Posts tagged embryonic stem cells
Articles and news from the latest research reports.
Stress gives cells a ‘second childhood’
What doesn’t kill cells may make them stronger—or considerably more flexible, at least. New findings from Haruko Obokata of the RIKEN Center for Developmental Biology in Kobe and Charles Vacanti at Brigham and Women’s Hospital in the United States suggest that exposing mouse cells to acidic stress can make them regress to an extremely developmentally immature state, transcending even that of embryonic stem (ES) cells (1, 2).
ES cells have the developmental capacity to form any tissue type in the body and this ‘pluripotency’ makes them of great interest to both scientists and clinicians. As these cells must be harvested from early-stage embryos, however, human ES cell research remains a politically and ethically fraught issue. As an alternative, researchers can ‘reprogram’ adult cells into ES cell-like induced pluripotent stem (iPS) cells, which offer the advantage of being genetically matched to their donor—an important consideration for regenerative medicine. However, the generation of iPS cells typically requires the introduction of reprogramming genes, which may affect their function or risk of cancerous transformation.
Obokata and colleagues have now discovered an alternative route to pluripotency, drawing on inspiration from the plant world. “Plants [such as] carrots can produce stem cells from totally differentiated cells when they are exposed to strong external stresses like dissection,” Obokata said in a recent interview with Nature. “I instinctively felt that we may have a similar mechanism to plants.”
Study Shows How the Nanog Protein Promotes Growth of Head and Neck Cancer
A new study led by researchers at The Ohio State University Comprehensive Cancer Center – Arthur G. James Cancer Hospital and Richard J. Solove Research Institute (OSUCCC–James) has identified a biochemical pathway in cancer stem cells that is essential for promoting head and neck cancer.
The study shows that a protein called Nanog, which is normally active in embryonic stem cells, promotes the growth of cancer stem cells in head and neck cancer. The findings provide information essential for designing novel targeted drugs that might improve the treatment of head and neck cancer.
Normally, Nanog helps healthy embryonic stem cells maintain their undifferentiated, uncommitted (i.e., pluripotent) state. But recent evidence suggests that Nanog promotes tumor growth by stimulating the proliferation of cancer stem cells.
“This study defines a signaling axis that is essential for head and neck cancer progression, and our findings show that this axis may be disrupted at three key steps,” says principal investigator Quintin Pan, PhD, associate professor of otolaryngology at the OSUCCC – James. “Targeted drugs that are designed to inhibit any or all of these three steps might greatly improve the treatment of head and neck cancer.”
The findings were published in a recent issue of the journal Oncogene.
Specifically, the study shows that an enzyme called “protein kinase C-epsilon” (PKCepsilon) adds energy-packing phosphate groups to the Nanog molecule. This phosphorylation of Nanog stabilizes and activates the molecule.
It also triggers a series of events: Two Nanog molecules bind together, and these are joined by a third “co-activating” molecule called p300. This molecular complex then binds to the promoter region of a gene called Bmi1, an event that increases the expression of the gene. This, in turn, stimulates proliferation of cancer stem cells.
“Our work shows that the PKCepsilon/Nanog/Bmi1 signaling axis is essential to promote head and neck cancer,” Pan says. “And it provides initial evidence that the development of inhibitors that block critical points in this axis might yield a potent collection of targeted anti-cancer therapeutics that could be valuable for the treatment of head and neck cancer.”
(Image: Gray’s Anatomy of the Human Body)
In a paper published in Cell yesterday, scientists from the US and Thailand have, for the first time, successfully produced embryonic stem cells from human skin cells.
That sounds interesting, but what are stem cells and where do they come from?
If you take a limb from a rose tree, and put it in soil, it will grow into a thriving bush.
But you might say: “Plants are special. This won’t work with animals.” Or will it? If you cut off a lizard’s tail, a new tail may grow. A lobster can grow back a lost claw.
There is a special type of flatworm that can be cut in half, again and again hundreds of times, and each half grows back into a full worm.
Similarly, if you cut out half a human liver, it will grow back. The story of Prometheus, whose liver was eaten away by eagles and regrew each day, suggests that the Greeks of ancient times knew about regeneration of organs.
This sort of regeneration is attributed to special cells called “stem cells”.
Reprogramming the workers
Most of our cells are like many professional workers – they are hardened in their ways and can’t manage career changes.
Blood cells carry oxygen or fight disease, muscle cells expand and contract to move us around, nerve cells carry signals, skin cells form a protective layer over our bodies, and structures made up of kidney cells filter our blood.
The cells of most organs or tissues are referred to as “terminally differentiated” cells. They have specialised, and many won’t divide again. If they are damaged or die they will disappear. This is very important.
Although we feel like we grow a lot after we are born, we really only double in size two or three times and most of our cells don’t divide much.
If they did we would be at great risk from cancer – the uncontrolled doubling of cells at the wrong time.
We have a lot of cells and it is important that none of them run out of control.
But some cells can double to renew themselves and can also differentiate and give rise to specialised progeny.
These are the stem cells. We need them to produce new skin to replace damaged skin cells. Similarly, we need them in our guts to replace damaged cells on the surface of our intestines.
Our blood cells also get worn out as they race around our bodies so we have blood stem cells that divide and replace themselves. They also differentiate to form the different types of white and red blood cells we need.
Australian researchers identified stem cells in the breast that can proliferate and form a complete functioning breast. There are also stem cells in the brain and in the heart.
While stem cells tend to be very rare, they exist in many of our organs.
Types of stem cells
The ultimate stem cells are embryonic stem cells.
These cells are found in the inner cell mass of the early embryo and are referred to as “totipotent” since they have the ability to form every cell that is needed in the growing embryo.
They can be extracted from the early embryo and grown in culture dishes.
They can also be genetically modified by the addition of DNA, then injected back into other embryos or into adult animals where find their way into localities that suit them and replace themselves by duplication or differentiate into other cell types that may be needed. For a long time this type of work had been done primarily in laboratory mice.
The techniques in yesterday’s Cell paper involved injecting the nucleus from a human skin cell into a human egg (the nucleus of which has been destroyed) then growing the resulting embryo until the inner cell mass cells could be harvested.
The method may still be controversial because it uses unfertilised eggs, but many people will regard it as preferable to using human embryos. And there are other interesting methods for making stem cells.
Somatic cells to stem cells
It is also possible to convert skin cells, and indeed many different terminally differentiated cells, back into what are called “induced pluripotent stem cells” or iPS cells.
One uses the “magic four” or “OKSM” set of DNA-binding proteins that govern normal stem cell biology:
- Octamer-binding transcription factor 4 (OCT4)
- Kruppel-like factor 4 (KLF4)
- SRY (sex determining region Y)-box 2 (SOX2)
- cellular myelocytomatosis virus-like gene (MYC)
In 2012 Shinya Yamanaka won the Nobel Prize for discovering how to convert normal cells into iPS cells using the OKSM regulators to turn on and off the right genes and convert skin cells into stem cells.
Researchers are continuing to investigate whether iPS cells have the same therapeutic potential as embryo derived stem cells.
It is hoped that stem cells may provide therapies for people suffering from degenerative diseases.
Skin cells could be taken from a patient, converted to stem cells, and then these could be injected back into the damaged organ.
Ideally, they would repopulate the damaged organ with new cells.
So why doesn’t this happen in normal biology? Why aren’t our own heart stem cells busy trying to repair broken hearts?
They may be but our natural supply of stem cells is limited and presumably insufficient to tackle severe disease.
So why don’t we just have more stem cells in our bodies?
The down side of having too many stem cells may be cancer.
Stem cells share a number of features with cancer cells – both are able to self-renew and double without limit.
One theory about cancer holds that the disease most often originates not from terminally differentiated cells but from one of the small number of stem cells in the relevant tissues.
The obvious concern about using stem cells for therapy is that injecting too many could increase the chances that some of these cells would proliferate beyond control, and ultimately give rise to cancer.
Stem cell therapy for regenerative medicine is an exciting idea.
Every day we are learning more about stem cells – how to purify or make them, and how to grow them in culture and direct them down particular pathways to repopulate different organs.
Future research will assess the risks and how effective they can be in experimental systems and ultimately in human patients.
Turning human stem cells into brain cells sheds light on neural development
Medical researchers have manipulated human stem cells into producing types of brain cells known to play important roles in neurodevelopmental disorders such as epilepsy, schizophrenia and autism. The new model cell system allows neuroscientists to investigate normal brain development, as well as to identify specific disruptions in biological signals that may contribute to neuropsychiatric diseases.
Scientists from The Children’s Hospital of Philadelphia and the Sloan-Kettering Institute for Cancer Research led a study team that described their research in the journal Cell Stem Cell, published online today.
The research harnesses human embryonic stem cells (hESCs), which differentiate into a broad range of different cell types. In the current study, the scientists directed the stem cells into becoming cortical interneurons—a class of brain cells that, by releasing the neurotransmitter GABA, controls electrical firing in brain circuits.
"Interneurons act like an orchestra conductor, directing other excitatory brain cells to fire in synchrony," said study co-leader Stewart A. Anderson, M.D., a research psychiatrist at The Children’s Hospital of Philadelphia. "However, when interneurons malfunction, the synchrony is disrupted, and seizures or mental disorders can result."
Anderson and study co-leader Lorenz Studer, M.D., of the Center for Stem Cell Biology at Sloan-Kettering, derived interneurons in a laboratory model that simulates how neurons normally develop in the human forebrain.
"Unlike, say, liver diseases, in which researchers can biopsy a section of a patient’s liver, neuroscientists cannot biopsy a living patient’s brain tissue," said Anderson. Hence it is important to produce a cell culture model of brain tissue for studying neurological diseases. Significantly, the human-derived cells in the current study also "wire up" in circuits with other types of brain cells taken from mice, when cultured together. Those interactions, Anderson added, allowed the study team to observe cell-to-cell signaling that occurs during forebrain development.
In ongoing studies, Anderson explained, he and colleagues are using their cell model to better define molecular events that occur during brain development. By selectively manipulating genes in the interneurons, the researchers seek to better understand how gene abnormalities may disrupt brain circuitry and give rise to particular diseases. Ultimately, those studies could help inform drug development by identifying molecules that could offer therapeutic targets for more effective treatments of neuropsychiatric diseases.
In addition, Anderson’s laboratory is studying interneurons derived from stem cells made from skin samples of patients with chromosome 22q.11.2 deletion syndrome, a genetic disease which has long been studied at The Children’s Hospital of Philadelphia. In this multisystem disorder, about one third of patients have autistic spectrum disorders, and a partially overlapping third of patients develop schizophrenia. Investigating the roles of genes and signaling pathways in their model cells may reveal specific genes that are crucial in those patients with this syndrome who have neurodevelopmental problems.
(Source: eurekalert.org)
Stem Cell Research Could Expand Clinical Use of Regenerative Human Cells
Research led by a biology professor in the School of Science at IUPUI has uncovered a method to produce retinal cells from regenerative human stem cells without the use of animal products, proteins or other foreign substances, which historically have limited the application of stem cells to treat disease and other human developmental disorders.
The study of human induced pluripotent stem cells (hiPSCs) has been pursued vigorously since they were first discovered in 2007 due to their ability to be manipulated into specific cell types. Scientists believe these cells hold considerable potential for cell replacement, disease modeling and pharmacological testing. However, clinical applications have been hindered by the fact that, to date, the cells have required animal products and proteins to grow and differentiate
A research team led by Jason S. Meyer, Ph.D., assistant professor of biology, successfully differentiated hiPSCs in a lab environment—completely through chemical methods—to form neural retinal cell types (including photoreceptors and retinal ganglion cells). Tests have shown the cells function and grow just as efficiently as those cells produced through traditional methods.
“Not only were we able to develop these (hiPSC) cells into retinal cells, but we were able to do so in a system devoid of any animal cells and proteins,” Meyer said. “Since these kinds of stem cells can be generated from a patient’s own cells, there will be nothing the body will recognize as foreign.”
In addition, this research should allow scientists to better reproduce these cells because they know exactly what components were included to spur growth and minimize or eliminate any variations, Meyer said. Furthermore, the cells function in a very similar fashion to human embryonic stem cells, but without controversial or immune rejection issues because they are derived from individual patients.
“This method could have a considerable impact on the treatment of retinal diseases such as age-related macular degeneration and forms of blindness with hereditary factors,” Meyer said. “We hope this will help us understand what goes wrong when diseases arise and that we can use this method as platform for the development of new treatments or drug therapies.”
“We’re talking about bringing stem cells a significant step closer to clinical use,” Meyer added.
The research will be published in the April edition of Stem Cells Translational Medicine.
Transplanted brain cells in monkeys light up personalized therapy
For the first time, scientists have transplanted neural cells derived from a monkey’s skin into its brain and watched the cells develop into several types of mature brain cells, according to the authors of a new study in Cell Reports. After six months, the cells looked entirely normal, and were only detectable because they initially were tagged with a fluorescent protein.
Because the cells were derived from adult cells in each monkey’s skin, the experiment is a proof-of-principle for the concept of personalized medicine, where treatments are designed for each individual.
And since the skin cells were not “foreign” tissue, there were no signs of immune rejection — potentially a major problem with cell transplants. “When you look at the brain, you cannot tell that it is a graft,” says senior author Su-Chun Zhang, a professor of neuroscience at the University of Wisconsin-Madison. “Structurally the host brain looks like a normal brain; the graft can only be seen under the fluorescent microscope.”
Marina Emborg, an associate professor of medical physics at UW-Madison and the lead co-author of the study, says, “This is the first time I saw, in a nonhuman primate, that the transplanted cells were so well integrated, with such a minimal reaction. And after six months, to see no scar, that was the best part.”
The cells were implanted in the monkeys “using a state-of-the-art surgical procedure” guided by an MRI image, says Emborg. The three rhesus monkeys used in the study at the Wisconsin National Primate Research Center had a lesion in a brain region that causes the movement disorder Parkinson’s disease, which afflicts up to 1 million Americans. Parkinson’s is caused by the death of a small number of neurons that make dopamine, a signaling chemical used in the brain.
The transplanted cells came from induced pluripotent stem cells (iPS cells), which can, like embryonic stem cells, develop into virtually any cell in the body. iPS cells, however, derive from adult cells rather than embryos.
In the lab, the iPS cells were converted into neural progenitor cells. These intermediate-stage cells can further specialize into the neurons that carry nerve signals, and the glial cells that perform many support and nutritional functions. This final stage of maturation occurred inside the monkey.
Zhang, who was the first in the world to derive neural cells from embryonic stem cells and then iPS cells, says one key to success was precise control over the development process. “We differentiate the stem cells only into neural cells. It would not work to transplant a cell population contaminated by non-neural cells.”
Another positive sign was the absence of any signs of cancer, says Zhang — a worrisome potential outcome of stem cell transplants. “Their appearance is normal, and we also used antibodies that mark cells that are dividing rapidly, as cancer cells are, and we do not see that. And when you look at what the cells have become, they become neurons with long axons [conducting fibers], as we’d expect. They also produce oligodendrocytes that are helping build insulating myelin sheaths for neurons, as they should. That means they have matured correctly, and are not cancerous.”
The experiment was designed as a proof of principle, says Zhang, who leads a group pioneering the use of iPS cells at the Waisman Center on the UW-Madison campus. The researchers did not transplant enough neurons to replace the dopamine-making cells in the brain, and the animal’s behavior did not improve.
Although promising, the transplant technique is a long way from the clinic, Zhang adds. “Unfortunately, this technique cannot be used to help patients until a number of questions are answered: Can this transplant improve the symptoms? Is it safe? Six months is not long enough… And what are the side effects? You may improve some symptoms, but if that leads to something else, then you have not solved the problem.”
Nonetheless, the new study represents a real step forward that may benefit human patients suffering from several diseases, says Emborg. “By taking cells from the animal and returning them in a new form to the same animal, this is a first step toward personalized medicine.”
The need for treatment is incessant, says Emborg, noting that each year, Parkinson’s is diagnosed in 60,000 patients. “I’m gratified that the Parkinson’s Disease Foundation took a risk as the primary funder for this small study. Now we want to move ahead and see if this leads to a real treatment for this awful disease.”
"It’s really the first-ever transplant of iPS cells from a non-human primate back into the same animal, not just in the brain," says Zhang. "I have not seen anybody transplanting reprogrammed iPS cells into the blood, the pancreas or anywhere else, into the same primate. This proof-of-principle study in primates presents hopes for personalized regenerative medicine."
(Source: news.wisc.edu)
New 3D printing technique could speed up progress towards creation of artificial organs
In the more immediate future it could be used to generate biopsy-like tissue samples for drug testing. The technique relies on an adjustable “microvalve” to build up layers of human embryonic stem cells (hESCs).
Altering the nozzle diameter precisely controls the rate at which cells are dispensed.
Lead scientist Dr Will Shu, from Heriot-Watt University in Edinburgh, said: “We found that the valve-based printing is gentle enough to maintain high stem cell viability, accurate enough to produce spheroids of uniform size, and most importantly, the printed hESCs maintained their pluripotency - the ability to differentiate into any other cell type.”
Embryonic stem cells, which originate from early stage embryos, are blank slates with the potential to become any type of tissue in the body.
The research is reported in the journal Biofabrication.
In the long term, the new printing technique could pave the way for hESCs being incorporated into transplant-ready laboratory-made organs and tissues, said the researchers.
The 3D structures will also enable scientists to create more accurate human tissue models for drug testing.
Cloning technology can produce embryonic stem cells, or cells with ESC properties, containing a patient’s own genetic programming.
Artificial tissue and organs made from such cells could be implanted into the patient from which they are derived without triggering a dangerous immune response.
Jason King, business development manager of stem cell biotech company Roslin Cellab, which took part in the research, said: “Normally laboratory grown cells grow in 2D but some cell types have been printed in 3D. However, up to now, human stem cell cultures have been too sensitive to manipulate in this way.
"This is a scientific development which we hope and believe will have immensely valuable long-term implications for reliable, animal-free, drug testing, and, in the longer term, to provide organs for transplant on demand, without the need for donation and without the problems of immune suppression and potential organ rejection."
Stem Cells May Hold Promise for Lou Gehrig’s Disease (ALS)
Apparent stem cell transplant success in mice may hold promise for people with amyotrophic lateral sclerosis (ALS), or Lou Gehrig’s disease. The results of the study were released today and will be presented at the American Academy of Neurology’s 65th Annual Meeting in San Diego, March 16 to 23, 2013. “There have been remarkable strides in stem cell transplantation when it comes to other diseases, such as cancer and heart failure,” said study author Stefania Corti, MD, PhD, with the University of Milan in Italy and a member of the American Academy of Neurology. “ALS is a fatal, progressive, degenerative disease that currently has no cure. Stem cell transplants may represent a promising avenue for effective cell-based treatment for ALS and other neurodegenerative diseases.”
For the study, mice with an animal model of ALS were injected with human neural stem cells taken from human induced pluripotent stem cells (iPSCs). iPSC are adult cells such as skin cells that have been genetically reprogrammed to an embryonic stem cell-like state. Neurons are a basic building block of the nervous system, which is affected by ALS. After injection, the stem cells migrated to the spinal cord of the mice, matured and multiplied.
The study found that stem cell transplantation significantly extended the lifespan of the mice by 20 days and improved their neuromuscular function by 15 percent. “Our study shows promise for testing stem cell transplantation in human clinical trials,” said Corti.
(Image: ALAMY)
Stem cell materials could boost research into key diseases
Stem cell manufacturing for drug screening and treatments for diseases such as Huntington’s and Parkinson’s could be boosted by a new method of generating stem cells, a study suggests.
Scientists have developed a family of compounds that can support the growth of human embryonic stem cells on a large scale for use in drug testing or treatments.
The new materials, which are water-based gels, act as a tiny scaffold to which cells can cling as they grow. Normally cells must be grown on expensive biological surfaces that can carry pathogens and contaminate cells.
Once cells have multiplied sufficiently for their intended purpose, the gels can be cooled, enabling the stem cells to drop off the scaffold without becoming damaged.
The new approach surpasses existing techniques of separating cells by mechanical or chemical means, which carry a greater risk of damage to cells.
Scientists say the materials could offer a means of enabling the stem cells to be produced in large numbers efficiently and without the risk of inadvertent contamination, facilitating research, drug screening programmes and clinical applications that call for large numbers of cells.
Researchers at the University of Edinburgh developed the new materials by screening hundreds of potential compounds for their ability to support stem cell growth. From a shortlist of four, one has been found to be effective, and researchers say the remaining three show similar potential.
Stem cells provide a powerful tool for screening drugs as they can be used to show the effects of drugs on cells and systems within the body.
The study, published in Nature Communications, was supported by the European Union Framework 7 Grant Funding. The gels are being developed under licence by technology company Ilika.
Dr Paul de Sousa, of the University of Edinburgh’s Scottish Centre for Regenerative Medicine, said: “This development could greatly enhance automated production of embryonic stem cells, which would improve the efficiency and reduce the cost of stem cell manufacturing. We are also looking into whether this work could help develop pluripotent stem cells induced from adult cells.”
Investigators’ Study Hints That Stem Cells Prepare for Maturity Much Earlier Than Anticipated
Unlike less versatile muscle or nerve cells, embryonic stem cells are by definition equipped to assume any cellular role. Scientists call this flexibility “pluripotency,” meaning that as an organism develops, stem cells must be ready at a moment’s notice to activate highly diverse gene expression programs used to turn them into blood, brain, or kidney cells.
Scientists from the lab of Stowers Investigator Ali Shilatifard, Ph.D., report in the December 27, 2012 online issue of Cell that one way cells stay so plastic is by stationing a protein called Ell3 at stretches of DNA known as “enhancers” required to activate a neighboring gene. Their findings suggest that Ell3 parked at the enhancer of a developmentally regulated gene, even one that is silent, primes it for future expression. This finding is significant as many of these same genes are abnormally switched on in cancer.
“We now know that some enhancer misregulation is involved in the pathogenesis of solid and hematological malignances,” says Shilatifard. “But a problem in the field has been how to identify inactive or poised enhancer elements. Our discovery that Ell3 interacts with enhancers in ES cells gives us a hand-hold to identify and to study them.”