Scientists from the German Cancer Research Center (DKFZ) and the stem cell institute HI-STEM in Heidelberg have succeeded for the first time in directly reprogramming human blood cells into a previously unknown type of neural stem cell. These induced stem cells are similar to those that occur during the early embryonic development of the central nervous system. They can be modified and multiplied indefinitely in lab and represent a candidate for the development of regenerative therapies.
Pluripotent embryonic stem cells can multiply indefinitely and generate all conceivable cell types. In 2006, the Japanese scientist Shinya Yamanaka recognized that such cells could also be produced in the laboratory from mature body cells. Four genetic factors alone are sufficient to reverse the course of development and produce so-called induced pluripotent stem cells (iPS) with identical properties to embryonic stem cells. Yamanaka was awarded the Nobel Prize for Medicine in 2012 for this discovery.
“This was a major breakthrough for stem cell research,” said Andreas Trumpp, German Cancer Research Center (DKFZ) and director of HI-STEM in Heidelberg. “This applies in particular to for research in Germany, where the generation of human embryonic stem cells is not permitted. Stem cells have enormous potential both for basic research and for the development of regenerative therapies that aim to restore diseased tissue in patients. However, reprogramming is also associated with problems: For example, pluripotent cells can form germline tumors, so-called teratomas.
For the first time, Trumpp’s team has succeeded in reprogramming mature human cells in such a way that a defined type of induced neural stem cell is produced that can multiply almost indefinitely. “We used four genetic factors like Yamanaka, but different ones for our reprogramming,” explains Marc Christian Thier, first author of the study. “We assumed that our factors would allow reprogramming to an early stage of development of the nervous system.”
In the past, other research groups also reprogrammed connective tissue cells into mature nerve cells or neural precursor cells. However, these artificially produced nerve cells often could not be expanded and could therefore not be used for therapeutic purposes. “Often, it was a heterogeneous mixture of different cell types that might not exist in the body under physiological conditions,” said Andreas Trumpp, explaining the problems.
Together with stem cell researcher Frank Edenhofer from the University of Innsbruck and neuroscientist Hannah Monyer from DKFZ and the Heidelberg University Hospital, Trumpp and his team have now succeeded in reprogramming connective tissue cells of the skin and pancreas as well as peripheral blood cells. “The origin of the cells had no influence on the properties of the stem cells,” said Thier. In particular, the possibility of extracting neural stem cells from the blood of patients without invasive intervention is a decisive advantage for future therapeutic approaches.
Notably, the reprogrammed cells are of a homogeneous cell type resembling a stage that occurs during the embryonic development of the nervous system. “Corresponding cells exist in mice and probably also in humans during early embryonic brain development,” said Thier. “We have described here a new neural stem cell type in the mammalian embryo.”
These so-called induced neural plate border stem cells (iNBSCs) have a broad development potential. The iNBSCs are expandable and multipotent and can develop in two directions. On the one hand, they can take the path of development to mature nerve cells and glial cells of the central nervous system. On the other hand, they can also develop into cells of the neural crest, from which different cell types emerge, for example, peripheral sensitive nerve cells or cartilage and bones of the skull.
The iNBSCs thus form an ideal basis for generating a broad range of different cell types for an individual patient. “These cells have the same genetic material as the donor and are therefore presumably self-recognized by the immune system and are not rejected,” explains Thier.
The CRISPR/Cas9 gene scissors can be used to modify the iNBSC or repair genetic defects, as the scientists have shown in their experiments. “They are therefore interesting both for basic research and the search for new active substances and for the development of regenerative therapies, for example in patients with diseases of the nervous system. However, until we can use them in patients, a lot of research work will still be necessary,” says Trumpp.
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