Sesaminol alters phospholipid metabolism and alleviates obesity-induced NAFLD.

The prevalence of obesity-induced non-alcoholic fatty liver disease (NAFLD) and insulin resistance is increasing worldwide. We previously demonstrated that sesaminol increases thermogenesis in adipocytes, improves insulin sensitivity, and mitigates obesity in mice. In this study, we demonstrated that sesaminol increased mitochondrial activity and reduced ROS production in hepatocytes. Therefore, we delve into the metabolic action of sesaminol in obesity-induced NAFLD or metabolic dysfunction-associated liver disease (MAFLD). Here, we report that sesaminol induces OXPHOS proteins and mitochondrial function in vivo. Further, our data suggest that sesaminol administration reduces hepatic triacylglycerol accumulation and LDL-C levels. Prominently, the lipidomics analyses revealed that sesaminol administration decreased the major phospholipids such as PC, PE, PI, CL, and PS to maintain membrane lipid homeostasis in the liver upon HFD challenge. Besides, SML reduced ePC and SM molecular species and increased PA levels in the HFD-fed mice. Also, sesaminol renders anti-inflammatory properties and dampens fibrosis markers in the liver. Remarkably, SML lowers the hepatic levels of ALT and AST enzymes and alleviates NAFLD in diet-induced obese mice. The molecular docking analysis identifies peroxisome proliferator-activated receptors as potential endogenous receptors for sesaminol. Together, our study demonstrates plant lignan sesaminol as a potential small molecule that alters the molecular species of major phospholipids, including sphingomyelin and ether-linked PCs in the liver tissue, improves metabolic parameters, and alleviates obesity-induced fatty liver disease in mice.

Sesaminol induces brown and beige adipocyte formation through suppression of myogenic program.

Adipocytes are key players in maintaining energy homeostasis and are classified into two different categories: white and brown adipocytes. While white adipocytes store energy as triacylglycerols in lipid droplets, brown adipocytes combust excess chemical energy and release in the form of heat through uncoupled respiration. This characteristic phenomenon of brown fat attracts researchers and pharmacological industries to view brown fat as one of the potential therapeutic targets for obesity and associated metabolic disease. In the current study, we investigated the effect of a small molecule, sesaminol (SML) on brown fat activity and found that SML induces the thermogenic program in primary white adipocytes as well as chow diet fed mice. In particular, SML treatment to mice elevated mitochondrial complex proteins and the rate of oxygen consumption in brown and white fat. Administration of SML to high fat diet (HFD) challenged mice decreased weight gain, adiposity and cholesterol levels along with an increase of brown fat gene program in brown and white fat. Mechanistically, SML repressed the myogenic gene program in C2C12 myoblasts and increased all mitochondrial marker genes as appeared in brown adipose cells. Together, our results demonstrate that SML stimulates brown adipose function and protects mice against diet-induced weight gain.

A rapid bead-based assay for screening of SARS-CoV-2 neutralizing antibodies.

Quantitative determination of neutralizing antibodies against Severe Acute Respiratory Syndrome Corona Virus-2 (SARS-CoV-2) is paramount in immunodiagnostics, vaccine efficacy testing, and immune response profiling among the vaccinated population. Cost-effective, rapid, easy-to-perform assays are essential to support the vaccine development process and immunosurveillance studies. We describe a bead-based screening assay for S1-neutralization using recombinant fluorescent proteins of hACE2 and SARS-CoV2-S1, immobilized on solid beads employing nanobodies/metal-affinity tags. Nanobody-mediated capture of SARS-CoV-2-Spike (S1) on agarose beads served as the trap for soluble recombinant ACE2-GFPSpark, inhibited by neutralizing antibody. The first approach demonstrates single-color fluorescent imaging of ACE2-GFPSpark binding to His-tagged S1-Receptor Binding Domain (RBD-His) immobilized beads. The second approach is dual-color imaging of soluble ACE2-GFPSpark to S1-Orange Fluorescent Protein (S1-OFPSpark) beads. Both methods showed a good correlation with the gold standard pseudovirion assay and can be adapted to any fluorescent platforms for screening.