Bacterial communities are key drivers of soil fertility and agriculture productivity. Understanding how soil bacterial communities change in response to different conditions is an important aspect in the development of sustainable agriculture. There is a desire to reduce the current reliance on high inputs of chemicals and fertilisers in agriculture, but limited data are available on how this might impact soil bacterial communities. This study investigated the bacterial communities in a spring barley monoculture site subjected to two different input regimes for over 12 years: a conventional chemical/fertiliser regime, and a reduced input regime. A culture independent approach was performed to compare the bacterial communities through 16S rRNA gene PCR-DGGE. PCO analysis revealed that the rhizosphere has a strong structuring effect on the bacterial community. Moreover, high inputs of agrichemicals lead to an increase of phosphorus level in the soil and a concomitant reduction of the bacterial diversity. These results may help to evaluate the environmental risks associated with agrichemical usage.
Molecules exuded by plant roots are thought to act as signals to influence the ability of microbial strains to colonize the roots and to survive in the rhizosphere. Differential bacterial responses to signals from different plant species may mediate the selection of specific rhizosphere populations. Very little, however, is known about the effects of plant exudates on patterns of bacterial gene expression. Here, we have tested the concept that plant root exudates modulate expression of bacterial genes involved in establishing microbe-plant interactions. We have examined the influence on the Pseudomonas aeruginosa PA01 transcriptome of exudates from two varieties of sugarbeet that select for genetically distinct pseudomonad populations in the rhizosphere. The response to the two exudates showed only a partial overlap; the majority of those genes with altered expression was regulated in response to only one of the two exudates. Genes with altered expression included those with functions previously implicated in microbe-plant interactions, such as aspects of metabolism, chemotaxis and type III secretion, and a subset with putative or unknown function. Use of a panel of mutants with targeted disruptions allowed us to identify previously uncharacterized genes with roles in the competitive ability of P. aeruginosa in the rhizosphere within this subset. No genes with host-specific effects were identified. Homologues of the genes identified occur in the genomes of both beneficial and pathogenic root-associated bacteria, suggesting that this strategy may help to elucidate molecular interactions that are important for biocontrol, plant growth promotion, and plant pathogenesis.Pseudomonas ͉ Rhizosphere colonization
The Pseudomonas quinolone signal (PQS), and its precursor 2-heptyl-4-quinolone (HHQ), play a key role in coordinating virulence in the important cystic fibrosis pathogen Pseudomonas aeruginosa. The discovery of HHQ analogues in Burkholderia and other microorganisms led us to investigate the possibility that these compounds can influence interspecies behaviour. We found that surface-associated phenotypes were repressed in Gram-positive and Gram-negative bacteria as well as in pathogenic yeast in response to PQS and HHQ. Motility was repressed in a broad range of bacteria, while biofilm formation in Bacillus subtilis and Candida albicans was repressed in the presence of HHQ, though initial adhesion was unaffected. Furthermore, HHQ exhibited potent bacteriostatic activity against several Gram-negative bacteria, including pathogenic Vibrio vulnificus. Structure-function analysis using synthetic analogues provided an insight into the molecular properties that underpin the ability of these compounds to influence microbial behaviour, revealing the alkyl chain to be fundamental. Defining the influence of these molecules on microbial-eukaryotic-host interactions will facilitate future therapeutic strategies which seek to combat microorganisms that are recalcitrant to conventional antimicrobial agents.
Pseudomonas aeruginosa is a gram-negative rod that is ubiquitous in nature. P. aeruginosa is also the quintessential opportunistic pathogen, causing a wide variety of infections in compromised hosts. In cystic fibrosis patients, P. aeruginosa is the leading cause of death. In this study, the evolutionary genetic relationships among 17 P. aeruginosa isolates were examined by comparative sequence analysis of the housekeeping gene encoding malate dehydrogenase and the chaperone groEL. The P. aeruginosa isolates examined included the sequenced strain PAO1, 11 strains recovered from cystic fibrosis patients in Ireland, 4 environmental isolates recovered from a hospital environment, and 1 isolate recovered from a plant rhizosphere. Phylogenetically, clinical and environmental isolates clustered together with one another on the mdh gene tree. At the groEL locus, among the 17 isolates examined, only two polymorphic sites were observed, highlighting the close genetic relationship between isolates from these different environments. Phenotypic analysis of 12 traits among our isolates, however, found that only clinical isolates produced phenazines and elastase. Furthermore, molecular analysis of the distribution of 15 regions associated with virulence showed that two of the environmental isolates examined lacked the majority of regions. Among the clinical isolates examined, the 15 virulence regions were variably present. The distribution of two prophages (Bacto1, Pf1) was also determined, with most isolates encoding both these regions. Of the four genomic islands (the flagellum island and PAGI-1, -2, and -3) examined, only two isolates contained the flagellum island, and PAGI-1, -2, and -3 were absent from all isolates tested. Our data demonstrate the significant role horizontal gene transfer and recombination, together with gene loss, play in the evolution of this important human pathogen.The remarkable ability of Pseudomonas aeruginosa to adapt and thrive in a wide variety of environments is due in part to its extensive genetic versatility, which contributes significantly to its potential as a pathogen. P. aeruginosa is an opportunistic pathogen that is a common cause of hospital-acquired infections, particularly infecting patients with predisposing factors, such as burn victims, immunocompromised hosts, or those with metabolic disorders. In cystic fibrosis (CF) patients, P. aeruginosa is believed to be a major contributory factor to chronic lung infections and is thought to form biofilms and to adhere to human mucin in the lower respiratory tract (46, 53). Once P. aeruginosa colonizes the CF patient's lung, it cannot be eradicated even by the most aggressive antibiotic therapy. It is likely that as part of colonization, invasion, and survival in the human host, P. aeruginosa utilizes a unique range of genes; however, the precise repertoire of virulence genes required is unclear.Several studies have examined the genetic diversity of P. aeruginosa isolates from CF patients (9,13,30,40,44,49). In these studies, it was deter...
Pseudomonas aeruginosa causes infections in a wide variety of hosts and is the leading cause of mortality in cystic fibrosis (CF) patients. Although most clinical isolates of P. aeruginosa share common virulence determinants, it is known that strains evolve and change phenotypically during CF lung infections. These changes can include alterations in the levels of N-acyl homoserine lactones (HSLs), which are secreted signal molecules. In the CF lung, fungi, especially Candida albicans and Aspergillus fumigatus, may coexist with P. aeruginosa but the implications for disease are not known. Recent studies have established that signalling can occur between P. aeruginosa and C. albicans, with the bacterial molecule 3-oxo-C12HSL affecting Candida morphology, and the fungal metabolite farnesol reducing levels of the Pseudomonas quinolone signal and pyocyanin in Pseudomonas. Whether these interactions are common and typical in clinical strains of P. aeruginosa was addressed using CF isolates that produced varied levels of HSLs. It was found that, whereas some clinical P. aeruginosa strains affected C. albicans morphology, others did not. This correlated closely with the amounts of 3-oxo-C12HSL produced by the isolates. Furthermore, it was established that signalling is bidirectional and that the C. albicans molecule farnesol inhibits swarming motility in P. aeruginosa CF strains. This work demonstrates that clinical isolates of these opportunistic pathogens can interact in strain-specific ways via secreted signals and illustrates the importance of studying these interactions to fully understand the microbial contribution to disease in polymicrobial infections.
Bacteria encode multiple protein secretion systems that are crucial for interaction with the environment and with hosts. In recent years, attention has focused on type VI secretion systems (T6SSs), which are specialized transporters widely encoded in Proteobacteria. The myriad of processes associated with these secretion systems could be explained by subclasses of T6SS, each involved in specialized functions. To assess diversity and predict function associated with different T6SSs, comparative genomic analysis of 34 Pseudomonas genomes was performed. This identified 70 T6SSs, with at least one locus in every strain, except for Pseudomonas stutzeri A1501. By comparing 11 core genes of the T6SS, it was possible to identify five main Pseudomonas phylogenetic clusters, with strains typically carrying T6SSs from more than one clade. In addition, most strains encode additional vgrG and hcp genes, which encode extracellular structural components of the secretion apparatus. Using a combination of phylogenetic and meta-analysis of transcriptome datasets it was possible to associate specific subsets of VgrG and Hcp proteins with each Pseudomonas T6SS clade. Moreover, a closer examination of the genomic context of vgrG genes in multiple strains highlights a number of additional genes associated with these regions. It is proposed that these genes may play a role in secretion or alternatively could be new T6S effectors.
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