Ethanol alters proliferation and differentiation of normal and chromosomally abnormal human embryonic stem cell-derived neurospheres.

Ethanol is a powerful substance and, when consumed during pregnancy, has significant psychoactive and developmental effects on the developing fetus. These abnormalities include growth retardation, neurological deficits, and behavioral and cognitive deficiencies, commonly referred to as fetal alcohol spectrum disorder. The effect of ethanol has been reported to affect cellular development on the embryonic level, however, not much is known about mutations contributing to the influence of ethanol. The purpose of our study was to determine if mutation contribute to changes in differentiation patterning, cell-cycle regulatory gene expression, and DNA methylation in human embryonic stem cells after ethanol exposure. We exposed human embryonic stem cells (with and without know DNA mutations) to a low concentration (20 mM) of ethanol and measured neurosphere proliferation and differentiation, glial protein levels, expression of various cell-cycle genes, and DNA methylation. Ethanol altered cell-cycle gene expression between the two cell lines; however, gene methylation was not affected in ether lines.

GABRB3 gene expression increases upon ethanol exposure in human embryonic stem cells.

Ionotropic receptors are the target for most mood-defining compounds. Chronic exposure to ethanol (EtOH) alters receptor-mediated responses and the numbers of these channels and specific subunits; as well as induces anxiolytic, sedative, and anesthetic activity in the human brain. However, very little is known regarding the effects of EtOH on ionotropic receptor transcription during early human development (preimplantation). Using two separate human embryonic stem cell lines the study shows that low amounts of EtOH (20 mM) alters transcription of the ionotropic subunit GABRB3. Changes in ionotrophic receptor expression influence the central nervous system development and have been shown to produce brain abnormalities in animal models. These results suggest that low concentrations of EtOH can alter ionotropic receptor transcription during early human development (preimplantation), which may be a contributing factor to the neurological phenotypes seen in fetal alcohol spectrum disorder (FASD).

Heat shock proteins, endothelin, and peripheral neuronal injury.

Heat shock proteins (HSP) are important in neuroprotection after a variety of stresses or injuries. Both heat shock proteins and endothelin are upregulated after peripheral nerve injury, but HSP regulation after injury has not been systematically studied in peripheral nerve. The purpose of this study was to examine the regulation of small and large heat shock proteins after injury to rat sciatic nerve. Secondly, using a parallel tissue culture model for the sciatic nerve (PC12 cells), we examined potential regulation of heat shock proteins by endothelin. Western analysis of constricted, mobilized or unperturbed nerve was used to examine HSP abundance after injury. Semiquantitative PCR was used to examine heat shock message levels after nerve injury in the dorsal root ganglia. Cultured undifferentiated and differentiated PC12 cells were treated with endothelin, then western analysis of cytosol- and membrane-enriched fractions of these cells was used to examine heat shock protein regulation after endothelin treatment. Heat shock proteins are expressed at very low levels in unperturbed sciatic nerve. Constriction injury of the nerve results in increased expression of small and large heat shock proteins, but no upregulation of HSP message in corresponding dorsal root ganglia. Endothelin treatment of PC12 does not cause upregulation of heat shock proteins. Together these data show that a broad range of HSP is involved in endogenous response to peripheral nerve injury and deserve further study as potential neuroprotectants. Regulation of heat shock proteins after nerve injury is not likely due to endothelin signaling.

Human embryonic stem cell model of ethanol-mediated early developmental toxicity.

BACKGROUND: Fetal alcohol syndrome is an important clinical problem. Human embryonic stem cells (hESC) have not been widely used to study developmental alcohol toxicity. Here we document the phenotype of hESC exposed to clinically-relevant, low dose ethanol (20mM). METHODS: All cultures were maintained in 3% O2 to reflect normal physiologic conditions. Undifferentiated hESC were expanded with basic fibroblast growth factor (bFGF), with or without ethanol, then differentiated without ethanol. Proliferation and apoptosis in response to ethanol were assayed, and PCR used to examine expression of GABA receptor subunits. Whole cell patch clamping was used to examine GABA(A) receptor function in undifferentiated hESC. Immunocytochemistry and western blotting were used to follow differentiation of early neurons, astrocytes, and oligodendrocytes, PRINCIPAL FINDINGS: Exposure to 20mM ethanol resulted in larger colonies of undifferentiated hESC despite an increase in apoptosis, because proliferation of the undifferentiated cells (and neuroblasts) was significantly increased. Differentiation of hESC (following a week of ethanol exposure) resulted in decreased expression of GFAP (by western) compared to unexposed cells, suggesting that astrocyte differentiation was reduced, while markers of oligodendrocyte and neuron differentiation were unchanged. At the message level, undifferentiated hESC express all GABA(A) receptor subunits, but functional receptors were not found by whole cell patch clamping. CONCLUSION: Our results in hESC suggest a complex mix of ethanol-induced phenotypic changes when ethanol exposure occurs very early in development. Not only increased apoptosis, but inappropriate proliferation and loss of trophic astrocytes could result from low-dose ethanol exposure very early in development. More generally, these studies support a role for hESC in developing hypotheses and focusing questions to complement animal studies of developmental toxicities.

Lectins identify glycan biomarkers on glioblastoma-derived cancer stem cells.

Glioblastoma (GBM) is a highly aggressive primary brain tumor with a poor prognosis. Despite aggressive therapy with surgery, radiotherapy, and chemotherapy, nearly all patients succumb to disease within 2 years. Several studies have supported the presence of stem-like cells in brain tumor cultures that are CD133-positive, are capable of self-renewal, and give rise to all cell types found within the tumor, potentially perpetuating growth. CD133 is a widely accepted marker for glioma-derived cancer stem cells; however, its reliability has been questioned, creating a need for other identifiers of this biologically important subpopulation. We used a panel of 20 lectins to identify differences in glycan expression found in the glycocalyx of undifferentiated glioma-derived stem cells and differentiated cells that arise from them. Fluorescently labeled lectins that specifically recognize α-N-acetylgalactosamine (GalNAc) and α-N-acetylglucosamine (GlcNAc) differentially bound to the cell surface based on the state of cellular differentiation. GalNAc and GlcNAc were highly expressed on the surface of undifferentiated cells and showed markedly reduced expression over a 12-day duration of differentiation. Additionally, the GalNAc-recognizing lectin Dolichos biflorus agglutinin was capable of specifically selecting and sorting glioma-derived stem cell populations from an unsorted tumor stock and this subpopulation had proliferative properties similar to CD133(+) cells in vitro and also had tumor-forming capability in vivo. Our preliminary results on a single cerebellar GBM suggest that GalNAc and GlcNAc are novel biomarkers for identifying glioma-derived stem cells and can be used to isolate cancer stem cells from unsorted cell populations, thereby creating new cell lines for research or clinical testing.

Low ethanol concentration alters CHRNA5 RNA levels during early human development.

Alcohol use is common and consumption during pregnancy has been shown to lead to a myriad of physical and neurologic abnormalities commonly referred to as fetal alcohol spectrum disorder. Substance addiction, which includes alcohol, has been shown to involve the major nicotinic acetylcholine receptor subunit CHRNA5. Using human embryonic stem cells as a model of early human development, we show that low concentrations of ethanol (20mM) can alter the expression of CHRNA5. Changes in CHRNA5 expression is linked to altered GABA and NMDA receptor expression, as well as abnormal development of the frontal cortex. These results suggest that alcohol exposure can alter early neurologic development, which may favor addiction and other developmental abnormalities in unborn children.

Heparin binding epidermal growth factor-like growth factor and PD169316 prevent apoptosis in mouse embryonic stem cells.

Apoptosis or programmed cell death is an important outcome of cell fate and is influenced by several factors. Heparin-binding epidermal growth factor-like growth factor (HB-EGF) is a member of the EGF family of growth factors and is synthesized as a membrane-associated precursor molecule (proHB-EGF). Under stressful conditions proHB-EGF is proteolytically cleaved and released as a soluble ligand (sHB-EGF) that activates the EGF receptor. We show that antibody against CD9, a membrane tetraspanin, induces apoptosis in mouse embryonic stem cells through the activation of specific EGF receptor residues (Y-1148 and Y-1173), caspase-3 and MAPK signalling. HB-EGF and the p38 inhibitor PD169316 act in a pro-survival manner by perturbing phosphorylation of EGFR Y-1173, suggesting its importance in inducing apoptosis. Caspase-3 activation was attenuated in the presence of HB-EGF and PD169316. Furthermore, HB-EGF and PD169316 prevent p38 phosphorylation while promoting the phosphorylation of the pro-survival SAPK/JNK and ERK. These results suggest a role for CD9 as an endogenous suppressor of apoptosis, an effect that is mimicked by HB-EGF and PD169316.

Activin a efficiently specifies definitive endoderm from human embryonic stem cells only when phosphatidylinositol 3-kinase signaling is suppressed.

Human ESCs (hESCs) respond to signals that determine their pluripotency, proliferation, survival, and differentiation status. In this report, we demonstrate that phosphatidylinositol 3-kinase (PI3K) antagonizes the ability of hESCs to differentiate in response to transforming growth factor beta family members such as Activin A and Nodal. Inhibition of PI3K signaling efficiently promotes differentiation of hESCs into mesendoderm and then definitive endoderm (DE) by allowing them to be specified by Activin/Nodal signals present in hESC cultures. Under conditions where hESCs are grown in mouse embryo fibroblast-conditioned medium under feeder-free conditions, approximately 70%-80% are converted into DE following 5 days of treatment with inhibitors of the PI3K pathway, such as LY 294002 and AKT1-II. Microarray and quantitative polymerase chain reaction-based gene expression profiling demonstrates that definitive endoderm formation under these conditions closely parallels that following specification with elevated Activin A and low fetal calf serum (FCS)/knockout serum replacement (KSR). Reduced insulin/insulin-like growth factor (IGF) signaling was found to be critical for cell fate commitment into DE. Levels of insulin/IGF present in FCS/KSR, normally used to promote self-renewal of hESCs, antagonized differentiation. In summary, we show that generation of hESC-DE requires two conditions: signaling by Activin/Nodal family members and release from inhibitory signals generated by PI3K through insulin/IGF. These findings have important implications for our understanding of hESC self-renewal and early cell fate decisions.