A nanobody-based blocking enzyme-linked immunosorbent assay for detecting antibodies against pseudorabies virus glycoprotein E

Pseudorabies(PR)is an acute infectious disease of pigs caused by the PR virus(PRV)and results in great economic losses to the pig industry worldwide.PRV glycoprotein E(gE)-based enzyme-linked immunosorbent assay(ELISA)has been used to distinguish gE-deleted vaccine-immunized pigs from wild-type virus-infected pigs to eradicate PR in some countries.Nanobody has the advantages of small size and easy genetic engineering and has been a promising diagnostic reagent.However,there were few reports about developing nanobody-based ELISA for detecting anti-PRV-gE antibodies.In the present study,the recombinant PRV-gE was expressed with a bacterial system and used to immunize the Bactrian camel.Then,two nanobodies against PRV-gE were screened from the immunized camel by phage display technique.Subsequently,two nanobody-HRP fusion proteins were expressed with HEK293T cells.The PRV-gE-Nb36-HRP fusion protein was selected as the probe for developing the blocking ELISA(bELISA)to detect anti-PRV-gE antibodies.Through optimizing the conditions of bELISA,the amount of coated antigen was 200 ng per well,and dilutions of the fusion protein and tested pig sera were separately 1:320 and 1:5.The cut-off value of bELISA was 24.20%,and the sensitivity and specificity were 96.43 and 92.63%,respectively.By detecting 233 clinical pig sera with the developed bELISA and a commercial kit,the results showed that the coincidence rate of two assays was 93.99%.Additionallly,epitope mapping showed that PRV-gE-Nb36 recognized a conserved conformational epitope in different reference PRV strains.Simple,great stability and low-cost nanobody-based bELISA for detecting anti-PRV-gE antibodies were developed.The bELISA could be used for monitoring and eradicating PR.

Two nanobody‑based immunoassays to differentiate antibodies against genotype 1 and 2 porcine reproductive and respiratory syndrome virus

Porcine reproductive and respiratory syndrome virus(PRRSV)infection causes significant economic loss to the global pig industry.Genotype 1 and 2 PRRSV(PRRSV-1 and-2)infections have been reported in China,Europe and America.For accurate prevention,nanobodies were first used as diagnostic reagents for PRRSV typing.In this study three nanobodies targeting both PRRSV-1 and-2,two targeting PRRSV-1 and three targeting PRRSV-2,were screened and produced.To develop two competitive ELISAs(cELISAs),the g1-2-PRRSV-Nb3-HRP nanobody was chosen for the g1-2-cELISA,to detect common antibodies against PRRSV-1 and-2,and the g1-PRRSV-Nb136-HRP nanobody was chosen for the g1-cELISA,to detect anti-PRRSV-1 antibodies.The two cELISAs were developed using PRRSV-1-N protein as coating antigen,and the amounts for both were 100 ng/well.The optimized dilution of testing pig sera was 1:20,the optimized reaction times were 30 min,and the colorimetric reaction times were 15 min.Then,the cut-off values of the g1-2-cELISA and g1-cELISA were 26.6%and 35.6%,respectively.Both of them have high sensitivity,strong specificity,good repeatability,and stability.In addition,for the 1534 clinical pig sera,an agreement rate of 99.02%(Kappa values=0.97)was determined between the g1-2-cELISA and the commercial IDEXX ELISA kit.For the g1-cELSIA,it can specifically detect anti-PRRSV-1 antibodies in the clinical pig sera.Importantly,combining two nanobody-based cELISAs can differentially detect antibodies against PRRSV-1 and-2.

Quantification of soluble epoxide hydrolase inhibitors in experimental and clinical samples using the nanobody-based ELISA

To ensure proper dosage of a drug,analytical quantification of it in biofluid is necessary.Liquid chromatography mass spectrometry(LC-MS)is the conventional method of choice as it permits accurate identification and quantification.However,it requires expensive instrumentation and is not appropriate for bedside use.Using soluble epoxide hydrolase(sEH)inhibitors(EC5026 and TPPU)as examples,we report development of a nanobody-based enzyme-linked immunosorbent assay(ELISA)for such small molecules and its use to accurately quantify the drug chemicals in human samples.Under optimized conditions,two nanobody-based ELISAs were successfully established for EC5026 and TPPU with low limits of detection of 0.085 ng/mL and 0.31 ng/mL,respectively,and two order of magnitude linear ranges with high precision and accuracy.The assay was designed to detect parent and two biologically active metabolites in the investigation of a new drug candidate EC5026.In addition,the ELISAs displayed excellent correlation with LC-MS analysis and evaluation of inhibitory potency.The results indicate that nanobody-based ELISA methods can efficiently analyze drug like compounds.These methods could be easily implemented by the bedside,in the field in remote areas or in veterinary practice.This work illustrates that nanobody based assays offer alternative and supplementary analytical tools to mass spectrometry for monitoring small molecule medicines during clinical development and therapy.Attributes of nanobody based pharmaceutical assays are discussed.

In Silico Evaluation of the Potential Interference of Boceprevir, Calpain Inhibitor II, Calpain Inhibitor XII, and GC376 in the Binding of SARS-CoV-2 Spike Protein to Human Nanobody Nb20

Virtual screening can be a helpful approach to propose treatments for COVID-19 by developing inhibitors for blocking the attachment of the virus to human cells. This study uses molecular docking, recovery time and dynamics to analyze if potential inhibitors of main protease (Mpro) of SARS-CoV-2 can interfere in the attachment of nanobodies, specifically Nb20, in the receptor binding domain (RBD) of SARS-CoV-2. The potential inhibitors are four compounds previously identified in a fluorescence resonance energy transfer (FRET)-based enzymatic assay for the SARS-CoV-2 Mpro: Boceprevir, Calpain Inhibitor II, Calpain Inhibitor XII, and GC376. The findings reveal that Boceprevir has the higher affinity with the RBD/Nb20 complex, followed by Calpain Inhibitor XII, GC376 and Calpain Inhibitor II. The recovery time indicates that the RBD/Nb20 complex needs a relatively short time to return to what it was before the presence of the ligands. For the RMSD the Boceprevir and Calpain Inhibitor II have the shortest interaction times, while Calpain Inhibitor XII shows slightly more interaction, but with significant pose fluctuations. On the other hand, GC376 remains stably bound for a longer duration compared to the other compounds, suggesting that they can potentially interfere with the neutralization process of Nb20.

VHH212 nanobody targeting the hypoxia-inducible factor 1α suppresses angiogenesis and potentiates gemcitabine therapy in pancreatic cancer in vivo

Objective:We aimed to develop a novel anti-HIF-1αintrabody to decrease gemcitabine resistance in pancreatic cancer patients.Methods:Surface plasmon resonance and glutathione S-transferase pull-down assays were conducted to identify the binding affinity and specificity of anti-HIF-1αVHH212[a single-domain antibody(nanobody)].Molecular dynamics simulation was used to determine the protein-protein interactions between hypoxia-inducible factor-1α(HIF-1α)and VHH212.The real-time polymerase chain reaction(PCR)and Western blot analyses were performed to identify the expressions of HIF-1αand VEGF-A in pancreatic ductal adenocarcinoma cell lines.The efficiency of the VHH212 nanobody in inhibiting the HIF-1 signaling pathway was measured using a dual-luciferase reporter assay.Finally,a PANC-1 xenograft model was developed to evaluate the anti-tumor efficiency of combined treatment.Immunohistochemistry analysis was conducted to detect the expressions of HIF-1αand VEGF-A in tumor tissues.Results:VHH212 was stably expressed in tumor cells with low cytotoxicity,high affinity,specific subcellular localization,and neutralization of HIF-1αin the cytoplasm or nucleus.The binding affinity between VHH212 and the HIF-1αPAS-B domain was 42.7 n M.Intrabody competitive inhibition of the HIF-1αheterodimer with an aryl hydrocarbon receptor nuclear translocator was used to inhibit the HIF-1/VEGF pathway in vitro.Compared with single agent gemcitabine,co-treatment with gemcitabine and a VHH212-encoding adenovirus significantly suppressed tumor growth in the xenograft model with 80.44%tumor inhibition.Conclusions:We developed an anti-HIF-1αnanobody and showed the function of VHH212 in a preclinical murine model of PANC-1 pancreatic cancer.The combination of VHH212 and gemcitabine significantly inhibited tumor development.These results suggested that combined use of anti-HIF-1αnanobodies with first-line treatment may in the future be an effective treatment for pancreatic cancer.

基于双特异纳米抗体FMDV血凝检测方法的建立

本研究利用基因工程方法将抗口蹄疫病毒(FMDV)纳米抗体Nb205和抗鸡醛化红细胞(cRBC)纳米抗体NbRBC48的基因片段连接,构建双特异纳米抗体Nb205-48,其相对分子质量为3.5×10^(4),能同时与FMDV和cRBC反应。利用Nb205-48成功建立了可用于FMDV抗原检测的血凝方法,该方法检测灵敏度为1μg/ml,与其他病毒无交叉反应,且批内和批间重复性好。分别采用血凝法和夹心ELISA方法对3批次FMDV抗原进行了检测,二者检测结果基本吻合。本研究建立了基于双特异纳米抗体Nb205-48的血凝检测方法,该方法具有较好的灵敏度、特异性和重复性,且简便、快捷、成本低,其检测结果与传统的FMDV定量检测方法的检测结果相关性好,为检测口蹄疫疫苗生产过程中FMDV抗原的含量提供了新方法。

纳米抗体在体内外诊断和治疗中的优势和临床应用

作为目前已知的能与抗原发生特异性结合的最小抗体,纳米抗体(nanobody,Nb)近年来在医学领域的发展非常迅速。相对于常规单克隆抗体制备繁琐、成本高、运输保存条件苛刻而言,纳米抗体结构简单、稳定性极高,在极端的条件下仍然保留与抗原结合的特性,同时其具备水溶性高、穿透力强、免疫原性弱、排斥反应小、可以进行批量生产等优势,使得其被大规模应用于临床。本综述将归纳纳米抗体的生物学性能和结构特征,阐明其在小分子、病原体和癌症等方面的诊断功能以及感染和肿瘤等治疗上的应用,并对未来纳米抗体的发展进行展望。

CTLA-4纳米抗体与肿瘤适配体共修饰的双靶向脂质体构建

目的:制备CTLA-4纳米抗体(Nb16)/适配体TLS11a修饰的脂质体,以制备一种能特异性靶向T细胞及肿瘤细胞的双靶向纳米制剂。方法:采用薄膜水化法制备得到纳米脂质体,然后通过化学键的耦联将氨基修饰到脂质体上,TLS11a适配体修饰巯基,Nb16纳米抗体自身带有巯基,将三者进行迈克尔加成反应,即可同时偶联纳米抗体和适配体到脂质体表面,制备得到双靶向脂质体(Nb16-Lipo-TLS11a)。运用透射电镜(TEM)、粒径和电位仪对Nb16-Lipo-TLS11a进行表征,并通过流式细胞术检测其与活化T细胞及肝癌细胞HepG2的结合情况。结果:制备的Nb16-Lipo-TLS11a为椭圆形的脂质体且表现呈均质、分散特征,粒径大小在100nm左右。结合实验结果直接或间接验证了Nb16-Lipo-TLS11a与活化T细胞及肝癌细胞的特异性结合能力。结论:本研究创新性构建的双靶向脂质体,能够特异性结合T细胞和靶细胞,为肿瘤靶向治疗提供了一种新策略。

基于纳米抗体的可再生免疫亲和柱结合高效液相色谱-串联质谱法测定玉米中的黄曲霉毒素B_(1)

目的研究黄曲霉毒素B_(1)(aflatoxinB_(1),AFB_(1))纳米抗体的表达产量的影响因素,开发具有可再生性的AFB_(1)免疫亲和柱,构建免疫亲和处理-高效液相色谱-串联质谱法(high performance liquid chromatography-tandem mass spectrometry,HPLC-MS/MS)测定玉米中AFB_(1)污染的分析方法。方法研究诱导温度、诱导时间和诱导剂浓度等对AFB_(1)纳米抗体表达量的影响,比对验证AFB_(1)纳米抗体可再生免疫亲和柱的耐受性和可再生使用次数。使用70%甲醇水溶液提取玉米样品中AFB_(1),提取液通过免疫亲和柱净化富集后进行HPLC-MS/MS检测,最后进行方法学验证并应用到实际样品检测。结果诱导AFB_(1)纳米抗体表达的最优条件分别为诱导温度16℃、诱导剂异丙基-β-D-硫代吡喃半乳糖苷浓度0.5 mmol/L、诱导时间14 h,在最优条件下产量可达7.8 mg/L。AFB_(1)纳米抗体具有良好灵敏度、亲和性、特异性和甲醇耐受性,制备的AFB_(1)免疫亲和柱具有极好的可再生性,重复使用150次以上,对AFB_(1)回收率仍可达80%以上。同时,建立的免疫亲和处理-HPLC-MS/MS,在0.1~100.0μg/L范围内呈现良好的线性关系,检出限为0.014μg/L,定量限为0.047μg/L。在3个不同加标浓度下,回收率在92.0%~104.1%,变异系数小于3.9%。结论本研究开发的AFB_(1)纳米抗体免疫亲和柱表现出优秀的再生性和高特异性,节约了检测成本,建立的免疫亲和处理-HPLC-MS/MS检测方法操作简便、回收率高、结果准确,适用于实际玉米样品中AFB_(1)的含量测定。

猪CD205分子CysR-FN Ⅱ蛋白特异性纳米抗体的筛选与鉴定研究

[目的]猪CD205分子作为猪树突状细胞(DC)特异性的抗原提呈受体,在抗原提呈过程中起关键作用。本研究通过噬菌体展示技术针对猪CD205分子CysR-FNⅡ蛋白进行筛选以获得其特异性的纳米抗体,为猪CD205靶向抗原提呈研究奠定基础。[方法]利用前期制备的猪CD205分子CysR-FNⅡ蛋白进行羊驼免疫,经6次皮下免疫后采集羊驼外周血淋巴细胞,提取总RNA后反转录获得cDNA,经PCR扩增编码纳米抗体的基因片段,构建猪CD205分子CysR-FNⅡ蛋白噬菌体展示纳米抗体基因文库,再运用噬菌体展示技术针对猪CD205分子CysR-FNⅡ蛋白进行亲和筛选,随机挑选单克隆菌落并使用Phage-ELISA方法鉴定出针对猪CD205分子CysR-FNⅡ蛋白的特异性纳米抗体。[结果]4轮亲和筛选后,通过Phage-ELISA方法鉴定和序列比对分析,共成功获得12个猪CD205分子CysR-FNⅡ蛋白特异性纳米抗体,其相对分子质量约为17×10^(3)。[结论]本研究成功筛选并获得猪CD205分子CysR-FNⅡ蛋白特异性的纳米抗体。

基于纳米抗体-荧光素酶的黄曲霉毒素B1检测方法构建

黄曲霉毒素B1(AFB1)是一种剧毒、致癌的食源性污染物,严重威胁食品安全和公共健康。为开发快速检测AFB1的生物发光酶联免疫分析(BLEIA)方法,系统测试了3种抗AFB1特异性纳米抗体(NB)与纳米荧光素酶(Nluc)融合蛋白(G8-Nluc、Nluc-NB26和Nluc-NB28)的可溶性表达、纯化情况及酶催化活性。基于3种融合蛋白分别建立BLEIA检测体系,选择Nluc-NB26用于谷物样品的分析和验证。结果表明,Nluc-NB26的可溶性表达量最高,稳定性更好,Nluc-NB28的可溶性表达量次之,而G8-Nluc基本不可溶。不同表面活性剂对G8-Nluc的促溶解性研究表明,添加N-月桂酰肌氨酸钠可显著提高其溶解度,纯化得到的3种融合蛋白均具有良好的酶活性及抗原结合活性。基于融合蛋白的BLEIA检测结果显示,Nluc-NB28-BLEIA、G8-Nluc-BLEIA和Nluc-NB26-BLEIA体系检测AFB1的IC_(50)值分别为4.213,1.697,2.169 ng/mL,表明G8-Nluc-BLEIA体系的灵敏度最高,Nluc-NB26-BLEIA与前者接近,Nluc-NB28-BLEIA最低。综合考虑融合蛋白的可溶性表达量、稳定性及检测性能,对Nluc-NB26-BLEIA开展实际样品的分析和验证,结果表明:这一方法检测谷物中AFB1的平均回收率在91.1%~104.1%之间,与商业化酶联免疫吸附测定试剂盒结果相似,而检测的时间和试剂成本明显降低。研究结果为开发快速、高灵敏的AFB1检测技术提供参考。

克百威纳米抗体的结构解析与体外进化研究

克百威曾是一种广泛用于农业虫害防治领域的氨基甲酸酯类农药,由于其对哺乳动物具有高毒性,对人畜安全及环境造成较大威胁,因此各国陆续出台了克百威禁限用政策,但其在农产品中被检出超标的问题仍时有报道,故对其加强监测十分必要。纳米抗体是一种新型的基因工程片段抗体,具有高稳定性、结构简单和高表达量等优势。本研究通过体外亲和力成熟技术,对实验室已有的克百威纳米抗体Nb5进行改造,进一步提升其灵敏度。首先,基于AlphaFold系统,预测纳米抗体三维结构并验证模型合理性;以分子对接结合丙氨酸扫描技术,研究克百威与纳米抗体的识别机制,并验证关键结合位点。结果表明:克百威分子进入了由CDR2、CDR3及FR3区组成的活性口袋腔,纳米抗体通过氢键和疏水作用力识别克百威,所涉及的关键氨基酸分别为Arg56、Trp58、Thr101、Val102、Ala103、Asp104和Cys105。基于噬菌体展示技术,构建了克百威纳米抗体的定点饱和突变库,并筛选到一株突变体H10,其IC_(50)值为17.6 ng/mL,其灵敏度比野生型Nb5提升了1倍,亲和力常数为1.54×10^(6)L/mol。该研究结果为开发针对小分子药物的纳米抗体体外亲和力成熟技术提供了一种有效的新思路。

抗黄曲霉毒素M1纳米抗体的筛选与初步鉴定

黄曲霉毒素M1(aflatoxin M1,AFM1)对人类和动物具有致癌性、诱变性、致畸性等,广泛存在于哺乳动物乳汁及其乳制品中。因此,制备特异性强、灵敏度高的抗体来检测AFM1至关重要。该研究以AFM1-BSA为抗原免疫双峰驼,采血分离淋巴细胞,提取总RNA反转录为cDNA,通过巢式PCR获得重链可变区(variable domain of heavy chain,VHH),与pComb3XSS载体连接电击转化至Escherichia coli TG1,构建AFM1特异性噬菌体展示文库。以AFM1-OVA为靶向抗原,使用4轮酸洗脱和竞争洗脱相结合的策略对文库进行淘选,并对抗AFM1纳米抗体进行初步鉴定,最后预测了精准的三维模型结构。结果显示,抗AFM1纳米抗体文库库容量为2.27×10^(9)CFU,多样性丰富,插入率为100%。经淘选共获得6条独特序列的纳米抗体。其中VHH-M4和VHH-M6具有较高的灵敏度,初步测定半抑制浓度分别为0.415 ng/mL和1.877 ng/mL,线性范围分别为0.141~1.652 ng/mL和0.800~3.811 ng/mL。一级和二级结构结果显示VHH-M4和VHH-M6均为亲水性蛋白,框架区(framework region,FR)和互补决定区(complementarity determining region,CDR)区符合典型纳米抗体的结构特征。该研究为AFM1免疫学检测提供核心元件,并为探究AFM1与VHH的分子结合机制奠定基础。

基于纳米抗体建立icELISA检测乳制品中黄曲霉毒素M1

纳米抗体(nanobody,Nb)具有稳定性高、特异性强、易于表达等优势,已经成为小分子免疫分析的重要工具。为了监测乳制品中黄曲霉毒素M1(aflatoxin M1,AFM1)的污染情况,以先前从双峰驼AFM1免疫文库中淘选得到的抗AFM1型纳米抗体M6为研究对象,评估其理化性质并建立间接竞争酶联免疫吸附测定法(indirect competitive enzyme-linked immunosorbent assay,icELISA)。优化反应体系中封闭方法、甲醇溶液、pH值和离子强度等参数后,建立竞争抑制标准曲线,并进行方法学验证特异性和准确性。结果表明,Nb-M6具有良好的亲和力和热稳定性;Nb-icELISA的检测限(limit of detection,LOD)为0.111 ng/mL,半数抑制浓度(half maximal inhibitory concentration,IC_(50))为1.498 ng/mL,乳制品加标回收率为89.8%~104.1%,与高效液相色谱法的检测结果趋于一致。该方法操作简单、便捷,可应用于乳制品中AFM1的初步批量筛查。

纳米抗体多聚化测略提升间接竞争性酶联免疫吸附实验检测黄曲霉毒素M_(1)的灵敏度

酶联免疫吸附实验(enzyme-linked immunosorbent assay,ELISA)具有高通量、操作简单、检测结果明显等优点,是一种较为理想的检测食品中真菌污染物的免疫分析技术。然而,传统的ELISA方法具有较大的局限性,比如使用时抗体易受温度影响,容易变性,贮存期短,易受到检测环境中其他物质干扰而造成假阳性或假阴性等。该实验使用实验室前期获得的抗黄曲霉毒素M_(1)(aflatoxin M_(1),AFM_(1))纳米抗体(nanobody-M4,Nb-M4)与C4结合蛋白(recombinant C4 binding protein alpha,C4BPa)C端片段融合形成自组装七聚体融合蛋白(Nb-M4-C4 bpα),并基于该七聚体开发应用于乳制品中AFM_(1)的间接竞争酶联免疫吸附法(indirect competitive enzyme-linked immunosorbent assay,icELISA)。在最佳实验参数下,AFM_(1)的IC_(50)为0.038 ng/mL,检测限为0.009 ng/mL,较单体Nb-M4的提高了8.63倍和5.56倍。与AFM_(1)类似物和其他常见真菌毒素的交叉反应可忽略不计,且在加标乳样中获得了良好的回收率和可重复性。此外,将所开发的方法应用于实际样品中AFM_(1)的分析,结果与HPLC的结果具有很好的相关性(R^(2)=0.995)。该研究表明,自组装的七聚化纳米抗体是改善亲和力和信号放大的有效策略,今后可用于灵敏、选择性和快速检测食品中的霉菌毒素和其他小分子污染物。

猪繁殖与呼吸综合征病毒GP5蛋白纳米抗体的筛选及其对病毒复制的抑制效应

为获得猪繁殖与呼吸综合征病毒(porcine reproductive and respiratory syndrome virus,PRRSV)GP5蛋白的特异性纳米抗体,并探究其对病毒复制的抑制效应。使用原核表达系统将PRRSV-GP5蛋白大量表达后经镍柱亲和层析法纯化,使用所获的重组GP5蛋白免疫羊驼,并于第0、14、28、42天时采血,检测羊驼体内抗体效价后分离全血淋巴细胞,提取细胞总RNA,反转录后使用巢式PCR扩增出重链抗体可变区(VHH)片段,并与pCANTAB-5E载体相连后转化入TG1感受态细胞,利用噬菌体展示技术构建GP5-VHH噬菌体抗体展示文库。经连续三轮特异性噬菌体的筛选与富集后,淘选出与PRRSV-GP5蛋白高结合力的纳米抗体,通过间接ELISA方法鉴定其反应原性,后将所获的纳米抗体基因克隆至真核表达载体pcDNA3.1(-)中,利用Lipofectamine3000转染至Marc^(-1)45细胞内,与PRRSV分别共孵育0、24、36、48、60、72 h,以探究所筛针对PRRSV-GP5蛋白的纳米抗体于胞内对病毒复制与转录产生的影响。结果表明,成功对PRRSV-GP5蛋白进行原核表达并纯化,得到浓度为2.16 mg·mL^(-1)的重组蛋白,对羊驼三次免疫14 d后,其体内抗体效价高达1∶819200,构建GP5-VHH噬菌体抗体展示文库,库容量达2.93×107 CFU·mL^(-1),插入率为98%。经对噬菌体抗体文库连续三轮淘选富集后,最终获得2株不同氨基酸序列的纳米抗体。间接ELISA结果显示,2株纳米抗体均与PRRSV-GP5蛋白具有良好的亲和力。将2株纳米抗体转染至Marc^(-1)45细胞内,它们分别于36与60 h时显著阻碍PRRSV的复制与转录,展现出了较好的阻碍病毒复制的能力。本研究首次筛选出针对PRRSV-GP5蛋白的特异性纳米抗体,且经验证所筛纳米抗体具备抑制PRRSV在细胞内复制的能力,研究结果为抗PRRSV新型药物的研发奠定了试验依据与物质基础。

纳米抗体在自身免疫性疾病中的应用

自身免疫性疾病是由于机体对自身抗原失去免疫耐受而发生的一类异质性疾病。近年来,抗体药物已成为治疗自身免疫性疾病的重要选择。单克隆抗体因相对分子质量大,不易穿透实体组织而应用受限,而纳米抗体是目前已知的具有完整抗原识别能力的最小抗体片段,具有易于改造、穿透力强、能够靶向更加隐蔽的表位等特点,在自身免疫性疾病的治疗中受到了广泛关注。本文重点阐述纳米抗体在类风湿关节炎、获得性血栓性血小板减少性紫癜、系统性红斑狼疮和银屑病等疾病治疗中的应用情况,展望纳米抗体在自身免疫性疾病治疗中的应用前景。

甲氧苄啶纳米抗体噬菌体展示文库的构建及初步筛选

【目的】构建甲氧苄啶(trimethoprim,TMP)纳米抗体(nanobody,Nb)噬菌体展示文库,制备TMP高亲和力纳米抗体,为TMP免疫分析方法的建立提供新型抗体材料。【方法】通过活性酯酶法将TMP半抗原Hapten B与牛血清白蛋白(BSA)、钥孔血蓝蛋白(KLH)偶联制备2种免疫原,Hapten A和Hapten B与卵清白蛋白(OVA)偶联制备2种包被原。采用磺胺增效剂类药物单克隆抗体5C4,通过间接ELISA方法验证免疫原和包被原偶联效果。将免疫原与弗氏佐剂混合,先后对羊驼进行基础免疫和加强免疫,监测每次免疫后羊驼抗血清效价及对TMP的亲和力,选取效价及TMP亲和力最高的外周血作为纳米抗体基因来源,构建噬菌体展示文库。分离羊驼外周血总淋巴细胞,扩增重链抗体可变区纳米抗体基因(VHH),插入噬菌粒,电击转化大肠杆菌XL1-Blue感受态细胞构建初始噬菌体纳米抗体展示文库。经辅助噬菌体救援,采用同源包被原浓度梯度递减包被、酸洗脱、TMP浓度梯度递减洗脱筛选策略筛选TMP高亲和力噬菌体并测序,原核表达纳米抗体,通过SDS-PAGE和Western blotting鉴定纳米抗体融合蛋白。【结果】间接ELISA检测结果显示,2种免疫原与2种包被原在稀释18000倍时D 450 nm值仍高于1.25。免疫原Hapten B-BSA 5次免疫后羊驼抗血清效价为1∶88000,对TMP的半数抑制浓度(IC 50)为12.21μg/L,但Hapten B-KLH 4次免疫后羊驼抗血清效价为1∶11000,对TMP的IC 50为30.56μg/L。以Hapten B-BSA五免后羊驼外周血为纳米抗体基因来源构建噬菌体展示文库,初始库容量为6.08×10^(7) CFU/mL,目的片段插入率为96%,噬菌体展示文库多样性良好。经4轮筛选后,获得3株TMP高亲和力噬菌体,测序分析后获得1株TMP高亲和力纳米抗体及序列。SDS-PAGE和Western blotting鉴定融合蛋白大小约为17 ku,蛋白含量80%以上。【结论】本研究成功构建TMP纳米抗体噬菌体展示文库,获得1株TMP高亲和力纳米抗体。研究结果为磺胺增效剂类药物纳米抗体的制备提供了理论依据和技术支持,为兽药等小分子新型识别材料的制备提供了新的思路。

纳米抗体在生物毒素及农药残留检测中的应用研究进展

骆驼科动物体内存在着天然缺失轻链的重链抗体,而通过重组表达重链抗体的可变域可获得一种具有抗原结合活性的蛋白,被称为单域抗体或纳米抗体。纳米抗体作为近些年来发现的一种新型抗体,其具有结构简单、相对分子质量小、稳定性强、耐受性高、水溶性高、抗原结合性能强,且易于表达纯化制备等特点,较常规抗体用途更广。纳米抗体的这些特点使其成为常规抗体的理想替代物,并且已被应用于检测食品中毒素、农药、兽药残留等小分子污染物。本文主要综述了纳米抗体的国内外研究进展,旨在介绍其结构、特性,以及这些特点在食品安全检测中的作用,并着重介绍了纳米抗体在食品安全检测方面的应用实例和最新进展,为纳米抗体在食品安全领域未来的研究方向提供参考依据。

胰腺多肽纳米抗体的制备及结合活性分析

胰腺多肽(pancreatic polypeptide,PP)是一种含36个氨基酸的胰腺激素,在评估胰腺功能和辅助诊断相关疾病中发挥重要作用。以PP为靶点,筛选特异性的PP纳米抗体,评估其与PP抗原是否具有结合活性。利用原核表达系统制备了高纯度的PP抗原,经免疫羊驼后构建了高库容和高丰度的胰腺多肽免疫的纳米抗体噬菌体文库,并通过噬菌体展示技术进行文库筛选,获得8株胰腺多肽纳米抗体。选取1株纳米抗体(PP-VHH)构建原核表达体系,经IPTG诱导表达、纯化与鉴定,通过间接ELISA和双抗夹心ELISA分别检测和评价抗原抗体的结合活性和血清中PP含量,结果显示,PP-VHH与PP具有结合活性,且PP-VHH可用于检测鸡和人血清中的PP。建立的双抗夹心ELISA法拟合曲线R^(2)为0.9868,可检测不同个体鸡血清中PP浓度为48~55 pg/mL。而人血清中PP浓度范围波动较大。综上所述,本研究筛选到的1株纳米抗体PP-VHH,可用于检测鸡和人血清中的PP含量,为评估胰腺功能异常或诊断相关疾病提供基础。