New Insights into Membrane Dynamics in Human Cells Revealed
Credit: University of Exeter
Organelles are the functional units of a cell. Like different parts of a production line in a factory, they perform specialised functions but depend on and interact with each other.
To adapt their functions to cellular needs, organelles need to be dynamic: they have to move in order to interact and cooperate with other organelles, to stay in position or to multiply by increasing in size and then dividing.
How these dynamic processes are mediated and regulated in the cell is an important and challenging question in cell biology.
Scientists have now discovered how the movement and membrane dynamics of a specific organelle – called peroxisomes – are mediated.
Peroxisomes fulfil important protective functions in the cell and are vital for health; loss of peroxisome function and dynamics leads to severe developmental and neurological defects.
Much about the way peroxisomes work is still unknown, but University of Exeter researchers have identified a protein called MIRO1 that plays a key role in attaching peroxisomes to motor proteins – allowing them to move within the cell.
“In this study, we identified MIRO1 as the missing adaptor protein which links peroxisomes to molecular motors and revealed a new role for MIRO1 in peroxisome motility in mammalian cells,” said Professor Michael Schrader, of the University of Exeter.
“In addition, we used MIRO1 as a tool to generate pulling forces at peroxisomes in living cells.
“We were able to redistribute peroxisomes within cells, but interestingly could even multiply them (by pulling them apart) or pull out enormously long protrusions of the peroxisomal membrane in patient cells.
“These experiments have provided us with new insights into the molecular mechanisms determining peroxisome number and shape in the cell under normal and disease conditions.
“In peroxisomal disorders, we often see altered numbers, different shapes or even different distributions of peroxisomes in patient cells.
“Understanding why this happens and how to modulate peroxisome numbers or distribution can provide new possibilities to improve cell performance in those patients.
“This might also be relevant to age-related conditions like dementia, deafness and blindness, as peroxisomes are known to have important protective functions within sensory cells.”
The research team combined molecular cell biology, microscopy, live-cell imaging analysis – by Dr Jeremy Metz from the Biomedical Informatics Hub – and mathematical modelling – by Dr David Richards of Exeter’s Centre for Biomedical Modelling and Analysis – to present the first mathematical model to understand, explain and predict peroxisome membrane dynamics in health and disease.
People with severe peroxisomal disorders, also known as Zellweger Spectrum Disorders, often die as children or young adults, and a charity called Zellweger UK exists to raise awareness and to support families and sufferers.
This article has been republished from materials provided by the University of Exeter. Note: material may have been edited for length and content. For further information, please contact the cited source.
Castro, I. G., Richards, D. M., Metz, J., Costello, J. L., Passmore, J. B., Schrader, T. A., . . . Schrader, M. (2018). A role for MIRO1 in motility and membrane dynamics of peroxisomes. Traffic. doi:10.1111/tra.12549
Sweet Spot of Activity in Immune System Key to Fighting CancerNews
Scientists have shown how stimulating a specific location on the surface of immune cells can be targeted with antibodies to help in their fight against cancer.READ MORE
Complete Skin Regeneration System of Fish UnraveledNews
Researchers at Tokyo Tech have succeeded in observing the behavior of epidermal cells for the regeneration of smooth skin without remaining scar tissue using their model animal, the zebrafish.READ MORE
Mechanism of Scar-free Wound Healing in Fruit Fly Embryos UncoveredNews
A new study conducted by a team of researchers at the University of Toronto may help scientists and medical professionals move toward scar-free wound repair.READ MORE