P21在慢性和急性肝损伤中的作用

Haksier Ehedego, C. Trautwein
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The NF-κB pathway regulator NEMO (also known as IKKγ) has been shown to control chronic inflammation and hepatocarcinogenesis in mice. \n \nThe hepatocyte specific deletion of NEMO (NEMOΔhepa), is of clinical interest as these animals develop a cascade of events which resemble the spectrum of human chronic liver disease, which leads from chronic hepatitis to liver cirrhosis and growth of hepatocellular carcinomas (HCC). Additionally, a recent study using human HCC tissue found a downregulation of NEMO in tumor tissue, further supporting the translational relevance of the NEMOΔhepa mice model [4]. \n \nThe deletion of NEMO in hepatocytes triggers increased p21 expression [5,6]. In order to study the relevance of p21 overexpression for disease progression of NEMOΔhepa livers, double knockout (NEMOΔhepa/p21−/−) mice carrying a hepatocyte specific deletion for NEMO and an additional constitutional deletion for p21 were generated. \n \nAlthough p21 is a cell cycle inhibitor its deletion had no impact on cell proliferation in 8 week-old NEMOΔhepa/p21−/− livers compared to NEMOΔhepa livers. This result was unexpected since p21 binds to CcnE/cdk2 and CcnA/cdk2 complexes thereby preventing progression from G1- to S-phase. Very likely the loss of p21 expression is compensated by other cell cycle inhibitors such as p-p27 and p18. \n \nDespite the unchanged cell cycle activity in p21 deficient NEMOΔhepa livers, the cell cycle regulator CcnA2 and CcnE2 were overexpressed. However, recent studies discovered that ectopic overexpression of CcnA or CcnE in mouse embryonic fibroblast (MEFs) lead to an increase in DNA double strand breakage [7]. Therefore the enhanced liver injury caused by exacerbation of DNA damage in p21-deficient NEMOΔhepa mice could be explained by elevated CcnA2 and CcnE2 expression. The DNA double strand breakage was quantified by pH2AX Immunofluorescence staining. \n \np21 is not only protective against DNA damage in the chronic liver injury model as challenging double mutant NEMOΔhepa/p21−/− mice with Lipopolysaccharide (LPS) enhanced DNA damage massively compared to NEMOΔhepa mice. After LPS administration NEMOΔhepa mice suffer from severe liver injury which is reflected in the increased alanine aminotransferase (ALT) and aspartataminotransferase (AST) serum values and apoptotic cells in the liver of these mice. However, in NEMOΔhepa/p21−/− mice transaminases and cell death were significantly enhanced. Finally, this enhanced liver injury in the double knockout animals resulted in a higher lethality of this mice after LPS administration. \n \nThe observed hypersensitivity against LPS due to the lack of p21 is mediated via the Tumor Necrosis Factor (TNF), since NEMOΔhepa/p21−/− mice which carry in addition a deletion for the TNF receptor 1 (NEMOΔhepa/p21−/−/TNF-R1−/−), showed a strong attenuation of the DNA damage and cell death. \n \nThe protective role of p21 in carcinogenesis was the first time visible in 26 week old knockout animals. Here, the double knockout mice (NEMOΔhepa/p21−/−) showed enhanced hepatocyte proliferation as revealed by Ki67 staining. This resulted consequently into a higher liver weight/body weight ratio but more interestingly p21- deficient NEMOΔhepa livers showed more frequently small tumors in comparison to NEMOΔhepa livers. \n \nFinally, a significantly increased number of HCCs were found in 52 week-old NEMOΔhepa/p21−/− animals, meaning that the loss of p21 expression caused exacerbation of hepatocarcinogenesis. Analysing the livers of these mice revealed that only the number of nodules was increased, whereas the sizes of the tumors were not significantly enlarged. This suggests that the loss of p21 overexpression in NEMOΔhepa animals has more impact on tumor initiation than on tumor progression. \n \nBeside hepatocarcinogenesis p21 had an additional protective role in cholestasis. Livers of 52 week old NEMOΔhepa/p21−/− animals display yellow inclusions and serum values for alkaline phosphatase, direct and total bilirubin confirmed the cholestatic phenotype. These cholestatic serum markers were significantly lower in NEMOΔhepa mice. \n \nTaken together, the enhanced p21 expression in NEMOΔhepa animals has a protective function in this model, as p21 protects against DNA damage, acceleration of hepatocarcinogenesis and cholestasis. Since liver disease progression is reduced in the presence of p21 expression, p21 has been shown to act as a tumor suppressor in the NEMOΔhepa model.","PeriodicalId":94164,"journal":{"name":"Oncoscience","volume":"108 1","pages":"56 - 57"},"PeriodicalIF":0.0000,"publicationDate":"2016-03-04","publicationTypes":"Journal Article","fieldsOfStudy":null,"isOpenAccess":false,"openAccessPdf":"","citationCount":"1","resultStr":"{\"title\":\"p21 in chronic and acute liver injury\",\"authors\":\"Haksier Ehedego, C. 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The NF-κB pathway regulator NEMO (also known as IKKγ) has been shown to control chronic inflammation and hepatocarcinogenesis in mice. \\n \\nThe hepatocyte specific deletion of NEMO (NEMOΔhepa), is of clinical interest as these animals develop a cascade of events which resemble the spectrum of human chronic liver disease, which leads from chronic hepatitis to liver cirrhosis and growth of hepatocellular carcinomas (HCC). Additionally, a recent study using human HCC tissue found a downregulation of NEMO in tumor tissue, further supporting the translational relevance of the NEMOΔhepa mice model [4]. \\n \\nThe deletion of NEMO in hepatocytes triggers increased p21 expression [5,6]. 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Therefore the enhanced liver injury caused by exacerbation of DNA damage in p21-deficient NEMOΔhepa mice could be explained by elevated CcnA2 and CcnE2 expression. The DNA double strand breakage was quantified by pH2AX Immunofluorescence staining. \\n \\np21 is not only protective against DNA damage in the chronic liver injury model as challenging double mutant NEMOΔhepa/p21−/− mice with Lipopolysaccharide (LPS) enhanced DNA damage massively compared to NEMOΔhepa mice. After LPS administration NEMOΔhepa mice suffer from severe liver injury which is reflected in the increased alanine aminotransferase (ALT) and aspartataminotransferase (AST) serum values and apoptotic cells in the liver of these mice. However, in NEMOΔhepa/p21−/− mice transaminases and cell death were significantly enhanced. 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引用次数: 1

摘要

P21一直被认为是一种肿瘤抑制因子,因为最初的研究表明P21−/−小鼠在16个月后自发形成肿瘤,而且这些小鼠对化学诱导的癌变更敏感[1,2]。相反,最近已经描述了p21作为致癌基因的潜在功能。例如,缺乏p53的小鼠会自发地发展为多发性肿瘤,p21的额外缺失会导致胸腺淋巴瘤的显著减少[3]。这表明p21在肿瘤发生过程中的完整功能谱尚未被清楚地确定。在NEMOΔhepa小鼠模型中进一步研究了p21的作用。NF-κB通路调节因子NEMO(也称为IKKγ)已被证明可以控制小鼠的慢性炎症和肝癌的发生。NEMO的肝细胞特异性缺失(NEMOΔhepa)具有临床意义,因为这些动物会发生一系列类似于人类慢性肝病的事件,从慢性肝炎到肝硬化和肝细胞癌(HCC)的生长。此外,最近一项使用人类HCC组织的研究发现肿瘤组织中NEMO下调,进一步支持NEMOΔhepa小鼠模型的翻译相关性[4]。肝细胞中NEMO的缺失会导致p21表达增加[5,6]。为了研究p21过表达与NEMOΔhepa肝脏疾病进展的相关性,产生了双敲除(NEMOΔhepa/p21−/−)小鼠,小鼠携带NEMO的肝细胞特异性缺失和p21的附加结构缺失。虽然p21是一种细胞周期抑制剂,但与NEMOΔhepa相比,它的缺失对8周龄NEMOΔhepa/p21−/−肝脏的细胞增殖没有影响。这一结果是出乎意料的,因为p21结合CcnE/cdk2和CcnA/cdk2复合物,从而阻止了从G1期到s期的进展。p21表达的缺失很可能被其他细胞周期抑制剂如p-p27和p18所补偿。尽管p21缺陷NEMOΔhepa肝脏的细胞周期活性不变,但细胞周期调节因子CcnA2和CcnE2过表达。然而,最近的研究发现,小鼠胚胎成纤维细胞(mef)中CcnA或CcnE的异位过表达会导致DNA双链断裂增加[7]。因此,p21缺陷NEMOΔhepa小鼠DNA损伤加重导致的肝损伤加重可能与CcnA2和CcnE2表达升高有关。pH2AX免疫荧光染色定量检测DNA双链断裂。p21不仅对慢性肝损伤模型中的DNA损伤具有保护作用,而且与NEMOΔhepa小鼠相比,脂多糖(LPS)对双重突变NEMOΔhepa/p21−/−小鼠的DNA损伤显著增强。LPS处理NEMOΔhepa小鼠肝脏损伤严重,表现为谷丙转氨酶(ALT)和天冬酰胺转氨酶(AST)血清值升高,肝脏细胞凋亡。然而,NEMOΔhepa/p21−/−小鼠的转氨酶和细胞死亡显著增强。最后,双敲除动物肝损伤的增强导致LPS给药后小鼠的死亡率更高。由于缺乏p21,观察到的对LPS的超敏反应是通过肿瘤坏死因子(TNF)介导的,因为NEMOΔhepa/p21−/−小鼠携带TNF受体1的缺失(NEMOΔhepa/p21−/−/TNF- r1−/−),显示出DNA损伤和细胞死亡的强烈衰减。p21在26周龄的基因敲除动物中首次显示出对肿瘤发生的保护作用。在这里,双基因敲除小鼠(NEMOΔhepa/p21−/−)通过Ki67染色显示肝细胞增殖增强。这导致肝脏重量/体重比更高,但更有趣的是,p21缺陷的NEMOΔhepa肝脏比NEMOΔhepa肝脏更频繁地显示小肿瘤。最后,在52周龄NEMOΔhepa/p21−/−动物中发现hcc数量显著增加,这意味着p21表达的丧失导致了肝癌发生的加剧。分析这些小鼠的肝脏显示,只有结节的数量增加,而肿瘤的大小没有明显增大。这表明NEMOΔhepa动物中p21过表达的缺失对肿瘤起始的影响大于对肿瘤进展的影响。除了肝癌发生外,p21在胆汁淤积中还具有额外的保护作用。52周龄NEMOΔhepa/p21−/−动物肝脏显示黄色包涵体,血清碱性磷酸酶、直接胆红素和总胆红素值证实胆汁淤积表型。这些胆汁淤积血清标志物在NEMOΔhepa小鼠中显著降低。综上所述,NEMOΔhepa动物中p21表达的增强在该模型中具有保护功能,因为p21可以防止DNA损伤、加速肝癌发生和胆汁淤积。 由于p21的表达减少了肝脏疾病的进展,p21在NEMOΔhepa模型中被证明是一种肿瘤抑制因子。
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p21 in chronic and acute liver injury
p21 historically has been considered a tumor suppressor since first studies showed that p21−/− mice display spontaneous tumor formation after 16 months and additionally these mice are more sensitive to chemically induced carcinogenesis [1,2]. On the contrary, recently a potential function as an oncogene has been described for p21. For instance mice deficient for p53 spontaneously develop multiple tumors and an additional deletion of p21 lead to a significant reduction of thymic lymphomas [3]. This argues that the complete spectrum of p21 function during tumorigenesis is not clearly identified. The role of p21 has been further studied in the NEMOΔhepa mice model. The NF-κB pathway regulator NEMO (also known as IKKγ) has been shown to control chronic inflammation and hepatocarcinogenesis in mice. The hepatocyte specific deletion of NEMO (NEMOΔhepa), is of clinical interest as these animals develop a cascade of events which resemble the spectrum of human chronic liver disease, which leads from chronic hepatitis to liver cirrhosis and growth of hepatocellular carcinomas (HCC). Additionally, a recent study using human HCC tissue found a downregulation of NEMO in tumor tissue, further supporting the translational relevance of the NEMOΔhepa mice model [4]. The deletion of NEMO in hepatocytes triggers increased p21 expression [5,6]. In order to study the relevance of p21 overexpression for disease progression of NEMOΔhepa livers, double knockout (NEMOΔhepa/p21−/−) mice carrying a hepatocyte specific deletion for NEMO and an additional constitutional deletion for p21 were generated. Although p21 is a cell cycle inhibitor its deletion had no impact on cell proliferation in 8 week-old NEMOΔhepa/p21−/− livers compared to NEMOΔhepa livers. This result was unexpected since p21 binds to CcnE/cdk2 and CcnA/cdk2 complexes thereby preventing progression from G1- to S-phase. Very likely the loss of p21 expression is compensated by other cell cycle inhibitors such as p-p27 and p18. Despite the unchanged cell cycle activity in p21 deficient NEMOΔhepa livers, the cell cycle regulator CcnA2 and CcnE2 were overexpressed. However, recent studies discovered that ectopic overexpression of CcnA or CcnE in mouse embryonic fibroblast (MEFs) lead to an increase in DNA double strand breakage [7]. Therefore the enhanced liver injury caused by exacerbation of DNA damage in p21-deficient NEMOΔhepa mice could be explained by elevated CcnA2 and CcnE2 expression. The DNA double strand breakage was quantified by pH2AX Immunofluorescence staining. p21 is not only protective against DNA damage in the chronic liver injury model as challenging double mutant NEMOΔhepa/p21−/− mice with Lipopolysaccharide (LPS) enhanced DNA damage massively compared to NEMOΔhepa mice. After LPS administration NEMOΔhepa mice suffer from severe liver injury which is reflected in the increased alanine aminotransferase (ALT) and aspartataminotransferase (AST) serum values and apoptotic cells in the liver of these mice. However, in NEMOΔhepa/p21−/− mice transaminases and cell death were significantly enhanced. Finally, this enhanced liver injury in the double knockout animals resulted in a higher lethality of this mice after LPS administration. The observed hypersensitivity against LPS due to the lack of p21 is mediated via the Tumor Necrosis Factor (TNF), since NEMOΔhepa/p21−/− mice which carry in addition a deletion for the TNF receptor 1 (NEMOΔhepa/p21−/−/TNF-R1−/−), showed a strong attenuation of the DNA damage and cell death. The protective role of p21 in carcinogenesis was the first time visible in 26 week old knockout animals. Here, the double knockout mice (NEMOΔhepa/p21−/−) showed enhanced hepatocyte proliferation as revealed by Ki67 staining. This resulted consequently into a higher liver weight/body weight ratio but more interestingly p21- deficient NEMOΔhepa livers showed more frequently small tumors in comparison to NEMOΔhepa livers. Finally, a significantly increased number of HCCs were found in 52 week-old NEMOΔhepa/p21−/− animals, meaning that the loss of p21 expression caused exacerbation of hepatocarcinogenesis. Analysing the livers of these mice revealed that only the number of nodules was increased, whereas the sizes of the tumors were not significantly enlarged. This suggests that the loss of p21 overexpression in NEMOΔhepa animals has more impact on tumor initiation than on tumor progression. Beside hepatocarcinogenesis p21 had an additional protective role in cholestasis. Livers of 52 week old NEMOΔhepa/p21−/− animals display yellow inclusions and serum values for alkaline phosphatase, direct and total bilirubin confirmed the cholestatic phenotype. These cholestatic serum markers were significantly lower in NEMOΔhepa mice. Taken together, the enhanced p21 expression in NEMOΔhepa animals has a protective function in this model, as p21 protects against DNA damage, acceleration of hepatocarcinogenesis and cholestasis. Since liver disease progression is reduced in the presence of p21 expression, p21 has been shown to act as a tumor suppressor in the NEMOΔhepa model.
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