The impact of carbon and nitrogen catabolite repression in microorganisms

•Microorganisms preferentially use different carbon and nitrogen sources.•Catabolite repression pathways influence nutrient uptake and nutrient switching.•Optimal functioning of CCR and NCR is essential for growth and survival.•CCR and NCR ensure greater flexibility in changing environmental conditi...

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Bibliographic Details
Published in:Microbiological research 2021-10, Vol.251, p.126831-126831, Article 126831
Main Authors: Nair, Abhinav, Sarma, Saurabh Jyoti
Format: Article
Language:English
Subjects:
Bacteria - genetics
Bacteria - metabolism
Carbon - metabolism
Carbon catabolite repression
Catabolite Repression
Fungi - genetics
Fungi - metabolism
Nitrogen - metabolism
Nitrogen catabolite repression
Nutrient switching
Nutrient uptake
Secondary carbon sources
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Summary:•Microorganisms preferentially use different carbon and nitrogen sources.•Catabolite repression pathways influence nutrient uptake and nutrient switching.•Optimal functioning of CCR and NCR is essential for growth and survival.•CCR and NCR ensure greater flexibility in changing environmental conditions.•CCR and NCR together interlink carbon and nitrogen metabolism in microorganisms. Organisms have cellular machinery that is focused on optimum utilization of resources to maximize growth and survival depending on various environmental and developmental factors. Catabolite repression is a strategy utilized by various species of bacteria and fungi to accommodate changes in the environment such as the depletion of resources, or an abundance of less-favored nutrient sources. Catabolite repression allows for the rapid use of certain substrates like glucose over other carbon sources. Effective handling of carbon and nitrogen catabolite repression in microorganisms is crucial to outcompete others in nutrient limiting conditions. Investigations into genes and proteins linked to preferential uptake of different nutrients under various environmental conditions can aid in identifying regulatory mechanisms that are crucial for optimum growth and survival of microorganisms. The exact time and way bacteria and fungi switch their utilization of certain nutrients is of great interest for scientific, industrial, and clinical reasons. Catabolite repression is of great significance for industrial applications that rely on microorganisms for the generation of valuable bio-products. The impact catabolite repression has on virulence of pathogenic bacteria and fungi and disease progression in hosts makes it important area of interest in medical research for the prevention of diseases and developing new treatment strategies. Regulatory networks under catabolite repression exemplify the flexibility and the tremendous diversity that is found in microorganisms and provides an impetus for newer insights into these networks.
ISSN:0944-5013
1618-0623
DOI:10.1016/j.micres.2021.126831