Object Recent studies have demonstrated the epigenetic regulation of immune responses. However, the potential role of N6-methyladenosine methylation (m6A) in the tumor microenvironment (TME) remains unknown. Method In this study, the m6A modification patterns of LUAD samples were comprehensively evaluated by combining TCGA and GEO data, while these modification patterns were systematically linked to the characteristics of immune infiltrating cells in TME. The m6A score was constructed using the principal component analysis algorithm to quantify the m6A modification mode of a single tumor. Result There were three distinct patterns of m6A modification identified. The characteristics of TME cell infiltration in these three patterns were highly consistent with these three immune phenotypes of the tumors, including immune rejection, immune-inflammatory, and immune inert phenotypes. Low m6A scores were characterized by immune activation and poor survival rate. Besides, m6A scores were associated with tumor mutational load (TMB) and were able to increase the ability of TMB to predict immunotherapy. Two immunotherapy cohorts confirmed that the patients with lower m6A scores demonstrated significant therapeutic advantages and clinical benefits. m6A modifications play an important role in the development of TME diversity. Assessing the m6A modification pattern of individual tumors can deepen the understanding as to the characteristics of TME infiltration and guide more effective immunotherapy strategies.
Solid‐state lithium‐metal batteries have been identified as a strategic research direction for the electric vehicle industry because of their promising high energy density and potential characteristic safety. However, the intrinsic mechanical properties of solid materials cause inevitable electro‐chemo‐mechanical failure of electrodes and electrolytes during charging and discharging; these failure mechanisms include lithium penetration and formation of cracks and voids, which pose a serious challenge for the long cycle life of solid‐state lithium‐metal batteries. Here, a short overview of the recent advances with a view to understand this challenge is provided. Furthermore, new insights into the cross‐talk behavior between the cathode and lithium‐metal anode are provided based on the non‐uniform Li+ flux inducing interactional electro‐chemo‐mechanical failure. Furthermore, guidelines for designing stable solid‐state lithium‐metal batteries and research directions to figure out the interelectrode‐talk‐related electro‐chemo‐mechanical failure mechanism are presented, which can be significant for accelerating the development of solid‐state lithium batteries.
Vascular endothelial barrier dysfunction is the most prominent manifestation and important cause of mortality in infectious acute lung injury (ALI). Exogenous apelin is effective in ameliorating lipopolysaccharide (LPS)-induced inflammatory response in ALI lungs, reducing exudation of lung tissue and decreasing mortality. This study set out to investigate the association between apelin and Friend leukemia integration-1 (Fli-1) in the prevention and treatment of ALI, and to elucidate the molecular mechanism by which apelin protects the permeability of the vascular endothelial barrier. At the vivo functional level, lung wet/dry weight ratio was used to detect whole lung permeability, evans blue assay and dual fluorescent protein tracking assay were used to detect lung vascular endothelial permeability, HE staining to observe the inflammatory status of lung tissue, and immunofluorescence staining for VE-cadherin expression levels in blood vessels. The changes in inflammatory factors in bronchoalveolar lavage fluid (BALF) were detected by ELASA. Western blot was used to detect the expression level of proteins. qRT-PCR was performed to detect changes in mRNA expression of Fli-1 and adherent junction-related proteins. The correlation analysis of Fli-1 with vascular endothelial permeability and SRC showed that Fli-1 participated in the process of ALI. After preventive and therapeutic treatment of ALI mice with exogenous apelin, Fli-1, APJ, VE-cadherin, phosphorylated-VE-cadherin (p-VE-cadherin) and β-catenin were up-regulated, while SRC, phosphorylated-SRC (p-SRC), VEGF and VEGF-R were down-regulated, which indicated that the stability of vascular endothelial barrier was enhanced. With the use of Fli-1 inhibitor irinotecan, the protective effect of apelin was weakened in various functional indexes, genes and proteins. The lung was maintained at the level of the injury. Our research shows that Fli-1 is involved in the LPS-induced ALI process. The molecular mechanism for apelin in preventing endothelial barrier dysfunction in ALI is through up-regulating Fli-1, thus regulating adherens junction-related proteins, and finally recovering the endothelial barrier function.
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