FUNCTIONAL INTERPLAY BETWEEN SUBTHRESHOLD ION CHANNELS IN PREAUTONOMIC NEURONS OF THE HYPOTHALAMIC PARAVENTRICULAR NUCLEUS IN HEALTH AND DISEASE CONDITIONS

Sonner, Patrick M.

18 December 2007

No description available.

Biology, Neuroscience

Ion channels

Preautonomic neurons

Hypothalamus

Paraventricular Nucleus

Hypertension

State-Dependent Network Connectivity Determines Gating in a K+ Channel

Bollepalli, M.K., Fowler, P.W., Rapedius, M., Shang, Lijun, Sansom, M.S.P., Tucker, S.J., Baukrowitz, T.

26 June 2014

Yes / X-ray crystallography has provided tremendous insight into the different structural states of membrane proteins and, in particular, of ion channels. However, the molecular forces that determine the thermodynamic stability of a particular state are poorly understood. Here we analyze the different X-ray structures of an inwardly rectifying potassium channel (Kir1.1) in relation to functional data we obtained for over 190 mutants in Kir1.1. This mutagenic perturbation analysis uncovered an extensive, state-dependent network of physically interacting residues that stabilizes the pre-open and open states of the channel, but fragments upon channel closure. We demonstrate that this gating network is an important structural determinant of the thermodynamic stability of these different gating states and determines the impact of individual mutations on channel function. These results have important implications for our understanding of not only K+ channel gating but also the more general nature of conformational transitions that occur in other allosteric proteins. / Wellcome Trust

X-ray crystallography

Ion channels

Gating network

K+ channel

Diverse mechanisms underlying the regulation of ion channels by carbon monoxide

Peers, C., Boyle, J.P., Scragg, J.L., Dallas, M.L., Al-Owais, M.M., Hettiarachichi, N.T., Elies, Jacobo, Johnson, E., Gamper, N., Steele, D.S.

02 July 2014

No / Carbon monoxide (CO) is firmly established as an important, physiological signalling molecule as well as a potent toxin. Through its ability to bind metal-containing proteins, it is known to interfere with a number of intracellular signalling pathways, and such actions can account for its physiological and pathological effects. In particular, CO can modulate the intracellular production of reactive oxygen species, NO and cGMP levels, as well as regulate MAPK signalling. In this review, we consider ion channels as more recently discovered effectors of CO signalling. CO is now known to regulate a growing number of different ion channel types, and detailed studies of the underlying mechanisms of action are revealing unexpected findings. For example, there are clear areas of contention surrounding its ability to increase the activity of high conductance, Ca2+-sensitive K+ channels. More recent studies have revealed the ability of CO to inhibit T-type Ca2+ channels and have unveiled a novel signalling pathway underlying tonic regulation of this channel. It is clear that the investigation of ion channels as effectors of CO signalling is in its infancy, and much more work is required to fully understand both the physiological and the toxic actions of this gas. Only then can its emerging use as a therapeutic tool be fully and safely exploited.

Carbon monoxide

Ion channels

CO signalling

T-type Ca2+ channels

Hydrogen sulfide inhibits Cav3.2 T-type Ca2 channels

Elies, Jacobo, Scragg, J.L., Huang, S., Dallas, M.L., Huang, D., MacDougall, D., Boyle, J.P., Gamper, N., Peers, C.

02 September 2014

No / The importance of H2S as a physiological signaling molecule continues to develop, and ion channels are emerging as a major family of target proteins through which H2S exerts many actions. The purpose of the present study was to investigate its effects on T-type Ca2+ channels. Using patch-clamp electrophysiology, we demonstrate that the H2S donor, NaHS (10 μM−1 mM) selectively inhibits Cav3.2 T-type channels heterologously expressed in HEK293 cells, whereas Cav3.1 and Cav3.3 channels were unaffected. The sensitivity of Cav3.2 channels to H2S required the presence of the redox-sensitive extracellular residue H191, which is also required for tonic binding of Zn2+ to this channel. Chelation of Zn2+ with N,N,N′,N′-tetra-2-picolylethylenediamine prevented channel inhibition by H2S and also reversed H2S inhibition when applied after H2S exposure, suggesting that H2S may act via increasing the affinity of the channel for extracellular Zn2+ binding. Inhibition of native T-type channels in 3 cell lines correlated with expression of Cav3.2 and not Cav3.1 channels. Notably, H2S also inhibited native T-type (primarily Cav3.2) channels in sensory dorsal root ganglion neurons. Our data demonstrate a novel target for H2S regulation, the T-type Ca2+ channel Cav3.2, and suggest that such modulation cannot account for the pronociceptive effects of this gasotransmitter. / This work was supported by the British Heart Foundation, the Medical Research Council, and the Hebei Medical University

Hydrogen sulfide

Ion channels

T-type Ca2 channels

Gasotransmitter

Inhibits

Modulation of L-Type Calcium Channels by Calmodulin and Lrrc10

del Rivero Morfin, Pedro Javier

January 2024

Voltage-gated L-type calcium (Ca²⁺) channels (Ca_v1.2/1.3) are essential to neuronal and cardiac physiology. They convey extracellular Ca²⁺ after membrane depolarization, a crucial event in muscle contraction, cardiac adrenergic response, neurotransmission, memory, and learning. CaV1.2/1.3 are fine-tuned by auxiliary proteins that orchestrate Ca²⁺ influx into cells, and human variants of these proteins can disrupt channel function leading to disease. The present work probes in depth molecular mechanisms of Ca_v1.2/1.3 regulation by small cytosolic proteins calmodulin (CaM) and Leucine-rich repeat containing protein 10 (Lrrc10), as well as their relevance in physiology and pathophysiology. Chapter 1 introduces basic concepts of ion channel function, classification of voltage-gated Ca²⁺ channels, molecular components of Ca_v1.2/1.3 channel complexes, and participation of Ca_v1.2/1.3 in cardiac and neuronal physiology and disease. Chapter 2 dissects the potential contribution of a selectivity-filter gate on both VDI and CDI of Ca_v1.3 through extensive biophysical characterization, revealing asymmetric participation of conformational changes in the domain IV selectivity filter. The uncovered inactivation mechanism may be of relevance for reversing the molecular phenotype observed in Timothy syndrome, an arrhythmogenic disorder that partially stems from reduced Ca_v1.2 inactivation. Chapter 3 considers Lrrc10 as a regulatory subunit of CaV channels, uncovers molecular mechanisms, including binding interfaces that support Ca_v1.2 upregulation, and evaluates the functional consequences of human variants in Lrrc10. As Lrr proteins can interact with a wide range of targets, Chapter 4 probes the promiscuity of Lrrc10 as an ion channel modulator. Using FRET analysis, I find that Lrrc10 can, in fact, associate with various ion channels. Further analysis revealed that Lrrc10 interaction with one of its potential targets, the cardiac NaV1.5 channel, alters channel function. More broadly, these studies establish a framework to systematically screen cross talk between ion channel subunits. Finally, in Chapter 5, I leverage insights obtained from in-depth characterization of Lrrc10 modulation to engineer a genetically encoded actuator that upregulates Ca_v1.2/1.3 currents in distinct physiological settings. Altogether, this work contributes to our molecular understanding of Ca_v1.2/1.3 regulation by small cytosolic proteins, and establishes new strategies to probe and manipulate a Ca²⁺ channel function that may ultimately aid in discovering potential new targets and tools for research and therapeutics.

Physiology

Biophysics

Calcium channels

Calmodulin--Physiological effect

Ion channels

Contribution of K+ Channels to Coronary Dysfunction in Metabolic Syndrome

Watanabe, Reina

24 June 2009

Indiana University-Purdue University Indianapolis (IUPUI) / Coronary microvascular function is markedly impaired by the onset of the metabolic syndrome and may be an important contributor to the increased cardiovascular events associated with this mutlifactorial disorder. Despite increasing appreciation for the role of coronary K+ channels in regulation of coronary microvascular function, the contribution of K+ channels to the deleterious influence of metabolic syndrome has not been determined. Accordingly, the overall goal of this investigation was to delineate the mechanistic contribution of K+ channels to coronary microvascular dysfunction in metabolic syndrome. Experiments were performed on Ossabaw miniature swine fed a normal maintenance diet or an excess calorie atherogenic diet that induces the classical clinical features of metabolic syndrome including obesity, insulin resistance, impaired glucose tolerance, dyslipidemia, hyperleptinemia, and atherosclerosis. Experiments involved in vivo studies of coronary blood flow in open-chest anesthetized swine as well as conscious, chronically instrumented swine and in vitro studies in isolated coronary arteries, arterioles, and vascular smooth muscle cells. We found that coronary microvascular dysfunction in the metabolic syndrome significantly impairs coronary vasodilation in response to metabolic as well as ischemic stimuli. This impairment was directly related to decreased membrane trafficking and functional expression of BKCa channels in vascular smooth muscle cells that was accompanied by augmented L-type Ca2+ channel activity and increased intracellular Ca2+ concentration. In addition, we discovered that impairment of coronary vasodilation in the metabolic syndrome is mediated by reductions in the functional contribution of voltage-dependent K+ channels to the dilator response. Taken together, findings from this investigation demonstrate that the metabolic syndrome markedly attenuates coronary microvascular function via the diminished contribution of K+ channels to the overall control of coronary blood flow. Our data implicate impaired functional expression of coronary K+ channels as a critical mechanism underlying the increased incidence of cardiac arrhythmias, infarction and sudden cardiac death in obese patients with the metabolic syndrome.

coronary circulation

obesity

ion channels

metabolic syndrome

blood flow

Coronary circulation -- Regulation

Metabolic syndrome

Obesity

Ion channels

Heart -- Diseases

Structural rearrangements of MscS during activation gating

Vásquez, Valeria.

January 2008

Thesis (Ph. D.)--University of Virginia, 2008. / Title from title page. Includes bibliographical references. Also available online through Digital Dissertations.

REGULATION OF HCN CHANNEL FUNCTION BY DIRECT cAMP BINDING AND SINGLET OXYGEN

Idikuda, Vinaykumar

01 January 2018

Hyperpolarization-activated, cyclic-nucleotide gated ion channels (HCN channels) are activated by membrane hyperpolarization and modulated by cyclic nucleotides. HCN channels are important to maintain the resting membrane potential and input resistance in neurons and have important physiological functions in the brain and heart. Four mammalian HCN isoforms, HCN1-4, and the isoform cloned from sea urchin, spHCN, have been extensively studied. Among these, only spHCN channel shows a voltage dependent inactivation. Previous studies have shown that the ligand binding in mHCN2 channel is activity dependent: cAMP binding increases along with channel opening or channels in the open state have higher binding affinity for cAMP. But to date, information pertaining to the ligand binding to an inactivated ion channel or desensitized receptor is lacking. To address this gap, we used fluorescently labelled cAMP analogues in conjunction with patch clamp fluorometry (PCF) to study the ligand binding to the spHCN channel in various conformational states. We show that inactivated spHCN channel shows reduced binding affinity for cAMP, compared to that of the closed or open channel. Parallelly, we noticed significant changes to channel function when a combination of laser and photosensitizer was used to study ligand binding. A reactive oxygen species called singlet oxygen has been confirmed to be the major player in this process. Both photo-dynamically generated and chemically generated singlet oxygen modifies spHCN channel by removing the inactivation. The effect of singlet oxygen on channel can be abolished by the mutation of a key histidine (H462) residue in the ion conducting pore. Taken together, these two projects expanded our understanding about the physicochemical nature of fluorophores from two aspects: (i) the release of photon as a valuable tool to study the conformational dynamics in proteins; (ii) the generation of singlet oxygen as an effective modulator of protein function.

HCN channels

Singlet Oxygen

cAMP

Patch clamp Fluorometry

Ligand binding

Ion Channels

spHCN

Voltage gated Ion channels

Cellular and Molecular Physiology

Neuroscience and Neurobiology

The Role of Ion Channels in Coordinating Neural Circuit Activity in Caenorhabditis elegans: A Dissertation

Pirri, Jennifer K.

28 March 2013

Despite the current understanding that sensorimotor circuits function through the action of transmitters and modulators, we have a limited understanding of how the nervous system directs the flow of information necessary to orchestrate complex behaviors. In this dissertation, I aimed to uncover how the nervous system coordinates these behaviors using the escape response of the soil nematode, Caenorhabditis elegans, as a paradigm. C. elegans exhibits a robust escape behavior in response to touch. The worm typically moves forward in a sinusoidal pattern, which is accompanied by exploratory head movements. During escape, the worm quickly retreats by moving backward from the point of stimulus while suppressing its head movements. It was previously shown that the biogenic amine tyramine played an important role in modulating the suppression of these head movmemetns in response to touch. We identified a novel tyramine-gated chloride channel, LGC-55, whose activation by tyramine coordinates motor programs essential for escape. Furthermore, we found that changing the electrical nature of a synapse within the neural circuit for escape behavior can reverse its behavioral output, indicating that the C. elegans connectome is established independent of the nature of synaptic activity or behavioral output. Finally, we characterized a unique mutant, zf35 , which is hyperactive in reversal behavior. This mutant was identified as a gain of function allele of the C. elegans P/Q/N-type voltage-gated calcium channel, UNC-2. Taken together, this work defines tyramine as a genuine neurotransmitter and completes the neural circuit that controls the initial phases of the C. elegans escape response. Additionally, this research further advances the understanding of how the interactions between transmitters and ion channels can precisely regulate neural circuit activity in the execution of a complex behavior.

Caenorhabditis elegans

ion channels

transmitters

escape behavior

Dissertations, UMMS

Ion Channels

Neurotransmitter Agents

Tyramine

Escape Reaction

Behavioral Neurobiology

Molecular and Cellular Neuroscience

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