MUG-Mel2, a novel highly pigmented and well characterized NRAS mutated human melanoma cell line.

NRAS mutation in melanoma has been associated with aggressive tumor biology and poor prognosis. Although targeted therapy has been tested for NRAS mutated melanoma, response rates still appear much weaker, than in BRAF mutated melanoma. While plenty of cell lines exist, however, only few melanogenic cell lines retain their in vivo characteristics. In this work we present an intensively pigmented and well-characterized cell line derived from a highly aggressive NRAS mutated cutaneous melanoma, named MUG-Mel2. We present the clinical course, unique morphology, angiogenic properties, growth characteristics using in vivo experiments and 3D cell culture, and results of the exome gene sequencing of an intensively pigmented melanogenic cell line MUG-Mel2, derived from a cutaneous metastasis of an aggressive NRAS p. Q61R mutated melanoma. Amongst several genetic alterations, mutations in GRIN2A, CREBP, PIK3C2G, ATM, and ATR were present. These mutations, known to reinforce DNA repair problems in melanoma, might serve as potential treatment targets. The aggressive and fast growing behavior in animal models and the obtained phenotype in 3D culture reveal a perfect model for research in the field of NRAS mutated melanoma.

Silica bioreplication preserves three-dimensional spheroid structures of human pluripotent stem cells and HepG2 cells.

Three-dimensional (3D) cell cultures produce more in vivo-like multicellular structures such as spheroids that cannot be obtained in two-dimensional (2D) cell cultures. Thus, they are increasingly employed as models for cancer and drug research, as well as tissue engineering. It has proven challenging to stabilize spheroid architectures for detailed morphological examination. Here we overcome this issue using a silica bioreplication (SBR) process employed on spheroids formed from human pluripotent stem cells (hPSCs) and hepatocellular carcinoma HepG2 cells cultured in the nanofibrillar cellulose (NFC) hydrogel. The cells in the spheroids are more round and tightly interacting with each other than those in 2D cultures, and they develop microvilli-like structures on the cell membranes as seen in 2D cultures. Furthermore, SBR preserves extracellular matrix-like materials and cellular proteins. These findings provide the first evidence of intact hPSC spheroid architectures and similar fine structures to 2D-cultured cells, providing a pathway to enable our understanding of morphogenesis in 3D cultures.

Effect of differentiation on endocytic profiles of endothelial and epithelial cell culture models.

Understanding mechanisms of endocytosis and trafficking of nanoparticles through endothelial and epithelial barriers leads potentially to improved efficacy of nanoparticulate drug delivery systems. Detailed characterizations of cell models with respect to endocytic pathway expression and activity (endocytic profiling) should facilitate data interpretation. We performed endocytic profiling of CaCo-2 and hCMEC/D3 cell lines, widely used as human intestinal and blood-brain barrier permeability models, respectively, during cell differentiation. Furthermore, we compared endocytic profiles of cell lines with those of primary cells. Expression of genes involved in specific endocytic pathways was analyzed at mRNA levels by quantitative real time PCR. Where possible, the respective protein levels were analyzed by Western blotting, and endocytic activities of cells were analyzed by flow cytometry. We showed that differentiated CaCo-2 cells formed tight, well polarized monolayers with reduced endocytic activity accompanied by reduced mRNA expression of most of the endocytosis-related genes. In contrast, hCMEC/D3 cells formed a leaky, less polarized barrier, and in vitro differentiation had little effect on either the expression of endocytosis-related genes or endocytic activity of these cells. Endocytic profiling of in vitro models and comparison with primary cells is an important measure to avoid misleading conclusions in nanoparticle permeation studies.

The use of nanofibrillar cellulose hydrogel as a flexible three-dimensional model to culture human pluripotent stem cells.

Human embryonic stem cells and induced pluripotent stem cells have great potential in research and therapies. The current in vitro culture systems for human pluripotent stem cells (hPSCs) do not mimic the three-dimensional (3D) in vivo stem cell niche that transiently supports stem cell proliferation and is subject to changes which facilitate subsequent differentiation during development. Here, we demonstrate, for the first time, that a novel plant-derived nanofibrillar cellulose (NFC) hydrogel creates a flexible 3D environment for hPSC culture. The pluripotency of hPSCs cultured in the NFC hydrogel was maintained for 26 days as evidenced by the expression of OCT4, NANOG, and SSEA-4, in vitro embryoid body formation and in vivo teratoma formation. The use of a cellulose enzyme, cellulase, enables easy cell propagation in 3D culture as well as a shift between 3D and two-dimensional cultures. More importantly, the removal of the NFC hydrogel facilitates differentiation while retaining 3D cell organization. Thus, the NFC hydrogel represents a flexible, xeno-free 3D culture system that supports pluripotency and will be useful in hPSC-based drug research and regenerative medicine.