Bivalent circular RNA vaccines against porcine epidemic diarrhea virus and transmissible gastroenteritis virus

✅ 全文

针对猪流行性腹泻病毒和猪传染性胃肠炎病毒的二价环状RNA疫苗

作者 Weibing Zhang; Lei Wang; Liyu Chu; Xu Ma; Wenjing Gao; Yarong Wu; Yongfeng Qiao; Xianjun Wang; Lu Zhao; Hong Hu; Xiaoyu Li; Ding Zhang; Tao Song; Guocan Yu; Haidong Wang; Chunbo Dong; Zhida Liu 期刊 Frontiers in Immunology 发表日期 2025 卷/期/页码 Vol. 16 ISSN 1664-3224 DOI 10.3389/fimmu.2025.1562865 类型 原创研究 (Original Research)

📄 英文摘要 English Abstract

EN

Porcine Epidemic Diarrhea Virus (PEDV) and Transmissible Gastroenteritis Virus (TGEV) pose significant threats to neonatal piglets, leading to severe diarrhea and potentially lethal consequences. Beyond enforcing stringent biosecurity protocols, effective and safe vaccinations are crucial in mitigating the impact of these diseases. In this study, the PEDV S1 (PS1) and TGEV S1 (TS1) antigens were initially chosen as candidates for the development of circRNA vaccines. Recognizing the comparatively lower immunogenicity of the PS1 antigen in contrast to the TS1 antigen, we strategically conjugated the PS1 with the pig fragment crystallizable (Fc) region to form PS1F. Despite these efforts, the bivalent circRNA vaccine prepared using an equal amount of the circRNAPS1F and circRNATS1 mixture still led to a reduction in the antibody levels against PS1. Subsequent dosage optimization of these two circRNA vaccines resulted in the induction of comparable levels of antigen specific antibodies and T cell immunity. Furthermore, sequential vaccination regimen with bivalent circRNA vaccine and commercial inactivated vaccines (IAV) could elicit a predominantly Th1-driven antibody responses and effectively neutralize both PEDV and TGEV. Our findings not only provide a potential strategy for the development of bivalent or multivalent circRNA/mRNA-based vaccines but also highlight the promising application of sequential vaccination strategies within the swine industry.

📄 中文摘要 Chinese Abstract

中文
猪流行性腹泻病毒(PEDV)和猪传染性胃肠炎病毒(TGEV)是高度致病性的冠状病毒,可引起仔猪严重腹泻及高死亡率,给全球养猪业造成巨大经济损失。PEDV与TGEV共感染日益普遍,使得单一病原疫苗的防控效果不足。现有双价疫苗(通常为灭活或减毒疫苗)受限于免疫效果不佳及安全性问题。环状RNA(circRNA)疫苗因其相较于mRNA疫苗具有更高的稳定性、持续蛋白表达、较低免疫原性及成本效益高的生产优势,已成为一种有前景的替代方案。本研究旨在通过优化抗原设计和免疫剂量策略,开发一种同时靶向PEDV和TGEV的双价circRNA疫苗。

📋 英文结构化总结 English Structured Summary

全文整理

EN

Background:

Porcine Epidemic Diarrhea Virus (PEDV) and Transmissible Gastroenteritis Virus (TGEV) are highly pathogenic coronaviruses that cause severe diarrhea and high mortality in neonatal piglets, leading to substantial economic losses in the global swine industry. Co-infections of PEDV and TGEV are increasingly common, rendering single-pathogen vaccines insufficient. Current bivalent vaccines—typically inactivated or attenuated—are limited by inadequate efficacy and safety concerns. Circular RNA (circRNA) vaccines have emerged as a promising alternative due to their enhanced stability, sustained protein expression, lower immunogenicity, and cost-effective production compared to mRNA vaccines. This study aimed to develop a bivalent circRNA vaccine targeting both PEDV and TGEV using optimized antigen design and dosing strategies.

Methods:

The S1 domains of PEDV (PS1) and TGEV (TS1) were selected as immunogens. To enhance the immunogenicity of PS1, it was fused with a porcine Fc region (PS1F). circRNAs encoding PS1, TS1, and PS1F were synthesized via in vitro transcription using a permuting intron-exon (PIE) system, purified by HPLC, and encapsulated into lipid nanoparticles (LNPs). Female BALB/c mice were immunized intramuscularly with various formulations, including monovalent and bivalent circRNA vaccines, and combinations with commercial inactivated vaccines (IAV). Humoral immune responses were assessed by ELISA for antigen-specific IgG, IgG1, and IgG2a titers. T cell responses were evaluated by flow cytometry for IFN-γ+ CD8+ T cells. Neutralization assays against live PEDV and TGEV were conducted using serum from immunized mice. Safety was monitored through body weight, serum biochemistry (ALT, AST, CREA), and histopathology.

Results:

Initial testing showed that circRNATS1 induced strong antibody responses even at low doses (≥2.5 mg), whereas circRNAPS1 elicited significantly weaker responses. Fusion of PS1 with the Fc region (PS1F) dramatically enhanced its immunogenicity, achieving endpoint titers ~10⁶—comparable to TS1. However, co-administration of equal doses of circRNAPS1F and circRNATS1 led to suppressed anti-PS1 responses due to antigenic competition, despite no interference in antigen expression in vitro. Dose optimization revealed that a bivalent formulation containing 20 µg circRNAPS1F and 5 µg circRNATS1 induced robust, balanced humoral and cellular immunity against both viruses. Sequential vaccination regimens (e.g., IAV prime followed by circRNA boost) elicited Th1-biased responses and superior neutralizing activity against TGEV compared to homologous regimens.

Data Summary:

The optimized bivalent circRNA vaccine (20 µg circRNAPS1F + 5 µg circRNATS1) induced high antigen-specific IgG titers (~10⁵–10⁶) and significant IFN-γ+ CD8+ T cell responses against both PS1 and TS1. Neutralization titers against authentic PEDV and TGEV were detectable and functional. In sequential vaccination, the IAV-circRNA group showed the highest neutralization titer against TGEV (significantly elevated vs. other groups; *P* < 0.01) and a strong Th1 bias (IgG2a/IgG1 ratio >1). No significant changes in body weight, liver/kidney function markers, or tissue pathology were observed post-vaccination, confirming safety.

Conclusions:

This study successfully developed a safe and effective bivalent circRNA vaccine against PEDV and TGEV by addressing antigenic competition through Fc fusion and dose optimization. The optimized formulation induces balanced, potent humoral and cellular immune responses. Furthermore, sequential vaccination with inactivated vaccine followed by circRNA boost enhances Th1 immunity and neutralizing capacity, particularly against TGEV. These findings provide a strategic framework for developing multivalent RNA-based vaccines against co-circulating swine pathogens.

Practical Significance:

The bivalent circRNA vaccine platform offers a promising solution for controlling concurrent PEDV and TGEV infections in swine herds. Its room-temperature stability, low production cost, and strong immunogenicity make it especially suitable for veterinary applications in resource-limited settings. The demonstrated success of sequential vaccination with existing commercial vaccines supports immediate integration into current swine health management programs, potentially reducing mortality and economic losses in the global pork industry.

📋 中文结构化总结 Chinese Structured Summary

中文

背景:

猪流行性腹泻病毒(PEDV)和猪传染性胃肠炎病毒(TGEV)是高度致病性的冠状病毒,可引起仔猪严重腹泻及高死亡率,给全球养猪业造成巨大经济损失。PEDV与TGEV共感染日益普遍,使得单一病原疫苗的防控效果不足。现有双价疫苗(通常为灭活或减毒疫苗)受限于免疫效果不佳及安全性问题。环状RNA(circRNA)疫苗因其相较于mRNA疫苗具有更高的稳定性、持续蛋白表达、较低免疫原性及成本效益高的生产优势,已成为一种有前景的替代方案。本研究旨在通过优化抗原设计和免疫剂量策略,开发一种同时靶向PEDV和TGEV的双价circRNA疫苗。

方法:

选择PEDV(PS1)和TGEV(TS1)的S1结构域作为免疫原。为增强PS1的免疫原性,将其与猪Fc区融合(PS1F)。通过体外转录结合内含子-外显子重排(PIE)系统合成编码PS1、TS1和PS1F的circRNA,经HPLC纯化后包封于脂质纳米颗粒(LNPs)中。对雌性BALB/c小鼠进行肌肉注射免疫,接种方案包括单价和双价circRNA疫苗,以及与商品化灭活疫苗(IAV)的联合接种。采用ELISA检测抗原特异性IgG、IgG1和IgG2a抗体滴度以评估体液免疫应答;通过流式细胞术检测IFN-γ⁺ CD8⁺ T细胞以评价T细胞应答;利用免疫小鼠血清进行针对活PEDV和TGEV的中和试验。安全性通过体重监测、血清生化指标(ALT、AST、CREA)及组织病理学检查进行评估。

结果:

初步测试显示,circRNATS1即使在低剂量(≥2.5 mg)下即可诱导强抗体应答,而circRNAPS1诱导的应答显著较弱。将PS1与Fc区融合(PS1F)后,其免疫原性显著增强,终点滴度达约10⁶,与TS1相当。然而,尽管体外抗原表达未受干扰,等剂量共注射circRNAPS1F与circRNATS1会导致抗PS1应答受到抑制,提示存在抗原竞争。剂量优化表明,含20 µg circRNAPS1F与5 µg circRNATS1的双价制剂可诱导针对两种病毒的强而均衡的体液和细胞免疫应答。序贯免疫方案(如IAV初免后circRNA加强)可诱导Th1偏向性应答,并对TGEV产生优于同源免疫方案的中和活性。

数据总结:

优化后的双价circRNA疫苗(20 µg circRNAPS1F + 5 µg circRNATS1)可诱导高水平抗原特异性IgG滴度(约10⁵–10⁶)及显著的IFN-γ⁺ CD8⁺ T细胞应答。针对真实PEDV和TGEV的中和滴度可检测且具有功能活性。在序贯免疫中,IAV-circRNA组对TGEV的中和滴度最高(显著高于其他组;*P* < 0.01),并呈现强Th1偏向性(IgG2a/IgG1比值 >1)。免疫后未见体重、肝肾功能指标或组织病理学显著变化,证实其安全性良好。

结论:

本研究通过Fc融合与剂量优化解决抗原竞争问题,成功开发出一种安全有效的抗PEDV和TGEV双价circRNA疫苗。优化后的制剂可诱导均衡且强效的体液与细胞免疫应答。此外,采用灭活疫苗初免后circRNA加强的序贯免疫策略可增强Th1免疫及中和能力,尤其对TGEV效果显著。这些成果为开发针对共循环猪病原的多价RNA疫苗提供了战略框架。

实际意义:

该双价circRNA疫苗平台为控制猪群中PEDV与TGEV并发感染提供了有前景的解决方案。其室温稳定性、低生产成本及强免疫原性使其特别适用于资源有限地区的兽医应用。与现有商品化疫苗联合使用的序贯免疫策略已获验证,可立即整合至当前猪健康管理项目中,有望降低全球养猪业的死亡率与经济损失。

📖 英文全文 English Full Text

EN

TYPE Original Research PUBLISHED 31 March 2025 DOI 10.3389/fimmu.2025.1562865 OPEN ACCESS EDITED BY Ang Lin, China Pharmaceutical University, China REVIEWED BY

Entao Li, University of Science and Technology of China, China Yongxiang Zhao, Jiangsu Academy of Agricultural Sciences (JAAS), China *CORRESPONDENCE

Zhida Liu zhida_liu@saari.org.cn Chunbo Dong Chunbo_dong@saari.org.cn Haidong Wang wanghaidong@sxau.edu.cn Guocan Yu guocanyu@mail.tsinghua.edu.cn † These authors have contributed equally to this work

Bivalent circular RNA vaccines against porcine epidemic diarrhea virus and transmissible gastroenteritis virus Weibing Zhang 1,2†, Lei Wang 2,3†, Liyu Chu 4†, Xu Ma 1,2, Wenjing Gao 1,2, Yarong Wu 2, Yongfeng Qiao 1,2, Xianjun Wang 1,2, Lu Zhao 1,2, Hong Hu 2,5, Xiaoyu Li 2, Ding Zhang 1, Tao Song 4, Guocan Yu 6*, Haidong Wang 1*, Chunbo Dong 1,2* and Zhida Liu 1,2* 1 College of Veterinary Medicine, Shanxi Agricultural University, Jinzhong, China, 2 Shanxi Academy of Advanced Research and Innovation, Taiyuan, China, 3 Department of Biochemistry and Molecular Biology, College of Basic Medical Sciences, Shanxi Medical University, Taiyuan, China, 4 Hebei Key Laboratory of Preventive Veterinary, College of Animal Science and Technology, Hebei Normal University of Science and Technology, Qinhuangdao, China, 5 Ankerui (Shanxi) Biological Cell Co., Ltd., Taiyuan, China, 6 Key Laboratory of Bioorganic Phosphorus Chemistry & Chemical Biology, Department of Chemistry, Tsinghua University, Beijing, China

RECEIVED 18 January 2025 ACCEPTED 17 March 2025 PUBLISHED 31 March 2025 CITATION

Zhang W, Wang L, Chu L, Ma X, Gao W, Wu Y, Qiao Y, Wang X, Zhao L, Hu H, Li X, Zhang D, Song T, Yu G, Wang H, Dong C and Liu Z (2025) Bivalent circular RNA vaccines against porcine epidemic diarrhea virus and transmissible gastroenteritis virus. Front. Immunol. 16:1562865. doi: 10.3389/fimmu.2025.1562865 COPYRIGHT

© 2025 Zhang, Wang, Chu, Ma, Gao, Wu, Qiao, Wang, Zhao, Hu, Li, Zhang, Song, Yu, Wang, Dong and Liu. This is an open-access article distributed under the terms of the Creative Commons Attribution License (CC BY). The use, distribution or reproduction in other forums is permitted, provided the original author(s) and the copyright owner(s) are credited and that the original publication in this journal is cited, in accordance with accepted academic practice. No use, distribution or reproduction is permitted which does not comply with these terms.

Porcine Epidemic Diarrhea Virus (PEDV) and Transmissible Gastroenteritis Virus (TGEV) pose significant threats to neonatal piglets, leading to severe diarrhea and potentially lethal consequences. Beyond enforcing stringent biosecurity protocols, effective and safe vaccinations are crucial in mitigating the impact of these diseases. In this study, the PEDV S1 (PS1) and TGEV S1 (TS1) antigens were initially chosen as candidates for the development of circRNA vaccines. Recognizing the comparatively lower immunogenicity of the PS1 antigen in contrast to the TS1 antigen, we strategically conjugated the PS1 with the pig fragment crystallizable (Fc) region to form PS1F. Despite these efforts, the bivalent circRNA vaccine prepared using an equal amount of the circRNAPS1F and circRNATS1 mixture still led to a reduction in the antibody levels against PS1. Subsequent dosage optimization of these two circRNA vaccines resulted in the induction of comparable levels of antigen specific antibodies and T cell immunity. Furthermore, sequential vaccination regimen with bivalent circRNA vaccine and commercial inactivated vaccines (IAV) could elicit a predominantly Th1-driven antibody responses and effectively neutralize both PEDV and TGEV. Our findings not only provide a potential strategy for the development of bivalent or multivalent circRNA/mRNA-based vaccines but also highlight the promising application of sequential vaccination strategies within the swine industry.

circRNA vaccine, bivalent, porcine epidemic diarrhea virus, transmissible gastroenteritis virus, sequential vaccination Frontiers in Immunology 01 frontiersin.org Zhang et al. 10.3389/fimmu.2025.1562865

important pathogens have been under development (19–24), including vaccines against both human and animal pathogens. Since then, studies of PEDV mRNA vaccines have also been reported and produced promising immune effects (12). The primary limitation of mRNA vaccines, however, resides in their vulnerability to degradation by RNases, necessitating storage and transportation at low temperatures. This poses a significant challenge for veterinary vaccine development. It has been established that circRNAs can be translated into proteins through a cap-independent mechanism (25), which enable their potential as a robust alternative to mRNA. Unlike linear mRNA, circRNA boasts exceptional stability due to its covalently closed circular configuration. Moreover, circRNA exhibits reduced immunogenicity and maintains the capacity for sustained and potent protein expression (26, 27), even in the absence of nucleotide modifications. Additionally, the absence of the need for capping and tailing reactions in circRNA synthesis further lowers production costs. These advantages make circRNA an attractive candidate for vaccine development, particularly in the veterinary field. Indeed, several studies have already been conducted on circRNA vaccines for coronavirus, rabies and mpox etc. (28–30), demonstrating that these vaccines can retain their integrity at room temperature for up to a month and effectively stimulate robust immune responses. Given this, we developed circRNA vaccines targeting PEDV and TGEV, utilizing PS1 and TS1 as immunogens. Despite the inconsistent immunogenicity observed with individual circRNAPS1 and circRNATS1 vaccines, we successfully obtain a bivalent vaccine with optimizing the antigen design and circRNA dosage ratio. This bivalent circRNA vaccine elicited comparable levels of B and T cell responses against both PEDV and TGEV. Our findings propose a promising dual-target strategy for combating both PEDV and TGEV viral infections simultaneously in the swine industry.

1 Introduction PEDV and TGEV belong to the a-coronavirus genus and are classified as single-stranded positive-sense RNA viruses, both of which have been identified as the causative agents of pandemic swine diarrhea, leading to significant challenges in the porcine industry (1). The TGEV was initially documented in 1946 within the borders of the United States (2) and subsequently identified across Europe, Asia, Africa, and South America. The first detection of PEDV in Europe can be traced back to the early 1970s (3). Since 2010, highly pathogenic strains of PEDV have been gradually spreading within pig herds and persistently prevailing across various countries in Asia, North America, and Europe (4–8), particularly among neonatal piglets less than 10 days old who experience a mortality rate of 100% following PEDV infection (9). The widespread global distribution of both PEDV and TGEV has resulted in significant economic consequences for the global swine industry. The vaccination emerges as the most efficacious preventive measure in the face of intricate and dynamic diarrhea epidemics. Due to a severe co-infection of PEDV and TGEV, single vaccination cannot simultaneously provide protection against both virus infections (10). As a result, bivalent inactivated or attenuated live vaccines that target both PEDV and TGEV have been primarily employed for piglet protection. However, the effectiveness and safety of current vaccines are insufficient (11). Consequently, there is an urgent need to develop innovative bivalent vaccines that can offer both safety and potent efficacy against PEDV and TGEV. The surface glycoprotein (S) of PEDV and TGEV is located in the outermost layer of the virion and shares functional similarities with the S protein of Severe Acute Respiratory Syndrome Coronavirus type 2 (SARS-CoV-2). The S protein plays a crucial role in binding to host cells, making its full-length or truncated forms significant targets for vaccine development (12, 13). Studies have shown that the core neutralizing epitope (COE) region of PEDV S1 has the function of producing neutralizing antibodies, while the N-terminal domain (NTD) region serves as potential coreceptor binding regions (12). The S1 domain of TGEV comprises four antigenic sites (or two antigenic sites), namely C, B, D, and A (or NTD and RBD) (14, 15), arranged sequentially from the Nterminus to the C-terminus. Among these sites, both A and D are capable of eliciting the production of neutralizing antibodies against TGEV in the host organism (14). Consequently, extensive utilization has been made of either the full-length S protein or specific domains such as S1 or COE region in immunogenic studies pertaining to PEDV or TGEV vaccines. Recent studies have shown that mRNA vaccines have significant advantages over traditional vaccines (16), including flexibility in targeting emerging or mutated pathogens and the ability to quickly design, produce, and induce powerful immune responses (17, 18). During the COVID-19 pandemic, mRNA vaccines targeting SARSCOV-2 emerged as the pioneering choice for human immunization, significantly propelling the advancement of mRNA vaccine development, numerous mRNA vaccine candidates against other

2 Materials and methods 2.1 Plasmid construction The codon-optimized PS1, TS1, PS1F and TS1F genes were synthesized and cloned into the commercially available pCDNA3.4 plasmid by LOGENBIO Biological Company. Subsequently, the genes were integrated into a vector constructed for the synthesis of circular RNA, as per the methodology established in previous research by Wesselhoeft et al. A comprehensive description of all these sequences is provided in the Supplementary Materials.

2.2 Cells and mice Expi293F cells (Thermo Fisher Scientific) were cultured in SMM 293-TII medium (Sino Biological) at 37°C under 5% CO2 in a shaking incubator and confirmed to be free of mycoplasma 02 frontiersin.org

Zhang et al. 10.3389/fimmu.2025.1562865 contamination. 6 to 8-week-old female BALB/c mice were purchased from Beijing Vital River Laboratory Animal Technology Co., LTD. The animals were housed under specific pathogen-free conditions in the Animal Care facility of Shanxi Agricultural University. All experimental procedures are conducted in strict accordance with the standards of the Institutional Animal Care and Use Committee of Shanxi Agricultural University (SXAUEAW-2023M.DF.001017216).

2.5 Protein purification Plasmids encoding the proteins of interest were mixed with PEI at a mass ratio of 1:4 and subsequently added to the culture medium containing 2 × 106 Expi293F cells/mL. The supernatant was collected five days post-transfection and filtered through a 0.22 mm filter. PS1 and TS1 proteins were purified using a 5 mL HisTrap HP affinity column (GE Healthcare, USA), followed by further separation via gel filtration on a Superdex 200 10/300 GL column (GE Healthcare, USA). The molecular size and purity of the proteins were assessed by sodium dodecyl sulfate-polyacrylamide gel electrophoresis (SDS-PAGE).

2.3 CircRNA preparation and purification The protocol for circRNA preparation follows the method as previous described (31). In brief, plasmid templates were linearized, and the resulting products were purified for subsequent IVT using the T7 High Yield RNA Synthesis Kit (Vazyme, China) at 37°C for 2 hours. Following this, the in vitro transcribed RNA products were treated with DNase I (Takara, Japan) to eliminate residual DNA, and Recombinant RNase Inhibitor (Takara, Japan) was introduced to mitigate RNA degradation. A subsequent thermal treatment at 70°C for 5 minutes was applied, after which GTP was incorporated to a final concentration of 2 mM, followed by the execution of an RNA circularization reaction at 55°C for 30 minutes. Finally, the RNA products were column-purified and analyzed on 2% agarose gels. To purify the circRNA, a high-performance liquid chromatography (HPLC) assay was performed using a 4.6×300 mm size exclusion column with a particle size of 5 µm and pore size of 1000 Å (Sepax Technologies, USA) on an Elite EClassical 3200 Series HPLC system (Elite, China). RNA samples were run in RNase-free phosphate buffer (containing 150 mM sodium phosphate at pH 7.0) at a flow rate of 0.6 mL/minute. Detection and collection of RNA were carried out through UV absorbance measurement at a wavelength of 260 nm. Subsequently, the obtained RNA fractions underwent desalting using a dedicated column, followed by precipitation with ammonium acetate and resuspension in RNase-free water. For splice junction analysis, the EasyScript One-Step gDNA Removal and cDNA Synthesis SuperMix (TransGen, China) was utilized for reverse transcription to synthesize cDNA using purified circRNA as a template. A standard PCR protocol with specific primer pairs spanning the splice junction of putative circRNA was utilized to amplify PCR products from synthetic cDNA templates. Then, these PCR products were cloned into pUC57 vectors for subsequent sequencing analysis.

2.6 CircRNA encapsulation The circRNAs were encapsulated into lipid nanoparticles (LNPs) as previously delineated (31). Briefly, the aqueous phase containing circRNAs was mixed with an ethanolic solution of lipids and cholesterol in a microfluidic device at a ratio of 1:3 (v/v). Then, the circRNA@LNP complexes were subjected to dialysis in PBS for 12 hours (MWCO = 3.5 kDa). The size of LNP-circRNA complex was determined using dynamic light scattering (DLS) on Zetasizer Nano (Malvern Instruments, UK) and the morphology assays were carried out on a Hitachi HT-7700 transmission electron microscope (Hitachi, Japan).

2.7 Mouse immunization The 6-8-week-old female BALB/c mice were immunized intramuscularly. The vaccination regimens and dosages of the commercial inactivated vaccine and circRNA-LNP vaccines were entailed in the accompanying figures. To evaluate the antibody responses, serum samples were collected biweekly following each vaccination. Additionally, spleens were harvested on day 7 postbooster immunization to evaluate T cell responses.

2.8 Enzyme-linked immunosorbent assay ELISA plates were coated with either 2 mg/mL of PS1/TS1 recombinant protein or PEDV S1 specific antibody (LG3) in PBS buffer (pH 7.0), followed by blocking with 5% fat-free milk in PBS. Thereafter, diluted serum samples were introduced into the wells. Plates were incubated with goat anti-mouse IgG-HRP (Easybio, China), goat anti-mouse IgG1-HRP (Abcam, UK), goat anti-mouse IgG2a-HRP (Abcam, UK) or the PEDV S1 specific antibody conjugated with HRP (LB9-HRP), and developed with 3,3’,5,5’tetramethylbenzidine (TMB) substrate. The reactions were stopped with 2 M H2SO4, and the absorbance at 450 nm was measured. The endpoint titer was defined as the highest reciprocal dilution of serum yielding an absorbance value exceeding 2.5-fold that of the background.

2.4 DNA/RNA transfection For expression analysis, 2 µg of plasmid DNA or 4 µg of HPLCpurified circRNA was transfected into 293F cells using polyethylenimine (PEI) as the transfection agent. The supernatants were harvested 48 hours post-transfection, and the expression of circRNA was evaluated by Western blotting.

Frontiers in Immunology 03 frontiersin.org Zhang et al. 10.3389/fimmu.2025.1562865 2.9 Neutralization assay 3 Results

Vero-81 cells for PEDV or ST cells for TGEV were seeded into 96-well plates. Following this, the serum samples were inactivated at 56°C for 30 minutes and then serially diluted (in 2-fold increments) with cell culture medium. These diluted serum samples were subsequently mixed with 200 TCID50/50 mL of the corresponding virus and incubated at 37°C for 1 hour, prior to being added to the 96-well plate containing the respective cells. The cells were monitored every 24 hours, and the observations of cytopathic effects (CPE) were recorded. The neutralizing antibody titer was calculated based on the Reed-Muench method as previously described (32).

3.1 Production and characterization of circRNAPS1 and circRNATS1 vaccines Given that the S1 region of the S protein is primarily responsible for generating neutralizing antibodies against PEDV and TGEV (Figure 1A), the respective coding sequence of S1 was optimized and inserted into the well-known permuting intron-exon (PIE) system derived from Anabaena pre-tRNALeu gene developed by Wesselhoeft et al. (27) to synthesize circRNA in vitro (Figure 1B). To ensure high purity of the circRNA, a purification procedure utilizing high-performance liquid chromatography (HPLC) was employed (Supplementary Figures S1A, B). After conducting a meticulous circRNA collection, we performed desalination and precipitation procedures to obtain high-quality circRNAPS1 and circRNATS1. Their quality was further confirmed through agarose gel electrophoresis and HPLC analysis (Supplementary Figures S1C, D). In addition, we calculated that the circularization efficiency of both types of circular RNAs exceeded 80% (Supplementary Figure S1E). Next, the circRNA samples were subjected to reverse transcription, followed by PCR amplification using primer pairs spanning the junction site and subsequent Sanger sequencing, to validate the accuracy of the splicing reaction. The results confirmed that both circRNAPS1 and circRNATS1 underwent precise splicing as anticipated (Figure 1C). Subsequently, the circRNA PS1 and circRNATS1 were transfected into 293F cells to assess their expression capacity in vitro, and the results demonstrated successful in vitro expression of both circRNAs (Figure 1D). Then, the circRNAPS1 and circRNATS1 were encapsulated in lipid nanoparticles (LNPs) to form circRNA-LNP complexes (Figure 1E). Dynamic light scattering (DLS) measurements revealed an average particle size of approximately 72.5 nm (Figure 1F), with a corresponding average zeta potential of approximately -3.3 mV (Figure 1G). Transmission electron microscopy (TEM) evaluation confirmed the spherical nanoparticle morphology of the circRNALNP complex (Figure 1H).

2.10 Flow cytometry analysis Spleens harvested from immunized mice were processed to generate single-cell suspensions, from which 2 x106 cells per sample were seeded into 96-well plates. 10 mg/mL of either PS1 or TS1 protein was utilized to stimulate the splenocytes. Then Brefeldin A Solution (BFA) was added to each well and incubated at 37°C for 6 hours to inhibit protein secretion and facilitate the detection of intracellular cytokines. Anti-FcgIII/II receptor (clone 2.4G2) was used to prevent non-specific binding. Fixable Viability Dye eFluor™ 450 (eBioscience, USA) was applied to exclude dead cells from the analysis. For surface staining, APC anti-mouse CD8a (BioLegend, USA) was used to identify CD8+ T cells, while intracellular staining for PE anti-mouse IFN-g (BioLegend, USA) was performed using the True-Nuclear™ transcription factor buffer set (BioLegend, USA). Data acquisition was performed on a CytoFLEX flow cytometer (Beckman Coulter, USA), and with subsequent data analysis using CytExpert software (BeckmanCoulter, USA).

2.11 In vivo toxicity analysis 6-8-week-old female BALB/c mice were immunized with LNP or the bivalent circRNA vaccine comprising 20 mg of circRNAPS1F and 5 mg of circRNATS1. Post-immunization, the body weight changes were monitored over a 14-day period. Serum samples were collected 48 hours after immunization to assess the levels of alanine aminotransferase (ALT), aspartate aminotransferase (AST), and creatinine (CREA) were determined. 7 days after the booster immunization, tissue samples from the heart, liver, spleen, lung, and kidney were harvested to hematoxylin and eosin staining for histopathological examination.

3.2 The circRNAPS1 and circRNATS1 vaccines stimulate antibody production in a dosedependent manner To evaluate the immunogenicity of the two circRNA vaccines, we initially immunized BALB/c female mice via intramuscular injection with different doses of circRNA P S 1 -LNP and circRNATS1-LNP. The vaccination protocol involved two doses administered with a two-week gap between the initial and the booster immunization (Figure 2A). Serum samples were collected 13 days post each immunization to perform enzyme-linked immunosorbent assay (ELISA) analyses for the quantification of specific antibodies against PS1 and TS1 antigens (Figures 2B, C). The results revealed that the serum antibody levels against both TS1 and PS1 escalated in a dose-dependent fashion. Notably, when the

2.12 Statistical analysis The data in this study were presented as mean ± S.D. Unpaired two-tailed Student’s t-tests were utilized for comparative analyses and P < 0.05 was considered statistically significant.

Frontiers in Immunology 04 frontiersin.org Zhang et al. 10.3389/fimmu.2025.1562865 FIGURE 1

Production and characterization of circRNAPS1 and circRNATS1 vaccines. (A) Schematic representation of the spike (S) protein from PEDV or TGEV. PS: S protein of PEDV; TS: S protein of TGEV. (B) The genes encoding the PS1 and TS1 domains were optimized, synthesized and inserted into the vector with PIE system for circRNA production in vitro. SP: Signal peptide. (C) The RT-PCR products of circRNATS1 and circRNAPS1 were analyzed by Sanger sequencing to validate the splicing sites of the circRNAs. (D) The expression levels of PS1 and TS1 in the supernatants were determined by western blot analysis at 48 hours post-transfection of 293F cells with circRNATS1 and circRNAPS1. (E) Schematic depiction of the circRNA-LNP complex. (F) Size distributions of the circRNA-LNP complex. (G) Zeta potential of the circRNA-LNP complex. (H) TEM image of the circRNA-LNP complex. Scale bar, 50 nm.

Immunogenicity assessment of the circRNAPS1 and circRNATS1 vaccines. (A) Schematic illustration of the immunogenicity assessment protocol for circRNAPS1 and circRNATS1 vaccinations. (B, C) Quantitative analysis of PS1-specific (B) and TS1-specific (C) IgG antibody titers induced by the circRNAPS1 and circRNATS1 vaccines, respectively, at the indicated dosages. These values are expressed as mean ± S.D, n=5. (ns, *P < 0.05, **P < 0.01, ***P < 0.001).

circRNATS1 dose surpassed 2.5 mg, there was a steady rise in TS1specific antibodies, culminating in endpoint titers nearing 106 in the cohort that received the highest vaccine dosage of 10 mg (Figure 2C). In contrast, for circRNAPS1, a dose of over 5 mg triggered a marked increase in PS1-specific antibodies in the serum (Figure 2B). However, a comparison between the groups that received the maximum dose of 10 mg revealed that the average PS1-specific antibody level was approximately one-tenth of that for TS1 (Figures 2B, C). These findings suggest that the immunogenicity of PS1 is comparatively lower, and improving the immunogenicity of PS1 could significantly advance the development of a bivalent vaccine against PEDV and TGEV.

vaccines (33, 34). Building on this, we conducted a redesign of circRNA sequences encoding fusion proteins, attaching a porcine Fc region at the C-terminus of both PS1 and TS1 (Figure 3A). Following the preparation process, we successfully obtained two circRNAs, designated as circRNAPS1F and circRNATS1F (Figure 3B, Supplementary Figures S2A-S2D). In addition, we calculated that the circularization efficiency of both types of circular RNAs exceeded 80% (Supplementary Figure S2E). The expression of these circRNAs was then validated by western blot (Figure 3C). After encapsulation in LNP (Figure 3D), we intramuscularly injected two circRNA vaccines into female BALB/c mice, each containing 10 mg of circRNAPS1F and 10 mg of circRNATS1F, with equivalent doses of circRNAPS1 and circRNATS1 used as controls (Figure 3E). The analysis of serum samples, collected after both the primary and booster immunizations, demonstrated a marked increase in the immunogenicity of circRNAPS1F vaccine compared to the circRNAPS1 vaccine, with endpoint titers against PS1 reaching approximately 106 (Figure 3F). In addition, on day 100 post-booster immunization, serum samples were collected and analyzed for anti-PS1 antibody levels using ELISA. The results showed that the antibody titers induced by the circular

3.3 The Fc fusion significantly amplifies the immunogenicity of PS1 in the form of circRNA Previous studies have revealed that incorporating the Fc region into an antigen can significantly boost the immunogenicity of

Frontiers in Immunology 06 frontiersin.org Zhang et al. 10.3389/fimmu.2025.1562865 FIGURE 3

The Fc fusion significantly amplifies the immunogenicity of PS1 in the form of circRNA. (A) Schematic illustration of the preparation of circRNAPS1F and circRNATS1F. (B) The RT-PCR products of circRNAPS1F and circRNATS1F were analyzed by Sanger sequencing to validate the splicing sites of the circRNAs. (C) The expression levels of PS1F and TS1F in the supernatants were determined by western blot analysis at 48 hours post-transfection of 293F cells with circRNAPS1F and circRNATS1F. (D) Schematic depiction of the circRNAPS1F/TS1F-LNP complex. (E) Schematic representation of the vaccination regimen with circRNAPS1F and circRNATS1F. An equivalent dosage of circRNAPS1/TS1-LNP or LNP control was administered following the same protocol. (F, G) Quantitative analysis of PS1-specific (F) and TS1-specific (G) IgG antibody titers post-vaccination. These values are expressed as mean ± S.D, n=5. (ns, *P < 0.05, ***P < 0.001).

specific antibodies targeting PS1 when compared to the standalone circRNAPS1F-LNP vaccine (Figure 4B). Conversely, no significant disparity was observed in the levels of specific antibodies against TS1 between the bivalent vaccine group and the circRNATS1-LNP vaccine group (Figure 4C). These findings indicate that while the immunogenicity of PS1 antigen was augmented by incorporating Fc fragment, achieving a comparable level to that of the TS1 antigen, coadministration of circRNAPS1F-LNP and circRNATS1-LNP still led to a pronounced decrease in the induction of antibodies specific to PS1. To ascertain the effect of co-transfection of circRNAPS1F and circRNATS1 on PS1F antigen expression, 293F cells were cotransfected with equal amounts of circRNAPS1F and circRNATS1, after which the expression of the PS1F antigen was evaluated. The results demonstrated that the presence of circRNATS1 did not exert a significantly influence on the expression of the PS1F derived from circRNAPS1F, implying that the observed disparities in the antibody response towards PS1F and TS1 in vivo could be ascribed to antigenic competition (Figure 4D). Therefore, this bivalent vaccine formulation should be further optimized to achieve robust antibody responses against both antigens.

RNA vaccine were maintained at a relatively high level. (Supplementary Figure S3). Unexpectedly, however, the fusion of an Fc tag with TS1 antigen in the circRNA vaccine did not augment its immunogenicity (Figure 3G). All these results indicated that circRNAPS1F and circRNATS1 should be used for subsequent bivalent vaccine development.

3.4 Equal dosing of the circRNAPS1F and circRNATS1 vaccines results in a diminished antibody response against PS1 In the pursuit of developing a bivalent vaccine, we initially coadministered equal dosing (10 mg circRNA) of circRNAPS1F-LNP and circRNATS1-LNP, employing an immunization protocol as described above. Concurrently, individual administrations of circRNAPS1F-LNP (10 mg) and circRNATS1-LNP (10 mg) served as respective controls (Figure 4A). Subsequent quantitative analyses of serum samples using ELISA revealed that, following booster immunization, the bivalent vaccine group demonstrated a significantly reduced presence of

Equal dosing of the circRNAPS1F and circRNATS1 vaccines leads to i a significant reduction in antibody levels against PS1. (A) Schematic depiction of the vaccination regimen. A mixture of circRNAPS1F (10 mg) and circRNATS1 (10 mg) was administered in accordance with the outlined protocol. Additionally, CircRNAPS1F (10 mg), CircRNATS1 (10 mg), or LNP (as a control) was delivered following the identical vaccination regimen. (B-C) Quantitative analysis of PS1-specific (B) and TS1-specific (C) IgG antibody titers. (D) Expression analysis of PSIF was performed 48 hours after transfection of 293F cells with the specified circRNAs. These values are expressed as mean ± S.D, n=5. (ns, *P < 0.05, ***P < 0.001).

varying dosages of circRNATS1-LNP (2.5, 5, or 10 mg) in mice. The ensuing data indicated that co-administration of circRNAPS1FLNP (20 mg) with 10 mg of circRNATS1 significantly influenced the production of PS1 antibody; however, the co-administration of circRNAPS1F-LNP (20 mg) with 2.5 mg and 5 mg of circRNATS1 did not result in significant suppression (Figure 5C). Furthermore, the bivalent vaccines containing 2.5, 5, or 10 mg of circRNATS1 elicited comparable levels of TS1 antibody to the respective standalone circRNA TS1 -LNP vaccines (Figure 5D). Informed by these observations, we formulated an optimized bivalent vaccine candidate, comprising circRNAPS1F-LNP (20 mg) and circRNATS1LNP (5 mg), simultaneously targeting both PEDV and TGEV.

3.5 Optimize the dose ratio of bivalent vaccines to induce robust humoral and cellular immune responses against both PEDV and TGEV To ameliorate the variances in the antibody response elicited by the bivalent vaccine, we undertook the optimization of circRNA dosages. The antibody induction capacity of 20 mg circRNAPS1F was initially evaluated (Figure 5A, B), with outcomes revealing a markedly elevated induction of PS1 specific antibodies by 20 mg circRNAPS1F compared to that induced by the 10 mg circRNAPS1F. Subsequently, we administered circRNAPS1F-LNP (20 mg) with

Optimize the dose ratio of bivalent vaccines to induce higher levels of humoral and cellular immune responses against both PEDV and TGEV. (A) Schematic depiction of the immunization regimen for the bivalent circRNA vaccine. (B) Quantitative analysis of PS1-specific IgG antibody titers induced by circRNAPS1F vaccine (10 mg or 20 mg). (C, D) Assessment of PS1 or TS1-specific IgG antibody titers induced by bivalent vaccines comprising circRNAPS1F-LNP (20 mg) and circRNATS1-LNP (0, 2.5, 5 or 10 mg). (E) Detection of PS1 and TS1 antigen-specific T cell responses, as indicated by IFN-g+ CD8+ T cells, in the splenocytes from mice immunized with bivalent vaccine comprising circRNAPS1F (20 mg) and circRNATS1 (5 mg). These values are expressed as mean ± S.D, n=5. (ns, *P < 0.05, **P < 0.01, ***P < 0.001).

IgG2a antibody levels against PS1 (Figure 6C), both the IAV-IAV and circRNA-IAV groups exhibited a Th2-biased antibody response. In contrast, the IAV-circRNA and circRNA-circRNA groups exhibited a tendency towards a Th1-biased response (Figure 6E). Upon evaluating the specific IgG1 and IgG2a antibody levels against TS1 (Figure 6D), only the IAV-IAV immunization group manifested a Th2-biased humoral response, whereas the remaining three groups demonstrated a more pronounced inclination towards a Th1-biased response (Figure 6F). These observations imply that circRNA vaccine formulation possesses a significant advantage in eliciting a Th1biased immune response. Furthermore, we conducted neutralization assays against authentic PEDV and TGEV, and the results revealed that the IAVcircRNA group exhibited a significantly elevated neutralization titer against TGEV when compared to the other three groups. Conversely, the neutralization effects against PEDV were found to be analogous across all four groups (Figures 6G, H). Collectively, the sequential vaccination procedure employed in the IAV-circRNA group emerges as an optimal approach for the protection against PEDV and TGEV infections within the porcine industry.

Following the booster immunization with the optimal bivalent vaccine, we assessed the CD8+ T cell immune response induced by this vaccine combination. Flow cytometry analysis revealed that significant T cell responses that were specifically generated against PEDV and TGEV upon antigenic stimulation (Figure 5E, Supplementary Figure S4). Collectively, these findings indicate that the optimized bivalent vaccine presents a promising dualtarget strategy for the simultaneous mitigation of both PEDV and TGEV infections within the swine industry.

3.6 Safety assessment of the bivalent vaccine candidate The safety profile of the bivalent vaccine candidate was evaluated in immunized mice. Monitoring of post-initial immunization body weight changes over a 14-day period demonstrated that, after an initial phase of weight reduction, the immunized mice exhibited a comparable weight change to that of the control group (Supplementary Figure S5A). Serum samples obtained 48 hours post-booster immunization were analyzed for hepatic, and renal function, with results showing no significant deviations from the normal range (Supplementary Figures S5BS5D). Furthermore, histopathological assessments of the heart, liver, spleen, lung, and kidney tissues from the immunized mice showed no notable pathological changes after administration of the bivalent circRNA vaccine (Supplementary Figure S5E). These observations collectively substantiate the safety profile of the circRNA vaccines, supporting their potential for clinical use.

4 Discussion The predominant clinical signs of PEDV and TGEV infections include vomiting and diarrhea, which lead to escalated mortality rates among piglets during production practices (9). In recent years, concurrent infections of PEDV and TGEV have been frequently observed clinically (36–39). The coexistence of these diseases not only exerts immense pressure on farms for prevention and control but also incurs substantial economic losses. Consequently, the development of bivalent vaccines that target both viruses has become an urgent necessity. Our current study demonstrates the development of a bivalent circRNA vaccine against both PEDV and TGEV through rational antigen design and vaccination dose optimization. This bivalent vaccine elicits robust humoral and cellular immune responses, and serum from immunized mice can effectively neutralize both PEDV and TGEV, underscoring its potential application in the swine industry to provide comprehensive protection against these infections. Initially, TS1 and PS1 domains were selected as immunogens for circRNA vaccine design. The subsequent results indicated that both vaccines exhibited robust immunogenicity, particularly circRNATS1, which effectively induced high levels of antibody titers in mice even at lower doses. In contrast, circRNAPS1 produced comparatively weaker antibody titers. To bolster the immunogenicity of the circRNAPS1 vaccine, we refined the PS1 antigen by incorporating a pFc region (33, 34). This strategic modification enhanced its immunogenicity to a level comparable with that of circRNATS1, thereby establishing a crucial foundation for developing an efficient bivalent circRNA vaccine capable of combating both PEDV and TGEV. However, when equal doses of circRNATS1 and circRNAPS1F were combined into a bivalent vaccine and administered, a notable difference was observed in their capacity to elicit antibody responses. The phenomenon described above has previously been

3.7 Sequential vaccination elicits robust immunity against both PEDV and TGEV Previous studies have demonstrated that sequential vaccination strategies elicit a heightened immune response against infectious agents as opposed to homologous vaccination regimens (35). Building upon these findings, we have elected to explore the potential of our circRNA-based bivalent vaccine when administered in tandem with commercially available inactivated vaccines (IAV) to ascertain whether this combinatorial approach can evoke a more potent immune response and confer superior protection against PEDV and TGEV. Within the context of prime-boost immunization, four discrete vaccination regimens were designed: IAV-IAV, circRNA-circRNA, IAV-circRNA, and circRNA-IAV. Following the immunization protocols as delineated in Figure 5A, specific antibodies elicited against PS1 and TS1 in serum samples were detected. The results revealed that both the IAV-circRNA and circRNA-circRNA vaccine groups exhibited markedly elevated antibody titers against PS1 compared to the other two groups (Figure 6A). Conversely, the antibody responses against TS1 were found to be similar among all four vaccine groups (Figure 6B). Additionally, we conducted a detailed analysis to investigate the specific IgG1 and IgG2a antibodies induced by these four immunization strategies. In the assessment of specific IgG1 and

Sequential vaccination elicits robust immunity against both PEDV and TGEV. (A, B) Quantitative analysis of PS1-specific (A) and TS1-specific (B) IgG antibody titers in serum samples from mice with various immunization strategies. (C, D) Assessment of PS1-specific (C) and TS1-specific (D) IgG1 and IgG2a antibody titers. (E, F) Calculation of the IgG2a/IgG1 ratios for PS1-specific (E) and TS1-specific (F) antibodies, as presented in panels (C) and (D). (G, H) Neutralization assays of authentic PEDV and TGEV were carried out using the serum from mice immunized with corresponding strategies. IAV: Commercially available inactivated bivalent vaccine against PEDV and TGEV; CircRNA: The optimized bivalent circRNA vaccine comprising 20 mg of circRNAPS1F and 5 mg of circRNATS1. These values are expressed as mean ± S.D, n=5. (ns, *P < 0.05, **P < 0.01, ***P < 0.001, ****P < 0.0001).

employing bivalent or multi-valent vaccine formulations. In the context of this study, the capacity of circRNAPS1F to induce antibody response was considerably compromised when it was administered as part of the bivalent circRNA vaccine. It is evident from our data that this suppression is not due to antigen expression levels, implying that our bivalent circRNA vaccine indeed confronts challenges related to antigenic competition. However, the

observed in the development of bivalent mRNA vaccines for RSV and SARS-CoV2 (40). Additionally, recent studies on multi-valent mRNA vaccines for mpox have shown that the simultaneous administration of different antigens in equal doses can lead to considerable variations in the antibody titers against each antigen (41). Such variability could significantly diminish the efficacy of the multi-valent vaccine, potentially negating the advantages of

Frontiers in Immunology 11 frontiersin.org Zhang et al. 10.3389/fimmu.2025.1562865 underlying mechanisms driving this phenomenon are not yet fully understood. Although, we have successfully addressed this issue by conjugating the PS1 with the pFc region and optimizing the dosage ratio of circRNATS1 and circRNAPS1F, it serves as a cautionary note that antigenic competition (40) must not be disregarded, and greater efforts should be dedicated to elicit sufficient antibody responses against all the immunogens during the development of bivalent and multivalent vaccines. During the 2019 COVID-19 pandemic, numerous studies have demonstrated that sequential vaccination using SARS-CoV-2 vaccines developed through various technologies yielded superior protective effects against infections (35). Dong et al. also found that a sequential vaccination strategy offered optimal cross-protection against influenza strains that have undergone antigenic drift and metastasis (42). In our current research, we have explored various immunization strategies using a bivalent circRNA vaccine in combination with commercially available inactivated vaccines (IAV). The findings revealed that both the circRNA-circRNA and IAV-circRNA vaccination groups produced higher total IgG, IgG1, and IgG2a antibody levels against the PS1 antigen compared to the IAV-IAV and circRNA-IAV groups, while all four vaccination strategies induced similar antibody levels against TS1, which may be due to its superior immunogenicity. Furthermore, immunization regimens incorporating circRNA vaccines were found to elicit Th1biased immune responses. Notably, the IAV-circRNA group showed a higher total IgG level and a more pronounced Th1biased antibody response against PS1 than the circRNA-IAV group. Additionally, the IAV-circRNA group demonstrated more effective neutralization of TGEV compared to the circRNA-IAV group. These observations underscore the potential of sequential vaccination strategies to offer enhanced protection against viral infections and highlight the importance of selecting the appropriate sequence of different vaccines for optimal efficacy. In summary, our study has successfully developed a potent bivalent circRNA vaccine and a sequential strategy that capable of offering protection against both individual or co-infections of PEDV and TGEV. Beyond PEDV and TGEV co-infections, extensive epidemiological investigations on porcine diarrheal virus disease have revealed that the predominant forms of co-infection also included PEDV-Porcine delta corona virus (PDCoV), PEDVporcine rotavirus (PoRV), and PEDV-TGEV-PoRV (1, 36–39). This complex landscape poses a significant challenge for the prevention and control of porcine diarrheal virus disease. Our research on the bivalent circular RNA vaccine platform, and the sequential immunization approach provides crucial insights and practical recommendations for the future development of bivalent and multivalent vaccines to combat these potential co-infections of porcine diarrheal viruses and greatly benefit the swine industry.

Ethics statement The animal study was approved by Institutional Animal Care and Use Committee of Shanxi Agricultural University (SXAUEAW-2023M.DF.001017216). The study was conducted in accordance with the local legislation and institutional requirements.

Author contributions ZL: Conceptualization, Funding acquisition, Project administration, Resources, Supervision, Writing – review & editing. WZ: Methodology, Validation, Visualization, Writing – original draft, Conceptualization, Data curation, Formal Analysis, Investigation. LW: Conceptualization, Data curation, Formal Analysis, Investigation, Methodology, Validation, Writing – original draft. LC: Data curation, Formal Analysis, Investigation, Methodology, Writing – original draft. XM: Investigation, Methodology, Validation, Writing – original draft. WG: Investigation, Methodology, Validation, Writing – original draft. YW: Data curation, Formal Analysis, Project administration, Writing – original draft. YQ: Formal Analysis, Investigation, Methodology, Writing – original draft. XW: Investigation, Methodology, Writing – original draft. LZ: Formal Analysis, Methodology, Writing – original draft. HH: Formal Analysis, Methodology, Writing – original draft. XL: Investigation, Methodology, Writing – original draft. DZ: Methodology, Resources, Writing – original draft. TS: Methodology, Resources, Writing – original draft. GY: Investigation, Methodology, Resources, Writing – review & editing. HW: Conceptualization, Resources, Supervision, Writing – review & editing. CD: Conceptualization, Project administration, Resources, Supervision, Writing – review & editing.

📖 中文全文 Chinese Full Text

中文

# 双价环状RNA疫苗抗猪流行性腹泻病毒和猪传染性胃肠炎病毒

**类型** 原创研究 **发表日期** 2025年3月31日 **DOI** 10.3389/fimmu.2025.1562865 **开放获取**

**编辑** 林昂,中国药科大学,中国

**审稿人**

李恩涛,中国科学技术 University,中国 赵永祥,江苏省农业科学院(JAAS),中国

**通讯作者**

刘智达 zhida_liu@saari.org.cn 董春波 Chunbo_dong@saari.org.cn 王海东 wanghaidong@sxau.edu.cn 于国灿 guocanyu@mail.tsinghua.edu.cn † 这些作者对本工作做出了同等贡献

**双价环状RNA疫苗抗猪流行性腹泻病毒和猪传染性胃肠炎病毒**

张维兵 1,2†,王磊 2,3†,褚丽玉 4†,马旭 1,2,高文静 1,2,吴亚荣 2,乔永峰 1,2,王宪军 1,2,赵璐 1,2,胡红 2,5,李晓宇 2,张鼎 1,宋涛 4,于国灿 6*,王海东 1*,董春波 1,2*,刘智达 1,2*

1 山西农业大学兽医学院,晋中,中国;2 山西先进研究与创新研究院,太原,中国;3 山西医科大学基础医学院生物化学与分子生物学系,太原,中国;4 河北科技师范学院动物科技学院预防兽医学重点实验室,秦皇岛,中国;5 安科瑞(山西)生物细胞有限公司,太原,中国;6 清华大学化学系生物有机磷化学与化学生物学重点实验室,北京,中国

**收稿日期** 2025年1月18日 **接受日期** 2025年3月17日 **发表日期** 2025年3月31日

**引用格式**

Zhang W, Wang L, Chu L, Ma X, Gao W, Wu Y, Qiao Y, Wang X, Zhao L, Hu H, Li X, Zhang D, Song T, Yu G, Wang H, Dong C and Liu Z (2025) Bivalent circular RNA vaccines against porcine epidemic diarrhea virus and transmissible gastroenteritis virus. Front. Immunol. 16:1562865. doi: 10.3389/fimmu.2025.1562865

**版权声明**

© 2025 Zhang, Wang, Chu, Ma, Gao, Wu, Qiao, Wang, Zhao, Hu, Li, Zhang, Song, Yu, Wang, Dong and Liu. 本文为开放获取文章,依据知识共享署名许可协议(CC BY)条款分发。在其他论坛使用、分发或复制本文须注明原作者和版权所有者,并按照公认的学术规范引用本期刊的原始发表。不符合上述条件的使用、分发或复制均不被允许。

猪流行性腹泻病毒(PEDV)和猪传染性胃肠炎病毒(TGEV)对仔猪构成重大威胁,可导致严重腹泻甚至致死后果。除严格执行生物安全规程外,安全有效的疫苗接种对于减轻这些疾病的影响至关重要。本研究最初选择PEDV S1(PS1)和TGEV S1(TS1)抗原作为环状RNA(circRNA)疫苗开发的候选抗原。鉴于PS1抗原的免疫原性相对低于TS1抗原,我们将PS1与猪可结晶片段(Fc)区域进行偶联,构建PS1F。尽管如此,使用等量circRNAPS1F和circRNATS1混合物制备的双价circRNA疫苗仍导致针对PS1的抗体水平下降。随后对两种circRNA疫苗的剂量进行优化,成功诱导了相当水平的特异性抗体和T细胞免疫应答。此外,采用双价circRNA疫苗与商品化灭活疫苗(IAV)序贯免疫方案,可诱导以Th1为主的优势抗体应答,并有效中和PEDV和TGEV。本研究结果不仅为开发双价或多价circRNA/mRNA疫苗提供了潜在策略,也凸显了序贯免疫策略在养猪业中的良好应用前景。

**关键词**:环状RNA疫苗,双价,猪流行性腹泻病毒,猪传染性胃肠炎病毒,序贯免疫

---

## 1 引言

PEDV和TGEV均属于α-冠状病毒属,为单股正链RNA病毒,二者均被确认为引起猪大流行性腹泻的病原体,给养猪业带来了重大挑战(1)。TGEV最早于1946年在美国被发现(2),随后在欧洲、亚洲、非洲和南美洲相继被检出。PEDV在欧洲的首次检出可追溯至20世纪70年代初(3)。自2010年以来,高致病性PEDV毒株在猪群中逐步传播,并在亚洲、北美和欧洲各国持续流行(4–8),尤其是10日龄以下的仔猪感染PEDV后死亡率可达100%(9)。PEDV和TGEV在全球的广泛分布给全球养猪业造成了重大经济影响。面对复杂多变的腹泻疫情,疫苗接种是最有效的预防手段。由于PEDV和TGEV存在严重的共感染现象,单一疫苗接种无法同时提供针对两种病毒感染的防护(10)。因此,针对PEDV和TGEV的双价灭活疫苗或弱毒活疫苗被主要用于仔猪保护。然而,现有疫苗的有效性和安全性尚显不足(11)。因此,亟需开发兼具安全性和强效保护力的创新型双价疫苗,以应对PEDV和TGEV的威胁。

PEDV和TGEV的表面糖蛋白(S蛋白)位于病毒颗粒的最外层,其功能与严重急性呼吸综合征冠状病毒2型(SARS-CoV-2)的S蛋白相似。S蛋白在宿主细胞结合中发挥关键作用,因此其全长或截短形式是疫苗开发的重要靶标(12, 13)。研究表明,PEDV S1的核心中和表位(COE)区域具有诱导中和抗体产生的功能,而N端结构域(NTD)区域则作为潜在的辅助受体结合区域(12)。TGEV的S1结构域包含四个抗原位点(或两个抗原位点),即C、B、D和A(或NTD和RBD)(14, 15),从N端到C端依次排列。其中,A和D位点均能在宿主中诱导产生针对TGEV的中和抗体(14)。因此,全长S蛋白或S1、COE等特定结构域已被广泛应用于PEDV或TGEV疫苗的免疫原性研究。

近期研究表明,mRNA疫苗相较于传统疫苗具有显著优势(16),包括针对新发或突变病原体的靶向灵活性,以及快速设计、生产和诱导强效免疫应答的能力(17, 18)。在COVID-19大流行期间,靶向SARS-CoV-2的mRNA疫苗成为人类免疫接种的首选方案,极大地推动了mRNA疫苗的发展,针对其他重要病原体的多种mRNA疫苗候选物也在研发中(19–24),包括针对人类和动物病原体的疫苗。此后,PEDV mRNA疫苗的研究也有报道,并产生了良好的免疫效果(12)。然而,mRNA疫苗的主要局限性在于其易被核糖核酸酶(RNase)降解,需要在低温条件下储存和运输,这对兽医疫苗的开发构成了重大挑战。

已有研究表明,circRNA可通过非帽依赖性机制翻译为蛋白质(25),这使其成为mRNA的有力替代选择。与线性mRNA不同,circRNA因其共价闭合的环状结构而具有卓越的稳定性。此外,circRNA免疫原性较低,且在不进行核苷酸修饰的情况下仍能维持持续而高效的蛋白质表达(26, 27)。同时,circRNA合成过程中无需加帽和加尾反应,进一步降低了生产成本。这些优势使circRNA成为疫苗开发中极具吸引力的候选平台,尤其在兽医领域。事实上,针对冠状病毒、狂犬病和猴痘等的circRNA疫苗研究已在开展(28–30),结果表明这些疫苗在室温下可保持完整性长达一个月,并能有效激发强效免疫应答。

基于此,我们以PS1和TS1为免疫原,开发了靶向PEDV和TGEV的circRNA疫苗。尽管单独的circRNAPS1和circRNATS1疫苗表现出不一致的免疫原性,但通过优化抗原设计和circRNA剂量配比,我们成功获得了双价疫苗。该双价circRNA疫苗对PEDV和TGEV均诱导了相当水平的B细胞和T细胞免疫应答。本研究结果为养猪业同时防控PEDV和TGEV病毒感染提供了一种有前景的双靶点策略。

## 2 材料与方法

### 2.1 质粒构建

经密码子优化的PS1、TS1、PS1F和TS1F基因由LOGENBIO生物公司合成,并克隆至商品化pCDNA3.4质粒中。随后,按照Wesselhoeft等先前研究建立的方法,将这些基因整合至用于环状RNA合成的载体中。所有序列的详细描述见