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Enzyme fights mutated protein in inherited Parkinson's disease
June 26, 2009An enzyme that naturally occurs in the brain helps destroy the mutated protein that is the most common cause of inherited Parkinson's disease, researchers at UT Southwestern Medical Center have found.
Their study, using human cells, provides a focus for further research into halting the action of the mutated protein. One of the most famous carriers of the mutation is Google co-founder Sergey Brin, who wrote about it on his blog in 2008.
"There are currently enormous efforts to identify potential therapies based on inhibiting this mutated protein," said Dr. Matthew Goldberg, assistant professor of neurology and psychiatry and senior author of the paper, which appears online in the journal Public Library of Science.
"Our paper is a major advance because we identify a protein that binds to the mutated protein and promotes its breakdown," he said.
The particular mutation that they studied affects a protein whose function is not well understood. In its normal form, it appears to have multiple sites where other molecules can attach themselves, like a space station with many docking areas.
Several mutations can affect the protein, which is named LRRK2. Some of the mutations cause Parkinson's disease.
The current theory is that the mutation leads to increased function of LRRK2 and to the formation of abnormal clumps of proteins inside brain nerve cells. The cells eventually die from these effects.
In the current study, the researchers used cultured human kidney cells and found that LRRK2 and a protein called CHIP "robustly" associated with each other.
Further testing showed that CHIP and LRRK2 could bind to each other in two different ways, either directly or indirectly by a third molecule that acted as a bridge.
When CHIP bound to either the normal or mutant form of LRRK2, levels of LRRK2 in the cell decreased, the researchers found. This occurred because the cells increased the rate at which they destroyed LRRK2.
"CHIP may be a useful therapeutic target for treatments to break down LRRK2 in people with Parkinson's," Dr. Goldberg said.
"Our next step is to identify cellular mechanisms that signal LRRK2 to be degraded by CHIP or by other mechanisms," he said. "Because LRRK2 mutations are believed to cause Parkinsonism by increasing the activity of LRRK2, enhancing the normal mechanisms that target LRRK2 for degradation by CHIP may be therapeutically beneficial."
UT Southwestern Medical Center
"Our paper is a major advance because we identify a protein that binds to the mutated protein and promotes its breakdown," he said.
The particular mutation that they studied affects a protein whose function is not well understood. In its normal form, it appears to have multiple sites where other molecules can attach themselves, like a space station with many docking areas.
Several mutations can affect the protein, which is named LRRK2. Some of the mutations cause Parkinson's disease.
The current theory is that the mutation leads to increased function of LRRK2 and to the formation of abnormal clumps of proteins inside brain nerve cells. The cells eventually die from these effects.
In the current study, the researchers used cultured human kidney cells and found that LRRK2 and a protein called CHIP "robustly" associated with each other.
Further testing showed that CHIP and LRRK2 could bind to each other in two different ways, either directly or indirectly by a third molecule that acted as a bridge.
When CHIP bound to either the normal or mutant form of LRRK2, levels of LRRK2 in the cell decreased, the researchers found. This occurred because the cells increased the rate at which they destroyed LRRK2.
"CHIP may be a useful therapeutic target for treatments to break down LRRK2 in people with Parkinson's," Dr. Goldberg said.
"Our next step is to identify cellular mechanisms that signal LRRK2 to be degraded by CHIP or by other mechanisms," he said. "Because LRRK2 mutations are believed to cause Parkinsonism by increasing the activity of LRRK2, enhancing the normal mechanisms that target LRRK2 for degradation by CHIP may be therapeutically beneficial."
UT Southwestern Medical Center
Mutated Protein Current Events and Mutated Protein News RSSPromising new treatment for Alzheimer's suggested based on Hebrew University research
Research carried out at the Hebrew University of Jerusalem has resulted in a promising approach to help treat Alzheimer's disease in a significant proportion of the population that suffers from a particularly rapid development of this disease.
Enzyme fights mutated protein in inherited Parkinson's disease
An enzyme that naturally occurs in the brain helps destroy the mutated protein that is the most common cause of inherited Parkinson's disease, researchers at UT Southwestern Medical Center have found.
Man's best friend recruited in the hunt for disease genes
For centuries man has had a uniquely close relationship with dogs - as a working animal, for security and, perhaps most importantly, for companionship. Now, dogs are taking on a new role - they are helping in the hunt for genetic mutations that lead to diseases in humans.
Researchers discover cell's 'quality control' mechanism
Researchers in Japan and Canada have discovered a key component of the quality control mechanism that operates inside human cells - sometimes too well. The breakthrough has significant implications for the development of new treatments for cystic fibrosis (CF) and some other hereditary diseases, the researchers say. Their results were published July 25 in the journal Science.
New Cancer Treatment Targets Both Tumor Cells and Blood Vessels
It takes more than one punch to fight tumors. Often, tumors have more than one way of surviving, and attacking the tumor alone is not enough.
RNA Toxicity Contributes to Neurodegenerative Disease, University of Pennsylvania Scientists Say
Expanding on prior research performed at the University of Pennsylvania, Penn biologists have determined that faulty RNA, the blueprint that creates mutated, toxic proteins, contributes to a family of neurodegenerative disorders in humans.
Adult stem cell changes underlie rare genetic disease associated with accelerated aging
Adult stem cells may provide an explanation for the cause of a Hutchinson-Gilford Progeria Syndrome (HGPS), a rare disease that causes premature aging in children, according to researchers at the National Cancer Institute (NCI), part of the National Institutes of Health (NIH).
Chemical chaperone could open door to treatment of neurological disorder
An unexpected finding turned out to be a clue leading researchers at Washington University School of Medicine in St. Louis to propose a new treatment approach for Niemann-Pick disease, a rare, deadly neurodegenerative disorder.
Huntington's disease problem start early
The damaging effects of the mutated protein involved in Huntington's disease take place earlier in cell life than previously believed, said researchers from Baylor College of Medicine in Houston in a report that appears in the current edition of the journal Neuron.
Researchers show that fibrosis can be stopped, cured and reversed
University of California, San Diego researchers have proven in animal studies that fibrosis in the liver can be not only stopped, but reversed.
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