Longevity gene regulates neural stem cells in mice

Researchers at the Stanford University School of Medicine have found that a gene long-known to regulate the lifespan of tiny roundworms also plays a role in regulating neural stem cells in mice.

Variations of the gene family, called FoxO, help roundworms live to an unusually ripe old age in the lab, and mutations in the FoxO3 gene have also recently been associated with long life in Japanese, German, American and Italian populations. Laboratory mice lacking FoxO3 live to about half their usual age of 30 months before dying of cancer.

The group found that in addition to dying young, adult mice lacking FoxO3 had fewer neural stem cells than normal mice of the same age. These neural stem cells normally generate new brain cells as needed, and also replenish their own population to maintain a lifetime pool of cells.

According to a press release by the Stanford University School of Medicine:

The researchers also discovered that the few stem cells found in the adult mice without FoxO3 more rapidly churned out neural cell precursors — those cells destined to become new neurons — than did the mice with normal FoxO3 levels. In fact, the brains of the mice that lacked FoxO3 were heavier than the control group, perhaps because they were burning through their pool of neural stem cells by making too many new nerve cells.

A better understanding of how neural stem cells maintain the brain as it ages could help those researchers who are developing therapies for disorders such as Alzheimer’s and Parkinson’s disease or stroke.

Cell Stem Cell: November 6, 2009
CIRM funding: Anne Brunet (RN1-00527-1)

Related Information: Stanford University School of Medicine, Brunet bio

A.A.

Old muscle stem cells experimentally returned to youth

Researchers at the University of California, Berkeley have found molecular pathways that human muscle stem cells rely on to repair damaged muscle. These pathways are active in younger people but less active in older people, explaining why muscles repair more slowly with age. The group found that younger volunteers had double the number of regenerative muscle stem cells in their thigh muscles compared to older volunteers. After two weeks in a leg cast, both groups began exercise routines to rebuild muscle. During this phase, the older volunteers had four times fewer muscle stem cells and rebuilt muscle more slowly. The researchers said that the poor response wasn’t the fault of the older stem cells. Instead, signals in the aging muscle and blood locked the stem cells in an inactive state. From their work in mice, the researchers knew that proteins present in the muscle surrounding the stem cells helped these cells respond to distress signals from the injured tissue. In the human cells, they found a protein called MAPK that interprets these distress signals and triggers the muscle stem cells to begin the repair process. Young people have high levels of MAPK and older people have low levels of MAPK, providing one explanation for the older volunteers’ poor response to exercise. In a lab dish, the group found that by artificially blocking MAPK in young muscle stem cells they could make young cells respond like older cells in a matter of days. The reverse was also true. Amplifying MAPK in older muscle stem cells in a lab dish rejuvenated the older cells. This work is an important step in verifying results from mouse stem cell aging studies in humans. The researchers hope their work could lead to therapies for muscle diseases and help older people to remain active, build stronger muscles and recover from injury.

EMBO Molecular Medicine: September 30, 2009
CIRM funding: Irina Conboy (RN1-00532-1), Morgan Carlson (T1-00007)

Related Information: Press Release, University of California, Berkeley

A.A.

Neural stem cells reverse Alzheimer's symptoms in mice

Researchers at the University of California, Irvine have reversed Alzheimer’s-like symptoms in a mouse model of the disease with injections of neural stem cells. The mice used in this study mimicked the human disease, showing learning and memory defects and accumulating both beta-amyloid plaques and tau protein tangles within the brain, the two hallmark pathologies of the disease.  Mice that received injections of mouse neural stem cells performed significantly better in memory tests than mice that received control injections. The stem cells did not replace cells lost to the disease. Instead, the injected cells secreted a protein known as brain-derived neurotrophic factor (BDNF), that helped nourish the surviving neurons, encouraging those cells to grow more fibers and form more connections. The injected cells did not reduce the plaques or tangles. Current therapies for Alzheimer’s disease can only reduce the severity of symptoms or slow progression. To date, this is only the second potential treatment shown to actually improve memory in mice with advanced plaque and tangle pathology.



Proceedings of the National Academy of Sciences, August 11, 2009
CIRM funding: Frank LaFerla (RS1-00247-1), Matthew Blurton-Jones (T1-00008)

Related Information: UCI Press Release, University of California, Irvine, LaFerla bio

E.R.

Protein required to maintain full potential of stem cells

Researchers at the University of California, San Francisco have pinpointed a protein that is critical for maintaining a stem cell’s full potential to self-renew and to differentiate. Stem cells lacking the protein were impaired in their ability to divide and make identical copies of themselves, called self-renewal. These cells also lost their capacity to differentiate into key cell types, such as cardiac muscle. The protein, Chd1, acts to keep chromosome strands loosely wound, which permits widespread gene activation in the cell’s nucleus. Previous studies hypothesized that this open chromosome structure is necessary in stem cells to maintain their potential to specialize into any cell type. Additional results in this study demonstrate that Chd1 is required for efficient reprogramming of adult cells, such as skin cells, back into a pluripotent state. These new insights into Chd1 function may lead to safer, more efficient methods for growing up large numbers of embryonic stem cells and deriving specific cell types, both critical steps for successful stem cell therapeutic strategies.

Nature, July 8, 2009 (online publication)
CIRM funding: Rupa Sridharan (T1-00002), Kathrin Plath (RN1-00564-1), Miguel Ramalho-Santos (RS1-00434-1)

Related Information: press release, University of California, San Francisco

Molecules found that control the development of blood vessel cells

Researchers at the Gladstone Institute of Cardiovascular Disease have identified two molecules, called microRNAs, that push early heart cells to mature into the smooth muscle cells that line blood vessels. These same molecules also control when those smooth muscle cells divide to repair damage or in diseases such as cancer or atherosclerosis, which both involve unhealthy blood vessel growth. The two microRNAs, miR-145 and miR-143, are abundant in the primitive heart cells of prenatal mice, leading those cells to differentiate into various mature heart and aorta cells. After birth, both microRNAs are present mainly in smooth muscle cells, which also line the small intestine. If both microRNAs are absent, smooth muscle cells in blood vessels start multiplying. This helps heal injured blood vessels, but it can also create abnormal blood vessel growth in certain diseases. This cell proliferation can thicken blood vessels in atherosclerosis, or it can nourish tumors with blood. These findings could help scientists create smooth muscle cells from embryonic stem cells for therapeutic uses, or could lead to therapies for atherosclerosis or cancer.

Nature, July 5, 2009 (online publication)
CIRM funding: Deepak Srivastava (RC1-00142-1), Kathy Ivey (T2-00003)

Related Information: Press Release, Gladstone Institute of Cardiovascular Disease, Srivastava bio

Genetic differences found between adult cell and embryonic-derived stem cells

Researchers at the University of California, Los Angeles have found genetic differences that distinguish induced pluripotent stem (iPS) cells from embryonic stem cells. These differences diminish over time, but never disappear entirely. iPS cells are created when adult cells, such as those from the skin, are reprogrammed to look and behave like embryonic stem cells. But until now, scientists didn’t know if the two types of stem cells were actually identical at a molecular level. This latest research shows that iPS and embryonic stem cells differ in which genes they have turned on or off. All early iPS cells share these genetic traits, regardless of what animal they come from, the type of adult cells the iPS cells start as, or what method was used to reprogram those adult cells. However, later cultures of iPS cells show that most, but not all, of these differences disappear over time, making later cultures of iPS cells more similar to embryonic stem cells. If scientists want to use iPS cells in medical therapies, this research will give them a better idea of how similar they are to embryonic stem cells.

Cell Stem Cell: July 2, 2009
CIRM funding: Mike Teitell (RS1-00313), Kathrin Plath (RN1-00564-1), William Lowry (RS1-00259-1, RL1-00681-1)

Related Information: Press Release, University of California, Los Angeles

Embryonic stem cells repair nerve damage from mutiple sclerosis in mice

Researchers at the University of California, Irvine have found that neurons derived from  embryonic stem cells were able to repair some damage in a mouse model of multiple sclerosis. In people with MS, the immune system attacks the insulation – called myelin – that covers and protects neurons of the brain and spinal cord. The transplanted cells caused a response in the animals that allowed the myelin coating to be repaired on damaged cells. In humans, repairing the myelin would likely also repair the function of those nerves, bringing back feeling and motor control in people with MS. At this time there are no therapies to repair this damage. Instead, available drugs simply slow the progression of the disease. In this early study, the transplanted neurons survived only two weeks. The authors say more work is needed to understand how the remyelination occurred and how to retain the transplanted cells.

Journal of Neuroimmunology: May 23, 2009 (online)
CIRM funding: Chris Shaumberg (T1-00008), Thomas Lane (RS1-0409)

Related Information: University of California, Irvine