Posts tagged motor neuron disease

Researchers at King’s College London have discovered how a molecular ‘scaffold’ which allows key parts of cells to interact, comes apart in dementia and motor neuron disease, revealing a potential new target for drug discovery.

The study, published today in Nature Communications, was funded by the UK Medical Research Council, Wellcome Trust, Alzheimer’s Research UK and the Motor Neurone Disease Association.

Researchers looked at two components of cells: mitochondria, the cell ‘power houses’ which produce energy for the cell;and the endoplasmic reticulum (ER) which makes proteins and stores calcium for signalling processes in the cell. ER and mitochondria form close associations and these interactions enable a number of important cell functions. However the mechanism by which ER and mitochondria become linked has not, until now, been fully understood.

Professor Chris Miller, from the Department of Neuroscience at the Institute of Psychiatry at King’s and lead author of the paper, says: “At the molecular level, many processes go wrong in dementia and motor neuron disease,and one of the puzzles we’re faced with is whether there is a common pathway connecting these different processes. Our study suggests that the loosening of this ‘scaffold’ between the mitochondria and ER in the cell may be a key process in neurodegenerative diseases such as dementia or motor neuron disease.”

By studying cells in a dish, the researchers discovered that an ER protein called VAPB binds to a mitochondrial protein called PTPIP51, to form a ‘scaffold’ enabling ER and mitochondria to form close associations. In fact, by increasing the levels of VAPB and PTPIP51, mitochondria and ER re-organised themselves to form tighter bonds.

Many of the cell’s functions that are controlled by ER-mitochondria associations are disrupted in neurodegenerative diseases, so the researchers studied how the strength of this ‘scaffold’ was affected in these diseases. TDP-43 is a protein which is strongly linked to Amyotrophic Lateral Sclerosis (ALS, a form of motor neuron disease) and Fronto-Temporal Dementia (FTD, the second most common form of dementia), but exactly how the protein causes neurodegeneration is not properly understood.

The researchers studied how TDP-43 affected mouse cells in a dish. They found that higher levels of TDP-43 resulted in a loosening of the scaffold which reduced ER-mitochondria bonds,affecting some important cellular functions that are linked to ALS and FTD.

Professor Miller concludes: “Our findings are important in terms of advancing our understanding of basic biology, but may also provide a potential new target for developing new treatments for these devastating disorders.”

(Source: kcl.ac.uk)

New research from the University of Sheffield could offer solutions into slowing down the progression of motor neurone disease (MND).

Scientists from the University of Sheffield’s Institute for Translational Neuroscience (SITraN) conducted pioneering research assessing how the devastating debilitating disease affects individual patients.

MND is an incurable disease destroying the body’s cells which control movement causing progressive disability. Present treatment options for those with MND only have a modest effect in improving the patient’s quality of life.

Professor Pamela Shaw, Director of SITraN, and her research team worked in collaboration with a fellow world leading MND scientist Dr Caterina Bendotti and her group at the Mario Negri Institute for Pharmacological Research in Milan, Italy. Together they investigated why the progression of MND following onset of symptoms varies in speed, even in the presence of a known genetic cause of the condition.

The research, published in the scientific journal Brain, investigated two mouse models of MND caused by an alteration in the SOD1 gene, a known cause of MND in humans. One of the strains had a rapidly progressing disease course and the other a much slower change in the symptoms of MND. The teams from Sheffield and Milan looked at the factors which might explain the differences observed in speed and severity in the progression of the disease. They used a scientific technique known as gene expression profiling to identify factors within motor neurones that control vulnerability or resistance to MND in order to shed light on the factors important for the speed of motor neurone injury in human patients.

The study, funded by the Motor Neurone Disease Association, revealed new evidence, at the point of onset of the disease, before muscle weakness was observed, showing key differences in major molecular pathways and the way the protective systems of the body responded, between the profiles of the rapid progressing and slow progressing mouse models. In the case of the model with rapidly progressing MND the motor neurones showed reduced functioning of the cellular systems for energy production, disposal of waste proteins and neuroprotection. Motor neurones from the model with more slowly progressing MND showed an increase in protective inflammation and immune responses and increased function of the mechanisms that protect motor neurones from damage.

The research provides valuable clues about mechanisms that have the effect of slowing down the progression of disabling symptoms in MND.

Professor Shaw said that the state-of-the-art Functional Genomics laboratory in SITraN had enabled the research team to use a cutting edge technique called gene expression profiling.
“This enables us to ‘get inside’ the motor neurones in health and disease and understand better what is happening to cause motor neurone injury in MND,” she said.

“This project was a wonderful collaboration, supported by the MND Association, between research teams in Sheffield and Milan. We are very excited about the results which have given us some new ideas for treatment strategies which may help to slow disease progression in human MND.”

Dr Caterina Bendotti said: “MND is a clinically heterogenous disease with a high variability in its course which makes assessments of potential therapies difficult. Thanks to the recent evidence in our laboratory of a difference in the speed of symptom progression in two MND models carrying the same gene mutation and the successful collaboration with Professor Pamela Shaw and her team, we have identified some mechanisms that may help to predict the disease duration and eventually to slow it down.

“I strongly believe that the new hypotheses generated by this study and our ongoing collaboration are the prerequisites to be able to fight this disease.”

Brian Dickie from MND Association added: “These new and important findings in mice open up the possibility for new treatment approaches in man. It is heartening to see such a productive collaboration between two of the leading MND research labs in Europe, combining their unique specialist knowledge and technical expertise in the fight against this devastating disease.”

MND affects more than 6,000 sufferers in the UK with the majority of cases being sporadic but approximately five per cent of cases are familial or inherited with an identifiable genetic cause. Sufferers may lose their ability to walk, talk, eat and breathe.

(Source: sheffield.ac.uk)

Proteins play important roles in the human body, particularly neuroproteins that maintain proper brain function.

Brain diseases such as ALS, Alzheimer’s, and Parkinson’s are known as “tangle diseases” because they are characterized by misfolded and tangled proteins which accumulate in the brain.

A team of Australian and American scientists discovered that an unusual amino acid called BMAA can be inserted into neuroproteins, causing them to misfold and aggregate. BMAA is produced by cyanobacteria, photosynthetic bacteria that form scums or mats in polluted lakes or estuaries.

BMAA has been detected in the brain tissues of ALS patients.

In an article published in PLOS ONE scientists at the University of Technology Sydney and the Institute for Ethnomedicine in Jackson Hole, Wyoming, report that BMAA mimics a dietary aminoacid, L-Serine, and is mistakenly incorporated into neuroproteins, causing the proteins to misfold. The misfolded proteins build up in cells, eventually killing them.

"We found that BMAA inserts itself by seizing the transfer RNA for L-Serine. This, in essence, puts a kink in the protein causing it to misfold," says lead author Dr. Rachael Dunlop, a cell biologist in Sydney working in the laboratory of Dr. Ken Rodgers.

"The cells then begin programmed cell death, called apoptosis. "Even more importantly, the scientists found that extra L-Serine added to the cell culture can prevent the insertion of BMAA into neuroproteins. The possibility that L-Serine could be used to prevent or slow ALS is now being studied."

Even though L-serine occurs in our diet, its safety and efficacy for ALS patients should be properly determined through FDA-approved clinical trials before anyone advocates its use,” says American co-author Dr. Paul Cox.

In ALS, motor neurons in the brain and spinal cord die, progressively paralyzing the body until even swallowing and breathing becomes impossible.

The disease is relatively rare but has affected a number of high-profile people including Professor Stephen Hawking and Yankee baseball player Lou Gehrig.

"For many years scientists have linked BMAA to an increased risk of motor neuron disease but the missing pieces of the puzzle relate to how this might occur. Finally, we have one of those pieces," said Dr Sandra Banack, a co-author on the paper.

(Source: eurekalert.org)

Amyotrophic Lateral Sclerosis (ALS) is a devastating motor neuron disease that rapidly atrophies the muscles, leading to complete paralysis. Despite its high profile — established when it afflicted the New York Yankees’ Lou Gehrig — ALS remains a disease that scientists are unable to predict, prevent, or cure.

Although several genetic ALS mutations have been identified, they only apply to a small number of cases. The ongoing challenge is to identify the mechanisms behind the non-genetic form of the disease and draw useful comparisons with the genetic forms.

Now, using samples of stem cells derived from the bone marrow of non-genetic ALS patients, Prof. Miguel Weil of Tel Aviv University’s Laboratory for Neurodegenerative Diseases and Personalized Medicine in the Department of Cell Research and Immunology and his team of researchers have uncovered four different biomarkers that characterize the non-genetic form of the disease. Each sample shows similar biological abnormalities to four specific genes, and further research could reveal additional commonalities. “Because these genes and their functions are already known, they give us a specific direction for research into non-genetic ALS diagnostics and therapeutics,” Prof. Weil says. His initial findings were reported in the journal Disease Markers.

Giving in to stress

To hunt for these biomarkers, Prof. Weil and his colleagues turned to samples of bone marrow collected from ALS patients. Though more difficult to collect than blood, bone marrow’s stem cells are easy to isolate and grow in a consistent manner. In the lab, he used these cells as cellular models for the disease. He ultimately discovered that cells from different ALS patients shared the same abnormal characteristics of four different genes that may act as biomarkers of the disease. And because the characteristics appear in tissues that are related to ALS — including in muscle, brain, and spinal cord tissues in mouse models of genetic ALS — they may well be connected to the degenerative process of the disease in humans, he believes.

Searching for the biological significance of these abnormalities, Prof. Weil put the cells under stress, applying toxins to induce the cells’ defense mechanisms. Healthy cells will try to fight off threats and often prove quite resilient, but ALS cells were found to be overwhelmingly sensitive to stress, with the vast majority choosing to die rather than fight. Because this is such an ingrained response, it can be used as a feature for drug screening for the disease, he adds.

The hunt for therapeutics

Whether these biomarkers are a cause or consequence of ALS is still unknown. However, this finding remains an important step towards uncovering the mechanisms of the disease. Because these genes have already been identified, it gives scientists a clear direction for future research. In addition, these biomarkers could lead to earlier and more accurate diagnostics.

Next, Prof. Weil plans to use his lab’s high-throughput screening facility — which can test thousands of compounds’ effects on diseased cells every day — to search for drug candidates with the potential to affect the abnormal expression of these genes or the stress response of ALS cells. A compound that has an impact on these indicators of ALS could be meaningful for treating the disease, he says.

Prof. Weil is the director of the new Cell Screening Facility for Personalized Medicine at TAU. The facility is dedicated to finding potential drugs for rare and Jewish hereditary diseases.

(Source: aftau.org)