利用转基因烟草确定AtELHYPRP2蛋白对赤霉菌的抗性及其亚细胞定位特征

采用遗传转化技术获得了整合有拟南芥AtELHYPRP2(EARLI1-LIKE HYBRID PROLINE-RICH PROTEIN 2,AT4G12500)基因的转基因烟草株系,研究了该基因编码蛋白对真菌病原体赤霉菌的抗性及其亚细胞定位特征。以拟南芥Col-0生态型基因组DNA为模板,通过聚合酶链反应扩增AtELHYPRP2基因编码序列,经限制性酶切后连接至pCAMBIA1302载体,构建产生pCAMBIA1302-AtELHYPRP2-GFP融合表达载体。进一步采用农杆菌LBA4404转化烟草叶片外植体,筛选得到转基因烟草植株。RT-PCR、Western blotting印迹分析结果显示,AtELHYPRP2基因在转化体中可以有效表达。激光共聚焦显微观察发现AtELHYPRP2-GFP融合蛋白产生的绿色荧光与碘化丙啶染色后产生的红色荧光能够重合,说明AtELHYPRP2蛋白定位于细胞表面。真菌侵染实验结果显示,组成性表达AtELHYPRP2基因能够增强烟草对赤霉菌的抗性,被侵染部位有明显的H2O2积累。转基因烟草植株中PR1基因的本底表达水平比野生型高,PR1和PR5基因的系统表达水平比野生型高,说明AtELHYPRP2基因可能在SAR反应中具有一定的作用。     

拟南芥抵抗丁香假单胞杆菌过程中AZI1基因功能研究

AZI1属于脂转移蛋白家族,它在拟南芥抵抗病原菌侵染过程中可能起着传递信号物质的作用。该实验以过表达和T-DNA插入突变体及野生型拟南芥植株为材料,通过RNA印迹、蛋白质免疫印迹和原位免疫组织化学方法,研究了拟南芥壬二酸诱导基因AZI1对丁香假单胞杆菌的抗性功能。结果表明:(1)AZI1基因可以被丁香假单胞杆菌、H2O2和乙烯利诱导,它可能参与水杨酸和乙烯介导的抗菌途径。(2)蛋白质免疫印迹实验结果显示,丁香假单胞杆菌侵染叶片的叶柄渗出液中存在AZI1蛋白及其同源物EARLI1,并能够与其他蛋白质形成复合体,说明AZI1有可能通过维管组织移动到个体的其他部位,与信号分子的转移有关。(3)AZI1及其同源物EARLI1主要在花序茎的木质化部位表达,过表达AZI1基因能够促进木质素的合成,提高拟南芥对丁香假单胞杆菌的抗性。     

拟南芥HyPRP蛋白AZI1在转基因烟草中的亚细胞定位及其对灰葡萄孢的抗性

通过农杆菌转化法得到了整合有拟南芥AZII基因的烟草植株,进一步利用转基因烟草分析了AZI1蛋白的亚细胞定位及其对真菌病原体的抗性特征。在上下游引物5’端分别引入NcoI和SpeI酶切位点,采用高保真耐热DNA聚合酶彤Pfu从拟南芥Co1-0生态型基因组DNA扩增AZII基因的编码序列,用NcoI和Spel对扩增片段和pCAMBIA1302质粒载体进行双酶切,通过T4DNA连接酶构建产生AZII-GFP融合表达载体。用包含融合表达载体的农杆菌细胞转化烟草叶片,经潮霉素选择获得了完整的再生植株,并收取了T。代种子。激光共聚焦显微观察发现,AZI1蛋白主要定位于细胞表面。病原体侵染结果显示,AZI1基因能够明显提高烟草对灰葡萄孢的抗性。说明AZI1蛋白通过分泌途径被定位到细胞表面后,能够抑制真菌病原体对植物组织的侵染过程。     

拟南芥AtDAD1 超量表达植株对H2O2抗性的研究

构建拟南芥AtDAD1超量表达载体,以农杆菌介导的方法转化拟南芥哥伦比亚生态型,比较AtDAD1超量表达植株和野生型植株表现型的差异,以及两者对H2O2抗性的不同。实验显示,AtDAD1转基因拟南芥生长较野生型拟南芥更为强壮,对高浓度H2O2有较强的耐受力。测定两者糖含量,发现AtDAD1转基因拟南芥叶片糖的含量明显高于野生型拟南芥叶片。以上结果表明,AtDAD1基因可能参与植物生长发育,并可能在拟南芥抵抗凋亡的过程中发挥重要的作用。     

拟南芥新型脂转移蛋白AtDHyPRP1的亚细胞定位及其对灰霉菌的抗性

通过遗传转化技术研究了拟南芥脂转移蛋白AtDHyPRP1在细胞中的定位及其对真菌病原体的抗性。采用PCR方法从拟南芥Ws生态型克隆了AtDHyPRP1基因,构建产生pRI101-AN-AtDHyPRP1植物双元表达载体和pCAMBIA1302-AtDHyPRP1-GFP融合表达载体,经农杆菌介导的叶盘和浸花法得到烟草和拟南芥转基因植株。AtDHyPRP1基因能够明显增加烟草对灰霉菌的抗性,转AtDHyPRP1烟草叶片的被侵染部位有大量H2O2积累,激光共聚焦显微观察发现AtDHyPRP1蛋白定位于细胞表面。说明AtDHyPRP1蛋白在合成后被分泌到细胞外执行特殊的功能,与植物抗病防御机制有关。     

大豆转录因子GmC2H2基因转化拟南芥效果分析

GmC2H2转录因子基因是本实验室获得的一个编码172个氨基酸携带516bp核苷酸的转录因子,属于经典C2H2型锌指蛋白.通过构建植物表达载体GmC2H2-pCAMBIA1304,借助优化的Floral-dip法转化模式植物拟南芥,经潮霉素Hygromycine( 45-50 mg/L)抗性筛选获得转基因拟南芥植株.GUS组织染色分析表明,GmC2H2基因在生长12d的转基因拟南芥幼苗中,表达部位主要集中在根部.对转基因拟南芥进行了低温(1℃)和脱落酸(200 μmol/L)胁迫处理,测定其生理生化指标,通过real-time qPCR确定目的基因在转基因拟南芥中的表达情况.结果表明,携带GmC2H2目的基因的转基因拟南芥中脯氨酸和可溶性糖水平要高于野生型植株,而丙二醛水平要低于野生型,在抗逆性方面明显优于野生型拟南芥植株;并且胁迫处理下的转基因拟南芥中GmC2H2基因的表达量要高于未胁迫处理的转基因植株,说明GmC2H2基因的表达受低温和ABA的诱导,初步明确了该转录因子基因的功能.     

ECS1参与调节CO2诱导的拟南芥气孔关闭和H2O2积累

CO2浓度升高可以诱导植物叶片气孔关闭,提高植物对高浓度CO2的适应性.但植物如何感知CO2浓度变化并启动气孔关闭反应的分子机制至今仍不十分清楚.利用高通量、非侵入的远红外成像技术,建立了拟南芥(Arabidopsis thaliana)气孔对CO2浓度变化反应相关的突变体筛选技术,筛选出对环境CO2浓度敏感的拟南芥突变体ecs1.遗传学分析表明,ecs1 为单基因隐性突变体,突变基因ECS1编码一个跨膜钙离子转运蛋白.与野生型拟南芥相比,360 μL·L-1CO2可引起ecs1突变体叶片温度上升和气孔关闭,ecs1突变体对900 μL·L-1CO2长时间处理具有较强的适应性.进一步的实验表明,360 μL·L-1CO2即可诱导ecs1突变体叶片积累较高浓度的H2O2,而900 μL·L-1CO2才能够诱导野生型拟南芥叶片积累H2O2.因此,ECS1可能参与调节高浓度CO2诱导的拟南芥气孔关闭和H2O2产生,H2O2可能作为第二信号分子介导CO2诱导拟南芥气孔关闭的反应.     

H2S位于H2O2下游参与乙烯诱导拟南芥气孔关闭过程

H2O2和H2S是植物体内重要的信号分子,二者均参与乙烯诱导的拟南芥气孔关闭过程。以拟南芥野生型及其突变体为材料研究了H2O2和H2S在乙烯诱导拟南芥气孔关闭过程中的相互关系。结果表明,乙烯能够诱导野生型拟南芥叶片H2S含量及L-/D-半胱氨酸脱巯基酶(L-/D-CDes)活性显著增加,促进气孔关闭,但对H2O2合成突变体AtrbohD、AtrbohF、Atpao2和Atpao4植株叶片无显著作用;乙烯亦可引起H2S合成突变体Atl-cdes和Atd-cdes气孔保卫细胞H2O2水平的显著增加,但对其气孔运动没有显著作用。此外,H2O2清除剂和合成抑制剂均能抑制乙烯诱导的拟南芥叶片H2S含量和L-/D-CDes活性的增加及气孔开度的减小;而H2S清除剂和合成抑制剂虽能抑制乙烯诱导的气孔关闭,却不能改变乙烯对拟南芥叶片气孔保卫细胞H2O2的作用效应。由此表明H2S位于H2O2下游介导乙烯诱导拟南芥气孔关闭过程。     

拟南芥AtDAD1超量表达植株对H2O2抗性的研究

构建拟南芥AtDAD1超量表达载体,以农杆菌介导的方法转化拟南芥哥伦比亚生态型,比较AtDAD1超量表达植株和野生型植株表现型的差异,以及两者对H₂O₂抗性的不同。实验显示,AtDAD1转基因拟南芥生长较野生型拟南芥更为强壮,对高浓度H₂O₂有较强的耐受力。测定两者糖含量,发现AtDAD1转基因拟南芥叶片糖的含量明显高于野生型拟南芥叶片。以上结果表明,AtDAD1基因可能参与植物生长发育,并可能在拟南芥抵抗凋亡的过程中发挥重要的作用。     

H_2O_2介导H_2S诱导的拟南芥气孔关闭

以拟南芥（Arabidopsis thaliana）为材料,研究了过氧化氢（H2O2）在硫化氢（H2S）调控气孔运动信号转导中的作用。结果表明,光下H2S的供体硫氢化钠（NaHS）能够诱导拟南芥气孔关闭;且能够显著提高叶片和保卫细胞胞质H2O2含量;H2O2的清除剂AsA和H2O2合成酶的抑制剂可不同程度地抑制NaHS诱导的拟南芥气孔关闭及叶片和保卫细胞胞质H2O2水平的升高;NaHS对AtrbohD、AtrbohF、Atpao2和Atpao4突变体气孔关闭、叶片和保卫细胞胞质H2O2水平升高的诱导作用要明显的小于野生型,但对AtPAO2和AtPAO4过表达株系叶片和保卫细胞H2O2水平的升高较野生型显著。据此推测,来源于NADPH氧化酶、细胞壁过氧化物酶和多胺氧化酶途径的H2O2参与H2S诱导的拟南芥气孔关闭。     

Cold-inducible expression of AZI1 and its function in improvement of freezing tolerance of Arabidopsis thaliana and Saccharomyces cerevisiae

AZI1 (AZELAIC ACID INDUCED 1) of Arabidopsis thaliana could be induced by azelaic acid and was involved in priming of systemic plant immunity. In the present work, expression of AZI1 in response to low temperature was investigated via RNA gel blot analysis. AZI1 could be induced slowly by cold stress and more than 6 h treatment at 4 °C was required to detect an increase in mRNA abundance. However, the high expression state could not be maintained stably and would decline to basal level when the plants were transferred to room temperature. In order to clarify the function of AZI1 in resistance to abiotic stresses, overexpressing, RNA interference and T-DNA knockout lines of this gene were used in electrolyte leakage assays. Overexpression of AZI1 resulted in reduced electrolyte leakage during freezing damage. In contrast, AZI1 knockdown and knockout lines showed increased tendencies in cellular damage after freezing treatment. To further validate the potential resistance of AZI1 to low-temperature stress, Saccharomyces cerevisiae cells were transformed with pESC-AZI1 in which AZI1 was under the control of GAL1 promoter. Compared to yeast cells containing empty pESC-URA, the survival rate of yeast cells harboring AZI1 increased obviously after freezing treatment. All these results suggested that AZI1 might be multifunctional and associated with cold tolerance of Arabidopsis.     

Stable siRNA-mediated silencing of antizyme inhibitor: regulation of ornithine decarboxylase activity

Ornithine decarboxylase (ODC) is the rate-limiting enzyme involved in the biosynthesis of polyamines essential for cell growth and differentiation. Aberrant upregulation of ODC, however, is widely believed to be a contributing factor in tumorigenesis. Antizyme is a major regulator of ODC, inhibiting ODC activity through the formation of complexes and facilitating degradation of ODC by the 26S proteasome. Moreover, the antizyme inhibitor (AZI) serves as another factor in regulating ODC, by binding to antizyme and releasing ODC from ODC-antizyme complexes. In our previous report, we observed elevated AZI expression in tumor specimens. Therefore, to evaluate the role of AZI in regulating ODC activity in tumors, we successfully down-regulated AZI expression using RNA interference technology in A549 lung cancer cells expressing high levels of AZI. Two AZI siRNAs, which were capable to generate a hairpin dsRNA loop targeting AZI, could successively decrease the expression of AZI. Using biological assays, antizyme activity increased in AZI-siRNA-transfected cells, and ODC levels and activity were reduced as well. Moreover, silencing AZI expression decreased intracellular polyamine levels, reduced cell proliferation, and prolonged population doubling time. Our results directly demonstrate that downregulation of AZI regulates ODC activity, intracellular polyamine levels, and cell growth through regulating antizyme activity. This study also suggests that highly expressed AZI may be partly responsible for increased ODC activity and cellular transformation.     

5-Azacytidine-induced Protein 2 (AZI2) Regulates Bone Mass by Fine-tuning Osteoclast Survival

5-Azacytidine-induced protein 2 (AZI2) is a TNF receptor (TNFR)-associated factor family member-associated NF-κB activator-binding kinase 1-binding protein that regulates the production of IFNs. A previous in vitro study showed that AZI2 is involved in dendritic cell differentiation. However, the roles of AZI2 in immunity and its pleiotropic functions are unknown in vivo. Here we report that AZI2 knock-out mice exhibit normal dendritic cell differentiation in vivo. However, we found that adult AZI2 knock-out mice have severe osteoporosis due to increased osteoclast longevity. We revealed that the higher longevity of AZI2-deficient osteoclasts is due to an augmented activation of proto-oncogene tyrosine-protein kinase Src (c-Src), which is a critical player in osteoclast survival. We found that AZI2 inhibits c-Src activity by regulating the activation of heat shock protein 90 (Hsp90), a chaperone involved in c-Src dephosphorylation. Furthermore, we demonstrated that AZI2 indirectly inhibits c-Src by interacting with the Hsp90 co-chaperone Cdc37. Strikingly, administration of a c-Src inhibitor markedly prevented bone loss in AZI2 knock-out mice. Together, these findings indicate that AZI2 regulates bone mass by fine-tuning osteoclast survival.     

Knockdown of antizyme inhibitor decreases prostate tumor growth in vivo

The endogenous protein antizyme inhibitor (AZI) is a potential oncogene which promotes cell growth by both inhibiting antizyme (AZ) activity and releasing ornithine decarboxylase (ODC) from AZ-mediated degradation. High levels of ODC and polyamines are associated with numerous types of neoplastic transformation, and the genomic region including AZI is frequently amplified in tumors of the ovary and prostate. To determine whether AZI functionally promotes prostate tumor growth, we made PC3M-LN4 (human) and AT6.1 (rat) cancer cell lines stably expressing shRNA to knockdown antizyme inhibitor 1 (AZI). AZI knockdown was confirmed by western blot, quantitative real-time PCR, and immunofluorescence. To examine the ability of these cells to form tumors in vivo, 1 × 10(6) cells were injected subcutaneously into nude mice either with (PC3M-LN4) or without (AT6.1) Matrigel. Tumor growth was measured two times per week by caliper. We found that cells in which AZI levels had been knocked down by shRNA formed significantly smaller tumors in vivo in both human and rat prostate cancer cell lines. These results suggest that not only does AZI promote tumor growth, but also that AZI may be a valid therapeutic target for cancer treatment.     

不同倍性香石竹杂交受精过程及胚胎发育研究

采用石蜡切片法对以四倍体香石竹品种‘紫蝴蝶’(2n=4x=60)为母本,单瓣中间材料‘NH6’(2n=2x=30)为父本杂交后受精过程及胚胎发育进行研究。结果表明:(1)授粉后17h,花粉管进入助细胞并释放内容物,精核进入极核细胞内,与二极核细胞融合形成初生胚乳核;授粉后1d,精核向卵核方向移动,贴伏于卵核核膜上;授粉后2d,形成合子及游离的胚乳核;随后,胚发育经过原胚、球形胚、心形胚、鱼雷形胚阶段。(2)杂交障碍发生在受精过程及胚胎发育的各个时期,表现为:精子与卵细胞不相融合或精子与二极核不相融合、合子未分裂或初生胚乳核未分裂及胚胎的败育。(3)胚败育虽能发生在原胚、球形胚、棒状形胚、三角形胚、心形胚、鱼雷形胚及子叶形胚阶段,但主要发生在球形胚阶段。     

2A肽介导猪PID1与CuZnSOD双基因真核共表达载体的构建与细胞表达

构建PID1基因与CuZnSOD基因的真核共表达载体,在PK15细胞中鉴定基因的表达。PCR扩增的PID1与CuZnSOD两基因分别经双酶切后定向插入pIRES2-AcGFP1空载体,构建pIRES2-CuZnSOD-PID1真核双表达载体并进行测序与酶切鉴定。采用脂质体转染法将重组质粒转染至PK15细胞,细胞内荧光显微镜下观察其荧光的表达,RT-PCR、Westernblot技术分别检测PID1基因与CuZnSOD基因mRNA和蛋白表达情况。重组克隆载体插入目的片段序列与PID1基因与CuZnSOD基因序列完全一致。PIRES2-CuZnSOD-PID1真核双表达载体测序、酶切鉴定结果与预期结果一致。荧光显微镜下观察转染后的PK15细胞出现绿色荧光。RT-PCR检测结果显示,转染细胞中PID1基因与CuZnSOD基因表达量明显高于对照组（P〈0.05）。Westernblot检测结果表明pIRES2-CuZnSODPID1真核双表达载体稳定有效表达。成功构建pIRES2-CuZnSOD-PID1真核共表达载体,且双基因在真核细胞独立稳定表达,为转基因猪等育种新材料的制备奠定基础。     

MEKK2基因siRNA重组腺病毒表达载体的构建及其对MEKK2的表达抑制

设计并合成针对人MEKK2基因3个不同部位siRNA靶点的模板DNA序列,将合成的互补片段退火后克隆入pRNAT-H1.1/Adeno穿梭载体中,并使其在大肠杆菌BJ5183中与腺病毒骨架质粒pAdEasy-1进行同源重组。将经鉴定正确的重组腺病毒质粒转染293A细胞,包装得到具有感染能力的pAd-MEKK2-siRNA重组腺病毒。病毒体外转导人胃腺癌AGS细胞,Western blot印迹法检测其对MEKK2表达的抑制。经酶切和测序鉴定均证实pAd-MEKK2-siRNA重组腺病毒载体构建成功,其插入序列正确无误。Western blot印迹检测结果显示,重组腺病毒表达载体可抑制MEKK2基因的表达,以pAd-MEKK2-siRNA2（针对MEKK2 cDNA 992-1 010的片段）抑制效果为最佳,pAd-MEKK2-siRNA1（针对MEKK2 cDNA 1 456-1 474的片段）和pAd-MEKK2-siRNA3（针对MEKK2 cDNA 1 351-1 369的片段）则未见明显的抑制效果。DNA Ladder和细胞存活测定结果表明,敲减MEKK2的表达后,AGS细胞接受H2O2刺激后的凋亡受到较强抑制、细胞存活数增加,明显高于野生型细胞和转导siRNA阴性对照腺病毒细胞接受H2O2刺激后的,差异具有统计学意义（P〈0.05）,而后两者之间差异无统计学意义（P〉0.05）。该研究成功地构建了针对MEKK2基因的siRNA重组腺病毒载体,为进一步深入研究MEKK2基因在人胃腺癌细胞中的作用和功能奠定了基础。     

The Centriolar Satellite Protein AZI1 Interacts with BBS4 and Regulates Ciliary Trafficking of the BBSome

Bardet-Biedl syndrome (BBS) is a well-known ciliopathy with mutations reported in 18 different genes. Most of the protein products of the BBS genes localize at or near the primary cilium and the centrosome. Near the centrosome, BBS proteins interact with centriolar satellite proteins, and the BBSome (a complex of seven BBS proteins) is believed to play a role in transporting ciliary membrane proteins. However, the precise mechanism by which BBSome ciliary trafficking activity is regulated is not fully understood. Here, we show that a centriolar satellite protein, AZI1 (also known as CEP131), interacts with the BBSome and regulates BBSome ciliary trafficking activity. Furthermore, we show that AZI1 interacts with the BBSome through BBS4. AZI1 is not involved in BBSome assembly, but accumulation of the BBSome in cilia is enhanced upon AZI1 depletion. Under conditions in which the BBSome does not normally enter cilia, such as in BBS3 or BBS5 depleted cells, knock down of AZI1 with siRNA restores BBSome trafficking to cilia. Finally, we show that azi1 knockdown in zebrafish embryos results in typical BBS phenotypes including Kupffer''s vesicle abnormalities and melanosome transport delay. These findings associate AZI1 with the BBS pathway. Our findings provide further insight into the regulation of BBSome ciliary trafficking and identify AZI1 as a novel BBS candidate gene.