Single methyl groups can act as toggle switches to specify transmembrane protein-protein interactions

Li He; Helena Steinocher; Ashish Shelar; Emily B. Cohen; Erin N. Heim; Birthe Brandt Kragelund; Gevorg Grigoryan; Daniel DiMaio

doi:10.7554/eLife.27701

Single methyl groups can act as toggle switches to specify transmembrane protein-protein interactions

Li He, Helena Steinocher, Ashish Shelar, Emily B. Cohen, Erin N. Heim, Birthe Brandt Kragelund, Gevorg Grigoryan, Daniel DiMaio^*

^*Corresponding author for this work

Biomolecular Sciences

8 Citations (Scopus)

49 Downloads (Pure)

Abstract

Transmembrane domains (TMDs) engage in protein-protein interactions that regulate many cellular processes, but the rules governing the specificity of these interactions are poorly understood. To discover these principles, we analyzed 26-residue model transmembrane proteins consisting exclusively of leucine and isoleucine (called LIL traptamers) that specifically activate the erythropoietin receptor (EPOR) in mouse cells to confer growth factor independence. We discovered that the placement of a single side chain methyl group at specific positions in a traptamer determined whether it associated productively with the TMD of the human EPOR, the mouse EPOR, or both receptors. Association of the traptamers with the EPOR induced EPOR oligomerization in an orientation that stimulated receptor activity. These results highlight the high intrinsic specificity of TMD interactions, demonstrate that a single methyl group can dictate specificity, and define the minimal chemical difference that can modulate the specificity of TMD interactions and the activity of transmembrane proteins.

Original language	English
Article number	e27701
Journal	eLife
Volume	6
Number of pages	28
ISSN	2050-084X
DOIs	https://doi.org/10.7554/eLife.27701
Publication status	Published - 4 Sept 2017

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He_2017_Single_methylFinal published version, 1.26 MBLicence: CC BY

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title = "Single methyl groups can act as toggle switches to specify transmembrane protein-protein interactions",

abstract = "Transmembrane domains (TMDs) engage in protein-protein interactions that regulate many cellular processes, but the rules governing the specificity of these interactions are poorly understood. To discover these principles, we analyzed 26-residue model transmembrane proteins consisting exclusively of leucine and isoleucine (called LIL traptamers) that specifically activate the erythropoietin receptor (EPOR) in mouse cells to confer growth factor independence. We discovered that the placement of a single side chain methyl group at specific positions in a traptamer determined whether it associated productively with the TMD of the human EPOR, the mouse EPOR, or both receptors. Association of the traptamers with the EPOR induced EPOR oligomerization in an orientation that stimulated receptor activity. These results highlight the high intrinsic specificity of TMD interactions, demonstrate that a single methyl group can dictate specificity, and define the minimal chemical difference that can modulate the specificity of TMD interactions and the activity of transmembrane proteins.",

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T1 - Single methyl groups can act as toggle switches to specify transmembrane protein-protein interactions

AU - He, Li

AU - Steinocher, Helena

AU - Shelar, Ashish

AU - Cohen, Emily B.

AU - Heim, Erin N.

AU - Kragelund, Birthe Brandt

AU - Grigoryan, Gevorg

AU - DiMaio, Daniel

PY - 2017/9/4

Y1 - 2017/9/4

N2 - Transmembrane domains (TMDs) engage in protein-protein interactions that regulate many cellular processes, but the rules governing the specificity of these interactions are poorly understood. To discover these principles, we analyzed 26-residue model transmembrane proteins consisting exclusively of leucine and isoleucine (called LIL traptamers) that specifically activate the erythropoietin receptor (EPOR) in mouse cells to confer growth factor independence. We discovered that the placement of a single side chain methyl group at specific positions in a traptamer determined whether it associated productively with the TMD of the human EPOR, the mouse EPOR, or both receptors. Association of the traptamers with the EPOR induced EPOR oligomerization in an orientation that stimulated receptor activity. These results highlight the high intrinsic specificity of TMD interactions, demonstrate that a single methyl group can dictate specificity, and define the minimal chemical difference that can modulate the specificity of TMD interactions and the activity of transmembrane proteins.

AB - Transmembrane domains (TMDs) engage in protein-protein interactions that regulate many cellular processes, but the rules governing the specificity of these interactions are poorly understood. To discover these principles, we analyzed 26-residue model transmembrane proteins consisting exclusively of leucine and isoleucine (called LIL traptamers) that specifically activate the erythropoietin receptor (EPOR) in mouse cells to confer growth factor independence. We discovered that the placement of a single side chain methyl group at specific positions in a traptamer determined whether it associated productively with the TMD of the human EPOR, the mouse EPOR, or both receptors. Association of the traptamers with the EPOR induced EPOR oligomerization in an orientation that stimulated receptor activity. These results highlight the high intrinsic specificity of TMD interactions, demonstrate that a single methyl group can dictate specificity, and define the minimal chemical difference that can modulate the specificity of TMD interactions and the activity of transmembrane proteins.

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JO - eLife

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Single methyl groups can act as toggle switches to specify transmembrane protein-protein interactions

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