探討結節性硬化症與淋巴血管平滑肌增生症之基因型與表型特徵

何晏寧; Yen-Ning Ho

請用此 Handle URI 來引用此文件： http://tdr.lib.ntu.edu.tw/jspui/handle/123456789/99942

完整後設資料紀錄

DC 欄位	值	語言
dc.contributor.advisor	陳沛隆	zh_TW
dc.contributor.advisor	Pei-Lung Chen	en
dc.contributor.author	何晏寧	zh_TW
dc.contributor.author	Yen-Ning Ho	en
dc.date.accessioned	2025-09-22T16:05:11Z	-
dc.date.available	2025-09-23	-
dc.date.copyright	2025-09-22	-
dc.date.issued	2025	-
dc.date.submitted	2025-07-30	-
dc.identifier.citation	1. Henske, E.P., et al., Tuberous sclerosis complex. Nature Reviews Disease Primers, 2016. 2(1): p. 16035. 2. Gómez, M.R., History of the tuberous sclerosis complex. Brain Dev, 1995. 17 Suppl: p. 55-7. 3. Uysal, S.P. and M. Şahin, Tuberous sclerosis: a review of the past, present, and future. Turk J Med Sci, 2020. 50(Si-2): p. 1665-1676. 4. Northrup, H. and D.A. Krueger, Tuberous sclerosis complex diagnostic criteria update: recommendations of the 2012 Iinternational Tuberous Sclerosis Complex Consensus Conference. Pediatr Neurol, 2013. 49(4): p. 243-54. 5. Patursky-Polischuk, I., et al., The TSC-mTOR pathway mediates translational activation of TOP mRNAs by insulin largely in a raptor- or rictor-independent manner. Mol Cell Biol, 2009. 29(3): p. 640-9. 6. Palavra, F., C. Robalo, and F. Reis, Recent Advances and Challenges of mTOR Inhibitors Use in the Treatment of Patients with Tuberous Sclerosis Complex. Oxidative Medicine and Cellular Longevity, 2017. 2017(1): p. 9820181. 7. Luo, C., et al., Perfect match: mTOR inhibitors and tuberous sclerosis complex. Orphanet Journal of Rare Diseases, 2022. 17(1): p. 106. 8. Muto, Y., et al., Genotype-phenotype correlation of renal lesions in the tuberous sclerosis complex. Human Genome Variation, 2022. 9(1): p. 5. 9. Martin, K.R., et al., The genomic landscape of tuberous sclerosis complex. Nat Commun, 2017. 8: p. 15816. 10. Curatolo, P. and R. Moavero, mTOR Inhibitors in Tuberous Sclerosis Complex. Curr Neuropharmacol, 2012. 10(4): p. 404-15. 11. Cockerell, I., et al., Effectiveness and safety of everolimus treatment in patients with tuberous sclerosis complex in real-world clinical practice. Orphanet Journal of Rare Diseases, 2023. 18(1): p. 377. 12. Northrup, H., et al., Updated International Tuberous Sclerosis Complex Diagnostic Criteria and Surveillance and Management Recommendations. Pediatr Neurol, 2021. 123: p. 50-66. 13. De Waele, L., L. Lagae, and D. Mekahli, Tuberous sclerosis complex: the past and the future. Pediatric Nephrology, 2015. 30(10): p. 1771-1780. 14. Hong, C.H., T.N. Darling, and C.H. Lee, Prevalence of tuberous sclerosis complex in Taiwan: a national population-based study. Neuroepidemiology, 2009. 33(4): p. 335-41. 15. Hong, C.H., et al., An estimation of the incidence of tuberous sclerosis complex in a nationwide retrospective cohort study (1997–2010). British Journal of Dermatology, 2016. 174(6): p. 1282-1289. 16. Tyburczy, M.E., et al., Mosaic and Intronic Mutations in TSC1/TSC2 Explain the Majority of TSC Patients with No Mutation Identified by Conventional Testing. PLoS Genet, 2015. 11(11): p. e1005637. 17. Qin, W., et al., Ultra deep sequencing detects a low rate of mosaic mutations in tuberous sclerosis complex. Hum Genet, 2010. 127(5): p. 573-82. 18. Klonowska, K., et al., Comprehensive genetic and phenotype analysis of 95 individuals with mosaic tuberous sclerosis complex. Am J Hum Genet, 2023. 110(6): p. 979-988. 19. Richards, S., et al., Standards and guidelines for the interpretation of sequence variants: a joint consensus recommendation of the American College of Medical Genetics and Genomics and the Association for Molecular Pathology. Genet Med, 2015. 17(5): p. 405-24. 20. Ciesielski, T.H., et al., Characterizing the pathogenicity of genetic variants: the consequences of context. npj Genomic Medicine, 2024. 9(1): p. 3. 21. Nellist, M., et al., Targeted Next Generation Sequencing reveals previously unidentified TSC1 and TSC2 mutations. BMC Med Genet, 2015. 16: p. 10. 22. Huang, J., et al., Gene mutations in sporadic lymphangioleiomyomatosis and genotype–phenotype correlation analysis. BMC Pulmonary Medicine, 2022. 22(1): p. 354. 23. Han, Z., et al., Tuberous sclerosis complex associated lymphangioleiomyomatosis. QJM: An International Journal of Medicine, 2023. 116(10): p. 873-874. 24. Marciniak, A., et al., Lymphangioleiomyomatosis with Tuberous Sclerosis Complex-A Case Study. J Pers Med, 2023. 13(11). 25. Henske, E.P. and F.X. McCormack, Lymphangioleiomyomatosis - a wolf in sheep's clothing. J Clin Invest, 2012. 122(11): p. 3807-16. 26. Koslow, M., et al., Lymphangioleiomyomatosis and Other Cystic Lung Diseases. Immunol Allergy Clin North Am, 2023. 43(2): p. 359-377. 27. Young, L.R., Y. Inoue, and F.X. McCormack, Diagnostic potential of serum VEGF-D for lymphangioleiomyomatosis. N Engl J Med, 2008. 358(2): p. 199-200. 28. Di Marco, F., et al., Natural history of incidental sporadic and tuberous sclerosis complex associated lymphangioleiomyomatosis. Respiratory Medicine, 2020. 168: p. 105993. 29. Avila, N.A., et al., Sporadic Lymphangioleiomyomatosis and Tuberous Sclerosis Complex with Lymphangioleiomyomatosis: Comparison of CT Features. Radiology, 2007. 242(1): p. 277-285. 30. Touraine, R., et al., Tuberous Sclerosis Complex: Genetic counselling and perinatal follow-up. Arch Pediatr, 2022. 29(5s): p. 5s3-5s7. 31. Adley, B.P., et al., Birt-Hogg-Dubé Syndrome: Clinicopathologic Findings and Genetic Alterations. Archives of Pathology & Laboratory Medicine, 2006. 130(12): p. 1865-1870. 32. Kluger, N., et al., Birt–Hogg–Dubé syndrome: clinical and genetic studies of 10 French families. British Journal of Dermatology, 2010. 162(3): p. 527-537. 33. Sato, T., et al., Mutation analysis of the TSC1 and TSC2 genes in Japanese patients with pulmonary lymphangioleiomyomatosis. Journal of Human Genetics, 2002. 47(1): p. 20-28. 34. Gupta, N. and E.P. Henske, Pulmonary manifestations in tuberous sclerosis complex. Am J Med Genet C Semin Med Genet, 2018. 178(3): p. 326-337. 35. McCormack Francis, X., et al., Efficacy and Safety of Sirolimus in Lymphangioleiomyomatosis. New England Journal of Medicine. 364(17): p. 1595-1606. 36. Curatolo, P., M. Verdecchia, and R. Bombardieri, Vigabatrin for tuberous sclerosis complex. Brain Dev, 2001. 23(7): p. 649-53. 37. Satam, H., et al., Next-Generation Sequencing Technology: Current Trends and Advancements. Biology (Basel), 2023. 12(7). 38. Qin, D., Next-generation sequencing and its clinical application. Cancer Biol Med, 2019. 16(1): p. 4-10. 39. Kozarewa, I., et al., Overview of Target Enrichment Strategies. Curr Protoc Mol Biol, 2015. 112: p. 7.21.1-7.21.23. 40. Zhao, S., et al., Accuracy and efficiency of germline variant calling pipelines for human genome data. Scientific Reports, 2020. 10(1): p. 20222. 41. Wu, H., et al., Combining full-length gene assay and SpliceAI to interpret the splicing impact of all possible SPINK1 coding variants. Human Genomics, 2024. 18(1): p. 21. 42. Bartlett, J.M.S. and D. Stirling, A Short History of the Polymerase Chain Reaction, in PCR Protocols, J.M.S. Bartlett and D. Stirling, Editors. 2003, Humana Press: Totowa, NJ. p. 3-6. 43. Zhao, S., et al., A brain somatic RHEB doublet mutation causes focal cortical dysplasia type II. Experimental & Molecular Medicine, 2019. 51(7): p. 1-11. 44. Geilswijk, M., et al., ERN GENTURIS clinical practice guidelines for the diagnosis, surveillance and management of people with Birt-Hogg-Dubé syndrome. European Journal of Human Genetics, 2024. 32(12): p. 1542-1550. 45. Belyavsky, A., N. Petinati, and N. Drize Hematopoiesis during Ontogenesis, Adult Life, and Aging. International Journal of Molecular Sciences, 2021. 22, DOI: 10.3390/ijms22179231. 46. Carlson, G.W., THE SALIVARY GLANDS: Embryology, Anatomy, and Surgical Applications. Surgical Clinics, 2000. 80(1): p. 261-273. 47. Ogórek, B., et al., Generalised mosaicism for TSC2 mutation in isolated lymphangioleiomyomatosis. Eur Respir J, 2019. 54(4). 48. Singh, R.R., Next-Generation Sequencing in High-Sensitive Detection of Mutations in Tumors: Challenges, Advances, and Applications. The Journal of Molecular Diagnostics, 2020. 22(8): p. 994-1007. 49. Roberts, P.S., et al., A 34 bp deletion within TSC2 is a rare polymorphism, not a pathogenic mutation. Ann Hum Genet, 2003. 67(Pt 6): p. 495-503. 50. Gudiseva, H.V., et al., Saliva DNA quality and genotyping efficiency in a predominantly elderly population. BMC Med Genomics, 2016. 9: p. 17. 51. Ferretti, E. and A.K. Hadjantonakis, Mesoderm specification and diversification: from single cells to emergent tissues. Curr Opin Cell Biol, 2019. 61: p. 110-116. 52. Nordgarden, H., et al., Salivary gland function in persons with ectodermal dysplasias. Eur J Oral Sci, 2003. 111(5): p. 371-6. 53. Fujita, A., et al., Detection of low-prevalence somatic TSC2 mutations in sporadic pulmonary lymphangioleiomyomatosis tissues by deep sequencing. Human Genetics, 2016. 135(1): p. 61-68.	-
dc.identifier.uri	http://tdr.lib.ntu.edu.tw/jspui/handle/123456789/99942	-
dc.description.abstract	結節性硬化症（Tuberous sclerosis complex , TSC）是一種罕見的自體顯性遺傳性疾病，平均每6,000到10,000個活產新生兒當中，就有一人罹病。TSC主要因TSC1以及TSC2兩個基因發生變異所致，兩個基因負責控制胞內的mTOR（mammalian target of rapamycin）路徑，一旦發生基因變異，此路徑將不正常活化，導致細胞異常增生，在各個器官當中形成錯構瘤（hamartoma）。儘管臨床診斷出TSC的表徵，患者經過基因檢驗可確認致病原因，但仍有少數患者無法以傳統基因檢驗的方式找到相關變異，可能原因包含基因變異發生在深度內含子（intron）或是患者本身存在低比例染色體鑲嵌現象（low-level mosaicism）等，此時用聚合酶連鎖反應（polymerase chain reaction, PCR）搭配次世代定序（next generation sequencing, NGS）的分子生物技術，方能做進一步確認。肺部的淋巴血管平滑肌增生症（lymphangioleiomyomatosis, LAM）在部分的TSC患者當中終生伴隨，造成患者呼吸困難、胸痛、肋膜積水以及乳糜胸等。然而，患有LAM的患者當中，依照基因變異的機制又可以分為偶發性淋巴血管平滑肌肉增生症（sporadic LAM, S-LAM）以及結節性硬化症相關淋巴血管平滑肌肉增生症（TSC-associated LAM, TSC-LAM），因此欲觀察在國立臺灣大學醫學院附設醫院之LAM患者當中，TSC-LAM之比例。臺大結節硬化症整合門診迄今已有10年以上的歷史，累積近200人的臨床數據，本研究將收集LAM患者，確認是否存在低比例染色體鑲嵌現象，並進一步確認其是否由TSC基因變異（TSC1或TSC2）所致。本研究收案胸腔科門診具LAM的病人共69位，並收集血液以及唾液檢體，利用實驗室建立的TSC次世代定序基因檢測套組（TSC next-generation sequencing panel）進行次世代定序基因檢測（next-generation sequencing, NGS），並將結果使用Integrative Genomics Viewer (IGV) 軟體來輔助初步判讀，再經由Mutect2、Gendiseak (GDK)、SpliceAI等生資工具來進行更進一步分析患者的單一核甘酸變異（single nucleotide variants, SNVs）、染色體結構變異（structure variants, SVs）以及拷貝數變異（copy number variants, CNVs），最後根據美國醫學遺傳學暨基因體學學會（American College of Medical Genetics and Genomics, ACMG）判讀之方法，試圖為個案找出致病性變異。我們對69位具有LAM的個案進行血液以及唾液的次世代基因定序，其中包含TSC1、TSC2、FLCN三個基因，結果顯示3位FLCN的致病性變異（pathogenic）、2位TSC2的高度懷疑致病變異（likely pathogenic）、2位TSC1和1位TSC2的臨床意義尚不明確（variant of unknown significance, VUS）之變異，其中4位為低比例染色體鑲嵌現象；其餘皆未發現致病變異，這樣的結果顯示此項檢測具有價值性，將TSC與FLCN基因所導致之Birt-Hogg-Dubé症候群（Birt-Hogg-Dubé syndrome）欲進行區分，除了影像學的輔助診斷，仍須依靠基因檢測不能只依據臨床病徵做診斷；除此，低比例染色體鑲嵌現象也需要NGS技術，方能找出臨床病徵不明顯之TSC個案。 TSC是一種具有高度異質性（heterogeneity）的自體顯性遺傳疾病，其病徵因患者之間的臨床表現差異極大，而有部分的TSC患者因症狀表現輕微或不典型，特別是低比例染色體鑲嵌的現象，可能未能及時被正確診斷。本研究旨在探討LAM的個案，致病原因是否為TSC或是其他原因所致。本研究結果除了發現低比例染色體鑲嵌的個案，顯示NGS檢驗的靈敏性與精確性，對於與TSC相似病徵的鑑別診斷也十分重要，提供胸腔科醫師以及LAM的個案更明確的醫療方針，未來仍有多個後續研究方向可探索。	zh_TW
dc.description.abstract	Tuberous Sclerosis Complex (TSC) is a rare autosomal dominant genetic disorder, with an estimated incidence of approximately one in every 6,000 to 10,000 live births. The condition is primarily attributed to pathogenic mutations in the TSC1 or TSC2 genes, both of which play a critical role in regulating the mTOR (mammalian target of rapamycin) signaling pathway. Mutations in these genes result in dysregulation and hyperactivation of the mTOR pathway, subsequently leading to abnormal cellular proliferation and the development of hamartomas—benign, disorganized growths—in multiple organ systems. Although the clinical manifestations of TSC can lead to a diagnosis, genetic testing is often employed to confirm the underlying pathogenic mutations. However, in a small subset of patients, conventional genetic testing fails to detect causative variants. Possible explanations include mutations located within deep intronic regions or the presence of low-level mosaicism in the patient. In such cases, advanced molecular techniques—such as polymerase chain reaction (PCR) in combination with next-generation sequencing (NGS)—are required for further confirmation and precise genetic characterization. Lymphangioleiomyomatosis (LAM) is a progressive disease that may persist lifelong in a subset of patients with TSC, leading to clinical manifestations such as dyspnea, chest pain, pleural effusion, and chylothorax. Among individuals diagnosed with LAM, the condition can be further classified based on the underlying genetic mechanisms into sporadic LAM (S-LAM) and TSC-associated LAM (TSC-LAM). Therefore, the objective is to investigate the proportion of TSC-LAM cases among LAM patients treated at the National Taiwan University Hospital (NTUH). The Integrated TSC Clinic at National Taiwan University Hospital (NTUH) has been established for over a decade and has accumulated clinical data from nearly 200 patients. This study aims to collect data from patients diagnosed with LAM to determine the presence of low-level mosaicism, and to further investigate whether the condition is attributable to pathogenic variants in the TSC1 or TSC2 genes. A total of 69 patients with LAM were enrolled from the pulmonology outpatient clinic for this study. Blood and saliva samples were collected from each participant, and NGS was performed using a laboratory-developed TSC next-generation sequencing panel. The sequencing results were initially interpreted using the Integrative Genomics Viewer (IGV) software, followed by further bioinformatic analysis using tools such as Mutect2, Gendiseak (GDK), and SpliceAI to identify single nucleotide variants (SNVs), structural variants (SVs), and copy number variants (CNVs). Finally, all findings were evaluated based on the interpretation guidelines of the American College of Medical Genetics and Genomics (ACMG) in an effort to identify pathogenic variants in each individual case. We performed NGS using blood and saliva samples from 69 patients with LAM, targeting three genes: TSC1, TSC2, and FLCN. The results revealed three cases with pathogenic variants in FLCN, two cases with likely pathogenic variants in TSC2, and variants of uncertain significance (VUS) in two cases involving TSC1 and one case involving TSC2. Among these, four patients exhibited low-level mosaicism. No pathogenic variants were identified in the remaining cases. These findings underscore the clinical utility of this genetic testing approach. Differentiating between TSC and Birt-Hogg-Dubé syndrome (caused by mutations in the FLCN gene) requires more than imaging studies; molecular genetic testing is essential and cannot be replaced by clinical assessment alone. Furthermore, low-level mosaicism can only be reliably detected through NGS technologies, enabling the identification of TSC cases with subtle or atypical clinical presentations. Tuberous Sclerosis Complex (TSC) is an autosomal dominant genetic disorder characterized by marked heterogeneity, with considerable variation in clinical manifestations among affected individuals. Some patients, particularly those with low-level chromosomal mosaicism, may present with mild or atypical symptoms, leading to delayed or missed diagnoses. The aim of this study was to investigate whether the underlying etiology of LAM in enrolled cases was attributable to TSC or to other genetic causes. The identification of cases with low-level mosaicism in our findings highlights the sensitivity and precision of NGS. Moreover, this underscores the importance of genetic testing in the differential diagnosis of diseases with overlapping clinical features, thereby offering more accurate diagnostic and treatment strategies for pulmonologists managing LAM patients. These results also open multiple avenues for future research.	en
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dc.description.tableofcontents	誌謝 i 中文摘要 ii 英文摘要 iv 圖次 x 表次 xii 第一章研究背景與動機 1 1.1結節硬化症之疾病介紹 1 1.1.1歷史演進 1 1.1.2致病機轉 2 1.1.3疾病發生率與遺傳模式 2 1.2結節硬化症之疾病診斷 3 1.2.1臨床表徵診斷標準 3 1.2.2基因診斷標準 5 1.3淋巴血管平滑肌增生症特性 5 1.3.1 概述 5 1.3.2偶發性淋巴血管平滑肌增生症 6 1.3.3結節性硬化症相關之淋巴血管平滑肌增生症 7 1.4與結節性硬化症相似之疾病—Birt-Hogg-Dubé Syndrome 9 1.5研究目的 9 1.6結節性硬化症之治療現況與照護方法 10 第二章研究方法 12 2.1研究對象來源與實驗設計 12 2.2受試者同意書 14 2.3實驗方法 14 2.3.1受試者血液DNA萃取 14 2.3.3受試者唾液DNA純化 17 2.3.4偵測DNA品質 18 2.3.5次世代定序平台 21 2.3.6基因致病變異位點之判讀 37 2.3.7利用人工智慧輔助判讀結構變異、拷貝數變異及剪接位點變異 37 2.3.8聚合酶連鎖反應 40 2.3.9桑格式定序 41 2.4國立台灣大學醫學院附設醫院結節性硬化症整合門診 42 2.5 REDCap資料庫 42 第三章研究結果 43 3.1次世代定序結果 43 3.2針對基因變異之個案驗證結果 45 3.3結構變異、拷貝數變異以及剪接位點變異分析結果 57 第四章討論 59 4.1針對具有淋巴血管平滑肌增生症個案之評估結果 59 4.1.1總收案之評估結果 59 4.1.2 TSC448血液與唾液定序驗證結果偏差之原因 59 4.1.3 TSC453與TSC486之臨床差異 60 4.1.4 驗證TSC504插入序列之過程 61 4.2探討DNA無法從唾液中抽取足量之原因 62 4.3收案流程更動之原因 62 4.4同時收集血液和唾液樣本之原因 63 4.5進一步研究 64 4.6遺傳諮詢 65 4.6.1案例報告1（TSC457） 65 4.6.2案例報告2（TSC458） 66 第五章結論 68 第六章參考文獻 70	-
dc.language.iso	zh_TW	-
dc.subject	低比例染色體鑲嵌現象	zh_TW
dc.subject	次世代定序	zh_TW
dc.subject	淋巴血管平滑肌增生症	zh_TW
dc.subject	比爾特霍格杜貝症候群	zh_TW
dc.subject	結節性硬化症	zh_TW
dc.subject	Tuberous Sclerosis Complex (TSC)	en
dc.subject	Next-generation sequencing (NGS)	en
dc.subject	Birt-Hogg-Dubé syndrome (BHDS)	en
dc.subject	Lymphangioleiomyomatosis (LAM)	en
dc.subject	Low-level mosaicism	en
dc.title	探討結節性硬化症與淋巴血管平滑肌增生症之基因型與表型特徵	zh_TW
dc.title	Exploring the Genotypic and Phenotypic Characteristics of Tuberous Sclerosis Complex (TSC) and Lymphangioleiomyomatosis	en
dc.type	Thesis	-
dc.date.schoolyear	113-2	-
dc.description.degree	碩士	-
dc.contributor.oralexamcommittee	楊偉勛;王鶴健	zh_TW
dc.contributor.oralexamcommittee	Wei-Shiung Yang;Hao-Chien Wang	en
dc.subject.keyword	結節性硬化症,次世代定序,低比例染色體鑲嵌現象,淋巴血管平滑肌增生症,比爾特霍格杜貝症候群,	zh_TW
dc.subject.keyword	Tuberous Sclerosis Complex (TSC),Next-generation sequencing (NGS),Low-level mosaicism,Lymphangioleiomyomatosis (LAM),Birt-Hogg-Dubé syndrome (BHDS),	en
dc.relation.page	75	-
dc.identifier.doi	10.6342/NTU202502817	-
dc.rights.note	未授權	-
dc.date.accepted	2025-07-31	-
dc.contributor.author-college	醫學院	-
dc.contributor.author-dept	分子醫學研究所	-
dc.date.embargo-lift	N/A	-
顯示於系所單位：	分子醫學研究所

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