Your search keyword '"voltage-gated ion channels"' showing total 3,534 results

1. Voltage-gated ion channel's gene expression in the myocardium of embryo and adult chickens.

Author

Lebedeva, E.A., Gonotkov, M.A., Furman, A.A., and Velegzhaninov, I.O.

Subjects

*GENE expression, *CARDIAC contraction, *CARDIOVASCULAR system, *CHICKEN embryos, *ONTOGENY, *ION channels, *VOLTAGE-gated ion channels

Abstract

The functioning of the cardiovascular system is critical for embryo survival. Cardiac contractions depend on the sequential activation of different classes of voltage-gated ion channels. Understanding the fundamental features of these interactions is important for identifying the mechanisms of pathologies development in the myocardium. However, at present there is no consensus on which ion channels are involved in the formation of automaticity in the early embryonic stages. The aim of this study was to elucidate the expression of genes encoding various types of ion channels that are involved in the generation of electrical activity chicken heart at different stages of ontogenesis. We analyzed the expression of 14 genes from different families of ion channels. It was revealed that the expression profiles of ion channel genes change depending on the stages of ontogenesis. The HCN4 , CACNA1D , SCN1A , SCN5A , KCNA1 genes have maximum expression at the tubular heart stage. In adult, a switch occurs to the higher expression of CACNA1C , KCNH6 , RYR and SLC8A1 genes. This data correlated with the results obtained by the microelectrode method. It can be assumed that the automaticity of the tubular heart is mainly due to the mechanism of the «membrane–clock» (hyperpolarization-activated current (I f), Ca2+–current L–type (I CaL), Na+–current (I Na) and the slow component of the delayed rectifier K+–current (I Ks)). Whereas in adult birds, the mechanism for generating electrical impulses is determined by both « membrane– clock» and «Ca2+–clock». [Display omitted] • At different stages of ontogenesis, the electrophysiology of the developing heart was studied. • These data coincide with changes in gene expression of voltage-gated ion channels. • The HCN4, CACNA1D, SCN1A, SCN5A, KCNA1 genes have maximum expression at the tubular heart. • In adult birds, a switch occurs to the expression of CACNA1C, KCNH6, RYR, SLC8A1 genes. • Thus, the embryonic heart automatism is due to M-clock, in adults – M-clock and Ca-clock. [ABSTRACT FROM AUTHOR]

Published

2024

2. A self-eliminating allelic-drive reverses insecticide resistance in Drosophila leaving no transgene in the population.

Author

Auradkar, Ankush, Corder, Rodrigo M., Marshall, John M., and Bier, Ethan

Subjects

VOLTAGE-gated ion channels, INSECTICIDE resistance, DROSOPHILA melanogaster, PUBLIC welfare, DROSOPHILA

Abstract

Insecticide resistance (IR) poses a significant global challenge to public health and welfare. Here, we develop a locally-acting unitary self-eliminating allelic-drive system, inserted into the Drosophila melanogaster yellow (y) locus. The drive cassette encodes both Cas9 and a single gRNA to bias inheritance of the favored wild-type (1014 L) allele over the IR (1014 F) variant of the voltage-gated sodium ion channel (vgsc) target locus. When enduring a fitness cost, this transiently-acting drive can increase the frequency of the wild-type allele to 100%, depending on its seeding ratio, before being eliminated from the population. However, in a fitness-neutral "hover" mode, the drive maintains a constant frequency in the population, completely converting IR alleles to wild-type, even at low initial seeding ratios. A self-eliminating allelic drive reverses an insecticide resistance genotype back to wild-type in a Drosophila population, and then recedes from the population due to its fitness cost, thereby achieving clean population replacement with a GMO-free endpoint. [ABSTRACT FROM AUTHOR]

Published

2024

3. Voltage-Gated Ion Channel Compensatory Effect in DEE: Implications for Future Therapies.

Author

Shabani, Khadijeh, Krupp, Johannes, Lemesre, Emilie, Lévy, Nicolas, and Tran, Helene

Subjects

*SODIUM channels, *POTASSIUM channels, *CALCIUM channels, *PHENOTYPIC plasticity, *INTELLECTUAL disabilities, *VOLTAGE-gated ion channels, *ION channels

Abstract

Developmental and Epileptic Encephalopathies (DEEs) represent a clinically and genetically heterogeneous group of rare and severe epilepsies. DEEs commonly begin early in infancy with frequent seizures of various types associated with intellectual disability and leading to a neurodevelopmental delay or regression. Disease-causing genomic variants have been identified in numerous genes and are implicated in over 100 types of DEEs. In this context, genes encoding voltage-gated ion channels (VGCs) play a significant role, and part of the large phenotypic variability observed in DEE patients carrying VGC mutations could be explained by the presence of genetic modifier alleles that can compensate for these mutations. This review will focus on the current knowledge of the compensatory effect of DEE-associated voltage-gated ion channels and their therapeutic implications in DEE. We will enter into detailed considerations regarding the sodium channels SCN1A, SCN2A, and SCN8A; the potassium channels KCNA1, KCNQ2, and KCNT1; and the calcium channels CACNA1A and CACNA1G. [ABSTRACT FROM AUTHOR]

Published

2024

4. Voltage-gated ion channels in epilepsies: circuit dysfunctions and treatments.

Author

Debanne, Dominique, Mylonaki, Konstantina, Musella, Maria Laura, and Russier, Michaël

Subjects

*ION channels, *SODIUM channels, *NEURAL inhibition, *PARTIAL epilepsy, *VOLTAGE-gated ion channels, *EPILEPSY, *NEURAL transmission, *INTERNEURONS

Abstract

Voltage-gated ion channels are key players in neuronal excitability, synaptic transmission, and neuronal synchrony and represent one of the major sources of abnormal function of neuronal circuits occurring during epilepsy. Epilepsy does not result solely from the imbalance between excitatory and inhibitory ion channels; loss of function in excitatory channels or gain of function in inhibitory channels is also reported in epileptic encephalopathies. Synaptic inhibition triggers focal epilepsies, possibly through the facilitation of excitatory synaptic transmission due to the deinactivation of axonal sodium channels. Neural synchrony and its transmission within neural microcircuits is controlled by voltage-gated ion channels located in the axon, the dendrites, and the cell body. New molecules targeting excitatory and inhibitory ion channels need to be identified and tested in in vitro and in vivo models of epileptic encephalopathies. Epileptic encephalopathies are generally considered to be functional disruptions in the balance between neural excitation and inhibition. Excitatory and inhibitory voltage-gated ion channels are key targets of antiepileptic drugs, playing a critical role in regulating neuronal excitation and synaptic transmission. Recent research has highlighted the significance of ion channels in various aspects of epilepsy, including presynaptic neurotransmitter release, intrinsic neuronal excitability, and neural synchrony. Genetic alterations in excitatory and inhibitory ion channels within principal neurons and in inhibitory interneurons have also been identified as key contributors to the development of epilepsies. We review these recent studies and shed light on the bidirectional relationship between epilepsy and neuronal excitability and the latest advancements in pharmacological therapeutics targeting ion channels for epilepsy treatment. [ABSTRACT FROM AUTHOR]

Published

2024

5. The role of astrocytes from synaptic to non-synaptic plasticity.

Author

Sanz-Gálvez, Rafael, Falardeau, Dominic, Kolta, Arlette, and Inglebert, Yanis

Subjects

NEUROPLASTICITY, VOLTAGE-gated ion channels, ASTROCYTES, KNOWLEDGE transfer, HOMEOSTASIS, INFORMATION processing

Abstract

Information storage and transfer in the brain require a high computational power. Neuronal network display various local or global mechanisms to allow information storage and transfer in the brain. From synaptic to intrinsic plasticity, the rules of input-output function modulation have been well characterized in neurons. In the past years, astrocytes have been suggested to increase the computational power of the brain and we are only just starting to uncover their role in information processing. Astrocytes maintain a close bidirectional communication with neurons to modify neuronal network excitability, transmission, axonal conduction, and plasticity through various mechanisms including the release of gliotransmitters or local ion homeostasis. Astrocytes have been significantly studied in the context of long-term or short-term synaptic plasticity, but this is not the only mechanism involved in memory formation. Plasticity of intrinsic neuronal excitability also participates in memory storage through regulation of voltage-gated ion channels or axonal morphological changes. Yet, the contribution of astrocytes to these other forms of non-synaptic plasticity remains to be investigated. In this review, we summarized the recent advances on the role of astrocytes in different forms of plasticity and discuss new directions and ideas to be explored regarding astrocytes-neuronal communication and regulation of plasticity. [ABSTRACT FROM AUTHOR]

Published

2024

6. Voltage-gated potassium channels and genetic epilepsy.

Author

Yiting Zheng and Jing Chen

Subjects

VOLTAGE-gated ion channels, POTASSIUM channels, DIAGNOSIS of epilepsy, GENETIC disorder diagnosis, GENETIC mutation, EPILEPSY

Abstract

Recent advances in exome and targeted sequencing have significantly improved the aetiological diagnosis of epilepsy, revealing an increasing number of epilepsy-related pathogenic genes. As a result, the diagnosis and treatment of epilepsy have become more accessible and more traceable. Voltage-gated potassium channels (Kv) regulate electrical excitability in neuron systems. Mutate Kv channels have been implicated in epilepsy as demonstrated in case reports and researches using gene-knockout mouse models. Both gain and loss-of-function of Kv channels lead to epilepsy with similar phenotypes through different mechanisms, bringing new challenges to the diagnosis and treatment of epilepsy. Research on genetic epilepsy is progressing rapidly, with several drug candidates targeting mutated genes or channels emerging. This article provides a brief overview of the symptoms and pathogenesis of epilepsy associated with voltage-gated potassium ion channels dysfunction and highlights recent progress in treatments. Here, we reviewed case reports of gene mutations related to epilepsy in recent years and summarized the proportion of Kv genes. Our focus is on the progress in precise treatments for specific voltage-gated potassium channel genes linked to epilepsy, including KCNA1, KCNA2, KCNB1, KCNC1, KCND2, KCNQ2, KCNQ3, KCNH1, and KCNH5. [ABSTRACT FROM AUTHOR]

Published

2024

7. A venom peptide-induced NaV channel modulation mechanism involving the interplay between fixed channel charges and ionic gradients.

Author

Thapa, Ashvriya, Jia Hao Beh, Robinson, Samuel D., Deuis, Jennifer R., Hue Tran, Vetter, Irina, and Keramidas, Angelo

Subjects

*MEMBRANE potential, *ACTIVATION energy, *ELECTRIC fields, *ION channels, *PEPTIDES, *SODIUM channels, *VOLTAGE-gated ion channels

Abstract

Venoms are used by arthropods either to immobilize prey or as defense against predators. Our study focuses on the venom peptide, Ta3a, from the African ant species, Tetramorium africanum and its effects on voltage-gated sodium (NaV) channels, which are ion channels responsible for the generation of electrical signals in electrically excitable cells, such as neurons. Using the NaV1.7 isoform as our model NaV channel we show that Ta3a prolongs single channel active periods with increased open probability and induces non-inactivating whole-cell currents. Ta3a-affected NaV1.7 channels exhibit a leftward (hyperpolarizing) shift in activation threshold, constitutive activity even in the absence of an activating voltage stimulus, and at cell membrane voltages where channels are normally silent. Current-voltage experiments show that Ta3a shifts the voltage at which NaV current changes direction (reversal potential) by altering the local ionic concentration of permeant ions (Na+) rather than changing the channel's preference for ionic species. We propose a model where Ta3a maintains the positively charged voltage-sensing (S4) domains of the channel in the activated configuration where their electric field is exposed to the extracellular membrane surface to create an ionic bilayer comprising S4 domains and mobile anions (Cl-). This bilayer has a depolarizing effect on the cell membrane, thus reducing the amount of externally applied voltage required for channel activation. [ABSTRACT FROM AUTHOR]

Published

2024

8. The TREK‐1 potassium channel is a potential pharmacological target for vasorelaxation in pulmonary hypertension.

Author

Csáki, Réka, Nagaraj, Chandran, Almássy, János, Khozeimeh, Mohammad Ali, Jeremic, Dusan, Olschewski, Horst, Dobolyi, Alice, Hoetzenecker, Konrad, Olschewski, Andrea, Enyedi, Péter, and Lengyel, Miklós

Subjects

*PULMONARY arterial hypertension, *LABORATORY rats, *MEMBRANE potential, *PULMONARY hypertension, *SMOOTH muscle, *VOLTAGE-gated ion channels, *POTASSIUM channels, *LUNGS

Abstract

Background and purpose: Pulmonary arterial hypertension (PAH) is a progressive disease in which chronic membrane potential (Em) depolarisation of the pulmonary arterial smooth muscle cells (PASMCs) causes calcium overload, a key pathological alteration. Under resting conditions, the negative Em is mainly set by two pore domain potassium (K2P) channels, of which the TASK‐1 has been extensively investigated. Experimental Approach: Ion channel currents and membrane potential of primary cultured human(h) PASMCs were measured using the voltage‐ and current clamp methods. Intracellular [Ca2+] was monitored using fluorescent microscopy. Pulmonary BP and vascular tone measurements were also performed ex vivo using a rat PAH model. Key Results: TREK‐1 was the most abundantly expressed K2P in hPASMCs of healthy donors and idiopathic(I) PAH patients. Background K+‐current was similar in hPASMCs for both groups and significantly enhanced by the TREK activator ML‐335. In donor hPASMCs, siRNA silencing or pharmacological inhibition of TREK‐1 caused depolarisation, reminiscent of the electrophysiological phenotype of idiopathic PAH. ML‐335 hyperpolarised donor hPASMCs and normalised the Em of IPAH hPASMCs. A close link was found between TREK‐1 activity and intracellular Ca2+‐signalling using a channel activator, ML‐335, and an inhibitor, spadin. In the rat, ML‐335 relaxed isolated pre‐constricted pulmonary arteries and significantly decreased pulmonary arterial pressure in the isolated perfused lung. Conclusions and Implications: These data suggest that TREK‐1is a key factor in Em setting and Ca2+ homeostasis of hPASMC, and therefore, essential for maintenance of a low resting pulmonary vascular tone. Thus TREK‐1 may represent a new therapeutic target for PAH. [ABSTRACT FROM AUTHOR]

Published

2024

9. Drug Repurposing Patent Applications: April–June 2024.

Author

Mucke, Hermann A.M.

Subjects

LIFE sciences, DRUGS, CATHETER-associated urinary tract infections, HIGH-density lipoprotein receptors, SCHWANNOMAS, SODIUM channels, T cells, NEURAL stimulation, VOLTAGE-gated ion channels

Abstract

The document "Drug Repurposing Patent Applications: April–June 2024" explores various drug repurposing patent applications, highlighting the potential of repurposed drugs in treating a wide range of conditions. Examples include treprostinil for enhancing the killing of Mycobacterium abscessus, lapaquistat for intestinal infections, and rabeprazole for inhibiting aortic valve calcification. The document also discusses the therapeutic applications of compounds like bupivacaine, fenofibrate, flibanserin, propofol, and methylene blue in different medical conditions, showcasing the versatility of repurposed drugs in addressing diverse health issues. [Extracted from the article]

Published

2024

10. Computational Modeling of Sodium-Ion-Channel-Based Glucose Sensing Biophysics to Study Cardiac Pacemaker Action Potential.

Author

Mahapatra, Chitaranjan, Shanmugam, Kirubanandan, and Rusho, Maher Ali

Subjects

ACTION potentials, MEDICAL personnel, CARDIAC arrest, ORDINARY differential equations, SODIUM channels, ION channels, VOLTAGE-gated ion channels

Abstract

Elevated blood glucose levels, known as hyperglycemia, play a significant role in sudden cardiac arrest, often resulting in sudden cardiac death, particularly among those with diabetes. Understanding the internal mechanisms has been a challenge for healthcare professionals, leading many research groups to investigate the relationship between blood glucose levels and cardiac electrical activity. Our hypothesis suggests that glucose-sensing biophysics mechanisms in cardiac tissue could clarify this connection. To explore this, we adapted a single-compartment computational model of the human pacemaker action potential. We incorporated glucose-sensing mechanisms with voltage-gated sodium ion channels using ordinary differential equations. Parameters for the model were based on existing experimental studies to mimic the impact of glucose levels on pacemaker action potential firing. Simulations using voltage clamp and current clamp techniques showed that elevated glucose levels decreased sodium ion channel currents, leading to a reduction in the pacemaker action potential frequency. In summary, our mathematical model provides a cellular-level understanding of how high glucose levels can lead to bradycardia and sudden cardiac death. [ABSTRACT FROM AUTHOR]

Published

2024

11. Biophysical mechanism of animal magnetoreception, orientation and navigation

Author

Dimitris J. Panagopoulos, Andreas Karabarbounis, and George P. Chrousos

Subjects

Geomagnetic field, Animal magnetoreception, Orientation, Navigation, Electromagnetic fields, Voltage-gated ion channels, Medicine, Science

Abstract

Abstract We describe a biophysical mechanism for animal magnetoreception, orientation and navigation in the geomagnetic field (GMF), based on the ion forced oscillation (IFO) mechanism in animal cell membrane voltage-gated ion channels (VGICs) (IFO-VGIC mechanism). We review previously suggested hypotheses. We describe the structure and function of VGICs and argue that they are the most sensitive electromagnetic sensors in all animals. We consider the magnetic force exerted by the GMF on a mobile ion within a VGIC of an animal with periodic velocity variation. We apply this force in the IFO equation resulting in solution connecting the GMF intensity with the velocity variation rate. We show that animals with periodic velocity variations, receive oscillating forces on their mobile ions within VGICs, which are forced to oscillate exerting forces on the voltage sensors of the channels, similar or greater to the forces from membrane voltage changes that normally induce gating. Thus, the GMF in combination with the varying animal velocity can gate VGICs and alter cell homeostasis in a degree depending, for a given velocity and velocity variation rate, on GMF intensity (unique in each latitude) and the angle between velocity and GMF axis, which determine animal position and orientation.

Published

2024

12. PIP2 inhibits pore opening of the cyclic nucleotide-gated channel SthK.

Author

Thon, Oliver, Wang, Zhihan, Schmidpeter, Philipp A. M., and Nimigean, Crina M.

Subjects

CYCLIC nucleotide-gated ion channels, BINDING sites, COMPRESSED natural gas, VOLTAGE-gated ion channels, ARGININE, ION channels, GLUE

Abstract

The signaling lipid phosphatidylinositol-4,5-bisphosphate (PIP2) regulates many ion channels. It inhibits eukaryotic cyclic nucleotide-gated (CNG) channels while activating their relatives, the hyperpolarization-activated and cyclic nucleotide-modulated (HCN) channels. The prokaryotic SthK channel from Spirochaeta thermophila shares features with CNG and HCN channels and is an established model for this channel family. Here, we show SthK activity is inhibited by PIP2. A cryo-EM structure of SthK in nanodiscs reveals a PIP2-fitting density coordinated by arginine and lysine residues from the S4 helix and the C-linker, located between voltage-sensing and pore domains of adjacent subunits. Mutation of two arginine residues weakens PIP2 inhibition with the double mutant displaying insensitivity to PIP2. We propose that PIP2 inhibits SthK by gluing S4 and S6 together, stabilizing a resting channel conformation. The PIP2 binding site is partially conserved in CNG channels suggesting the possibility of a similar inhibition mechanism in the eukaryotic homologs. Thon et al. showed that the signaling lipid PIP2 inhibits a bacterial homolog of cyclic nucleotide-gated ion channels by binding between the voltage-sensing and pore domains of adjacent subunits and stabilizing a resting channel state. [ABSTRACT FROM AUTHOR]

Published

2024

13. Potential roles of voltage-gated ion channel disruption in Tuberous Sclerosis Complex.

Author

Egido-Betancourt, Hailey X., Strowd III, Roy E., and Raab-Graham, Kimberly F.

Subjects

POTASSIUM channels, GAIN-of-function mutations, TUBEROUS sclerosis, ION channels, CALCIUM channels, VOLTAGE-gated ion channels, SODIUM channels

Abstract

Tuberous Sclerosis Complex (TSC) is a lynchpin disorder, as it results in overactive mammalian target of rapamycin (mTOR) signaling, which has been implicated in a multitude of disease states. TSC is an autosomal dominant disease where 90% of affected individuals develop epilepsy. Epilepsy results from aberrant neuronal excitability that leads to recurring seizures. Under neurotypical conditions, the coordinated activity of voltage-gated ion channels keep neurons operating in an optimal range, thus providing network stability. Interestingly, loss or gain of function mutations in voltage-gated potassium, sodium, or calcium channels leads to altered excitability and seizures. To date, little is known about voltage-gated ion channel expression and function in TSC. However, data is beginning to emerge on how mTOR signaling regulates voltage-gated ion channel expression in neurons. Herein, we provide a comprehensive review of the literature describing common seizure types in patients with TSC, and suggest possible parallels between acquired epilepsies with known voltage-gated ion channel dysfunction. Furthermore, we discuss possible links towardmTOR regulation of voltage-gated ion channels expression and channel kinetics and the underlying epileptic manifestations in patients with TSC. [ABSTRACT FROM AUTHOR]

Published

2024

14. hERG channel agonist NS1643 strongly inhibits invasive astrocytoma cell line SMA-560.

Author

Benn, Kieran W., Yuan, Patrick H., Chong, Harvey K., Stylii, Stanley S., Luwor, Rodney B., and French, Christopher R.

Subjects

*BRAIN tumors, *CELL migration, *ION channels, *TEMOZOLOMIDE, *CANCER treatment, *VOLTAGE-gated ion channels, *POTASSIUM channels

Abstract

Gliomas are highly malignant brain tumours that remain refractory to treatment. Treatment is typically surgical intervention followed by concomitant temozolomide and radiotherapy; however patient prognosis remains poor. Voltage gated ion channels have emerged as novel targets in cancer therapy and inhibition of a potassium selective subtype (hERG, Kv11.1) has demonstrated antitumour activity. Unfortunately blockade of hERG has been limited by cardiotoxicity, however hERG channel agonists have produced similar chemotherapeutic benefit without significant side effects. In this study, electrophysiological recordings suggest the presence of hERG channels in the anaplastic astrocytoma cell line SMA-560, and treatment with the hERG channel agonist NS1643, resulted in a significant reduction in the proliferation of SMA-560 cells. In addition, NS1643 treatment also resulted in a reduction of the secretion of matrix metalloproteinase-9 and SMA-560 cell migration. When combined with temozolomide, an additive impact was observed, suggesting that NS1643 may be a suitable adjuvant to temozolomide and limit the invasiveness of glioma. [ABSTRACT FROM AUTHOR]

Published

2024

15. Association of SCN1A Polymorphisms rs3812718 and rs2298771 with Epilepsy.

Author

Katsarou, Martha-Spyridoula, Siatouni, Anna, Tsikrika, Danae, Kokkiou, Elena, Stefanatou, Maria, Verentzioti, Anastasia, Alexoudi, Athanasia, Gatzonis, Stylianos, Drakoulis, Nikolaos, and Papasavva, Maria

Subjects

*SEIZURES (Medicine), *VOLTAGE-gated ion channels, *SINGLE nucleotide polymorphisms, *EPILEPSY, *ACTION potentials, *SODIUM channels

Abstract

Background/Objectives: Epilepsy is a brain disease with both environmental and genetic inputs. Ion channel dysfunction seems to be of great significance for abnormal neuronal behavior during epileptic seizures. Within neurons, the voltage-gated sodium channels are crucial proteins contributing to the initiation and propagation of action potentials. The voltage-gated sodium channel α subunit 1 (SCN1A) gene encodes for the α subunit of a voltage-gated ion channel. The aim of the study was to investigate the relation of two common SCN1A variants, i.e., rs3812718 and rs2298771, with distinct epileptic phenotypes in a South-Eastern European population. Methods: DNA was extracted from 214 unrelated participants with focal onset, focal to bilateral tonic–clonic, or generalized onset epileptic seizures and genotyped using real-time PCR (LightSNiP assays) followed by melting curve analysis. Statistical analysis of the results was performed using IBM SPSS Statistics software (version 29.0 for Windows). Results: Genotype frequency distribution analysis indicated an association for the A-allele-containing genotypes of both rs3812718 and rs2298771 polymorphisms of SCN1A with generalized onset seizures and focal to bilateral tonic–clonic seizures versus focal onset seizures. Conclusions: Consequently, the study provides evidence that supports a potential association of the investigated SCN1A polymorphisms with distinct seizure subtype susceptibility in South-Eastern Europeans. [ABSTRACT FROM AUTHOR]

Published

2024

16. Identification and Characterization of Shaker Potassium Channel Gene Family and Response to Salt and Chilling Stress in Rice.

Author

Tian, Quanxiang, Yu, Tongyuan, Dong, Mengyuan, Hu, Yue, Chen, Xiaoguang, Xue, Yuan, Fang, Yunxia, Zhang, Jian, Zhang, Xiaoqin, and Xue, Dawei

Subjects

*SALT tolerance in plants, *GENE families, *STRAINS & stresses (Mechanics), *POTASSIUM channels, *POTENTIAL functions, *ABIOTIC stress, *VOLTAGE-gated ion channels

Abstract

Shaker potassium channel proteins are a class of voltage-gated ion channels responsible for K+ uptake and translocation, playing a crucial role in plant growth and salt tolerance. In this study, bioinformatic analysis was performed to identify the members within the Shaker gene family. Moreover, the expression patterns of rice Shaker(OsShaker) K+ channel genes were analyzed in different tissues and salt treatment by RT–qPCR. The results revealed that there were eight OsShaker K+ channel genes distributed on chromosomes 1, 2, 5, 6 and 7 in rice, and their promoters contained a variety of cis-regulatory elements, including hormone-responsive, light-responsive, and stress-responsive elements, etc. Most of the OsShaker K+ channel genes were expressed in all tissues of rice, but at different levels in different tissues. In addition, the expression of OsShaker K+ channel genes differed in the timing, organization and intensity of response to salt and chilling stress. In conclusion, our findings provide a reference for the understanding of OsShaker K+ channel genes, as well as their potential functions in response to salt and chilling stress in rice. [ABSTRACT FROM AUTHOR]

Published

2024

17. Ion channels in osteoarthritis: emerging roles and potential targets.

Author

Zhou, Renpeng, Fu, Wenyu, Vasylyev, Dmytro, Waxman, Stephen G., and Liu, Chuan-ju

Subjects

*TRP channels, *ACID-sensing ion channels, *CHLORIDE channels, *ION channels, *SODIUM channels, *VOLTAGE-gated ion channels, *OSTEOARTHRITIS

Abstract

Osteoarthritis (OA) is a highly prevalent joint disease that causes substantial disability, yet effective approaches to disease prevention or to the delay of OA progression are lacking. Emerging evidence has pinpointed ion channels as pivotal mediators in OA pathogenesis and as promising targets for disease-modifying treatments. Preclinical studies have assessed the potential of a variety of ion channel modulators to modify disease pathways involved in cartilage degeneration, synovial inflammation, bone hyperplasia and pain, and to provide symptomatic relief in models of OA. Some of these modulators are currently being evaluated in clinical trials. This review explores the structures and functions of ion channels, including transient receptor potential channels, Piezo channels, voltage-gated sodium channels, voltage-dependent calcium channels, potassium channels, acid-sensing ion channels, chloride channels and the ATP-dependent P2XR channels in the osteoarthritic joint. The discussion spans channel-targeting drug discovery and potential clinical applications, emphasizing opportunities for further research, and underscoring the growing clinical impact of ion channel biology in OA. Ion channels have key functions in chondrocytes, bone cells, immune cells and neurons. Liu and colleagues discuss how these functions might contribute to cartilage degeneration, bone formation inflammation and pain in osteoarthritis, and highlight the therapeutic potential of ion channel modulators. Key points: Ion channels have key functions in the joints and emerge as important contributors to pathogenic processes in osteoarthritis (OA). Dysregulation of mechanical and biochemical stimuli activates ion channels such as TRPV4 and Piezo channels, leading to Ca2+ and Na+ influx, which contributes to cartilage destruction, inflammation and pain in OA. Some ion channels typically associated with peripheral neurons are also expressed in chondrocytes and immune cells, and have a crucial role in the pathophysiology of OA. Exploration of ion channel expression, interactions, and properties in joints, along with development of specific channel agonists and antagonists, has helped to accelerate research on their potential roles in OA. Several ion channel modulators have been recently tested in animal models and patients with OA, with encouraging results. Targeting of ion channels holds promise for the development of new and more effective OA treatment strategies. [ABSTRACT FROM AUTHOR]

Published

2024

18. Bioelectric pharmacology of cancer: A systematic review of ion channel drugs affecting the cancer phenotype.

Author

Kofman, Karina and Levin, Michael

Subjects

*VOLTAGE-gated ion channels, *ION channels, *LIGAND-gated ion channels, *EVOLUTIONARY developmental biology, *PHARMACOLOGY, *CARCINOGENS, *ANTINEOPLASTIC agents

Abstract

Cancer is a pernicious and pressing medical problem; moreover, it is a failure of multicellular morphogenesis that sheds much light on evolutionary developmental biology. Numerous classes of pharmacological agents have been considered as cancer therapeutics and evaluated as potential carcinogenic agents; however, these are spread throughout the primary literature. Here, we briefly review recent work on ion channel drugs as promising anti-cancer treatments and present a systematic review of the known cancer-relevant effects of 109 drugs targeting ion channels. The roles of ion channels in cancer are consistent with the importance of bioelectrical parameters in cell regulation and with the functions of bioelectric signaling in morphogenetic signals that act as cancer suppressors. We find that compounds that are well-known for having targets in the nervous system, such as voltage-gated ion channels, ligand-gated ion channels, proton pumps, and gap junctions are especially relevant to cancer. Our review suggests further opportunities for the repurposing of numerous promising candidates in the field of cancer electroceuticals. [ABSTRACT FROM AUTHOR]

Published

2024

19. The Phytochemical, Quercetin, Attenuates Nociceptive and Pathological Pain: Neurophysiological Mechanisms and Therapeutic Potential.

Author

Takeda, Mamoru, Sashide, Yukito, Toyota, Ryou, and Ito, Haruka

Subjects

*ACID-sensing ion channels, *VOLTAGE-gated ion channels, *NOCICEPTIVE pain, *QUERCETIN, *LOCAL anesthetics, *NEUROPHYSIOLOGY

Abstract

Although phytochemicals are plant-derived toxins that are primarily produced as a form of defense against insects or microbes, several lines of study have demonstrated that the phytochemical, quercetin, has several beneficial biological actions for human health, including antioxidant and inflammatory effects without side effects. Quercetin is a flavonoid that is widely found in fruits and vegetables. Since recent studies have demonstrated that quercetin can modulate neuronal excitability in the nervous system, including nociceptive sensory transmission via mechanoreceptors and voltage-gated ion channels, and inhibit the cyclooxygenase-2-cascade, it is possible that quercetin could be a complementary alternative medicine candidate; specifically, a therapeutic agent against nociceptive and pathological pain. The focus of this review is to elucidate the neurophysiological mechanisms underlying the modulatory effects of quercetin on nociceptive neuronal activity under nociceptive and pathological conditions, without inducing side effects. Based on the results of our previous research on trigeminal pain, we have confirmed in vivo that the phytochemical, quercetin, demonstrates (i) a local anesthetic effect on nociceptive pain, (ii) a local anesthetic effect on pain related to acute inflammation, and (iii) an anti-inflammatory effect on chronic pain. In addition, we discuss the contribution of quercetin to the relief of nociceptive and inflammatory pain and its potential clinical application. [ABSTRACT FROM AUTHOR]

Published

2024

20. KCNG4 Genetic Variant Linked to Migraine Prevents Expression of KCNB1.

Author

Lacroix, Gabriel, Bhat, Shreyas, Shafia, Zerghona, and Blunck, Rikard

Subjects

*VOLTAGE-gated ion channels, *GENETIC variation, *CELLULAR signal transduction, *MIGRAINE, *GENE expression

Abstract

Migraines are a common type of headache affecting around 15% of the population. The signalling pathways leading to migraines have not been fully understood, but neuronal voltage-gated ion channels, such as KCNG4, have been linked to this pathology. KCNG4 (Kv6.4) is a silent member of the superfamily of voltage-gated potassium (Kv) channels, which expresses in heterotetramers with members of the KCNB (Kv2) family. The genetic variant Kv6.4-L360P has previously been linked to migraines, but their mode of action remains unknown. Here, we characterized the molecular characteristics of Kv6.4-L360P when co-expressed with Kv2.1. We found that Kv6.4-L360P almost completely abolishes Kv2 currents, and we propose that this mechanism in the trigeminal system, linked to the initiation of migraine, leads to the pathology. [ABSTRACT FROM AUTHOR]

Published

2024

21. Protein nanoparticles induce the activation of voltage-dependent non-selective ion channels to modulate biological osmotic pressure in cytotoxic cerebral edema.

Author

Wei Fan, Liming Liu, Yuxuan Yin, Jiayi Zhang, Zhaoshun Qiu, Jun Guo, and Guangming Li

Subjects

CEREBRAL edema, PRIMARY cell culture, OSMOTIC pressure, CHLORIDE channels, LABORATORY rats, VOLTAGE-gated ion channels, ION channels

Abstract

Introduction: Cytotoxic cerebral edema is a serious complication associated with cerebral ischemic stroke and is widely treated using the hypertonic dehydrant. Here, we propose, for the first time, the decrease of intracellular osmosis as a treatment strategy for alleviating cytotoxic cerebral edema. Methods: We established a fluorescence resonance energy transfer-based intermediate filament tension probe for the study and in situ evaluation of osmotic gradients, which were examined in real-time in living cells from primary cultures as well as cell lines. The MCAO rat model was used to confirm our therapy of cerebral edema. Results: Depolymerization of microfilaments/microtubules and the production of NLRP3 inflammasome resulted in an abundance of protein nanoparticles (PNs) in the glutamate-induced swelling of astrocytes. PNs induced changes in membrane potential and intracellular second messengers, thereby contributing to hyper-osmosis and the resultant astrocyte swelling via the activation of voltage-dependent nonselective ion channels. Therefore, multiple inhibitors of PNs, sodium and chloride ion channels were screened as compound combinations, based on a decrease in cell osmosis and astrocyte swelling, which was followed by further confirmation of the effectiveness of the compound combination against alleviated cerebral edema after ischemia. Discussion: The present study proposes new pathological mechanisms underlying "electrophysiology-biochemical signal-osmotic tension," which are responsible for cascade regulation in cerebral edema. It also explores various compound combinations as a potential treatment strategy for cerebral edema, which act by multi-targeting intracellular PNs and voltage-dependent nonselective ion flux to reduce astrocyte osmosis. [ABSTRACT FROM AUTHOR]

Published

2024

22. Effect of Crude Extract from the Sea Anemone Bunodeopsis globulifera on Voltage-Gated Ion Channels from Central and Peripheral Murine Nervous Systems.

Author

Flores-Pérez, Aleida Jeannette, Loya-López, Santiago, Ávalos-Fuentes, Arturo, Calderon-Rivera, Aida, Damo, Elisa, Lazcano-Pérez, Fernando, Khanna, Rajesh, Florán-Garduño, Benjamin, and Sánchez-Rodríguez, Judith

Subjects

*VOLTAGE-gated ion channels, *SEA anemones, *SODIUM channels, *PERIPHERAL nervous system, *PROTEIN structure, *POTASSIUM channels

Abstract

Sea anemones are an important source of bioactive compounds with potential pharmacological applications. Their toxins are produced and stored in organelles called nematocysts and act on specific targets, including voltage-gated ion channels. To date, sea anemone toxins have demonstrated effects on voltage-gated sodium and potassium channels, facilitating investigations into the structure and function of these proteins. In this study, we evaluated the effect of Bunodeopsis globulifera sea anemone crude extract, and of a low molecular weight fraction, on voltage-gated sodium and calcium channels within the murine nervous system. Notably, the crude extract led to a significant reduction in total sodium current, while also triggering calcium-dependent glutamate release. Furthermore, the low molecular weight fraction, in particular, enhanced total calcium currents and current density. These findings underscore the existence of sea anemone toxins with diverse mechanisms of action beyond those previously documented. [ABSTRACT FROM AUTHOR]

Published

2024

23. Microelectrode Arrays Measure Blocking of Voltage‐Gated Calcium Ion Channels on Supported Lipid Bilayers Derived from Primary Neurons.

Author

Lu, Zixuan, Barberio, Chiara, Fernandez‐Villegas, Ana, Withers, Aimee, Wheeler, Alexandra, Kallitsis, Konstantinos, Martinelli, Eleonora, Savva, Achilleas, Hess, Becky M., Pappa, Anna‐Maria, Schierle, Gabriele S. Kaminski, and Owens, Róisín M.

Subjects

*VOLTAGE-gated ion channels, *ION channels, *BILAYER lipid membranes, *NEURONS, *NEUROLOGICAL disorders, *DRUG use testing

Abstract

Drug studies targeting neuronal ion channels are crucial to understand neuronal function and develop therapies for neurological diseases. The traditional method to study neuronal ion‐channel activities heavily relies on the whole‐cell patch clamp as the industry standard. However, this technique is both technically challenging and labour‐intensive, while involving the complexity of keeping cells alive with low throughput. Therefore, the shortcomings are limiting the efficiency of ion‐channel‐related neuroscience research and drug testing. Here, this work reports a new system of integrating neuron membranes with organic microelectrode arrays (OMEAs) for ion‐channel‐related drug studies. This work demonstrates that the supported lipid bilayers (SLBs) derived from both neuron‐like (neuroblastoma) cells and primary neurons are integrated with OMEAs for the first time. The increased expression of voltage‐gated calcium (CaV) ion channels on differentiated SH‐SY5Y SLBs compared to non‐differentiated ones is sensed electrically. Also, dose‐response of the CaV ion‐channel blocking effect on primary cortical neuronal SLBs from rats is monitored. The dose range causing ion channel blocking is comparable to literature. This system overcomes the major challenges from traditional methods (e.g., patch clamp) and showcases an easy‐to‐test, rapid, ultra‐sensitive, cell‐free, and high‐throughput platform to monitor dose‐dependent ion‐channel blocking effects on native neuronal membranes. [ABSTRACT FROM AUTHOR]

Published

2024

24. Voltage-Gated Ion Channels Are Transcriptional Targets of Sox10 during Oligodendrocyte Development.

Author

Peters, Christian, Aberle, Tim, Sock, Elisabeth, Brunner, Jessica, Küspert, Melanie, Hillgärtner, Simone, Wüst, Hannah M., and Wegner, Michael

Subjects

*TRANSCRIPTION factors, *SOX transcription factors, *ION channels, *CENTRAL nervous system, *GENE regulatory networks, *VOLTAGE-gated ion channels

Abstract

The transcription factor Sox10 is an important determinant of oligodendroglial identity and influences oligodendroglial development and characteristics at various stages. Starting from RNA-seq data, we here show that the expression of several voltage-gated ion channels with known expression and important function in oligodendroglial cells depends upon Sox10. These include the Nav1.1, Cav2.2, Kv1.1, and Kir4.1 channels. For each of the four encoding genes, we found at least one regulatory region that is activated by Sox10 in vitro and at the same time bound by Sox10 in vivo. Cell-specific deletion of Sox10 in oligodendroglial cells furthermore led to a strong downregulation of all four ion channels in a mouse model and thus in vivo. Our study provides a clear functional link between voltage-gated ion channels and the transcriptional regulatory network in oligodendroglial cells. Furthermore, our study argues that Sox10 exerts at least some of its functions in oligodendrocyte progenitor cells, in myelinating oligodendrocytes, or throughout lineage development via these ion channels. By doing so, we present one way in which oligodendroglial development and properties can be linked to neuronal activity to ensure crosstalk between cell types during the development and function of the central nervous system. [ABSTRACT FROM AUTHOR]

Published

2024

25. First-Principles Electrophysiological Models of Cardiac Ventricular Myocytes as a Basis of Multiscale Mechanics of the Heart.

Author

Mythri, T. G., Hossain, Shaikh J., Greenstein, Joseph L., Winslow, Raimond L., and Bhattacharya, Baidurya

Subjects

*HEART, *MEMBRANE potential, *ACTION potentials, *MUSCLE cells, *ION channels, *VOLTAGE-gated ion channels, *ELECTROPHYSIOLOGY, *INTRACELLULAR calcium

Abstract

Cardiac electromechanics is a coupled multiphysics and multiscale problem. Of great interest to medicine and pharmacology is how the heart responds to changes in ion channel dynamics within the myocyte that are either caused by disease or by the administration of drugs. A successful model of cardiac mechanical response must therefore incorporate a first-principles description of electrophysiology of the cardiac myocyte including intracellular calcium dynamics, transmembrane ionic currents and action potential (AP) formation at the cellular level. This article reviews the evolution of electrophysiological models of cardiac ventricular myocytes in terms of coupled differential equations whose state variables include ion channel gating parameters, intracellular ionic concentrations and the membrane voltage. The myocytes are connected through gap junctions forming fibers, which in turn connect to form cardiac tissues. The electromechanical response of cardiac tissues is coupled through intracellular calcium dynamics and stretch induced/ modulated currents, and can be solved using suitable discretization schemes under appropriate initial and boundary conditions. We discuss in detail the single-cell dynamics of the ORd model of human ventricular myocytes and describe the propagation of AP in periodically paced 1D fibers and 2D tissues. The origin of tissue-level diseased conditions in altered subcellular dynamics are discussed. [ABSTRACT FROM AUTHOR]

Published

2024

26. Biomimetic protein structural transitions regulate activation and inhibition of the broad-spectrum bactericidal activity of cationic nanoparticles.

Author

Ji, Wenke, Hu, Yongjin, Wang, Xiao, Zhao, Jinghua, He, Yan, Zhu, Zhiyuan, and Rao, Jingyi

Subjects

VOLTAGE-gated ion channels, ANTIMICROBIAL polymers, SMART materials, BIOMIMETICS, ION channels, CATIONIC polymers, NANOPARTICLES

Abstract

The development of cationic polymers as alternative materials to antibiotics necessitates addressing the challenge of balancing their antimicrobial activity and toxicity. Here we propose a precise switching strategy inspired by biomimetic voltage-gated ion channels, enabling controlled activation and inhibition of cationic antimicrobial functions through protein conformational transitions in diverse physiological environments. Following thermodynamic studies on the specific recognition between mannose end groups on polycations and concanavalin A (ConA), we synthesized a type of ConA-polycation nanoparticle. The nanoparticle was inhibited under neutral conditions, with cationic moieties shielded by ConA's β -sheet. This shielding suppresses their antimicrobial activity, thereby ensuring satisfactory biocompatibility. In mildly acidic environments, however, the transition of a portion of ConA to an α -helix conformation exposed cations at the particle periphery, activating antibacterial functionality. Compared to inhibited nanoparticles, those in the activated state exhibited a 32–256 times reduction in the minimum bactericidal concentration against bacteria and fungi (2–16 µg/mL). In a murine acute pulmonary infection model, intravenous administration of inhibited nanoparticles effectively reduced bacterial counts by 4-log within 12 h. The biomimetic design, regulating cationic antimicrobial functionality through the alteration in protein secondary structure, significantly retards bacterial resistance development, holding great promise for intelligent antimicrobial materials. Cationic antimicrobial polymers exhibit advantages distinct from antibiotics due to their lower propensity for resistance development. However, the presence of cationic moieties also poses a threat to healthy cells and tissues, significantly constraining their potential for clinical applications. To address this challenge, we propose a biomimetic strategy that mimics voltage-gated ion channels to activate the antimicrobial functionality of cations selectively in bacterial environments through the conformational transitions of proteins between β –sheets and α –helices. In healthy tissues, the antimicrobial functionality is inhibited, ensuring satisfactory biocompatibility. Antimicrobial cationic materials capable of intelligent switching between an activated state and an inhibited state in response to environmental changes offer an effective strategy to prevent the development of resistance and mitigate potential side effects. [Display omitted] [ABSTRACT FROM AUTHOR]

Published

2024

27. Spatial and temporal analysis on calcium dynamics simulation inside CA1 pyramidal neuron.

Author

Al-Aryachiyah, C. J. and Yuniati, A.

Subjects

*VOLTAGE-gated ion channels, *ION channels, *CALCIUM, *INTRACELLULAR calcium, *CONCENTRATION functions, *WAVE analysis, *PYRAMIDAL neurons

Abstract

Simulation with NEURON Simulator was carried out to model a realistic morphology of CA1 pyramidal neuron. The modeling was projected for calcium wave analysis in temporal and spatial dynamics. The morphology was built by implementing geometrical data and realistic biophysical parameters. Hodgkin-Huxley conductance-based voltage gated ion channels and kinetic scheme including calcium-induced calcium-release (CICR) were implemented as the intracellular mechanism. Recording point, [InsP3] variation, and active mechanism modification for basal analysis were subsequently manipulated due to simulation purposes. The results showed that the amplitude of calcium concentration as distance function decreased with increasing distance in each branch of apical. The same modeling of basal records revealed that calcium concentration amplitude strongly correlated to dendritic size (morphology) and initial [InsP3]. Modified simulations demonstrated that active mechanisms influenced by the distribution and conductance of the ion channels will greatly affect the intracellular calcium signaling in basal. [ABSTRACT FROM AUTHOR]

Published

2024

28. A novel image segmentation method based on spatial autocorrelation identifies A-type potassium channel clusters in the thalamus

Author

Csaba Dávid, Kristóf Giber, Katalin Kerti-Szigeti, Mihály Köllő, Zoltan Nusser, and Laszlo Acsady

Subjects

image segmentation, thalamus, potassium channels, somatosensory, voltage-gated ion channels, cluster, Medicine, Science, Biology (General), QH301-705.5

Abstract

Unsupervised segmentation in biological and non-biological images is only partially resolved. Segmentation either requires arbitrary thresholds or large teaching datasets. Here, we propose a spatial autocorrelation method based on Local Moran’s I coefficient to differentiate signal, background, and noise in any type of image. The method, originally described for geoinformatics, does not require a predefined intensity threshold or teaching algorithm for image segmentation and allows quantitative comparison of samples obtained in different conditions. It utilizes relative intensity as well as spatial information of neighboring elements to select spatially contiguous groups of pixels. We demonstrate that Moran’s method outperforms threshold-based method in both artificially generated as well as in natural images especially when background noise is substantial. This superior performance can be attributed to the exclusion of false positive pixels resulting from isolated, high intensity pixels in high noise conditions. To test the method’s power in real situation, we used high power confocal images of the somatosensory thalamus immunostained for Kv4.2 and Kv4.3 (A-type) voltage-gated potassium channels in mice. Moran’s method identified high-intensity Kv4.2 and Kv4.3 ion channel clusters in the thalamic neuropil. Spatial distribution of these clusters displayed strong correlation with large sensory axon terminals of subcortical origin. The unique association of the special presynaptic terminals and a postsynaptic voltage-gated ion channel cluster was confirmed with electron microscopy. These data demonstrate that Moran’s method is a rapid, simple image segmentation method optimal for variable and high noise conditions.

Published

2024

29. Cardiomyocyte Reduction of Hybrid/Complex N‐Glycosylation in the Adult Causes Heart Failure With Reduced Ejection Fraction in the Absence of Cellular Remodeling

Author

Anthony M. Young, John A. Miller, Andrew R. Ednie, and Eric S. Bennett

Subjects

EC coupling, echocardiography, heart failure, N‐glycosylation, voltage‐gated ion channels, Diseases of the circulatory (Cardiovascular) system, RC666-701

Abstract

Background Heart failure (HF) presents a massive burden to health care with a complex pathophysiology that results in HF with reduced left ventricle ejection fraction (EF) or HF with preserved EF. It has been shown that relatively modest changes in protein glycosylation, an essential posttranslational modification, are associated with clinical presentations of HF. We and others previously showed that such aberrant protein glycosylation in animal models can lead to HF. Methods and Results We develop and characterize a novel, tamoxifen‐inducible, cardiomyocyte Mgat1 knockout mouse strain, achieved through deletion of Mgat1, alpha‐1,3‐mannosyl‐glycoproten 2‐beta‐N‐acetlyglucosaminyltransferase, which encodes N‐acetylglucosaminyltransferase I. We investigate the role of hybrid/complex N‐glycosylation in adult HFrEF pathogenesis at the ion channel, cardiomyocyte, tissue, and gross cardiac level. The data demonstrate successful reduction of N‐acetylglucosaminyltransferase I activity and confirm that hybrid/complex N‐glycans modulate gating of cardiomyocyte voltage‐gated calcium channels. A longitudinal study shows that the tamoxifen‐inducible, cardiomyocyte Mgat1 knockout mice present with significantly reduced systolic function by 28 days post induction that progresses into HFrEF by 8 weeks post induction, without significant ventricular dilation or hypertrophy. Further, there was minimal, if any, physiologic or pathophysiologic cardiomyocyte electromechanical remodeling or fibrosis observed before (10–21 days post induction) or after (90–130 days post induction) HFrEF development. Conclusions The tamoxifen‐inducible, cardiomyocyte Mgat1 knockout mouse strain created and characterized here provides a model to describe novel mechanisms and causes responsible for HFrEF onset in the adult, likely occurring primarily through tissue‐level reductions in electromechanical activity in the absence of (or at least before) cardiomyocyte remodeling and fibrosis.

Published

2024

30. Editorial: Role of ion channels and metabotropic receptors in oligodendrogliogenesis: novel targets for demyelinating pathologies.

Author

Cherchi, Federica, Swire, Matthew, and Lecca, Davide

Subjects

G protein coupled receptors, CENTRAL nervous system, CALCIUM ions, CALCIUM channels, RNA regulation, OLIGODENDROGLIA, VOLTAGE-gated ion channels, ION channels

Abstract

The editorial discusses the crucial role of ion channels and metabotropic receptors in oligodendrogliogenesis, particularly in the context of demyelinating diseases like multiple sclerosis. While ion channels have been recognized as potential therapeutic targets, the emerging understanding of metabotropic receptors presents new opportunities for therapeutic development. The article highlights the need for further research to understand the specific roles of these molecular targets in promoting myelin repair and addressing demyelinating pathologies. Additionally, the editorial mentions advancements in imaging techniques and the exploration of miRNAs in regulating oligodendrocyte differentiation as promising areas for future research in CNS repair. [Extracted from the article]

Published

2024

31. Conservation of Ligand Binding Between Voltage-Gated Sodium and T-Type Calcium Channels

Author

Finol-Urdaneta, Rocio K., McArthur, Jeffrey R., Adams, David J., Stephens, Gary, editor, and Stevens, Edward, editor

Published

2024

32. Ion Channels as Targets in Drug Discovery: Outlook and Perspectives

Author

Stevens, Edward B., Stephens, Gary J., Stephens, Gary, editor, and Stevens, Edward, editor

Published

2024

33. Eavesdropping on Ion Channels Using the Patch Clamp Technique: Cells send electrical impulses throughout the body, but electrophysiologists struggled to tune into these signals until the patch clamp technique was developed.

Author

TRAN, LAURA

Subjects

VOLTAGE-gated ion channels, MOLECULAR biology, MEMBRANE potential, ACTION potentials, BIOLOGICAL membranes, ION channels, POTASSIUM channels

Abstract

The article provides an overview of the patch clamp technique, a method used to study ion channels in cells. It explains how the technique was developed and refined by researchers such as Kenneth Cole, Erwin Neher, and Bert Sakmann. The authors discuss the different patch configurations that have been developed and highlight the ongoing relevance of the technique in studying ion channels and its integration with other technologies. The patch clamp technique has greatly advanced our understanding of cellular electrophysiology and its role in diseases. [Extracted from the article]

Published

2024

34. Exploring oak processionary caterpillar induced lepidopterism (part 2): ex vivo bio-assays unmask the role of TRPV1.

Author

Seldeslachts, Andrea, Undheim, Eivind Andreas Baste, Vriens, Joris, Tytgat, Jan, and Peigneur, Steve

Subjects

*LIGAND-gated ion channels, *TRPV cation channels, *PEPTIDES, *VENOM, *VOLTAGE-gated ion channels, *EXANTHEMA, *OAK, *HOT peppers

Abstract

As human skin comes into contact with the tiny hairs or setae of the oak processionary caterpillar, Thaumetopoea processionea, a silent yet intense chemical confrontation occurs. The result is a mix of issues: skin rashes and an intense itching that typically lasts days and weeks after the contact. This discomfort poses a significant health threat not only to humans but also to animals. In Western Europe, the alarming increase in outbreaks extends beyond areas near infested trees due to the dispersion of the setae. Predictions indicate a sustained rise in outbreaks, fueled by global changes favoring the caterpillar's survival and distribution. Currently, the absence of an efficient treatment persists due to significant gaps in our comprehension of the pathophysiology associated with this envenomation. Here, we explored the interaction between the venom extract derived from the setae of T. processionea and voltage- and ligand-gated ion channels and receptors. By conducting electrophysiological analyses, we discovered ex vivo evidence highlighting the significant role of TPTX1-Tp1, a peptide toxin from T. processionea, in modulating TRPV1. TPTX1-Tp1 is a secapin-like peptide and demonstrates a unique ability to modulate TRPV1 channels in the presence of capsaicin, leading to cell depolarization, itch and inflammatory responses. This discovery opens new avenues for developing a topical medication, suggesting the incorporation of a TRPV1 blocker as a potential solution for the local effects caused by T. processionea. [ABSTRACT FROM AUTHOR]

Published

2024

35. Opposite effects of acute and chronic IGF1 on rat dorsal root ganglion neuron excitability.

Author

Pastor, Jennyfer and Attali, Bernard

Subjects

VOLTAGE-gated ion channels, DORSAL root ganglia, NEURAL transmission, PERIPHERAL nervous system, CENTRAL nervous system, PEPTIDE hormones, SENSORY neurons, NEURONS

Abstract

Insulin-like growth factor-1 (IGF-1) is a polypeptide hormone with a ubiquitous distribution in numerous tissues and with various functions in both neuronal and non-neuronal cells. IGF-1 provides trophic support for many neurons of both the central and peripheral nervous systems. In the central nervous system (CNS), IGF-1R signaling regulates brain development, increases neuronal firing and modulates synaptic transmission. IGF-1 and IGF-IR are not only expressed in CNS neurons but also in sensory dorsal root ganglion (DRG) nociceptive neurons that convey pain signals. DRG nociceptive neurons express a variety of receptors and ion channels that are essential players of neuronal excitability, notably the ligand-gated cation channel TRPV1 and the voltage-gated M-type K+ channel, which, respectively, triggers and dampens sensory neuron excitability. Although many lines of evidence suggest that IGF-IR signaling contributes to pain sensitivity, its possible modulation of TRPV1 and M-type K+ channel remains largely unexplored. In this study, we examined the impact of IGF-1R signaling on DRG neuron excitability and its modulation of TRPV1 and M-type K+ channel activities in cultured rat DRG neurons. Acute application of IGF-1 to DRG neurons triggered hyper-excitability by inducing spontaneous firing or by increasing the frequency of spikes evoked by depolarizing current injection. These effects were prevented by the IGF-1R antagonist NVP-AEW541 and by the PI3Kinase blocker wortmannin. Surprisingly, acute exposure to IGF-1 profoundly inhibited both the TRPV1 current and the spike burst evoked by capsaicin. The Src kinase inhibitor PP2 potently depressed the capsaicin-evoked spike burst but did not alter the IGF-1 inhibition of the hyperexcitability triggered by capsaicin. Chronic IGF-1 treatment (24 h) reduced the spike firing evoked by depolarizing current injection and upregulated the M-current density. In contrast, chronic IGF-1 markedly increased the spike burst evoked by capsaicin. In all, our data suggest that IGF-1 exerts complex effects on DRG neuron excitability as revealed by its dual and opposite actions upon acute and chronic exposures. [ABSTRACT FROM AUTHOR]

Published

2024

36. Direct modulation of G protein-gated inwardly rectifying potassium (GIRK) channels.

Author

Ha Nguyen, Glaaser, Ian W., and Slesinger, Paul A.

Subjects

CELLULAR signal transduction, SMALL molecules, POTASSIUM, ION channels, VOLTAGE-gated ion channels, PHOSPHOINOSITIDES, POTASSIUM channels

Abstract

Ion channels play a pivotal role in regulating cellular excitability and signal transduction processes. Among the various ion channels, G-protein-coupled inwardly rectifying potassium (GIRK) channels serve as key mediators of neurotransmission and cellular responses to extracellular signals. GIRK channels are members of the larger family of inwardly-rectifying potassium (Kir) channels. Typically, GIRK channels are activated via the direct binding of G-protein βγ subunits upon the activation of G-protein-coupled receptors (GPCRs). GIRK channel activation requires the presence of the lipid signaling molecule, phosphatidylinositol 4,5-bisphosphate (PIP2). GIRK channels are also modulated by endogenous proteins and other molecules, including RGS proteins, cholesterol, and SNX27 as well as exogenous compounds, such as alcohol. In the last decade or so, several groups have developed novel drugs and small molecules, such as ML297, GAT1508 and GiGA1, that activate GIRK channels in a G-protein independent manner. Here, we aim to provide a comprehensive overview focusing on the direct modulation of GIRK channels by G-proteins, PIP2, cholesterol, and novel modulatory compounds. These studies offer valuable insights into the underlying molecular mechanisms of channel function, and have potential implications for both basic research and therapeutic development. [ABSTRACT FROM AUTHOR]

Published

2024

37. Structural basis for hyperpolarization-dependent opening of human HCN1 channel.

Author

Burtscher, Verena, Mount, Jonathan, Huang, Jian, Cowgill, John, Chang, Yongchang, Bickel, Kathleen, Chen, Jianhan, Yuan, Peng, and Chanda, Baron

Subjects

ION channels, VOLTAGE-gated ion channels, CHARGE transfer, ACTION potentials, ELECTRIC circuits, GATES, HUMAN body

Abstract

Hyperpolarization and cyclic nucleotide (HCN) activated ion channels are critical for the automaticity of action potentials in pacemaking and rhythmic electrical circuits in the human body. Unlike most voltage-gated ion channels, the HCN and related plant ion channels activate upon membrane hyperpolarization. Although functional studies have identified residues in the interface between the voltage-sensing and pore domain as crucial for inverted electromechanical coupling, the structural mechanisms for this unusual voltage-dependence remain unclear. Here, we present cryo-electron microscopy structures of human HCN1 corresponding to Closed, Open, and a putative Intermediate state. Our structures reveal that the downward motion of the gating charges past the charge transfer center is accompanied by concomitant unwinding of the inner end of the S4 and S5 helices, disrupting the tight gating interface observed in the Closed state structure. This helix-coil transition at the intracellular gating interface accompanies a concerted iris-like dilation of the pore helices and underlies the reversed voltage dependence of HCN channels. HCN ion channels activate upon hyperpolarization, in contrast to other members of the voltage-gated ion channel superfamily. Here, authors reveal the structural basis of inverted voltage-dependence by solving the structures of this channel in Closed, Open and Intermediate conformations. [ABSTRACT FROM AUTHOR]

Published

2024

38. Etiological involvement of KCND1 variants in an X-linked neurodevelopmental disorder with variable expressivity.

Author

Kalm, Tassja, Schob, Claudia, Völler, Hanna, Gardeitchik, Thatjana, Gilissen, Christian, Pfundt, Rolph, Klöckner, Chiara, Platzer, Konrad, Klabunde-Cherwon, Annick, Ries, Markus, Syrbe, Steffen, Beccaria, Francesca, Madia, Francesca, Scala, Marcello, Zara, Federico, Hofstede, Floris, Simon, Marleen E.H., van Jaarsveld, Richard H., Oegema, Renske, and van Gassen, Koen L.I.

Subjects

*POTASSIUM channels, *VOLTAGE-gated ion channels, *NEURAL development, *SELF-expression, *MISSENSE mutation, *ION channels, *LEAD

Abstract

Utilizing trio whole-exome sequencing and a gene matching approach, we identified a cohort of 18 male individuals from 17 families with hemizygous variants in KCND1 , including two de novo missense variants, three maternally inherited protein-truncating variants, and 12 maternally inherited missense variants. Affected subjects present with a neurodevelopmental disorder characterized by diverse neurological abnormalities, mostly delays in different developmental domains, but also distinct neuropsychiatric signs and epilepsy. Heterozygous carrier mothers are clinically unaffected. KCND1 encodes the α-subunit of Kv4.1 voltage-gated potassium channels. All variant-associated amino acid substitutions affect either the cytoplasmic N- or C-terminus of the channel protein except for two occurring in transmembrane segments 1 and 4. Kv4.1 channels were functionally characterized in the absence and presence of auxiliary β subunits. Variant-specific alterations of biophysical channel properties were diverse and varied in magnitude. Genetic data analysis in combination with our functional assessment shows that Kv4.1 channel dysfunction is involved in the pathogenesis of an X-linked neurodevelopmental disorder frequently associated with a variable neuropsychiatric clinical phenotype. Hemizygous variants of KCND1 lead to alterations in the biophysical properties of the encoded ion channel, implicating dysfunction of Kv4.1 voltage-gated potassium channels in the etiology of an X-linked neurodevelopmental disorder with variable expressivity. [ABSTRACT FROM AUTHOR]

Published

2024

39. Voltage-gated ion channels as novel regulators of epithelial ion transport in the osmoregulatory organs of insects.

Author

Dates, Jocelyne and Kolosov, Dennis

Subjects

*VOLTAGE-gated ion channels, *ION transport (Biology), *MEMBRANE potential, *INSECTS, *SIGNAL detection

Abstract

Voltage-gated ion channels (VGICs) respond to changes in membrane potential (Vm) and typically exhibit fast kinetic properties. They play an important role in signal detection and propagation in excitable tissues. In contrast, the role of VGICs in non-excitable tissues like epithelia is less studied and less clear. Studies in epithelia of vertebrates and invertebrates demonstrate wide expression of VGICs in epithelia of animals. Recently, VGICs have emerged as regulators of ion transport in the Malpighian tubules (MTs) and other osmoregulatory organs of insects. This mini-review aims to concisely summarize which VGICs have been implicated in the regulation of ion transport in the osmoregulatory epithelia of insects to date, and highlight select groups for further study. We have also speculated on the roles VGICs may potentially play in regulating processes connected directly to ion transport in insects (e.g., acid-base balance, desiccation, thermal tolerance). This review is not meant to be exhaustive but should rather serve as a thought-provoking collection of select existing highlights on VGICs, and to emphasize how understudied this mechanism of ion transport regulation is in insect epithelia. [ABSTRACT FROM AUTHOR]

Published

2024

40. A synthetic flavonoid derivate in the plasma membrane transforms the voltage‐clamp fluorometry signal of CiHv1.

Author

Pethő, Zoltán, Pajtás, Dávid, Piga, Martina, Magyar, Zsuzsanna, Zakany, Florina, Kovacs, Tamas, Zidar, Nace, Panyi, Gyorgy, Varga, Zoltan, and Papp, Ferenc

Subjects

*FLAVONOIDS, *CELL membranes, *FLUORIMETRY, *ION channels, *CIONA intestinalis, *VOLTAGE-gated ion channels, *FLUORESCENT proteins

Abstract

Voltage‐clamp fluorometry (VCF) enables the study of voltage‐sensitive proteins through fluorescent labeling accompanied by ionic current measurements for voltage‐gated ion channels. The heterogeneity of the fluorescent signal represents a significant challenge in VCF. The VCF signal depends on where the cysteine mutation is incorporated, making it difficult to compare data among different mutations and different studies and standardize their interpretation. We have recently shown that the VCF signal originates from quenching amino acids in the vicinity of the attached fluorophores, together with the effect of the lipid microenvironment. Based on these, we performed experiments to test the hypothesis that the VCF signal could be altered by amphiphilic quenching molecules in the cell membrane. Here we show that a phenylalanine‐conjugated flavonoid (4‐oxo‐2‐phenyl‐4H‐chromene‐7‐yl)‐phenylalanine, (later Oxophench) has potent effects on the VCF signals of the Ciona intestinalis HV1 (CiHv1) proton channel. Using spectrofluorimetry, we showed that Oxophench quenches TAMRA (5(6)‐carboxytetramethylrhodamine‐(methane thiosulfonate)) fluorescence. Moreover, Oxophench reduces the baseline fluorescence in oocytes and incorporates into the cell membrane while reducing the membrane fluidity of HEK293 cells. Our model calculations confirmed that Oxophench, a potent membrane‐bound quencher, modifies the VCF signal during conformational changes. These results support our previously published model of VCF signal generation and point out that a change in the VCF signal may not necessarily indicate an altered conformational transition of the investigated protein. [ABSTRACT FROM AUTHOR]

Published

2024

41. Modeling Excitable Cells with Memristors.

Author

Sah, Maheshwar, Ascoli, Alon, Tetzlaff, Ronald, Rajamani, Vetriveeran, and Budhathoki, Ram Kaji

Subjects

MEMRISTORS, POTASSIUM channels, VOLTAGE-gated ion channels, ION channels, BIOLOGICAL membranes, BIOLOGICAL systems, POTASSIUM ions

Abstract

This paper presents an in-depth analysis of an excitable membrane of a biological system by proposing a novel approach that the cells of the excitable membrane can be modeled as the networks of memristors. We provide compelling evidence from the Chay neuron model that the state-independent mixed ion channel is a nonlinear resistor, while the state-dependent voltage-sensitive potassium ion channel and calcium-sensitive potassium ion channel function as generic memristors from the perspective of electrical circuit theory. The mechanisms that give rise to periodic oscillation, aperiodic (chaotic) oscillation, spikes, and bursting in an excitable cell are also analyzed via a small-signal model, a pole-zero diagram of admittance functions, local activity, the edge of chaos, and the Hopf bifurcation theorem. It is also proved that the zeros of the admittance functions are equivalent to the eigen values of the Jacobian matrix, and the presence of the positive real parts of the eigen values between the two bifurcation points lead to the generation of complicated electrical signals in an excitable membrane. The innovative concepts outlined in this paper pave the way for a deeper understanding of the dynamic behavior of excitable cells, offering potent tools for simulating and exploring the fundamental characteristics of biological neurons. [ABSTRACT FROM AUTHOR]

Published

2024

42. Investigation of Emergence and Underlying Mechanisms of Multidrug Resistance in Klebsiella pneumoniae Induced by S-amlodipine Stress.

Author

Liu Xinxin, Fang Hui, Xia Dasheng, Luo Yi, and Mao Daqing

Subjects

MULTIDRUG resistance, KLEBSIELLA pneumoniae, REGULATOR genes, POLYMYXIN B, BACTERIAL cell surfaces, BACTERIAL cell membranes, VOLTAGE-gated ion channels

Abstract

S-amlodipine (S-AM) is a commonly prescribed antihypertensive drug for patients with hypertension, and it is used for an extended duration in most hypertensive patients. However, it remains unclear whether long-term exposure to non-antibiotic drug S-amlodipine induces bacterial antibiotic resistance. To investigate the potential impact of S-AM on bacterial antibiotic resistance, we conducted a 60-day in vitro evolution experiment in which intestinal pathogen K. pneumoniae was exposed to 2 mg⋅L-1 S-AM. We determined the resistance of the evolved strains to six antibiotics through antibiotic susceptibility testing. Furthermore, we delved into the potential resistance mechanisms of K. pneumoniae via genome sequencing, fluorescence quantitative PCR, and bioinformatics analysis. This study observed that the mutation frequency of K. pneumoniae increased from 10-7 to 1.5 x 10-1 under S-AM stress, and the intracellular reactive oxygen species (ROS) levels of the evolved strains significantly increased compared to that of the control strains. Additionally, the evolved strains exhibited heightened resistance to polymyxin, kanamycin, chloramphenicol, erythromycin, and moxifloxacin. Whole genome sequencing analysis results showed the presence of three non-synonymous single nucleotide polymorphism (SNP) mutation sites, one synonymous SNP mutation site, two intergenic SNPs, and one intergenic insertion site in the evolved strains. These non-synonymous gene mutations include the HAMP domain-containing histidine kinase crrB gene, sensor domain-containing diguanylate cyclase, and type 3 fimbria adhesin subunit mrkD gene. Notably, the mutated crrB gene, in collaboration with the crrA gene, enhanced the modification of the lipid A component of the cell membrane lipopoly-saccharide (LPS) in the evolved strains. This modification increased the positive charge on the bacterial cell membrane surface, hindering polymyxin-cell interactions and contributing to increased polymyxin resistance in K. pneumoniae. Fluorescence quantitative PCR results revealed that exposure to S-AM enhanced the mRNA expressions of two-component regulatory system genes (e.g., crrAB, phoPQ, pmrAB, and pmrDFIK), multidrug efflux pump genes (e.g., emrD and oqxAB), and the intrinsic resistance gene aadA2, which might be responsible for increased bacterial resistance to multiple antibiotics. In summary, this study is the first to demonstrate that S-AM stress triggers multiple antibiotic resistance in K. pneumoniae and elucidates the underlying molecular mechanisms, serving as an early warning for potential health risks associated with long-term medication in hypertensive patients. It lays a foundation for further exploration of antibiotic resistance in diverse intestinal bacteria under prolonged S-AM stress. [ABSTRACT FROM AUTHOR]

Published

2024

43. Therapeutic role of voltage-gated potassium channels in age-related neurodegenerative diseases.

Author

Urrutia, Janire, Arrizabalaga-Iriondo, Ane, Sanchez-del-Rey, Ana, Martinez-Ibargüen, Agustín, Gallego, Mónica, Casis, Oscar, and Revuelta, Miren

Subjects

HUNTINGTON disease, POTASSIUM channels, ION channels, NEURODEGENERATION, VOLTAGE-gated ion channels, MEMBRANE potential, SPINOCEREBELLAR ataxia, PARKINSON'S disease

Abstract

Voltage-gated ion channels are essential for membrane potential maintenance, homeostasis, electrical signal production and controlling the Ca2+ flow through the membrane. Among all ion channels, the key regulators of neuronal excitability are the voltage-gated potassium channels (KV), the largest family of K+ channels. Due to the ROS high levels in the aging brain, K+ channels might be affected by oxidative agents and be key in aging and neurodegeneration processes. This review provides new insight about channelopathies in the most studied neurodegenerative disorders, such as Alzheimer Disease, Parkinson's Disease, Huntington Disease or Spinocerebellar Ataxia. The main affected KV channels in these neurodegenerative diseases are the KV1, KV2.1, KV3, KV4 and KV7. Moreover, in order to prevent or repair the development of these neurodegenerative diseases, previous KV channel modulators have been proposed as therapeutic targets. [ABSTRACT FROM AUTHOR]

Published

2024

44. Celastrol Ameliorates Neuronal Mitochondrial Dysfunction Induced by Intracerebral Hemorrhage via Targeting cAMP‐Activated Exchange Protein‐1.

Author

Li, Xiang, Liu, Wen, Jiang, Guannan, Lian, Jinrong, Zhong, Yi, Zhou, Jialei, Li, Haiying, Xu, Xingshun, Liu, Yaobo, Cao, Cong, Tao, Jin, Cheng, Jian, Zhang, John H, and Chen, Gang

Subjects

*CEREBRAL hemorrhage, *CYCLIC adenylic acid, *MITOCHONDRIA, *POTASSIUM channels, *VOLTAGE-gated ion channels, *NEURAL development, *BRAIN injuries

Abstract

Mitochondrial dysfunction contributes to the development of secondary brain injury (SBI) following intracerebral hemorrhage (ICH) and represents a promising therapeutic target. Celastrol, the primary active component of Tripterygium wilfordii, is a natural product that exhibits mitochondrial and neuronal protection in various cell types. This study aims to investigate the neuroprotective effects of celastrol against ICH‐induced SBI and explore its underlying mechanisms. Celastrol improves neurobehavioral and cognitive abilities in mice with autologous blood‐induced ICH, reduces neuronal death in vivo and in vitro, and promotes mitochondrial function recovery in neurons. Single‐cell nuclear sequencing reveals that the cyclic adenosine monophosphate (cAMP)/cAMP‐activated exchange protein‐1 (EPAC‐1) signaling pathways are impacted by celastrol. Celastrol binds to cNMP (a domain of EPAC‐1) to inhibit its interaction with voltage‐dependent anion‐selective channel protein 1 (VDAC1) and blocks the opening of mitochondrial permeability transition pores. After neuron‐specific knockout of EPAC1, the neuroprotective effects of celastrol are diminished. In summary, this study demonstrates that celastrol, through its interaction with EPAC‐1, ameliorates mitochondrial dysfunction in neurons, thus potentially improving SBI induced by ICH. These findings suggest that targeting EPAC‐1 with celastrol can be a promising therapeutic approach for treating ICH‐induced SBI. [ABSTRACT FROM AUTHOR]

Published

2024

45. Stimulation of Biological Structures on the Nanoscale Using Interfaces with Large Built-In Spontaneous Polarizations.

Author

Zia, Nida, Stroscio, Michael, and Dutta, Mitra

Subjects

*VOLTAGE-gated ion channels, *ION channels, *MORPHOLOGY, *ELECTRIC potential, *BIOLOGICAL systems, *ELECTRIC stimulation, *QUANTUM dots, *MODULATION-doped field-effect transistors

Abstract

The electric potential stimulation of biological structures in aqueous environments is well-known to be a result of the gating of voltage-gated ion channels. Such voltage-gated ion channels are ubiquitous in the membranes of a wide variety of cells and they play central roles in a wide variety of sensing mechanisms and neuronal functions in biological systems. Experimental studies of ion-channel gating are frequently conducted using path-clamp techniques by placing a cumbersome external electrode in the vicinity of the extracellular side of the ion channel. Recently, it has been demonstrated that laser-induced polarization of nanoscale quantum dots can produce voltage sufficient to gate voltage-gated ion channels. This study specifically focuses on a new method of gating voltage-gated ion channels using 2D structures made of materials exhibiting large naturally occurring spontaneous polarizations, thereby eliminating the need for an external electrode or an illuminating laser. The work presents the use of self-polarizing semiconductor flakes, namely, 2H-SiC, ZnO, and GaN, to produce electric potential that is sufficient to gate voltage-gated ion channels when existing in proximity to it. [ABSTRACT FROM AUTHOR]

Published

2024

46. The road to evolution of ProTx2: how to be a subtype-specific inhibition of human Nav1.7.

Author

Fan Zhao, Yuanyuan Liu, Yiyu Liu, Qi Ye, Hongtao Yang, Mingze Gui, and Yongbo Song

Subjects

SODIUM channels, CONOTOXINS, AMINO acid residues, ANALGESICS, VOLTAGE-gated ion channels, PEPTIDES, ELECTROSTATIC interaction

Abstract

The human voltage-gated sodium channel Nav1.7 is a widely proven target for analgesic drug studies. ProTx2, a 30-residue polypeptide from Peruvian green tarantula venom, shows high specificity to activity against human Nav1.7, suggesting its potential to become a non-addictive analgesic. However, its high sensitivity to human Nav1.4 raises concerns about muscle side effects. Here, we engineered three mutants (R13A, R13D, and K27Y) of ProTx2 to evaluate their pharmacological activities toward Nav1.7 and Nav1.4. It is demonstrated that the mutant R13D maintained the analgesic effect in mice while dramatically reducing its muscle toxicity compared with ProTx2. The main reason is the formation of a strong electrostatic interaction between R13D and the negatively charged amino acid residues in DII/S3-S4 of Nav1.7, which is absent in Nav1.4. This study advances our understanding and insights on peptide toxins, paving the way for safer, effective non-addictive analgesic development. [ABSTRACT FROM AUTHOR]

Published

2024

47. Understanding the role of boron in plant adaptation to soil salinity.

Author

Qu, Mei, Huang, Xin, García‐Caparrós, Pedro, Shabala, Lana, Fuglsang, Anja Thoe, Yu, Min, and Shabala, Sergey

Subjects

*SOIL salinity, *PLANT adaptation, *VOLTAGE-gated ion channels, *PLANT-soil relationships, *BORON

Abstract

Soil salinity is a major environmental constraint affecting the sustainability and profitability of agricultural production systems. Salinity stress tolerance has been present in wild crop relatives but then lost, or significantly weakened, during their domestication. Given the genetic and physiological complexity of salinity tolerance traits, agronomical solutions may be a suitable alternative to crop breeding for improved salinity stress tolerance. One of them is optimizing fertilization practices to assist plants in dealing with elevated salt levels in the soil. In this review, we analyse the causal relationship between the availability of boron (an essential metalloid micronutrient) and plant's adaptive responses to salinity stress at the whole‐plant, cellular, and molecular levels, and a possibility of using boron for salt stress mitigation. The topics covered include the impact of salinity and the role of boron in cell wall remodelling, plasma membrane integrity, hormonal signalling, and operation of various membrane transporters mediating plant ionic and water homeostasis. Of specific interest is the role of boron in the regulation of H+‐ATPase activity whose operation is essential for the control of a broad range of voltage‐gated ion channels. The complex relationship between boron availability and expression patterns and the operation of aquaporins is also discussed. [ABSTRACT FROM AUTHOR]

Published

2024

48. Genetic or Pharmacological Ablation of Acid-Sensing Ion Channel 1a (ASIC1a) Is Not Neuroprotective in a Mouse Model of Spinal Cord Injury.

Author

Foster, Victoria S., Saez, Natalie J., Gillespie, Ellen R., Jogia, Trisha, Reid, Chantelle, Maljevic, Snezana, Jung, Woncheol, Lao, Hong W., Ruitenberg, Marc J., and King, Glenn F.

Subjects

*ACID-sensing ion channels, *SPINAL cord injuries, *CELL death, *LABORATORY mice, *ION channels, *ANIMAL disease models, *VOLTAGE-gated ion channels

Abstract

Acid-sensing ion channel 1a (ASIC1a) is a proton-activated channel that is expressed ubiquitously throughout the central nervous system and in various types of immune cells. Its role in spinal cord injury (SCI) is controversial; inhibition of ASIC1a has been reported to improve SCI pathology in vivo, but conversely, gene ablation increased kainite-mediated excitotoxic cell death in vitro. Here, we re-examined the role of ASIC1a in a mouse model of SCI. First, we observed functional outcomes up to 42 days post-operation (DPO) in SCI mice with a selective genetic ablation of ASIC1a. Mice lacking ASIC1a had significantly worsened locomotor ability and increased lesion size compared with mice possessing the ASIC1a gene. Next, we explored pharmacological antagonism of this ion channel by administering the potent ASIC1a inhibitor, Hi1a. Consistent with a role for ASIC1a to attenuate excitotoxicity, accelerated neuronal cell loss was found at the lesion site in SCI mice treated with Hi1a, but there were no differences in locomotor recovery. Moreover, ASIC1a inhibition did not cause significant alterations to neutrophil migration, microglial density, or blood–spinal cord barrier integrity. [ABSTRACT FROM AUTHOR]

Published

2024

49. Spreading depolarizations pose critical energy challenges in acute brain injury.

Author

Lindquist, Britta E.

Subjects

*THRESHOLD energy, *BRAIN injuries, *VOLTAGE-gated ion channels, *ION bombardment, *LACTIC acid, *STROKE

Abstract

Spreading depolarization (SD) is an electrochemical wave of neuronal depolarization mediated by extracellular K+ and glutamate, interacting with voltage-gated and ligandgated ion channels. SD is increasingly recognized as a major cause of injury progression in stroke and brain trauma, where the mechanisms of SD-induced neuronal injury are intimately linked to energetic status and metabolic impairment. Here, I review the established working model of SD initiation and propagation. Then, I summarize the historical and recent evidence for the metabolic impact of SD, transitioning from a descriptive to a mechanistic working model of metabolic signaling and its potential to promote neuronal survival and resilience. I quantify the energetic cost of restoring ionic gradients eroded during SD, and the extent to which ion pumping impacts high-energy phosphate pools and the energy charge of affected tissue. I link energy deficits to adaptive increases in the utilization of glucose and O2, and the resulting accumulation of lactic acid and CO2 downstream of catabolic metabolic activity. Finally, I discuss the neuromodulatory and vasoactive paracrine signaling mediated by adenosine and acidosis, highlighting these metabolites' potential to protect vulnerable tissue in the context of high-frequency SD clusters. [ABSTRACT FROM AUTHOR]

Published

2024

50. Phytochemical Modulation of Ion Channels in Oncologic Symptomatology and Treatment.

Author

Rao, Rohan, Mohammed, Caroline, Alschuler, Lise, Pomeranz Krummel, Daniel A., and Sengupta, Soma

Subjects

*CANNABIDIOL, *PHYTOCHEMICALS, *ANXIETY, *PANCYTOPENIA, *CANCER pain, *RESVERATROL, *QUALITY of life, *MOLECULAR structure, *ANOREXIA nervosa, *TUMORS, *CANCER fatigue, *VOMITING, *ION channels, *NAUSEA, *SYMPTOMS

Abstract

Simple Summary: Cancer is a leading cause of death worldwide. The costs involved in cancer diagnosis and treatment are extraordinary. Important steps that can be taken that would reduce costs include earlier cancer diagnosis for which significant headway is being made through biomarker identification in bodily fluids and imaging. Other important steps will be to identify treatment approaches that do not 'break the bank' and affect a patient's wellbeing. Herein, we aim to highlight the potential of phytochemicals as a cost-effective approach to aid in the treatment of cancer. We focus on phytochemicals that target ion channels, as molecules that mediate critical communication of a cell with its environment. Ultimately, we posit that phytochemicals targeting ion channels can be employed to aid cancer treatment. Modern chemotherapies offer a broad approach to cancer treatment but eliminate both cancer and non-cancer cells indiscriminately and, thus, are associated with a host of side effects. Advances in precision oncology have brought about new targeted therapeutics, albeit mostly limited to a subset of patients with an actionable mutation. They too come with side effects and, ultimately, 'self-resistance' to the treatment. There is recent interest in the modulation of ion channels, transmembrane proteins that regulate the flow of electrically charged molecules in and out of cells, as an approach to aid treatment of cancer. Phytochemicals have been shown to act on ion channels with high specificity regardless of the tumor's genetic profile. This paper explores the use of phytochemicals in cancer symptom management and treatment. [ABSTRACT FROM AUTHOR]

Published

2024