Stalk model of membrane fusion: Solution of energy crisis

Yonathan Kozlovsky; Michael M. Kozlov

doi:10.1016/S0006-3495(02)75450-7

Stalk model of membrane fusion: Solution of energy crisis

Yonathan Kozlovsky, Michael M. Kozlov^*

^*Corresponding author for this work

Physiology Pharmacology

Tel Aviv University

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

391 Scopus citations

Abstract

Membrane fusion proceeds via formation of intermediate nonbilayer structures. The stalk model of fusion intermediate is commonly recognized to account for the major phenomenology of the fusion process. However, in its current form, the stalk model poses a challenge. On one hand, it is able to describe qualitatively the modulation of the fusion reaction by the lipid composition of the membranes. On the other, it predicts very large values of the stalk energy, so that the related energy barrier for fusion cannot be overcome by membranes within a biologically reasonable span of time. We suggest a new structure for the fusion stalk, which resolves the energy crisis of the model. Our approach is based on a combined deformation of the stalk membrane including bending of the membrane surface and tilt of the hydrocarbon chains of lipid molecules. We demonstrate that the energy of the fusion stalk is a few times smaller than those predicted previously and the stalks are feasible in real systems. We account quantitatively for the experimental results on dependence of the fusion reaction on the lipid composition of different membrane monolayers. We analyze the dependence of the stalk energy on the distance between the fusing membranes and provide the experimentally testable predictions for the structural features of the stalk intermediates.

Original language	English
Pages (from-to)	882-895
Number of pages	14
Journal	Biophysical Journal
Volume	82
Issue number	2
DOIs	https://doi.org/10.1016/S0006-3495(02)75450-7
State	Published - 2002

Funding

Funders	Funder number
Israel Academy of Sciences and Humanities
Israel Science Foundation

UN SDGs

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

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10.1016/S0006-3495(02)75450-7

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title = "Stalk model of membrane fusion: Solution of energy crisis",

abstract = "Membrane fusion proceeds via formation of intermediate nonbilayer structures. The stalk model of fusion intermediate is commonly recognized to account for the major phenomenology of the fusion process. However, in its current form, the stalk model poses a challenge. On one hand, it is able to describe qualitatively the modulation of the fusion reaction by the lipid composition of the membranes. On the other, it predicts very large values of the stalk energy, so that the related energy barrier for fusion cannot be overcome by membranes within a biologically reasonable span of time. We suggest a new structure for the fusion stalk, which resolves the energy crisis of the model. Our approach is based on a combined deformation of the stalk membrane including bending of the membrane surface and tilt of the hydrocarbon chains of lipid molecules. We demonstrate that the energy of the fusion stalk is a few times smaller than those predicted previously and the stalks are feasible in real systems. We account quantitatively for the experimental results on dependence of the fusion reaction on the lipid composition of different membrane monolayers. We analyze the dependence of the stalk energy on the distance between the fusing membranes and provide the experimentally testable predictions for the structural features of the stalk intermediates.",

author = "Yonathan Kozlovsky and Kozlov, {Michael M.}",

note = "Funding Information: To conclude, the present work resolves the energy crisis of the stalk model of membrane fusion. We suggest a specific structure of the stalk intermediate where the major roles are played by deformations of tilt and splay of the hydrocarbon chains. We demonstrate that the stalk intermediates have energies much smaller than those predicted previously and can be formed in real systems due to thermal fluctuations of the membranes. The obtained dependence of the stalk energy on the lipid compositions of the membrane monolayers agrees with the existing experimental data. We predict that the stalk energy, practically, does not depend on the intramembrane distance, provided that the stalk base is sufficiently free to expand in the lateral direction. We are grateful to Leonid Chernomordik for stimulating discussions, critical reading of the manuscript, and constructive suggestions. We thank David Andelman, Samuel Safran, and Michael Schick for helpful discussions. M. K. is grateful to the Israel Science Foundation funded by the Israel Academy of Science and Humanities and the Human Frontier Science Program Organization for the financial support. Appendix A ",

year = "2002",

doi = "10.1016/S0006-3495(02)75450-7",

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T1 - Stalk model of membrane fusion

T2 - Solution of energy crisis

AU - Kozlovsky, Yonathan

AU - Kozlov, Michael M.

N1 - Funding Information: To conclude, the present work resolves the energy crisis of the stalk model of membrane fusion. We suggest a specific structure of the stalk intermediate where the major roles are played by deformations of tilt and splay of the hydrocarbon chains. We demonstrate that the stalk intermediates have energies much smaller than those predicted previously and can be formed in real systems due to thermal fluctuations of the membranes. The obtained dependence of the stalk energy on the lipid compositions of the membrane monolayers agrees with the existing experimental data. We predict that the stalk energy, practically, does not depend on the intramembrane distance, provided that the stalk base is sufficiently free to expand in the lateral direction. We are grateful to Leonid Chernomordik for stimulating discussions, critical reading of the manuscript, and constructive suggestions. We thank David Andelman, Samuel Safran, and Michael Schick for helpful discussions. M. K. is grateful to the Israel Science Foundation funded by the Israel Academy of Science and Humanities and the Human Frontier Science Program Organization for the financial support. Appendix A

PY - 2002

Y1 - 2002

N2 - Membrane fusion proceeds via formation of intermediate nonbilayer structures. The stalk model of fusion intermediate is commonly recognized to account for the major phenomenology of the fusion process. However, in its current form, the stalk model poses a challenge. On one hand, it is able to describe qualitatively the modulation of the fusion reaction by the lipid composition of the membranes. On the other, it predicts very large values of the stalk energy, so that the related energy barrier for fusion cannot be overcome by membranes within a biologically reasonable span of time. We suggest a new structure for the fusion stalk, which resolves the energy crisis of the model. Our approach is based on a combined deformation of the stalk membrane including bending of the membrane surface and tilt of the hydrocarbon chains of lipid molecules. We demonstrate that the energy of the fusion stalk is a few times smaller than those predicted previously and the stalks are feasible in real systems. We account quantitatively for the experimental results on dependence of the fusion reaction on the lipid composition of different membrane monolayers. We analyze the dependence of the stalk energy on the distance between the fusing membranes and provide the experimentally testable predictions for the structural features of the stalk intermediates.

AB - Membrane fusion proceeds via formation of intermediate nonbilayer structures. The stalk model of fusion intermediate is commonly recognized to account for the major phenomenology of the fusion process. However, in its current form, the stalk model poses a challenge. On one hand, it is able to describe qualitatively the modulation of the fusion reaction by the lipid composition of the membranes. On the other, it predicts very large values of the stalk energy, so that the related energy barrier for fusion cannot be overcome by membranes within a biologically reasonable span of time. We suggest a new structure for the fusion stalk, which resolves the energy crisis of the model. Our approach is based on a combined deformation of the stalk membrane including bending of the membrane surface and tilt of the hydrocarbon chains of lipid molecules. We demonstrate that the energy of the fusion stalk is a few times smaller than those predicted previously and the stalks are feasible in real systems. We account quantitatively for the experimental results on dependence of the fusion reaction on the lipid composition of different membrane monolayers. We analyze the dependence of the stalk energy on the distance between the fusing membranes and provide the experimentally testable predictions for the structural features of the stalk intermediates.

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JO - Biophysical Journal

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Stalk model of membrane fusion: Solution of energy crisis

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