Scientists at The Scripps Research Institute (TSRI) have found a new approach to the “reprogramming” of ordinary adult cells into stem cells.
In a study published in an Advance Online paper in Nature Biotechnology, the TSRI scientists screened a library of 100 million antibodies and found several that can help reprogram mature skin-like cells into stem cells known as induced pluripotent stem cells (IPSCs).
Making IPSCs from more mature types of cells normally involves genetic engineering by inserting four transcription factor genes into the DNA of those cells. The new approach uses antibodies identified by the scientists that can be applied to mature cells where they bind to proteins on the cell surface as a substitute for three of the standard transcription factor gene insertions.
IPSCs that are made using genetic engineering have many unknown risks associated with them and are not currently utilized outside of research studies. This new discovery opens the possibility of taking a persons own cells, reverse aging them back into young stem cells and then using those to replace aged or damaged cells throughout the body.
“This result suggests that ultimately we might be able to make IPSCs without putting anything in the cell nucleus, which potentially means that these stem cells will have fewer mutations and overall better properties,” said study senior author Kristin Baldwin, associate professor in TSRI’s department of neuroscience.
IPSCs can be made from patients’ own cells, and have a multitude of potential uses in personalized cell therapies and organ regeneration. However, none of IPSCs’ envisioned clinical uses has yet been realized, in part because of the risks involved in making them.
The standard IPSC induction procedure, developed a decade ago and known as OSKM, involves the insertion into adult cells of genes for four transcription factor proteins: Oct4, Sox2, Klf4 and c-Myc. With these genes added and active, the transcription factor proteins they encode are produced and in turn reprogram the cells to become IPSCs.
One problem with this procedure is that this nuclear reprogramming typically yields a collection of IPSCs with variable properties. “This variability can be a problem even when we’re using IPSCs in the laboratory for studying diseases,” Baldwin said.
In contrast, during ordinary animal development, cell identity is altered by molecular signals that come in from outside the cell and induce changes in gene activity, without any risky insertions of DNA. To find natural pathways like these through which ordinary cells could be turned into IPSCs Baldwin and her laboratory teamed up with the TSRI laboratory of Richard Lerner, the Lita Annenberg Hazen Professor of Immunochemistry. Lerner has helped pioneer the development and screening of large libraries of human antibodies for finding new antibody-based drugs and scientific probes.
In this case, the team, including graduate student Joel W. Blanchard and postdoctoral research associate Jia Xie, who were lead authors, set up a library of about 100 million distinct antibodies and used it to find any that could substitute for OSKM transcription factors.
In an initial set of experiments, the researchers tried to identify antibodies that can replace both Sox2 and c-Myc. They established a large population of mouse fibroblast cells — often used to make IPSCs in experiments — and inserted the genes for the other two transcription factors, Oct4 and Klf4. Next they added their huge library of antibody genes to the population of cells, such that each cell ended up containing the genes for one or more of the antibodies.
The scientists could then observe which of the cells began forming stem cell colonies indicating that one of the antibodies produced by those cells had successfully replaced the functions of Sox2 and c-Myc and triggered the switch in cell identity. Sequencing the DNA of these cells allowed the researchers to determine the antibodies responsible.
In this way, the TSRI team discovered two antibodies that can be substituted for both Sox2 and c-Myc, and in a similar set of tests they found two antibodies that can replace a third transcription factor, Oct4. The scientists showed that instead of inserting these transcription factor genes they could simply supply the antibodies to the fibroblast cells in culture.
In this initial study, the scientists were unable to find antibodies that replace the function of the fourth OSKM transcription factor, Klf4. However, Baldwin expects that with more extensive screening she and her colleagues eventually will find antibody substitutes for Klf4 as well. “That one I think is going to take us a few more years to figure out,” she said.
The antibody-screening approach in principle allows scientists not only to find antibodies that can replace OSKM transcription factors, but also to study the natural signaling pathways through which these antibodies work.
In a proof of this principle, the scientists found that one of the Sox2-replacing antibodies binds to a protein on the cell membrane called Basp1. This binding event blocks Basp1’s normal activity and thus removes the restraints on WT1, a transcription factor protein that works in the cell nucleus. WT1, unleashed, then alters the activity of multiple genes, ultimately including Sox2’s, to promote the stem cell state using a different order of events than when using the original reprogramming factors.
The TSRI researchers now plan larger, more complex antibody-screening studies using human cells rather than mouse cells.
Reference: Joel W Blanchard, Jia Xie, Nadja El-Mecharrafie, Simon Gross, Sohyon Lee, Richard A Lerner, Kristin K Baldwin. Replacing reprogramming factors with antibodies selected from combinatorial antibody libraries. Nature Biotechnology, 2017; DOI: 10.1038/nbt.3963