Depolarization Of Cells Research Articles

Cochlear origin of tinnitus and outer hair cell motor protein Prestin as a biomarker for tinnitus

Peripheral dysfunction and hearing loss are known risk factors for tinnitus; however, a portion of tinnitus patients exhibit no apparent peripheral auditory deficits. This article proposes that tinnitus may originate in the cochlea due to, undetectable damage to outer hair cells (OHCs) in individuals with normal hearing. The study further suggests that peripheral auditory deficits can be identified through the outer hair cell motor protein Prestin, which has potential as a biomarker for early detection. Minor OHC losses, which do not result in clinically detectable hearing loss, may lead to insufficient depolarization of inner hair cells (IHCs), thereby reducing sensory input along the cochlea-cortex pathway in the central auditory system. From a homeostatic gain control perspective, decreased amplification by OHCs, including abnormal electromotile responses, may lead to inadequate encoding by IHCs, contributing to the cochlear origin of tinnitus. Damage to OHCs that does not affect hearing thresholds, or abnormal electromotile contractions influenced by Prestin, may contribute to peripheral auditory dysfunction underlying tinnitus. As a result, pre-neural mismatched synchronization between OHCs and IHCs, driven by abnormal OHC electromotility, could cause sound processing disorders within the central auditory system. This pathophysiological mechanism at the cochlear level may lead to pathological alterations at multiple levels of the central auditory system. Prestin may serve as a potential biomarker for tinnitus, offering valuable insights into its cochlear origin and guiding future therapeutic developments.

Multicellular adaptation to electrophysiological perturbations analyzed by deterministic and stochastic bioelectrical models

Cells can compensate a disruptive change in one ion channel by compensatory changes in other channels. We have simulated the adaptation of a multicellular aggregate of non-excitable cells to the electrophysiological perturbation produced by the external blocking of a cation channel. In the biophysical model employed, we consider that this blocking provokes a cell depolarization that opens a voltage-gated calcium channel, thus allowing toxic Ca2+ levels. The cell adaptation to this externally-induced perturbation is ascribed to the multiplicity of channels available to keep the cell membrane potential within a physiological window. We propose that the cell depolarization provokes the upregulated expression of a compensatory channel protein that resets the cell potential to the correct polarized value, which prevents the calcium entry. To this end, we use two different simulation algorithms based on deterministic and stochastic methods. The simulations suggest that because of the local correlations coupling the cell potential to transcription, short-term bioelectrical perturbations can trigger long-term biochemical adaptations to novel stressors in multicellular aggregates. Previous experimental data on planarian flatworms’ adaptation to a barium-containing environment is also discussed.

Zhachong Shisanwei pill drug-containing serum protects H2O2-Induced PC12 cells injury by suppressing apoptosis, oxidative stress via regulating the MAPK signaling pathway.

Zhachong Shisanwei Pill (ZSP) is a classical Mongolian formula that combines 13 types of Chinese medicinal materials and has been used for treating ischemic stroke (IS) for centuries. However, the underlying molecular mechanisms have yet to be fully elucidated. The aim of this study is to explore potential mechanism of ZSP on nerve cells in cerebral ischemic injury. To simulate the pathological process of oxidative stress following IS, an injury model using PC12 cells was induced with hydrogen peroxide (H2O2). Afterward, PC12 cells were treated with ZSP medicated serum at low, medium, and high doses. Various assays were conducted to assess cell viability and oxidative stress indicators, including lactate dehydrogenase (LDH), malondialdehyde (MDA), superoxide dismutase (SOD), catalase (CAT), reactive oxygen species (ROS), and mitochondrial membrane potential (MMP). Cell apoptosis was evaluated through morphological assessment and flow cytometry. Additionally, the expression levels of apoptosis-related proteins (Bcl-2, Bax, Caspase-9, Caspase-3, PARP) and signaling pathway proteins (JNK, phosphorylated JNK, ERK, phosphorylated ERK, p38, and phosphorylated p38) were measured using automated Western blotting. Our findings indicate that ZSP medicated serum preconditioning improves the condition of PC12 cells injured by H2O2. Specifically, it increased cell survival rates and reduced LDH release. Additionally, ZSP treatment decreased ROS levels and MDA content, while enhancing the activity of SOD and CAT in the injured PC12 cells. ZSP also reversed the depolarization of mitochondrial membrane potential and protected cells from apoptosis by modulating the expression of apoptosis-related proteins, including Bcl-2, Bax, Caspase-9, Caspase-3, and PARP. Furthermore, the overactivation of the MAPK signaling pathway due to H2O2-induced injury was inhibited, as evidenced by the downregulation of phosphorylated JNK, ERK, and p38 levels. Mongolian medicine ZSP demonstrates protective effects against H2O2-induced oxidative stress and apoptosis in PC12 cells. The underlying mechanism may involve the inhibition of the MAPK signaling pathway, enhancement of antioxidant enzyme activity, reduction of intracellular peroxidation levels, and suppression of intrinsic apoptosis pathways.

Trehalose Attenuates In Vitro Neurotoxicity of 6-Hydroxydopamine by Reducing Oxidative Stress and Activation of MAPK/AMPK Signaling Pathways.

The effects of trehalose, an autophagy-inducing disaccharide with neuroprotective properties, on the neurotoxicity of parkinsonian mimetics 6-hydroxydopamine (6-OHDA) and 1-methyl-4-phenylpiridinium (MPP+) are poorly understood. In our study, trehalose suppressed 6-OHDA-induced caspase-3/PARP1 cleavage (detected by immunoblotting), apoptotic DNA fragmentation/phosphatidylserine externalization, oxidative stress, mitochondrial depolarization (flow cytometry), and mitochondrial damage (electron microscopy) in SH-SY5Y neuroblastoma cells. The protection was not mediated by autophagy, autophagic receptor p62, or antioxidant enzymes superoxide dismutase and catalase. Trehalose suppressed 6-OHDA-induced activation of c-Jun N-terminal kinase (JNK), p38 mitogen-activated protein kinase (MAPK), and AMP-activated protein kinase (AMPK), as revealed by immunoblotting. Pharmacological/genetic inhibition of JNK, p38 MAPK, or AMPK mimicked the trehalose-mediated cytoprotection. Trehalose did not affect the extracellular signal-regulated kinase (ERK) and mechanistic target of rapamycin complex 1 (mTORC1)/4EBP1 pathways, while it reduced the prosurvival mTORC2/AKT signaling. Finally, trehalose enhanced oxidative stress, mitochondrial damage, and apoptosis without decreasing JNK, p38 MAPK, AMPK, or AKT activation in SH-SY5Y cells exposed to MPP+. In conclusion, trehalose protects SH-SY5Y cells from 6-OHDA-induced oxidative stress, mitochondrial damage, and apoptosis through autophagy/p62-independent inhibition of JNK, p38 MAPK, and AMPK. The opposite effects of trehalose on the neurotoxicity of 6-OHDA and MPP+ suggest caution in its potential development as a neuroprotective agent.

Modulating apoptosis as a novel therapeutic strategy against Respiratory Syncytial Virus infection: insights from Rotenone

Respiratory syncytial virus (RSV) is a significant cause of acute lower respiratory tract infections, particularly in vulnerable populations such as neonates, infants, young children, and the elderly. Among infants, RSV is the primary cause of bronchiolitis and pneumonia, contributing to a notable proportion of child mortality under the age of 5. In this study, we focused on investigating the pathogenicity of a lethal RSV strain, GZ08-18, as a model for understanding mechanisms of hypervirulent RSV. Our findings indicate that the heightened pathogenicity of GZ08-18 stems from compromised activation of intrinsic apoptosis, as evidenced by aberration of mitochondrial membrane depolarization in host cells. We thus hypothesized that enhancing intrinsic apoptosis could potentially attenuate the virulence of RSV strains and explored the effects of Rotenone, a natural compound known to stimulate the intrinsic apoptosis pathway, on inhibiting RSV infection. Our results demonstrate that Rotenone treatment significantly improved mouse survival rates and mitigated lung pathology following GZ08-18 infection. These findings suggest that modulating the suppressed apoptosis induced by RSV infection represents a promising avenue for antiviral intervention strategies.

Manifesting the Dasatinib-gallic acid co-amorphous system to augment anticancer potential: Physicochemical characterization, in silico molecular simulation, ex vivo permeability, and in vitro efficacy

Dasatinib (DAB) has been explored for repurposing in the treatment of breast cancer (BC) due to its known effectiveness in treating leukemia, in addition to its role as a tyrosine kinase inhibitor. Gallic acid (GA) was chosen as a co-former due to its anticancer potential in BC, as demonstrated in several previous studies. DAB is a low-solubility drug, which is a significant hurdle for its oral bioavailability. To address this limitation, a DAB and GA co-amorphous (DAB-GA-CA) system was developed using liquid-assisted grinding and ball mill technology to enhance solubility, bioavailability, and anti-tumor efficacy. Physical characterization investigation revealed that the emergence of the halo diffractogram in PXRD, single glass transition temperature (Tg) value at 111.7 °C in DSC thermogram, and irregularly shaped blocks with loose, porous surfaces in SEM analysis indicated the formation of the DAB-GA-CA system at 1:1 M ratio. Furthermore, FTIR, Raman spectroscopy, in-silico molecular docking, and molecular dynamic studies confirmed the intermolecular hydrogen connections between DAB and GA. Moreover, the outcomes of the ligands (DAB and GA) and receptors (BCL-2, mTOR, estrogen receptor, and HER-2) docking studies demonstrated that both DAB and GA could interact with those receptors, leading to preventive action on BC cells. Additionally, the solubility and dissolution rate significantly improved at pH 6.8, and the permeability study indicated that DAB-GA-CA showed 1.9 times higher apparent permeability compared to crystalline DAB. Furthermore, in vitro cytotoxicity assessments of the DAB-GA-CA system revealed 3.42 times lower IC50 than free DAB. The mitochondrial membrane depolarization, apoptotic index, and reactive oxygen species formation in MCF-7 cells were also notably higher in the DAB-GA-CA system than in free DAB. Hence, this research suggests that the DAB-GA-CA system could substantially enhance oral delivery, solubility, and therapeutic efficacy.

Mechanisms and Functions of Sweet Reception in Oral and Extraoral Organs.

The oral detection of sugars relies on two types of receptor systems. The first is the G-protein-coupled receptor TAS1R2/TAS1R3. When activated, this receptor triggers a downstream signaling cascade involving gustducin, phospholipase Cβ2 (PLCβ2), and transient receptor potential channel M5 (TRPM5). The second type of receptor is the glucose transporter. When glucose enters the cell via this transporter, it is metabolized to produce ATP. This ATP inhibits the opening of KATP channels, leading to cell depolarization. Beside these receptor systems, sweet-sensitive taste cells have mechanisms to regulate their sensitivity to sweet substances based on internal and external states of the body. Sweet taste receptors are not limited to the oral cavity; they are also present in extraoral organs such as the gastrointestinal tract, pancreas, and brain. These extraoral sweet receptors are involved in various functions, including glucose absorption, insulin release, sugar preference, and food intake, contributing to the maintenance of energy homeostasis. Additionally, sweet receptors may have unique roles in certain organs like the trachea and bone. This review summarizes past and recent studies on sweet receptor systems, exploring the molecular mechanisms and physiological functions of sweet (sugar) detection in both oral and extraoral organs.

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

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.

Vaccarin Ameliorates Doxorubicin-Induced Cardiotoxicity via Inhibition of p38 MAPK Mediated Mitochondrial Dysfunction.

Doxorubicin is a frequently used chemotherapeutic agent for treating various malignancies. However, it leads to severe cardiotoxic side effects, such as heart failure, and elevates the risk of sudden cardiac death among cancer patients. While oxidative stress has been identified as the primary cause of doxorubicin-induced cardiotoxicity, therapeutic antioxidant approaches have yielded unsatisfactory outcomes. The aim of this study is to explore the therapeutic potential of vaccarin, an active flavonoid glycoside extracted from traditional Chinese herbal agent Semen Vaccariae, in doxorubicin-induced cardiotoxicity. We observed that vaccarin significantly ameliorates doxorubicin-induced heart dysfunction in mouse model and suppresses oxidative stress mediated cell apoptosis via specifically inhibiting the activation of p38 MAPK pathway. In vitro, we observed that vaccarin alleviates doxorubicin-induced mitochondrial membrane depolarization and ROS generation in H9c2 cell, but the p38 MAPK agonist anisomycin reverses these effects. Our findings provide a promising natural antioxidant to protect against DOX-induced cardiotoxicity.

Unsaturated fatty acid, Nonacosenoic acid isolated from an endophyte Chaetomium nigricolor inhabiting the stem of Catharanthus roseus and its bioactivity

The endophytic fungus Chaetomium nigricolor culture filtrate's hexane extract was used to identify a cytotoxic very long-chain fatty acid. Based on multiple spectroscopic investigations, the structure of the compound was predicted to be an unsaturated fatty acid, Nonacosenoic acid (NA). Using the MTT assay, the compound's cytotoxic potential was evaluated against MCF-7, A-431, U-251, and HEK-293 T cells. The compound was moderately cytotoxic to breast carcinoma cell line, MCF-7 cells and negligibly cytotoxic to non-cancerous cell line HEK-293 T cells. The compound exhibited mild cytotoxic activity against A-431 and U-251 cells. The compound also induced ROS generation and mitochondrial depolarization in MCF-7 cells when assessed via the NBT and JC-1 assays, respectively. This is the first report on the production of nonacosenoic acid from the endophytic fungus Chaetomium nigricolor and the assessment of its bioactivity.

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

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. 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. 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. 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.

L-Serine Protects Murine Retinal Ganglion Cells from Oxidative Stress via Modulation of Mitochondrial Dysfunction

Purpose This study aimed to investigate the effects of l-serine on mitochondrial dysfunction in retinal ganglion cells after exposure to H2O2-induced oxidative stress. Methods Retinal ganglion cells obtained from C57BL6 mice (postnatal days 1–4) were purified and cultured. A cell viability assay was performed following exposure to H2O2-induced oxidative stress to assess the cytoprotective effects of l-serine on retinal ganglion cells. Flow cytometry with CellROX Deep Red and MitoSOX dyes was performed to analyze the cytoplasmic and mitochondrial reactive oxygen species levels, respectively. Staining with the fluorescent probe JC-1 was used to detect changes in the mitochondrial membrane potential. The oxygen consumption rate and Bioenergetic Health Index were used to evaluate mitochondrial respiration. Results H2O2 treatment was found to induce mitochondrial dysfunction in retinal ganglion cells. Pretreatment with l-serine prevented cytotoxicity and significantly increased the viability of retinal ganglion cells following exposure to H2O2-induced oxidative stress (p < .05). l-Serine alleviated reactive oxygen species production in retinal ganglion cells following exposure to H2O2-induced oxidative (p < .05). Further, it successfully mitigated H2O2-induced mitochondrial depolarization in retinal ganglion cells (p < .05) and significantly increased the oxygen consumption rate and Bioenergetic Health Index in retinal ganglion cells following exposure to H2O2-induced oxidative stress (p < .05). Conclusion Pretreatment with l-serine protected retinal ganglion cells from H2O2-induced oxidative stress by improving mitochondrial function. The findings of the present study suggest that l-serine is a potential candidate for treatment of reactive oxygen species-related ocular diseases such as mitochondrial optic neuropathies.

Non-drug therapies for patients with vibration disease associated with exposure to local vibration

Non-drug methods include acupuncture, the most effective way to regulate the body's energy system. Pulsed magnetic stimulation (PMS) is based on the application of the principles of electromagnetic induction, causes hyperpolarization or depolarization of nerve cells. The methods are practically not used in the clinic of occupational diseases, and their effectiveness in the treatment of vibration disease (VD) has not been established. The study aims to evaluate changes in the central nervous system and peripheral nerves, as well as in the psychological status of patients with vibration disease after sessions of acupuncture and pulsed magnetic stimulation. Using the acupuncture method, 24 male patients were treated with a diagnosis of VD associated with exposure to local vibration (average age 49.9±3.8 years, average length of service — 19.4±4.3 years), PMS — 24 people with a diagnosis of VD associated with exposure to local vibration (average age 48.8±3.4 years, average length of service — 18.1±3.4 years). The treatment methods performed made it possible to improve the quality of therapy, which was confirmed by a positive change in the indicators of visual and somatosensory evoked potentials, data from electroneuromyographic studies, vibration sensitivity and algesimetry, the state of the mnestic and attentional spheres of activity improved. The use of the acupuncture method allowed to improve the indicators of bioelectric activity of the brain: the amplitude of the peak N1 of visual evoked potentials increased (from 3.2 to 6.7 MV, p&lt;0.05), the latency of the peak P200 decreased from 178.0 to 142.5 ms, p&lt;0.05. The threshold of pain sensitivity on the zygomatic bone, on the phalanx of the 2nd finger of the hand and on the protruding part of the inner ankle decreased by 63, 125 and 250 Hz, p&lt;0.05. Vibration sensitivity improved (on the ulnar process, phalanx of 2 fingers of the hand, p&lt;0.01, on the tubercle of the tibia, p&lt;0.05). Magnetic stimulation contributed to the improvement of cerebral changes in the treated patients — the latency of auditory evoked potentials decreased (p&lt;0.03 for peak P1 and p&lt;0.05 for peak P2), the amplitude of visual evoked potentials increased (p&lt;0.05), the bioelectric activity of the occipital lobes of the brain increased. The duration of the afferent excitation wave at the level of the cervical region (latency N11 and N13, p&lt;0.05) and thalamic structures (latency P25, p&lt;0.05) increased. Non-drug therapy allowed to restore the time of excitation by the motor component of axons in patients on the upper extremities during acupuncture, on the upper and lower extremities during treatment with magnetic stimulation (p&lt;0.05), improved indicators characterizing the mnestic-attentional and psychoemotional spheres of the treated. Ethics. Conclusion of the MEС of the Federal State Budgetary Scientific Institution "East Siberian Institute of Medical and Environmental Research" No. 32 dated 09/10/2019.

The Impact of Chronic Magnesium Deficiency on Excitable Tissues-Translational Aspects.

Neuromuscular excitability is a vital body function, and Mg2+ is an essential regulatory cation for the function of excitable membranes. Loss of Mg2+ homeostasis disturbs fluxes of other cations across cell membranes, leading to pathophysiological electrogenesis, which can eventually cause vital threat to the patient. Chronic subclinical Mg2+ deficiency is an increasingly prevalent condition in the general population. It is associated with an elevated risk of cardiovascular, respiratory and neurological conditions and an increased mortality. Magnesium favours bronchodilation (by antagonizing Ca2+ channels on airway smooth muscle and inhibiting the release of endogenous bronchoconstrictors). Magnesium exerts antihypertensive effects by reducing peripheral vascular resistance (increasing endothelial NO and PgI2 release and inhibiting Ca2+ influx into vascular smooth muscle). Magnesium deficiency disturbs heart impulse generation and propagation by prolonging cell depolarization (due to Na+/K+ pump and Kir channel dysfunction) and dysregulating cardiac gap junctions, causing arrhythmias, while prolonged diastolic Ca2+ release (through leaky RyRs) disturbs cardiac excitation-contraction coupling, compromising diastolic relaxation and systolic contraction. In the brain, Mg2+ regulates the function of ion channels and neurotransmitters (blocks voltage-gated Ca2+ channel-mediated transmitter release, antagonizes NMDARs, activates GABAARs, suppresses nAChR ion current and modulates gap junction channels) and blocks ACh release at neuromuscular junctions. Magnesium exerts multiple therapeutic neuroactive effects (antiepileptic, antimigraine, analgesic, neuroprotective, antidepressant, anxiolytic, etc.). This review focuses on the effects of Mg2+ on excitable tissues in health and disease. As a natural membrane stabilizer, Mg2+ opposes the development of many conditions of hyperexcitability. Its beneficial recompensation and supplementation help treat hyperexcitability and should therefore be considered wherever needed.

Choroid plexus epithelial cells react to hypertonic KCl by passive cell shrinkage not by NKCC1-mediated water import

Choroid plexus epithelial cells react to changes in osmolarity by passive cell volume changes as other mammalian cells. In previous studies, hyperosmolar challenges resulted in cell shrinkage when either mannitol or NaCl was applied to increase osmolarity. However, a robust cell swelling, despite an outward osmotic gradient, was reported upon challenge with KCl-induced hypertonicity. This was interpreted as inward obligate water transport with Na+, K+, and Cl− mediated by NKCC1. In the present study, single cell volume changes were recorded by pinhole calcein-fluorescence microscopy and contrast imaging before and after 1-minute challenges with osmolarity change. Mannitol- and NaCl-induced hyperosmolarity of 30 mOsm induced the expected ~10% reductions in cell volume by both methods (n=9). Similar KCl-induced hyperosmolarity led to three different responses: cell shrinkage by ~6%, cell swelling by ~50%, or a combined pattern with shrinkage followed by swelling (n=9). Some of the swollen cells started blebbing and/or disrupted, while others partially regained cell volume even after blebbing. KCl-induced cell swelling was sensitive to the NKCC1 inhibitor bumetanide (10 μM), indicating the dependence of the swelling on inward transport by this mechanism. The observation that cell swelling can occur despite a preceding shrinkage indicated that the water influx did not occur against an osmotic gradient. Another observation against NKCC1-mediated water transport was a robust ~14% cell shrinkage induced by 100 mOsm NaCl hyperosmolarity (n=5). Under these conditions, the inward chemical gradient for ions transported by NKCC1 are of similar magnitude as under 15 mOsm KCl-induced hyperosmolarity, where a subset of cells reacted with ~12% swelling (the majority of cells were shrinking, n=5). Thus, the cell swelling is not driven by the combined gradients for Na+, K+, and Cl− into the cells, but is probably secondary to a KCl-induced cell depolarization. Interestingly, cell depolarization by the monovalent cation ionophore gramicidin (10 μM) induces a Na+-dependent cell swelling in a subset of cells with similar magnitude and duration as KCl-induced hyperosmolarity (n=5). Thus, the heterogeneous response to KCl-induced hyperosmolarity may rely on variations in the initial membrane potential among isolated cells. In conclusion, this study can reproduce many of the previous observations regarding cell volume responses to hyperosmolarity in choroid plexus epithelial cells including a bumetanide-sensitive swelling phenomenon in a subset of cells. However, the ionic gradients are not driving this cell swelling, but is rather a consequence of cell depolarization. The research was supported by the Independent Research Fund Denmark | Medical Sciences and Aarhus University Research Foundation. This is the full abstract presented at the American Physiology Summit 2024 meeting and is only available in HTML format. There are no additional versions or additional content available for this abstract. Physiology was not involved in the peer review process.

Mechanosensor channels of the lens and ciliary body: patch clamp studies

Epithelia from the lens and the ciliary body possess mechanosensors, including Piezo1 and transient receptor potential (TRP) channels, that may partake in the regulation of lens and aqueous humor volume. Although these mechanosensor channels commonly allow calcium entry, the outcomes of elevated intracellular calcium vary with the type of channel activated. For instance, separate activation of TRPV4 and TRPV1 increases Na-K-ATPase and Na/K/2Cl cotransporter activities, respectively. To further understand the role of mechanosensitivity in lens and ciliary body, we are currently using patch clamp techniques to characterize the response of primary cultured cells to chemical agonists and antagonists, as well as direct mechanical stimulation. Previously, we found that in mouse lens epithelial cells (mLEC), TRPV4 activation by agonist GSK1016790A (GSK) is followed by disappearance of a fast, transient K+-like outward current (Ipeak), decrease of a steady state outward current (Iss), fast depolarization of resting membrane potential (RMP) values from near -50 mV to near 0 mV, increase of Cx43 hemichannel-like events, and increase of overall membrane conductance ( gm) at holding potential (HP) = -50mV. More recently, we found that in mLEC, shear stress (streaming of external solution from a pipette tip over the cell membrane) reduced Ipeak but did not cause large RMP changes. Porcine non-pigmented epithelial cells (pNPE) in normal conditions display no Ipeak, small Iss, small RMP near -20 mV and spontaneous Cx43 hemichannel-like event activity. Nevertheless, GSK caused further depolarization of pNPE cells, and while no gm changes were seen when GSK was applied while holding cells at -50 mV, gm did increase when GSK exposure occurred during repeated ±80 mV pulses. Preliminary experiments show that activation of TRPM3 by its agonist pregnenolone causes a minimal hyperpolarization in mLEC. In comparison, in a line of human LEC (HLE B3) expressing TRPM3 channels, and which appear generally depolarized, pregnenolone caused a proportionally larger shift toward more negative RMP values; more intriguing, GSK has no measurable effect on the gm of HLE B3 cells. Taken together, and apart from considerations of cell- and species-specific differences, the data suggest that mechanosensor channels have different and/or opposite effects on the regulation of membrane ion channel activity, and thus on cell function. R01EY029171 and R01EY009532. This is the full abstract presented at the American Physiology Summit 2024 meeting and is only available in HTML format. There are no additional versions or additional content available for this abstract. Physiology was not involved in the peer review process.

Stronger vasoconstriction and weaker vasodilation in mesenteric arteries of Ossabaw than Göttingen minipigs before manifestation of metabolic syndrome

The metabolic syndrome predisposes and contributes to the development and progression of atherosclerosis. The minipig strain “Ossabaw” is characterized by a polygenic predisposition to develop metabolic syndrome and diffuse atherosclerosis in response to a hypercaloric atherogenic diet. The aim of this study was to investigate whether Ossabaw minipigs exhibit an altered vasomotor function even before they develop their diseased phenotype. Mesenteric arteries of adult Ossabaw (n=30) and Göttingen minipigs (n=40), a pig strain without genetic predisposition to a metabolic syndrome, were harvested postmortem, dissected, and mounted on a myograph for isometric force measurements. Maximal vasoconstriction to smooth muscle cell depolarization with potassium chloride (KClmax) was repeatedly induced (twice 0.6×10−1 mol/L and twice 1.2×10−1 mol/L). Cumulative concentration-response curves were determined in response to 1×10−9 -1×10−4 mol/L norepinephrine. Endothelium-dependent and -independent vasodilation were analyzed in response to carbachol and nitroprusside, respectively (1×10−9 - 1×10−4 mol/L, each) after pre-constriction by norepinephrine. The baseline diameter of mesenteric arteries from Ossabaw minipigs was smaller than that from Göttingen minipigs (329±20 vs. 435±11 μm), and mesenteric arteries of Ossabaw minipigs developed a higher baseline force of contraction than mesenteric arteries of Göttingen minipigs (6.2±0.7 vs. 3.6±0.3 mN). The maximal vasoconstrictor response to KCl was comparable between the minipig strains. Vasoconstriction in response to norepinephrine was more pronounced in Ossabaw than in Göttingen minipigs (143±9 vs. 108±6% KClmax). Endothelium-dependent vasodilation (46.4±5.5 vs. 16.0±3.0% of norepinephrine-induced preconstriction) and -independent vasodilation (36.7±4.9 vs. 2.3±0.6% of norepinephrine-induced preconstriction) were less pronounced in Ossabaw than in Göttingen minipigs. Neither the differences in baseline diameter nor in baseline developed force of contraction had any effect on the above data, as analyzed in retrospectively matched subsets of mesenteric arteries with a comparable baseline diameter or a comparable baseline developed force of contraction, respectively. Even before the development of metabolic syndrome, vasomotor function is shifted to more vasoconstriction and less vasodilation in Ossabaw minipigs, suggesting a genetic predisposition for the early development of vascular dysfunction. Thus, Ossabaw minipigs may be a suitable model to reflect the human situation of a heterogeneous, genetically determined primordial risk constellation for vascular dysfunction. This work was supported by the German Research Foundation [SFB 1116 B08 to G.H. and P.K.] and the European COST ACTION in CARDIOPROTECTION [CA16225 to G.H. and IG16225 to G.H. and P.K.]. This is the full abstract presented at the American Physiology Summit 2024 meeting and is only available in HTML format. There are no additional versions or additional content available for this abstract. Physiology was not involved in the peer review process.

ONC212 enhances YM155 cytotoxicity by triggering SLC35F2 expression and NOXA-dependent MCL1 degradation in acute myeloid leukemia cells

Although the anticancer activity of ONC212 has been reported, the precise mechanism underlying its apoptotic effects remains unclear. In this study, we investigated the apoptotic mechanism of ONC212 in acute myeloid leukemia (AML) cells. ONC212 induces apoptosis, MCL1 downregulation, and mitochondrial depolarization in AML U937 cells. Ectopic MCL1 expression alleviates mitochondria-mediated apoptosis in ONC212-treated U937 cells. ONC212 triggers AKT phosphorylation, inducing NOX4-dependent ROS production and promoting HuR transcription. HuR-mediated ATF4 mRNA stabilization stimulates NOXA and SLC35F2 expression; ONC212-induced upregulation of NOXA leads to MCL1 degradation. The synergistic effect of ONC212 on YM155 cytotoxicity was dependent on increased SLC35F2 expression. In addition, YM155 feedback facilitated the activation of the ONC212-induced signaling pathway. A similar mechanism explains ONC212- and ONC212/YM155-induced AML HL-60 cell death. The continuous treatment of U937 cells with the benzene metabolite hydroquinone (HQ) generated U937/HQ cells, exhibiting enhanced responsiveness to the cytotoxic effects of ONC212. In U937/HQ cells, ONC212 triggered apoptosis through NOXA-mediated MCL1 downregulation, enhancing YM155 cytotoxicity. Collectively, our data suggested that ONC212 upregulated SLC35F2 expression and triggered NOXA-mediated MCL1 degradation in U937, U937/HQ, and HL-60 cells by activating the AKT/NOX4/HuR/ATF4 pathway. The ONC212-induced signaling pathway showed anti-AML activity and enhanced YM155 cytotoxicity.

Epigenetic control of adaptive or homeostatic splicing during interval-training activities.

Interval-training activities induce adaptive cellular changes without altering their fundamental identity, but the precise underlying molecular mechanisms are not fully understood. In this study, we demonstrate that interval-training depolarization (ITD) of pituitary cells triggers distinct adaptive or homeostatic splicing responses of alternative exons. This occurs while preserving the steady-state expression of the Prolactin and other hormone genes. The nature of these splicing responses depends on the exon's DNA methylation status, the methyl-C-binding protein MeCP2 and its associated CA-rich motif-binding hnRNP L. Interestingly, the steady expression of the Prolactin gene is also reliant on MeCP2, whose disruption leads to exacerbated multi-exon aberrant splicing and overexpression of the hormone gene transcripts upon ITD, similar to the observed hyperprolactinemia or activity-dependent aberrant splicing in Rett Syndrome. Therefore, epigenetic control is crucial for both adaptive and homeostatic splicing and particularly the steady expression of the Prolactin hormone gene during ITD. Disruption in this regulation may have significant implications for the development of progressive diseases.

TSPO deficiency exacerbates acute lung injury via NLRP3 inflammasome-mediated pyroptosis.

Acute respiratory distress syndrome (ARDS) is a common cause of respiratory failure in many critically ill patients. Although inflammasome activation plays an important role in the induction of acute lung injury (ALI) and ARDS, the regulatory mechanism of this process is still unclear. When cells are stimulated by inflammation, the integrity and physiological function of mitochondria play a crucial part in pyroptosis. However, the underlying mechanisms and function of mitochondrial proteins in the process of pyroptosis are largely not yet known. Here, we identified the 18-kDa translocator protein (TSPO), a mitochondrial outer membrane protein, as an important mediator regulating nucleotide-binding domain, leucine-rich repeat, and pyrin domain-containing protein 3 (NLRP3) inflammasome activation in macrophages during ALI. TSPO gene knockout (KO) and lipopolysaccharide (LPS)-induced ALI/ARDS mouse models were employed to investigate the biological role of TSPO in the pathogenesis of ARDS. Murine macrophages were used to further characterize the effect of TSPO on the NLRP3 inflammasome pathway. Activation of NLRP3 inflammasome was preformed through LPS+adenosine triphosphate (ATP) co-stimulation, followed by detection of mitochondrial membrane potential, reactive oxygen species (ROS) production, and cell death to evaluate the potential biological function of TSPO. Comparisons between two groups were performed with a two-sided unpaired t -test. TSPO- KO mice exhibited more severe pulmonary inflammation in response to LPS-induced ALI. TSPO deficiency resulted in enhanced activation of the NLRP3 inflammasome pathway, promoting more proinflammatory cytokine production of macrophages in LPS-injured lung tissue, including interleukin (IL)-1β, IL-18, and macrophage inflammatory protein (MIP)-2. Mitochondria in TSPO -KO macrophages tended to depolarize in response to cellular stress. The increased production of mitochondrial damage-associated molecular pattern led to enhanced mitochondrial membrane depolarization and pyroptosis in TSPO -KO cells. TSPO may be the key regulator of cellular pyroptosis, and it plays a vital protective role in ARDS occurrence and development.