Deltamethrin (DLT) is a type-II pyrethroid ester insecticide used in agricultural and domestic applications as well as in public health. However, transmembrane ionic channels perturbed by this compound remain largely unclear, although the agent is thought to alter the gating characteristics of voltage-gated Na+ (NaV) channel current. In this study, we reappraised whether and how it and other related compounds can make any further modifications on voltage-gated Na+ current (INa) in pituitary tumor (GH3) cells. Cell exposure to DLT produced a differential and dose-dependent stimulation of peak (transient, INa(T)) or sustained (late, INa(L)) INa; consequently, the EC50 value required for DLT-stimulated INa(T) or INa(L) was determined to be 11.2 or 2.5 μM, respectively. However, neither the fast nor slow component in the inactivation time constant of INa(T) activated by short depolarizing pulse was changed with the DLT presence; conversely, tefluthrin (Tef), a type-I pyrethroid insecticide, can accentuate INa with a slowing in inactivation time course of the current. The INa(L) augmented by DLT was attenuated by further application of either dapagliflozin (Dapa) or amiloride, but not by chlorotoxin. During pulse train (PT) stimulation, with the Tef or DLT presence, the cumulative inhibition of INa(T) became slowed; moreover, following PT stimuli, a large tail current with a slowly recovering process was observed. Alternatively, during rapid depolarizing pulse, the amplitude of INa(L) and tail INa (INa(Tail)) for each depolarizing pulse became progressively increased by adding DLT, not by Tef. The recovery time constant following PT stimulation with continued presence of Tef or DLT was shortened by further addition of Dapa. The voltage-dependent hysteresis (Hys(V)) of persistent INa was differentially augmented by Tef or DLT. Taken together, the magnitude, gating, frequency dependence, as well as Hys(V) behavior of INa exerted by the presence of DLT or Tef might exert a synergistic impact on varying functional activities of excitable cells in culture or in vivo.
Background: Activated microglia-mediated neuro-inflammation plays a vital aspect in regulating the micromilieu of the central nervous system. Neuro-inflammation involves distinct alterations of microglial phenotypes, containing nocuous pro-inflammatory (M1) phenotype and neuroprotective anti-inflammatory (M2) phenotype. Currently, there is no effective treatment for modulating such alterations. Little evidence shows that melatonin prevents the detrimental cascade of activated microglia-mediated neuro-inflammation. Methods: The expression levels of M1/M2 marker of primary microglia influenced by Melatonin were detected via qPCR. Functional activities were explored by western blotting, luciferase activity, EMSA, and ChIP assay. Structure interaction was assessed by molecular docking and LIGPLOT analysis. ER stress detection was examined by ultrastructure TEM, calapin activity, and ERSE assay. The neurobehavioral evaluations and immunofluorescence staining in animals were used for investigation of Melatonin on the neuroinflammation in vivo. Results: Melatonin had targeted on Peroxisome Proliferator Activated Receptor Delta (PPARd) activity, boosted LPS-stimulated alterations in polarization from the M1 to the M2 phenotype, and thereby inhibited NFkB–IKKb activation in primary microglia. The PPARd agonist L-165041 or over-expression of PPARd plasmid (ov-PPARd) showed similar results. Molecular docking screening, dynamic simulation approaches, and biological studies of melatonin showed that the activated site was located at PPARd (phospho-Thr256-PPARd). Furthermore, we found that activated microglia had lowered PPARd activity as well as the downstream SIRT1 formation via enhancing ER stress. Melatonin, PPARd agonist and ov-PPARd all effectively reversed the above-mentioned effects. Melatonin blocked ER stress by regulating calapin activity and expression in LPS-activated microglia. Additionally, melatonin or L-165041 ameliorated the neurobehavioral deficits in LPS-aggravated neuroinflammatory mice through blocking microglia activities, and also promoted phenotype changes to M2-predominant microglia. Conclusions Melatonin suppressed neuro-inflammation in vitro and in vivo by tuning microglial activation through the ER stress-dependent PPARd/SIRT1 signaling cascade. We proposed that this treatment strategy is an encouraging pharmacological approach for the remedy of neuro-inflammation associated disorders.
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