大鼠肝癌发生过程中p53的突变和甲胎蛋白的表达

采用免疫组织化学ＡＢＣ和ＰＡＰ法,对二乙基亚硝胺（ＤＥＮ）诱发大鼠肝癌发生过程中突变型ｐ５３蛋白（ｍｐ５３）和甲胎蛋白（ＡＦＰ）在肝细胞中的表达进行了系统观察。结果显示：（１）ＤＥＮ诱发大鼠肝癌发生率为１００％;（２）正常大鼠及诱癌第４周大鼠的肝细胞均不表达ｍｐ５３,至诱癌第８周,可见少量肝细胞表达ｍｐ５３,诱癌晚期的癌结节内大部分肝癌细胞呈ｍｐ５３阳性表达,ｍｐ５３免疫反应阳性产物为胞核内棕褐色颗粒;（３）正常大鼠肝细胞不表达ＡＦＰ,诱癌早期（４～８周）的大鼠肝小叶内可见少量ＡＦＰ阳性肝细胞,多为小肝细胞,呈散在分布,此后ＡＦＰ阳性肝细胞逐渐增多,晚期的癌结节内大部分癌细胞呈ＡＦＰ阳性,ＡＦＰ免疫反应阳性产物为胞浆内棕褐色颗粒。结果提示,ｍｐ５３和ＡＦＰ可作为分析肝癌进展的病理学指标     

Bax蛋白在大鼠肝癌发生过程中的表达和意义

通过动态观察Bax蛋白在实验性大鼠肝癌发生过程中肝细胞的表达,探讨Bax蛋白与肝癌发生的关系及其生物学意义。用DEN饲喂大鼠,分别于第4、8、12、16、18周处死大鼠,取其肝脏,石蜡切片,ABC法免疫组织化染色。结果显示：正常成年大鼠肝细胞均有中等程度Bax蛋白表达。至诱癌第4周大鼠肝小叶内有少数肝细胞呈Bax蛋白免疫阳性反应,随诱癌发展进程,呈Bax蛋白免疫阳性反应肝细胞进一步减少,第12周,只可见肝细胞增生结节的多数肝细胞呈Bax蛋白免疫阳性反应。诱癌晚期（第18周）,癌结节内肝癌细胞均呈Bax免疫反应阳性,其强度较正常肝细胞明显增强,Bax蛋白免疫反应产物为胞质内粗大的棕褐色颗粒。部争肝细胞胞质和胞膜均呈阳性,肝癌细胞最为常见。结果表明：Bax蛋白表达减少或缺失是肝癌发生过程中的早期事件,可能参与肝癌的启动过程。     

生长休止蛋白7在成年大鼠肾脏、心脏和肝脏中的差异表达

目的研究生长休止蛋白7（Gas7）在成年大鼠肾脏、心脏和肝脏的表达。方法成年SD大鼠16只,分别采用逆转录聚合酶链反应（RT-PCR）方法和免疫组织化学方法检测Gas7基因mRNA和蛋白在成年SD大鼠肾脏、心脏和肝脏的表达,并进行图像分析和统计学处理。结果RT—PCR结果显示,Gas7mRNA在肾脏高表达,在心脏的表达弱于肾脏（P〈0．05）,而在肝脏的表达最弱,基本检测不到。免疫组化结果显示,在肾脏中,Gas7免疫阳性产物在近髓肾单位的近曲小管呈强阳性反应,在集合管表达较弱,在肾小球和其余肾小管未见表达;在心脏中,Gas7免疫阳性产物均匀分布于心肌细胞,呈中等强度反应,弱于肾脏（P〈O．05）;在肝脏中,Gas7蛋白未见明显表达,与其mRNA在肝脏的表达相似。结论Gas7在大鼠肾脏、心脏和肝脏表达的不同,尤其在肾脏组织分布的差异性,提示Gas7在成年大鼠肾脏和心脏结构以及功能的维持中可能起着重要作用。     

脑出血后脑组织中水通道蛋白4的定位分布变化

目的观察脑出血(intracerebral hemorrhage,ICH)后大鼠脑组织中水通道蛋白4(aquaporin 4,AQP4)的定位分布变化,以探讨AQP4在出血性脑水肿发生发展中的作用。方法 SD雄性大鼠随机分为假手术(sham)组和ICH组(ICH后1d、3d、7d),采用自体血注入法建立大鼠ICH动物模型,干湿重法检测脑水含量变化,透射电镜检测组织结构病理变化,免疫荧光双标记检测AQP4的定位分布变化。结果 ICH后1d、3d出血侧脑组织明显水肿,ICH后1d血肿周围组织结构破坏最为明显,可见毛细血管内皮细胞肿胀及血管周围间隙增宽等改变;免疫荧光结果显示,ICH后脑组织中,AQP4在血肿周围组织、外胶质界膜、内胶质界膜等与水转运密切相关的极性表达部位,其免疫反应发生变化;而在穹窿下器、齿状回等AQP4的非极性表达部位,AQP4的免疫反应无明显变化。结论结果表明,ICH后病理改变主要影响AQP4的极性表达非极性表达则不受影响。由此提示,AQP4极性表达变化可能促进出血性脑水肿的发展。     

生长休止蛋白7在大鼠小脑皮质发育过程中的动态表达

目的研究生长休止蛋白7(Gas7)在大鼠小脑皮质不同发育时期的动态表达。方法采用逆转录聚合酶链反应(RT-PCR)方法检测Gas7mRNA在大鼠小脑皮质不同发育时期的表达;免疫组织化学方法观察Gas7蛋白在大鼠小脑皮质不同发育时期的表达和分布。结果 RT-PCR结果:Gas7mRNA在大鼠小脑皮质发育时期的表达呈现先增强后减弱的趋势,高峰出现在生后第21d(P21)。免疫组化实验结果:在胚胎第18.5d(E18.5)和E20.5仅Purkinje细胞层有Gas7免疫阳性产物分布;出生当天(P0)外颗粒层出现Gas7阳性神经纤维,Purkinje细胞层出现形态不规则的Gas7免疫阳性细胞;P7外颗粒层和Purkinje细胞层免疫反应增强,内颗粒层出现一些散在的Gas7强阳性细胞,胞体较小,突起清晰可见;P14小脑皮质4层均有Gas7阳性表达;P21小脑皮质3层Gas7免疫阳性反应较P14增强(P0.01);Adult(2月龄)较P21免疫反应减弱(P0.01)。结论 Gas7在大鼠小脑皮质发育过程中的动态表达呈现出时空特异性,提示Gas7基因在大鼠小脑皮质发育过程中可能起着重要的调控作用。     

亨廷顿蛋白相关蛋白1在成年大鼠脊髓中的分布

目的观察亨廷顿蛋白相关蛋白1(huntingtin-associated protein 1, HAP1)在成年大鼠脊髓中的分布特点.方法采用免疫组织化学ABC法和免疫印迹(Western blotting)方法.结果免疫组织化学结果显示,在成年大鼠脊髓中,以背角灰质浅层(Rexed Ⅰ,Ⅱ层)的HAP1免疫反应性最强,阳性细胞最密集,免疫反应产物除分布在胞体外,还大量弥散分布于胞体间的神经毡内;背角深层有部分HAP1免疫反应阳性细胞呈散在分布,中央管周围灰质(Rexed X)内阳性胞体密度和免疫反应性强度仅次于后角浅层,而在脊髓腹角,偶见HAP1免疫反应阳性神经元.此外, Western blotting分析显示,脊髓背角内HAP1表达水平明显高于脊髓前角.结论 HAP1主要分布于大鼠脊髓背角灰质浅层和中央管周围灰质神经元内,提示其可能与痛觉信息一级传入和/或调控有关.     

大鼠视网膜中HAP1的免疫组织化学定位及不同光照条件对HAP1表达的影响

目的探讨亨廷顿蛋白相关蛋白1(huntingtin associated protein 1, HAP1)是否存在于视网膜内及是否与视觉有关.方法对正常大鼠眼球壁用ABC法进行免疫组织化学染色,观察HAP1在视网膜中的定位;用半定量免疫印迹方法(Western blotting)检测不同光照条件对大鼠视网膜中HAP1表达的影响.结果 HAP1较广泛地分布在大鼠视网膜各层,但以内核层及外核层中免疫反应较强,阳性反应产物主要定位在节细胞层和内核层/外核层中部分细胞胞体内;其余各层中,HAP1免疫反应较弱,阳性产物呈弥散分布,未见明显的阳性胞体.在连续处于黑暗环境中72小时大鼠视网膜中,HAP1表达较常规光照动物明显减少,而连续光照72h大鼠视网膜内HAP1表达无明显变化.结论 HAP1在视网膜中的存在及不同光照条件对视网膜HAP1表达的影响表明,HAP1可能与视觉活动有关.     

Gas7在大鼠海马和齿状回发育过程中的动态表达

目的研究生长休止蛋白7（Gas7）在大鼠海马和齿状回不同发育阶段的表达。方法采用免疫组织化学方法观察Gas7在SD大鼠胚胎第18d（E18）、新生（P0）、生后第7d（P7）、P14、P21和成年海马和齿状回中的表达和分布。结果在大鼠脑海马和齿状回部位的冠状切片上,Gas7免疫反应阳性产物主要表达在海马的锥体细胞、齿状回的颗粒细胞和门区的多形层细胞。随着发育的进程,在海马,Gas7较早表达在CA3区,其次是CA2和CA1区;在齿状回,Gas7在外臂的表达早于内臂,在颗粒细胞层的表达是按先外层后内层的顺序。在围生期,Gas7在海马和齿状回各区的表达逐渐增强,至P14达到高峰,后逐渐降低,至P21其表达强度和分布趋于恒定至成年水平。结论 Gas7在大鼠海马和齿状回发育过程中的动态表达具有时间和空间上的特异性,提示Gas7可能参与了海马和齿状回形态形成和功能成熟的调控。     

大鵟肾脏组织结构及相关活性物质的表达

应用生物显微技术及免疫组织化学方法,对大鵟肾脏的组织结构进行观察,检测了AQP2、AQP3和Bax、Bcl-2蛋白在肾脏中的表达.结果 表明,大鵟肾脏红褐色,表面覆以极薄的结缔组织膜,无肾脂囊.相对体积比哺乳类大,占体重的2.1%.肾小球毛细血管分支少,结构简单.但是肾小球单位面积上的数目比哺乳类多,这对于在旺盛的新陈代谢过程中,迅速排除废物、保持水盐平衡是有利的.集合管是尿重吸收的重要部位,上皮细胞有AQP2、AQP3免疫反应阳性表达,提示AQP2和AQP3对大鵟肾脏水的平衡有重要的调节作用.近曲小管上皮细胞有Bax和Bcl-2免疫反应阳性表达,说明Bax和Bcl-2的协同表达参与正常大鵟肾脏细胞凋亡的调控.     

在大鼠肝癌发生过程中GABA-BR1的表达变化及意义

为探讨γ-氨基丁酸B型受体1(γ-aminobutyric acid type B1 receptor,GABA-BR1)与肝癌发生的关系,利用二乙基亚硝胺(DEN)制备诱发型大鼠肝癌模型,模拟人类肝癌发生发展过程,采用免疫组织化学技术对GABA-BR1和细胞周期素E(Cyclin E)蛋白在大鼠肝脏中的表达进行定性和定量分析.结果显示,在正常肝组织中有少量散在分布的GABA-BR1表达阳性的细胞;在变性或坏死灶周围GABA-BR1表达阳性的肝细胞较多;增生结节中部分肝细胞呈过表达;在肝癌细胞中广泛表达.Cyclin E与GABA-BR1阳性表达的细胞分布特点相似.实验结果提示,在肝癌发生发展过程GABA-BR1过表达,可能对肝细胞的异常增生或癌变过程起到抑制作用.     

Tissue distribution and membrane localization of aquaporin-9 water channel: evidence for sex-linked differences in liver.

Aquaporin-9 (AQP9) is a water channel membrane protein also permeable to small solutes such as urea, glycerol, and 5-fluorouracil, a chemotherapeutic agent. With the aim of understanding the pathophysiological role of AQP9, we performed an extensive analysis by Western blotting, RT-PCR, and immunolocalization in rat tissues. Western blotting analysis revealed a major band of approximately 32 kD in testis, liver, and brain. Immunofluorescence showed strong expression of AQP9 in the plasma membrane of testis Leydig cells. In liver, AQP9 expression was found to be sex-linked. Male rats had higher levels of AQP9 than female in terms of both protein and mRNA. Moreover, in female livers the expression of AQP9 was mostly confined to perivascular hepatocytes, whereas males showed a more homogeneous hepatocyte staining. No differences in AQP9 expression level related to the age or to protein content of the diet were found, indicating that differences in the liver may be gender-dependent. In the brain, AQP9 expression was found in tanycytes mainly localized in the areas lacking a blood-brain barrier (BBB), such as the circumventricular organs (CVOs) of the third ventricles, the subfornical organ, the hypothalamic regions, and the glial processes of the pineal gland. AQP9 expression in the osmosensitive region of the brain suggests a role in the mechanism of central osmoreception. All these findings show a unique tissue distribution of AQP9 compared to the other known aquaporins.     

Immunolocalization of AQP9 in liver, epididymis, testis, spleen, and brain

The aims of this study were to determine the cellular and subcellular localization of aquaporin-9 (AQP9) in different rat organs by immunoblotting, immunohistochemistry and immunoelectron microscopy. To analyze this, we used rabbit antibodies to rat AQP9 raised against three different AQP9 peptides (amino acids 267-287, 274-295, and 278-295). In Cos7 cells transfected with rat AQP9, the affinity-purified antibodies exhibited marked labeling, whereas nontransfected cells and cells transfected with aquaporin-8 (AQP8) exhibited no labeling, indicating the specificity of the AQP9 antibodies. Immunoblotting revealed a predominant band of 28 kDa in membranes of total rat liver, epididymis, testes, spleen, and brain. Preabsorption with the immunizing peptides eliminated the labeling. Immunohistochemistry showed strong anti-AQP9 labeling in liver hepatocytes. The labeling was strongest at the sinusoidal surface, and there was little intracellular labeling. Immunoelectron microscopy revealed that the labeling was associated with the plasma membrane of the hepatocytes. In testes Leydig cells exhibited anti-AQP9 labeling, and in epididymis, the stereocilia of the ciliated cells (principal cells) exhibited significant labeling, whereas there was no labeling of the nonciliated cells (basal cells). This was confirmed by immunoelectron microscopy. In spleen strong labeling of cells was observed of leukocytes in the red pulp, whereas there was no labeling of cells in the white pulp. In rat brain, AQP9 immunolabeling was confined to ependymal cells lining the ventricles and to the tanycytes of the mediobasal hypothalamus. Antibody preabsorbed with the immunizing peptide revealed no labeling. In conclusion, AQP9 proteins is strongly expressed in rat liver, testes, epididymis, spleen, and brain.     

Knockdown of hepatocyte aquaporin-8 by RNA interference induces defective bile canalicular water transport

Aquaporin-8 (AQP8) water channels, which are expressed in rat hepatocyte bile canalicular membranes, are involved in water transport during bile formation. Nevertheless, there is no conclusive evidence that AQP8 mediates water secretion into the bile canaliculus. In this study, we directly evaluated whether AQP8 gene silencing by RNA interference inhibits canalicular water secretion in the human hepatocyte-derived cell line, HepG2. By RT-PCR and immunoblotting we found that HepG2 cells express AQP8 and by confocal immunofluorescence microscopy that it is localized intracellularly and on the canalicular membrane, as described in rat hepatocytes. We also verified the expression of AQP8 in normal human liver. Forty-eight hours after transfection of HepG2 cells with RNA duplexes targeting two different regions of human AQP8 molecule, the levels of AQP8 protein specifically decreased by 60-70%. We found that AQP8 knockdown cells showed a significant decline in the canalicular volume of approximately 70% (P < 0.01), suggesting an impairment in the basal (nonstimulated) canalicular water movement. We also found that the decreased AQP8 expression inhibited the canalicular water transport in response either to an inward osmotic gradient (-65%, P < 0.05) or to the bile secretory agonist dibutyryl cAMP (-80%, P < 0.05). Our data suggest that AQP8 plays a major role in water transport across canalicular membrane of HepG2 cells and support the notion that defective expression of AQP8 causes bile secretory dysfunction in human hepatocytes.     

The water channel aquaporin-8 is mainly intracellular in rat hepatocytes, and its plasma membrane insertion is stimulated by cyclic AMP

We previously found that water transport across hepatocyte plasma membranes occurs mainly via a non-channel mediated pathway. Recently, it has been reported that mRNA for the water channel, aquaporin-8 (AQP8), is present in hepatocytes. To further explore this issue, we studied protein expression, subcellular localization, and regulation of AQP8 in rat hepatocytes. By subcellular fractionation and immunoblot analysis, we detected an N-glycosylated band of approximately 34 kDa corresponding to AQP8 in hepatocyte plasma and intracellular microsomal membranes. Confocal immunofluorescence microscopy for AQP8 in cultured hepatocytes showed a predominant intracellular vesicular localization. Dibutyryl cAMP (Bt(2)cAMP) stimulated the redistribution of AQP8 to plasma membranes. Bt(2)cAMP also significantly increased hepatocyte membrane water permeability, an effect that was prevented by the water channel blocker dimethyl sulfoxide. The microtubule blocker colchicine but not its inactive analog lumicolchicine inhibited the Bt(2)cAMP effect on both AQP8 redistribution to cell surface and hepatocyte membrane water permeability. Our data suggest that in rat hepatocytes AQP8 is localized largely in intracellular vesicles and can be redistributed to plasma membranes via a microtubule-depending, cAMP-stimulated mechanism. These studies also suggest that aquaporins contribute to water transport in cAMP-stimulated hepatocytes, a process that could be relevant to regulated hepatocyte bile secretion.     

早期糖尿病大鼠晶状体和视网膜水通道蛋白4表达的研究

目的观察早期糖尿病大鼠晶状体、视网膜水通道蛋白4(aquaporin 4,AQP-4)表达的变化,探讨糖尿病大鼠眼组织水代谢改变的机制。方法 SD大鼠分为正常对照组和糖尿病组。制作糖尿病大鼠模型,于第4、8周取材,用免疫组化法和计算机图像分析系统半定量分析各组大鼠晶状体、视网膜AQP-4表达的变化。结果正常及糖尿病大鼠AQP-4在晶状体上皮均无表达。AQP-4在视网膜上有表达,正常大鼠主要表达于视网膜视杆视锥层、节细胞层和神经纤维层,糖尿病大鼠从内界膜延伸至视细胞层整个视网膜厚度均可见AQP-4阳性表达,特别是在神经节细胞层毛细血管内皮和神经纤维层阳性表达更明显。糖尿病大鼠视网膜组织AQP-4阳性表达标随周龄的延长而增强。结论糖尿病大鼠视网膜AQP-4的表达较正常组增强,提示水通道蛋白的表达增加是糖尿病早期发生视网膜水肿的机制之一。     

High insulin levels are required for FAT/CD36 plasma membrane translocation and enhanced fatty acid uptake in obese Zucker rat hepatocytes

In myocytes and adipocytes, insulin increases fatty acid translocase (FAT)/CD36 translocation to the plasma membrane (PM), enhancing fatty acid (FA) uptake. Evidence links increased hepatic FAT/CD36 protein amount and gene expression with hyperinsulinemia in animal models and patients with fatty liver, but whether insulin regulates FAT/CD36 expression, amount, distribution, and function in hepatocytes is currently unknown. To investigate this, FAT/CD36 protein content in isolated hepatocytes, subfractions of organelles, and density-gradient isolated membrane subfractions was analyzed in obese and lean Zucker rats by Western blotting in liver sections by immunohistochemistry and in hepatocytes by immunocytochemistry. The uptake of oleate and oleate incorporation into lipids were assessed in hepatocytes at short time points (30-600 s). We found that FAT/CD36 protein amount at the PM was higher in hepatocytes from obese rats than from lean controls. In obese rat hepatocytes, decreased cytoplasmatic content of FAT/CD36 and redistribution from low- to middle- to middle- to high-density subfractions of microsomes were found. Hallmarks of obese Zucker rat hepatocytes were increased amount of FAT/CD36 protein at the PM and enhanced FA uptake and incorporation into triglycerides, which were maintained only when exposed to hyperinsulinemic conditions (80 mU/l). In conclusion, high insulin levels are required for FAT/CD36 translocation to the PM in obese rat hepatocytes to enhance FA uptake and triglyceride synthesis. These results suggest that the hyperinsulinemia found in animal models and patients with insulin resistance and fatty liver might contribute to liver fat accumulation by inducing FAT/CD36 functional presence at the PM of hepatocytes.     

Membrane microdomains in hepatocytes: potential target areas for proteins involved in canalicular bile secretion

The formation of hepatic bile requires that water be transported across liver epithelia. Rat hepatocytes express three aquaporins (AQPs): AQP8, AQP9, and AQP0. Recognizing that cholesterol and sphingolipids are thought to promote the assembly of proteins into specialized membrane microdomains, we hypothesized that canalicular bile secretion involves the trafficking of vesicles to and from localized lipid-enriched microdomains in the canalicular plasma membrane. Hepatocyte plasma membranes were sonicated in Triton and centrifuged overnight on a sucrose gradient to yield a Triton-soluble pellet and a Triton-insoluble, sphingolipid-enriched microdomain fraction at the 5%/30% sucrose interface. The detergent-insoluble portion of the hepatocyte plasma membrane was enriched in alkaline phosphatase (a microdomain-positive marker) and devoid of amino-peptidase N (a microdomain-negative marker), enriched in caveolin, both AQP8 and AQP9, but negative for clathrin. The microdomain fractions contained chloride-bicarbonate anion exchanger isoform 2 and multidrug resistance-associated protein 2. Exposure of isolated hepatocytes to glucagon increased the expression of AQP8 but not AQP9 in the microdomain fractions. Sphingolipid analysis of the insoluble fraction showed the predominant species to be sphingomyelin. These data support the presence of sphingolipid-enriched microdomains of the hepatocyte membrane that represent potential localized target areas for the clustering of AQPs and functionally related proteins involved in canalicular bile secretion.