Derivation of the MUSIe002-A human embryonic stem cell line.

The MUSIe002-A cell line was established from in vitro fertilization of human sperm and oocytes donated for research with informed consent. This cell line exhibited normal human embryonic stem cell (hESC) characteristics, including typical cell morphology, expression of all pluripotent stem cell markers, and potential to differentiate into three germ layers. A karyotyping analysis revealed 46 XY chromosome and cells that did not have mycoplasma contamination. MUSIe002-A represents a valuable unlimited cell source and is of potential interest for human in vitro stem cell based-models, genetic modifications, and stem cell-based therapy of human disease.

Derivation of human embryonic stem cell line MUSIe001-A from an embryo with homozygous α0-thalassemia (SEA deletion).

MUSIe001-A cell line was derived from a Southeast Asian (SEA) type deletion α0-thalassemia embryo. The SEA deletion embryo was donated for research with informed consent. This cell line shows normal hESC morphology, expresses all pluripotent markers, and has the potential to differentiate into all three germ layers in vitro and in vivo. The MUSIe001-A line has normal karyotype and is free from mycoplasma contamination. PCR analysis confirmed the MUSIe001-A cell line to be a SEA type deletion. MUSIe001-A is a valuable proof of principle model for gene therapy that will facilitate the development of new treatments for affected foetuses.

High-efficiency derivation of human embryonic stem cell lines using a culture system with minimized trophoblast cell proliferation.

BACKGROUND: Due to their extensive self-renewal and multilineage differentiation capacity, human embryonic stem cells (hESCs) have great potential for studying developmental biology, disease modeling, and developing cell replacement therapy. The first hESC line was generated in 1998 by culturing inner cell mass (ICM) cells isolated from human blastocysts using an immunosurgery technique. Since then, many techniques including mechanical ICM isolation, laser dissection, and whole embryo culture have been used to derive hESC lines. However, the hESC derivation efficiency remains low, usually less than 50%, and it requires a large number of human embryos to derive a significant number of hESC lines. Due to a shortage of and restricted access to human embryos, a novel approach with better hESC derivation efficiency is badly needed to decrease the number of embryos used. METHODS: We hypothesized that the low hESC derivation efficiency might be due to extensive proliferation of trophoblast (TE) cells which could interfere with ICM proliferation. We therefore developed a methodology to minimize TE cell proliferation by culturing ICM in a feeder-free system for 3 days before transferring them onto feeder cells. RESULTS: This minimized trophoblast cell proliferation (MTP) technique could be successfully used to derive hESCs from normal, abnormal, and frozen-thawed embryos with better derivation efficiency of more than 50% (range 50-100%; median 70%). CONCLUSIONS: We successfully developed a better hESC derivation methodology using the "MTP" culture system. This methodology can be effectively used to derive hESCs from both normal and abnormal embryos under feeder-free conditions with higher efficiency when compared with other methodologies. With this methodology, large-scale production of clinical-grade hESCs is feasible.