Clinical implementation of RNA sequencing for Mendelian disease diagnostics

被引：97

作者：

Yepez, Vicente A. ^{[1
,2
,3
]}

Gusic, Mirjana ^{[1
,4
,5
]}

Kopajtich, Robert ^{[1
,4
]}

Mertes, Christian ^{[2
]}

Smith, Nicholas H. ^{[2
]}

Alston, Charlotte L. ^{[6
,7
]}

Ban, Rui ^{[4
,8
]}

Beblo, Skadi ^{[9
]}

Berutti, Riccardo ^{[1
,4
]}

Blessing, Holger ^{[10
]}

Ciara, Elzbieta ^{[11
]}

Distelmaier, Felix ^{[12
]}

Freisinger, Peter ^{[13
]}

Haeberle, Johannes ^{[14
,15
]}

Hayflick, Susan J. ^{[16
]}

Hempel, Maja ^{[17
]}

Itkis, Yulia S. ^{[18
]}

Kishita, Yoshihito ^{[19
,20
]}

Klopstock, Thomas ^{[21
,22
,23
]}

Krylova, Tatiana D. ^{[18
]}

Lamperti, Costanza ^{[24
]}

Lenz, Dominic ^{[25
]}

Makowski, Christine ^{[26
]}

Mosegaard, Signe ^{[27
]}

Mueller, Michaela F. ^{[2
]}

Munoz-Pujol, Gerard ^{[28
]}

Nadel, Agnieszka ^{[1
,4
]}

Ohtake, Akira ^{[29
,30
]}

Okazaki, Yasushi ^{[19
]}

Procopio, Elena ^{[31
]}

Schwarzmayr, Thomas ^{[1
,4
]}

Smet, Joel ^{[32
]}

Staufner, Christian ^{[25
]}

Stenton, Sarah L. ^{[1
,4
]}

Strom, Tim M. ^{[1
,4
]}

Terrile, Caterina ^{[4
]}

Tort, Frederic ^{[28
]}

Van Coster, Rudy ^{[32
]}

Vanlander, Arnaud ^{[32
]}

Wagner, Matias ^{[1
,4
]}

Xu, Manting ^{[4
,8
]}

Fang, Fang ^{[8
]}

Ghezzi, Daniele ^{[24
,33
]}

Mayr, Johannes A. ^{[34
]}

Piekutowska-Abramczuk, Dorota ^{[11
]}

Ribes, Antonia ^{[28
]}

Roetig, Agnes ^{[35
]}

Taylor, Robert W. ^{[6
,7
]}

Wortmann, Saskia B. ^{[1
,34
,36
]}

Murayama, Kei ^{[37
]}

机构：

[1] Tech Univ Munich, Sch Med, Inst Human Genet, Munich, Germany

[2] Tech Univ Munich, Dept Informat, Garching, Germany

[3] Ludwig Maximilians Univ Munchen, Dept Biochem, Quantitat Biosci Munich, Munich, Germany

[4] Helmholtz Zentrum Munchen, Inst Neurogen, Neuherberg, Germany

[5] DZHK German Ctr Cardiovasc Res, Partner Site Munich Heart Alliance, Munich, Germany

[6] Newcastle Univ, Fac Med Sci, Wellcome Ctr Mitochondrial Res, Translat & Clin Res Inst, Newcastle Upon Tyne NE2 4HH, Tyne & Wear, England

[7] Newcastle Upon Tyne Hosp NHS Fdn Trust, Royal Victoria Infirm, NHS Highly Specialised Serv Rare Mitochondrial Di, Queen Victoria Rd, Newcastle Upon Tyne NE1 4LP, Tyne & Wear, England

[8] Capital Med Univ, Beijing Childrens Hosp, Natl Ctr Childrens Hlth, Dept Pediat Neurol, Beijing, Peoples R China

[9] Univ Leipzig, Univ Hosp, Hosp Children & Adolescents,Dept Women & Child Hl, Ctr Pediat Res Leipzig CPL,Ctr Rare Dis, Leipzig, Germany

[10] Univ Erlangen Nurnberg, Childrens & AdolescentsHosp, Dept Inborn Metab Dis, Erlangen, Germany

[11] Childrens Mem Hlth Inst, Dept Med Genet, Warsaw, Poland

[12] Heinrich Heine Univ, Dept Gen Pediat Neonatol & Pediat Cardiol, Dusseldorf, Germany

[13] Klinikum Reutlingen, Dept Pediat, Reutlingen, Germany

[14] Univ Childrens Hosp Zurich, Zurich, Switzerland

[15] Childrens Res Ctr, Zurich, Switzerland

[16] Oregon Hlth & Sci Univ, Dept Mol & Med Genet, Portland, OR 97201 USA

[17] Univ Med Ctr Hamburg Eppendorf, Inst Human Genet, Hamburg, Germany

[18] Res Ctr Med Genet, Moscow, Russia

[19] Juntendo Univ, Intractable Dis Res Ctr, Grad Sch Med, Diagnost & Therapeut Intractable Dis, Tokyo, Japan

[20] Kindai Univ, Fac Sci & Engn, Dept Life Sci, Osaka, Japan

[21] Ludwig Maximilians Univ Munchen, Univ Hosp, Friedrich Baur Inst, Dept Neurol, Munich, Germany

[22] German Ctr Neurodegenerat Dis DZNE, Munich, Germany

[23] Munich Cluster Syst Neurol SyNergy, Munich, Germany

[24] Fdn IRCCS Ist Ricovero & Cura Carattere Sci, Unit Med Genet & Neurogenet, Ist Neurol Carlo Besta, Milan, Italy

[25] Univ Hosp Heidelberg, Ctr Pediat & Adolescent Med, Div Neuropediat & Pediat Metab Med, Heidelberg, Germany

[26] Tech Univ Munich, Dept Pediat, Munich, Germany

[27] Aarhus Univ, Dept Clin Med, Res Unit Mol Med, Aarhus, Denmark

[28] Hosp Clin Barcelona, Dept Biochem & Mol Genet, Sect Inborn Errors Metab IBC, CIBERER,IDIBAPS, Barcelona, Spain

[29] Saitama Med Univ, Fac Med, Dept Pediat & Clin Genom, Saitama, Japan

[30] Saitama Med Univ Hosp, Ctr Intractable Dis, Saitama, Japan

[31] Anna Meyer Children Hosp, Inborn Metab & Muscular Disorders Unit, Florence, Italy

[32] Ghent Univ Hosp, Dept Pediat Neurol & Metab, Ghent, Belgium

[33] Univ Milan, Dept Pathophysiol & Transplantat, Milan, Italy

[34] Paracelsus Med Univ Salzburg, Univ Childrens Hosp, Salzburg, Austria

[35] Univ Paris, Inst Imagine, INSERM UMR 1163, Paris, France

[36] Radboudumc Nijmegen, Amalia Childrens Hosp, Nijmegen, Netherlands

[37] Chiba Childrens Hosp, Dept Metab, Chiba, Japan

[38] Helmholtz Zentrum Munchen, Inst Computat Biol, Neuherberg, Germany

来源：

GENOME MEDICINE | 2022年 / 14卷 / 01期

基金：

英国医学研究理事会; 美国国家卫生研究院; 日本学术振兴会;

关键词：

RNA-seq; Genetic diagnostics; Mendelian diseases; MUTATIONS CAUSE; MITOCHONDRIAL DISEASE; GENE-EXPRESSION; VARIANTS; DEFECT; COMPLEX; DEFICIENCY; GENOMICS; ONSET; CARDIOMYOPATHY;

D O I：

10.1186/s13073-022-01019-9

中图分类号：

Q3 [遗传学];

学科分类号：

071007 ; 090102 ;

摘要：

Background Lack of functional evidence hampers variant interpretation, leaving a large proportion of individuals with a suspected Mendelian disorder without genetic diagnosis after whole genome or whole exome sequencing (WES). Research studies advocate to further sequence transcriptomes to directly and systematically probe gene expression defects. However, collection of additional biopsies and establishment of lab workflows, analytical pipelines, and defined concepts in clinical interpretation of aberrant gene expression are still needed for adopting RNA sequencing (RNA-seq) in routine diagnostics. Methods We implemented an automated RNA-seq protocol and a computational workflow with which we analyzed skin fibroblasts of 303 individuals with a suspected mitochondrial disease that previously underwent WES. We also assessed through simulations how aberrant expression and mono-allelic expression tests depend on RNA-seq coverage. Results We detected on average 12,500 genes per sample including around 60% of all disease genes-a coverage substantially higher than with whole blood, supporting the use of skin biopsies. We prioritized genes demonstrating aberrant expression, aberrant splicing, or mono-allelic expression. The pipeline required less than 1 week from sample preparation to result reporting and provided a median of eight disease-associated genes per patient for inspection. A genetic diagnosis was established for 16% of the 205 WES-inconclusive cases. Detection of aberrant expression was a major contributor to diagnosis including instances of 50% reduction, which, together with mono-allelic expression, allowed for the diagnosis of dominant disorders caused by haploinsufficiency. Moreover, calling aberrant splicing and variants from RNA-seq data enabled detecting and validating splice-disrupting variants, of which the majority fell outside WES-covered regions. Conclusion Together, these results show that streamlined experimental and computational processes can accelerate the implementation of RNA-seq in routine diagnostics.

引用

页数：26

共 125 条

[1] Genetic effects on gene expression across human tissues
Aguet, Francois
Brown, Andrew A.
Castel, Stephane E.
Davis, Joe R.
He, Yuan
Jo, Brian
Mohammadi, Pejman
Park, Yoson
Parsana, Princy
Segre, Ayellet V.
Strober, Benjamin J.
Zappala, Zachary
Cummings, Beryl B.
Gelfand, Ellen T.
Hadley, Kane
Huang, Katherine H.
Lek, Monkol
Li, Xiao
Nedzel, Jared L.
Nguyen, Duyen Y.
Noble, Michael S.
Sullivan, Timothy J.
Tukiainen, Taru
MacArthur, Daniel G.
Getz, Gad
Management, Nih Program
Addington, Anjene
Guan, Ping
Koester, Susan
Little, A. Roger
Lockhart, Nicole C.
Moore, Helen M.
Rao, Abhi
Struewing, Jeffery P.
Volpi, Simona
Collection, Biospecimen
Brigham, Lori E.
Hasz, Richard
Hunter, Marcus
Johns, Christopher
Johnson, Mark
Kopen, Gene
Leinweber, William F.
Lonsdale, John T.
McDonald, Alisa
Mestichelli, Bernadette
Myer, Kevin
Roe, Bryan
Salvatore, Michael
Shad, Saboor
[J]. NATURE, 2017, 550 (7675) : 204 - +
[2] Clinical, biochemical, and genetic spectrum of seven patients with NFU1 deficiency
Ahting, Uwe
Mayr, Johannes A.
Vanlander, Arnaud V.
Hardy, Steven A.
Santra, Saikat
Makowski, Christine
Alston, Charlotte L.
Zimmermann, Franz A.
Abela, Lucia
Plecko, Barbara
Rohrbach, Marianne
Spranger, Stephanie
Seneca, Sara
Rolinski, Boris
Hagendorff, Angela
Hempel, Maja
Sperl, Wolfgang
Meitinger, Thomas
Smet, Joel
Taylor, Robert W.
Van Coster, Rudy
Freisinger, Peter
Prokisch, Holger
Haack, Tobias B.
[J]. FRONTIERS IN GENETICS, 2015, 6
[3] Mapping RNA splicing variations in clinically accessible and nonaccessible tissues to facilitate Mendelian disease diagnosis using RNA-seq
Aicher, Joseph K.
Jewell, Paul
Vaquero-Garcia, Jorge
Barash, Yoseph
Bhoj, Elizabeth J.
[J]. GENETICS IN MEDICINE, 2020, 22 (07) : 1181 - 1190
[4] Mutations in MDH2, Encoding a Krebs Cycle Enzyme, Cause Early-Onset Severe Encephalopathy
Ait-El-Mkadem, Samira
Dayem-Quere, Manal
Gusic, Mirjana
Chaussenot, Annabelle
Bannwarth, Sylvie
Francois, Berengere
Genin, Emmanuelle C.
Fragaki, Konstantina
Volker-Touw, Catharina L. M.
Vasnier, Christelle
Serre, Valerie
van Gassen, Koen L. I.
Lespinasse, Francoise
Richter, Susan
Eisenhofer, Graeme
Rouzier, Cecile
Mochel, Fanny
De Saint-Martin, Anne
Warde, Marie-Therese Abi
de Sain-van der Velde, Monique G. M.
Jans, Judith J. M.
Amiel, Jeanne
Avsec, Ziga
Mertes, Christian
Haack, Tobias B.
Strom, Tim
Meitinger, Thomas
Bonnen, Penelope E.
Taylor, Robert W.
Gagneur, Julien
van Hasselt, Peter M.
Rotig, Agnes
Delahodde, Agnes
Prokisch, Holger
Fuchs, Sabine A.
Paquis-Flucklinger, Veronique
[J]. AMERICAN JOURNAL OF HUMAN GENETICS, 2017, 100 (01) : 151 - 159
[5] A global reference for human genetic variation
Altshuler, David M.
Durbin, Richard M.
Abecasis, Goncalo R.
Bentley, David R.
Chakravarti, Aravinda
Clark, Andrew G.
Donnelly, Peter
Eichler, Evan E.
Flicek, Paul
Gabriel, Stacey B.
Gibbs, Richard A.
Green, Eric D.
Hurles, Matthew E.
Knoppers, Bartha M.
Korbel, Jan O.
Lander, Eric S.
Lee, Charles
Lehrach, Hans
Mardis, Elaine R.
Marth, Gabor T.
McVean, Gil A.
Nickerson, Deborah A.
Wang, Jun
Wilson, Richard K.
Boerwinkle, Eric
Doddapaneni, Harsha
Han, Yi
Korchina, Viktoriya
Kovar, Christie
Lee, Sandra
Muzny, Donna
Reid, Jeffrey G.
Zhu, Yiming
Chang, Yuqi
Feng, Qiang
Fang, Xiaodong
Guo, Xiaosen
Jian, Min
Jiang, Hui
Jin, Xin
Lan, Tianming
Li, Guoqing
Li, Jingxiang
Li, Yingrui
Liu, Shengmao
Liu, Xiao
Lu, Yao
Ma, Xuedi
Tang, Meifang
Wang, Bo
[J]. NATURE, 2015, 526 (7571) : 68 - +
[6] Gene therapy for ALS: A review
Amado, Defne A.
Davidson, Beverly L.
[J]. MOLECULAR THERAPY, 2021, 29 (12) : 3345 - 3358
[7] OMIM.org: leveraging knowledge across phenotype-gene relationships
Amberger, Joanna S.
Bocchini, Carol A.
Scott, Alan F.
Hamosh, Ada
[J]. NUCLEIC ACIDS RESEARCH, 2019, 47 (D1) : D1038 - D1043
[8] [Anonymous], 2005, Regional and Urban Statistics, Refenence Guide, P1
[9] The landscape of genomic imprinting across diverse adult human tissues
Baran, Yael
Subramaniam, Meena
Biton, Anne
Tukiainen, Taru
Tsang, Emily K.
Rivas, Manuel A.
Pirinen, Matti
Gutierrez-Arcelus, Maria
Smith, Kevin S.
Kukurba, Kim R.
Zhang, Rui
Eng, Celeste
Torgerson, Dara G.
Urbanek, Cydney
Li, Jin Billy
Rodriguez-Santana, Jose R.
Burchard, Esteban G.
Seibold, Max A.
MacArthur, Daniel G.
Montgomery, Stephen B.
Zaitlen, Noah A.
Lappalainen, Tuuli
[J]. GENOME RESEARCH, 2015, 25 (07) : 927 - 936
[10] Ancestry patterns inferred from massive RNA-seq data
Barral-Arca, Ruth
Pardo-Seco, Jacobo
Bello, Xabi
Martinon-Torres, Federico
Salas, Antonio
[J]. RNA, 2019, 25 (07) : 857 - 868

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