Homotypic interaction and amino acid distribution of unilaterally conserved transmembrane helices

Christian Lothar Ried; Sebastian Kube; Jan Kirrbach; Dieter Langosch

doi:10.1016/j.jmb.2012.04.008

Homotypic interaction and amino acid distribution of unilaterally conserved transmembrane helices

Christian Lothar Ried, Sebastian Kube, Jan Kirrbach, Dieter Langosch

Chair of Biopolymer Chemistry

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

10 Scopus citations

Abstract

Formation of non-covalent functional complexes of integral membrane proteins is frequently supported by sequence-specific interaction of their transmembrane helices. Here, we aligned human single-span membrane proteins with orthologs from other eukaryotes. We find that almost half of the human single-span membrane proteins contain a transmembrane helix that exhibits significant non-random unilateral conservation. Furthermore, unilateral conservation of transmembrane domains (TMDs) correlates well with their ability to self-interact. Glycine, polar non-ionizable, and aromatic amino acids are overrepresented in conserved versus non-conserved helix faces. Hence, our genome-wide analysis indicates that these amino acid types generally support interaction of single-span membrane protein TMDs.

Original language	English
Pages (from-to)	251-257
Number of pages	7
Journal	Journal of Molecular Biology
Volume	420
Issue number	3
DOIs	https://doi.org/10.1016/j.jmb.2012.04.008
State	Published - 13 Jul 2012

Keywords

conservation
evolution
interaction
sidedness
transmembrane helix

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10.1016/j.jmb.2012.04.008

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title = "Homotypic interaction and amino acid distribution of unilaterally conserved transmembrane helices",

abstract = "Formation of non-covalent functional complexes of integral membrane proteins is frequently supported by sequence-specific interaction of their transmembrane helices. Here, we aligned human single-span membrane proteins with orthologs from other eukaryotes. We find that almost half of the human single-span membrane proteins contain a transmembrane helix that exhibits significant non-random unilateral conservation. Furthermore, unilateral conservation of transmembrane domains (TMDs) correlates well with their ability to self-interact. Glycine, polar non-ionizable, and aromatic amino acids are overrepresented in conserved versus non-conserved helix faces. Hence, our genome-wide analysis indicates that these amino acid types generally support interaction of single-span membrane protein TMDs.",

keywords = "conservation, evolution, interaction, sidedness, transmembrane helix",

author = "Ried, {Christian Lothar} and Sebastian Kube and Jan Kirrbach and Dieter Langosch",

note = "Funding Information: The authors would like to thank Drs. Frishman and Scherer for valuable comments on the manuscript and Dr. Arnold for support with SIMAP. This work was supported by a grant from the Deutsche Forschungsgemeinschaft and the Center for Integrative Protein Science Munich . ",

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AU - Ried, Christian Lothar

AU - Kube, Sebastian

AU - Kirrbach, Jan

AU - Langosch, Dieter

N1 - Funding Information: The authors would like to thank Drs. Frishman and Scherer for valuable comments on the manuscript and Dr. Arnold for support with SIMAP. This work was supported by a grant from the Deutsche Forschungsgemeinschaft and the Center for Integrative Protein Science Munich .

PY - 2012/7/13

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N2 - Formation of non-covalent functional complexes of integral membrane proteins is frequently supported by sequence-specific interaction of their transmembrane helices. Here, we aligned human single-span membrane proteins with orthologs from other eukaryotes. We find that almost half of the human single-span membrane proteins contain a transmembrane helix that exhibits significant non-random unilateral conservation. Furthermore, unilateral conservation of transmembrane domains (TMDs) correlates well with their ability to self-interact. Glycine, polar non-ionizable, and aromatic amino acids are overrepresented in conserved versus non-conserved helix faces. Hence, our genome-wide analysis indicates that these amino acid types generally support interaction of single-span membrane protein TMDs.

AB - Formation of non-covalent functional complexes of integral membrane proteins is frequently supported by sequence-specific interaction of their transmembrane helices. Here, we aligned human single-span membrane proteins with orthologs from other eukaryotes. We find that almost half of the human single-span membrane proteins contain a transmembrane helix that exhibits significant non-random unilateral conservation. Furthermore, unilateral conservation of transmembrane domains (TMDs) correlates well with their ability to self-interact. Glycine, polar non-ionizable, and aromatic amino acids are overrepresented in conserved versus non-conserved helix faces. Hence, our genome-wide analysis indicates that these amino acid types generally support interaction of single-span membrane protein TMDs.

KW - conservation

KW - evolution

KW - interaction

KW - sidedness

KW - transmembrane helix

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JF - Journal of Molecular Biology

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ER -

Homotypic interaction and amino acid distribution of unilaterally conserved transmembrane helices

Abstract

Keywords

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