Expansion of the genetic mutation spectrum of different pathologies and identification of new disease-relevant genes in humans by means of Whole Exome Sequencing

Trotz der rasanten Entwicklung molekulargenetischer Analysemethoden sind die Auslöser vieler Erbrankheiten bislang ungeklärt. Eine Identifikation der genetischen Ursache einer Erkrankung ist jedoch essenziell, um zusätzliche invasive Tests vermeiden, adäquate Therapiemaßnahmen in die Wege leiten, akkurate Prognosen stellen und eine entsprechende genetische Beratung anbieten zu können. Next Generation Sequencing (NGS)-basierte Techniken wie die Whole Exome Sequenzierung (WES) haben die humangenetische Forschung und Diagnostik in den letzten Jahren revolutioniert. Die WES ermöglicht die Sequenzierung der Exons aller proteincodierenden Gene von mehreren Individuen gleichzeitig und stellt ein hilfreiches Werkzeug bei der Suche nach neuen kranheitsrelevanten Genen im Menschen dar. Die vorliegende Arbeit beschäftigt sich mit der Aufklärung genetischer Ursachen verschiedenster Erkrankungen in konsanguinen Familien aus dem nahen und mittleren Osten mittels WES. Insgesamt wurden 43 Patienten mit unterschiedlichen Krankheitsbildern untersucht, darunter viele mit Skelettdysplasien oder Neuropathien. In 22 Fällen (51%) konnte die entsprechende krankheitsverursachende Mutation ausfindig gemacht werden. In 21% der aufgeklärten Fälle wurden Sequenzvarianten detektiert, die in der Literatur bereits als pathogen beschrieben wurden, während 63% bisher noch unbekannte Mutationen in bereits als krankheitsrelevant beschriebenen Genen darstellten. Zudem konnten im Rahmen dieser Arbeit drei neue, für den Menschen krankheitsrelevante Gene identifiziert werden, solute carrier family 10 member 7 (SLC10A7), T-box 4 (TBX4) und MIA SH3 domain ER export factor 3 (MIA3). SLC10A7 codiert für einen Transporter aus der Familie der solute carrier, der in der Plasmamembran verankert ist. In dieser Arbeit geleistete Analyseergebnisse konnten zu der Erstbeschreibung von homozygoten pathogenen SLC10A7-Mutationen als Ursache für eine Skelettdysplasie mit Amelogenesis imperfecta beitragen. Bei TBX4 handelt es sich um einen hochkonservierten Transkriptionsfaktor, der während der embryonalen Entwicklung an der Ausbildung der unteren Extremitäten beteiligt ist. Homozygote pathogene TBX4-Mutationen wurden im Kontext dieser Arbeit erstmalig mit einer posterioren Amelie mit Becken- und Lungenhypoplasie in Verbindung gebracht. MIA3 ist ein Transmembranprotein des endoplasmatischen Retikulums, das eine essenzielle Rolle bei der Proteinsekretion spielt. Die hier vorgestellten Patienten mit homozygoten pathogenen MIA3-Mutationen zeigen eine komplexe syndromale Erkrankung, die sich hauptsächlich in einer Kollagenopathie, Diabetes mellitus und milder mentaler Retardierung manifestiert und ein neues Krankheitsbild darstellt. Die im Rahmen dieser Arbeit erzielten Ergebnisse erweitern somit zum einen das Mutationsspektrum verschiedener bekannter Krankheitsbilder und offenbaren zum anderen neue krankheitsrelevante Gene im Menschen.Despite the rapid development of molecular genetic analysis methods, the causes of many hereditary diseases are still unknown. However, it is essential to identify the genetic cause of a disease in order to avoid additional invasive tests, to initiate adequate therapeutic measures, to be able to provdide accurate prognoses, and to offer appropriate genetic counselling. Over the past years, Next Generation Sequencing (NGS)-based technologies such as Whole Exome Sequencing (WES) have revolutionized research and diagnostics in human genetics. WES enables sequencing of the exons of all protein-coding genes from several individuals simultaneously and is a powerful tool in identifying new disease-relevant genes in humans. The present work deals with the elucidation of genetic disease causes in consanguineous families from the Near and Middle East by means of WES. A total of 43 patients with various clinical phenotypes were examined, including many with skeletal dysplasias or neuropathies. In 22 cases (51%), the genetic cause of the disease could be found. In 21% of the solved cases, sequence variants were detected that were already described as pathogenic in the literature, while 63% showed previously unknown mutations in genes already described as disease-relevant in humans. In addition, three new disease-relevant genes could be identified within the scope of this work: solute carrier family 10 member 7 (SLC10A7), T-box 4 (TBX4) and MIA SH3 domain ER export factor 3 (MIA3). SLC10A7 encodes a transporter from the family of solute carriers, which is anchored in the plasma membrane. The analysis results performed in this study could contribute to the first description of homozygous pathogenic SLC10A7 mutations as the cause of a novel skeletal dysplasia with amelogenesis imperfecta. TBX4 is a highly conserved transcription factor that is involved in the formation of the lower extremities during embryonic development. Homozygous pathogenic TBX4 mutations were associated for the first time with posterior amelia with pelvic and pulmonary hypoplasia in the context of this study. MIA3 is a transmembrane protein of the endoplasmic reticulum that plays an essential role in the secretory pathway. The patients presented here with homozygous pathogenic MIA3 mutations show a complex syndromal disease manifesting mainly in a collagenopathy, diabetes mellitus, and mild mental retardation, representing a novel clinical picture. The results obtained within the scope of this work expand on the one hand the range of mutations of various known diseases and on the other hand reveal novel disease-relevant genes in humans

Zebrafish as a model to investigate a biallelic gain-of-function variant in MSGN1, associated with a novel skeletal dysplasia syndrome

Abstract Background/Objectives Rare genetic disorders causing specific congenital developmental abnormalities often manifest in single families. Investigation of disease-causing molecular features are most times lacking, although these investigations may open novel therapeutic options for patients. In this study, we aimed to identify the genetic cause in an Iranian patient with severe skeletal dysplasia and to model its molecular function in zebrafish embryos. Results The proband displays short stature and multiple skeletal abnormalities, including mesomelic dysplasia of the arms with complete humero-radio-ulna synostosis, arched clavicles, pelvic dysplasia, short and thin fibulae, proportionally short vertebrae, hyperlordosis and mild kyphosis. Exome sequencing of the patient revealed a novel homozygous c.374G > T, p.(Arg125Leu) missense variant in MSGN1 (NM_001105569). MSGN1, a basic-Helix–Loop–Helix transcription factor, plays a crucial role in formation of presomitic mesoderm progenitor cells/mesodermal stem cells during early developmental processes in vertebrates. Initial in vitro experiments show protein stability and correct intracellular localization of the novel variant in the nucleus and imply retained transcription factor function. To test the pathogenicity of the detected variant, we overexpressed wild-type and mutant msgn1 mRNA in zebrafish embryos and analyzed tbxta (T/brachyury/ntl). Overexpression of wild-type or mutant msgn1 mRNA significantly reduces tbxta expression in the tailbud compared to control embryos. Mutant msgn1 mRNA injected embryos depict a more severe effect, implying a gain-of-function mechanism. In vivo analysis on embryonic development was performed by clonal msgn1 overexpression in zebrafish embryos further demonstrated altered cell compartments in the presomitic mesoderm, notochord and pectoral fin buds. Detection of ectopic tbx6 and bmp2 expression in these embryos hint to affected downstream signals due to Msgn1 gain-of-function. Conclusion In contrast to loss-of-function effects described in animal knockdown models, gain-of-function of MSGN1 explains the only mildly affected axial skeleton of the proband and rather normal vertebrae. In this context we observed notochord bending and potentially disruption of pectoral fin buds/upper extremity after overexpression of msgn1 in zebrafish embryos. The latter might result from Msgn1 function on mesenchymal stem cells or on chondrogenesis in these regions. In addition, we detected ectopic tbx6 and bmp2a expression after gain of Msgn1 function in zebrafish, which are interconnected to short stature, congenital scoliosis, limb shortening and prominent skeletal malformations in patients. Our findings highlight a rare, so far undescribed skeletal dysplasia syndrome associated with a gain-of-function mutation in MSGN1 and hint to its molecular downstream effectors

SLC10A7 mutations cause a skeletal dysplasia with amelogenesis imperfecta mediated by GAG biosynthesis defects

Skeletal dysplasia with multiple dislocations are severe disorders characterized by dislocations of large joints and short stature. The majority of them have been linked to pathogenic variants in genes encoding glycosyltransferases, sulfotransferases or epimerases required for glycosaminoglycan synthesis. Using exome sequencing, we identify homozygous mutations in SLC10A7 in six individuals with skeletal dysplasia with multiple dislocations and amelogenesis imperfecta. SLC10A7 encodes a 10-transmembrane-domain transporter located at the plasma membrane. Functional studies in vitro demonstrate that SLC10A7 mutations reduce SLC10A7 protein expression. We generate a Slc10a7(-/-) mouse model, which displays shortened long bones, growth plate disorganization and tooth enamel anomalies, recapitulating the human phenotype. Furthermore, we identify decreased heparan sulfate levels in Slc10a7(-/-) mouse cartilage and patient fibroblasts. Finally, we find an abnormal N-glycoprotein electrophoretic profile in patient blood samples. Together, our findings support the involvement of SLC10A7 in glycosaminoglycan synthesis and specifically in skeletal development