New research at Oregon State University provides evidence for the first time that disruption of circadian rhythms - the biological "clocks" found in many animals - can clearly cause accelerated neurodegeneration, loss of motor function and premature death.

The study was published in Neurobiology of Disease and done by researchers at OSU and Oregon Health and Science University. Prior to this, it wasn't clear which came first - whether the disruption of biological clock mechanisms was the cause or the result of neurodegeneration.

"In these experiments, we showed through both environmental and genetic approaches that disrupting the biological clock accelerated these health problems," said Kuntol Rakshit, an OSU graduate fellow.

Two related studies from Northwestern University offer new strategies for tackling the challenges of preventing and treating diseases of protein folding, such as Alzheimer's, Parkinson's and Huntington's diseases, amyotrophic lateral sclerosis (ALS), cancer, cystic fibrosis and type 2 diabetes.

To do its job properly within the cell, a protein first must fold itself into the proper shape. If it doesn't, trouble can result. More than 300 diseases have at their root proteins that misfold, aggregate and eventually cause cellular dysfunction and death.

Treatment that increases brain levels of an important regulatory enzyme may slow the loss of brain cells that characterizes Huntington's disease (HD) and other neurodegenerative disorders. In a report receiving advance online publication in Nature Medicine, a Massachusetts General Hospital (MGH)-based research team reports that increased expression of Sirt1, one of a family of enzymes called sirtuins, in the brain of a mouse model of HD protected against neurodegeneration. They also identified a potential mechanism for this protective effect.

Working with genetically engineered mice, Johns Hopkins researchers have discovered that a gene (SIRT1) linked to slowing the aging process in cells also appears to dramatically delay the onset of Huntington's disease (HD) and slow the progression of the relentless neurodegenerative disorder.

HD in humans is a rare, fatal disorder caused by a mutation in a single gene and marked by progressive brain damage. Symptoms, which typically first appear in midlife, include jerky twitch-like movements, coordination troubles, psychiatric disorders and dementia. Although the gene responsible for HD was identified in 1993, much is still unknown about the biology of the disease. There is no cure, and there are no effective treatments.

A new drug candidate may be the first capable of halting the devastating mental decline of Alzheimer's disease, based on the findings of a study published in PLoS one.

When given to mice with Alzheimer's, the drug, known as J147, improved memory and prevented brain damage caused by the disease. The new compound, developed by scientists at the Salk Institute for Biological Studies, could be tested for treatment of the disease in humans in the near future.