This release is available in French.
An international team of researchers has published a benchmark study showing that gene expression in several animal models of Huntington’s Disease (HD) closely resembles that of human HD patients.
The results, published August 1, 2007, in the , validate the applicability of using animal models to study human disease and will have important consequences for the pertinence of these models in preclinical drug testing.
Huntington’s disease is an incurable and fatal hereditary neurodegenerative disorder caused by a mutation in the gene that encodes the huntingtin protein. Neurons in certain regions of the brain succumb to the effects of the altered protein, leading to severe motor, psychiatric, and cognitive decline. Several recent studies have shown that the mutant huntingtin protein modifies the transcriptional activity of genes in affected neurons. This disease mechanism is a promising new avenue for research into the causes of neuronal death and a novel potential approach for treatment.
Led by EPFL professor Ruth Luthi-Carter, and involving collaborators from six countries, the current study found a marked resemblance between the molecular etiology of neurons in animal models and neurons in patients with HD. This implies that animal models are relevant for studying human HD and testing potential treatments.
To come to this conclusion, the scientists measured the gene expression profile of seven different transgenic mouse models of HD, representing different conditions and disease stages. These profiles clarified the role of different forms and dosages of the protein hungtintin in the transcriptional activity of neurons. They then designed and implemented novel computational methods for quantifying similarities between RNA profiles that would allow for comparisons between the gene expression in mice and in human patients. “Interestingly, results of different testing strategies converged to show that several available models accurately recapitulate the molecular changes observed in human HD,” explains Luthi-Carter. “It underlines the suitability of these animal models for preclinical testing of drugs that affect gene transcription in Huntington’s Disease.”
EPFL Laboratory of functional neurogenomics, http://lngf.epfl.ch/
Alexandre Kuhn ; +41 21 693 1731
Professor Ruth Luthi-Carter; +41 21 693 9533
Contact: Alexandre Kuhn
Ecole Polytechnique Fédérale de Lausanne
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ST. PAUL, MN — Researchers have identified a new gene mutation linked to frontotemporal dementia, according to a study published in the July 10, 2007 issue of Neurology®, the medical journal of the American Academy of Neurology.
Frontotemporal dementia, one form of which is known as Pick’s disease, involves progressive shrinking of the areas of the brain that control behavior and language. Symptoms include language problems and personality changes, often with inappropriate social behavior. Unlike Alzheimer’s disease dementia, the disease does not affect memory in the early stages. The genetic form of the disease is rare; most cases occur randomly.
“We are hopeful that this finding will help us better understand how this disease works and eventually help us develop new therapies for the disease,” said study author Amalia Bruni, MD, of the Regional Neurogenetic Centre in Lamezia Terme, Italy.
The researchers discovered a new mutation in the gene named progranulin in an extended family in southern Italy. The genealogy of this family has been reconstructed for 15 generations, going back to the 16th century; 36 family members have had frontotemporal dementia. For this study, DNA tests were conducted on 70 family members, including 13 people with the disease. “This is an important result that we pursued for more than 10 years,” said study co-author Ekaterina Rogaeva, PhD, with the Centre for Research in Neurodegenerative Diseases at the University of Toronto.
The mutation identified in this study is in a gene on chromosome 17. The mutation leads to a loss of progranulin, a protein growth factor that helps brain cells survive. The mutation causes only half of the protein to be produced, because only one copy of the gene is active. Production of too much progranulin has been associated with cancer.
The new gene mutation was found in nine of those family members with the disease and 10 people who are currently too young to have the symptoms of the disease. But four people with the disease did not have the gene mutation. Bruni noted that these four people belong to a branch of the family with the disease in at least three generations. “These results are intriguing, since the family has two genetically distinct diseases that appear almost identical,” said Bruni.
The Italian family had no cases with two copies of the mutated gene. “We would have expected to see cases with two copies of the mutated gene, especially since this family shares much of the same genetic material, as there have been at least five marriages between first cousins over the years,” Bruni said. “It’s possible that loss of both copies of the progranulin gene leads to the death of embryos, and that’s why there were no cases with two copies of the mutated gene.”
“Another intriguing aspect in this Italian family is the variable age at onset, which ranged from 35 to 87 years in the family members who inherited the same mutation. Our future research will try to identify the modifying factors responsible for the severity of the disorder,” said Rogaeva.
Rogaeva says their studies will also try to identify the second gene responsible for dementia in this family.
The study was supported by grants from the Canadian Institutes of Health Research, Howard Hughes Medical Institute, Canada Foundation for Innovation, Japan-Canada and Canadian Institutes of Health Research Joint Health Research Program, Parkinson Society of Canada, W. Garfield Weston Fellows, Japanese Society for the Promotion of Science, National Institute on Aging Intramural Program, Italian Ministry of Health, and the Calabria Regional Health Department.
The American Academy of Neurology, an association of more than 20,000 neurologists and neuroscience professionals, is dedicated to improving patient care through education and research. A neurologist is a doctor with specialized training in diagnosing, treating and managing disorders of the brain and nervous system such as stroke, Alzheimer’s disease, epilepsy, Parkinson’s disease, and multiple sclerosis.
For more information about the American Academy of Neurology, visit http://www.aan.com.
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