Enhanced hematopoietic differentiation toward erythrocytes from murine embryonic stem cells with HepG2-conditioned medium

Quinazoline-2,4(1H,3H)-dione modulates STAT3 and FOXO3a signaling in HepG2 cells

Hepatocellular carcinoma (HCC), the most prominent type of primary liver cancer, often diagnosed late, leading to poor prognosis and limited treatment options. This study investigated the anti-carcinogenic effect of Quinazoline-2,4(1H,3H)-dione (Qd), a quinazoline derivative of natural origin and identified Qd as an effective compound against HCC via STAT3 and FOXO3a signaling. STAT3 and FOXO3a are two well-known molecular drivers of HCC. In silico findings revealed Qd as the potent candidate due to its highly stable interaction with STAT3 and FOXO3a. To validate its anticancer activity, in vitro experiments were conducted on the HepG2 cell line. Qd exerts cytotoxic effect in HepG2 cells with an IC50 value of 26.07 μM, while being non-toxic in WRL-68 cells at a lower concentrations with an IC50 of 326.5 μM. Morphological changes and apoptotic cell death were confirmed using DAPI staining and Live/Dead assay. Qd also induced ROS-mediated mitochondrial damage. Qd upregulated mRNA expressions of pro-apoptotic and necroptotic markers while downregulating anti-apoptotic marker. Accordingly, the protein expression analysis demonstrated increased levels of Bax, Caspase 3, c-PARP, RIPK1, RIPK3 and MLKL, while decreasing Bcl2 and PARP expressions. Gene and protein expression of STAT3 remained at a basal level while FOXO3a gene expression increased significantly at 5 μM Qd concentration. Significant changes were particularly observed at 5 μM Qd concentration in all in vitro experiments. Despite quinazoline compounds have been shown biological and pharmacological effects, the anticancer effect of Qd is elusive till date. These in silico and in vitro findings highlighted Qd as a potent compound for further exploration in HCC therapy by targeting apoptotic and necroptotic cell death pathways.

Tissue inhibitor of metalloproteinase proteins inhibit teratoma growth in mice transplanted with pluripotent stem cells

Pluripotent stem cells (PSCs) can serve as an unlimited cell source for transplantation therapies for treating various devastating diseases, such as cardiovascular diseases, diabetes, and Parkinson's disease. However, PSC transplantation has some associated risks, including teratoma formation from the remaining undifferentiated PSCs. Thus, for successful clinical application, it is essential to ablate the proliferative PSCs before or after transplantation. In this study, neural stem cell-derived conditioned medium (NSC-CM) inhibited the proliferation of PSCs and PSC-derived neural precursor (NP) cells without influencing the potential of PSC-NP cells to differentiate into neurons in vitro and prevented teratoma growth in vivo. Moreover, we found that the NSC-CM remarkably decreased the expression levels of Oct4 and cyclin D1 that Oct4 directly binds to and increased the cleaved-caspase 3-positive cell death through the DNA damage response in PSCs and PSC-NPs. Interestingly, we found that NSCs distinctly secreted the tissue inhibitor of metalloproteinase (TIMP)-1 and TIMP-2 proteins. These proteins suppressed not only the proliferation of PSCs in cell culture but also teratoma growth in mice transplanted with PSCs through inhibition of matrix metalloproteinase (MMP)-2 and MMP-9 activity. Taken together, these results suggest that the TIMP proteins may improve the efficacy and safety of the PSC-based transplantation therapy.

Promotion of Erythropoietic Differentiation in Hematopoietic Stem Cells by SOCS3 Knock-Down

Suppressor of cytokine signaling 3 (SOCS3) plays an important role in mice fetal liver erythropoiesis, but the roles of SOCS3 in human hematopoietic stem cells (HSCs) have not been well investigated. In the present study, lentiviral small interference RNA expression vectors (shRNA) of SOCS3 were constructed and stably transferred into HSCs. We found that SOCS3 knockdown induced erythroid expansion in HSCs. Conversely, Ectopic expression of SOCS3 in progenitor cells blocked erythroid expansion and erythroid colony formation of HSCs. To further explore the involved mechanism, we compared gene expression profiles of SOCS3-shRNA tranduced HSCs with that of control HSCs by whole genome microarrays. The results indicated that cell developmental process related genes, especially hematopoietic lineage-specific genes, associated with the responses to SOCS3 in HSCs.Downexpression of SOCS3 in HSCs or differentiated erythroid progenitor cells induced a transcriptional program enriched for erythroid development relative genes. Our results proved that SOCS3 down-expression induced lineage commitment towards erythroid progenitor cell fate by activation of erythroid-specific gene in HSCs and provided new insight into the mechanism of erythropoietic development.

Trichostatin A combined with cytokines induces differentiation of embryonic stem cells into hepatocytes

AIM: To present a novel 3-step procedure to efficiently direct the differentiation of mouse embryonic stem cells (ESCs) into hepatocytes.

METHODS: Mouse ESCs were first induced to differentiate into definitive endoderm cells by three days of activin A treatment. Next, definitive endoderm cells were induced to efficiently differentiate to hepatocytes in the presence of acid fibroblast growth factor (aFGF) and trichostatin A (TSA) in the culture medium for 5 d.

RESULTS: After 10 d of further in vitro maturation, the morphological and phenotypic markers of hepatocytes were characterized using light microscopy, immunofluorescence and RT-PCR. Furthermore, these cells were tested for the functions associated with mature hepatocytes including glycogen storage, indocyanine green uptake and release, and the rate of hepatic differentiation was determined by counting the albumin-positive cells, which showed that the rate of hepatic differentiation was 57.38%.

CONCLUSION: The method presented in this study provides a new resource for hepatocyte transplantation.

Early exposure of murine embryonic stem cells to hematopoietic cytokines differentially directs definitive erythropoiesis and cardiomyogenesis in alginate hydrogel three-dimensional cultures

HepG2-conditioned medium (CM) facilitates early differentiation of murine embryonic stem cells (mESCs) into hematopoietic cells in two-dimensional cultures through formation of embryoid-like colonies (ELCs), bypassing embryoid body (EB) formation. We now demonstrate that three-dimensional (3D) cultures of alginate-encapsulated mESCs cultured in a rotating wall vessel bioreactor can be differentially driven toward definitive erythropoiesis and cardiomyogenesis in the absence of ELC formation. Three groups were evaluated: mESCs in maintenance medium with leukemia inhibitory factor (LIF, control) and mESCs cultured with HepG2 CM (CM1 and CM2). Control and CM1 groups were cultivated for 8 days in early differentiation medium with murine stem cell factor (mSCF) followed by 10 days in hematopoietic differentiation medium (HDM) containing human erythropoietin, m-interleukin (mIL)-3, and mSCF. CM2 cells were cultured for 18 days in HDM, bypassing early differentiation. In CM1, a fivefold expansion of hematopoietic colonies was observed at day 14, with enhancement of erythroid progenitors, hematopoietic genes (Gata-2 and SCL), erythroid genes (EKLF and β-major globin), and proteins (Gata-1 and β-globin), although ζ-globin was not expressed. In contrast, CM2 primarily produced beating colonies in standard hematopoietic colony assay and expressed early cardiomyogenic markers, anti-sarcomeric α-actinin and Gata-4. In conclusion, a scalable, automatable, integrated, 3D bioprocess for the differentiation of mESC toward definitive erythroblasts has been established. Interestingly, cardiomyogenesis was also directed in a specific protocol with HepG2 CM and hematopoietic cytokines making this platform a useful tool for the study of erythroid and cardiomyogenic development.

Improving embryonic stem cell expansion through the combination of perfusion and Bioprocess model design

BACKGROUND

High proliferative and differentiation capacity renders embryonic stem cells (ESCs) a promising cell source for tissue engineering and cell-based therapies. Harnessing their potential, however, requires well-designed, efficient and reproducible expansion and differentiation protocols as well as avoiding hazardous by-products, such as teratoma formation. Traditional, standard culture methodologies are fragmented and limited in their fed-batch feeding strategies that afford a sub-optimal environment for cellular metabolism. Herein, we investigate the impact of metabolic stress as a result of inefficient feeding utilizing a novel perfusion bioreactor and a mathematical model to achieve bioprocess improvement.

METHODOLOGY/PRINCIPAL FINDINGS

To characterize nutritional requirements, the expansion of undifferentiated murine ESCs (mESCs) encapsulated in hydrogels was performed in batch and perfusion cultures using bioreactors. Despite sufficient nutrient and growth factor provision, the accumulation of inhibitory metabolites resulted in the unscheduled differentiation of mESCs and a decline in their cell numbers in the batch cultures. In contrast, perfusion cultures maintained metabolite concentration below toxic levels, resulting in the robust expansion (>16-fold) of high quality 'naïve' mESCs within 4 days. A multi-scale mathematical model describing population segregated growth kinetics, metabolism and the expression of selected pluripotency ('stemness') genes was implemented to maximize information from available experimental data. A global sensitivity analysis (GSA) was employed that identified significant (6/29) model parameters and enabled model validation. Predicting the preferential propagation of undifferentiated ESCs in perfusion culture conditions demonstrates synchrony between theory and experiment.

CONCLUSIONS/SIGNIFICANCE

The limitations of batch culture highlight the importance of cellular metabolism in maintaining pluripotency, which necessitates the design of suitable ESC bioprocesses. We propose a novel investigational framework that integrates a novel perfusion culture platform (controlled metabolic conditions) with mathematical modeling (information maximization) to enhance ESC bioprocess productivity and facilitate bioprocess optimization.

Effects of shear stress on germ lineage specification of embryonic stem cells

Mechanobiology to date has focused on differentiated cells or progenitors, yet the effects of mechanical forces on early differentiation of pluripotent stem cells are still largely unknown. To study the effects of cellular deformation, we utilize a fluid flow bioreactor to apply steady laminar shear stress to mouse embryonic stem cells (ESCs) cultured on a two dimensional surface. Shear stress was found to affect pluripotency, as well as germ specification to the mesodermal, endodermal, and ectodermal lineages, as indicated by gene expression of OCT4, T-BRACHY, AFP, and NES, respectively. The ectodermal and mesodermal response to shear stress was dependent on stress magnitude (ranging from 1.5 to 15 dynes cm(-2)). Furthermore, increasing the duration from one to four days resulted in a sustained increase in T-BRACHY and a marked suppression of AFP. These changes in differentiation occurred concurrently with the activation of Wnt and estrogen pathways, as determined by PCR arrays for signalling molecules. Together these studies show that the mechanical microenvironment may be an important regulator during early differentiation events, including gastrulation. This insight furthers understanding of normal and pathological events during development, as well as facilitates strategies for scale up production of stem cells for clinical therapies.