Wolff D J, Gustashaw K M, Zurcher V, Ko L, White W, Weiss L, Van Dyke D L, Schwartz S, Willard H F
Center for Human Genetics Laboratories, Cleveland, Ohio 44106-9959, USA.
Hum Genet. 1997 Aug;100(2):256-61. doi: 10.1007/s004390050501.
High resolution cytogenetics, microsatellite marker analyses, and fluorescence in situ hybridization were used to define Xq deletions encompassing the fragile X gene, FMR1, detected in individuals from two unrelated families. In Family 1, a 19-year-old male had facial features consistent with fragile X syndrome; however, his profound mental and growth retardation, small testes, and lover limb skeletal defects and contractures demonstrated a more severe phenotype, suggestive of a contiguous gene syndrome. A cytogenetic deletion including Xq26.3-q27.3 was observed in the proband, his phenotypically normal mother, and his learning-disabled non-dysmorphic sister. Methylation analyses at the FMR1 and androgen receptor loci indicated that the deleted X was inactive in > 95% of his mother's white blood cells and 80-85% of the sister's leukocytes. The proximal breakpoint for the deletion was approximately 10 Mb centromeric to FMR1, and the distal breakpoint mapped 1 Mb distal to FMR1. This deletion, encompassing approximately 13 Mb of DNA, is the largest deletion including FMR1 reported to date. In the second family, a slightly smaller deletion was detected. A female with moderate to severe mental retardation, seizures, and hypothyroidism, had a de novo cytogenetic deletion extending from Xq26.3 to q27.3, which removed approximately 12 Mb of DNA around the FMR1 gene. Cytogenetic, and molecular data revealed that approximately 50% of her white blood cells contained an active deleted X. These findings indicate that males with deletions including Xq26.3-q27.3 may exhibit a more severe phenotype than typical fragile X males, and females with similar deletions may have an abnormal phenotype if the deleted X remains active in a significant proportion of the cells. Thus, important genes for intellectual and neurological development, in addition to FMR1, may reside in Xq26.3-q27.3. One candidate gene in this region, SOX3, is thought to be involved in neuronal development and its loss may partly explain the more severe phenotypes of our patients.
高分辨率细胞遗传学、微卫星标记分析和荧光原位杂交技术被用于确定在两个无血缘关系家庭的个体中检测到的包含脆性X基因(FMR1)的Xq缺失。在家庭1中,一名19岁男性具有与脆性X综合征一致的面部特征;然而,他严重的智力和生长发育迟缓、小睾丸以及下肢骨骼缺陷和挛缩表明其表型更为严重,提示存在一种相邻基因综合征。在先证者、其表型正常的母亲以及有学习障碍但无畸形的妹妹中观察到了包括Xq26.3 - q27.3的细胞遗传学缺失。FMR1和雄激素受体位点的甲基化分析表明,缺失的X在其母亲超过95%的白细胞以及妹妹80 - 85%的白细胞中是失活的。缺失的近端断点位于FMR1着丝粒约10 Mb处,远端断点位于FMR1远端1 Mb处。这个包含约13 Mb DNA的缺失是迄今为止报道的包含FMR1的最大缺失。在第二个家庭中,检测到一个稍小的缺失。一名患有中度至重度智力发育迟缓、癫痫和甲状腺功能减退的女性,有一个从Xq26.3延伸至q27.3的新发细胞遗传学缺失,该缺失在FMR1基因周围移除了约12 Mb的DNA。细胞遗传学和分子数据显示,她约50%的白细胞含有一个活跃的缺失X。这些发现表明,包含Xq26.3 - q27.3缺失的男性可能表现出比典型脆性X男性更严重的表型,而具有类似缺失的女性如果缺失的X在相当比例的细胞中保持活跃可能具有异常表型。因此,除了FMR1之外,智力和神经发育的重要基因可能位于Xq26.3 - q27.3。该区域的一个候选基因SOX3被认为参与神经元发育,其缺失可能部分解释了我们患者更严重的表型。
