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全基因组从头测序揭示了与 SRY 阴性猪性别发育差异相关的基因组变异。

Whole-genome de novo sequencing reveals genomic variants associated with differences of sex development in SRY negative pigs.

机构信息

Guangdong Provincial Key Laboratory of Animal Molecular Design and Precise Breeding, School of Life Science and Engineering, Foshan University, Foshan, 528255, P.R. China.

出版信息

Biol Sex Differ. 2024 Sep 2;15(1):68. doi: 10.1186/s13293-024-00644-w.

DOI:10.1186/s13293-024-00644-w
PMID:39223676
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC11367908/
Abstract

BACKGROUND

Differences of sex development (DSD) are congenital conditions in which chromosomal, gonadal, or phenotypic sex is atypical. In more than 50% of human DSD cases, a molecular diagnosis is not available. In intensively farmed pig populations, the incidence of XX DSD pigs is relatively high, leading to economic losses for pig breeders. Interestingly, in the majority of 38, XX DSD pigs, gonads still develop into testis-like structures or ovotestes despite the absence of the testis-determining gene (SRY). However, the current understanding of the molecular background of XX DSD pigs remains limited.

METHODS

Anatomical and histological characteristics of XX DSD pigs were analysed using necropsy and HE staining. We employed whole-genome sequencing (WGS) with 10× Genomics technology and used de novo assembly methodology to study normal female and XX DSD pigs. Finally, the identified variants were validated in 32 XX DSD pigs, and the expression levels of the candidate variants in the gonads of XX DSD pigs were further examined.

RESULTS

XX DSD pigs are characterised by the intersex reproductive organs and the absence of germ cells in the seminiferous tubules of the gonads. We identified 4,950 single-nucleotide polymorphisms (SNPs) from non-synonymous mutations in XX DSD pigs. Cohort validation results highlighted two specific SNPs, "c.218T > C" in the "Interferon-induced transmembrane protein 1 gene (IFITM1)" and "c.1043C > G" in the "Newborn ovary homeobox gene (NOBOX)", which were found exclusively in XX DSD pigs. Moreover, we verified 14 candidate structural variants (SVs) from 1,474 SVs, identifying a 70 bp deletion fragment in intron 5 of the WW domain-containing oxidoreductase gene (WWOX) in 62.5% of XX DSD pigs. The expression levels of these three candidate genes in the gonads of XX DSD pigs were significantly different from those of normal female pigs.

CONCLUSION

The nucleotide changes of IFITM1 (c.218T > C), NOBOX (c.1043 C > G), and a 70 bp deletion fragment of the WWOX were the most dominant variants among XX DSD pigs. This study provides a theoretical basis for better understanding the molecular background of XX DSD pigs. DSD are conditions affecting development of the gonads or genitalia. These disorders can happen in many different types of animals, including pigs, goats, dogs, and people. In people, DSD happens in about 0.02-0.13% of births, and in pigs, the rate is between 0.08% and 0.75%. Pigs have a common type of DSD where the animal has female chromosomes (38, XX) but no SRY gene, which is usually found on the Y chromosome in males. XX DSD pigs may look like both males and females on the outside and have testis-like or ovotestis (a mix of ovary and testis) gonads inside. XX DSD pigs often lead to not being able to have piglets, slower growth, lower chance of survival, and poorer meat quality. Here, we used a method called whole-genome de novo sequencing to look for variants in the DNA of XX DSD pigs. We then checked these differences in a larger group of pigs. Our results reveal the nucleotide changes in IFITM1 (c.218T > C), NOBOX (c.1043 C > G), and a 70 bp deletion fragment in intron 5 of the WWOX, all linked to XX DSD pigs. The expression levels of these three genes were also different in the gonads of XX DSD pigs compared to normal female pigs. These variants are expected to serve as valuable molecular markers for XX DSD pigs. Because pigs are a lot like humans in their genes, physiology, and body structure, this research could help us learn more about what causes DSD in people.

摘要

背景

性发育障碍(DSD)是一种先天性疾病,其染色体、性腺或表型性别异常。在超过 50%的人类 DSD 病例中,无法进行分子诊断。在集约化养殖的猪群中,XX 型 DSD 猪的发病率相对较高,给猪养殖户带来经济损失。有趣的是,在大多数 38, XX DSD 猪中,尽管睾丸决定基因(SRY)缺失,但性腺仍发育成睾丸样结构或卵睾。然而,目前对 XX DSD 猪的分子背景了解有限。

方法

采用大体解剖和 HE 染色分析 XX DSD 猪的解剖和组织学特征。我们使用 10×Genomics 技术进行全基因组测序(WGS),并采用从头组装方法研究正常雌性和 XX DSD 猪。最后,在 32 头 XX DSD 猪中验证了鉴定出的变异,并进一步研究了候选变异在 XX DSD 猪性腺中的表达水平。

结果

XX DSD 猪的特征为两性生殖器官,性腺生精小管内无生殖细胞。我们从 XX DSD 猪的非同义突变中鉴定出 4950 个单核苷酸多态性(SNP)。XX DSD 猪的队列验证结果突出了两个特定的 SNP,即“Interferon-induced transmembrane protein 1 gene (IFITM1)”中的“c.218T > C”和“Newborn ovary homeobox gene (NOBOX)”中的“c.1043C > G”,这两个 SNP 仅在 XX DSD 猪中发现。此外,我们从 1474 个 SV 中验证了 14 个候选结构变异(SV),在 62.5%的 XX DSD 猪中发现了 WW 结构域包含氧化还原酶基因(WWOX)第 5 内含子中的 70 bp 缺失片段。XX DSD 猪性腺中这三个候选基因的表达水平与正常雌性猪明显不同。

结论

IFITM1(c.218T > C)、NOBOX(c.1043C > G)和 WWOX 第 5 内含子中的 70 bp 缺失片段的核苷酸变化是 XX DSD 猪中最主要的变异。本研究为更好地了解 XX DSD 猪的分子背景提供了理论依据。性发育障碍是影响性腺或生殖器发育的疾病。这些疾病在许多不同类型的动物中都会发生,包括猪、山羊、狗和人。在人群中,DSD 的发生率约为 0.02-0.13%,而在猪中,发生率在 0.08%到 0.75%之间。猪有一种常见的 DSD 类型,即动物具有女性染色体(38,XX)但没有通常在男性 Y 染色体上发现的 SRY 基因。XX DSD 猪可能在外表上看起来像男性和女性,内部有睾丸样或卵睾(卵巢和睾丸的混合物)性腺。XX DSD 猪通常会导致无法产仔、生长缓慢、存活率低和肉质差。在这里,我们使用了一种称为全基因组从头测序的方法来寻找 XX DSD 猪 DNA 中的变异。然后,我们在更大的猪群中检查了这些差异。我们的结果揭示了 IFITM1(c.218T > C)、NOBOX(c.1043C > G)和 WWOX 第 5 内含子中的 70 bp 缺失片段中的核苷酸变化与 XX DSD 猪有关。与正常雌性猪相比,这三个基因在 XX DSD 猪性腺中的表达水平也不同。这些变体有望成为 XX DSD 猪的有价值的分子标记。由于猪在基因、生理和身体结构上与人类非常相似,因此这项研究可以帮助我们更多地了解人类 DSD 的原因。

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https://cdn.ncbi.nlm.nih.gov/pmc/blobs/c3e0/11367908/ecf7527bf9c9/13293_2024_644_Fig5_HTML.jpg
https://cdn.ncbi.nlm.nih.gov/pmc/blobs/c3e0/11367908/37f2ebaa8ed6/13293_2024_644_Fig6_HTML.jpg
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