摘要：Lipopolysaccharides (LPS) derived from intestinal symbionts plays a critical role in modulating and maintaining mucosal immunity. In this study, we investigated the chemical characteristics and antiobesity properties of Akkermansia muciniphila HW07 LPS (ALPS). ALPS was identified as hypo-acylated, mono/bis-phosphorylated, rough-type LPS. Compared to Escherichia coli LPS (ELPS), ALPS functions as a weak agonist of TLR4/TLR2. Intraperitoneal administration of ALPS in diet-induced obese (DIO) mice suppressed weight gain, improved metabolic parameters, restored gut barrier integrity, and modulated the gut microbiota. Notably, ALPS treatment significantly increased plasma interleukin (IL) -22 levels. Furthermore, neutralizing IL-22 with an antibody eliminated the antiobesity effects of ALPS in DIO mice. Mechanistically, ALPS upregulated the expression of both IL-22 and its upstream cytokine IL-23 in a TLR4-dependent manner. These findings confirm that activation of the TLR4?IL-23?IL-22 immune axis is a key mechanism underlying the antiobesity effect of ALPS. In acute toxicity assessment, no fatalities were observed in ALPS-treated mice, whereas ELPS treatment led to a 40% mortality rate. Collectively, our results demonstrate that hypo-acylated LPS from A. muciniphila functions as a metabolically beneficial immune modulator that exerts immunomodulatory effects through the TLR4?IL-22 axis and suggests ALPS as a promising novel therapeutic strategy for metabolic disorders.

 Cell Metabolism [IF=30.9]

Advanced Materials [IF=26.8]

文獻引用產品：

bs-5758R-BF555 | FAP Rabbit pAb, BF555 conjugated | IF

bs-10423R-BF647 | Collagen I Rabbit pAb | IF

作者單位：英國牛津大學

摘要：Cardiovascular diseases (CVDs) are the leading cause of death worldwide. However, the pathophysiological mechanisms of CVDs are not yet fully understood, and animal models do not accurately replicate human heart function. Heart-on-a-chip technologies with increasing complexity are being developed to mimic aspects of native human cardiac physiology for mechanistic studies and as screening platforms for drugs and nanomedicines. Here, a 3D human myocardial ischemia-on-a-chip platform incorporating perfusable vasculature in direct contact with myocardial regions is designed. Infusing a vasoconstrictor cocktail, including angiotensin II and phenylephrine, into this heart-on-a-chip model leads to increased arrhythmias in cardiomyocyte pacing, fibroblast activation, and damage to blood vessels, all of which are hallmarks of ischemic heart injury. To verify the potential of this platform for drug and nanocarrier screening, a proof-of-concept study is conducted with cardiac homing peptide-conjugated liposomes containing Alamandine. This nanomedicine formulation enhances targeting to the ischemia model, alleviates myocardial ischemia-related characteristics, and improves cardiomyocyte beating. This confirms that the vascularized chip model of human myocardial ischemia provides both functional and mechanistic insights into myocardial tissue pathophysiology and can contribute to the development of cardiac remodeling medicines.

Bioactive Materials [IF=20.3]