It is unclear at exactly what point the phrase “stem cell” entered the vernacular, one of very few scientific terms that achieve the status of, say, DNA in not requiring a detailed explanation every time it is written down or spoken.
Whether or not you know exactly what they are or what they do, stem cells imply something very specific: In them is invested the next generation of medicine, revolutionary treatments for everything from Parkinson’s to Alzheimer’s. On the horizon, there is also the hope of growing genetically matched tissue (even whole organs) to replace anything that has been damaged by disease or accident.
But perhaps the reason stem cells managed to lodge themselves so deep in the public psyche was not just because of their awesome scientific potential, or their ability to turn into the treatments of the future. Perhaps it was politics. For years, stem cells dominated all other science stories in newspaper headlines because they framed an ethical conundrum — to get to the most versatile stem cells meant destroying human embryos.
Research on stem cells became a political football, leading to delays in funding for scientists, particularly in the US. Not that the work itself was straightforward — the process of extracting stem cells from embryos is difficult and there is a very limited supply of material. Inevitable disappointment followed the years of headlines — where were the promised treatments? Was it all over-hyped?
For Paul Fairchild, co-director of the newly founded Oxford Stem Cell Institute, disappointment is just not on the agenda. Over a coffee in the University of Oxford’s pathology department, where he is a professor, he explains his vision for the coming, post-hype decade of stem cell science.
“It’s an exciting time in stem cell biology for a host of reasons,” he says. “We’ve entered a whole new phase in the stem cell field, which has been held up enormously by ethical issues for over a decade.”
Key to this is the discovery, in the past few years, of a way to make stem cells that do not require the destruction of embryos. In one move, these induced pluripotent stem (iPS) cells remove the ethical roadblocks faced by embryonic stem cells and, because they are so much easier to make, give scientists an inexhaustible supply of material, bringing them ever closer to those hoped-for treatments.
Fairchild says that iPS technology will “completely revolutionize the whole of medicine this century.” The talk is matched by action: The Oxford Stem Cell Institute is a recognition of the importance of the work ahead, a collaboration that brings together 37 laboratories across 17 departments at the university.
“It’s an attempt to try and bring all of the work in stem cell biology under one umbrella organization to allow people to collaborate more effectively,” Fairchild says.
Stem cells are the body’s master cells, the raw material from which we are built. Unlike normal body cells, they can reproduce an indefinite number of times and, when prodded in the right way, can turn themselves into any type of cell in the body. The most versatile stem cells are those found in the embryo at just a few days old — this ball of a few dozen embryonic stem (ES) cells eventually goes on to form everything that makes up a person.
In 1998, James Thomson at the University of Wisconsin-Madison announced that he had isolated human ES cells in the lab. Finally, these powerful cells were within the grasp of scientists to experiment with, understand and develop into fixes for the things that go wrong.
There were some immediate practical problems with the work. Once scientists had extracted ES cells from an embryo, they could create an immortal line of the cells to use in research. However, the wide genetic variations in humans mean that scientists need lots of different lines of ES cells to treat and understand the wide variety of faults. Each new line of ES cells can only be created by fertilizing an egg, and these are a precious, rare commodity.
This is also where the ethical problems lie. Extracting ES cells destroys the embryo — for some, this is akin to killing a potential human life. Former US president George W. Bush banned the use of federal dollars to support research using human ES cells on all but a limited number of cell lines that already existed in research labs prior to August 2001. US President Barack Obama reversed that ban, only to be thwarted by a federal court ruling last year that, once again, put the scientists into a state of uncertainty. By contrast, the UK laws are relatively civil — after much debate about the ethics of using human embryos, the government passed strict, but fair, laws that allowed ES research to go ahead.
However, that did not get rid of the practical problems of a lack of donor eggs, or that the experiments with ES cells as treatments — to repair a damaged heart, for instance — were proving unsuccessful.
Enter the iPS cell. In 2007, Shinya Yamanaka at Kyoto University in Japan demonstrated a way of producing ES-like cells without using eggs. He took a skin cell and, using a virus, inserted four specific bits of DNA into the skin cell’s nucleus. The skin cell incorporated the genetic material and was regressed into an ES-like cell — it had been “reprogrammed” using a batch of chemicals in the lab. In a few short experiments, scientists had a near-limitless supply of stem cells that were, seemingly, as good as ES cells for their research.
By creating iPS cells from patients with genetic diseases, scientists have been able to watch which genes go wrong in a variety of conditions, how and when it happens — all of it critical detail in finding ways to stop diseases in their tracks.
The method works like this: Take some skin cells from a person with Parkinson’s disease and then regress these back into iPS cells. Then coax these stem cells to turn into neurons and watch how they work and, crucially, how they go wrong. These neurons are genetically identical to the patient’s own brain cells — allowing scientists to model the disease more accurately and test out ideas or even screen potential drugs.
“It’s possible now, of course, to take a few cells from an individual with an intractable disease of some kind for which there are no animal models or any way of studying it, to reprogram them to an iPS cell state and then differentiate from those the cell type that’s affected from the disease,” Fair-child says. “We now have a way of taking them from that person and studying the cell type itself in vitro that will almost certainly have symptoms of the disease. It’s possible to produce these models of human disease in vitro which we’ve never had access to before.”
Models using iPS cells have proliferated in a few short years: They are now available for, among other things, motor neurone disease, juvenile diabetes and sickle cell anaemia.
“It’s exciting to have models that we can now probe and find out what is actually going on for the first time,” Fairchild says.
Traditionally, scientists use animal models of disease in order to carry out experiments or test brand new drugs — but these models are not perfect. Using human cells taken from a patient with a human disease is a more promising way of gauging what might happen in people.
Fairchild has been examining how to use iPS cells to modulate the body’s immune system. It is a route, he hopes, to less rejection when people get transplants of replacement tissue. The same techniques could even develop into a better way to treat cancer.
He started by differentiating embryonic stem cells into a key part of the body’s immune system called dendritic cells. These cells continually sample proteins, called antigens, that sit on the surface of everything in the body. If they determine that the antigen comes from something potentially dangerous or foreign, they set the body’s killer T-cells to go after the danger and destroy it. On the flip side, the dendritic cells can also dial down the ferocity of the killer T-cells if they recognize an antigen as non-foreign.
One way Fairchild’s team is using this idea is to grow dendritic cells that can recognize the antigens on tumors. Inserting these cells into a patient would dial up the immune system’s natural response to that tumor.
“What you do is grow the dendritic cells, then feed them with the tumor-associated antigens in vitro,” he says. “Then put those back into the patient, so that they’re presenting those melanoma antigens.”
His experiments have shown that the dendritic cells do indeed stimulate the body’s T-cells to respond robustly. The T-cells are then programmed to find the tumor and destroy it. That means a better natural response to cancer, all without the need for toxic chemotherapy.
Another way to use the dendritic cells is to dial down the body’s immune response to transplanted tissue or organs. Anyone who has a transplant needs immunosuppressant drugs for the rest of their lives to prevent their immune systems from attacking the new tissue. Stem cells offer the possibility of growing genetically matched tissue for patients, so rejection should, in theory, not be a problem.
However, Fairchild says that growing matched tissue for every individual is likely to be prohibitively expensive for now. Instead, scientists would probably grow replacements from a bank of stem cells that are close matches to the majority of the population, but that means that replacement tissue would still provoke the recipient’s immune system.
Fairchild’s solution is to grow dendritic cells from the same stem cells being used to grow the replacement tissue for the patient. The dendritic cells can then be used to train the recipient’s immune system that the replacement tissue is not to be rejected.
The creativity in the field is exciting, but it is right, also, to point out the many technical issues facing iPS cells in moving outside the lab. Just recently, Andras Nagy of Mount Sinai Hospital and Timo Otonkoski at the University of Helsinki found genetic abnormalities when creating iPS cells. In a study published in Nature, they reported the deletion or amplification of certain strands of DNA.
“Our analysis shows that these genetic changes are a result of the reprogramming process itself, which raises the concern that the resultant cell lines are mutant or defective,” Nagy says.
It is just one of a number of research papers raising concerns about the way iPS cells are produced.
“In a laboratory dish, pluripotent stem cells promise to become any sort of cell a researcher could want,” wrote Monya Baker, editor of Nature Reports Stem Cells, in a 2009 article looking to the future of the iPS technology. “But when transplanted into the body, such cells could grow unpredictably: Clinicians worry most about tumor formation, although one can imagine other dangers, such as tissues growing in the wrong place.”
The very things that make iPS cells so useful in lab situations — their immortality and versatility — would be disastrous if left unchecked inside people, but, for a field that is barely a few years old, the remarkable pace of achievement should give plenty of hope that these challenges will be met.
“Turning knowledge into medicine is never easy,” Baker says. “But the pace of knowledge generation itself is fast and furious.”
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