Out-of-whack protein may boost Parkinson's

Scientists studying rats induced to display a form of Parkinson’s disease discovered that a protein commonly found in brain cells can be toxic if — at one pinpoint location in its amino acid structure — it lacks a chemical compound called a phosphate.

When scientists used gene therapy to simulate a phosphate at this critical position, the rats’ brain cells didn’t develop the Parkinson-like pathology that would normally occur.

The finding provides new insight into the fundamentals of Parkinson’s disease and the role of an abundant yet mysterious brain protein known as alpha-synuclein, which is believed to help brain cells communicate but may have a more sinister role in the development of neurological diseases.

“We have another potential target for therapy, but there is a great deal left to discover,” said Nicholas Muzyczka, Ph.D., a professor of molecular genetics and microbiology in the College of Medicine and an eminent scholar with the UF Genetics Institute. “This is one more piece of information about what might be causing the toxicity in Parkinson’s disease, and it gives us a little more to go on about what alpha-synuclein does in the brain.”

Generally located at the synapses of nerve cells, alpha-synuclein is believed to aid in brain function, possibly by helping cells communicate with one another by controlling the release of neurotransmitters such as dopamine.

Mutations of alpha-synuclein may cause a rare, inherited form of Parkinson’s, and the protein has been found to be the major component of Lewy bodies, which are abnormal clusters of protein in the brain cells of patients with Parkinson’s disease.

The National Parkinson Foundation estimates 1.5 million Americans currently have Parkinson’s disease and about 60,000 new cases are diagnosed each year. It is caused by the death or impairment of certain nerve cells in a part of the brain called the substantia nigra. When these cells die, the body is deprived of dopamine, a neurotransmitter vital for movement.

“We know of several enzymes that can cause phosphorylation in the proper position of the alpha-synuclein protein,” said Oleg Gorbatyuk, Ph.D., an assistant professor of molecular genetics and microbiology. “Increasing their expression in brains afflicted with Parkinson’s disease could possibly provide a gene therapy approach to the disease.”

In experiments described in the Jan. 15 issue of PNAS, UF researchers used gene transfer to enhance the production of three versions of alpha-synuclein in the substantia nigra region on one side of the rats’ brains. The other side was not treated, for comparison purposes.

Of the types of alpha-synuclein, the one that simulated phosphorylation at position 129 of the protein was nontoxic. But the other versions of the protein all caused significant loss of dopamine neurons in the substantia nigra.

“Adding a phosphate group is about the smallest thing that can possibly happen in biology,” said Mark R. Cookson, an investigator in the Cell Biology and Gene Expression Unit of the National Institute on Aging who was not involved in the research. “But this relatively minor, innocuous change can switch everything around from being a big problem to being no problem. This research really gives us an idea of some things going on in inherited cases of Parkinson’s disease, and if we use that genetic information as a handle to get into the common disease, it is possible to take this from genetics to a drug discovery program.”

Source: University of Florida

Blood-related genetic mechanisms found important in Parkinson's disease
What does the genetics of blood cells have to do with brain cells related to Parkinson's disease? From an unusual collaboration of neurologists and a pharmacologist comes the surprising answer: Genetic mechanisms at play in blood cells also control a gene and protein that cause Parkinson's disease.
NVIDIA Announced New Geforce GTX 200 GPUs
Imagine instead of taking over five hours to convert a video for your iPod, it only takes 35 minutes. Imagine using your PC to simulate protein folding to help find a cure for debilitating diseases. Imagine that your PC can dramatically accelerate everyday tasks, and deliver an exciting visual experience in the process.
How to construct a 'firefly' worm
Research describing a new modified luminescent worm that allows, for the first time, to measure, in real time, the metabolism of an entire living organism has just been published in the journal BMC Physiology.
Major 'missed' biochemical pathway emerges as important in virtually all cells
A new study by Duke University researchers provides more evidence that the nitric oxide (NO) system in the life of a cell plays a key role in disease, and the findings point to ways to improve treatment of illnesses such as heart disease and cancer.
Protein key to neuro-regeneration
Researchers at the Peninsula Medical School in the South West of England, University College London, the San Raffaele Scientific Institute in Milan and Cancer Research UK, have for the first time identified a protein that is key to the regeneration of damage in the peripheral nervous system and which could with further research lead to understanding diseases of our peripheral nervous systems and provide clues to methods of repairing damage in the central nervous system, according to a paper published this week in the Journal of Cell Biology.
Turning back the clock for Schwann cells
Myelin-making Schwann cells have an ability every aging Hollywood star would envy: they can become young again. According to a study appearing in the May 19 issue of the Journal of Cell Biology, David B. Parkinson (University College London, London, UK) and collogues have pinned down a protein that returns the cells to their youth, a finding that might help researchers understand why myelin production falters in some diseases.
Biosensor for measuring stress in cells
Cancer, nervous system disorders such as Parkinson’s disease, cardiovascular disorders and old age have one thing in common: Both in afflicted tissue and in aging cells, scientists have observed oxidative changes in important biomolecules. These are caused by reactive oxygen molecules, including the notorious “free radicals” that are formed as a by-product of cellular respiration and attack cellular proteins, nucleic and fatty acids.
Seeing Alzheimer's amyloids
In an important step toward demystifying the role protein clumps play in the development of neurodegenerative disease, researchers have created a stunning three-dimensional picture of an Alzheimer’s peptide aggregate using electron microscopy.

Out-of-whack protein may boost Parkinson's

Related stories:

News discussion: