BOSTON–Collaborating scientists in Boston and North Carolina have found that a particular gene can block key steps of the lung cancer process in mice. The researchers report in the journal Nature that LKB1 is not only a “tumor-suppressor” gene for non-small cell lung cancer in mice, it also may be more powerful than other, better-known suppressors. The study will be published on the journal’s Web site on Aug. 5 and later in a print version.
If further research shows LKB1 has a similar effect in human lung cells, it could influence the way non-small cell lung cancer is diagnosed and treated, says the study’s senior author, Kwok-Kin Wong, MD, PhD, of Dana-Farber, one of three institutions, along with Massachusetts General Hospital and the University of North Carolina School of Medicine, leading the work. If tumors with LKB1 mutations are found to be especially fast-growing, for example, patients with such tumors might be candidates for more aggressive therapy.
People born with defective versions of LKB1 often develop Peutz-Jeghers syndrome, which is marked by intestinal growths and an increased risk for certain cancers. Non-inherited mutations of the gene have been found in some lung cancers. This suggested that LKB1 normally thwarts tumors from forming. Mutated versions may be unable to act as a brake on cancer.
To find out, the investigators ran a series of experiments in mice with a defective form of a gene called Kras, which drives the formation and growth of lung cancer. They tracked the development of lung cancer in animals with mutated LKB1 and compared it to the experience of animals with abnormalities in either of two well-known tumor-suppressor genes.
They found that while Kras “cooperated” with the mutated tumor-suppressor genes to produce lung cancer, it cooperated even more strongly with mutated LKB1. “The LKB1-deficient tumors grew more rapidly and spread more frequently than the others, and comprised all three types of non-small cell lung cancer — squamous cell carcinoma, large-cell carcinoma, and adenocarcinoma — rather than just one or two,” Wong says. “This suggests that LKB1 plays a role at major stages of the tumors’ development: initiation, differentiation of normal lung cells into cancer cells, and metastasis.”
An examination of human non-small-cell lung tissue suggests LKB1 mutations play a role there as well. Of 144 samples analyzed, 34 percent of the lung adenocarcinomas and 19 percent of the squamous cell carcinomas contained abnormal versions of the gene, researchers report.
“We were surprised at how significant a role LKB1 mutations play in non-small cell lung cancer development in mice,” say Wong, who is also an assistant professor of medicine at Harvard Medical School. “This suggests there may be additional lung tumor-suppressor genes yet to be discovered. We’re currently examining whether these results apply to human lung cancers as well and, if so, how such information can improve treatment.”
The lead author of the study was Hongbin Ji, PhD, of Dana-Farber. Other Dana-Farber co-authors include Dongpo Cai, PhD, Liang Chen, PhD, Pasi Janne, MD, PhD, Bruce Johnson, MD, Jussi Koivunen, MD, PhD, Danan Li, Mei-Chih Liang, PhD, Kate McNamara, Matthew Meyerson, MD, PhD, Samanthi Perera, PhD, Geoffrey Shapiro, MD, PhD, and Takeshi Shimamura, PhD. Other authors were based at Children’s Hospital Boston, Brigham and Women’s Hospital, Broad Institute of Harvard University and Massachusetts Institute of Technology, University of Tennessee Health Science Center, and the University of Texas Southwestern Medical Center.
The research was supported by the National Institutes of Health, the Sidney Kimmel Foundation for Cancer Research, the American Federation of Aging, the Joan Scarangello Foundation to Conquer Lung Cancer, the Flight Attendant Medical Research Institute, the Waxman Foundation, the Harvard Stem Cell Institute, and the Linda Verville Foundation.
Dana-Farber Cancer Institute (www.dana-farber.org) is a principal teaching affiliate of the Harvard Medical School and is among the leading cancer research and care centers in the United States. It is a founding member of the Dana-Farber/Harvard Cancer Center (DF/HCC), designated a comprehensive cancer center by the National Cancer Institute.
Contact: Bill Schaller
Dana-Farber Cancer Institute
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Type 2 diabetes is reaching epidemic proportions in the developed world. Determining if and how certain genes predispose individuals to type 2 diabetes is likely to lead to the development of new treatment strategies for individuals with the disease.
In a study appearing in the August issue of the Journal of Clinical Investigation Valeriya Lyssenko and colleagues from Lund University in Sweden show that certain variants of the gene TCF7L2 make individuals more susceptible to type 2 diabetes. The susceptibility variants were associated with increased expression of TCF7L2 in pancreatic islet cells and decreased islet cell secretion of insulin. Consistent with this, ectopic overexpression of TCF7L2 in human islet cells decreased insulin secretion in response to exposure to glucose. This study identifies TCF7L2 type 2 diabetes susceptibility variants and provides a mechanism by which these genetic variants might cause susceptibility to the disease. As discussed by the authors and in the accompanying commentary by Andrew Hattersley from Peninsula Medical School in the United Kingdom, future studies are likely to investigate the potential for manipulating the signaling pathways controlled by TCF7L2 for the development of new therapeutics for type 2 diabetes.
TITLE: Mechanisms by which common variants in the TCF7L2 gene increase risk of type 2 diabetes
Lund University, University Hospital Malma, Malma, Sweden.
Phone: 46-40-391214; Fax: 46-40-391222; E-mail: Valeri.Lyssenko@med.lu.se.
View the PDF of this article at: https://www.the-jci.org/article.php?id=30706
TITLE: Prime suspect: the TCF7L2 gene and type 2 diabetes risk
Andrew T. Hattersley
Institute of Biomedical and Clinical Sciences, Peninsula Medical School, Exeter, United Kingdom.
Phone: 44-1392-406806; Fax: 44-1392-406767; E-mail: Andrew.Hattersley@pms.ac.uk.
View the PDF of this article at: https://www.the-jci.org/article.php?id=33077
Contact: Karen Honey
Journal of Clinical Investigation
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Gene fusions trigger cancer growth, could impact treatment choices
ANN ARBOR, Mich. — Researchers at the University of Michigan Comprehensive Cancer Center have discovered how genes turn on the switch that leads to prostate cancer.
The team discovered that pieces of two chromosomes can trade places with each other and cause two genes to fuse together. The fused genes then override the “off” switch that keeps cells from growing uncontrollably, causing prostate cancer to develop.
By testing these gene fusions in mice and in cell cultures, the researchers showed that the fusions are what cause prostate cancer to develop. But it’s not just one set of genes that fuse. The researchers found that any one of several in a family of genes can become scrambled and fuse. Results of the study appear in the Aug. 2 issue of Nature.
“Each of these switches, or gene fusions, represent different molecular subtypes. This tells us there’s not just one type of prostate cancer. It’s a more complex disease and potentially needs to be treated differently in each patient,” says lead study author Arul Chinnaiyan, M.D., Ph.D., director of the Michigan Center for Translational Pathology, a new U-M center whose goal is to translate research into real world practice.
The gene fusion research is the centerpiece project of the new center. In the current study, researchers found one of several abnormal gene fusions in the prostate cancer tissue samples they tested. In 2005, the researchers identified a prostate-specific gene called TMPRSS2, which fuses with either ERG or ETV1, two genes known to be involved in several types of cancer.
The Nature paper reports on five additional genes that fuse with ERG or ETV1 to cause prostate cancer. Gene fusions were involved in 60 percent to 70 percent of the prostate cancer cell lines the researchers looked at. The genes involved are all controlled by a different mechanism. For example, four of the genes are regulated by androgen, a male sex hormone known to fuel prostate cancer. Androgen deprivation is a common therapy for prostate cancer.
Knowing which gene fusion is involved in an individual patient’s tumor could impact treatment options. If an androgen-regulated gene is involved, androgen therapy would be appropriate. But if the gene fusion involves a gene that represses androgen, the anti-androgen therapy could encourage the cancer’s growth. This may also explain why androgen treatment is not effective for some prostate cancers.
“Typing someone’s prostate cancer by gene fusion can affect the treatment given. We would not want to give androgen to someone whose prostate cancer gene fusion is not regulated by androgen,” says Chinnaiyan, who is the S.P. Hicks Collegiate Professor of Pathology at the U-M Medical School.
Rearrangements in chromosomes and fused genes are known to play a role in blood cell cancers like leukemia and lymphoma, and in Ewing’s sarcoma. A fused gene combination that plays a role in chronic myelogenous leukemia led researchers to develop the drug Gleevec, which has dramatically improved survival rates for that disease.
Chinnaiyan believes the prostate gene fusions will eventually lead to similar treatments for prostate cancer.
“More immediately, we hope to develop tests for diagnosis or prognosis. But long-term, we hope this will lead to better therapies to treat prostate cancer. The key challenge is to find a drug that would go after this gene fusion,” Chinnaiyan says.
The gene fusion technology has been licensed to San Diego-based Gen-Probe Inc., which is working on a screening tool to detect gene fusions in urine. The tool could one day supplement or replace the prostate specific antigen, or PSA, test currently used to screen for prostate cancer.
The idea of translating laboratory research findings into a test or treatment that will impact patients is central to the new Michigan Center for Translational Pathology. The center brings together experts in genomics, proteomics and bioinformatics to look at common patterns and potential targets in cancer and other diseases. This is the first center of its kind in the nation in that it is associated with one of 39 National Cancer Institute-designated “comprehensive” cancer centers, a premier medical school and a large health system with both clinicians and patients.
The center’s goal is to study the genes, proteins and other markers on cells to develop new diagnostic tests or screening tools as well as targeted treatments for cancer and other diseases, with the key being to translate these laboratory discoveries into clinical applications.
Chinnaiyan and his team have received numerous awards and honors, including the American Association for Cancer Research Team Science Award for their previously published work on gene fusions, and the Specialized Program of Research Excellence Outstanding Investigator award. The new Center for Translational Pathology supported in part by the Prostate Cancer Foundation, which has offered to match up to $1 million dollars in donations to support work related to developing therapies against prostate cancer gene fusions at the university.
“Mapping of the human genome was only the beginning. Equipped with the comprehensive analysis of the human genome, we can now systematically examine the blueprint of disease at the molecular level. This essential knowledge may lead to better diagnostic tests and promising new treatments for cancer, cardiovascular disease, diabetes and other illnesses,” Chinnaiyan says.
For information about the Michigan Center for Translational Pathology, go to http://www.med.umich.edu/mctp.
About 218,890 men will be diagnosed with prostate cancer this year, and 27,050 will die from the disease, according to the American Cancer Society. The gene fusion work is not currently available for treatment or diagnosis, and no clinical trials are currently recruiting. For information about prostate cancer and currently available treatments, go to http://www.mcancer.org or call the U-M Cancer AnswerLine at 800-865-1125.
In addition to Chinnaiyan, U-M study authors were Scott Tomlins; Saravana Dhanasekaran, Ph.D.; Bharathi Laxman; Qi Cao; Beth Helgeson; Xuhong Cao; David Morris, M.D.; Anjana Menon; Xiaojun Jing; Bo Han; James Montie, M.D.; Kenneth Pienta, M.D.; Diane Roulston; Rajal Shah, M.D.; Sooryanarayana Varambally, Ph.D.; and Rohit Mehra, M.D. Mark Rubin, M.D., from Brigham and Women’s Hospital, Dana-Farber Cancer Institute and Harvard Medical School is also a study author.
Funding for the study came from the U.S. Department of Defense, the National Institutes of Health, the Early Detection Research Network, the Prostate Cancer Foundation and Gen-Probe Inc.
The University of Michigan has filed for a patent on the detection of gene fusions in prostate cancer, on which Tomlins, Mehra, Rubin and Chinnaiyan are co-inventors. The diagnostic field of use has been licensed to Gen-Probe Inc. Chinnaiyan also has a sponsored research agreement with Gen-Probe; however, GenProbe has had no role in the design or experimentation of this study, nor has it participated in the writing of the manuscript.
Reference: Nature, Vol. 448, No. 7153, Aug. 2, 2007
Contact: Nicole Fawcett
University of Michigan Health System
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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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STANFORD, Calif. – Killing cancerous tumors isn’t easy, as anyone who has suffered through chemotherapy can attest. But a new study in mice shows that switching off a single malfunctioning gene can halt the limitless division of tumor cells and turn them back to the path of their own planned obsolescence.
The surprising possibility that a cell’s own natural mechanism for ensuring its mortality could be used to vanquish tumors opens the door to a new approach to developing drugs to treat cancer patients, according to Dean Felsher, MD, PhD, associate professor of medicine (oncology) and of pathology at the Stanford University School of Medicine. Felsher is the senior author of the study to be published July 30 in the advance online version of the Proceedings of the National Academy of Sciences.
“Our research implies that by shutting off a critical cancer gene, tumor cells can realize that they are broken and restore this physiologic fail-safe program,” said Felsher.
Cancer can be notoriously resistant to medical treatment. Not only do cancer cells proliferate uncontrollably, they somehow circumvent the mechanism that causes normal cells to die when they get old or malfunction. That makes cancer cells effectively immortal unless doctors manage to squelch them.
The gene Felsher’s team studied produces a protein called Myc (pronounced “mick”), which promotes cell division. A mutation of the gene causes cells to overproduce the protein, prompting perpetual cell division and tumor growth. By turning off the mutated gene, the researchers found that not only did uncontrolled cell division cease, but the cells also reactivated a normal physiological mechanism, called senescence, which makes it possible for a cell to eventually die.
“What was unexpected was just the fact that cancer cells had retained the ability to undergo senescence at all,” said Felsher. Cancer researchers had long thought the senescence process had to be irreversibly disrupted for a tumor to develop.
The researchers worked with a series of mice engineered to have Myc-triggered cancers of either the liver, blood or bones, along with a specially constructed version of the Myc gene that they could switch off by feeding the mice antibiotics. When the mice dined on doses of the drugs, invariably, the tumors ceased growing and then diminished, with some disappearing over the course of just a few days.
Although Felsher’s lab had previously shown that mouse tumors diminished and disappeared when Myc was switched off, they hadn’t been sure how the process actually worked. Historically, most research involving genetic methods of battling cancer cells has focused on reactivating genes called tumor-suppressor genes, which are generally overcome by a proliferating cancer. No one had explored the idea that senescence might play a key role in diminishing tumors.
Felsher described senescence as acting like a fail-safe mechanism to stop cancer. When a cell detects a deleterious mutation, it launches the senescence process, resulting in the permanent loss of the cell’s ability to proliferate, thus halting any cancer.
“In order to become tumor cells, those cells have to overcome senescence,” said Chi-Hwa Wu, PhD, postdoctoral researcher in Felsher’s lab and first author of the study. Wu had the inspiration to explore whether the sudden diminishment they had observed in the tumors might be due to the reactivation of some latent remnant of the trigger for senescence.
Through a series of experiments looking at enzymes associated with the senescence process, as well as some molecular markers, Wu confirmed her suspicion. And not only was senescence occurring in cells that had been thought to be incapable of it, the process was reactivated in all the different tumors they studied.
Consider it a cell version of the Jekyll-and-Hyde transformation. “It’s sort of like Mr. Hyde realizing that there’s something wrong with him and then being able to put himself back into his normal state as Dr. Jekyll,” Felsher said.
In addition to the deepened understanding of how the process of senescence works, Felsher and Wu see a lot of potential for new approaches to treating cancer, beyond the traditional tactic of trying to kill cancer cells directly. “This work implies that maybe part of the strategy should involve figuring out how to get the cancer cells to just be allowed to do what they originally wanted to do anyway, which is to not be proliferating endlessly and growing uncontrolled,” said Felsher.
The next step for the team is to see how well the approach works in human cancer cells. “And we’re also trying to figure out what the mechanism is,” Felsher said. “What are the molecular mechanisms of this, so that we can figure out how to better treat cancer””
Other authors on the research paper are Jan van Riggelen, PhD, postdoctoral researcher; Alper Yetil, graduate student in cancer biology; Alice Fan, MD, instructor in medicine (oncology), and medical student Pavan Bachireddy.
The study was funded by the National Cancer Institute, the National Institutes of Health, the Leukemia and Lymphoma Society, the Burroughs Wellcome Fund, the Damon Runyon Lilly Clinical Investigator Award, the Lymphoma Research Foundation and the Howard Hughes Medical Institute.
Stanford University Medical Center integrates research, medical education and patient care at its three institutions – Stanford University School of Medicine, Stanford Hospital & Clinics and Lucile Packard Children’s Hospital at Stanford. For more information, please visit the Web site of the medical center’s Office of Communication & Public Affairs at http://mednews.stanford.edu.
Contact: Lou Bergeron
Stanford University Medical Center
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WINSTON-SALEM, N.C. – A gene discovered by scientists at Wake Forest University School of Medicine has been linked to lupus and related autoimmune diseases. The finding, reported in the current issue of Nature Genetics, is the latest in a series of revelations that shed new light on what goes wrong in human cells to cause the diseases.
“This research is a huge leap toward understanding the cause of lupus and related autoimmune diseases,” said Fred Perrino, Ph.D., a co-author on the paper and a professor of biochemistry at Wake Forest. “There had been few clues before now.”
Perrino, who discovered the gene in 1998, said he suspected it was involved in human disease, but it took a group of researchers from around the world collaborating to put the puzzle together.
“We’ve known that lupus was a complex disease, but now we have a specific protein and a particular cellular process that appears to be one of the causes,” said Perrino. “We’re connecting the dots to understand the biology of what’s going on with the disease.”
In Nature Genetics, lead author Min Ae Lee-Kirsch, M.D., from the Technische Universität Dresden in Dresden, Germany, and colleagues report finding variations of the TREX1 gene discovered by Perrino in patients with systemic lupus erythematosus. The study involved 417 lupus patients from the United Kingdom and Germany. Mutations were found in nine patients with lupus and were absent in 1,712 people without lupus.
“Our data identify a stronger risk for developing lupus in patients that carry variants of the gene,” said Lee-Kirsch.
In recent years, the gene was also linked to Aicardi-Goutieres syndrome, a rare neurological disease that causes death in infants, and to chilblain lupus, an inherited disease associated with painful bluish-red skin lesions that occur during cold weather and usually improve in summer. The current research also links it to Sjogren’s syndrome, a form of lupus.
The diseases are all autoimmuine diseases, which means that the body makes antibodies against itself. In lupus, these antibodies cause pain and inflammation in various parts of the body, including the skin, joints, heart, lungs, blood, kidneys and brain. The disease is characterized by pain, heat, redness, swelling and loss of function.
Perrino began studying the protein made by the gene more than 14 years ago.
“We basically cracked open cells to locate the protein and find the gene,” said Perrino. “In the 14 years since, we’ve learned a lot about the protein and how it functions.”
The gene manufactures a protein, also known as TREX1, whose function is to “disassemble” or “unravel” DNA, the strand of genetic material that controls processes within cells. The “unraveling” occurs during the natural process of cells dying and being replaced by new cells. If a cell’s DNA isn’t degraded or unraveled during cell death, the body develops antibodies against it.
“If the TREX1 protein isn’t working to disassemble the DNA, you make antibodies to your own DNA and can end up with a disease like lupus,” said Perrino.
Perrino and colleagues at Wake Forest have been studying the gene and its protein since 1993. Thomas Hollis, Ph.D., an assistant professor of biochemistry at Wake Forest, is credited with solving the structure of both TREX1 and a similar protein, TREX2. Perrino has also developed a way to measure the function of the proteins.
In a study reported in April in the Journal of Biological Chemistry, Hollis and Perrino found that three variations of the gene reduced the activity of the protein by four- to 35,000-fold.
“Now that we have the structure, we can understand how it disassembles DNA and how mutations in the gene may affect that process,” said Hollis.
The researchers hope that understanding more about the gene’s mutations and the structure of the protein may lead to drug treatments to help ensure that mutant copies of the gene are inactive.
Media Contacts: Karen Richardson, email@example.com; Shannon Koontz, firstname.lastname@example.org; at 336-716-4587.
Wake Forest University Baptist Medical Center is an academic health system comprised of North Carolina Baptist Hospital and Wake Forest University Health Sciences, which operates the university’s School of Medicine. U.S. News & World Report ranks Wake Forest University School of Medicine 18th in primary care and 44th in research among the nation’s medical schools. It ranks 35th in research funding by the National Institutes of Health. Almost 150 members of the medical school faculty are listed in Best Doctors in America.
Contact: Karen Richardson
Wake Forest University Baptist Medical Center
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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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