Development of a Three-Dimensional In Vitro Model for Longitudinal Observation of Cell Behavior: Monitoring by Magnetic Resonance Imaging and Optical Imaging

Purpose: The aim of this study is the development of a three-dimensional multicellular spheroid cell culture model for the longitudinal comparative and large-scale screening of cancer cell proliferation with noninvasive molecular imaging techniques under controlled and quantifiable conditions. Procedures: The human glioblastoma cell line Gli36ΔEGFR was genetically modified to constitutively express the fluorescence protein mCherry, and additionally labeled with iron oxide nanoparticles for high-field MRI detection. The proliferation of aggregates was longitudinally monitored with fluorescence imaging and correlated with aggregate size by light microscopy, while MRI measurements served localization in 3D space. Irradiation with γ-rays was used to detect proliferational response. Results: Cell proliferation in the stationary three-dimensonal model can be observed over days with high accuracy. A linear relationship of fluorescence intensity with cell aggregate size was found, allowing absolute quantitation of cells in a wide range of cell amounts. Glioblastoma cells showed pronounced suppression of proliferation for several days following high-dose γ-irradiation. Conclusions: Through the combination of two-dimensional optical imaging and 3D MRI, the position of individual cell aggregates and their corresponding light emission can be detected. This allows an exact quantification of cell proliferation, with a focus on very small cell amounts (below 100 cells) using high resolution noninvasive techniques as a well-controlled basis for further cell transplantation studies

Ceramide synthase 4 regulates stem cell homeostasis and hair follicle cycling

Ceramides are crucial for skin barrier function, but little is known about the regulation of epidermal appendages and whether stem cell populations that control their regeneration depend on specific ceramide species. Here we demonstrate that ceramide synthase 4 (CerS4) is highly expressed in the epidermis of adult mice where it is localized in the interfollicular epidermis and defined populations within the pilosebaceous unit. Inactivation of CerS4 in mice resulted in precocious activation of hair follicle bulge stem cells while expanding the Lrig1+ junctional zone and sebaceous glands. This was preceded first by a decrease in bone morphogenetic protein (BMP) and a subsequent increase in Wnt signaling. This imbalance in quiescent versus activating signals likely promoted a prolonged anagen-like hair follicle state after the second catagen, which exhausted stem cells over time ultimately resulting in hair loss in aged mice. K14-Cre-mediated deletion of CerS4 revealed a similar phenotype, thus suggesting an epidermis intrinsic function of CerS4 in regulating the regeneration of the pilosebaceous unit. The data indicate that CerS4-directed epidermal ceramide composition is essential to control hair follicle stem and progenitor cell behavior potentially through its regulation of BMP and Wnt signaling