Physical mapping of autonomic/sympathetic candidate genetic loci for hypertension in the human genome: a somatic cell radiation hybrid library approach.

Allelic variation at multiple genetic loci may contribute to hypertension. Since autonomic/sympathetic dysfunction may play an early, pathogenic, heritable role in hypertension, we evaluated candidate loci likely to contribute to such dysfunction, including catecholamine biosynthetic enzymes, catecholamine transporters, neuropeptides, and adrenergic receptors. Since chromosomal locations and physical map positions of many of these loci had not yet been identified, we used the GeneBridge4 human/hamster radiation (somatic cell) hybrid library panel (resolution approximately 1 to approximately 1.5 Mb), along with specifically designed oligonucleotide primers and PCR (200-400 bp products) to position these loci in the human genome. Primers were designed from sequences outside the coding regions (3'-flanking or intronic segments) to avoid cross-species (hamster) amplification. Chromosomal positions were assigned in cR (centi-Ray) units ( approximately 270 Kbp/cR(3000) for GeneBridge 4). A total of 13 loci were newly assigned chromosomal positions; of particular interest was a cluster of adrenergic candidate loci on chromosome 5q (including ADRB2, ADRA1A, DRD1, GPRK6, and NPY6R), a region harbouring linkage peaks for blood pressure. Such physical map positions will enable more precise selection of polymorphic microsatellite and single nucleotide polymorphism markers at these loci, to aid in linkage and association studies of autonomic/sympathetic dysfunction in human hypertension.

An STS content map of human chromosome 11: localization of 910 YAC clones and 109 islands.

Physical mapping of human chromosomes at a resolution of 100 kb to 1 Mb will provide important reagents for gene identification and framework templates for ultimately determining the complete DNA sequence. Sequence-tagged site (STS) content mapping, coupled with large fragment cloning in yeast artificial chromosomes, provides an efficient mechanism for producing first-generation, low-resolution maps of human chromosomes. Previously, we produced a set of standardized STSs for human chromosome 11 regionally localized by fluorescence in situ hybridization or somatic cell hybrid analysis. In this paper, we used these as well as other STS content, and identify 109 islands spanning an estimated 218 Mb on the 126-Mb chromosome. Since about 62% of the islands contain markers ordered on chromosome 11 by genetic or radiation hybrid analysis, this data set represents a first-order approximation of a physical map of human chromosome 11. This set of clones, contigs, and associated STSs will provide the material for the production of a continuous overlapping set of YACs as well for high-resolution physical mapping based upon sampled and complete DNA sequencing.

Large-scale screening of yeast artificial chromosome libraries using PCR.

The construction of physical maps of the human genome using sequence-tagged site content mapping requires that thousands of PCR amplifications be performed. On this scale, measures to reduce cost and to increase throughput become serious considerations. We describe relatively simple measures developed in our laboratory that increase the rate at which these reactions can be performed in a cost-effective manner. These measures have been extensively tested in our laboratory and are readily applicable in other laboratories including those performing library screening on a more modest scale.

A sequence-tagged site map of human chromosome 11.

We report the construction of 370 sequence-tagged sites (STSs) that are detectable by PCR amplification under sets of standardized conditions and that have been regionally mapped to human chromosome 11. DNA sequences were determined by sequencing directly from cosmid templates using primers complementary to T3 and T7 promoters present in the cloning vector. Oligonucleotide PCR primers were predicted by computer and tested using a battery of genomic DNAs. Cosmids were regionally localized on chromosome 11 by using fluorescence in situ hybridization or by analyzing a somatic cell hybrid panel. Additional STSs corresponding to known genes and markers on chromosome 11 were also produced under the same series of standardized conditions. The resulting STSs provide uniform coverage of chromosome 11 with an average spacing of 340 kb. The DNA sequence determined for use in STS production corresponds to about 0.1% (116 kb) of chromosome 11 and has been analyzed for the presence of repetitive sequences, similarities to known genes and motifs, and possible exons. Computer analysis of this sequence has identified and therefore mapped at least eight new genes on chromosome 11.