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Comparative genomics to investigate genome function and adaptations in the newly sequenced Brachyspira hyodysenteriae and Brachyspira pilosicolipwanch@msu.ac.th, Phatthanaphong Wanchanthuek January 2009 (has links)
Brachyspira hyodysenteriae and Brachyspira pilosicoli are anaerobic intestinal spirochaetes that are the aetiological agents of swine dysentery and intestinal spirochaetosis, respectively. As part of this PhD study the genome sequence of B. hyodysenteriae strain WA1 and a near complete sequence of B. pilosicoli strain 95/1000 were obtained, and subjected to comparative genomic analysis. The B. hyodysenteriae genome consisted of a circular 3.0 Mb chromosome, and a 35,940 bp circular plasmid that has not previously been described. The incomplete genome of B. pilosicoli contained 4 scaffolds. There were 2,652 and 2,297 predicted ORFs in the B. hyodysenteriae and B. pilosicoli strains, respectively. Of the predicted ORFs, more had similarities to proteins of the enteric Clostridium species than they did to proteins of other spirochaetes. Many of these genes were associated with transport and metabolism, and they may have been gradually acquired through horizontal gene transfer in the environment of the large intestine.
A reconstruction of central metabolic pathways of the Brachyspira species identified a complete set of coding sequences for glycolysis, gluconeogenesis, a non-oxidative pentose phosphate pathway, nucleotide metabolism and a respiratory electron transport chain. A notable finding was the presence of rfb genes on the B. hyodysenteriae plasmid, and their apparent absence from B. pilosicoli. As these genes are involved in rhamnose biosynthesis it is likely that the composition of the B. hyodysenteriae lipooligosaccharide O-sugars is different from that of B. pilosicoli. O-antigen differences in these related species could be associated with differences in their specific niches, and/or with their disease specificity. Overall, comparison of B. hyodysenteriae and B. pilosicoli protein content and analysis of their central metabolic pathways showed that they have diverged markedly from other spirochaetes in the process of adapting to their habitat in the large intestine.
The presence of overlapping genes in the two spirochaetes and in other spirochaete species also was investigated. The number of overlapping genes in the 12 spirochaete genomes examined ranged from 11-45%. Of these, 80% were unidirectional. Overlapping genes were found irregularly distributed within the Brachyspira genomes such that 70-80% of them occurred on the same strand (unidirectional, ->->/<-<-), with 16-28% occurring on opposite DNA strands (divergent, <-->). The remaining 4-6% of overlapping genes were convergent (-><-). The majority of the unidirectional overlap regions were relatively short, with >50% of the total observations overlapping by >4 bp. A small number of overlapping gene-pairs were duplicated within each genome and there were some triplet overlapping genes. Unique orthologous overlapping genes were identified within the various spirochaete genera. Over 75% of the overlapping genes in the Brachyspira species were in the same or related metabolic pathway. This finding suggests that overlapping genes are not only likely to be the result of functional constraints but also are constrained from a metabolomic context. Of the remaining 25% overlapping genes, 50% contained one hypothetical gene with unknown function. In addition, in one of the orthologous overlapping genes in the Brachyspira species, a promoter was shared, indicating the presence of a novel class of overlapping gene operon in these intestinal spirochaetes.
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Insights on quorum-quenching properties of Lysinibacillus fusiformis strain RB21, a Malaysian municipal solid-waste landfill soil isolate, via complete genome sequence analysisYong, D., Ee, R., Lim, Y., Chang, Chien-Yi, Yin, W., Chan, K. 05 July 2015 (has links)
Yes / Lysinibacillus fusiformis strain RB21 is a quorum-quenching bacterium that is able to degrade quorum-sensing signaling molecules. Here, we present the first complete genome sequence of L. fusiformis strain RB21. The finished genome is 4.8 Mbp in size, and the quorum-quenching gene was identified. / University of Malaya for High Impact Research (UM-MOHE HIR) grant UM C/625/1/HIR/MOHE/CHAN/01, no. A000001-50001 and grant UM C/625/1/HIR/MOHE/CHAN/14/1, H-50001-A000027
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Mutation of the maturase lipoprotein attenuates the virulence of Streptococcus equi to a greater extent than does loss of general lipoprotein lipidation.Hamilton, A., Robinson, C., Sutcliffe, I.C., Slater, I., Maskell, D.J., Smith, K., Waller, A., Harrington, Dean J. January 2006 (has links)
Streptococcus equi is the causative agent of strangles, a prevalent and highly contagious disease of horses. Despite the animal suffering and economic burden associated with strangles, little is known about the molecular basis of S. equi virulence. Here we have investigated the contributions of a specific lipoprotein and the general lipoprotein processing pathway to the abilities of S. equi to colonize equine epithelial tissues in vitro and to cause disease in both a mouse model and the natural host in vivo. Colonization of air interface organ cultures after they were inoculated with a mutant strain deficient in the maturase lipoprotein (prtM138-213, with a deletion of nucleotides 138 to 213) was significantly less than that for cultures infected with wild-type S. equi strain 4047 or a mutant strain that was unable to lipidate preprolipoproteins (lgt190-685). Moreover, mucus production was significantly greater in both wild-type-infected and lgt190-685-infected organ cultures. Both mutants were significantly attenuated compared with the wild-type strain in a mouse model of strangles, although 2 of 30 mice infected with the lgt190-685 mutant did still exhibit signs of disease. In contrast, only the prtM138-213 mutant was significantly attenuated in a pony infection study, with 0 of 5 infected ponies exhibiting pathological signs of strangles compared with 4 of 4 infected with the wild-type and 3 of 5 infected with the lgt190-685 mutant. We believe that this is the first study to evaluate the contribution of lipoproteins to the virulence of a gram-positive pathogen in its natural host. These data suggest that the PrtM lipoprotein is a potential vaccine candidate, and further investigation of its activity and its substrate(s) are warranted.
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Clusters de gènes de résistance aux maladies chez le haricot commun : bases moléculaires, régulation et évolution / Disease resistance gene clusters in common bean : molecular basis, regulation and evolutionRichard, Manon 16 December 2014 (has links)
Le haricot commun est la légumineuse à graine la plus consommée au monde en alimentation humaine. Le génome du haricot possède plusieurs énormes clusters de gènes de résistance (R) qui ont la particularité de se cartographier en extrémité de groupes de liaison. Le génome du haricot commun (génotype Andin G19833) a été récemment séquencé et nous avons participé à ce projet en annotant la famille des NB-LRR (NL), classe prépondérante des gènes de résistance. Ces données génomiques nous ont permis de réaliser les 3 études suivantes. (i) L’identification des bases moléculaires de Co-x un gène R vis-à-vis d’une souche très virulente de C. lindemuthianum chez JaloEEP558 a été initiée. La cartographie fine de Co-x suivie du séquençage de la région cible chez JaloEEP558 (Co-x) a permis d’identifier un gène candidat codant une kinase atypique qui pourrait être la cible d’un effecteur fongique, gardée par un gène R. (ii) Des études récentes ont mis en évidence l’implication de petits ARNs (miRNAs induisant la production de phased siRNAs) dans la régulation de l’expression des NL. Le séquençage et l’analyse de banques de sRNAs de haricot nous ont permis d’identifier ce mécanisme et de mettre le doigt sur un nouveau mécanisme de régulation des NL impliquant des sRNAs de 24 nt. (iii) Des ADN satellites ont été étudiés à l’échelle du génome du haricot. L’étude des centromères de haricot a permis de mettre en évidence l’existence de 2 ADN satellites différents, Nazca et CentPv2. Nous avons également étudié un ADN satellite subtélomérique khipu précédemment identifié au niveau de 2 clusters de gènes R du haricot. L’étude de khipu à l’échelle du génome suggère l’existence d’échanges fréquents de séquences entre subtélomères de chromosomes non homologues. Ces résultats nous ont amenés à proposer que des éléments structuraux et une combinaison de mécanismes de régulation (TGS et PTGS) permettent la prolifération des NL sans effet néfaste pour la plante, conduisant à l’obtention de très gros clusters de NL dans le génome du haricot. / Common bean is the main source of protein for human consumption in many developing countries. Several huge disease resistance (R) gene clusters have been mapped at the end of common bean linkage groups. The common bean genome (Andean genotype G19833) has recently been sequenced. Access to the complete genome sequence of common bean allowed us to annotate the Nucleotide Binding-Leucine Rich Repeat (NL) encoding gene family, the prevalent class of disease R genes in plants, and to perform the 3 following studies: (i) We have investigated the molecular basis of Co-x, an anthracnose R gene to a highly virulent strain of C. lindemuthianum, previously identified in the Andean cultivar JaloEEP558. Fine mapping of Co-x and sequencing of the target region in JaloEEP558, allowed us to identify a candidate gene encoding an atypical kinase. We hypothesised that this atypical kinase is a fungal effector target. (ii) Several recent studies have highlighted the role of small RNA (miRNAs that triggered phased siRNAs production) in the regulating of NL gene expression. Analyses of small RNAs libraries of common bean led to the identification of this mechanism in common bean and also allowed us to propose a new NL regulation pathway involving 24 nt sRNAs. (iii) We have studied centromeric and subtelomeric satellite DNAs at common bean genome level. We have identified 2 different satellite DNAs in common bean centromeres, Nazca and CentPv2. We have also conducted the analyze of the subtelomeric satellite khipu, previously identified in common bean R clusters and confirmed that frequent sequence exchange occurs between non-homologous chromosome ends in common bean genome. Together, these results led us to propose that both structural elements and a combination of regulatory mechanisms (TGS, PTGS) allow the amplification of NL sequences without detrimental effect for the plant leading to the large NL clusters observed in common bean.
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