MODULATION OF RAT KUPFFER CELLS ON HIGH DENSITY LIPOPROTEIN RECEPTORS ON HEPATOCYTES

The present study found that conditioned media from Kupffer cells preincubated with acetylated LDL or acetylated LDL and zymosan increased the number of HDL receptors on hepatocytes, using the method of conditioned media transfer. This indicated that the transferable factors produced by Kupffer cells modulate HDL receptors on hepatocytes.

Chlamydia pneumoniae replicates in Kupffer cells in mouse model of liver infection

AIM: To develop an animal model of liver infection with Chlamydia pneumoniae (C. pneumoniae) in intraperito-neally infected mice for studying the presence of chlamy-diae in Kupffer cells and hepatocytes.METHODS: A total of 80 BALB/c mice were inoculated intraperitoneally with C. pneumoniae and sacrificed at various time points after infection. Chlamydiae were looked for in liver homogenates as well as in Kupffer cells and hepatocytes separated by liver perfusion with collagenase. C. pneumoniae was detected by both isola-tion in LLC-MK2 cells and fluorescence in situ hybridiza-tion (FISH). The releasing of TNFA-α by C. pneumoniae in vitro stimulated Kupffer cells was studied by enzyme-linked immunosorbent assay.RESULTS: C. pneumoniae isolation from liver homoge-nates reached a plateau on d 7 after infection when 6 of 10 animals were positive, then decreased, and became negative by d 20. C. pneumoniae isolation from sepa-rated Kupffer cells reached a plateau on d 7 when 5 of 10 animals were positive, and became negative by d 20. The detection of C. pneumoniae in separated Kupffer cells by FISH, confirmed the results obtained by culture. Isolated hepatocytes were always negative. Stimula-tion of Kupffer cells by alive C. pneumoniae elicited high TNF-α levels. CONCLUSION: A productive infection by C. pneumo-niae may take place in Kupffer cells and C. pneumoniae induces a local pro-inflammatory activity. C. pneumoniae is therefore, able to act as antigenic stimulus when local-ized in the liver. One could speculate that C. pneumoniaeinfection, involving cells of the innate immunity such as Kupffer cells, could also trigger pathological immune re-actions involving the liver, as observed in human patients with primary biliary cirrhosis.

Mitochondrial DNA from hepatocytes as a ligand for TLR9: Drivers of nonalcoholic steatohepatitis?

Nonalcoholic fatty liver disease(NAFLD) is the most common liver disease worldwide, affecting approximately one third of the Western world. It consists of a wide spectrum of liver disorders, ranging from fatty liver to nonalcoholic steatohepatitis(NASH), which consists of steatosis, ballooning injury and inflammation. Despite an alarming growth in the statistics surrounding NAFLD, there are as yet no effective therapies for its treatment. Innate immune signaling has been thought to play a significant role in initiating and augmenting hepatic inflammation, contributing to the transition from nonalcoholic fatty liver to NASH. An immune response is triggered by countless signals called damage-associated molecular patterns(DAMPs) elicited by lipid-laden and damaged hepatocytes, which are recognized by pattern recognition receptors(PRRs) on hepatic immune cells to initiate inflammatory signaling. In this editorial, in addition to summarizing innate immune signaling in NAFLD and discussing potential therapies that target innate immune pathways, we have described a recent study that demonstrated that mitochondrial DNA serves as a DAMP activating a hepatic PRR, TLR9, in mice and in the plasma of NASH patients. In addition to identifying a new ligand for TLR9 during NASH progression, the study shows that blocking TLR9 reverses NASH, paving the way for the development of future NASH therapy.

基于肠源性高密度脂蛋白调控脂多糖介导Kupffer-肝细胞Cross-Talk探讨脾虚膏脂转输障碍的分子生物学基础

脾虚膏脂转输障碍是血脂异常的关键病机。脾失健运引起肝脏代谢功能障碍可能导致血脂异常。肠道功能紊乱是脾虚膏脂转输障碍的启动因素,以其介导“炎症-代谢”紊乱为切入点,深入揭示血脂异常疾病发病机制以提高中西医结合防治水平逐渐成为基础和临床研究焦点和热点。从肠源性高密度脂蛋白(high-density lipoprotein 3,HDL3)调控脂多糖(lipopolysaccharide,LPS)介导Kupffer-肝细胞cross-talk的角度,深入分析脾虚膏脂转输障碍的分子生物学机制,揭示健脾化浊法的效应机制,为临床防治血脂异常提供科学依据。

大鼠肝细胞与Kupffer细胞共同培养对两者功能和形态影响

目的观察大鼠肝实质细胞与Kupffer细胞体外共同培养时对两者生长、形态及功能的影响。方法采用原位二步Ⅳ型胶原灌注法、Percoll液密度梯度离心法分离Wistar大鼠肝实质细胞与Kupffer细胞;体外将肝实质细胞与Kupffer细胞按6∶1比例共同培养。观察不同情况下肝细胞生存时间和形态,每隔24 h检测培养上清液中清蛋白和谷丙转氨酶（ALT）、谷草转氨酶（AST）的水平,并在培养36 h用放免法检测上清液中白细胞介素1（IL-1）、白细胞介素6（IL-6）、肿瘤坏死因子α（TNF-α）含量。结果单独培养组肝细胞的生长、增殖迅速,并向正常肝细胞的形态演变,肝细胞可培养存活至15 d;共同培养组肝细胞生长增殖缓慢,细胞可培养存活至10 d。共同培养组上清液中清蛋白水平在24、36、48、60 h比单独培养组低（t=2.551~3.139,P〈0.05）;ALT、AST水平在24、36、48、60 h比单独培养组高（t=2.446~3.108,P〈0.05）;共同培养组Kupffer细胞保持IL-1I、L-6、TNF-α分泌功能,而单独培养组未检测到IL-1I、L-6、TNF-α。结论大鼠Kupffer细胞和肝实质细胞在适宜的培养条件下可进行共同培养,二者可以保持良好的分泌功能,可用于实验研究。

大鼠肝细胞、Kupffer细胞体外共同培养的初步研究

目的研究SD大鼠Kupffer细胞与肝实质细胞体外共同培养时肝实质细胞生长、形态及功能状况.方法原位二步IV型胶原灌注法联合Percoll液密度梯度离心法分离肝实质细胞与Kupffer细胞;体外进行两种细胞单独培养、肝细胞与Kupffer细胞按6∶1比例共同培养,观察不同情况下肝细胞生存时间和形态,检测培养上清中白蛋白和糖的水平.结果单独培养组肝细胞的生长、增殖迅速,并向正常肝细胞的形态演变,肝细胞可培养存活至21 d;共同培养组肝细胞于48 h即开始出现少量的死亡细胞,细胞生长增值缓慢,细胞可培养存活至10 d.单独培养组上清白蛋白水平在48、96、120、144、168 h比混合培养组高(P<0.05);单独培养组上清糖水平在96、144、168 h高于混合培养组(P<0.05).结论肝实质细胞和Kupffer细胞在适宜的培养条件下可进行共培养;但共培养时肝细胞的生长、白蛋白合成功能和糖代谢会受到影响,肝细胞存活时间缩短,提示在共培养体系要实现肝实质细胞和Kupffer细胞两者良好生长和功能的协调,体外共培养条件需进一步优化.

参苓白术散对非酒精性脂肪性肝病大鼠肝细胞、Kupffer细胞5-LO/LTB4通路的影响

目的基于5-脂氧化酶(5-lipoxygenase,5-LO)/白三稀B4(leukotrienes B4,LTB4)通路探讨参苓白术散对非酒精性脂肪性肝病(nonalcoholic fatty liver disease,NAFLD)大鼠肝细胞、库普弗(Kupffer)细胞作用机制。方法通过Ⅳ型胶原酶离体循环灌注法分离SD大鼠肝细胞及Kupffer细胞,利用油红O染色观察肝组织脂滴蓄积情况;ELISA法检测肝组织LTB4含量;RT-PCR法、Western blot法检测大鼠肝细胞及Kupffer细胞5-LO、白三烯B4受体(LTB4 receptor type 1,BLT1)mRNA及蛋白表达水平。结果高脂饮食8周能诱导大鼠NAFLD表现,建模成功。与模型组比较,2个药物剂量干预组大鼠肝组织LTB4含量均显著下降(P<0.01);肝细胞、Kupffer细胞中的5-LO、BLT1 mRNA及其蛋白表达水平均亦有不同程度的下调(P<0.01)。2个剂量组间比较,以高剂量参苓白术散组效果较为显著(P<0.05或P<0.01)。结论参苓白术散可能通过抑制NAFLD大鼠肝细胞、Kupffer细胞5-LO/LTB4通路的激活,减轻肝脏脂质蓄积,发挥防治NAFLD的作用。

分离、鉴定与培养大鼠肝细胞、肝星状细胞和Kupffer细胞

目的：建立稳定的同时分离原代大鼠肝细胞（HC）、肝星状细胞（HSC）和Kupffer细胞（KC）的方法,并初步评估其在体外培养的特征。方法：通过胶原酶原位灌注获得肝脏单细胞悬液,随后行等密度离心结合选择性贴壁纯化肝脏原代细胞,细胞的产量和活力经自动细胞计数仪计算出,纯度经免疫荧光、特殊染色及吞噬等实验进行鉴定。结果：大鼠原代HC产量为（21.0±8.2）×10~6/g肝组织,活力为92.1%±2.1%,纯度为96.5%±2.2%;原代HSC产量为（2.5±0.8）×10~6/g肝组织,活力为90.1%±3.8%,纯度为93.1%±1.5%;原代KC产量为（4.1±1.2）×10~6/g肝组织,活力为96.2%±2.7%,纯度为95.1%±1.4%。分离的HC、HSC和KC适合体外长期培养。HSC在体外培养过程中失去维生素A,逐渐向成纤维细胞表型转变。KC在体外可增殖,至14 d时仍表达CD68,具有较强的吞噬能力。结论：成功建立同时分离和培养大鼠HC、HSC和KC的方法,为进一步研究肝脏病理生理提供细胞基础。

Gene expression profiles of hepatic cell-type specific marker genes in progression of liver fibrosis

AIM: To determine the gene expression profile data for the whole liver during development of dimethylni-trosamine (DMN)-induced hepatic fibrosis.METHODS: Marker genes were identified for different types of hepatic cells, including hepatic stellate cells (HSCs), Kupffer cells (including other inflammatory cells), and hepatocytes, using independent temporal DNA microarray data obtained from isolated hepatic cells. RESULTS: The cell-type analysis of gene expression gave several key results and led to formation of three hypotheses: (1) changes in the expression of HSC-specific marker genes during fibrosis were similar to gene expression data in in vitro cultured HSCs, suggesting a major role of the self-activating characteristics of HSCs in formation of fibrosis; (2) expression of mast cell-specific marker genes reached a peak during liver fibrosis, suggesting a possible role of mast cells in formation of fibrosis; and (3) abnormal expression of hepatocyte-specific marker genes was found across several metabolic pathways during fibrosis, including sulfur-containing amino acid metabolism, fatty acid metabolism, and drug metabolism, suggesting a mechanistic relationship between these abnormalities and symptoms of liver fibrosis. CONCLUSION: Analysis of marker genes for specific hepatic cell types can identify the key aspects of fibro-genesis. Sequential activation of inflammatory cells and the self-supporting properties of HSCs play an important role in development of fibrosis.

利用NASH大鼠原代肝细胞与原代Kupffer细胞共培养建立NASH原代细胞模型

目的:通过分离并提纯非酒精性脂肪性肝炎(NASH)大鼠原代肝细胞以及原代Kupffer细胞建立体外NASH原代细胞模型,为研究NASH提供可靠的细胞实验技术支持。方法:选择SD大鼠40只,随机分为2组(n=20):对照组和NASH组,对照组大鼠利用普通饲料喂养,NASH组大鼠利用高脂饲料(88%基础饲料+10%猪油+2%胆固醇)喂养,6~8周后,利用NASH评分表,病理观察下肝组织切片脂肪变+小叶内炎症+气球样变评分≥4分,表明大鼠NASH模型的成功建立,利用胶原酶原位灌注法分离并提纯NASH模型大鼠原代肝细胞以及原代Kupffer细胞,利用CK-18及CD68免疫荧光以及墨汁吞墨实验进行细胞鉴定,利用油红O染色、试剂盒测定谷丙转氨酶(ALT)、谷草转氨酶(AST)含量观察NASH大鼠原代肝细胞脂质累积和肝功情况,Western blot检测原代Kupffer细胞炎症因子表达情况,最后采用原代肝细胞:原代Kupffer细胞=6∶1比例共培养,显微镜下观察细胞状态。结果:实验成功分离并提纯NASH原代肝细胞以及原代Kupffer细胞,通过油红O染色,NASH组大鼠原代肝细胞存在明显的脂肪沉积,且NASH组大鼠原代肝细胞中AST、ALT明显高于对照组,存在明显肝损伤(P<0.05),Western blot测定原代Kupffer细胞TNF-α、IL-1β以及MCP-1,NASH组大鼠明显高于对照组(P<0.05)。结论:通过胶原酶原位灌注法可以成功分离NASH大鼠原代肝细胞以及原代Kupffer细胞,同时成功建立比例共培养大鼠体外原代细胞NASH模型。

NLRP3炎性小体活化与细胞焦亡在肝纤维化中的作用

NLRP3炎性小体是由天然免疫受体蛋白NLRP3、衔接蛋白ASC和pro-Caspase-1组成的多蛋白复合体。NLRP3炎性小体活化后,pro-Caspase-1自活化为Caspase-1。Caspase-1一方面促使pro-IL-1β和pro-IL-18转变为IL-1β和IL-18,另一方面剪切gasdermin D(GSDMD)并释放N末端,形成Gasdermin D-NT。Gasdermin D-NT转移至细胞膜上,在细胞膜上形成孔道,将IL-1β和IL-18分泌至细胞外,同时细胞发生焦亡。此过程有助于抵抗病原体感染、应激反应,发挥天然免疫的防御作用并维持机体平衡状态。NLRP3炎性小体活化和细胞焦亡是肝纤维化发生发展的关键因素。肝纤维化形成中涉及多种细胞的NLRP3炎性小体活化和细胞焦亡过程,比如肝实质细胞、Kupffer细胞和肝星状细胞等。本文主要总结了NLRP3炎性小体的活化机制,并阐述了NLRP3炎性小体活化及细胞焦亡在肝纤维化中的作用。

库普弗细胞对原代培养贮脂细胞激活的调节作用

目的：观察库普弗细胞在贮脂细胞激活中的促进转化、促增殖及促进细胞外基质合成的效应；方法：采用库弗细胞和贮脂细胞分离培养，流式细胞仪测定ＤＮＡ含量，免疫组化和图像分析对贮脂细胞中Ⅰ、Ⅲ、Ⅳ型胶原和纤维粘连蛋白进行定量分析，液闪法检测贮脂细胞中＾３Ｈ－脯氨酸参入量；结果：（１）分离培养的贮脂细胞完全符合该细胞的各种特征；（２）贮脂细胞是肝纤维化中细胞外基质过度沉积的重要细胞来源之一；

血小板活化因子对体外培养肝细胞的作用

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大鼠原代肝细胞、星状细胞、枯否细胞和肝窦内皮细胞的同步分离与培养

目的探索和建立同步分离大鼠原代肝细胞、星状细胞、枯否细胞和肝窦内皮细胞,并进一步鉴定和培养的方法。方法联合应用原位灌注、离体灌注、梯度密度离心和差速贴壁等分离方法,获取4种大鼠肝内原代细胞,采用形态学观察、免疫荧光染色和墨汁吞噬实验等方法对所分离的各种原代细胞进行纯度鉴定。结果通过原位灌注结合离体灌注、密度梯度离心结合差速贴壁等分离手段,成功实现了大鼠原代肝细胞、星状细胞、枯否细胞以及肝窦内皮细胞的同步分离,且所得原代细胞得率、活力及纯度等指标均符合后续细胞实验要求。结论通过简易方法同步分离大鼠原代肝细胞、星状细胞、枯否细胞以及肝窦内皮细胞是可行的。

胰岛素对大鼠肝细胞损伤的保护及其抗炎机制

目的观察胰岛素对大鼠继发性肝细胞损伤是否具有保护作用并探讨其机制。方法胶原酶原位灌流分离大鼠枯否细胞(Kupffercell,KC)及肝细胞并原代培养,分别用脂多糖(LPS)及胰岛素处理KC4h,ELISA法检测KC培养上清液中肿瘤坏死因子-α(TNF-α)和白介素-10(IL-10)水平;将不同处理的KC培养上清液分别作用肝细胞,12h后检测肝细胞损伤及存活率,并给予TNF-α单克隆抗体(TNF-α-mAb)阻断TNF-α,观察胰岛素对肝细胞作用的变化。结果(1)LPS处理的KC培养上清液可引起肝细胞损伤,使丙氨酸氨基转移酶(ALT)和天门冬氨酸氨基转移酶(AST)增高;胰岛素可减轻上述肝细胞损伤(ALT活性降低30.1%,AST活性降低21.2%)(P<0.01,n=8),提高肝细胞存活率(P<0.01,n=8);(2)胰岛素降低KC培养上清液中的TNF-α水平(P<0.01,n=8),同时增加了IL-10的水平(P<0.05,n=8);(3)LPS激活的KC培养上清中加入TNF-α-mAb(中和TNF-α),亦可减轻肝细胞损伤,而此时胰岛素对肝细胞的保护效应未见叠加增强。结论首次发现胰岛素可通过抑制KC分泌促炎性细胞因子TNF-α,同时促进其释放抗炎性细胞因子IL-10,从而减轻肝细胞损伤,促进肝细胞存活。

肝细胞增殖因子促进受损肝细胞增殖的可能机制

目的:探讨肝细胞增殖因子(ALR)促进受损肝细胞增殖的可能机制。方法:采用细胞增殖试验(MTT法)观察经ALR刺激的大鼠肝枯否细胞(KC)的条件培养液(KCCM+)对受损肝细胞增殖的影响,同时用免疫组织化学方法检测正常大鼠肝脏组织中ALR的分布、大鼠枯否细胞膜表面结合的ALR以及ALR对枯否细胞IL-6表达的影响。结果:受损肝细胞经枯否细胞条件培养液刺激后增殖明显。正常大鼠肝细胞内可表达合成ALR,枯否细胞膜表面可见ALR免疫反应颗粒,经ALR刺激后枯否细胞IL-6免疫反应信号增强。结论:ALR可能通过首先刺激枯否细胞,从而促进受损肝细胞增殖。

稀土元素钐和镧在小鼠肝脏中的分布与沉积的电镜与X线微区分析术研究

本实验运用电镜与X线微区分析术对稀土元素钐和镧在小鼠肝脏中的分布与沉积进行了研究。结果显示,注射小剂量氯化钐(40mg/kg)后,枯否氏细胞中出现钐凝集体。注射大剂量钐(510mg/kg与1000mg/kg)后,钐进入肝细胞质、线粒体、溶酶体与核内,并于胞质中形成钐凝集体。于末次注射后2周,钐凝集体仍沉积于枯否氏细胞与肝细胞。注射氯化镧(300mg/kg)后,枯否氏细胞中出现镧凝集体,而肝细胞中则检测不到镧的存在。本文描述了两种稀土元素引起的肝细胞形态变化。

小鼠肝脏细胞摄取镨的动态研究──电镜和X射线微区分析术观察

在给小鼠１次静脉注射氯化错（６０ｍｇ／ｋｇ体重）后５ｍｉｎ至４８ｈ内的９个间期应用电镜结合Ｘ射线微区分析术，对镨在肝细胞与枯否细胞中的运转进行了追踪观察。在５ｍｉｎ～２ｈ，两种细胞均以胞吞方式摄取肝血窦中含镨微粒，在胞质中形成吞噬体。在吞噬体内，微粒群处于由稀疏至密集的浓缩过程，小吞噬体互相融合。这种胞吞作用在枯否细胞极为活跃，在肝细胞则较微弱。在４～４８ｈ，许多枯否细胞的胞质几乎被吞噬体充满，细胞变性；肝细胞内的吞噬体汇聚于胆小管周围。在胆小管腔内可见高电子致密微粒群，表明镨可经胆汁途径排出。

内毒素诱导产生的一氧化氮介导体外肝细胞损害

弄清ＮＯ在ＬＰＳ所致肝损害中的作用。采用ＬＰＳ刺激体外肝细胞、Ｋｕｐｆｅｒ细胞单独及联合培养，观察ＮＯ产生情况及培养肝细胞形态改变。结果显示：ＬＰＳ刺激后各组培养上清ＮＯ产物水平显著升高，尤其Ｋｕｐｆｅｒ细胞单独培养及肝细胞／Ｋｕｐｆｅｒ细胞联合培养升高更加显著，分别约为对照组的１０倍和８倍，并且联合培养组中肝细胞形态出现明显改变，贴壁肝细胞变小、变圆，核内染色质致密、结块，部分染色质边集，核膜皱折变形。加用ｉＮＯＳ抑制剂（氨基胍）则培养上清中ＮＯ产物水平明显降低（降低６０％～６５％），肝细胞形态无明显改变。结论提示：通过诱导Ｋｕｐｆｅｒ细胞及肝细胞产生大量ＮＯ而介导肝细胞损伤，可能是ＬＰＳ所致肝损害的重要机制之一。

内毒素诱导的库普弗细胞活化对肝细胞损伤的影响及姜黄素的干预作用

目的观察脂多糖(LPS)激活库普弗细胞(KC)后对肝细胞损伤的影响及姜黄素的干预作用。方法①分离大鼠KC,培养48h后分别添加不同浓度的姜黄素培养3h,检测乳酸脱氢酶(LDH)分析药物毒性剂量;②取无细胞毒性的3种浓度姜黄素(10mmol/L～30mmol/L)分别温育KC,另设正常组和模型对照组,1h后加LPS(浓度0.1mg/L)作用2h,然后取上清以ELISA法测定TNF-α含量;③将上述各组KC换液洗涤后,继续培养12h,然后取其培养液分别作用于分离培养24h的肝细胞,检测各时间点(作用后3h,6h,12h,24h)肝细胞上清的ALT、LDH活性。结果①姜黄素低于30mmol浓度对KC无细胞毒性;②姜黄素能显著抑制LPS刺激后KC的TNF-α的分泌量,量效关系显著,其中30mmol组接近正常水平;③经LPS作用的KC培养液对正常肝细胞有明显的损伤作用,而经姜黄素保护的各组培养液,对肝细胞的损伤作用明显减轻,呈显著的浓度依赖性。结论姜黄素可以通过抑制LPS诱导的KC活化而减轻肝细胞损伤。