Liver Cells Created From Patients’ Skin Cells
Research paves way for new liver disease research and possibly cell-based therapy
By creating diseased liver cells from a small sample of human skin, scientists have for the first time shown that stem cells can be used to model a diverse range of inherited disorders. The University of Cambridge researchers’ findings, which will hopefully lead to new treatments for those suffering from liver diseases, were published today in The Journal of Clinical Investigation.
Because liver cells (hepatocytes) cannot be grown in the laboratory, researching liver disorders is extremely difficult. However, today’s new research, which was funded by the Wellcome Trust and the Medical Research Council (MRC), demonstrates how to create diseased liver-like cells from patients suffering from a variety of liver disorders.
By replicating the organ’s cells, researchers can not only investigate exactly what is happening in a diseased cell, they can also test the effectiveness of new therapies to treat these conditions. It is hoped that their discovery will lead to tailored treatments for specific individuals and eventually cell-based therapy – when cells from patients with genetic diseases are ‘cured’ and transplanted back. Additionally, as the process could be used to model cells from other parts of the body, their findings could have implications for conditions affecting other organs.
Dr Ludovic Vallier of the MRC Centre for Stem Cell Biology and Regenerative Medicine, University of Cambridge, principal investigator of the research, said: “Our work represents an important step towards delivering the clinical promises of stem cells. However, more work remains to be done and our group is dedicated to achieving this ultimate goal by increasing the knowledge necessary for the development of new therapies.”
In the UK, liver disease is the fifth largest cause of death after cardiovascular, cancer, stroke, and respiratory diseases. Over the past 30 years mortality from liver disease in young and middle-aged people has increased over six times, with the number of individuals dying from the disease increasing at a rate of 8-10 per cent every year.
By 2012, the UK is expected to have the highest liver disease death rates in Europe and, without action to tackle the disease, it could overtake stroke and coronary heart disease as the leading cause of death within the next 10-20 years. In the United States, it accounts for approximately 25,000 deaths a year.
For their research, the scientists took skin biopsies from seven patients who suffered from a variety of inherited liver diseases and three healthy individuals (the control group). They then reprogrammed cells from the skin samples back into stem cells. These stem cells were then used to generate liver cells which mimicked a broad range of liver diseases – the first time patient-specific liver diseases have been modelled using stem cells – and to create ‘healthy’ liver cells from the control group. Importantly, the three diseases the scientists modelled covered a diverse range of pathological mechanisms, thereby demonstrating the potential application of their research on a wide variety of disorders.
Dr Tamir Rashid of the Laboratory for Regenerative Medicine, University of Cambridge, lead author of the paper, said: “We know that given the shortage of donor liver organs alternative strategies must urgently be sought. Our study improves the possibility that such alternatives will be found – either using new drugs or a cell-based therapeutic approach.”
Professor Mark Thursz, a specialist in liver disease and Professor of Hepatology at Imperial College (who was not affiliated with the study), commented on the importance of the research: “Liver disease is the fifth most common cause of mortality in many developed countries and unlike the other leading causes of death, the rate of liver related mortality is increasing.
“The development of patient specific liver cell lines from stem cells is a significant advance in the battle against liver diseases. This technology holds promise in the short term by providing new tools to explore the biology of liver diseases and in the long term as a potential source of liver cells for patients with liver failure.”
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