Flowering Poration—A Synergistic Multi-Mode Antibacterial Mechanism by a Bacteriocin Fold

Katharine Hammond; Helen Lewis; Samantha Halliwell; Florie Desriac; Brunello Nardone; Jascindra Ravi; Bart W. Hoogenboom; Mathew Upton; Jeremy Derrick; Maxim G. Ryadnov

Flowering Poration—A Synergistic Multi-Mode Antibacterial Mechanism by a Bacteriocin Fold

Katharine Hammond, Helen Lewis, Samantha Halliwell, Florie Desriac, Brunello Nardone, Jascindra Ravi, Bart W. Hoogenboom, Mathew Upton, Jeremy Derrick, Maxim G. Ryadnov

Division of Evolution, Infection and Genomics

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

Abstract

Bacteriocins are a distinct family of antimicrobial proteins postulated to porate bacterial membranes. However, direct experimental evidence of pore formation by these proteins is lacking. Here we report a multi-mode poration mechanism induced by four-helix bacteriocins, epidermicin NI01 and aureocin A53. Using a combination of crystallography, spectroscopy, bioassays, and nanoscale imaging, we established that individual two-helix segments of epidermicin retain antibacterial activity but each of these segments adopts a particular poration mode. In the intact protein these segments act synergistically to balance out antibacterial and hemolytic activities. The study sets a precedent of multi-mode membrane disruption advancing the current understanding of structure-activity relationships in pore-forming proteins.

Original language	English
Article number	101423
Pages (from-to)	1-11
Number of pages	11
Journal	iScience
Volume	23
Issue number	8
Early online date	29 Jul 2020
Publication status	Published - 21 Aug 2020

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https://doi.org/10.1016/j.isci.2020.101423

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title = "Flowering Poration—A Synergistic Multi-Mode Antibacterial Mechanism by a Bacteriocin Fold",

abstract = "Bacteriocins are a distinct family of antimicrobial proteins postulated to porate bacterial membranes. However, direct experimental evidence of pore formation by these proteins is lacking. Here we report a multi-mode poration mechanism induced by four-helix bacteriocins, epidermicin NI01 and aureocin A53. Using a combination of crystallography, spectroscopy, bioassays, and nanoscale imaging, we established that individual two-helix segments of epidermicin retain antibacterial activity but each of these segments adopts a particular poration mode. In the intact protein these segments act synergistically to balance out antibacterial and hemolytic activities. The study sets a precedent of multi-mode membrane disruption advancing the current understanding of structure-activity relationships in pore-forming proteins.",

author = "Katharine Hammond and Helen Lewis and Samantha Halliwell and Florie Desriac and Brunello Nardone and Jascindra Ravi and Hoogenboom, {Bart W.} and Mathew Upton and Jeremy Derrick and Ryadnov, {Maxim G.}",

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AU - Hammond, Katharine

AU - Lewis, Helen

AU - Halliwell, Samantha

AU - Desriac, Florie

AU - Nardone, Brunello

AU - Ravi, Jascindra

AU - Hoogenboom, Bart W.

AU - Upton, Mathew

AU - Derrick, Jeremy

AU - Ryadnov, Maxim G.

PY - 2020/8/21

Y1 - 2020/8/21

N2 - Bacteriocins are a distinct family of antimicrobial proteins postulated to porate bacterial membranes. However, direct experimental evidence of pore formation by these proteins is lacking. Here we report a multi-mode poration mechanism induced by four-helix bacteriocins, epidermicin NI01 and aureocin A53. Using a combination of crystallography, spectroscopy, bioassays, and nanoscale imaging, we established that individual two-helix segments of epidermicin retain antibacterial activity but each of these segments adopts a particular poration mode. In the intact protein these segments act synergistically to balance out antibacterial and hemolytic activities. The study sets a precedent of multi-mode membrane disruption advancing the current understanding of structure-activity relationships in pore-forming proteins.

AB - Bacteriocins are a distinct family of antimicrobial proteins postulated to porate bacterial membranes. However, direct experimental evidence of pore formation by these proteins is lacking. Here we report a multi-mode poration mechanism induced by four-helix bacteriocins, epidermicin NI01 and aureocin A53. Using a combination of crystallography, spectroscopy, bioassays, and nanoscale imaging, we established that individual two-helix segments of epidermicin retain antibacterial activity but each of these segments adopts a particular poration mode. In the intact protein these segments act synergistically to balance out antibacterial and hemolytic activities. The study sets a precedent of multi-mode membrane disruption advancing the current understanding of structure-activity relationships in pore-forming proteins.

M3 - Article

SN - 2589-0042

VL - 23

SP - 1

EP - 11

JO - iScience

JF - iScience

IS - 8

M1 - 101423

ER -

Flowering Poration—A Synergistic Multi-Mode Antibacterial Mechanism by a Bacteriocin Fold

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