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 Motor Neuron Disease 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 Motor Neuron Disease. 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 Motor Neuron Disease Treatment strategies which may help to slow disease progression in human MN.”
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.