Oda Satoyo, Ushiama Mineko, Nakamura Wataru, Gotoh Masahiro, Tanabe Noriko, Watanabe Tomoko, Odaka Yoko, Aoyagi Kazuhiko, Sakamoto Hiromi, Nakajima Takeshi, Sugano Kokichi, Yoshida Teruhiko, Shiraishi Yuichi, Hirata Makoto
Department of Genetic Medicine and Services, National Cancer Center Hospital, Tokyo, Japan.
Department of Clinical Laboratories, National Cancer Center Hospital, Tokyo, Japan.
Front Oncol. 2023 Aug 3;13:1205847. doi: 10.3389/fonc.2023.1205847. eCollection 2023.
Genetic testing of the gene by sequencing analysis and MLPA is available across commercial laboratories for the definitive genetic diagnosis of familial adenomatous polyposis (FAP). However, some genetic alterations are difficult to detect using conventional analyses. Here, we report a case of a complex genomic rearrangement, which was identified in a patient with FAP by a series of genomic analyses, including multigene panel testing, chromosomal analyses, and long-read sequencing. A woman in her thirties was diagnosed with FAP due to multiple polyps in her colon and underwent total colectomy. Subsequent examination revealed fundic gland polyposis. No family history suggesting FAP was noted except for a first-degree relative with desmoid fibromatosis. The conventional gene testing was performed by her former doctor, but no pathogenic variant was detected, except for 2 variants of unknown significance. The patient was referred to our hospital for further genetic analysis. After obtaining informed consent in genetic counseling, we conducted a multigene panel analysis. As insertion of a part of the sequence was detected within exon16 of , further analyses, including chromosomal analysis and long-read sequencing, were performed and a complex translocation between chromosomes 3 and 5 containing several breakpoints in and was identified. No phenotype associated with pathogenic variants, such as split-hand/foot malformation (SHFM) or ectrodactyly, ectodermal dysplasia, or cleft lip/palate syndrome (EEC) was identified in the patient or her relatives. Multimodal genomic analyses should be considered in cases where no pathogenic germline variants are detected by conventional genetic testing despite an evident medical or family history of hereditary cancer syndromes.
通过测序分析和多重连接依赖探针扩增(MLPA)对该基因进行基因检测,在各商业实验室均可进行,用于家族性腺瘤性息肉病(FAP)的确切基因诊断。然而,使用传统分析方法难以检测到一些基因改变。在此,我们报告一例复杂基因组重排病例,该病例通过一系列基因组分析在一名FAP患者中被鉴定出来,包括多基因panel检测、染色体分析和长读长测序。一名三十多岁的女性因结肠多发息肉被诊断为FAP,并接受了全结肠切除术。随后的检查发现胃底腺息肉病。除了一名患有硬纤维瘤病的一级亲属外,未发现提示FAP的家族史。她之前的医生进行了传统的基因检测,但除了2个意义不明的变异外,未检测到致病变异。该患者被转诊至我院进行进一步的基因分析。在遗传咨询中获得知情同意后,我们进行了多基因panel分析。由于在该基因的第16外显子内检测到一部分序列的插入,因此进行了包括染色体分析和长读长测序在内的进一步分析,并鉴定出在该基因和其他基因中含有几个断点的3号和5号染色体之间的复杂易位。在患者及其亲属中未发现与该基因致病变异相关的表型,如裂手/裂足畸形(SHFM)或缺指(趾)、外胚层发育不良或唇腭裂综合征(EEC)。对于尽管有明显的遗传性癌症综合征医学或家族史,但传统基因检测未检测到致病胚系变异的病例,应考虑进行多模式基因组分析。
