Project description:Matrigel, a mouse tumor extracellular matrix (ECM) protein mixture, is an indispensable component of most organoid tissue culture. However, it has limited the utility of organoids for drug development and regenerative medicine due to its tumor-derived origin, batch-to batch variation, high cost, and safety issues. Here, we demonstrate that gastrointestinal (GI) tissue-derived ECM hydrogels are a suitable substitute for Matrigel in GI organoid culture. We found that the development and function of GI organoids grown in GI ECM hydrogels are comparable or often superior to those in Matrigel. In addition, GI ECM hydrogels enabled long-term subculture and transplantation of GI organoids by providing GI tissue-mimetic microenvironments. Tissue-specific and age-related ECM profiles of GI ECM hydrogels that affect organoid development were also elucidated through proteomic analysis. Together, our results suggest that ECM hydrogels derived from decellularized GI tissues are an effective alternative to the current gold standard, Matrigel, and produce organoids suitable for GI disease modeling, drug development, and tissue regeneration.

Project description:Organoid technology has provided unique insights into human organ development, function, and diseases. Patient derived organoids are increasingly used for drug screening, modeling rare disorders, designing regenerative therapies, and understanding pathological changes associated with disease progression. However, the use of Matrigel to grow organoids represents a major challenge in the clinical translation of organoid technology. Matrigel is a poorly defined cocktail of extracellular matrix proteins and growth factors extracted from the Engelbreth Holm Swarm mouse tumor. The extracellular matrix is a major driver of multiple cellular processes and differs significantly between tissues as well as in healthy and diseases states of the same tissue. Therefore, we envisioned that extracellular matrix derived from a native healthy tissue would be sufficient to support organoid growth akin to organogenesis in vivo. Here, we have developed hydrogels from decellularized human and bovine endometrium. These hydrogels supported the growth of mouse and human endometrial organoids, which was comparable to Matrigel. Organoids grown in endometrial hydrogels were proteomically more similar to the native tissue than the organoids cultured in Matrigel. Proteomic and Raman spectroscopy analyses showed that the method of decellularization affects the biochemical composition of hydrogels and subsequently, their ability to support organoid growth. The amount of laminin in hydrogels correlated with the number and the shape of organoids. We also demonstrated the utility of endometrial hydrogels in developing solid scaffolds for supporting high throughput cell culture-based applications. In summary, endometrial hydrogels overcome a major limitation of organoid technology and greatly expand the applicability of organoids to understand endometrial biology and associated pathologies.

Project description:Matrigel, a mouse tumor extracellular matrix (ECM) protein mixture, is an indispensable component of most organoid tissue culture. However, it has limited the utility of organoids for drug development and regenerative medicine due to its tumor-derived origin, batch-to22 batch variation, high cost, and safety issues. Here, we demonstrate that gastrointestinal (GI) tissue-derived ECM hydrogels are a suitable substitute for Matrigel in GI organoid culture. We found that the development and function of GI organoids grown in GI ECM hydrogels are comparable or often superior to those in Matrigel. In addition, GI ECM hydrogels enabled long-term subculture and transplantation of GI organoids by providing GI tissue-mimetic microenvironments. Tissue-specific and age-related ECM profiles of GI ECM hydrogels that affect organoid development were also elucidated through proteomic analysis. Together, our results suggest that ECM hydrogels derived from decellularized GI tissues are an effective alternative to the current gold standard, Matrigel, and produce organoids suitable for GI disease modeling, drug development, and tissue regeneration.

Project description:This experiment compares the transcriptome profile of human spinal cord organoids generated from iPSCs in Matrigel, 1% alginate hydrogel, or 2% alginate hydrogel. Spinal cord organoids were generated from human iPSCs and then encapsulated in the respective hydrogels before further maturation. Organoids were harvested on days 30, 60, and 90 for each group. In addition to the differences between hydrogel groups, neuronal and glial markers at each time point were also assessed for the development of the organoids.

Project description:scRNA-seq was used to characterise hiPSC-derived kidney organoids differentiated within fully synthetic self-assembling peptide hydrogels of variable mechanical strengths and compare these to organoids differentiated within the animal-derived matrix, Matrigel. Organoids were matured in the respective matrices until day 24 of differentiation and 6 organoids per support matrix were then pooled and dissociated using the cold-active protease from Bacillus licheniformis. Cells were processed on the 10x Genomics Chromium platform using the Single-Cell 3’ v3.1 protocol. The NextSeq500 (Illumina) was used to sequence the libraries generated and initial processing of the data was carried out using the 10X Genomic Cell Ranger v3.1.0 pipeline.

Project description:The aim of this study is to compare the transcriptomic profiles of various ex vivo models of pancreatic cancer. First, primary tumours and their corresponding xenografts in nude mice were analysed by RNA-seq. Monocultures of pancreatic cancer cells derived from the xenografts were then prepared as 2D monolayers, Matrigel-embedded organoids, spheres in suspension and 3D cultures in self-assembling peptide amphiphile (PA) hydrogels. Seven-day cultures were then analysed by RNA-seq. The results suggest that all ex vivo monocultures retain patient-specific transcriptional profiles, especially cancer stem cell signatures, while being deficient in the expression of stromal components such as the core matrisome. Correlations with the primary tumours were generally higher in PA hydrogels than organoids. Biased gene expression signatures were identified in certain models. This is the first study to explore the transcriptomic signatures of four different ex vivo models matched to their primary tumours of origin.

Project description:The ex vivo modelling of pancreatic ductal adenocarcinoma (PDAC) using patient-derived cells is a promising tool to predict treatment responses. Matrigel-based organoid and organotypic approaches are limited by their undefined molecular composition, hindering the recapitulation of the tumour’s characteristic desmoplasia, which is known to promote drug resistance. To overcome these limitations, we used self-assembling peptide amphiphiles (PAs) gelled in a minimal extracellular matrix to model the pancreatic tumour microenvironment and to establish 3D multicellular cultures of patient-derived PDAC cells, pancreatic stellate cells and macrophages. Matrisome analysis of 3D cultures demonstrated consistent ECM protein deposition, which was highly reminiscent of the corresponding primary PDAC tissues. The proteomic data obtained was also compared to the corresponding patient-derived xenografts (PDX) in nude mice and Matrigel-based cultures. Characterisation of the chemosensitivity of the cultures revealed realistic treatment responses by PDAC cells in PA hydrogels based on the responses of their corresponding PDX tumours. Histological, transcriptional and functional techniques confirmed these similarities, which were not observed in Matrigel-based cultures. These findings demonstrate the biomimetic nature of PA hydrogels, which enable cultured cells to recreate the PDAC matrisome ex vivo and to respond to chemotherapeutic agents in a predictive manner.

Project description:The influence of 2D and 3D cell culture platforms on vascular function was investigated by comparing gene expression for human pluripotent stem cell-derived endothelial cells (H1-ECs), primary human brain vascular pericytes (pericytes), and human umbilical vein endothelial cells (HUVECs) cultured on tissue culture polystyrene (TCP, “2D”), on or in poly(ethylene glycol) (PEG) hydrogels formed via “thiol-ene” photopolymerization, and on or in gelled Matrigel. ECs cocultured with pericytes in PEG formed vascular networks with global gene expression that was highly correlated to a standard 3D Matrigel assay (Spearman’s coefficients ≥ 0.98). H1-ECs, HUVECs, and pericytes were characterized gene expression signatures associated with the cell cycle and mitosis when cultured on TCP surfaces compared to cells cultured on top of or encapsulated in PEG hydrogels or Matrigel. The proliferative signature was not necessarily a function of the 2D format, since endothelial cells cultured on PEG hydrogels were not characterized by increased proliferation or a proliferative gene signature compared to cells encapsulated in PEG hydrogels. The proliferative phenotype for H1-ECs on TCP was regulated by FAK-ERK activity, and inhibition or knockdown of ERK pathway signaling decreased proliferation and cell cycle genes while increasing expression of “3D-like” vasculature development genes. Our results suggest that cells in 2D culture adopt a highly proliferative state that interferes with normal vascular function and provides unique insight into the importance of cellular and extracellular context for in vitro tissue modeling.

Project description:Human salivary gland organoids have opened tremendous possibilities for regenerative medicine in patients undergoing radiotherapy for the treatment of head and neck cancer. However, their clinical translation is greatly limited by the current use of Matrigel for organoid derivation and expansion. Here, we envisage that the use of a fully, synthetic hydrogel based on the oligo(-ethylene glycol) functionalized polymer polyisocyanopeptides (PICs) can provide an environment suitable for the generation and expansion of salivary gland organoids (SGOs) after optimization of PIC polymer properties. We demonstrate that PIC hydrogels decorated with the cell-binding peptide RGD allow SGO formation from salivary gland (SG)-derived stem cells. This self-renewal potential is preserved for only 4 passages. It was found that SGOs differentiated prematurely in PIC hydrogels affecting their self-renewal capacity. Similarly, SGOs show decreased expression of immediate early genes (IEGs) after culture in PIC hydrogels. Activation of multiple signalling pathways involved in IEG expression by β-adrenergic agonist isoproterenol, led to increased stem cell self-renewal capacity as measured by organoid forming efficiency (OFE). These results indicate that PIC hydrogels are promising 3D matrices for SGOs, with the option to be used clinically, after further optimization of the hydrogel and culture conditions.

Project description:Human intestinal organoids were grown in a typical 3D matrigel culture environment, or in an alginate gel, then a subset from each condition were xenotransplanted to vascularized and mature in vivo. Epithelium was isolated and epithelial only organoids (enteroids) were then grown from each condition prior to sequencing bulk RNA-sequencing.