It’s a discordant note in the symphony of good news that usually accompanies stem cell research announcements. Stem cells hold enormous promise in regenerative medicine, thanks to their ability to regenerate diseased or damaged tissues. They have made it possible to markedly improve the effectiveness of many medical treatments — muscle regeneration in cases of dystrophy, skin grafts for treating burn victims, and the treatment of leukemia via bone marrow transplants.
The problem is obtaining them. Those that are the true source of life, in the first days of embryonic development, are of course the most highly sought after; still undifferentiated, they are “pluripotent,” meaning they can evolve into liver, muscle, eye — any kind of cell. But the issue of how to obtain them clearly raises insurmountable ethical questions.
“In this regard, the recent discovery of the “reprogramming” phenomenon, by which somatic cells can be induced to convert to a pluripotent state simply by forcing the expression of a few genes, opens a phenomenal number of possibilities in regenerative medicine,” says Didier Trono, Dean of the EPFL School of Life Sciences. “Imagine, for example, collecting a few cells from the hair follicle of a hemophiliac patient, reprogramming them to the pluripotentiality of their embryonic precursor, correcting the mutation responsible for the coagulation disorder that plagues the patient, and then re-administering them, genetically “cured,” after having orchestrated a differentiation into fully functional progeny.”
Increased risks for cancer?
But a study that has just been published in the journal Cell Death and Differentiation, to be followed by two articles in the journal Nature, is dampening those hopes. Conducted by the Department of Biochemistry at the University of Geneva and the European Institute of Oncology in Milan, with the participation of Trono’s laboratory, it concludes that these reprogrammed cells exhibit a “genomic instability” that appears to be caused by the process used to return the cells to their embryonic state. Even more serious, the genetic mutations observed resemble mutations that are found in cancer cells. The scientists draw the conclusion that reprogrammed stem cells need to be extensively investigated before they can even be considered for use in regenerative medicine.
The experiments were done using mouse mammary and fibroblast cells. The researchers used three different processes for reprogramming the cells to a “stem,” or embryonic, state. The first method was developed expressly for this study, and the others have already been well documented.
Yet all the processes led to the same, implacable conclusion: the genetic anomalies multiplied, in a manner that seems to indicate that they are inherent to the reprogramming process itself, which typically makes use of oncogenes. “Interestingly, oncogenes have the potential to induce genomic instability,” the authors explain.
These results underline the necessity of conducting further studies. First, to see if the genetic anomalies are serious enough to compromise the function and stability of cells regenerated using the reprogrammed cells; and second, to “refine the methods used for generating induced pluripotent cells, in order to avoid this problem. These results will thus motivate scientists to come up with a solution,” concludes Trono.