Modulation of defensive reactivity by GLRB allelic variation: converging evidence from an intermediate phenotype approach

Representing a phylogenetically old and very basic mechanism of inhibitory neurotransmission, glycine receptors have been implicated in the modulation of behavioral components underlying defensive responding toward threat. As one of the first findings being confirmed by genome-wide association studi...

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Bibliographic Details
Published in:Translational psychiatry 2017-09, Vol.7 (9), p.e1227-e1227
Main Authors: Lueken, U, Kuhn, M, Yang, Y, Straube, B, Kircher, T, Wittchen, H-U, Pfleiderer, B, Arolt, V, Wittmann, A, Ströhle, A, Weber, H, Reif, A, Domschke, K, Deckert, J, Lonsdorf, T B
Format: Article
Language:English
Subjects:
59/57
631/208/2489
631/378/1595
Adult
Behavioral Sciences
Biological Psychology
Cerebral Cortex - diagnostic imaging
Cerebral Cortex - physiology
Conditioning, Classical - physiology
Connectome - methods
Fear - physiology
Genotype & phenotype
Germany
Humans
Magnetic Resonance Imaging
Medicine
Medicine & Public Health
Neurosciences
Original
original-article
Pharmacotherapy
Phenotype
Psychiatry
Receptors, Glycine - genetics
Reflex, Startle - physiology
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Summary:Representing a phylogenetically old and very basic mechanism of inhibitory neurotransmission, glycine receptors have been implicated in the modulation of behavioral components underlying defensive responding toward threat. As one of the first findings being confirmed by genome-wide association studies for the phenotype of panic disorder and agoraphobia, allelic variation in a gene coding for the glycine receptor beta subunit ( GLRB ) has recently been associated with increased neural fear network activation and enhanced acoustic startle reflexes. On the basis of two independent healthy control samples, we here aimed to further explore the functional significance of the GLRB genotype (rs7688285) by employing an intermediate phenotype approach. We focused on the phenotype of defensive system reactivity across the levels of brain function, structure, and physiology. Converging evidence across both samples was found for increased neurofunctional activation in the (anterior) insular cortex in GLRB risk allele carriers and altered fear conditioning as a function of genotype. The robustness of GLRB effects is demonstrated by consistent findings across different experimental fear conditioning paradigms and recording sites. Altogether, findings provide translational evidence for glycine neurotransmission as a modulator of the brain’s evolutionary old dynamic defensive system and provide further support for a strong, biologically plausible candidate intermediate phenotype of defensive reactivity. As such, glycine-dependent neurotransmission may open up new avenues for mechanistic research on the etiopathogenesis of fear and anxiety disorders.
ISSN:2158-3188
2158-3188
DOI:10.1038/tp.2017.186