“These cells will allow us to gain a much greater understanding of normal embryonic development and have the real potential for use in developing ways to grow new tissues and organs for transplantation,” said Carol Ware, a professor of comparative medicine. She is the lead author of a paper describing the new cell line.
In an article, Ware and her colleagues from the UW Institute for Stem Cell and Regenerative Medicine describe how they successfully created a line of naïve human embryonic stem cells without introducing an artificial set of genes.
The findings are reported in the March 10 issue of the journal Proceedings of the National Academy of Sciences. The cells, called naïve embryonic stem cells, normally appear at the earliest stages of embryonic development. They retain the ability to turn into any of all the different types of cells of the human body — a capacity called “pluripotency.”
They first took embryonic stem cells that are slightly more developed, called primed stem cells, and grew them in a medium that contained factors that switched them back — or “reverse toggled” them — to the naïve state. They then used the reverse toggled cells to develop a culture medium that would keep them in the naïve state and create a stable cell line for study and research.
University of Washington researchers have created a line of human embryonic stem cells with the ability to develop into a far broader range of tissues than most existing cell lines.
While these transgenic cells are valuable research tools, the presence of artificially introduced genes meant the cells will not develop as normal embryonic cells would nor could they be safely used to create tissues and organs for transplantation.
The new cell line is called Elf1: “El” for the Ellison Foundation, a major supporter of the lab’s work; “f” for female, the sex of the stem cell; and “1″ for first.
Story Source:
Researchers had been able to develop naïve cells using mouse embryonic stem cells, but to create naive human embryonic stem cells has required inserting a set of genes that force the cells to behave like naive cells.
The above story is based on materials provided by University of Washington – Health Sciences/UW News, Community Relations & Marketing. The original article was written by Michael McCarthy. Note: Materials may be edited for content and length.
While the “reverse toggled” cells are much easier to create and will prove valuable research tools, Ware said, the cells that were directly derived from embryos are the more important advance because they are more likely to behave, grow and develop as embryonic cells do in nature.
