Hoopes Richard R, Middleton Frank A, Sen Saunak, Hueber Paul A, Reid Robert, Bushinsky David A, Scheinman Steven J
Department of Medicine, SUNY Upstate Medical University, 750 E. Adams Street, Syracuse, NY 13210, USA.
J Am Soc Nephrol. 2006 May;17(5):1292-304. doi: 10.1681/ASN.2005080828. Epub 2006 Apr 12.
Hypercalciuria is the most common risk factor for kidney stones and has a substantial genetic component. The genetic hypercalciuric stone-forming (GHS) rat model displays complex changes in physiology involving intestine, bone, and kidney and overexpression of the vitamin D receptor, thereby reproducing the human phenotype of idiopathic hypercalciuria. Through quantitative trait locus (QTL) mapping of rats that were bred from GHS female rats and normocalciuric Wistar Kyoto (WKY) male rats, loci that are linked to hypercalciuria and account for a 6 to eight-fold phenotypic difference between the GHS and WKY progenitors were mapped. GHS x WKY rats were backcrossed to breed for congenic rats with the chromosome 1 QTL HC1 on a normocalciuric WKY background. Ten generations of backcrosses produced N10F1 rats, which were intercrossed to produce rats that were homozygous for GHS loci in the HC1 region between markers D1Mit2 and D1Mit32. On a high-calcium diet (1.2% calcium), significantly different levels of calcium excretion were found between male congenic (1.67 +/- 0.71 mg/24 h) and male WKY control rats (0.78 +/- 0.19 mg/24 h) and between female congenic (3.11 +/- 0.90 mg/24 h) and female WKY controls (2.11 +/- 0.50 mg/24 h); the congenics preserve the calcium excretion phenotype of the GHS parent strain. Microarray expression analyses of the congenic rats, compared with WKY rats, showed that of the top 100 most changed genes, twice as many as were statistically expected mapped to chromosome 1. Of these, there is a clear bias in gene expression change for genes in the region of the HC1. Of >1100 gene groups analyzed, one third of the 50 most differentially expressed gene groups have direct or secondary action on calcium metabolism or transport. This is the first QTL for hypercalciuria to be isolated in a congenic animal.
高钙尿症是肾结石最常见的危险因素,且具有很大的遗传成分。遗传性高钙尿结石形成(GHS)大鼠模型表现出涉及肠道、骨骼和肾脏的复杂生理变化以及维生素D受体的过表达,从而再现了特发性高钙尿症的人类表型。通过对由GHS雌性大鼠和正常钙尿的Wistar Kyoto(WKY)雄性大鼠培育的大鼠进行数量性状基因座(QTL)定位,定位了与高钙尿症相关且导致GHS和WKY亲代之间表型差异6至8倍的基因座。将GHS×WKY大鼠回交,以培育在正常钙尿的WKY背景下带有1号染色体QTL HC1的近交系大鼠。经过十代回交产生了N10F1大鼠,将其进行杂交以产生在标记D1Mit2和D1Mit32之间的HC1区域中GHS基因座纯合的大鼠。在高钙饮食(钙含量为1.2%)条件下,发现雄性近交系大鼠(1.67±0.71mg/24h)与雄性WKY对照大鼠(0.78±0.19mg/24h)之间以及雌性近交系大鼠(3.11±0.90mg/24h)与雌性WKY对照大鼠(2.11±0.50mg/24h)之间的钙排泄水平存在显著差异;近交系大鼠保留了GHS亲代品系的钙排泄表型。与WKY大鼠相比,对近交系大鼠进行的微阵列表达分析表明,在变化最大的前100个基因中,按统计学预期映射到1号染色体上的基因数量是其两倍。其中,HC1区域的基因在基因表达变化上存在明显偏差。在分析的1100多个基因组中,50个差异表达最显著的基因组中有三分之一对钙代谢或转运具有直接或间接作用。这是在近交系动物中分离出的首个高钙尿症QTL。
