The blood of young and old people differs. In an article published recently in the scientific journal Blood, a research group at Lund University in Sweden explain how they have succeeded in rejuvenating the blood of mice by reversing, or re-programming, the stem cells that produce blood.
Stem cells form the origin of all the cells in the body and can divide an unlimited number of times. When stem cells divide, one cell remains a stem cell and the other matures into the type of cell needed by the body, for example a blood cell.*
"Our ageing process is a consequence of changes in our stem cells over time", explained Martin Wahlestedt, a doctoral student in stem cell biology at the Faculty of Medicine at Lund University, and principal author of the article.
"Some of the changes are irreversible, for example damage to the stem cells' DNA, and some could be gradual changes, known as epigenetic changes, that are not necessarily irreversible, even if they are maintained through multiple cell divisions. When the stem cells are re-programmed, as we have done, the epigenetic changes are cancelled."**
The discovery that forms the basis for the research group's method was awarded the Nobel Prize in Medicine last year.
The composition of blood is one example of how it ages; blood from a young person contains a certain mix of B- and T-lymphocytes and myeloid cells.***
"In older people, the number of B- and T-lymphocytes falls, while the number of myeloid cells increases", said Martin Wahlestedt.
When an elderly person is affected by leukaemia, the cancer often has its origin in the myeloid cells, of which the elderly have more. Being able to 're-start' the blood, as Martin and his colleagues have done in their studies on mice, therefore presents interesting possibilities for future treatment.
"There is a lot of focus on how stem cells could be used in different treatments, but all that they are routinely used for in clinical work today is bone marrow transplants for diseases where the blood and immune systems have to be regenerated", said Martin Wahlestedt, continuing:
"A critical factor that gives an indication of whether the procedure is going to work or not is the age of the bone marrow donor. By reversing the development of the stem cells in the bone marrow, it may be possible to avoid negative age-related changes."
Even if the composition of the blood in old and young mice is remarkably like that in young and elderly people, Martin Wahlestedt stressed that the science is still only at the stage of basic research, far from a functioning treatment. The research group is pleased with the results, because they indicate that it may not primarily be damage to DNA that causes blood to age, but rather the reversible epigenetic changes.
'An epigenetic component of hematopoietic stem cell aging amenable to reprogramming into a young state' Blood. 2013 Mar 8. Wahlestedt M, Norddahl GL, Sten G, Ugale A, Micha Frisk MA, Mattsson R, Deierborg T, Sigvardsson M, Bryder D.
Link to Blood: http://bloodjournal.hematologylibrary.org/content/early/2013/03/08/blood-2012-11-469080.abstract?sid=43720289-eae7-402a-9ff6-c926fffb5337
For more information, please contact: Martin Wahlestedt, doctoral student, tel: +46 46 222 03 13, Martin.Wahlestedt[at] med [dot] lu [dot] se; or David Bryder, Associate Professor and research group leader, David.Bryder@med.lu.se.
*About stem cells:
There are different types of stem cells. Embryonic stem cells, which can be extracted from an embryo at an early stage, have the capacity to develop into all types of cell. Stem cells are also found in adults, where they have more limited development potential, but can divide in principle an unlimited number of times. For example, blood cell-forming stem cells in bone marrow create all types of blood cell and stem cells in the brain create many different types of brain cell.
Epigenetics is a term that has historically been used to describe the aspects of genetics that cannot be explained by the composition of an individual's DNA alone. For tissue and organs to form, a number of different types of cell must be developed. This happens through the activation and de-activation of different genes. When a cell formed in this manner then divides again, the gene expression can be maintained in the daughter cells. This is referred to as 'epigenetic inheritance'. The epigenetic mechanisms, or which genes are activated or de-activated, can be affected by factors such as age, chemicals, drugs and diet.
*** About the composition of blood:
B- and T-lymphocytes and myeloid cells are all white blood cells. Lymphocytes, as the name suggests, are particularly common in the lymphatic system. T-lymphocytes patrol the body and recognise a specific bacteria or virus. B-lymphocytes 'remember' old infections and can quickly be activated again if required. This memory capacity is the mechanism behind immunity. The myeloid cells belong to the blood system's 'big eaters' – they neutralise damaged tissue, dead cells, and to a certain extent also bacteria.
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