Turning off the protein tap – a new clue to neurodegenerative disease

Turning off the protein tap -- A new clue to neurodegenerative disease
Pictured is the cerebellar region of the brain of a mouse lacking the Golgi protein GM130 with the Purkinje neurons labelled in green and DNA in blue. There is loss of Purkinje neurons in the lobes on the right hand side, which results in inability to coordinate muscle movement (ataxia). Credit: The University of Manchester/Martin Lowe

Disabling a part of brain cells that acts as a tap to regulate the flow of proteins has been shown to cause neurodegeneration, a new study from The University of Manchester has found.

The research, which was carried out in mice, focused on the Golgi apparatus - a compartment inside all cells in the body that controls the processing and transport of proteins. It is fundamental for the growth of the and also for the release of many types of proteins such as hormones, neurotransmitters and the proteins that make up our skeletons.

Working with Chinese colleagues, the Manchester researchers examined the role of the Golgi apparatus in neurons, or , and found that mice in which the apparatus was disabled suffered from , severe ataxia, and postnatal death.

Ataxia is a term for a group of disorders that affect co-ordination, balance and speech. Any part of the body can be affected, but people with ataxia often have difficulties with balance and walking, speaking, swallowing, tasks such as writing and eating, and vision. It can be inherited, brought on through incidents such as a stroke, or through old age.

Although the function of the Golgi apparatus, named after its Italian discoverer, is well understood, it has not been previously been shown to have a role in neurodegeneration. With these results the scientists think they may have found a new avenue to explore in the search for the causes of some neurodegenerative diseases.

Turning off the protein tap -- A new clue to neurodegenerative disease
Pictured is the cerebellar region of a mouse brain labelled for the Golgi apparatus (red), DNA (blue) and Purkinje neutrosn (green). The Purkinje neurons have an elaborate Golgi, as first observed by Camillo Golgi when he discovered the organelle in 1898. Liu et al have shown that Golgi positioning and organisational are disrupted in mice lacking the Golgi protein GM130, which leads to death of Purkinje neurons and ataxia. Credit: The University of Manchester/Martin Lowe

Professor Martin Lowe, the lead researcher, said: "Our results, combined with previous work, suggest that during the cellular changes that occur, loss of the Golgi function could be an important intermediary step that contributes to cell death."

How much the Golgi apparatus contributes to the major neurodegenerative diseases such as Alzheimer's or Parkinson's is something that is currently unclear, though other studies have made this link.

Professor Lowe added: "Together with other published work our findings suggest that in certain the loss of function of the Golgi apparatus may contribute to the pathology that is occurring."

More information: Chunyi Liu et al. Loss of the golgin GM130 causes Golgi disruption, Purkinje neuron loss, and ataxia in mice, Proceedings of the National Academy of Sciences (2017). DOI: 10.1073/pnas.1608576114

Citation: Turning off the protein tap – a new clue to neurodegenerative disease (2017, February 8) retrieved 1 December 2023 from https://medicalxpress.com/news/2017-02-protein-clue-neurodegenerative-disease.html
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