Turner syndrome masquerading as normal early puberty

Females with Turner's syndrome (TS) are at an increased risk of developing autoimmune thyroid disease. Studies assessing the influence of karyotype on thyroid autoimmunity in adults with TS have yielded conflicting results but have been limited by small numbers. The aim of this study was to determine the frequency of thyroid autoimmunity in a large cohort of women with TS and to assess the influence of karyotype on the development of thyroid disease. Data were available for 145 women with TS attending a dedicated adult Turner clinic. The mean age was 26 years (range 16-52 years). Information regarding the presence of thyroid disease, karyotype, thyroid autoantibodies and thyroid function was recorded in all. The chi-squared test with Yates' correction was used to assess the association between karyotype and thyroid autoimmunity. Forty-one per cent of women with TS had positive thyroid autoantibodies and 16% of women were hypothyroid on replacement therapy with thyroxine. However, 83% of women with an X-isochromosome had positive thyroid autoantibodies compared with 33% of women with other karyotypes (P < 0.0001). Women with an isochromosome-X karyotype were also significantly more likely to become frankly hypothyroid and require thyroxine compared with other karyotypes (37.5% isochromosome-X vs. 14% 45, X vs. 6% other karyotypes P = 0.0034). In this large cohort of women with TS we have shown that the risk of developing autoimmune thyroid disease is particularly high in women with an X-isochromosome, suggesting that a gene on the long arm of the X chromosome (Xq) may play an important pathogenetic role in the development of autoimmune thyroid disease.

Ovarian failure can result from several different genetic mechanisms-X chromosomal abnormalities, autosomal recessive genes causing various types of XX gonadal dysgenesis, and autosomal dominant genes. The number and precise location of loci on the X are still under investigation, but it is clear that, in aggregate, these genes are responsible for ovarian maintenance, given that monosomy X shows germ cells that undergo accelerated atresia. Despite recent hypotheses, at present there is no evidence for a gene directing primary ovarian differentiation; this process may be constitutive. Phenotypic/karyotypic correlation and limited molecular confirmation have long shown that proximal Xp and proximal Xq contain regions of the most importance to ovarian maintenance. Terminal deletions at Xp11 result in 50% primary amenorrhea and 50% premature ovarian failure or fertility. Deletions at Xq13 usually produce primary amenorrhea. Terminal deletions nearer the telomeres on either Xp of Xq bring about premature ovarian failure more often than complete ovarian failure. The X-linked zinc finger gene (ZFX) and diaphanous 2 Drosophila homologue (DIAPH2) are the only candidate genes for ovarian maintenance that map to the X chromosome. Additional, as yet unidentified, genes along the X chromosome must be involved. The search for these genes in humans is hampered by the lack of candidate genes that map to the X chromosome, the scarcity of patients with fortuitous autosomal translocations, and small pedigrees, which hinder mapping of the loci. In addition, difficulties with human germ cell research also make it challenging to dissect genes important to ovarian development. Autosomal genes also are involved in ovarian differentiation and gonadal failure. Follicle-stimulating hormone receptor and ataxia telangiectasia are examples of autosomal genes known to cause human ovarian failure. Transgenic mouse models point to many other candidate autosomal genes, and sequencing of the human homologues in affected women should lead to the discovery of new genes responsible for human ovarian failure. Identification, functional analysis, and mapping of novel genes specifically expressed in the ovary of mice and women eventually should lead to fruitful dissection of essential genes in mammalian ovarian development and maintenance. Copyright 2000 Wiley-Liss, Inc.