An SNP map of human chromosome 22

James C. Mullikin; Sarah Hunt; Charlotte G. Cole; Beverley Mortimore; Catherine M. Rice; J.H. Burton; Lucy Matthews; Rebecca Pavitt; R. W. Plumb; Sarah Sims; R. Ainscough; J. Attwood; J. Bailey; K. F. Barlow; Richard Bruskiewich; P. N. Butcher; Emma Carter; Y. Chen; Chris M. Clee; Penny Coggill; J. Davies; Robert M. Davies; Elisabeth Dawson; Matthew D. Francis; A. A. Joy; R. G. Lamble; Cordelia F. Langford; J. Macarthy; V. Mall; A. Moreland; E. K. Overton-Larty; M. T. Ross; Lauren Smith; Charles A. Steward; John Sulston; Emma Tinsley; K. J. Turney; David L. Willey; Greer Wilson; Amanda A. McMurray; Ian Dunham; Jane Rogers; D. R. Bentley

doi:10.1038/35035089

An SNP map of human chromosome 22

James C. Mullikin(Wellcome Sanger Institute), Sarah Hunt(Wellcome Sanger Institute), Charlotte G. Cole(Wellcome Sanger Institute), Beverley Mortimore(Wellcome Sanger Institute), Catherine M. Rice(Wellcome Sanger Institute), J.H. Burton(Wellcome Sanger Institute), Lucy Matthews(Wellcome Sanger Institute), Rebecca Pavitt(Wellcome Sanger Institute), R. W. Plumb(Wellcome Sanger Institute), Sarah Sims(Wellcome Sanger Institute), R. Ainscough(Wellcome Sanger Institute), J. Attwood(Wellcome Sanger Institute), J. Bailey(Wellcome Sanger Institute), K. F. Barlow(Wellcome Sanger Institute), Richard Bruskiewich(Wellcome Sanger Institute), P. N. Butcher(Wellcome Sanger Institute), Emma Carter(Wellcome Sanger Institute), Y. Chen(Wellcome Sanger Institute), Chris M. Clee(Wellcome Sanger Institute), Penny Coggill(Wellcome Sanger Institute), J. Davies(Wellcome Sanger Institute), Robert M. Davies(Wellcome Sanger Institute), Elisabeth Dawson(Wellcome Sanger Institute), Matthew D. Francis(Wellcome Trust), A. A. Joy(Wellcome Trust), R. G. Lamble(Wellcome Trust), Cordelia F. Langford(Wellcome Trust), J. Macarthy(Wellcome Trust), V. Mall(Wellcome Trust), A. Moreland(Wellcome Trust), E. K. Overton-Larty(Wellcome Trust), M. T. Ross(Wellcome Trust), Lauren Smith(Wellcome Trust), Charles A. Steward(Wellcome Trust), John Sulston(Wellcome Trust), Emma Tinsley(Wellcome Trust), K. J. Turney(Wellcome Trust), David L. Willey(Wellcome Trust), Greer Wilson(Wellcome Trust), Amanda A. McMurray(Wellcome Trust), Ian Dunham(Wellcome Trust), Jane Rogers(Wellcome Trust), D. R. Bentley(Wellcome Trust)

Nature

September 1, 2000

10.1038/35035089

Cited by 152Open Access

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Abstract

The human genome sequence will provide a reference for measuring DNA sequence variation in human populations. Sequence variants are responsible for the genetic component of individuality, including complex characteristics such as disease susceptibility and drug response. Most sequence variants are single nucleotide polymorphisms (SNPs), where two alternate bases occur at one position. Comparison of any two genomes reveals around 1 SNP per kilobase. A sufficiently dense map of SNPs would allow the detection of sequence variants responsible for particular characteristics on the basis that they are associated with a specific SNP allele. Here we have evaluated large-scale sequencing approaches to obtaining SNPs, and have constructed a map of 2,730 SNPs on human chromosome 22. Most of the SNPs are within 25 kilobases of a transcribed exon, and are valuable for association studies. We have scaled up the process, detecting over 65,000 SNPs in the genome as part of The SNP Consortium programme, which is on target to build a map of 1 SNP every 5 kilobases that is integrated with the human genome sequence and that is freely available in the public domain.

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