准噶尔小胸鳖甲抗冻蛋白MPAFP5毕赤酵母表达产物的理化性质

研究准噶尔小胸鳖甲Microdera punctipennis dzhungarica Kasz抗冻蛋白MPAFP5真核表达产物的功能及理化性质。首先用硫酸铵浓度梯度沉淀初步纯化酵母真核表达产物,然后通过细菌低温保护实验检测抗冻蛋白MPAFP5低温保护功能,同时探讨抗冻蛋白MPAFP5在酸碱环境和100℃时的稳定性,并通过等电聚焦凝胶电泳检测其等电点。研究表明MPAFP5真核表达产物在低温下能够提高细菌的存活率,能够耐受高温和一定程度的强酸强碱,其等电点约为5.8左右。准噶尔小胸鳖甲抗冻蛋白MPAFP5真核表达产物与赤翅甲抗冻蛋白(DAFP)的比较表明拟步甲类昆虫抗冻蛋白具有相似的理化性质。     

新疆准噶尔小胸鳖甲抗冻蛋白在毕赤酵母中的分泌表达

目的：利用酵母Pichia pastoris蛋白表达系统,表达准噶尔小胸鳖甲抗冻蛋白。方法：根据新疆准噶尔小胸鳖甲抗冻蛋白(MPAFP5)基因序列设计引物,并分别在5’引物和3’引物中引入了EcoRI和SalI酶切位点,经PCR扩增MPAFP5基因成熟肽序列后与pGEX4T-1载体相连,再将MPAFP5从pGEX4T-1载体上切下亚克隆至穿梭质粒pGAPZαA上,获得的重组穿梭质粒pGAPZαA-MPAFP5,经线性化后采用电转化法将重组穿梭质粒转入酵母细胞SMD1168内,Zeocin^ 筛选鉴定重组子,小瓶发酵后取上清作SDS-PAGE检测,并用Western-blot检测表达蛋白的正确性。结果：MPAFP5成功地在酵母表达系统获得表达,Western-blot检测表明表达产物为准噶尔小胸鳖甲抗冻蛋白。结论：酵母表达系统能够高效表达准噶尔小胸鳖甲抗冻蛋白,为高密度发酵大量生产抗冻蛋白奠定了基础。     

准噶尔小胸鳖甲融合抗冻蛋白活性的比较研究

为了比较准噶尔小胸鳖甲Microdera punctipennis dzhungarica原核表达的不同融合抗冻蛋白活性是否存在差异,分别利用重组表达质粒pGEX-4T-1-Mpafp5和pMAL-p2x-Mpafp5在大肠杆菌Escherichia coli BL21(DE3)中诱导表达融合抗冻蛋白GST-MpAFP5和MBP-MpAFP5,并利用亲和层析纯化蛋白。SDS-PAGE分析结果证明获得了两种高效表达纯化的GST-MpAFP5和MBP-MpAFP5融合蛋白。在浓度为0.5 mg/mL时,两种蛋白的热滞值分别为0.51℃和1.336℃,其溶液冰晶形态均为棱型。抗冻保护实验结果显示： 准噶尔小胸鳖甲两种融合抗冻蛋白均能够显著提高细菌在低温下的存活率,并且MBP-MpAFP5对细菌的保护效果显著高于GST-MpAFP5。研究结果对于准噶尔小胸鳖甲抗冻蛋白的应用具有重要的理论意义。     

荒漠甲虫光滑鳖甲和小胸鳖甲抗冻蛋白基因及其3'-UTR的序列分析

拟步甲科昆虫光滑鳖甲Anatolica polita Kaszab和小胸鳖甲Microdera punctipennis Kaszab分别是新疆准噶尔盆地荒漠地区的广布种和特有种。它们的生活习性有很大差异,光滑鳖甲白天活动,且活动范围广,而小胸鳖甲喜阴避光夜晚活动,活动范围小,但在两者体内都发现有多拷贝的抗冻蛋白基因,并且抗冻蛋白基因在夏季也有表达。为了比较这两种昆虫的抗冻蛋白序列以及不同时期表达的抗冻蛋白序列的差异情况,本研究分别以光滑鳖甲和小胸鳖甲的过冬和夏季成虫为材料,根据已克隆的抗冻蛋白基因序列设计通用引物,扩增新的抗冻蛋白基因及其3'-非翻译区(3'-UTR)。序列分析结果表明,无论是冬季还是夏季表达的抗冻蛋白在两种昆虫中都具有拟步甲科昆虫抗冻蛋白的特点,即含有不同数量的"TCTXSXXCXXAX"12个氨基酸的重复序列;光滑鳖甲抗冻蛋白基因的变异性大于小胸鳖甲,并且在重复基序的保守位点都有突变现象。小胸鳖甲抗冻蛋白在C末端有较大变异。光滑鳖甲抗冻蛋白基因的3'-UTR区变异较大,而小胸鳖甲抗冻蛋白基因的3'-UTR区几乎没有变异。推测两种昆虫抗冻蛋白及抗冻蛋白基因3'-UTR的变异性可能与抗冻蛋白的表达调控以及昆虫对微环境的适应性有关。     

新疆准噶尔小胸鳖甲抗冻蛋白基因的克隆和抗冻活性分析

根据GenBank中已发表的昆虫抗冻蛋白基因的保守序列设计引物,利用RT-PCR技术结合3'-RACE扩增的方法,从新疆荒漠昆虫准噶尔小胸鳖甲 Microdera punctipenis dzunarica中获得了长约294 bp不含信号肽的抗冻蛋白cDNA片段,命名为MpAFP5,其全长序列为363 bp(GenBank注册号为：AY821792)。基因测序结果表明, MpAFP5-cDNA片段与加拿大拟步甲Dendroides canadensis AFP 8基因片段、黄粉甲Tenebrio molitor THP 4-9基因片段的核苷酸同源性分别达68.4%和71.8%,氨基酸序列同源性分别达70%和81%。将MpAFP5构建到原核表达载体pGEX4T-1中,重组质粒pGEX4T-1-MpAFP5在大肠杆菌BL21(DE3)中能够表达融合抗冻蛋白,SDS-PAGE分析显示融合蛋白的分子量约为37 kD,Western印迹分析证明MpAFP5在大肠杆菌中正确表达。细菌的抗冻实验结果显示准噶尔小胸鳖甲融合抗冻蛋白对细菌具有显著的抗冻保护作用,保护效果与抗冻蛋白剂量呈正相关性。     

荒漠甲虫小胸鳖甲抗冻蛋白的酵母表达及应用

昆虫抗冻蛋白(Antifreeze protein,AFP)的抗冻活性很高,可应用于生物组织和细胞的低温保存。为了在酵母中表达荒漠甲虫小胸鳖甲Microdera punctipennis抗冻蛋白Mp AFP698,并确定其在低温下的保护作用,本文通过构建真核表达载体p PIC9K-Mpafp698,转化巴斯德毕赤酵母GS115,诱导表达小胸鳖甲抗冻蛋白Mp AFP698。利用免疫印迹(Western blotting)分析Mp AFP698蛋白的特异性表达,结果显示Mpafp698基因可整合到酵母基因组中并分泌表达,且酵母自身蛋白很少分泌表达。检测抗冻蛋白的低温保护作用,结果发现,小胸鳖甲抗冻蛋白可显著改善冷冻小鼠肝脏等器官的细胞形态,降低血细胞在4℃的溶血率,提高SF9细胞冻融后的存活率。本研究表明,小胸鳖甲AFP可以在毕赤酵母中分泌表达,便于纯化,有良好的低温保护效果。     

差示扫描量热法分析光滑鳖甲抗冻蛋白ApAFP914 TXT基序对抗冻活性的影响

研究光滑鳖甲抗冻蛋白Ap AFP914及其突变体的原核表达及活性,推测TXT基序的突变对昆虫抗冻蛋白抗冻活性的影响。通过定点突变新疆荒漠昆虫光滑鳖甲抗冻蛋白apafp914基因TXT基序的规则位点个数,并亚克隆至p ET32a原核表达载体,转化大肠杆菌,Ni-NTA纯化得到融合蛋白Trx A-Ap AFP914及3种突变体蛋白;利用Swis S-Model服务器预测分析了Ap AFP914蛋白的三维结构;通过差示扫描量热法测定Trx A-Ap AFP914及其突变体的热滞活性。结果显示,4种融合蛋白分子量均在30 k D左右;且突变蛋白Trx A-A19T具有最高的热滞活性,而突变体Trx A-T33F和Trx A-T3345F的热滞活性显著低于未突变的Trx A-914。研究结果表明昆虫抗冻蛋白的TXT基序越规则其具有的热滞活性越高。     

准噶尔小胸鳖甲抗冻蛋白MpAFP698在真核细胞中的表达与鉴定

目的:构建真核表达质粒pEGFP-N1-mpafp698,转染人胚肾293T细胞,并表达准噶尔小胸鳖甲抗冻蛋白MpAFP698.方法:PCR扩增出mpafp698序列,将其克隆入本室保存的真核表达载体pEGFP-N1中,转染293T细胞;利用RT-PCR、流式细胞仪、免疫荧光、Western 印迹检测蛋白表达.结果:构...     

农杆菌介导的天绿香遗传转化影响因素的研究

通过农杆菌介导的方法将新疆准噶尔小胸鳖甲抗冻蛋白基因Mpafp149导入天绿香中,对影响农杆菌转化频率的各种因素进行了研究。结果表明农杆菌介导天绿香遗传转化的潮霉素最佳筛选浓度为8 mg·L^-1,预培养时间2 d,共培养时间2 d,菌液浓度OD₆₀₀为0.2～0.25,浸染时间为8 min时适宜天绿香不定芽的诱导,有利于天绿香转基因植株的获得。通过PCR检测,初步证明外源基因Mpafp149已整合到天绿香基因组中。     

昆虫抗冻蛋白: 规则结构适应功能

抗冻蛋白在环境温度低于体液熔点时能够结合到生物体内的冰核表面,通过限制冰核生长和抑制冰晶重结晶而保护有机体免受结冰引起的伤害。与其他生物抗冻蛋白比较,昆虫抗冻蛋白有很强的活性,结构上具有显著特征,如一级结构规律重复,超二级结构为β-螺旋,可与冰晶发生相互作用,具有TXT基序等。该文综述了近年来关于昆虫抗冻蛋白的结构以及分子生物学等方面研究的新进展,讨论了其结构与功能的关系。     

Expression of biologically active recombinant antifreeze protein His-MpAFP149 from the desert beetle (<Emphasis Type="Italic">Microdera punctipennis dzungarica</Emphasis>) in <Emphasis Type="Italic">Escherichia coli</Emphasis>

An insect antifreeze protein gene Mpafp149 was cloned by the RT-PCR approach from the desert beetle Microdera punctipennis dzungarica. Sequence analysis revealed that this gene encoding a protein of 120 amid acids and this protein showed 65–76% homology with other insect antifreeze proteins, the deduced amino acid sequence displays very high similarities in those regions that contain tandem the 12-residue repeats (TCTxSxxCxxAx) domain and the TCT motif. Mpafp149 gene was cloned into pET-28a vector and expressed in Escherichia coli. A single-step purification based on specific binding of histidine residues was achieved. The purified His-MpAFP149 was SDS–PAGE analyzed, showing an atypical migration with molecular weight of about 24 kDa. The expression of His-MpAFP149 was confirmed by Western blot with specific binding to anti-GST-MpAFP149 antibody. The thermal hysteresis activity of the purified recombinant protein was 0.915°C at 0.09 mg/ml, and the supercooling point was −9.6°C at 0.03 mg/ml. In vitro antifreeze activity assay by measuring the survival rate of bacteria at −7 and −20°C respectively, with the protection of His-MpAFP149 showed that the His-MpAFP149 fusion protein was able to enhance the freeze resistance of bacteria.     

荒漠昆虫小胸鳖甲Ras GTP酶激活蛋白基因 MpRasGAP 的克隆及低温表达分析

【目的】丝裂原活化蛋白激酶 (mitogen activated protein kinase, MAPK)级联是细胞的重要信息传递系统之一,Ras GTP酶激活蛋白（Ras GTPase-activating protein, RasGAP）基因 RasGAP 和c-Jun氨基末端激酶（c-Jun N-terminal kinase, JNK）基因 JNK 分别是MAPK信号转导途径的上、下游基因。本研究旨在确定荒漠昆虫小胸鳖甲 Microdera punctipennis RasGAP 及 JNK 基因对低温的响应情况。【方法】从荒漠甲虫小胸鳖甲中克隆获得 RasGAP 基因的cDNA序列,利用生物信息学分析软件分析其氨基酸序列并构建进化树,利用实时荧光定量PCR检测低温胁迫条件下 RasGAP 和 JNK 基因的表达情况。【结果】小胸鳖甲RasGAP cDNA的开放阅读框2 523 bp,命名为 MpRasGAP （GenBank登录号：KM677930）,编码840个氨基酸,分子量96.594 kDa,编码蛋白MpRasGAP属于RasGAP超家族。MpRasGAP与赤拟谷盗 Tribolium castaneum RasGAP的氨基酸序列一致性达89%。小胸鳖甲在4℃和-4℃低温胁迫1 h后,MpRasGAP 的mRNA水平都显著高于室温对照（25℃）。小胸鳖甲在4℃处理3 h或-4℃处理1 h后, MpJNK 的mRNA水平也显著升高。【结论】本研究结果表明小胸鳖甲MpRasGAP 和 MpJNK 的mRNA水平受低温诱导。研究结果有助于深入研究荒漠昆虫在低温下MAPK信号转导途径的作用机制。     

Thermal stability properties of an antifreeze protein from the desert beetle Microdera punctipennis

An insect antifreeze protein gene Mpafp698 was cloned by the RT-PCR approach from the desert beetle Microdera punctipennis. The gene was constructed and heterogeneously expressed in Escherichia coli as fusion proteins, His-MpAFP698, glutathione S-transferase (GST)-MpAFP698, and maltose-binding protein (MBP)-MpAFP698. The thermostability and thermal hysteresis activity of these proteins were determined, with the aim of elucidating the biological characteristics of this protein. The approximate thermal hysteresis (TH) value of the purified His-MpAFP698 was 0.37 °C at 0.84 mg/ml, and maintained approximately 95.7% of the TH activity at 100 °C for 5 min. Furthermore, heat incubation showed that MBP-MpAFP698 was 10 °C more thermostable than MBP protein, indicating that MpAFP698 could, to some extent, improve the thermal stability of the fused partner MBP protein. This study suggests that MpAFP698 has a high thermal stability and could be used to improve the thermal stability of the less stable proteins by producing fusion proteins, which could be used for biotechnological purposes.     

Expression of insect (Microdera puntipennis dzungarica) antifreeze protein MpAFP149 confers the cold tolerance to transgenic tobacco

To elucidate the function of antifreeze protein from Microdera puntipennis dzhungarica for freezing stress tolerance in plant, the construct of MpAFP149 gene with the signal peptide sequence responsible for secreting the native MpAFP149 into the apoplast space under control of a cauliflower mosaic virus 35S promoter was introduced into tobacco by Agrobacterium tumefaciens-mediated transformation. The observation of immunogold localization by TEM (transmission electron microscope) showed that the heterologous MpAFP149 protein was mainly distributed on the cell wall in apoplast of the transgenic tobacco plant. T1 generation transgenic tobacco plants displayed a more frost resistant phenotype and kept the lower ion leakage ratio and MDA (malondialdehyde) content in the leaves compared with wild-type ones at -1 degrees C for 3 days. The results showed that MpAFP149 provided protection and conferred cold tolerance to transgenic tobacco plant during freezing stress.     

A complex family of highly heterogeneous and internally repetitive hyperactive antifreeze proteins from the beetle Tenebrio molitor.

We have previously identified a Thr- and Cys-rich thermal hysteresis (antifreeze) protein (THP) in the beetle Tenebrio molitor that has 10-100 times the freezing point depression activity of fish antifreeze proteins. Because this 8.4 kDa protein is significantly different in its properties from THP preparations previously reported from this insect, a thorough search was undertaken for other antifreeze types. Many active proteins were observed, but all appeared to be isoforms of the THP that differed in their number of 12-amino acid repeats (consensus sequence CTxSxxCxxAxT), amino acid substitutions, and N-linked glycosylation. Mass spectral analysis has matched most of these isoforms with cDNA sequences of 17 different clones from a larval fat body library that encode eight different mature THPs containing 84, 96, or 120 amino acids. Genomic Southern blots suggest there may be 30-50 tightly linked copies of the gene, which is a signature consistently seen with unrelated fish antifreeze protein genes, and one that has been associated with the need to rapidly increase gene product in response to climate change. A three-dimensional model is proposed for the fully disulfide-bonded structure of T. molitor THP, which can accommodate addition or deletion of 12-amino acid repeats. The structure is a beta-helix that places most of the Thr in a regular array on one side of the protein to form a putative ice-binding surface.     

Characterization and cloning of a Tenebrio molitor hemolymph protein with sequence similarity to insect odorant-binding proteins

The yellow mealworm beetle, Tenebrio molitor, produces a number of moderately abundant low molecular weight hemolymph proteins ( approximately 12 kDa) which behave in a similar manner during purification and share antigenic epitopes. The cDNA sequence of the major component (THP12) was determined and the deduced protein sequence was found to be similar to those of insect odorant-binding proteins. Southern blot analysis suggests that at least some of the diversity in this family of proteins is encoded at the gene level. Both northern and western blot analysis indicate that THP12 is present in a variety of developmental stages and both sexes. THP12 was originally classified as an antifreeze protein, but the lack of antifreeze activity in the recombinant protein, as well as the clear separation of the antifreeze activity from THP12 following HPLC purification, has ruled out this function. The abundance of THP12, the similarity of THP12 to insect odorant-binding proteins, and the presence of hydrophobic cavities inside the protein (Rothemund et al., A new class of hexahelical insect proteins revealed as putative carriers of small hydrophobic ligands. Structure, 7 (1999) 1325-1332.) suggest that THP12 may function to carry non-water soluble compounds in the hemolymph. THP12 is also similar, particularly in structurally important regions, to other insect proteins from non-sensory tissues, suggesting the existence of a large family of carrier proteins which may perform diverse functions throughout the insect.