Posts tagged neurodegenerative diseases

ScienceDaily (July 20, 2012) — Scientists at the University of Manchester have uncovered how the internal mechanisms in nerve cells wire the brain. The findings open up new avenues in the investigation of neurodegenerative diseases by analysing the cellular processes underlying these conditions.

Illustration of spectraplakins in axonal growth organising microtubules. (Credit: Image courtesy of University of Manchester)

Dr Andreas Prokop and his team at the Faculty of Life Sciences have been studying the growth of axons, the thin cable-like extensions of nerve cells that wire the brain. If axons don’t develop properly this can lead to birth disorders, mental and physical impairments and the gradual decay of brain capacity during aging.

Axon growth is directed by the hand shaped growth cone which sits in the tip of the axon. It is well documented how growth cones perceive signals from the outside to follow pathways to specific targets, but very little is known about the internal machinery that dictates their behaviour.

Dr Prokop has been studying the key driver of growth cone movements, the cytoskeleton. The cytoskeleton helps to maintain a cell’s shape and is made up of the protein filaments, actin and microtubules. Microtubules are the key driving force of axon growth whilst actin helps to regulate the direction the axon grows.

Dr Prokop and his team used fruit flies to analyse how actin and microtubule proteins combine in the cytoskeleton to coordinate axon growth. They focussed on the multifunctional proteins called spectraplakins which are essential for axonal growth and have known roles in neurodegeneration and wound healing of the skin.

What the team demonstrate in this recent paper is that spectraplakins link microtubules to actin to help them extend in the direction the axon is growing. If this link is missing then microtubule networks show disorganised criss-crossed arrangements instead of parallel bundles and axon growth is hampered.

By understanding the molecular detail of these interactions the team made a second important finding. Spectraplakins collect not only at the tip of microtubules but also along the shaft, which helps to stabilise them and ensure they act as a stable structure within the axon.

This additional function of spectraplakins relates them to a class of microtubule-binding proteins including Tau. Tau is an important player in neurodegenerative diseases, such as Alzheimer’s, which is still little understood. In support of the author’s findings, another publication has just shown that the human spectraplakin, Dystonin, causes neurodegeneration when affected in its linkage to microtubules.

Talking about his research Dr Prokop said: “Understanding cytoskeletal machinery at the cell level is a holy grail of current cell research that will have powerful clinical applications. Thus, cytoskeleton is crucially involved in virtually all aspects of a cell’s life, including cell shape changes, cell division, cell movement, contacts and signalling between cells, and dynamic transport events within cells. Accordingly, the cytoskeleton lies at the root of many brain disorders. Therefore, deciphering the principles of cytoskeletal machinery during the fundamental process of axon growth will essentially help research into the causes of a broad spectrum of diseases. Spectraplakins like at the heart of this machinery and our research opens up new avenues for its investigation”

What Dr Prokop’s paper in the Journal of Neuroscience also demonstrates is the successful research technique using the fruit fly Drosophila. The team was able to replicate its findings regarding axon growth in mice which in turn means the findings can be translated to humans.

Dr Prokop points out fruit flies provide ideal means to make sense of these findings and essentially help to unravel the many mysteries of neurodegeneration.

Dr Prokop continues: “Understanding how spectraplakins perform their cellular functions has important implications for basic as well as biomedical research. Thus, besides their roles during axon growth, spectraplakins of mice and humans are clinically important for a number of conditions and processes including skin blistering, neuro-degeneration, wound healing, synapse formation and neuron migration during brain development. Understanding spectraplakins in one biological process will instruct research on the other clinically relevant roles of these proteins.”

Source: Science Daily

ScienceDaily (July 19, 2012) — While clinical trial results are being released regarding drugs intended to decrease amyloid production — thought to contribute to decline in Alzheimer’s disease — clinical trials of drugs targeting other disease proteins, such as tau, are in their initial phases.

Penn Medicine research presented July 19 at the 2012 Alzheimer’s Association International Conference (AAIC) shows that an anti-tau treatment called epithilone D (EpoD) was effective in preventing and intervening the progress of Alzheimer’s disease in animal models, improving neuron function and cognition, as well as decreasing tau pathology.

By targeting tau, the drug aims to stabilize microtubules, which help support and transport of essential nutrients and information between cells. When tau malfunctions, microtubules break and tau accumulates into tangles.

"This drug effectively hits a tau target by correcting tau loss of function, thereby stabilizing microtubules and offsetting the loss of tau due to its formation into neurofibrillary tangles in animal models, which suggests that this could be an important option to mediate tau function in Alzheimer’s and other tau-based neurodegenerative diseases," said John Trojanowski, MD, PhD, professor of Pathology and Laboratory Medicine in the Perelman School of Medicine at the University of Pennsylvania. "In addition to drugs targeting amyloid, which may not work in advanced Alzheimer’s disease, our hope is that this and other anti-tau drugs can be tested in people with Alzheimer’s disease to determine whether stabilizing microtubules damaged by malfunctioning tau protein may improve clinical and pathological outcomes."

The drug, identified through Penn’s Center for Neurodegenerative Disease Research (CNDR) Drug Discovery Program, was previously shown to prevent further neurological damage and improve cognitive performance in animal models*. The Penn research team includes senior investigator Bin Zhang, MD, and Kurt Brunden, PhD, director of Drug Discovery at CNDR.

Bristol-Myers Squibb, who developed and owns the rights to the drug, has started enrolling patients into a phase I clinical trial in people with mild Alzheimer’s disease.

Source: Science Daily

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