Study Reveals How a Key Protein Protects Blood Stem Cells
Complete the form below to unlock access to ALL audio articles.
Scientists have made a breakthrough discovery of a key protein that supports the production of healthy blood cells throughout life by regulating the body’s inflammatory response.
The study is the first to reveal a protein that has a crucial role in protecting the blood’s stem cells, which continually produce all blood and immune cells needed in the body, from premature aging.
The discovery shows that the protein, known as YTHDF2, protects these stem cells from damage when the body is fighting an infection and allows them to continue functioning correctly throughout life.
Preventing Burnout
Scientists have long puzzled over how these cells, known as hematopoietic stem cells, protect themselves from burnout whilst ramping up the production of immune cells to combat an infection.
Previous studies found that the YTHDF2 protein has an important role in the development of healthy blood cells, a process known as haematopoiesis.
A team of researchers, jointly led by the University of Edinburgh and Queen Mary University of London, studied mice that lacked YTHDF2 protein to better understand its role in blood stem cells.
They treated YTHDF2 deficient young mice with a chemical that mimics a viral infection to investigate whether the protein had a role during the immune response or inflammation.
Regulating Inflammation
The team found that the YTHDF2 deficient mice’s hematopoietic stem cells displayed signs of chronic inflammation that limited their long–term ability to produce new blood cells.
During infections these stem cells produce vast numbers of specialised immune cells.
But the resulting inflammatory process is an emergency response and needs careful regulation to avoid the stem cells from becoming exhausted and unable to function correctly in the future.
The study is the first to reveal that the YTHDF2 protein protects the long-term integrity of hematopoietic stem cells by regulating the activity of genes that drive inflammatory processes.
Premature Aging
In the absence of YTHDF2, the damage to the young mice’s stem cells altered the production of blood cell types, causing them to resemble the blood of much older mice.
During the aging process hematopoietic stem cells naturally lose their potency and ability to manufacture new blood cells, leaving older adults more vulnerable to infection.
Further studies are needed to reveal whether manipulating YTHDF2 levels during ageing could help preserve stem cells and improve their ability to fight infections.
"We know that inflammatory pathways induced by infection force blood stem cells to rapidly produce immune cells to help combat infections. However, these pathways can eventually exhaust stem cells or cause their premature ageing, and it is important to understand how this can be stopped. We hope that our new discovery that YTHDF2 prevents this inflammation-induced exhaustion can be harnessed to therapeutically protect blood stem cell integrity during infection." - Professor Kamil Kranc, Barts Cancer Institute, Queen Mary University of London
"Our investigations not only uncover the key significance of YTHDF2 in protecting blood stem cells but also highlight the importance of mRNA modifications in this process. One key function of YTHDF2 is to bind to the m6A chemical modification on mRNA and promote degradation. Our work demonstrating that YTHDF2 downregulates the activity of pro-inflammatory genes, may establish a paradigm whereby m6A mRNA modification regulates inflammatory pathways in blood and also other tissue stem cells." - Professor Dónal O'Carroll, University of Edinburgh's School of Biological Sciences
Reference: Mapperley C, van de Lagemaat LN, Lawson H, et al. The mRNA m6A reader YTHDF2 suppresses proinflammatory pathways and sustains hematopoietic stem cell function. J Exp Med. 2021;218(3). doi:10.1084/jem.20200829
This article has been republished from the following materials. Note: material may have been edited for length and content. For further information, please contact the cited source.