Expression of a phosphorylated form of ATF4

基础研究学习记忆过程中磷酸化的CREB 在大鼠脑纹状体内的表达江刚舒斯云包新民陈旭红常铉基金项目 国家自然科学基金(30270431)作者单位:510282广州,第一军医大学珠江医院神经科学研究所摘要目的探讨大鼠在学习记忆过程中磷酸化的转录因子环磷酸腺苷反应单元结合蛋白(cAM Pr esponsive element binding pro tein,CREB)在脑纹状体内的表达。

方法将动物首先在Y 迷宫中进行学习记忆训练,然后应用免疫组织化学方法检测磷酸化的CREB (phosphorylated CREB,pCREB)在脑纹状体内的表达。

结果大鼠经电Y 迷宫训练后,脑纹状体内侧的边缘区内即有明显的pCREB 阳性表达,而假训练组或对照组的边缘区内均无明显的pCREB 阳性表达。

此外,在海马、前额叶皮质和扣带回等处也有较多的pCREB 阳性表达。

结论大鼠进行电Y 迷宫厌暗学习时,脑纹状体边缘区内磷酸化的转录因子pCREB 参与学习记忆的信号转导过程。

关键词 转录因子;CREB;Y 迷宫;逃避性学习;记忆;纹状体;边缘区;动物Expression of phosphorylated CREB in the rat striatum during learning and memory JI A N G Gang,SH U Si -y un,Bao X in -min,et al.I nstitute f or Neur oscience of Fir st Military Medical Univer sity ,Zhuj iang H osp ital,Guangz hou 510282,ChinaAbstractObjectiveT o ex plore the expression of phosphor ylated cAM P responsive element binding pro -tein (pCREB)in t he rat striatum dur ing learning and memory.Methods After Y -maze training in r ats,the pos-i tiv e ex pression of pCREB in the striatum was investig ated w ith immunohistochemical technique.Results A fter Y -maze training immediately,the positive expression of pCREB was obser ved obv iously in medial border of the stria -tum,the marginal division(Mr D),of t he training group,but there w as only few positive ex pression of pCR EB in t he M r D of pseudotraining or contr ol g roups.In addition,the posit ive expression w as also observed in the hippocam -pus,prefr ontal cortex,cingulum cortex of the br ain.Conclusion Phosphorylated transcriptional facto r pCREB int he M rD participates in the signal transduction dur ing lear ning and memor y processes in Y -maze tr aining courses ofr ats.Key w ords T ranscriptional factor;CREB;Y -maze;A voidance learning ;M emor y;Striatum;M arg inal division;Animal脑纹状体边缘区(marginal division,M rD)是舒斯云首先于1987年在大鼠脑纹状体发现的一个新亚区,其位于纹状体的尾侧,环绕苍白球的头外侧,由紧密排列的梭形细胞构成[1]。

未折叠蛋白反应英语The Unfolded Protein Response.The unfolded protein response (UPR) is a cellular signaling pathway that is activated when the endoplasmic reticulum (ER) experiences a buildup of unfolded or misfolded proteins. This response is crucial for maintaining cellular homeostasis and preventing the accumulation of potentially harmful proteins. The UPR serves to restore ER function by enhancing protein folding capacity, reducing protein translation, and promoting the degradation of damaged proteins.The ER is a crucial organelle responsible for protein synthesis, folding, and trafficking. When the ER is unable to cope with the demand for protein folding, it triggers the UPR to address the imbalance. This imbalance can be caused by various factors such as changes in cellular metabolism, environmental stress, or mutations that affect protein folding.The UPR is initiated by three ER-resident transmembrane proteins: protein kinase RNA-like endoplasmic reticulum kinase (PERK), inositol-requiring enzyme 1α (IRE1α), and activating transcription factor 6 (ATF6). Under normal conditions, these proteins are bound to the ER chaperone BiP/GRP78, which inhibits their activation. However, when unfolded proteins accumulate in the ER, BiP/GRP78 dissociates from these sensors, allowing them to initiate the UPR.PERK activation leads to the phosphorylation of the eukaryotic translation initiation factor 2α (eIF2α), which attenuates global protein synthesis. This reductionin protein synthesis reduces the load on the ER, allowingit to focus on folding the existing proteins. Additionally, phosphorylated eIF2α promotes the translation of specific mRNAs, including those encoding transcription factors such as ATF4, which induce the expression of genes involved in amino acid metabolism, oxidative stress resistance, and chaperone synthesis.IRE1α activation leads to its endonuclease activity, which splices the mRNA of the transcription factor XBP1. This splicing event converts XBP1 from an inactive form to an active form that can regulate the expression of genes involved in ER expansion, lipid metabolism, and protein degradation.ATF6 activation leads to its translocation to the Golgi apparatus, where it is cleaved to release its cytosolic domain. This cleaved ATF6 fragment then enters the nucleus and activates the expression of genes encoding chaperones, ER-associated degradation (ERAD) components, and other proteins that enhance ER function.Collectively, these UPR signaling branches aim to restore ER homeostasis by enhancing protein folding capacity, reducing protein synthesis, and promoting the degradation of damaged proteins. If the ER stress persists despite these adaptive responses, the UPR can also trigger apoptotic signaling, leading to cell death.The UPR plays a crucial role in maintaining cellularprotein homeostasis and preventing the accumulation of potentially harmful proteins. Its activation is a highly conserved mechanism across different cell types and organisms, indicating its importance in maintainingcellular function and survival.In summary, the unfolded protein response is a complex cellular signaling pathway that is activated in response to ER stress. It involves the activation of three ER-resident sensors, PERK, IRE1α, and ATF6, which trigger adaptive responses to restore ER homeostasis. These responses include enhancing protein folding capacity, reducing protein synthesis, and promoting the degradation of damaged proteins. The UPR is crucial for maintaining cellular protein homeostasis and preventing the accumulation of potentially harmful proteins.。

Facial ExpressionA facial expression results from one or more motions or positions of the muscles of the face. They are closely associated with our emotions. Charles Darwin noted in his book The Expression of the Emotions in Man and Animal:...the young and the old of widely different races, both with man and animals, express the same state of mind by the same movements.In the mid-20th century most anthropologists believed that facial expressions were entirely learned and could therefore differ among cultures, but studies (eventually with people of the Papua New Guinea highlands who had not been in contact with the outside world) have supported Darwin's belief to a large degree, particularly for expressions of anger, sadness, fear, surprise, disgust, contempt and happiness. Research has also shown that consciously making expressions can induce the corresponding emotion.Facial expressions are a form of nonverbal communication, and can be voluntary or involuntary. Most people's success rate at reading emotions from facial expression is only a little over 50 percent. Microexpressions, brief flashes of a facial expression, are likely to be involuntary and unconscious, and most people do not learn to read them at all. Recognizing facial expressions uses some of the same brain systems as face recognition.Facial expressions include:•anger, sadness, fear, surprise, disgust, contempt and happiness•blank•excitement•laughter•crying (that is with sadness)•shock•puzzlement•frown•desire•concentration•smile•smugness or self-satisfaction•sneer•snarl•tongue-showing•pout•etc.The muscles of facial expression are:•Auricularis anterior muscle•Buccinator muscle•Corrugator supercilii muscle •Depressor anguli oris muscle •Depressor labii inferioris muscle •Depressor septi nasi muscle•Frontalis muscle•Levator anguli oris muscle•Levator labii superioris muscle •Levator labii superioris alaeque nasi muscle •Mentalis muscle•Nasalis muscle•Orbicularis oculi muscle•Orbicularis oris muscle•Platysma muscle•Procerus muscle•Risorius muscle•Zygomaticus major muscle •Zygomaticus minor muscle。

柯里拉京调节自噬影响巨噬细胞源性泡沫细胞形成的研究*吴静宜， 邓欣， 姜丙通， 胡蒙蒙， 李志杰， 张雅琼， 赵毅， 车彦云△（云南省药食同源饮品工程研究中心，云南中医药大学，云南 昆明 650500）［摘要］ 目的：探讨柯里拉京（Cor ）通过自噬抑制巨噬细胞源性泡沫细胞的形成及其机制。

方法：以THP -1和J774A.1巨噬细胞为研究对象，分别设正常组、泡沫细胞模型组（ox -LDL+LPS 组/ox -LDL 组）和不同浓度Cor 处理组（Cor 组）。

油红O 染色观察各组细胞内脂滴沉积情况，ELISA 法检测各组细胞内总胆固醇（TC ）和游离胆固醇（FC ）含量及细胞上清液白细胞介素6（IL -6）、单核细胞趋化蛋白1（MCP -1）、IL -1β、肿瘤坏死因子α（TNF -α）的表达；分子对接建模预测Cor 与自噬和炎症相关靶点的作用；Western blot 检测各组细胞中自噬和炎症相关蛋白的表达水平，试剂盒检测caspase -1活性。

结果：与模型组比较，Cor 中、高剂量组可显著减少THP -1和J774A.1两种巨噬细胞内的红色脂滴；Cor 可减少细胞脂滴沉积，呈浓度依赖性降低胆固醇酯（CE ）/TC （P <0.05或P <0.01），显著降低IL -6、MCP -1、IL -1β和TNF -α的含量（P <0.01）；Cor 与受体哺乳动物雷帕霉素靶蛋白（mTOR ）的结合亲和力最好，最佳结合亲和力是−9.8 kcal/mol ；同时Cor 高剂量组可显著上调磷酸化AMP 活化蛋白激酶（p -AMPK ）/AMPK 的蛋白表达水平（P <0.01），显著下调磷酸化mTOR （p -mTOR ）/mTOR 、P62、核苷酸结合寡聚化结构域样受体蛋白3（NLRP3）、含caspase 募集结构域的凋亡相关斑点样蛋白（ASC ）和caspase -1的蛋白表达水平（P <0.05或P <0.01），beclin -1和LC3的蛋白表达无显著性差异（P >0.05）；此外，Cor 也显著抑制了caspase -1的活性（P <0.05）。

Useful Expressions1. 丰富的想象力 a great imagination (L1)2. 在某一指定的日期 on an appointed day (L4)3. 他不会得到任何提示，只有凭运气。

He was subject to no guidance or influence, only chances. (L11)4. 他也许心有所属。

His affections might be engaged upon a lady of his own selection. (L18)5. 当场回报 be rewarded on the spot (L23)6. 不确定因素 the element of uncertainty (L24)7. 掌上明珠the apple of one’s eye (L26)8. 如果他命不该绝 if fate did not determine for him a different destiny (L36)9. 时间一刻都不能耽误。

There was not an instant to be lost. (L66)10. 毫不犹豫地 without the slightest hesitation (L75)11. 她的心象被灼烧一样。

Her soul had burned with agony. (L85)12. ……不能轻率地考虑。

sth. is not to be lightly considered. (L94)Useful Expressions1. 一家供应家常口味外卖的餐馆a restaurant offering takeout homestyle meals (L1)2. 一个大家都熟悉的本地流浪汉a well-known local homeless man (L5)3. 收拢他的那些袋子 gather up his numerous bags (L14)4. 侧身替他开了门 step aside and hold the door for him (L17)5. 礼貌是一种工具，它提醒我们周围还有别人存在。

索拉非尼抑制人非小细胞肺癌细胞的增殖并诱导其凋亡祁慧薇1，范理宏21. 上海交通大学附属第六人民医院肺内科，上海　200233；2. 上海市肺科医院肿瘤科，上海　200433[摘要]　目的：观察索拉非尼对人非小细胞肺癌（non-small cell lung cancer ，NSCLC ）A549和H1299细胞增殖和凋亡的影响，并探讨其可能机制。

方法：不同浓度索拉非尼作用A549和H1299细胞后，应用CCK-8（cell counting kit-8）法检测细胞的增殖抑制率，FCM 检测细胞周期和细胞凋亡，蛋白质印迹法检测细胞的磷酸化细胞外信号调节激酶（phosphorylated extracellular signal-regulated kinase ，p-ERK ）和磷酸化Akt （phosphorylated Akt ，p-Akt ）蛋白的表达水平。

结果：不同浓度索拉非尼能抑制A549和H1299细胞的增殖，且呈浓度依赖性（P ＜0.05）；索拉非尼能诱导细胞凋亡，与对照组比较，G 0/G 1期细胞比率明显上升，S 期细胞比率相应下降，细胞阻滞于G 0/G 1期（P ＜0.05）；索拉非尼作用后，A549和H1299细胞中p-ERK 蛋白的表达明显低于对照组（P ＜0.05）。

结论：索拉非尼能抑制人NSCLC A549和H1299细胞的增殖并诱导其凋亡，其作用机制可能与阻断ERK 信号通路有关。

[关键词]　癌，非小细胞肺；细胞外信号调节激酶类；细胞凋亡；信号传递；索拉非尼[中图分类号]　R734.2[文献标志码]　A[文章编号]　1000-7431 (2011) 12-1077-05Sorafenib inhibits the growth of human non-small cell lung cancer cells and induces their apoptosisQI Hui-wei 1, FAN Li-hong 21. Department of Respiratory Medicine, Shanghai Sixth People’s Hospital, Shanghai Jiaotong University, Shanghai 200233, China;2. Department of Oncology, Shanghai Pulmonary Hospital, Shanghai 200433, China[ABSTRACT]　Objective: To observe the effects of sorafenib on the proliferation and apoptosis of human non-small cell lung cancer (NSCLC) A549 and H1299 cells and to explore their possible mechanisms. Methods: The A549 and H1299 cells were treated with sorafenib at different concentrations. The inhibitory rate of cell proliferation was assessed by cell counting kit-8 (CCK-8). The apoptosis and the cell cycle distribution were analyzed by fl ow cytometry (FCM). The expression levels of phosphorylated extracellular signal-regulated kinase (p-ERK) and phosphorylated-Akt (p-Akt) proteins in A549 and H1299 cells were examined by Western blotting. Results: The proliferation of A549 and H1299 cells was inhibited via treatment with different concentrations of sorafenib in a dose-dependent manner (P ＜0.05). Sorafenib can induce apoptosis. The percentage of cells at G 0/G 1 phase was signi fi cantly increased, andwhich at S phase was signi fi cantly decreased in sorafenib-treated group, as compared with those in the control group (P ＜0.05). The expression level of p-ERK protein in A549 and H1299 cells treated with sorafenib was lower than that in the untreated control group (P ＜0.05). Conclusion: Sorafenib can inhibitthe proliferation of human NSCLC A549 and H1299 cells and induce the apoptosis. This effect may be associated with the block of ERK signaling pathway.[KEY WORDS]　Carcinoma, non-small cell lung; Extracellular signal-regulated kinases; Apoptosis; Signal transduction; Sorafenib[TUMOR , 2011, 31 (12): 1077-1081]Correspondence to: FAN Li-hong （范理宏） E-mail: fanlih@Received 2011-08-25 Accepted 2011-10-10肺癌是目前世界上发病率和病死率较高的恶性肿瘤之一，其中非小细胞肺癌（non-small cell lung cancer ，NSCLC ）占肺癌的75%～85%。

The Power of Writing as a Form of Expression Writing has long been recognized as a powerful form of expression, allowing individuals to convey their thoughts, emotions, and experiences in a tangible and lasting way. From ancient civilizations carving symbols into stone tablets to modern-day authors publishing best-selling novels, the written word has the ability to captivate, inspire, and provoke change. The power of writing as a form of expression is undeniable, impacting both the writer and the reader in profound ways.For many individuals, writing serves as a means of catharsis, providing an outlet for processing emotions and experiences. Whether through journaling, poetry, or personal essays, the act of putting pen to paper (or fingers to keyboard) can be incredibly therapeutic. By articulating their thoughts and feelings, writers are able to gain clarity and insight into their own inner workings. This process of self-reflection can lead to healing and personal growth, as individuals confront and make sense of their experiences through writing.Furthermore, writing allows individuals to share their unique perspectives and stories with the world. Through memoirs, autobiographies, and personal blogs, writers can connect with readers on a deeply human level, fostering empathy and understanding. By sharing their triumphs, struggles, and lessons learned, writers have the power to inspire and uplift others who may be facing similar challenges. In this way, writing serves as a form of communal support, reminding us that we are not alone in our experiences.In addition to its personal and interpersonal impact, writing also has the power to effect societal change. Throughout history, influential writers have used their words to challenge the status quo, advocate for justice, and incite social movements. From Harriet Beecher Stowe's \"Uncle Tom's Cabin\" to Upton Sinclair's \"The Jungle,\" literature has played a pivotal role in raising awareness about pressing social issues and galvanizing public action. Even in the digital age, social media platforms and online publications have become powerful tools for amplifying diverse voices and catalyzing change.However, it is important to acknowledge that the power of writing is not without its limitations. While words have the potential to inspire and unite, they can also be used todeceive and manipulate. In an age of misinformation and fake news, the written word can be weaponized to spread falsehoods and sow discord. Additionally, not all individuals have equal access to the means of writing and publishing their stories. Marginalized voices, particularly those from underrepresented communities, may struggle to have their narratives heard in a society that often privileges certain perspectives.Despite these challenges, the power of writing as a form of expression remains undiminished. As technology continues to evolve, new forms of writing and storytelling are emerging, expanding the possibilities for creative expression and connection. Whether through traditional books and essays or innovative digital mediums, the written word continues to shape our understanding of the world and ourselves. In an increasingly complex and interconnected global society, the power of writing as a form of expression serves as a beacon of truth, empathy, and resilience.。

⾼通量快速细胞蛋⽩检测⽅法——In-CellOn-CellWestern样品数量太多，如何做⾼通量WB？WB实验周期太长，想进⾏快速检测？蛋⽩分⼦量>400KD的WB怎么做？磷酸化蛋⽩、细胞膜内蛋⽩检测困难？恭喜你，打开本⽂，你将获得⼀次性解决以上问题的新型WB⽅法——In-Cell/On-Cell WesternIn-Cell/On-Cell WesternIn-Cell/On-Cell WesternIn-Cell/On-Cell Western是在96孔板或384孔板培养的细胞上依据抗原抗体结合原理,利⽤⽬标蛋⽩的特异性抗体及近红外荧光染料标记的⼆抗，对⽬标蛋⽩进⾏定量分析的技术。

1In-Cell/On-Cell Western的实验流程实验流程步骤1以⼀定密度在96/384孔板上培养细胞2⽣长到合适密度后，加药物或其他处理3加⼊多聚甲醛进⾏固定4加⼊Triton X-100对细胞进⾏透化处理5BSA封闭30 min6加⼊⼀抗孵育1h7加⼊荧光标记⼆抗，洗涤检测2In-Cell/On-Cell Western提⾼⾼通量实验的可重复性和准确性HeLa细胞分别⽤10uM的CAM和DMSO处理7天，In-Cell Western检测氧化磷酸化复合物的的⽔平，统计学数据表明，对照组、DMSO和CAM处理组的变异系数CV均较低，重复性好。

GAPDH和PMLC20通过WB分别在两张膜上各做13个重复，变异系数为0.27；GAPDH和PMLC20通过ICW检测，30个重复，变异系数为0.08-0.16。

与化学发光膜WB法相⽐，ICW的通量更⾼，变异系数更低，提⾼实验结果重复性和准确性。

与膜上WB法相⽐， In-Cell/On-Cell Western更快速便捷3In-Cell/On-Cell Western的应⽤举例01Insulin Rearch02Signaling Pathways03Drug Rearch04RNAi05Apoptosis06Ion Channel01.Insulin RearchDose-dependent results of human insulin receptor activation. A. Images of ICW signals detected by an Odyssey® Infrared Imaging System (LI-COR, Bad Homburg, Germany) with the 700- and 800-nm channels. The signals obtained from DNA and cell stain with DRAQ5™ and Sapphire700™ excited at ~680 nm and detected at ~700 nm are displayed in red, whereas the signals obtained from detecting the phosphorylated human insulin receptor (p-hIR) excited at ~780 nm and detected at ~800 nm are displayed in green. The composite overlay shows both measurements in one image.measurements in one image.值得注意的是，胰岛素筛选主要是基于胰岛素刺激细胞后，对细胞膜受体磷酸化⽔平进⾏检测，因其对细胞培养需求⼤，普通WB难以实现，⽽LI-COR Odyssey 的In-Cell Western能对⼈胰岛素和胰岛素类似物的效价进⾏⾼灵敏度的定量检测，因此美国药典（United States Pharmacopoeia，USP）推荐⽤LI-COR Odyssey的In-Cell Western⽅法进⾏胰岛素筛选。

Influence of proline-rich inositol polyphosphate 5-phosphatase,on earlydevelopment of fertilized mouse eggs,via inhibition of phosphorylation of AktX.Deng*,†,C.Feng‡,E.-H.Wang†,Y .-Q.Zhu§,C.Cui¶,Z.-H.Zong‡,G.-S.Li¶,C.Liu‡,J.Meng‡and B.-Z.Yu†,‡*Experimental Center of the Functional Subjects,†Institute of Pathology and Pathophysiology,‡Department of Biochemistry and Molecular Biology,§Department of Cell Biology,and ¶Department of Physiology,China Medical University,Shenyang,Liaoning,China Received 23August 2010;revision accepted 17November 2010AbstractObjectives :Proline-rich inositol polyphosphate 5-phosphatase (PIPP)is one of the signal-modifying enzymes that play pivotal regulatory roles in PI3K signalling pathway.The aim of this study was to determine the role of PIPP in early development of fertilized mouse eggs,via inhibition of Akt activity and subsequent downstream signalling events.Materials and methods :The mRNA transcript lev-els of endogenous PIPP and Akt1,Akt2,Akt3were detected in G 1,S,G 2and M phases of fertilized mouse eggs by RT-PCR.Levels of exogenous PIPP,phosphorylated Akt at Ser473,dephosphorylated cdc2at Tyr15and levels of CCNB1,were detected respectively by immunoblotting.Changes in Akt localization were observed by fluoroimmunoassay;meanwhile,changes in activity of Akt and its down-stream MPF were detected.Percentages of cells undergoing division were determined by counting,using a dissecting microscope.Results :PIPP and Akt1transcripts were detectable in G 1,S,G 2and M phases of fertilized mouse eggs,but Akt2and Akt3were not.We also observed that overexpression of PIPP in fertilized eggs decreased expression of phosphorylated Akt at Ser473and altered membrane localization of phosphorylated Akt at Ser473specifically.Furthermore,overexpression of PIPP resulted in decreases in mitosis-phase pro-moting factor activity,level of dephosphorylated cdc2at Tyr15and cleavage rate of fertilized mouse eggs.Conclusions :Our data suggest,for the first time,that PIPP may affect development of fertilized mouse eggs by inhibition of level of phosphorylated Akt at Ser473and subsequent inhibition of downstream signal cascades.IntroductionProline-rich inositol polyphosphate 5-phosphatase,PIPP,is a novel regulator of phosphoinositide 3-kinase (PI3K)signalling pathway.PIPP hydrolyzes 5-position phosphate of phosphatidylinositol 3,4,5trisphosphate [PtdIns(3,4,5)P 2]or phosphatidylinositol 4,5bisphosphate [PtdIns(4,5)P 3]to form PtdIns(3,4)P 2or PtdIns(4)P,respectively (1–3).Mitchell et al.have demonstrated that PIPP may inhibit amplitude of Ser473-Akt phosphory-lation by means of hydrolysing PtdIns(3,4,5)P 3to decrease binding of PtdIns(3,4,5)P 3and PH domains of Akt in somatic cells (3).Therefore,we postulate that PIPP may also lower the level of phosphorylated Akt at Ser473in fertilized mouse eggs.Akt,also called protein kinase B,is a serine ⁄threonine protein kinase and is a downstream factor of PI3K.It is well established that Akt plays an important role in many cell processes such as glucose metabolism,cell prolifera-tion,apoptosis,transcription and cell migration (4–7).There are three isoforms of Akt (1,2,3,PKB a ,b ,c )and they share high sequence identity and are composed of three functionally distinct regions:an N-terminal pleck-strin homology (PH)domain (amino acids 1-106),a cen-tral catalytic domain (amino acids 148-411)and a C-terminal regulatory domain (amino acids 412-480).The PH domain of Akt mediates interactions of Akt with other proteins involved in signal transduction by binding PtdIns(3,4,5)P 3or PtdIns(3,4)P 2,and then targeting Akt to plasma membranes.Membrane recruitment is a hallmark of Akt activation (8–10).When Akt is in its stable form,it dissociates from the plasma membrane and targetsCorrespondence:B.-Z.Yu,Department of Biochemical and Molecular Biology,China Medical University,Beier Road,Heping District,Sheny-ang 110001,Liaoning Province,China.Tel.:+0086-24-23256666,ext.5299;Fax:+0086-24-23261253;E-mail:ybzbiochem@ 156Ó2011Blackwell Publishing Ltd.Cell Prolif.,2011,44,156–165doi:10.1111/j.1365-2184.2011.00743.xsubstrates located in the cytoplasm and nucleus(8).How-ever,when Akt is phosphorylated at residue Ser473,it is activated and recruited to the cell membrane(8–10). Although it is well established that phosphorylation of Akt at Ser473is required for plasma membrane localiza-tion and that PIPP may inhibit the level of phosphoryla-tion of Akt at Ser473(8–11),whether PIPP plays a role as negative regulator of Akt in fertilized mammalian eggs remains unexplored.Previously,we have reported that Akt can phosphory-late cdc25B-S351(cell division cycle25homologue B) and subsequently activate mitosis-phase promoting factor (MPF)to promote cell division of fertilized mouse eggs (12).MPF is a highly conserved complex consisting of a cdc2kinase and an activating subunit CCNB1(13–17); prior to mitosis,cdc2⁄CCNB1complex remains enzymat-ically inactive.On entry into M phase,cdc25dephosph-orylates cdc2on both residues Tyr15and Thr14,leading to activation of MPF(18,19).Thus,it is likely that G2⁄M transition(activation of MPF)is induced by dephosphor-ylation of cdc2through cdc25(20–24).We have previ-ously demonstrated that Akt activity is associated with dephosphorylation of cdc2and G2⁄M transition in fertil-ized mouse eggs(12).Moreover,PIPP,as one of the newly categorized AKT negative regulators,has been reported to play a critical role in some somatic cells. However,PIPP function in signalling events in develop-ment of fertilized mammalian eggs,remains largely unknown.The fertilized mouse egg is the simplest natural mito-tic cycle model in vertebrates that is close to fertilized human eggs,but there have only been limited reports on studying regulatory mechanisms of mitosis of fertilized mouse eggs.We have previously shown that Akt may be involved in regulating G2⁄M transition in cells of fertil-ized mouse eggs(12),therefore,we hypothesize that PIPP might play an important role in their early develop-ment by inhibiting phosphorylation level of Akt.To test this hypothesis,in this study we examined the effect of PIPP overexpression on Akt phosphorylation at Ser473, as well as its downstream signalling events,in the early development of fertilized mouse eggs.Our results show that PIPP indeed plays an important role in their early development through influencing the PI3K⁄Akt signal-ling pathway.Materials and methodsAnimalsKunming strain mice were obtained from the Depart-ment of Laboratory Animals,China Medical University (CMU).All experiments were performed at CMU in accordance with NIH Guidelines of USA for Care and Use of Laboratory Animals.Protocols for animal handling and treatment procedures were reviewed and approved by the CMU Animal Care and Use Committee.Reagents and plasmidsPhospho-Akt1⁄2⁄3(Ser473)polyclonal antibody,b-actin antibody,horseradish peroxidase(HRP)-conjugated goat anti-rabbit IgG antibody,fluorescein isothiocyanate (FITC)-conjugated goat anti-rabbit IgG antibody,phos-pho-cdc2at Tyr15monoclonal antibody,cdc2monoclonal antibody and CCNB1antibody were purchased from Santa Cruz Biotechnology Inc.(Santa Cruz,CA,USA), enhanced chemiluminescence(ECL)detection kit was from Pierce Biotechnology Inc.,Rockford,IL,USA. [c-32P]ATP was purchased from Peking YaHui Biotech-nology Co.,Beijing,China and pEFBOS vectors(FLAG vector)and pEFBOS-PIPP(FLAG-PIPP)plasmids were kind gifts from Professor Christina Mitchell(Monash Uni-versity,Australia).Other reagents unless otherwise speci-fied,were purchased from Sigma-Aldrich,Shanghai, China.Collection and culture of mouse GV-intact oocytes and fertilized eggsGV-intact oocytes were collected from3-week-old female Kunming mice(24,25)byfirst immersing ovaries in M2 medium.Follicles were punctured with afine needle to release cumulus-enclosed oocytes or naturally denuded GV-intact oocytes.GV-intact oocytes were released from attached follicular cells by repeated pipetting with a mouth-operated micropipette,and then collected and stored at)70°C until used.Fertilized mouse eggs were collected and cultured according to the method described by Hogan and Con-stantini(26).Female mice(Kunming strain,4–6weeks old)were abdominally injected with10IU of pregnant mare’s serum gonadotropin and48h later with10IU human chorionic gonadotropin(hCG).A single female was placed with a single male for fertilization.Fertilized mouse eggs were collected with M2medium the next day(20h after the hCG injection)from the oviducts of females possessing a vaginal plug.These fertilized eggs were collected by repeated pipetting and counting with a mouth-operated micropipette,and then were cultured in M16medium under paraffin oil at37°C in humidified atmosphere of5%CO2in air,until reaching desired cell cycle phases(G1,11–20h after hCG injection;S,20–26h after hCG injection;G2,26–29h after hCG injec-tion;M,29–32h after hCG injection)(Fig.1).Ó2011Blackwell Publishing Ltd,Cell Proliferation,44,156–165.Influence of PIPP in fertilized mouse eggs157Isolation of mRNA,cDNA synthesis and PCRTotal mRNA was extracted from GV-intact oocytes and fertilized mouse eggs (200eggs for each sample)at each phase of mitosis,using QuickPrep TM MicromRNA Purification Kit (Amersham Bioscience Co.,Shanghai,China)according to manufacturer’s instructions.RT-PCR reactions were carried out using RNA PCR Kit (AMV)Ver2.1(TaKaRa Biotechnology (Dalian)Co.,Ltd.)according to manufacturer’s instructions.Sequences of primers were designed using PRIMER 5.0software,and synthesized by Shanghai Sangon Biological Engineering Technology &Services Co.Ltd.,Shanghai,China Sequences of primers for Akt1,Akt2,Akt3,PIPP and b -actin cDNA amplifications are shown in Table 1.PCR products were separated by electrophoresis in 1%agarose gel and stained with ethidium bromide for visualization.Immunocytochemical analysisGV-intact oocytes,fertilized eggs at G 1,S,G 2or M phase,and fertilized eggs at G 1phase microinjected with FLAG vector,FLAG-PIPP 1l g ⁄ml and ⁄or wortmannin 1l M for 10pl ⁄per egg for 10h were fixed in 4%paraformalde-hyde in phosphate-buffered saline (PBS)for 1h at room temperature (RT)and permeabilized for 30min in 0.5%TritonX-100in PBS at 37°C.These eggs were stained overnight with phospho-Akt (Ser473)antibody diluted 1:100at 4°C.After washing three times in PBS contain-ing 1mg ⁄ml bovine serum albumin (BSA),eggs were incubated for 2h at RT in FITC-conjugated goat anti-rabbit secondary antibody,followed by staining with 2l g ⁄ml propidine iodide (PI)for 30s at RT for chroma-tin visualization.Immunofluorescence images were obta-ined using a laser scanning confocal microscope (TCS SP2AOBS;Leica Microsystems Inc.,Exton,PA,USA)with Leica confocal software.Microinjection and observation of fertilized mouse eggs Plasmid DNAs (FLAG-PIPP or FLAG vector)were diluted to 1l g ⁄ml in 5mmol ⁄l Tris and 0.5mmol ⁄l EDTA (pH 7.4;TE)without nuclease contaminant and were microinjected into the fertilized eggs at G 1phase (18h after injection of hCG)using a NARISHIGE micro-injection system (Japan),and an Olympus model IX-70inverted microscope with Hoffmann optics,essentially according to methods described by Bornslaeger (27).Typical injection volume was 5%of total cell volume or 10pl per egg.Eggs in control groups were either not microinjected or microinjected with TE buffer,FLAG vector or wortmannin.Eggs were cultured in M16medium and collected at indicated time-points after hCG injection,for the further experiments.Percentages of cell division were determined after counting using a dissecting microscope,30h after injection of hCG and results were analysed statistically.In addition,microinjected eggs from each group were collected at 26h for Akt activity analy-sis,and at 28h for MPF activity analysis,and western blot analysis for assessing expression of FLAG-PIPP,phospho-Akt at Ser473,dephosphorylation status of phos-pho-cdc2at Tyr 15or expression of CCNB1,and stored in )70°C until used.Western blottingProtein extracts of eggs were prepared by adding approxi-mately 200eggs or 300eggs in minimal volume of collec-tion medium to 20l l of protein extraction buffer (100m M NaCl,20m M Tris-HCl [pH 7.5],0.5%Triton X-100,0.5%NP-40)containing 1m M phenylmethylsulfonyl fluo-ride and 1l g ⁄ml leupeptin and emmli sam-ple buffer was added to protein extracts,and mixtures were boiled for 5min and resolved on 10%SDS–PAGE gel.For immunoblotting,fractionated proteins werePMSG hCG19CleavageGV|G S G M |Injection||1||2||Oocyte stagel One-cell stage (Fertilized egg )l Two-cell stageTime process before and after fertilization of mouse egg (h)(–48)------(–11)---0 2 4 6 8 10 12 14 16 18 20 22 24 26//Figure 1.Development model of fertilized mouse eggs.G1phase:0–9h post fertilization (11–20h after hCG injection);S phase:9–15h post fertilization (20–26h after hCG injection);G2phase:15–18h post fertilization (26–29h after hCG injection);M phase:18–21h post fertilization (29–30h after hCG injection).Table 1.Primer sequences used in PCR analysescDNA (Amplicon size;bp)Forward 5¢–3¢primer Reverse 5¢–3¢primer Genbank no.Akt1(396)atgctggacaaggacggg cacgatgttggcaaagaa NM_009652Akt2(672)aaggatgaagtcgcccaca ccagttgatgctgaggaa NM_007434Akt3(292)gttgggttcagaagaggg tcggctacggcttggata NM_0117852PIPP (412)ctgtcccctacctttcgg gcaaccctatggcaatca NM_172439b -actin (337)gtggcatccatgaaactacataacgcagctcagtaacagtcNM_007393Ó2011Blackwell Publishing Ltd,Cell Proliferation ,44,156–165.158X.Deng et al.transferred to nitrocellulose membranes which were blocked with3%BSA in Tris-buffered saline containing 0.05%Tween20,and probed with primary antibodies in a sealed plastic bag at4°C overnight.Primary antibodies against FLAG tag,phospho-Akt1⁄2⁄3(Ser473),b-actin, phospho-cdc2at Tyr15,cdc2or CCNB1were used at 1:400dilution.Membranes were then incubated in HRP-conjugated second antibody at1:2000(Beijing Zhongshan Biotechnology,Beijing,China).Proteins were detected using an ECL detection system.Assay of MPF activityMPF kinase activity was measured using histone H1 kinase assay(12,28–31).Five cultured eggs in M16med-ium were collected,washed in collection buffer(PBS con-taining1mg⁄ml polyvinyl alcohol,5m M EDTA,10m M Na3VO4and10m M NaF),and then transferred to an Eppendorf tube containing5l l of collection buffer.The Eppendorf tube was immediately stored at)70°C until kinase assay was performed.Frozen eggs were thawed and subjected to freezing and thawing three times.A total of25l l of MPF buffer (54m M b-glycerophosphate,14.5m M pnitrophenylphos-phate,24m M3-(N-morpholino)-propanesulfonic acid [MOPS;pH7.2],14.5m M MgCl2,14.5m M ethylenegly-coltetraacetic acid,0.12m M EDTA,1m M dithiothreitol [DTT],2.4l M PKA inhibitor peptide[PKI],75m M geni-stein[a tyrosine kinase inhibitor],10l M ML-9[a myosin light chain kinase inhibitor],1mg⁄ml histone H1[type III-s],and1mg⁄l each of leupeptin,aprotonin,pepstatin, chymostatin,and trypsin-chymotrypsin inhibitor)was then added to disrupted cells.Histone H1kinase reaction was initiated by adding25l l of20l Ci⁄ml[c-32P]ATP incu-bated at30°C for10min.Then25-l l aliquots were spot-ted on Whatman p81paper,and reaction was stopped with 5%H3PO4solution.After thorough washing,radioactivity on thefilter paper was counted using a Beckman Scintilla-tion Counter(Beckman,Preston,Maryland,USA).Parallel incubation was performed to confirm phos-phorylation of histone H1.Protein extract from10eggs was incubated in50l l of MPF reaction buffer containing 50l Ci⁄ml[c-32P]ATP at37°C for30min,and reaction was stopped by adding an equal quantity of2·SDS buf-fer.The reaction was then resolved on12%SDS–PAGE gel,and incorporation of32P into histone H1was visual-ized by autoradiography.Assay of Akt activityTen eggs cultured in M16medium were collected and lysed as described above and assayed for30min at room temperature in Akt reaction buffer containing50m M Hepes(pH7.5),10m M MgCl2,1m M DTT,1l M PKI, 40l Ci⁄ml[c-32P]ATP,and0.2mg⁄ml histone H2B as substrate.Akt activity was also determined by scintillation counting and autoradiography,as in the MPF activity assay.Statistical analysisData are presented as mean±SEM of separate experi-ments(n>3)and compared by one-way analysis of vari-ance with SPSS11.5software(SPSS,Chicago,IL,USA). P<0.05was taken as significant.ResultsExpressions of Akt1,Akt2and PIPP mRNAWe have previously reported that Akt may phosphorylate cdc25B-Ser351and subsequently activate MPF to promote cell division of fertilized mouse eggs.However,expres-sions of three Akt isoforms and PIPP at mRNA levels in fertilized mouse eggs have not been examined.Therefore, wefirst examined transcript levels of Akt1,Akt2,Akt3 and PIPP in G1,S,G2,and M phases,by RT-PCR.As shown in Fig.2,Akt1and PIPP transcripts were detectable in all phases.However,Akt2transcript was detected only in G1phase of these eggs(Fig.2)and no Akt3transcripts were detected(data not shown);GV-intact oocytes and b-actin were used as control groups,respectively.The data suggested that Akt1and PIPP may be necessary for development of fertilized mouse eggs and that Akt2may play a major role in prophase of DNA synthesis,but Akt3 may not be required for their development.Effect of PIPP on phosphorylation status of Akt at Ser473 To determine phosphorylated levels of Akt at Ser473dur-ing G1,S,G2and M phases,samples were taken fromGV G1S G2MAkt1672 bpAkt2397 bpPIPP412 bpβ-Actin337 bpFigure2.RT-PCR analyses of Akt1,Akt2and PIPP mRNA expres-sion in fertilized mouse eggs.Line1:GV-intact oocytes;Line2:fertil-ized eggs at G1phase;Line3:fertilized eggs at S phase;Line4:fertilized eggs at G2phase;Line5:fertilized eggs at M phase.GV-intact oocytes and b-actin were served as controls.Ó2011Blackwell Publishing Ltd,Cell Proliferation,44,156–165.Influence of PIPP in fertilized mouse eggs159each stage.GV-intact oocytes and b -actin were used as control groups.Immunoblot analysis showed that levels of phosphorylated Akt1⁄2⁄3at Ser473were higher at four mitotic phases than of GV-intact oocytes (Fig.3A),sug-gesting that Akt was phosphorylated.To determine effects of overexpression of PIPP on phosphorylated Akt at Ser473,fertilized eggs were cul-tured in M16medium after microinjection of FLAG-PIPP.Two control groups were non-microinjected or microinjection with FLAG vector only.Cell lysateswere immunoblotted with FLAG tag antibody,phos-phorylated Akt at Ser473site-specific antibody,or b -actin antibody (as control)(Fig.3B).Compared to untreated eggs and FLAG vector-expressing eggs,over-expression of PIPP at around 130kDa was observed in fertilized eggs microinjected with FLAG-PIPP (Fig.3B,upper panel).As molecular weight of FLAG vector (about 1kDa)is too small to be observed,we ignored its expres-sion.Levels of phosphorylated Akt at Ser473was dis-tinctly reduced in eggs microinjected with FLAG-PIPP (Fig.3B,middle panel)compared with eggs non-micro-injected or microinjected with FLAG vector only,suggest-ing that overexpression of PIPP negatively regulated phosphorylation status of Akt at Ser473in mouse one-cell embryos.Overexpression of PIPP affects localization of phosphorylated Akt at Ser473Previous reports have indicated that Akt activity is driven by membrane localization initiated by binding PH domain of Akt to PtdIns(3,4,5)P 3or PtdIns(3,4)P 2,followed by phosphorylation at residues serine 473and threonine 308(3,9,32).Phosphorylation of Thr308may promote confor-mation change of hydrophobic and phosphate binding pockets more suitable for the hydrophobic motif (HM)binding to other proteins (8).Thus,membrane localization of Akt requires Ser 473phosphorylation (8,32,33).Furthermore,PIPP has been identified as a negative regulator of PI3-kinase signalling by hydrolysing 5-posi-tion phosphate of PtdIns(4,5)P 2and ⁄or PtdIns(3,4,5)P 3and regulation of phosphorylation of Akt at Ser473in somatic cells (3).Hence,here we examined the effect of PIPP on localization of phosphorylated Akt at Ser473in mitotic stages in development of fertilized eggs.Samples were incubated with anti-phospho-Akt (Ser473)specific antibody,and subsequently labelled by secondary FITC-conjugated goat-anti-rabbit antibody (Fig.4A,left panels,green).DNA was counterstained with PI (Fig.4A,middle panels,red).Results showed that phosphorylated Akt at Ser473co-localized with cytomembranes of fertilized eggs during mitotic stages (Fig.4A-a).When fertilized eggs were treated with FLAG-PIPP or wortmannin,locali-zation of phosphorylated Akt at Ser473was dissociated from cytomembranes to cytoplasm and nucleus.In the meantime,cell division was delayed (Fig.54-b,line 3and 4).As controls,phosphorylated Akt in eggs treated with FLAG vector remained localized at the cytomembrane and cell division of these cells was not affected (Fig.4A-b,line 2).Untreated GV-intact oocytes were used as fur-ther control for inactive Akt (Fig.4A-b,line 1).Our results suggest that PIPP regulated Akt localization by inhibiting its phosphorylated level.GVG 1S G 2MpAkt Ser473-ActinG1SG2MFertilized eggs************overexpression on phosphorylation mouse eggs.(A)Expression of phosphorylated Immunoblot analysis of phosphorylation of oocytes were used as control.(A-b)phospho-Akt at Ser473(pAkt phosphorylated Akt at Ser473⁄b -actin significance between experimental 0.001).Error bar represents mean experiments.(B )Expression of exogenous inhibition of overexpression of PIPP Ser473.Fertilized mouse eggs were either microinjected with plasmids DNA (FLAG-vector immunoblotted with antibodies specific Ser473.b -actin served as loading control.Ó2011Blackwell Publishing Ltd,Cell Proliferation ,44,156–165.160X.Deng et al.Overexpression of PIPP affects Akt activityTo investigate effects of PIPP on Akt activity,we mea-sured Akt activities using histone H2B as substrate.Fertilized eggs were either not microinjected or micro-injected with FLAG vector,FLAG-PIPP,or wortmannin.Untreated GV-intact oocytes were used as further control for inactive Akt.Results showed that Akt activities in non-microinjected fertilized eggs or fertilized eggs micro-injected with FLAG vector were significantly higher than that in GV-intact oocytes or fertilized eggs micro-injected with FLAG-PIPP or wortmannin (***P <0.001)(Fig.4B),suggesting that PIPP plays an important role in regulating Akt activity during early development of fertil-ized mouse eggs.Overexpression of PIPP affects MPF activity and dephosphorylation of cdc2at Tyr15The inhibitory effect of FLAG-PIPP on Akt activity in fer-tilized eggs suggests a role for PIPP in regulating fertilized mouse embryonic cleavage,by influencing Akt down-stream signal cascades.First,to determine whether over-expression of PIPP may suppress MPF activity (H1kinase activity)in early development of fertilized eggs were collected at 28h after hCG injection for assay of H1kinase activity.The results showed that MPF activities in eggs treated with FLAG-PIPP or Wortmannin were main-tained notably at a relatively lower level than that in untreated eggs,or eggs treated with TE buffer or FLAG vectors (***P <0.001;Fig.5A).pAKT Ser473 PI Merged21pAKT Ser473 PI MergedW o r t m a n n i n F L A G -P I P P F L A G v e c t o r O o c y t e sGV-intact OocytesFertilized EggsFLAG vector FLAG-PIPP WortmanninOocytes Fertilized eggs*********distribution of phosphorylated Akt at Ser473and Akt with pAkt Ser473antibody and then treated with stained with propidium iodide (PI,red,middle).Panels phospho-Akt Ser473during G 1,S,G 2or M phases fertilized eggs microinjected with FLAG vector,FLAG-PIPP eggs,or fertilized eggs treated with FLAG vector,FLAG-PIPP Ó2011Blackwell Publishing Ltd,Cell Proliferation ,44,156–165.Influence of PIPP in fertilized mouse eggs161Second,to investigate whether overexpression of PIPP may suppress dephosphorylation of cdc2at Tyr15in fertil-ized mouse eggs,we used pTyr15of cdc2antibody to detect phosphorylation status of cdc2at Tyr15in M phase, by microinjecting them with FLAG-PIPP or wortmannin. Eggs were non-microinjected,microinjected with TE buf-fer or FLAG vector as control groups.Eggs were collected at28h after hCG injection and immunoblotted using spe-cific phospho-cdc2Tyr15antibody;cdc2antibody was used as control.As anticipated,no significant difference was noted in the three control groups(P>0.05).However, in groups microinjected with FLAG-PIPP or wortmannin, phosphorylation levels of cdc2at Tyr15were relatively higher than those of control groups(***P<0.001;******FLAG-PIPP Wortmannin******Untreated TE buffer FLAG vector FLAG-PIPP WortmanninFLAG-PIPP WortmanninMouse fertilized eggs******G2⁄M transition ofcounting and autoradiography.experimental groups versus controlfertilized mouse eggs.(B-a)panel).Unphosphorylatedwere reported asasterisk(***P<0.001).Eggs were untreated,FLAG-PIPP microinjection.Data were pooled fromgroups is indicatedÓ2011Blackwell Publishing Ltd,Cell Proliferation,44,156–165.162X.Deng et al.Fig.5B),suggesting that PIPP overexpression may delay G2⁄M transition by blocking dephosphorylation level of phosphorylated cdc2at Tyr15,which in turn lead to mitotic delay of these fertilized eggs.In addition,we also exam-ined expression of CCNB1during G2⁄M transition in various groups of eggs(non-microinjected,microinjected with TE buffer,FLAG vector,FLAG-PIPP,or with wort-mannin).No significant difference in CCNB1expression among these groups was observed(Fig.5C). Overexpression of PIPP affected egg cell divisionTo examine whether PIPP would affect the mitotic cell cycle,fertilized mouse eggs were cultured in M16 medium in G1phase for10h after eggs were non-micro-injected,microinjected with TE buffer,FLAG vector, FLAG-PIPP,or wortmannin.Eggs were non-microinject-ed,microinjected with TE buffer or FLAG vector as con-trol groups.In three control groups,in the region of56%eggs reached the two-cell stage30h after hCG injection; there was no significant difference among these control groups(P>0.05).However,only<11%of eggs that had been microinjected with FLAG-PIPP or wortmannin reached two-cell stages30h after hCG injection (***P<0.001,Fig.5D).These results demonstrate that overexpression of PIPP may interfere with the time course of cell division of fertilized mouse eggs,suggesting that PIPP may indirectly block early cell division by inhibiting Akt activity in these early embryos.Together,these results strongly suggest that PIPP functions as a negative regula-tor at G2⁄M transition by inhibiting Akt phosphorylation and subsequent downstream signalling events. DiscussionThe relatively uncharacterized PIPP possesses N-and C-terminal proline-rich domains,a central5-phosphatase domain and a SKICH domain.The5-phosphatase domain encoded by amino acids424-729may hydrolyze5-posi-tion phosphate from PtdIns(3,4,5)P3and⁄or PtdIns(4,5)P2 forming PtdIns(3,4)P2and PtdIns(4)P,respectively.Cata-lytically inactive PIPP in this5-phosphatase domain was made from mutating histidine557within the PIPP sequence to alanine(3).The SKICH domain from amino acids736to816mediates PIPP localization to plasma membrane ruffles(Fig.6).Although PIPP has been shown to have a wide tissue distribution,including in brain,heart,kidney,stomach,small intestine and lung, little is known about its function in fertilized eggs(1,3). Previous reports indicate that PI3K is activated by stimu-lation of growth factors and then PI3K phosphorylates PtdIns(4,5)P2at D-3position of the inositol ring to gener-ate PtdIns(3,4,5)P3(34,35).PtdIns(3,4,5)P3may bind the PH domain of Akt and meanwhile,Akt becomes activated which facilitates glucose uptake.In somatic cells,PtdIns(3,4,5)P3is rapidly dephosphorylated by lipid phosphatases including PIPP.However,the role of 5-phosphatases as a suppressor has not been elucidated in fertilized mammalian eggs(36–38).In this study,we detected Akt1,Akt2,Akt3,PIPP mRNA expression and expressive change of phosphory-lated Akt1⁄2⁄3at Ser473in thefirst round of mitosis of the fertilized mouse eggs.To the best of our knowledge, these observations have not been reported previously. Furthermore,we microinjected FLAG-PIPP or FLAG vector into the eggs in G1phase and harvested them dur-ing transition of G2⁄M.We chose anti-FLAG tag antibody to detect expression of FLAG-PIPP after microinjecting the eggs with FLAG-PIPP or FLAG vector.Molecular weight of PIPP is108kDa and we observed expression of FLAG-PIPP of around130kDa in these eggs microin-jected with FLAG-PIPP(Fig.3B,upper panel).Moc-hizuki and Ooms have also observed this band of around 130kDa(2,3);moreover,Mochizuki and Takenawa have reported that this was due to phosphorylation of PIPP(2). Our data indicate that exogenous PIPP may be expressed in fertilized eggs and overexpression of PIPP may inhibit phosphorylation of Akt(Fig.3B,middle panel).Thus,we speculated that PIPP may interfere with the mitotic pro-cess of our fertilized mouse eggs via an Akt pathway.A previous report of our team has shown that Akt is one of the key promoting factors for thefirst round of mitosis of fertilized mouse eggs;Akt overexpression pro-motes their(12).In this study,we further demonstrated that Akt1and PIPP transcripts were detected in G1,S,G2 and M phase,but Akt2transcripts were expressed only in G1and no Akt3transcript was found in allphasesPIPPHydrolyzing1 424 729 816 1003PtdIns(3,4,5)P3Binding PH domainAkt1 148 412 480PH domain(1–106)Proline-rich5-ptase Catalytic domainSKICH TailFigure6.Domain organization of the mannalian proline-rich inosi-tol polyphosphate5-phosphatases(PIPP)and protein kinase B(Akt). The proline-rich domain of PIPP may hydrolyze5-position phosphates of PtsIna(3,4,5)P3and⁄or PtsIna(4,5)P2forming PtsIna(3,4)P2and⁄or PtsIna(4)P.The PH domain of Akt may bind PtdIns(3,4,5)P3.Ó2011Blackwell Publishing Ltd,Cell Proliferation,44,156–165.Influence of PIPP in fertilized mouse eggs163。

安徽大学硕士学位论文LKB1（Thr336）磷酸化多克隆抗体的制备及在细胞中表达的检测Preparation and Intracellular Expression detection of Phosphorylated LKB1 (Thr336) Polyclonal Antibody姓名：任艳敏学科专业：细胞生物学研究方向：细胞凋亡与肿瘤发生指导教师：黄蓓完成时间： 2008-5LKB1（Thr336）磷酸化多克隆抗体的制备及在细胞中表达的检测摘要PJS综合症是一种遗传性肿瘤综合症，该病患者患肿瘤的几率增加。

致病基因编码的核定位激酶LKB1作为肿瘤抑制子在发挥作用，但是LKB1在细胞中调控的机制及生理基础都不清楚。

研究表明LKB1在细胞中被磷酸化并且Thr336磷酸化位点在LKB1抑制细胞生长中起到重要的作用。

为了研究LKB1在不同细胞中的表达规律及其对细胞增殖的抑制功能，本实验通过生物信息学方法选取LKB1 Thr336位点附近10个氨基酸且使Thr336位点磷酸化，并铰链上BSA，以此为抗原，对兔子进行免疫，制备的抗血清通过Western blot检测抗体效价，并用LKB1抗体和p-LKB1(Thr336)抗体分别对人正常肝脏细胞HL7702、人胚肾细胞HEK293、小鼠肉瘤细胞S180、非洲绿猴肾细胞COS7及人结肠癌细胞Caco2检测。

结果显示，LKB1抗体不仅识别His-LKB1蛋白而且识别p-LKB1(Thr336)肽段，而p-LKB1(Thr336)抗体仅识别p-LKB1(Thr336)抗原；且在正常细胞及肿瘤细胞中LKB1和p-LKB1(Thr336)表达量有差异，在增殖越快的细胞中，p-LKB1(Thr336)表达量越高。

关键词： LKB1; 磷酸化多克隆抗体; 免疫印迹法; 生物信息学AbstractPeutz±Jeghers syndrome is an inherited cancer syndrome, which results in a greatly increased risk of developing tumours in those affected. The causative gene encodes a nuclear-localized protein kinase, termed LKB1, which is predicted to function as a tumour suppressor. The mechanism by which LKB1 is regulated in cells is not known, and nor have any of its physiological substrates been identified. Recent studies have demonstrated that LKB1 is phosphorylated in cells and Its Thr336 phosphorylation site play an important role in cell growth inhibition. To study the expression and the suppression to cell proliferation of LKB1in different cells, the LKB1Thr336 was phosphorylated and the neighboring 10-amino acid region was chosen to hinge on a BSA through Bioinformatics methods. Then the constructed peptide was used as antigen to immunize rabbits and antibody titer was performed by anti-serum western blot detection. In addition, Rabbit anti-LKB1 antibody and the p-LKB1 (Thr336) antibody were also used to assay with several cell lines, including the human liver cells HL7702, embryonic kidney cells HEK293, the mice sarcoma cells S180, the African green monkey kidney cells COS7 and the human colon cancer cells Caco2. The results showed that Rabbit-anti-LKB1 antibodies can interact with both His-LKB1 protein and p-LKB1 (Thr336) peptide, while the p-LKB1 (Thr336) antibody can only interact with p-LKB1 (Thr336) antigen. Moreover, there are quite different expression patterns of LKB1 and p-LKB1 (Thr336) between normal and tumor cells. Our results also suggested that the expression levels of p-LKB1 (Thr336) are in positive correlation with the proliferation of cells.Key words：p-LKB1 (Thr336); Phosphorylated Polyclonal antibody; Western blot；Bioinformatics目录第1章绪论 (7)1.1. LKB1/STK11 的基本结构及分布 (7)1.2 LKB1/STK11的生物学功能 (7)1.3. LKB1磷酸化位点研究现状 (10)1.4.国内外LKB1 Thr336位点磷酸化抗体研究现状 (11)1.5.本实验的目的和意义 (11)第2章LKB1蛋白的生物信息分析及磷酸化抗原的设计 (14)2.1 实验有关数据库 (14)2.2 实验方法 (14)2.2.1 LKB1蛋白序列分析 (14)2.2.2.LKB1磷酸化位点分析 (15)2.2.3. LKB1抗原决定蔟的预测 (17)2.2.4. LKB1疏水性及抗原性分析 (17)2.2.5.合成肽段的设计原则 (19)2.3. LKB1抗原设计合成结果及纯度检测 (19)第3章His-LKB1重组蛋白的诱导表达及分离纯化 (21)3.1实验材料 (21)3.2实验方法 (26)3.3. SDS-PAGE检测实验结果 (30)第4章 LKB1（Thr336）多肽抗原的设计及其多克隆抗体的制备 (33)4.1 实验试剂 (33)4.2 实验方法 (33)4.2.1兔子免疫与血清处理 (33)4.2.2 Western blot方法检测抗体及效价 (34)4.3 实验结果 (36)第5章 P-LKB1（Thr336）抗体的特异性鉴定 (38)5.1 实验材料 (38)5.2 实验方法-Western blot检测抗体特异性 (38)5.3 Western Blot检测抗体特异性结果 (38)第6章 p- LKB1（Thr336）多克隆抗体的分离纯化 (39)6.1 实验材料 (39)6.2 实验方法-抗原条结合法分离纯化抗血清 (40)6.3 实验结果 (40)第7章LKB1在正常细胞及肿瘤细胞中表达的检测 (41)7.1. 实验材料与试剂 (41)7.2 实验方法 (42)7.2.1细胞培养方法 (42)7.2.4 LKB1在细胞中表达规律的检测 (45)7.3 实验结果 (45)总结 (47)1.. 结果与讨论 (47)2. 本实验创新点 (48)3. 存在的问题与展望 (48)致谢 (49)参考文献 (50)第1章绪论LKB1 基因,又名STKⅡ( serinePthreonine proteinkinase 11) 基因, 是由Hemminki 等[1]在1998 年从Peutz Jeghers syndrome ( PJS) 患者的血细胞中克隆出来的一种基因, PJS是一种常染色体显性遗传疾病，患者不但肠道、胃、胰腺发生恶性肿瘤的可能性增加, 而且在乳腺、子宫颈、肺、卵巢、睾丸发生恶性变危险度也增加，初步估计93 %的PJS 患者平均在43 岁时发生恶性肿瘤[2]。

related processes. The rationale and potential of targeting mitochondrial fission protein Drp1in cancer therapy will be discussed.2. Mitochondrial dynamics and cancer progression The mitochondrial network exists as mixed structures of long interconnected tubules with short isolated dot-like spheres. The status of mitochondrial network is regulated by highly dynamic processes involving fusion, fission and movement of the organelle along cytoskeleton tracks. Highly conserved dynamin-related GTPases (DRPs) have been identified as the primary regulators of mitochondrial dynamics [2]. Notably, dynamin-related protein 1 (Drp1) is essential for mitochondrial fission. Mitofusins (Mfn1 and Mfn2)and Opa1 are required for mitochondrial fusion. By modifying the balance of mitochondrial fusion and fission events, the mitochondrial network remodels in response to a variety of signals derived from both endogenous and exogenous stimuli. Defects in the regulation of such balance have been correlated with human pathologies [2].Mitochondrial fission is required for certain normal cellular functions such as facilitating organelle transport in neurons [3], removal of damaged mitochondria through mitophagy [4]and proper mitochondrial distribution during cell division [5]. This process is achieved through the coordination of Drp1 with other adaptor proteins including Mff, Fis1 and MiDs.Drp1 polymerizes into spirals around mitochondria, which constricts the organelle through GTP hydrolysis leading to mitochondrial division [6]. The activity of Drp1 is under complex regulation through posttranslational modifications, including phosphorylation, S-nitrosylation, ubiquitination and SUMOylation [7]. Excessive mitochondrial fission mediated by dysregulated Drp1 has been observed in diseases including cancer and neurodegenerative diseases.2.1 The cycle of mitochondrial remodeling and the cell cycle Cancer is characterized as a disease of inappropriate cell proliferation, with dysregulated cellcycle control as one of its fundamental aspects [8]. Recent findings have revealed that mitochondrial fusion and fission cycles are integrated into the regulation of cell cycle progression [9,10]. Mitochondria cannot be created de novo. They are formed from the division of existing organelles, and they must be inherited from mother cells through cell division. Mitochondria grow continuously throughout the cell cycle, and the organization of the mitochondrial network is sophisticatedly controlled across the different phases of the cell cycle. At the G1/S border, mitochondria form a single, giant tubular network [9].Mitochondria at this cell cycle stage are hyperpolarized and highly coupled, which is associated with increased energy production in order to prepare for the initiation of the highly energy consuming process – DNA synthesis [9]. In addition, such mitochondrial hyperfusion also facilitates the mixing of mitochondrial contents such as mtDNA between adjacent mitochondria in order to maintain a homogenous mitochondrial network within the cell, thus ensuring proper inheritance following cellular division.The formation of a highly connected mitochondrial network at G1/S border is transient.During the following S, G2 and M phases, the hyperfused mitochondrial network is then disassembled and becomes increasingly fragmented. Evidence has shown that Drp1-mediated mitochondrial fission is required for the proper progression of those cell cycle phases following G1/S transition [10]. Extensive fragmentation of the mitochondrial network is achieved at mitosis and is required to facilitate the equal segregation ofmitochondrial contents between daughter cells. Mitotic mitochondrial fission is directly regulated by the kinases involved in mitosis. Phosphorylation by mitotic kinase Aurora A promotes RalA relocalization to mitochondrial membranes, where it recruits the effector RalBP1. RalBP1 functions as a scaffold for cyclin B/cyclin-dependent kinase 1 (cdk1),NIH-PA Author ManuscriptNIH-PA Author ManuscriptNIH-PA Author Manuscriptwhich promotes phosphorylation of Drp1 at Ser616 resulting in mitochondrial fission [5,11].Sustained mitochondrial hyperfusion beyond the G1/S border induces replication stresscausing ATM-dependent G2/M delay and chromosomal instability during mitosis [10]. The replication stress was shown due to constant replication initiation signaling generated from hyperfused mitochondria [9,10]. Prolonged mitochondrial fusion also causes mitochondrial bridges between daughter cells resulting in a defective cytokinesis, unequal distribution of mitochondria and even missegregation of chromosomes causing aneuploidy. Theseorganelle segregation abnormalities in turn lead to mitochondrial dysfunction and delay in cell growth [5]. The genome instability is well illustrated by the disorganized nuclear structure and micronuclei in cells that experience persistent mitochondrial hyperfusion(Figure 1). Thus, the alterations in mitochondrial morphology may initiate a mitochondria-to-nucleus retrograde signaling in order to activate cell cycle checkpoint at G2/M, and thus ensure proper mitochondrial inheritance during every cell division cycle. These novelobservations established functional links between mitochondrial morphology and cell cycle progression and have lead to the investigation as to whether cancer cells have dysregulated mitochondrial dynamics that contribute to cancer progression.2.2 Drp1-mediated mitochondrial fission in cancersCumulative evidence is beginning to reveal the links between cancer and dysregulated mitochondrial dynamics. It has been found that non-small-cell lung carcinoma A549 cells have markedly higher levels of Drp1 and lower levels of fusion protein Mfn-2 than normal airway cells [12]. Such changes in the mitochondrial dynamics proteins were related with enhanced mitochondrial fission and reduced fusion in these tumor cells. In human tissues, it was found that lung adenocarcinoma sections had an increase in both the total expression and the phosphorylated form of Drp1, and reduced expression of Mfn-2 when compared to adjacent non-neoplastic lung tissue. Importantly, reversing mitochondrial fission in these tumor cells was able to suppress cell growth both in vitro and in vivo [12]. Suchdysregulated mitochondrial fission has also been observed in human breast carcinomas [13].Interestingly, Drp1-mediated mitochondrial fission is also required for cancer cell migration and invasion [13]. Mitochondrial fission is a critical process for distribution of mitochondria into lamellipodial regions at the leading edge of breast cancer cells in response tochemoattractant-induced migration. The localization of mitochondria into the leading edge has been posited to provide necessary energy at the defined subcellular region. Further, it has also been reported that Drp1-mediated mitochondrial fission is enhanced by the overexpression of an oncogenic protein survivin, contributing to the development ofglycolytic phenotype of neuroblastoma [14]. Enhanced glycolysis is one of the hallmarks of many different cancer types, which promotes tumor cell progression and confers drug resistance.Mitochondrial hyperfusion triggers S phase initiation, and this alone is sufficient to drive G0quiescent cells into S phase of the cell cycle, suggesting mitochondrial morphology may be under direct regulation of growth factor and convey the growth signals to the cell cyclemachinery. Both Aurora A and RalA, which regulates mitotic phosphorylation of Drp1, act downstream of oncogenic Ras, contributing to tumorigenesis through the induction of genome instability [15,16]. Therefore enhanced mitochondrial fission may function as an important point of convergence in mediating oncogenic signaling and promoting cancer cell growth and metastasis. Since most of the Drp1 is cytosolic and overexpression of wild-type Drp1 alone does not seem to enhance mitochondrial fission [17], enhanced Drp1 activation and recruitment may play more important roles for the increased mitochondrial fissionobserved in those cancer cells. The non-mitochondrial roles for Drp1 and the consequences of Drp1 upregulation due to non-mitochondrial function remain to be revealed.NIH-PA Author Manuscript NIH-PA Author Manuscript NIH-PA Author Manuscript2.3 Inhibiting Drp1 for cancer therapyDespite the protective role of mitochondrial fusion against cytotoxic stimuli [18], Drp1knockout immortalized mouse embryonic fibroblasts (MEFs) maintain the ability to undergo efficient apoptosis albeit with a slight delay in the release of apoptotic factors such as cytochrome c from mitochondria [19]. Intriguingly, persistent mitochondrial hyperfusion due to Drp1 depletion also induces cytochrome c release from mitochondria, leading toapoptosis [20]. Reduced cancer cell growth and/or enhanced spontaneous apoptosis induced by inhibiting Drp1 have been observed both in vitro and in vivo in several cancer types,including colon, breast, lung and cervical cancers [10,12,20,21]. The mechanism underlying the cellular dysfunction and cell death induced by mitochondrial hyperfusion seems to be the increased replication stress and mitotic defects that severely affect the genome integrity of cancer cells. Persistent mitochondrial fusion also causes mitochondrial dysfunction including accumulation of mtDNA mutation and generation of reactive oxygen species (ROS) [21,22]. This combined effect of genome instability and mitochondrial dysfunction may eventually result in the activation of mitochondrial apoptotic pathway [20]. This unique mechanism could potentially circumvent the resistance of cancer cells to conventional chemotherapy.The first selective inhibitor for Drp1, mitochondrial division inhibitor-1 (mdivi-1), was identified from a chemical library screen using yeast-based assays [23]. Mdivi-1 is aquinazolinone derivative, attenuating Drp1 self-assembly, thereby causing the inhibition of mitochondrial division. Due to its potential in preventing mitochondrial fragmentation-related apoptosis, mdivi-1 has shown protective efficacy in a number of disease models,including acute kidney injury, heart ischemia/reperfusion injury and Parkinson’s disease[18]. Thus mdivi-1 represents a potential class of therapeutics for stroke, myocardialinfarction and neurodegenerative diseases [23]. Importantly, in terms of cancer mdivi-1 also induces gross genome instability [10] and was shown to have in vivo efficacy against lung tumor [12]. In addition, there was no significant toxicity in rodent disease models observed after mdivi-1 therapy, although in-depth toxicology, pharmacodynamics andpharmacokinetics of mdivi-1 have not been reported. Recently, the possible off-target effects of mdivi-1 have been reported, such as Drp1-independent role of mdivi-1 in preventingmitochondrial outer membrane permeabilization (MOMP) [24], and the effect of mdivi-1 on ion currents and cell membrane potential [25]. While mdivi-1 may still serve as an important research tool, due to its undesired effects and relatively high IC50 in preventingmitochondrial fission in mammalian cells (IC50 ≈ 50 μM) [23], the development of more potent and specific inhibitors is guaranteed. Mdivi-1 could possibly be employed as a lead compound for further optimization. Moreover, structural insights into the action of Drp1 will also undoubtedly facilitate the rational design and development of new generations of inhibitors. Excitingly, a novel Drp1 peptide inhibitor P110, which was designed to inhibit the interaction between Drp1 and Fis1, has been reported recently. P110 preventsmitochondrial fragmentation by selectively inhibiting the GTPase activity of Drp1 and blocks Drp1/Fis1 interaction, showing neuroprotectivity in a cell culture model ofParkinson’s disease [26]. It would also be interesting to test whether P110 has antitumor potential.3. Expert opinionAs enhanced mitochondrial fission and impaired fusion appear to contribute fundamentally to the causes of certain aspects of cancer, Drp1-mediated mitochondrial fission thus may well represent a promising novel therapeutic target for cancers with excessive mitochondrial fission. Drp1 inhibition, either through genetic ablation or by pharmacological inhibitor mdivi-1 has shown initial proof of principle in cancer treatment. Nevertheless, manyquestions remain to be addressed in order to provide more comprehensive molecular basis NIH-PA Author Manuscript NIH-PA Author Manuscript NIH-PA Author Manuscriptfor the development of effective Drp1-related targeted therapy. What is the frequency of Drp1 dysregulation across different types of human cancers, what is the molecularmechanism that leads to Drp1 dysregulation in cancers, do alterations in mitochondrial morphology directly contribute to tumorigenesis, and what are the molecular events that transduce signals derived from altered mitochondrial morphology? A better elucidation of the functional significance of mitochondrial dynamics in cancer physiology together with a clearer understanding of the molecular machineries that regulate mitochondrial dynamics will undoubtedly present a promising avenue for future exploration of mitochondrial dynamics-based therapeutic options.BibliographyPapers of special note have been highlighted as either of interest (•) or of considerable interest (••) to the readers.1. Green DR, Van Houten B. SnapShot: mitochondrial quality control. Cell. 2011; 147(4):950, 950 e1.[PubMed: 22078889]2. Westermann B. Mitochondrial fusion and fission in cell life and death. Nat Rev Mol Cell Biol.2010; 11(12):872–84. [PubMed: 21102612]3. Morris RL, Hollenbeck PJ. The regulation of bidirectional mitochondrial transport is coordinated with axonal outgrowth. J Cell Sci. 1993; 104(Pt 3):917–27. [PubMed: 8314882]4. Twig G, Elorza A, Molina AJ, et al. Fission and selective fusion govern mitochondrial segregation and elimination by autophagy. EMBO J. 2008; 27(2):433–46. [PubMed: 18200046]5. Kashatus DF, Lim KH, Brady DC, et al. RALA and RALBP1 regulate mitochondrial fission at mitosis. Nat Cell Biol. 2011; 13(9):1108–15. [PubMed: 21822277]6•. Mears JA, Lackner LL, Fang S, et al. Conformational changes in Dnm1 support a contractile mechanism for mitochondrial fission. Nat Struct Mol Biol. 2011; 18(1):20–6. Provides structual insights into the mechanism of Drp1-mediated mitochondrial fission. [PubMed: 21170049]7. Elgass K, Pakay J, Ryan MT, Palmer CS. Recent advances into the understanding of mitochondrialfission. Biochim Biophys Acta. 2013; 1833(1):150–61. [PubMed: 22580041]8. Hanahan D, Weinberg RA. Hallmarks of cancer: the next generation. Cell. 2011; 144(5):646–74.[PubMed: 21376230]9•. Mitra K, Wunder C, Roysam B, et al. A hyperfused mitochondrial state achieved at G1-S regulatescyclin E buildup and entry into S phase. Proc Natl Acad Sci USA. 2009; 106(29):11960–5.Demonstrates that mitochondrial fusion and fission cycle is coupled with cell division cycle.[PubMed: 19617534]10•. Qian W, Choi S, Gibson GA, et al. Mitochondrial hyperfusion induced by loss of the fissionprotein Drp1 causes ATM-dependent G2/M arrest and aneuploidy through DNA replication stress. J Cell Sci. 2012; 125(Pt 23):5745–57. Presents a potential mechanism how dysregulated mitochondrial fission induces genome instability. [PubMed: 23015593]11. Taguchi N, Ishihara N, Jofuku A, et al. Mitotic phosphorylation of dynamin-related GTPase Drp1participates in mitochondrial fission. J Biol Chem. 2007; 282(15):11521–9. [PubMed: 17301055]12•. Rehman J, Zhang HJ, Toth PT, et al. Inhibition of mitochondrial fission prevents cell cycleprogression in lung cancer. FASEB J. 2012; 26(5):2175–86. First demonstration of the in vivo efficacy of Drp1 inhibitor mdivi-1 in suppression of tumor growth. [PubMed: 22321727]13. Zhao J, Zhang J, Yu M, et al. Mitochondrial dynamics regulates migration and invasion of breastcancer cells. Oncogene. 201210.1038/onc.2012.49414. Hagenbuchner J, Kuznetsov AV, Obexer P, Ausserlechner MJ. BIRC5/Survivin enhances aerobicglycolysis and drug resistance by altered regulation of the mitochondrial fusion/fission machinery.Oncogene. 201210.1038/onc.2012.50015. Yang G, Mercado-Uribe I, Multani AS, et al. RAS promotes tumorigenesis through genomicinstability induced by imbalanced expression of Aurora-A and BRCA2 in midbody duringcytokinesis. Int J Cancer. 2013; 133(2):275–85. [PubMed: 23319376]NIH-PA Author ManuscriptNIH-PA Author ManuscriptNIH-PA Author Manuscript16. Lim KH, Mercado-Uribe I, Multani AS, et al. Activation of RalA is critical for Ras-induced tumorigenesis of human cells. Cancer Cell. 2005; 7(6):533–45. [PubMed: 15950903]17. Smirnova E, Griparic L, Shurland DL, van der Bliek AM. Dynamin-related protein Drp1 is required for mitochondrial division in mammalian cells. Mol Biol Cell. 2001; 12(8):2245–56.[PubMed: 11514614]18. Lackner LL, Nunnari J. Small molecule inhibitors of mitochondrial division: tools that translate basic biological research into medicine. Chem Biol. 2010; 17(6):78–83.19. Ishihara N, Nomura M, Jofuku A, et al. Mitochondrial fission factor Drp1 is essential for embryonic development and synapse formation in mice. Nat Cell Biol. 2009; 11(8):958–66.[PubMed: 19578372]20. Inoue-Yamauchi A, Oda H. Depletion of mitochondrial fission factor DRP1 causes increased apoptosis in human colon cancer cells. Biochem Biophys Res Commun. 2012; 421(1):81–5.[PubMed: 22487795]21. Parone PA, Da Cruz S, Tondera D, et al. Preventing mitochondrial fission impairs mitochondrial function and leads to loss of mitochondrial DNA. PLoS One. 2008; 3(9):e3257. [PubMed:18806874]22. Malena A, Loro E, Di Re M, et al. Inhibitiony of mitochondrial fission favours mutant over wild-type mitochondrial DNA. Hum Mol Genet. 2009; 18(18):3407–16. [PubMed: 19561330]23•. Cassidy-Stone A, Chipuk JE, Ingerman E, et al. Chemical inhibition of the mitochondrial division dynamin reveals its role in Bax/Bak-dependent mitochondrial outer membrane permeabilization.Dev Cell. 2008; 14(2):193–204. Identification of the first small molecule inhibitor of Drp1(mdivi-1) in a yeast-based chemical library screen. [PubMed: 18267088]24. Kushnareva Y, Andreyev AY, Kuwana T, Newmeyer DD. Bax activation initiates the assembly of a multimeric catalyst that facilitates Bax pore formation in mitochondrial outer membranes. PLoS Biol. 2012; 10(9):e1001394. [PubMed: 23049480]25. So EC, Hsing CH, Liang CH, Wu SN. The actions of mdivi-1, an inhibitor of mitochondrial fission, on rapidly activating delayed-rectifier K(+) current and membrane potential in HL-1murine atrial cardiomyocytes. Eur J Pharmacol. 2012; 683(1–3):1–9. [PubMed: 22374256]26. Qi X, Qvit N, Su YC, Mochly-Rosen D. A novel Drp1 inhibitor diminishes aberrant mitochondrialfission and neurotoxicity. J Cell Sci. 2013; 126(Pt 3):789–802. [PubMed: 23239023]NIH-PA Author Manuscript NIH-PA Author Manuscript NIH-PA Author ManuscriptFigure 1. Mitochondrial hyperfusion induced by depletion of Drp1 causes genome instability MDA-MB-231 breast cancer cells stably expressing mitochondria-targeted GFP were transfected with control or Drp1 siRNA for 4 days. DNA was visualized by DAPI staining.Control cells contained the relatively short and dispersed mitochondria. In contrast, Drp1knockdown cells showed hyperfused mitochondria concomitant with the disorganized nuclear structure and micronuclei, a marker for genome instability.NIH-PA Author Manuscript NIH-PA Author Manuscript NIH-PA Author Manuscript。

专利名称：Expression of apoAI and variants thereof using spliceosome mediated RNA trans-splicing发明人：Madaiah Puttaraju,Edward Otto,Mariano A.Garcia-Blanco,Gerard J. McGarrity,Gary F.Temple申请号：US11141447申请日：20050531公开号：US20060194317A1公开日：20060831专利内容由知识产权出版社提供摘要：Methods and compositions for generating novel nucleic acid molecules through targeted spliceosome mediated RNA trans-splicing that result in expression of a apoAI protein, an apoAI variant, the preferred embodiment referred to herein as the apoAI Milano variant, a pre-pro-apoAI or an analogue of apoAI. The methods and compositions include pre-trans-splicing molecules (PTMs) designed to interact with a target precursor messenger RNA molecule (target pre-mRNA) and mediate a trans-splicing reaction resulting in the generation of a novel chimeric RNA molecule (chimeric RNA) capable of encoding apoAI, the apoAI Milano variant, or an analogue of apoAI. The expression of this apoAI protein results in protection against vascular disorders resulting from plaque build up, i.e., atherosclerosis, strokes and heart attacks.申请人：Madaiah Puttaraju,Edward Otto,Mariano A. Garcia-Blanco,Gerard J. McGarrity,Gary F. Temple地址：Germantown MD US,Reston VA US,Durham NC US,Gaithersburg MDUS,Washington Grove MD US 国籍：US,US,US,US,US更多信息请下载全文后查看。

5’-磷酸腺苷专业英语用词5'-Adenosine Monophosphate: A Key Component of Cellular Energy Transfer.In the intricate web of biochemical reactions that sustain life, 5'-adenosine monophosphate (5'-AMP) occupies a pivotal position. It is an adenosine derivative that plays a crucial role in energy transfer within cells, particularly in the synthesis of ATP (adenosine triphosphate), the "molecular currency" of intracellular energy.The structure of 5'-AMP is relatively simple, yet its importance in cellular metabolism is immense. It consists of an adenosine base linked to a phosphate group through an ester bond. This phosphate group can be further phosphorylated to form ADP (adenosine diphosphate) and ultimately ATP, the latter being the most energetically charged form of adenosine phosphate.The conversion of 5'-AMP to ATP is a key step in the cellular energy generation process, occurring primarily in the mitochondria of eukaryotic cells. Here, the electron transport chain harnesses the energy released from the oxidation of nutrients to pump protons across a membrane, creating a proton gradient that drives the synthesis of ATP from ADP and 5'-AMP.The role of 5'-AMP extends beyond its participation in ATP synthesis. It is a key intermediate in various enzymatic reactions, serving as a precursor for the synthesis of other important molecules such as cAMP (cyclic adenosine monophosphate) and CTP (CTP: creatine phosphotransferase). These molecules play crucial roles in regulating cellular processes like metabolism, signal transduction, and gene expression.The importance of 5'-AMP in cellular metabolism is further underscored by its involvement in the regulation of enzyme activities. For instance, allosteric enzymes, which catalyze key steps in metabolic pathways, can be activated or inhibited by changes in the concentration of 5'-AMP.This allows cells to fine-tune their metabolic responses to changing environmental conditions and nutritional availability.In addition to its role in metabolism, 5'-AMP has also been implicated in the regulation of cellular growth and proliferation. By modulating the activity of kinases and phosphatases, 5'-AMP can influence the phosphorylation state of key proteins involved in cell cycle control and apoptosis. This, in turn, affects the rate of cell division and cell death, thereby influencing tissue homeostasis and disease progression.The study of 5'-AMP and its role in cellular metabolism has been a focus of intense research for decades. This research has not only deepened our understanding of how cells convert energy into biochemical work but has also led to the development of novel therapeutic strategies aimed at manipulating cellular metabolism to treat diseases like cancer, diabetes, and cardiovascular disease.In conclusion, 5'-adenosine monophosphate is a crucialcomponent of cellular metabolism, playing a pivotal role in energy transfer and regulation. Its importance extends across multiple biological processes, from ATP synthesis to signal transduction and gene expression. The continued study of 5'-AMP and its role in cellular metabolism holds the promise of unlocking new insights into the fundamental mechanisms of life and leading to the development of innovative therapeutic approaches.。

Journal of Biotechnology84(2000)155–161Expression of a mineral phosphate solubilizing gene from Erwinia herbicola in two rhizobacterial strainsHilda Rodrı´guez a,*,Tania Gonzalez a,Guillermo Selman ba Department of Microbiology,Cuban Research Institute on Sugarcane By-Products(ICIDCA),P.O.Box4026,CP11000,Ha6ana,Cubab Plant Di6ision,Genetic Engineering and Biotechnology Center,Ha6ana,CubaReceived2December1999;received in revised form11August2000;accepted16August2000AbstractA genetic construction was carried out using the broad host range vector pKT230and plasmid pMCG898,which encodes the Erwinia herbicola pyrroloquinoline quinone(PQQ)synthase,a gene involved in mineral phosphate solubilization(mps).Thefinal construction was transformed and expressed in Escherichia coli MC1061,and the recombinant plasmids were transferred to Burkholderia cepacia IS-16and Pseudomonas sp.PSS recipient cells by conjugation.Clones containing recombinant plasmids produced higher clearing halos in plates with insoluble phosphate as the unique(P)source,in comparison with those of strains without plasmids,demonstrating the heterologous expression of the E.herbicola gene in the recipient strains.This genetic manipulation allowed the increase in mps ability of both strains,enhancing their potentialities as growth promoters of agricultural crops.These results represent thefirst report on the application of the recombinant DNA methodology for the obtainment of improved phosphate solubilizing ability from rhizobacterial strains for biofertilization purposes.©2000Published by Elsevier Science B.V.Keywords:Phosphate solubilization;PGPR;Genetically engineered microorganisms;GEM;Biofertilization/locate/jbiotec1.IntroductionRhizosphere bacteria can enhance plant growth by different mechanisms(Glick,1995a).One of these is the dissolution of insoluble phosphates from soil,making phosphorous(P)available for plant assimilation.In fact,a considerable P com-ponent in soil is in the form of insoluble mineral phosphates or organic matter(Goldstein,1994). Free inorganic phosphate is released from organic P compounds by enzymatic processes(Rossolini et al.,1998),while the production of organic acids,such as gluconic acid,by soil microorgan-isms is the principal mechanism for mps(Ro-drı´guez and Fraga,1999).Genetic manipulation is considered the most promising way to create more effective plant growth promoting rhizobacteria(PGPR)(Glick and Bashan,1997).The pSL775derived vector*Corresponding author.Fax:+53-7-338236.E-mail address:hilda@.cu(H.Rodrı´guez).0168-1656/00/$-see front matter©2000Publilshed by Elsevier Science B.V. PII:S0168-1656(00)00347-3H.Rodrı´guez et al./Journal of Biotechnology84(2000)155–161 156pMCG898carries an insert from an E.herbicola genomic library,selected by its ability to solubilize mineral phosphate(Goldstein and Liu,1987). Plasmid pMCG898contains a1.8kb region en-coding the PQQ synthase enzyme(Liu et al., 1992).The metabolic function of the PQQ syn-thase enzyme is the biosynthesis of the cofactor PQQ,necessary for the assembly of the glucose dehydrogenase(GDH)holenzyme,which acts in the oxidation of glucose to gluconic acid (Goldstein,1994,1995).A mineral phosphate sol-ubilizing gene from Pseudomonas cepacia has also been cloned and expressed in E.coli,and its involvement in gluconic acid production was also demonstrated(Babu-Khan et al.,1995). Burkholderia cepacia IS-16strain is being used in Cuba as a biofertilizer in several important crops(Martı´nez A.,et al.,personal communica-tion),and the improvement of its plant growth promoting capacity would be an important contri-bution to enhance results in the agricultural prac-tice.On the other hand,P.sp.PSS(Villa et al., 1997)has the ability to inhibit the growth of microorganisms by producing antibiotics and siderophores,indirectly stimulating plant growth. It would be of a great value to complement this ability with an efficient solubilization of soil P. In this paper the transfer of the E.herbicola PQQ synthase gene to both IS-16and PSS bacte-rial strains is reported,using the broad host range vector pKT230.The expression of this trait in recipient cells was evaluated in relation with the enhancement of mps ability.2.Materials and methods2.1.Bacterial strains,plasmids and culture conditionsThe bacterial strains and plasmids used in this study are listed in Table1.E.coli was cultured in Luria Bertani(LB)broth and maintained in LB agar at37°C.Pseudomonas and Burkholderia strains were cultivated at30°C in nutrient broth (NB)and nutrient agar(NA)(Sambroock et al., 1989).Cultures were incubated in an orbital shaker at175rpm.The antibiotics used for selec-tion were(m g ml−1):Ampicillin(Amp),100; streptomycin(Str),100;spectinomycin(Sp),100; tetracycline(Tet),25;kanamycin(Km),50.For the assay of mps,the strains were culti-vated in a medium based in that described by Illmer and Schinner(1992),with the following composition(g l−1):glucose,10;NH4NO3,0.373; MgSO4,0.41;KCl,0.295;NaCl,0.2;FeCl3,0.003; Ca3HPO4,0.7.Agar(20g l−1)was added for plate cultures.For kinetic studies,1000ml Erlen-Table1Bacterial strains and plasmids aStrain or Reference CharacteristicsplasmidStrainSambroock et al., F−araD139(ara-leu)7696galE15galK16(lac)X74rpsL(Str r)hsdR2(r k−m k)mcrAEscherichia colimcrB1MC10611989 Burkhordelia Wild type,Ap r,Sp r Martı´nez et al., cepacia .P.sp.PSS Wild type,Ap r,Km r,Sp r Villa et al.,1997 PlasmidContains the PQQ synthase gene involved in mps,Ap r Goldstein&Liu, pMCG8981987pKT230Broad host range vector for Gram negative bacteria,Str r,Km r Bagdasariam etal.,1981pRK2013Helper plasmid,Km r Figurski&Helinski,1979a Str,Streptomycin,Ap,Ampicillin,Sp,Spectinomycyn,Km,Kanamycin,Tet,Tetracycline.H.Rodrı´guez et al./Journal of Biotechnology84(2000)155–161157meyerflasks with200ml of medium were used, with a rate of inoculation of5%.Samples were withdrawn at different time intervals and the solu-ble P concentration was estimated in the superna-tant after centrifugation of the samples at 10000×g.The experiments were carried out in triplicate.2.2.DeterminationsGrowth was estimated by the measurement of the absorbance at600nm.Samples from cultures grown in medium with tricalcium phosphate were previously diluted1:1(v/v)using1N HCl to dissolve the residual insoluble phosphate and measured against a blank identically treated.Sol-uble P was determined in the supernatant accord-ing to Chen et al.(1956).Mineral phosphate solubilization(mps)was assayed by measuring the halo size in plates containing tricalcium phos-phate as the only P source.Exponentially growing cultures were adjusted to an optical density of0.5 (at600nm),1m l of these samples was inoculated in the plates and the halos measured after24h of incubation at30°C.2.3.Recombinant DNA techniquesPlasmid extraction using the alkaline lysis method,agarose gel electrophoresis,preparation of competent cells and E.coli transformation were essentially as described by Sambroock et al. (1989).Restriction enzymes(New England Bio-lab),T4ligase(New England Biolab)and alkaline phosphatase(Sigma),were used according to the manufacturer’s instructions.2.4.Genetic constructionsThe subcloning strategy is shown in Fig.1.The pKT230vector(IncQ,RSF1010replicon,Bag-dasariam et al.,1981)was digested with BamHI, dephosphorylated and re-ligated with plasmid pMCG898(Goldstein and Liu,1987)previously digested with BamHI and the ligation mixture was transformed in E.coli MC1061.Transformants were selected for the expression of the expected antibiotic resistance profile(Ap,Km and Str)in LB-agar plates.2.5.ConjugationPlasmids were transferred from E.coli to Burkholderia and Pseudomonas strains by a tri-parental mating,using the pRK2013plasmid as a helper(Figurski and Helinski,1979).Matings were performed overnight on NA plates,using 1:10:1and1:1:1rates from overnight cultures of donor,recipient and helper strains,respectively. The resultant growth was plated on NA medium containing Str,Km and Sp.The Sp resistant trait, harbored by IS-16and PSS strains,was used to select against the donor E.coli strain.2.6.Plasmid stability in the recombinant strains To analyze the stability of the recombinant pL230plasmid in the host rizobacterial strains, single colonies of the transconjugants grown in NA plus Str and Km were inoculated in NB medium without antibiotics.After8h of growth, the cultures were diluted1000fold in non-antibi-otic medium.The dilution procedure was repeated several times until the cells had gone through50 generations,on the absence of selective(antibi-otic)pressure.The cultures were sampled and plated on NA in both the presence and absence of Km and Str as selective antibiotics.The stability was determined by comparing the number of colonies present on selective and non-selective plates.3.Results and discussionWhen the broad host range vector pKT230was transferred by conjugation to both recipient strains,frequencies of8×10−4(transconjugants per recipient cell)for the1:1recipient to donor strain ratio and of5×10−4for the1:10propor-tion,were obtained for B.cepacia IS-16,while 4×10−4for the1:1ratio and7×10−3for the 1:10proportion were found for P.sp.PSS.This indicates that,for both strains,a higher frequency was obtained when the recipient to donor strain ratio was increased10fold.Therefore,this ratio was selected for further conjugations.H.Rodrı´guez et al./Journal of Biotechnology84(2000)155–161158Fig.1.Genetic construction for the transfer of the PQQ synthase gene from E.herbicola to vector pKT230.Km r:resistance to kanamycin;Ap:resistance to ampicillin;Str:resistance to streptomycin.Ligation from the experimental strategy shown in Fig.1was transformed in E.coli.The fre-quency of transformation of pL230plasmid was 3.5×102(transformants per m g DNA).Some clones were selected for further characterization. The expression of phosphate solubilization abil-ity from the selected E.coli transformants was assayed in plates with insoluble phosphate as the unique P source.Clones containing recombinant plasmids formed clearing halos with greater di-ameter than those of strains without plasmids (Fig.2).Representative clones were transferred to both recipient rhizobacterial strains by conjugation and transconjugants were selected by antibiotic-resis-tance criteria.Twenty-eight of the putative transconjugants(14from each strain),harboring the pL230plasmid,were further characterized for halos formation on insoluble phosphate medium. Table2shows the results of halo size on trical-cium phosphate plates from the transconjugants resulting in increased phosphate solubilization. The wild type strains PSS and IS-16can solubilize inorganic phosphate at a basal level,so both of them produced clearing halo when grown on tri-calcium phosphate medium.The significant in-crease of the halo size in transconjugants with pL230constructions,in comparison with the strains without plasmid,was indicative of the expression of the cloned gene,which allowed theH .Rodrı´guez et al ./Journal of Biotechnology 84(2000)155–161159Fig.2.Clearing halos formation on medium containing trical-cium phosphate as the sole P source by the bacterial cultures.(a)E .coli MC 1061strain.(b)Strain MC 1061harboring plasmid pL230with the PQQ synthase gene from E .herbicola .binant constructions in the obtained clones.The presence of a foreign plasmid can produce a metabolic load in the host microorganism (Glick,1995b).In this study,the growth of transconjugants with increased mps activity was evaluated in NB medium,in comparison with the strains without the recombinant plasmid.The growth rate and final cell density of the transconjugants were similar to that of the wild type strains (data not shown),suggesting that the recombinant plasmid did not adversely affect the growth of the host cells,at least in the assayed conditionsOn the other hand,the stability of the recombi-nant plasmid in the host cell under laboratory growth conditions was studied for some of the obtained clones.After 50generations of growth on non selective medium the rate of cells keeping the ability to growth on the antibiotic medium were 7,12,13and 15%for clones C916–3,C916–2,C916–5and C308S–1,respectively.This indi-cates that instability of the plasmid may occur in non-selective conditions.This suggests chromoso-mal integration of the genes as an advantageous strategy for future works.Kinetic analysis of P concentration in the cul-ture broth using an insoluble P source has been used by several authors to show P release capacity of microbial strains.However,a lack of correla-tion between substrate utilization-as measured by halo size-and P concentration in liquid cultures has been reported (Das,1963;Ostwall and Bhide,1972),and variations in P concentrations along the cultivation time have also been observed (Khan and Bhatarar,1977;Babenko et al.,1984).In this study the kinetics of soluble P concentra-tion was assayed from several transconjugants versus the recipient strain cultured in medium with an insoluble P source.Although higher P values were always detected for the transconju-gants in some intervals,variations in P concentra-tion were observed along the cultivation time for both strains.An example of this is shown in Fig.3.Several increases and decreases of P concentra-tion were detected along the cultivation time.Besides this,a correlation between pH increase and P drop and vice versa was observed.These results could support the hypothesis proposed byenhancement of mps in comparison with the wild type strains.In order to demonstrate the presence of the recombinant plasmids,all transconjugants with increased halo formation were submitted to plas-mid purification.The extracts were used to retro-transform the E .coli MC1061strain.In all cases a high frequency of transformants showing the phenotype corresponding to the antibiotic resis-tance encoded by the plasmid (Str,Ap and Km)were obtained.On the other hand,digestions of the extracted plasmids with the appropriate en-zymes produced fragments in correspondence with the size of the original plasmids (data not shown),corroborating the presence of the recom-Table 2Diameters of clearing halos on tricalcium phosphate medium from transconjugants and wild type strains a StrainHalo size (mm)%of increase PSS (wild type) 4.690.7–C307S-1 5.190.5*116.190.6*C308S-1325.590.6*C309S-1205.690.6*C310S-122IS-16(wild type) 4.490.4*–6.290.6*42C916-2 5.590.6*C916-525a*,Significant difference with the wild type strain (Student’s t -test,95%reliability).H.Rodrı´guez et al./Journal of Biotechnology84(2000)155–161160Fig.3.Kinetics of soluble P and pH of cultures from the wild type strain PSS and the transconjugant C308S-1grown in medium with an insoluble P source.Illmer and Schinner(1992)about the probable formation of Organo-P compounds with the or-ganic acids,which are further used as nutrient source by the bacteria.These evidences also sup-port the idea that P concentration is not a reliable parameter for assessing phosphate solubilization capability of a microbial strain for comparative studies.In previous works,genes involved in mps from E.herbicola(Goldstein and Liu,1987)and P. cepacia(Babu-Khan et al.,1995)were expressed in E.coli,producing an increase in hydroxyapatite dissolution.The present results demonstrate that heterologous expression of a mps gene from E. herbicola in B.cepacia and P.sp.strains was also possible and that tricalcium phosphate was solu-bilized as well by the effect of this gene product. The enhancement of the mps trait obtained in this work is a relevant step,which would allow a higher efficiency of phosphate utilization by the plant,thus improving the plant growth promotion effect of both rhizobacterial strains.In future studies chromosomal insertion of the PQQ syn-thase gene would be advantageous,both to avoid horizontal transfer risk and to increase the stabil-ity of the new trait.AcknowledgementsWe are grateful to Dr Shih-Tung Liu for the kind supply of plasmid pMCG898.Skilful techni-cal assistance of Isabel Goyre is greatly appreciated.ReferencesBabenko,Y.S.,Tyrygina,G.,Grigoryev,E.F.,Dolgikh,L.M., Borisova,T.I.,1984.Biological activity and physiologo-biochemical properties of bacteria dissolving phosphates.Microbiologiya53,533–539.Babu-Khan,S.,Yeo, C.T.,Martin,W.L.,Duron,M.R., Rogers,R.D.,Goldstein,A.,1995.Cloning of a mineral phosphate-solubilizing gene from Pseudomonas cepacia.Appl.Environ.Microbiol.61,972–978. Bagdasariam,H.,Lurz,R.,Ru¨ckert, B.,Franklin, F.C.H, Bagdasarian,M.M.,Frey,J.,Timmis,K.N.,1981.Specific-purpose plasmid cloning vectors.II.Broad host range, high copy number,RSF1010-derived vectors,and a host-vector system for gene cloning in Pseudomonas.Gene16, 237–274.Chen,P.S.,Jr,Torribara,T.Y.,Warner,H.,1956.Microdeter-mination of phosphorous.Anal.Chem.28,1756–1758. Das,A.C.,1963.Utilization of insoluble phosphates by soil fungi.J.Indian Soc.Soil Sci.11,203–207.H.Rodrı´guez et al./Journal of Biotechnology84(2000)155–161161Figurski,D.H.,Helinski,D.R.,1979.Replication of an origin-containing derivative of plasmid RK2dependent on a plasmid function provided in trans.Proc.Natl.Acad.Sci.USA76,1648–1662.Glick,B.R.,1995a.The enhancement of plant growth by free living bacteria.Can.J.Microbiol.41,109–117.Glick, B.R.,1995b.Metabolic load and heterologous gene expression.Biotechnol.Adv.13,247–261.Glick,B.R.,Bashan,Y.,1997.Genetic manipulation of plant growth-promoting bacteria to enhance biocontrol of phy-tophatogens.Biotechnol.Adv.15,353–378. Goldstein,A.,1994.Involvement of the quinoprotein glucose dehydrogenase in the solubilization of exogenous mineral phosphates by gram-negative bacteria.In:Torriani-Gorni,A.,Yagil,E.,Silver,S.(Eds.),Phosphate in Microorgan-isms:Cellular and Molecular Biology.ASM Press,Wash-ington,DC,pp.197–203.Goldstein, A.,1995.Recent Progress in understanding the molecular genetics and biochemistry of calcium phosphate solubilization by gram negative bacteria.Biol.Agric.Hor-tic.12,185–193.Goldstein,A.,Liu,S.T.,1987.Molecular cloning and regula-tion of a mineral phosphate solubilizing gene from Erwinia herbicola.Biotechnology5,72–74.Illmer,P.,Schinner, F.,1992.Solubilization of inorganic phosphates by microorganisms isolated from forest soil.Soil.Biol.Biochem.24,389–395.Khan,J.A.,Bhatarar,R.M.,1977.Studies on solubilization of insoluble phosphate rocks by Aspergillus niger and Penicil-lium sp..Fertil.Technol.14,329–333.Liu,S.T.,Lee,L.Y.,Taj,C.Y.,Hung,C.H.,Chang,Y.S., Wolfrang,J.H.,Rogers,R.,Goldstein, A.H.,1992.Cloning of an Erwinia herbicola gene necessary for glu-conic acid production and enhanced mineral phosphate solubilization in Escherichia coli HB101:nucleotide se-quence and probable involvement in biosynthesis of the coenzyme Pyrroloquinoline Quinone.J.Bacteriol.174, 5814–5819.Ostwall,K.P.,Bhide,V.P.,1972.Solubilization of tricalcium phosphate by soil Pseudomonas.Indian J.Exp.Biol.10, 153–154.Rodrı´guez,H.,Fraga,R.,1999.Phosphate solubilizing bacte-ria and their role in plant growth promotion.Biotechnol.Adv.in press.Rossolini,G.M.,Shipa,S.,Riccio,M.L.,Berlutti, F., Macaskie,L.E.,Thaller,M.C.,1998.Bacterial non-specific acid phosphatases:physiology,evolution,and use as tools in microbial biotechnology.Cell.Mol.Life Sci.54,833–850.Sambroock,J.,Fritsch,E.F.,Maniatis,T.,1989.Molecular Cloning:A Laboratory Manual,second ed.Cold Spring Harbor Laboratory Press,New York.Villa,Diaz de Villegas,M.E.,Michelena,G.,Lorenzo,M., Stefanova,M.,1997.Synthesis of metabolites of Pseu-domonas sp.PSS for biological control of phytopathogenic fungi and weeds.In:Proceedings:‘Pseudomonas’97’.VI International Congress on Pseudomonas:Molecular Biol-ogy and Biotechnology.Madrid,Spain,p.191..。

The power of expression refers to the ability to effectively communicate thoughts, emotions, and ideas through various forms of communication. Whether it's through spoken words, written language, art, music, or any other creative outlet, expression allows individuals to convey their innermost feelings and connect with others on a deeper level.Expression plays a crucial role in human interaction and connection. It enables individuals to share their experiences, beliefs, and perspectives with others, fostering understanding and empathy. Through expression, people can find common ground and build meaningful relationships based on mutual understanding and respect. Furthermore, the power of expression is a catalyst for change and progress. It has the ability to inspire, motivate, and mobilize individuals and communities to take action. Through powerful speeches, compelling stories, and impactful artwork, expression has been instrumental in driving social and political movements, advocating for justice and equality, and challenging the status quo. In addition, expression serves as a form of self-discovery and personal growth. It allows individuals to explore and make sense of their own thoughts and emotions, leading to a deeper understandingof oneself. Through creative expression, people can find healing, catharsis, and a sense of empowerment.Overall, the power of expression is a fundamental aspect of human experience. It enables individuals to connect, create, and effect change, making it an essential tool for personal and collective growth. Whether through words, art, or music, the act of expression holds immense power in shaping our understanding of ourselves andthe world around us.。

Review:GPCRs (Guanine Nucleotide Binding–Protein Coupled Receptors) comprise large and diverse gene families in fungi, plants, and the animal kingdom. Also termed serpentine receptors, GPCRs are polytopic membrane proteins that share a common structure with seven transmembrane segments, but sequence similarity is minimal among the most distant GPCRs. Their principal function is to transmit information about the extracellular environment to the interior of the cell, and they do this by interacting with the G-proteins. GPCRs recognize a variety of ligands and stimuli including peptide and non-peptide hormones and neurotransmitters, chemokines, prostanoids and proteinases, biogenic amines, nucleosides, lipids, growth factors, odorant molecules and light. These receptors affect the generation of small molecules that act as intracellular mediators or second messengers, and can regulate a highly interconnected network of biochemical routes. The intracellular signaling pathways activated by GPCR signaling include cAMP (Cyclic Adenosine Monophosphate)/ PKA (Protein Kinase-A) pathway, Ca2+/PKC(Protein Kinase- C) pathway, Ca2+/NFAT (Nuclear Factor of Activated T-cells) pathway, PLC (Phospholipase- C) pathway, PTK (Protein Tyrosine Kinase) pathway, PKC/MEK (MAPK/ERK1) pathway, p43/p44MAPK (Mitogen Activated Protein Kinase) pathway, p38 MAP pathway, PI3K (Phosphoinositide-3 Kinase) pathway, NO-cGMP pathway, Rho pathway, NF-KappaB (Nuclear Factor-Kappa B) pathway and JAK (Janus Kinase )/ STAT (Signal Transducers and Activators of Transcription Factors) pathway (Ref.1).Upon activation, GPCRs interact with their cognate G-proteins. G-proteins are heterotrimers (i.e., made of three different subunits) associated with the inner surface of the plasma membrane. The three subunits are: G-Alpha , G-Beta and G-Gamma. When signaling, they function in essence as dimers because the signal is communicated either by the G-Alpha subunit or the G-Beta-Gamma complex. Currently there are 20 known G-Alpha , 6 G-Beta , and 11 G-Gamma subunits. On the basis of sequence similarity, the G-Alpha subunits have been divided into four families: G-AlphaS, G-AlphaI, G-AlphaQ, and G-Alpha12/13 . These G-Alpha subunits regulate the activity of several second messenger-generating systems. In the inactive state, G-Alpha has GDP in its binding site. When a hormone or other ligand binds to the associated GPCR, an allosteric change takes place in the receptor. This triggers an allosteric change in G-Alpha causing GDP to leave and be replaced by GTP. GTP activates G-Alpha causing it to dissociate from G-Beta-Gamma (which remain linked as a dimer) (Ref.2).The G-Alpha subunit has many different functions, depending on its isoform. G-alpha subunit consists of 4 isoforms: G-AlphaQ, G-AlphaS, G-AlphaI and G-Alpha12/13.G-AlphaQ family controls the activity of Phosphatidylinositol-specific Phospholipases, such as PLC-Beta, which hydrolyzes PIP2 (Phosphatidylinositol 4,5-Bisphosphate) to generate two-second messengers, IP3 (Inositol 1,4,5-Trisphosphate) and DAG (Diacylglycerol). IP3 and DAG in turn lead to an increase in the intracellular concentrations of free Ca2+ and the activation of a number of Protein Kinases, including PKC (Ref.3). G-AlphaQ, working through PKC and possibly directly, also appears to regulate various isoforms of PLD (Phospholipase-D). G-AlphaQ is reported to activate the transcription factor NF-KappaB through PYK2 (Proline-Rich Tyrosine Kinase-2). The members of the G-AlphaS family activate AC (Adenylyl Cyclase) leading to the production of cAMP in the cell. cAMP then binds to the regulatory subunit of PKA (Protein Kinase-A) leading to the dissociation of the catalytic subunits. Once the catalytic subunits of PKA dissociate, they become active. PKA then lead to the phosphorylation of the GPCR. Once the GPCR is phosphorylated, it can then couple to G-AlphaI instead of G-AlphaS. G-AlphaI family members can inhibit AC, thereby controlling the intracellular concentrations of cAMP. G-Alpha subunits of the G-AlphaI family, which includes G-AlphaI-1, G-AlphaI-2, G-AlphaI-3, G-AlphaI-O, transducin (G-AlphaI-T), and gustducin (G-AlphaI-gust), also activate a variety of Phospholipases and Phosphodiesterases, and promote the opening of several ion channels. G-AlphaI and G-AlphaI-O can regulate signals from c-Src to STAT3 and to the Rap pathways. Both G-AlphaI and G-AlphaQ-coupled receptors can potently stimulate MAPK activation (Ref.4).G-Beta-Gamma Subunit of G-Proteins directly couples to at least four effector molecules: PLC- Beta, K+ channels, AC, and PI3K. Overexpression of G-Beta-Gamma subunit was found to be sufficient to stimulate MAPKs. Furthermore, stimulation of MAPK activity by co expressedG-Beta-Gamma dimers did not require PKC activation, but involved the activation of Ras. The small G-protein Ras becomes activated when its GEF is recruited to the membrane (via RTKs, FAK (Focal Adhesion Kinase), etc.). Once Ras binds GTP, it can then recruit the serine/threonine kinase Raf to the membrane. When Raf translocate to the membrane, it becomes activated and then phosphorylates the dual specificity kinase MEK. This leads to the activation of MEK, which then phosphorylates a critical tyrosine and threonine on ERK (Extracellular signal-Regulated Kinase). ERK then phosphorylates and activate other cellular proteins (like p90RSK) as well as translocate into the nucleus and phosphorylate/activate transcription factors (like Elk1) and leads to changes in gene expression and cell cycle progression. G-Beta-Gamma also binds to PLC-Beta, which facilitates its activation by G-AlphaQ, and it has been shown to enhance G-AlphaS activation of AC. Further, G-Beta-Gamma also interacts with ion channels and recruits BARK (Beta-Adrenergic Receptor Kinase) and PI3K-Gamma to the membrane. G-Beta-Gamma could lead to the activation of the non-receptor tyrosine kinase Src. Src then leads to the tyrosine phosphorylation of the adapter protein SHC. SHC then recruit the GRB2 (Growth Factor Receptor Bound Protein-2)-SOS (Son Of Sevenless) complex to the membrane via the SH2 domain of GRB2 binding to the Phosphotyrosine on SHC. SOS, a GEF for Ras, can then exchange the GDP bound to Ras to GTP. Once Ras binds GTP, it is then activated, and the ERK activation cascade is initiated. GPCRs that couple to G-AlphaS could also activate ERK via G-Beta-Gamma. The nature of the signaling pathways controlled by G-Alpha12 family of GTPases (Guanosine Triphosphatases) has just begun to be elucidated. G-Alpha12 has been reported to directly interact with a GTPase-activating protein for Ras, Ras-GAP, and BTK (Bruton's Tyrosine Kinase). These observations require confirmation and extension to establish the cellular consequences in native systems of these direct interactions. G-Alpha12 is thought to stimulate PLD, c-Src, and PKC by as-yet unidentified mechanisms. In many cases it appears that different members of the MAPK family, such as ERK5 or JNK (c-Jun NH2-terminal Kinase), are activated. This activation should lead to regulation of gene expression. G-Alpha13 directly interacts with and activates a guanine nucleotide exchange factor for the GTPase Rho, p115RhoGEF, and thus activates Rho, leading to a variety of effects that include regulation of the Na+-H+ exchanger. Through the activation of PYK2, G-Alpha13 may engage the PI3K pathway to activate the protein kinase Akt and regulate NF-KappaB. How G-Alpha13 activates PYK2 is currently not understood (Ref.5).GPCRs mediate hormonal control of numerous signaling pathways. Many of these pathways are dynamically regulated. At the level of the receptor, regulation can occur via inhibition of GPCR/G-Protein coupling (desensitization), redistribution of cell surface receptors (trafficking), and receptor degradation (down-regulation). Two protein families, GRKs (G- protein-coupled Receptor Kinases) and Arrestins, play a critical role in regulating these processes. GRKs specifically phosphorylate the activated form of the receptor, which in turn promotes Arrestin binding. Arrestin binding sterically inhibits coupling of the GPCR to its respective G protein (a process termed receptor desensitization) and targets the receptor for internalisation via clathrin-coated pits. By regulating both the functional status and number of plasma membrane located GPCRs the GRKs play a pivotal role in modulating GPCR-mediated signal transduction. GPCRs are a pharmacologically important protein family with approximately 450 genes identified to date. Pathways involving these receptors are the targets of hundreds of drugs, including antihistamines, neuroleptics, antidepressants, and antihypertensives (Ref.6).。

Wnt信号途径促进脂肪间充质干细胞向Ⅱ型肺泡上皮细胞分化石莉;竭晶;王芳;赵丹;张秀芳;彭丽萍【摘要】背景：脂肪间充质干细胞向Ⅱ型肺泡上皮细胞定向分化的能力以及调节机制尚未完全阐明。

<br> 目的：观察脂肪间充质干细胞在体外分化为Ⅱ型肺泡上皮的能力以及W nt途径对分化的调节作用。

<br> 方法：取大鼠脂肪组织，体外分离培养脂肪间充质干细胞并通过流式细胞术进行鉴定。

实验分为对照组、小气道生长液组和Wnt3a组，对照组用普通DMEM培养基培养，小气道生长液组和Wnt3a组均使用小气道生长液培养，且Wnt3a组加入Wnt信号通路激动剂Wnt3a培养。

诱导10 d后分别通过qRT-PCR和免疫荧光检测Ⅱ型肺泡上皮标志物肺表面活性蛋白B，C，D的表达，并于诱导5 d和10 d时通过Western blot 检测磷酸化β-catenin和GSK-3β。

<br> 结果与结论：大鼠脂肪组织中可成功分离出纯度较高的脂肪间充质干细胞，可表达 CD44和 CD29，不表达CD11b 和CD45；经小气道生长液诱导后，脂肪间充质干细胞中肺表面活性蛋白B，C，D蛋白和mRNA表达均上调(P <0.01)，表明其可被诱导为Ⅱ型上皮细胞；加入Wnt3a后，经诱导的脂肪间充质干细胞中肺表面活性蛋白B，C，D蛋白和mRNA表达均高于小气道生长液组(P <0.01)，且在诱导过程中磷酸化β-catenin表达随时间逐渐上调而GSK-3β表达逐渐下调(P <0.01)。

结果证实，Wnt信号通路在脂肪间充质干细胞诱导分化为Ⅱ肺泡上皮细胞过程中激活并促进干细胞的定向分化。

%BACKGROUND:Ability of adipose mesenchymal stem cels differentiating into type II alveolar epithelial cels and the regulating mechanism have not been fuly elucidated. <br> OBJECTIVE:To study the ability of adipose mesenchymal stem cels differentiating into type IIalveolar epithelial cels in vitro and the function of Wnt pathway in the regulation of differentiation. <br> METHODS:Adipose mesenchymal stem cels were obtained from fat tissue of rats and identified by flow cytometry. The adipose mesenchymal stem cels were divided into control group, smal airway growth medium (SAGM) group and Wnt3a group. Control group was treated with normal DMEM medium; SAGM and Wnt3a groups were both treated with smal airway growth medium, and additionaly, the Wnt3a group was treated with Wnt3a, a Wnt signaling pathway agonist. After 10 days, quantitative RT-PCR and immunofluorescence detection were used to test the expression of surfactant proteins B, C, D, type II alveolar epithelial marker s. Phosphorylatedβ-catenin and GSK-3β were detected using western blot after 5 and 10 days of induction. <br> RESULTS AND CONCLUSION: Adipose mesenchymal stem cels with high purity could be successfuly isolated from the adipose tissue of rats, and expressed CD44 and CD29, but not CD11b and CD45. After SAGM treatment, protein and mRNA expressions of surfactant proteins B, C, D were al increased in adipose mesenchymal stem cels (P < 0.01), indicating the ability of adipose mesenchymal stem cels to be induced into type II epithelial cels. Surfactant proteins B, C, D expressions at protein and mRNA levels were significantly higher in the Wnt3a group than the SAGM group (P < 0.01). During the induction progress, the expression of phosphorylated β-catenin gradualy increased, but GSK-3βexpression gradualy decreased in the Wnt3a group (P < 0.01). These findings indicate that Wnt signaling pathways areinvolved in differentiation of adipose mesenchymal stem cels into type II alveolar epithelial cels.【期刊名称】《中国组织工程研究》【年(卷),期】2015(000)032【总页数】7页(P5148-5154)【关键词】干细胞;脂肪干细胞;脂肪间充质干细胞;Ⅱ型肺泡上皮细胞;分化;Wnt3a;β-catenin;大鼠;脂肪;流式细胞术;GSK-3β;肺泡;国家自然科学基金【作者】石莉;竭晶;王芳;赵丹;张秀芳;彭丽萍【作者单位】吉林大学第一医院二部急诊科，吉林省长春市 130033;吉林大学第一医院呼吸科，吉林省长春市 130021;吉林大学中日联谊医院内镜中心，吉林省长春市 130033;吉林大学第一医院呼吸科，吉林省长春市 130021;吉林大学第一医院呼吸科，吉林省长春市 130021;吉林大学第一医院呼吸科，吉林省长春市130021【正文语种】中文【中图分类】R394.2文章亮点：文章结果显示，大鼠脂肪组织中可成功分离出纯度较高的脂肪间充质干细胞，经小气道生长液诱导后可分化为Ⅱ型肺泡上皮细胞，并且Wnt信号通路在脂肪间充质干细胞诱导分化为Ⅱ肺泡上皮细胞过程中激活并促进干细胞的定向分化。