The influence of microgravity on invasive growth in Saccharomyces cerevisiae

This study investigates the effects of microgravity on colony growth and the morphological transition from single cells to short invasive filaments in the model eukaryotic organism Saccharomyces cerevisiae. Two-dimensional spreading of the yeast colonies grown on semi-solid agar medium was reduced under microgravity in the Σ1278b laboratory strain but not in the CMBSESA1 industrial strain. This was supported by the Σ1278b proteome map under microgravity conditions, which revealed upregulation of proteins linked to anaerobic conditions. The Σ1278b strain showed a reduced invasive growth in the center of the yeast colony. Bud scar distribution was slightly affected, with a switch toward more random budding. Together, microgravity conditions disturb spatially programmed budding patterns and generate strain-dependent growth differences in yeast colonies on semi-solid medium.     

Greenhouse design integration benefits for extended spaceflight

It has been demonstrated that plants can be grown in microgravity, and almost every space programme has included experimental greenhouses to investigate technical and biological feasibility, as well as the habitability-related benefits of plant growth activities in space.Aside from nutritional and life support system applications, these benefits include sensory and spatial enhancement of the spacecraft environment, both through the plants as such and the design of their growth chambers, as well as by providing meaningful occupation through individual interaction. In view of long duration missions, plant growth facilities should not be regarded as a desirable add-on, but as an essential component of the habitat.Following a review of existing greenhouse designs and plants grown on past missions, the paper summarizes the benefits of greenhouses and outlines potential forms of architectural integration within the spacecraft interior.