 |
|
Stem cells derived from adult testes produce wide range of tissue types
September 20, 2007Promising new source of stem cells
After a decade of research, Howard Hughes Medical Institute scientists have succeeded in reprogramming adult stem cells from the testes of male mice into functional blood vessels and contractile cardiac tissue. The research offers a promising new source of stem cells for use in organ regeneration studies.
Some scientists think that organ-specific adult stem cells may offer the same therapeutic potential as embryonic stem cells, without the ethical concerns or the risk of immune rejection that are associated with embryonic stem cell therapies. However, adult stem cells may lack the plasticity and pluripotency of embryonic stem cells' capacity to generate any cell type. The study of adult stem cells has also been limited by their relative scarcity in various organs and the attendant difficulties in identifying and harvesting them, as well as differentiating them in large quantities into functional vascularized tissues.
HHMI investigator Shahin Rafii and his colleagues at Weill Cornell Medical College appear to have solved some of these problems in male mice. Using spermatogonial progenitor cells obtained from the mouse's testes, the researchers reprogrammed the cells to form multipotent adult spermatogonial-derived stem cells. If the same can be done with human cells, they say, adult stem cells may be a promising source of new therapies for men, for diseases such as vascular diseases, heart disease, Alzheimer's, Parkinson's, stroke, diabetes, and even cancer.
Scientists have had good success in deriving pluripotent stem cell lines - those with the ability to develop into multiple cell types -- from adult testes cells. But only a small subset of cells from the testes has the potential to become pluripotent, and until now, investigators have lacked a means to identify and isolate them.
In a paper published online in the September 20, 2007, issue of the journal Nature, Rafii and colleagues at Weill Cornell Medical College and Memorial Sloan-Kettering Cancer Center report that they have identified a novel cell surface marker that is expressed on a unique set of cells within adult testes known as the spermatogonial stem and progenitor cells (SPCs). The marker, GPR125, enabled the scientists to identify and harvest a large number of SPCs from adult mouse testes, then propagate and reprogram them in the lab to become stem cells that could differentiate into many cell types.
The researchers demonstrated that these multipotent adult spermatogonial-derived stem cells (MASCs) could develop in vivo into working blood vessel (endothelial) cells and tissue, as well as contractile cardiac tissue, brain cells, and a host of other cell types. They also injected MASCs from culture into mouse blastocysts-embryonic cells-that they implanted in mature female mice. When the blastocysts developed into mice, the researchers could see that the MASCs had differentiated into many kinds of tissue. These data suggested that the MASCs are truly multipotent: reprogrammable to differentiate into functional tissues.
Ten years ago, Rafii observed that human testicular cancer cells share many characteristics with adult stem cells. As an oncologist, he also noticed that a large number of patients with testicular cancer develop tumors called teratomas, which contain different types of tissue. Based on these observations, he reasoned that spermatogonia, whose sole function is to generate the precursors to sperm, have the potential to readily give rise to pluripotent cells. As such, he thought, they might prove more amenable to reprogramming than other adult stem cells.
Using gene screening studies, Rafii and colleagues discovered a potential specific surface marker on SPCs. Comparison of all cells in the adult testis showed that this G-protein coupled receptor, known as GPR125, was expressed on SPCs, but not other mature germ cells. With GPR125 in hand, Rafii could isolate large numbers of SPCs from adult mouse testes.
They also established a highly sophisticated culture system in which the progenitor cells rapidly grow and divide, creating a large population of cells that can be converted into MASCs.
"It appears that these specialized GPR125-positive spermatogonial cells could be an easily obtained and manipulated source of stem cells with a similar capability to form new tissues that we see in embryonic stem cells," said Rafii. For male patients, he believes, "It could someday mean a readily available source of stem cells that gets around ethical issues linked to embryonic stem cells. It also avoids issues linked to tissue transplant rejection, since these autologous cells come from the patient's own body."
Rafii's team is currently pursuing a similar study of human testes to determine whether stem cells derived from their spermatogonial progenitor cells share the pluripotency of the mouse MASCs. "We believe this to be an easily obtainable goal in the near future," he said.
If they succeed, several steps remain before such stem cells could be applicable to humans. "We still have to learn the exact biochemical and epigenetic 'switch' that tells GPR125-positive SPCs to convert into MASCs," said Marco Seandel, a senior post-doctoral fellow in Rafii's laboratory who is the first author of the Nature paper. "Discovering that switch will be crucial to our being able to create MASCs on demand,"
There is a chance that implanted cells derived from MASCs may trigger cancer in the recipient. This is an area that requires further investigation, Rafii said. However, he noted, "So far, we haven't seen any cancer or evidence of pro-cancerous activity in adult mice that are implanted with differentiated MASC cell tissue derivatives."
Rafii and his team have worked out the growing conditions that coax spermatogonial progenitor cells to develop into MASC germ lines-- genetically stable stem cells that continue reproducing indefinitely. Stem cell studies have been limited to date by the scarcity of germ cell lines. "None of these GPR125-positive germ cell lines was previously readily available for genetic, biochemical, and cellular analysis by other laboratories," says Rafii. "We intend to share them with other researchers."
Rafii's lab is now investigating whether GPR125 can be used to isolate cells from other adult tissues that can be converted into multipotent stem cells. His group has also begun pursuing a similar effort in ovaries. "It's much more difficult," he said. "However, it is possible that reprogrammable stem cells with similar properties to GPR125-positive SPCs may also exist, although at very low numbers, in adult mouse or human ovaries." His lab is actively investigating this intriguing possibility, Rafii said.
Howard Hughes Medical Institute
HHMI investigator Shahin Rafii and his colleagues at Weill Cornell Medical College appear to have solved some of these problems in male mice. Using spermatogonial progenitor cells obtained from the mouse's testes, the researchers reprogrammed the cells to form multipotent adult spermatogonial-derived stem cells. If the same can be done with human cells, they say, adult stem cells may be a promising source of new therapies for men, for diseases such as vascular diseases, heart disease, Alzheimer's, Parkinson's, stroke, diabetes, and even cancer.
Scientists have had good success in deriving pluripotent stem cell lines - those with the ability to develop into multiple cell types -- from adult testes cells. But only a small subset of cells from the testes has the potential to become pluripotent, and until now, investigators have lacked a means to identify and isolate them.
In a paper published online in the September 20, 2007, issue of the journal Nature, Rafii and colleagues at Weill Cornell Medical College and Memorial Sloan-Kettering Cancer Center report that they have identified a novel cell surface marker that is expressed on a unique set of cells within adult testes known as the spermatogonial stem and progenitor cells (SPCs). The marker, GPR125, enabled the scientists to identify and harvest a large number of SPCs from adult mouse testes, then propagate and reprogram them in the lab to become stem cells that could differentiate into many cell types.
The researchers demonstrated that these multipotent adult spermatogonial-derived stem cells (MASCs) could develop in vivo into working blood vessel (endothelial) cells and tissue, as well as contractile cardiac tissue, brain cells, and a host of other cell types. They also injected MASCs from culture into mouse blastocysts-embryonic cells-that they implanted in mature female mice. When the blastocysts developed into mice, the researchers could see that the MASCs had differentiated into many kinds of tissue. These data suggested that the MASCs are truly multipotent: reprogrammable to differentiate into functional tissues.
Ten years ago, Rafii observed that human testicular cancer cells share many characteristics with adult stem cells. As an oncologist, he also noticed that a large number of patients with testicular cancer develop tumors called teratomas, which contain different types of tissue. Based on these observations, he reasoned that spermatogonia, whose sole function is to generate the precursors to sperm, have the potential to readily give rise to pluripotent cells. As such, he thought, they might prove more amenable to reprogramming than other adult stem cells.
Using gene screening studies, Rafii and colleagues discovered a potential specific surface marker on SPCs. Comparison of all cells in the adult testis showed that this G-protein coupled receptor, known as GPR125, was expressed on SPCs, but not other mature germ cells. With GPR125 in hand, Rafii could isolate large numbers of SPCs from adult mouse testes.
They also established a highly sophisticated culture system in which the progenitor cells rapidly grow and divide, creating a large population of cells that can be converted into MASCs.
"It appears that these specialized GPR125-positive spermatogonial cells could be an easily obtained and manipulated source of stem cells with a similar capability to form new tissues that we see in embryonic stem cells," said Rafii. For male patients, he believes, "It could someday mean a readily available source of stem cells that gets around ethical issues linked to embryonic stem cells. It also avoids issues linked to tissue transplant rejection, since these autologous cells come from the patient's own body."
Rafii's team is currently pursuing a similar study of human testes to determine whether stem cells derived from their spermatogonial progenitor cells share the pluripotency of the mouse MASCs. "We believe this to be an easily obtainable goal in the near future," he said.
If they succeed, several steps remain before such stem cells could be applicable to humans. "We still have to learn the exact biochemical and epigenetic 'switch' that tells GPR125-positive SPCs to convert into MASCs," said Marco Seandel, a senior post-doctoral fellow in Rafii's laboratory who is the first author of the Nature paper. "Discovering that switch will be crucial to our being able to create MASCs on demand,"
There is a chance that implanted cells derived from MASCs may trigger cancer in the recipient. This is an area that requires further investigation, Rafii said. However, he noted, "So far, we haven't seen any cancer or evidence of pro-cancerous activity in adult mice that are implanted with differentiated MASC cell tissue derivatives."
Rafii and his team have worked out the growing conditions that coax spermatogonial progenitor cells to develop into MASC germ lines-- genetically stable stem cells that continue reproducing indefinitely. Stem cell studies have been limited to date by the scarcity of germ cell lines. "None of these GPR125-positive germ cell lines was previously readily available for genetic, biochemical, and cellular analysis by other laboratories," says Rafii. "We intend to share them with other researchers."
Rafii's lab is now investigating whether GPR125 can be used to isolate cells from other adult tissues that can be converted into multipotent stem cells. His group has also begun pursuing a similar effort in ovaries. "It's much more difficult," he said. "However, it is possible that reprogrammable stem cells with similar properties to GPR125-positive SPCs may also exist, although at very low numbers, in adult mouse or human ovaries." His lab is actively investigating this intriguing possibility, Rafii said.
Howard Hughes Medical Institute
Stem Cells Current Events and Stem Cells News RSSPure insulin-producing cells produced in mouse
Singapore researchers have developed an unlimited number of pure insulin-producing cells from mouse embryonic stem cells (ESCs).
Adult stem cell breakthrough
The first tissue-engineered trachea (windpipe), utilising the patient's own stem cells, has been successfully transplanted into a young woman with a failing airway. The bioengineered trachea immediately provided the patient with a normally functioning airway, thereby saving her life.
First trachea transplant without immunosuppression
After 4 years of going from consultation to consultation, Claudia Castillo finally found a solution to her respiratory problems. The young Colombian woman suffered from a cough that took a long time to be diagnosed as tuberculosis.
First Trial in the U.S. to Treat Both Ischemic & Non-Ischemic Heart Failure to be Performed by U of U Researchers Using Patient's Own Stem Cells
Researchers at the University of Utah are enrolling people in a new clinical trial that uses a patient's own stem cells to treat ischemic and non-ischemic heart failure.
New imaging technique tracks cancer-killing cells over prolonged period
Coaxing a patient's own cells to hunt down and tackle infected or diseased cells is a promising therapeutic approach for many disorders.
Exercise increases brain growth factor and receptors, prevents stem cell drop in middle age
A new study confirms that exercise can reverse the age-related decline in the production of neural stem cells in the hippocampus of the mouse brain, and suggests that this happens because exercise restores a brain chemical which promotes the production and maturation of new stem cells.
Intraspinal implant of mesenchymal stem cells may not heal the demyelinated spinal cord
Multiple sclerosis is a disease caused by the loss of the myelinated sheath surrounding the nerve fibers of the spinal cord.
Protein can nurture or devastate brain cells, depending on its 'friends,' researchers find
Researchers at UT Southwestern Medical Center have uncovered new insights into the "Dr. Jekyll and Mr. Hyde" nature of a protein that stimulates stem-cell maturation in the brain but, paradoxically, can also lead to nerve-cell damage.
The bonsai effect: Wounded plants make jasmonates, inhibiting cell division, stunting growth
It is well known that plants growing under unfavourable conditions are generally smaller than those growing in stress-free conditions: indeed it is estimated that in the US, abiotic stress reduces the yield of agricultural crops by an average of 22%.
Stem Cells from Monkey Teeth Can Stimulate Growth and Generation of Brain Cells
Researchers at the Yerkes National Primate Research Center, Emory University, have discovered dental pulp stem cells can stimulate growth and generation of several types of neural cells. Findings from this study, available in the October issue of the journal Stem Cells, suggest dental pulp stem cells show promise for use in cell therapy and regenerative medicine, particularly therapies associated with the central nervous system.
More Stem Cells Current Events and Stem Cells News Articles
 | The Stem Cell Divide: The Facts, the Fiction, and the Fear Driving the Greatest Scientific, Political, and Religious Debate of Our Time by Michael Bellomo As politics, religion, and the media weigh in on the complex stem cell issue, more and more of the scientific reality is getting lost. In the search for the truth, "The Stem Cell Divide" does not take sides and debunks the distortions and exaggerations that come from every camp, while providing a complete picture of what scientists have accomplished so far, what they're currently doing and what... |
 | Stem Cell Now by Christopher Thomas Scott The essential account of the most important scientific advance—and most volatile ethical debate—of our time While many believe stem cell research holds the key to curing a wide range of ailments, others see this research as opening a Pandora’s box that will devalue human life. In Stem Cell Now, Christopher Scott—executive director of Stanford University’s Stem Cells and Society... |
 | Stem Cell Research: Medical Applications And Ethical Controversy (The New Biology) by Joseph, Ph.D. Panno This is an informative reference to the technological advances, applications, and issues of stem cell research. The past few years have seen controversy and debate surrounding stem cell research. Because skin cells have the capability to divide - unlike most of the cells in our body - our skin can heal itself through the division of cells. Scientists have attempted to apply this concept to major... |
 | The Stem Cell Controversy: Debating the Issues (Contemporary Issue Series) Stem cell research is headline news. Researchers are eager to move forward, state governments and private foundations are rushing to support it, and the sick and afflicted are desperate for its benefits. Yet powerful forces in our society - led by President George W. Bush - find it morally troubling and they are doing all in their powers to restrict its development beyond a very limited scale.... |
 | Fundamentals of the Stem Cell Debate: The Scientific, Religious, Ethical, and Political Issues Few recent advances in science have generated as much excitement and controversy as human embryonic stem cells. The potential of these cells to replace diseased or damaged cells in virtually every tissue of the body heralds the advent of an extraordinary new field of medicine. Controversy arises, however, because current techniques required to harvest stem cells involve the destruction of the... |
 | Essentials of Stem Cell Biology by Robert Lanza, E. Donnall Thomas, James Thomson, Roger Pedersen, John Gearhart, Brigid Hogan, Douglas Melton, Michael West This abridged version of the bestselling reference Handbook of Stem Cells, Two-Volume Set attempts to incorporate all the essential subject matter of the original two-volume edition in a single volume. The material has been reworked in an accessible format suitable for students and general readers interested in following the latest advances in stem cells, including full color presentation... |
 | Stem Cell Century: Law and Policy for a Breakthrough Technology by Russell Korobkin The explosion of interest in stem cell research raises a raft of controversial policy questions. When should human embryos be used to create stem cells? Should cloning be outlawed? Should egg and tissue donors be paid? Should we allow scientists to patent stem cells? Is the government entitled to a portion of the revenue from stem cell technology created with public funds? How should the... |
 | The Stem Cell Dilemma: Beacons of Hope or Harbingers of Doom? by Leo Furcht, William Hoffman TodayÕs scientists are showing us how stem cells create and repair the human body. Unlocking these secrets has become the new Holy Grail of biomedical research. But behind that search lies a sharp divide. Stem cells offer the hope of creating or repairing tissues lost to age, disease, and injury. Yet because of this ability, stem cells hold the potential to incite an international biological... |
 | Cell of Cells: The Global Race to Capture and Control the Stem Cell by Cynthia Fox Positioned at the cutting edge of science, Cell of Cells charts the international race to utilize the stem cell.From a lab in the Sahara, where one problem is sand in the petri dishes, to an Israeli lab that narrowly escapes a terrorist bomb, stem cells have gone global. Not only are the cells studied in an escalating number of labs—and lands—but they are already being used. In Japan, a... |
 | Stem Cell Wars: Inside Stories from the Frontlines by Eve Herold Americans have become the victims of misinformation about stem cell research. Over the last few years, the stem cell debate has been intensely political, religious, and confusing to many people. Now, Eve Herold explains what this science is all about, who is for and against it, and why it must go forward. She pulls together fascinating stories to highlight every aspect of this multifaceted... |
| © 2008 BrightSurf.com |