Search Results (176)

Olive oil, a cornerstone of the Mediterranean diet, contains a saponifiable lipid fraction rich in oleic acid, and a non-saponifiable fraction composed of minor bioactive constituents such as squalene, vitamin E, oleuropein aglycone, hydroxytyrosol, oleocanthal, and oleacein, among other phenolic and triterpenic compounds. These components are well-documented for their cardiovascular, anti-inflammatory, antioxidant, and neuroprotective activities. This review explores the physiological relevance of olive oil lipids and their derivatives on cellular membranes and ion transport systems, by combining biochemical and electrophysiological insights. We discuss how oleic acid and its metabolites influence membrane lipid composition, modulate fluidity, and reorganize lipid rafts—key elements for the proper localization and function of ion channels. Additionally, we examine evidence showing that several olive oil components regulate ion channels such as TRP, potassium, calcium, and chloride channels, as well as other transporters, thereby influencing ionic homeostasis, oxidative balance, and signal transduction in excitable and non-excitable cells. By combining these findings, we propose a conceptual framework in which olive oil lipids and their derivatives act as multimodal regulators of bioelectrical signaling. By modulating cell membrane dynamics, these functional molecules help maintain cellular communication and homeostasis. This integrative view not only strengthens our understanding of olive oil’s health-promoting effects but also opens new avenues for targeting ion-regulatory mechanisms in metabolic, cardiovascular, and neurological diseases. Full article

Large-conductance, voltage- and calcium-activated potassium (BK) channels are crucial regulators of cellular excitability, influenced by various signaling molecules, including heme. The BK channel contains a heme-sensitive motif located at the sequence ⁶¹²CKACH⁶¹⁶, which is a conserved heme regulatory motif (HRM) found in the cytochrome c protein family. This motif is situated within a linker region of approximately 120 residues that connect the RCK1 and RCK2 domains, and it also includes terminal α-helices similar to those found in cytochrome c family proteins. However, much of this region has yet to be structurally defined. We conducted a sequence alignment of the BK linker region with mitochondrial cytochrome c and cytochrome c domains from various hemoproteins to better understand this functionally significant region. In addition to the HRM motif, we discovered that important structural and functional elements of cytochrome c proteins are conserved in the BK RCK1-RCK2 linker. Firstly, the part of the BK region that is resolved in available atomic structures shows similarities in secondary structural elements with cytochrome c domain proteins. Secondly, the Met80 residue in cytochrome c domains, which acts as the second axial ligand to the heme iron, aligns with the BK channel. Beyond its role in electron shuttling, cytochrome c domains exhibit various catalytic properties, including peroxidase activity—specifically, the oxidation of suitable substrates using peroxides. Our findings reveal that the linker region endows human BK channels with peroxidase activity, showing an apparent H₂O₂ affinity approximately 40-fold greater than that of mitochondrial cytochrome c under baseline conditions. This peroxidase activity was reduced when substitutions were made at ⁶¹²CKACH⁶¹⁶ and other relevant sites. These results indicate that the BK channel possesses a novel module similar to the cytochrome c domains of hemoproteins, which may give rise to unique physiological functions for these widespread ion channels. Full article

Redox regulation is crucial for the cardiac action potential, coordinating the sodium-driven depolarization, calcium-mediated plateau formation, and potassium-dependent repolarization processes required for proper heart function. Under physiological conditions, low-level reactive oxygen species (ROS), generated by mitochondria and membrane oxidases, adjust ion channel function and support excitation–contraction coupling. However, when ROS accumulate, they modify a variety of important channel proteins in cardiomyocytes, which commonly results in reducing potassium currents, enhancing sodium and calcium influx, and enhancing intracellular calcium release. These redox-driven alterations disrupt the cardiac rhythm, promote after-depolarizations, impair contractile force, and accelerate the development of heart diseases. Experimental models demonstrate that oxidizing agents reduce repolarizing currents, whereas reducing systems restore normal channel activity. Similarly, oxidative modifications of calcium-handling proteins amplify sarcoplasmic reticulum release and diastolic calcium leak. Understanding the precise redox-dependent modifications of cardiac ion channels would guide new possibilities for targeted therapies aimed at restoring electrophysiological homeostasis under oxidative stress, potentially alleviating myocardial infarction and cardiovascular dysfunction. Full article

Fibrosis represents a pivotal pathological process in numerous diseases, characterized by excessive deposition of extracellular matrix (ECM) that disrupts normal tissue architecture and function. In the heart, cardiac fibrosis significantly impairs both structural integrity and functional capacity, contributing to the progression of heart failure. Central to this process are cardiac fibroblasts (CFs), which, upon activation, differentiate into contractile myofibroblasts, driving pathological ECM accumulation. Transforming growth factor-beta (TGFβ) is a well-established regulator of fibroblast activation; however, the precise molecular mechanisms, particularly the involvement of ion channels, remain poorly understood. Emerging evidence highlights the regulatory role of ion channels, including calcium-activated potassium (K_Ca) channels, in fibroblast activation. This study elucidates the role of ion channels and investigates the mechanism by which Yoda1, an agonist of the mechanosensitive ion channel Piezo1, modulates TGFβ-induced fibroblast activation. Using NIH/3T3 fibroblasts, we demonstrated that TGFβ-induced activation is regulated by tetraethylammonium (TEA)-sensitive potassium channels, but not by specific K⁺ channel subtypes such as BK, SK, or IK channels. Intriguingly, Yoda1 was found to inhibit TGFβ-induced fibroblast activation through a Piezo1-independent mechanism. Transcriptomic analysis revealed that Yoda1 modulates fibroblast activation by altering gene expression pathways associated with fibrotic processes. Bromodomain-containing protein 4 (BRD4) was identified as a critical mediator of Yoda1’s effects, as pharmacological inhibition of BRD4 with JQ1 or ZL0454 suppressed TGFβ-induced expression of the fibroblast activation marker Periostin (Postn). Conversely, BRD4 overexpression attenuated the inhibitory effects of Yoda1 in both mouse and rat CFs. These results provide novel insights into the pharmacological modulation of TGFβ-induced cardiac fibroblast activation and highlight promising therapeutic targets for the treatment of fibrosis-related cardiac pathologies. Full article

Neuropathic pain is a chronic and debilitating disorder of the somatosensory system that affects a significant proportion of the population and is characterized by abnormal responses such as hyperalgesia and allodynia. Voltage-gated ion channels, including sodium (Na_V), calcium (Ca_V), and potassium (K_V) channels, play a pivotal role in modulating neuronal excitability and pain signal transmission following nerve injury. This review intends to provide a comprehensive analysis of the molecular and cellular mechanisms by which dysregulation in the expression, localization, and function of specific Na_V channel subtypes (mainly Na_V1.7 and Na_V1.8) and their auxiliary subunits contributes to aberrant neuronal activation, the generation of ectopic discharges, and sensitization in neuropathic pain. Likewise, special emphasis is placed on the crucial role of Ca_V channels, particularly Ca_V2.2 and the auxiliary subunit Ca_Vα₂δ, whose overexpression increases calcium influx, neurotransmitter release, and neuronal hyperexcitability, thus maintaining persistent pain states. Furthermore, K_V channels (particularly K_V7 channels) function as brakes on neuronal excitability, and their dysregulation facilitates the development and maintenance of neuropathic pain. Therefore, targeting specific K_V channel subtypes to restore their function is also a promising therapeutic strategy for alleviating neuropathic pain symptoms. On the other hand, recent advances in the development of small molecules as selective modulators or inhibitors targeting voltage-gated ion channels are also discussed. These agents have improved efficacy and safety profiles in preclinical and clinical studies by attenuating pathophysiological channel activity and restoring neuronal function. This review seeks to contribute to guiding future research and drug development toward more effective mechanism-based treatments by discussing the molecular mechanisms underlying neuropathic pain and highlighting translational therapeutic opportunities. Full article

Ion channels are proteins that regulate the flow of ions across cell membranes, playing a vital role in cervical cancer development and progression. These channels serve as both potential diagnostic markers and therapeutic targets, offering new opportunities for cancer treatment. Moreover, ion channels are crucial molecular indicators and possible therapeutic targets due to their role in the development of cervical cancer. Our review focuses on the various types of ion channels which are associated with cervical cancer (CCa), including sodium, calcium, and potassium channels. In our review, we clarify their diagnostic and prognostic value, as well as their relationship to the prognosis and stage of the disease. We also examine how ion channels contribute to the metastasis of cervical cancer, specifically in relation to their influence on cell motility, invasion, and interaction with the tumor microenvironment. By examining preclinical and clinical research involving ion channel blockers and modulators, we also highlight the therapeutic potential of targeting ion channels. We have demonstrated the available assays and imaging methods based on ion channel activity as examples of emerging diagnostic breakthroughs that show promise for enhancing the early detection of cervical cancer. Additionally, the possibility that ion channel modulator-based combination therapy could improve the efficacy of traditional treatments is investigated. To demonstrate the potential of ion channels in cervical cancer diagnosis and treatment, our review highlights the current challenges and the promising role in cervical cancer diagnostics and therapy. Full article

Electrical stimulation of the skin has proven effective in pain management and antibacterial treatment, particularly in wound healing and counteracting the aging processes. The latter processes rely on epidermal cell migration, increased fibroblast proliferation, and upregulation of extracellular matrix protein expression. While an electrical field stimulates these processes, it is unclear how the electrical signal results in transcriptional control. Here, we postulate that the activation of voltage-gated channels, specifically voltage-gated potassium channels Kv1.3, is implicated in initiating the downstream signaling pathways that lead to increased collagen expression. We postulate that Kv1.3 and possibly calcium-activated potassium channel activity leads to the engagement of store-operated calcium channels and modulates the intracellular calcium ions distribution. In turn, changes in intracellular calcium concentration can activate calcium-generated transcriptional effectors. The Kv1.3 channel, identified via fluorescence imaging with ShK toxin (peptide), shows high-level expression in the human dermal fibroblast cell membrane. We also performed proliferation, collagen expression, and calcium imaging studies for variable electrical fields to help understand the link between the electrical stimulation, Kv1.3 channels, intracellular calcium concentration, and protein expression. Full article

Metabolic stress on the heart can cause dilation of coronary arterioles for blood flow recruitment. Although potassium ions (K⁺) released from the myocardium are a major mediator for this response, the underlying signaling pathways for vasodilation are incompletely understood. Herein, the roles of smooth muscle inward-rectifier K⁺ channel subtype 2.1 (K_ir2.1) and Na⁺/K⁺-ATPase were examined. Porcine coronary arterioles were isolated, cannulated, and pressurized for vasomotor study. Vessels developed basal tone and dilated concentration-dependently to extraluminal K⁺ from 7 to 20 mM. Higher K⁺ concentrations (25–40 mM) caused graded vasoconstriction. Vasodilation to K⁺ (10 mM) was not altered by endothelial removal, and blockade of ATP-sensitive K⁺ channels, voltage-sensitive K⁺ channels, or calcium-activated K⁺ channels did not affect K⁺-induced vasodilation. However, sustained but not abrupt transient vasodilation to K⁺ was reduced by the nonspecific K_ir channel inhibitor Ba²⁺ or K_ir2.1 channel blocker chloroethylclonidine. The Na⁺/K⁺-ATPase inhibitor ouabain attenuated K⁺-elicited vasodilation, and ouabain with Ba²⁺ abolished the response. Transfection of arterioles with K_ir2.1 antisense oligonucleotides abolished sustained but not transient dilation. It is concluded that extraluminal K⁺ elevation within the physiological range induces initial transient dilation of porcine coronary arterioles by activating smooth muscle Na⁺/K⁺-ATPase and sustained dilation via smooth muscle K_ir2.1 channels. Full article

Medulloblastoma (MB) groups 3 and 4 lack targeted therapies despite their dismal prognoses. Ion channels and pumps have been implicated in promoting MB metastasis and growth; however, their roles remain poorly understood. In this study, we repurposed FDA-approved channel blockers and modulators to investigate their potential anti-tumor effects in MB cell lines (DAOY and D283) and primary cell cultures derived from a patient with MB. For the first time, we report spontaneous calcium signaling in MB cells. Spontaneous calcium signals were significantly reduced by mibefradil (calcium channel blocker), paxilline (calcium-activated potassium channel blocker), and thioridazine (potassium channel blocker). These drugs induced dose-dependent cytotoxicity in both the DAOY and D283 cell lines, as well as in primary cell cultures of a patient with group 3 or 4 MB. In contrast, digoxin and ouabain, inhibitors of the Na/K pump, reduced the calcium signaling by over 90% in DAOY cells and induced approximately 90% cell death in DAOY cells and 80% cell death in D283 cells. However, these effects were significantly diminished in the cells derived from a patient with MB, highlighting the variability in drug sensitivity among MB models. These findings demonstrate that calcium signaling is critical for MB cell survival and that the targeted inhibition of calcium pathways suppresses tumor cell growth across multiple MB models. Full article

Scorpion venom peptides, particularly those derived from Asian species, have garnered significant attention, offering therapeutic potential in pain management, cancer, anticoagulation, and infectious diseases. This review provides a comprehensive analysis of scorpion venom peptides, focusing on their roles as voltage-gated sodium (Nav), potassium (Kv), and calcium (Cav) channel modulators. It analyzed Nav1.7 inhibition for analgesia, Kv1.3 blockade for anticancer activity, and membrane disruption for antimicrobial effects. While the low targeting specificity and high toxicity of some scorpion venom peptides pose challenges to their clinical application, recent research has made strides in overcoming these limitations. This review summarizes the latest progress in scorpion venom peptide research, discussing their mechanisms of action, therapeutic potential, and challenges in clinical translation. This work aims to provide new insights and directions for the development of novel therapeutic drugs. Full article

Chinese scorpion (CS), a traditional animal-based medicine used for over a millennium, has been documented since AD 935–960. It is derived from the scorpion Buthus martensii Karsch and is used to treat various ailments such as stroke, epilepsy, rheumatism, and more. Modern research has identified the pharmacological mechanisms behind its traditional uses, with active components like venom and proteins showing analgesic, antitumor, antiepileptic, and antithrombotic effects. Studies reveal that CS affects ion channels, crucial for cellular functions, through interactions with sodium, potassium, and calcium channels, potentially explaining its therapeutic effects. Future research aims to elucidate the precise mechanisms, target specific ion channel subtypes, and validate clinical efficacy and safety, paving the way for novel therapies based on these natural compounds. Full article

The healing process involves cell migration, which is sustained by an electrical potential difference that emerges between the edges of skin wounds and the center of the wound. The electrical potential in cells’ membranes is responsible for their migration in an electric field. The differences in the transmembrane electrochemical gradient generate this potential. The concomitant blockade of potassium and calcium channels by amiodarone at a medium dosage favored wound healing, but the effect was less intense than in the case of the selective blocking of potassium channels. According to this suggestion, blocking calcium channels might have a partial effect on blocking potassium channels. Given that nimodipine inhibits both L-type and T-type calcium channels, we aimed to investigate which of these calcium channels are involved in wound healing. Hence, we performed an experimental study in which nimodipine was used in three concentrations: 200 nM, which blocks only L-type calcium channels, 1000 nM, which blocks both L-type and T-type calcium channels, and 10,000 nM, which blocks calcium channels and activates CB1 cannabinoid receptors, respectively. The present research is a continuation of previous studies conducted by us, aimed to propose new perspectives on wound treatment. In conclusion, the blocking of calcium channels favored wound healing under our experimental conditions, but this happened only by simultaneously blocking the L-type and T-type calcium channels, because only the medium nimodipine concentration had a statistically significant effect. Full article

Ion channels are essential for mineral ion homeostasis in mammalian cells, and these are activated or inhibited by environmental stimuli such as heat, cold, mechanical, acidic, or basic stresses. These expressions and functions are quite diverse between cell types. The function and importance of ion channels are well-studied in neurons and cardiac cells, while those functions in pluripotent stem cells (PSCs) were not fully understood. Some sodium, potassium, chloride, calcium, transient receptor potential channels and mechanosensitive Piezo channels are found to be expressed and implicated in pluripotency and self-renewal capacity in PSCs. This review summarizes present and previous reports about ion channels and their response to environmental stimuli in PSCs. Furthermore, we compare the expressions and roles between PSCs and their differentiated embryoid bodies. We then discuss those contributions to pluripotency and differentiation. Full article

Background: Apigenin (4′,5,7-trihydroxyflavone), a flavonoid with potential cardiovascular benefits, has unclear mechanisms of action. This study investigates its effects on vascular function in Spontaneously Hypertensive Rats (SHRs). Methods: Mesenteric vascular beds (MVBs) were isolated from SHRs and perfused with increasing doses of apigenin after pre-contraction with phenylephrine. To explore the mechanisms, different MVBs were pre-perfused with antagonists and inhibitors, including indomethacin, L-NAME, and potassium channel blockers (tetraethylammonium, a non-specific potassium channel blocker; glibenclamide, an ATP-sensitive potassium channel blocker; 4-aminopyridine, a voltage-gated potassium channel blocker; charybdotoxin a selective intermediate-conductance calcium-activated potassium channel blocker; and apamin, a selective small-conductance calcium-activated potassium channel blocker). Results: Apigenin induced a dose-dependent reduction in perfusion pressure in MVBs with intact endothelium, an effect abolished by endothelium removal. L-NAME reduced apigenin-induced vasodilation by approximately 40%. The vasodilatory effect was blocked by potassium chloride and tetraethylammonium. The inhibition of small and intermediate calcium-activated potassium channels with charybdotoxin and apamin reduced apigenin-induced vasodilation by 50%, and a combination of these blockers with L-NAME completely inhibited the effect. Conclusions: Apigenin promotes vasodilation in resistance arteries through endothelial nitric oxide and calcium-activated potassium channels. These findings suggest that apigenin could have therapeutic potential in cardiovascular disease, warranting further clinical research. Full article

Introduction: We sought to determine by systematic review the independent effect of overweight/obesity on cutaneous microvascular reactivity in adults as measured by laser-Doppler fluxmetry. Methods: CINAHL Complete, SPORTSDiscus, Embase, Medline, and Cochrane Library were searched until March 2024 to identify studies investigating cutaneous microvascular reactivity in an overweight/obese but otherwise healthy group versus a lean/healthy weight. Reporting is consistent with the Preferred Reporting Items for Systematic Reviews and Meta-Analyses (PRISMA) statement. Quality appraisal of included studies was performed using the Strengthening the Reporting of Observational Studies in Epidemiology (STROBE) checklist. Results: Nineteen eligible articles reported on 1847 participants. Most articles reported impaired cutaneous microvascular reactivity in cohorts with overweight/obesity compared to cohorts with lean/healthy weight. Investigating reactivity via post-occlusive reactive hyperaemia (PORH) and iontophoresis of acetylcholine (ACh) has shown significance. No significant differences were reported between groups in response to local heating or to iontophoresis of methacholine or insulin, while findings of the effect of obesity on iontophoresis of sodium nitroprusside (SNP) were mixed. Conclusions: The pathophysiology of impaired cutaneous microvascular reactivity in overweight/obesity requires further investigation; however, impaired function of vasoactive substances, endothelial dysfunction, sensory nerves, and calcium-activated potassium channels may be implicated. Identifying these impaired microvascular responses should inform possible therapy targets in overweight and obesity.activated potassium channels may be implicated. Identifying these impaired microvascular responses should inform possible therapy targets in overweight and obesity. Full article