The Development of Bacteriophage Resistance in Vibrio alginolyticus Depends on a Complex Metabolic Adaptation Strategy

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The Development of Bacteriophage Resistance in Vibrio alginolyticus Depends on a Complex Metabolic Adaptation Strategy. / Skliros, Dimitrios; Kalatzis, Panos G.; Kalloniati, Chrysanthi; Komaitis, Fotios; Papathanasiou, Sokratis; Kouri, Evangelia D.; Udvardi, Michael K.; Kokkari, Constantina; Katharios, Pantelis; Flemetakis, Emmanouil.

In: Viruses, Vol. 13, No. 4, 656, 2021.

Research output: Contribution to journalJournal articleResearchpeer-review

Harvard

Skliros, D, Kalatzis, PG, Kalloniati, C, Komaitis, F, Papathanasiou, S, Kouri, ED, Udvardi, MK, Kokkari, C, Katharios, P & Flemetakis, E 2021, 'The Development of Bacteriophage Resistance in Vibrio alginolyticus Depends on a Complex Metabolic Adaptation Strategy', Viruses, vol. 13, no. 4, 656. https://doi.org/10.3390/v13040656

APA

Skliros, D., Kalatzis, P. G., Kalloniati, C., Komaitis, F., Papathanasiou, S., Kouri, E. D., Udvardi, M. K., Kokkari, C., Katharios, P., & Flemetakis, E. (2021). The Development of Bacteriophage Resistance in Vibrio alginolyticus Depends on a Complex Metabolic Adaptation Strategy. Viruses, 13(4), [656]. https://doi.org/10.3390/v13040656

Vancouver

Skliros D, Kalatzis PG, Kalloniati C, Komaitis F, Papathanasiou S, Kouri ED et al. The Development of Bacteriophage Resistance in Vibrio alginolyticus Depends on a Complex Metabolic Adaptation Strategy. Viruses. 2021;13(4). 656. https://doi.org/10.3390/v13040656

Author

Skliros, Dimitrios ; Kalatzis, Panos G. ; Kalloniati, Chrysanthi ; Komaitis, Fotios ; Papathanasiou, Sokratis ; Kouri, Evangelia D. ; Udvardi, Michael K. ; Kokkari, Constantina ; Katharios, Pantelis ; Flemetakis, Emmanouil. / The Development of Bacteriophage Resistance in Vibrio alginolyticus Depends on a Complex Metabolic Adaptation Strategy. In: Viruses. 2021 ; Vol. 13, No. 4.

Bibtex

@article{56cb4181419f469ea5317093c5099b5b,
title = "The Development of Bacteriophage Resistance in Vibrio alginolyticus Depends on a Complex Metabolic Adaptation Strategy",
abstract = "Lytic bacteriophages have been well documented to play a pivotal role in microbial ecology due to their complex interactions with bacterial species, especially in aquatic habitats. Although the use of phages as antimicrobial agents, known as phage therapy, in the aquatic environment has been increasing, recent research has revealed drawbacks due to the development of phage-resistant strains among Gram-negative species. Acquired phage resistance in marine Vibrios has been proven to be a very complicated process utilizing biochemical, metabolic, and molecular adaptation strategies. The results of our multi-omics approach, incorporating transcriptome and metabolome analyses of Vibrio alginolyticus phage-resistant strains, corroborate this prospect. Our results provide insights into phage-tolerant strains diminishing the expression of phage receptors ompF, lamB, and btuB. The same pattern was observed for genes encoding natural nutrient channels, such as rbsA, ptsG, tryP, livH, lysE, and hisp, meaning that the cell needs to readjust its biochemistry to achieve phage resistance. The results showed reprogramming of bacterial metabolism by transcript regulations in key-metabolic pathways, such as the tricarboxylic acid cycle (TCA) and lysine biosynthesis, as well as the content of intracellular metabolites belonging to processes that could also significantly affect the cell physiology. Finally, SNP analysis in resistant strains revealed no evidence of amino acid alterations in the studied putative bacterial phage receptors, but several SNPs were detected in genes involved in transcriptional regulation. This phenomenon appears to be a phage-specific, fine-tuned metabolic engineering, imposed by the different phage genera the bacteria have interacted with, updating the role of lytic phages in microbial marine ecology.",
keywords = "host&#8211, phage interaction, receptors, transporters, Vibrio alginolyticus, acquired phage resistance, metabolic reprogramming, bacteriophages, host metabolism",
author = "Dimitrios Skliros and Kalatzis, {Panos G.} and Chrysanthi Kalloniati and Fotios Komaitis and Sokratis Papathanasiou and Kouri, {Evangelia D.} and Udvardi, {Michael K.} and Constantina Kokkari and Pantelis Katharios and Emmanouil Flemetakis",
year = "2021",
doi = "10.3390/v13040656",
language = "English",
volume = "13",
journal = "Viruses",
issn = "1999-4915",
publisher = "M D P I AG",
number = "4",

}

RIS

TY - JOUR

T1 - The Development of Bacteriophage Resistance in Vibrio alginolyticus Depends on a Complex Metabolic Adaptation Strategy

AU - Skliros, Dimitrios

AU - Kalatzis, Panos G.

AU - Kalloniati, Chrysanthi

AU - Komaitis, Fotios

AU - Papathanasiou, Sokratis

AU - Kouri, Evangelia D.

AU - Udvardi, Michael K.

AU - Kokkari, Constantina

AU - Katharios, Pantelis

AU - Flemetakis, Emmanouil

PY - 2021

Y1 - 2021

N2 - Lytic bacteriophages have been well documented to play a pivotal role in microbial ecology due to their complex interactions with bacterial species, especially in aquatic habitats. Although the use of phages as antimicrobial agents, known as phage therapy, in the aquatic environment has been increasing, recent research has revealed drawbacks due to the development of phage-resistant strains among Gram-negative species. Acquired phage resistance in marine Vibrios has been proven to be a very complicated process utilizing biochemical, metabolic, and molecular adaptation strategies. The results of our multi-omics approach, incorporating transcriptome and metabolome analyses of Vibrio alginolyticus phage-resistant strains, corroborate this prospect. Our results provide insights into phage-tolerant strains diminishing the expression of phage receptors ompF, lamB, and btuB. The same pattern was observed for genes encoding natural nutrient channels, such as rbsA, ptsG, tryP, livH, lysE, and hisp, meaning that the cell needs to readjust its biochemistry to achieve phage resistance. The results showed reprogramming of bacterial metabolism by transcript regulations in key-metabolic pathways, such as the tricarboxylic acid cycle (TCA) and lysine biosynthesis, as well as the content of intracellular metabolites belonging to processes that could also significantly affect the cell physiology. Finally, SNP analysis in resistant strains revealed no evidence of amino acid alterations in the studied putative bacterial phage receptors, but several SNPs were detected in genes involved in transcriptional regulation. This phenomenon appears to be a phage-specific, fine-tuned metabolic engineering, imposed by the different phage genera the bacteria have interacted with, updating the role of lytic phages in microbial marine ecology.

AB - Lytic bacteriophages have been well documented to play a pivotal role in microbial ecology due to their complex interactions with bacterial species, especially in aquatic habitats. Although the use of phages as antimicrobial agents, known as phage therapy, in the aquatic environment has been increasing, recent research has revealed drawbacks due to the development of phage-resistant strains among Gram-negative species. Acquired phage resistance in marine Vibrios has been proven to be a very complicated process utilizing biochemical, metabolic, and molecular adaptation strategies. The results of our multi-omics approach, incorporating transcriptome and metabolome analyses of Vibrio alginolyticus phage-resistant strains, corroborate this prospect. Our results provide insights into phage-tolerant strains diminishing the expression of phage receptors ompF, lamB, and btuB. The same pattern was observed for genes encoding natural nutrient channels, such as rbsA, ptsG, tryP, livH, lysE, and hisp, meaning that the cell needs to readjust its biochemistry to achieve phage resistance. The results showed reprogramming of bacterial metabolism by transcript regulations in key-metabolic pathways, such as the tricarboxylic acid cycle (TCA) and lysine biosynthesis, as well as the content of intracellular metabolites belonging to processes that could also significantly affect the cell physiology. Finally, SNP analysis in resistant strains revealed no evidence of amino acid alterations in the studied putative bacterial phage receptors, but several SNPs were detected in genes involved in transcriptional regulation. This phenomenon appears to be a phage-specific, fine-tuned metabolic engineering, imposed by the different phage genera the bacteria have interacted with, updating the role of lytic phages in microbial marine ecology.

KW - host&#8211

KW - phage interaction

KW - receptors

KW - transporters

KW - Vibrio alginolyticus

KW - acquired phage resistance

KW - metabolic reprogramming

KW - bacteriophages

KW - host metabolism

U2 - 10.3390/v13040656

DO - 10.3390/v13040656

M3 - Journal article

C2 - 33920240

VL - 13

JO - Viruses

JF - Viruses

SN - 1999-4915

IS - 4

M1 - 656

ER -

ID: 261216018