 |
|
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 RSSNew discovery about the formation of new brain cells
The generation of new nerve cells in the brain is regulated by a peptide known as C3a, which directly affects the stem cells' maturation into nerve cells and is also important for the migration of new nerve cells through the brain tissue, reveals new research from the Sahlgrenska Academy published in the journal Stem Cells.
Umbilical cord blood stem cell transplant may help lung, heart disorders
Two separate studies published in the current issue of Cell Transplantation (18:8), - now freely available on-line have shown that transplanted human-derived umbilical cord blood (UCB) stem cells transplanted in an animal model had positive therapeutic effects on specific lung and heart disorders the animal models.
Gene mismatch influences success of bone marrow transplants
A commonly inherited gene deletion can increase the likelihood of immune complications following bone marrow transplantation, an international team of researchers reports in the November 22 advance online issue of Nature Genetics.
New research shows versatility of amniotic fluid stem cells
For the first time, scientists have demonstrated that stem cells found in amniotic fluid meet an important test of potential to become specialized cell types, which suggests they may be useful for treating a wider array of diseases and conditions than scientists originally thought.
First reconstitution of an epidermis from human embryonic stem cells
Stem cell research is making great strides. This is yet again illustrated by a study carried out by the I-STEM* Institute (I-STEM/ Inserm UEVE U861/AFM), published in the Lancet on 21 November 2009. The I-STEM team, directed by Marc Peschanski has just succeeded in recreating a whole epidermis from human embryonic stem cells.
Bone Implant Offers Hope for Skull Deformities
A synthetic bone matrix offers hope for babies born with craniosynostosis, a condition that causes the plates in the skull to fuse too soon.
Your Own Stem Cells Can Treat Heart Disease
The largest national stem cell study for heart disease showed the first evidence that transplanting a potent form of adult stem cells into the heart muscle of subjects with severe angina results in less pain and an improved ability to walk. The transplant subjects also experienced fewer deaths than those who didn't receive stem cells.
Is hepatic differentiation of embryonic stem cells induced by valproic acid and cytokines?
Embryonic stem (ES) cells, known for their capacity to proliferate indefinitely and differentiate into almost all types of cells including hepatocytes, have raised the hope of cellular replacement therapy for liver failure.
Paradoxical protein might prevent cancer
One difficulty with fighting cancer cells is that they are similar in many respects to the body's stem cells. By focusing on the differences, researchers at Karolinska Institutet have found a new way of tackling colon cancer. The study is presented in the prestigious journal Cell.
U of M researchers find 2 units of umbilical cord blood reduce risk of leukemia recurrence
A new study from the Masonic Cancer Center, University of Minnesota shows that patients who have acute leukemia and are transplanted with two units of umbilical cord blood (UCB) have significantly reduced risk of the disease returning.
More Stem Cells Current Events and Stem Cells News Articles
 |
Essentials of Stem Cell Biology, Second Edition by Robert Lanza (Editor), John Gearhart (Editor), Brigid Hogan (Editor), Douglas Melton (Editor), Roger Pederson (Editor), E. Donnall Thomas (Editor), James Thomson (Editor), Sir Ian Wilmut (Editor) First developed as an accessible abridgement of the successful Handbook of Stem Cells, Essentials of Stem Cell Biology serves the needs of the evolving population of scientists, researchers, practitioners and students that are embracing the latest advances in stem cells. Representing the combined effort of seven editors and more than 200 scholars and scientists whose pioneering work has defined our understanding of stem cells, this book combines the prerequisites for a general understanding of adult and embryonic stem cells with a presentation by the world?s experts of the latest research information about specific organ systems. From basic biology/mechanisms, early development, ectoderm, mesoderm, endoderm, methods to application of stem cells to specific human diseases, regulation and... |
 |
Stem Cell Now by Christopher Thomas Scott (Author) 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 Program—lays out the scientific and ethical issues surrounding this national dilemma. Scott guides readers through the latest advances in stem cell research in clear, accessible language, telling the stories of the researchers who are exploring the potential of stem cells to cure cancer, grow new organs, and repair the immune system. He also leads readers through a... |
 |
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 (Author) There has been much recent debate about the merits, dangers, and nature of stem cell research. Some see in it the answer to every debilitating disease known to man, while others see it as a step away from human cloning. While the battle has raged, research is moving ahead, and California has already passed a measure that will give $3 billion in support to stem cell research. But as politics, religion, and the media weigh in on this complex issue, more and more of the scientific reality of stem cell research is getting lost. In the search for the truth about stem cell science, the author has interviewed the scientists whose cutting-edge research is at the very heart of this hot-button issue. The book explains what they have accomplished so far, what they're currently doing, and what... |
 |
Human Stem Cell Manual: A Laboratory Guide by Jeanne F. Loring (Editor), Robin L. Wesselschmidt (Editor), Philip H. Schwartz (Editor) Stem cells are self-replicating and undifferentiated, meaning their function is not yet cell, tissue, or organ-specific. Due to the unique nature of these cells, research into their biology and function holds great promise for therapeutic applications through replacement or repair of diseased and damaged cells. This reader-friendly manual provides a practical "hands on" guide to the culture of human embryonic and somatic stem cells. By presenting methods for embryonic and adult lines side-by-side, the authors lay out an elegant and unique path to understanding the science of stem cell practice. The authors begin with a broad-based introduction to the field, and also review legal and regulatory issues and patents. Each experimental strategy is presented with an historical introduction,... |
 |
Cell of Cells: The Global Race to Capture and Control the Stem Cell by Cynthia Fox (Author) Publication Date is March 26, 2007 |
 |
Stem Cell Research: Medical Applications And Ethical Controversy (The New Biology) by Joseph, Ph.D. Panno (Author) 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 organs, trying to see if stem cells can be used to make the repairs that post-mitotic cells cannot. "Stem Cell Research" is a comprehensive and interesting introduction to this popular new science for non-experts. Explaining how stems cells can be obtained from several places, including skin, bone marrow, and most usefully, embryos, this book covers all the fundamental aspects of stem cell... |
 |
The Stem Cell Dilemma: Beacons of Hope or Harbingers of Doom? by Leo Furcht (Author), William Hoffman (Author) 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 arms race. THE STEM CELL DILEMMA will tell you everything you ever wanted to know about stem cells: what they are, how they work, and why their use has become so controversial. We are standing at a scientific crossroads, the likes of which the world has never seen. It is a moment that will change forever the practice of medicine and the future of life as we know it. |
 |
Stem Cell Activator by Bell Lifestyle Products - 60 Capsules by Bell Lifestyle Products, Inc. BENEFITS: Helps to activate naturally millions of stem cells from our own bone marrow. The increase in stem cells released from the bone marrow into the blood stream have the potential to become other types of tissue cells with specialized function. Stem cells will multiply and are able to become heart cells liver cells or any other organ. Located everywhere in our body stem cells are even under our skin layered between the epidermis and dermis. This is why an increase in stem cells under our skin may help to create a more youthful cell that would replenish elastin and collagen and thus may make us look younger. If our bone marrow does not produce enough stem cells this can result in many illnesses especially a weak heart kidneys liver pancreas in fact all healthy functions of our body... |
 |
Stem Cells: Scientific Progress And Future Research Directions by National Institutes of Health (Author) The makings of future news headlines about tomorrow’s life saving therapies starts in the biomedical research laboratory. Ideas abound; early successes and later failures and knowledge gained from both; the rare lightning bolt of an unexpected breakthrough discovery --- this is a glimpse of the behind the scenes action of some of the world’s most acclaimed stem cell scientists’ quest to solve some of the human body’s most challenging mysteries. Stem cells --- what lies ahead? The following chapters explore some of the cutting edge research featuring stem cells. Disease and disorders with no therapies or at best, partially effective ones, are the lure of the pursuit of stem cell research. Described here are examples of significant progress that is a prologue to an era of... |
 |
Mesenchymal Stem Cells: Methods and Protocols (Methods in Molecular Biology) by Darwin J. Prockop (Editor), Donald G. Phinney (Editor), Bruce A. Bunnell (Editor) For over forty years, mesenchymal stem cells (MSCs) have been scrutinized and studied, garnering much attention due to their broad therapeutic efficacy. In Mesenchymal Stem Cells: Methods and Protocols, leaders in the field were assembled to contribute detailed methodologies for the isolation and characterization of human and rodent MSCs. Recently, these vital cells have shown therapeutic benefits in the treatment of myocardial infarction, stroke, lung diseases, spinal cord injury and other neurological disorders, thus promising a boundless future in their study. Cutting edge and easy to use, Mesenchymal Stem Cells: Methods and Protocols is the perfect resource for scientists attempting to pursue this important and ever-developing field of research. |
| © 2009 BrightSurf.com |