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Studies of the generation and function of phospholipid asymmetry Eastman, Simon J.
Abstract
It is well established that biological membranes maintain an asymmetric transbilayer distribution of component molecules, including lipids. The mechanisms by which this lipid asymmetry is established and maintained are not well understood. In addition, little is known concerning the biological significance of lipid asymmetry. This thesis employs large unilamellar vesicle (LUV) model membrane systems to examine the ability of transmembrane pH gradients (ΔpH) to generate lipid asymmetry and investigate the consequences of lipid asymmetry in membrane fusion phenomena. The first area of investigation demonstrates that transmembrane pH gradients can influence the inter-vesicular exchange of stearylamine and oleic acid. Vesicles containing stearylamine are shown to aggregate immediately with vesicles containing phosphatidylserine and disaggregation occurs as stearylamine equilibrates between the two vesicle populations. Despite visible flocculation during the aggregation phase, vesicle integrity is maintained. It is also shown that stearylamine is the only lipid to exchange, fusion does not occur and vesicles are able to maintain a pH gradient. When stearylamine is sequestered to the inner monolayer in response to a transmembrane pH gradient (inside acidic) aggregation is not observed and diffusion of stearylamine to acceptor vesicles is greatly reduced. The ability of ΔpH-dependent lipid asymmetry to modulate lipid exchange is also demonstrated for fatty acids. Oleic acid can be induced to transfer from one population of vesicles to another by maintaining a basic interior pH in the acceptor vesicles. It is also shown that the same acceptor vesicles can deplete serum albumin of bound fatty acid. The second area of investigation concerns asymmetric transbilayer distributions of dioleoylphosphatidic acid (DOPA) induced by transmembrane pH gradients. A fluorescent assay is developed employing 2-(p-toluidinyl)naphthalene-6-sulfonic acid (TNS) as a probe of lipid asymmetry. The kinetics of DOPA transport are shown to be consistent with the transport of the uncharged (protonated) form. Transport of the neutral species can be rapid, exhibiting half-times for transbilayer transport of approximately 25 s at 45°C. These studies also indicate that the transport of DOPA is associated with a large activation energy (28 Kcal/mol). The third area builds on the ability to generate LUVs with an asymmetric distribution of DOPA and concerns studies on the ability of lipid asymmetry to regulate Ca2+ stimulated fusion of LUV systems. It is shown that for LUVs composed of DOPC:DOPE:PI:DOPA (25:60:5:10 mol/mol) rapid and essentially complete fusion is observed by fluorescent resonance energy transfer techniques when Ca2+ is added. Alternatively, for LUVs with the same lipid composition but when DOPA has been sequestered to the inner monolayer, due to the presence of a pH gradient (interior basic), little or no fusion is observed upon addition of Ca2+ It is demonstrated that the extent of Ca2+induced fusion correlates with the amount of exterior DOPA. It is also shown that LUVs containing only 2.5 mol% DOPA, but when all the DOPA is in the outer monolayer, can be induced to fuse to the same extent and with the same initial rate as LUVs containing 5 mol% DOPA. These results strongly support a regulatory role for lipid asymmetry in membrane fusion and indicate that the fusogenic tendencies of lipid bilayers are largely determined by the properties of one monolayer.
Item Metadata
Title |
Studies of the generation and function of phospholipid asymmetry
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Creator | |
Publisher |
University of British Columbia
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Date Issued |
1992
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Description |
It is well established that biological membranes maintain an asymmetric
transbilayer distribution of component molecules, including lipids. The mechanisms by
which this lipid asymmetry is established and maintained are not well understood. In
addition, little is known concerning the biological significance of lipid asymmetry. This
thesis employs large unilamellar vesicle (LUV) model membrane systems to examine the
ability of transmembrane pH gradients (ΔpH) to generate lipid asymmetry and investigate
the consequences of lipid asymmetry in membrane fusion phenomena.
The first area of investigation demonstrates that transmembrane pH gradients can
influence the inter-vesicular exchange of stearylamine and oleic acid. Vesicles
containing stearylamine are shown to aggregate immediately with vesicles containing
phosphatidylserine and disaggregation occurs as stearylamine equilibrates between the
two vesicle populations. Despite visible flocculation during the aggregation phase,
vesicle integrity is maintained. It is also shown that stearylamine is the only lipid to
exchange, fusion does not occur and vesicles are able to maintain a pH gradient. When
stearylamine is sequestered to the inner monolayer in response to a transmembrane pH
gradient (inside acidic) aggregation is not observed and diffusion of stearylamine to
acceptor vesicles is greatly reduced. The ability of ΔpH-dependent lipid asymmetry to
modulate lipid exchange is also demonstrated for fatty acids. Oleic acid can be induced
to transfer from one population of vesicles to another by maintaining a basic interior pH
in the acceptor vesicles. It is also shown that the same acceptor vesicles can deplete
serum albumin of bound fatty acid.
The second area of investigation concerns asymmetric transbilayer distributions
of dioleoylphosphatidic acid (DOPA) induced by transmembrane pH gradients. A fluorescent assay is developed employing 2-(p-toluidinyl)naphthalene-6-sulfonic acid
(TNS) as a probe of lipid asymmetry. The kinetics of DOPA transport are shown to be
consistent with the transport of the uncharged (protonated) form. Transport of the neutral
species can be rapid, exhibiting half-times for transbilayer transport of approximately 25
s at 45°C. These studies also indicate that the transport of DOPA is associated with a
large activation energy (28 Kcal/mol).
The third area builds on the ability to generate LUVs with an asymmetric
distribution of DOPA and concerns studies on the ability of lipid asymmetry to regulate
Ca2+ stimulated fusion of LUV systems. It is shown that for LUVs composed of
DOPC:DOPE:PI:DOPA (25:60:5:10 mol/mol) rapid and essentially complete fusion is
observed by fluorescent resonance energy transfer techniques when Ca2+ is added.
Alternatively, for LUVs with the same lipid composition but when DOPA has been
sequestered to the inner monolayer, due to the presence of a pH gradient (interior basic),
little or no fusion is observed upon addition of Ca2+ It is demonstrated that the extent of
Ca2+induced fusion correlates with the amount of exterior DOPA. It is also shown that
LUVs containing only 2.5 mol% DOPA, but when all the DOPA is in the outer
monolayer, can be induced to fuse to the same extent and with the same initial rate as
LUVs containing 5 mol% DOPA. These results strongly support a regulatory role for
lipid asymmetry in membrane fusion and indicate that the fusogenic tendencies of lipid
bilayers are largely determined by the properties of one monolayer.
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Extent |
2078937 bytes
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Genre | |
Type | |
File Format |
application/pdf
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Language |
eng
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Date Available |
2008-12-20
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Provider |
Vancouver : University of British Columbia Library
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Rights |
For non-commercial purposes only, such as research, private study and education. Additional conditions apply, see Terms of Use https://open.library.ubc.ca/terms_of_use.
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DOI |
10.14288/1.0086810
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URI | |
Degree | |
Program | |
Affiliation | |
Degree Grantor |
University of British Columbia
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Graduation Date |
1992-05
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Campus | |
Scholarly Level |
Graduate
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Aggregated Source Repository |
DSpace
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Rights
For non-commercial purposes only, such as research, private study and education. Additional conditions apply, see Terms of Use https://open.library.ubc.ca/terms_of_use.