Flejter W L, Fergestad J, Gorski J, Varvill T, Chandrasekharappa S
Department of Pediatrics, University of Utah, Salt Lake City, Utah, USA.
Am J Hum Genet. 1998 Sep;63(3):794-802. doi: 10.1086/302016.
The genetic mechanisms involved in sex differentiation are poorly understood, and progress in identification of the genes involved has been slow. The fortuitous finding of chromosomal rearrangements in association with a sex-reversed phenotype has led to the isolation of SRY and SOX9, both shown to be involved in the sex-determining pathway. In addition, duplications of the X chromosome, deletions of chromosomes 9 and 10, and translocations involving chromosome 17 have been reported to be associated with abnormal testicular differentiation, leading to male-to-female sex reversal in 46,XY individuals. We present the cytogenetic and molecular analyses of four sex-reversed XY females, each with gonadal dysgenesis and other variable malformations, and with terminal deletions of distal chromosome 9p, resulting from unbalanced autosomal translocations. PCR amplification and DNA sequence analysis of SRY revealed no mutations in the high-mobility-group domain (i.e., HMG box) in any of the four patients. Conventional and molecular cytogenetic analyses of metaphase chromosomes from each patient suggest that the smallest region of overlap (SRO) of deletions involves a very small region of distal band 9p24. Loss-of-heterozygosity studies using 17 highly polymorphic microsatellite markers, as well as FISH using YAC clones corresponding to the most distal markers on 9p, showed that the SRO lies distal to marker D9S1779. These results significantly narrow the putative sex-determining gene to the very terminal region of the short arm of chromosome 9.
人们对性别分化所涉及的遗传机制了解甚少,在确定相关基因方面进展缓慢。偶然发现与性反转表型相关的染色体重排,促使了SRY和SOX9的分离,二者均显示参与性别决定途径。此外,据报道,X染色体重复、9号和10号染色体缺失以及涉及17号染色体的易位与睾丸分化异常有关,导致46,XY个体发生男性向女性的性反转。我们展示了4例性反转XY女性的细胞遗传学和分子分析结果,她们均患有性腺发育不全及其他可变畸形,且因常染色体不平衡易位导致9号染色体短臂末端缺失。对SRY进行PCR扩增和DNA序列分析,结果显示这4例患者的高迁移率族结构域(即HMG盒)均未发生突变。对每位患者中期染色体进行常规和分子细胞遗传学分析表明,缺失的最小重叠区域(SRO)涉及9号染色体短臂末端24区的一个非常小的区域。使用17个高度多态性微卫星标记进行杂合性缺失研究,以及使用与9号染色体最末端标记对应的YAC克隆进行荧光原位杂交,结果表明SRO位于标记D9S1779的远端。这些结果将推测的性别决定基因显著缩小至9号染色体短臂的最末端区域。