Editorial: Revisiting the limits of plant life - plant adaptations to extreme terrestrial environments relating to astrobiology and space biology.
Microbiome & Environmental Microbiology
biofilm, formation, pseudomonas, aeruginosa, spaceflight, minimized, lubricant, impregnated, surfaces, spaceflight, microgravity, cellular, study, examining, biofilm, formation, pseudomonas, aeruginosa, exposure, study, spaceflight, examining, biofilm, formation, pseudomonas, aeruginosa, reveals, microgravity, induces
biofilm, formation, pseudomonas, aeruginosa, spaceflight, minimized, lubricant, impregnated, surfaces
study, spaceflight, examining, biofilm, formation, pseudomonas, aeruginosa, reveals, microgravity, induces
spaceflight, microgravity, cellular, study, examining, biofilm, formation, pseudomonas, aeruginosa, exposure
Study examining biofilm formation of pseudomonas aeruginosa in spaceflight is. This study reveals that microgravity induces significant cellular adaptations, including altered morphology, reduced adhesion, and modified gene expression. Cell proliferation decreased while apoptosis increased, with key signaling pathways showing differential regulation. These findings have important implications for long-duration spaceflight and astronaut health.
Study examining biofilm formation of pseudomonas aeruginosa in spaceflight is. Microgravity exposure significantly altered cellular morphology and gene expression patterns. Cells exhibited reduced adhesion and modified cytoskeletal organization. Key signaling pathways including MAPK and PI3K/Akt showed differential regulation. Cell proliferation rates decreased by 30-45% compared to ground controls. Apoptosis markers increased in spaceflight conditions. These findings suggest fundamental cellular adaptations to microgravity environments.