Mechanism of bacterial predation via ixotrophy

Yun-Wei Lien; Davide Amendola; Kang Soo Lee; Nina Bartlau; Jingwei Xu; Go Furusawa; Martin F Polz; Roman Stocker; Gregor L Weiss; Martin Pilhofer

doi:10.1126/science.adp0614

Mechanism of bacterial predation via ixotrophy

Yun-Wei Lien, Davide Amendola, Kang Soo Lee, Nina Bartlau, Jingwei Xu, Go Furusawa, Martin F Polz, Roman Stocker, Gregor L Weiss (Corresponding author), Martin Pilhofer (Corresponding author)

Department of Microbiology and Ecosystem Science

Publications: Contribution to journal › Article › Peer Reviewed

Abstract

Ixotrophy is a contact-dependent predatory strategy of filamentous bacteria in aquatic environments for which the molecular mechanism remains unknown. We show that predator-prey contact can be established by gliding motility or extracellular assemblages we call "grappling hooks." Cryo-electron microscopy identified the grappling hooks as heptamers of a type IX secretion system substrate. After close predator-prey contact is established, cryo-electron tomography and functional assays showed that puncturing by a type VI secretion system mediated killing. Single-cell analyses with stable isotope-labeled prey revealed that prey components are taken up by the attacker. Depending on nutrient availability, insertion sequence elements toggle the activity of ixotrophy. A marine metagenomic time series shows coupled dynamics of ixotrophic bacteria and prey. We found that the mechanism of ixotrophy involves multiple cellular machineries, is conserved, and may shape microbial populations in the environment.

Original language	English
Article number	eadp0614
Journal	Science
Volume	386
Issue number	6719
DOIs	https://doi.org/10.1126/science.adp0614
Publication status	Published - 18 Oct 2024

Austrian Fields of Science 2012

106022 Microbiology

Keywords

Bacterial Adhesion
Bacteroidetes/physiology
Cryoelectron Microscopy
Single-Cell Analysis
Type VI Secretion Systems/metabolism
Vibrio/physiology
Flagella/ultrastructure

UN SDGs

This output contributes to the following UN Sustainable Development Goals (SDGs)

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10.1126/science.adp0614

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title = "Mechanism of bacterial predation via ixotrophy",

abstract = "Ixotrophy is a contact-dependent predatory strategy of filamentous bacteria in aquatic environments for which the molecular mechanism remains unknown. We show that predator-prey contact can be established by gliding motility or extracellular assemblages we call {"}grappling hooks.{"} Cryo-electron microscopy identified the grappling hooks as heptamers of a type IX secretion system substrate. After close predator-prey contact is established, cryo-electron tomography and functional assays showed that puncturing by a type VI secretion system mediated killing. Single-cell analyses with stable isotope-labeled prey revealed that prey components are taken up by the attacker. Depending on nutrient availability, insertion sequence elements toggle the activity of ixotrophy. A marine metagenomic time series shows coupled dynamics of ixotrophic bacteria and prey. We found that the mechanism of ixotrophy involves multiple cellular machineries, is conserved, and may shape microbial populations in the environment.",

keywords = "Bacterial Adhesion, Bacteroidetes/physiology, Cryoelectron Microscopy, Single-Cell Analysis, Type VI Secretion Systems/metabolism, Vibrio/physiology, Flagella/ultrastructure",

author = "Yun-Wei Lien and Davide Amendola and Lee, {Kang Soo} and Nina Bartlau and Jingwei Xu and Go Furusawa and Polz, {Martin F} and Roman Stocker and Weiss, {Gregor L} and Martin Pilhofer",

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doi = "10.1126/science.adp0614",

language = "English",

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AU - Lien, Yun-Wei

AU - Amendola, Davide

AU - Lee, Kang Soo

AU - Bartlau, Nina

AU - Xu, Jingwei

AU - Furusawa, Go

AU - Polz, Martin F

AU - Stocker, Roman

AU - Weiss, Gregor L

AU - Pilhofer, Martin

PY - 2024/10/18

Y1 - 2024/10/18

N2 - Ixotrophy is a contact-dependent predatory strategy of filamentous bacteria in aquatic environments for which the molecular mechanism remains unknown. We show that predator-prey contact can be established by gliding motility or extracellular assemblages we call "grappling hooks." Cryo-electron microscopy identified the grappling hooks as heptamers of a type IX secretion system substrate. After close predator-prey contact is established, cryo-electron tomography and functional assays showed that puncturing by a type VI secretion system mediated killing. Single-cell analyses with stable isotope-labeled prey revealed that prey components are taken up by the attacker. Depending on nutrient availability, insertion sequence elements toggle the activity of ixotrophy. A marine metagenomic time series shows coupled dynamics of ixotrophic bacteria and prey. We found that the mechanism of ixotrophy involves multiple cellular machineries, is conserved, and may shape microbial populations in the environment.

AB - Ixotrophy is a contact-dependent predatory strategy of filamentous bacteria in aquatic environments for which the molecular mechanism remains unknown. We show that predator-prey contact can be established by gliding motility or extracellular assemblages we call "grappling hooks." Cryo-electron microscopy identified the grappling hooks as heptamers of a type IX secretion system substrate. After close predator-prey contact is established, cryo-electron tomography and functional assays showed that puncturing by a type VI secretion system mediated killing. Single-cell analyses with stable isotope-labeled prey revealed that prey components are taken up by the attacker. Depending on nutrient availability, insertion sequence elements toggle the activity of ixotrophy. A marine metagenomic time series shows coupled dynamics of ixotrophic bacteria and prey. We found that the mechanism of ixotrophy involves multiple cellular machineries, is conserved, and may shape microbial populations in the environment.

KW - Bacterial Adhesion

KW - Bacteroidetes/physiology

KW - Cryoelectron Microscopy

KW - Single-Cell Analysis

KW - Type VI Secretion Systems/metabolism

KW - Vibrio/physiology

KW - Flagella/ultrastructure

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U2 - 10.1126/science.adp0614

DO - 10.1126/science.adp0614

M3 - Article

C2 - 39418385

SN - 0036-8075

VL - 386

JO - Science

JF - Science

IS - 6719

M1 - eadp0614

ER -

Mechanism of bacterial predation via ixotrophy

Abstract

Austrian Fields of Science 2012

Keywords

UN SDGs

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