胎儿性别发育及以后的经典遗传和激素转换

IF 0.8 4区 生物学 Q4 GENETICS & HEREDITY
Medizinische Genetik Pub Date : 2023-08-16 eCollection Date: 2023-09-01 DOI:10.1515/medgen-2023-2036
Paul-Martin Holterhus, Alexandra Kulle, Hauke Busch, Malte Spielmann
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引用次数: 0

摘要

摘要人类胎儿性别发育的关键基因和激素转换特征。它们对性腺性别决定以及随后生殖和体细胞性别表型的分化具有决定性作用。只有在最初的阶段,这些开关似乎表现得像计算机科学中的双0和1系统,并总是导致典型的男性或女性表型。最近的数据表明,这种模式是不够的。此外,在不同突变的情况下,这些开关中的许多可能会起到不同的作用,导致基因功能和剂量、酶活性、性激素水平和性激素敏感性的功能连续性改变,从而导致性发育生物学差异(DSD)的广泛临床范围,以及生殖器和体细胞性表型的潜在多样性。性腺原质最初是一个双能器官,可以发育成睾丸或卵巢。性别决定区Y(SRY)是性腺性别决定的最重要的上游开关,诱导SOX9进一步下游,导致睾丸支持细胞分化和卵巢途径的抑制。如果SRY不存在(实际上是“关闭”),e。 g.在46,XX雌性中,RSPO1、WNT4、FOXL2和其他因素抑制雄性途径并促进卵巢发育。睾酮及其更强效的衍生物二氢睾酮(DHT)和AMH是表型性别分化中最重要的上游激素转换。生殖器的男性化。 e.形成阴囊的外生殖器中线融合、生殖器结节的生长和Wolffian管的发育,是对睾丸中类固醇生成细胞合成的睾酮的反应。由于支持细胞产生的抗米勒激素(AMH),男性的米勒管不会发育成子宫和输卵管。这两种激素依赖性开关的功能由其相应的受体,细胞内雄激素受体(AR)和跨膜AMH II型受体来确保。缺乏高睾酮和高AMH对胎儿期女性生殖器官的解剖学发育至关重要。最近的技术进步,包括单细胞和空间转录组学,可能会对这些分子开关的性质有更多的了解。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Classic genetic and hormonal switches during fetal sex development and beyond.

Critical genetic and hormonal switches characterize fetal sex development in humans. They are decisive for gonadal sex determination and subsequent differentiation of the genital and somatic sex phenotype. Only at the first glace these switches seem to behave like the dual 0 and 1 system in computer sciences and lead invariably to either typically male or female phenotypes. More recent data indicate that this model is insufficient. In addition, in case of distinct mutations, many of these switches may act variably, causing a functional continuum of alterations of gene functions and -dosages, enzymatic activities, sex hormone levels, and sex hormone sensitivity, giving rise to a broad clinical spectrum of biological differences of sex development (DSD) and potentially diversity of genital and somatic sex phenotypes. The gonadal anlage is initially a bipotential organ that can develop either into a testis or an ovary. Sex-determining region Y (SRY) is the most important upstream switch of gonadal sex determination inducing SOX9 further downstream, leading to testicular Sertoli cell differentiation and the repression of ovarian pathways. If SRY is absent (virtually "switched off"), e. g., in 46,XX females, RSPO1, WNT4, FOXL2, and other factors repress the male pathway and promote ovarian development. Testosterone and its more potent derivative, dihydrotestosterone (DHT) as well as AMH, are the most important upstream hormonal switches in phenotypic sex differentiation. Masculinization of the genitalia, i. e., external genital midline fusion forming the scrotum, growth of the genital tubercle, and Wolffian duct development, occurs in response to testosterone synthesized by steroidogenic cells in the testis. Müllerian ducts will not develop into a uterus and fallopian tubes in males due to Anti-Müllerian-Hormone (AMH) produced by the Sertoli cells. The functionality of these two hormone-dependent switches is ensured by their corresponding receptors, the intracellular androgen receptor (AR) and the transmembrane AMH type II receptor. The absence of high testosterone and high AMH is crucial for anatomically female genital development during fetal life. Recent technological advances, including single-cell and spatial transcriptomics, will likely shed more light on the nature of these molecular switches.

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来源期刊
Medizinische Genetik
Medizinische Genetik Medicine-Genetics (clinical)
CiteScore
1.40
自引率
9.10%
发文量
48
审稿时长
>12 weeks
期刊介绍: medizinischegenetik is a scientific journal that is owned and published by the German Society of Human Genetics e.V. since 1989. The journal was founded by Prof. Jan Murken, München. Self-published until 2006, from 2007-2019 published at Springer Verlag and since 2020 at De Gruyter. medizinischegenetik serves education and training among colleagues, the interdisciplinary exchange of knowledge in all areas of human genetics in clinics, practice, research and teaching. Each issue of the quarterly journal deals with a focus that provides a comprehensive overview of current developments in specific clinical pictures, technical developments and therapeutic approaches. All reviews are written in English language. The journal thus creates a platform for the international exchange of knowledge and increased awareness of German research activities in the scientific community. In addition, medizinischegenetik contains information on activities in its own subject in the German-language section. This includes conference reports, association announcements, personnel matters, statements and guidelines. With health policy questions, historical retrospectives and comments on current developments, the profession takes a stand on human genetic issues in Germany, Austria and Switzerland.
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