The question of how salamanders regenerate their legs when amputated is an ancient one that dates back to the days of Aristotle. Now scientists have come one step closer to solving the mystery. Contrary to what researchers previously believed, when a salamander’s legs are removed the cells near the amputation site revert to adult stem cells, but do not become pluripotent, or capable of developing into any body part. That explains why a salamander who loses a tail doesn’t regrow a leg in its place.
In the study, published in Nature, scientists explain that when a salamander’s limb is amputated, the muscle, bone, and skin cells at the amputation site change into a clump of adult stem cells called a blastema. Before this experiment, researchers had hypothesized that these undifferentiated blastema cells — which all look identical — are pluripotent and thus able to form many different cells types. But it was not clear how the original cells from adult tissue were reprogrammed, or how the blastema cells went on to form the correct tissue types [Nature News].
To determine how cells give rise to a regrown limb, scientists first inserted a snippet of DNA into the genome of a salamander called an axolotl, which caused it to produce a glowing green protein. From the eggs of these glowing salamanders, they then removed the cells that would eventually develop into legs. Next they removed the future leg-cells of a normal salamander embryo, and implanted in their place the cells that would produce glowing legs–when these formerly normal salamander developed, they had fluorescent limbs. Finally, the researchers amputated their salamanders’ legs, which then regrew. Cells in the new legs also contained the fluorescent protein and glowed under a microscope so the scientists could watch blastemas form and legs regrow in cell-by-cell detail. Contrary to expectation, skin cells that joined the blastema later divided into skin cells. Muscle became muscle. Cartilage became cartilage. Only cells from just beneath the skin could become more than one cell type [Wired.com].
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