小鼠受精卵早期发育过程中PKB/Akt对p21蛋白表达及定位的影响

初步探讨在小鼠受精卵早期发育过程中PKB/Akt对p21蛋白表达及定位的影响。通过显微操作技术注射野生型、持续激活型及激酶失活型的PKB的mRNA,用免疫荧光方法检测p21蛋白的细胞定位、Western blot方法检测p21蛋白的表达。结果显示在注射不同形式的PKB mRNA后p21蛋白的表达无明显差别,但是细胞定位发生改变,PKB被激活后,p21蛋白滞留在胞浆中。因而初步认为在小鼠受精卵中,PKB/Akt通过影响p21的细胞定位而影响细胞周期的进程。     

PKB/Akt通过Girdin蛋白调控小鼠受精卵微丝聚集

通过研究PKB/Akt与Girdin蛋白之间的关系,目的在于揭示Girdin蛋白在PKB/Akt调控小鼠受精卵微丝聚集中的作用。研究中首先结合软件(http://scansite.mit.edu//)预测了PKB/Akt对Girdin蛋白的磷酸化位点,并制定特定位点磷酸化抗体,通过蛋白免疫印迹检测经PKB/Akt m RNA或PKB/Akt si RNA处理后的小鼠受精卵中Girdin蛋白磷酸化改变情况。同时检测了磷酸化的Girdin蛋白亚细胞定位及同微丝骨架的定位关系。进一步通过显微注射PKB/Akt m RNA再注射Girdin si RNA检测小鼠受精卵微丝骨架的聚集。结果显示经持续激活型PKB/Akt m RNA、野生型PKB/Akt m RNA处理后的小鼠受精卵中p-Girdin-1 417分布位置更加集中在2-细胞分裂沟处。经野生型和持续激活型PKB/Aktm RNA注射组p-Girdin-1 417表达增强,但是并不影响Girdin蛋白的总的表达。说明si RNA介导的PKB/Akt表达敲低非常明显地降低了Girdin蛋白的磷酸化。激光共聚焦研究显示在Akt m RNA和Girdin si RNA共注射组微丝骨架分布明显散乱。本研究结果充分说明Girdin蛋白在小鼠受精卵中受到PKB/Akt的调节,PKB/Akt通过磷酸化Girdin蛋白改变微丝骨架的聚集。     

激光共聚焦显微镜观察小鼠早期胚胎中PKB/Akt对微丝聚合的影响

在本实验中我们用优化的免疫荧光化学法结合激光共聚焦显微技术,观察了微丝在小鼠卵细胞不同期的分布情况及PKB/Akt对小鼠卵母细胞和早期胚胎的微丝聚合的影响。结果显示,在小鼠卵母细胞及早期胚胎中均有微丝的表达,且主要集中在纺锤体处的质膜处、极体及分裂沟处。注射激活型PKB/Akt mRNA能够增强微丝的聚集。相反,注射激酶失活型的PKB/AktmRNA减弱了微丝的聚合。因而我们认为PKB/Akt可以影响小鼠卵细胞和早期胚胎的微丝聚集。     

高糖和LY294002干预影响足细胞内Ⅳ型胶原表达

探讨高糖和PI3K/Akt通路对足细胞内Ⅳ型胶原(Col Ⅳ)表达的影响。体外培养小鼠足细胞,给予高糖(30mmol/L)处理后,分别于0,12,24,48h收集细胞,采用免疫细胞化学染色法和Western blot技术检测Col Ⅳ的表达;Western blot技术检测Akt的活化及LY294002对Col Ⅳ表达的抑制效应。结果表明,高糖诱导足细胞内Col Ⅳ蛋白表达增多,24h明显,各时间点与高糖刺激前相比均有统计学差异(P<0.05);高糖激活Akt蛋白磷酸化,p-Akt随刺激时间延长表达增多。PI3K/Akt通路抑制剂LY294002孵育细胞24h后,可减弱高糖诱导的足细胞内Col Ⅳ的表达(P<0.05)。因此,高糖可能通过激活PI3K/Akt通路上调足细胞内Ⅳ型胶原表达。     

HMGB1对小鼠系膜细胞细胞周期及细胞周期相关蛋白表达的影响

该实验以小鼠系膜细胞MMC为研究对象,以重组HMGB1为刺激物,通过检测细胞周期的变化及细胞PCNA、CyclinD1、CDK4和p16的表达水平,初步探讨HMGB1对系膜细胞的细胞周期及其相关调控因子的影响。选取小鼠系膜细胞MMC为研究对象,随机分为对照组及0.05mg/LHMGB1刺激组,经流式细胞术检测发现HMGB1能够上调小鼠系膜细胞中S期细胞所占比例;免疫细胞化学检测显示,PCNA蛋白在小鼠系膜细胞中的表达上调;通过RT-PCR技术及Western blot技术检测到小鼠系膜细胞中CyclinD1 mRNA和蛋白以及CDK4蛋白的高表达情况,而p16蛋白的表达呈时间依赖性降低。由此可见,HMGB1可能是通过上调CyclinD1/CDK4的表达,并下调p16的表达,促进细胞从G_0/G_1期进入S期,介导了小鼠系膜细胞的异常增殖,可能是HMGB1参与狼疮性肾炎发病的可能机制之一。     

pEGFP-P21-WT及pEGFP-P21-S145A融合表达载体在小鼠卵母细胞中的定位

目的 通过构建pEGFP-P21-WT及pEGFP-P21-S145A融合表达载体,确定在小鼠卵母细胞中的定位.方法 采用显微注射方法将融合表达载体导入小鼠卵母细胞中,荧光镜下直接观察P21及突变体的细胞定位.结果 pEGFP-P21-WT注射后,荧光分布集中于核中,而pEGFP-P21-S145A注射后,荧光信号主要分布于胞浆中,对照组（注射pEGFP-C3）荧光信号均匀分布于整个细胞内.结论 P21蛋白145位突变后影响了P21蛋白的细胞定位.     

SMMC 7721肝癌细胞蛋白激酶B活性增高可驱动有功能的上皮钙粘着蛋白到细胞表面(英)

为了研究蛋白激酶B（PKB）对上皮钙粘着蛋白（E-cadherin）的调节,使用了用胰岛素处理的野生型SMMC 7721细胞及稳定表达持续激活PKB的SMMC 7721细胞株(Gag-PKB/SMMC 7721).用RNA印迹法和蛋白质印迹法检测细胞E-cadherin 表达,发现通过胰岛素刺激或在细胞中表达持续激活PKB从而增加PKB活性,不影响E-cadherin的转录和蛋白质合成,但用流式细胞术和免疫荧光定位E-cadherin,则发现PKB活性增加能明显驱动E-cadherin到细胞表面,从而导致部分通过E-cadherin途径的细胞粘聚增加和细胞调亡的抑制.因此,我们提供新的证据表明,增加PKB活性可驱动有功能的E-cadherin分子到细胞表面.     

SMMC7721肝癌细胞蛋白激酶B活性增高可驱动有功能的上皮钙粘着蛋白到细胞表面(英文)

为了研究蛋白激酶B (PKB)对上皮钙粘着蛋白 (E cadherin)的调节 ,使用了用胰岛素处理的野生型SMMC 772 1细胞及稳定表达持续激活PKB的SMMC 772 1细胞株 (Gag PKB/SMMC 772 1) .用RNA印迹法和蛋白质印迹法检测细胞E cadherin表达 ,发现通过胰岛素刺激或在细胞中表达持续激活PKB从而增加PKB活性 ,不影响E cadherin的转录和蛋白质合成 ,但用流式细胞术和免疫荧光定位E cadherin ,则发现PKB活性增加能明显驱动E cadherin到细胞表面 ,从而导致部分通过E cadherin途径的细胞粘聚增加和细胞调亡的抑制 .因此 ,我们提供新的证据表明 ,增加PKB活性可驱动有功能的E cadherin分子到细胞表面 .     

胰岛素在小鼠受精卵早期发育中的作用

大量研究已经证实生长因子和激素在胚胎早期发育的细胞增殖与分化过程中起着重要的作用．应用定量ELISA,RT—PCR,免疫印迹和免疫荧光的方法检测胰岛素在小鼠受精卵和卵母细胞中的表达和定位．发现胰岛素均匀分布在卵细胞的胞浆中．同时也检测到mTOR（mammalian target of rapamycin）和p70S6K的表达、活性和定位．在小鼠受精卵中mTOR和p70S6K的表达没有明显不同．二者在G1,G2和M期分布在细胞浆,在S期聚集在原核的周围．在不同时期,mTOR的活性是波动的．利用P13K的特异性抑制剂渥曼青霉素,观察到卵裂率明显减低．当使用mTOR的特异性抑制剂雷帕霉素时,受精卵的第一次有丝分裂延迟．这些结果表明胰岛素存在于小鼠的卵母细胞和受精卵中,并且胰岛素可能通过激活P13K／PKB／mTOR／S6K的信号传导通路在小鼠的早期胚胎发育中发挥功能作用．     

AURKB与MAPK参与调控小鼠受精卵早期发育

Aurora 激酶是肿瘤研究领域的热点, 近年来有研究表明该激酶家族在卵母细胞减数分裂中也起着重要的调节作用, 但对于其在哺乳动物早期胚胎发育中的研究鲜有报道. 本研究通过实时荧光定量PCR、免疫印迹、免疫荧光检测了Aurora 激酶 B(Aurora kinase B, AURKB)在小鼠受精卵中的表达和定位, 运用RNA 干扰技术观察了AURKB 功能缺失后对小鼠受精卵发育早期的影响, 并检测丝裂原激活蛋白激酶 (mitogen-activated protein kinase, MAPK)通路抑制后小鼠受精卵卵裂及AURKB 表达、 活性变化. 结果表明, 在小鼠受精卵第一次卵裂进程中, G2/M 期为AURKB 的稳定表达时相, 其蛋白在G1/S 期少量分布于细胞浆, G2 期聚集于染色质周围, 进入有丝分裂后分布于全细胞. AURKB 的功能缺失可导致受精卵发生异常分裂. MAPK 通路的抑制亦可破坏受精卵的正常卵裂, 并下调AURKB的蛋白表达及活性. 结果提示, Aurora 激酶B 是小鼠受精卵早期发育所必需的, 并与MAPK 通路的激活相关.     

Protein kinase B/Akt may regulate G2/M transition in the fertilized mouse egg by changing the localization of p21(Cip1/WAF1)

Protein kinase B (PKB, also called Akt) is known as a serine/threonine protein kinase. Some studies indicate that the Akt signalling pathway strongly promotes G2/M transition in mammalian cell cycle progression, but the mechanism remains to be clarified, especially in the fertilized mouse egg. Here, we report that the expression of Akt at both the protein and mRNA level was highest in G2 phase, accompanied by a peak of Akt activity. In addition, the subcellular localization of p21(Cip1/WAF1) has been proposed to be critical in the cell cycle. Hence, we detected the expression and localization of p21(Cip1/WAF1) after injecting fertilized mouse eggs with Akt mRNA. In one-cell stage fertilized embryos microinjected with mRNA coding for a constitutively active myristoylated Akt (myr-Akt), p21(Cip1/WAF1) was retained in the cytoplasm. Microinjection of mRNA of kinase-deficient Akt(Akt-KD) resulted in nuclear localization of p21(Cip1/WAF1) . Meanwhile, microinjection of different types of Akt mRNA affected the phosphorylation status of p21(Cip1/WAF1) . However, there was no obvious difference in the protein expression of p21(Cip1/WAF1) . Therefore, Akt controls the cell cycle by changing the subcellular localization of p21(Cip1/WAF1) , most likely by affecting the phosphorylation status of p21(Cip1/WAF1) .     

Spatiotemporal changes in Ha-ras p21 expression through the hepatocyte cell cycle during liver regeneration.

The protein product of the ras oncogene, Ha-ras (p21), is thought to be an important regulator of cell growth. The cytoplasmic relocalization of p21 in the cell during the cell cycle suggests a transient signaling role for this protein in association with its signal transduction function. Because of the importance of this role we examined spatial patterns in vivo of p21 expression at the protein and mRNA levels in hepatocytes during compensatory growth in rat liver following partial hepatectomy. A low level of p21 was immunolocalized on the cytoplasmic membrane of nonregenerating hepatocytes. The level of hepatic p21 increased significantly and without spatial restriction within the liver from 36 to 60 hr after partial hepatectomy (PH). p21 was localized in the cytoplasm of dividing hepatocytes and on the hepatic cytoplasmic membrane. The elevated p21 level decreased and was found mainly on hepatocyte plasma membranes by 96 hr after PH. Immunogold electron microscopy showed p21 localized over mitochondrial membranes and nuclei in nondividing regenerating hepatocytes. Approximately 50% of nonregenerating hepatocytes show nuclear localization of p21. This percentage changes with time following PH. The decrease in nuclear localization was accompanied with an increase in the low number of hepatocytes which demonstrated cytoplasmic localization in nondividing hepatocytes in regenerating liver. Flow cytometric analysis revealed a significant increase of p21 at 36 hr after PH which was 12 hr after the initial induction of ras mRNA. ras mRNA level increased 1.5-fold at 24 hr after PH and a maximum twofold induction was observed at 48 hr. Cell-cycle analysis of regenerating hepatocytes indicated a synchronized first peak of cell division 36-40 hr after PH. Dual parameter flow cytometry revealed that the level of p21 in hepatocytes in S phase and G2/M phase of the cell cycle was significantly higher than that in G0/G1 phase during regeneration. These findings suggest that p21 is important for the progression of regenerating hepatocytes to S phase and then to G2/M phase.     

Spatiotemporal changes in Ha-ras p21 expression through the hepatocyte cell cycle during liver regeneration

The protein product of the ras oncogene, Ha-ras (p21), is thought to be an important regulator of cell growth. The cytoplasmic relocalization of p21 in the cell during the cell cycle suggests a transient signaling role for this protein in association with its signal transduction function. Because of the importance of this role we examined spatial patterns in vivo of p21 expression at the protein and mRNA levels in hepatocytes during compensatory growth in rat liver following partial hepatectomy. A low level of p21 was immunolocalized on the cytoplasmic membrane of nonregenerating hepatocytes. The level of hepatic p21 increased significantly and without spatial restriction within the liver from 36 to 60 hr after partial hepatectomy (PH). p21 was localized in the cytoplasm of dividing hepatocytes and on the hepatic cytoplasmic membrane. The elevated p21 level decreased and was found mainly on hepatocyte plasma membranes by 96 hr after PH. Immunogold electron microscopy showed p21 localized over mitochondrial membranes and nuclei in nondividing regenerating hepatocytes. Approximately 50% of nonregenerating hepatocytes show nuclear localization of p21. This percentage changes with time following PH. The decrease in nuclear localization was accompanied with an increase in the low number of hepatocytes which demonstrated cytoplasmic localization in nondividing hepatocytes in regenerating liver. Flow cytometric analysis revealed a significant increase of p21 at 36 hr after PH which was 12 hr after the initial induction of ras mRNA. ras mRNA level increased 1.5-fold at 24 hr after PH and a maximum twofold induction was observed at 48 hr. Cell-cycle analysis of regenerating hepatocytes indicated a synchronized first peak of cell division 36–40 hr after PH. Dual parameter flow cytometry revealed that the level of p21 in hepatocytes in S phase and G₂/M phase of the cell cycle was significantly higher than that in G₀/G₁ phase during regeneration. These findings suggest that p21 is important for the progression of regenerating hepatocytes to S phase and then to G₂/M phase.     

Immunocytochemical localization in normal and transformed human cells in tissue culture using a monoclonal antibody to the src protein of the Harvey strain of murine sarcoma virus

Using a rat monoclonal antibody directed against the p21 src protein of the Harvey strain of Murine Sarcoma Virus (MSV), we have examined the reactivity of human cells in tissue culture using immunofluorescence and electron microscopy. Qualitative results indicated that untransformed mouse and human fibroblastic cells have undetectable amounts of p21; these levels were greatly increased after transformation with Harvey MSV. A group of human tumor cell lines adapted to tissue culture were examined and almost all of the epithelial tumor lines showed significant localization with this antibody. Notable exceptions were two melanoma cell lines which were negative for p21 by immunofluorescence. When normal human epithelial cells derived from esophageal or foreskin epithelium were examined, the antibody showed significant reactivity with subconfluent growing cells. After the normal cells were allowed to become quiescent, the reactivity with this antibody decreased. All of the localization seen by fluorescence was in a distribution consistent with the previously demonstrated location of p21 scr on the inner aspect of the plasma membrane. Electron microscope localization showed labeling for this antigen on the inner surface of the plasma membrane in both transformed mouse cells and in the human tumor cell lines MCF-7 and HTB-2 (RT4). These results suggest that the amounts of p21-like proteins detectable in human epithelial tumor cells do not necessarily reflect their malignant potential, but may be related to their epithelial nature. The loss of detectable localization at quiescence suggests that p21 levels decrease when these epithelial cells stop growing, and raises the possibility that an analog of p21 may be used by these human epithelial cells to regulate cell growth.     

Iron deprivation induces apoptosis independently of p53 in human and murine tumour cells

Iron deprivation induces apoptosis in some sensitive cultured tumour cells, while other cells are resistant. In order to elucidate the mechanisms involved in apoptosis induction by iron deprivation, we studied the expression of p53 and the expression of selected p53-regulated genes. To discriminate between changes coupled only with iron deprivation and changes involved in apoptosis induction by iron deprivation, we compared the expression of the genes in sensitive (human Raji, mouse 38C13) versus resistant (human HeLa, mouse EL4) cells under iron deprivation. Iron deprivation was achieved by incubation in a defined iron-free medium. The level of p53 mRNA decreased significantly under iron deprivation in sensitive cells, but it did not change in resistant cells. On the contrary, the level of the p53 protein under iron deprivation was slightly increased in sensitive cells while it was not changed in resistant cells. The activity of p53 was assessed by the expression of selected p53-regulated targets, i.e. p21(WAF1/CIP1) gene, mdm2, bcl-2 and bax. We did not detect any relevant change in mRNA levels as well as in protein levels of these genes under iron deprivation with the exception of p21(WAF1/CIP1). We detected a significant increase in the level of p21 mRNA in both (sensitive and resistant) mouse cell lines tested, however, we did not find any change in both (sensitive and resistant) human cell lines. Moreover, the p21(WAF1/CIP1) protein was accumulated in mouse-sensitive 38C13 cells under iron deprivation while all other cell lines tested, including human-sensitive cell line Raji, did not show any accumulation of p21(WAF1/CIP1) protein. It seems that the p21(WAF1/CIP1) mRNA, as well as protein accumulation, is not specifically coupled with apoptosis induction by iron deprivation and that it is rather cell-line specific. Taken together, we suggest that iron deprivation induces apoptosis at least in some cell types independently of the p53 pathway.     

Mouse and human GTPBP2, newly identified members of the GP-1 family of GTPase

We earlier identified the GTPBP1 gene which encodes a putative GTPase structurally related to peptidyl elongation factors. This finding was the result of a search for genes, the expression of which is induced by interferon-gamma in a macrophage cell line, THP-1. In the current study, we probed the expressed sequence tag database with the deduced amino acid sequence of GTPBP1 to search for partial cDNA clones homologous to GTPBP1. We used one of the partial cDNA clones to screen a mouse brain cDNA library and identified a novel gene, mouse GTPBP2, encoding a protein consisting of 582 amino acids and carrying GTP-binding motifs. The deduced amino acid sequence of mouse GTPBP2 revealed 44.2% similarity to mouse GTPBP1. We also cloned a human homologue of this gene from a cDNA library of the human T cell line, Jurkat. GTPBP2 protein was found highly conserved between human and mouse (over 99% identical), thereby suggesting a fundamental role of this molecule across species. On Northern blot analysis of various mouse tissues, GTPBP2 mRNA was detected in brain, thymus, kidney and skeletal muscle, but was scarce in liver. Level of expression of GTPBP2 mRNA was enhanced by interferon-gamma in THP-1 cells, HeLa cells, and thioglycollate-elicited mouse peritoneal macrophages. In addition, we determined the chromosomal localization of GTPBP1 and GTPBP2 genes in human and mouse. The GTPBP1 gene was mapped to mouse chromosome 15, region E3, and human chromosome 22q12-13.1, while the GTPBP2 gene is located in mouse chromosome 17, region C-D, and human chromosome 6p21-12.