Ahf-Caltide, a Novel Polypeptide Derived from Calpastatin, Protects against Oxidative Stress Injury by Stabilizing the Expression of CaV1.2 Calcium Channel.

Reperfusion after ischemia would cause massive myocardial injury, which leads to oxidative stress (OS). Calcium homeostasis imbalance plays an essential role in myocardial OS injury. CaV1.2 calcium channel mediates calcium influx into cardiomyocytes, and its activity is modulated by a region of calpastatin (CAST) domain L, CSL54-64. In this study, the effect of Ahf-caltide, derived from CSL54-64, on myocardial OS injury was investigated. Ahf-caltide decreased the levels of LDH, MDA and ROS and increased heart rate, coronary flow, cell survival and SOD activity during OS. In addition, Ahf-caltide permeated into H9c2 cells and increased CaV1.2, CaVß2 and CAST levels by inhibiting protein degradation. At different Ca2+ concentrations (25 nM, 10 µM, 1 mM), the binding of CSL to the IQ motif in the C terminus of the CaV1.2 channel was increased in a H2O2 concentration-dependent manner. CSL54-64 was predicted to be responsible for the binding of CSL to CaV1.2. In conclusion, Ahf-caltide exerted a cardioprotective effect on myocardial OS injury by stabilizing CaV1.2 protein expression. Our study, for the first time, proposed that restoring calcium homeostasis by targeting the CaV1.2 calcium channel and its regulating factor CAST could be a novel treatment for myocardial OS injury.

Binding characteristics of calpastatin domain L to NaV1.5 sodium channel and its IQ motif mutants.

NaV1.5 channel is an integral membrane protein involved in the initiation and conduction of action potentials. IQ motif is located in the C-terminal domain of NaV1.5 sodium channel, which is highly conserved in human sodium channel subtypes. IQ motif is involved in the Ca2+-dependent regulation through interaction with the regulatory proteins such as calpastatin domain L (CSL). Mutations in SCN5A, the gene encoding NaV1.5 channel, have been linked to many cardiac arrhythmias, such as Long QT syndrome type 3 (LQT3) and Brugada syndrome (BRS). LQT3-associated mutations in NaV1.5 IQ motif, IQQ1909R and IQR1913H, have been reported to affect the late INa. A BRS-associated mutation in NaV1.5 IQ motif, IQA1924T, has been reported to affect the peak INa. But the detailed pathogenic mechanisms of LQT3 and BRS remains unclear. To explore the binding properties of CSL to IQ motif and its muants associated with LQT3/BRS, molecular docking and GST pull down assay were performed in this study. As a result, S58 and E59 in CSL activating channel effect region L54-64 were involved in the conformation of the CSL/IQWT complex by protein-protein docking. IQ motif could bind to CSL in a [CSL]-dependent and [Ca2+]-dependent manner by pull down assay. However, the binding affinities of IQQ1909R and IQR1913H to CSL were decreased and its reaction rates with CSL were slower. The binding characteristics of IQA1924T to CSL was opposite in a [Ca2+]-dependent manner and its binding efficacy became smaller. The changes of the binding characteristics of IQmutants to CSL would affect the regulation of NaV1.5 channel, which may be related to LQT3 and BRS.

A potent antiarrhythmic drug N-methyl berbamine extends the action potential through inhibiting both calcium and potassium currents.

N-methyl berbamine (N-MB) is a berberine derivative. Its analogue berbamine has been reported to have remarkable antiarrhythmic and ischemic protective effects. However, the pharmacological effects of N-MB are ill-defined. In this study, molecular docking was used to evaluate the binding of N-MB to CaV1.2 Ca2+ and KV11.1 K+ channels, and the effects of N-MB on action potential and ionic currents were observed in the ventricular myocytes of rabbits, HEK293 cells stably transfected with the hCaV1.2 gene and CHO cells stably transfected with hERG (human ether-a-go-go related gene). The results showed that N-MB was able to bind to both CaV1.2 and KV11.1 channels. Following a perfusion with N-MB, the durations of action potentials (APD20, APD50 and APD90) were extended, and the outward tail current, Itail, as well as the hERG current, IhERG, were inhibited, while the amplitude of action potential (APA) was only slightly reduced. N-MB also decreased the peak amplitude of the L-type Ca2+ channel current, ICaL, as well as the CaV1.2 current, ICaV1.2; this may limit the prolongation of APD. In conclusion, N-MB is a potent and natural antiarrhythmic multitarget drug that may elicit its antiarrhythmic effect through blocking both Ca2+ and K+ channel currents.

Integrated Analysis of Gut Microbiome and Adipose Transcriptome Reveals Beneficial Effects of Resistant Dextrin from Wheat Starch on Insulin Resistance in Kunming Mice.

Systemic chronic inflammation is recognized as a significant contributor to the development of obesity-related insulin resistance. Previous studies have revealed the physiological benefits of resistant dextrin (RD), including obesity reduction, lower fasting glucose levels, and anti-inflammation. The present study investigated the effects of RD intervention on insulin resistance (IR) in Kunming mice, expounding the mechanisms through the gut microbiome and transcriptome of white adipose. In this eight-week study, we investigated changes in tissue weight, glucose-lipid metabolism levels, serum inflammation levels, and lesions of epididymal white adipose tissue (eWAT) evaluated via Hematoxylin and Eosin (H&E) staining. Moreover, we analyzed the gut microbiota composition and transcriptome of eWAT to assess the potential protective effects of RD intervention. Compared with a high-fat, high-sugar diet (HFHSD) group, the RD intervention significantly enhanced glucose homeostasis (e.g., AUC-OGTT, HOMA-IR, p < 0.001), and reduced lipid metabolism (e.g., TG, LDL-C, p < 0.001) and serum inflammation levels (e.g., IL-1ß, IL-6, p < 0.001). The RD intervention also led to changes in the gut microbiota composition, with an increase in the abundance of probiotics (e.g., Parabacteroides, Faecalibaculum, and Muribaculum, p < 0.05) and a decrease in harmful bacteria (Colidextribacter, p < 0.05). Moreover, the RD intervention had a noticeable effect on the gene transcription profile of eWAT, and KEGG enrichment analysis revealed that differential genes were enriched in PI3K/AKT, AMPK, in glucose-lipid metabolism, and in the regulation of lipolysis in adipocytes signaling pathways. The findings demonstrated that RD not only ameliorated IR, but also remodeled the gut microbiota and modified the transcriptome profile of eWAT.

A Comparative Study of Resistant Dextrins and Resistant Maltodextrins from Different Tuber Crop Starches.

The anti-digestibility of resistant dextrin (RD) and resistant maltodextrin (RMD) is usually significantly affected by processing techniques, reaction conditions, and starch sources. The objective of this investigation is to elucidate the similarities and differences in the anti-digestive properties of RD and RMD prepared from three different tuber crop starches, namely, potato, cassava, and sweet potato, and to reveal the associated mechanisms. The results show that all RMDs have a microstructure characterized by irregular fragmentation and porous surfaces, no longer maintaining the original crystalline structure of starches. Conversely, RDs preserve the structural morphology of starches, featuring rough surfaces and similar crystalline structures. RDs exhibite hydrolysis rates of approximately 40%, whereas RMDs displaye rates lower than 8%. This disparity can be attributed to the reduction of α-1,4 and α-1,6 bonds and the development of a highly branched spatial structure in RMDs. The indigestible components of the three types of RDs range from 34% to 37%, whereas RMDs vary from 80% to 85%, with potato resistant maltodextrin displaying the highest content (84.96%, p < 0.05). In conclusion, there are significant differences in the processing performances between different tuber crop starches. For the preparation of RMDs, potato starch seems to be superior to sweet potato and cassava starches. These attributes lay the foundation for considering RDs and RMDs as suitable components for liquid beverages, solid dietary fiber supplements, and low glycemic index (low-GI) products.

MiR-140-3p Impedes Gastric Cancer Progression and Metastasis by Regulating BCL2/BECN1-Mediated Autophagy.

INTRODUCTION: MiRNAs have been proven to modulate the progression of gastric cancer (GC). In this field, we evaluated the role and mechanism of miR-140-3p in GC. METHODS: Western blotting and qRT-PCR were used to detect the levels of miR-140-3p and BCL2. The interaction of miR-140-3p and BCL2 was confirmed by dual-luciferase reporter and miRNA pull-down assays. CCK-8, EdU, wound healing, and Transwell invasion assays were performed to evaluate cell proliferation, migration and invasion. Autophagy was analyzed using Western blot analysis of the LC3-II/I ratio and immunofluorescence staining. A xenograft model was established to reveal the role of miR-140-3p in tumorigenesis. RESULTS: In GC cell lines and tissues, miR-140-3p was highly expressed, and BCL2 was expressed at low levels. MiR-140-3p directly inhibited BCL2 expression and indirectly promoted BECN1 expression, and BCL2 inhibited BECN1 expression. MiR-140-3p overexpression or silencing restrained or facilitated migration, invasion and EMT in GC cells. Moreover, we noticed that overexpression or downregulation of miR-140-3p promoted or suppressed BECN1-dependent autophagy in GC cells. BCL2 introduction or BECN1 silencing in GC cells partially blocked the effects of miR-140-3p. In conclusion, miR-140-3p directly downregulated the expression of BCL2, BCL2 downregulation further activated BECN1-dependent autophagy, and autophagy activation further inhibited EMT. CONCLUSION: miR-140-3p may act as a tumor suppressor by targeting BCL2 and regulating downstream BECN1-induced autophagy and metastasis in GC progression.