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Auteurs principaux: Nadel, Omer, Hanna, Rawad, Rozenberg, Andrey, Shitrit, Dror, Tahan, Ran, Pekarsky, Irena, Béjà, Oded, Kleifeld, Oded, Lindell, Debbie
Format: Artículo científico
Langue:en
Publié: Nature 2025
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Accès en ligne:https://pubmed.ncbi.nlm.nih.gov/41224996/
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author Nadel, Omer
Hanna, Rawad
Rozenberg, Andrey
Shitrit, Dror
Tahan, Ran
Pekarsky, Irena
Béjà, Oded
Kleifeld, Oded
Lindell, Debbie
author_facet Nadel, Omer
Hanna, Rawad
Rozenberg, Andrey
Shitrit, Dror
Tahan, Ran
Pekarsky, Irena
Béjà, Oded
Kleifeld, Oded
Lindell, Debbie
Nadel, Omer
Hanna, Rawad
Rozenberg, Andrey
Shitrit, Dror
Tahan, Ran
Pekarsky, Irena
Béjà, Oded
Kleifeld, Oded
Lindell, Debbie
collection PubMed - marine biology
contents Viral NblA proteins negatively affect oceanic cyanobacterial photosynthesis. Nadel, Omer Hanna, Rawad Rozenberg, Andrey Shitrit, Dror Tahan, Ran Pekarsky, Irena Béjà, Oded Kleifeld, Oded Lindell, Debbie Aquatic Organisms Bacterial Proteins Bacteriophages Cyanobacteria Light-Harvesting Protein Complexes Oceans and Seas Photosynthesis Phycobilisomes Proteolysis Seawater Viral Proteins Marine picocyanobacteria are abundant photosynthetic organisms of global importance. They coexist in the ocean with cyanophages-viruses that infect cyanobacteria. Cyanophages carry many auxiliary metabolic genes acquired from their hosts that are thought to redirect host metabolism for the phage's benefit. One such gene is nblA, which is present in multiple cyanophage families. Under nutrient deprivation cyanobacterial NblA is responsible for inducing proteolytic degradation of the phycobilisome, the large cyanobacterial photosynthetic light-harvesting complex. This increases the pool of amino acids available for essential tasks, serving as a survival mechanism. Ectopic expression of different cyanophage nblA genes results in host pigment protein degradation. However, the benefit of the virus-encoded NblA for cyanophages and the broader impact on the host are unclear. Here, using a recently developed genetic manipulation system for marine cyanophages, we reveal that viral NblA significantly accelerates the cyanophage infection cycle, directs degradation of the host phycobilisome and other proteins, and reduces host photosynthetic light-harvesting efficiency. Metagenomic analysis revealed that cyanophages carrying nblA are widespread in the oceans and comprise 35% and 65% of oceanic T7-like cyanophages in surface and deep photic zones, respectively. Our results show a large benefit of NblA to the cyanophage, while it exerts a negative effect on the host photosynthetic apparatus and host photosynthesis. These findings suggest that cyanophage NblA has an adverse global impact on light harvesting by oceanic picocyanobacteria.
format Artículo científico
id pubmed_41224996
institution PubMed
language en
publishDate 2025
publisher Nature
record_format pubmed
spellingShingle Viral NblA proteins negatively affect oceanic cyanobacterial photosynthesis.
Nadel, Omer
Hanna, Rawad
Rozenberg, Andrey
Shitrit, Dror
Tahan, Ran
Pekarsky, Irena
Béjà, Oded
Kleifeld, Oded
Lindell, Debbie
Aquatic Organisms
Bacterial Proteins
Bacteriophages
Cyanobacteria
Light-Harvesting Protein Complexes
Oceans and Seas
Photosynthesis
Phycobilisomes
Proteolysis
Seawater
Viral Proteins
Viral NblA proteins negatively affect oceanic cyanobacterial photosynthesis. Nadel, Omer Hanna, Rawad Rozenberg, Andrey Shitrit, Dror Tahan, Ran Pekarsky, Irena Béjà, Oded Kleifeld, Oded Lindell, Debbie Aquatic Organisms Bacterial Proteins Bacteriophages Cyanobacteria Light-Harvesting Protein Complexes Oceans and Seas Photosynthesis Phycobilisomes Proteolysis Seawater Viral Proteins Marine picocyanobacteria are abundant photosynthetic organisms of global importance. They coexist in the ocean with cyanophages-viruses that infect cyanobacteria. Cyanophages carry many auxiliary metabolic genes acquired from their hosts that are thought to redirect host metabolism for the phage's benefit. One such gene is nblA, which is present in multiple cyanophage families. Under nutrient deprivation cyanobacterial NblA is responsible for inducing proteolytic degradation of the phycobilisome, the large cyanobacterial photosynthetic light-harvesting complex. This increases the pool of amino acids available for essential tasks, serving as a survival mechanism. Ectopic expression of different cyanophage nblA genes results in host pigment protein degradation. However, the benefit of the virus-encoded NblA for cyanophages and the broader impact on the host are unclear. Here, using a recently developed genetic manipulation system for marine cyanophages, we reveal that viral NblA significantly accelerates the cyanophage infection cycle, directs degradation of the host phycobilisome and other proteins, and reduces host photosynthetic light-harvesting efficiency. Metagenomic analysis revealed that cyanophages carrying nblA are widespread in the oceans and comprise 35% and 65% of oceanic T7-like cyanophages in surface and deep photic zones, respectively. Our results show a large benefit of NblA to the cyanophage, while it exerts a negative effect on the host photosynthetic apparatus and host photosynthesis. These findings suggest that cyanophage NblA has an adverse global impact on light harvesting by oceanic picocyanobacteria.
title Viral NblA proteins negatively affect oceanic cyanobacterial photosynthesis.
topic Aquatic Organisms
Bacterial Proteins
Bacteriophages
Cyanobacteria
Light-Harvesting Protein Complexes
Oceans and Seas
Photosynthesis
Phycobilisomes
Proteolysis
Seawater
Viral Proteins
url https://pubmed.ncbi.nlm.nih.gov/41224996/