Engineered vascularized bone grafts.

Clinical protocols utilize bone marrow to seed synthetic and decellularized allogeneic bone grafts for enhancement of scaffold remodeling and fusion. Marrow-derived cytokines induce host neovascularization at the graft surface, but hypoxic conditions cause cell death at the core. Addition of cellular components that generate an extensive primitive plexus-like vascular network that would perfuse the entire scaffold upon anastomosis could potentially yield significantly higher-quality grafts. We used a mouse model to develop a two-stage protocol for generating vascularized bone grafts using mesenchymal stem cells (hMSCs) from human bone marrow and umbilical cord-derived endothelial cells. The endothelial cells formed tube-like structures and subsequently networks throughout the bone scaffold 4-7 days after implantation. hMSCs were essential for stable vasculature both in vitro and in vivo; however, contrary to expectations, vasculature derived from hMSCs briefly cultured in medium designed to maintain a proliferative, nondifferentiated state was more extensive and stable than that with hMSCs with a TGF-beta-induced smooth muscle cell phenotype. Anastomosis occurred by day 11, with most hMSCs associating closely with the network. Although initially immature and highly permeable, at 4 weeks the network was mature. Initiation of scaffold mineralization had also occurred by this period. Some human-derived vessels were still present at 5 months, but the majority of the graft vasculature had been functionally remodeled with host cells. In conclusion, clinically relevant progenitor sources for pericytes and endothelial cells can serve to generate highly functional microvascular networks for tissue engineered bone grafts.

Renal tumouroids: challenges of manufacturing 3D cultures from patient derived primary cells.

Recent advancements in 3D in vitro culture have allowed for the development of cancer tissue models which accurately recapitulate the tumour microenvironment. Consequently, there has been increased innovation in therapeutic drug screening. While organoid cultures show great potential, they are limited by the time scale of their growth in vitro and the dependence upon commercial matrices, such as Matrigel, which do not allow for manipulations of their composition or mechanical properties. Here, we show a straightforward approach for the isolation and culture of primary human renal carcinoma cells and matched non-affected kidney. This approach does not require any specific selection for cancer cells, and allows for their direct culture in amenable 3D collagen-based matrices, with the preservation of cancer cells as confirmed by NGS sequencing. This method allows for culture of patient-derived cancer cells in 3D microenvironment, which can be used for downstream experimentation such as investigation of cell-matrix interaction or drug screening.

The anti-angiogenic tyrosine kinase inhibitor Pazopanib kills cancer cells and disrupts endothelial networks in biomimetic three-dimensional renal tumouroids.

Pazopanib is a tyrosine kinase inhibitor used to treat renal cell carcinoma. Few in vitro studies investigate its effects towards cancer cells or endothelial cells in the presence of cancer. We tested the effect of Pazopanib on renal cell carcinoma cells (CAKI-2,786-O) in two-dimensional and three-dimensional tumouroids made of dense extracellular matrix, treated in normoxia and hypoxia. Finally, we engineered complex tumouroids with a stromal compartment containing fibroblasts and endothelial cells. Simple CAKI-2 tumouroids were more resistant to Pazopanib than 786-O tumouroids. Under hypoxia, while the more 'resistant' CAKI-2 tumouroids showed no decrease in viability, 786-O tumouroids required higher Pazopanib concentrations to induce cell death. In complex tumouroids, Pazopanib exposure led to a reduction in the overall cell viability (p < 0.0001), disruption of endothelial networks and direct killing of renal cell carcinoma cells. We report a biomimetic multicellular tumouroid for drug testing, suitable for agents whose primary target is not confined to cancer cells.

Elements of the niche for adult stem cell expansion.

Adult stem cells are crucial for tissue homeostasis. These cells reside within exclusive locations in tissues, termed niches, which protect adult stem cell fidelity and regulate their many functions through biophysical-, biochemical- and cellular-mediated mechanisms. There is a growing understanding of how these mechanisms and their components contribute towards maintaining stem cell quiescence, self-renewal, expansion and differentiation patterns. In vitro expansion of adult stem cells is a powerful tool for understanding stem cell biology, and for tissue engineering and regenerative medicine applications. However, it is technically challenging, since adult stem cell removal from their native microenvironment has negative repercussions on their sustainability. In this review, we overview specific elements of the biomimetic niche and how recreating such elements can help in vitro propagation of adult stem cells.

TPA-induced signal transduction: a link between PKC and EGFR signaling modulates the assembly of intercellular junctions in Caco-2 cells.

Recent studies suggest that signal transduction may have an important role in the development and regulation of the metastatic phenotype. Here, we investigated the role of the epidermal growth factor receptor (EGFR), and protein kinase C (PKC), in the process of reassembly of cadherin-dependent cell-cell adhesion of Caco-2 cells. We used chemical activation of PKC and EGFR with 12- O-tetradecanoylphorbol-13-acetate (TPA), a tumor-promoting agent, pretreatment with protein kinase inhibitors and subcellular fractionation to analyze the effect of the phorbol ester on the redistribution of junctional proteins. Transepithelial resistance (TER), electron microscopy and immunofluorescence analyses were also carried out. Activation with TPA resulted in disassembly of adherens junctions (AJs), but the tight junction (TJ) structure and function remained unaltered. TPA affected E-cadherin levels. In Caco-2 cells at day 2 of culture, when most E-cadherin is not associated with the cytoskeleton, a decrease in the level of this protein was observed as soon as 6 h after TPA addition. However, at day 5 of culture, the major effect observed after 6 h of treatment was a translocation of the protein from the Triton-insoluble to the -soluble fraction. On the other hand, TPA did not significantly affect the E-cadherin-associated proteins alpha and beta-catenins. Potent specific EGFR inhibitors, such as PD153035 and Tyrphostin 25, as well as Calphostin C, an inhibitor of PKC, significantly blocked the effect of TPA on AJs. Furthermore, inhibition of the TPA effect by the PD98059 MAPK inhibitor suggests that activation of this kinase was the final event in the modulation of cadherin-dependent cell-cell adhesion. Pretreatment of cell monolayers with Calphostin C before EGF treatment, one of the ligands of EGFR, blocked the redistribution of E-cadherin caused by EGF. Based on these results, we conclude that both EGFR and PKC activation are involved in TPA-induced cell signaling for modulation of cadherin-dependent cell-cell adhesion and cell shape in Caco-2 cells.