Derivation of high-purity definitive endoderm from human parthenogenetic stem cells using an in vitro analog of the primitive streak.

Human parthenogenetic stem cells (hpSCs) are pluripotent stem cells with enormous potential as cell sources for cell-based therapies: hpSCs may have histocompatibilty advantages over human embryonic stem cells (hESCs) and derivation of hpSCs does not require viable blastocyst destruction. For translation of all pluripotent stem cell-based therapies, derivation of differentiated cell products that are not contaminated with undifferentiated cells is a major technical roadblock. We report here a novel method to derive high-purity definitive endoderm (DE) from hpSCs, based on reproducing features of the normal human embryonic microenvironment. The method mimics the developmental process of transition through a primitive streak, using a differentiation device that incorporates a three-dimensional extracellular matrix (ECM) combined with a porous membrane. Treatment of undifferentiated hpSCs above the membrane results an epithelial-to-mesenchymal transition (EMT); thus, responsive cells acquire the ability to migrate through the membrane into the ECM, where they differentiate into DE. Importantly, the resultant DE is highly purified, and is not contaminated by undifferentiated cells, as assessed by OCT4 expression using immunocytochemistry and flow cytometry. The functional properties of the DE are also preserved by the process: DE differentiated in the device can generate a highly enriched population of hepatocyte-like cells (HLCs) characterized by expression of hepatic lineage markers, indocyanine green clearance, glycogen storage, cytochrome P450 activity, and engraftment in the liver after transplantation into immunodeficient mice. The method is broadly applicable and we obtained purified DE using hESCs, as well as several hpSC lines. The novel method described here represents a significant step toward the efficient generation of high-purity cells derived from DE, including hepatocytes and pancreatic endocrine cells, for use in regenerative medicine and drug discovery, as well as a platform for studying cell fate specification and behavior during development.

Derivation of human parthenogenetic stem cell lines.

Pluripotent stem cells (PSCs) derived from parthenogenetically activated human oocytes demonstrate the typical characteristics displayed by human embryonic stem cells (hESCs) including infinite division and in vitro and in vivo differentiation into cells of all germ lineages. Different activation techniques allow the creation of either human leukocyte antigen (HLA) heterozygous human parthenogenetic stem cell (hpSC) lines, which are HLA-matched/histocompatible with the oocyte donor, or HLA-homozygous hpSC lines, which may be histocompatible to significant segments of the human population. This immune-matching advantage, combined with the advantage of derivation from nonviable human embryos that originate from unfertilized parthenogenetically activated oocytes, makes hpSCs a promising source of PSCs for cell-based transplantation therapy. This chapter describes two approaches for the parthenogenetic activation of human oocytes, their cultivation to the blastocyst stage, and the subsequent derivation of PSC lines.

Human parthenogenetic stem cells produce enriched populations of definitive endoderm cells after trichostatin A pretreatment.

Human parthenogenetic stem cells (hpSC) hold great promise as a source of pluripotent stem cells for cell-based transplantation therapy due to their ethical method of derivation as well as the enhanced capacity for immunomatching with significant segments of the human population. We report here the directed differentiation of hpSC to produce enriched populations of definitive endoderm. Moreover, we find that treatment of undifferentiated hpSC by trichostatin A (TSA) before applying the directed differentiation protocol significantly increases the proportion of definitive endoderm cells in the final population. TSA-pretreated as well as non-TSA-treated hpSC undergoing differentiation toward definitive endoderm demonstrate a similar temporal sequence of gene expression to that which occurs in the course of definitive endoderm differentiation during vertebrate gastrulation and for differentiation of hESCs to definitive endoderm. Creation of the definitive endoderm lineages from hpSC represents the critical first step toward the development of hpSC-based cellular therapies for diseases of the liver or pancreas.

Equivalence of conventionally-derived and parthenote-derived human embryonic stem cells.

BACKGROUND: As human embryonic stem cell (hESC) lines can be derived via multiple means, it is important to determine particular characteristics of individual lines that may dictate the applications to which they are best suited. The objective of this work was to determine points of equivalence and differences between conventionally-derived hESC and parthenote-derived hESC lines (phESC) in the undifferentiated state and during neural differentiation. METHODOLOGY/PRINCIPAL FINDINGS: hESC and phESC were exposed to the same expansion conditions and subsequent neural and retinal pigmented epithelium (RPE) differentiation protocols. Growth rates and gross morphology were recorded during expansion. RTPCR for developmentally relevant genes and global DNA methylation profiling were used to compare gene expression and epigenetic characteristics. Parthenote lines proliferated more slowly than conventional hESC lines and yielded lower quantities of less mature differentiated cells in a neural progenitor cell (NPC) differentiation protocol. However, the cell lines performed similarly in a RPE differentiation protocol. The DNA methylation analysis showed similar general profiles, but the two cell types differed in methylation of imprinted genes. There were no major differences in gene expression between the lines before differentiation, but when differentiated into NPCs, the two cell types differed in expression of extracellular matrix (ECM) genes. CONCLUSIONS/SIGNIFICANCE: These data show that hESC and phESC are similar in the undifferentiated state, and both cell types are capable of differentiation along neural lineages. The differences between the cell types, in proliferation and extent of differentiation, may be linked, in part, to the observed differences in ECM synthesis and methylation of imprinted genes.

Repression of sestrin family genes contributes to oncogenic Ras-induced reactive oxygen species up-regulation and genetic instability.

Oncogenic mutations within RAS genes and inactivation of p53 are the most common events in cancer. Earlier, we reported that activated Ras contributes to chromosome instability, especially in p53-deficient cells. Here we show that an increase in intracellular reactive oxygen species (ROS) and oxidative DNA damage represents a major mechanism of Ras-induced mutagenesis. Introduction of oncogenic H- or N-Ras caused elevated intracellular ROS, accumulation of 8-oxo-2'-deoxyguanosine, and increased number of chromosome breaks in mitotic cells, which were prevented by antioxidant N-acetyl-L-cysteine. By using Ras mutants that selectively activate either of the three major targets of Ras (Raf, RalGDS, and phosphatidylinositol-3-kinase) as well as dominant-negative Rac1 and RalA mutants and inhibitors of mitogen-activated protein kinase (MAPK)/extracellular signal-regulated kinases kinase-1 and p38 MAPKs, we have shown that several Ras effectors independently mediate ROS up-regulation. Introduction of oncogenic RAS resulted in repression of transcription from sestrin family genes SESN1 and SESN3, which encode antioxidant modulators of peroxiredoxins. Inhibition of mRNAs from these genes in control cells by RNA interference substantially increased ROS levels and mutagenesis. Ectopic expression of SESN1 and SESN3 from lentiviral constructs interfered with Ras-induced ROS increase, suggesting their important contribution to the effect. The stability of Ras-induced increase in ROS was dependent on a p53 function: in the p53-positive cells displaying activation of p53 in response to Ras, only transient (4-7 days) elevation of ROS was observed, whereas in the p53-deficient cells the up-regulation was permanent. The reversion to normal ROS levels in the Ras-expressing p53-positive cells correlated with up-regulation of p53-responsive genes, including reactivation of SESN1 gene. Thus, changes in expression of sestrins can represent an important determinant of genetic instability in neoplastic cells showing simultaneous dysfunctions of Ras and p53.

The antioxidant function of the p53 tumor suppressor.

It is widely accepted that the p53 tumor suppressor restricts abnormal cells by induction of growth arrest or by triggering apoptosis. Here we show that, in addition, p53 protects the genome from oxidation by reactive oxygen species (ROS), a major cause of DNA damage and genetic instability. In the absence of severe stresses, relatively low levels of p53 are sufficient for upregulation of several genes with antioxidant products, which is associated with a decrease in intracellular ROS. Downregulation of p53 results in excessive oxidation of DNA, increased mutation rate and karyotype instability, which are prevented by incubation with the antioxidant N-acetylcysteine (NAC). Dietary supplementation with NAC prevented frequent lymphomas characteristic of Trp53-knockout mice, and slowed the growth of lung cancer xenografts deficient in p53. Our results provide a new paradigm for a nonrestrictive tumor suppressor function of p53 and highlight the potential importance of antioxidants in the prophylaxis and treatment of cancer.

Activation of Ras-Ral pathway attenuates p53-independent DNA damage G2 checkpoint.

Earlier we have found that in p53-deficient cells the expression of activated Ras attenuates the DNA damage-induced arrest in G(1) and G(2). In the present work we studied Ras-mediated effects on the G(2) checkpoint in two human cell lines, MDAH041 immortalized fibroblasts and Saos-2 osteosarcoma cells. The transduction of the H-Ras mutants that retain certain functions (V12S35, V12G37, and V12C40 retain the ability to activate Raf or RalGDS or phosphatidylinositol 3-kinase, respectively) as well as the activated or dominant-negative mutants of RalA (V23 and N28, respectively) has revealed that the activation of Ras-RalGEFs-Ral pathway was responsible for the attenuation of the G(2) arrest induced by ethyl metanesulfonate or doxorubicin. Noteworthy, the activated RalA V23N49 mutant, which cannot interact with RLIP76/RalBP1 protein, one of the best studied Ral effectors, retained the ability to attenuate the DNA damage-induced G(2) arrest. Activation of the Ras-Ral signaling affected neither the level nor the intracellular localization of cyclin B1 and CDC2 but interfered with the CDC2 inhibitory phosphorylation at Tyr(15) and the decrease in the cyclin B/CDC2 kinase activity in damaged cells. The revealed function of the Ras-Ral pathway may contribute to the development of genetic instability in neoplastic cells.