Showing papers by "Anand Swaroop published in 1995"

Human SEC13Rp functions in yeast and is located on transport vesicles budding from the endoplasmic reticulum.

Abstract: In the yeast Saccharomyces cerevisiae, Sec13p is required for intracellular protein transport from the ER to the Golgi apparatus, and has also been identified as a component of the COPII vesicle coat structure. Recently, a human cDNA encoding a protein 53% identical to yeast Sec13p has been isolated. In this report, we apply the genetic assays of complementation and synthetic lethality to demonstrate the conservation of function between this human protein, designated SEC13Rp, and yeast Sec13p. We show that two reciprocal human/yeast fusion constructs, encoding the NH2-terminal half of one protein and the COOH-terminal half of the other, can each complement the secretion defect of a sec13-1 mutant at 36 degrees C. The chimera encoding the NH2-terminal half of the yeast protein and the COOH-terminal half of the human protein is also able to complement a SEC13 deletion. Overexpression of either the entire human SEC13Rp protein or the chimera encoding the NH2-terminal half of the human protein and the COOH-terminal half of the yeast protein inhibits the growth of a sec13-1 mutant at 24 degrees C; this growth inhibition is not seen in a wild-type strain nor in other sec mutants, suggesting that the NH2-terminal half of SEC13Rp may compete with Sec13-1p for a common target. We show by immunoelectronmicroscopy of mammalian cells that SEC13Rp (like the putative mammalian homologues of the COPII subunits Sar1p and Sec23p) resides in the region of the transitional ER. We also show that the distribution of SEC13Rp is not affected by brefeldin A treatment. This report presents the first demonstration of a putative mammalian COPII component functioning in yeast, and highlights a potentially useful approach for the study of conserved mammalian proteins in a genetically tractable system.

Expression and chromosomal localization of cDNA clones from an enriched human retinal pigment epithelial (RPE) cell line library: identification of two RPE-specific genes

Abstract: We have previously constructed an enriched cDNA library from a human retinal pigment epithelium (RPE) cell line and generated expressed sequence tags (ESTs) from novel clones. Here, we report the analysis of expression of 14 cDNAs and identify two clones, AA1 and AA28, that appear to be specifically expressed in RPE but not in any other tissue tested. We have also localized 15 novel cDNAs (including the two RPE-specific cDNAs) to human chromosomes using in situ hybridization or in conjunction with somatic cell hybrid analysis. The cDNAs were mapped to the following chromosomal regions:1p35→p33, 1q41→q42 (two clones), 3q11.2→q13.1, 3q24→q25, 4q13→q21, 6q22→q23, 7q34→q36, 10q23→ q24, 11q23→q24, 15q25→q26, 19p13.3, 20p13, 21q11.2→ q21, and 21q22.2→q22.3. The genetic and functional analysis of the two RPE-specific genes should contribute to a better understanding of RPE function. Chromosomal localization of RPE cDNAs will be valuable in identifying candidate genes for inherited diseases involving RPE dysfunction and aid in establishing the expression map of the human genome.

Dinucleotide polymorphism at the DXS1178 locus is tightly linked to PGK1 at Xq13

Abstract: A polymorphic CA repeat (locus name DXS1178) was isolated from a 1-megabase YAC (OTCC) containing the OTC gene, located at Xp21.1. However, amplification in human-rodent hybrid cells and segregation analysis in three CEPH families mapped the DXS1178 locus at Xq13. The mapping ambiguity is apparently caused by the chimeric nature of the OTCC YAC clone.