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Genetic research at King's College London (KCL) has had significant impact on the current and future care of people with motor neurone disease (MND). KCL researchers discovered several MND-causing genes, which have been taken up by diagnostic and research laboratories throughout the world. This has improved early diagnosis and predictive gene testing in high-risk families and enabled children to be born free of MND by pre-implantation genetic diagnosis. Research laboratories in academia and industry have used mutant genes in cellular and animal models to identify fundamental disease mechanisms and disease-critical pathways to advance drug discovery for this fatal disease.
Acute promyelocytic leukaemia (APL) is of interest because it is the first cancer that can be cured with drugs that target a unique molecular abnormality. KCL research has developed accurate molecular techniques which are essential to diagnose the disease, guide treatment, and monitor for relapse. Sub-microscopic levels of leukaemic cells remaining in the patient's bone marrow after treatment (referred to as `minimal residual disease') give an early warning of re-occurrence of the disease. Our laboratory has developed sensitive tests for these cells, allowing treatment to be tailored to individual patient needs. This has had a major impact on APL diagnosis and monitoring and has been incorporated in national and international disease-treatment guidelines.
As a result of research from Oxford's Professor Andrew Wilkie, accurate genetic diagnostic tests are now available for over 23% of all craniosynostosis cases nationally and internationally, leading to improved family planning and clinical management of this common condition worldwide. The premature fusion of cranial sutures, known as craniosynostosis, is a common developmental abnormality that occurs in 1 in 2,500 births. Over the past 20 years, the University of Oxford's Clinical Genetics Lab, led by Professor Wilkie in collaboration with the Oxford Craniofacial Unit, has identified more than half of the known genetic mutations that cause craniosynostosis and other malformations of the skull.
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.
Research carried out by the University of Southampton into the genetic causes of diseases, and the gene mapping techniques and applications derived from this research, has benefited patients worldwide through improved prediction, diagnosis and treatment for common diseases with a complex genetic basis. A particularly striking example is age-related macular degeneration which is a common cause of blindness. Commercially, the research provides cost-effective strategies for genotyping DNA samples, and marker-based selection strategies for economically relevant animal species, such as cattle. The work underpins the development of the personal genomics industry, which specialises in individual genetic risk profiling.
The Caldecott/Jeggo/O'Driscoll laboratories have identified human genetic diseases that are caused by defects in genes involved in DNA strand-break repair. Many of these diseases are associated with neurological pathologies such as cerebellar ataxia (resulting in poor balance, movement control, and patients often being wheelchair bound), microcephaly (smaller-than-normal head circumference), and developmental delay. The Caldecott/Jeggo/O'Driscoll laboratories have engaged in identifying/diagnosing patients with such diseases as a service to clinicians/clinical geneticists in the UK National Health Service (NHS) and worldwide. Since 2008, these laboratories have identified the underlying genetic defect in more than 150 patients with a range of hereditary DNA damage-related disorders. In particular, these laboratories have diagnosed patients with genetic defects in the DNA damage response genes Lig4, NHEJ1-XLF, DCLRE1C-Artemis, PRKDC-DNA-PKcs, PCNT, ORC1, ATRIP, ATR, and TDP2. These diagnoses benefit both the clinical geneticist and the patient; identifying not only the cause of the patient's disease but also enabling better disease management. For example, if not first diagnosed, standard chemotherapeutic regimes can be fatal in cancer patients who harbour homozygous TDP2 mutations, and standard conditioning regimes used during bone-marrow transplantation can be fatal in LIG4 Syndrome patients. These diagnoses can therefore translate into increased patient survival.
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 from the University of Oxford's Clinical Genetics Laboratory initiated the introduction of an upper age limit of 40 years for sperm donors in the UK and internationally and led to increased public awareness of the effect of paternal age in the transmission of inherited disease. Oxford researchers, led by Professor Andrew Wilkie, were the first to describe the exclusively paternal transmission of de novo mutations, in a rare craniofacial disorder called Apert Syndrome; they also showed that the accumulation of such mutations leads to a disproportionate risk of disease transmission with age. By showing that the frequency of mutations increases with paternal age, this research contributed to important changes in clinical practice relating to sperm donation. This has also had a significant cultural impact, as the research and its clinical outcomes have challenged public perceptions of paternal age.
Research by Professor Elizabeth Shephard at the UCL Research Department of Structural and Molecular Biology has led to identification of the genetic origin of Trimethylaminuria (TMAU), commonly known as fish-odour syndrome. This has led to genetic diagnosis and genetic counselling for TMAU in the UK, Europe, USA and Canada, and the publication of guidelines for treatment and diagnosis. Shephard has engaged closely with patient groups over the years to publicise her findings. There is now an increased understanding among medical practitioners and the public that the body odour produced is due to a metabolic defect of genetic origin, and is not due to poor hygiene.
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.