白藜芦醇抑制肠癌细胞焦亡的作用*

目的: 研究白藜芦醇(Res)对肠癌细胞焦亡的影响。方法: ①葡聚糖硫酸钠(DSS)诱发小鼠结肠癌(CRC)实验:30只C57BL/6小鼠随机分为正常对照组(Contro组),氧化偶氮甲烷(AOM)组,AOM/DSS组,AOM/DSS+Res组和Res组,每组6只,造模周期共70 d。第1周第1日对AOM组、AOM/DSS组和AOM/DSS+Res组小鼠AOM(10 mg/kg)腹腔注射一次,无菌水饮水,1% DSS水供AOM/DSS组和AOM/DSS+Res组饮用,对AOM/DSS+Res组和Res组小鼠灌胃给予Res(50 mg/kg),造模结束后,取小鼠结肠组织固定、包埋、切片; IHC和Western blot检测小鼠结肠组织NLRP3、Caspase-1、IL-18蛋白表达情况。②离体实验:HCT 116细胞给予Res(2.4 μg/L)以及转染miR-31,加Res实验分为4组,分别标记0 h、12 h、24 h、48 h组;细胞转染分组为5组,即control组、miR-31 mimic组、miR-31 mimic+Res组、miR-31inhibitor组、miR-31inhibitor+Res组,48 h后收集细胞,每组设置三个复孔,并通过Western blot检测细胞NLRP3、Caspase-1、GSDMD-N、IL-18和IL-1β蛋白表达情况。结果: 动物实验:与control组相比较,AOM/DSS组NLRP3、Caspase-1、IL-18蛋白表达显著升高(P<0.01),AOM/DSS+Res组NLRP3、Caspase-1、IL-18蛋白表达水平相较于AOM/DSS组有显著下降(P<0.01);细胞实验:与control组相比,miR-31 mimic组NLRP3(P<0.01)、GSDMD-N(P<0.05)、IL-18(P<0.01)蛋白表达显著升高, miR-31 inhibitor组NLRP3、GSDMD-N、IL-18蛋白表达显著降低(P<0.05)。结论: Res可通过细胞焦亡抑制结肠癌。     

MCC950对脑出血大鼠神经损伤的作用*

目的: 研究NLRP3炎性小体抑制剂MCC950对脑出血(ICH)大鼠神经损伤的作用。方法: 72只SD大鼠随机分为3组(n=24):sham组、ICH组和MCC950组。ICH组和MCC950组采用自体非抗凝血注射方法建立大鼠脑出血模型后,给予MCC950组大鼠腹腔注射MCC950 10 mg/kg(2 mg/ml),连续给药3 d。模型建立72 h后,进行前肢放置实验、转角实验和mNSS评分,观察ICH大鼠神经功能情况;新鲜脑组织切片,观察血肿体积变化情况;HE染色,观察脑组织病理学改变情况;干湿比重法,观察脑组织水肿变化情况;FJC染色,观察神经元退化的情况;TUNEL染色,观察神经元凋亡情况;Western blot,观察NLRP3、ASC、caspase-1、IL-1β、IL-18、GSDMD蛋白表达及激活水平的情况。结果: 与sham组比较,ICH组大鼠左前肢放置成功百分比和左侧转身百分比显著下降(P＜0.01,P＜0.05),mNSS评分显著升高(P＜0.01),右侧脑内血肿体积显著增大,血肿周围脑组织中小胶质细胞数量增加,神经元数量减少,神经细胞肿胀,排布不均,部分细胞固缩性坏死,染色加深,右侧基底部含水量显著增多(P＜0.05),血肿周围脑组织中FJC阳性和TUNEL阳性细胞数量显著增加(P＜0.05),NLRP3、ASC、caspase-1、pro-caspase-1、caspase-1/pro-caspase-1比值、GSDMD-N、GSDMD、GSDMD-N/GSDMD比值、IL-1β和IL-18水平显著升高(P＜0.01,P＜0.05)。与ICH组比较,MCC950组大鼠左前肢放置成功百分比和左侧转身百分比显著升高(P＜0.05),mNSS评分显著降低(P＜0.01),右侧脑内血肿体积显著减小,血肿周围脑组织中神经细胞肿胀显著减轻,固缩坏死细胞数量减少,右侧基底含水量显著减少(P＜0.05),血肿周围脑组织中FJC阳性和TUNEL阳性细胞数量显著减少(P＜ 0.05),NLRP3、ASC、caspase-1、pro-caspase-1、caspase-1/pro-caspase-1比值、GSDMD-N、GSDMD、GSDMD-N/GSDMD比值、IL-1β和IL-18水平显著降低(P＜0.05)。结论: MCC950可以通过抑制NLRP3炎性小体介导的炎症反应和细胞焦亡改善ICH后的神经损伤。     

Caspase-6 promotes activation of the caspase-11-NLRP3 inflammasome during gram-negative bacterial infections

The innate immune system acts as the first line of defense against infection. One key component of the innate immune response to gram-negative bacterial infections is inflammasome activation. The caspase-11 (CASP11)-nucleotide-binding oligomerization domain-like receptor pyrin domain-containing 3 (NLRP3) inflammasome is activated by cytosolic lipopolysaccharide, a gram-negative bacterial cell wall component, to trigger pyroptosis and host defense during infection. Although several cellular signaling pathways have been shown to regulate CASP11-NLRP3 inflammasome activation in response to lipopolysaccharide, the upstream molecules regulating CASP11 activation during infection with live pathogens remain unclear. Here, we report that the understudied caspase-6 (CASP6) contributes to the activation of the CASP11-NLRP3 inflammasome in response to infections with gram-negative bacteria. Using in vitro cellular systems with bone marrow-derived macrophages and 293T cells, we found that CASP6 can directly process CASP11 by cleaving at Asp59 and Asp285, the CASP11 auto-cleavage sites, which could contribute to the activation of CASP11 during gram-negative bacterial infection. Thus, the loss of CASP6 led to impaired CASP11-NLRP3 inflammasome activation in response to gram-negative bacteria. These results demonstrate that CASP6 potentiates activation of the CASP11-NLRP3 inflammasome to produce inflammatory cytokines during gram-negative bacterial infections.     

Caspase-1在炎症及程序性细胞死亡过程中的作用

Caspase家族是一类半胱氨酸天冬氨酸特异性蛋白酶,其中caspase-1是最先在哺乳动物细胞中被鉴定出来的家族成员,介导了某些特定类型细胞的凋亡。在微生物感染或细胞内危险信号存在时,caspase-1可通过与炎性体结合而发生激活,从而加工pro-IL-1β和pro-IL-18等炎症因子使其成熟并释放,在炎症反应中起着核心调控作用。此外,caspase-1还能介导一种特殊的促炎症的程序性细胞死亡(Pyroptosis)。caspase-1参与的炎症及程序性细胞死亡能有效提高机体抵抗内源和外源各种刺激的能力,达到保护宿主的目的,而caspase-1的功能异常则与多种疾病密切相关。     

Role of pyroptosis in cardiovascular disease

Cardiac function is determined by the dynamic equilibrium of various cell types and the extracellular matrix that composes the heart. Cardiovascular diseases (CVDs), especially atherosclerosis and myocardial infarction, are often accompanied by cell death and acute/chronic inflammatory reactions. Caspase‐dependent pyroptosis is characterized by the activation of pathways leading to the activation of NOD‐like receptors, especially the NLRP3 inflammasome and its downstream effector inflammatory factors interleukin (IL)‐1β and IL‐18. Many studies in the past decade have investigated the role of pyroptosis in CVDs. The findings of these studies have led to the development of therapeutic approaches based on the regulation of pyroptosis, and some of these approaches are in clinical trials. This review summarizes the molecular mechanisms, regulation and cellular effects of pyroptosis briefly and then discusses the current pyroptosis studies in CVD research.     

Gasdermin D is an executor of pyroptosis and required for interleukin-1β secretion

Inflammasome is an intracellular signaling complex of the innate immune system. Activation of inflammasomes promotes the secretion of interleukin 1β (IL-1β) and IL-18 and triggers pyroptosis. Caspase-1 and -11 (or -4/5 in human) in the canonical and non-canonical inflammasome pathways, respectively, are crucial for inflammasome-mediated inflammatory responses. Here we report that gasdermin D (GSDMD) is another crucial component of inflammasomes. We discovered the presence of GSDMD protein in nigericin-induced NLRP3 inflammasomes by a quantitative mass spectrometry-based analysis. Gene deletion of GSDMD demonstrated that GSDMD is required for pyroptosis and for the secretion but not proteolytic maturation of IL-1β in both canonical and non-canonical inflammasome responses. It was known that GSDMD is a substrate of caspase-1 and we showed its cleavage at the predicted site during inflammasome activation and that this cleavage was required for pyroptosis and IL-1β secretion. Expression of the N-terminal proteolytic fragment of GSDMD can trigger cell death and N-terminal modification such as tagging with Flag sequence disrupted the function of GSDMD. We also found that pro-caspase-1 is capable of processing GSDMD and ASC is not essential for GSDMD to function. Further analyses of LPS plus nigericin- or Salmonella typhimurium-treated macrophage cell lines and primary cells showed that apoptosis became apparent in Gsdmd^−/− cells, indicating a suppression of apoptosis by pyroptosis. The induction of apoptosis required NLRP3 or other inflammasome receptors and ASC, and caspase-1 may partially contribute to the activation of apoptotic caspases in Gsdmd^−/− cells. These data provide new insights into the molecular mechanisms of pyroptosis and reveal an unexpected interplay between apoptosis and pyroptosis.     

Effects of NIX‐mediated mitophagy on ox‐LDL‐induced macrophage pyroptosis in atherosclerosis

Pyroptosis is a form of cell death that is uniquely dependent on caspase‐1. Pyroptosis involved in oxidized low‐density lipoprotein (ox‐LDL)‐induced human macrophage death through the promotion of caspase‐1 activation is important for the formation of unstable plaques in atherosclerosis. The mitochondrial outer membrane protein NIX directly interacts with microtubule‐associated protein 1 light chain 3 (LC3). Although we previously showed that NIX‐mediated mitochondrial autophagy is involved in the clearance of damaged mitochondria, how NIX contributes to ox‐LDL‐induced macrophage pyroptosis remains unknown. Here, immunoperoxidase staining Nix expression decreased in human atherosclerosis. When we silenced NIX expression in murine macrophage cell, active caspase‐1, and mature interleukin‐1β expression levels were increased and LC3 was reduced. In addition, LDH release and acridine orange and ethidium bromide staining indicated that damage to macrophage cell membranes induced by ox‐LDL was substantially worse. Moreover, intracellular reactive oxygen species and NLRP3 inflammasome levels increased. Taken together, these results demonstrated that NIX inhibits ox‐LDL‐induced macrophage pyroptosis via autophagy in atherosclerosis.     

Activating Nrf2 signalling alleviates osteoarthritis development by inhibiting inflammasome activation

Osteoarthritis (OA), which is characterized by proliferation of subchondral bone and the degeneration of articular cartilage, is the most prevalent human arthritis. Nod‐like receptor pyrin domain 3 (NLRP3) inflammasome is a hot spot in recent year and has been reported to be associated with OA synovial inflammation. However, there are few studies on NLRP3 inflammasome in chondrocyte. Licochalcone A (Lico A), a compound extracted from Glycyrrhiza species, has various biological effects such as anti‐inflammation, anti‐apoptotic, anti‐cancer and anti‐oxidation. In this study, we investigated the protective effect of Lico A on chondrocytes stimulated by lipopolysaccharide (LPS) and surgically induced OA models. In vitro, Lico A could reduce the expression of NLRP3, apoptosis‐associated speck‐like protein (ASC), Gasdermin D (GSDMD), caspase‐1, interleukin‐1beta (IL‐1β) and IL‐18, which indicated that Lico A attenuates LPS‐induced chondrocytes pyroptosis. In addition, Lico A ameliorates the degradation of extracellular matrix (ECM) by enhancing the expression of aggrecan and collagen‐II. Meanwhile, we found that Lico A inhibits NLRP3 inflammasome via nuclear factor erythroid‐2‐related factor 2 (Nrf2)/haeme oxygenase‐1(HO‐1)/nuclear factor kappa‐B (NF‐κB) axis. And the Nrf2 small interfering RNA (siRNA) could reverse the anti‐pyroptosis effects of Lico A in mouse OA chondrocytes. In vivo, Lico A mitigates progression OA in a mouse model and reduces OA Research Society International (OARSI) scores. Thus, Lico A may have therapeutic potential in OA.     

Betulinic acid inhibits pyroptosis in spinal cord injury by augmenting autophagy via the AMPK-mTOR-TFEB signaling pathway

Spinal cord injury (SCI) results in a wide range of disabilities. Its complex pathophysiological process limits the effectiveness of many clinical treatments. Betulinic acid (BA) has been shown to be an effective treatment for some neurological diseases, but it has not been studied in SCI. In this study, we assessed the role of BA in SCI and investigated its underlying mechanism. We used a mouse model of SCI, and functional outcomes following injury were assessed. Western blotting, ELISA, and immunofluorescence techniques were employed to analyze levels of autophagy, mitophagy, pyroptosis, and AMPK-related signaling pathways were also examined. Our results showed that BA significantly improved functional recovery following SCI. Furthermore, autophagy, mitophagy, ROS level and pyroptosis were implicated in the mechanism of BA in the treatment of SCI. Specifically, our results suggest that BA restored autophagy flux following injury, which induced mitophagy to eliminate the accumulation of ROS and inhibits pyroptosis. Further mechanistic studies revealed that BA likely regulates autophagy and mitophagy via the AMPK-mTOR-TFEB signaling pathway. Those results showed that BA can significantly promote the recovery following SCI and that it may be a promising therapy for SCI.