结核分枝杆菌热休克蛋白Hsp16.3及其合成肽在小鼠体内诱导的免疫应答

目的比较结核分枝杆菌Hsp16.3和Hsp16.3合成肽在小鼠体内诱导的免疫应答及保护力。方法80只BALB/c小鼠随机分5组共免疫3次,间隔2周。分别于0、2、4、6、8周采集血液,ELISA法检测在抗原Hsp16.3和Hsp16.3合成肽包被时血清中的抗体浓度及第8周时血清中的抗体滴度。末次免疫完成后4周,取每组8只免疫小鼠分离脾淋巴细胞,用Hsp16.3和Hsp16.3合成肽分别刺激后,MTT法测定脾淋巴细胞的增殖指数,     

结核杆菌小分子热休克蛋白Hsp16.3的高效自发再折叠和再组装

来自结核杆菌的小分子热休克蛋白Hsp16.3以九聚体的形式存在.用三种不同的强变性条件（100℃加热15 min,12 mol/L脲或8 mol/L盐酸胍处理4 h）将Hsp16.3变性, 然后通过冷却或透析使之复性,并利用孔径梯度聚丙烯酰胺凝胶电泳和圆二色性光谱比较了变性-复性前后Hsp16.3的各个层次高级结构.结果显示,变性的Hsp16.3几乎可以完全恢复至天然构象,这表明小分子热休克蛋白Hsp16.3具有很强的自发折叠和组装能力.     

结核杆菌小分子热休克蛋白Hsp16.3的高效自发再折叠和再组装

来自结核杆菌的小分子热休克蛋白Hsp16.3以九聚体的形式存在.用三种不同的强变性条件(100℃加热15 min,12 mol/L脲或8 mol/L盐酸胍处理4 h)将Hsp16.3变性, 然后通过冷却或透析使之复性,并利用孔径梯度聚丙烯酰胺凝胶电泳和圆二色性光谱比较了变性-复性前后Hsp16.3的各个层次高级结构.结果显示,变性的Hsp16.3几乎可以完全恢复至天然构象,这表明小分子热休克蛋白Hsp16.3具有很强的自发折叠和组装能力.     

结核分枝杆菌分泌蛋白Ag85B、Hsp16.3和ESAT6在血清学检测中的初步应用

目的：探讨结核分枝杆菌分泌蛋白Hsp16.3、Ag85B以及融合蛋白ESAT6-CFP10、Ag85B-Hsp16.3和Ag85B-ESAT6用于TB病人血清学检测的意义。方法：将已构建的含5种目的基因的表达载体（pProEXHTb-Hsp16.3、pProEXHTa-Ag85B、pProEXHTb-ESAT6-CFP10、pProEXHTa-Ag85B-Hsp16.3、pProEXHTa-Ag85B-ESAT6）,分别转入宿主菌E.coli DH5α中,诱导表达后分别获得Hsp16.3、Ag85B、ESAT6-CFP10、Ag85B-Hsp16.3和Ag85B-ESAT6五种蛋白,采用Ni2＋亲和层析柱进行纯化,并用透析方法进行目的蛋白的复性。将经过复性的5种蛋白分别作为抗原,采用间接ELISA方法检测待测的血清样本,经OPD显色,测定各孔OD490值并判定结果。结果：五种蛋白被成功纯化并复性,通过ELISA方法共检测了22例TB病人血清、10例非结核病人血清和6例正常对照血清,Hsp16.3、Ag85B、ESAT6-CFP10、Ag85B-Hsp16.3和Ag85B-ESAT6这5种抗原的灵敏度分别为36.4%、90.9%、77.3%、95.5%、100%,特异性分别为100%、75%、100%、93.8%、93.8%。统计分析显示,ESAT6-CFP10和Ag85B、Ag85B-Hsp16.3、Ag85B-ESAT6这三种蛋白ELISA检测的结果无差异,而与Hsp16.3和痰涂片检测结果有显著差异。结论：Ag85B-Hsp16.3和Ag85B-ESAT6可作为结核分枝杆菌ELISA检测的初选抗原。     

结核分枝杆菌分泌蛋白Ag85B、Hsp16.3和ESAT6在血清学检测中 的初步应用

目的:探讨结核分枝杆菌分泌蛋白Hsp16.3、Ag85B以及融合蛋白ESAT6-CFP10、Ag85B-Hsp16.3和Ag85B-ESAT6用于TB病人血清学检测的意义。方法:将已构建的含5种目的基因的表达载体(pProEXHTb-Hsp16.3、pProEXHTa-Ag85B、pProEXHTb-ESAT6-CFP10、pProEXHTa-Ag85B-Hsp16.3、pProEXHTa-Ag85B-ESAT6),分别转入宿主菌E.coli DH5α中,诱导表达后分别获得Hsp16.3、Ag85B、ESAT6-CFP10、Ag85B-Hsp16.3和Ag85B-ESAT6五种蛋白,采用Ni2+亲和层析柱进行纯化,并用透析方法进行目的蛋白的复性。将经过复性的5种蛋白分别作为抗原,采用间接ELISA方法检测待测的血清样本,经OPD显色,测定各孔OD490值并判定结果。结果:五种蛋白被成功纯化并复性,通过ELISA方法共检测了22例TB病人血清、10例非结核病人血清和6例正常对照血清,Hsp16.3、Ag85B、ESAT6-CFP10、Ag85B-Hsp16.3和Ag85B-ESAT6这5种抗原的灵敏度分别为36.4%、90.9%、77.3%、95.5%、100%,特异性分别为100%、75%、100%、93.8%、93.8%。统计分析显示,ESAT6-CFP10和Ag85B、Ag85B-Hsp16.3、Ag85B-ESAT6这三种蛋白ELISA检测的结果无差异,而与Hsp16.3和痰涂片检测结果有显著差异。结论:Ag85B-Hsp16.3和Ag85B-ESAT6可作为结核分枝杆菌ELISA检测的初选抗原。     

结核分枝杆菌融合蛋白Ag85B-Hsp16.3、Ag85B-ESAT6 和分泌蛋白 Hsp16.3 体外对人肝癌细胞HepG-2 的作用*

目的:探讨结核分枝杆菌融合蛋白Ag85B-Hsp16.3、Ag85B-ESAT6及分泌蛋白Hsp16.3对人肝癌细胞HepG-2的作用。方法:将已构建的含3种目的基因的表达载体pProEXHTa-Ag85B-Hsp16.3、pProEXHTa-Ag85B-ESAT6和pProEXHTb-Hsp16.3,分别转入宿主菌E.coliDH5α中,诱导表达后分别获得Ag85B-Hsp16.3、Ag85B-ESAT6和Hsp16.3三种蛋白,采用Ni2+亲和层析柱进行纯化,并用透析方法进行目的蛋白的复性。复性的蛋白按照不同浓度和作用时间分别与肝癌细胞HepG-2反应,用MTT法检测细胞生长情况。结果:三种蛋白被成功纯化并复性。MTT数据统计分析显示,终浓度10μg/ml的三种蛋白对HepG-2细胞生长没有明显作用,当三种蛋白的终浓度分别为20、40、80μg/ml时均能够抑制HepG-2细胞的生长,并且抑制作用随着蛋白终浓度的增大以及作用时间的延长而增强。不同类别的蛋白抑制作用没有明显差别。结论:结核分枝杆菌的部分分泌蛋白能够抑制肝癌细胞HepG-2的生长。     

果蝇Hsp83多克隆抗体的制备及鉴定

目的制备和鉴定抗Hsp83蛋白的多克隆抗体。方法利用PCR技术从果蝇cDNA中获得hsp83基因片段,构建重组质粒;将其转化到BL21(DE3)菌株中诱导蛋白表达,利用Ni-NTA亲和法纯化重组蛋白;再将纯化的蛋白免疫BALB/C小鼠制备多克隆抗体;利用免疫印迹法(Western blot)和免疫荧光染色法检测多克隆抗体的特异性。结果构建的pET28ahsp83质粒在大肠杆菌中成功表达了Hsp83融合蛋白,蛋白纯化后作为抗原免疫小鼠,获得了抗Hsp83的多克隆抗体。免疫印迹法和免疫荧光染色法检测显示,抗果蝇Hsp83多克隆抗体具有较高的特异性,并能检测出内源性Hsp83蛋白。果蝇卵巢免疫荧光染色显示,Hsp83蛋白定位在卵巢细胞的细胞质中。结论成功制备了小鼠抗Hsp83蛋白的特异性抗体,此工作为深入研究Hsp83蛋白的功能奠定了基础。     

Leu122对Hsp16.3组装过程中亚基相互作用的影响

小分子热休克蛋白是种类最多的热休克蛋白家族 ,它们均以寡聚体的形式存在 .研究表明 ,来自结核杆菌的小分子热休克蛋白Hsp16 3是以 3个三聚体的形式存在的九聚体 .为了探讨Hsp16 3体外组装过程中的亚基相互作用和识别 ,利用野生型Hsp16 3及其L12 2A突变体蛋白为模型 ,采用高效液相分子筛层析、非变性聚丙烯酰胺凝胶电泳和脲梯度凝胶电泳等方法进行研究 .结果表明 ,Hsp16 3在体外能自发地再组装成九聚体 .12 2位的亮氨酸残基对Hsp16 3体外再组装过程中的亚基相互作用有重要的影响 ,并且在Hsp16 3的组装过程中 ,亚基之间的相互识别是高度灵敏和特异的 ,野生型蛋白的亚基和L12 2A突变体蛋白的亚基并不能形成杂合体 ,只有完全相同的亚基才能组装成九聚体     

棉铃虫Hsp70的多克隆抗体制备及鉴定

HSPs(热休克蛋白)是机体在不利环境条件刺激下合成的一类蛋白质,在进化上高度保守,普遍存在于生物体,其中Hsp70是最为保守的成员。研究发现,昆虫滞育过程中普遍存在Hsp70表达上调的现象。然而,现有的研究均是在基因水平的检测结果。为了能从蛋白水平检测棉铃虫中Hsp70的表达,本研究制备了棉铃虫Hsp70的多克隆抗体。构建了hsp70的原核表达载体并在大肠杆菌BL21(DE3)中成功表达,重组蛋白经镍柱纯化后免疫兔子,制备了棉铃虫Hsp70的多克隆抗体。抗体的效价较高,达到了1∶256 000,此外Western结果表明,制备的抗体能检测出热诱导的Hsp70蛋白。本研究制备了高效价且较为特异的Hsp70对克隆抗体,该抗体为后续从蛋白水平研究棉铃虫滞育过程中Hsp70的表达及其分子机制奠定了基础。     

Hsp70-NP融合蛋白增强诱导HTNV NP特异性CTL的实验研究

本文采用纯化蛋白Hsp70-NP,NP,Hsp70分别免疫C57/BL6小鼠,取各组小鼠脾淋巴细胞进行淋巴细胞增殖试验和细胞毒试验.此外,为了获得细胞毒实验的靶细胞,本文还采用脂质体介导质粒pcDNA3.1/S转染黑色素瘤细胞B16,通过G418筛选稳定克隆,并用RT-PCR,Western blots以及免疫荧光染色证实N蛋白在胞浆中表达.淋巴细胞增殖实验表明,Hsp70-NP,NP组小鼠脾淋巴细胞均能够对体外抗原刺激产生增殖反应,而Hsp70-NP组的增殖指数明显高于NP免疫组.细胞毒实验结果表明,LDH的释放具有效应细胞依赖性,Hsp70-NP,NP免疫组脾淋巴细胞均可以特异性杀伤靶细胞B16-N,而Hsp70-NP免疫组的杀伤率显著高于NP免疫组.实验结果显示,Hsp70可以增强NP诱导产生特异性CTL的能力.本研究结果为进一步设计基于NP的合成肽疫苗或基因疫苗提供了重要实验依据.     

Inter-subunit Cross-linking Suppressed the Dynamic Oligomeric Dissociation of Mycobacterium tuberculosis Hsp16.3 and Reduced Its Chaperone Activity

Small heat shock proteins (sHsps) usually exist as dynamic oligomers and oligomeric dissociation was believed to be a prerequisite for their chaperone activities. The truth of this hypothesis was verified in our present study on Hsp16.3, one member of sHsps from Mycobacterium tuberculosis, mainly by utilizing chemical cross-linking. Analysis using size exclusion chromatography demonstrated that the heat-induced oligomeric dissociation of Hsp16.3 was severely blocked due to highly efficient inter-subunit cross-linkages generated by chemical cross-linking, as well as its chaperone activity being reduced. Further analysis by non-denaturing pore gradient polyacrylamide gel electrophoresis and fluorescence spectrometry revealed that the dynamic oligomeric dissociation/reassociation process of Hsp16.3 at room temperature was suppressed by inter-subunit cross-linkages, accompanied by significantly decreased exposure of hydrophobic surfaces that are usually hidden in oligomers. These findings supported the hypothesis that substrate-binding sites of sHsps are exposed presumably by dissociation of larger oligomers into smaller active oligomers, and therefore such a dissociation process could be adjusted to modulate chaperone activities.     

Monodisperse Hsp16.3 nonamer exhibits dynamic dissociation and reassociation,with the nonamer dissociation prerequisite for chaperone-like activity

Small heat-shock proteins (sHsps) of various origins exist commonly as oligomers and exhibit chaperone-like activities in vitro. Hsp16.3, the sHsp from Mycobacterium tuberculosis, was previously shown to exist as a monodisperse nonamer in solution when analyzed by size-exclusion chromatography and electron cryomicroscropy. This study represents part of our effort to understand the chaperone mechanism of Hsp16.3, focusing on the role of the oligomeric status of the protein. Here, we present evidence to show that the Hsp16.3 nonamer dissociates at elevated temperatures, accompanied by a greatly enhanced chaperone-like activity. Moreover, the chaperone-like activity was increased dramatically when the nonameric structure of Hsp16.3 was disturbed by chemical cross-linking, which impeded the correct reassociation of Hsp16.3 nonamer. These suggest that the dissociation of the nonameric structure is a prerequisite for Hsp16.3 to bind to denaturing substrate proteins. On the other hand, our data obtained by using radiolabeled and non-radiolabeled proteins clearly demonstrated that subunit exchange occurs readily between the Hsp16.3 oligomers, even at a temperature as low as 4 degrees C. In light of all these observations, we propose that Hsp16.3, although it appears to be homogeneous when examined at room temperature, actually undertakes rapid dynamic dissociation/reassociation, with the equilibrium, and thus the chaperone-like activities, regulated mainly by the environmental temperature.     

Temperature-dependent subunit exchange and chaperone-like activities of Hsp16.3, a small heat shock protein from Mycobacterium tuberculosis

Small heat shock proteins (sHsps) usually exist as oligomers that undergo dynamic oligomeric dissociation/re-association, with the dissociated oligomers as active forms to bind substrate proteins under heat shock conditions. In this study, however, we found that Hsp16.3, one sHsp from Mycobacterium tuberculosis, is able to sensitively modulate its chaperone-like activity in a range of physiological temperatures (from 25 to 37.5 degrees C) while its native oligomeric size is still maintained. Further analysis demonstrated that Hsp16.3 exposes higher hydrophobic surfaces upon temperatures increasing and that a large soluble complex between Hsp16.3 and substrate is formed only in the condition of heating temperature up to 35 and 37.5 degrees C. Structural analysis by fluorescence anisotropy showed that Hsp16.3 nonameric structure becomes more dynamic and variable at elevated temperatures. Moreover, subunit exchange between Hsp16.3 oligomers was found to occur faster upon temperatures increasing as revealed by fluorescence energy resonance transfer. These observations indicate that Hsp16.3 is able to modulate its chaperone activity by adjusting the dynamics of oligomeric dissociation/re-association process while maintaining its static oligomeric size unchangeable. A kinetic model is therefore proposed to explain the mechanism of sHsps-binding substrate proteins through oligomeric dissociation. The present study also implied that Hsp16.3 is at least capable of binding non-native proteins in vivo while expressing in the host organism that survives at 37 degrees C.     

The Mycobacterium tuberculosis small heat shock protein Hsp16.3 exposes hydrophobic surfaces at mild conditions: conformational flexibility and molecular chaperone activity

Hsp16.3, the alpha-crystallin-related small heat shock protein of Mycobacterium tuberculosis that is maximally expressed during the stationary phase and is a major membrane protein, has been reported to form specific trimer-of-trimers structure and to act as an effective molecular chaperone (Chang Z et al., 1996, J. Biol Chem 271:7218-7223). However, little is known about its action mechanism. In this study, Hsp16.3 conformational intermediates with dramatically increased chaperone activities were detected after treatment with very low concentrations of guanidine hydrochloride (0.05 M), urea (0.3 M), or mild heating (30 degrees C). The intermediates showed a significant increase in their capacity to bind the hydrophobic probe 1-anilino-8-naphthalene sulfonate (ANS), indicating an increased exposure of hydrophobic surfaces. Interestingly, the greatest chaperone activities of Hsp16.3 were observed in the presence of 0.3 M guanidine HCl or when heated to 35 degrees C. CD spectroscopy studies revealed no significant changes in protein secondary and tertiary structures at these mild treatments. Our in vitro studies also indicate that long-time-heated Hsp16.3, heated even to temperatures as high as 85 degrees C, has almost the same, if not a slightly greater, chaperone activities as the native protein when cooled to room temperature and its secondary structures also almost recovered. Together, these results suggest that Hsp16.3 modulates its chaperone activity by exposing hydrophobic surfaces and that the protein structure is highly stable and flexible, thus highly adapted for its function.     

The association of small heat shock protein Hsp16.3 with the plasma membrane of Mycobacterium tuberculosis: dissociation of oligomers is a prerequisite

Hsp16.3, a small heat shock protein from Mycobacterium tuberculosis (MTB), was originally identified as an immuno-dominant antigen and later found to be a major membrane protein. In vitro studies show that Hsp16.3 exists as nonamers and undergoes dynamic dissociation/re-association equilibrium in solutions. Nevertheless, neither the details nor the physiological implications of the presence of Hsp16.3 in the plasma membrane have been studied. In this study, we demonstrated that the purified Hsp16.3 proteins were able to interact with the MTB plasma membrane in a specific and reversible manner, suggesting that there might be subunit exchange between membrane-bound Hsp16.3 and soluble Hsp16.3 oligomers. The dissociation of Hsp16.3 oligomers appears to be a prerequisite for its membrane binding, which is interesting in view that the dissociation of small heat shock protein oligomers was also found to be necessary for it to bind denaturing substrate proteins. Furthermore, the oligomeric structure of Hsp16.3 seems to be more dynamic and flexible when incubating with the mycobacterium lipids. The physiological implications of these observations for Hsp16.3, and small heat shock proteins in general, are discussed.     

Chaperone-Like Activity of <Emphasis Type="Italic">Mycobacterium tuberculosis</Emphasis> Hsp16.3 Does Not Require Its Intact (Native) Structures

Small heat shock proteins (sHsps) were found to exhibit efficient chaperone-like activities under stress conditions although their native structures are severely disturbed. Here, using an alternative approach (site-directed mutagenesis), we obtained two structurally and functionally distinct Mycobacterium tuberculosis Hsp16.3 single-site mutant proteins. The G59W mutant protein (with Gly59 substituted by Trp) is capable of exhibiting efficient chaperone-like activity even under non-stress conditions although its secondary, tertiary, and quaternary structures are very different from that of the wild type protein. By contrast, the G59A mutant protein (with Gly59 substituted by Ala) resembles with the wild type protein in structure and function. These observations suggest that the Gly59 of the Hsp16.3 protein is critical for its folding and assembly. In particular, we propose that the exhibition of chaperone-like activity for Hsp16.3 does not require its intact (native) structures but requires the disturbance of its native structures (i.e., the native structure-disturbed Hsp16.3 retains its chaperone-like activity or even becomes more active). In addition, the behavior of such an active mutant protein (G59W) also strongly supports our previous suggestion that Hsp16.3 exhibits chaperone-like activity via oligomeric dissociation.     

Electrostatic interactions play a critical role in Mycobacterium tuberculosis Hsp16.3 binding of substrate proteins

Mycobacterium tuberculosis Hsp16.3, a member of a small heat shock protein family, has chaperone-like activity in vitro and suppresses thermally or chemically induced aggregation of proteins. The nature of the interactions between Hsp16.3 and the denatured substrate proteins was investigated. A dramatic enhancement of chaperone-like activity of Hsp16.3 upon increasing temperature was accompanied by decreased ANS-detectable surface hydrophobicity. Hsp16.3 exhibited significantly enhanced chaperone-like activity after preincubation at 100°C with almost unchanged surface hydrophobicity. The interaction between Hsp16.3 and dithiothreitol-treated insulin B chains was markedly weakened in the presence of NaCl but greatly enhanced by the addition of a low-polarity alcohol, accompanied by significantly increased and decreased surface hydrophobicity, respectively. A working model for Hsp16.3 binding to its substrate proteins is proposed.