Mouse cells exposed to an acidic environment turned into embryonic-like "STAP" cells. These were used to generate an entire fetus.

A coauthor of a disputed study on a new way generating stem cells through exposure to acid and other stresses has asked for its retraction, it was reported Monday.

Teruhiko Wakayama asked for retraction of two papers describing so-called STAP cells, according to the Yomiuri Shimbun. The papers had been published in the Jan. 30 edition of the journal Nature. Other news outlets, including the Wall Street Journal and the Boston Globe, quickly followed up with the call for retraction.

The original announcement gained worldwide attention because it promised an easy way to generate pluripotent stem cells, which act like embryonic stem cells. Simply immersing cells in an acid bath or squeezing them was enough to reprogram them to the embryonic-like state, the scientists reported. The acronym STAP stands for stimulus-triggered acquisition of pluripotency.

However, researchers attempting to replicate the experiment, including those at the Salk Institute and The Scripps Research Institute in La Jolla, have so far reported failure. And errors in the papers, including duplication of images, have caused scientists to question the findings.

The first author of both papers is Haruko Obokata, 30, of the Riken Center for Developmental Biology in Japan. She was hailed as a scientific prodigy after the research was published. Another coauthor, Charles Vacanti, chairman of the Anesthesiology department at Brigham and Womens Hospital in Boston, had previously said the errors were caused by overwork and didn't affect the results.

As recently as Feb. 27, Wakayama said scientists should give replication efforts a year before passing judgment.

But on Monday, Wakayama said the irregularities render the findings questionable.

"Wakayama said images that show pluripotency of STAP cells look almost identical to those used in Obokatas doctoral thesis about pluripotent stem cells that exist in human body," the Yomiuri Shimbun reported.

Wakayama is probably acting out of a sense of duty, said Jeanne Loring, a stem cell scientist at The Scripps Research Institute.

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STAP cells paper coauthor asks for retraction

The recent news of veteran TV journalist Tom Brokaw being diagnosed with multiple myeloma sparked interest in this rare form of cancer. Approximately 20,000 people are diagnosed annually with multiple myeloma cancer of the plasma cells in the bodys bone marrow. These abnormal plasma cells dont produce antibodies, so the immune system cant fight off infections.

Like Brokaw, who is 74, the majority of people diagnosed with multiple myeloma as well as more common blood cancers such as leukemia and lymphoma are older than 65. That means that many of these patients depend on Medicare to pay for their treatment, which often includes a blood or bone marrow transplant (BMT).

Ten years ago, patients older than 55 were commonly excluded from this treatment option. Today, because of medical advances, the Medicare population is the fastest-growing segment of patients in most BMT programs in the United States.

However, because of Medicare coverage restrictions, many patients who need a transplant are unable to receive treatment unless they are in the financial position to pay privately for their care.

The financial burden is even more significant when a transplant requires the use of donated stem cells, often needed for those with blood cancers such as leukemia and lymphoma. Because of a difference in the way that Medicare reimburses hospitals for BMT in comparison with solid organ transplantation, each BMT using donor cells results in a substantial financial loss to the hospital providing care.

The financial loss per transplant case is large enough that it is unsustainable, cannot be offset by private insurance payments and is threatening our ability to continue to deliver this vital therapy to those who need it most.

Our clinical success in finding ways to treat older patients has created an unfortunate, but very real, financial threat to the continued existence of our field. In December, we began a dialogue with our partners at Medicare to remedy this situation and hope that continued discussions will result in a correction of the rate-setting methodology currently used.

We are mindful that BMT is an expensive therapy. There is no question that expert teams and significant resources are required. But it is also a lifesaving therapy. Currently, there are more than 100,000 transplant survivors in the United States. With continuing advances in the use of transplant, we project 250,000 by 2020 and 500,000 by 2030 with a quarter of the survivors being over 60 years old.

These costs would not disappear if this treatment were not available. The costs of providing alternate therapies that do not have the potential to be curative are significant. Older patients deserve continued access to therapies that will provide them with the best chance of enjoying more well-earned years of high-quality life with their families and friends.

This month, the American Society for Blood and Marrow Transplantation (ASBMT) celebrates 20 years since its founding. We represent nearly 2,000 transplant clinicians and health care professionals worldwide. Recently we gathered in Dallas for our annual meeting to share cutting-edge research and knowledge, continuing our quest to be the best in the world at what we do for the sake of our patients.

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Blood, marrow transplants must be kept accessible

The approach involves using enzymes to destroy a gene in the immune cells of people with HIV, thereby increasing resistance to the virus

Scanning electron micrograph of a human T cell from the immune system of a healthy donor. Credit:NIAID/NIH - Wikimedia Commons

A clinical trial has shown that a gene-editing technique can be safe and effective in humans. For the first time, researchers used enzymes called zinc-finger nucleases (ZFNs) to target and destroy a gene in the immune cells of 12 people with HIV, increasing their resistance to the virus. The findings were published March 5 in The New England Journal of Medicine.

This is the first major advance in HIV gene therapy since it was demonstrated that the Berlin patient Timothy Brown was free of HIV, says John Rossi, a molecular biologist at the Beckman Research Institute of the City of Hope National Medical Center in Duarte, California. In 2008, researchers reported thatBrown gained the ability to control his HIV infectionafter they treated him with donor bone-marrow stem cells that carried a mutation in a gene calledCCR5. Most HIV strains use a protein encoded byCCR5as a gateway into the T cells of a hosts immune system. People who carry a mutated version of the gene, including Brown's donor, are resistant to HIV.

But similar treatment isnot feasible for most people with HIV: it is invasive, and the body is likely to attack the donor cells. So a team led by Carl June and Pablo Tebas, immunologists at the University of Pennsylvania in Philadelphia, sought to create the beneficialCCR5 mutation in a persons own cells, using targeted gene editing.

Personalized medicine The researchers drew blood from 12 people with HIV who had been taking antiretroviral drugs to keep the virus in check. After culturing blood cells from each participant, the team used a commercially available ZFN to target theCCR5gene in those cells. The treatment succeeded in disrupting the gene in about 25% of each participants cultured cells; the researchers then transfused all of the cultured cells into the participants. After treatment, all had elevated levels of T cells in their blood, suggesting that the virus was less capable of destroying them.

Six of the 12 participants then stopped their antiretroviral drug therapy, while the team monitored their levels of virus and T cells. Their HIV levels rebounded more slowly than normal, and their T-cell levels remained high for weeks. In short, the presence of HIV seemed to drive the modified immune cells, which lacked a functionalCCR5gene, to proliferate in the body. Researchers suspect that the virus was unable to infect and destroy the altered cells.

They used HIV to help in its own demise, says Paula Cannon, who studies gene therapy at the University of Southern California in Los Angeles. They throw the cells back at it and say, Ha, now what?

Long-term action In this first small trial, the gene-editing approach seemed to be safe: Tebas says that the worst side effect was that the chemical used in the process made the patients bodies smell bad for several days.

The trial isnt the end game, but its an important advance in the direction of this kind of research, says Anthony Fauci, director of the National Institute of Allergy and Infectious Diseases in Bethesda, Maryland. Its more practical and applicable than doing a stem-cell transplant, he says, although it remains to be seen whether it is as effective.

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Gene-Editing Technique Shown to Work as HIV Treatment

The breakthrough might set up another showdown about cloning for therapeutic purposes

OHSU Photos

From Nature magazine

It was hailed some 15 years ago as the great hope for a biomedical revolution: the use of cloning techniques to create perfectly matched tissues that would someday cure ailments ranging from diabetes to Parkinsons disease. Since then, the approach has been enveloped in ethical debate, tainted by fraud and, in recent years, overshadowed by a competing technology. Most groups gave up long ago on the finicky core method production of patient-specific embryonic stem cells (ESCs) from cloning. A quieter debate followed: do we still need therapeutic cloning?

A paper published this week by Shoukhrat Mitalipov, a reproductive biology specialist at the Oregon Health and Science University in Beaverton, and his colleagues is sure to rekindle that debate. Mitalipov and his team have finally created patient-specific ESCs through cloning, and they are keen to prove that the technology is worth pursuing.

Therapeutic cloning, or somatic-cell nuclear transfer (SCNT), begins with the same process used to create Dolly, the famous cloned sheep, in 1996. A donor cell from a body tissue such as skin is fused with an unfertilized egg from which the nucleus has been removed. The egg reprograms the DNA in the donor cell to an embryonic state and divides until it has reached the early, blastocyst stage. The cells are then harvested and cultured to create a stable cell line that is genetically matched to the donor and that can become almost any cell type in the human body.

Many scientists have tried to create human SCNT cell lines; none had succeeded until now. Most infamously, Woo Suk Hwang of Seoul National University in South Korea used hundreds of human eggs to report two successes, in 2004 and 2005. Both turned out to be fabricated. Other researchers made some headway. Mitalipov created SCNT lines in monkeys in 2007. And Dieter Egli, a regenerative medicine specialist at the New York Stem Cell Foundation, successfully produced human SCNT lines, but only when the eggs nucleus was left in the cell. As a result, the cells had abnormal numbers of chromosomes, limiting their use.

Monkeying around Mitalipov and his group began work on their new study last September, using eggs from young donors recruited through a university advertising campaign. In December, after some false starts, cells from four cloned embryos that Mitalipov had engineered began to grow. It looks like colonies, it looks like colonies, he kept thinking. Masahito Tachibana, a fertility specialist from Sendai, Japan, who is finishing a 5-year stint in Mitalipovs laboratory, nervously sectioned the 1-millimetre-wide clumps of cells and transferred them to new culture plates, where they continued to grow evidence of success. Mitalipov cancelled his holiday plans. I was happy to spend Christmas culturing cells, he says. My family understood.

The success came through minor technical tweaks. The researchers used inactivated Sendai virus (known to induce fusion of cells) to unite the egg and body cells, and an electric jolt to activate embryo development. When their first attempts produced six blastocysts but no stable cell lines, they added caffeine, which protects the egg from premature activation.

None of these techniques is new, but the researchers tested them in various combinations in more than 1,000 monkey eggs before moving on to human cells. They made the right improvements to the protocol, says Egli. Its big news. Its convincing. I believe it.

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Patient-Specific Human Embryonic Stem Cells Created by Cloning

14 hours ago This image shows an embryonic stem cell differentiating into a neuronal cell. Credit: Anne Rupprecht/Vetmeduni Vienna

Cells have a metabolism that can be altered according to its function. If cellular metabolism is disturbed, it can lead to disease of the entire organism. Researchers at the Vetmeduni Vienna discovered that the uncoupling proteins UCP2 and UPC4 are involved in different types of cellular metabolism. As a result, cell alterations can now be detected much earlier than was thus far possible. This research work was recently published in the PLOS ONE journal.

UCPs or uncoupling proteins are present in mitochondria, the powerhouse of each cell in the body. The functions of most of the five known UCPs remain mysterious (UCP2-UCP5), whereby only the distinct function for UCP1 has thus far been discovered. UCP1 is responsible for heat production when muscle activity is deficient such as is the case with babies and animals in hibernation. The research team at the Department of Physiology and Biophysics at the University of Veterinary Medicine in Vienna were able to provide a fundamental explanatory concept for the function of UCP2 and UPC4 for the first time. Each of these proteins are involved in different types of cell metabolism.

UCP2 in Stem Cells and Cancer Cells

In earlier studies of immune cells, lead author, Anne Rupprecht, had already shown that UCP2 could be involved in increased metabolism. Embryonic stem cells precisely exhibit such an increased metabolism, as they rapidly and continually divide, just like cancer cells. Rupprecht searched for various UCPs in embryonic stem cells of mice and in effect found UCP2. "Very high amounts of UCP2 even indicated an especially strong increase in metabolism. In other studies UCP2 had also already been detected in cancer cells", according to Rupprecht.

UCP4 in Nerve Cells

In contrast to UCP2, UCP4 is only found in nerve cells. Nerve cells have a completely different metabolism. They seldom divide, unlike stem cells and cancer cells. The research team of Prof. Elena Pohl therefore examined embryonic stem cells that differentiated to nerve cells in culture. On the basis of this model system, the researchers could show that UCP2 is still existent in the quickly reproducing stem cells, yet at the moment of differentiation are replaced by UPC4.

"In our work, we have examined the natural process of cell differentiation from stem cells to neurons. We know that metabolism changes during differentiation. The fact that we found UCP2 in one case and in the other UCP4 proves for the first time that these proteins are associated with varying types of cell metabolism", specified Elena Pohl.

The researchers, for example, found only UCP2 in neuroblastoma cells - nerve cells that have malignant changes. UCP4, the usual protein of nerve cells was not detectable. UPC4 apparently got lost in the changed nerve cells that were on their way to becoming rapidly reproductive cancer cells.

UCPs for early detection of disease

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Hot on the trail of cellular metabolism: Researchers unravel the function of cell proteins

Orange County, CA (PRWEB) March 03, 2014

The top stem cell treatment clinic in Southern California, Telehealth, is now offering several knee pain treatment options for avoiding joint replacement. The regenerative medicine treatments involve either platelet rich plasma therapy, bone marrow derived stem cell injections or blood derived stem cell treatment. Call for more information and scheduling call (888) 828-4575. The treatments may be completely or partially covered by insurance.

Although knee replacement procedures have been exceptionally successful for reducing one's pain and improving functional abilities, there are some risks associated with the procedure, along with the fact they are not meant to last forever. Unlike conventional nonoperative treatments, such as steroid injections, regenerative medicine treatments maintain the ability to repair and regenerate arthritic tissue as opposed to simply masking pain.

The Board Certified doctors at Telehealth have extensive experience and regenerative medicine therapies for degenerative arthritis of the knee. Stem cell therapy for arthritis has been shown in several small published studies to provide excellent pain relief and maintain cartilage in the knee.

All of the treatments provided are low-risk and outpatient. They involve blood or bone marrow from the patient him or herself, which reduces the risk profile even more.

Telehealth Medical Group has two locations in Southern California. One is right in Santa Ana, while the other is in Upland. Appointments are readily available. Call for more information and scheduling to (888) 828-4575.

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Southern California Stem Cell Clinic, Telehealth, Now Offering Several Knee Treatment Options to Avoid Joint Replacement

Researchers in Bern have discovered that, during a viral infection, immune cells control the blood stem cells in the bone marrow and therefore also the body's own defenses. The findings could allow for new forms of therapy, such as for bone marrow diseases like leukemia.

During a viral infection, the body needs various defense mechanisms -- amongst other things, a large number of white blood cells (leukocytes) must be produced in the bone marrow within a short period of time. In the bone marrow, stem cells are responsible for this task: the blood stem cells. In addition to white blood cells, blood stem cells also produce red blood cells and platelets.

The blood stem cells are located in specialized niches in the bone marrow and are surrounded by specialized niche cells. During an infection, the blood stem cells must complete two tasks: they must first recognise that more blood cells have to be produced and, secondly, they must recognise what kind of.

Now, for the first time, researchers at the Department of Medical Oncology at the University of Bern and Bern University Hospital headed by Prof. Adrian Ochsenbein have investigated how the blood stem cells in the bone marrow are regulated by the immune system's so-called T killer cells during a viral infection. As this regulation mechanism mediated by the immune system also plays an important role in other diseases such as leukemia, these findings could lead to novel therapeutic approaches. The study is being published in the peer-reviewed journal "Cell Stem Cell" today.

T Killer cells trigger defenses

One function of T killer cells is to "patrol" in the blood and remove pathogen-infected cells. However, they also interact with the blood stem cells in the bone marrow. The oncologists in Bern were able to show that messenger substances secreted by the T killer cells modulate the niche cells. In turn, the niche cells control the production and also the differentiation of the blood stem cells.

This mechanism is important in order to fight pathogens such as viruses or bacteria. However, various forms of the bone marrow disease leukemia are caused by a malignant transformation of exactly these blood stem cells. This leads to the formation of so-called leukemia stem cells. In both cases, the mechanisms are similar: the "good" mechanism regulates healthy blood stem cells during an infection, whilst the "bad" one leads to the multiplication of leukemia stem cells. This in turn leads to a progression of the leukemia.

This similarity has already been investigated in a previous project by the same group of researchers. "We hope that this will enable us to better understand and fight infectious diseases as well as bone marrow diseases such as leukemia," says Carsten Riether from the Department of Clinical Research at the University of Bern and the Department of Medical Oncology at Bern University Hospital and the University of Bern.

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The above story is based on materials provided by University of Bern. Note: Materials may be edited for content and length.

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Immune cells regulate blood stem cells, research shows

On a Saturday last September, Be the Match Foundation sponsored a 5-kilometer walk and run in Creve Coeur Park to promote donor awareness. The foundation is an international bone marrow registry, and it coordinates marrow and stem cell transplants that are used to treat blood disorders.

Mark Pearl was at the event. Two of his three kids were born with a rare blood disorder called Fanconi anemia. Alexandra was diagnosed on Christmas Day 2000. She was 5. Her younger brother, Matthew, was diagnosed shortly thereafter. A marrow donor in Sweden was quickly found for Alexandra, but no matches were found for Matthew.

Mark and his wife, Diane, began organizing donor drives. Its easy to register as a donor. A couple of swabs on the inside of a cheek to collect DNA is all that is required. At their first drive in February 2001, they registered more than 4,000 potential donors. No matches. Over the next five and a half years, they organized more than 1,000 drives and registered more than 100,000 potential donors.

A donor was eventually found in North Carolina. As is almost always the case, the donor registered at someone elses drive. Matthew received his transplant in 2006.

He and his sister are fine.

Also at the event in Creve Coeur was Brian Jakubeck. He did not know Mark, but he had registered as a potential donor at one of the drives the Pearls had organized for Matthew. One of the last drives, actually.

How did that happen? Mark has season tickets for the Rams and sits next to Ted Cassimatis, who is a college friend of Brians brother. So as the Pearls reached out well beyond their own circle of friends, Ted sent out a mass email to his friends, and that email reached Brian. He and his wife, Kathy, registered as potential donors at a drive in May 2006.

Sometime later, Brian heard the good news from Ted that a donor had been found for his friends son.

Several years passed. In August 2012, Brian heard from Be the Match. He appeared to be a match. Would he agree to have some blood samples taken to confirm that he was a match? Sure, he said.

The results were positive. He was a match. He had more tests shortly before Christmas, and in January of last year, he went to St. Louis University Hospital and gave his stem cells. This was done in a process called apheresis. It is similar to giving plasma or platelets. The blood goes through an IV, passes through a machine that collects the stem cells, and then is returned through another IV. Its painless, but takes about six hours.

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McClellan: Bone marrow registry drives often pay it forward

Cambridge News Follow us on

Monday 24 Feb 2014 2:43 PM

Written byELEANOR DICKINSON

Sufferers of serious brain diseases could one day be helped by stem cell treatments , according to scientists at Cambridge University.

Scientists at the University hope to be able to use the regenerative power of stem cells to treat major brain conditions such as Parkinsons and Huntingtons disease.

Their findings are expected to be revealed at the Cambridge Festival of Science next month.

Robin Franklin, the newly appointed Professor of Stem Cell Medicine, will be discussing his research into central nervous system regeneration and the possibility of treating multiple sclerosis.

He said: The brain, although capable of unmatched feats of adaptability, is generally considered to be an organ that is very poor at mending itself after injury.

However, one particular type of brain cell, called the oligodendrocyte the cell that makes the myelin wrapping around nerve fibres can be regenerated when lost in disease by the brains own stem cells.

By studying in the laboratory how brain stem cells generate new oligodendrocytes it has been possible to identify ways in which this important regenerative process might be achieved in the clinic, offering the

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Stem cells to fight brain diseases say Cambridge scientists

PUBLIC RELEASE DATE:

20-Feb-2014

Contact: Deborah Williams-Hedges debwms@caltech.edu 626-395-3227 California Institute of Technology

In the battle against infection, immune cells are the body's offense and defensesome cells go on the attack while others block invading pathogens. It has long been known that a population of blood stem cells that resides in the bone marrow generates all of these immune cells. But most scientists have believed that blood stem cells participate in battles against infection in a delayed way, replenishing immune cells on the front line only after they become depleted.

Now, using a novel microfluidic technique, researchers at Caltech have shown that these stem cells might be more actively involved, sensing danger signals directly and quickly producing new immune cells to join the fight.

"It has been most people's belief that the bone marrow has the function of making these cells but that the response to infection is something that happens locally, at the infection site," says David Baltimore, president emeritus and the Robert Andrews Millikan Professor of Biology at Caltech. "We've shown that these bone marrow cells themselves are sensitive to infection-related molecules and that they respond very rapidly. So the bone marrow is actually set up to respond to infection."

The study, led by Jimmy Zhao, a graduate student in the UCLA-Caltech Medical Scientist Training Program, will appear in the April 3 issue of the journal Cell Stem Cell.

In the work, the researchers show that blood stem cells have all the components needed to detect an invasion and to mount an inflammatory response. They show, as others have previously, that these cells have on their surface a type of receptor called a toll-like receptor. The researchers then identify an entire internal response pathway that can translate activation of those receptors by infection-related molecules, or danger signals, into the production of cytokines, signaling molecules that can crank up immune-cell production. Interestingly, they show for the first time that the transcription factor NF-B, known to be the central organizer of the immune response to infection, is part of that response pathway.

To examine what happens to a blood stem cell once it is activated by a danger signal, the Baltimore lab teamed up with chemists from the lab of James Heath, the Elizabeth W. Gilloon Professor and professor of chemistry at Caltech. They devised a microfluidic chipprinted in flexible silicon on a glass slide, complete with input and output ports, control valves, and thousands of tiny wellsthat would enable single-cell analysis. At the bottom of each well, they attached DNA molecules in strips and introduced a flow of antibodiespathogen-targeting proteins of the immune systemthat had complementary DNA. They then added the stem cells along with infection-related molecules and incubated the whole sample. Since the antibodies were selected based on their ability to bind to certain cytokines, they specifically captured any of those cytokines released by the cells after activation. When the researchers added a secondary antibody and a dye, the cytokines lit up. "They all light up the same color, but you can tell which is which because you've attached the DNA in an orderly fashion," explains Baltimore. "So you've got both visualization and localization that tells you which molecule was secreted." In this way, they were able to measure, for example, that the cytokine IL-6 was secreted most frequentlyby 21.9 percent of the cells tested.

"The experimental challenges here were significantwe needed to isolate what are actually quite rare cells, and then measure the levels of a dozen secreted proteins from each of those cells," says Heath. "The end result was sort of like putting on a new pair of glasseswe were able to observe functional properties of these stem cells that were totally unexpected."

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A changing view of bone marrow cells

7 hours ago Blood stem cell cultures: Blood stem cells from colonies (cell clusters) in vitro consisting of different blood cells. Nine blood stem cell colonies are illustrated in the image, which have developed into differentiated cell types, particularly into white blood cells (leukocytes).Credit: Department of Clinical Research of the University of Bern, Tumor-Immunology research group

Researchers in Bern, Germany, have discovered that, during a viral infection, immune cells control the blood stem cells in the bone marrow and therefore also the body's own defences. The findings could allow for new forms of therapy, such as for bone marrow diseases like leukaemia.

During a viral infection, the body needs various defence mechanisms amongst other things, a large number of white blood cells (leukocytes) must be produced in the bone marrow within a short period of time. In the bone marrow, stem cells are responsible for this task: the blood stem cells. In addition to white blood cells, blood stem cells also produce red blood cells and platelets.

The blood stem cells are located in specialized niches in the bone marrow and are surrounded by specialized niche cells. During an infection, the blood stem cells must complete two tasks: they must first recognise that more blood cells have to be produced and, secondly, they must recognise what kind of.

Now, for the first time, researchers at the Department of Medical Oncology at the University of Bern and Bern University Hospital headed by Prof. Adrian Ochsenbein have investigated how the blood stem cells in the bone marrow are regulated by the immune system's so-called T killer cells during a viral infection. As this regulation mechanism mediated by the immune system also plays an important role in other diseases such as leukaemia, these findings could lead to novel therapeutic approaches. The study is being published in the peer-reviewed journal Cell Stem Cell today.

T Killer cells trigger defences

One function of T killer cells is to "patrol" in the blood and remove pathogen-infected cells. However, they also interact with the blood stem cells in the bone marrow. The oncologists in Bern were able to show that messenger substances secreted by the T killer cells modulate the niche cells. In turn, the niche cells control the production and also the differentiation of the blood stem cells.

This mechanism is important in order to fight pathogens such as viruses or bacteria. However, various forms of the bone marrow disease leukaemia are caused by a malignant transformation of exactly these blood stem cells. This leads to the formation of so-called leukaemia stem cells. In both cases, the mechanisms are similar: the "good" mechanism regulates healthy blood stem cells during an infection, whilst the "bad" one leads to the multiplication of leukaemia stem cells. This in turn leads to a progression of the leukaemia.

This similarity has already been investigated in a previous project by the same group of researchers. "We hope that this will enable us to better understand and fight infectious diseases as well as bone marrow diseases such as leukaemia," says Carsten Riether from the Department of Clinical Research at the University of Bern and the Department of Medical Oncology at Bern University Hospital and the University of Bern.

Explore further: New discovery on early immune system development

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Immune cells regulate blood stem cells

Freeport, The Bahamas (PRWEB) February 21, 2014

Okyanos Heart Institute, whose mission it is to bring a new standard of care and a better quality of life to patients with coronary artery disease using adult stem cell therapy, announces CEO Matt Feshbach will present at the STEMSO Conference. He will join a panel to discuss the opportunities available through the new stem cell research and Therapy Act. The conference will be held at the Grand Lucayan Resort in Freeport, Grand Bahamas, February 19-22, 2014. The panel discussion will be Friday, February 21 from 8:45 9:45 a.m.

The conference, titled Bridging the Gap: Research to Point of Care, brings together medical scientists, clinicians, regulatory experts, and investors to discuss progress in the field of research and clinical protocols and the process of taking promising therapies to fight chronic disease to market in a responsible manner.

Friday opening remarks will be delivered by Ian Rolle, President of Grand Bahama Port Authority from 8:30 a.m. to 8:45 a.m. followed by the panel presentation until 9:45 a.m. which, in addition to Rolle will include Feshbach, Mitchell Fuerst, Esq., managing partner, Fuerst, Ittleman, David and Joseph. The panel will be moderated by Arthur K. Parris, Jr. of Parris Whittaker.

"With the passing of the Bahamas Stem Cell Research and Therapy Act, which requires high standards of patient safety and care, we believe the Bahamas is an ideal location to bring internationally-approved, adult stem cell technology to patients with unmet medical needs such as chronic coronary artery disease (CAD), says Feshbach. I am pleased to discuss the opportunities available in the Bahamas with investors, doctors and other stakeholders interested in making the Bahamas a world-class destination for adult stem cell therapy."

The STEMSO 2014 Conference in Freeport, Grand Bahama poses a unique opportunity for medical organizations which focus on adult stem cell-based medical treatments, states Douglas Hammond, president of STEMSO. This conference will provide companies looking to expand their research or clinical practices to offshore locations many good reasons to choose the Bahamas. Those attending will be able to network and view the most advanced research and clinical protocols utilizing autologous and allogeneic stem cells in the world today.

The complete agenda can be found on the organizations website at http://www.stemso.org. Other speakers include stem cell researchers, scientists and practitioners from around the world with leading discoveries in the field, and investors in the healthcare space.

Registration is open for attending and exhibiting on STEMSOs website.

ABOUT OKYANOS HEART INSTITUTE: (Oh key AH nos) Based in Freeport, The Bahamas, Okyanos Heart Institutes mission is to bring a new standard of care and a better quality of life to patients with coronary artery disease using cardiac stem cell therapy. Okyanos adheres to U.S. surgical center standards and is led by Chief Medical Officer Howard T. Walpole Jr., M.D., M.B.A., F.A.C.C., F.S.C.A.I. Okyanos Treatment utilizes a unique blend of stem and regenerative cells derived from ones own adipose (fat) tissue. The cells, when placed into the heart via a minimally-invasive procedure, can stimulate the growth of new blood vessels, a process known as angiogenesis. Angiogenesis facilitates blood flow in the heart, which supports intake and use of oxygen (as demonstrated in rigorous clinical trials such as the PRECISE trial). The literary name Okyanos, the Greek god of rivers, symbolizes restoration of blood flow. For more information, go to http://www.okyanos.com/.

NEW MEDIA CONTENT: Okyanos LinkedIn Page: http://www.linkedin.com/company/okyanos-heart-institute Okyanos Facebook Page: https://www.facebook.com/OKYANOS Okyanos Twitter Page: https://twitter.com/#!/OkyanosHeart Okyanos Google+ Page: https://plus.google.com/+Okyanos/posts Okyanos You Tube Physician Channel: http://www.youtube.com/user/okyanosforphysicians

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Okyanos Heart Institute CEO Matt Feshbach to Speak on Panel at International Stem Cell Society Global Conference

A new study describes the complexity of the new T cell repertoire following immune-depleting therapy to treat multiple sclerosis, improving our understanding of immune tolerance and clinical outcomes.

In the Immune Tolerance Network's (ITN) HALT-MS study, 24 patients with relapsing, remitting multiple sclerosis received high-dose immunosuppression followed by a transplant of their own stem cells, called an autologous stem cell transplant, to potentially reprogram the immune system so that it stops attacking the brain and spinal cord. Data published in the Journal of Clinical Investigation quantified and characterized T cell populations following this aggressive regimen to understand how the reconstituting immune system is related to patient outcomes.

ITN investigators used a high-throughput, deep-sequencing technology (Adaptive Biotechnologies, ImmunoSEQTM Platform) to analyze the T cell receptor (TCR) sequences in CD4+ and CD8+ cells to compare the repertoire at baseline pre-transplant, two months post-transplant and 12 months post-transplant.

Using this approach, alongside conventional flow cytometry, the investigators found that CD4+ and CD8+ lymphocytes exhibit different reconstitution patterns following transplantation. The scientists observed that the dominant CD8+ T cell clones present at baseline were expanded at 12 months post-transplant, suggesting these clones were not effectively eradicated during treatment. In contrast, the dominant CD4+ T cell clones present at baseline were undetectable at 12 months, and the reconstituted CD4+ T cell repertoire was predominantly composed of new clones.

The results also suggest the possibility that differences in repertoire diversity early in the reconstitution process might be associated with clinical outcomes. Nineteen patients who responded to treatment had a more diverse repertoire two months following transplant compared to four patients who did not respond. Despite the low number of non-responders, these comparisons approached statistical significance and point to the possibility that complexity in the T cell compartment may be important for establishing immune tolerance.

This is one of the first studies to quantitatively compare the baseline T cell repertoire with the reconstituted repertoire following autologous stem cell transplant, and provides a previously unseen in-depth analysis of how the immune system reconstitutes itself following immune-depleting therapy.

About The Immune Tolerance Network

The Immune Tolerance Network (ITN) is a research consortium sponsored by the National Institute of Allergy and Infectious Diseases, part of the National Institutes of Health. The ITN develops and conducts clinical and mechanistic studies of immune tolerance therapies designed to prevent disease-causing immune responses, without compromising the natural protective properties of the immune system. Visit http://www.immunetolerance.org for more information.

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The above story is based on materials provided by Immune Tolerance Network. Note: Materials may be edited for content and length.

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Deep TCR sequencing reveals extensive renewal of the T cell repertoire following autologous stem cell transplant in MS

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PITTSBURGH (KDKA) After injuries from gymnastics and dance when she was younger, Linda Morning-Starpoole was having terrible knee pain.

Sitting and standing up and getting up and moving, Linda said.

The news from her orthopedic surgeon was not encouraging.

I was sent off with a prescription, and basically said, take this, and when it gets so bad, well take out your knees. And that was really upsetting to me. It was such an ugly picture that was painted for my future, Linda said.

Traditional treatment might involve steroid injections, physical therapy, and joint replacement.

But Linda wanted an alternative. When she first heard about using stem cell injections, she was very intrigued.

The thought of me healing me with my own self is what sold me on the procedure, Linda said.

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Stem Cells Being Used To Treat Knee, Joint Pain

ALAMEDA, Calif.--(BUSINESS WIRE)--BioTime, Inc. (NYSE MKT: BTX), a biotechnology company that develops and markets products in the field of regenerative medicine, today announced that Chief Executive Officer Michael D. West, PhD will present at the 9th Annual Stem Cell Summit in New York. Dr. West will speak in the session Disrupting the Pharma Model with Allogeneic Stem Cell Therapies on February 18, 2014, starting at 9:05 a.m. EST.

Dr. West will discuss the potential comparative advantages of treating disease with BioTime's PureStem-based therapeutics compared to traditional small molecule pharmaceuticals and BioTime's product development strategy. The presentation will be made available on BioTime's website at http://www.biotimeinc.com.

About BioTime, Inc.

BioTime is a biotechnology company engaged in research and product development in the field of regenerative medicine. Regenerative medicine refers to therapies based on stem cell technology that are designed to rebuild cell and tissue function lost due to degenerative disease or injury. BioTimes focus is on pluripotent stem cell technology based on human embryonic stem (hES) cells and induced pluripotent stem (iPS) cells. hES and iPS cells provide a means of manufacturing every cell type in the human body and therefore show considerable promise for the development of a number of new therapeutic products. BioTimes therapeutic and research products include a wide array of proprietary PureStem progenitors, HyStem hydrogels, culture media, and differentiation kits. BioTime is developing Renevia (a HyStem product) as a biocompatible, implantable hyaluronan and collagen-based matrix for cell delivery in human clinical applications. In addition, BioTime has developed Hextend, a blood plasma volume expander for use in surgery, emergency trauma treatment and other applications. Hextend is manufactured and distributed in the U.S. by Hospira, Inc. and in South Korea by CJ CheilJedang Corporation under exclusive licensing agreements.

BioTime is also developing stem cell and other products for research, therapeutic, and diagnostic use through its subsidiaries:

Asterias Biotherapeutics, Inc. is a new subsidiary which has acquired the stem cell assets of Geron Corporation, including patents and other intellectual property, biological materials, reagents and equipment for the development of new therapeutic products for regenerative medicine.

OncoCyte Corporation is developing products and technologies to diagnose and treat cancer.

Cell Cure Neurosciences Ltd. (Cell Cure Neurosciences) is an Israel-based biotechnology company focused on developing stem cell-based therapies for retinal and neurological disorders, including the development of retinal pigment epithelial cells for the treatment of macular degeneration, and treatments for multiple sclerosis.

LifeMap Sciences, Inc. (LifeMap Sciences) markets, sells and distributes GeneCards, the leading human gene database, as part of an integrated database suite that also includes the LifeMap Discovery database of embryonic development, stem cell research and regenerative medicine, and MalaCards, the human disease database.

ES Cell International Pte Ltd., a Singapore private limited company, developed clinical and research grade hES cell lines and plans to market those cell lines and other BioTime research products in over-seas markets as part of BioTimes ESI BIO Division.

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BioTime CEO Dr. Michael West to Present at 9th Annual Stem Cell Summit

stem cell research stem cell therapy marrow transplant and lung repair stem cell transplant
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stem cell research stem cell therapy marrow transplant and lung repair stem cell transplant - Video

PUBLIC RELEASE DATE:

13-Feb-2014

Contact: Joseph Caputo joseph_caputo@harvard.edu 617-496-1491 Harvard University

Harvard stem cell scientists have a new theory for how stem cells decide whether to become liver or pancreatic cells during development. A cell's fate, the researchers found, is determined by the nearby presence of prostaglandin E2, a messenger molecule best known for its role in inflammation and pain. The discovery, published in the journal Developmental Cell, could potentially make liver and pancreas cells easier to generate both in the lab and for future cell therapies.

Wolfram Goessling, MD, PhD, and Trista North, PhD, both principal faculty members of the Harvard Stem Cell Institute (HSCI), identified a gradient of prostaglandin E2 in the region of zebrafish embryos where stem cells differentiate into the internal organs. Experiments conducted by postdoctoral fellow Sahar Nissim, MD, PhD, in the Goessling lab showed how liver-or-pancreas-fated stem cells have specific receptors on their membranes to detect the amount of prostaglandin E2 hormone present and coerce the cell into differentiating into a specific organ type.

"Cells that see more prostaglandin become liver and the cells that see less prostaglandin become pancreas," said Goessling, a Harvard Medical School Assistant Professor of Medicine at Brigham and Women's Hospital and Dana-Farber Cancer Institute. "This is the first time that prostaglandin is being reported as a factor that can lead this fate switch and essentially instruct what kind of identity a cell is going to be."

The researchers next collaborated with the laboratory of HSCI Affiliated Faculty member Richard Maas, MD, PhD, Director of the Genetics Division at Brigham and Women's Hospital, to see whether prostaglandin E2 has a similar function in mammals. Richard Sherwood, PhD, a former graduate student of HSCI Co-director Doug Melton, was successfully able to instruct mouse stem cells to become either liver or pancreas cells by exposing them to different amounts of the hormone. Other experiments showed that prostaglandin E2 could also enhance liver growth and regeneration of liver cells.

Goessling and his research partner North, a Harvard Medical School Assistant Professor of Pathology at Beth Israel Deaconess Hospital, first became intrigued by prostaglandin E2 in 2005, as postdoctoral fellows in the lab of HSCI Executive Committee Chair Leonard Zon, MD. It caught their attention during a chemical screen exposing 2,500 known drugs to zebrafish embryos to find any that could amplify blood stem cell populations. Prostaglandin E2 was the most successful hit the first molecule discovered in any system to have such an effectand recently successfully completed Phase 1b clinical trials as a therapeutic to improve cord blood transplants.

"Prostaglandin might be a master regulator of cell growth in different organs," Goessling said. "It's used in cord blood, as we have shown, it works in the liver, and who knows what other organs might be affected by it."

With evidence of how prostaglandin E2 works in the liver, the researchers next want to calibrate how it can be used in the laboratory to instruct induced pluripotent stem cellsmature cells that have been reprogrammed into a stem-like stateto become liver or pancreas cells. The scientists predict that such a protocol could benefit patients who need liver cells for transplantation or who have had organ injury.

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Harvard scientists find cell fate switch that decides liver, or pancreas?

Instead of being shut out of a $40 million stem cell grant awarded to Stanford University, San Diego researchers will be major partners, say the scientists who lead the project.

Joseph Ecker of the Salk Institute and Michael Snyder of Stanford say that under an informal arrangement, they will jointly allocate money granted from the California Institute for Regenerative Medicine for a new center on stem cell genomics. CIRM is responsible for distributing $3 billion in state bond money to turn stem cell research into disease treatments.

Joseph Ecker, a Salk Institute researcher and co-principal investigator of the new center for stem cell genomics created with a $40 million grant from the California Institute for Regenerative Medicine. / Salk Institute

Genomics, the study of the complete set of genes and DNA in an organism, is necessary to help understand how stem cells function. Stem cells contain virtually the same genes as adult cells but differ in which genes are turned on and off. The signals that cause stem cells to differentiate are not well understood.

By analyzing the genomes of stem cells, researchers expect to better understand how stem cells can produce more stem cells, and which genes are involved in directing stem cells down the path to becoming adult cells of interest, such as islet cells that make insulin, bone or retinal cells.

Last months decision had been characterized as a big win for Stanford, because the university had been awarded the grant over competing applications, including one from The Scripps Research Institute and San Diego DNA sequencing giant Illumina.

Ecker and Snyder said that belief is a misunderstanding, because their proposal is a cooperative venture involving extensive participation from San Diego biomedical scientists.

Michael Snyder, a Stanford University researcher and co-principal investigator of the new center for stem cell genomics created with a $40 million grant from the California Institute for Regenerative Medicine. / Stanford University

The leadership issue is confusing, because CIRM requires a single institute to be listed as the lead on funding proposals, even if the institutions are sharing leadership, Ecker said by email. In fact, Mike Snyder and I, by proxy Stanford and Salk, are equal partners. Responsibility for administration of the center will fall equally to Stanford and Salk researchers, as well as strategic steering and decision-making on what projects to pursue.

Besides Salk and Stanford, partners are UC San Diego, the Ludwig Institute for Cancer Research, the J. Craig Venter Institute, The Scripps Research Institute and UC Santa Cruz. The Howard Hughes Medical Institute also plays a role.

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Salk, Stanford equal partners in stem cell genomics program

Poets and physicians know that a scarred heart cannot beat the way it used to, but the science of reprogramming cells offers hope--for the physical heart, at least.

A team of University of Michigan biomedical engineers has turned cells common in scar tissue into colonies of beating heart cells. Their findings could advance the path toward regenerating tissue that's been damaged in a heart attack.

Previous work in direct reprogramming, jumping straight from a cell type involved in scarring to heart muscle cells, has a low success rate. But Andrew Putnam, an associate professor of biomedical engineering and head of the Cell Signaling in Engineered Tissues Lab, thinks he knows at least one of the missing factors for better reprogramming.

"Many reprogramming studies don't consider the environment that the cells are in -- they don't consider anything other than the genes," he said. "The environment can dictate the expression of those genes."

To explore how the cells' surroundings might improve the efficiency of reprogramming, Yen Peng Kong, a post-doctoral researcher in the lab, attempted to turn scarring cells, or fibroblasts, into heart muscle cells while growing them in gels of varying stiffness. He and his colleagues compared a soft commercial gel with medium-stiffness fibrin, made of the proteins that link with platelets to form blood clots, and with high-stiffness collagen, made of structural proteins.

The fibroblasts came from mouse embryos. To begin the conversion to heart muscle cells, Kong infected the fibroblasts with a specially designed virus that carried mouse transgenes -- genes expressed by stem cells.

Fooled into stem cell behavior, the fibroblasts transformed themselves into stem-cell-like progenitor cells. This transition, which would be skipped in direct reprogramming, encouraged the cells to divide and grow into colonies rather than remaining as lone rangers. The tighter community might have helped to ease the next transition, since naturally developing heart muscle cells are also close with their neighbors.

After seven days, Kong changed the mixture used to feed the cells, adding a protein that encourages the growth of heart tissue. This helped push the cells toward adopting the heart muscle identity. A few days later, some of the colonies were contracting spontaneously, marking themselves out as heart muscle colonies.

The transition was particularly successful in the fibrin and fibrin-collagen mixes, which saw as many as half of the colonies converting to heart muscle.

The team has yet to discover exactly what it is about fibrin that makes it better for supporting heart muscle cell. While most materials either stretch or weaken under strain, fibrin gets harder. Putnam wonders whether the fibrin was successful because heart muscles expect a material that toughens up when they contract.

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Help for a scarred heart: Scarring cells turned to beating ...

Poway, California (PRWEB) February 13, 2014

The leading Regenerative Veterinary Medicine company, Vet-Stem, Inc., and Americas best-loved pet insurer, Petplan, are working together to bring stem cell therapy and other regenerative cell therapies to pets nationwide. Stem cell therapy by Vet-Stem has been available for pets like dogs and cats for the last decade and covered by Petplan since 2010.

Founded in 2003 by Chris and Natasha Ashton, Petplan was recently named to Forbes magazines annual ranking of Americas Most Promising Companies for the second year in a row, and is rated one of the top pet insurance companies by Consumer Advocate and Canine Journal. Petplan proudly offers life-long coverage for hereditary and chronic conditions as well as alternative treatments, like stem cell therapy, as standard.

Our core value is that pets come first, and that starts with our comprehensive plans. So, were excited to see so many of our policyholders start to take advantage of cutting-edge treatments like Vet-Stem Regenerative Cell Therapy. Our team thrives on being able to provide coverage for the best and most up-to-date treatment modalities for the pets in our Petplan family, so hearing great stories about stem cell therapy from our policyholders is a real boost for us! - Dr. Jules Benson, Vice President of Veterinary Services at Petplan

Current uses of stem cell therapy are treating the pain and inflammation from arthritis and to repair orthopedic injuries. According to veterinarians, greater than 80% of dogs showed an improved quality of life after stem cell therapy. At 90 days post-treatment, more than 33% of dogs discontinued use of non-steroidal anti-inflammatory drugs (NSAIDs) completely, with an additional 28% decreasing their usage.

I started Vet-Stem in order to help horses with career-ending injuries to their tendons and ligaments, but so many more animals have been saved from a life of pain or even from euthanasia. I feel privileged and excited to be a part of this therapy that has changed how veterinary medicine is practiced, as well as contributing to changes in human medicine, - Robert Harman, DVM, CEO, Vet-Stem, Inc.

About Vet-Stem, Inc. Vet-Stem, Inc. was formed in 2002 to bring regenerative medicine to the veterinary profession. The privately held company is working to develop therapies in veterinary medicine that apply regenerative technologies while utilizing the natural healing properties inherent in all animals. As the first company in the United States to provide an adipose-derived stem cell service to veterinarians for their patients, Vet-Stem, Inc. pioneered the use of regenerative stem cells in veterinary medicine. The company holds exclusive licenses to over 50 patents including world-wide veterinary rights for use of adipose derived stem cells. In the last decade over 10,000 animals have been treated using Vet-Stem, Inc.s services, and Vet-Stem is actively investigating stem cell therapy for immune-mediated and inflammatory disease, as well as organ disease and failure. For more on Vet-Stem, Inc. and Veterinary Regenerative Medicine visit http://www.vet-stem.com or call 858-748-2004.

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Vet-Stem, Inc. and Petplan Work Together in the New Year to Bring Regenerative Cell Therapies to Pets