Whole exome sequencing in identifying genetic factors in musculoskeletal diseases

Skarp, S. (Sini)

19 November 2019

Abstract Musculoskeletal diseases, such as osteoarthritis (OA), lumbar disc degeneration (LDD) and osteoporosis (OP), are common complex disorders affected by both environmental and genetic factors. OA and LDD are degenerative diseases affecting joints and spine and Modic changes (MC) are a specific phenotype of LDD. OP is a disorder causing bone fragility. There are families with a history of early onset cartilage degradation, disc disorders and bone fragility as well as rare, more severe disorders with these traits as part of the phenotype. The aim of this study was to identify predisposing genetic factors in Finnish families with three different musculoskeletal phenotypes and to investigate the use of whole exome sequencing (WES) as a tool. Six families were studied here, three diagnosed with hip and knee OA, two with MC and one with primary OP. Using WES together with in silico and in vitro analyses we identified new candidate genes. In the two OA families we identified family specific variants, c.-127G>T in the 5’UTR of FIP1L1 and p.Arg210Gly in OLIG3. We observed expression of these genes in human bone and cartilage. Both FIP1L1 and OLIG3 participate in the regulation of transcription. Family specific variants were also found in both families with MC: p.Gln1611fs in HSPG2 and p.Glu553Lys in MAML1. HSPG2 encodes for an important structural protein in the disc and MAML1 is a transcription factor. The family with primary OP had previously been reported to carry a heterozygous COL1A2 deletion leading to nonsense-mediated mRNA decay. In the WES we identified an additional change that may contribute to the phenotype: p.Arg428* in ZNF528. We showed experimentally that the variant leads to expression of a truncated form of ZNF528 in the nucleus. ZNF528 binding sites are located near genes associated with bone phenotypes. We identified twelve potential target genes for ZNF528 that were differentially expressed in patients’ cells compared to controls. Altogether, we identified five new candidate genes for the studied phenotypes demonstrating that WES can be used as a tool in studying complex musculoskeletal phenotypes in families. One of the identified candidate genes, HSPG2, encodes a structural protein, whereas, OLIG3, FIP1L1, MAML1 and ZNF528, participate in the regulation of transcription supporting the importance of regulatory mechanisms in the pathogenesis of musculoskeletal diseases. / Tiivistelmä Tuki- ja liikuntaelinsairaudet, kuten nivelrikko, välilevyrappeuma ja osteoporoosi, ovat yleisiä, monitekijäisiä sairauksia. Nivelrikko ja välilevynrappeuma ovat eteneviä nivelten ja selkärangan sairauksia. Modic muutokset ovat välilevyn ja nikaman välisten päätelevyjen muutoksia. Osteoporoosi on luuta haurastuttava sairaus. Varhaisessa iässä ilmenevää ruston haurastumista, välilevyn sairauksia tai luun haurautta tavataan myös suvuittain esiintyvinä sairauksina tai vakavien harvinaisten sairauksien oireina. Tutkimuksen tarkoitus oli tunnistaa altistavia geneettisiä tekijöitä kolmelle tuki- ja liikuntaelimistön sairaudelle suomalaisissa perheissä käyttäen eksomisekvensointi-menetelmää. Aineisto koostui kuudesta perheestä: kolmessa oli diagnosoitu lonkan ja polven nivelrikko, kahdessa selän välilevyjen Modic muutoksia ja yhdessä primaarinen vaikea selän osteoporoosi. Tunnistimme uusia ehdokasgeenejä käyttäen eksomisekvensointi-menetelmää sekä in silico ja in vitro analyysejä. Kahdessa nivelrikkoperheessä tunnistimme perhekohtaiset variantit kahdessa geenissä: c.-127G>T variantin FIP1L1 geenin säätelyalueella ja p.Arg210Gly variantin OLIG3 geenissä. Osoitimme, että nämä traskription säätelyyn osallistuvat geenit ilmenevät ihmisen luu- ja rustokudoksessa. Perhekohtaiset variantit havaittiin myös perheissä, joilla oli todettu Modic muutoksia: p.Gln1611fs HSPG2 -geenissä ja p.Glu553Lys MAML1 -geenissä. HSPG2 koodaa välilevylle tärkeää rakenneproteiinia ja MAML1 on transkriptiota säätelevä tekijä. Primaarista osteoporoosia sairastavalla perheellä oli aiemmin havaittu heterotsygootti, geenituotteen hajottamiseen johtava deleetio, COL1A2 -geenissä. Eksomisekvensoinnlla havaitsimme mahdollisesti taudin ilmiasuun lisäksi vaikuttavan muutoksen ZNF528 -geenissä. Osoitimme kokeellisesti, että havaittu variantti johtaa lyhentyneen proteiinin tuottoon solussa. ZNF528 on transkriptiotekijä, jolle tunnistimme kaksitoista mahdollista kohdegeeniä ja havaitsimme että niiden tuotto oli muuttunut potilaiden soluissa kontrollisoluihin verrattuna. Tunnistimme viisi uutta ehdokasgeeniä kolmessa eri sairaudessa eksomisekvensointi-menetelmän avulla. Yksi tunnistetuista geeneistä, HSPG2, koodaa rakenneproteiinia, ja muut osallistuvat transkription säätelyyn. Tämä tukee käsitystä säätelytekijöiden tärkeydestä TULE sairauksien synnyssä.

disc degeneration

genetics

osteoarthritis

osteoporosis

whole exome sequencing

eksomisekvensointi

genetiikka

nivelrikko

osteoporoosi

välilevyn rappeuma

The genetic basis of seasonal affective disorder

Ho, Kwo Wei David

01 May 2015

Family and twin studies have shown a heritable component to seasonal affective disorder (SAD). While a few studies have examined individual genetic variants in SAD, many methodological issues exist in the current literature. First, most studies combined major depression (MDD) and bipolar (BD) cases in the genetic analysis of SAD. This makes it difficult to differentiate the effect from MDD and BD. Second, most studies adopted a candidate gene approach and used fairly small sample sizes. This does not allow for testing across a wide variety of genes, and it yields less robust P-values. Third, healthy controls have been used, but not case comparisons, which makes it difficult to differentiate the effects of seasonality from that of the primary illness (MDD and BD). To overcome these issues, seasonal MDD and BD cases were separated into two different studies in this thesis; sample sizes for both studies are the largest in the current SAD molecular genetics literature; GWAS was used to test for potential risk loci in a hypothesis-free fashion; case comparisons were incorporated to exclude potential genetic contributions related generally to the primary diseases themselves (MDD and BD). For MDD, we performed a GWAS with 562 seasonal MDD cases and 1,225 comparison cases with non-seasonal MDD. Subjects were drawn from two iterations of the Genetics of Recurrent Early Onset Depression (GenRED) study. Seasonal cases were those whose depressive episodes typically started in fall or winter. A mega-analysis of the two GWAS datasets was done using SNPTEST. We found that two single nucleotide polymorphisms (SNPs), rs149882931 and rs77073398, on chromosome 16p12.1 were associated with seasonal depression, at a genome-wide significant level (OR= 1.66, P= 3.59 x 10-8 and OR=1.62, 4.76 x 10-8, respectively). Since SAD is more prevalent in females, a female-specific analysis was carried out. The two variants were more significant in this analysis: P=2.18x10-9 (OR=1.89) and P=2.79x10-9 (OR=1.82), respectively, and a significant sex-by-SNP interaction was observed. These SNPs are located in a conserved intergenic region between the genes HS3ST4 and C16orf82. The protein product of HS3ST4 modifies the side chains of heparan sulfate proteoglycans. We therefore tested the hypothesis that the heparan sulfate biosynthesis pathway would be enriched in nominally significant SNPs using the SNP ratio test, and found evidence for such enrichment (P=0.008, SNP ratio test, P=0.027, SKAT). For BD, the GWAS analysis of 818 seasonal BD cases and 1,515 healthy controls showed that BD-S is most strongly associated with two SNPs within the ZBTB20 genes. BD subjects were drawn from NIMH Bipolar Genetics Study (BIGS), and seasonal cases were defined as those with depressive episodes starting in fall or winter. An association study was carried out with SNPTEST, and we found two single nucleotide polymorphisms (SNPs) in the intronic region of ZBTB20 gene to be associated with BD-S (rs7646282, OR=2.34, P= 7.23 x 10-8 and rs139459337, OR=2.37, 8.05 x 10-8). A similar case-only study was carried out with 818 BD-S cases and 1239 cases without seasonal depressive symptoms (non-BDS), though no SNP was found to be significantly associated in this analysis. rs7646282 is the strongest SNP in cis-association with ZBTB20 gene expression, and ZBTB20 has been shown to affect the neural development of the hippocampus, a brain region implicated in the pathophysiology of BD. Finally, we sought to determine whether there is a role for circadian rhythm genes in BD susceptibility. In this study, we used a discovery set of 189 exome-sequenced BD patients and 105 healthy controls to look for circadian genes associated with BD. We found the DRD2 gene to be the circadian gene most strongly associated with BD. Among the rare damaging variants in the DRD2 gene, the S311C variant was the predominant SNP. To test whether this variant segregates in family members with BD, we genotyped the family members of probands from the discovery sample. This data was used for a linkage and family-based association study. Even though the linkage analysis was only very weakly positive, the family-based association study showed significant segregation of the variant in family members with BD (P< 0.05). To follow up on this finding, we further genotyped 2,185 unrelated BD cases and 1,982 healthy controls. We found no support for the S311C variant in this replication dataset. Sub-phenotype study of psychotic features and mood-incongruence also did not show significant association. Meta-analysis with 2,994 BD cases and 3,661 controls, however, revealed no association between the S311C variant and BD.

Bipolar disorder

Circadian rhythm

GWAS

Major depressive disorder

Seasonal affective disorder

Whole exome sequencing

Genetics

Novel genetic causes and functional studies of severe neurological and multi-organ diseases in children

Paakkola, T. (Teija)

12 September 2019

Abstract Undefined severe neurological and multi-organ diseases are rare as single diseases, but as a group of diseases, they are responsible for significant morbidity, impaired quality of life and mortality, emphasizing the importance of neuroscience research and its translation into novel diagnostic and treatment strategies. Molecular karyotyping and whole-exome sequencing were used to identify three novel disease-causing genes, GLE1, NHLRC2 and MYH7B, in Northem Finnish families having children with undefined progressive neuromuscular diseases. Functional studies on GLE1, NHLRC2, and MYH7B were conducted in order to understand better the impact of these mutations. The studies revealed that the cellular localization of GLE1 was impaired due to a mutation in the coding gene. The NHLRC2 is involved in many biological processes and its dysfunction has a role in the development of a novel FINCA disease and in fibrosis. Furthermore, mutations in MYH7B in the myosin family have now been connected to encephalomyopathies. Mutations in GLE1, NHLRC2 and MYH7B are involved in encephalomyopathies and neurodegeneration, stressing the important role of these genes in normal psychomotor development Analyses of these previously uncharacterized disease-causing gene mutations provided new insights into the etiologies behind these diseases, representing a relevant starting point for resolving the pathomechanisms underpinning these disorders. The newly-discovered human disease-causing genes and the novel phenotypes of childhood onset neuromuscular diseases provide the possibility for offering the relevant families preclinical diagnostics and may be beneficial in the identification of similar clinical phenotypes all around the world. / Tiivistelmä Yksittäiset, määrittelemättömät, vaikeat neurologiset monielinsairaudet ovat harvinaisia. Sen sijaan neurologisten ja monielinsairauksien alle ryhmittyvät taudit ovat merkittävä syy useisiin sairauksiin, jotka heikentävät elämänlaatua ja aiheuttavat kuolleisuutta. Tästä johtuen neurotieteiden tutkimus ja saatujen tulosten soveltaminen diagnostiikassa ja hoitomuotojen kehittämisessä on hyvin tärkeää. Molekyylikaryotyypitys- ja eksomisekvensointi-menetelmiä hyödynnettiin etsittäessä taudin syytä eteneville neuromuskulaarisairauksille pohjoissuomalaisissa perheissä. Tutkimuksessa tehtiin lisäksi funktionaalisia kokeita GLE1-, NHLRC2- ja MYH7B-proteiineilla, jotta ymmärrettäisiin paremmin löydettyjen mutaatioiden vaikutus potilaiden sairauksiin. Havaittiin, että GLE1-mutaatio vaikutti proteiinin solunsisäiseen paikantumiseen. NHLRC2-proteiini puolestaan on mukana useissa solun biologisissa prosesseissa ja sen toiminnanhäiriö vaikuttaa FINCA-taudin ja fibroosin kehittymiseen. MYH7B-myosiinigeenimutaatio puolestaan yhdistettiin ensimmäistä kertaa enkefalomyopatiaan. Havaittujen tautigeenien; GLE1, NHLRC2 ja MYH7B, vaikutus enkefalomyopatioissa ja neurodegeneraatiossa kertoo, että kyseisillä geeneillä on hyvin todennäköisesti tärkeä rooli ihmisen kehityksessä. Kyseisten, aiemmin tuntemattomien sairautta-aiheuttavien geenimutaatioiden analysointi lisäsi tietoa sairauksien etiologiasta ja loi pohjan tautimekanismien ratkaisemiselle tulevaisuudessa. Työssä esitettyjä uusia sairautta-aiheuttavia geenejä ja uusia karakterisoituja lapsuusiän neuromuskulaarisairauksien ilmiasuja voidaan hyödyntää perheille tarjotun sikiödiagnostiikan lisäksi myös muiden potilaiden samankaltaisen taudinkuvan diagnosoinnissa maailmanlaajuisesti.

arthrogryposis

encephalomyopathy

neurodegeneration

neuromuscular diseases

whole-exome sequencing

artrogrypoosi

eksomisekvensointi

enkefalomyopatia

neurodegeneraatio

neuromuskulaarisairaudet

Whole Exome Sequencing to Identify Disease-Causing Mutations in Lower Motor Neuron Disease and Peripheral Neuropathy

Wagner, Justin

January 2016

Lower motor neuron diseases and peripheral neuropathies are two groups of diseases that include multiple rare disorders where many causes are unknown and definitive treatments are unavailable. Understanding the molecular etiology of these genetic diseases provides an opportunity for rapid diagnosis, preconception genetic counseling and, in a subset, direction for the development of future treatment options. The recent introduction of whole exome sequencing (WES) marks a new era in Mendelian genetic disease research as the majority of the coding region of the genome can be sequenced in a timely and cost-effective manner. In this study, WES was used to investigate the molecular etiology of a cohort of 37 patients presenting with lower motor neuron disease or peripheral neuropathy. A molecular diagnosis was determined for seven patients informing the diagnostic utility of WES. Novel phenotypes were found for three genes originally associated with a different disorder. Finally, the foundation has been laid, through the use of functional studies and large scale data-sharing, to identify novel disease-causing genes for lower motor neuron disease and peripheral neuropathy.

Charcot-Marie-Tooth

Next Generation Sequencing

Whole-Exome Sequencing

Peripheral Neuropathy

Lower Motor Neuron Disease

Indolent feature of Helicobacter pylori-uninfected intramucosal signet ring cell carcinomas with CDH1 mutations / ヘリコバクターピロリ未感染胃に発生するCDH1変異粘膜内印環細胞癌は進行が遅い特徴を持つ

Nikaido, Mitsuhiro

24 September 2021

京都大学 / 新制・論文博士 / 博士(医学) / 乙第13442号 / 論医博第2241号 / 新制||医||1054(附属図書館) / 京都大学大学院医学研究科医学専攻 / (主査)教授 羽賀 博典, 教授 藤田 恭之, 教授 伊藤 貴浩 / 学位規則第4条第2項該当 / Doctor of Medical Science / Kyoto University / DFAM

gastric cancer

signet ring cell carcinoma

Helicobacter pylori

CDH1

whole-exome sequencing

490

EMS Mutagenesis in Quinoa: Developing a Genetic Resource

Cox, Brian James

18 June 2020

Chenopodium quinoa, a South American pseudocereal, has valuable agricultural traits such as salt tolerance and drought tolerance, and it has beneficial nutritional properties such as high protein content and a complete amino acid profile. However, problems including disease susceptibility, low harvest index, lodging, seed shattering, low heat tolerance, and saponin content plague quinoa. Genetic resources for quinoa are needed to fix these problems and make quinoa more available throughout the world. We used ethyl methanesulfonate (EMS) to create a mutant population of QQ74 quinoa (USDA GRIN PI 614886) of 5,030 mutant families. We did whole exome sequencing (WES) on 44 mutant families. Using the recently published quinoa reference genome and MAPS, a mutation detection pipeline, we found a mutation rate of 11.35 mutations/Mb in these families. We also used whole genome sequencing (WGS) to calculate a mutation rate of 21.67 mutations/Mb in an additional nine mutant families. To demonstrate the utility of this population as a genetic resource, we found an EMS-induced nonsense mutation in the betalain synthesis pathway that prevents red betacyanins from accumulating in the hypocotyl of quinoa. With the mutation rates in our population, we calculate that analysis of 300 mutant families will yield 3-7 mutations in any gene of interest, which will facilitate forward and reverse genetic studies in quinoa.

Chenopodium quinoa

ethyl methanesulfonate

mutation

whole exome sequencing

whole genome sequencing

betalains

Life Sciences

Dominant mutations in ORAI1 cause tubular aggregate myopathy with hypocalcemia via constitutive activation of store-operated Ca2+ channels / ORAI1遺伝子の優性変異は、ストア作動性Ca2+チャネルの恒常的活性化を通して細管集合体ミオパチーを引き起こす

Endo, Yukari

23 March 2015

京都大学 / 0048 / 新制・論文博士 / 博士(医学) / 乙第12920号 / 論医博第2095号 / 新制||医||1010(附属図書館) / 32130 / (主査)教授 髙橋 良輔, 教授 松田 文彦, 教授 瀬原 淳子 / 学位規則第4条第2項該当 / Doctor of Medical Science / Kyoto University / DFAM

Tubular aggregate myopathy

Store-operated Ca2+ entry

Whole exome sequencing

490

Genetic Investigations of Juvenile Idiopathic Arthritis

McIntosh, Laura A.

29 October 2018

No description available.

Immunology

juvenile idiopathic arthritis

DOCK2

genome-wide association study

whole exome sequencing

mouse model of arthritis

Which Test is Best? Evaluating the Diagnostic Yield of Sequencing-based Testing Approaches for Patients with Neurodevelopmental Disorders at a Pediatric Institution: A Retrospective Chart Review

Little, Nicholas J.

11 July 2019

No description available.

Genetics

Whole Exome Sequencing

Gene Panel

Diagnostic Yield

Neurodevelopmental Disorders

Intellectual Disability

Next-generation Sequencing

Genetic analysis of pheochromocytoma and paraganglioma complicating cyanotic congenital heart disease / チアノーゼ性先天性心疾患に伴う褐色細胞腫及びパラガングリオーマの遺伝学的解析

Ogasawara, Tatsuki

23 January 2023

京都大学 / 新制・課程博士 / 博士(医学) / 甲第24314号 / 医博第4908号 / 新制||医||1062(附属図書館) / 京都大学大学院医学研究科医学専攻 / (主査)教授 小林 恭, 教授 松田 文彦, 教授 柳田 素子 / 学位規則第4条第1項該当 / Doctor of Medical Science / Kyoto University / DFAM

pheochromocytoma

paraganglioma

cyanotic congenital heart disease

whole exome sequencing

clonal selection

HIF2α

490