TY - JOUR
T1 - The protein coat in membrane fusion
T2 - Lessons from fission
AU - Kozlov, Michael M.
AU - Chernomordik, Leonid V.
PY - 2002/1/1
Y1 - 2002/1/1
N2 - Multiple cell biological processes involve two opposite rearrangements of membrane configuration, referred to as fusion and fission. While membrane intermediates in protein-mediated fusion have been studied in some detail, the global force which drives sequential stages of the fusion reaction from early local intermediates to an expanding fusion pore remains unknown. Fusion proceeds via stages, which are analogous but in the opposite direction to that of membrane budding-off and fission driven by protein coats. On the basis of this analogy, we propose that an interconnected coat formed by membrane-bound activated fusion proteins surrounding the membrane contact zone generates the driving force for fusion. This fusion protein coat has a strongly curved intrinsic shape opposite to that of the protein coat driving fission. To relieve internal stresses, the fusion protein coat spontaneously bends out of the initial shape of the membrane surface. This bending produces elastic stresses in the underlying lipid bilayer and drives its fusion with the apposing membrane. The hypothesis that 'bystander' proteins (i.e. fusion proteins outside the contact zone) generate the driving force for fusion offers a new interpretation for a number of known features of the fusion reaction mediated by the prototype fusion protein, influenza hemagglutinin, and might bring new insights into mechanisms of other fusion reactions.
AB - Multiple cell biological processes involve two opposite rearrangements of membrane configuration, referred to as fusion and fission. While membrane intermediates in protein-mediated fusion have been studied in some detail, the global force which drives sequential stages of the fusion reaction from early local intermediates to an expanding fusion pore remains unknown. Fusion proceeds via stages, which are analogous but in the opposite direction to that of membrane budding-off and fission driven by protein coats. On the basis of this analogy, we propose that an interconnected coat formed by membrane-bound activated fusion proteins surrounding the membrane contact zone generates the driving force for fusion. This fusion protein coat has a strongly curved intrinsic shape opposite to that of the protein coat driving fission. To relieve internal stresses, the fusion protein coat spontaneously bends out of the initial shape of the membrane surface. This bending produces elastic stresses in the underlying lipid bilayer and drives its fusion with the apposing membrane. The hypothesis that 'bystander' proteins (i.e. fusion proteins outside the contact zone) generate the driving force for fusion offers a new interpretation for a number of known features of the fusion reaction mediated by the prototype fusion protein, influenza hemagglutinin, and might bring new insights into mechanisms of other fusion reactions.
KW - Hemagglutinin
KW - Membrane curvature
KW - Membrane fission
KW - Membrane fusion
KW - Protein coat
UR - http://www.scopus.com/inward/record.url?scp=0036215247&partnerID=8YFLogxK
U2 - 10.1034/j.1600-0854.2002.030403.x
DO - 10.1034/j.1600-0854.2002.030403.x
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AN - SCOPUS:0036215247
SN - 1398-9219
VL - 3
SP - 256
EP - 267
JO - Traffic
JF - Traffic
IS - 4
ER -