Desensitization is an important mechanism that curtails the activity of ligand-gated ion-channels (LGICs). Although the structural basis of desensitization is not fully resolved, it is thought to be governed by the physicochemical properties of the bound ligand. Here, we show the importance of an allosteric cation binding pocket in controlling transitions between activated and desensitized states of rat kainate-type (KAR) ionotropic glutamate receptors (iGluRs). Tethering a positive charge to this pocket sustains KAR activation, preventing desensitization, whereas mutations that disrupt cation binding eliminate channel gating. These different outcomes explain the structural distinction between deactivation and desensitization. Deactivation occurs when the ligand unbinds before the cation, whereas desensitization proceeds if a ligand is bound without cation pocket occupancy. This sequence of events is absent from AMPA-type iGluRs, identifying cations as gatekeepers of KAR gating, a role unique among even closely-related LGICs.
Key points• This study identifies the gating structure responsible for controlling ion-channel subconductance behaviour at a major neurotransmitter receptor, namely kainate-type ionotropic glutamate receptor.• Evidence is provided that the activation process may be made up of two clearly distinct conductance phases.• The study speculates that functional diversity amongst ionotropic glutamate receptors emerged during evolution by re-deploying the same structures to carry out different tasks.Abstract Kainate-selective ionotropic glutamate receptors (iGluRs) fulfil key roles in the CNS, making them the subject of detailed structural and functional analyses. Although they are known to gate a channel pore with high and low ion-permeation rates, it is still not clear how switches between these gating modes are achieved at the structural level. Here, we uncover an unexpected role for the ligand-binding domain (LBD) dimer assembly in this process. Covalent crosslinking of the dimer interface keeps kainate receptors out of the main open state but permits access to lower conductance states suggesting that significant rearrangements of the dimer interface are required for the receptor to achieve full activation. These observations differ from NMDA-selective iGluRs where constraining dimer movement reduces open-channel probability. In contrast, our data show that restricting movement of the dimer interface interferes with conformational changes that underlie both activation and desensitization. Working within the limits of a common architectural design, we propose functionally diverse iGluR families were able to emerge during evolution by re-deploying existing gating structures to fulfil different tasks.
Despite an improved understanding of its pathophysiology and a wide range of new treatments, cardiovascular disease (CVD) remains a serious public health issue and the number one cause of mortality in the United States. Conditions that promote chronic systemic inflammation, such as obesity, cancer, and autoimmune and infectious diseases, are now known to play an important role in promoting CVD by inducing the expression of endothelial adhesion molecules and chemokines; these in turn promote leukocyte adherence and infiltration, which initiates and spurs the progression of CVD. In response to this new understanding, researchers are evaluating the potential cardiovascular benefits of new-generation therapies based on endogenous molecules with anti-inflammatory properties. Similarly, targeted approaches that leverage the phenotypic differences between non-inflamed and inflamed endothelia have the potential to selectively deliver therapeutics and decrease the morbidity and mortality of CVD patients. In this review, we discuss the role of inflammation in CVD and explore the therapeutic potential of targeting inflamed vasculature through conventional and biomimetic approaches.
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