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King's College London (KCL) researchers have had a tremendous impact on furthering the understanding of how titin mutations lead to severe hereditary and spontaneous muscle diseases, which has ultimately improved clinical guidelines, genetic diagnosis and counselling of patients and their families. New genetic tests, driven by KCL research pinpointing how specific mutations adversely impact the normal interaction of titin with other proteins and lead to a loss of muscle function, have been adopted by public health agencies across Europe. Based on these original research insights, novel potential treatment targets continue to be discovered, and drugs aimed at these targets are currently being developed.
Professor Dickson's research group at Royal Holloway has pioneered the enabling technologies for the development of genetic therapies for the incurable disease Duchenne Muscular Dystrophy (DMD). Dickson's group has, (i) cloned replacement copies of the normal DMD gene, (ii) identified a natural substitute for the defective gene, and (iii) demonstrated that synthetic DNA can be used to correct the defective gene. The work has created impact on health and welfare through the development and clinical trials of a series of investigational medicinal products for this hitherto incurable disease, several clinical trials, and impact on commerce through industrial investment and licensed patents.
Understanding and finding treatments for rare disease represents a major challenge across medicine. We have shown this is possible for rare muscle channelopathies and our work has directly benefited the lives of patients. Our 15 year basic research programme has elucidated the genetic architecture and identified new disease mechanisms for these disabling muscle conditions. We also determined the true disease frequency through the only UK epidemiology study. We translated fundamental research into new DNA-based diagnostic testing and electrophysiological diagnostics for rapid and reliable diagnosis. Our research led directly to our centre being commissioned by the NHS (£6m) as the only UK centre for diagnosis and management and we established the UK NHS national genetics channelopathy reference laboratory. We have built the world's largest genetically stratified patient cohorts which allowed us to lead the first international randomised controlled trial. This trial showed clear efficacy of a reprofiled mexiletine. This led to a successful European orphan product status application for this indication and national treatment guidelines.
Research at the UCL School of Pharmacy has positively influenced healthcare in startle disease/hyperekplexia, a rare disease that affects humans and several animal species, including dogs, horses and cattle. The identification and functional characterisation of mutations in genes involved in human startle disease by researchers at the School has improved genetic diagnostics and patient care. Our research on startle disease in cattle and dogs has also led to new non- invasive diagnostic tests that have alleviated animal suffering and reduced negative economic impacts on farmers. Overall, our findings have been translated into tangible benefits for the human and animal populations affected by this disease and have changed the way in which the disease is diagnosed and treated. We have also significantly increased the awareness of this rare disorder by communicating with academics, healthcare and veterinary professionals, and the general public.
Research by Professor David Brook on inherited disorders has made a major contribution to the human genetics field. The work involved gene identification and mutation detection for genotype/phenotype correlation analysis in patients, which has led to the development of diagnostic tests for inherited conditions including myotonic dystrophy type 1 (DM1), Holt-Oram Syndrome (HOS), and campomelic dysplasia (CD). The tests have benefitted patients in the UK and throughout the rest of the world and in many cases they have been used as the definitive diagnostic measure. The assays developed have also been used in affected families for prenatal diagnosis to enable informed reproductive decisions.
Research conducted by Professor TM Cox has led to several advances in the management of lysosomal storage disorders; i) development of miglustat (Zavesca®); now available throughout the world (EMA and FDA approved) for adult patients with Gaucher's disease and throughout the European Union and five other countries worldwide for adult and pediatric patients with Niemann- Pick type C disease, ii) development of the potential successor eliglustat; now in Phase 3 clinical trials, iii) identification of a biomarker for Gaucher's: CCL18/PARC, now incorporated into NHS standard operating procedures for monitoring therapeutic intervention. His pre-clinical research into gene therapy for Tay-Sachs disease also helped establish the NIH-funded Gene Therapy Consortium and gain the FDA's pre-IND approval for clinical trials in 2013, which together have raised public awareness of this disease.
Congenital myasthenic syndromes (CMS) are inherited neuromuscular disorders caused by defects at neuromuscular junctions, which are often a result of acetylcholine receptor gene mutations. A subset of CMS patients (around 14% in the US and Europe) have limb-girdle myasthenia (LGM). This disease can be highly disabling with symptoms including increasing weakness of skeletal muscles. As a result of collaborative work between Newcastle and Oxford, it was determined that many LGM patients have a mutation of the Dok-7 gene (unrelated to the acetylholine receptor), and do not, therefore, respond to standard CMS treatments. Since then, a number of additional mutations have been discovered, and genetic testing is now available for the majority of known LGM-causative genes. Crucially, Dok-7 patients, and those with other non-receptor related mutations, can now be diagnosed accurately and treated effectively, with ephedrine and salbutamol (in the US, albuterol). This significantly improves these patients' quality of life by enabling them to walk and breathe unassisted.
Ataxia telangiectasia (A-T) is an inherited disease affecting multiple systems in the body, causing severe disability and death. Work led by Professor Malcolm Taylor at the University of Birmingham has been central to the biological and clinical understanding of this disease, from the identification of the gene responsible to the clarification of related conditions with different underlying causes. As a result of this work, within the 2008-13 period, his laboratory has been designated the national laboratory for clinical diagnosis of A-T — a service also offered internationally — and has also changed national screening policy for breast cancer, following his confirmation of the increased risks of A-T patients and those who carry a single copy of the gene for this type of tumour. Furthermore, he has contributed in a major way to patient support for this condition.
Research conducted by Professor Jo Bradwell at the University of Birmingham provided the basis of the commercially available diagnostic test Freelite®, which quantifies free immunoglobulin light chains in serum and was the first and only assay for the diagnosis and monitoring of Multiple Myeloma (MM). MM is a cancer of immunoglobulin producing plasma cells in the bone marrow. Freelite® has markedly improved the diagnosis and management of MM, is helpful in the diagnosis of all B cell lymphoid neoplasias and provides prognostic information for premalignant conditions present in over 3% of people over 50 years of age. Freelite was commercialised by the University of Birmingham spinout company, the Binding Site, which has achieved worldwide sales, with over 360,000 tests being sold per month in 90 countries and an ongoing 25% annual growth in sales. The company provides annual revenue of £55m and employment for 620 people in the UK and abroad. An improved second generation of tests has been developed by Professor Mark Drayson at the University of Birmingham, which has been commercialised by a second University spinout company Serascience, which started marketing a point of care free light chain diagnostic test worldwide in April 2013.
Long-standing research led by Prof. O'Rahilly (Department of Clinical Biochemistry) into the genetic and biochemical basis of severe insulin resistance syndromes, has led to improvements in diagnosis and care of patients internationally. These advances have facilitated revision of existing clinical classifications and implementation of novel diagnostic and management algorithms for these conditions. The clinical applicability of this research was recognised in 2011 by the Department of Health-England who have commissioned a national severe insulin resistance service in Cambridge, with support totalling ~£450,000 per annum.