A polyalanine-based peptide cannot form a stable transmembrane α-helix in fully hydrated phospholipid bilayers

R. N.A.H. Lewis; Y. P. Zhang; R. S. Hodges; W. K. Subczynski; A. Kusumi; C. R. Flach; R. Mendelsohn; R. N. McElhaney

doi:10.1021/bi010555m

A polyalanine-based peptide cannot form a stable transmembrane α-helix in fully hydrated phospholipid bilayers

R. N.A.H. Lewis
, Y. P. Zhang
, R. S. Hodges
, W. K. Subczynski
, A. Kusumi
, C. R. Flach
, R. Mendelsohn
, R. N. McElhaney

Rutgers Newark, Chemistry

Rutgers, The State University

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

33 Scopus citations

Abstract

The conformation and amide proton exchangeability of the peptide acetyl-K₂-A₂₄-K₂-amide (A₂₄) and its interaction with phosphatidylcholine bilayers were examined by a variety of physical techniques. When dissolved in or cast from methanol as a dried film, A₂₄ is predominantly α-helical. In aqueous media, however, A₂₄ exists primarily as a mixture of helical (though not necessarily α-helical) and random coiled structures, both of which allow rapid H - D exchange of all amide protons. When incorporated into phospholipids in the absence of water, A₂₄ also exists primarily as a transmembrane α-helix. However, upon hydration of that system, rapid exchange of all amide protons also occurs along with a marked change in the amide I absorption band of the peptide. Also, when dispersed with phosphatidylcholine in aqueous media, the conformation and thermal stability of A₂₄ are not significantly altered by the presence of the phospholipid or by its gel/liquid-crystalline phase transition. Differential scanning calorimetric and electron spin resonance spectroscopic studies indicate that A₂₄ has relatively minor effects on the thermodynamic properties of the lipid hydrocarbon chain-melting phase transition, that it does not abolish the lipid pretransition, and that its presence has no significant effect on the orientational order or rates of motion of the phospholipid hydrocarbon chains. We therefore conclude that A₂₄ has sufficient α-helical propensity, but insufficient hydrophobicity, to maintain a stable transmembrane association with phospholipid bilayers in the presence of water. Instead, it exists primarily as a dynamic mixture of helices and other conformers and resides mostly in the aqueous phase where it interacts weakly with the bilayer surface or with the polar/apolar interracial region of phosphatidylcholine bilayers. Thus, polyalanine-based peptides are not good models for the transmembrane α-helical segments of natural membrane proteins.

Original language	American English
Pages (from-to)	12103-12111
Number of pages	9
Journal	Biochemistry
Volume	40
Issue number	40
DOIs	https://doi.org/10.1021/bi010555m
State	Published - Oct 9 2001

ASJC Scopus subject areas

Biochemistry

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10.1021/bi010555m

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@article{c7cdee03b29c475fbc60077aa0c3ba14,

title = "A polyalanine-based peptide cannot form a stable transmembrane α-helix in fully hydrated phospholipid bilayers",

abstract = "The conformation and amide proton exchangeability of the peptide acetyl-K2-A24-K2-amide (A24) and its interaction with phosphatidylcholine bilayers were examined by a variety of physical techniques. When dissolved in or cast from methanol as a dried film, A24 is predominantly α-helical. In aqueous media, however, A24 exists primarily as a mixture of helical (though not necessarily α-helical) and random coiled structures, both of which allow rapid H - D exchange of all amide protons. When incorporated into phospholipids in the absence of water, A24 also exists primarily as a transmembrane α-helix. However, upon hydration of that system, rapid exchange of all amide protons also occurs along with a marked change in the amide I absorption band of the peptide. Also, when dispersed with phosphatidylcholine in aqueous media, the conformation and thermal stability of A24 are not significantly altered by the presence of the phospholipid or by its gel/liquid-crystalline phase transition. Differential scanning calorimetric and electron spin resonance spectroscopic studies indicate that A24 has relatively minor effects on the thermodynamic properties of the lipid hydrocarbon chain-melting phase transition, that it does not abolish the lipid pretransition, and that its presence has no significant effect on the orientational order or rates of motion of the phospholipid hydrocarbon chains. We therefore conclude that A24 has sufficient α-helical propensity, but insufficient hydrophobicity, to maintain a stable transmembrane association with phospholipid bilayers in the presence of water. Instead, it exists primarily as a dynamic mixture of helices and other conformers and resides mostly in the aqueous phase where it interacts weakly with the bilayer surface or with the polar/apolar interracial region of phosphatidylcholine bilayers. Thus, polyalanine-based peptides are not good models for the transmembrane α-helical segments of natural membrane proteins.",

author = "Lewis, \{R. N.A.H.\} and Zhang, \{Y. P.\} and Hodges, \{R. S.\} and Subczynski, \{W. K.\} and A. Kusumi and Flach, \{C. R.\} and R. Mendelsohn and McElhaney, \{R. N.\}",

year = "2001",

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doi = "10.1021/bi010555m",

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T1 - A polyalanine-based peptide cannot form a stable transmembrane α-helix in fully hydrated phospholipid bilayers

AU - Lewis, R. N.A.H.

AU - Zhang, Y. P.

AU - Hodges, R. S.

AU - Subczynski, W. K.

AU - Kusumi, A.

AU - Flach, C. R.

AU - Mendelsohn, R.

AU - McElhaney, R. N.

PY - 2001/10/9

Y1 - 2001/10/9

N2 - The conformation and amide proton exchangeability of the peptide acetyl-K2-A24-K2-amide (A24) and its interaction with phosphatidylcholine bilayers were examined by a variety of physical techniques. When dissolved in or cast from methanol as a dried film, A24 is predominantly α-helical. In aqueous media, however, A24 exists primarily as a mixture of helical (though not necessarily α-helical) and random coiled structures, both of which allow rapid H - D exchange of all amide protons. When incorporated into phospholipids in the absence of water, A24 also exists primarily as a transmembrane α-helix. However, upon hydration of that system, rapid exchange of all amide protons also occurs along with a marked change in the amide I absorption band of the peptide. Also, when dispersed with phosphatidylcholine in aqueous media, the conformation and thermal stability of A24 are not significantly altered by the presence of the phospholipid or by its gel/liquid-crystalline phase transition. Differential scanning calorimetric and electron spin resonance spectroscopic studies indicate that A24 has relatively minor effects on the thermodynamic properties of the lipid hydrocarbon chain-melting phase transition, that it does not abolish the lipid pretransition, and that its presence has no significant effect on the orientational order or rates of motion of the phospholipid hydrocarbon chains. We therefore conclude that A24 has sufficient α-helical propensity, but insufficient hydrophobicity, to maintain a stable transmembrane association with phospholipid bilayers in the presence of water. Instead, it exists primarily as a dynamic mixture of helices and other conformers and resides mostly in the aqueous phase where it interacts weakly with the bilayer surface or with the polar/apolar interracial region of phosphatidylcholine bilayers. Thus, polyalanine-based peptides are not good models for the transmembrane α-helical segments of natural membrane proteins.

AB - The conformation and amide proton exchangeability of the peptide acetyl-K2-A24-K2-amide (A24) and its interaction with phosphatidylcholine bilayers were examined by a variety of physical techniques. When dissolved in or cast from methanol as a dried film, A24 is predominantly α-helical. In aqueous media, however, A24 exists primarily as a mixture of helical (though not necessarily α-helical) and random coiled structures, both of which allow rapid H - D exchange of all amide protons. When incorporated into phospholipids in the absence of water, A24 also exists primarily as a transmembrane α-helix. However, upon hydration of that system, rapid exchange of all amide protons also occurs along with a marked change in the amide I absorption band of the peptide. Also, when dispersed with phosphatidylcholine in aqueous media, the conformation and thermal stability of A24 are not significantly altered by the presence of the phospholipid or by its gel/liquid-crystalline phase transition. Differential scanning calorimetric and electron spin resonance spectroscopic studies indicate that A24 has relatively minor effects on the thermodynamic properties of the lipid hydrocarbon chain-melting phase transition, that it does not abolish the lipid pretransition, and that its presence has no significant effect on the orientational order or rates of motion of the phospholipid hydrocarbon chains. We therefore conclude that A24 has sufficient α-helical propensity, but insufficient hydrophobicity, to maintain a stable transmembrane association with phospholipid bilayers in the presence of water. Instead, it exists primarily as a dynamic mixture of helices and other conformers and resides mostly in the aqueous phase where it interacts weakly with the bilayer surface or with the polar/apolar interracial region of phosphatidylcholine bilayers. Thus, polyalanine-based peptides are not good models for the transmembrane α-helical segments of natural membrane proteins.

UR - https://www.scopus.com/pages/publications/0035833986

UR - https://www.scopus.com/pages/publications/0035833986#tab=citedBy

U2 - 10.1021/bi010555m

DO - 10.1021/bi010555m

M3 - Article

C2 - 11580285

SN - 0006-2960

VL - 40

SP - 12103

EP - 12111

JO - Biochemistry

JF - Biochemistry

IS - 40

ER -

A polyalanine-based peptide cannot form a stable transmembrane α-helix in fully hydrated phospholipid bilayers

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