炎症相关因子在血管性痴呆发病机制中的作用

血管性痴呆（vascular dementia,VD）是指由各种脑血管病,包括缺血性脑血管病、出血性脑血管病及急性与慢性缺氧性脑血管病引起的脑功能障碍,进而产生认知功能障碍的临床综合征。血管性痴呆是一种慢性进行性疾病,被认为是仅次于阿尔兹海默症,导致痴呆的第2位原因。目前,血管性痴呆的发病机制尚不明确,有可能与炎症、神经元损伤、胆碱能系统功能障碍、脑白质病变及氧化应激等有关。其中,炎症反应在急性与慢性脑缺血继发性脑损伤中起主要作用。抑制炎症能改善血管性痴呆动物模型的症状,显示炎症可能在血管性痴呆发病机制中发挥重要作用。参与炎症反应的相关因子,如细胞因子等可对中枢神经系统造成损伤。同时,炎症相关因子会触发炎症级联反应,加重脑损伤。本文总结了有关炎症相关因子参与导致血管性痴呆的各种病理损害和促进其发生发展的分子机制的最新研究进展,这些都有助于了解炎症相关因子在血管性痴呆发病机制中的作用。     

microRNA在对乙酰氨基酚所致肝损伤中抗损伤作用研究进展

药物引起的急性肝损伤(drug-induced liver injury,DILI)是导致肝衰竭的重要原因,其中以对乙酰氨基酚(acetaminophen,APAP)最常见。microRNA为一类非编码小RNA,在肝脏中具有重要的生物学功能,其对APAP所致肝损伤过程中代谢损伤、炎症发展以及肝再生等病理过程具有显著调控作用,对APAP所致肝损伤(acetaminophen-induced liver injury,AILI)发生发展产生重要影响。APAP所致的肝损伤能引起不同种类microRNA含量的变化,其中多种microRNA表达含量的变化能抑制炎症的发展,减轻肝损伤程度,对肝组织起保护作用。这属于机体应对损伤刺激时所表现的自我保护性机制。本文对在AILI中具有抗损伤作用的microRNA相关研究进行综述,并总结microRNA作用靶点与调控机制。     

实验性自身免疫性葡萄膜炎模型中肝脏免疫系统紊乱的研究（英文）

葡萄膜炎是一种反复发作的炎症性疾病,可导致免疫系统功能障碍和多器官损伤.然而,葡萄膜炎是否导致肝功能损害尚不十分清楚.本文通过运用流式分析技术和激光共聚焦成像技术,研究了实验性自身免疫葡萄膜炎模型的肝脏病理和功能变化.结果显示肝损伤可出现在葡萄膜炎的炎症后期并与眼损伤程度相关.并且CD3~+CD4~+T细胞、CD3~-NK1.1~+DX5~-NK细胞、和CD11b~~+F4/80~-ly6c~+细胞在感染的眼睛和肝脏中增加.将CD3~+CD4~+T细胞回输给炎症的小鼠后,眼睛和肝脏的病理损伤加重.此外,在炎症的小鼠中可见血管扩张,大量淋巴细胞浸润到炎症的眼和肝脏的血管周围.总之,我们的研究结果提示,肝损伤可以发生在小鼠葡萄膜炎模型中,这种损伤可能与通过外周循环浸润到肝脏的CD3~+CD4~+T细胞有关.     

DNA损伤修复蛋白在炎症免疫反应中的作用

细胞代谢或细胞应激均可以引起DNA损伤。DNA损伤可以引起一系列级联反应即DNA损伤反应。炎症免疫反应是活体组织对损伤因子所起的防御反应。DNA损伤反应与炎症的发生发展密切相关,而DNA损伤修复蛋白在免疫系统中具有重要作用。本文将就DNA损伤修复蛋白在炎症免疫反应中的作用及其机制进行综述。     

脓毒症致凝血异常发生机制的研究进展

脓毒症是由感染引起的全身炎症反应综合征,其病情凶险,死亡率高。凝血异常是脓毒症的主要特点之一,是多方面因素共同作用的结果。在脓毒症的发生发展过程中,炎症因子既可以激活凝血级联反应又可以抑制抗凝系统和纤维蛋白溶解系统,最终导致其凝血活性增强,炎症诱导的凝血紊乱进一步促进和加重炎症反应。而脓毒症患者的高凝状态可导致静脉血栓栓塞甚至DIC的发生,引起了研究者们的广泛关注。本文将就脓毒症致凝血异常发生机制的研究进展做一综述。     

白细胞介素-6在酒精性肝病中的作用

酒精性肝病（alcoholic liver disease,ALD）是由于长期过量饮酒导致肝的内部组织发生炎症损伤的慢性肝病。乙醇及其衍生物在代谢过程中直接或间接诱导引起的肝炎症反应可能是ALD发病的重要机制。然而,该过程内在的细胞分子机制尚不明确。最新研究发现,白细胞介素-6（interleukin-6,IL-6）对乙醇介导的肝细胞炎症反应具有双重作用,既参与了酒精损伤的炎症驱动过程,激活细胞凋亡的信号通路来刺激巨噬细胞和淋巴细胞合成急性反应蛋白加剧炎症反应,又能引起肝细胞再生,上调抗炎性细胞因子水平,发挥抗炎症功能来改善肝损伤程度。而运动应激可造成肌源性IL-6暂时性显著增加,改变肝的氧化-炎症状态,将机体保持在长期抗炎症的适应性状态中,并防治肝细胞炎症损伤。本文在加深对酒精性肝病炎症病理机制理解的同时,综述有关酒精性肝细胞炎症相关因子变化及IL-6调控途径。考虑临床利用IL-6联合炎性因子途径的靶向治疗,将有望成为一种可行性新颖的疗法,有利于实验室筛选炎症相关酒精性肝病干预药物,为酒精性肝疾病的预防与治疗提供新的靶点与思路。     

体外肝细胞损伤模型分子机制探讨

肝损伤是临床常见的危害人类健康的疾病,是各种原因引起肝脏疾病的共同的表现,也是各型肝病共同的病理基础。建立稳定可靠体外肝细胞损伤模型,对于肝损伤病理机制研究及有效防治肝损伤药物筛选提供了前提。针对肝细胞损伤分子机制不同,目前已成功建立基于免疫损伤、氧化损伤、脂肪损伤等体外肝细胞损伤模型,用于临床药物筛选及疗效作用机制研究,本文对目前常见体外肝细胞损伤模型及其发生的分子生物学机制进行探讨。     

间充质干细胞与肝缺血再灌注损伤

肝脏手术中普遍发生的缺血再灌注损伤(IRI)可导致肝脏功能损害,目前尚缺乏确切有效的治疗手段。肝脏IRI的机制复杂,炎症反应失衡主导的损伤继发于肝脏理化损害之后,并具有全身性的特点。间充质干细胞(MSC)所具备的免疫调节功能与肝脏IRI中免疫失衡这一重要病理生理过程相契合,凭借其易获取、低免疫源性的特点,故可尝试用于IRI的治疗。目前多项试验初步验证了其有效性,但确切机制有待进一步明确。可见,MSC用于肝脏IRI的治疗拓展了细胞治疗的应用范围,并为肝脏IRI提供了可能的治疗手段。     

研究报告: 实验性自身免疫性葡萄膜炎模型中肝脏免疫系统紊乱的研究

葡萄膜炎是一种反复发作的炎症性疾病,可导致免疫系统功能障碍和多器官损伤．然而,葡萄膜炎是否导致肝功能损害尚不十分清楚．本文通过运用流式分析技术和激光共聚焦成像技术,研究了实验性自身免疫葡萄膜炎模型的肝脏病理和功能变化．结果显示肝损伤可出现在葡萄膜炎的炎症后期并与眼损伤程度相关．并且CD3⁺ CD4⁺ T细胞、CD3^- NK1.1⁺ DX5^- NK细胞、和CD11b⁺ F4/80^- ly6c⁺ 细胞在感染的眼睛和肝脏中增加．将CD3⁺ CD4⁺ T细胞回输给炎症的小鼠后,眼睛和肝脏的病理损伤加重．此外,在炎症的小鼠中可见血管扩张,大量淋巴细胞浸润到炎症的眼和肝脏的血管周围．总之,我们的研究结果提示,肝损伤可以发生在小鼠葡萄膜炎模型中,这种损伤可能与通过外周循环浸润到肝脏的CD3⁺ CD4⁺ T细胞有关．     

JNK信号传导通路在胆汁淤积性肝损伤机制中的作用

胆汁淤积性肝损伤是严重影响人类肝脏健康的慢性疾病,病因复杂。JNK信号通路在细胞分化、细胞凋亡、应激反应及多种疾病的发生与发展中起到重要的作用。近些年来发现c-Jun氨基末端激酶(c-Jun N-terminal kinase,JNK)在各种肝损伤的分子机制中均起到重要作用,且在胆汁淤积导致的肝损伤机制中也有参与。本文简述了JNK通路结构及功能,并对JNK通路在胆汁淤积性肝损伤中的作用、影响因素及研究进展进行了总结与分析。     

Tle1 attenuates hepatic ischemia/reperfusion injury by suppressing NOD2/NF-κB signaling

ABSTRACT

Liver damage induced by ischemia/reperfusion (I/R) remains a primary issue in multiple hepatic surgeries. Innate immune-mediated inflammatory responses during the reperfusion stage aggravate the injury. Nevertheless, the detailed mechanism of hepatic I/R has not been fully clarified yet. Our research focuses on the role of Transducin-like enhancer of split-1 (Tle1) in the liver I/R injury and the relation between Tle1 and Nucleotide-binding oligomerization domain 2 (NOD2). To answer these questions, we constructed mouse models of I/R and cell models of hypoxia/reoxygenation (H/R). We found decreased Tle1 accompanied by increased NOD2 during reperfusion. Mice pro-injected with Tle1-siRNA emerged aggravated liver dysfunction. Repression of Tle1 had a significant impact on NOD2 and downstream NF-κB signaling in vitro. However, alteration of NOD2 failed to affect the expression of Tle1. To conclude, our study demonstrates that Tle1 shelters the liver from I/R injury through suppression of NOD2-dependent NF-κB activation and subsequent inflammatory responses.     

Inflammatory, hemostatic, and clinical changes in a baboon experimental model for heatstroke.

The mortality and neurological morbidity in heatstroke have been attributed to the host's inflammatory and hemostatic responses to heat stress, suggesting that immunomodulation may improve outcome. We postulated that an experimental baboon model of heatstroke will reproduce human responses and clinical outcome to allow testing of new therapeutic strategies. Eight anesthetized juvenile baboons (Papio hamadryas) were subjected to heat stress in an incubator maintained at 44-47 degrees C until rectal temperature attained 42.5 degrees C (moderate heatstroke; n = 4) or systolic arterial pressure fell to <90 mmHg (severe heatstroke; n = 4) and were allowed to recover at room temperature. Four sham-heated animals served as a control group. Rectal temperature at the end of heat stress was 42.5 +/- 0.0 and 43.3 +/- 0.1 degrees C, respectively. All heat-stressed animals had systemic inflammation and activated coagulation, indicated by increased plasma IL-6, prothrombin time, activated partial thromboplastin time, and D-dimer levels, and decreased platelet count. Biochemical markers and/or histology evidenced cellular injury/dysfunction: plasma levels of thrombomodulin, creatinine, creatine kinase, lactic dehydrogenase, and alanine aminotransferase were increased, and varying degrees of tissue damage were present in liver, brain, and gut. No baboon with severe heatstroke survived. Neurological morbidity but no mortality was observed in baboons with moderate heatstroke. Nonsurvivors displayed significantly greater coagulopathy, inflammatory activity, and tissue injury than survivors. Sham-heated animals had an uneventful course. Heat stress elicited distinct patterns of inflammatory and hemostatic responses associated with outcome. The baboon model of heatstroke appears suitable for testing whether immunomodulation of the host's responses can improve outcome.     

Prediction of immune factors and signaling pathways in lung injury induced by LPS based on network analysis

ObjectiveTo construct a regulatory network involved in acute lung injury, so as to provide a new theoretical basis and research ideas for studying the relationship between inflammatory factors and immune proteins to collectively regulate the occurrence of acute lung injury.MethodBy using Meta-analysis, GO, KEGG and other methods notarized and constructed the regulatory network pathways of cytokine cascade and lung injury induced by LPS.ResultsThe result of Meta-analysis showed that the correlation between CD14, TNF-α, IL-6 gene and acute lung injury was statistically significant. GO analysis and KEGG analysis showed that acute lung injury contained CD14, TNF-α, IL-6 and other involved factors in the induced process of LPS, these inflammatory factors and immune proteins jointly regulate the process of disease development.ConclusionCD14 receptor is an important receptor involved in mediating LPS-activated cells, and is a high-affinity LPS receptor. LPS stimulates inflammatory effector cells to bind to LPS receptor- CD14 to activate intracellular signal cascade. Direct or indirect involvement of pathogenic factors enable cytokine caused by induction form a particularly complex network of cytokine regulatory pathways, of which the inflammatory factors TNF-α and IL-6 are simultaneously involved in LPS-mediated and CD14-mediated cytokine cascades.     

Moderate hypothermia suppressed excessive generation of superoxide anion radical and inflammatory reactions in blood and liver in heatstroke: Laboratory study in rats

Abstract

The study was performed to demonstrate superoxide radical (O₂·–) generation, systemic inflammation and liver injury caused by heatstroke and to reveal suppressive effects of moderate hypothermia. Heatstroke was defined as achieving pharyngeal temperature of 40°C with arterial pressure reduction. Heatstroke rats were divided to four groups by the temperature after the onset; 40°C, 37°C, 32°C and sham-treated with 37°C. O₂·– current was measured continuously in the right atrium using an electrochemical O₂·– senor. The O₂·– current increased in all groups except for the sham-treated group during the induction. After the onset of heatstroke, the O₂·– current was suppressed with temperature-dependency. Plasma and liver high-mobility group box 1, intercellular adhesion molecule-1, plasma aspartate aminotransferase and alanine aminotransferase were also suppressed with the suppression of O₂·– generation. Therefore, excessive O₂·– generation might be a key factor in heatstroke and the suppression with moderate hypothermia would be a therapeutic modality.     

Proteomic analysis of hypothalamic injury in heatstroke rats

Ischemic and oxidative damage to the hypothalamus may be associated with decreased heat tolerance as well as heatstroke formation. The present study explores the hypothalamic proteome mechanisms associated with heatstroke‐mediated hypothalamic ischemia, and oxidative damage. Heatstroke rats had hypotension, hypothalamic ischemia, and lethality. In addition, they had hyperthermia and hypothalamic blood–brain–barrier disruption, oxidative stress, activated inflammation, and neuronal apoptosis and degeneration. 2DE combined LC‐MS/MS revealed that heatstroke‐induced ischemic injury and apoptosis were associated with upregulation of L‐lactate dehydrogenase but downregulation of both dihydropyriminase‐related protein and 14‐3‐3 Zeta isoform protein. Heat‐induced blood–brain–barrier disruption might be related to upregulation of glial fibrillary acidic protein. Oxidative stress caused by heatstroke might be related to upregulation of cytosolic dehydrogenase‐1. Also, heat‐induced overproduction of proinflammatory cytokines might be associated with downregulation of stathmin 1. Heat‐induced hypothalamic ischemia, apoptosis, injury (or upregulation of L‐lactate dehydrogenase), blood–brain–barrier disruption (or upregulation of glial fibrillary acidic protein), oxidative stress (or upregulation of cytosolic dehydrogenase‐1), and activated inflammation (or downregulation of stathmin 1) were all significantly reversed by whole body cooling. Our data indicate that cooling therapy improves outcomes of heatstroke by modulating hypothalamic proteome mechanisms.     

Molecular mechanisms of hepatic apoptosis

Apoptosis is a prominent feature of liver diseases. Causative factors such as alcohol, viruses, toxic bile acids, fatty acids, drugs, and immune response, can induce apoptotic cell death via membrane receptors and intracellular stress. Apoptotic signaling network, including membrane death receptor-mediated cascade, reactive oxygen species (ROS) generation, endoplasmic reticulum (ER) stress, lysosomal permeabilization, and mitochondrial dysfunction, is intermixed each other, but one mechanism may dominate at a particular stage. Mechanisms of hepatic apoptosis are complicated by multiple signaling pathways. The progression of liver disease is affected by the balance between apoptotic and antiapoptotic capabilities. Therapeutic options of liver injury are impacted by the clear understanding toward mechanisms of hepatic apoptosis.     

Neutrophils induce paracrine telomere dysfunction and senescence in ROS‐dependent manner

Cellular senescence is characterized by an irreversible cell cycle arrest as well as a pro‐inflammatory phenotype, thought to contribute to aging and age‐related diseases. Neutrophils have essential roles in inflammatory responses; however, in certain contexts their abundance is associated with a number of age‐related diseases, including liver disease. The relationship between neutrophils and cellular senescence is not well understood. Here, we show that telomeres in non‐immune cells are highly susceptible to oxidative damage caused by neighboring neutrophils. Neutrophils cause telomere dysfunction both in vitro and ex vivo in a ROS‐dependent manner. In a mouse model of acute liver injury, depletion of neutrophils reduces telomere dysfunction and senescence. Finally, we show that senescent cells mediate the recruitment of neutrophils to the aged liver and propose that this may be a mechanism by which senescence spreads to surrounding cells. Our results suggest that interventions that counteract neutrophil‐induced senescence may be beneficial during aging and age‐related disease.     

Proteomic identification of hippocalcin and its protective role in heatstroke-induced hypothalamic injury in mice

Heatstroke is a devastating condition that is characterized by severe hyperthermia and central nervous system dysfunction. However, the mechanism of thermoregulatory center dysfunction of the hypothalamus in heatstroke is unclear. In this study, we established a heatstroke mouse model and a heat-stressed neuronal cellular model on the pheochromocytoma-12 (PC12) cell line. These models revealed that HS promoted obvious neuronal injury in the hypothalamus, with high pathological scores. In addition, PC12 cell apoptosis was evident by decreased cell viability, increased caspase-3 activity, and high apoptosis rates. Furthermore, 14 differentially expressed proteins in the hypothalamus were analyzed by fluorescence two-dimensional difference gel electrophoresis and identified by matrix-assisted laser desorption ionization time-of-flight mass spectrometry. Expression changes in hippocalcin (HPAC), a downregulated neuron-specific calcium-binding protein, were confirmed in the hypothalamus of the heatstroke mice and heat-stressed PC12 cells by immunochemistry and western blot. Moreover, HPAC overexpression and HPAC-targeted small interfering RNA experiments revealed that HPAC functioned as an antiapoptotic protein in heat-stressed PC12 cells and hypothalamic injury. Lastly, ulinastatin (UTI), a cell-protective drug that is clinically used to treat patients with heatstroke, was used in vitro and in vivo to confirm the role of HPAC; UTI inhibited heat stress (HS)-induced downregulation of HPAC expression, protected hypothalamic neurons and PC12 cells from HS-induced apoptosis and increased heat tolerance in the heatstroke animals. In summary, our study has uncovered and demonstrated the protective role of HPAC in heatstroke-induced hypothalamic injury in mice.     

Mechanisms of cadmium-mediated acute hepatotoxicity

The mechanism of cadmium-mediated acute hepatotoxicity has been the subject of numerous investigations and although some uncertainties persist, sufficient evidence has emerged to provide a reasonable account of the toxic process. Acute hepatotoxicity involves two pathways, one for the initial injury produced by direct effects of cadmium and the other for the subsequent injury produced by inflammation. Primary injury appears to be caused by the binding of Cd2+ to sulfhydryl groups on critical molecules in mitochondria. Thiol group inactivation causes oxidative stress, the mitochondrial permeability transition, and mitochondrial dysfunction. Although cadmium may injure hepatocytes directly, there are compelling reasons to believe that hepatocellular injury is produced in vivo as the result of ischemia caused by damage to endothelial cells. Secondary injury from acute cadmium exposure is thought to occur from the activation of Kupffer cells and a cascade of events involving several types of liver cells and a large number of inflammatory and cytotoxic mediators. In this regard, it is clear that Kupffer cell activation and neutrophil infiltration are important events in the toxic process, and the involvement of proinflammatory cytokines and chemokines has also been implicated. The precise roles of the soluble mediators of inflammation warrant further investigation.     

Mtu1-Mediated Thiouridine Formation of Mitochondrial tRNAs Is Required for Mitochondrial Translation and Is Involved in Reversible Infantile Liver Injury

Reversible infantile liver failure (RILF) is a unique heritable liver disease characterized by acute liver failure followed by spontaneous recovery at an early stage of life. Genetic mutations in MTU1 have been identified in RILF patients. MTU1 is a mitochondrial enzyme that catalyzes the 2-thiolation of 5-taurinomethyl-2-thiouridine (τm⁵s²U) found in the anticodon of a subset of mitochondrial tRNAs (mt-tRNAs). Although the genetic basis of RILF is clear, the molecular mechanism that drives the pathogenesis remains elusive. We here generated liver-specific knockout of Mtu1 (Mtu1^LKO) mice, which exhibited symptoms of liver injury characterized by hepatic inflammation and elevated levels of plasma lactate and AST. Mechanistically, Mtu1 deficiency resulted in a loss of 2-thiolation in mt-tRNAs, which led to a marked impairment of mitochondrial translation. Consequently, Mtu1^LKO mice exhibited severe disruption of mitochondrial membrane integrity and a broad decrease in respiratory complex activities in the hepatocytes. Interestingly, mitochondrial dysfunction induced signaling pathways related to mitochondrial proliferation and the suppression of oxidative stress. The present study demonstrates that Mtu1-dependent 2-thiolation of mt-tRNA is indispensable for mitochondrial translation and that Mtu1 deficiency is a primary cause of RILF. In addition, Mtu1 deficiency is associated with multiple cytoprotective pathways that might prevent catastrophic liver failure and assist in the recovery from liver injury.