Preparation and characterization of a single-domain antibody specific for the porcine epidemic diarrhea virus spike protein

✅ 全文

猪流行性腹泻病毒刺突蛋白单域抗体的制备与表征

作者 Fuxiang Bao; Lixin Wang; Xinxin Zhao; Ting‐Jang Lu; Abdelaziz NA; Xuefei Wang; Jinshan Cao; Yanan Du 期刊 AMB Express 发表日期 2019 ISSN 2191-0855 DOI 10.1186/s13568-019-0834-1 类型 原创研究 (Original Research)

📄 中文摘要 Chinese Abstract

中文
猪流行性腹泻(PED)是由猪流行性腹泻病毒(PEDV)引起的一种高度接触性猪病毒性疾病,以急性水样腹泻、脱水和呕吐为特征,在新生仔猪和断奶仔猪中死亡率较高。PEDV的刺突蛋白在病毒附着和细胞融合中起关键作用,其S1亚基含有主要的中和表位,使其成为疫苗研发和诊断的关键靶点。尽管已有疫苗,但对新生仔猪的有效保护仍然有限,凸显了改进诊断工具和治疗药物的必要性。

📋 英文结构化总结 English Structured Summary

全文整理

EN

Background:

Porcine epidemic diarrhea (PED) is a highly contagious viral disease of swine caused by porcine epidemic diarrhea virus (PEDV), characterized by acute watery diarrhea, dehydration, and vomiting, with high mortality in neonatal and postweaning piglets. The spike protein of PEDV plays a critical role in viral attachment and cell fusion, and its S1 subunit contains major neutralizing epitopes, making it a key target for vaccine development and diagnostics. Despite existing vaccines, effective protection for newborn piglets remains limited, highlighting the need for improved diagnostic tools and therapeutic agents.

Methods:

A healthy Alashan Bactrian camel was immunized with inactivated PEDV strain CV777, and peripheral blood mononuclear cells (PBMCs) were collected to construct a phage display single-domain antibody (sdAb) library. The VHH gene fragments were amplified via nested PCR, cloned into the pCANTAB 5E vector, and transformed into *E. coli* TG1. The resulting library was panned against purified recombinant PEDV spike protein (amino acids 444–770) expressed from the pET-28a vector. Specific sdAbs were enriched through three rounds of biopanning, and positive clones were identified by phage ELISA. One high-binding clone, S7, was selected for soluble expression in *E. coli* using a modified pET-25b vector fused to a streptavidin-binding protein (SBP) tag.

Results:

The constructed sdAb phage display library had a size of 3.4 × 10⁶. After three rounds of panning, 20 out of 96 randomly selected clones showed strong binding to the PEDV spike protein. The S7 sdAb was expressed solubly in *E. coli* with an expected molecular weight of ~20 kDa and purified under native conditions. ELISA confirmed that S7 specifically bound the spike protein even at 1 μg/ml, with no cross-reactivity to irrelevant His-tagged proteins. Immunocytochemistry demonstrated that S7 effectively stained PEDV-infected Vero cells, while uninfected cells showed no signal. However, neutralization assays revealed no significant reduction in viral infectivity across tested concentrations (12.5–100 μg/ml).

Data Summary:

The antibody library size was 3.4 × 10⁶ CFU; after three rounds of panning, phage recovery increased 30-fold compared to the first round. In ELISA, S7 exhibited strong binding to the spike protein at concentrations as low as 1 μg/ml. Neutralization tests showed TCID₅₀ values ranging from 10⁵ to 10⁵.²⁵/0.1 ml across all S7 concentrations, comparable to the PBS control (TCID₅₀ = 10⁵.²⁵), indicating no neutralizing activity.

Conclusions:

This study successfully generated a PEDV spike protein-specific single-domain antibody (S7) from an immunized Bactrian camel. The S7 antibody demonstrates high specificity and strong binding affinity to the PEDV spike protein in both ELISA and immunofluorescence assays, enabling clear detection of PEDV in infected cells. However, it lacks neutralizing activity, limiting its use as a therapeutic agent but supporting its potential as a diagnostic or imaging tool.

Practical Significance:

The S7 sdAb, especially when fused with the SBP tag for simplified detection via streptavidin-based systems, holds promise as a nanoprobe for developing sensitive diagnostic assays for PEDV or for tracing viral localization in host cells to study virus–host interactions in research settings.

📋 中文结构化总结 Chinese Structured Summary

中文

背景:

猪流行性腹泻(PED)是由猪流行性腹泻病毒(PEDV)引起的一种高度接触性猪病毒性疾病,以急性水样腹泻、脱水和呕吐为特征,在新生仔猪和断奶仔猪中死亡率较高。PEDV的刺突蛋白在病毒附着和细胞融合中起关键作用,其S1亚基含有主要的中和表位,使其成为疫苗研发和诊断的关键靶点。尽管已有疫苗,但对新生仔猪的有效保护仍然有限,凸显了改进诊断工具和治疗药物的必要性。

方法:

用灭活的PEDV CV777株免疫健康的阿拉善双峰驼,采集外周血单核细胞(PBMCs)构建噬菌体展示单域抗体(sdAb)文库。通过巢式PCR扩增VHH基因片段,将其克隆至pCANTAB 5E载体并转化入大肠杆菌TG1。将所得文库针对由pET-28a载体表达的纯化重组PEDV刺突蛋白(第444–770位氨基酸)进行筛选。通过三轮生物淘选富集特异性sdAb,并通过噬菌体ELISA鉴定阳性克隆。选取一个高结合力克隆S7,使用融合链霉亲和素结合蛋白(SBP)标签的改良pET-25b载体在大肠杆菌中进行可溶性表达。

结果:

所构建的sdAb噬菌体展示文库大小为3.4 × 10⁶。经过三轮淘选后,96个随机挑选的克隆中有20个对PEDV刺突蛋白表现出强结合力。S7 sdAb在大肠杆菌中以约20 kDa的预期分子量可溶性表达,并在天然条件下纯化。ELISA证实,即使在1 μg/ml浓度下,S7仍能特异性结合刺突蛋白,且与无关的His标签蛋白无交叉反应。免疫细胞化学显示,S7能有效染色PEDV感染的Vero细胞,而未感染细胞无信号。然而,中和试验显示,在测试浓度(12.5–100 μg/ml)范围内,病毒滴度未见显著降低。

数据总结:

抗体文库大小为3.4 × 10⁶ CFU;经过三轮淘选后,噬菌体回收率较第一轮提高了30倍。在ELISA中,S7在低至1 μg/ml的浓度下即表现出对刺突蛋白的强结合力。中和试验显示,在所有S7浓度下,TCID₅₀值范围为10⁵至10⁵.²⁵/0.1 ml,与PBS对照组(TCID₅₀ = 10⁵.²⁵)相当,表明无中和活性。

结论:

本研究成功从免疫双峰驼中获得了针对PEDV刺突蛋白的特异性单域抗体(S7)。S7抗体在ELISA和免疫荧光试验中均表现出对PEDV刺突蛋白的高特异性和强结合亲和力,能够清晰检测感染细胞中的PEDV。然而,该抗体缺乏中和活性,限制了其作为治疗药物的应用,但支持其作为诊断或成像工具的潜力。

实际意义:

S7 sdAb,尤其是与SBP标签融合后可通过链霉亲和素系统简化检测,有望作为纳米探针用于开发PEDV高灵敏诊断方法,或在研究环境中追踪病毒在宿主细胞中的定位,以研究病毒-宿主相互作用。

📖 英文全文 English Full Text

EN

AMB Express AMB Express 3814 phenaturepg AMB Express 2191-0855 pmc-is-collection-domain yes pmc-collection-title Springer Nature - PMC COVID-19 Collection PMC6626092 PMC6626092.2 6626092 7100282 31300902 10.1186/s13568-019-0834-1 834 2 Original Article Preparation and characterization of a single-domain antibody specific for the porcine epidemic diarrhea virus spike protein Bao Fuxiang 1 2 Wang Lixin 1 Zhao Xinxin 1 Lu Ting 1 Na A. Mi 1 Wang Xuefei 1 Cao Jinshan + 86 04714309175 jinshancao@imau.edu.cn 1 2 Du Yanan + 86 04714309175 yanandu@126.com 1 2 1 0000 0004 1756 9607 grid.411638.9 College of Veterinary Medicine, Inner Mongolia Agricultural University, No. 306, Zhaowuda Road, Saihan District, Huhhot, 010018 China 2 0000 0004 0369 6250 grid.418524.e Key Laboratory of Clinical Diagnosis and Treatment Techniques for Animal Disease, Ministry of Agriculture (LDTA), Huhhot, China 12 7 2019 2019 9 354895 104 23 6 2019 5 7 2019 12 07 2019 28 07 2019 23 04 2024 6626092 10.1186/s13568-019-0834-1 1 12 07 2019 7100282 10.1186/s13568-019-0834-1 2 12 07 2019 © The Author(s) 2019 Open Access This article is distributed under the terms of the Creative Commons Attribution 4.0 International License ( http://creativecommons.org/licenses/by/4.0/ ), which permits unrestricted use, distribution, and reproduction in any medium, provided you give appropriate credit to the original author(s) and the source, provide a link to the Creative Commons license, and indicate if changes were made. Porcine epidemic diarrhea (PED) is a diarrheal disease of swine caused by porcine epidemic diarrhea virus (PEDV). It is characterized by acute watery diarrhea, dehydration and vomiting in swine of all ages and is especially fatal for neonatal and postweaning piglets. The spike protein of PEDV plays an important role in mediating virus attachment and fusion to target cells, and recent studies also reported that the neutralizing epitopes of the spike protein were mainly located in the S1 subunit, which makes it a candidate for vaccine development and clinical diagnosis. In this study, we successfully constructed an immune phage display single-domain antibody library with a library size of 3.4 × 10 6 . A single-domain antibody, named S7, specific for the spike protein of PEDV was identified from the phage display single-domain antibody library. S7 could be expressed in a soluble form in E. coli , bound to the spike protein of PEDV in ELISA and stained the PEDV virus in Vero cells, but it showed no neutralization activity on PEDV. These results indicated the potent application of the S7 antibody as an imaging probe or as a candidate for the development of a diagnostic assay. Electronic supplementary material The online version of this article (10.1186/s13568-019-0834-1) contains supplementary material, which is available to authorized users. Keywords Porcine epidemic diarrhea virus (PEDV) Spike protein Bactrian camel Single-domain antibody Nanobody Phage display antibody library Immunofluorescence Neutralization activity http://dx.doi.org/10.13039/501100001809 National Natural Science Foundation of China 81660297 Bao Fuxiang Research Program of Science and Technology at Universities of Inner Mongolia Autonomous Region NJZY069 Bao Fuxiang The Innovation Fund for Young Talent at College of Veterinary Medicine, Inner Mongolia Agricultural University 2015QNJJ01 Bao Fuxiang pmc-status-qastatus 0 pmc-status-live yes pmc-status-embargo no pmc-status-released yes pmc-prop-open-access yes pmc-prop-olf no pmc-prop-manuscript no pmc-prop-legally-suppressed no pmc-prop-has-pdf yes pmc-prop-has-supplement yes pmc-prop-pdf-only no pmc-prop-suppress-copyright no pmc-prop-is-real-version no pmc-prop-is-scanned-article no pmc-prop-preprint no pmc-prop-in-epmc yes issue-copyright-statement © The Author(s) 2019 Introduction Porcine epidemic diarrhea (PED) is a diarrheal disease of swine caused by the porcine epidemic diarrhea virus (PEDV). It is characterized by acute watery diarrhea, dehydration and vomiting in swine of all ages and is especially fatal for neonatal and postweaning piglets. The disease was first described in Europe in the early seventies, and the PEDV virus was first isolated in Belgium and the United Kingdom in 1978. Since the nineties, several outbreaks have been reported in Asian countries, such as South Korea, China and Japan, and they have been characterized by relatively high mortality rates ranging from 50 to 95%, causing severe damage to the swine industry (Lee 2015 ; Song et al. 2015b ). In the late autumn of 2010, a large-scale outbreak of diarrhea characterized by severe watery diarrhea, dehydration with high morbidity and mortality emerged in a swine farm in southern China, and it has affected an estimated millions of piglets and greatly threatened the global swine industry. The accumulated evidence suggests that the causative agent of the disease was PEDV with a possible variation (Li et al. 2012 ; Song et al. 2015a ; Tian et al. 2013 ). PEDV is a member of the family Coronaviridae and has a single-stranded, positive-sense RNA genome. PEDV mainly infects piglets and can infect several cell lines in vitro, such as Vero cells. The complete genome of PEDV comprises approximately 280,000 nucleotides (nt) with 5′ and 3′ ends containing untranslated regions (UTRs). The remaining genomic sequences contain seven open reading frames (ORFs) and encode four proteins: spike (S), envelope (E), membrane (M) and nucleoprotein (N) (Rasmussen et al. 2018 ; Yang et al. 2014 ). The spike protein of PEDV is a type one membrane glycoprotein consisting of the N terminal S1 and C terminal S2 subunits and plays an important role in mediating virus attachment and fusion to target cells. The spike protein contains a multidomain architecture and has been reported to bind to carbohydrate (sialic acid) and aminopeptidase N molecules in porcine cells (Li et al. 2016 ; Meng et al. 2014 ; Sun et al. 2018 ). The neutralizing epitopes of the spike protein were identified in recent studies, and that suggested that the epitopes were mainly located in the S1 subunit (Chang et al. 2019 ; Li et al. 2017 ). The recombinant expressed S1 protein can also induce protective immunity in piglets (Makadiya et al. 2016 ; Oh et al. 2014 ). These factors make the spike protein of PEDV a putative candidate for developing an efficient protective vaccine. Although there has been some success in developing a vaccine for PEDV, it is noteworthy that no effective vaccine is available in the market to protect newborn piglets. An attenuated vaccine has been designed for use in sows to protect neonatal piglets in some Asian countries; however, the efficiency of the vaccine still needs to be verified (Paudel et al. 2014 ; Song et al. 2007 ). Passive immunization by oral administration of egg yolk antibodies (IgY) obtained from immunized chickens and the colostrum obtained from immunized cows has been shown to prevent and treat PEDV infection in newborn piglets (Lee et al. 2015 ). Early diagnosis and corresponding prevention and treatment measures are key points for managing PEDV infection, which requires effective antibodies for both diagnostic assays and treatment. In this study, we immunized the Alashan Bactrian camel with PEDV and established a phage display antibody library. The spike protein of PEDV was cloned, expressed and purified and was used as the antigen to enrich and select a virus-specific single-domain antibody (sdAb). The PEDV-specific single-domain antibody was expressed and purified, and the specificity of the antibody was determined. Materials and methods Expression and purification of the PEDV spike protein Based on the published spike protein gene sequences of the PEDV CV777 strain and its antigenic properties, we designed a pair of primers (S1 and S2) to anneal to truncated PEDV spike protein 444–770 amino acid and added the Eco RI and Xho I restriction sites at the end of the sequences (Table  1 ). PEDV virus strain CV777 (obtained from Wuhan Institute of Virology, China Academy of Sciences) genomic RNA was extracted from the PEDV-infected Vero cell culture medium with TRIzol reagent (Invitrogen, USA), and the first strand cDNA was synthesized with the GoScript Reverse Transcription System (Promega, USA). The truncated S gene sequence was amplified by PCR, cloned into the pET-28a vector by Eco RI and Xho I (TaKaRa, Japan) digestion and ligation, and transformed into E. coli Transetta-DE3 (Transgene, Beijing, China). Expression of the recombinant proteins was induced by 1 mM IPTG and analyzed by SDS-PAGE electroporation, after which the proteins were purified by Ni–NTA Agarose (Qiagen, Germany) under denaturing conditions. The purified S protein was transformed onto a PVDF membrane (Bio-Rad, USA) for further western blot detection by incubation with Rabbit Anti-6× His Polyclonal Antibody (Sangon Biotech, Shanghai, China) at a 1:2000 dilution in PBS and then with 1:20,000 PBS-diluted Goat Anti-Rabbit IgG Antibody (GenScript, Nanjing, China). The protein band was visualized with ImageQuant LAS 4000 (GE Healthcare, USA) by adding the Pierce™ ECL Western Blotting Substrate (Thermo Scientific, USA) onto the membrane. Table 1 PCR primers Primers Sequences S1 5′-CGGAATTCGCACCTGCCGTCGTTGTT-3′ S2 5′-CTAGCTCGAGACCGTACTTGGTGATGACAAT-3′ P1 5′-GTCCTGGCTGCTCTTCTACAAGG-3′ P2 5′-GGTACGTGCTGTTGAACTGTTCC-3′ P3 5′-CCAGCCGGCCATGGCTGAKTBCAGCTGGTGGAGTCTGG-3′ P4 5′-GGACTAGTGCGGCCGCTGAGGAGACRGTGACCWGGGT-3′ P5 5′-ATCTTAATTACTGGCCCAGCCGGCCATGGCTGAKGTB CAGCTGCAGGCGTCTGGRGGAGG-3′ P6 5′-ATTGCGTCAGCTATTAGTGCGGCCGCTGAGGAGACRGTGACCWGGGTCC-3′ R1 5′-CCATGATTACGCCAAGCTTTGGAGCC-3′ R2 5′-CCATGATTACGCCAAGCTTTGGAGCC-3′

Bactrian camel immunization A healthy 5-year-old female Alashan Bactrian camel was chosen for PEDV immunization. The cell culture medium containing 10 5  pfu/ml PEDV strain CV777 inactivated by formaldehyde was mixed with equal volume of Freund’s Complete Adjuvant (FCA) (Sigma-Aldrich, USA) and subcutaneously injected into the camel cervical area for the first immunization, and Freund’s Incomplete Adjuvant (FIA) (Sigma-Aldrich, USA) was used for the second and third immunizations. The time interval between immunizations was 10 days, and the camel blood was taken from the jugular vein 10 days after each injection to prepare the serum for evaluation of the PEDV heavy chain antibody (IgG2) titer. The camel was farmed in the isolated Gobi area of the Alxa Left Banner in Inner Mongolia and was provided free access to water and food. The experimental procedures were performed in accordance with the institutional and national guidelines and regulations and were approved by the Animal Care and Use Committee of Inner Mongolia Agriculture University. Construction and screening of Bactrian camel phage display antibody library One hundred fifty milliliters of blood was taken from the jugular vein of the immunized camel, and peripheral blood monocytes (PBMCs) were obtained with a PBMC isolation kit (TBD science, Tianjin Haoyang Biological Manufacture CO., LTD) according to the manufacturer’s instructions. Total RNA was extracted from the PBMCs with TRIzol reagent (Invitrogen, USA), and first strand cDNA was synthesized with the GoScript™ Reverse Transcription System (Promega, USA) by using Oligo (dT) 12–18 (Invitrogen, USA). The VHH fragment was amplified with a nested PCR method by using the primers listed in Table  1 . In the first round of PCR, a fragment containing the leader sequence to the CH 2 region of the IgG (900 bp for VH and 600 bp for VHH) was amplified with primers P1 and P2, and the 600 bp fragment was purified by 1% agarose gel electroporation and used as the template for the second round of PCR. The second round of PCR with primers P3 and P4, which anneal to the VHH FR1 and FR4 regions, respectively, amplified the VHH. Sfi I and Not I restrictions sites were introduced in the VHH fragment by the third round of PCR with primers P5 and P6. The PCR-amplified VHH fragments were digested by Sfi I and Not I (New England Biolabs, UK) and ligated into the pCANTAB 5E plasmid (GE Healthcare, USA), cleaved by the same restriction enzymes, with T4 ligase (New England Biolabs, UK). The ligation products were electro-transformed into competent E. coli TG1 for antibody library construction. The antibody library size was estimated by calculating the colony forming units (CFU) of 10 serial dilutions of the library on a 2 × YT-AG plate, and the electro-transformation efficiency was evaluated by the PCR method with the pCANTAB 5E phagemid vector sequencing primers R1 and R2 (Table  1 ). The antibody library was diluted in 2 × YT medium containing 100 μg/ml ampicillin and 2% glucose to an OD 600 nm  = 0.3 and incubated at 37 °C for 1 h with 250 r/min agitation. Recombinant phages were rescued by superinfection of bacteria with M13K07 helper phage (GE Healthcare), and the phages were purified by adding 1/5 volume of PEG/NaCl on ice for 1 h and centrifuged at 4 °C for 20 min at 10,000 g . Then, the phage pellets were resuspended in PBS and filtered through a 0.22 μm membrane for further screening. Afterwards, 100 μl 1 × 10 11  pfu/ml of recombinant phages was mixed with an equal volume of 2% skimmed milk solution and added to a 96-well Stripwel microplate (Corning, USA) coated with S protein at 20 μg/ml and incubated at RT for 1 h. The bound phages were eluted with 100 μl of 100 mM triethylamine and neutralized with 50 μl of 1 M Tris–HCl. Half of the eluted phages were added to 10 ml E. coli TG1 (OD 600 nm  = 0.5), and then 10 9  cfu/ml of M13K07 was added. The culture medium was changed to 100 ml 2 × YT medium containing 100 μg/ml ampicillin and 70 μg/ml kanamycin. The phages were harvested and purified with PEG/NaCl for a new round of enrichment. The E. coli TG1 cells infected with the eluted phages from the third round of enrichment were grown on 2 × YT-AG plates. Individual clones with target specificity were identified with phage ELISA. Briefly, 10 μg/ml of S protein was coated on the Stripwel microplate overnight at 4 °C. After blocking with 2% skimmed milk solution, 100 μl of recombinant phages prepared from 48 randomly picked clones were added to each well, and M13K07 helper phage was used as a negative control and PBS was used as a blank control. Then, 100 μl of HRP/anti-M13 monoclonal antibody (GE Healthcare, USA) was added to each well, followed by TMB substrate (Promega, USA) for visualization. The plate was read at 450 nm in a microplate reader, and absorbance of experimental group/negative control ≥ 2.1 was considered positive. Expression and purification of the sdAb The plasmids of the positive clones from phage ELISA were isolated, and the VHH gene was digested with Nco I and Not I and ligated to a modified pET-25b vector that contained the 38-amino acid sequence of streptavidin binding protein (SBP) between the Not I and Xho I restriction sites (Additional file 1 : Fig. S1) The resulting vector was transformed into competent E. coli Transetta-DE3 (Transgene, Beijing, China). Expression of the recombinant sdAb was induced by 1 mM IPTG, and then the proteins were purified by the Ni–NTA Agarose (Qiagen, Germany) under native conditions. The expression and purification of the sdAb was analyzed by SDS-PAGE electroporation and western blot with HRP-streptavidin (Solarbio Life Sciences, Beijing, China). Binding activity and specificity of the sdAb Different concentrations of the purified recombinant sdAb were added to a 10 μg/ml S protein-coated 96-well Stripwell microplate (Corning, USA), and the protein extracted from the bacterial cells transformed with the empty pET-25b vector containing both an SBP-tag and a 6× His tag was used as a negative control. PBS was used as a blank control. The binding activity of each well was detected with HRP-streptavidin (Solarbio Life Sciences, Beijing, China) at a 1:10,000 concentration and visualized with the TMB solution, and the plate was read at 450 nm in a microplate reader. Immunocytochemistry Vero cells (obtained from Wuhan Institute of Virology, China Academy of Sciences) were seeded on a petri dish, infected with 1 ml of PEDV mixed with 1 ml of pancreatin (10 μg/ml) and incubated at 37 °C for 1 h. The supernatant was removed, and the cells were incubated with Dulbecco’s modified Eagle medium (DMEM) containing 1% fetal bovine serum (Gibco, USA) at 37 °C with 5% CO 2 for 48 h. The culture medium was removed from cells when the cytopathic effect (CPE) reached 50–70%. The cells were washed with PBS once, fixed with 4% paraformaldehyde (Solarbio, Beijing, China) for 10 min, washed with PBST three times and blocked with 3% BSA at 37 °C for 1 h. The fixed cells were incubated with 150 μg purified recombinant sdAb diluted in PBS at 4 °C overnight, and an equal volume of PBS was added to another dish of infected cell to use as a negative control. After three washes, the cells were incubated with 1:300 diluted FITC-streptavidin (Solarbio, Beijing, China) at 37 °C for 30 min and washed with PBST five times. The cell nuclei were stained with 4,6-diamidino-2-phenylindole (DAPI) solution for 5 min at room temperature and washed five times with PBST, and fluorescent signals were detected by confocal microscopy (ZEISS, LSM-800). Neutralizing activity The purified recombinant sdAb was used in a microtiter neutralization assay in Vero cells. Recombinant sdAb at 100, 50, 25 and 12.5 μg/ml final concentrations were incubated with 100 times the tissue culture infectious dose 50 (TCID 50 ) of PEDV strain CV777 at 37 °C for 1 h and added to the Vero cells in 96-well plates for 72 h. Cells incubated with PBS were used as a negative control. The cytopathic effect and the neutralization activity of the recombinant sdAb antibody were calculated by comparing the changes in the TCID 50 value. All experiments were repeated three times. Statistical analysis GraphPad Prism 6.0 (GraphPad Software, Inc., La Jolla, CA, USA) was used for all univariate statistical analyses. The date of neutralization activity was presented as the mean value ±  SEMs and analyzed by Student’s t -test. * P values < 0.05 were considered to be significant. Results Expression and purification of PEDV spike protein The truncated spike gene of PEDV was PCR amplified with a pair of specific primers. A single specific gene fragment with a molecular weight of approximately 1000 bp was obtained from the amplification as shown in Fig.  1 a, and the sequencing result showed that the gene fragment corresponded to the 1330–2310 bp of the PEDV spike protein gene (444–770 amino acids, data not shown). The recombinant spike protein with a 36.5 kDa molecular weight was expressed in the periplasm of E. coli in soluble form by ligating the gene fragment to the pET-28a vector and transforming it in E. coli . After purification with a Ni–NTA Agarose, we successfully obtained a high-purity recombinant spike protein as shown by SDS-PAGE analysis in Fig.  1 b, and by western blotting analysis using an anti-6× His tag antibody (Fig.  1 c). Fig. 1 Cloning, expression and purification of the PEDV spike protein. a PCR amplification of the truncated spike gene of PEDV corresponding to the 1330–2310 bp of the spike protein gene (444–770 amino acids). Lanes 1–2, PCR amplification products of the PEDV spike gene. b SDS-PAGE analysis of the expression and purification of the PEDV spike protein. Lanes 1–2, the supernatant of E. coli cell lysate that were transformed with the PEDV spike protein gene after induction. Lanes 3–4, PEDV spike protein eluted from Ni–NTA Agarose. c Western blot analysis of the PEDV spike protein with an anti-6× His antibody. Lanes 1–2, the purified PEDV spike protein. Lane M, molecular weight marker

Construction and screening of a single-domain antibody phage display library The diagram of the construction and screening of a single-domain antibody phage display library is indicated in Fig.  2 . The PCR-amplified VHH gene was ligated into the pCANTAB 5E plasmid and transformed into E. coli TG1, and 5.49 × 10 6 transformants were obtained. We randomly picked 24 clones and amplified them with the R1 and R2 pCANTAB 5E sequencing primers, and the results showed that 15 clones were obtained from the ~ 400 bp amplicons (Additional file 1 : Fig S2). We calculated the positive rate of the transformation to be 62.5%; thus, the real size of the antibody library was 3.4 × 10 6 . Fig. 2 Schematic diagram of the construction and screening of a single-domain phage display library. Peripheral blood mononuclear cells (PBMCs) were isolated from the blood samples of a Bactrian camel immunized with PEDV, and total RNA was extracted from the PBMCs and reverse transcribed to cDNA. The VHH gene fragments with restriction enzyme sequences were amplified with nested PCR. In the first round of PCR, the gene fragment (~ 600 bp) containing the VHH, hinge region and CH2 domain was amplified from the cDNA, and then the VHH gene was amplified by a pair of primers specific for VHH gene FR1 to FR4 using the product of the first PCR (600 bp product). Sfi I and Not I restriction sites were added on the third round of PCR. The VHH gene was ligated into the pCANTAB 5E plasmid and transformed into E. coli TG1, and after rescue by the M13K07 helper phage, the VHH gene was displayed on the phage surface. The PEDV spike protein-specific phages were enriched by three rounds of biopanning

After rescue by M13K07 helper phage, the phage display antibody library was screened against PEDV spike protein by three rounds of panning. The enrichment factor of the output to input phage was increased with the panning procedure and with a 30-fold increase in phage recovery after the third round of panning compared with the first round (Table  2 ). We randomly picked 96 clones from the third elution to evaluate the binding activity to the spike protein by phage ELISA, and 20 these clones showed high OD 450 nm values (Fig.  3 ). Table 2 Enrichment of sdAb-displaying phage by panning with the spike protein of PEDV Round Input (clones) Output (clones) Enriching factor a 1 5 × 10 9 1 × 10 6 2 × 10 −4 2 5 × 10 9 6 × 10 7 1.2 × 10 −2 3 5 × 10 9 3 × 10 7 6 × 10 −3 a Enriching factor = Output (clones)/input (clones)

Fig. 3 The PEDV spike protein-specific recombinant phages were identified by phage ELISA. The recombinant phages of 96 clones that were randomly picked from the third round of panning were added to microplates coated with the PEDV spike protein, and the bound phages were detected with HRP/anti-M13 monoclonal antibody. M13K07 helper phage was used as a negative control

Expression and purification of a recombinant sdAb We selected the S7 clones with the highest binding activity to the spike protein from phage ELISA for further expression and characterization. SDS-PAGE results showed that the recombinant S7 antibody was expressed in a soluble form in the supernatant of the cell lysate with an expected molecular weight of 20 kDa, and concentrated recombinant S7 antibody was eluted from the Ni–NTA Agarose as shown in Fig.  4 a. The purified recombinant S7 antibody was verified with HRP-streptavidin, which binds to the 38-amino acid SBP fusion partner of the sdAb in western blot analysis, and a 20-kDa specific band was detected (Fig.  4 b). Fig. 4 Expression and purification of the S7 antibody. The gene fragment of the S7 antibody was ligated into a modified pET-25b vector and fusion expression with SBP Tag. The recombinant S7 antibody was purified with Ni–NTA agarose and verified with HRP-streptavidin in western blot analysis. Lane M, molecular weight marker. Lane 1, the supernatant of E. coli cell lysate that were transformed with the S7 antibody gene after induction. Lane 2, the flow-through from Ni–NTA Agarose after incubation with the S7 antibody. Lane 3, elution 1. Lane 4, elution 2. Lane WB, western blot analysis of the purified S7 antibody

Binding activity and specificity of the recombinant sdAb The binding activity and specificity of the recombinant S7 antibody were analyzed by ELISA. The results showed that OD 450 nm values increased with increasing recombinant S7 antibody concentrations, and the S7 antibody showed a very strong binding activity to the spike protein even with a concentration of 1 μg/ml. The OD 450 nm value of the recombinant S7 antibody to an irrelevant 6× His-tagged protein was similar to that of PBS used as blank control, which indicated that the recombinant S7 antibody bound specifically to the spike protein (Fig.  5 ). Fig. 5 The binding activity and specificity of the S7 antibody were analyzed by indirect ELISA. 5, 1 and 0.2 μg/ml final concentrations of S7 antibody were added to PEDV spike protein-coated microplates, and the binding of S7 antibody was detected with HRP-streptavidin. Protein extracts from E. coli transformed with the modified pET-25b vector were used as a negative control, and PBS solution was used as a blank control

Immunocytochemistry PEDV in Vero cells was detected with the recombinant S7 antibody and visualized with FITC-streptavidin, and the fluorescent signal and images were obtained through confocal microscopy. The results showed that the PEDV virions in Vero cells could be detected by the recombinant S7 antibody outside the cell nucleus, while the PEDV-free Vero cells were not stained by the recombinant S7 antibody (Fig.  6 ). Fig. 6 Immunocytochemistry analysis of the binding activity of S7 antibody to PEDV in living cells. The Vero cells infected with PEDV were incubated with S7 antibody and subsequently detected with FITC-streptavidin ( a ), and the uninfected Vero cells were used as a negative control ( b ). Cell nuclei were stained with DAPI. The merged images showed the localization of PEDV in Vero cells ( a ), but no fluorescent signal was detected in the PEDV-free Vero cells ( b )

Neutralizing activity The effect of recombinant S7 antibody on the infectious titer of PEDV was analyzed by TCID 50 assay. The results demonstrated that the recombinant S7 antibody failed to neutralize PEDV. PEDV incubated with 100, 50, 25 and 12.5 μg/ml final concentrations of recombinant S7 antibody showed TCID 50 /0.1 ml ranging from 10 5 to 10 5.25 , which is not significantly different from the control group incubated with PBS that showed TCID 50 /0.1 ml of 10 5.25 (Fig.  7 ). Fig. 7 Neutralization activity assessment of the S7 antibody. The neutralization effect of the S7 antibody on PEDV was analyzed in Vero cells. Different concentrations of S7 antibody were incubated with PEDV, and the TCID 50 was determined by the Reed Muench method. PBS was used as a negative control

Discussion PEDV is the causative agent of porcine epidemic diarrhea, which is an acute and highly contagious viral disease of swine. Pigs of all ages and breeds are susceptible to PEDV, and infections of suckling piglets 1–5 days old were the most serious, with the highest infection rate and mortality of 100%. The main symptoms of the disease are vomiting, severe diarrhea and dehydration. The PEDV genome is a single-stranded RNA belonging to the coronavirus family. The total length of the PEDV genome is approximately 28 Kb, containing at least 7 open reading frames (Chen et al. 2019 ; Nefedeva et al. 2019 ). The spike protein of PEDV is composed of 1383 amino acids, including signal peptide (1–18 aa), neutralization epitopes (499–638 aa, 748–755 aa, 764–771 aa and 1368–1374 aa), transmembrane region (1334–1356 aa), and a short cytoplasmic region in the middle. The spike protein plays a key regulatory role in the binding of the virus to the receptor. It is involved in the binding to cell receptors and in membrane fusion, which can indirectly regulate virus invasion and stimulate the host to produce neutralizing antibodies, making it the main target for the development of novel genetically engineered vaccines and antibodies that are used for diagnostic and disease prevention and treatment (Kim et al. 2018 ). Single-domain antibodies are a unique kind of antibody that naturally lacks a light chain and the CH1 region of IgG. They are found in camelids and nurse sharks, and they possess the unique properties of small molecular size (15 kDa, 1/10 of conventional antibody), low immunogenicity, strong tissue penetrating ability, high binding affinity and good stability (Arbabi-Ghahroudi 2017 ; Greenberg et al. 1995 ; Hamers-Casterman et al. 1993 ). Due to their single-domain nature and excellent properties, sdAbs have become ideal for developing sensitive diagnostic assays, immuno-imaging probes, and immunotherapeutics, especially for infectious diseases and tumors (Beghein and Gettemans 2017 ; Iezzi et al. 2018 ; Wilken and McPherson 2018 ). Considering the broad application of sdAbs on the diagnosis and treatment of viral diseases, in this study we identified and characterized a sdAb specific for the spike protein of PEDV. We constructed a camel immune phage display library of single-domain antibodies with a library size of 3.4 × 10 6 by immunizing a Bactrian camel with PEDV, ligating the VHH gene to the pCANTAB 5E plasmid and transforming it in E. coli TG1. The truncated S gene of PEDV corresponding to the 444–770 amino acids of the PEDV spike protein, which covers most neutralizing epitopes of the spike protein, was cloned, expressed and purified to use as an antigen to screen spike protein-specific sdAbs. After three rounds of panning and selection, a spike protein-specific sdAb named S7 was selected and characterized. For convenience of detection, we fused the S7 antibody gene to an SBP-tag in the pET-25b vector. The SBP-tag is a 38-amino acid peptide and can strongly bind to streptavidin with an equilibrium dissociation constant of 2.5 nM (Keefe et al. 2001 ; Yang and Veraksa 2017 ). The S7 antibody was expressed in a soluble form in E. coli with a high yield, and the western blot results showed that HRP-streptavidin could bind to the purified recombinant S7 antibody fused to the SBP-tag. This simplified detection strategy may favor the application of sdAbs as detection agents in immunoassays or immuno-imaging and is similar to the use of quantum dots to label sdAbs for tracer materials (Modi et al. 2018 ; Wang et al. 2014 ). The specificity of the S7 antibody to the spike protein and PEDV were further assessed by ELISA, immunocytochemistry and neutralization experiments. ELISA results demonstrated that the S7 antibody could specifically bind to the spike protein with strong binding activity, even at a 1 μg/ml (50 pmol) concentration, demonstrating that the S7 antibody could strongly bind to the spike protein, which is in accordance with published data on sdAbs. Due to their excellent properties of smaller size, permeability and stability, sdAbs have been widely used as probes for immuno-imaging and diagnostic assays. In the present study, PEDV-infected Vero cells were stained with the S7 antibody followed by FITC-streptavidin in a direct immunofluorescence assay. The Vero cells infected with PEDV were nicely stained by the S7 antibody, and the control Vero cells without PEDV infection had no signal. These results suggest the potent application of the S7 antibody as a nanoprobe for the detection of PEDV in living cells. Unfortunately, we did not find any neutralization effects of the S7 antibody on PEDV infection in the current study, which suggests that the S7 antibody is not a suitable passive immunization agent or therapeutic antibody. The results were in accordance with the recent findings that antibodies raised by the spike protein of PEDV with different binding epitopes showed distinct neutralizing effects on different strains of PEDV (Li et al. 2017 ). In conclusion, a Bactrian camel immune phage display antibody library was constructed, and a PEDV spike protein-specific sdAb S7 was isolated from the library. The soluble S7 antibody fused with an SBP-tag specifically bound to the spike protein with high binding activity in an ELISA and could nicely stain the PEDV-infected Vero cells in an immunofluorescence assay but had no PEDV neutralizing activity. In brief, the S7 antibody can be a useful nanoprobe for potent application in PEDV diagnostic assays or for tracing PEDV in living cells to study virus-host interactions. Additional file

Additional file 1. Additional figures.

Publisher's Note Springer Nature remains neutral with regard to jurisdictional claims in published maps and institutional affiliations. Acknowledgements The authors thank the staff at the Animal Disease Control and Prevention Center of Alxa Left Banner for their kind help with Bactrian camel immunization and blood sampling. Authors’ contributions BFX, DYN and CJS conceived and designed the experiments. BFX, WLX, ZXX, LT, AMN, WXF, and DYN carried out the experiments. BFX, WLX, DYN and CJS analyzed the data. BFX, WLX, ZXX, LT, AMN, and WXF contributed reagents/materials/analysis tools. BFX, DYN and CJS wrote the paper. BFX, DYN and CJS contributed to the study, interpretation of the studies, Analysis of the data and review of the manuscript. BFX, DYN and CJS supervised the project. All authors read and approved the final manuscript. Funding This study was funded by the National Natural Science Foundation of China (No. 81660297), the Research Program of Science and Technology at Universities of Inner Mongolia Autonomous Region (No. NJZY069), The Innovation Fund for Young Talent at College of Veterinary Medicine, Inner Mongolia Agricultural University (No. 2015QNJJ01). Availability of data and materials Please contact the authors for all requests. Ethics approval and consent to participate Blood samples from a 5-year-old female Bactrian camel that was farmed in the Gobi Desert of the Alxa Left Banner in Inner Mongolia were collected according to the Animal Ethics Procedures and Guidelines of the People’s Republic of China. The current study was approved by the Animal Care and Use Committee of Inner Mongolia Agriculture University. Consent for publication Not applicable. Competing interests The authors declare that they have no competing interests. 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中文

# 猪流行性腹泻病毒刺突蛋白特异性单域抗体的制备与表征

## 摘要

猪流行性腹泻(PED)是由猪流行性腹泻病毒(PEDV)引起的一种猪的腹泻性疾病。该病以各年龄猪只的急性水样腹泻、脱水和呕吐为特征,对新生仔猪和断奶仔猪尤为致命。PEDV的刺突蛋白在介导病毒与靶细胞的附着和融合中发挥重要作用,近期研究还报道刺突蛋白的中和表位主要位于S1亚基,这使其成为疫苗研发和临床诊断的候选靶标。本研究成功构建了免疫噬菌体展示单域抗体文库,文库容量为3.4×10⁶。从该噬菌体展示单域抗体文库中鉴定出了一种针对PEDV刺突蛋白的单域抗体,命名为S7。S7可在大肠杆菌中以可溶形式表达,在ELISA中能与PEDV刺突蛋白结合,并能对Vero细胞中的PEDV病毒进行染色,但对PEDV未表现出中和活性。这些结果表明S7抗体在成像探针或诊断检测方法开发中具有良好的应用潜力。

**关键词:** 猪流行性腹泻病毒(PEDV);刺突蛋白;双峰驼;单域抗体;纳米抗体;噬菌体展示抗体文库;免疫荧光;中和活性

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## 引言

猪流行性腹泻(PED)是由猪流行性腹泻病毒(PEDV)引起的一种猪的腹泻性疾病。该病以各年龄猪只的急性水样腹泻、脱水和呕吐为特征,对新生仔猪和断奶仔猪尤为致命。该病于20世纪70年代初在欧洲首次被描述,PEDV病毒于1978年在比利时和英国首次被分离。自20世纪90年代以来,亚洲多个国家(如韩国、中国和日本)报告了多次疫情,死亡率相对较高,介于50%至95%之间,对养猪业造成了严重损害(Lee 2015;Song et al. 2015b)。2010年末,中国南方某猪场暴发了大规模腹泻疫情,以严重水样腹泻、高发病率和高脱水死亡率为特征,估计影响了数百万仔猪,严重威胁了全球养猪业。积累的证据表明,该疾病的病原体为PEDV,可能存在变异(Li et al. 2012;Song et al. 2015a;Tian et al. 2013)。

PEDV是冠状病毒科的成员,具有单股正链RNA基因组。PEDV主要感染仔猪,在体外可感染多种细胞系,如Vero细胞。PEDV的完整基因组约包含280,000个核苷酸(nt),5′端和3′端含有非翻译区(UTR)。其余基因组序列包含七个开放阅读框(ORF),编码四种蛋白:刺突蛋白(S)、包膜蛋白(E)、膜蛋白(M)和核蛋白(N)(Rasmussen et al. 2018;Yang et al. 2014)。

PEDV的刺突蛋白是一种I型膜糖蛋白,由N端S1亚基和C端S2亚基组成,在介导病毒与靶细胞的附着和融合中发挥重要作用。刺突蛋白具有多结构域架构,据报道可结合猪细胞中的碳水化合物(唾液酸)和氨基肽酶N分子(Li et al. 2016;Meng et al. 2014;Sun et al. 2018)。近期研究鉴定了刺突蛋白的中和表位,表明这些表位主要位于S1亚基(Chang et al. 2019;Li et al. 2017)。重组表达的S1蛋白也能在仔猪中诱导保护性免疫(Makadiya et al. 2016;Oh et al. 2014)。这些因素使PEDV的刺突蛋白成为开发高效保护性疫苗的候选靶标。

尽管PEDV疫苗研发已取得一定进展,但值得注意的是,目前市场上尚无有效疫苗可用于保护新生仔猪。在一些亚洲国家已设计了用于母猪的减毒疫苗以保护新生仔猪,但疫苗效力仍有待验证(Paudel et al. 2014;Song et al. 2007)。口服免疫鸡获得的卵黄抗体(IgY)和免疫牛获得的初乳进行被动免疫,已被证明可预防和治疗新生仔猪的PEDV感染(Lee et al. 2015)。早期诊断及相应的预防和治疗措施是管理PEDV感染的关键,这需要有效的抗体用于诊断检测和治疗。

本研究以PEDV免疫阿拉善双峰驼,建立了噬菌体展示抗体文库。对PEDV刺突蛋白进行了克隆、表达和纯化,并将其作为抗原富集和筛选病毒特异性单域抗体(sdAb)。对PEDV特异性单域抗体进行了表达和纯化,并确定了抗体的特异性。

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## 材料与方法

### PEDV刺突蛋白的表达与纯化

根据已发表的PEDV CV777株刺突蛋白基因序列及其抗原特性,设计了一对引物(S1和S2),退火至截短的PEDV刺突蛋白444–770位氨基酸,并在序列末端添加EcoRI和XhoI限制性酶切位点(表1)。使用TRIzol试剂(Invitrogen,美国)从PEDV感染的Vero细胞培养液中提取PEDV病毒株CV777(来源于中国科学院武汉病毒研究所)的基因组RNA,并使用GoScript逆转录系统(Promega,USA)合成第一链cDNA。通过PCR扩增截短的S基因片段,经EcoRI和XhoI(TaKaRa,日本)酶切和连接后克隆至pET-28a载体,并转化至大肠杆菌Transetta-DE3(Transgene,北京,中国)。用1 mM IPTG诱导重组蛋白表达,通过SDS-PAGE电泳分析,然后在变性条件下使用Ni-NTA琼脂糖(Qiagen,德国)纯化蛋白。将纯化的S蛋白转印至PVDF膜(Bio-Rad,USA),用于进一步的Western blot检测,方法为用兔抗6×His多克隆抗体(Sangon Biotech,上海,中国)以1:2000的稀释度在PBS中孵育,再用1:20,000 PBS稀释的羊抗兔IgG抗体(GenScript,南京,中国)孵育。将Pierce™ ECL Western印迹底物(Thermo Scientific,USA)加至膜上,使用ImageQuant LAS 4000(GE Healthcare,USA)显色观察蛋白条带。

**表1 PCR引物**

| 引物 | 序列 | |------|------| | S1 | 5′-CGGAATTCGCACCTGCCGTCGTTGTT-3′ | | S2 | 5′-CTAGCTCGAGACCGTACTTGGTGATGACAAT-3′ | | P1 | 5′-GTCCTGGCTGCTCTTCTACAAGG-3′ | | P2 | 5′-GGTACGTGCTGTTGAACTGTTCC-3′ | | P3 | 5′-CCAGCCGGCCATGGCTGAKTBCAGCTGGTGGAGTCTGG-3′ | | P4 | 5′-GGACTAGTGCGGCCGCTGAGGAGACRGTGACCWGGGT-3′ | | P5 | 5′-ATCTTAATTACTGGCCCAGCCGGCCATGGCTGAKGTBCAGCTGCAGGCGTCTGGRGGAGG-3′ | | P6 | 5′-ATTGCGTCAGCTATTAGTGCGGCCGCTGAGGAGACRGTGACCWGGGTCC-3′ | | R1 | 5′-CCATGATTACGCCAAGCTTTGGAGCC-3′ | | R2 | 5′-CCATGATTACGCCAAGCTTTGGAGCC-3′ |

### 双峰驼免疫

选择一头健康的5岁雌性阿拉善双峰驼进行PEDV免疫。将含有10⁵ pfu/ml经甲醛灭活的PEDV CV777株的培养液与等体积的弗氏完全佐剂(FCA)(Sigma-Aldrich,USA)混合,皮下注射至骆驼颈部区域进行首次免疫,第二和第三次免疫使用弗氏不完全佐剂(FIA)(Sigma-Aldrich,USA)。免疫间隔时间为10天,每次注射后10天从颈静脉采血制备血清,用于评估PEDV重链抗体(IgG2)效价。骆驼饲养于内蒙古阿拉善左旗的隔离戈壁地区,自由饮水和进食。实验程序按照机构和国家的指导方针和规定进行,并经内蒙古农业大学动物护理和使用委员会批准。

### 双峰驼噬菌体展示抗体文库的构建与筛选

从免疫骆驼的颈静脉采集150 mL血液,使用PBMC分离试剂盒(TBD science,天津昊阳生物制造有限公司)按照制造商说明书分离外周血单核细胞(PBMC)。使用TRIzol试剂(Invitrogen,USA)从PBMC中提取总RNA,使用GoScript™逆转录系统(Promega,USA)以Oligo(dT)₁₂₋₁₈(Invitrogen,USA)为引物合成第一链cDNA。使用表1所列引物通过巢式PCR方法扩增VHH片段。第一轮PCR以引物P1和P2扩增包含IgG前导序列至CH2区的片段(VH为900 bp,VHH为600 bp),将600 bp片段经1%琼脂糖凝胶电泳纯化后作为第二轮PCR的模板。第二轮PCR以引物P3和P4分别退火至VHH FR1和FR4区,扩增VHH。第三轮PCR以引物P5和P6在VHH片段中引入SfiI和NotI限制性酶切位点。PCR扩增的VHH片段经SfiI和NotI(New England Biolabs,UK)消化后,与经相同限制性内切酶切割的pCANTAB 5E质粒(GE Healthcare,USA)通过T4连接酶(New England Biolabs,UK)连接。将连接产物电转化至感受态大肠杆菌TG1用于抗体文库构建。通过计算文库在2×YT-AG平板上10倍系列稀释的菌落形成单位(CFU)来估算抗体文库容量,并使用pCANTAB 5E噬菌粒载体测序引物R1和R2(表1)通过PCR方法评估电转化效率。

将抗体文库在含100 μg/mL氨苄青霉素和2%葡萄糖的2×YT培养基中稀释至OD₆₀₀ = 0.3,37°C振荡(250 r/min)孵育1小时。用M13K07辅助噬菌体(GE Healthcare)超感染细菌以拯救重组噬菌体,通过在冰上加入1/5体积的PEG/NaCl孵育1小时,4°C、10,000 ×g离心20分钟纯化噬菌体。将噬菌体沉淀重悬于PBS中,经0.22 μm滤膜过滤后用于进一步筛选。

随后,将100 μL 1×10¹¹ pfu/mL的重组噬菌体与等体积2%脱脂奶溶液混合,加入以20 μg/mL S蛋白包被的96孔Stripwel微孔板(Corning,USA),室温孵育1小时。用100 μL 100 mM三乙胺洗脱结合的噬菌体,用50 μL 1 M Tris-HCl中和。将一半洗脱的噬菌体加入10 mL大肠杆菌TG1(OD₆₀₀ = 0.5),然后加入10⁹ cfu/mL的M13K07。将培养液更换为100 mL含100 μg/mL氨苄青霉素和70 μg/mL卡那霉素的2×YT培养基。用PEG/NaCl收获并纯化噬菌体,用于新一轮富集。

将第三轮富集洗脱的噬菌体感染的大肠杆菌TG1细胞在2×YT-AG平板上培养。通过噬菌体ELISA鉴定具有目标特异性的单个克隆。简言之,将10 μg/mL S蛋白在4°C过夜包被于Stripwel微孔板上。用2%脱脂奶溶液封闭后,将48个随机挑选的克隆制备的100 μL重组噬菌体加入各孔,以M13K07辅助噬菌体作为阴性对照,PBS作为空白对照。然后每孔加入100 μL HRP/抗M13单克隆抗体(GE Healthcare,USA),随后加入TMB底物(Promega,USA)显色。在微孔板读数仪上读取450 nm处的吸光度,实验组/阴性对照的吸光度比值≥2.1判定为阳性。

### sdAb的表达与纯化

从噬菌体ELISA中挑选阳性克隆提取质粒,将VHH基因用NcoI和NotI消化,连接至经改造的pET-25b载体,该载体在NotI和XhoI限制性酶切位点之间含有38个氨基酸的链霉亲和素结合蛋白(SBP)序列(附加文件1:图S1)。将所得载体转化至感受态大肠杆菌Transetta-DE3(Transgene,北京,中国)。用1 mM IPTG诱导重组sdAb表达,然后在天然条件下使用Ni-NTA琼脂糖(Qiagen,德国)纯化蛋白。通过SDS-PAGE电泳和HRP-链霉亲和素(Solarbio Life Sciences,北京,China)Western blot分析sdAb的表达和纯化。

### sdAb的结合活性与特异性

将不同浓度的纯化重组sdAb加入以10 μg/mL S蛋白包被的96孔Stripwel微孔板(Corning,USA),以转化有空pET-25b载体(含有SBP标签和6×His标签)的细菌细胞提取蛋白作为阴性对照,PBS作为空白对照。各孔用1:10,000浓度的HRP-链霉亲和素(Solarbio Life Sciences,北京,China)检测结合活性,用TMB溶液显色,在微孔板读数仪上读取450 nm处的吸光度。

### 免疫细胞化学

将Vero细胞(来源于中国科学院武汉病毒研究所)接种于培养皿中,用1 mL PEDV与1 mL胰蛋白酶(10 μg/mL)混合感染,37°C孵育1小时。去除上清,将细胞在含1%胎牛血清(Gibco,USA)的Dulbecco改良Eagle培养基(DMEM)中,37°C、5% CO₂条件下孵育48小时。当细胞病变效应(CPE)达到50%-70%时去除培养液。用PBS洗涤细胞一次,用4%多聚甲醛(Solarbio,北京,China)固定10分钟,用PBST洗涤三次,用3% BSA在37°C封闭1小时。将固定细胞与150 μg纯化重组sdAb(用PBS稀释)在4°C过夜孵育,另一皿感染细胞加入等体积PBS作为阴性对照。洗涤三次后,将细胞与1:300稀释的FITC-链霉亲和素(Solarbio,北京,China)在37°C孵育30分钟,用PBST洗涤五次。用4,6-二脒基-2-苯基吲哚(DAPI)溶液在室温染色细胞核5分钟,用PBST洗涤五次,通过共聚焦显微镜(ZEISS,LSM-800)检测荧光信号。

### 中和活性

将纯化重组sdAb用于Vero细胞微量中和试验。将终浓度为100、50、25和12.5 μg/mL的重组sdAb与100倍组织培养感染剂量50(TCID₅₀)的PEDV CV777株在37°C孵育1小时,然后加入96孔板中的Vero细胞培养72小时。以PBS孵育的细胞作为阴性对照。通过比较TCID₅₀值的变化计算细胞病变效应和重组sdAb抗体的中和活性。所有实验重复三次。

### 统计分析

使用GraphPad Prism 6.0(GraphPad Software, Inc., La Jolla, CA, USA)进行所有单变量统计分析。中和活性数据以平均值±SEM表示,采用Student's t检验分析。*P*值<0.05被认为具有统计学意义。

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## 结果

### PEDV刺突蛋白的表达与纯化

用一对特异性引物PCR扩增PEDV的截短刺突基因。如图1a所示,从扩增中获得了一个分子量约为1000 bp的特异性基因片段,测序结果显示该基因片段对应于PEDV刺突蛋白基因的1330-2310 bp(444-770位氨基酸,数据未显示)。通过将基因片段连接至pET-28a载体并转化大肠杆菌,在可溶形式下于大肠杆菌周质中表达了分子量为36.5 kDa的重组刺突蛋白。经Ni-NTA琼脂糖纯化后,成功获得了高纯度的重组刺突蛋白,SDS-PAGE分析如图1b所示,使用抗6×His标签抗体的Western blot分析如图1c所示。

**图1 PEDV刺突蛋白的克隆、表达与纯化。** a. PEDV截短刺突基因的PCR扩增,对应于刺突蛋白基因的1330-2310 bp(444-770位氨基酸)。泳道1-2,PEDV刺突基因的PCR扩增产物。b. PEDV刺突蛋白表达和纯化的SDS-PAGE分析。泳道1-2,转化有PEDV刺突蛋白基因的大肠杆菌诱导后裂解液上清。泳道3-4,从Ni-NTA琼脂糖洗脱的PEDV刺突蛋白。c. 用抗6×His抗体对PEDV刺突蛋白进行Western blot分析。泳道1-2,纯化的PEDV刺突蛋白。泳道M,分子量标准。

### 单域抗体噬菌体展示文库的构建与筛选

单域抗体噬菌体展示文库的构建与筛选示意图如图2所示。将PCR扩增的VHH基因连接至pCANTAB 5E质粒并转化至大肠杆菌TG1,获得5.49×10⁶个转化子。随机挑选24个克隆,用R1和R2 pCANTAB 5E测序引物进行扩增,结果显示15个克隆获得了约400 bp的扩增产物(附加文件1:图S2)。计算转化阳性率为62.5%,因此抗体文库的实际容量为3.4×10⁶。

**图2 单域噬菌体展示文库构建与筛选示意图。** 从PEDV免疫的双峰驼血液样本中分离外周血单核细胞(PBMC),从PBMC中提取总RNA并逆转录为cDNA。通过巢式PCR扩增含有限制性酶切位点的VHH基因片段。第一轮PCR从cDNA扩增含有VHH、铰链区和CH2区的基因片段(约600 bp),然后以第一轮PCR产物(600 bp产物)为模板,用一对特异性针对VHH基因FR1至FR4的引物扩增VHH基因。第三轮PCR添加SfiI和NotI限制性酶切位点。将VHH基因连接至pCANTAB 5E质粒并转化至大肠杆菌TG1,经M13K07辅助噬菌体拯救后,VHH基因展示在噬菌体表面。通过三轮生物淘选富集PEDV刺突蛋白特异性噬菌体。

经M13K07辅助噬菌体拯救后,通过三轮淘选针对PEDV刺突蛋白筛选噬菌体展示抗体文库。随着淘选程序的进行,输出与输入噬菌体的富集因子增加,第三轮淘选后的噬菌体回收率较第一轮提高了30倍(表2)。从第三次洗脱中随机挑选96个克隆,通过噬菌体ELISA评估其与刺突蛋白的结合活性,其中20个克隆显示出较高的OD₄₀₅值(图3)。

**表2 以PEDV刺突蛋白淘选sdAb展示噬菌体的富集情况**

| 轮次 | 输入(克隆数) | 输出(克隆数) | 富集因子ᵃ | |------|--------------|--------------|----------| | 1 | 5×10⁹ | 1×10⁶ | 2×10⁻⁴ | | 2 | 5×10⁹ | 6×10⁷ | 1.2×10⁻² | | 3 | 5×10⁹ | 3×10⁷ | 6×10⁻³ |

ᵃ 富集因子 = 输出(克隆数)/ 输入(克隆数)

**图3 通过噬菌体ELISA鉴定PEDV刺突蛋白特异性重组噬菌体。** 将从第三轮淘选中随机挑选的96个克隆的重组噬菌体加入以PEDV刺突蛋白包被的微孔板中,用HRP/抗M13单克隆抗体检测结合的噬菌体。以M13K07辅助噬菌体作为阴性对照。

### 重组sdAb的表达与纯化

从噬菌体ELISA中选择与刺突蛋白结合活性最高的S7克隆进行进一步表达和表征。SDS-PAGE结果显示,重组S7抗体以可溶形式在细胞裂解液上清中表达,预期分子量为20 kDa,浓缩的重组S7抗体从Ni-NTA琼脂糖洗脱,如图4a所示。用HRP-链霉亲和素(与sdAb融合的38个氨基酸SBP融合伴侣结合)在Western blot分析中验证纯化的重组S7抗体,检测到20 kDa的特异性条带(图4b)。

**图4 S7抗体的表达与纯化。** 将S7抗体基因片段连接至经改造的pET-25b载体并与SBP标签融合表达。用Ni-NTA琼脂糖纯化重组S7抗体,并通过HRP-链霉亲和素在Western blot分析中验证。泳道M,分子量标准。泳道1,转化有S7抗体基因的大肠杆菌诱导后裂解液上清。泳道2,S7抗体与Ni-NTA琼脂糖孵育后的流穿液。泳道3,洗脱1。泳道4,洗脱2。泳道WB,纯化S7抗体的Western blot分析。

### 重组sdAb的结合活性与特异性

通过ELISA分析重组S7抗体的结合活性和特异性。结果显示,OD₄₅₀值随重组S7抗体浓度的增加而增加,S7抗体即使在1 μg/mL的浓度下对刺突蛋白也表现出很强的结合活性。重组S7抗体与无关6×His标记蛋白的OD₄₅₀值与作为空白对照的PBS相似,表明重组S7抗体与刺突蛋白特异性结合(图5)。

**图5 通过间接ELISA分析S7抗体的结合活性和特异性。** 将终浓度为5、1和0.2 μg/mL的S7抗体加入PEDV刺突蛋白包被的微孔板中,用HRP-链霉亲和素检测S7抗体的结合。以转化有经改造pET-25b载体的大肠杆菌蛋白提取物作为阴性对照,以PBS溶液作为空白对照。

### 免疫细胞化学

用重组S7抗体检测Vero细胞中的PEDV,并用FITC-链霉亲和素显色,通过共聚焦显微镜获取荧光信号和图像。结果显示,Vero细胞中的PEDV病毒粒子可被重组S7抗体在细胞核外检测到,而未感染PEDV的Vero细胞不被重组S7抗体染色(图6)。

**图6 S7抗体与活细胞中PEDV结合活性的免疫细胞化学分析。** 将感染PEDV的Vero细胞与S7抗体孵育,随后用FITC-链霉亲和素检测(a),以未感染的Vero细胞作为阴性对照(b)。细胞核用DAPI染色。合并图像显示PEDV在Vero细胞中的定位(a),但在无PEDV的Vero细胞中未检测到荧光信号(b)。

### 中和活性

通过TCID₅₀试验分析重组S7抗体对PEDV感染滴度的影响。结果表明,重组S7抗体未能中和PEDV。与100、50、25和12.5 μg/mL终浓度的重组S7抗体孵育的PEDV的TCID₅₀/0.1 mL范围为10⁵至10⁵·²⁵,与PBS孵育的对照组(TCID₅₀/0.1 mL为10⁵·²⁵)无显著差异(图7)。

**图7 S7抗体中和活性评估。** 在Vero细胞中分析S7抗体对PEDV的中和作用。将不同浓度的S7抗体与PEDV孵育,通过Reed-Muench方法测定TCID₅₀。以PBS作为阴性对照。

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## 讨论

PEDV是猪流行性腹泻的病原体,这是一种急性、高度传染性的猪病毒性疾病。各年龄和品种的猪均对PEDV易感,其中1-5日龄哺乳仔猪的感染最为严重,感染率和死亡率最高可达100%。该病的主要症状为呕吐、严重腹泻和脱水。PEDV基因组为属于冠状病毒科的单股RNA,全长约28 Kb,含有至少7个开放阅读框(Chen et al. 2019;Nefedeva et al. 2019)。

PEDV的刺突蛋白由1383个氨基酸组成,包括信号肽(1-18 aa)、中和表位(499-638 aa、748-755 aa、764-771 aa和1368-1374 aa)、跨膜区(1334-1356 aa)以及中间的短胞质区。刺突蛋白在病毒与受体结合中起关键调控作用,参与细胞受体结合和膜融合,可间接调节病毒入侵并刺激宿主产生中和抗体,使其成为开发用于诊断和疾病预防与治疗的新型基因工程疫苗和抗体的主要靶标(Kim et al. 2018)。

单域抗体是一类独特的天然缺乏轻链和IgG CH1区的抗体,发现于骆驼科动物和护士鲨中,具有分子量小(15 kDa,为常规抗体的1/10)、免疫原性低、组织穿透能力强、结合亲和力高和稳定性好等独特特性(Arbabi-Ghahroudi 2017;Greenberg et al. 1995;Hamers-Casterman et al. 1993)。由于其单域特性和优良性能,sdAb已成为开发灵敏诊断检测方法、免疫成像探针和免疫治疗药物的理想选择,特别是在传染病和肿瘤领域(Beghein and Gettemans 2017;Iezzi et al. 2018;Wilken and McPherson 2018)。

考虑到sdAb在病毒性疾病诊断和治疗中的广泛应用,本研究鉴定并表征了一种针对PEDV刺突蛋白的sdAb。通过以PEDV免疫双峰驼,将VHH基因连接至pCANTAB 5E质粒并转化至大肠杆菌TG1,构建了文库容量为3.4×10⁶的骆驼免疫噬菌体展示单域抗体文库。克隆、表达和纯化了对应于PEDV刺突蛋白444-770位氨基酸的截短S基因(该区域覆盖了刺突蛋白的大部分中和表位),作为抗原用于筛选刺突蛋白特异性sdAb。经过三轮淘选和筛选,选择并表征了一种名为S7的刺突蛋白特异性sdAb。

为便于检测,我们将S7抗体基因与pET-25b载体中的SBP标签融合。SBP标签是一个38个氨基酸的肽段,能以2.5 nM的平衡解离常数与链霉亲和素强结合(Keefe et al. 2001;Yang and Veraksa 2017)。S7抗体在大肠杆菌中以可溶形式高效表达,Western blot结果显示HRP-链霉亲和素可与融合有SBP标签的纯化重组S7抗体结合。这种简化的检测策略可能有利于sdAb作为检测试剂在免疫分析或免疫成像中的应用,类似于使用量子点标记sdAb作为示踪材料(Modi et al. 2018;Wang et al. 2014)。

通过ELISA、免疫细胞化学和中和实验进一步评估了S7抗体对刺突蛋白和PEDV的特异性。ELISA结果表明,S7抗体能以强结合活性与刺突蛋白特异性结合,即使在1 μg/mL(50 pmol)的浓度下也是如此,证明S7抗体与刺突蛋白强结合,这与已发表的sdAb数据一致。由于其尺寸小、渗透性和稳定性等优良特性,sdAb已被广泛用作免疫成像和诊断检测的探针。在本研究中,在直接免疫荧光试验中,以S7抗体染色PEDV感染的Vero细胞,随后用FITC-链霉亲和素检测。S7抗体能很好地染色PEDV感染的Vero细胞,而未感染PEDV的对照Vero细胞无信号。这些结果表明S7抗体作为纳米探针在活细胞中检测PEDV方面具有良好的应用潜力。

遗憾的是,在本研究中未发现S7抗体对PEDV感染的任何中和作用,这表明S7抗体不适合作为被动免疫剂或治疗性抗体。该结果与近期研究结果一致,即由PEDV刺突蛋白诱导的针对不同结合表位的抗体对不同PEDV毒株表现出不同的中和效果(Li et al. 2017)。

总之,本研究构建了双峰驼免疫噬菌体展示抗体文库,并从该文库中分离出PEDV刺突蛋白特异性sdAb S7。与SBP标签融合的可溶性S7抗体在ELISA中以高结合活性与刺突蛋白特异性结合,在免疫荧光试验中能很好地染色PEDV感染的Vero细胞,但不具有PEDV中和活性。简言之,S7抗体可作为一种有用的纳米探针,在PEDV诊断检测或活细胞中示踪PEDV以研究病毒-宿主相互作用方面具有良好应用前景。

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## 致谢

感谢阿拉善左旗动物疫病预防控制中心工作人员在双峰驼免疫和血液采样方面的友好帮助。

## 作者贡献

BFX、DYN和CJS构思并设计了实验。BFX、WLX、ZXX、LT、AMN、WXF和DYN进行了实验。BFX、WLX、DYN和CJS分析了数据。BFX、WLX、ZXX、LT、AMN和WXF提供了试剂/材料/分析工具。BFX、DYN和CJS撰写了论文。BFX、DYN和CJS参与了研究、研究解释、数据分析和论文审阅。BFX、DYN和CJS监督了项目。所有作者阅读并批准了最终稿件。

## 基金资助

本研究由中国国家自然科学基金(No. 81660297)、内蒙古自治区高等学校科学研究项目(No. NJZY069)和内蒙古农业大学兽医学院青年创新人才基金(No. 2015QNJJ01)资助。

## 数据可用性

所有请求请联系作者。

## 伦理批准与知情同意

按照中华人民共和国动物伦理程序和指导方针,采集了饲养于内蒙古阿拉善左旗戈壁沙漠的一头5岁雌性双峰驼的血液样本。本研究经内蒙古农业大学动物护理和使用委员会批准。

## 出版同意

不适用。

## 利益冲突

作者声明无利益冲突。