Abstract

The identification of new genes in genomic and cDNA sequencing projects is far outpacing the discovery of their functions. The goal of this project is to close this gap using genomic analysis in zebrafish. A systematic analysis of the expression patterns and map positions of transcribed genes will be used to link cloned genes to mutant phenotypes. This project will 1) facilitate the cloning of zebrafish mutations, and 2) yield functional information about orthologous genes in other vertebrates. The successful analysis of the floating head (flh) mutation illustrates the potential of this approach. The combination of the expression pattern and map position of the zebrafish Not-1 gene led to its identification as a candidate for the flh mutation, which disrupts pattern formation in the embryo. Subsequent analysis confirmed that the Not-1 gene is inactivated in flh mutants. Not-1 homologs have been identified in other vertebrates, and these genes are likely to have the same function in pattern formation as defined by the flh mutation in zebrafish. This project will use expression pattern and map position to identify candidate genes for the large number of zebrafish mutations that have recently been isolated in genetic screens. This proposal has three main goals: 1) Genetic mapping of 250 mutations that define essential gene functions to facilitate the cloning of these genes. These mutations will be mapping by centromere-linkage analysis, an efficient mapping strategy that allows most loci to be localized to a linkage group with approximately 400 PCR assays. 2) Candidate genes for mutations with tissue specific phenotypes will be identified in a systematic screen of the expression patterns of transcribed genes. 1500 novel zebrafish genes will be identified by partial sequence analysis of cDNA clones (production of expressed sequence tags, EST), and the expression patterns of these genes will be determined by wholemount in situ hybridization. 3) Positional candidate genes for the mutations localized in Part 1 will be identified by mapping genes discovered in Part 2 and in other studies. Genes will be mapped by following the segregation of PCR-based gene markers in zebrafish-mouse cell hybrids and in genetic mapping crosses. Since these mutations disrupt many diverse aspects of development and physiology -- and in many cases mimic human diseases -- the gene functions revealed by genomic analysis in zebrafish will be broadly relevant to vertebrate biology and medicine.

  Funding Agency

Agency
National Institute of Health (NIH)
Institute
National Center for Research Resources (NCRR)
Type
Research Project (R01)
Project #
5R01RR012349-06
Application #
6394671
Study Section
Genome Study Section (GNM)
Program Officer
Chang, Michael
Project Start
1997-08-15
Project End
2002-07-31
Budget Start
2001-08-01
Budget End
2002-07-31
Support Year
6
Fiscal Year
2001
Total Cost
$306,510
Indirect Cost

  Institution

Name
Stanford University
Department
Anatomy/Cell Biology
Type
Schools of Medicine
DUNS #
800771545
City
Stanford
State
CA
Country
United States
Zip Code
94305

  Publications

Bellipanni, Gianfranco; Varga, Mate; Maegawa, Shingo et al. (2006) Essential and opposing roles of zebrafish beta-catenins in the formation of dorsal axial structures and neurectoderm. Development 133:1299-309
Pietsch, Jacy; Delalande, Jean-Marie; Jakaitis, Brett et al. (2006) lessen encodes a zebrafish trap100 required for enteric nervous system development. Development 133:395-406
Woods, Ian G; Talbot, William S (2005) The you gene encodes an EGF-CUB protein essential for Hedgehog signaling in zebrafish. PLoS Biol 3:e66
Woods, Ian G; Wilson, Catherine; Friedlander, Brian et al. (2005) The zebrafish gene map defines ancestral vertebrate chromosomes. Genome Res 15:1307-14
Lee, Jeong-Soo; von der Hardt, Sophia; Rusch, Melissa A et al. (2004) Axon sorting in the optic tract requires HSPG synthesis by ext2 (dackel) and extl3 (boxer). Neuron 44:947-60
Urtishak, Karen A; Choob, Michael; Tian, Xiaobing et al. (2003) Targeted gene knockdown in zebrafish using negatively charged peptide nucleic acid mimics. Dev Dyn 228:405-13
Levkowitz, Gil; Zeller, Jorg; Sirotkin, Howard I et al. (2003) Zinc finger protein too few controls the development of monoaminergic neurons. Nat Neurosci 6:28-33
Stickney, Heather L; Schmutz, Jeremy; Woods, Ian G et al. (2002) Rapid mapping of zebrafish mutations with SNPs and oligonucleotide microarrays. Genome Res 12:1929-34
Kramer, Carina; Mayr, Thomas; Nowak, Matthias et al. (2002) Maternally supplied Smad5 is required for ventral specification in zebrafish embryos prior to zygotic Bmp signaling. Dev Biol 250:263-79
Imai, Y; Gates, M A; Melby, A E et al. (2001) The homeobox genes vox and vent are redundant repressors of dorsal fates in zebrafish. Development 128:2407-20

Showing the most recent 10 out of 25 publications