What question did this study set out to answer?

Investigate the structural and functional implications of negative allostery in GABAB hetero-tetramers.

March 23, 2026Open Access

Functional and structural basis of a negative allostery within GABAB hetero-tetramers

Key Points

Investigate the structural and functional implications of negative allostery in GABAB hetero-tetramers.
Used cryo-EM to visualize GABAB hetero-tetramer structure in the apo state.
Analyzed the influence of disease-associated mutations on receptor function.
Studied the interactions of GABAB oligomers in neurons.
Confirmed the existence of GABAB oligomers in neurons.
Identified the asymmetrical interaction between heterodimers preventing activation.
Showed that mutations can specifically alter the function of GABAB oligomers.

Abstract

G protein coupled receptors (GPCRs) oligomerization may allow signal integration from different GPCR units. The GABAB receptor, activated by the main inhibitory transmitter, GABA, is an obligatory heterodimer. It is the target of two therapeutic drugs, baclofen and GHB, and can form stable oligomers. The existence, roles, and possible allosteric interaction of GABAB oligomers remain elusive. Here, we show that GABAB oligomers exist in neurons. Their function can be specifically affected by human disease-associated mutations, demonstrating their essential role for normal brain function. The cryo-EM structure of a hetero-tetramer in the apo state reveals the heterodimers interacting in an asymmetrical way to prevent one unit from being activated. This represents a nice example of a negative allosteric interaction between GPCRs related to human diseases.

Functional and structural basis of a negative allostery within GABAB hetero-tetramers

Key Points

Abstract

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