Coupling Protonation States of Acid-Sensing Ion Channels to Dynamics and Function

Miaro, Megan

17 August 2022

Acid-sensing ion channels (ASICs) are trimeric, sodium-selective proton-gated ion channels. Having ligands as small as protons presents a challenge when studying the structure-function relationships of pH-dependent gating. Knowing where protons must bind to evoke a pH-dependent conformational change related to gating would provide one with insights into the molecular mechanisms underlying pH-dependent function in ASICs. We use molecular dynamics (MD) simulations that allow us to model explicit protons and directly examine the effects of changing protonation states on ASIC1 dynamics. We first combine the use of unbiased MD simulations with pKₐ prediction on the three functional states of cASIC1 to identify the effects of protonation state changes on interactions between ionizable residues in the acidic pocket (ACP), a region rich in acidic residues in the protein that plays a role in pH-sensing. We interpret the importance of E98, a buried residue in the ACP with a highly shifted pKₐ value, as well as the positively charged R191, also in the ACP, which has a flexible side chain and can interact with multiple negatively charged side chains, and the role of these residues in the pH-dependent collapse of the ACP. Additionally, we identify a hydrogen-bond network in the palm domain that consists of the Q277 side chain that interacts with the E80 side chain and L414 backbone carbonyl. This network contributes to a stable desensitized state and is stabilized by an E80-/E412H/E417H protonation configuration. Next, targeted MD was combined with pKₐ prediction to simulate the full transition pathways and to link protonation states with the molecular mechanisms involved in conformational changes. Our results suggest four residues, E98, E314, H328, and E374, that may be important in pH-sensing and gating, and that require further functional investigation in the context of activation and desensitization. This research exemplifies how MD is a useful tool in studying how protonation directly affects the structural dynamics of a protein and how it can complement existing functional studies and be used to suggest future experimental investigations.

Acid-sensing ion channels

UNDERSTANDING THE PATHOPHYSIOLOGY OF MIGRAINE: ACTIVATION AND SENSITIZATION OF DURAL AFFERENTS

Yan, Jin

January 2011

Migraine is one of the most common neurological disorders. The pathological conditions that initiate and sensitize afferent pain signaling are poorly understood. The goal of this study is to identify the ion channels and signaling proteins underlying activation and sensitization of meningeal nociceptors.In trigeminal neurons retrogradely labeled from the cranial meninges, approximately 80% responded to a pH 6.0 application with a rapidly activating and desensitizing ASIC-like current. Pharmacological experiments and kinetics analysis demonstrated that dural afferent pH-sensitive currents were mediated via activation of ASIC3. In addition, applications of decreased pH solutions were able to excite these neurons and generate action potentials. In awake animals, application of decreased pH solutions to the dura produced dose-dependent facial and hindpaw allodynia, which was also mediated through activation of ASIC3. Accumulating evidence indicates that meningeal inflammation induced sensitization of dural afferents contributes to migraine headache. We have demonstrated here that in the presence of mast cell mediators, dural afferents showed a decreased pH threshold and increased activity in response to pH stimuli both in vivo and in vitro. These data provide a cellular mechanism by which decreased pH in the meninges directly excites afferent pain-sensing neurons potentially contributing to migraine headache. It also indicates that inflammatory events within the meninges could sensitize afferent pain signaling and result in increased sensitivity of dural afferents.Intracranial Interleukin-6 (IL-6) levels have been shown to be elevated during migraine attacks, suggesting that this cytokine may facilitate pain signaling from the meninges. Here we reported that in awake animals, direct application of IL-6 to the dura produced dose-dependent facial and hindpaw allodynia via activation of the ERK signaling pathway. IL-6 application was also able to increase neuronal excitability in a manner consistent with phosphorylation of Nav1.7. These data provide a cellular mechanism by which IL-6 in the meninges causes sensitization of dural afferents therefore contributing to the pathogenesis of migraine.These findings are discussed in relation to how activation and sensitization of primary afferent neurons might initiate migraine pain signaling and how the research included in this dissertation relates to the development of new therapeutic strategies for migraine.

Interleukin 6

Migraine

Nav1.7

Medical Pharmacology

acid sensing ion channels

dural afferents

Examining the role of ASIC1A in mouse models of addiction and CO2-evoked panic-like behaviors

Kreple, Collin John

01 May 2015

Acid-sensing ion channel 1A (ASIC1A) is abundant in the nucleus accumbens (NAc), a region known for its role in addiction. Because ASIC1A has been previously suggested to promote associative learning, we hypothesized that disrupting ASIC1A in the NAc would reduce drug-associated learning and memory. However, contrary to this hypothesis, we found that disrupting ASIC1A in the NAc increased cocaine-conditioned place preference, suggesting an unexpected role for ASIC1A in addiction-related behavior. Investigating the underlying mechanisms, we identified a novel postsynaptic current during neurotransmission mediated by ASIC1A and ASIC2 and thus well-positioned to regulate synapse structure and function. Consistent with this possibility, disrupting ASIC1A altered dendritic spine density and glutamate receptor function, and increased cocaine-evoked plasticity in AMPA-to-NMDA ratio, all resembling changes previously associated with cocaine-induced behavior. Together, these data suggest ASIC1A inhibits plasticity underlying addiction-related behavior, and raise the possibility of therapies for drug addiction by targeting ASIC-dependent neurotransmission. The amygdala plays critical roles in the learning and expression of fear-related behavior. Previous studies have implicated the amygdala in CO2-evoked fear-like behavior in mice; however, a more recent study demonstrated that humans lacking the amygdala bilaterally experience fear and panic with CO2-inhalation. Because all subjects lacking the amygdala had panic attacks after inhaling CO2 compared to only 25% of controls, this data suggests the amygdala may play an inhibitory role in CO2-evoked panic. To assess the role of the amygdala in CO2-evoked behaviors in mice, we lesioned the amygdala and optogenetically stimulated different amygdalar nuclei. We found that large unilateral and bilateral amygdala lesions caused the emergence of escape-like jumping behavior in mice exposed to CO2 and a relative deficit in CO2-evoked freezing. This jumping behavior depended on the dorsal periaqueductal gray, a brain area previously associated with panic attacks. Additionally, the putative CO2 chemosensor ASIC1A and ASIC2 are not necessary for CO2-evoked jumping, and may even play an inhibitory role in this behavior. Optogenetic manipulation of the amygdala revealed that stimulation of the basolateral amygdala enhanced jumping behavior and inhibited freezing behavior. This may be due to the basolateral amygdala's ability to inhibit the main output center of the amygdala, the central nucleus. Together, these results suggest that different amygdalar nuclei differentially modulate CO2-evoked behavior by regulating the switch between mobile and immobile defense responses. Additionally, they provide additional evidence that amygdalar dysfunction may contribute to panic disorder.

publicabstract

Acid-sensing ion channels

Anxiety disorder

Drug addiction

Learning and memory

Biophysics

The Role of ASIC1a in The Regulation of Synaptic Release Probability

Culver, Soluman B.

23 September 2013

No description available.

Neurosciences

Pathology

Physiology

Ion channels

electrophysiology

acid

acid-sensing ion channels

pathology

ACID-SENSING ION CHANNELS: TARGETS FOR NEUROPEPTIDE MODULATION AND NEURONAL DAMAGE

Frey, Erin N.

23 July 2013

No description available.

Biomedical Research

Neurosciences

acid sensing ion channels

acidosis

ischemia

dynorphin

opioid peptides

RFamides

ASICs