A Roadmap to Gene Discoveries and Novel Therapies in Monogenic Low and High Bone Mass Disorders.

Wei Zhou,Wim Van Hul,Natalia Garcia-Giralt,Antonio Maurizi,Daniel Grinberg,Graham R. Williams,Maria Luisa Brandi,Outi Mäkitie,Wolfgang Högler,Celia L. Gregson,Diana Ovejero Crespo,Anders Kämpe,Susanna Balcells,Luca Sangiorgi,Dylan J. M. Bergen,M. Carola Zillikens,Melissa M. Formosa,J. H. Duncan Bassett

doi:10.3389/fendo.2021.709711

Abstract

Genetic disorders of the skeleton encompass a diverse group of bone diseases differing in clinical characteristics, severity, incidence and molecular etiology. Of particular interest are the monogenic rare bone mass disorders, with the underlying genetic defect contributing to either low or high bone mass phenotype. Extensive, deep phenotyping coupled with high-throughput, cost-effective genotyping is crucial in the characterization and diagnosis of affected individuals. Massive parallel sequencing efforts have been instrumental in the discovery of novel causal genes that merit functional validation using in vitro and ex vivo cell-based techniques, and in vivo models, mainly mice and zebrafish. These translational models also serve as an excellent platform for therapeutic discovery, bridging the gap between basic science research and the clinic. Altogether, genetic studies of monogenic rare bone mass disorders have broadened our knowledge on molecular signaling pathways coordinating bone development and metabolism, disease inheritance patterns, development of new and improved bone biomarkers, and identification of novel drug targets. In this comprehensive review we describe approaches to further enhance the innovative processes taking discoveries from clinic to bench, and then back to clinic in rare bone mass disorders. We highlight the importance of cross laboratory collaboration to perform functional validation in multiple model systems after identification of a novel disease gene. We describe the monogenic forms of rare low and high rare bone mass disorders known to date, provide a roadmap to unravel the genetic determinants of monogenic rare bone mass disorders using proper phenotyping and genotyping methods, and describe different genetic validation approaches paving the way for future treatments.

Highlights

Skeletal development is regulated by numerous genetic factors that guide the growth, modeling and remodeling of skeletal structures starting in early fetal development and continuing throughout life
The variability of presentation and genotypes has made it difficult to differentiate between Osteogenesis imperfecta (OI) and so-called primary osteoporosis, which is why we present a spectrum of these entities (Table 1)
A specific diagnosis is helpful in the follow-up and treatment of the patient, and in predicting long-term outcomes of the disorder

Summary

Introduction

Skeletal development is regulated by numerous genetic factors that guide the growth, modeling and remodeling of skeletal structures starting in early fetal development and continuing throughout life. These processes are crucial for attainment of normal height, skeletal patterning, bone shape, and mobility, and for maintenance of normal bone mass and fracture resistance. More than 460 different forms of skeletal dysplasia, most of them monogenic, have been recognized [1] They are estimated to affect approximately 1/5,000 children [2, 3], and can have distinct clinical manifestations and course. The genetic basis has been described and mutations in the responsible genes identified in a significant proportion of these conditions, for several distinct skeletal dysplasia phenotypes the genetic cause is still not known [1]

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Conclusion