei that cannot be easily ascribed to any of the previously reported fimbrial types in this species (type I or type III). Polymerase chain reaction (PCR) and immunofluorescence assays were carried out to study fimbriae and flagella in H. alvei strains isolated from different sources. No correlation between the results obtained by PCR and those obtained by phenotypic methods were found, and the antibodies used gave cross or different recognition patterns of the surface structures present in these strains. We report as well that strain and growth temperature influence fimbriation and expression of flagella in human and animal isolates of H. alvei. This study also indicates that the absence of fimbriae have a significant positive influence on the initial adhesion of H. alvei to human epithelial cells.     

The Symbiotic Requirements of Different Medicago Spp. Suggest the Evolution of Sinorhizobium Meliloti and S. Medicae with Hosts Differentially Adapted to Soil pH

Nitrogen fixing rhizobia associated with the Medicago L. genus belong to two closely related species Sinorhizobium medicae and S. meliloti. To investigate the symbiotic requirements of different Medicago species for the two microsymbionts, 39 bacterial isolates from nodules of eleven Medicago species growing in their natural habitats in the Mediterranean basin plus six historical Australian commercial inocula were symbiotically characterized with Medicago hosts. The bacterial species allocation was first assigned on the basis of symbiotic proficiency with M. polymorpha. PCR primers specific for 16S rDNA were then designed to distinguish S. medicae and S. meliloti. PCR amplification results confirmed the species allocation acquired in the glasshouse. PCR fingerprints generated from ERIC, BOXA1R and nif-directed RPO1 primers revealed that the Mediterranean strains were genetically heterogenous. Moreover PCR fingerprints with ERIC and BOX primers showed that these repetitive DNA elements were specifically distributed and conserved in S. meliloti and S. medicae, clustering the strains into two divergent groups according to their species. Linking the Sinorhizobium species with the plant species of origin we have found that S. medicae was mostly associated with medics well adapted to moderately acid soils such as M. polymorpha, M. arabica and M. murex whereas S. meliloti was predominantly isolated from plants naturally growing on alkaline or neutral pH soils such as M. littoralis and M. tornata. Moreover in glasshouse experiments the S. medicae strains were able to induce well-developed nodules on M. murex whilst S. meliloti was not infective on this species. This feature provides a very distinguishing characteristic for S. medicae. Results from the symbiotic, genotypic and cultural characterization suggest that S. meliloti and S. medicae have adapted to different Medicago species according to the niches these medics usually occupy in their natural habitats.     

果蝇肠道共生菌对宿主作用的研究进展

肠道共生菌是动物体内的重要组成部分,在宿主的生长发育和健康等方面发挥着重要作用,近年来已成为国内外的研究热点.果蝇作为研究肠道微生物菌群功能的优秀模型,在肠道共生菌与宿主关系研究方面已取得许多重要进展.在本文中,我们首先对果蝇肠道微生物的组成和特征作了总结,然后对果蝇肠道共生菌在其生长发育、营养与代谢、行为反应、寿命以...     

Specificity grouping of the accessory gene regulator quorum-sensing system of<Emphasis Type="Italic"> Staphylococcus epidermidis</Emphasis> is linked to infection

Staphylococcus epidermidis represents the most frequent pathogen involved in nosocomial infections and infections of indwelling medical devices. The strain-to-strain variation of the gene encoding the quorum-sensing pheromone of S. epidermidis as well as the correlation between specificity groups and origin from infection were determined. The pro-pheromone gene was highly conserved and showed infrequent, non-synonymous, single-nucleotide polymorphisms that led to conservative amino acid exchanges only. Importantly, one specificity group was significantly more frequent among strains isolated from infection. The finding that quorum-sensing specificity groups are linked to infection demonstrates the relevance of quorum-sensing for virulence in this critical human pathogen and contributes to the scientific basis needed for the development of quorum-sensing-targeting drugs.     

Rhizobium strains expressing uptake hydrogenase in different host species of cowpea miscellany

Uptake hydrogenase activity in nodules of green gram (Vigna radiata (L.) (Wilczek)), black gram (Vigna mungo (L.) (Hepper)), cowpea (Vigna unguiculata (L.) and cluster bean (Cyamopsis tetragonoloba (L.) (Taub.)), formed with two Hup⁺ (S24 and CT2014) and one Hup⁻ (M11)Rhizobium strains, was determined at different levels of external H2 in air atmosphere. Nodules of all the 4 host species formed by inoculation with strains S24 and CT2014, showed H2 uptake but not those formed with strain M11. H₂ uptake rates were higher in 1 and 2% H₂ in air atmosphere (v/v) than at 5 or 10% levels in all the host species. Variations in the relative rates of H₂ uptake were observed both, due to host species as well as due toRhizobium strains. However, no host dependent complete repression of the expression of H₂ uptake activity was observed in nodules of any of the host species formed with Hup⁺ strains.     

Numerical Analysis of Astragalus cicer Microsymbionts

Thirty-seven rhizobium strains, isolated from root nodules of Astragalus cicer (L.) (cicer milkvetch) deriving from different geographic regions, were compared with the representative strains of the known rhizobial species and genera by numerical analysis of phenotypic characteristics. Our results indicated that Astragalus cicer rhizobia were related to the bacteria of Mesorhizobium species and formed two major phena. One phenon, localized on Mesorhizobium loti branch, contained strains from Poland. Another cluster, placed in the vicinity of M. tianshanense, M. mediterraneum, M. ciceri, and M. huakuii, comprised cicer milkvetch nodule isolates from Canada, Ukraine, and one strain from Poland. The relationship of Astragalus cicer microsymbionts to bacteria of the Mesorhizobium species was also supported by phage typing. Received: 10 February 2000 / Accepted: 8 March 2000     

Isolation of New <Emphasis Type="Italic">Symbiodinium</Emphasis> Strains from Tridacnid Giant Clam (<Emphasis Type="Italic">Tridacna crocea</Emphasis>) and Sea Slug (<Emphasis Type="Italic">Pteraeolidia ianthina</Emphasis>) Using Culture Medium Containing Giant Clam Tissue Homogenate

Recent molecular biological studies have revealed that some photosymbiotic invertebrates dwelling in coral reefs host several genetically different dinoflagellates, Symbiodinium species, as symbionts. However, little is known about the difference in physiologic characteristics among these symbionts living in a single host, because some Symbiodinium strains are difficult to culture in vitro. To isolate some of these Symbiodinium strains, we have developed an agar culture medium plate containing antibiotics and a giant clam tissue homogenate. Using-this medium we isolated two new Symbiodinium strains from two molluscan hosts, Tridacna crocea and Pteraeolidia ianthina, each of which hosted two different Symbiodinium strains belonging to Symbiodinium C and D, respectively. The tissue homogenate was essential for the growth of Symbiodinium D. Although it was not essential for the growth of Symbiodinium C, it did stimulate the initial growth. For the isolation of some Symbiodinium strains, isolation medium containing host homogenate is effective.