Human Embryonic Stem Cell Proliferation and Differentiation as Parameters to Evaluate Developmental Toxicity

In vitro models based on embryonic stem cells (ESC) are highly promising for improvement of predictive toxicology screening in humans. After the successful validation of embryonic stem cell test (EST) in 2001; concerns have been raised on the usage of mouse ESC and also the morphological evaluation of beating cell clusters. This requires specialized skill-sets and is highly prone to misjudgement and false positive results. To overcome these limitations, we undertook the present study incorporating improvisations over the conventional EST. Here, we explored the potential of a human ESC (hESC)-based assay to evaluate the potential toxicity of penicillin-G, caffeine, and hydroxyurea. Drug treatment inhibited hESC adhesion and substantially altered the morphology and viability (similar to 50%) of embryoid bodies (EBs). Flow cytometry analysis not only showed a significant increase of apoptotic cells in the highest doses but also induced a diverse pattern in DNA content and cell cycle distribution relative to control. Both semi-quantitative and quantitative RT-PCR studies revealed a selective down regulation of markers associated with stemness (Nanog, Rex1, SOX-2, and hTERT); cardiac mesoderm (Cripto1, MEF-2C, and Brachyury); hepatic endoderm (AFP, HNF-3 beta, HNF-4 alpha, GATA-4, and SOX-17); and neuroectoderm (Nestin, SOX-1, NURR1, NEFH, Synaptophysin, TH, and Olig2) in a drug as well as dose dependent manner indicating abnormal differentiation. Furthermore, a decrease in the expression of AFP and GFAP proteins followed by a dose-dependent reduction in the levels of hCG-beta, progesterone-II, and estradiol hormones was demonstrated by immunocytochemistry and ECLIA, respectively. This new and unique approach comprising of DNA cell cycle analysis, germ layer-specific marker expression and hormone levels as endpoints might offer a clinically relevant and commercially viable alternative for predicting in vivo developmental toxicity. J. Cell. Physiol. 226: 1583-1595, 2011. (C) 2010 Wiley-Liss, Inc.