Difference between revisions of "Main Page"
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*[[Special:ShiverSpecialpage|Shiver et al. (2020) Chemical-genetic interrogation of RNA polymerase mutants reveals structure-function relationships and physiological tradeoffs. BioRxiv]] | *[[Special:ShiverSpecialpage|Shiver et al. (2020) Chemical-genetic interrogation of RNA polymerase mutants reveals structure-function relationships and physiological tradeoffs. BioRxiv]] | ||
*[[Special:ECGASpecialpage|Xia J et al. (2019) Bacteria-to-human protein networks reveal origins of endogenous DNA damage. Cell. 176:127-143.e24.]] | *[[Special:ECGASpecialpage|Xia J et al. (2019) Bacteria-to-human protein networks reveal origins of endogenous DNA damage. Cell. 176:127-143.e24.]] | ||
| + | *[[Special:CamposSpecialpage|Campos et al. (2018) Genomewide phenotypic analysis of growth, cell morphogenesis, and cell cycle events in ''Escherichia coli''. Mol Syst Biol. 14(6):e7573.]] | ||
*[[Special:Specialpeterspage|Peters JM et al. (2016) A comprehensive, CRISPR-based functional analysis of essential genes in bacteria. Cell. 165:1493-1506.]] | *[[Special:Specialpeterspage|Peters JM et al. (2016) A comprehensive, CRISPR-based functional analysis of essential genes in bacteria. Cell. 165:1493-1506.]] | ||
*[[Special:Ecolispecialpage|Nichols et al. (2010) Phenotypic landscape of a bacterial cell. Cell. 144:143-56.]] Fitness of 3,979 ''E. coli'' mutants in 324 growth conditions. | *[[Special:Ecolispecialpage|Nichols et al. (2010) Phenotypic landscape of a bacterial cell. Cell. 144:143-56.]] Fitness of 3,979 ''E. coli'' mutants in 324 growth conditions. | ||
| + | *[[Special:CamposSpecialpage|Campos et al. (2018) Genomewide phenotypic analysis of growth, cell morphogenesis, and cell cycle events in ''Escherichia coli''. Mol Syst Biol. 14(6):e7573.]] | ||
[https://github.com/microbialphenotypes/OMPwiki/issues Bug tracker for OMPwiki] | [https://github.com/microbialphenotypes/OMPwiki/issues Bug tracker for OMPwiki] | ||
Revision as of 13:58, 30 June 2020
What are microbial phenotypes & why do they need an ontology?A phenotype is the expression of a genotype (i.e. the full genetic complement of an organism) in a given environment. For example, eye color, number of seeds per pod, and coat color are phenotypic traits that can be observed in flies, lupines, and ponies, respectively. Within an individual organism, both changes in genetic makeup, such as from bacterial conjugation, and variation in gene expression can result in different phenotypes under similar environmental conditions. Conversely, environmental variation can lead to different outcomes for genetically identical organisms, through variable gene expression. Myriad genetically and taxonomically diverse microbes exhibit countless variability in their morphological and physiological traits, both within and among species. Oftentimes these result in unique and exquisite manifestations, such as the symbiosis between the bioluminescent Vibrio fischeri bacterium and its squid host Euprymna scolopes. Characterization of phenotypes is critically important for medical microbial identification, and many unique biotechnological applications of microbes are rooted in phenotypes. Genetic manipulation with associated phenotypic characterization remains an important tool for determining protein function in microorganisms amenable to manipulation, such as Escherichia coli. To facilitate research in all of these areas, we are developing the Ontology of Microbial Phenotypes to allow for standardized capture of essential phenotypic information.
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