Metabolic Profiles of Clinical Strain of Staphylococcus aureus to Subtle Changes in the Environmental Parameters at Different Phases of Growth

• Main Author: Mousa M. Alreshidi
• Format: Article
• Language: English
• Published: Journal of Pure and Applied Microbiology 2020-03-01
• Series: Journal of Pure and Applied Microbiology
• Subjects: cytoplasmic metabolites; s. aureus; metabolic homeostasis; stress responses
• Online Access: https://microbiologyjournal.org/metabolic-profiles-of-clinical-strain-of-staphylococcus-aureus-to-subtle-changes-in-the-environmental-parameters-at-different-phases-of-growth/

Staphylococcus aureusis an important pathogen that can lead to high number of infections worldwide. The present study was aimed to investigate cytoplasmic metabolites of S. aureus at mid-exponential and stationary phases following growth in a combination of conditions including variations in pH and temperature. The result of metabolic analysis demonstrated that most of the metabolites measured at stationary phase under optimal conditions were significantly altered in comparison to equivalent cells harvested at mid- exponential phase. The major alteration was mainly observed in nitrogenous bases and organic acids, which were relatively decreased in cells grown to stationary phase, while mannitol, galactonic acid and adenosine were relatively increased in the cultures harvested at stationary phase. At both phases, the metabolic profiles were substantially different between cultures grown under ideal control conditions compared with those grown under more acidic and alkali conditions with lower temperature of 35°C. The analyses of cells harvested from control and treatment samples at mid-exponential phase showed that nitrogenous bases including uracil and adenine were significantly decrease in treatment groups compared with reference controls. However, these metabolites were relatively increased in the treatment cells grown to stationary phase. It was evident that variants in environmental parameters led to differential profiles of cytoplasmic metabolites during adaptation processes to applied conditions. These results provided robust evidence supporting the hypothesis that specific alterations in cytoplasmic metabolites were essential for S. aureus to adapt and hence survive under changes in the environmental parameters.