Longitudinal characterization of multispecies microbial populations recovered from spaceflight potable water
Metabolism & Nutrition
transcriptome, proteome, responses, rnalater, preserved, tissue, arabidopsis, thaliana, responses, growth, study, examining, transcriptome, proteome, rnalater, preserved, tissue, plant, responses, study, examining, transcriptome, proteome, rnalater, preserved, tissue, microgravity, profoundly
transcriptome, proteome, responses, rnalater, preserved, tissue, arabidopsis, thaliana
responses, study, examining, transcriptome, proteome, rnalater, preserved, tissue, microgravity, profoundly
responses, growth, study, examining, transcriptome, proteome, rnalater, preserved, tissue, plant
Study examining transcriptome and proteome responses in rnalater preserved tissue. Microgravity profoundly affects plant biology, disrupting normal gravitropic responses while enhancing phototropism. Gene expression, cell wall structure, and reproductive processes are all modified. Understanding these adaptations is crucial for developing sustainable food production systems for long-duration space missions.
Study examining transcriptome and proteome responses in rnalater preserved tissue. Plant growth and development were significantly altered in microgravity conditions. Root gravitropism was disrupted with random directional growth. Phototropic responses remained functional but were enhanced. Gene expression patterns differed substantially from ground controls. Cell wall synthesis and structure were modified. Flowering time and reproductive success varied among species tested.