Coexistence of phage and bacteria on the boundary of self-organized refuges

Silja Heilmann; Kim Sneppen; Sandeep Krishna

doi:10.1073/pnas.1200771109

Coexistence of phage and bacteria on the boundary of self-organized refuges

Silja Heilmann, Kim Sneppen, Sandeep Krishna

Abstract

Bacteriophage are voracious predators of bacteria and a major determinant in shaping bacterial life strategies. Many phage species are virulent, meaning that infection leads to certain death of the host and immediate release of a large batch of phage progeny. Despite this apparent voraciousness, bacteria have stably coexisted with virulent phages for eons. Here, using individual-based stochastic spatial models, we study the conditions for achieving coexistence on the edge between two habitats, one of which is a bacterial refuge with conditions hostile to phage whereas the other is phage friendly. We show how bacterial density-dependent, or quorum-sensing, mechanisms such as the formation of biofilm can produce such refuges and edges in a self-organized manner. Coexistence on these edges exhibits the following properties, all of which are observed in real phage-bacteria ecosystems but difficult to achieve together in nonspatial ecosystem models: (i) highly efficient virulent phage with relatively long lifetimes, high infection rates and large burst sizes; (ii) large, stable, and high-density populations of phage and bacteria; (iii) a fast turnover of both phage and bacteria; and (iv) stability over evolutionary timescales despite imbalances in the rates of phage vs. bacterial evolution.

Original language	English
Journal	Proceedings of the National Academy of Sciences of the United States of America
Volume	109
Issue number	31
Pages (from-to)	12828-33
Number of pages	6
ISSN	0027-8424
DOIs	https://doi.org/10.1073/pnas.1200771109
Publication status	Published - 31 Jul 2012

Keywords

Bacteria/virology
Bacterial Physiological Phenomena
Bacteriophages/physiology
Biological Evolution
Ecosystem
Models, Biological
Quorum Sensing/physiology

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title = "Coexistence of phage and bacteria on the boundary of self-organized refuges",

abstract = "Bacteriophage are voracious predators of bacteria and a major determinant in shaping bacterial life strategies. Many phage species are virulent, meaning that infection leads to certain death of the host and immediate release of a large batch of phage progeny. Despite this apparent voraciousness, bacteria have stably coexisted with virulent phages for eons. Here, using individual-based stochastic spatial models, we study the conditions for achieving coexistence on the edge between two habitats, one of which is a bacterial refuge with conditions hostile to phage whereas the other is phage friendly. We show how bacterial density-dependent, or quorum-sensing, mechanisms such as the formation of biofilm can produce such refuges and edges in a self-organized manner. Coexistence on these edges exhibits the following properties, all of which are observed in real phage-bacteria ecosystems but difficult to achieve together in nonspatial ecosystem models: (i) highly efficient virulent phage with relatively long lifetimes, high infection rates and large burst sizes; (ii) large, stable, and high-density populations of phage and bacteria; (iii) a fast turnover of both phage and bacteria; and (iv) stability over evolutionary timescales despite imbalances in the rates of phage vs. bacterial evolution.",

keywords = "Bacteria/virology, Bacterial Physiological Phenomena, Bacteriophages/physiology, Biological Evolution, Ecosystem, Models, Biological, Quorum Sensing/physiology",

author = "Silja Heilmann and Kim Sneppen and Sandeep Krishna",

year = "2012",

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T1 - Coexistence of phage and bacteria on the boundary of self-organized refuges

AU - Heilmann, Silja

AU - Sneppen, Kim

AU - Krishna, Sandeep

PY - 2012/7/31

Y1 - 2012/7/31

N2 - Bacteriophage are voracious predators of bacteria and a major determinant in shaping bacterial life strategies. Many phage species are virulent, meaning that infection leads to certain death of the host and immediate release of a large batch of phage progeny. Despite this apparent voraciousness, bacteria have stably coexisted with virulent phages for eons. Here, using individual-based stochastic spatial models, we study the conditions for achieving coexistence on the edge between two habitats, one of which is a bacterial refuge with conditions hostile to phage whereas the other is phage friendly. We show how bacterial density-dependent, or quorum-sensing, mechanisms such as the formation of biofilm can produce such refuges and edges in a self-organized manner. Coexistence on these edges exhibits the following properties, all of which are observed in real phage-bacteria ecosystems but difficult to achieve together in nonspatial ecosystem models: (i) highly efficient virulent phage with relatively long lifetimes, high infection rates and large burst sizes; (ii) large, stable, and high-density populations of phage and bacteria; (iii) a fast turnover of both phage and bacteria; and (iv) stability over evolutionary timescales despite imbalances in the rates of phage vs. bacterial evolution.

AB - Bacteriophage are voracious predators of bacteria and a major determinant in shaping bacterial life strategies. Many phage species are virulent, meaning that infection leads to certain death of the host and immediate release of a large batch of phage progeny. Despite this apparent voraciousness, bacteria have stably coexisted with virulent phages for eons. Here, using individual-based stochastic spatial models, we study the conditions for achieving coexistence on the edge between two habitats, one of which is a bacterial refuge with conditions hostile to phage whereas the other is phage friendly. We show how bacterial density-dependent, or quorum-sensing, mechanisms such as the formation of biofilm can produce such refuges and edges in a self-organized manner. Coexistence on these edges exhibits the following properties, all of which are observed in real phage-bacteria ecosystems but difficult to achieve together in nonspatial ecosystem models: (i) highly efficient virulent phage with relatively long lifetimes, high infection rates and large burst sizes; (ii) large, stable, and high-density populations of phage and bacteria; (iii) a fast turnover of both phage and bacteria; and (iv) stability over evolutionary timescales despite imbalances in the rates of phage vs. bacterial evolution.

KW - Bacteria/virology

KW - Bacterial Physiological Phenomena

KW - Bacteriophages/physiology

KW - Biological Evolution

KW - Ecosystem

KW - Models, Biological

KW - Quorum Sensing/physiology

U2 - 10.1073/pnas.1200771109

DO - 10.1073/pnas.1200771109

M3 - Journal article

C2 - 22807479

SN - 0027-8424

VL - 109

SP - 12828

EP - 12833

JO - Proceedings of the National Academy of Sciences of the United States of America

JF - Proceedings of the National Academy of Sciences of the United States of America

IS - 31

ER -

Coexistence of phage and bacteria on the boundary of self-organized refuges

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Keywords

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