Environment-specific virocell metabolic reprogramming

Cristina Howard-Varona; Morgan M. Lindback; Jane D. Fudyma; Azriel Krongauz; Natalie E. Solonenko; Ahmed A. Zayed; William B. Andreopoulos; Heather M. Olson; Young Mo Kim; Jennifer E. Kyle; Tijana Glavina del Rio; Joshua N. Adkins; Malak M. Tfaily; Subhadeep Paul; Matthew B. Sullivan; Melissa B. Duhaime

doi:10.1093/ismejo/wrae055

Environment-specific virocell metabolic reprogramming

Cristina Howard-Varona, Morgan M. Lindback, Jane D. Fudyma, Azriel Krongauz, Natalie E. Solonenko, Ahmed A. Zayed, William B. Andreopoulos, Heather M. Olson, Young Mo Kim, Jennifer E. Kyle, Tijana Glavina del Rio, Joshua N. Adkins, Malak M. Tfaily, Subhadeep Paul, Matthew B. Sullivan, Melissa B. Duhaime

Environmental Science, Research

Research output: Contribution to journal › Article › peer-review

2 Scopus citations

Abstract

Viruses impact microbial systems through killing hosts, horizontal gene transfer, and altering cellular metabolism, consequently impacting nutrient cycles. A virus-infected cell, a "virocell,"is distinct from its uninfected sister cell as the virus commandeers cellular machinery to produce viruses rather than replicate cells. Problematically, virocell responses to the nutrient-limited conditions that abound in nature are poorly understood. Here we used a systems biology approach to investigate virocell metabolic reprogramming under nutrient limitation. Using transcriptomics, proteomics, lipidomics, and endo-and exo-metabolomics, we assessed how low phosphate (low-P) conditions impacted virocells of a marine Pseudoalteromonas host when independently infected by two unrelated phages (HP1 and HS2). With the combined stresses of infection and nutrient limitation, a set of nested responses were observed. First, low-P imposed common cellular responses on all cells (virocells and uninfected cells), including activating the canonical P-stress response, and decreasing transcription, translation, and extracellular organic matter consumption. Second, low-P imposed infection-specific responses (for both virocells), including enhancing nitrogen assimilation and fatty acid degradation, and decreasing extracellular lipid relative abundance. Third, low-P suggested virocell-specific strategies. Specifically, HS2-virocells regulated gene expression by increasing transcription and ribosomal protein production, whereas HP1-virocells accumulated host proteins, decreased extracellular peptide relative abundance, and invested in broader energy and resource acquisition. These results suggest that although environmental conditions shape metabolism in common ways regardless of infection, virocell-specific strategies exist to support viral replication during nutrient limitation, and a framework now exists for identifying metabolic strategies of nutrient-limited virocells in nature.

Original language	English (US)
Article number	wrae055
Journal	ISME Journal
Volume	18
Issue number	1
DOIs	https://doi.org/10.1093/ismejo/wrae055
State	Published - Jan 1 2024

Keywords

bacteria
ecology
marine
metabolic reprogramming
multi-omics
nutrient limitation
virocell
virus

ASJC Scopus subject areas

Microbiology
Ecology, Evolution, Behavior and Systematics

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10.1093/ismejo/wrae055

Cite this

Howard-Varona, C., Lindback, M. M., Fudyma, J. D., Krongauz, A., Solonenko, N. E., Zayed, A. A., Andreopoulos, W. B., Olson, H. M., Kim, Y. M., Kyle, J. E., del Rio, T. G., Adkins, J. N., Tfaily, M. M., Paul, S., Sullivan, M. B., & Duhaime, M. B. (2024). Environment-specific virocell metabolic reprogramming. ISME Journal, 18(1), Article wrae055. https://doi.org/10.1093/ismejo/wrae055

@article{c08202911aac4766960cf17377ac57e8,

title = "Environment-specific virocell metabolic reprogramming",

abstract = "Viruses impact microbial systems through killing hosts, horizontal gene transfer, and altering cellular metabolism, consequently impacting nutrient cycles. A virus-infected cell, a {"}virocell,{"}is distinct from its uninfected sister cell as the virus commandeers cellular machinery to produce viruses rather than replicate cells. Problematically, virocell responses to the nutrient-limited conditions that abound in nature are poorly understood. Here we used a systems biology approach to investigate virocell metabolic reprogramming under nutrient limitation. Using transcriptomics, proteomics, lipidomics, and endo-and exo-metabolomics, we assessed how low phosphate (low-P) conditions impacted virocells of a marine Pseudoalteromonas host when independently infected by two unrelated phages (HP1 and HS2). With the combined stresses of infection and nutrient limitation, a set of nested responses were observed. First, low-P imposed common cellular responses on all cells (virocells and uninfected cells), including activating the canonical P-stress response, and decreasing transcription, translation, and extracellular organic matter consumption. Second, low-P imposed infection-specific responses (for both virocells), including enhancing nitrogen assimilation and fatty acid degradation, and decreasing extracellular lipid relative abundance. Third, low-P suggested virocell-specific strategies. Specifically, HS2-virocells regulated gene expression by increasing transcription and ribosomal protein production, whereas HP1-virocells accumulated host proteins, decreased extracellular peptide relative abundance, and invested in broader energy and resource acquisition. These results suggest that although environmental conditions shape metabolism in common ways regardless of infection, virocell-specific strategies exist to support viral replication during nutrient limitation, and a framework now exists for identifying metabolic strategies of nutrient-limited virocells in nature.",

keywords = "bacteria, ecology, marine, metabolic reprogramming, multi-omics, nutrient limitation, virocell, virus",

author = "Cristina Howard-Varona and Lindback, {Morgan M.} and Fudyma, {Jane D.} and Azriel Krongauz and Solonenko, {Natalie E.} and Zayed, {Ahmed A.} and Andreopoulos, {William B.} and Olson, {Heather M.} and Kim, {Young Mo} and Kyle, {Jennifer E.} and {del Rio}, {Tijana Glavina} and Adkins, {Joshua N.} and Tfaily, {Malak M.} and Subhadeep Paul and Sullivan, {Matthew B.} and Duhaime, {Melissa B.}",

note = "Publisher Copyright: {\textcopyright} The Author(s) 2024.",

year = "2024",

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doi = "10.1093/ismejo/wrae055",

language = "English (US)",

volume = "18",

journal = "ISME Journal",

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TY - JOUR

T1 - Environment-specific virocell metabolic reprogramming

AU - Howard-Varona, Cristina

AU - Lindback, Morgan M.

AU - Fudyma, Jane D.

AU - Krongauz, Azriel

AU - Solonenko, Natalie E.

AU - Zayed, Ahmed A.

AU - Andreopoulos, William B.

AU - Olson, Heather M.

AU - Kim, Young Mo

AU - Kyle, Jennifer E.

AU - del Rio, Tijana Glavina

AU - Adkins, Joshua N.

AU - Tfaily, Malak M.

AU - Paul, Subhadeep

AU - Sullivan, Matthew B.

AU - Duhaime, Melissa B.

N1 - Publisher Copyright: © The Author(s) 2024.

PY - 2024/1/1

Y1 - 2024/1/1

N2 - Viruses impact microbial systems through killing hosts, horizontal gene transfer, and altering cellular metabolism, consequently impacting nutrient cycles. A virus-infected cell, a "virocell,"is distinct from its uninfected sister cell as the virus commandeers cellular machinery to produce viruses rather than replicate cells. Problematically, virocell responses to the nutrient-limited conditions that abound in nature are poorly understood. Here we used a systems biology approach to investigate virocell metabolic reprogramming under nutrient limitation. Using transcriptomics, proteomics, lipidomics, and endo-and exo-metabolomics, we assessed how low phosphate (low-P) conditions impacted virocells of a marine Pseudoalteromonas host when independently infected by two unrelated phages (HP1 and HS2). With the combined stresses of infection and nutrient limitation, a set of nested responses were observed. First, low-P imposed common cellular responses on all cells (virocells and uninfected cells), including activating the canonical P-stress response, and decreasing transcription, translation, and extracellular organic matter consumption. Second, low-P imposed infection-specific responses (for both virocells), including enhancing nitrogen assimilation and fatty acid degradation, and decreasing extracellular lipid relative abundance. Third, low-P suggested virocell-specific strategies. Specifically, HS2-virocells regulated gene expression by increasing transcription and ribosomal protein production, whereas HP1-virocells accumulated host proteins, decreased extracellular peptide relative abundance, and invested in broader energy and resource acquisition. These results suggest that although environmental conditions shape metabolism in common ways regardless of infection, virocell-specific strategies exist to support viral replication during nutrient limitation, and a framework now exists for identifying metabolic strategies of nutrient-limited virocells in nature.

AB - Viruses impact microbial systems through killing hosts, horizontal gene transfer, and altering cellular metabolism, consequently impacting nutrient cycles. A virus-infected cell, a "virocell,"is distinct from its uninfected sister cell as the virus commandeers cellular machinery to produce viruses rather than replicate cells. Problematically, virocell responses to the nutrient-limited conditions that abound in nature are poorly understood. Here we used a systems biology approach to investigate virocell metabolic reprogramming under nutrient limitation. Using transcriptomics, proteomics, lipidomics, and endo-and exo-metabolomics, we assessed how low phosphate (low-P) conditions impacted virocells of a marine Pseudoalteromonas host when independently infected by two unrelated phages (HP1 and HS2). With the combined stresses of infection and nutrient limitation, a set of nested responses were observed. First, low-P imposed common cellular responses on all cells (virocells and uninfected cells), including activating the canonical P-stress response, and decreasing transcription, translation, and extracellular organic matter consumption. Second, low-P imposed infection-specific responses (for both virocells), including enhancing nitrogen assimilation and fatty acid degradation, and decreasing extracellular lipid relative abundance. Third, low-P suggested virocell-specific strategies. Specifically, HS2-virocells regulated gene expression by increasing transcription and ribosomal protein production, whereas HP1-virocells accumulated host proteins, decreased extracellular peptide relative abundance, and invested in broader energy and resource acquisition. These results suggest that although environmental conditions shape metabolism in common ways regardless of infection, virocell-specific strategies exist to support viral replication during nutrient limitation, and a framework now exists for identifying metabolic strategies of nutrient-limited virocells in nature.

KW - bacteria

KW - ecology

KW - marine

KW - metabolic reprogramming

KW - multi-omics

KW - nutrient limitation

KW - virocell

KW - virus

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DO - 10.1093/ismejo/wrae055

M3 - Article

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AN - SCOPUS:85196129834

SN - 1751-7362

VL - 18

JO - ISME Journal

JF - ISME Journal

IS - 1

M1 - wrae055

ER -

Environment-specific virocell metabolic reprogramming

Abstract

Keywords

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