紫色红曲霉Mp-21 MpMcrA基因的克隆与生物信息学分析

McrA为最近在构巢曲霉(Aspergillus nidulans)中发现的全局调控因子，具有调控丝状真菌生长发育和次级代谢的作用，利用生物信息学分析方法找到并克隆紫色红曲霉（Monascus purpureus）中mcrA基因，将其命名为MpMcrA。分析MpMcrA蛋白质理化性质、亲疏水性、亚细胞定位、信号肽、跨膜区域及磷酸化位点、转录因子结合位点以及蛋白质二级结构。利用ProtParam、ProtScale、PSORTII、SignalP4.1等生物信息学软件对MpMcrA进行系统分析。 结果表明，MpMcrA基因长1 356 bp，其中含有3个外显子，2个内含子，编码410个氨基酸，与构巢曲霉序列比对蛋白相似性高达64％。预测结果显示，MpMcrA属于亲水蛋白，位于细胞核可能性大，不存在跨膜区域，不属于膜蛋白；不存在剪切位点，不属于分泌蛋白；基因含有54个潜在的磷酸化位点；可能存在5个转录因子结合位点；蛋白结构大部分为无规则卷曲，整体结构较松散。对MpMcrA基因进行了生物信息学分析，得到了基因特征和分析结果。初步确定MpMcrA基因为构巢曲霉同源mcrA基因，在红曲霉中未见有报道。     

花生铝响应类受体蛋白激酶AhPRK4的原核表达分析

花粉类受体蛋白激酶(pollen receptor-like protein kinase,PRK)是一类富含LRR结构域的类受体蛋白激酶,不仅在花粉发育和植物受精中发挥作用,也在胁迫响应中发挥作用。基于对前期花生根尖铝胁迫转录组数据的分析,我们发现了在转录水平响应铝胁迫的花粉类受体蛋白激酶基因AhPRK4,为探究AhPRK4在花生铝胁迫中的功能,该文进一步分析了铝胁迫处理下AhPRK4在花生耐铝品种‘99-1507''和铝敏感品种‘中花2号''(‘ZH2'')根尖中的转录变化,通过序列分析、进化树构建等分析了AhPRK4蛋白的结构特点和亲缘关系,克隆了AhPRK4的胞内域序列(AhPRK4-CD),并通过原核表达和体外磷酸化体系分析了AhPRK4-CD的自磷酸化活性。结果表明:(1)不同铝处理时间及不同铝浓度处理后,AhPRK4的转录水平上调,显著响应铝处理,是铝诱导基因;(2)AhPRK4含有673个氨基酸,属于LRR-III蛋白激酶家族成员,具跨膜域和信号肽,且预测具有磷酸化活性位点;(3)体外诱导表达出约71 kD的可溶性蛋白(GST-AhPRK4-CD),经凝胶亲和层析纯化,得到基于蛋白印迹实验(Western Blot)验证正确的重组蛋白,重组蛋白可发生磷酸化修饰,但无明显的自磷酸化现象。综上认为,AhPRK4是一个铝胁迫应答基因,参与花生铝胁迫早期应答机制,且能发生磷酸化修饰。     

环境变化和时序衰老过程中酵母蛋白激酶Sch9磷酸化的调控

出芽酵母(Saccharomyces cerevisiae)蛋白激酶Sch9与哺乳动物蛋白激酶S6K1同源.S6K1是哺乳动物雷帕霉素靶蛋白(mTOR)和磷脂酰肌醇3激酶(PI3K)的底物,且与很多人类疾病相关,包括肥胖症、糖尿病和癌症.Sch9和S6K1都对不同营养条件和环境胁迫条件下的细胞生长调控很重要.Sch9激活环内的磷酸化位点570位苏氨酸残基也被称为PDK1位点,而737位苏氨酸位点也被称为PDK2位点,这两个位点的磷酸化对Sch9的活性非常重要.蛋白激酶Pkh1/2磷酸化Sch9的PDK1位点,而雷帕霉素靶蛋白复合体1(TORC1)磷酸化PDK2位点.为了深入了解Sch9在细胞中的功能,阐明不同环境条件下及时序衰老过程中Sch9的PDK1和PDK2位点磷酸化的调控就显得尤为重要.利用特异性识别570位苏氨酸残基磷酸化的Sch9蛋白和特异性识别737位苏氨酸残基磷酸化的Sch9蛋白的两种抗体,对不同环境条件下和时序衰老过程中Sch9的两个位点的磷酸化调控进行了研究.研究结果揭示了Sch9的两个磷酸化位点在营养感受、胁迫应答、热量限制和时序衰老过程中的调控方式.揭示Sch9的PDK1位点磷酸化的调控与热量限制延长出芽酵母时序寿命密切相关.     

APOE4通过Calpain/p35-p25/Cdk5增加tau蛋白磷酸化

摘要 目的：探究载脂蛋白APOE4对小鼠海马组织中tau蛋白磷酸化的作用。方法：采用6月龄人载脂蛋白APOE3,APOE4转基因纯合小鼠,用Western Blot检测小鼠海马组织中tau蛋白的磷酸化程度及Calpain蛋白、p35/25、CDK5等蛋白表达水平。使用脑立体定位术向小鼠侧脑室注射Ca²⁺螯合剂EGTA或二甲基亚砜DMSO两次,给药时间间隔4小时,第二次给药结束后两小时内处死小鼠。检测海马中Calpain蛋白、CDK5、p35/25及tau蛋白的磷酸化的变化情况。结果：①与野生型小鼠和APOE3-TR小鼠相比,APOE4-TR小鼠海马中tau蛋白在Ser396,Thr181及Thr231位点的磷酸化均显著性增高,同时Calpain2、p35/25和CDK5的表达水平也增加。②使用Ca²⁺螯合剂EGTA后,与对照DMSO给药组相比,Ca²⁺螯合剂EGTA给药组小鼠海马组织中tau蛋白在Ser396位的磷酸化显著下降,但未检测到tau蛋白在Thr181及Thr231位点的磷酸发生显著性变化,同时Calpain 2蛋白、p35/25和CDK5的表达水平降低。结论：人载脂蛋白APOE4引起小鼠海马tau蛋白磷酸化异常增高,并且可能是通过Calpain/p35-p25/CDK5信号通路调控tau蛋白Ser396位点磷酸化。     

大肠杆菌CusS的生物信息学分析及对银离子胁迫的响应

【目的】解析大肠杆菌(Escherichia coli) K-12菌株同型二聚体内膜传感器组氨酸激酶(sensor histidine kinase, CusS)蛋白在细菌应答金属银离子胁迫中的调控机制,为该菌的防治提供重要科学依据。【方法】利用ProtParam、ProtScale、Protein-Sol、TMHMM、SignalP、LocTree3、NetNGlyc-1.0、NetPhosBac-3.0、SOPMA、I-TASSERF、STRING和MEGA分别预测CusS的理化性质、亲水性、可溶性、跨膜域、信号肽、亚细胞定位、糖基化位点、磷酸化位点、二级结构、三级结构、蛋白互作的关系网络和蛋白在革兰阴性杆菌中的同源性。采用Red同源重组技术构建大肠杆菌ΔcusS,在不同培养基中连续监测ΔcusS的生长情况,观察该基因缺失后的细菌生长活性;通过最小抑菌浓度(minimal inhibitory concentration, MIC)试验评价该缺失株对金属铜、银离子和临床常见抗生素的敏感性变化;运用RT-qPCR检测cusS缺失后其下游基因cusCFBA和cusR转录水平。【结果】CusS蛋白由480个氨基酸组成,相对分子质量为53 738.05,原子总数为7 624,等电点为6.02,具有稳定性,是一种亲水性、不溶性蛋白;含有跨膜域;不存在信号肽,定位于细胞内膜中;存在2个糖基化位点、24个丝氨酸磷酸化位点、14个苏氨酸磷酸化位点和3个酪氨酸磷酸化位点;二级结构中α-螺旋占比55.42%,β-折叠占比11.67%,β-转角占比3.75%,无规则卷曲占比29.17%;cusS在埃希菌属和志贺菌属中的保守性高;菌落PCR和一代测序验证ΔcusS构建成功;连续检测生长曲线表明cusS缺失并不影响细菌的生长代谢,但CusS蛋白为大肠杆菌抵御金属银胁迫的关键基因。【结论】cusS作为一个关键基因,它的缺失并不影响大肠杆菌的生长活性,但会显著降低细菌抵御银离子胁迫的应答能力。缺失cusS将使下游基因cusCFBA和cusR的mRNA表达水平显著下降。对CusS蛋白进行生物信息学分析及表型初探,为深入了解CusS在大肠杆菌应答银离子胁迫的调控机制奠定了基础。     

利用酿酒酵母转座子文库筛选线粒体镁代谢相关基因

镁离子对于维持细胞正常功能十分重要,糖尿病、高血压、慢性呼吸道疾病、骨质疏松、心律失常等多种疾病都与镁代谢失衡有关．MRS2 基因编码线粒体镁离子转运蛋白,MRS2缺失会导致酵母线粒体镁离子浓度下降、线粒体内Ⅱ型内含子剪接缺陷和非发酵碳源培养基上的生长缺陷．为了增进对线粒体镁离子代谢调控基因的了解,利用酿酒酵母mTn-lacZ/LEU2转座子文库筛选MRS2的抑制基因,发现线粒体载体家族成员YMR166C基因的缺失可以挽救MRS2基因缺失突变体的生长缺陷、Ⅱ型内含子剪接缺陷,并可以调节线粒体镁离子浓度,首次发现YMR166C是线粒体镁代谢相关基因.     

基于转录组测序数据对Weissella confusa XU1中低聚木糖代谢系统的分析

[目的]近年来由于在发酵方面的良好特性,低聚木糖的益生作用越来越得到公众的关注。研究发现相比于葡萄糖和木糖Weissella confusa XU1在以低聚木糖为唯一碳源时生长情况最好。本文将对Weissella confusa XU1中低聚木糖的代谢机制进行研究。[方法]本研究分别以葡萄糖、木糖和低聚木糖作为唯一碳源对Weissella confusa XU1进行转录组测序并进行比较分析。[结果]通过转录组分析发现以低聚木糖为唯一碳源的处理中部分编码MFS转运蛋白和糖基水解酶的基因转录水平显著上升,Weissella confusa XU1中的糖酵解过程和磷酸戊糖途径也得到显著增强。[结论]本研究根据转录组数据分析得出Weissella confusa XU1中的低聚木糖代谢机制。本研究首次在革兰氏阳性菌中发现MFS转运蛋白参与到低聚木糖转运的过程,为提高微生物对木聚糖利用效率进行分子改造提供了改造方向,该机制为低聚木糖代谢的研究和Weissella的工业化应用提供了新的思路。     

异源表达德氏乳杆菌保加利亚亚种TCS1调控酸适应基因提高乳酸乳球菌NZ9000耐酸性

[目的] 在乳酸乳球菌NZ9000中异源表达德氏乳杆菌保加利亚亚种中由双组分系统TCS1（JN675228/JN675229）调控的与酸适应相关基因,进而探究德氏乳杆菌保加利亚亚种应对酸胁迫的机制。[方法] 通过逆转录聚合酶链式反应和十二烷基硫酸钠-聚丙烯酰胺凝胶电泳验证由德氏乳杆菌保加利亚亚种TCS1调控的与酸适应相关基因中腺嘌呤磷酸核糖转移酶（aprt）、D-丙氨酸-D-丙氨酸连接酶（ddl）、寡肽ABC转运蛋白（oppDII）和延伸因子Ts（tsf）在乳酸乳球菌NZ9000中的表达情况。酸处理实验验证基因表达对宿主菌酸胁迫耐受能力的影响。并采用酵母双杂交验证双组分系统TCS1与表达的酸适应相关基因之间的互作关系及具体的互作部位。[结果] 结果表明,乳酸乳球菌NZ9000中成功表达了aprt、ddl、oppDII和tsf。aprt、ddl基因使重组菌对酸胁迫的抗性分别提高了75倍和114倍。oppDII和tsf基因的表达对重组菌株的耐酸能力没有明显影响。酵母双杂交实验表明TCS1中的组氨酸蛋白激酶HPK1与Ddl之间存在相互作用,且HPK1-C结构域是二者相互作用的关键区域。[结论] aprt和ddl过表达菌株酸刺激的适应能力显著高于对照菌株,该研究结果可为德氏乳杆菌保加利亚亚种及类似菌株耐酸性特性的获得策略提供参考。     

梨果黑斑病菌AaCaMK基因克隆、生物信息学分析及其在侵染结构分化中的表达分析

[背景] 钙/钙调素依赖型蛋白激酶（Calcium/Calmodulin-Dependent Protein Kinase,CaMK）是真核生物细胞钙信号途径中钙调素下游的一类重要靶蛋白,对病原物生长、胁迫响应及致病性等具有重要的调控作用。[目的] 对梨果黑斑病菌互隔交链孢（Alternaria alternata）AaCaMK基因进行克隆、生物信息学分析,并对其在侵染结构分化过程中的基因表达情况进行分析,为进一步研究梨果黑斑病菌钙离子信号途径中AaCaMK对A.alternata侵染结构分化调控的分子机制提供一定的理论依据。[方法] 采用同源克隆法从A. alternata JT-03中克隆得到3个AaCaMK基因;通过TMHMM、ProtScale、SOPMA等软件对AaCaMK基因进行生物信息学分析;利用实时荧光定量PCR （RT-qPCR）技术分析AaCaMK在梨果黑斑病菌侵染结构分化过程中的表达情况。[结果] 克隆得到片段分别为1 212、1 200、2 349 bp的AaCaMK1、AaCaMK2和AaCaMK3基因;生物信息学分析表明,AaCaMK1、AaCaMK2和AaCaMK3均含有典型的蛋白激酶超家族催化结构域（PKC_Like Superfamily）,并且AaCaMK1和AaCaMK2共同含有CaMK类丝/苏氨酸蛋白激酶催化结构域（STKc_CaMK）,AaCaMK3含有LKB1/CaMKK类丝/苏氨酸蛋白激酶催化结构域（STKc_LKB1_CaMKK）;同源性分析表明,AaCaMK1、AaCaMK2和AaCaMK3分别与玉米大斑病菌CAK1、CAK2和CAK3的相似性高达94.32%、97.49%和86.57%;RT-qPCR分析表明,AaCaMK1、AaCaMK2和AaCaMK3在疏水及果蜡诱导A. alternata侵染结构分化过程中均显著上调表达（P<0.05）,而且果蜡诱导作用更显著。其中AaCaMK1和AaCaMK2在附着胞形成时期（6 h）表达量为对照的1.51倍和3.05倍,而AaCaMK3在侵染菌丝形成阶段（8 h）表达量最高,为对照的2.86倍,并且在果蜡诱导下,这3个基因在芽管伸长阶段（4 h）的上调表达量显著高于疏水界面。[结论] 钙信号中AaCaMK基因在疏水及果蜡诱导A.alternata侵染结构分化过程中发挥重要的调控作用。     

大花杓兰亲环素基因的克隆及生物信息学分析

亲环素是一个多基因家族,在植物生命活动中发挥着重要的作用。该研究以大花杓兰(Cypripedium macranthum)为材料,采用RT-PCR技术克隆到1个亲环素基因(CyP),并对其进行生物信息学分析。结果表明:大花杓兰CyP基因的开放阅读框序列为525 bp,命名为CmCyP(GenBank登录号为MH411125),编码174个氨基酸。预测CmCyP蛋白是一个位于细胞质、相对分子量约为18 kD、理论pI为8.73、无信号肽、跨膜结构域的亲水性蛋白质。磷酸化和糖基化位点预测分析发现,CmCyP蛋白存在18个潜在的磷酸化位点和2个潜在的糖基化位点。蛋白保守结构域预测分析发现,CmCyP蛋白包含一个高度保守的肽脯氨酰顺反异构酶结构域,属于单结构域亲环素。对二级结构进行预测分析发现,CmCyP蛋白中存在无规卷曲70个、延伸链56个、α-螺旋23个、β-折叠25个,这4种结构元件在三级结构中也有体现。系统进化树结果显示,大花杓兰CmCyP蛋白与铁皮石斛(Dendrobium catenatum)和万带兰(Vanda hybrid cultivar)的CyP蛋白的亲缘关系较近。该研究首次克隆了大花杓兰亲环素基因(CmCyP),为进一步探讨CmCyP基因的生物学功能奠定了基础。     

GsSnRK1 interplays with transcription factor GsERF7 from wild soybean to regulate soybean stress resistance

Although the function and regulation of SnRK1 have been studied in various plants, its molecular mechanisms in response to abiotic stresses are still elusive. In this work, we identified an AP2/ERF domain-containing protein (designated GsERF7) interacting with GsSnRK1 from a wild soybean cDNA library. GsERF7 gene expressed dominantly in wild soybean roots and was responsive to ethylene, salt, and alkaline. GsERF7 bound GCC cis-acting element and could be phosphorylated on S36 by GsSnRK1. GsERF7 phosphorylation facilitated its translocation from cytoplasm to nucleus and enhanced its transactivation activity. When coexpressed in the hairy roots of soybean seedlings, GsSnRK1(wt) and GsERF7(wt) promoted plants to generate higher tolerance to salt and alkaline stresses than their mutated species, suggesting that GsSnRK1 may function as a biochemical and genetic upstream kinase of GsERF7 to regulate plant adaptation to environmental stresses. Furthermore, the altered expression patterns of representative abiotic stress-responsive and hormone-synthetic genes were determined in transgenic soybean hairy roots after stress treatments. These results will aid our understanding of molecular mechanism of how SnRK1 kinase plays a cardinal role in regulating plant stress resistances through activating the biological functions of downstream factors.     

Identification of novel interactors and potential phosphorylation substrates of GsSnRK1 from wild soybean (Glycine soja)

The plant sucrose nonfermenting kinase 1 (SnRK1) kinases play the central roles in the processes of energy balance, hormone perception, stress resistance, metabolism, growth, and development. However, the functions of these kinases are still elusive. In this study, we used GsSnRK1 of wild soybean as bait to perform library‐scale screens by the means of yeast two‐hybrid to identify its interacting proteins. The putative interactions were verified by yeast retransformation and β‐galactosidase assays, and the selected interactions were further confirmed in planta by bimolecular fluorescence complementation and biochemical Co‐IP assays. Protein phosphorylation analyses were carried out by phos‐tag assay and anti‐phospho‐(Ser/Thr) substrate antibodies. Finally, we obtained 24 GsSnRK1 interactors and several putative substrates that can be categorized into SnRK1 regulatory β subunit, protein modification, biotic and abiotic stress‐related, hormone perception and signalling, gene expression regulation, water and nitrogen transport, metabolism, and unknown proteins. Intriguingly, we first discovered that GsSnRK1 interacted with and phosphorylated the components of soybean nodulation and symbiotic nitrogen fixation. The interactions and potential functions of GsSnRK1 and its associated proteins were extensively discussed and analysed. This work provides plausible clues to elucidate the novel functions of SnRK1 in response to variable environmental, metabolic, and physiological requirements.     

TORC1 signaling regulates cytoplasmic pH through Sir2 in yeast

Glucose controls the phosphorylation of silent information regulator 2 (Sir2), a NAD⁺‐dependent protein deacetylase, which regulates the expression of the ATP‐dependent proton pump Pma1 and replicative lifespan (RLS) in yeast. TORC1 signaling, which is a central regulator of cell growth and lifespan, is regulated by glucose as well as nitrogen sources. In this study, we demonstrate that TORC1 signaling controls Sir2 phosphorylation through casein kinase 2 (CK2) to regulate PMA1 expression and cytoplasmic pH (pHc) in yeast. Inhibition of TORC1 signaling by either TOR1 deletion or rapamycin treatment decreased PMA1 expression, pHc, and vacuolar pH, whereas activation of TORC1 signaling by expressing constitutively active GTR1 (GTR1Q65L) resulted in the opposite phenotypes. Deletion of SIR2 or expression of a phospho‐mutant form of SIR2 increased PMA1 expression, pHc, and vacuolar pH in the tor1Δ mutant, suggesting a functional interaction between Sir2 and TORC1 signaling. Furthermore, deletion of TOR1 or KNS1 encoding a LAMMER kinase decreased the phosphorylation level of Sir2, suggesting that TORC1 signaling controls Sir2 phosphorylation. It was also found that Sit4, a protein phosphatase 2A (PP2A)‐like phosphatase, and Kns1 are required for TORC1 signaling to regulate PMA1 expression and that TORC1 signaling and the cyclic AMP (cAMP)/protein kinase A (PKA) pathway converge on CK2 to regulate PMA1 expression through Sir2. Taken together, these findings suggest that TORC1 signaling regulates PMA1 expression and pHc through the CK2–Sir2 axis, which is also controlled by cAMP/PKA signaling in yeast.     

Inhibition of core histones acetylation by carcinogenic nickel(II)

In Drosophila, protein kinase CK2 regulates a diverse array of developmental processes. One of these is cell-fate specification (neurogenesis) wherein CK2 regulates basic-helix-loop-helix (bHLH) repressors encoded by the Enhancer of Split Complex (E(spl)C). Specifically, CK2 phosphorylates and activates repressor functions of E(spl)M8 during eye development. In this study we describe the interaction of CK2 with an E(spl)-related bHLH repressor, Deadpan (Dpn). Unlike E(spl)-repressors which are expressed in cells destined for a non-neural cell fate, Dpn is expressed in the neuronal cells and is thought to control the activity of proneural genes. Dpn also regulates sex-determination by repressing sxl, the primary gene involved in sex differentiation. We demonstrate that Dpn is weakly phosphorylated by monomeric CK2α, whereas it is robustly phosphorylated by the embryo-holoenzyme, suggesting a positive role for CK2β. The weak phosphorylation by CK2α is markedly stimulated by the activator polylysine to levels comparable to those with the holoenzyme. In addition, pull down assays indicate a direct interaction between Dpn and CK2. This is the first demonstration that Dpn is a partner and target of CK2, and raises the possibility that its repressor functions might also be regulated by phosphorylation.     

PP2ACdc55 regulates G1 cyclin stability

Maintaining accurate progression through the cell cycle requires the proper temporal expression and regulation of cyclins. The mammalian D-type cyclins promote G₁-S transition. D1 cyclin protein stability is regulated through its ubiquitylation and resulting proteolysis catalyzed by the SCF E3 ubiquitin ligase complex containing the F-box protein, Fbx4. SCF E3-ligase-dependent ubiquitylation of D1 is trigged by an increase in the phosphorylation status of the cyclin. As inhibition of ubiquitin-dependent D1 degradation is seen in many human cancers, we set out to uncover how D-type cyclin phosphorylation is regulated. Here we show that in S. cerevisiae, a heterotrimeric protein phosphatase 2A (PP2A^Cdc55) containing the mammalian PPP2R2/PR55 B subunit ortholog Cdc55 regulates the stability of the G₁ cyclin Cln2 by directly regulating its phosphorylation state. Cells lacking Cdc55 contain drastically reduced Cln2 levels caused by degradation due to cdk-dependent hyperphosphorylation, as a Cln2 mutant unable to be phosphorylated by the yeast cdk Cdc28 is highly stable in cdc55-null cells. Moreover, cdc55-null cells become inviable when the SCF^Grr1 activity known to regulate Cln2 levels is eliminated or when Cln2 is overexpressed, indicating a critical relationship between SCF and PP2A functions in regulating cell cycle progression through modulation of G₁-S cyclin degradation/stability. In sum, our results indicate that PP2A is absolutely required to maintain G₁-S cyclin levels through modulating their phosphorylation status, an event necessary to properly transit through the cell cycle.     

Low temperature-stimulated phosphorylation regulates the binding of nuclear factors to the promoter of Wcs120 , a cold-specific gene in wheat

The Wcs120 gene encodes a highly abundant protein which appears to play an important role during cold acclimation of wheat. To understand the regulatory mechanism controlling its expression at low temperature, the promoter region has been characterized. Electrophoretic mobility shift assays using short promoter fragments revealed the presence in nuclear extracts from non-acclimated (NA) plants of multiple DNA-binding proteins which interact with several elements. In contrast, no DNA-binding activity was observed in the nuclear extracts from cold-acclimated (CA) plants. In vitro dephosphorylation of these CA nuclear extracts with alkaline phosphatase restored the binding activity. Moreover, okadaic acid (a potent phosphatase inhibitor) markedly stimulated the in vivo accumulation of the WCS120 family of proteins. This suggests that protein phosphatases PP1 and/or PP2A negatively regulate the expression of the Wcs120 gene. In addition, both Ca²⁺-dependent and Ca²⁺-independent kinase activities were found to be significantly higher in the CA nuclear extracts. Western analysis using antibodies directed against protein kinase C (PKC) isoforms showed that a PKCγ homolog (84 kDa) is selectively translocated into the nucleus in response to low temperature. Taken together, our results suggest that, in vivo, the expression of the Wcs120 gene may be regulated by nuclear factors whose binding activity is modulated by a phosphorylation/dephosphorylation mechanism. Received: 9 June 1997 / Accepted: 18 August 1997     

Re‐programming of gene expression in the CS8 rice line over‐expressing ADPglucose pyrophosphorylase induces a suppressor of starch biosynthesis

The CS8 transgenic rice (Oryza sativa L.) lines expressing an up‐regulated glgC gene produced higher levels of ADPglucose (ADPglc), the substrate for starch synthases. However, the increase in grain weight was much less than the increase in ADPglc levels suggesting one or more downstream rate‐limiting steps. Endosperm starch levels were not further enhanced in double transgenic plants expressing both glgC and the maize brittle‐1 gene, the latter responsible for transport of ADPglc into the amyloplast. These studies demonstrate that critical processes within the amyloplast stroma restrict maximum carbon flow into starch. RNA‐seq analysis showed extensive re‐programming of gene expression in the CS8 with 2073 genes up‐regulated and 140 down‐regulated. One conspicuous gene, up‐regulated ~15‐fold, coded for a biochemically uncharacterized starch binding domain‐containing protein (SBDCP1) possessing a plastid transit peptide. Confocal microscopy and transmission electron microscopy analysis confirmed that SBDCP1 was located in the amyloplasts. Reciprocal immunoprecipitation and pull‐down assays indicated an interaction between SBDCP1 and starch synthase IIIa (SSIIIa), which was down‐regulated at the protein level in the CS8 line. Furthermore, binding by SBDCP1 inhibited SSIIIa starch polymerization activity in a non‐competitive manner. Surprisingly, artificial microRNA gene suppression of SBDCP1 restored protein expression levels of SSIIIa in the CS8 line resulting in starch with lower amylose content and increased amylopectin chains with a higher degree of polymerization. Collectively, our results support the involvement of additional non‐enzymatic factors such as SBDCP in starch biosynthesis.     

LncRNA‐DANCR contributes to lung adenocarcinoma progression by sponging miR‐496 to modulate mTOR expression

Long non‐coding RNAs (lncRNAs) have emerged as new and important regulators of pathological processes including tumour development. In this study, we demonstrated that differentiation antagonizing non‐protein coding RNA (DANCR) was up‐regulated in lung adenocarcinoma (ADC) and that the knockdown of DANCR inhibited tumour cell proliferation, migration and invasion and restored cell apoptosis rescued; cotransfection with a miR‐496 inhibitor reversed these effects. Luciferase reporter assays showed that miR‐496 directly modulated DANCR; additionally, we used RNA‐binding protein immunoprecipitation (RIP) and RNA pull‐down assays to further confirm that the suppression of DANCR by miR‐496 was RISC‐dependent. Our study also indicated that mTOR was a target of miR‐496 and that DANCR could modulate the expression levels of mTOR by working as a competing endogenous RNA (ceRNA). Furthermore, the knockdown of DANCR reduced tumour volumes in vivo compared with those of the control group. In conclusion, this study showed that DANCR might be an oncogenic lncRNA that regulates mTOR expression through directly binding to miR‐496. DANCR may be regarded as a biomarker or therapeutic target for ADC.     

Phosphorylation of p27KIP1 homologs KRP6 and 7 by SNF1‐related protein kinase–1 links plant energy homeostasis and cell proliferation

SNF1‐related protein kinase–1 (SnRK1), the plant kinase homolog of mammalian AMP‐activated protein kinase (AMPK), is a sensor that maintains cellular energy homeostasis via control of anabolism/catabolism balance. AMPK‐dependent phosphorylation of p27^KIP1 affects cell‐cycle progression, autophagy and apoptosis. Here, we show that SnRK1 phosphorylates the Arabidopsis thaliana cyclin‐dependent kinase inhibitor p27^KIP1 homologs AtKRP6 and AtKRP7, thus extending the role of this kinase to regulation of cell‐cycle progression. AtKRP6 and 7 were phosphorylated in vitro by a recombinant activated catalytic subunit of SnRK1 (AtSnRK1α1). Tandem mass spectrometry and site‐specific mutagenesis identified Thr152 and Thr151 as the phosphorylated residues on AtKRP6‐ and AtKRP7, respectively. AtSnRK1 physically interacts with AtKRP6 in the nucleus of transformed BY–2 tobacco protoplasts, but, in contrast to mammals, the AtKRP6 Thr152 phosphorylation state alone did not modify its nuclear localization. Using a heterologous yeast system, consisting of a cdc28 yeast mutant complemented by A. thaliana CDKA;1, cell proliferation was shown to be abolished by AtKRP6^WT and by the non‐phosphorylatable form AtKRP6^T152A, but not by the phosphorylation‐mimetic form AtKRP6^T152D. Moreover, A. thaliana SnRK1α1/KRP6 double over‐expressor plants showed an attenuated AtKRP6‐associated phenotype (strongly serrated leaves and inability to undergo callogenesis). Furthermore, this severe phenotype was not observed in AtKRP6^T152D over‐expressor plants. Overall, these results establish that the energy sensor AtSnRK1 plays a cardinal role in the control of cell proliferation in A. thaliana plants through inhibition of AtKRP6 biological function by phosphorylation.     

LIM蛋白KyoT2与人类紧密连接蛋白2的相互作用

KyoT是一种LIM结构域蛋白,是以RBP－J为诱饵蛋白通过酵母双杂交系统得到的新分子,KyoT2可以抑制RBP－J介导的转录,以KyoT2为诱饵蛋白,通过酵母双杂交筛选得到了人类紧密连接蛋白2（ZO－2）,的一种新的剪接体ZO－2－i3,序列分析表明,新的剪接体有19个外显子,与已发表序列比较,见ZO－2－i3分子的激酶后区发生了改变,为排除酵母双杂交实验的假阳性,实验首先在酵母中验证KyoT2与ZO－2-i3的体外直接相互作用并得到阳性结果,进而在大肠杆菌中原核表达纯化带有His标签的KyoT2蛋白,使用抗His标签的抗体,通过GST pull-down assay验证KyoT2与ZO－2－i3的体外直接相互作用,也获得阳性结果,并通过酵母实验初步确定了其作用位点,即KyoT2通过LIM2结构域与ZO－2-i3相互作用,本实验验证了KyoT2与Z－2－i3的相互作用,并初步确定其相互作用位点,对探讨KyoT的功能具有重要意义。