Researchers from the Centre for Genomic Regulation in Barcelona, Spain, have discovered an even faster and more efficient way to reprogram adult cells to make induced pluripotent stem cells (iPSCs).
This new discovery decreases the time it takes to derived iPSCs from adult cells from a few weeks to a few days. It also elucidated new things about the reprogramming process for iPSCs and their potential for regenerative medical applications.
iPSCs behave similarly to embryonic stem cells, but they can be created from terminally differentiated adult cells. The problem with the earlier protocols for the derivation of iPSCs is that only a very small percentage of cells were successfully reprogrammed (0.1%-2%). Also this reprogramming process takes weeks and is a rather hit-and-miss process.
The Centre for Genomic Regulation (CRG) research team have been able to reprogram adult cells very efficiently and in a very short period of time.
“Our group was using a particular transcription factor (C/EBPalpha) to reprogram one type of blood cells into another (transdifferentiation). We have now discovered that this factor also acts as a catalyst when reprogramming adult cells into iPS,” said Thomas Graf, senior group leader at the CRG and ICREA research professor.
“The work that we’ve just published presents a detailed description of the mechanism for transforming a blood cell into an iPS. We now understand the mechanics used by the cell so we can reprogram it and make it become pluripotent again in a controlled way, successfully and in a short period of time,” said Graf.
Genetic information is compacted into the nucleus like a wadded up ball of yarn. In order to access genes for gene expression, that ball of yarn has to be unwound so that the cell can find the information it needs.
The C/EBPalpha (CCAAT/Enhancer Binding Protein alpha) protein temporarily unwinds that region of DNA that contains the genes necessary for the induction of pluripotency. Thus, when the reprogramming process begin, the right genes are activated and they enable the successful reprogramming all the cells.
“We already knew that C/EBPalpha was related to cell transdifferentiation processes. We now know its role and why it serves as a catalyst in the reprogramming,” said Bruno Di Stefano, a PhD student. “Following the process described by Yamanaka the reprogramming took weeks, had a very small success rate and, in addition, accumulated mutations and errors. If we incorporate C/EBPalpha, the same process takes only a few days, has a much higher success rate and less possibility of errors, said Di Stefano.
This discovery provides a remarkable insight into stem cell-forming molecular mechanisms, and is of great interest for those studies on the early stages of life, during embryonic development. At the same time, the work provides new clues for successfully reprogramming cells in humans and advances in regenerative medicine and its medical applications.