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Sequencing and Analysis of the Flavobacterium Columnare ATCC 49512 GenomeTekedar, Hasan Cihad 17 May 2014 (has links)
Flavobacterium columnare is a Gram negative fish pathogen that causes columnaris disease, which infects populations of wild and cultured fish species. However, pathogenic mechanisms of F. columnare are largely unknown. The purpose of this research is to obtain the complete sequence of the F. columnare ATCC 49512 genome to advance pathogenesis research and increase our understanding of this pathogen. To accomplish this, genome sequencing by using Sanger and 454 sequencing was conducted. The sequences were assembled, gaps were filled, and the circular genome was autoannotated. The F. columnare genome size is 3.2 Mb and AT rich (68.5% AT). It contains 2,882 predicted proteins, 71 tRNA genes and five ribosomal RNA operons. More than half (57.1%) of the open reading frames have assigned function, which included chondroitin AC lyase, proteases, collagenases, and genes involved in biofilm formation, secretion systems, iron acquisition, and gliding motility.
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Evaluating the Bacterial (meta)genome for Antimicrobial Resistance using High-throughput SequencingVan Camp, Pieter-Jan 24 May 2022 (has links)
No description available.
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Genomic Epidemiology and Detection of Antimicrobial Resistance Determinants in Salmonella Dublin Isolates Originating from CattleByrne, Brianna 19 June 2019 (has links)
No description available.
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Complete Genome Sequence of the Hyperthermophilic Bacteria - Thermotoga SP. Strain RQ7Puranik, Rutika 21 April 2015 (has links)
No description available.
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Deciphering and Expending Clostridium formicoaceticum Metabolism Based on Whole Genome SequencingBao, Teng January 2016 (has links)
No description available.
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Do the diversity of plants honey bees pollinate change over summer? : A study of the diversity of plant DNA found in honey over a summerLundberg, Eli January 2024 (has links)
The honey bee (Apis mellifera) is important both ecologically, as a generalist pollinator, and economically by pollinating our crops and producing honey. Honey bees use plants for foraging for pollen and nectar, which together constitute their entire diet. Yet, as flowering times of plants vary during the summer, so do the floral resources available. Honey bees are known to be selective for their food sources. Thus, their specificity in plant choices could vary according to the availability of flower sources, showing a differing usage of plant diversity in different timepoints. Alternatively, the honey bees selectivity to fulfill their nutrient needs could lead to a constant usage of diversity. The taxonomic origin of the plant DNA found in honey can be identified and used to investigate the plant taxa the bees have collected nectar and pollen from. This study asks whether the diversity of plants which honey bees use varies during summer (June, July, and August). I used two diversity indices as response variables: 1) the Shannon-Wiener diversity index and 2) the number of plant genera identified in the DNA in the honey. I used data gathered from 41 hives from 14 Finnish beekeepers. An ANOVA test revealed no significant difference among the three timepoints in either response variable, indicating honey bees select a constant diversity of plants throughout the season. The result suggest that different plants can fulfill honey bees’ requirements at different parts of the summer. Honey bees are generalists, but selective, producing a relatively constant usage of plants throughout the season.
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Whole-genome sequencing analysis of quorumsensing Aeromonas hydrophila strain M023 from freshwaterTan, W., Yin, W., Chang, Chien-Yi, Chan, K. 19 February 2015 (has links)
Yes / Aeromonas hydrophila is a well-known waterborne pathogen that recently was found to infect humans. Here, we report the draft genome of a freshwater isolate from a Malaysian waterfall, A. hydrophila strain M023, which portrays N-acylhomoserine lactone-dependent quorum sensing. / University of Malaya via High Impact Research Grants (UM C/625/1/HIR/MOHE/CHAN/01, A-000001-50001, and UM C/625/1/HIR/MOHE/CHAN/14/1, H-50001-A000027)
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Analysis of quorum-sensing Pantoea stewartii strain M073a through whole-genome sequencingMohamad, N.I., Tan, W., Chang, Chien-Yi, Tee, K.K., Yin, W., Chan, K. 2015 February 1919 (has links)
Yes / Pantoea stewartii strain M073a is a Gram-negative bacterium isolated from a tropical waterfall. This strain exhibits quorum-sensing activity. Here, the assembly and annotation of its genome are presented. / High Impact Research Grants from the University of Malaya (UM.C/625/1/HIR/MOHE/CHAN/01, grant no. A-000001-50001 and UM-MOHE HIR Grant UM.C/625/1/HIR/MOHE/ CHAN/14/1, no. H-50001-A000027)
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The new phylogeny of the genus Mycobacterium: The old and the newsTortoli, E., Fedrizzi, T., Meehan, Conor J., Trovato, A., Grottola, A., Giacobazzi, E., Fregni Serpini, G., Tagliazucchi, S., Fabio, A., Bettua, C., Bertorelli, R., Frascaro, F., De Sanctis, V., Pecorari, M., Jousson, O., Segata, N., Cirillo, D.M. 24 September 2019 (has links)
No / Background: Phylogenetic studies of bacteria have been based so far either on a single gene (usually the 16SrRNA) or on concatenated housekeeping genes. For what concerns the genus Mycobacterium these approaches support the separation of rapidly and slowly growing species and the clustering of most species in well-defined phylogenetic groups. The advent of high-throughput shotgun sequencing leads us to revise conventional tax-onomy of mycobacteria on the light of genomic data. For this purpose we investigated 88 newly sequenced species in addition to 60 retrieved from GenBank and used the Average Nucleotide Identity pairwise scores to reconstruct phylogenetic relationships within this genus.Results:Our analysis confirmed the separation of slow and rapid growers and the intermediate position occupied by the M. terrae complex. Among the rapid growers, the species of the M. chelonae-abscessus complex belonged to the most ancestral cluster. Other major clades of rapid growers included the species related to M. fortuitum and M. smegmatis and a large grouping containing mostly environmental species rarely isolated from humans. The members of the M. terrae complex appeared as the most ancestral slow growers. Among slow growers two deep branches led to the clusters of species related to M. celatum and M. xenopi and to a large group harboring most of the species more frequently responsible of disease in humans, including the major pathogenic mycobacteria (M.tuberculosis,M. leprae,M. ulcerans). The species previously grouped in the M. simiae complex were allocated in a number of sub-clades; of them, only the one including the species M. simiae identified the real members of this complex. The other clades included also species previously not considered related to M. simiae. The ANI analysis,in most cases supported by Genome to Genome Distance and by Genomic Signature-Delta Difference, showed that a number of species with standing in literature were indeed synonymous.Conclusions:Genomic data revealed to be much more informative in comparison with phenotype. We believe that the genomic revolution enabled by high-throughput shotgun sequencing should now be considered in order to revise the conservative approaches still informing taxonomic sciences.
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Whole genome sequencing to complement tuberculosis drug resistance surveys in UgandaSsengooba, W., Meehan, Conor J., Lukoye, D., Kasule, G.W., Musisi, K., Joloba, M.L., Cobelens, F.G., de Jong, B.C. 24 September 2019 (has links)
Yes / Understanding the circulating Mycobacterium tuberculosis resistance mutations is vital for better TB control strategies, especially to inform a new MDR-TB treatment programme. We complemented the phenotypic drug susceptibility testing (DST) based drug resistance surveys (DRSs) conducted in Uganda between 2008 and 2011 with Whole Genome Sequencing (WGS) of 90 Mycobacterium tuberculosis isolates phenotypically resistant to rifampicin and/or isoniazid to better understand the extent of drug resistance.
A total of 31 (34.4 %) patients had MDR-TB, 5 (5.6 %) mono-rifampicin resistance and 54 (60.0 %) mono-isoniazid resistance by phenotypic DST. Pyrazinamide resistance mutations were identified in 32.3% of the MDR-TB patients. Resistance to injectable agents was detected in 4/90 (4.4%), and none to fluoroquinolones or novel drugs. Compensatory mutations in rpoC were identified in two patients. The sensitivity and specificity of drug resistance mutations compared to phenotypic DST were for rpoB 88.6% and 98.1%, katG 60.0% and 100%, fabG1 16.5% and 100%, katG and/or fabG1 71.8% and 100%, embCAB 63.0% and 82.5%, rrs 11.4% and 100%, rpsL 20.5% and 95.7% and rrs and/or rpsL 31.8% and 95.7%.
Phylogenetic analysis showed dispersed MDR-TB isolate, with only one cluster of three Beijing family from South West Uganda.
Among tuberculosis patients in Uganda, resistance beyond first-line drugs as well as compensatory mutations remain low, and MDR-TB isolates did not arise from a dominant clone. Our findings show the potential use of sequencing for complementing DRSs or surveillance in this setting, with good specificity compared to phenotypic DST. The reported high confidence mutations can be included in molecular assays, and population-based studies can track transmission of MDR-TB including the Beijing family strains in the South West of the country. / Erasmus Mundus Joint Doctorate Program of the European Union through a training grant to WS and the European Research Council-INTERRUPTB starting grant (nr.311725) to BdJ.
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