基于核糖体展示技术进行抗狂犬病毒人源抗体的制备

构建了核糖体展示人源抗狂犬病毒单链抗体(scFv)库,筛选制备特异抗狂犬病毒糖蛋白(RVGp)的稳定性人源抗体.应用核糖体抗体库技术,从经狂犬病毒Vero疫苗免疫的志愿者外周血淋巴细胞中分离、构建核糖体展示scFv基因库.体外转录翻译后,以RVGp重组蛋白作筛选抗原,采用亲和富集法淘选RVGp特异性scFv抗体基因.在原核系统pET22b(+)/BL21(DE3)中实现scFv抗体片段的可溶性表达,ELISA鉴定阳性克隆.然后对筛选的scFv进行稳定性改构,构建VH-Lc-VK稳定性抗体,并对其生物学活性进行初步研究.成功构建了库容量约为6.2×1012的核糖体展示scFv抗体基因库.在180个筛选克隆中,克隆RB24、RB71、RB109和RB156显示出较高的ELISA值,其基因序列分析结果显示,它们是全新的人源抗RVGp抗体.改构后的抗RVGp VH-Lc-VK抗体的稳定性明显改进,可特异识别RVGp并有效中和狂犬病毒,抑制狂犬病毒对靶细胞的感染.以上结果表明,人源抗RVGp特异性抗体的获得,为狂犬病的有效预防、诊断和治疗提供了新的途径,而且将为其他人源抗体的制备提供理论依据和技术基础.     

抗CD20嵌合抗体片段F(ab′)2突变体在大肠杆菌中的高效分泌表达

构建抗CD20嵌合抗体片段F(ab′)₂ 突变体 ,研究其在大肠杆菌中的高效表达及其表达产物的生物学活性。采用PCR法构建抗CD20嵌合抗体片段F(ab′)₂ 突变体 ,并用双脱氧终止法测定DNA序列 ;采用 19L发酵罐高密度发酵抗CD20嵌合抗体片段F(ab′)₂ 突变体 ,采用亲和色谱和分子筛色谱法纯化表达产物 ,并用SDS-PAGE和薄层激光扫描鉴定纯化产物 ;采用活细胞间接免疫荧光法测定纯化产物与靶细胞的结合活性 ;MTT法测定纯化产物对Raji细胞的生长抑制作用 ,并研究其作用机理。DNA序列测定结果表明 ,抗CD20嵌合抗体片段F(ab′)₂ 突变体已成功构建 ,表达可溶性产物的产量达 360mg L ,具有与Raji细胞 (CD20⁺)结合的活性 ,并抑制Raji细胞的生长 ,其作用机理为诱导Raji细胞凋亡。此突变体有望成为治疗非何杰金氏B细胞淋巴瘤的药物。     

抗血管内皮生长因子受体2双价单链抗体的构建表达及其活性研究

为了竞争性抑制血管内皮生长因子(VEGF)与其受体(VEGFR-2)的结合,构建表达了能够与VEGFR-2胞外3区(KDR3)特异结合的双价单链抗体(bivalent single-chain Fv,BsFv),并鉴定其生物活性。以KDR3特异结合单链抗体AK404(scFv AK404)基因为模板,设计引物引入中间连接肽(G₄S)₃连接两个scFv片段,将其克隆入原核表达载体pET22b,并转化至大肠杆菌BL21(DE3)中诱导表达,表达产物依次经过镍柱亲和层析纯化和透析复性;基于生物膜层表面干涉技术(Bio-Layer Interferometry,BLI)技术的体外亲和力监测实验和VEGF诱导的人脐静脉内皮细胞(HUVEC)增殖实验鉴定表达产物与KDR结合的活性。酶切鉴定和DNA测序结果表明BsFv构建成功;SDS-PAGE显示37 ℃下1 mmol/L IPTG诱导细菌6 h获得包涵体,经镍柱亲和层析纯化和透析复性得到纯度为90%的BsFv;经Western blotting鉴定为目的蛋白;体外结合实验表明:BsFv特异性结合KDR胞外3区的亲合力约为单价抗体AK404的2倍;内皮细胞增殖抑制实验表明:BsFv可剂量依赖性地抑制HUVEC细胞增殖,且其抑制效果强于AK404。上述结果表明:BsFv在抗血管生成活性方面比其scFv具有明显优势,为进一步用于抗血管生成抗肿瘤治疗和肿瘤诊断奠定了基础。     

抗CD20嵌合抗体片段Fab′突变体的表达和活性研究

利用PCR方法从抗CD20单链抗体（ScFv）表达载体上扩增抗CD20抗体轻链可变区基因（V^L）、重链可变区基因（V^H）,同时在抗体的可变区引入突变,然后将V^H、V^L基因重组到Fab′表达载体pYZF1中,构建抗CD20嵌合抗体Fab′片段表达载体,并在大肠杆菌16c9中进行高效可溶性分泌表达。经大量的筛选,获得一个产量和活性均有所提高的突变克隆。其突变位点在轻链可变区的CDR1区,即G77→A（Ser→Asn）。突变的抗体的表达量为每克干菌3.8 mg,而未突变抗体的表达量为每克干菌1.3 mg。突变体的亲和力常数K_a为2.2×10⁹ L/mol,约为突变前的2倍。竞争性免疫荧光抑制实验表明,突变的Fab′片段能竞争性抑制鼠源性抗CD20抗体HI₄₇和CD20表达细胞Raji细胞的结合,使HI₄₇的结合阳性率由98%下降至37.55%,体外细胞生长抑制试验亦证明突变的Fab′片段的抑制活性明显高于未突变的抗体。     

人源抗狂犬病毒中和性全抗体在昆虫细胞中的表达

将来源于噬菌体抗体库的人源狂犬病毒糖蛋白特异性单抗G10Fab的基因 ,克隆入杆状病毒人源IgG抗体表达载体 ,通过转染将重组质粒导入昆虫细胞 ,以全抗体的形式表达了一株人源抗狂犬病毒基因工程抗体G10。用亲和层析的方法纯化了表达产物 ,经与一株鼠源糖蛋白特异性单抗竞争证实 ,该单克隆抗体特异性识别狂犬病毒糖蛋白 ,亲和力约为 10 -9M。体外中和实验证明 ,该单抗对狂犬病毒aG株具有体外中和活性     

人源抗狂犬病毒中和性全抗体在昆明细胞中的表达

将来源于噬菌体抗体库的人源狂犬病毒糖蛋白特性异特单抗G10Fab基因的,克隆入杆状病毒人源IgG抗体表达载体,通过转染将重组质粒导入昆虫细胞,以全抗体的形式表达了一株人源抗狂犬病毒基因工程抗体R10。用亲和层析的方法纯化了表达产物,经过一株鼠源糖蛋白特异性单抗竞争证实,该单克隆抗体特异性识别狂犬病毒糖蛋白,亲和力约为10^-9M.体外中和实验证明,该单抗对狂犬病毒aG株具有体外中和活性。     

人源抗狂犬病毒糖蛋白Ⅲ号表位链置换基因工程抗体研究

为获得针对狂犬病毒糖蛋白Ⅲ号表位的人源单抗,本研究采用噬菌体展示平台,对一株狂犬病毒糖蛋白Ⅲ号抗原表位的人源单抗CR4098采用链置换法进行改造。以CR4098单链抗体为骨架,从狂犬疫苗接种者外周血分离淋巴细胞,提核酸逆转录,PCR扩增抗体轻链可变区基因,替换CR4098的轻链基因,构建轻链置换文库。经纯化狂犬病毒aG株富集筛选,以上述筛选出的轻链阳性克隆为骨架,构建重链置换抗体库,富集筛选后通过ELISA和IFA鉴定阳性抗体克隆并进行序列测定。利用IgG表达载体VH/VK双质粒系统瞬时转染293T细胞实现IgG抗体的分泌型表达,通过亲和力测定和中和试验鉴定IgG抗体功能。结果显示,通过轻链置换,我们获得14株抗狂犬病毒scFv抗体,通过ELISA、IFA、亲和力测定及中和试验确定人源抗体RV3A5特异性结合狂犬病毒糖蛋白,对狂犬病毒CVS株和aG株均具有良好的中和活性,亲和力达到2.8×10-9 M。通过竞争ELISA对抗体结合表位进行鉴定,结果表明RV3A5特异性识别糖蛋白Ⅲ号抗原表位。通过链置换法成功获得1株全新的针对狂犬病毒糖蛋白Ⅲ号表位的高亲和力人源中和抗体,为狂犬病毒抗体制剂鸡尾酒治疗奠定了基础。     

重组痘苗狂犬病毒糖蛋白的构建、表达及其遗传稳定性研究

狂犬病毒糖蛋白基因的痘苗病毒表达质粒 pWS 4在鸡胚细胞内与野生型痘苗病毒天坛株 (痘苗病毒 )同源重组 ,经蚀斑纯化 ,获得表达狂犬病毒糖蛋白基因的重组痘苗病毒 (重组病毒 )。该重组病毒DNAdotblot显示强阳性信号 ,间接免疫荧光试验胞膜及胞浆均见到强阳性荧光反应 ,Westernblot分析仅在 6 4ku处呈现一条狂犬病毒非融合性糖蛋白带。免疫小鼠和狗 ,第 2 8d抗狂犬病毒中和抗体滴度分别达 2 4 30和 >6 96。初免后 14d用 5 0～ 10 0LD50 狂犬病毒CVS株对小鼠脑内攻击 ,保护率达 80 %以上。致病性明显减弱。从第 11代起连续传至 30代 ,病毒纯度、病毒滴度、血凝滴度、蛋白的表达、抗原活性和保护性均无差异 ,说明该重组病毒有良好的遗传稳定性。     

Pichia pastoris酵母中表达人源中和性抗甲型肝炎病毒scFv-Fc融合抗体的研究

为了探讨人源抗甲型肝炎（甲肝）病毒scFv—Fc融合抗体在酵母中的表达特性,将获得的人源抗甲肝病毒中和性单链可变区抗体（scFv抗体）基因克隆入含信号肽及人IgG1Fc抗体基因的酵母细胞表达载体中,获得了一株中和性人源抗甲肝病毒pPiscFv—FcHA16融合抗体的分泌表达,并对表达产物进行了纯化。同时对表达产物的生物学特性进行了一系列鉴定。表达的pPiscFv—FcHA16融合抗体为具有不同糖基化形式的同源二聚体,与相应的CHO细胞表达的IgG抗体相比,pPiscFv—FcHA16融合抗体仍保持很好的抗原结合活性,以及与中和性鼠抗甲肝病毒单克隆抗体的竞争抑制能力。同时也保持了对甲肝病毒的体外中和活性。这些结果表明,在酵母中表达的单链可变区（scFv）与IgG1Fc区的融合抗体具有很好的生物学活性,有希望用做体外诊断,用纯化相应的抗原,或者可能用于体内预防与治疗。     

抗A型肉毒毒素人源单链抗体融合蛋白的重组设计*

以获得的抗A型肉毒毒素单链抗体为模板,进行融合改构,将人IgG1的Fc片段连接到ScFv的C端,在大肠杆菌中实现抗体融合蛋白ScFv-Fc的表达,表达量30%以上,蛋白以包含体形式存在,经过体外变复性的抗体融合蛋白ScFv-Fc,进行Prote in G Sepharose柱亲和层析纯化,纯度达90%~95%。体外活性检测结果表明,重组抗体融合蛋白ScFv-Fc可以特异结合A型肉毒类毒素抗原,其相对亲和力近似于母本单链抗体,其稳定性高于母本单链抗体。     

人源抗狂犬病毒单链抗体基因原核表达质粒的构建及高效表达

在原核系统中高效表达抗狂犬病毒单链抗体scFv41,以便进一步研究其生物学功能,预测临床应用前景。以重组质粒pCANTABscFv41为模板,PCR扩增带NcoI和NotI位点的scFv41基因,克隆入原核表达载体pET-22b( ),酶切鉴定重组表达质粒,转化大肠杆菌BL21(DE3),IPTG诱导表达。竞争ELISA检测表达蛋白的特异结合活性。酶切鉴定证实scFv41基因已插入原核表达载体pETl-22b( ),重组表达质粒pET-scFv41在大肠杆菌BL21(DE3)中获得了高效表达,表达量约占菌体蛋白总量的30％。竞争ELISA检测结果表明scFv41表达蛋白可特异抑制抗狂犬病毒IGY与狂犬病毒的特异性结合。该实验为进一步研究scFv41的生物学特性和免疫保护作用,及基因工程抗体的制备奠定了基础。     

狂犬病毒CTN—1株在Vero细胞上的适应传代研究

本文报导了用我国狂犬病毒固定毒人二倍体细胞适应株（ＣＴＮ－１）进行Ｖｅｒｏ细胞适应传代研究。通过连续传代培养,滴度可达８．０１ｏｇＬＤ５０／ｍｌ,达到了ＷＨＯ规定的不需浓缩的标准。病毒用０．０１ＭＯＩ感染细胞其产量与１Ｍｏｌ感染量相仿。病毒增殖高峰在４－５天,维持达１５天无明显下降,且可连续收获４－５次。因此,该毒种符合ＷＨＯ提出的疫苗生产毒种要求,可用于狂犬病疫苗生产。     

基于狂犬病病毒G蛋白scFv介导的靶向shRNA制备与鉴定

【目的】探讨以狂犬病病毒G糖蛋白单链抗体介导的载体表达shRNA靶向制剂,靶向抑制狂犬病毒复制的可行性。【方法】应用PCR技术获得狂犬病毒G糖蛋白单链抗体scFv(G)和绿脓杆菌跨膜区-酵母DNA结合结构域ETA-GAL4基因,通过搭桥PCR法获得scFv(G)-ETA-GAL4(SEG)嵌合基因;克隆至原核表达载体pET28a(+),构建重组表达质粒pET28a(+)-scFv(G)-ETA-GAL4(pET28a-SEG);在大肠杆菌BL21(DE3)中经IPTG诱导表达,利用镍柱亲和层析法纯化包涵体,经复性、鉴定制得SEG蛋白;ELISA法检测表达蛋白与狂犬病毒特异结合活性;将SEG蛋白与含shRNA的质粒(pRNATU6.3-shRNA)连接制成靶向shRNA,接入100 TCID50狂犬病毒感染BHK-21细胞,35 h观察细胞中绿色荧光蛋白(GFP)表达情况;48 h用直接免疫荧光抗体试验测定复合物抑制病毒效果。【结果】克隆得到1557 bp的SEG蛋白编码基因,大肠杆菌中成功表达57 KDa的SEG蛋白,能与抗His的单克隆抗体发生特异性反应,SEG蛋白经镍柱纯化、复性后得率为2.8 mg/mL。ELISA试验证明SEG蛋白在一定浓度范围内与RV结合呈正相关。细胞试验表明GFP在细胞内得到表达;直接免疫荧光试验测定该复合物能抑制76%病毒复制。【结论】SEG蛋白能与携带shRNA的质粒结合,可运送该质粒至RV感染BHK-21细胞中,抑制狂犬病毒的复制。     

Development of recombinant single-chain variable fragment against hepatitis A virus and its use in quantification of hepatitis A antigen

Phage display technology has been utilized for identification of specific binding molecules to an antigenic target thereby enabling the rapid generation and selection of high affinity, fully human antibodies directed towards disease target appropriate for antibody therapy. In the present study, single chain Fv antibody fragment (scFv) to hepatitis A virus (HAV) was selected from phage displayed antibody library constructed from peripheral blood lymphocytes (PBLs) of a vaccinated donor. The variable heavy (V(H)) and light chains (V(L)) were amplified using cDNA as template, assembled into scFv using splicing by overlap extension PCR (SOE PCR) and cloned into phagemid vector as a fusion for display of scFv on bacteriophage. The phage displaying antibody fragments were subjected to three rounds of panning with HAV antigen on solid phase. High affinity antibodies reactive to hepatitis A virus were identified by phage ELISA and cloned into a bacterial expression vector pET20b. The scFv was purified by immobilized metal affinity chromatography (IMAC) on a nickel-nitrilotriacetic acid (NTA) agarose column and characterized. The binding activity and specificity of the scFv was established by its non-reactivity towards other human viral antigens as determined by ELISA and immunoblot analysis. The scFv was further used in the development of an in-house IC-ELISA format in combination with a commercially available mouse monoclonal antibody for the quantification of hepatitis A virus antigen in human vaccine preparations. The adjusted r2 values obtained by subjecting the values obtained by quantification of the NIBSC standards using the commercial and the in-house ELISA kits by regression analysis were 0.99 and 0.95. 39 vaccine samples were subjected to quantification using both the kits. Regressional statistical analysis through the origin of the samples indicated International Unit (IU) values of 0.0416x and 0.0419x, respectively for the commercial and in-house kit respectively.     

Preparation and diagnostic use of a novel recombinant single-chain antibody against rabies virus glycoprotein

Rabies virus (RABV) causes a fatal infectious disease, but effective protection may be achieved with the use of rabies immunoglobulin and a rabies vaccine. Virus-neutralizing antibodies (VNA), which play an important role in the prevention of rabies, are commonly evaluated by the RABV neutralizing test. For determining serum VNA levels or virus titers during the RABV vaccine manufacturing process, reliability of the assay method is highly important and mainly dependent on the diagnostic antibody. Most diagnostic antibodies are monoclonal antibodies (mAbs) made from hybridoma cell lines and are costly and time consuming to prepare. Thus, production of a cost-effective mAb for determining rabies VNA levels or RABV titers is needed. In this report, we describe the prokaryotic production of a RABV-specific single-chain variable fragment (scFv) protein with a His-tag (scFv98H) from a previously constructed plasmid in a bioreactor, including the purification and refolding process as well as the functional testing of the protein. The antigen-specific binding characteristics, affinity, and relative affinity of the purified protein were tested. The scFv98H antibody was compared with a commercial RABV nucleoprotein mAb for assaying the VNA level of anti-rabies serum samples from different sources or testing the growth kinetics of RABV strains for vaccine manufactured in China. The results indicated that scFv98H may be used as a novel diagnostic tool to assay VNA levels or virus titers and may be used as an alternative for the diagnostic antibody presently employed for these purposes.     

Construction of combinatorial immune library of single chain human antibodies to orthopoxviruses and selection from this library antibodies to recombinant protein prA30L of variola virus

A combinatorial immune library of human single-chain antibody fragments (scFv) was constructed on the base of genes encoding variable domains of heavy and light chains of immunoglobulins cloned from the lymphocytes of four vaccinia virus (VACV) vaccinated donors. The size of the library was 3 x 10(7) independent clones. After the library was enriched with the clones producing scFv against recombinant analogue of variola virus surface protein prA30L, a panel of unique antibodies specific to both prA30L and VACV was selected from the library. A plaque reduction neutralization test was performed for all selected antibodies and two antibodies were shown to be able to neutralize plaque formation of VACV in Vero E6 cells monolayer. Binding specificities of these antibodies were confirmed using ELISA and Western blot analysis. To determine the amino acid sequences of neutralizing antibodies their genes were sequenced.     

人源抗狂犬病毒单克隆抗体Fab段基因的获得和表达

运用噬菌体表面呈现（phage display）技术获得了人源抗狂犬病毒糖蛋白基因工程单克隆抗体Fab段基因及其表达。从狂犬病毒PM株Vero细胞疫苗免疫的人抗凝血中分离获得外周淋巴细胞,提取细胞总RNA,通过RTPCR方法,用一组人IgG Fab基因4特异性引物,从合成的cDNA中扩增了一组轻链和重链Fab段基因,将轻链和重链Fab段基因,将轻链和重链先后克隆入噬菌体载体pComb3,成功地建立了抗狂犬病毒抗原的方法,对此抗体库进行富积筛选表达,成功地获得了抗狂犬病毒的人源单抗Fab段基因及其在大肠杆菌中的有效表达,对其中一株单抗G10进行了较为系统的分析,发现它与一株鼠源中和性狂犬病毒糖蛋白特异性单抗存在竞争,证实该单抗能识别狂犬病毒糖蛋白,其序列资料分析表明,该单抗为一株新的抗狂犬病毒人源基因工程抗体。     

Identification of binding epitope for anti-rabies virus glycoprotein single-chain Fv fragment FV57

Single-chain Fv fragment (scFv) of anti-rabies glycoprotein (G protein) has been recommended as a new agent for detecting and neutralizing lethal rabies virus. In this study, we constructed scFv that corresponded to the FV fragment of CR57, a monoclonal antibody against rabies virus, and called it FV57. Despite its virus neutralization activity, FV57 may or may not recognize the same epitope as that recognized by CR57. To resolve this issue, the binding epitope of rabies virus G protein recognized by FV57 was identified. A recombinant rabies virus G protein fragment (RVG179; residues 179-281) comprising several epitopes was expressed in E.coli, purified, and the specificity of its binding with FV57 was determined. In addition, a peptide (abbreviated as EP, residues 224-236) comprising the known epitope of G protein to which CR57 binds was synthesized and the potency of its binding with FV57 was also determined. The results showed that FV57 could specifically bind to RVG179 and EP. Competitive ELISA experiments indicated that RVG179 and EP were able to compete with the rabies virus G protein for binding with FV57. Since no other epitope within residues 224- 236 has been reported, except for the epitope to which CR57 binds (residues 226-231), the epitope recognized by FV57 was the same as its intact antibody CR57. This demonstrated that the complementarity-determining regions (CDRs) of the heavy and light chains of FV57 have folded into the correct conformation as those of CR57.