Mesomelia-synostoses syndrome: contiguous deletion syndrome, SULF1 haploinsufficiency or enhancer adoption?

IF 1.3 4区生物学 Q4 GENETICS & HEREDITY

Molecular Cytogenetics Pub Date : 2024-07-12 DOI:10.1186/s13039-024-00684-2

Ingrid Bendas Feres Lima, Lúcia de Fátima Marques de Moraes, Carlos Roberto da Fonseca, Juan Clinton Llerena Junior, Mana Mehrjouy, Niels Tommerup, Elenice Ferreira Bastos

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引用次数: 0

Abstract

Background: Mesomelia-Synostoses Syndrome (MSS)(OMIM 600,383) is a rare autosomal dominant disorder characterized by mesomelic limb shortening, acral synostoses and multiple congenital malformations which is described as a contiguous deletion syndrome involving the two genes SULF1 and SLCO5A1. The study of apparently balanced chromosomal rearrangements (BCRs) is a cytogenetic strategy used to identify candidate genes associated with Mendelian diseases or abnormal phenotypes. With the improved development of genomic technologies, new methods refine this search, allowing better delineation of breakpoints as well as more accurate genotype-phenotype correlation.

Case presentation: We present a boy with a global development deficit, delayed speech development and an ASD (Asperger) family history, with an apparently balanced "de novo" reciprocal translocation [t(1;8)(p32.2;q13)dn]. The cytogenetic molecular study identified a likely pathogenic deletion of 21 kb in the 15q12 region, while mate pair sequencing identified gene-truncations at both the 1p32.2 and 8q13 translocation breakpoints.

Conclusions: The identification of a pathogenic alteration on 15q12 involving GABRA5 was likely the main cause of the ASD-phenotype. Importantly, the chr8 translocation breakpoint truncating SLCO5A1 exclude SLCO5A1 as a candidate for MSS, leaving SULF1 as the primary candidate. However, the deletions observed in MSS remove a topological associated domain (TAD) boundary separating SULF1 and SLCO5A1. Hence, Mesomelia-Synostoses syndrome is either caused by haploinsufficiency of SULF1 or ectopic enhancer effects where skeletal/chrondrogenic SULF1 enhancers drive excopic expression of developmental genes in adjacent TADs including PRDM14, NCOA2 and/or EYA1.

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间畸形-发育不全综合征：连续缺失综合征、SULF1单倍体缺陷还是增强子通过？

背景：中胚层畸形-突触综合征（MSS）（OMIM 600,383）是一种罕见的常染色体显性遗传疾病，以中胚层肢体短缩、尖突和多发性先天畸形为特征，被描述为涉及两个基因 SULF1 和 SLCO5A1 的连续缺失综合征。研究明显的平衡染色体重排（BCR）是一种细胞遗传学策略，用于鉴定与孟德尔疾病或异常表型相关的候选基因。随着基因组学技术的不断发展，新的方法完善了这一研究，从而可以更好地划分断点，并更准确地确定基因型与表型之间的相关性：病例介绍：我们接诊了一名患有全身发育缺陷、语言发育迟缓和 ASD（阿斯伯格）家族史的男孩，他患有明显平衡的 "从头 "互易位[t(1;8)(p32.2;q13)dn]。细胞遗传学分子研究确定了 15q12 区域 21 kb 的可能致病性缺失，而配对测序则确定了 1p32.2 和 8q13 易位断点的基因截断：结论：15q12上涉及GABRA5的致病性改变很可能是导致ASD表型的主要原因。重要的是，截断 SLCO5A1 的 chr8 易位断点排除了 SLCO5A1 作为 MSS 候选者的可能性，因此 SULF1 成为主要候选者。然而，在中脊髓侧索硬化症中观察到的缺失消除了将 SULF1 和 SLCO5A1 分隔开来的拓扑相关域（TAD）边界。因此，间畸形-发育不全综合征要么是由 SULF1 单倍体缺乏引起的，要么是由骨骼/软骨基因 SULF1 增强子驱动相邻 TAD（包括 PRDM14、NCOA2 和/或 EYA1）中发育基因异位表达的异位增强子效应引起的。

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来源期刊

Molecular Cytogenetics GENETICS & HEREDITY-

CiteScore

2.60

自引率

7.70%

发文量

审稿时长

>12 weeks

期刊介绍： Molecular Cytogenetics encompasses all aspects of chromosome biology and the application of molecular cytogenetic techniques in all areas of biology and medicine, including structural and functional organization of the chromosome and nucleus, genome variation, expression and evolution, chromosome abnormalities and genomic variations in medical genetics and tumor genetics. Molecular Cytogenetics primarily defines a large set of the techniques that operate either with the entire genome or with specific targeted DNA sequences. Topical areas include, but are not limited to: -Structural and functional organization of chromosome and nucleus- Genome variation, expression and evolution- Animal and plant molecular cytogenetics and genomics- Chromosome abnormalities and genomic variations in clinical genetics- Applications in preimplantation, pre- and post-natal diagnosis- Applications in the central nervous system, cancer and haematology research- Previously unreported applications of molecular cytogenetic techniques- Development of new techniques or significant enhancements to established techniques. This journal is a source for numerous scientists all over the world, who wish to improve or introduce molecular cytogenetic techniques into their practice.