Gabre

Predicted to enable GABA-gated chloride ion channel activity and transmitter-gated monoatomic ion channel activity involved in regulation of postsynaptic membrane potential. Predicted to contribute to GABA-A receptor activity; benzodiazepine receptor activity; and chloride channel activity. Predicted to be involved in several processes, including GABAergic synaptic transmission; chloride transmembrane transport; and inhibitory synapse assembly. Predicted to act upstream of or within chloride transport. Predicted to be located in plasma membrane. Predicted to be part of GABA-A receptor complex. Predicted to be active in GABA-ergic synapse; dendrite membrane; and postsynaptic membrane. Is expressed in several structures, including brain; heart; limb; skeleton; and urinary system. Orthologous to human GABRE (gamma-aminobutyric acid type A receptor subunit epsilon). [provided by Alliance of Genome Resources, Jul 2025]

A protein domain is a distinct structural or functional region within a protein that can evolve, function, and exist independently of the rest of the protein chain. These domains in mouse Gabre often fold into stable, three-dimensional structures and are associated with specific biological functions, such as binding to DNA, other proteins, or small molecules.

Biological processes and signaling networks where the Gabre gene in mouse plays a role, providing insight into its function and relevance in health or disease.

The most significant associations for this gene, including commonly observed domains, pathway involvement, and functional highlights based on current data.

Locations within the cell where the protein is known or predicted to be active, providing insight into its function and cellular context.

Describes the biological processes, cellular components, and molecular functions associated with the mouse Gabre gene, providing context for its role in the cell.