A new study, published today in the journal Applied Materials & Interfaces reports the discovery of a new method for growing human embryonic stem cells that does not depend on feeder cells from human or animal cells.
Traditionally, embryonic stem cells are cultivated with the help of feeder cells derived from animals. Feeder cells secrete a host of growth factors and other signaling molecules that prevent the embryonic stem cells from differentiating and maintain their pluripotency. However, the use of animal products in the production of human cells lines rules out their use in the treatment of humans, since they can become contaminated with animal proteins that will cause rejection by the immune system or animal viruses that can infect the patient and cause significant disease.
The team of scientists led by the University of Surrey and in collaboration with Professor Peter Donovan at the University of California have developed a scaffold of carbon nanotubes upon which human stem cells can be grown into a variety of tissues. These nanotube networks mimic the surface of the body’s natural support cells and act as scaffolding for stem cells to grow on. Even cultured cells that have previously relied on feeder cells can now be grown safely in the laboratory, which paves the way for revolutionary steps in replacing tissue after injury or disease.
Dr Alan Dalton, senior lecturer from the Department of Physics at the University of Surrey said: “While carbon nanotubes have been used in the field of biomedicine for some time, their use in human stem cell research has not previously been explored successfully.”
“Synthetic stem cell scaffolding has the potential to change the lives of thousands of people, suffering from diseases such as Parkinson’s, diabetes and heart disease, as well as vision and hearing loss. It could lead to cheaper transplant treatments and could potentially one day allow us to produce whole human organs without the need for donors.”
Regenerative medicine depends on stem cells for the promises that it can potentially deliver to ailing patients. Training stem cells to repair injured tissues with custom-grown tissue substitutes and to replace dead cells are some of the goals of regenerative medicine. A major player in regenerative medicine is induced pluripotent stem cells (iPSCs), which are made from a patient’s own tissues. Because iPSCs are derived from a patient’s own cells, their chance of being rejected by the patient’s own immune system is rather low. Unfortunately, Shinya Yamanaka’s formula for making iPSCs, for which he was awarded last year’s Nobel Prize, utilizes a strict recipe that uses a precise combination of genes, some of which increase the risk of cancer risk, and, therefore, restricts their full potential for clinical application.
However, the laboratory Juan Carlos Izpisua Belmonte and his colleagues at the Salk Institute have published a paper in the journal Cell Stem Cell that shows that the recipe for iPSCs is much more versatile than originally thought. For the first time, Izpisua Belmonte and his colleague have replaced a gene that was once thought to be impossible to substitute in the production of iPSCs. This creates the potential for more flexible recipes that should speed the adoption of iPSCs for stem cell-based therapies.
Pluripotent stem cells come from two main sources. Embryonic stem cells (ESCs) are derived from early human blastocyst-stage embryos. The cells of the inner cell mass are extracted and these immature cells that have never differentiated into specific cell types, and are cultured, grown, and propagated to form an embryonic stem cell line. Secondly, induced pluripotent stem cells or iPSCs, are derived from mature cells that have been reprogrammed back into an undifferentiated state. In 2006 by Yamanaka introduced four different genes into a mature cell to reprogram the cell to pluripotency. This pluripotent cell can be cultured and grown into an iPSCs line. Because of Yamanaka’s initial success in iPSC production, most stem cell researchers adopted his recipe, even though variations on his protocol have been examined and used.
Izpisua Belmonte and his colleagues used a fresh approach for the derivation of iPSCs. They played around with the Yamanka protocol and in doing do discovered that pluripotency (the stem cell’s ability to differentiate into nearly any kind of adult cell) can also be programmed into adult cells by “balancing” the genes required for differentiation. What genes? Those genes that code for “lineage transcription factors,” which are proteins that direct stem cells to differentiate first into a particular cell lineage, or type, such as a blood cell versus a skin cell, and then finally into a specific cell, such as a white blood cell.
“Prior to this series of experiments, most researchers in the field started from the premise that they were trying to impose an ’embryonic-like’ state on mature cells,” says Izpisua Belmonte, who holds the Institute’s Roger Guillemin Chair. “Accordingly, major efforts had focused on the identification of factors that are typical of naturally occurring embryonic stem cells, which would allow or further enhance reprogramming.”
Despite these efforts, there seemed to be no way to determine through genetic identity alone that cells were pluripotent. Instead, pluripotency was routinely evaluated by functional assays. In other words, if it acts like a stem cell, it must be a stem cell.
That condition led the team to their key insight. “Pluripotency does not seem to represent a discrete cellular entity but rather a functional state elicited by a balance between opposite differentiation forces,” says Izpisua Belmonte.
Once they understood this, they realized the four extra genes weren’t necessary for pluripotency. Instead, adult cells could be reprogrammed by altering the balance of “lineage specifiers,” genes that were already in the cell that specified what type of adult tissue a cell might become.
“One of the implications of our findings is that stem cell identity is actually not fixed but rather an equilibrium that can be achieved by multiple different combinations of factors that are not necessarily typical of ESCs,” says Ignacio Sancho-Martinez, one of the first authors of the paper and a postdoctoral researcher in Izpisua Belmonte’s laboratory.
Izpisua Belmonte’s laboratory showed that more than seven additional genes can facilitate reprogramming adult cells to iPSCs. Most importantly, for the first time in human cells, they were able to replace a gene from the original recipe called Oct4, which had been replaced in mouse cells, but was still thought indispensable for the reprogramming of human cells. Their ability to replace it, as well as SOX2, another gene once thought essential that had never been replaced in combination with Oct4, demonstrated that stem cell development must be viewed in an entirely new way. In point of fact, Belmonte’s group showed that genes that specify mesendodermal lineage can replace OCT4 in human iPSC generation, and ectodermal lineage specifiers are able to replace SOX2 in hiPSC generation. Simultaneous replacement of OCT4 and SOX2 allows human cell reprogramming to iPSCs
“It was generally assumed that development led to cell/tissue specification by ‘opening’ certain differentiation doors,” says Emmanuel Nivet, a post-doctoral researcher in Izpisua Belmonte’s laboratory and co-first author of the paper, along with Sancho-Martinez and Nuria Montserrat of the Center for Regenerative Medicine in Barcelona, Spain.
Instead, the successful substitution of both Oct4 and SOX2 shows the opposite. “Pluripotency is like a room with all doors open, in which differentiation is accomplished by ‘closing’ doors,” Nivet says. “Inversely, reprogramming to pluripotency is accomplished by opening doors.”
This work should help to overcome one of the major hurdles in the widespread adoption of iPSC-based therapies; namely, that the original four genes used to reprogram stem cells had been implicated in cancer. “Recent studies in cancer, many of them done by my Salk colleagues, have shown molecular similarities between the proliferation of stem cells and cancer cells, so it is not surprising that oncogenes [genes linked to cancer] would be part of the iPSC recipe,” says Izpisua Belmonte.
With this new method, which allows for a customized recipe, the team hopes to push therapeutic research forward. “Since we have shown that it is possible to replace genes thought essential for reprogramming with several different genes that have not been previously involved in tumorigenesis, it is our hope that this study will enable iPSC research to more quickly translate into the clinic,” says Izpisua Belmonte.
Other researchers on the study were Tomoaki Hishida, Sachin Kumar, Yuriko Hishida, Yun Xia and Concepcion Rodriguez Esteban of the Salk Institute; Laia Miquel and Carme Cortina of the Center of Regenerative Medicine in Barcelona, Spain.