BACKGROUND: Linkage studies alone do not produce sufficient resolution to narrow the location of a quantitative trait locus (QTL) to a small-enough chromosomal region for gene identification. One solution to this problem is to use interval-specific congenic recombinant (ISCR) lines to narrow the chromosomal interval known to contain the QTL. In previous work, we mapped four QTLs for differential ethanol sensitivity in the inbred long-sleep (ILS) and inbred short-sleep (ISS) strains and generated reciprocal congenic strains in which each full QTL interval from ILS was bred onto the ISS background and vice versa. METHODS: ISCR lines were derived by identifying mice carrying recombination events in the congenic interval during backcrossing of the ISS.ILS.Lore congenics to ISS. Recombinant mice were backcrossed to ISS, and progeny carrying the ISCR chromosome were identified and tested to determine whether the ISCR region carried the donor Lore QTL. RESULTS: We developed multiple ISCR lines for each Lore QTL, in which the QTL interval was broken into a number of smaller intervals. For all four QTLs, we reduced the size of the interval, in one case to 3.7 cM. CONCLUSIONS: Use of ISCR lines can narrow each Lore candidate region to a few centimorgans. Such an interval size is conducive to brute-force approaches to identify candidate genes, entailing bioinformatics, gene expression, and DNA sequencing strategies.
BACKGROUND: Linkage studies alone do not produce sufficient resolution to narrow the location of a quantitative trait locus (QTL) to a small-enough chromosomal region for gene identification. One solution to this problem is to use interval-specific congenic recombinant (ISCR) lines to narrow the chromosomal interval known to contain the QTL. In previous work, we mapped four QTLs for differential ethanol sensitivity in the inbred long-sleep (ILS) and inbred short-sleep (ISS) strains and generated reciprocal congenic strains in which each full QTL interval from ILS was bred onto the ISS background and vice versa. METHODS: ISCR lines were derived by identifying mice carrying recombination events in the congenic interval during backcrossing of the ISS.ILS.Lore congenics to ISS. Recombinant mice were backcrossed to ISS, and progeny carrying the ISCR chromosome were identified and tested to determine whether the ISCR region carried the donor Lore QTL. RESULTS: We developed multiple ISCR lines for each Lore QTL, in which the QTL interval was broken into a number of smaller intervals. For all four QTLs, we reduced the size of the interval, in one case to 3.7 cM. CONCLUSIONS: Use of ISCR lines can narrow each Lore candidate region to a few centimorgans. Such an interval size is conducive to brute-force approaches to identify candidate genes, entailing bioinformatics, gene expression, and DNA sequencing strategies.
Authors: Oduola Abiola; Joe M Angel; Philip Avner; Alexander A Bachmanov; John K Belknap; Beth Bennett; Elizabeth P Blankenhorn; David A Blizard; Valerie Bolivar; Gundrun A Brockmann; Kari J Buck; Jean-Francoise Bureau; William L Casley; Elissa J Chesler; James M Cheverud; Gary A Churchill; Melloni Cook; John C Crabbe; Wim E Crusio; Ariel Darvasi; Gerald de Haan; Peter Dermant; R W Doerge; Rosemary W Elliot; Charles R Farber; Lorraine Flaherty; Jonathan Flint; Howard Gershenfeld; John P Gibson; Jing Gu; Weikuan Gu; Heinz Himmelbauer; Robert Hitzemann; Hui-Chen Hsu; Kent Hunter; Fuad F Iraqi; Ritsert C Jansen; Thomas E Johnson; Byron C Jones; Gerd Kempermann; Frank Lammert; Lu Lu; Kenneth F Manly; Douglas B Matthews; Juan F Medrano; Margarete Mehrabian; Guy Mittlemann; Beverly A Mock; Jeffrey S Mogil; Xavier Montagutelli; Grant Morahan; John D Mountz; Hiroki Nagase; Richard S Nowakowski; Bruce F O'Hara; Alexander V Osadchuk; Beverly Paigen; Abraham A Palmer; Jeremy L Peirce; Daniel Pomp; Michael Rosemann; Glenn D Rosen; Leonard C Schalkwyk; Ze'ev Seltzer; Stephen Settle; Kazuhiro Shimomura; Siming Shou; James M Sikela; Linda D Siracusa; Jimmy L Spearow; Cory Teuscher; David W Threadgill; Linda A Toth; Ayo A Toye; Csaba Vadasz; Gary Van Zant; Edward Wakeland; Robert W Williams; Huang-Ge Zhang; Fei Zou Journal: Nat Rev Genet Date: 2003-11 Impact factor: 53.242
Authors: L S Wang; Y Jiao; Y Huang; X Y Liu; G Gibson; B Bennett; K M Hamre; D W Li; H Y Zhao; J Gelernter; H R Kranzler; L A Farrer; L Lu; Y J Wang; W K Gu Journal: Genet Mol Res Date: 2013-11-26
Authors: Laura Dumas; C Michael Dickens; Nathan Anderson; Jonathan Davis; Beth Bennett; Richard A Radcliffe; James M Sikela Journal: Mamm Genome Date: 2014-02-20 Impact factor: 2.957