Objective:To investigate the effects of the small molecule inhibitor of human antigen R (HuR)protein, MS-444 on intestinal fat absorption and triglyceride synthesis.Methods:MS-444 was administered by enema to normal chow diet(NCD)and high-fat diet(HFD)mouse models.Key indicators including body weight, serum triglycerides(TAG), serum free fatty acids(FFA), hepatic lipid deposition, and adipose tissue weights were measured.Additionally, the impact of MS-444 on intestinal lipid absorption and the triglyceride synthesis enzymes diacylglycerol acyltransferase 2 (DGAT2)and monoacylglycerol acyltransferase 2(MGAT2)were also assessed.Results:The study demonstrated that MS-444 enema markedly reduced serum TAG and FFA levels in both NCD-and HFD-fed mice [NCD mice TAG: (0.854±0.145)mmol vs.(0.608±0.120)mmol, P=0.032, NCD mice FFA: (0.650±0.119)mmol vs.(0.432±0.106)mmol, P=0.032; HFD mice TAG: (1.410±0.254)mmol vs.(0.704±0.132)mmol, P=0.008, HFD mice FFA: (1.202±0.195)mmol vs.(0.772±0.102)mmol, P=0.008], as well as hepatic lipid deposition [(14.300±0.704)μmol/g vs.(7.640±1.584)μmol/g, P=0.008] in HFD-fed mice.MS-444 modulated intestinal fat absorption by lowering TAG levels[(10.350±2.046)μmol/g vs.(6.802±2.037)μmol/g, P=0.031], while elevating intestinal FFA levels[(5.746±1.433)μmol/g vs.(8.050±1.121)μmol/g, P=0.032]. Mechanistically, MS-444 significantly inhibited the interaction between HuR and the enzymes DGAT2 and MGAT2 in the proximal small intestine, leading to downregulation of their mRNA and protein expression, thereby inhibiting intestinal triglyceride synthesis. Conclusions:MS-444 can alleviate HFD-induced non-alcoholic fatty liver disease(NAFLD)and obesity by reducing intestinal fat absorption.The functional interaction between HuR and the enzymes DGAT2 and MGAT2 may play a key regulatory role, indicating the therapeutic potential application value of MS-444 in metabolic disorders.

Objective:To investigate the effects of the small molecule inhibitor of human antigen R (HuR)protein, MS-444 on intestinal fat absorption and triglyceride synthesis.Methods:MS-444 was administered by enema to normal chow diet(NCD)and high-fat diet(HFD)mouse models.Key indicators including body weight, serum triglycerides(TAG), serum free fatty acids(FFA), hepatic lipid deposition, and adipose tissue weights were measured.Additionally, the impact of MS-444 on intestinal lipid absorption and the triglyceride synthesis enzymes diacylglycerol acyltransferase 2 (DGAT2)and monoacylglycerol acyltransferase 2(MGAT2)were also assessed.Results:The study demonstrated that MS-444 enema markedly reduced serum TAG and FFA levels in both NCD-and HFD-fed mice [NCD mice TAG: (0.854±0.145)mmol vs.(0.608±0.120)mmol, P=0.032, NCD mice FFA: (0.650±0.119)mmol vs.(0.432±0.106)mmol, P=0.032; HFD mice TAG: (1.410±0.254)mmol vs.(0.704±0.132)mmol, P=0.008, HFD mice FFA: (1.202±0.195)mmol vs.(0.772±0.102)mmol, P=0.008], as well as hepatic lipid deposition [(14.300±0.704)μmol/g vs.(7.640±1.584)μmol/g, P=0.008] in HFD-fed mice.MS-444 modulated intestinal fat absorption by lowering TAG levels[(10.350±2.046)μmol/g vs.(6.802±2.037)μmol/g, P=0.031], while elevating intestinal FFA levels[(5.746±1.433)μmol/g vs.(8.050±1.121)μmol/g, P=0.032]. Mechanistically, MS-444 significantly inhibited the interaction between HuR and the enzymes DGAT2 and MGAT2 in the proximal small intestine, leading to downregulation of their mRNA and protein expression, thereby inhibiting intestinal triglyceride synthesis. Conclusions:MS-444 can alleviate HFD-induced non-alcoholic fatty liver disease(NAFLD)and obesity by reducing intestinal fat absorption.The functional interaction between HuR and the enzymes DGAT2 and MGAT2 may play a key regulatory role, indicating the therapeutic potential application value of MS-444 in metabolic disorders.