Articles
●
Metabolism & Nutrition
●
Spatial regulation of a common precursor from two distinct genes generates metabolite diversity
Spatial regulation of a common precursor from two distinct genes generates metabolite diversity
Metabolism & Nutrition
Abstractive Summary
Study examining genomic, functional, and metabolic enhancements in multidrug-resistant enterobacter. Space travel induces significant metabolic changes, including insulin resistance, altered lipid profiles, and reduced metabolic rate. Vitamin D deficiency and gut microbiome shifts are common. These metabolic adaptations have implications for nutrition planning and long-term health maintenance during extended missions.
Extractive Summary
Study examining genomic, functional, and metabolic enhancements in multidrug-resistant enterobacter. Metabolic function was substantially altered in space environments. Glucose metabolism showed insulin resistance patterns. Lipid profiles shifted with elevated triglycerides. Energy expenditure patterns changed despite controlled diet. Metabolic rate decreased by 5-10% during long missions. Vitamin D deficiency was common despite supplementation. Gut microbiome composition shifted significantly.
554
Keywords
genomic, functional, metabolic, enhancements, multidrug, resistant, enterobacter, bugandensis, facilitating, persistence, metabolic, patterns, shifted, despite, study, examining, genomic, functional, enhancements, multidrug, metabolic, study, examining, genomic, functional, enhancements, multidrug, resistant, enterobacter, space
Abstractive Keywords
metabolic, study, examining, genomic, functional, enhancements, multidrug, resistant, enterobacter, space
Extractive Keywords
metabolic, patterns, shifted, despite, study, examining, genomic, functional, enhancements, multidrug
Topic Match Articles