ABSTRACT
Chondromodulin-I (ChM-I) is suggested in higher vertebrate systems to function as a key regulatory protein for cartilage development. To further understand the process of chondrogenesis and the function of ChM-I, we have cloned the zebrafish cDNA for chondromodulin-1 (chm1) and have mapped the chm1 gene locus. The expression profile of chm1 was determined during zebrafish embryonic development and compared to that of type II collagen (col2a1). Maternal chm1 transcripts were detected before midblastula transition and zygotic expression of chm1 was first observed in the notochord at the 10-somite stage. At later developmental stages, chm1 expression was detected in areas surrounding the otic vesicles, in the developing craniofacial cartilage elements, and in the chondrogenic region of the pectoral fins.
Subject(s)
Cartilage/embryology , Growth Substances/biosynthesis , Growth Substances/genetics , Intercellular Signaling Peptides and Proteins , Membrane Proteins , Notochord/metabolism , Amino Acid Sequence , Animals , Cattle , DNA, Complementary/metabolism , Humans , In Situ Hybridization , Molecular Sequence Data , Phylogeny , Radiation Hybrid Mapping , Reverse Transcriptase Polymerase Chain Reaction , Sequence Analysis, DNA , Sequence Homology, Amino Acid , Time Factors , Tissue Distribution , Zebrafish , Zygote/metabolismABSTRACT
We have characterized a collection of zebrafish/mouse somatic cell hybrids with 211 genes and markers chosen from the 25 zebrafish linkage groups. Most of the zebrafish genome is represented in this collection with 88% of genes/markers present in at least one hybrid cell line. Although most hybrids contain chromosomal fragments, there are a few instances where a complete or nearly complete zebrafish chromosome has been maintained in a mouse background, based on multiple markers covering the entire chromosome. In addition to their use in mapping studies, this collection of somatic cell hybrids should constitute an important tool as a source of specific chromosome fragments and for assessing the function of genome regions.
Subject(s)
Zebrafish/genetics , Animals , Cell Line , Genetic Linkage , Genetic Markers , Hybrid Cells , In Situ Hybridization, Fluorescence , Mice , Microsatellite Repeats , Polymerase Chain ReactionABSTRACT
The zebrafish is the first vertebrate organism used for large-scale genetic screens seeking genes critical to development. These screens have been quite successful, with more than 1800 recessive mutations discovered that speak to morphogenesis of the vertebrate embryo. The cloning of the mutant genes depends on a dense genetic map. The 2000 markers we present here, using microsatellite (CA) repeats, provides 1.2-cM average resolution. One centimorgan in zebrafish is about 0. 74 megabase, so, for many mutations, these markers are close enough to begin positional cloning by YAC walks.
Subject(s)
Microsatellite Repeats/genetics , Zebrafish/genetics , Animals , Cloning, Molecular , Female , Gene Library , Genetic Linkage , Genome , Male , Mutation , Physical Chromosome MappingABSTRACT
To exploit fully the power of the zebrafish system as a model for vertebrate development, it will be necessary to develop efficient tools for genomic analysis. In this report we have tested whether single-strand conformation polymorphism analysis (SSCP) can be utilized for gene mapping in zebrafish. Over 100 primer pairs derived from noncoding regions of known genes and partially characterized cDNAs were analyzed, and a polymorphism frequency of approximately 50% was detected in zebrafish strains used for genetic mapping studies. A subset of these polymorphic cDNAs was localized on the zebrafish map. SSCP thus represents an efficient strategy for mapping transcribed sequences with a high resolution in the zebrafish genome, which will facilitate the integration of existing zebrafish framework maps, the generation of a zebrafish EST map, and the application of alternative gene localization strategies such as comparative mapping.
Subject(s)
Physical Chromosome Mapping/methods , Polymorphism, Single-Stranded Conformational , Zebrafish/genetics , 3' Untranslated Regions , Animals , Crosses, Genetic , DNA Primers , DNA, Complementary/genetics , Expressed Sequence Tags , Sensitivity and SpecificityABSTRACT
We have constructed a zebrafish genetic linkage map consisting of 705 simple sequence-length polymorphism markers (SSLPs). The map covers 2350 centimorgans (cM) of the zebrafish genome with an average resolution of 3.3 cM. It is a complete map in genetic mapping terms (there is one linkage group for each of the 25 chromosomes), and it has been confirmed by somatic-cell hybrids and centromere-mapping using half-tetrad analysis. The markers are highly polymorphic in the zebrafish strains used for genetic crosses and provide a means to compare genetic segregation of developmental mutations between laboratories. These markers will provide an initial infrastructure for the positional cloning of the nearly 600 zebrafish genes identified as crucial to vertebrate development,and will become the anchor for the physical map of the zebrafish genome.
Subject(s)
Microsatellite Repeats/genetics , Zebrafish/genetics , Animals , Chromosome Mapping , Genes/genetics , Genetic Linkage , Genetic Markers/genetics , Genome , Sequence Analysis, DNAABSTRACT
The ultimate informativeness of the zebrafish mutations described in this issue will rest in part on the ability to clone these genes. However, the genetic infrastructure required for the positional cloning in zebrafish is still in its infancy. Here we report a reference cross panel of DNA, consisting of 520 F2 progeny (1040 meioses) that has been anchored to a zebrafish genetic linkage map by 102 simple sequence length polymorphisms. This reference cross DNA provides: (1) a panel of DNA from the cross that was used to construct the genetic linkage map, upon which polymorphic gene(s) and genetic markers can be mapped; (2) a fine order mapping tool, with a maximum resolution of 0.1 cM; and (3) a foundation for the development of a physical map (an ordered array of clones each containing a known portion of the genome). This reference cross DNA will serve as a resource enabling investigators to relate genes or genetic markers directly to a single genetic linkage map and avoid the problem of integrating different maps with different genetic markers, as must be currently done when using randomly amplified polymorphic DNA markers, or as has occurred with human genetic linkage maps.
Subject(s)
Crosses, Genetic , Polymorphism, Genetic , Sequence Analysis, DNA , Zebrafish/genetics , Alleles , Animals , DNA Primers/standards , Genetic Markers , Genotype , Reference Standards , Repetitive Sequences, Nucleic Acid , Sequence Analysis, DNA/standardsABSTRACT
The expression of the murine paired-box-containing gene, Pax2, is examined in the developing central nervous system by in situ hybridization. Pax2 expression is detected along the boundaries of primary divisions of the neural tube. Initially, Pax2 is expressed in the ventricular zone in two compartments of cells on either side of the sulcus limitans and along the entire rhombencephalon and spinal cord. At later times, Pax2 is restricted to progeny cells that have migrated to specific regions of the intermediate zone. In the eye, Pax2 expression is restricted to the ventral half of the optic cup and stalk and later to the optic disc and nerve. In the ear, expression is restricted to regions of the otic vesicle that form neuronal components. The transient and restricted nature of Pax2 expression suggests that this murine segmentation gene homologue may also establish compartmental boundaries and contribute to the specification of neuronal identity, as do certain Drosophila segmentation genes.
