ABSTRACT
Upon the completion of the SACCHAROMYCES: cerevisiae genomic sequence in 1996 [Goffeau,A. et al. (1997) NATURE:, 387, 5], several creative and ambitious projects have been initiated to explore the functions of gene products or gene expression on a genome-wide scale. To help researchers take advantage of these projects, the SACCHAROMYCES: Genome Database (SGD) has created two new tools, Function Junction and Expression Connection. Together, the tools form a central resource for querying multiple large-scale analysis projects for data about individual genes. Function Junction provides information from diverse projects that shed light on the role a gene product plays in the cell, while Expression Connection delivers information produced by the ever-increasing number of microarray projects. WWW access to SGD is available at genome-www.stanford. edu/Saccharomyces/.
Subject(s)
Databases, Factual , Genome, Fungal , Saccharomyces cerevisiae/genetics , Gene Expression Regulation, Fungal , Genes, Fungal/genetics , Genes, Fungal/physiology , InternetABSTRACT
The Saccharomyces Genome Database (SGD) stores and organizes information about the nearly 6200 genes in the yeast genome. The information is organized around the 'locus page' and directs users to the detailed information they seek. SGD is endeavoring to integrate the existing information about yeast genes with the large volume of data generated by functional analyses that are beginning to appear in the literature and on web sites. New features will include searches of systematic analyses and Gene Summary Paragraphs that succinctly review the literature for each gene. In addition to current information, such as gene product and phenotype descriptions, the new locus page will also describe a gene product's cellular process, function and localization using a controlled vocabulary developed in collaboration with two other model organism databases. We describe these developments in SGD through the newly reorganized locus page. The SGD is accessible via the WWW at http://genome-www.stanford.edu/Saccharomyces/
Subject(s)
Databases, Factual , Genome, Fungal , Saccharomyces/genetics , Database Management Systems , InternetABSTRACT
Olfactory receptors are G protein-coupled, seven-transmembrane-domain proteins that are responsible for binding odorants in the nasal epithelium. They are encoded by a large gene family, members of which are organized in several clusters scattered throughout the genomes of mammalian species. Here we describe the mapping of mouse sequences corresponding to four conserved olfactory receptor genes, each representing separate, recently identified canine gene subfamilies. Three of the four canine genes detected related gene clusters in regions of mouse Chromosomes (Chrs) 2, 9, and 10, near previously mapped mouse olfactory genes, while one detected a formerly unidentified gene cluster located on mouse Chr 6. In addition, we have localized two human gene clusters with homology to the canine gene, CfOLF4, within the established physical map of Chr 19p. Combined with recently published studies, these data link the four conserved olfactory gene subfamilies to homologous regions of the human, dog, and mouse genomes.
Subject(s)
Chromosome Mapping , Multigene Family/genetics , Receptors, Odorant/genetics , Animals , Chromosomes, Human, Pair 19/genetics , Conserved Sequence , DNA-Binding Proteins/genetics , Dogs , Humans , Mice , Smell/genetics , Trans-Activators/geneticsABSTRACT
We performed a comparative study of four subfamilies of olfactory receptor genes first identified in the dog to assess changes in the gene family during mammalian evolution, and to begin linking the dog genetic map to that of humans. The human subfamilies were localized to chromosomes 7, 11, and 19. The two subfamilies that were tightly linked in the dog genome were also tightly linked in the human genome. The four subfamilies were compared in human (primate), horse (perissodactyl), and a variety of artiodactyls and carnivores. Some changes in gene number were detected, but overall subfamily size appeared to have been established before the divergence of these mammals 60-100 million years ago.
Subject(s)
Chromosomes, Human, Pair 11 , Chromosomes, Human, Pair 19 , Chromosomes, Human, Pair 7 , Evolution, Molecular , Genes , Receptors, Odorant/genetics , Amino Acid Sequence , Animals , Base Sequence , Blotting, Southern , Chromosome Mapping , DNA , Dogs , Humans , Mammals , Molecular Sequence Data , Receptors, Odorant/classification , Sequence Homology, Amino AcidABSTRACT
Four members of the canine olfactory receptor gene family were characterized. The predicted proteins shared 40-64% identity with previously identified olfactory receptors. The four subfamilies identified in Southern hybridization experiments had as few as 2 and as many as 20 members. All four genes were expressed exclusively in olfactory epithelium. Expression of multiple members of the larger subfamilies was detected, suggesting that most if not all of the cross-hybridizing bands in genomic Southern blots represented actively transcribed olfactory receptor genes. Analysis of large DNA fragments using Southern blots of pulsed-field gels indicated that subfamily members were clustered together, and that two of the subfamilies were closely linked in the dog genome. Analysis of the four olfactory receptor gene subfamilies in 26 breeds of dog provided evidence that the number of genes per subfamily was stable in spite of differential selection on the basis of olfactory acuity in scent hounds, sight hounds, and toy breeds.
Subject(s)
Dogs/genetics , Receptors, Odorant/genetics , Amino Acid Sequence , Animals , Cloning, Molecular , Cosmids , Gene Expression , Genes , Molecular Sequence Data , Multigene Family , RNA, Messenger/genetics , Sequence Alignment , Sequence Homology, Amino Acid , Smell/physiology , Species SpecificityABSTRACT
When mitochondrial DNA sequence variation is analyzed from a sample of 637 individuals in 14 European populations, most populations show little differentiation with respect to each other. However, the Saami distinguish themselves by a comparatively large amount of sequence difference when compared with the other populations, by a different distribution of sequence diversity within the population, and by the occurrence of particular sequence motifs. Thus, the Saami seem to have a long history distinct from other European populations. Linguistic affiliations are not reflected in the patterns of relationships of mitochondrial lineages in European populations, whereas prior studies of nuclear gene frequencies have shown a correlation between genetic and linguistic evolution. It is argued that this apparent contradiction is attributable to the fact that genetic lineages and gene frequencies reflect different time perspectives on population history, the latter being more in concordance with linguistic evolution.
Subject(s)
DNA, Mitochondrial/genetics , Ethnicity/genetics , Genome, Human , Language , Base Sequence , Ethnicity/classification , Ethnicity/history , Europe , Evolution, Molecular , Finland , Gene Frequency , Genetic Markers , History, Modern 1601- , Humans , Molecular Sequence Data , Sequence Homology, Nucleic AcidABSTRACT
Mitochondrial DNA (mtDNA) was extracted from teeth stored from 3 months to 20 years, including teeth from the semi-skeletonized remains of a murder victim which had been buried for 10 months. Tooth donors and/or their maternal relatives provided blood or buccal cells, from which mtDNA was also extracted. Enzymatic amplification and direct sequencing of roughly 650 nucleotides from two highly polymorphic regions of mtDNA yielded identical sequences for each comparison of tooth and fresh DNA. Our results suggest that teeth provide an excellent source for high molecular weight mtDNA that can be valuable for extending the time in which decomposed human remains can be genetically identified.
