Close to the bone
A genetic screening approach to studying bone disease has found nine genes associated with bone health and suggests a new way to discover genes that may be implicated in human skeletal diseases. A collaborative study of the mineral content, strength and flexibility of bones has found clues to the cause of bone disorders such as osteoporosis, osteogenesis imperfecta, and high bone density syndromes. The study, which brings together specialist skills in mouse gene deletion and bone measurement to assess the strength of bones in 100 mutant mouse lines, is the largest reported screen of its type for genes that regulate bone health.
All nine of the new genes discovered had not previously been implicated in skeletal disorders and were discovered by randomly screening different strains of mice engineered such that a single gene had been inactivated in their genome.
Chronic diseases such as osteoporosis represent a global healthcare burden but little is known about their genetic basis. Osteoporosis is the most common of skeletal disorders, affecting hundreds of millions of people worldwide at a cost of billions of pounds each year. Although it is known there is a strong genetic component to this disease, few of the genes that control bone structure and density are known.
“We are developing new ways of finding genes that are essential for normal development of the skeleton, and which maintain the structure and integrity of bone during adulthood. These genes will provide new understanding of the mechanisms responsible for bone diseases and may ultimately lead to the development of new treatments. We collaborated with outstanding colleagues at the Sanger Institute and several Universities. Our studies span many areas of expertise and we have developed a detailed and specific rapid-throughput system to screen bones from mice that lack a single gene. This strategy makes use of existing shared resources at Sanger and greatly reduces the number of mice required.”
Professor Graham Williams Senior author from Imperial College London
The team used an approach that looked at many different physical traits and identified a new classification system for bone mutants based on mineral content, strength, and the density and flexibility of bone. The bones from some mutants were found to be brittle, while others were flexible but weak.
The Sanger Institute Mouse Genetics Projects, the largest centre for genetically engineered mice, generated the mice strains used in the study. These strains of mice were first screened at the Sanger Institute before being sent on to the other collaborating Institutes for further analysis.
“The Mouse Genetics Project’s broad primary trait screen independently identified five genes that when deleted cause bone abnormalities. The other groups used X-ray microradiography, micro-CT and biomechanical testing to further characterise these five genes and identified an additional five genes that affect bone composition. Our study is an example of where approaching biology without any prior assumptions and looking broadly at the effects of inactivating a gene allows you to find new biological insights that wouldn’t be possible in other, more focused studies.”
Dr Jacqueline White One of the authors from the Wellcome Sanger Institute
Serendipitously, one of the random genes selected, Sparc, is a well-studied gene whose deletion results in weak, brittle bones. The screen positively identified this gene as affecting bone health and this acted as a well-characterised positive control for the identification of the nine new genes that the study uncovered.
This study demonstrates that the loss of function of the each of these 10 genes can disrupt the structure and composition of bone. This disruption can be classified into three distinct, different categories: weak and flexible bone with low mineral content similar to postmenopausal osteoporosis, weak and brittle with low mineral content similar to osteogenesis imperfecta and high bone mass which is rare in humans.
“This genome-wide approach is extremely exciting and holds great promise for discovery of genetic susceptibilities and influences in bone disease in addition to providing potential targets for drug development. As we learn more about common diseases that affect millions of individuals it is apparent that many such conditions can have genetically heterogeneous etiologies. The approach outlined by these investigators, although labour intensive, is a terrific example of the power of functional genomics.
“Human genetics studies require these model organisms to get a better understanding of disease and find plausible targets for treatments. This approach has allowed the teams to gain biological insights into the pathways in the body that may be potential therapeutic targets and, perhaps more importantly, help us to start to understand the biology behind bone structure.”
Jim Lupski MD PhD, DSc, a medical genomicist and the Cullen Professor and Vice Chair of Genetics at the Baylor College of medicine in Houston, Texas, USA
The team is currently applying this same technique to study different disease traits in the eye and the brain. As these models are freely available to researchers worldwide from the Mouse Genetics Project, the hope is that other organisations will use these resources to continue the study of these gene deletions.
More information
Funding
A full list of funding can be found on the paper.
Participating Centres
- Molecular Endocrinology Group, Department of Medicine, Imperial College London, London, W12 0NN, UK
- Mouse Genetics Project, Wellcome Trust Sanger Institute, Wellcome Trust Genome Campus, Hinxton, Cambridge, CB10 1SA, UK
- The Mellanby Centre for Bone Research, Department of Human Metabolism, University of Sheffield, Sheffield, S10 2RX, UK
- School of Health and Related Research, University of Sheffield, Sheffield, S1 4DA, UK
- Queen Mary University of London, Oral Growth and Development, Institute of Dentistry, Bart’s and The London School of Medicine, London, E1 1BB, UK
- Garvan Institute of Medical Research, Sydney, Australia
Publications:
Selected websites
The Oxford University Clinical Research Unit
The Oxford University Clinical Research Unit (OUCRU-VN) is a large-scale clinical and public health research unit with campuses in Ho Chi Minh City and Hanoi in Viet Nam. OUCRU-VN is hosted by the Hospital of Tropical Diseases (HTD) in Ho Chi Minh City, and the National Hospital for Tropical Diseases (NHTD) in Hanoi. As a Wellcome Trust Major Overseas Programme, OUCRU-VN has received considerable support from the Trust since its establishment in 1991.
The work of the unit covers clinical and public health research and includes work in immunology, host and pathogen genetics, molecular biology, virology, mathematical modelling, bioinformatics, biostatistics and epidemiology.
Overall, OUCRU-VN aims to have a positive and significant impact on global health and, in particular, the prevention, diagnosis and treatment of infectious diseases. This is being achieved via an integrated long-term research programme, contributions to training, the scientific literature, national and international meetings and membership of national and international committees. Priority is given to health issues important to the hospitals, and to Viet Nam as a whole. All work is intended not only to benefit the patients seen daily at our host hospitals, but also to help improve patient care throughout the country.
The Sanger Mouse Genetics Project
The Sanger Mouse Genetics Project is the largest producer of genetically engineered mice in the world and the largest single centre phenotyping mouse mutants. The Sanger Institute has also lead the production of knockout embryonic stem cell lines for most protein coding genes in the mouse genomes, and played a leading role in the sequencing of the mouse genome. These resources are made available to the research community fostering science around the globe in many areas of biology.
Imperial College London
Imperial College London consistently rated amongst the world’s best universities, Imperial College London is a science-based institution with a reputation for excellence in teaching and research that attracts 14,000 students and 6,000 staff of the highest international quality. Innovative research at the College explores the interface between science, medicine, engineering and business, delivering practical solutions that improve quality of life and the environment – underpinned by a dynamic enterprise culture.
Since its foundation in 1907, Imperial’s contributions to society have included the discovery of penicillin, the development of holography and the foundations of fibre optics. This commitment to the application of research for the benefit of all continues today, with current focuses including interdisciplinary collaborations to improve global health, tackle climate change, develop sustainable sources of energy and address security challenges.
In 2007, Imperial College London and Imperial College Healthcare NHS Trust formed the UK’s first Academic Health Science Centre. This unique partnership aims to improve the quality of life of patients and populations by taking new discoveries and translating them into new therapies as quickly as possible.
The Wellcome Trust Sanger Institute
The Wellcome Trust Sanger Institute is one of the world’s leading genome centres. Through its ability to conduct research at scale, it is able to engage in bold and long-term exploratory projects that are designed to influence and empower medical science globally. Institute research findings, generated through its own research programmes and through its leading role in international consortia, are being used to develop new diagnostics and treatments for human disease.
The Wellcome Trust
The Wellcome Trust is a global charitable foundation dedicated to achieving extraordinary improvements in human and animal health. We support the brightest minds in biomedical research and the medical humanities. Our breadth of support includes public engagement, education and the application of research to improve health. We are independent of both political and commercial interests.