Regulation of exocytosis by direct Gbg blockade of fusion
Vanderbilt University, Nashville TN
Investigators
Linked publications & trials
Abstract
Summary Inhibition of secretion by Gi/o-coupled GPCRs is an important control mechanism used by many hormones and neuromodulators. It is well documented that activation of Gi/o-coupled GPCRs in secretory cells releases Gï¢ï§ subunits that inhibit Ca2+ entry through voltage-dependent Ca2+ channels (VDCCs), leading to reduced hormone release. However, a direct interaction between Gï¢ï§ and soluble N-ethylmaleimide-sensitive factor attachment protein receptor (SNARE) proteins also inhibits transmitter hormone release in many systems. This mechanism is not only more acute and direct in controlling evoked release but also has the ability to modify spontaneous release. However, the mechanistic details of this SNARE-mediated modulation remain understudied, with many open questions. For example, which GPCRs work through this mechanism? We have also found that Gï¢ï§ inhibition of Ca2+ entry synergizes with Gï¢ï§ inhibition of SNARE-mediated exocytosis. We will address the mechanism of this synergism as well as itâs implications in physiology. Adding another layer of complexity is the diversity of Gï¢ and Gï§ isoforms and the control of specificity of Gï¢ï§s. Using proteomic assays, we have found that specific Gï¢ï§ subunits (i.e. Gï¢1ï§2) bind to SNARE even without GPCR agonists whereas adding agonists enhances Gï¢1ï§2 binding but also brings new Gï¢ï§s (e.g. Gï¢2ï§3) to SNAREs. These data suggest that unique Gï¢ï§ subunits can differentially act on SNARE to achieve different degrees of modulation via GPCRs or even without GPCR activation. Therefore, we propose that SNARE-mediated Gï¢ï§ modulation of hormone release exerts its functional diversity by different combination of Gï¢ï§ subunits and different degree of SNARE binding. This leads us to focus on three specific aims that test (1) which GPCRs work through modulation of Ca2+ entry and which work through binding SNARE (2) what is the mechanism of synergism between the two Gï¢ï§-mediated mechanisms and (3) what is the role of particular Gï¢ and ï§ subunits in GPCR regulation of hormone release. Given the huge diversity of GPCRs in CNS, given Gï¢ï§âs close ties to modulation of exocytosis, and given their relevance to many hormonal and neurological disorders, this project will illuminate a more versatile modulation of secretion by different Gï¢ï§s, bridge the knowledge gap between tonic and phasic modulation of release via GPCRs in secretion, and unravel molecular mechanisms underpinning various hormonal and neurological disorders.
View original record on NIH RePORTER →