Our understanding of the roles played by zinc in the physiological and pathological functioning of the brain is rapidly expanding. The increased availability of genetically modified animal models, selective zinc-sensitive fluorescent probes, and novel chelators is producing a remarkable body of exciting new data that clearly establishes this metal ion as a key modulator of intracellular and intercellular neuronal signaling. In this Mini-Symposium, we will review and discuss the most recent findings that link zinc to synaptic function as well as the injurious effects of zinc dyshomeostasis within the context of neuronal death associated with major human neurological disorders, including stroke, epilepsy, and Alzheimer’s disease.
Summary Zn2+ that is co-released with glutamate from mossy fiber terminals can influence synaptic function. Here, we demonstrate that synaptically released Zn2+ activates a selective post-synaptic Zn2+-sensing receptor (ZnR) in the CA3 region of the hippocampus. ZnR activation induced intracellular release of Ca2+, as well as phosphorylation of extracellular-regulated kinase and Ca2+/calmodulin kinase. ZnR-mediated Ca2+ rises were dramatically attenuated in slices from mice lacking vesicular Zn2+. In addition, knockdown of the expression of the orphan G-protein coupled receptor GPR39 attenuated ZnR activity in a neuronal cell line. Importantly, we observed widespread GPR39 labeling in CA3 neurons, suggesting a role for this receptor in mediating ZnR signaling in the hippocampus. Our results describe a unique role for synaptic Zn2+ acting as the physiological ligand of a metabotropic receptor and provide a novel pathway by which synaptic-Zn2+ can regulate neuronal function.
Changes in extracellular zinc concentration participate in modulating fundamental cellular processes such as proliferation, secretion, and ion transport in a mechanism that is not well understood. Here, we show that a micromolar concentration of extracellular zinc triggers a massive release of calcium from thapsigarginsensitive intracellular pools in the colonocytic cell line HT29. Calcium release was blocked by a phospholipase-C inhibitor, indicating that formation of inositol 1,4,5-triphosphate is required for zinc-dependent calcium release. Zinc influx was not observed, indicating that extracellular zinc triggered the release. The Ca i 2؉ release was zinc specific and could not be triggered by other heavy metals. Furthermore, zinc failed to activate the Ca 2؉ -sensing receptor heterologously expressed in HEK293 cells. The zinc-induced Ca i 2؉ rise stimulated the activity of the Na ؉ ͞H ؉ exchanger in HT29 cells. Our results indicate that a previously uncharacterized extracellular, G protein-coupled, Zn 2؉ -sensing receptor is functional in colonocytes. Because Ca i 2؉ rise is known to regulate key cellular and signal-transduction processes, the zinc-sensing receptor may provide the missing link between extracellular zinc concentration changes and the regulation of cellular processes.Z inc is an essential micronutrient involved in structural and regulatory cellular functions. Zinc interacts with zinc-finger domains and acts as a cofactor of numerous enzymes (1, 2). Zinc ions also specifically bind to many membrane receptors, transporters, and channels, thereby modulating their activity (3). Therefore, it is not surprising that zinc deficiency affects multiple organs, including the digestive (4), immune (5), and neuronal (2) systems. A severe lack of zinc also is linked to the attenuation of growth and sexual development (2). Conversely, an excess of extracellular zinc is considered toxic. Indeed, brain ischemia is accompanied by a massive release of synaptic zinc permeating into neurons, leading to neuronal cell death (6-8). Furthermore, striking changes in plasma-zinc concentration occur during diverse pathophysiological syndromes including myocardial infarction, hepatic renal failure, and neoplastic processes (9). Despite the large fluctuations in extracellular zinc concentrations and their subsequent clinical importance, little is known about cellular signaling mechanisms that sense changes in extracellular-zinc concentration.The calcium-sensing receptor serves as an example for the importance of an ion-sensing mechanism. It is a G proteincoupled receptor that senses changes in extracellular calcium and regulates diverse cellular functions (10, 11). Although the existence of other ion-sensing mechanisms have been suggested (12), none have been characterized fully yet.Gastrointestinal pathology, manifested in severe diarrhea, is an important hallmark of zinc deficiency. Indeed, zinc has a major role in the duration and severity of diarrheal diseases (4). The morbidity and mortality caused by diarrheal diseas...
Vesicular Zn2+ regulates postsynaptic neuronal excitability upon its corelease with glutamate. We previously demonstrated that synaptic Zn2+ acts via a distinct metabotropic zinc-sensing receptor (mZnR) in neurons to trigger Ca2+ responses in the hippocampus. Here, we show that physiological activation of mZnR signaling induces enhanced K+/Cl− cotransporter 2 (KCC2) activity and surface expression. As KCC2 is the major Cl− outward transporter in neurons, Zn2+ also triggers a pronounced hyperpolarizing shift in the GABAA reversal potential. Mossy fiber stimulation-dependent upregulation of KCC2 activity is eliminated in slices from Zn2+ transporter 3-deficient animals, which lack synaptic Zn2+. Importantly, activity-dependent ZnR signaling and subsequent enhancement of KCC2 activity are also absent in slices from mice lacking the G-protein-coupled receptor GPR39, identifying this protein as the functional neuronal mZnR. Our work elucidates a fundamentally important role for synaptically released Zn2+ acting as a neurotransmitter signal via activation of a mZnR to increase Cl− transport, thereby enhancing inhibitory tone in postsynaptic cells.
SUMMARY Mitochondrial Ca2+ overload is a critical, preceding event in neuronal damage encountered during neurodegenerative and ischemic insults. We found that loss of PTEN-induced putative kinase 1 (PINK1) function, implicated in Parkinson disease, inhibits the mitochondrial Na+/Ca2+ exchanger (NCLX), leading to impaired mitochondrial Ca2+ extrusion. NCLX activity was, however, fully rescued by activation of the protein kinase A (PKA) pathway. We further show that PKA rescues NCLX activity by phosphorylating serine 258, a putative regulatory NCLX site. Remarkably, a constitutively active phosphomimetic mutant of NCLX (NCLXS258D) prevents mitochondrial Ca2+ overload and mitochondrial depolarization in PINK1 knockout neurons, thereby enhancing neuronal survival. Our results identify an mitochondrial Ca2+ transport regulatory pathway that protects against mitochondrial Ca2+ overload. Because mitochondrial Ca2+ dyshomeostasis is a prominent feature of multiple disorders, the link between NCLX and PKA may offer a therapeutic target.
Zinc is an essential cofactor for the activity and folding of up to ten percent of mammalian proteins and can modulate the function of many others. Because of the pleiotropic effects of zinc on every aspect of cell physiology, deficits of cellular zinc content, resulting from zinc deficiency or excessive rise in its cellular concentration, can have catastrophic consequences and are linked to major patho-physiologies including diabetes and stroke. Thus, the concentration of cellular zinc requires establishment of discrete, active cellular gradients. The cellular distribution of zinc into organelles is precisely managed to provide the zinc concentration required by each cell compartment. The complexity of zinc homeostasis is reflected by the surprisingly large variety and number of zinc homeostatic proteins found in virtually every cell compartment. Given their ubiquity and importance, it is surprising that many aspects of the function, regulation, and crosstalk by which zinc transporters operate are poorly understood. In this mini-review, we will focus on the mechanisms and players required for generating physiologically appropriate zinc gradients across the plasma membrane and vesicular compartments. We will also highlight some of the unsolved issues regarding their role in cellular zinc homeostasis.
scite is a Brooklyn-based organization that helps researchers better discover and understand research articles through Smart Citations–citations that display the context of the citation and describe whether the article provides supporting or contrasting evidence. scite is used by students and researchers from around the world and is funded in part by the National Science Foundation and the National Institute on Drug Abuse of the National Institutes of Health.
hi@scite.ai
10624 S. Eastern Ave., Ste. A-614
Henderson, NV 89052, USA
Copyright © 2024 scite LLC. All rights reserved.
Made with 💙 for researchers
Part of the Research Solutions Family.