Growth of Endothelial Cells in Space and in Simulated Microgravity - a Comparison on the Secretory Level.

BACKGROUND/AIMS: Endothelial cells exposed to the Random Positioning Machine (RPM) reveal three different phenotypes. They grow as a two-dimensional monolayer and form three-dimensional (3D) structures such as spheroids and tubular constructs. As part of the ESA-SPHEROIDS project we want to understand how endothelial cells (ECs) react and adapt to long-term microgravity. METHODS: During a spaceflight to the International Space Station (ISS) and a subsequent stay onboard, human ECs (EA.hy926 cell line) were cultured for 12 days in real microgravity inside an automatic flight hardware, specially designed for use in space. ECs were cultivated in the absence or presence of vascular endothelial growth factor, which had demonstrated a cell-protective effect on ECs exposed to an RPM simulating microgravity. After cell fixation in space and return of the samples, we examined cell morphology and analyzed supernatants by Multianalyte Profiling technology. RESULTS: The fixed samples comprised 3D multicellular spheroids and tube-like structures in addition to monolayer cells, which are exclusively observed during growth under Earth gravity (1g). Within the 3D aggregates we detected enhanced collagen and laminin. The supernatant analysis unveiled alterations in secretion of several growth factors, cytokines, and extracellular matrix components as compared to cells cultivated at 1g or on the RPM. This confirmed an influence of gravity on interacting key proteins and genes and demonstrated a flight hardware impact on the endothelial secretome. CONCLUSION: Since formation of tube-like aggregates was observed only on the RPM and during spaceflight, we conclude that microgravity may be the major cause for ECs' 3D aggregation.

Three-dimensional growth of human endothelial cells in an automated cell culture experiment container during the SpaceX CRS-8 ISS space mission - The SPHEROIDS project.

Human endothelial cells (ECs) were sent to the International Space Station (ISS) to determine the impact of microgravity on the formation of three-dimensional structures. For this project, an automatic experiment unit (EU) was designed allowing cell culture in space. In order to enable a safe cell culture, cell nourishment and fixation after a pre-programmed timeframe, the materials used for construction of the EUs were tested in regard to their biocompatibility. These tests revealed a high biocompatibility for all parts of the EUs, which were in contact with the cells or the medium used. Most importantly, we found polyether ether ketones for surrounding the incubation chamber, which kept cellular viability above 80% and allowed the cells to adhere as long as they were exposed to normal gravity. After assembling the EU the ECs were cultured therein, where they showed good cell viability at least for 14 days. In addition, the functionality of the automatic medium exchange, and fixation procedures were confirmed. Two days before launch, the ECs were cultured in the EUs, which were afterwards mounted on the SpaceX CRS-8 rocket. 5 and 12 days after launch the cells were fixed. Subsequent analyses revealed a scaffold-free formation of spheroids in space.