Trolox‐induced cardiac differentiation is mediated by the inhibition of Wnt/β‐catenin signaling in human embryonic stem cells

Cardiac differentiation of human pluripotent stem cells may be induced under chemically defined conditions, wherein the regulation of Wnt/β‐catenin pathway is often desirable. Here, we examined the effect of trolox, a vitamin E analog, on the cardiac differentiation of human embryonic stem cells (hESCs). 6‐Hydroxy‐2,5,7,8‐tetramethylchromane‐2‐carboxylic acid (Trolox) significantly enhanced cardiac differentiation in a time‐ and dose‐dependent manner after the mesodermal differentiation of hESCs. Trolox promoted hESC cardiac differentiation through its inhibitory activity against the Wnt/β‐catenin pathway. This study demonstrates an efficient cardiac differentiation method and reveals a novel Wnt/β‐catenin regulator.     

Nandrolone and stanozolol induce leydig cell tumor proliferation through an estrogen‐dependent mechanism involving IGF‐I system

Several substances such as anabolic androgenic steroids (AAS), peptide hormones like insulin‐like growth factor‐I (IGF‐I), aromatase inhibitors and estrogen antagonists are offered via the Internet, and are assumed without considering the potential deleterious effects that can be caused by their administration. In this study we aimed to determine if nandrolone and stanozolol, two commonly used AAS, could have an effect on Leydig cell tumor proliferation and if their effects could be potentiated by the concomitant use of IGF‐I. Using a rat Leydig tumor cell line, R2C cells, as experimental model we found that nandrolone and stanozolol caused a dose‐dependent induction of aromatase expression and estradiol (E2) production. When used in combination with IGF‐I they were more effective than single molecules in inducing aromatase expression. AAS exhibited estrogenic activity and induced rapid estrogen receptor (ER)‐dependent pathways involving IGF1R, AKT, and ERK1/2 phosphorylation. Inhibitors for these kinases decreased AAS‐dependent aromatase expression. Up‐regulated aromatase levels and related E2 production increased cell proliferation as a consequence of increased cyclin E expression. The observation that ER antagonist ICI182,780 was also able to significantly reduce ASS‐ and AAS + IGF‐induced cell proliferation, confirmed a role for estrogens in AAS‐dependent proliferative effects. Taken together these data clearly indicate that the use of high doses of AAS, as it occurs in doping practice, enhances Leydig cell proliferation, increasing the risk of tumor development. This risk is higher when AAS are used in association with IGF‐I. To our knowledge this is the first report directly associating AAS and testicular cancer. J. Cell. Physiol. 227: 2079–2088, 2012. © 2011 Wiley Periodicals, Inc.     

Modulation of tumorigenesis and oestrogen receptor‐α expression by cell culture conditions in a stem cell‐derived breast epithelial cell line

Background information. The common phenotypes of cancer and stem cells suggest that cancers arise from stem cells. Oestrogen is one of the few most important determinants of breast cancer, as shown by several lines of convincing evidence. We have previously reported a human breast epithelial cell type (Type 1 HBEC) with stem cell characteristics and ERα (oestrogen receptor α) expression. A tumorigenic cell line, M13SV1R2, was developed from this cell type after SV40 (simian virus 40) large T‐antigen transfection and X‐ray irradiation. The cell line, however, was not responsive to oestrogen for cell growth or tumour development. In the present study, we tested the hypothesis that deprivation of growth factors and hormones may change the tumorigenicity and oestrogen response of this cell line. Results. The M13SV1R2 cells lost their tumorigenicity after culturing in a growth factor/hormone‐deprived medium for >10 passages (referred to as R2d cells) concomitant with the expression of two tumour suppressor genes, namely those coding for maspin and α6 integrin. However, these cells acquired oestrogen responsiveness in cell growth and tumour development. By immunocytochemistry, Western blotting and flow cytometry analysis, oestrogen treatment of R2d cells was found to induce many important effects related to breast carcinogenesis, namely: (i) the emergence of a subpopulation of cells expressing CD44^+/high/CD24^?/low breast tumour stem cell markers; (ii) the induction of EMT (epithelial‐to‐mesenchymal transition); (iii) the acquisition of metastatic ability; and (iv) the expression of COX‐2 (cyclo‐oxygenase‐2) through a CD44‐mediated mechanism. Conclusion. An oestrogen‐responsive cell line with ERα and CD44⁺/CD24^?/low expression can be derived from breast epithelial stem cells. The tumorigenicity and oestrogen response of these cells could depend on the cell culture conditions. The findings of this study have implications in regard to the origins of (1) ERα‐positive breast cancers, (2) CD44⁺/CD24^?/low breast tumour stem cells and (3) the metastatic ability of breast cancer.     

Oestrogen regulates proliferation and differentiation of human islet‐derived precursor cells through oestrogen receptor alpha

E2 (oestradiol‐17β) is an important hormone that regulates various cell functions including insulin production. hIPCs (human islet‐derived precursor cells) are capable of proliferating and differentiating into cells that secrete insulin in response to glucose in vivo and in vitro. However, the effect of E2 on hIPCs is currently unclear. In this study, we found that ERα (oestrogen receptor alpha), but not ERβ, was expressed on hIPCs, and E2 promoted the proliferation and inhibited the differentiation of adult hIPCs. Although fetal hIPCs also express ERα, no effect of E2 on the fetal hIPCs was observed, suggesting differing roles of E2 at different stages of pancreatic development. This study indicates that E2 may be one of the key factors that control the turnover of adult pancreatic β cells by regulating the proliferation and differentiation of adult hIPCs through ERα.     

NDV‐D90 inhibits 17β‐estradiol‐mediated resistance to apoptosis by differentially modulating classic and nonclassic estrogen receptors in breast cancer cells

Newcastle disease virus (NDV) is endowed with the oncolytic ability to kill tumor cells, while rarely causing side effects in normal cells. Both estrogen receptor α (ERα) and the G protein estrogen receptor (GPER) modulate multiple biological activities in response to estrogen, including apoptosis in breast cancer (BC) cells. Here, we investigated whether NDV‐D90, a novel strain isolated from natural sources in China, promoted apoptosis by modulating the expression of ERα or the GPER in BC cells exposed to 17β‐estradiol (E2). We found that NDV‐D90 significantly killed the tumor cell lines MCF‐7 and BT549 in a time‐ and dose‐dependent manner. We also found that NDV‐D90 exerted its effects on the two cell lines mainly by inducing apoptosis but not necrosis. NDV‐D90 induced apoptosis via the intrinsic and extrinsic signaling pathways in MCF‐7 cells (ER‐positive cells) during E2 exposure not only by disrupting the E2/ERα axis and enhancing GPER expression but also by modulating the expression of several apoptosis‐related proteins through ERα‐and GPER‐independent processes. NDV‐D90 promoted apoptosis via the intrinsic signaling pathway in BT549 cells (ER‐negative cells), possibly by impairing E2‐mediated GPER expression. Furthermore, NDV‐D90 exerted its antitumor effects in vivo by inducing apoptosis. Overall, these results demonstrated that NDV‐D90 promotes apoptosis by differentially modulating the expression of ERα and the GPER in ER‐positive and negative BC cells exposed to estrogen, respectively, and can be utilized as an effective approach to treating BC.     

Proneural bHLH neurogenin 2 differentially regulates Nurr1-induced dopamine neuron differentiation in rat and mouse neural precursor cells in vitro

Roles of Nurr1 and neurogenin 2 (Ngn2) have been shown in midbrain dopamine (DA) neuron development. We present here rat and mouse species-dependent differences of Nurr1 and Ngn2 actions in DA neuron differentiation. Nurr1 exogene expression caused an efficient generation of tyrosine hydroxylase (TH)-positive DA cells from rat neural precursor cells (NPCs). Nurr1-induced TH+ cell yields were low and highly variable depending on the origins of NPCs in mouse cultures. Coexpression of Ngn2 repressed Nurr1-induced generation of TH+ cells in rat cultures. In clear contrast, a robust enhancement in Nurr1-induced DA cell yields was observed in mouse NPCs by Ngn2. These findings imply that DA neurons may develop differently in the midbrains of these two species.     

Both GPER and membrane oestrogen receptor‐α activation protect ventricular remodelling in 17β oestradiol‐treated ovariectomized infarcted rats

Clinical and experimental studies have established that gender is a factor in the development of ventricular hypertrophy. We investigated whether the attenuated hypertrophic effect of oestradiol was via activation of phosphatidylinositol 3‐kinase (PI3K)/Akt/endothelial nitric oxide synthase (eNOS) through non‐genomic action. Twenty‐four hours after coronary ligation, female Wistar rats were randomized into control, subcutaneous oestradiol treatment or a G‐protein coupled oestrogen receptor (GPER) agonist, G‐1 and treated for 4 weeks starting from 2 weeks after bilateral ovariectomy. Ventricular hypertrophy assessed by cardiomyocyte size after infarction was similarly attenuated by oestradiol or G‐1 in infarcted rats. The phosphorylation of Akt and eNOS was significantly decreased in infarcted rats and restored by oestradiol and G‐1, implying the GPER pathway in this process. Oestradiol‐induced Akt phosphorylation was not abrogated by G‐15 (a GPER blocker). Akt activation was not inhibited by actinomycin D. When a membrane‐impermeable oestrogen‐albumin construct was applied, similar responses in terms of eNOS activation to those of oestradiol were achieved. Furthermore, PPT, an ERα receptor agonist, activated the phosphorylation of Akt and eNOS. Thus, membrane ERα receptor played a role in mediating the phosphorylation of Akt and eNOS. The specific PI3K inhibitor, LY290042, completely abolished Akt activation and eNOS phosphorylation in infarcted hearts treated with either oestradiol or oestradiol + G‐15. These data support the conclusions that oestradiol improves ventricular remodelling by both GPER‐ and membrane‐bound ERα‐dependent mechanisms that converge into the PI3K/Akt/eNOS pathway, unveiling a novel mechanism by which oestradiol regulates pathological cardiomyocyte growth after infarction.     

Calpain‐2 plays a pivotal role in the inhibitory effects of propofol against TNF‐α‐induced autophagy in mouse hippocampal neurons

Calpains are calcium‐dependent proteases and play critical roles in neuronal autophagy induced by inflammation. Propofol has been reported to exert anti‐inflammatory effects in neurons. We aimed to identify whether and how propofol‐modulated calpain activity and neuron autophagy in response to tumour necrosis factor‐α (TNF‐α). Mouse hippocampal neurons were pre‐treated with propofol and exposed to TNF‐α. Autophagy was evaluated by fluorescent autophagy assay and by measuring LC3I and LC3II expression. Intracellular calcium concentration was measured by fluorescent assay. Calpain activation was measured by calpain activity assay. The protein expression of intracellular signalling molecules was detected by Western blot analysis. Compared with untreated control neurons, 40 ng/mL TNF‐α treatment for 2 hours induced neuron autophagy, which was attenuated by 25 μmol/L propofol. TNF‐α induced intracellular calcium accumulation, the phosphorylation of calcium/calmodulin‐dependent protein kinase II (CAMK II) and calpain‐2, calpain activation and lysosomal cathepsin B release as well as tyrosine kinase receptor B (TrkB) truncation. These effects were alleviated by propofol, calcium chelator, CAMK II inhibitor, calpain‐2 inhibitor, calpain‐2 siRNA transfection and N‐Methyl‐d ‐aspartic acid (NMDA) receptor antagonist. Propofol, via NMDA receptor, inhibited TNF‐α‐mediated hippocampal neuron autophagy. The mechanism may involve calcium and calcium‐dependent signalling pathway, especially CAMK II and calpain‐2.     

Induction of neuronal activation by femtosecond‐pulsed laser irradiation and its potential application for amyloid‐β–induced toxicity assessment

Manipulating neural activity is crucial for studying the neural connectivity and the pathophysiology of neurodegenerative disease. Among various techniques for neural activation, direct optical stimulation method with femtosecond‐pulsed laser is simple and can be specifically applied on a single neuron. Brief irradiation of femtosecond laser pulses on a neuron elevates intracellular calcium, and it propagates to adjacent neurons. However, the mechanisms of laser‐induced neural activation are still unclear. In this report, we have elucidated the mechanism of laser‐induced neural activation which could be mediated by superoxide, specifically blocked by diphenyleneiodonium chloride, and depletion in intracellular calcium storage. Furthermore, we also showed that the propagation of calcium initiated by laser stimulation is dependent on the presence of extracellular calcium as well as electrical and chemical synapses. We verified the applicability of such mechanism for the assessment of neuronal functionality, by measuring calcium elevation, intracellular calcium propagation, ROS increase, and performing cell death assay in vehicle and Aβ‐treated neurons. This work suggests promising applications of the potential for implementing such laser‐induced neural activation for rapid and reliable drug screening.

     

The role of β‐adrenergic receptors and p38MAPK signaling pathways in physiological processes of cardiosphere‐derived cells

The effects of β adrenergic receptors (β‐ARs) and p38 mitogen‐activated protein kinases (MAPK) pathways on cardiosphere‐derived cells (CDCs) are largely unknown. This study aimed to investigate the roles of β‐ARs and p38MAPK pathways on the proliferation, apoptosis, and differentiation capacity of CDCs. The CDCs were treated with β1‐AR blocker (Met group), β2‐AR antagonist (ICI group), and p38MAPK inhibitor (SB group), non‐selective β‐AR blocker (PRO group), and β‐AR agonist (ISO group). The viability, apoptotic rate and differentiation status of CDCs were determined by MST‐1 assay, flow cytometery, and Western blot, respectively. The CDCs viability significantly reduced in ICI group (all P < 0.05), and SB group had a significant high viability after 48 h treatment (P < 0.05). Compared with control group, all treated groups had a low apoptotic rate. After treatment for 72 h, ISO treatment elevated the expression of Nkx2.5, and could partially or fully attenuate the inhibitory effects of β‐AR antagonists and/or p38MAPK inhibitor. A similar overall trend of protein expression levels among all groups could be observed between protein pairs of cTnT and β1‐AR as well as c‐Kit and β2‐AR, respectively. These results suggested that β‐ARs and p38MAPK signaling pathways play crucial roles in the proliferation and differentiation of CDCs. Our findings should be helpful for better understanding the molecular mechanism underlying the physiological processes of CDCs.     

PI3K‐p110‐alpha‐subtype signalling mediates survival,proliferation and neurogenesis of cortical progenitor cells via activation of mTORC2

Development of the cerebral cortex is controlled by growth factors among which transforming growth factor beta (TGFβ) and insulin‐like growth factor 1 (IGF1) have a central role. The TGFβ‐ and IGF1‐pathways cross‐talk and share signalling molecules, but in the central nervous system putative points of intersection remain unknown. We studied the biological effects and down‐stream molecules of TGFβ and IGF1 in cells derived from the mouse cerebral cortex at two developmental time points, E13.5 and E16.5. IGF1 induces PI3K, AKT and the mammalian target of rapamycin complexes (mTORC1/mTORC2) primarily in E13.5‐derived cells, resulting in proliferation, survival and neuronal differentiation, but has small impact on E16.5‐derived cells. TGFβ has little effect at E13.5. It does not activate the PI3K‐ and mTOR‐signalling network directly, but requires its activity to mediate neuronal differentiation specifically at E16.5. Our data indicate a central role of mTORC2 in survival, proliferation as well as neuronal differentiation of E16.5‐derived cortical cells. mTORC2 promotes these cellular processes and is under control of PI3K‐p110‐alpha signalling. PI3K‐p110‐beta signalling activates mTORC2 in E16.5‐derived cells but it does not influence cell survival, proliferation and differentiation. This finding indicates that different mTORC2 subtypes may be implicated in cortical development and that these subtypes are under control of different PI3K isoforms.

     

ChIP‐Seq of ERα and RNA polymerase II defines genes differentially responding to ligands

We used ChIP‐Seq to map ERα‐binding sites and to profile changes in RNA polymerase II (RNAPII) occupancy in MCF‐7 cells in response to estradiol (E2), tamoxifen or fulvestrant. We identify 10 205 high confidence ERα‐binding sites in response to E2 of which 68% contain an estrogen response element (ERE) and only 7% contain a FOXA1 motif. Remarkably, 596 genes change significantly in RNAPII occupancy (59% up and 41% down) already after 1 h of E2 exposure. Although promoter proximal enrichment of RNAPII (PPEP) occurs frequently in MCF‐7 cells (17%), it is only observed on a minority of E2‐regulated genes (4%). Tamoxifen and fulvestrant partially reduce ERα DNA binding and prevent RNAPII loading on the promoter and coding body on E2‐upregulated genes. Both ligands act differently on E2‐downregulated genes: tamoxifen acts as an agonist thus downregulating these genes, whereas fulvestrant antagonizes E2‐induced repression and often increases RNAPII occupancy. Furthermore, our data identify genes preferentially regulated by tamoxifen but not by E2 or fulvestrant. Thus (partial) antagonist loaded ERα acts mechanistically different on E2‐activated and E2‐repressed genes.     

Cytoskeleton‐associated proteins are enriched in human embryonic‐stem cell‐derived neuroectodermal spheres

The ability to generate neural lineages from human embryonic stem cells (hESCs) in a controlled manner would further investigation of human neurogenesis and development of potential cell therapeutic applications to treat neurological diseases; however, generating such neural stem cells (NSCs) remains a challenge. In an attempt to characterize the cellular mechanisms involved in hESC differentiation into neuroprogenitor cells, we performed 2‐DE using protein extracts from hESC‐derived embryoid bodies (EBs) and neuroectodermal spheres (NESs) bearing neuroprogenitors. Of 47 differentially expressed protein spots, 28 nonredundant spots were shown to be upregulated in the NESs; these protein spots included neurogenesis‐related proteins (TAF1, SEPT2, NPH3, and CRABP), as expected. Interestingly, 6 of these 28 protein spots were cytoskeleton‐associated proteins (CSAP) such as Fascin‐1, Cofilin‐1, and Stathmin‐1. Western‐blot analyses confirmed the increased levels of these proteins in the NESs. Furthermore, immunostaining analysis showed that both Fascin‐1 and Stathmin‐1 were preferentially expressed in the inner rims of neural rosettes, which are characteristic features of neuroprogenitors in culture. We also confirmed prominent expression of Fascin‐1 in (sub‐)ventricular zone in E15.5 mouse fetal brain. Our results suggest that, in addition to the induction of those genes involved in neural development, hESC differentiation into the NES is associated with a marked reorganization of the cellular cytoskeleton.     

Cross talk between glucocorticoid and estrogen receptors occurs at a subset of proinflammatory genes

Glucocorticoids exert potent anti-inflammatory effects by repressing proinflammatory genes. We previously demonstrated that estrogens repress numerous proinflammatory genes in U2OS cells. The objective of this study was to determine if cross talk occurs between the glucocorticoid receptor (GR) and estrogen receptor (ER)α. The effects of dexamethasone (Dex) and estradiol on 23 proinflammatory genes were examined in human U2OS cells stably transfected with ERα or GR. Three classes of genes were regulated by ERα and/or GR. Thirteen genes were repressed by both estradiol and Dex (ER/GR-repressed genes). Five genes were repressed by ER (ER-only repressed genes), and another five genes were repressed by GR (GR-only repressed genes). To examine if cross talk occurs between ER and GR at ER/GR-repressed genes, U2OS-GR cells were infected with an adenovirus that expresses ERα. The ER antagonist, ICI 182780 (ICI), blocked Dex repression of ER/GR-repressed genes. ICI did not have any effect on the GR-only repressed genes or genes activated by Dex. These results demonstrate that ICI acts on subset of proinflammatory genes in the presence of ERα but not on GR-activated genes. ICI recruited ERα to the IL-8 promoter but did not prevent Dex recruitment of GR. ICI antagonized Dex repression of the TNF response element by blocking the recruitment of nuclear coactivator 2. These findings indicate that the ICI-ERα complex blocks Dex-mediated repression by interfering with nuclear coactivator 2 recruitment to GR. Our results suggest that it might be possible to exploit ER and GR cross talk for glucocorticoid therapies using drugs that interact with ERs.     

Delta-like 1 participates in the specification of ventral midbrain progenitor derived dopaminergic neurons

Delta-like 1 (Dlk1), a member of the Delta/Notch protein family, is expressed in the mouse ventral midbrain (VM) as early as embryonic day 11.5 (E11.5) followed by exclusive expression in tyrosine 3-monooxygenase (TH) positive neurons from E12.5 onwards. To further elucidate the yet unknown function of Dlk1 in VM neuron development, we investigated the effect of soluble Dlk1 protein as well as the intrinsic Dlk1 function in the course of VM progenitor expansion and dopaminergic (DA) neuron differentiation in vitro . Dlk1 treatment during expansion increased DA progenitor proliferation and the proportion of NR4A2+ neurons expressing TH after differentiation, whereas Dlk1 treatment during the course of DA precursor differentiation did not alter TH+ neuron counts. In contrast, silencing of endogenously expressed Dlk1 prior to DA precursor differentiation partially prevented the expression of DA neuron markers, which was not accompanied with alteration of overall or local proliferation. Due to the latter finding in combination with the absence of Dlk1 negative DA neurons in differentiated cultures, we suggest that Dlk1 expression might have a permissive effect on DA neuron differentiation in vitro . The study presented here is the first publication identifying Dlk1 effects on ventral midbrain-derived DA precursor differentiation.