Posts tagged ALS

By using a model, researchers at the University of Montreal have identified and “switched off” a chemical chain that causes neurodegenerative diseases such as Huntington’s disease, amyotrophic lateral sclerosis and dementia. The findings could one day be of particular therapeutic benefit to Huntington’s disease patients. “We’ve identified a new way to protect neurons that express mutant huntingtin proteins,” explained Dr. Alex Parker of the University of Montreal’s Department of Pathology and Cell Biology and its affiliated CRCHUM Research Centre. A cardinal feature of Huntington’s disease – a fatal genetic disease that typically affects patients in midlife and causes progressive death of specific areas of the brain – is the aggregation of mutant huntingtin protein in cells. “Our model revealed that increasing another cell chemical called progranulin reduced the death of neurons by combating the accumulation of the mutant proteins. Furthermore, this approach may protect against neurodegenerative diseases other than Huntington’s disease.”

There is no cure for Huntingdon’s disease and current strategies show only modest benefits, and a component of the protein aggregates involved are also present in other degenerative diseases. “My team and I wondered if the proteins in question, TDP-43 and FUS, were just innocent bystanders or if they affected the toxicity caused by mutant huntingtin,” Dr. Parker said. To answer this question, Dr. Parker and University of Montreal doctoral student Arnaud Tauffenberger turned to a simple genetic model based on the expression of mutant huntingtin in the nervous system of the transparent roundworm C. elegans. A large number of human disease genes are conserved in worms, and C. elegans in particular enables researchers to rapidly conduct genetic analyses that would not be possible in mammals.

Dr. Parker’s team found that deleting the TDP-43 and FUS genes, which produce the proteins of the same name, reduced neurodegeneration caused by mutant huntingtin. They then confirmed their findings in the cell of a mammal cell, again by using models. The next step was then to determining how neuroprotection works. TDP-43 targets a chemical called progranulin, a protein linked to dementia. “We demonstrated that removing progranulin from either worms or cells enhanced huntingtin toxicity, but increasing progranulin reduced cell death in mammalian neurons. This points towards progranulin as a potent neuroprotective agent against mutant huntingtin neurodegeneration,” Dr. Parker said. The researchers will need to do further testing this in more complex biological models to determine if the same chemical switches work in all mammals. If they do, then progranulin treatment may slow disease onset or progression in Huntington’s disease patients.

(Source: eurekalert.org)

A novel test that measures proteins from nerve damage that are deposited in blood and spinal fluid reveals the rate of progression of amyotrophic lateral sclerosis (ALS) in patients, according to researchers from Mayo Clinic’s campus in Florida, Emory University and the University of Florida.

Their study, which appears online in the Journal of Neurology, Neurosurgery & Psychiatry, suggests this test, if perfected, could help physicians and researchers identify those patients at most risk for rapid progression. These patients could then be offered new therapies now being developed or tested.

ALS — also known as Lou Gehrig’s disease — is a progressive neurodegenerative disease caused by deterioration of motor neurons (nerve cells) that control voluntary muscle movement. The rate of progression varies widely among patients, and survival from the date of diagnosis can be months to 10 years or more, says Kevin Boylan, M.D., medical director of the ALS Clinic at Mayo Clinic in Florida.

"In the care of our ALS patients there is a need for more reliable ways to determine how fast the disease is progressing," says Dr. Boylan, who is the study’s lead investigator. "Many ALS researchers have been trying to develop a molecular biomarker test for nerve damage like this, and we are encouraged that this test shows such promise. Because blood samples are more readily collected than spinal fluid, we are especially interested in further evaluating this test in peripheral blood in comparison to spinal fluid."

There are no curative or even significantly beneficial therapies in clinics now for ALS treatment, but many are in development, Dr. Boylan says. A test like this could help identify those patients who are at risk for faster progression of weakness. With experimental treatments that primarily slow progression of ALS, detecting a treatment response in patients with faster progression may be easier to detect, says Dr. Boylan. Now, patients with varying rates of progression participate together in clinical studies, which can make analysis of a drug’s benefit difficult, he says.

"If there were a way to identify people who are likely to have relatively faster progression, it should be possible to conduct therapeutic trials with smaller numbers of patients in less time than is required presently," Dr. Boylan says.

A longer-range goal is to develop tests of this kind to gauge how well a patient is responding to experimental therapies, he adds.

The test measures neurofilament heavy form in blood and spinal fluid. These are proteins that provide structure to motor neurons, and when these nerves are damaged by the disease, the proteins break down and float free in blood serum and in the spinal fluid. Earlier research in this area was conducted by Gerry Shaw, Ph.D., a neuroscientist at the University of Florida, who is the study’s senior investigator and the developer of the neurofilament assay used in the study.

The researchers measured neurofilament heavy form in blood and spinal fluid samples from patients at Mayo Clinic and at Emory University, and correlated levels of the protein with rate of progression. “We demonstrated a solid association between higher levels of this protein and a faster progression of muscle weakness,” Dr. Boylan says. There was also evidence suggesting that ALS patients with higher protein levels may have shorter survival, he adds.

(Source: mayoclinic.org)

Amyotrophic lateral sclerosis, also called Lou Gehrig’s disease, is a devastatingly cruel neurodegenerative disorder that robs sufferers of the ability to move, speak and, finally, breathe. Now researchers at the Stanford University School of Medicine and San Francisco’s Gladstone Institutes have used baker’s yeast — a tiny, one-celled organism — to identify a chink in the armor of the currently incurable disease that may eventually lead to new therapies for human patients.

“Even though yeast and humans are separated by a billion years of evolution, we were able to use the power of yeast genetics to identify an unexpected potential drug target for ALS,” said Aaron Gitler, PhD, an associate professor of genetics at Stanford. “Many neurodegenerative disorders such as ALS, Parkinson’s and Alzheimer’s exhibit protein clumping or misfolding within the neurons that is thought to either cause or contribute to the conditions. We are trying to figure out why these proteins aggregate in neurons in the brain and spinal cord, and what happens when they do.”

In 2008, Gitler received a New Innovator award from the National Institutes of Health to use yeast as a model for understanding human neurodegenerative diseases and as a way to identify new targets for drug development.

(Source: med.stanford.edu)

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Scientists at the University of Bath are one step further to understanding the role of one of the proteins that causes the neurodegenerative disorder, Amyotrophic Lateral Sclerosis (ALS), also known as Motor Neurone Disease (MND).

The scientists studied a protein called angiogenin, which is present in the spinal cord and brain that protects neurones from cell death. Mutations in this protein have been found in sufferers of MND and are thought to play a key role in the progression of the condition.

MND triggers progressive weakness, muscle atrophy and muscle twitches and spasms. The disease affects around 5000 people in the UK.

The team of cell biologists and structural biologists have, for the first time, produced images of the 3D structures of 11 mutant versions of angiogenin to see how the mutations changed the structure of the active part of the molecule, damaging its function.

The study, published in the prestigious journal Nature Communications, provides insights into the causes of this disease and related conditions such as Parkinson’s Disease.

The team also looked at the effects of the malfunctioning proteins on neurones grown from embryonic stem cells in the laboratory.

They found that some of the mutations stopped the protein being transported to the cell nucleus, a process that is critical for the protein to function correctly.

The mutations also prevented the cells from producing stress granules, the neurone’s natural defence from stress caused by low oxygen levels.

Dr Vasanta Subramanian, Reader in Biology & Biochemistry at the University, said:

“This study is exciting because it’s the first time we’ve directly linked the structure of these faulty proteins with their effects in the cell.

“We’ve worked alongside Professor Ravi Acharya’s group to combine structural knowledge with cell biology to gain new insights into the causes of this devastating disease.

“We hope that the scientific community can use this new knowledge to help design new drugs that will bind selectively to the defective protein to protect the body from its damaging effects.”

The findings were welcomed by medical research charity, the Motor Neurone Disease (MND) Association, the only national charity in England, Wales and Northern Ireland dedicated to supporting people living with MND while funding and promoting cutting-edge global research to bring about a world free of the disease.

Dr Brian Dickie, Director of Research Development at the charity, said: “The researchers at the University of Bath have skilfully combined aspects of biology, chemistry and physics to answer some fundamental questions on how angiogenin can damage motor neurones. It not only advances our understanding of the disease, but may also give rise to new ideas on treatment development.”

(Source: bath.ac.uk)

ScienceDaily (July 18, 2012) — Researchers at Oregon Health & Science University School of Dentistry have discovered that TDP-43, a protein strongly linked to ALS (amyotrophic lateral sclerosis) and other neurodegenerative diseases, appears to activate a variety of different molecular pathways when genetically manipulated. The findings have implications for understanding and possibly treating ALS and neurodegenerative diseases such as Alzheimer’s and Parkinson’s.

ALS affects two in 100,000 adults in the United States annually and the prognosis for patients is grim.The new discovery is published online in G3: Genes, Genomes, Genetics (and the July 2012 print issue of G3).

Using a fruit fly model, the OHSU team genetically increased or eliminated TDP-43 to study its effect on the central nervous system. By using massively parallel sequencing methods to profile the expression of genes in the central nervous system, the team found that the loss of TDP-43 results in widespread gene activation and altered splicing, much of which is reversed by rescue of TDP-43 expression. Although previous studies have implicated both absence and over expression of TDP-43 in ALS, the OHSU study showed little overlap in the gene expression between these two manipulations, suggesting that the bulk of the genes affected are different.

"Our data suggest that TDP-43 plays a role in synaptic transmission, synaptic release and endocytosis," said Dennis Hazelett, Ph.D., lead author of the study. "We also uncovered a potential novel regulation of several pathways, many targets of which appear to be conserved."

Source: Science Daily