Project description:Extracellular vesicles and their contents are gaining recognition as important mediators of intercellular communication through the transfer of bioactive molecules such as non-coding RNA. We evaluated the contribution of EV miRNA in intercellular communication between hepatocellular cancer cells and hepatic stellate cells. EV-based miRNA was comprehensively assessed in both cell types individually. Using co-cultures of both HCC and HSC cells in transwell and 3D spheroids culture, we established EV-based miR-126-3p as a potential EV-based miRNA mediator of HSC to HCC communication through which tumor cell migration, invasion and three-dimensional growth in spheroids could be influenced. Manipulation of miR-126-3p by enforced expression or inhibition using pre-miR-126-3p or antimiR-126-3p respectively did not alter cell viability, proliferation, or sensitivity to either sorafenib or regorafenib. In contrast, migration was decreased in HepG2 cells with enforced expression of miR-126-3p. Knockdown of miR-126-3p in HepG2 resulted in a significant increase in ADAM9 expression and in LX-2 cells increased collagen accumulation and the compactness of spheroids but did not alter the number or size of spheroids. The restoration of miR-126 in 3D-co-culture of HepG2 and LX2 cells with precursor showed significant alleviated expression of ADAM9 and VEGF, While the silencing of miR-126 was elevated the expression of ADAM9 and VEGF. These studies implicate miR-126-3p in functional effects on migration, invasion, and spheroid growth in HCC cells in the presence of HSC, and thus demonstrate the presence of functional EV RNA based intercellular signaling between HSC and HCC cells that may be relevant to tumor cell behavior.

Project description:The communacation between the Hepatocellular carcinoma (HCC) and hepatic stellate cells(HSC) is not completely understood. Then a tumor-on-a-chip model was used to evaluate the crosstalk between the HCC cells (HCCLM3) and HSCs (LX2). After 5 days co-culture, we degraded the collagen hydrogel to isolate HCCLM3 cells and LX2 cells for RNA-seq.

Project description:Background: Hepatocellular carcinoma (HCC) is a major therapeutic challenge, with limited long-term benefits from treatments such as regorafenib due to their efficacy and adverse effects. Proteoglycan-4 (PRG4) has previously shown promise in enhancing anti-proliferative effects of multi-kinase inhibitors in simple in vitro two-dimensional (2D) HCC models. Objective: We evaluated the adjuvant effect of PRG4 in enhancing regorafenib’s anti-tumor efficacy in preclinical more complex in vitro three-dimensional (3D) HCC tumoroids, and in vivo HCC models. Design: HLC19 and HLF HCC cell lines were engineered to stably overexpress PRG4. Anti-proliferative effects of PRG4, either alone or in combination with regorafenib, were evaluated in 2D monolayers, 3D Matrigel embedded spheroids and orthotopic xenograft mouse models established via HCC cells intrahepatic injection. RNA sequencing was done to assess the transcriptomic profiles of PRG4 overexpressing spheroids. Results: PRG4 expression partially inhibited HCC tumor growth in vivo, but enhanced regorafenib treatment leading to a near-complete tumor regression. PRG4 expression significantly impaired cell growth in both 2D and 3D HCC models in vitro. In an angiogenesis in vitro model, PRG4 hindered endothelial tubulogenesis both alone and in combination with regorafenib. By transcriptomic analysis of matrigel-embedded HCC cell spheroids exposed to PRG4 and/or regorafenib, PDGF pathway emerged as a target of PRG4 + regorafenib, corroborating the role of PRG4 in impairing angiogenesis. G0/G1 phase of cell cycle resulted more delayed in spheroids exposed to PRG4 and regorafenib than those treated with regorafenib only, compared to untreated cells. Conclusions: PRG4 enhances the anti-tumor activity of regorafenib across various HCC models. These findings support PRG4 as a promising adjuvant candidate to improve clinical outcomes in HCC.

Project description:mRNA sequencing of mesenchymal stem cells in 2D culture systems, mesenchymal stem cells spheroids and mesenchymal stem cells/extracellular matrix in 3D culture systems to profile gene expressions

Project description:Human bone marrow mesenchymal stromal cells (MSCs) are conventionally cultured as adherent monolayers on tissue culture plastic. MSCs can also be cultured as 3D cell aggregates (spheroids). Optimised 3D conditions (60,000 MSCs cultured as a spheroid for 5 days) inhibited MSC proliferation and induced cell shrinkage in the absence of cell death. Primary human MSCs isolated from 2 donors were cultured under both monolayer (2D MSCs) and optimised 3D (3D MSCs) conditions. High quality RNA was isolated from all samples, and global gene expression analysis was performed in duplicate (using Agilent SurePrint G3 Human Gene Expression 8x60K v2 Microarrays) to identify gene expression changes in 3D compared to 2D MSC cultures.

Project description:Liver-derived cells from the surface and cave-adapted morphs of Astyanax mexicanus are valuable in vitro resources to explore the metabolism of these unique fish. However, 2D cultures have not yet fully mimicked the metabolic profile of the fish liver. Also, 3D culturing can modulate the transcriptomic profile of cells when compared to its 2D counterpart. Hence, to widen the range of metabolic pathways that can be depicted in vitro, we cultured the liver-derived SFL and CFL into 3D spheroids. We 3D cultured the cells at various cell seeding densities for 4 weeks and characterized the resultant transcriptome. The 3D cultured SFL and CFL cells indeed depicted a wider range of metabolic pathways as compared to the 2D culture. Further, the 3D spheroids also showed surface and cave-specific responses, making the spheroids an exciting system to study cave adaptation. Taken together, SFL and CFL spheroids prove to be a promising model for overall understanding of altered metabolism in Astyanax mexicanus.

Project description:Background. Fallopian tube secretory epithelial cells (FTSECs) have been implicated as a cell-of-origin for high-grade serous epithelial ovarian cancer. However, there are relatively few in vitro models of this tissue type available for use in studies of FTSEC biology and malignant transformation. In vitro three-dimensional (3D) cell culture models aim to recreate the architecture and geometry of tissues in vivo and restore the complex network of cell-cell/cell-matrix interactions that occur throughout the surface of the cell membrane. Results. We have established and characterized 3D spheroid culture models of primary FTSECs. FTSEC spheroids contain central cores of hyaline matrix surrounded by mono- or multi-layer epithelial sheets. We found that 3D culturing alters the molecular characteristics of FTSECs compared to 2D cultures of the same cells. Gene expression profiling identified more than a thousand differentially expressed genes between 3D and 2D cultures of the same FTSEC lines. Pathways significantly under-represented in 3D FTSEC cultures were associated with cell cycle progression and DNA replication. This was also reflected in the reduced proliferative indices observed in 3D spheroids stained for the proliferation marker MIB1. Comparisons with gene expression profiles of fresh fallopian tube tissues revealed that 2D FTSEC cultures clustered with follicular phase tubal epithelium, whereas 3D FTSEC cultures clustered with luteal phase samples. Conclusions. This 3D model of fallopian tube secretory epithelial cells will advance our ability to study the underlying biology and etiology of fallopian tube tissues and the pathogenesis of high-grade serous epithelial ovarian cancer. 3 primary FTSEC lines were plated in 2D, or in 3D on polyHEMA coated plates

Project description:The development of more complex but reliable systems for compound testing in a pharmaceutical context is a challenging task to date. Three-dimensional (3D), organ mimetic cell culture is aiming to become an alternative to common two-dimensional (2D) cell culture or animal testing in that field. We developed a biocompatible 3D cell culture environment for a hepatocellular carcinoma (HCC) model that enables cellular maintenance in a polycarbonate scaffold structure. Albumin, regarded as a differentiation marker, was elevated in statically 3D cultivated HepG2 cells. Expression of HCC tumor marker alpha-fetoprotein (AFP) was reduced compared to immunofluorescence stainings of 2D cultivated cells. Remarkably, expression of cytokeratin and pathophysiologically relevant beta-1 integrin (ITGB1) was found enhanced in nonperfused 3D cell culture. Changes in gene expression induced by the 3D cultivation environment were investigated using Ingenuity Pathway Analysis (IPA). Our findings revealed involvement of the insulin growth factor (IGF) signaling pathway in upregulation of matrix metalloproteinases (MMP) and ITGB1. The experimental data indicate a more differentiated state in 3D cultivated HepG2 cells than in the respective 2D experiments. Hence, scaffold-supported 3D cultivation of HepG2 cells may lead to a gain of information valuable for both drug testing and cancer research. HepG2 cells were cultivated for five days under 2D and 3D statical and perfused conditions. Cultivation was started with 0.25x10^6 cells in 2D and with 1x10^6 vital cells for the 3D experiments. The day of seeding was defined as d0. The groups were classified as follows: 2D, i.e., monolayer cultures, 3D, i.e., statical 3D cultures and BR, which denotes perfused 3D culture of HepG2 cells. The perfusable bioreactor system was operated using a peristaltic pump. It houses the MatriGrid, a polycarbonate-based microporous cellular support. For 3D static cultivation, cell-inoculated MatriGrids were placed in wells of a 24-well plate. Microarray experiments of three 2D (i.e., control), three 3D statically and three actively perfused 3D cultivations were performed at SIRS-Lab GmbH (SIRS-Lab GmbH, Jena, Germany) according to the manufacturer's instructions (Illumina, San Diego, CA). Altogether, 9 RNA samples of hepatocyte cultures and an internal control RNA were hybridized on two HumanHT-12 v4 Expression BeadChips.

Project description:Physiologically relevant in vitro models are a priority in predictive toxicology in order to replace and/or reduce animal experiments. The compromised toxicant metabolism of many immortalized human liver cell lines grown as monolayers as compared to in vivo metabolism limits their physiological relevance. However, recent efforts to culture liver cells in a 3D environment, such as spheroids, to better mimic the in vivo conditions, may enhance the toxicant metabolism of human liver cell lines. In this study, we characterized the dynamic changes in the transcriptome of HepG2/C3A hepatocarcinoma cell spheroids maintained in a clinostat system (CelVivo) to gain insight into the metabolic capacity of this model as a function of spheroid size and culture time. We assessed morphological changes (size, necrotic core), cell health, and proliferation rate from initial spheroid seeding to 35 days of continuous culture in conjunction with a time-course (0, 3, 7, 10, 14, 21, 28 days) of the transcriptome (TempO-Seq, BioSpyder). The phenotypic characteristics of HepG2/C3A growing in spheroids was comparable to monolayer growth until ~Day 12 (Day 10-14) when a significant decrease in cell doubling rate was noted which was concurrent with down regulation of cell proliferation and cell cycle pathways over this time period. Principal Component Analysis and hierarchal clustering of the transcriptome data suggests that the Day 3, 7, and 10 spheroids are pronouncedly different from the Day 14, 21, and 28 spheroid in support of a biological transition time point during the long-term 3D spheroid cultures. Unexpectedly, the expression of genes encoding toxicant metabolism and transport rapidly increased during the early time points of spheroids to peak at Day 7 or Day 10 as compared to monolayer cultures with gradual decrease in expression with further culture, suggesting the most metabolically responsive time window for exposure studies. Overall, here we provide baseline information on the cellular and molecular characterization, with a particular focus on toxicant metabolic capacity dynamics and cell growth of HepG2/C3A 3D spheroid cultures over the time course.

Project description:2D culture as a model for drug testing often turns to be clinically futile. Therefore, 3D cultures (3Ds) show potential to better model responses to drugs observed in vivo. In preliminary studies, using melanoma (B16F10) and renal (RenCa) cancer, we confirmed that 3Ds better mimics the tumor microenvironment. Here, we evaluate how the proposed 3D mode of culture affects tumor cell susceptibility to anti-cancer drugs, which have distinct mechanisms of action (everolimus, doxorubicin, cisplatin). Melanoma spheroids show higher resistance to all used drugs, as compared to 2D. In RCC model, such modulation was only observed for doxorubicin treatment. As drug distribution was not affected by the 3D shape, we assessed the expression of MDR1 and mTor. Upregulation of MDR1 in RCC spheroids was observed, in contrast to melanoma. In both models mTor expression was not affected by the 3D cultures. By NGS, 10 genes related with metabolism of xenobiotics by cytochrome p450 were deregulated in renal cancer spheroids; 9 of them were later confirmed in melanoma model. The differences between 3D models and classical 2D cultures point to the potential to uncover new non canonical mechanisms to explain drug resistance set by the tumor in its microenvironment.