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Aging stem cells in mice may hold answers to diseases of the aged, Stanford study finds

STANFORD, Calif. -- As stem cells in the blood grow older, genetic mutations accumulate that could be at the root of blood diseases that strike people as they age, according to work done in mice by researchers at the Stanford University School of Medicine.

"This and our previous work points out why older people are more likely to get blood diseases, such as leukemia or anemia, and are less likely to make new antibodies that would protect against infections like the flu," said senior author Irving Weissman, MD, director of the Stanford Institute for Stem Cell Biology and Regenerative Medicine and of the Stanford Comprehensive Cancer Center. The work will be published in the June 6 issue of Nature.

In past studies, this group of researchers had shown that blood-forming stem cells in the bone marrow of mice became less able to divide and replenish the supply of blood cells as they aged. The question was why.

Researchers have put forward many theories about how cells age, said Derrick Rossi, PhD, postdoctoral scholar and co-first author of the paper. One of those theories has to do with cells accumulating genetic mutations. "The idea is that, over time, accumulated DNA damage progressively diminishes the cell's ability to perform its normal function," he said.

However, researchers had thought that mutations were unlikely to underlie aging in blood-forming stem cells because they very rarely divide, and most mutations crop up during division. The infrequent divisions were believed to protect the cells from acquiring new mutations.

Rossi, Weissman and the other first author, postdoctoral scholar David Bryder, PhD, tested that idea in two different sets of experiments. In the first, they studied the blood-forming stem cells of mice engineered to have single mutations that make them especially prone to accumulating additional genetic errors. In each of the three different types of mutant mice they studied, the stem cells appeared to behave normally and to produce new blood cells.

However, the full truth came out when they took blood-forming stem cells from any of the three types of mice and used those cells to repopulate the bone marrow of irradiated mice. This type of experiment is much like using a bone marrow transplant to bring back the bone marrow in a person who has undergone extensive chemotherapy.

Normally, a few stem cells are enough to completely replenish the bone marrow of mice and produce normal amounts of blood and immune cells. However, error-filled blood-forming stem cells taken from the mutant mice were much less effective at colonizing the depleted bone marrow than normal stem cells, and became even less effective when taken from older mutant mice.

Rossi said these results suggest that mutations accumulating in stem cells as they age were preventing them from doing their normal job of producing new blood and immune system cells. However, these results were in mutant mice. Rossi wanted to know if the stem cells in normal, healthy mice also accumulate damage as they age.

To address this, in the second set of experiments, Rossi isolated stem cells from the bone marrow of normal young and old mice, then stained those cells with a chemical that clings to a protein that's associated with DNA damage. This protein can act as a flag to highlight nearby DNA damage.

What he found is that young stem cells from normal mice contained no stain and therefore little or no DNA damage. Older stem cells, on the other hand, showed extensive staining.

All of this adds up to one thing: blood-forming stem cells do accumulate DNA damage with age even though they rarely divide, and that damage is passed on to the blood and immune system cells they make. Weissman said these findings could explain the origin of blood cancer (leukemia) and immune dysfunctions that occur as people age.

The next step is to show whether these results from mice hold true for human blood-forming stem cells. "If this work does extrapolate to humans, then it is absolutely consistent with the idea that blood-forming stem cells are the breeding ground for pre-leukemic mutations," said Weissman, the Virginia and D.K. Ludwig Professor for Clinical Investigation in Cancer Research.

EMBARGOED FOR RELEASE UNTIL: Wednesday, June 6, 2007, at 10 a.m. Pacific time to coincide with publication in the journal Nature PRINT MEDIA CONTACT: Amy Adams at (650) 723-3900 (amyadams@stanford.edu) BROADCAST MEDIA CONTACT: M.A. Malone at (650) 723-6912 (mamalone@stanford.edu)

Additional Stanford researchers who contributed to this work include postdoctoral scholar Jun Seita, MD, PhD.

Funding for this study came from the National Cancer Institute's Center for Cancer Research, the Damon Runyon Cancer Foundation, the California Institute of Regenerative Medicine, a Swedish Medical Research Council scholarship (STINT) and a Cancerfonden grant.

Stanford University Medical Center integrates research, medical education and patient care at its three institutions - Stanford University School of Medicine, Stanford Hospital & Clinics and Lucile Packard Children's Hospital at Stanford. For more information, please visit the Web site of the medical center's Office of Communication & Public Affairs at http://mednews.stanford.edu.

A twist of fate -- Reprogrammed fibroblasts resemble embryonic stem cells

Stem cell biology takes another exciting leap forward as scientists report that normal tissue cells can be reprogrammed to exhibit many of the properties that are characteristic of embryonic stem cells, including the ability to give rise to multiple cell types and contribute to the germline. These findings, published in the inaugural issue of the journal Cell Stem Cell, published by Cell Press, provide strong support for the rationale that it may be possible to generate stem cells with nearly unlimited potential directly from a patient’s own cells, an idea that has significant implications for regenerative therapeutics.

Although transplantation of stem cells generated from human embryos is considered to be a promising option for replacement of damaged or diseased tissues, there are serious difficulties and concerns associated with this methodology. Controversial ethical issues are associated with the use of human embryos, and tissue rejection remains a major concern with stem cell transplants, just as it is for organ transplants. One way to avoid these potential problems is to find a way to reliably reprogram an individual’s differentiated tissue cells into cells that behave like embryonic stem cells and can give rise to any fetal or adult cell type.

Recent research discovered that expression of four transcription factors can induce a pluripotent state in adult fibroblasts. Dr. Konrad Hochedlinger from the Massachusetts General Hospital Center for Regenerative Medicine and the Harvard Stem Cell Institute, Dr. Kathrin Plath from the Institute for Stem Cell Biology and Medicine at UCLA, and their colleagues improved this approach and combined it with an efficient selection process, which allowed them to generate induced pluripotent cells from fibroblasts that were, based on the assays used, indistinguishable from ES cells. For example, genome-wide analysis revealed that the induced stem cells were highly similar to embryonic stem cells with regards to global DNA methylation and histone methylation patterns. In addition, female-induced stem cells showed reactivation of the X chromosome that was silenced in differentiated cells and exhibited random X inactivation upon differentiation.

“Our results demonstrate that the ectopic expression of four transcription factors is sufficient to globally reset the epigenetic landscape of fibroblasts into that of pluripotent cells that are remarkably similar to embryonic stem cells,” explains Dr. Hochedlinger. Dr. Plath adds “The fact that our induced pluripotent cells are epigenetically similar to ES cells suggests that epigenetic abnormalities will not pose a problem for the potential therapeutic applications of induced pluripotent cells.” The researchers went on to show that the induced pluripotent cells could differentiate into numerous cell types, including blood cells in culture and oocytes in animals. Importantly, two related papers being published in the journal Nature demonstrate that similar induced pluripotent cells can also give rise to fertilized embryos and viable offspring, respectively. Future studies are needed to examine whether direct reprogramming of human cells follows these promising patterns observed in mice.

These studies and other recent advances in strategies aimed at generating patient-specific stem cell lines are discussed in the review article by Dr. Shinya Yamanaka in the current issue of Cell Stem Cell.

Journalists please note: The related papers in the journal Nature will go live at the same time and follow the same embargo, 1:00pm Eastern Time US on Wednesday, 6 June 2007. For further information please contact Ruth Francis, Senior Press Officer at Nature: r.francis@nature.com or visit Nature's press site at http://press.nature.com/press.

The researchers include Nimet Maherali of Massachusetts General Hospital Cancer Center and Center for Regenerative Medicine and Harvard Stem Cell Institute in Boston, MA and Harvard University in Cambridge, MA; Rupa Sridharan, Wei Xie, Robin Yachechko, Jason Tchieu, and Kathrin Plath of UCLA School of Medicine in Los Angeles, CA; Jochen Utikal, Sarah Eminli, Katrin Arnold, Matthias Stadtfeld, and Konrad Hochedlinger of Massachusetts General Hospital Cancer Center and Center for Regenerative Medicine and Harvard Stem Cell Institute in Boston, MA; Rudolf Jaenisch of the Whitehead Institute at Massachusetts Institute of Technology in Cambridge, MA.

TN.M. is supported by a graduate scholarship from the Natural Sciences and Engineering Council of Canada and a Sir James Lougheed Award. K.P. is supported by the Margaret E. Early Trust Foundation and is a Special Fellow of the Leukemia and Lymphoma Society. K.H. is supported by the Harvard Stem Cell Institute and is a V Scholar.

Maherali et al.: “Directly Reprogrammed Fibroblasts Show Global Epigenetic Remodeling and Widespread Tissue Contribution.” Publishing in Cell Stem Cell 1, 55–70, July 2007. DOI 10.1016/j.stem.2007.05.014