IPS Cell Therapy

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“Wide-ranging applications for pluripotent stem cells”

February 2nd, 2012

The Hindu Shinya Yamanaka, Centre for iPS Cell Research and Application, Japan delivering a lecture in Chennai on Thursday. Photo: V. Ganesan

Many more diseases can be targeted, says expert

While applications of induced pluripotent stem cells in stem cell therapy may be limited to a few diseases, its applications in drug discovery are wide-ranging, and many more diseases can be targeted, Shinya Yamanaka, Director, Centre for iPS Cell Research and Application, Japan, has said.

The Japanese scientist, whose breakthrough was the creation of embryonic-like stem cells from adult skin cells, believes that the best chance for stem cell therapy lies in offering hope to those suffering from a few conditions, among them, macular disease, Type 1 Diabetes, and spinal cord injuries.

On the other hand, there were multiple possibilities with drug discovery for a range of diseases, and Prof. Yamanaka was hopeful that more scientists would continue to use iPS for studying this potential.

He currently serves as the Director of the Center for iPS Cell Research and Application and as Professor at the Institute for Frontier Medical Sciences at Kyoto University. He is also a Senior Investigator at the University of California, San Francisco (UCSF) - affiliated J. David Gladstone Institutes.

An invited speaker of the CellPress-TNQ India Distinguished Lectureship Series, co-sponsored by Cell Press and TNQ Books and Journals, Prof. Yamanaka spoke to a Chennai audience on Tuesday evening about those “immortal” cells, that he originally thought would take “forever” to create, but actually took only six years.

“My fixed vision for my research team was to re-programme adult cells to function like embryonic-like stem cells. I knew it could be done, but just didn't know how to do it,” Prof. Yamanaka said.

Embryonic stem cells are important because they are pluripotent, or possess the ability to differentiate into any other type of cell, and are capable of rapid proliferation. However, despite the immense possibilities of that, embryonic cells are a mixed blessing: there are issues with post-transplant rejection (since they cannot be used from a patient's own cells), and many countries of the world do not allow the use of human embryos.

Dr. Yamanaka's solution would scale these challenges if only he and his team could find a way to endow non-embryonic cells with those two key characteristics of embryonic stem cells.

In 2006, he and his team of young researchers — Yoshimi Tokuzawa, Kazutoshi Takahashi and Tomoko Ishisaka — were able to show that by introducing four factors into mouse skin cells, it was possible to generate ES-like mouse cells. The next year, they followed up that achievement, replicating the same strategy and converted human skin cells into iPS cells. “All we need is a small sample of skin (2-3millimetres) from the patient. This will be used to generate skin fibroblasts, and adding the factors, they can be converted to iPS cells. These cells can make any type of cell, including beating cardiac myocytes (heart cells), Prof.Yamanaka explained.

iPS cells hold out for humanity a lot of hope in curing diseases that have a single cell cause. Prominent among them are Lou Gehrig's Disease or Amyotrophic lateral sclerosis (ALS), also known as motor neuron disease. Motor neurons degenerate and die, and no effective treatment exists thus far. One reason is that there have not been good disease models for ALS in humans. It is difficult to get motor neuron from human patients and motor neurons cannot divide.

“Now, iPS cells can proliferate and can be differentiated to make motor neurons in large numbers,” he explained. Already a scientist in Japan has clarified motor neuron cells from iPS. “We are hoping that in the near future we would be able to evolve drug candidates that will be useful for ALS patients.” Treatment of spinal cord injuries using iPS cells has showed good results in mice and monkey specimens, and it is likely that in two or three years, scientists will be ready to start treatment for humans.

Toxicology, or drug side effects, is another area where iPS cells can be of use. Testing drug candidates directly on patients can be extremely dangerous. However, iPS cells can be differentiated into the requisite cell type, and the drugs tested on them for reactions. And yet, as wonderful as they may seem, iPS cells do have drawbacks, and there are multiple challenges to be faced before the technology can be applied to medicine. Are they equivalent and indistinguishable from ES cells? For a technology that has been around for only five years, the questions remain about safety. Also to derive patient-specific iPS cells, the process is time, and money-consuming, Prof. Yamanaka pointed out.

There are however, solutions in the offing, for the man who made the world's jaw drop with his discovery. One would be to create an iPS cell bank, where iPS cells could be created in advance from healthy volunteers donating peripheral blood, and skin fibroblasts, apart from frozen cord blood. The process of setting a rigorous quality control mechanism to select the best and safest iPS clones is on and would be complete within a year or two. “Many scientists are studying iPS cells across the world, and I'm optimistic that because of these efforts, we can overcome the challenges of iPS, and contribute to newer treatments for intractable diseases,” Prof. Yamanaka said.

N. Ram, Director, Kasturi & Sons Limited, introduced the speaker. Mariam Ram, managing director, TNQ India; and Emilie Marcus, executive editor, Cell Press, spoke.

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“Wide-ranging applications for pluripotent stem cells”

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Skin cells turned into neural precusors, bypassing stem-cell stage

February 1st, 2012

ScienceDaily (Jan. 30, 2012) — Mouse skin cells can be converted directly into cells that become the three main parts of the nervous system, according to researchers at the Stanford University School of Medicine. The finding is an extension of a previous study by the same group showing that mouse and human skin cells can be directly converted into functional neurons.

The multiple successes of the direct conversion method could refute the idea that pluripotency (a term that describes the ability of stem cells to become nearly any cell in the body) is necessary for a cell to transform from one cell type to another. Together, the results raise the possibility that embryonic stem cell research and another technique called "induced pluripotency" could be supplanted by a more direct way of generating specific types of cells for therapy or research.

This new study, published online Jan. 30 in the Proceedings of the National Academy of Sciences, is a substantial advance over the previous paper in that it transforms the skin cells into neural precursor cells, as opposed to neurons. While neural precursor cells can differentiate into neurons, they can also become the two other main cell types in the nervous system: astrocytes and oligodendrocytes. In addition to their greater versatility, the newly derived neural precursor cells offer another advantage over neurons because they can be cultivated to large numbers in the laboratory -- a feature critical for their long-term usefulness in transplantation or drug screening.

In the study, the switch from skin to neural precursor cells occurred with high efficiency over a period of about three weeks after the addition of just three transcription factors. (In the previous study, a different combination of three transcription factors was used to generate mature neurons.) The finding implies that it may one day be possible to generate a variety of neural-system cells for transplantation that would perfectly match a human patient.

"We are thrilled about the prospects for potential medical use of these cells," said Marius Wernig, MD, assistant professor of pathology and a member of Stanford's Institute for Stem Cell Biology and Regenerative Medicine. "We've shown the cells can integrate into a mouse brain and produce a missing protein important for the conduction of electrical signal by the neurons. This is important because the mouse model we used mimics that of a human genetic brain disease. However, more work needs to be done to generate similar cells from human skin cells and assess their safety and efficacy."

Wernig is the senior author of the research. Graduate student Ernesto Lujan is the first author.

While much research has been devoted to harnessing the pluripotency of embryonic stem cells, taking those cells from an embryo and then implanting them in a patient could prove difficult because they would not match genetically. An alternative technique involves a concept called induced pluripotency, first described in 2006. In this approach, transcription factors are added to specialized cells like those found in skin to first drive them back along the developmental timeline to an undifferentiated stem-cell-like state. These "iPS cells" are then grown under a variety of conditions to induce them to re-specialize into many different cell types.

Scientists had thought that it was necessary for a cell to first enter an induced pluripotent state or for researchers to start with an embryonic stem cell, which is pluripotent by nature, before it could go on to become a new cell type. However, research from Wernig's laboratory in early 2010 showed that it was possible to directly convert one "adult" cell type to another with the application of specialized transcription factors, a process known as transdifferentiation.

Wernig and his colleagues first converted skin cells from an adult mouse to functional neurons (which they termed induced neuronal, or iN, cells), and then replicated the feat with human cells. In 2011 they showed that they could also directly convert liver cells into iN cells.

"Dr. Wernig's demonstration that fibroblasts can be converted into functional nerve cells opens the door to consider new ways to regenerate damaged neurons using cells surrounding the area of injury," said pediatric cardiologist Deepak Srivastava, MD, who was not involved in these studies. "It also suggests that we may be able to transdifferentiate cells into other cell types." Srivastava is the director of cardiovascular research at the Gladstone Institutes at the University of California-San Francisco. In 2010, Srivastava transdifferentiated mouse heart fibroblasts into beating heart muscle cells.

"Direct conversion has a number of advantages," said Lujan. "It occurs with relatively high efficiency and it generates a fairly homogenous population of cells. In contrast, cells derived from iPS cells must be carefully screened to eliminate any remaining pluripotent cells or cells that can differentiate into different lineages." Pluripotent cells can cause cancers when transplanted into animals or humans.

The lab's previous success converting skin cells into neurons spurred Wernig and Lujan to see if they could also generate the more-versatile neural precursor cells, or NPCs. To do so, they infected embryonic mouse skin cells -- a commonly used laboratory cell line -- with a virus encoding 11 transcription factors known to be expressed at high levels in NPCs. A little more than three weeks later, they saw that about 10 percent of the cells had begun to look and act like NPCs.

Repeated experiments allowed them to winnow the original panel of 11 transcription factors to just three: Brn2, Sox2 and FoxG1. (In contrast, the conversion of skin cells directly to functional neurons requires the transcription factors Brn2, Ascl1 and Myt1l.) Skin cells expressing these three transcription factors became neural precursor cells that were able to differentiate into not just neurons and astrocytes, but also oligodendrocytes, which make the myelin that insulates nerve fibers and allows them to transmit signals. The scientists dubbed the newly converted population "induced neural precursor cells," or iNPCs.

In addition to confirming that the astrocytes, neurons and oligodendrocytes were expressing the appropriate genes and that they resembled their naturally derived peers in both shape and function when grown in the laboratory, the researchers wanted to know how the iNPCs would react when transplanted into an animal. They injected them into the brains of newborn laboratory mice bred to lack the ability to myelinate neurons. After 10 weeks, Lujan found that the cells had differentiated into oligodendroytes and had begun to coat the animals' neurons with myelin.

"Not only do these cells appear functional in the laboratory, they also seem to be able to integrate appropriately in an in vivo animal model," said Lujan.

The scientists are now working to replicate the work with skin cells from adult mice and humans, but Lujan emphasized that much more research is needed before any human transplantation experiments could be conducted. In the meantime, however, the ability to quickly and efficiently generate neural precursor cells that can be grown in the laboratory to mass quantities and maintained over time will be valuable in disease and drug-targeting studies.

"In addition to direct therapeutic application, these cells may be very useful to study human diseases in a laboratory dish or even following transplantation into a developing rodent brain," said Wernig.

In addition to Wernig and Lujan, other Stanford researchers involved in the study include postdoctoral scholars Soham Chanda, PhD, and Henrik Ahlenius, PhD; and professor of molecular and cellular physiology Thomas Sudhof, MD.

The research was supported by the California Institute for Regenerative Medicine, the New York Stem Cell Foundation, the Ellison Medical Foundation, the Stinehart-Reed Foundation and the National Institutes of Health.

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The above story is reprinted from materials provided by Stanford University Medical Center. The original article was written by Krista Conger.

Note: Materials may be edited for content and length. For further information, please contact the source cited above.

Journal Reference:

E. Lujan, S. Chanda, H. Ahlenius, T. C. Sudhof, M. Wernig. Direct conversion of mouse fibroblasts to self-renewing, tripotent neural precursor cells. Proceedings of the National Academy of Sciences, 2012; DOI: 10.1073/pnas.1121003109

Note: If no author is given, the source is cited instead.

Disclaimer: This article is not intended to provide medical advice, diagnosis or treatment. Views expressed here do not necessarily reflect those of ScienceDaily or its staff.

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Skin cells turned into neural precusors, bypassing stem-cell stage

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Researchers turn skin cells into neural precusors, bypassing stem-cell stage

January 31st, 2012

The multiple successes of the direct conversion method could refute the idea that pluripotency (a term that describes the ability of stem cells to become nearly any cell in the body) is necessary for a cell to transform from one cell type to another. Together, the results raise the possibility that embryonic stem cell research and another technique called "induced pluripotency" could be supplanted by a more direct way of generating specific types of cells for therapy or research.

This new study, which will be published online Jan. 30 in the Proceedings of the National Academy of Sciences, is a substantial advance over the previous paper in that it transforms the skin cells into neural precursor cells, as opposed to neurons. While neural precursor cells can differentiate into neurons, they can also become the two other main cell types in the nervous system: astrocytes and oligodendrocytes. In addition to their greater versatility, the newly derived neural precursor cells offer another advantage over neurons because they can be cultivated to large numbers in the laboratory — a feature critical for their long-term usefulness in transplantation or drug screening.