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Hauptverfasser: Carr, Alex V, Otwell, Anne E, Hunt, Kristopher A, Chen, Yan, Wilson, James, Faria, José P, Liu, Filipe, Edirisinghe, Janaka N, Valenzuela, Jacob J, Turkarslan, Serdar, Lui, Lauren M, Nielsen, Torben N, Arkin, Adam P, Henry, Christopher S, Petzold, Christopher J, Stahl, David A, Baliga, Nitin S
Format: Artículo científico
Sprache:en
Veröffentlicht: The ISME journal 2025
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Online-Zugang:https://pubmed.ncbi.nlm.nih.gov/40349173/
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author Carr, Alex V
Otwell, Anne E
Hunt, Kristopher A
Chen, Yan
Wilson, James
Faria, José P
Liu, Filipe
Edirisinghe, Janaka N
Valenzuela, Jacob J
Turkarslan, Serdar
Lui, Lauren M
Nielsen, Torben N
Arkin, Adam P
Henry, Christopher S
Petzold, Christopher J
Stahl, David A
Baliga, Nitin S
author_facet Carr, Alex V
Otwell, Anne E
Hunt, Kristopher A
Chen, Yan
Wilson, James
Faria, José P
Liu, Filipe
Edirisinghe, Janaka N
Valenzuela, Jacob J
Turkarslan, Serdar
Lui, Lauren M
Nielsen, Torben N
Arkin, Adam P
Henry, Christopher S
Petzold, Christopher J
Stahl, David A
Baliga, Nitin S
Carr, Alex V
Otwell, Anne E
Hunt, Kristopher A
Chen, Yan
Wilson, James
Faria, José P
Liu, Filipe
Edirisinghe, Janaka N
Valenzuela, Jacob J
Turkarslan, Serdar
Lui, Lauren M
Nielsen, Torben N
Arkin, Adam P
Henry, Christopher S
Petzold, Christopher J
Stahl, David A
Baliga, Nitin S
collection PubMed - marine biology
contents Emergence and disruption of cooperativity in a denitrifying microbial community. Carr, Alex V Otwell, Anne E Hunt, Kristopher A Chen, Yan Wilson, James Faria, José P Liu, Filipe Edirisinghe, Janaka N Valenzuela, Jacob J Turkarslan, Serdar Lui, Lauren M Nielsen, Torben N Arkin, Adam P Henry, Christopher S Petzold, Christopher J Stahl, David A Baliga, Nitin S Denitrification Nitrates Comamonadaceae Nitrites Nitrous Oxide Nitric Oxide Microbiota Anthropogenic perturbations to the nitrogen cycle, primarily through use of synthetic fertilizers, is driving an unprecedented increase in the emission of nitrous oxide (N2O), a potent greenhouse gas and an ozone depleting substance, causing urgency in identifying the sources and sinks of N2O. Microbial denitrification is a primary contributor to biotic production of N2O in anoxic regions of soil, marine systems, and wastewater treatment facilities. Here, through comprehensive genome analysis, we show that pathway partitioning is a ubiquitous mechanism of complete denitrification within microbial communities. We have investigated mechanisms and consequences of process partitioning of denitrification through detailed physiological characterization and kinetic modeling of a synthetic community of Rhodanobacter thiooxydans FW510-R12 and Acidovorax sp. GW101-3H11. We have discovered that these two bacterial isolates, from a heavily nitrate (NO3-) contaminated superfund site, complete denitrification through the exchange of nitrite (NO2-) and nitric oxide (NO). The process partitioning of denitrification and other processes, including amino acid metabolism, contribute to increased cooperativity within this denitrifying community. We demonstrate that certain contexts, such as high NO3-, cause unbalanced growth of community members, due to differences in their substrate utilization kinetics. The altered growth characteristics of community members drives accumulation of toxic NO2-, which disrupts denitrification causing N2O off gassing.
format Artículo científico
id pubmed_40349173
institution PubMed
language en
publishDate 2025
publisher The ISME journal
record_format pubmed
spellingShingle Emergence and disruption of cooperativity in a denitrifying microbial community.
Carr, Alex V
Otwell, Anne E
Hunt, Kristopher A
Chen, Yan
Wilson, James
Faria, José P
Liu, Filipe
Edirisinghe, Janaka N
Valenzuela, Jacob J
Turkarslan, Serdar
Lui, Lauren M
Nielsen, Torben N
Arkin, Adam P
Henry, Christopher S
Petzold, Christopher J
Stahl, David A
Baliga, Nitin S
Denitrification
Nitrates
Comamonadaceae
Nitrites
Nitrous Oxide
Nitric Oxide
Microbiota
Emergence and disruption of cooperativity in a denitrifying microbial community. Carr, Alex V Otwell, Anne E Hunt, Kristopher A Chen, Yan Wilson, James Faria, José P Liu, Filipe Edirisinghe, Janaka N Valenzuela, Jacob J Turkarslan, Serdar Lui, Lauren M Nielsen, Torben N Arkin, Adam P Henry, Christopher S Petzold, Christopher J Stahl, David A Baliga, Nitin S Denitrification Nitrates Comamonadaceae Nitrites Nitrous Oxide Nitric Oxide Microbiota Anthropogenic perturbations to the nitrogen cycle, primarily through use of synthetic fertilizers, is driving an unprecedented increase in the emission of nitrous oxide (N2O), a potent greenhouse gas and an ozone depleting substance, causing urgency in identifying the sources and sinks of N2O. Microbial denitrification is a primary contributor to biotic production of N2O in anoxic regions of soil, marine systems, and wastewater treatment facilities. Here, through comprehensive genome analysis, we show that pathway partitioning is a ubiquitous mechanism of complete denitrification within microbial communities. We have investigated mechanisms and consequences of process partitioning of denitrification through detailed physiological characterization and kinetic modeling of a synthetic community of Rhodanobacter thiooxydans FW510-R12 and Acidovorax sp. GW101-3H11. We have discovered that these two bacterial isolates, from a heavily nitrate (NO3-) contaminated superfund site, complete denitrification through the exchange of nitrite (NO2-) and nitric oxide (NO). The process partitioning of denitrification and other processes, including amino acid metabolism, contribute to increased cooperativity within this denitrifying community. We demonstrate that certain contexts, such as high NO3-, cause unbalanced growth of community members, due to differences in their substrate utilization kinetics. The altered growth characteristics of community members drives accumulation of toxic NO2-, which disrupts denitrification causing N2O off gassing.
title Emergence and disruption of cooperativity in a denitrifying microbial community.
topic Denitrification
Nitrates
Comamonadaceae
Nitrites
Nitrous Oxide
Nitric Oxide
Microbiota
url https://pubmed.ncbi.nlm.nih.gov/40349173/