Project description:Comparison of gene expression of different colon carcinoma cell lines under 2D and 3D culturing conditions Cells were seeded under 2D and 3D culturing condition. After seven days total RNA was isolated and used for cDNA synthesis.

Project description:Ewing sarcoma is a pediatric bone cancer with poor survival in relapsed cases, highlighting the need for better preclinical models. Here, we developed a scalable 3D spheroid platform using SLA-printed microcavity arrays to generate uniform Ewing sarcoma spheroids. High-throughput screening of 11 compounds identified Torin 2, Talazoparib, and Trabectedin as potent inhibitors. Incorporating lung fibroblasts into hybrid spheroids revealed fibroblast-induced drug resistance, mimicking the metastatic tumor microenvironment. Transcriptomic analysis identified activation of NF-κB and TGF-β signaling pathways as key mediators of this resistance. This platform offers a cost-effective, biologically relevant system for drug testing and mechanistic studies in Ewing sarcoma and other stromal-influenced cancers.

Project description:Single-cell assays have revealed the scope and importance of heterogeneity in many biological systems. However, low sensitivity makes it difficult to delineate biological variation from noise, and as a result, the capacity of such assays to identify cellular state differences that arise from genes expressed at low-to-mid abundance is highly limited. To overcome this limitation, we developed CloneSeq, a microfluidics-based technology for 3D-culturing and RNA sequencing (RNA-seq) of small clones. CloneSeq shows that unlike random cell groups, clonal cancer cells originating from a single cell share similar transcriptional profiles. CloneSeq also dramatically improves sensitivity compared to standard single-cell RNA-seq. CloneSeq analysis of non-small cell adenocarcinoma cells revealed the presence of novel cancer-specific subpopulations, including cancer stem-like cells (CSLCs). Based on expression signatures, we identify CSLCs in highly proliferative clones, suggesting that our 3D culturing system promotes stemness. Supporting this, ESCs grown within the 3D hydrogel spheres retained their pluripotent state in the absence of pluripotent media. Moreover, reprogramming efficiency of mouse embryonic fibroblasts within the 3D spheres was significantly improved relative to that of cells grown on gelatin-coated plates. Our results highlight CloneSeq as an extremely useful tool for capturing lowly-expressed genes within clones, and for identifying rare cell populations such as stem-like and cancer-initiating cells.

Project description:Neural Stem Cells (NSCs) of biological behaviors are frequently regulated by the three-dimensional (3D) niches that they located in. The impact of cell density cue inside niche on cellular outcomes are usually underestimated and understudied. In this study, a facile NSCs of 3D culture system was developed using collagen self-assembled fibril hydrogel. We used RNA sequencing and molecular biology technologies to investigate the NSCs of cell contacts and differentiations in developed 3D hydrogel culture system with low (0.75 million/mL), medium (1.5 million/mL), and high (3 million/mL) cell packing density. Compared with low cell density system, cytoskeletal spreading, gap junction, and tight junction mediated cell contacts were significantly improved in high cell density culture. Moreover, high cell density increased NSCs differentiation into immature (Tuj1) neuron, while there is no discrepancy of NSCs differentiation into astrocytes in different cell densities of 3D culturing system. This study provides new understanding in the regulation of 3D cultured NSCs behaviors through niche of cell density cue.

Project description:Development of systems allowing the maintenance of native properties of mesenchymal stromal cells (MSC) is a critical challenge for studying physiological functions of skeletal progenitors, as well as towards cellular therapy and regenerative medicine applications. Conventional stem cell culture in monolayer on plastic dishes (2D) is associated with progressive loss of functionality, likely due to the absence of a biomimetic microenvironment and the selection of adherent populations. Here we demonstrate that 2D MSC expansion can be entirely bypassed by culturing freshly isolated bone marrow cells within the pores of 3D scaffolds in a perfusion-based bioreactor system, followed by enzymatic digestion for cell retrieval. The 3D-perfusion system supported MSC growth while maintaining cells of the hematopoietic lineage, and thus generated a cellular environment mimicking some features of the bone marrow stroma. As compared to 2D-expansion, sorted CD45- cells derived from 3D-perfusion culture after the same time (3 weeks) or a similar extent of proliferation (7-8 doublings) maintained a 4.3-fold higher clonogenicity and exhibited a superior differentiation capacity towards all typical mesenchymal lineages, with similar immunomodulatory function in vitro. Transcriptomic analysis performed on MSC from 5 donors validated the robustness of the process and indicated a reduced inter-donor variability as well as a significant upregulation of multipotency-related gene clusters following 3D-perfusion as compared to 2D expansion. The described system offers a model to study how factors of a 3D engineered niche may regulate MSC function and, by streamlining conventional labor-intensive processes, is prone to automation and scalability within closed bioreactor systems. Nucleated cells were isolated from 5 fresh human bone marrow aspirates by means of red blood cells lyses buffer and then were seeded into a 3D perfusion bioreactor system using a pure hydroxyapatite 3D scaffold and in conventional Petri dishes (2D). After culture for 19 days, cells from both systems were enzymatically retrieved and sorted using anti-CD45-coated magnetic beads. Total RNA was extracted from CD45- cells, QCed and hybridized to Affymetrix microarrays.

Project description:A genomic expression comparison was done among neural progenitor cells cultured on 2D substrates, 3D porous polystyrene scaffolds, and as 3D neural spheres (in vivo surrogate), with the goal of assessing the feasibility of establishing the meaning of 3D and associated physiological relevance at the molecular level Neural progenitor cells were cultured on 2D surfaces, in 3D scaffolds and as 3D neural spheres. Chemical cues are controlled by coating. Only spacial properties of the culture systems were compared.

Project description:Comparison of gene expression of different colon carcinoma cell lines under 2D and 3D culturing conditions

Project description:Human mesenchymal stromal cells (MSCs) hold great regenerative medicine potential due to their pluripotency and paracrine functions. However, MSCs lose stemness and immunomodulatory capabilities in two-dimensional (2D) culture, which differs from the natural MSC niche. We investigated methods to enhance MSC characteristics by employing an in vivo-like culture using functional polymers. Implementing FP003 polymer-based 3D culture, we observed increased expression of stemness markers (Oct4, Nanog), in hMSCs compared to 2D culture on regular plastic. This 3D environment also enhanced expression COX2 and HO1, known for their immunomodulatory functions. MSCs cultured in 3D exhibited higher secretion of PGE2 and effectively suppressed TNF- release from LPS-stimulated splenocytes, surpassing 2D-cultured MSCs. To explore therapeutic potential in vivo, we administered 3D-cultured MSCs via intravenous injection in a mouse model of neuroinflammation. Remarkably, this approach significantly reduced the expression of Iba1 and GFAP compared to 2D-cultured MSC injection. RNA-seq analysis revealed upregulated adhesion-related genes, including ITGA2, in MSCs cultured in 3D. Ectopic ITGA2 expression notably enhanced immunomodulatory function. In summary, our findings demonstrate that an in vivo mimetic 3D culture provides a beneficial microenvironment for MSCs, enhancing their immunomodulatory function through ITGA2 expression. Engineered MSCs can thus be utilized as an effective cell therapy source.

Project description:The tumor microenvironment consists of resident tumor cells organized within a compositionally diverse, three-dimensional (3D) extracellular matrix (ECM) network that cannot be replicated in vitro using bottom-up synthesis. We report a new self-assembly system to engineer ECM-rich 3D MatriSpheres wherein tumor cells actively organize and concentrate microgram quantities of decellularized ECM dispersions which modulate cell phenotype. 3D colorectal cancer (CRC) MatriSpheres were created using decellularized small intestine submucosa (SIS) as an orthotopic ECM source that had greater proteomic homology to CRC tumor ECM than traditional ECM formulations such as Matrigel. SIS ECM was rapidly concentrated from its environment and assembled into ECM-rich 3D stroma-like regions by mouse and human CRC cell lines within 4-5 days via a mechanism that was rheologically distinct from bulk hydrogel formation. Both ECM organization and transcriptional regulation by 3D ECM cues affected programs of malignancy, lipid metabolism, and immunoregulation that corresponded with an in vivo MC38 tumor cell subpopulation identified via single cell RNA sequencing. This 3D modeling approach stimulates tumor specific tissue morphogenesis that incorporates the complexities of both cancer cell and ECM compartments in a scalable, spontaneous assembly process that may further facilitate precision medicine.

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