Induced pluripotent stem cell (iPS) technology appears to be a general strategy to generate pluripotent stem cells from any given mammalian species. So far, iPS cells have been reported for mouse, human, rat, and monkey. These four species have also established embryonic stem cell (ESC) lines that serve as the gold standard for pluripotency comparisons. Attempts have been made to generate porcine ESC by various means without success. Here we report the successful generation of pluripotent stem cells from fibroblasts isolated from the Tibetan miniature pig using a modified iPS protocol. The resulting iPS cell lines more closely resemble human ESC than cells from other species, have normal karyotype, stain positive for alkaline phosphatase, express high levels of ESC-like markers (Nanog, Rex1, Lin28, and SSEA4), and can differentiate into teratomas composed of the three germ layers. Because porcine physiology closely resembles human, the iPS cells reported here provide an attractive model to study certain human diseases or assess therapeutic applications of iPS in a large animal model.
Induced nuclear reprogramming through induced pluripotent stem cell (iPS)2 technology is an amazing achievement full of challenge to the intellect and important practical implications (1, 2). Overexpression of exogenous factors that are highly enriched in embryonic stem cell (ESC) can rearrange the genetic program of different cell types, including somatic and adult stem cells, and induce a long lasting ESC-like pluripotent state (3-7). The repercussions of iPS technology are vast: it provides a way to create patient-specific stem cells that bypasses ethical and technical issues surrounding human ESC derivation and somatic cell nuclear transfer (8, 9), a state of the art model for studying genetic diseases in vitro (10, 11), and an incredible backwards route that can crystallize our current understanding of developmental and stem cell biology. Many questions, especially mechanistic, remain unanswered, but the current rhythm of research may bring iPS to clinical application sooner than expected. However, before jumping onto such extraordinary endeavor, safety must be scrupulously tested in an animal model close enough to humans. Nowadays that iPS technology is expanding, with improved delivery systems, chemical additions, new tissue culture conditions, and multiple cell sources being reported regularly, such animal model is essential to set up quality standards (12-18). Mice, and maybe rats, will possibly continue unrivalled as the easier ways to learn about reprogramming machinery and improve methodology, but their size, physiology, and reduced lifespan are handicaps for making serious assumptions regarding safety in humans. Given philogenetic similarity, monkeys are theoretically an excellent alternative, but in practice ethical concerns remain to at least some extent, and they are neither easy to maintain nor to breed. Swine, a regular source of food whose farming humans have adapted over myriads of years and whose physiology is r...
