A novel method for somatic cell nuclear transfer to mouse embryonic stem cells.

Nuclear reprogramming by somatic cell nuclear transfer (SCNT) provides a practical approach for generating autologous pluripotent cells from adult somatic cells. It has been shown that murine somatic cells can also be reprogrammed to a pluripotent-like state by fusion with embryonic stem (ES) cells. Typically, the first step in SCNT involves enucleation of the recipient cell. However, recent evidence suggests that enucleated diploid ES cells may lack reprogramming capabilities. Here we have developed methods whereby larger tetraploid ES cells are first generated by fusion of two mouse ES cell lines transfected with plasmids carrying different antibiotic-resistance cassettes, followed by double antibiotic selection. Tetraploid ES cells grown on tissue culture disks or wells can be efficiently enucleated (up to 99%) using a combination of cytochalasin B treatment and centrifugation, with cytoplasts generated from these cells larger than those obtained from normal diploid ES cells. Also, we show that the enucleation rate is dependent on centrifugation time and cell ploidy. Further, we demonstrate that normal diploid ES cells can be fused to tetraploid ES cells to form heterokaryons, and that selective differential centrifugation conditions can be applied where the tetraploid nucleus is removed while the diploid donor nucleus is retained. This technology opens new avenues for generating autologous, diploid pluripotent cells, and provides a dynamic model for studying nuclear reprogramming in ES cells.

Tetraploid embryonic stem cells contribute to the inner cell mass of mouse blastocysts.

The demonstration that mouse somatic cells can be reprogrammed following fusion with embryonic stem (ES) cells may provide an alternative to somatic cell nuclear transfer (therapeutic cloning) to generate autologous stem cells. In an attempt to produce cells with an increased pool of reprogramming factors, tetraploid ES cells were produced by polyethylene glycol mediated fusion of two ES cell lines transfected with plasmids carrying puromycin or neomycin resistance cassettes, respectively, followed by double antibiotic selection. Tetraploid ES cells retain properties characteristic of diploid ES cells, including the expression of pluripotent gene markers Oct4 and Rex1. On injection into the testis capsule of severe combined immunodeficient (SCID) mice, tetraploid ES cells are able to form teratomas containing cells representative of all three germ layers. Further, these cells demonstrated the ability to integrate into the inner cell mass of blastocysts. This study indicates that tetraploid ES cells are promising candidates as cytoplasm donors for reprogramming studies.