A systematic genome-wide analysis of zebrafish protein-coding gene function

Since the publication of the human reference genome, the identities of specific genes associated with human diseases are being discovered at a rapid rate. A central problem is that the biological activity of these genes is often unclear. Detailed investigations in model vertebrate organisms, typical...

Full description

Saved in:
Bibliographic Details
Published inNature (London) Vol. 496; no. 7446; pp. 494 - 497
Main Authors Kettleborough, Ross N W, Busch-Nentwich, Elisabeth M, Harvey, Steven A, Dooley, Christopher M, de Bruijn, Ewart, van Eeden, Freek, Sealy, Ian, White, Richard J, Herd, Colin, Nijman, Isaac J, Fényes, Fruzsina, Mehroke, Selina, Scahill, Catherine, Gibbons, Richard, Wali, Neha, Carruthers, Samantha, Hall, Amanda, Yen, Jennifer, Cuppen, Edwin, Stemple, Derek L
Format Journal Article
LanguageEnglish
Published England Nature Publishing Group 25.04.2013
Subjects
Alleles
Animals
Data mining
Disease
DNA sequencing
Exome - genetics
Female
Gene Knockout Techniques
Genes
Genetic aspects
Genetic Complementation Test
Genetics
Genome - genetics
Genomes
Genomics
Male
Molecular Sequence Annotation
Mutagenesis
Mutation
Mutation - genetics
Nucleotide sequencing
Phenotype
Polymorphism, Single Nucleotide - genetics
Proteins
Zebra fish
Zebrafish
Zebrafish - genetics
Zebrafish - physiology
Zebrafish Proteins - genetics
Zebrafish Proteins - metabolism
United States
Online AccessGet full text

Cover

More Information
Summary:Since the publication of the human reference genome, the identities of specific genes associated with human diseases are being discovered at a rapid rate. A central problem is that the biological activity of these genes is often unclear. Detailed investigations in model vertebrate organisms, typically mice, have been essential for understanding the activities of many orthologues of these disease-associated genes. Although gene-targeting approaches and phenotype analysis have led to a detailed understanding of nearly 6,000 protein-coding genes, this number falls considerably short of the more than 22,000 mouse protein-coding genes. Similarly, in zebrafish genetics, one-by-one gene studies using positional cloning, insertional mutagenesis, antisense morpholino oligonucleotides, targeted re-sequencing, and zinc finger and TAL endonucleases have made substantial contributions to our understanding of the biological activity of vertebrate genes, but again the number of genes studied falls well short of the more than 26,000 zebrafish protein-coding genes. Importantly, for both mice and zebrafish, none of these strategies are particularly suited to the rapid generation of knockouts in thousands of genes and the assessment of their biological activity. Here we describe an active project that aims to identify and phenotype the disruptive mutations in every zebrafish protein-coding gene, using a well-annotated zebrafish reference genome sequence, high-throughput sequencing and efficient chemical mutagenesis. So far we have identified potentially disruptive mutations in more than 38% of all known zebrafish protein-coding genes. We have developed a multi-allelic phenotyping scheme to efficiently assess the effects of each allele during embryogenesis and have analysed the phenotypic consequences of over 1,000 alleles. All mutant alleles and data are available to the community and our phenotyping scheme is adaptable to phenotypic analysis beyond embryogenesis.
Bibliography:These authors contributed equally to this work.
ISSN:0028-0836
1476-4687
DOI:10.1038/nature11992