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The Institute of Functional Genomics (IGF) is a multidisciplinary research centre which is developing a project focused on the functional genomics of physiological and pathological cellular communications in the fields of neurobiology, endocrinology, oncology and cardiology.
This project is based on a multi-scale strategy from 'molecule to systems' and combines structural, biochemical, genetic, epigenetic, omics, physiological and behavioural studies. A major effort is paid to the development of single-cell studies through multiple dimensions and multi-omic approaches, that are necessary to address the complexity of life.
The project of IGF is increasingly based on translational research, promoted by the recruitment of teams of clinicians from different fields (neurovascular, diabetology, neuro-oncology and psychiatry). The objective is to identify new mechanisms and concepts in the field of cellular communications, in order to develop new therapeutic strategies and diagnostic tools.
INSIDE-OUT PHARMACOLOGY OF NICOTINIC AND, POSSIBLY, PSYCHIATRIC DRUG
Henry LESTER
California Institute of Technology (CALTECH)
The classical targets for antipsychotic and antidepressant drugs are G protein-coupled receptors and neurotransmitter transporters, respectively. Full therapeutic actions of these drugs require several weeks. We show how therapeutic effects may eventually accrue after existing therapeutic ligands bind to these classical targets, not on the plasma membrane but rather within endoplasmic reticulum (ER) and cis-Golgi. Consequences of such binding may include pharmacological chaperoning: the nascent drug targets are stabilized against degradation and can therefore exit the ER more readily. Another effect may be matchmaking: heterodimers and homodimers of the target form and can more readily exit the ER. Summarizing recent data for nicotinic receptors, we explain how such effects could lead to reduced ER stress and to a decreased unfolded protein response, including changes in gene activation and protein synthesis. In effects not directly related to cellular stress, escorting would allow increased ER exit and trafficking of known associated proteins, as well as other proteins such as growth factors and their receptors, producing both cell-autonomous and non-cell-autonomous effects. Axonal transport of relevant proteins may underlie the several weeks required for full therapy. In contrast, the antidepressant effects of ketamine and other N -methyl-D-aspartate receptor ligands, which occur within <2 hours, could arise from dendritically localized intracellular binding, followed by chaperoning, matchmaking, escorting, and reduced ER stress. Thus, the effects of intracellular binding extend beyond proteostasis of the targets themselves and involve pathways distinct from ion channel and G protein activation. We propose experimental tests and note pathophysiological correlates.
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