IL-10_(23-57)-PE40可溶表达、纯化及其细胞活性

以IL-10的功能短肽(35肽,即IL10第23至57氨基酸残基)为导向部分与PE40(绿脓杆菌外毒素除去受体结合区后的剩余部分)融合分别置入pet20b(+)和pet28a(+)构建重组毒素IL102357PE40的两种表达质粒,其中置于pet20b(+)的重组毒素在BL21(DE3)pLysS中以周质分泌可溶形式表达,置于pet28a(+)的重组毒素在Rosettablue(DE3)中以高效胞质可溶形式表达;依次通过硫酸铵盐析、疏水层析、阴离子交换层析、铜离子亲和层析纯化周质分泌成份,得90%重组毒素纯品;细胞活性实验表明,该重组毒素只对单核巨噬细胞有杀伤作用;细胞ELISA显示,该重组毒素对单核巨噬细胞的杀伤作用(IC50为13.9pmolL)符合绿脓杆菌外毒素的作用机理.     

IL-1018-57-PE40高效表达、纯化及细胞活性之研究

以IL-10的功能短肽(40肽,即IL-10第18号至57号氨基酸)为导向部分与PE40(绿脓杆菌外毒素除去受体结合区后的剩余部分)融合分别构建了IL-101857PE40的胞质和胞周质表达质粒,其中,IL101857PE40在Rosettablue(DE3)中以高效胞质可溶形式表达,在BL21(DE3)pLysS中以胞周质分泌形式表达;表达宿主菌Rosettablue(DE3)超声波破碎后,依次通过硫酸铵盐析、疏水层析、铜离子亲和层析、阴离子交换层析纯化后,得96%重组毒素纯品;细胞活性实验、细胞ELISA和荧光标记实验表明,构建的IL101857PE40符合免疫毒素的作用机理。因此,该实验为PE免疫毒素的规模制备和纯化做了一定的有益的探索。     

IL-1018-57-PE40高效表达、纯化及细胞活性之研究

以IL-10的功能短肽（40肽,即IL-10第18号至57号氨基酸）为导向部分与PE40（绿脓杆菌外毒素除去受体结合区后的剩余部分）融合分别构建了IL-10_18-57-PE40的胞质和胞周质表达质粒,其中,IL-10_18-57-PE40在Rosettablue(DE3)中以高效胞质可溶形式表达,在BL21（DE3）pLysS中以胞周质分泌形式表达;表达宿主菌Rosettablue(DE3)超声波破碎后,依次通过硫酸铵盐析、疏水层析、铜离子亲和层析、阴离子交换层析纯化后,得96%重组毒素纯品;细胞活性实验、细胞ELISA和荧光标记实验表明,构建的IL-10_18-57-PE40符合免疫毒素的作用机理。因此,该实验为PE免疫毒素的规模制备和纯化做了一定的有益的探索。     

重组毒素rCCK_(96-104)PE38靶向结肠癌生物特性研究

旨在原核表达并纯化新型重组毒素rCCK_(96-104)PE38,验证其对结肠癌细胞的靶向杀伤作用。使用基因扩增技术将反向编译的胆囊收缩素CCK_(96-104)与绿脓杆菌外毒素PE38融合,构建原核表达载体。利用Ni-NTA亲和层析进行纯化。通过结肠癌细胞体外杀伤实验以及结肠癌裸鼠模型的治疗验证rCCK_(96-104)PE38的抗肿瘤能力。结果显示,扩增出的rCCK_(96-104)PE38序列正确,成功利用pET-28a原核表达系统实现了活性表达。纯化后的重组蛋白能够在体外诱导结肠癌细胞凋亡,并能抑制裸鼠模型体内的肿瘤生长。成功制备高纯度、无标签的rCCK_(96-104)PE38重组免疫毒素,体内、体外实验证实其具有抑制结肠癌的能力。     

两种人粒酶B嵌合基因的表达及对肿瘤细胞的杀伤作用

通过重组PCR构建了抗HER2单链抗体基因、绿脓杆菌外毒素 (PE)转位肽序列和活性型粒酶B(GrBa)基因相融合的sFv2 3e PEⅡ GrBa基因 ,以及N端包含PE部分转位肽序列的PEⅡ GrBa基因 .将这 2种粒酶B嵌合蛋白基因瞬时转染或稳定转染HeLa细胞及SKBR 3细胞 .通过间接免疫荧光、细胞计数、MTT、ELISA等方法 ,观察到细胞浆中表达的PEⅡ GrBa蛋白直接杀伤其表达细胞 ;而sFv2 3e PEⅡ GrBa表达后被分泌至细胞外 ,对产生它的细胞没有杀伤性 ,但能够特异识别并杀伤HER2阳性肿瘤细胞 .结果表明 ,抗肿瘤表面抗原的抗体能够介导靶向识别 ,转位结构域可以辅助效应分子活化、转位至细胞液并杀伤细胞 ,为肿瘤的靶向治疗提供了新的策略 .     

IL-1023-57-PE40分泌表达的初步研究

将IL-1023-57-PE40基因与pelB信号肽融合置于pET-20b构建分泌表达质粒pET-20b-IL-1023-57-PE40,然后将pET-20b-IL-1023-57-PE40分别转化至BL21(DE3),BL21(DE3)pLysS,Rosetta(DE3),E·coliK12TB1,ER2566中。无论是在37℃或是在26℃,亦或在培养基中添加葡萄糖的情况下,IPTG诱导后,IL-1023-57-PE40蛋白只在BL21(DE3)pLysS菌中以可溶分泌形式表达,其中以37℃时培养基中不添加葡萄糖表达量为最高,占菌体蛋白总量的15%,说明蛋白的分泌表达与菌种的选择有关。表达产物经免疫印记检测可被抗PE40的特异抗体识别。通过质粒稳定性实验证明,pET-20b-IL-1023-57-PE40在BL21(DE3)中不稳定,导致蛋白的不表达,在Rosetta(DE3)BL21,E·coliK12TB1,ER2566中稳定但不表达,因此,以Rosetta(DE3)BL21为例,通过SDS-PAGE、DNAStar和ANThewin蛋白分析软件对本室构建的几种PE重组毒素进行比较分析,我们发现:并不是所有PE重组毒素融合信号肽序列后,就能分泌表达,PE重组毒素分泌表达还可能与导向部分的性质有关。     

TGFα-PE 40的基因克隆、表达和对人癌细胞生长的抑制作用

本文报告了构建人转化生长因子α和绿脓杆菌外毒素融合基因的表达型重组质粒pYX382和pYX 3825,两种质粒转化大肠杆菌BL21后,经IPTG 诱导,表达融合蛋白TGFα-PE 40,表达产物分子量为46 kd,具有和抗TGF a抗体和抗PE 抗体反应的能力,重组质粒pYX 3825带有信号肽顺序,因而在细菌中表达产物大部分被分泌到培基和周质中。TGFa-PE 40具有和细胞表面EGFR 结合的能力,因而,能与过度表达EGFR 的癌细胞结合,将毒素蛋白的活性部分带入细胞而显示对癌细胞蛋白质合成的强烈抑制和对癌细胞的杀伤。     

N端融合不同长度转位肽的重组粒酶B抑制细胞生长作用的比较

采用重组PCR法将粒酶B基因的N端信号肽和酸性二肽编码序列去除,与两种不同长度的绿脓杆菌外毒素（PE）转位肽序列分别连接,将它们插入pIND诱导表达载体,通过脂质体法与pVgRXR辅助质粒共转染HeLa细胞,建立了重组PE II-GrBa基因的诱导表达细胞系。松甾酮A诱导后Western印迹检测到目的基因的表达,间接免疫荧光观察到表达细胞出现多核巨细胞的异常形态。两种表达的PE II-GrBa融合蛋白均能够切割粒酶B的细胞内源性和外源性底物,并且使细胞生长速度减慢。其中,PE II-(aa 280358)-GrBa的底物切割能力和生长抑制作用较强。流式细胞仪分析这种抑制作用可能与细胞周期的G2期受到阻遏有关。上述结果证实了PE II-GrBa融合蛋白仍然具有抑制细胞生长的作用,并且较短的转位肽对GrBa活性的影响较小,有助于进一步优化转位肽/细胞毒性效应蛋白重组分子的结构用于肿瘤细胞杀伤。     

白细胞介素2-绿脓杆菌外毒素融合基因的克隆及高效表达

利用聚合酶链式反应和寡核苷酸介导的定向诱变技术构建了白细胞介素2-绿脓杆菌外毒素IL2-PE40、IL2-PE40KDEL、IL2-PE66~(4Glu)和IL2-PE66~(4Glu)KDEL融合基因的原核表达重组质粒,并实现了高效表达,表达产物占菌体总可溶蛋白的20％～30％。此外,由于这一表达质粒在IL-2cDNA与PE基因连接处引入了唯一的SmaⅠ位点,其5＇、3＇端分别含有唯一的EcoRⅠ、PstⅠ位点,因此可方便地用其它基因替换IL-2或PE基因而获得相应融合蛋白的表达质粒。     

嵌合重组caspase-3诱导表达促进肿瘤细胞凋亡

通过稳定转染人宫颈癌HeLa细胞,建立了野生型caspase-3（wt-casp3）,大小亚基序列颠倒的重组caspase-3 (r-casp3),和N端融合绿脓杆菌外毒素（PE）转膜肽段的嵌合重组caspase-3 (cr-casp3)的诱导表达细胞系.蜕皮素诱导后细胞中检测到目的基因的表达,MTT检测和细胞计数结果表明,r-casp3和cr-casp3诱导表达后有效地导致HeLa细胞死亡,通过测定细胞中caspase-3活性,以及细胞周期检测、DNA梯状电泳条带检测(DNA ladder)、电镜观察等证实r-casp3和cr-casp3诱导表达后细胞发生了凋亡,且二者的促凋亡活性相当,而wt-casp3诱导表达细胞并未出现上述效应.结果表明,与野生型caspase-3活化需要上游分子的切割不同,重组caspase-3具有自发的促凋亡活性,而N端PE肽段的融合不影响这种活性,因此PE转膜结构域和重组caspase-3有望参与构建能转膜进入细胞内部,并杀伤细胞的新型肿瘤治疗分子.     

Selective immunosuppression of activated T cells with the chimeric toxin IL-2-PE40. Inhibition of experimental autoimmune uveoretinitis

A characteristic of activated T lymphocytes is the expression of high affinity IL-2R. We studied a new method of selective immunosuppression directed against activated T cells by using a chimeric recombinant protein (IL-2-PE40) composed of IL-2 fused to a modified Pseudomonas exotoxin lacking its cell recognition domain. As a model of T cell-mediated disease, we used experimental autoimmune uveoretinitis (EAU) produced in Lewis rats by active immunization with the retinal S-Ag. The treatment protocol consisted of i.p. injection of IL-2-PE40 at 0.25 micrograms/g every 12 h. Controls were PBS, PE40, or IL-2-PE40asp553 a mutant form of the molecule with reduced activity. Treatment with IL-2-PE40 resulted in a significant reduction of the incidence and severity of EAU over controls. The analysis of the effect of i.p. injection of IL-2-PE40 on the popliteal draining lymph nodes of immunized animals showed a marked reduction in the lymphocytes content. Transfer experiments demonstrated that IL-2-PE40 prevented the development of EAU effector T cells. Interestingly, although activated B cells were reported to express IL-2R, there was no significant reduction of antibody production against the immunizing Ag under IL-2-PE40 treatment, suggesting sparing of the B cells.     

IL-2-PE40 prevents the development of tumors in mice injected with IL-2 receptor expressing EL4 transfectant tumor cells

A number of different immunotherapeutic reagents are currently being developed to target IL-2R for the treatment of leukemia, graft rejection, and certain autoimmune diseases. Previously, we have shown that IL-2-PE40, a chimeric protein composed of human IL-2 linked to the N-terminus of a truncated form of Pseudomonas exotoxin (PE), could effectively kill a variety of cell lines in vitro expressing either low, intermediate, or high affinity IL-2R. Here, we demonstrate that IL-2-PE40 can successfully retard or prevent the growth of a lethal ascites tumor or a solid tumor composed of EL4J murine thymoma cells transfected with the p55 murine IL-2R. The transfected line, EL4J-3.4, expresses 1,000 to 3,000 high affinity IL-2R. Survival extension in the ascites model was achieved by initiating treatment either after 4 to 6 h or within 5 days post-tumor injection in both athymic nude and C57BL/6 mice. Similarly, the growth of an aggressive s.c. solid tumor could also be inhibited. Extension of survival was not achieved either by using the truncated toxin alone not attached to IL-2 or by using an IL-2-PE40Asp553 mutant lacking a functional toxin. Survival extension was not caused by IL-2 activated NK or other host effector mechanisms as IL-2-PE40 was unable to prevent the receptor-negative EL4J parental line from forming a lethal ascites or a solid tumor. Thus, IL-2-PE40 is a potent, specific cytolytic reagent that may prove useful in the arsenal of anti-IL-2R immunotherapeutics.     

IL-2-PE40 is cytotoxic for activated T lymphocytes expressing IL-2 receptors

IL-2-PE40 is a chimeric molecule in which IL-2 is attached to the amino end of modified Pseudomonas exotoxin molecule lacking cell recognition domain. This molecule was extremely toxic for Con A-stimulated spleen cells from mice. Moreover, IL-2-PE40 has suppressive effect against Ag-activated cells; it inhibits the generation of cytotoxic T lymphocyte activity in a MLC. IL-2-PE40 could be a useful agent in IL-2R targeting therapy including immunosuppressive therapy for allograft rejection or some autoimmune diseases.     

A divalent recombinant immunotoxin formed by a disulfide bond between the extension peptide chains.

Recombinant immunotoxin for the treatment of cancer was made by connecting toxins to 'carcinoma-specific' antibodies that selectively bind to cancer cells, then kills them without harming the normal cells. The divalent recombinant immunotoxin, [B3(Fab)-ext-PE38]2, is a derivative of B3(Fab)-PE38. B3(Fab)-PE38 was made by fusing the Fab domain of the monoclonal antibody (MAb) B3 to PE38, a truncated mutant form of Pseudomonas exotoxin (PE). In this study, B3(Fab)-ext-PE38 was constructed, which has the hinge region of the B3(Fab)-PE38 extended with the peptide extension, G4C(G4S)2, and connected to the C3 connector. The Cys residue of the extension peptide chain makes the disulfide bond between the two Fab domains. The extension sequence (ext) makes the dimerization of B3(Fab)-ext-PE38 easier to form the divalent immunotoxin, because it decreases the steric hindrance between the two PE38s. The constructed genes were expressed in E. coli as inclusion bodies. Polypeptides that were obtained from the inclusion body were refolded, and the active forms were purified. The ID50 values of the divalent molecule, [B3(Fab)-ext-PE38]2, were about 4 ng/ml on A431 cell lines, about 1 ng/ml on CRL1739 cell lines, and 5 ng/ml on MCF-7 cell lines. The [B3(Fab)-ext-PE38]2 showed about a 12-fold higher cytotoxicity on CRL1739 cell lines than B3(scFv)-PE40 did.     

A method for increasing the yield of properly folded recombinant fusion proteins: single-chain immunotoxins from renaturation of bacterial inclusion bodies.

Many proteins produced in Escherichia coli accumulate in inclusion bodies. We have systematically evaluated the parameters that affect the refolding and renaturation of enzymatically active molecules from bacterial inclusion bodies containing a recombinant single-chain immunotoxin, B3(Fv)-PE38KDEL. This recombinant molecule is composed of the variable domains of monoclonal antibody B3 (B3(Fv)) fused to a truncated mutant form of Pseudomonas exotoxin A (PE38KDEL). This immunotoxin kills carcinoma cells in vitro, causes tumor regression in animal tumor models, and is being developed as an anti-cancer therapeutic agent (Brinkmann et al., 1991, Proc. Natl. Acad. Sci. USA 88, 8616-8620). Like many other recombinant proteins, B3(Fv)-PE38KDEL is produced in E. coli in inclusion bodies and must be denatured and refolded to become active. This requires correct folding, formation of native disulfide bonds, and the association of different domains. All these steps are strongly dependent on the renaturation conditions used. Optimum conditions of refolding were obtained by the addition of reduced and oxidized thiol reagents to promote disulfide bond formation and the addition of a labilizing agent such as L-arginine. Furthermore, the necessity to reactivate proteins at low protein concentrations due to its tendency to aggregate at high concentrations was overcome by a step-by-step addition of denatured and reduced protein into the refolding solution. This approach should be useful for the production of active forms of other recombinant proteins.     

In vitro and in vivo suppression of interleukin-2-activated killer cell activity by chimeric proteins between interleukin-2 and Pseudomonas exotoxin.

The biological effects of IL-2 are mediated through high (complex of alpha and beta chain) or intermediate (beta chain) affinity IL-2 receptors. Previously, chimeric proteins composed of IL-2 and Pseudomonas exotoxin (IL-2-PE) were shown to be specifically cytotoxic to cells bearing IL-2 receptors. It has also been shown that IL-2-PE chimeric proteins can abrogate T cell-mediated immune response in vitro. In the current study, we have investigated the effects of IL-2-PE on LAK activity both in vivo and in vitro. We administered either IL-2-PE40 (comprised of IL-2 and 40-kDa portion of PE) or IL-2-PE66 (comprised of IL-2 and 66-kDa molecule of PE) to normal C57BL/6 mice for 3 or 8 days and LAK activity was assessed in various organs of mice. We found that IL-2-PE40 generated LAK activity in various compartments of mice and the level of activity was slightly lower than that observed with an equivalent amount of recombinant (r) IL-2 alone. However, IL-2-PE66 failed to generate LAK activity which would have been induced due to an equivalent concentration of rIL-2. IL-2-PE66 also did not induce LAK activity from the splenocytes during in vitro culture while IL-2-PE40 generated good LAK activity. An equivalent amount of IL-2 also generated potent LAK activity. The suppression of LAK activity by IL-2-PE66 was also evident in cells preactivated with IL-2; however, this inhibition was partial. The suppressive activity of IL-2-PE66 was shown to be mediated through IL-2 receptor interactions as excess amounts of rIL-2 were able to abrogate its effect. Both IL-2 toxins were equivalently cytotoxic to IL-2 receptor-bearing HUT 102 cells and both were able to compete from high and intermediate affinity IL-2 receptors. Taken together, our data indicate that IL-2-PE66 is highly cytotoxic to LAK cells while IL-2-PE40 is less cytotoxic. Thus, data from our study and from other published reports indicate that IL-2-PE66 is more potent immunosuppressive agent than IL-2-PE40.     

A novel strategy for the negative selection in mouse embryonic stem cells operated with immunotoxin-mediated cell targeting.

Immunotoxoin-mediated cell targeting (IMCT) is a technique for conditionally ablating specific cell types based on the cytotoxic activity of a recombinant immunotoxin anti-Tac (Fv)-PE40. To examine the feasibility of this technique for the negative selection in mouse embryonic stem (ES) cells, we investigated the responsiveness of cells expressing human interleukin-2 receptor alpha subunit to anti-Tac(Fv)-PE40. The immunotoxin treatment efficiently eliminated only ES cells bearing the receptor as a consequence of the target specificity of anti-Tac(Fv)-PE40, indicating that IMCT can be used as a novel strategy for positive and negative selection to enrich ES cell clones with a targeted mutation.