A new understanding of everyday cellular processes
- Cellular processes happen every day in humans and plants, such as homeostasis and photosynthesis
- The cells involved in the process are so complex it’s challenged human understanding, especially how they act in different environments
- A bioelectrical conceptualisation of cells could be the key to researching how cells operate, researchers at the School of Life Sciences, University of Warwick argue
- If the genetics, physics and physiology can be grounded on bioelectrical conceptualisation of cells it could have implications for research in conditions related to cellular processes
We use cells to breathe, to moderate body temperature, to grow and many other every day processes, however the cells in these processes are so complex its left scientists perplexed into how they develop in different environments. Researchers from the University of Warwick say future research needs to look into the bioelectrical composition of cells for answers.
Cellular processes happen every day for survival, form homeostasis to photosynthesis and anaerobic respiration to aerobic respiration. However the complexity of cells has fascinated and challenged human understanding for centuries.
It’s cellular “machinery” responsible for key functions have been the focus of biology research, and despite previous research exploring the molecular and genetic basis of these processes showing unprecedented insights, we still can’t fully understand and predict cell behaviour when challenged to different conditions.
In particular, the basis of heterogeneity in single-cell behaviour and the initiation of many different metabolic, transcriptional or mechanical responses to environmental stimuli remain largely unexplained.
Researchers from the School of Life Sciences at the University of Warwick have today, the 20th May had the paper ‘Bioelectrical understanding and engineering of cell biology’ published in the journal Royal Society Interface, in which they have gone beyond the status quo of understanding cell behaviours, and argue a combination of genetics, physics and physiology can be grounded on a bioelectrical conceptualisation of cells.
They argue that a bioelectrical view can provide predictive biological understanding, which can open up novel ways to control cell behaviours by electrical and electrochemical means, setting the stage for the emergence of bioelectrical engineering.
Dr Orkun Soyer, from the School of Life Sciences at the University of Warwick comments:
“When looking at the underlying chemistry of this “machinery” it is easy to recognise the importance of electricity in biological phenomena.
“Here we advocate that the understanding of cells as electrical entities will pave the way to fully understand, predict and modulate cellular function. When cellular functions are understood it could have a huge impact on healthcare, as conditions related to, for example, homeostasis such as heart failure or diabetes, could have new treatments researched if we can manipulate the bioelectricity in the cells.”
ENDS
20 MAY 2020
NOTES TO EDITORS
Images available at:
https://warwick.ac.uk/services/communications/medialibrary/images/march2020/soyer-sasi-thumb-1.jpg
Caption: Professor Orkun Soyer, School of Life Sciences, University of Warwick
Paper available to view at: https://royalsocietypublishing.org/doi/full/10.1098/rsif.2020.0013?af=R
FOR FURTHER INFORMATION PLEASE CONTACT
Alice Scott
Media Relations Manager – Science
University of Warwick
Tel: +44 (0) 7920 531 221
E-mail: alice.j.scott@warwick.ac.uk
FOR FURTHER INFORMATION PLEASE CONTACT
Alice Scott
Media Relations Manager – Science
University of Warwick
Tel: +44 (0) 7920 531 221
E-mail: alice.j.scott@warwick.ac.uk