New! Sign up for our free email newsletter.
Science News
from research organizations

Masterswitch discovered in body's immune system

Date:
February 11, 2019
Source:
University of Manchester
Summary:
Scientists have discovered a critical part of the body's immune system with potentially major implications for the treatment of some of the most devastating diseases affecting humans. The study could translate into treatments for autoimmune diseases including Cancer, Diabetes, Multiple Sclerosis and Crohn's Disease within a few years.
Share:
FULL STORY

Scientists have discovered a critical part of the body's immune system with potentially major implications for the treatment of some of the most devastating diseases affecting humans.

Professor Graham Lord, from The University of Manchester, led the study, which could translate into treatments for autoimmune diseases including Cancer, Diabetes, Multiple Sclerosis and Crohn's Disease within a few years.

It is published in the Journal of Clinical Investigation today.

The discovery of the molecular pathway regulated by a tiny molecule -- known as microRNA-142 -- is a major advance in our understanding of the immune system.

The 10-year-study found that microRNA-142 controls Regulatory T cells, which modulate the immune system and prevent autoimmune disease. It is, they found, the most highly expressed regulator in the immune system.

Professor Lord, led the research while at Kings College London in collaboration with Professor Richard Jenner at UCL.

And according to Professor Lord, the discovery could be translated into a viable drug treatment within a few years.

He said: "Autoimmune diseases often target people in the prime of their life creating a significant socio-economic burden on them. Sometimes, the effect can be devastating, causing terrible hardship and suffering.

"But these findings represent a significant step forward in the understanding of the immune system and we believe many people worldwide may benefit."

If the activity of Regulatory T cells is too low, this can cause other immune cells to attack our own body tissues. If these Regulatory T cells are too active, this leads to suppression of immune responses and can allow cancers to evade the immune system.

So being able to control them is a major step forward in our ability to control- and harness -- the therapeutic power of the immune system.

Professor Richard Jenner from UCL, who led the computational side of the project, said that: "We were able to trace the molecular fingerprints of this molecule across other genes to determine how it acted as such a critical regulator."

Professor Lord, now Vice President and Dean of the Faculty of Biology, Medicine and Health at The University of Manchester, added: "Scientists over the past decade or so have developed therapies which are able to modulate different pathways of the immune system. We hope that this new discovery will lead to the development of new ways to treat autoimmunity, infectious diseases and cancer and we are incredibly excited about where this may lead."


Story Source:

Materials provided by University of Manchester. Note: Content may be edited for style and length.


Journal Reference:

  1. Nelomi Anandagoda, Joanna C.D. Willis, Arnulf Hertweck, Luke B. Roberts, Ian Jackson, M. Refik Gökmen, Richard G. Jenner, Jane K. Howard, Graham M. Lord. microRNA-142–mediated repression of phosphodiesterase 3B critically regulates peripheral immune tolerance. Journal of Clinical Investigation, 2019; DOI: 10.1172/JCI124725

Cite This Page:

University of Manchester. "Masterswitch discovered in body's immune system." ScienceDaily. ScienceDaily, 11 February 2019. <www.sciencedaily.com/releases/2019/02/190211164002.htm>.
University of Manchester. (2019, February 11). Masterswitch discovered in body's immune system. ScienceDaily. Retrieved November 25, 2024 from www.sciencedaily.com/releases/2019/02/190211164002.htm
University of Manchester. "Masterswitch discovered in body's immune system." ScienceDaily. www.sciencedaily.com/releases/2019/02/190211164002.htm (accessed November 25, 2024).

Explore More

from ScienceDaily

RELATED STORIES