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: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:Extracellular matrix (ECM) structural and compositional abnormalities are a hallmark of many cancers. Tumor associated macrophages (TAM) are considered pivotal players in mounting pro-tumoral functions; yet, their role in tumor-ECM remodeling remains largely ambiguous. Using an orthotopic murine model of colorectal cancer we defined two major CRC TAM subsets arising from Ly6Chi monocytes recruited in a CCR2-depedent manner. TAM-deficient CRC tumors established Ccr2-/- mice exhibited attenuated growth. Advanced imaging techniques revealed that the enhanced deposition, linearization and cross-linking of collagen fibers typical to tumor growth were absent in the Ccr2-/- tumors. Moreover, the Ccr2-/- tumors displayed altered ECM composition with 348 proteins that were differentially expressed in comparison with WT tumors, among them 46 were ECM related. Integrating transcriptomic and proteomic approaches we defined a TAM signature of ECM remodeling enzymes, structural and affiliated proteins. Specifically, were prominent proteins involved with the synthesis and assembly of collagen type I, IV and XIV. Finally, decellularized 3D ECM fragments extracted from WT tumors, but not from Ccr2-/- tumors or upstream healthy colon, enhanced tumor cell proliferation in vitro and tumor development in the native colonic environment. Collectively, our integrated biophysical-immunologic-omic approaches uncover new mechanistic insights of TAM-mediated remodeling of tumor ECM structure and composition.

Project description:Tumor cell response to irradiation also depends on their microenvironment. Therefore ongoing investigation of three-dimensional (3D) cell culture models provide researchers with essential data studying and remodeling radiotherapeutic implications in cancer treatment. 3D culture models were shown to mimic in vivo cell microenvironment more accurately than the standard two-dimensional cell monolayer (2D) cultures. Growing evidence suggests that 2D and 3D cultured cell gene expression pattern discrepancies following irradiation is highly dependent on cell-ECM interactions. It has been shown that laminin-rich-extracellular matrix (lr-ECM) used in 3D cultures not only alters cancer cell phenotype and response to external stimuli but also affects their differentiation, migration and survivability. Thus, a change in these fundamental cell properties demands us to reconsider data previously collected using 2D in vitro models. RNA was harvested from two colorectal cancer cell lines cultivated under 3D cell culture conditions, 4h after treatment of single (2 Gy or 10 Gy) or fractionated (5x2 Gy) ionizing radiation dose.

Project description:The liver is the most common site for colorectal cancer (CRC) metastasis and new tissue culture models are needed to study hepatic metastasis from CRC as none of the current models mimic the biological, biochemical and structural characteristics of the metastatic microenvironment. Decellularization provides a novel approach for the study of cancer extracellular matrix (ECM) as decellularized scaffolds retained their tissue-specific features and biological properties. In the present study we created a 3D model of CRC and matched CRC liver metastasis (CRLM) using patient-derived decellularized ECM scaffolds seeded with HT-29 CRC cell line. Here we show increased HT-29 cell proliferation and migration capability when cultured in cancer-derived scaffolds compared to same-patient healthy colon and liver tissues. CRLM scaffolds also induced activation of epithelial-mesenchymal transition (EMT) with cancer cells showing loss of E-cadherin expression and increased Vimentin expression. EMT was confirmed by gene expression profiling, with the most represented biological processes in CRLM-seeded scaffolds involving demethylation, deacethylation, cellular response to stress metabolic processes, response to oxygen level and to starvation. The complex 3D culture environment reduced the HT-29 cell response to anti-CRC drug 5-FU when used at standard IC50 determined in 2D cultures. In conclusion, our 3D culture system with patient-derived tissue-specific decellularized ECM better recapitulates the metastatic microenvironment compared to conventional 2D culture conditions and represents a relevant approach for the study of liver CRC metastasis formation and progression. Transcriptomic analysis was performed comparing the global gene expression profiles of HT29 cells grown on CRLM and HL scaffolds. The transcriptomic profile of each 3D subtype was compared with HT29 cells grown in plastic. Hierarchical clustering analysis revealed that the gene expression signature of recellularized CRLM scaffolds was more comparable to recellularized HL scaffolds, than to HT29 cells grown in 2D. Gene set enrichment analysis (GSEA) of the differently expressed genes (DEG) up-regulated in recellularized CRLM scaffolds compared to HT29 grown in 2D revealed that genes involved in demethylation, deacethylation and metabolic process belong to the most enriched biological pathways in repopulated-CRLM scaffolds. Comparing the DEG between recellularized CRLM scaffolds vs HT29 grown in 2D with a series of a-priori defined gene-set, called Hallmark, we obtained concordant results with the “HYPOXIA” and “EPITHELIAL_MESENCHYMAL_TRANSITION” pathway, enriched in recellularized CRLM, supporting the idea that 3D culture models are the ability to re-create a complex environment in terms of oxygen tension, nutrients, and metabolic gradient, similarly to the in vivo environment.

Project description:The AT-rich interacting domain-containing protein 1A (ARID1A) is a tumor suppressor gene that has been implicated in various cancers, including colorectal cancer (CRC). The present study employed a proteomic approach to uncover the molecular mechanisms of ARID1A in CRC carcinogenesis.

Project description:Decellularized extracellular matrix (dECM) is used to make regenerative biomaterials. As the ECM markups vary across organs, derived dECM products may possess different molecular and biological profiles as well. This study aims to compare the proteomic profiles of dECM biomaterials derived from small intestinal submucosa (SIS) and vocal fold (VF) tissue using mass spectrometry-based proteomics.

Project description:In vitro cell culture studies are common in cancer research field, and reliable biomimetic 3D models are needed to ensure physiological relevance. In this manuscript, we hypothesized that decellularized xenograft tumors can serve as an optimal 3D substrate to generate a top-down approach for in vitro tumor modeling. Methods: Multiple tumor cell lines were xenografted and the formed solid tumors were recovered for their decellularization by several techniques and further characterization by histology and proteomics techniques. Selected decellularized tumor xenograft samples were seeded with human triple negative breast cancer (TNBC)c ells and cell behavior was compared among them and with other control 2D and 3D cell culture methods. Results: A soft treatment using Freeze-EDTA-DNAse allows proper decellularization of xenografted tumor samples. Interestingly, proteomic data show that samples decellularized from TMBC xenograft models had different extracellular matrix (ECM) composition compared to the rest of xenograft tumors tested. The in vitro re-cellularization of decellularized ECM (dECM) yields tumor-type specific cell-behavior in TNBC context. Conclusions: Data indicate that dECM derived from xenograft tumors is a feasible substrate for re-seeding purposes, thereby promoting tumor-type specific cell behavior. These data serve as a proof-of-concept for further potential generation of patient-specific in vitro research models.

Project description:Organoids have huge therapeutic potential and are increasingly opening up new avenues within regenerative medicine. However, the clinical application is greatly limited by the lack of effective GMP-complaint systems for organoid expansion in culture. Here, we envisage that the use of extracellular matrix hydrogels derived from decellularized tissues (DT) can provide the instructive native environment necessary to direct cell growth. These gels possess the biochemical signature of tissue-specific ECM, and have the potential for clinical translation due to their natural, non-carcinogenic origin. We show that gels developed from decellularized porcine small intestinal mucosa have similar physiological range and mechanical properties to commercially available gels. ECM-derived gels enable formation and growth of endoderm-derived organoids and, moreover, supports in vivo organoid growth. The development of these ECM-derived hydrogels opens up the potential for human organoids to be used clinically.

Project description:The role of perivascular cell heterogeneity in tumor metastasis remains unknown. Here, we dissected the heterogeneity of perivascular cells by single-cell RNA sequencing and defined 13 subpopulations of pericytes within human colorectal cancers (CRC). Among them, an extracellular matrix (ECM)-rich subpopulation of TCF21high tumor pericytes (TPCs) was identified, which highly correlated with metastatic potentials in human CRC patients. Pericyte-specific conditional deletion of Tcf21 in mice mitigated CRC metastasis by decreasing perivascular ECM resmodeling, maintaining the integrity of the basement membrane, and reducing circulating cancer cells. Conversely, co-injection of CRC cells with TCF21high TPCs markedly promoted metastasis. Mechanistically, high expression of TCF21 in TPCs altered ECM stiffness, collagen deposition/rearrangement, and basement membrane degradation, which collectively instigated tumor cell intravasation and metastasis. Compelling experimental evidence showed that the loss of integrin α5 activated the FAK/PI3K/AKT axis, impaired DNA hypermethylation of TCF21, leading to high expression of TCF21 in TPCs. Our data provide new mechanistic insights into functions of a specific subpopulation of perivascular cells in promoting cancer metastasis and therapeutic targeting of metastasis-promoting TPCs may provide a new paradigm for cancer therapy.