Adrian F. Daly, Leslie A. Dunnington, David F. Rodriguez-Buritica, Erica Spiegel, Francesco Brancati, Giovanna Mantovani, Vandana M. Rawal, Fabio Rueda Faucz, Hadia Hijazi, Jean-Hubert Caberg, Anna Maria Nardone, Mario Bengala, Paola Fortugno, Giulia Del Sindaco, Marta Ragonese, Helen Gould, Salvatore Cannavò, Patrick Pétrossians, Andrea Lania, James R. Lupski, Albert Beckers, Constantine A. Stratakis, Brynn Levy, Giampaolo Trivellin, Martin Franke
{"title":"临床中的染色质构象捕获:4C-seq/HiC区分GPR101基因座上的致病性重复和中性重复","authors":"Adrian F. Daly, Leslie A. Dunnington, David F. Rodriguez-Buritica, Erica Spiegel, Francesco Brancati, Giovanna Mantovani, Vandana M. Rawal, Fabio Rueda Faucz, Hadia Hijazi, Jean-Hubert Caberg, Anna Maria Nardone, Mario Bengala, Paola Fortugno, Giulia Del Sindaco, Marta Ragonese, Helen Gould, Salvatore Cannavò, Patrick Pétrossians, Andrea Lania, James R. Lupski, Albert Beckers, Constantine A. Stratakis, Brynn Levy, Giampaolo Trivellin, Martin Franke","doi":"10.1186/s13073-024-01378-5","DOIUrl":null,"url":null,"abstract":"X-linked acrogigantism (X-LAG; MIM: 300942) is a severe form of pituitary gigantism caused by chromosome Xq26.3 duplications involving GPR101. X-LAG-associated duplications disrupt the integrity of the topologically associating domain (TAD) containing GPR101 and lead to the formation of a neo-TAD that drives pituitary GPR101 misexpression and gigantism. As X-LAG is fully penetrant and heritable, duplications involving GPR101 identified on prenatal screening studies, like amniocentesis, can pose an interpretation challenge for medical geneticists and raise important concerns for patients and families. Therefore, providing robust information on the functional genomic impact of such duplications has important research and clinical value with respect to gene regulation and triplosensitivity traits. We employed 4C/HiC-seq as a clinical tool to determine the functional impact of incidentally discovered GPR101 duplications on TAD integrity in three families. After defining duplications and breakpoints around GPR101 by clinical-grade and high-density aCGH, we constructed 4C/HiC chromatin contact maps for our study population and compared them with normal and active (X-LAG) controls. We showed that duplications involving GPR101 that preserved the centromeric invariant TAD boundary did not generate a pathogenic neo-TAD and that ectopic enhancers were not adopted. This allowed us to discount presumptive/suspected X-LAG diagnoses and GPR101 misexpression, obviating the need for intensive clinical follow-up. 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Rawal, Fabio Rueda Faucz, Hadia Hijazi, Jean-Hubert Caberg, Anna Maria Nardone, Mario Bengala, Paola Fortugno, Giulia Del Sindaco, Marta Ragonese, Helen Gould, Salvatore Cannavò, Patrick Pétrossians, Andrea Lania, James R. Lupski, Albert Beckers, Constantine A. Stratakis, Brynn Levy, Giampaolo Trivellin, Martin Franke\",\"doi\":\"10.1186/s13073-024-01378-5\",\"DOIUrl\":null,\"url\":null,\"abstract\":\"X-linked acrogigantism (X-LAG; MIM: 300942) is a severe form of pituitary gigantism caused by chromosome Xq26.3 duplications involving GPR101. X-LAG-associated duplications disrupt the integrity of the topologically associating domain (TAD) containing GPR101 and lead to the formation of a neo-TAD that drives pituitary GPR101 misexpression and gigantism. 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引用次数: 0
摘要
X-LAG(X-linked acrogigantism;MIM:300942)是一种严重的垂体巨幼症,由涉及 GPR101 的染色体 Xq26.3 重复所引起。X-LAG相关复制破坏了含有GPR101的拓扑关联结构域(TAD)的完整性,并导致新TAD的形成,从而驱动垂体GPR101表达异常和巨人症。由于X-LAG具有全透性和遗传性,在羊膜腔穿刺术等产前筛查研究中发现的涉及GPR101的重复可能会给医学遗传学家带来解释上的挑战,并引起患者和家属的极大关注。因此,提供有关此类重复的功能基因组影响的可靠信息,对于基因调控和三重敏感性特征具有重要的研究和临床价值。我们利用 4C/HiC-seq 作为临床工具,确定了在三个家族中偶然发现的 GPR101 基因重复对 TAD 完整性的功能影响。通过临床级高密度 aCGH 确定了 GPR101 周围的重复和断点后,我们为研究人群构建了 4C/HiC 染色质接触图,并将其与正常对照和活性(X-LAG)对照进行了比较。我们发现,涉及 GPR101 的复制保留了中心粒不变的 TAD 边界,但并没有产生致病的新 TAD,也没有采用异位增强子。这使我们能够排除推定/疑似 X-LAG 诊断和 GPR101 表达异常,从而无需进行深入的临床随访。这项研究强调了 TAD 边界和染色质相互作用在确定拷贝数变异的功能影响方面的重要性,并为使用 4C/HiC-seq 作为临床工具提供了概念验证,以便为遗传咨询获取关键信息,并为疑似 TAD 病例的临床决策提供支持。
Chromatin conformation capture in the clinic: 4C-seq/HiC distinguishes pathogenic from neutral duplications at the GPR101 locus
X-linked acrogigantism (X-LAG; MIM: 300942) is a severe form of pituitary gigantism caused by chromosome Xq26.3 duplications involving GPR101. X-LAG-associated duplications disrupt the integrity of the topologically associating domain (TAD) containing GPR101 and lead to the formation of a neo-TAD that drives pituitary GPR101 misexpression and gigantism. As X-LAG is fully penetrant and heritable, duplications involving GPR101 identified on prenatal screening studies, like amniocentesis, can pose an interpretation challenge for medical geneticists and raise important concerns for patients and families. Therefore, providing robust information on the functional genomic impact of such duplications has important research and clinical value with respect to gene regulation and triplosensitivity traits. We employed 4C/HiC-seq as a clinical tool to determine the functional impact of incidentally discovered GPR101 duplications on TAD integrity in three families. After defining duplications and breakpoints around GPR101 by clinical-grade and high-density aCGH, we constructed 4C/HiC chromatin contact maps for our study population and compared them with normal and active (X-LAG) controls. We showed that duplications involving GPR101 that preserved the centromeric invariant TAD boundary did not generate a pathogenic neo-TAD and that ectopic enhancers were not adopted. This allowed us to discount presumptive/suspected X-LAG diagnoses and GPR101 misexpression, obviating the need for intensive clinical follow-up. This study highlights the importance of TAD boundaries and chromatin interactions in determining the functional impact of copy number variants and provides proof-of-concept for using 4C/HiC-seq as a clinical tool to acquire crucial information for genetic counseling and to support clinical decision-making in cases of suspected TADopathies.
期刊介绍:
Genome Medicine is an open access journal that publishes outstanding research applying genetics, genomics, and multi-omics to understand, diagnose, and treat disease. Bridging basic science and clinical research, it covers areas such as cancer genomics, immuno-oncology, immunogenomics, infectious disease, microbiome, neurogenomics, systems medicine, clinical genomics, gene therapies, precision medicine, and clinical trials. The journal publishes original research, methods, software, and reviews to serve authors and promote broad interest and importance in the field.