Fish proteome analysis: Model organisms and non‐sequenced species
Identifieur interne : 000C97 ( Istex/Corpus ); précédent : 000C96; suivant : 000C98Fish proteome analysis: Model organisms and non‐sequenced species
Auteurs : Ignasi Forné ; Joaquin Abián ; Joan CerdàSource :
- PROTEOMICS [ 1615-9853 ] ; 2010-02.
English descriptors
- KwdEn :
Abstract
In the last decade, proteomic technologies have been increasingly used in fish biology research. Proteomics has been applied primarily to investigate the physiology, development biology and the impact of contaminants in fish model organisms, such as zebrafish (Danio rerio), as well as in some commercial species produced in aquaculture, mainly salmonids and cyprinids. However, the lack of previous genetic information on most fish species has been a major drawback for a more general application of the different proteomic technologies currently available. Also, many teleosts of interest in biological research and with potential application in aquaculture hold unique physiological characteristics that cannot be directly addressed from the study of small laboratory fish models. This review describes proteomic approaches that have been used to investigate diverse biological questions in model and non‐model fish species. We will also evaluate the current possibilities to integrate fish proteomics with other “omic” approaches, as well as with additional complementary techniques, in order to address the future challenges in fish biology research.
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DOI: 10.1002/pmic.200900609
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ISTEX:E95212DBAA3FAF4943ED303F70036A7B6EF25BA0Le document en format XML
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Proteomics has been applied primarily to investigate the physiology, development biology and the impact of contaminants in fish model organisms, such as zebrafish (Danio rerio), as well as in some commercial species produced in aquaculture, mainly salmonids and cyprinids. However, the lack of previous genetic information on most fish species has been a major drawback for a more general application of the different proteomic technologies currently available. Also, many teleosts of interest in biological research and with potential application in aquaculture hold unique physiological characteristics that cannot be directly addressed from the study of small laboratory fish models. This review describes proteomic approaches that have been used to investigate diverse biological questions in model and non‐model fish species. 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|texte= Fish proteome analysis: Model organisms and non‐sequenced species
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