Research progress on transient receptor potential melastatin 2 channel in nervous system diseases

Systematic Analysis of the Relationship Between Elevated Zinc and Epilepsy

Previous studies have indicated a potential relationship between zinc and epilepsy. The aim of this study is to investigate the causal relationship between zinc, zinc-dependent carbonic anhydrase, and gray matter volume in brain regions enriched with zinc and epilepsy, as well as explore the possible mechanisms by which zinc contributes to epilepsy. First, this study assessed the risk causality between zinc, carbonic anhydrase, and gray matter volume alterations in zinc-enriched brain regions and various subtypes of epilepsy based on Two-sample Mendelian randomization analysis. And then, this study conducted GO/KEGG analysis based on colocalization analysis, MAGMA analysis, lasso regression, random forest model, and XGBoost model. The results of Mendelian randomization analyses showed a causal relationship between zinc, carbonic anhydrase-4, and generalized epilepsy (p = 0.044 , p = 0.010). Additionally, carbonic anhydrase-1 and gray matter volume of the caudate nucleus were found to be associated with epilepsy and focal epilepsy (p = 0.014, p = 0.003 and p = 0.022, p = 0.009). A colocalization relationship was found between epilepsy and focal epilepsy (PP.H4.abf = 97.7e - 2). Meanwhile, the MAGMA analysis indicated that SNPs associated with epilepsy and focal epilepsy were functionally localized to zinc-finger-protein-related genes (p < 1.0e - 5). The genes associated with focal epilepsy were found to have a molecular function of zinc ion binding (FDR = 2.3e - 6). After the onset of epilepsy, the function of the gene whose expression changed in the rats with focal epilepsy was enriched in the biological process of vascular response (FDR = 4.0e - 5). These results revealed mechanism of the increased risk of epilepsy caused by elevated zinc may be related to the increase of zinc ion-dependent carbonic anhydrase or the increase of the volume of zinc-rich caudate gray matter.

Antidepressants Are Poor Inhibitors of Heat-Evoked Ion Currents Mediated by TRPM2

INTRODUCTION

The heat and redox-sensitive ion channel TRPM2 was reported to be a causative mechanism for depression in a mouse model and to be upregulated in the hippocampus in patients suffering from depressive disorders. TRPM2 may thus be a novel target for antidepressants, but so far, selective TRPM2-inhibitors have not yet been developed. In this in vitro study, we examined the inhibitory effects of several established antidepressants on heat-evoked inward currents of TRPM2.

METHODS

Human (h) TRPM2 expressed in HEK293 cells was examined by means of whole-cell patch clamp recordings. Effects of duloxetine, amitriptyline, sertraline, fluoxetine, paroxetine, citalopram, escitalopram, ketamine, pregabalin, lidocaine, and QX-314 were explored on heat-evoked currents in cells pretreated with ADP-ribose (ADPR).

RESULTS

While inward currents induced by 1 mM ADPR in the pipette solution displayed a strong rundown hampering pharmacological experiments, heat-evoked currents in cells loaded with 200 μM APDR remained stable upon repetitive activation. Among all substances examined, only inhibition induced by duloxetine displayed a clear concentration-dependency. Thirty micromolar duloxetine was required for 50% inhibition, the same degree of inhibition was also induced by 30 μM amitriptyline, fluoxetine, and paroxetine. While citalopram, escitalopram, ketamine, and pregabalin failed to robustly modify TRPM2, sertraline and low concentrations of lidocaine even potentiated heat-evoked currents.

CONCLUSION

Our data indicate that some, but not all established antidepressants inhibit hTRPM2 when it is activated by heat and ADPR in vitro, e.g., presumably relevant endogenous agonists. However, none of the examined substances exhibited a potent inhibition which is likely to translate into a clinically relevant effect at effective plasma concentrations. Whether or not TRPM2 may be a relevant target for antidepressants cannot be conclusively assessed by a single in vitro study, thus further studies are required along these lines. Nevertheless, future studies may get simplified by the novel approach we developed for in vitro pharmacological analysis of TRPM2.