A Single-Dose Intramuscular Nanoparticle Vaccine With or Without Prior Intrauterine Priming Triggers Specific Uterine and Colostral Mucosal Antibodies and Systemic Immunity in Gilts but Not Passive Protection for Suckling Piglets

✅ 全文

单次肌内注射纳米颗粒疫苗(无论是否预先进行宫内 priming)在母猪中触发特异性子宫和初乳黏膜抗体及系统性免疫,但未能为哺乳仔猪提供被动保护

作者 Pooja Choudhary; Amir Khajavinia; Ramin Mohammadi; Siew Hon Ng; Nathalie Bérubé; Damayanthi Yalamati; Azita Haddadi; Heather L. Wilson 期刊 Frontiers in Veterinary Science 发表日期 2022 卷/期/页码 Vol. 9 ISSN 2297-1769 DOI 10.3389/fvets.2022.931232 类型 原创研究 (Original Research)

📄 英文摘要 English Abstract

EN

An effective single-dose vaccine that protects the dam and her suckling offspring against infectious disease would be widely beneficial to livestock animals. We assessed whether a single-dose intramuscular (i.m.) porcine epidemic diarrhea virus (PEDV) vaccine administered to the gilt 30 days post-breeding could generate mucosal and systemic immunity and sufficient colostral and mature milk antibodies to protect suckling piglets against infectious challenge. The vaccine was comprised of polymeric poly-(lactide-co-glycolide) (PGLA)-nanoparticle (NP) encapsulating recombinant PEDV spike protein 1 (PEDVS1) associated with ARC4 and ARC7 adjuvants, a muramyl dipeptide analog and a monophosphoryl lipid A (MPLA) analog, respectively (NP-PEDVS1). To establish whether prior mucosal exposure could augment the i.m. immune response and/or contribute to mucosal tolerance, gilts were immunized with the NP-PEDVS1 vaccineviathe intrauterine route at breeding, followed by the i.m. vaccine 30 days later. Archived colostrum from gilts that were challenged with low-dose PEDV plus alum was used as positive reference samples for neutralizing antibodies and passive protection. On day 100 of gestation (70 days post i.m. immunization), both vaccinated groups showed significant PEDVS1-specific IgG and IgA in the serum, as well as in uterine tissue collected on the day of euthanasia. Anti-PEDVS1 colostral IgG antibody titers collected at farrowing were significantly higher relative to the negative control gilts indicating that the NP vaccine was effective in contributing to the colostral antibodies. The PEDVS1-specific colostral IgA and anti-PEDVS1 IgG and IgA antibodies in the mature milk collected 6 days after farrowing were low for both vaccinated groups. No statistical differences between the vaccinated groups were observed, suggesting that the i.u. priming vaccine did not induce mucosal tolerance. Piglets born to either group of vaccinated gilts did not receive sufficient neutralizing antibodies to protect them against infectious PEDV at 3 days of age. In summary, a single i.m. NP vaccine administered 30 days after breeding and a joint i.u./i.m. vaccine administered at breeding and 30 days post-breeding induced significant anti-PEDVS1 immunity in systemic and mucosal sites but did not provide passive protection in suckling offspring.

📄 中文摘要 Chinese Abstract

中文
养猪行业重视后备母猪和经产母猪的高繁殖性能,以及仔猪的高存活率和生长速度。猪流行性腹泻病毒(PEDV)可感染所有年龄段的动物,但如果仔猪未能从母体获得被动免疫力,该病毒可在出生后最初几天内导致高达90%–100%的感染仔猪死亡。据估计,PEDV对美国所有年龄段生猪经济福利造成的净年损失在9亿至18亿美元之间。及时有效地对后备母猪/经产母猪进行免疫接种以激发对仔猪的被动保护,对于改善猪群健康、抵御新生仔猪传染性疾病以及维持具有成本效益的养殖业具有极高的需求。 亚单位疫苗是畜禽极为安全的选择,因为它们不会恢复为致病形式。然而,由于亚单位抗原经过高度纯化,其免疫原性往往较差,必须与佐剂配合使用才能诱导强效免疫。我们使用了PEDV刺突蛋白的S1片段(该片段对细胞入侵至关重要),并在妊娠第三阶段对后备母猪进行了三次可溶性疫苗制剂的肌肉免疫接种,从而为哺乳仔猪提供了被动保护。复合佐剂可以精细调节并选择性引导免疫反应的类型或增强免疫反应的强度。ARC4佐剂是一种MDP衍生物。ARC7是一种糖脂,是TLR4配体及单磷酰脂质A(MPLA)类似物。聚乳酸-羟基乙酸共聚物(PLGA)纳米颗粒已被证明是免疫调节剂、蛋白质和肽类的潜在递送载体。

📋 英文结构化总结 English Structured Summary

全文整理

EN

Header:

Background The swine industry values high-reproductive performance by gilts and sows, as well as high-piglet survival and growth rates. Porcine Epidemic Diarrhea Virus (PEDV) affects all ages of animals, but it kills up to 90–100% of infected piglets within the first few days after birth if they do not receive passive immunity from their dams. It is estimated that the net annual decrease for the U.S. economic welfare from PEDV summed across all ages of pig ranges from $900 million to $1.8 billion. The timely and effective immunization of gilts/sows to trigger passive protection for piglets is highly sought to improve swine health, protect against neonatal infectious diseases, and maintain a cost-effective industry.

Subunit vaccines are extremely safe options for livestock because they cannot revert to a pathogenic form. However, because subunit antigens are highly purified, they tend to be poorly immunogenic and must be formulated with adjuvants to induce strong immunity. We used the S1 portion of the PEDV spike protein that is essential for cellular entry, and three intramuscular immunizations with a soluble vaccine formulation in gilts in the 3rd trimester contributed to the passive protection to suckling piglets. Combination adjuvants can fine-tune and selectively direct the type of immune response or augment the magnitude of the immune response. ARC4 adjuvant is an MDP derivative. ARC7 is a glycolipid, a TLR4 ligand, and a monophosphoryl lipid A (MPLA) analog. Poly(lactic-co-glycolic acid) (PLGA) nanoparticles have been shown as potential delivery vehicles for immunomodulators, proteins, and peptides.

Header:

Methods We assessed whether a single-dose intramuscular (i.m.) porcine epidemic diarrhea virus (PEDV) vaccine administered to the gilt 30 days post-breeding could generate mucosal and systemic immunity and sufficient colostral and mature milk antibodies to protect suckling piglets against infectious challenge. The vaccine was comprised of polymeric poly-(lactide-co-glycolide) (PGLA)-nanoparticle (NP) encapsulating recombinant PEDV spike protein 1 (PEDVS1) associated with ARC4 and ARC7 adjuvants, a muramyl dipeptide analog and a monophosphoryl lipid A (MPLA) analog, respectively (NP-PEDVS1). To establish whether prior mucosal exposure could augment the i.m. immune response and/or contribute to mucosal tolerance, gilts were immunized with the NP-PEDVS1 vaccine via the intrauterine route at breeding, followed by the i.m. vaccine 30 days later. Archived colostrum from gilts that were challenged with low-dose PEDV plus alum was used as positive reference samples for neutralizing antibodies and passive protection.

Header:

Results On day 100 of gestation (70 days post i.m. immunization), both vaccinated groups showed significant PEDVS1-specific IgG and IgA in the serum, as well as in uterine tissue collected on the day of euthanasia. Anti-PEDVS1 colostral IgG antibody titers collected at farrowing were significantly higher relative to the negative control gilts indicating that the NP vaccine was effective in contributing to the colostral antibodies. The PEDVS1-specific colostral IgA and anti-PEDVS1 IgG and IgA antibodies in the mature milk collected 6 days after farrowing were low for both vaccinated groups. No statistical differences between the vaccinated groups were observed, suggesting that the i.u. priming vaccine did not induce mucosal tolerance. Piglets born to either group of vaccinated gilts did not receive sufficient neutralizing antibodies to protect them against infectious PEDV at 3 days of age.

Header:

Data Summary Both vaccinated groups showed significant PEDVS1-specific IgG and IgA in serum and uterine tissue. Anti-PEDVS1 colostral IgG titers were significantly higher than negative controls. PEDVS1-specific colostral IgA and mature milk IgG and IgA were low. No statistical differences between the i.m. alone and i.u./i.m. groups were observed. Piglets from vaccinated gilts did not receive sufficient neutralizing antibodies to protect against PEDV challenge at 3 days of age.

Header:

Conclusions In summary, a single i.m. NP vaccine administered 30 days after breeding and a joint i.u./i.m. vaccine administered at breeding and 30 days post-breeding induced significant anti-PEDVS1 immunity in systemic and mucosal sites but did not provide passive protection in suckling offspring. Neither vaccine was sufficient to promote protective suckling piglets against infectious PEDV.

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Practical Significance An effective single-dose vaccine that protects the dam and her suckling offspring against infectious disease would be widely beneficial to livestock animals. The timely and effective immunization of gilts/sows to trigger passive protection for piglets is highly sought to improve swine health, protect against neonatal infectious diseases, and maintain a cost-effective industry.

📋 中文结构化总结 Chinese Structured Summary

中文

背景:

养猪行业重视后备母猪和经产母猪的高繁殖性能,以及仔猪的高存活率和生长速度。猪流行性腹泻病毒(PEDV)可感染所有年龄段的动物,但如果仔猪未能从母体获得被动免疫力,该病毒可在出生后最初几天内导致高达90%–100%的感染仔猪死亡。据估计,PEDV对美国所有年龄段生猪经济福利造成的净年损失在9亿至18亿美元之间。及时有效地对后备母猪/经产母猪进行免疫接种以激发对仔猪的被动保护,对于改善猪群健康、抵御新生仔猪传染性疾病以及维持具有成本效益的养殖业具有极高的需求。

亚单位疫苗是畜禽极为安全的选择,因为它们不会恢复为致病形式。然而,由于亚单位抗原经过高度纯化,其免疫原性往往较差,必须与佐剂配合使用才能诱导强效免疫。我们使用了PEDV刺突蛋白的S1片段(该片段对细胞入侵至关重要),并在妊娠第三阶段对后备母猪进行了三次可溶性疫苗制剂的肌肉免疫接种,从而为哺乳仔猪提供了被动保护。复合佐剂可以精细调节并选择性引导免疫反应的类型或增强免疫反应的强度。ARC4佐剂是一种MDP衍生物。ARC7是一种糖脂,是TLR4配体及单磷酰脂质A(MPLA)类似物。聚乳酸-羟基乙酸共聚物(PLGA)纳米颗粒已被证明是免疫调节剂、蛋白质和肽类的潜在递送载体。

方法:

我们评估了在配种后30天对后备母猪单次肌肉注射(i.m.)猪流行性腹泻病毒(PEDV)疫苗是否能产生黏膜和系统性免疫,以及足够的初乳和常乳抗体来保护哺乳仔猪抵抗感染性攻毒。该疫苗由聚合聚乳酸-羟基乙酸共聚物(PLGA)纳米颗粒(NP)组成,其中包封了重组PEDV刺突蛋白1(PEDVS1),并与ARC4和ARC7佐剂联合使用,分别为胞壁酰二肽类似物和单磷酰脂质A(MPLA)类似物(NP-PEDVS1)。为确定先前的黏膜暴露是否能增强肌肉注射免疫反应和/或导致黏膜耐受,在配种时通过子宫内途径对后备母猪接种NP-PEDVS1疫苗,30天后再进行肌肉注射疫苗接种。使用经低剂量PEDV加明矾攻毒的后备母猪的存档初乳作为中和抗体和被动保护的正对照参考样本。

结果:

在妊娠第100天(肌肉免疫后70天),两个接种组在血清中以及安乐死当天采集的子宫组织中均显示出显著的PEDVS1特异性IgG和IgA。分娩时采集的初乳中抗PEDVS1 IgG抗体滴度显著高于阴性对照组后备母猪,表明NP疫苗有效促进了初乳抗体的产生。分娩后6天采集的常乳中PEDVS1特异性初乳IgA及抗PEDVS1 IgG和IgA抗体在两个接种组中均较低。两个接种组之间未观察到统计学差异,表明子宫内初始免疫未诱导黏膜耐受。两个接种组后备母猪所产仔猪在3日龄时未获得足够的中和抗体以抵抗PEDV感染性攻毒。

数据总结:

两个接种组在血清和子宫组织中均显示出显著的PEDVS1特异性IgG和IgA。初乳中抗PEDVS1 IgG滴度显著高于阴性对照组。PEDVS1特异性初乳IgA及常乳IgG和IgA水平较低。单独肌肉注射组与子宫内/肌肉注射联合组之间未观察到统计学差异。接种后备母猪所产仔猪在3日龄时未获得足够的中和抗体以抵抗PEDV攻毒。

结论:

总之,在配种后30天单次肌肉注射NP疫苗,以及在配种时和配种后30天联合进行子宫内/肌肉注射疫苗,均在全身和黏膜部位诱导了显著的抗PEDVS1免疫,但未能为哺乳仔猪提供被动保护。两种疫苗均不足以保护哺乳仔猪抵抗PEDV感染。

实际意义:

一种能有效保护母体及其哺乳后代抵抗传染病的单剂疫苗将对畜禽养殖产生广泛的益处。及时有效地对后备母猪/经产母猪进行免疫接种以激发对仔猪的被动保护,对于改善猪群健康、抵御新生仔猪传染性疾病以及维持具有成本效益的养殖业具有极高的需求。

📖 英文全文 English Full Text

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ORIGINAL RESEARCH published: 03 August 2022 doi: 10.3389/fvets.2022.931232

Edited by: Maxim C.-J. Cheeran, University of Minnesota, United States Reviewed by: Renukaradhya J. Gourapura, The Ohio State University, United States Scott Dee, Pipestone Applied Research, United States Bert Devriendt, Ghent University, Belgium Stephanie N. Langel, Duke University, United States Cheryl Dvorak, University of Minnesota Twin Cities, United States *Correspondence: Heather L. Wilson heather.wilson@usask.ca Specialty section: This article was submitted to Veterinary Infectious Diseases, a section of the journal Frontiers in Veterinary Science Received: 28 April 2022 Accepted: 15 June 2022 Published: 03 August 2022 Citation: Choudhary P, Khajavinia A, Mohammadi R, Ng SH, Bérubé N, Yalamati D, Haddadi A and Wilson HL (2022) A Single-Dose Intramuscular Nanoparticle Vaccine With or Without Prior Intrauterine Priming Triggers Specific Uterine and Colostral Mucosal Antibodies and Systemic Immunity in Gilts but Not Passive Protection for Suckling Piglets. Front. Vet. Sci. 9:931232. doi: 10.3389/fvets.2022.931232

A Single-Dose Intramuscular Nanoparticle Vaccine With or Without Prior Intrauterine Priming Triggers Specific Uterine and Colostral Mucosal Antibodies and Systemic Immunity in Gilts but Not Passive Protection for Suckling Piglets Pooja Choudhary 1 , Amir Khajavinia 2 , Ramin Mohammadi 2 , Siew Hon Ng 1 , Nathalie Bérubé 1 , Damayanthi Yalamati 3 , Azita Haddadi 2 and Heather L. Wilson 1,4,5* 1

Vaccine and Infectious Disease Organization, University of Saskatchewan, Saskatoon, SK, Canada, 2 Division of Pharmacy, College of Pharmacy and Nutrition, University of Saskatchewan, Saskatoon, SK, Canada, 3 Alberta Research Chemicals Inc., Edmonton, AB, Canada, 4 Department of Veterinary Microbiology, Western College of Veterinary Medicine, University of Saskatchewan, Saskatoon, SK, Canada, 5 Vaccinology and Immunotherapeutics Program at the School of Public Health, University of Saskatchewan, Saskatoon, SK, Canada

An effective single-dose vaccine that protects the dam and her suckling offspring against infectious disease would be widely beneficial to livestock animals. We assessed whether a single-dose intramuscular (i.m.) porcine epidemic diarrhea virus (PEDV) vaccine administered to the gilt 30 days post-breeding could generate mucosal and systemic immunity and sufficient colostral and mature milk antibodies to protect suckling piglets against infectious challenge. The vaccine was comprised of polymeric poly-(lactide-coglycolide) (PGLA)-nanoparticle (NP) encapsulating recombinant PEDV spike protein 1 (PEDVS1) associated with ARC4 and ARC7 adjuvants, a muramyl dipeptide analog and a monophosphoryl lipid A (MPLA) analog, respectively (NP-PEDVS1). To establish whether prior mucosal exposure could augment the i.m. immune response and/or contribute to mucosal tolerance, gilts were immunized with the NP-PEDVS1 vaccine via the intrauterine route at breeding, followed by the i.m. vaccine 30 days later. Archived colostrum from gilts that were challenged with low-dose PEDV plus alum was used as positive reference samples for neutralizing antibodies and passive protection. On day 100 of gestation (70 days post i.m. immunization), both vaccinated groups showed significant PEDVS1specific IgG and IgA in the serum, as well as in uterine tissue collected on the day of euthanasia. Anti-PEDVS1 colostral IgG antibody titers collected at farrowing were significantly higher relative to the negative control gilts indicating that the NP vaccine was effective in contributing to the colostral antibodies. The PEDVS1-specific colostral IgA and anti-PEDVS1 IgG and IgA antibodies in the mature milk collected 6 days after farrowing were low for both vaccinated groups. No statistical differences between the vaccinated groups were observed, suggesting that the i.u. priming vaccine did not

Frontiers in Veterinary Science | www.frontiersin.org 1 August 2022 | Volume 9 | Article 931232 Choudhary et al. Pig Nanoparticle Intramuscular and Intrauterine Vaccines

induce mucosal tolerance. Piglets born to either group of vaccinated gilts did not receive sufficient neutralizing antibodies to protect them against infectious PEDV at 3 days of age. In summary, a single i.m. NP vaccine administered 30 days after breeding and a joint i.u./i.m. vaccine administered at breeding and 30 days post-breeding induced significant anti-PEDVS1 immunity in systemic and mucosal sites but did not provide passive protection in suckling offspring. Keywords: pigs, vaccine, intrauterine, intramuscular, nanoparticle, adjuvants

derivative (10). ARC7 is a glycolipid, a TLR4 ligand, and a monophosphoryl lipid A (MPLA) analog. MPLA is a detoxified derivative of LPS that has an immunomodulatory impact on the innate and adaptive immune system and has been used as a vaccine adjuvant in humans (11). Finally, poly(lactic-coglycolic acid) (PLGA) nanoparticles (NPs) have been shown as potential delivery vehicles for immunomodulators (12–16), proteins, and peptides (12, 15, 16). Our research showed the subcutaneous immunization of mice with a polymeric NP vaccine with protein antigen plus ARC4/7 formulated poly(lactide-co-glycolide) (PGLA) NPs triggered robust antigenspecific IFNγ and IL-17A production (10). Others have shown the MPLA combined with Streptococcus suis proteins provides immunological protection in pigs (17), and that the pig innate immune response was induced in response to MDP administration (18), so it is reasonable to assess whether these adjuvants will trigger an innate immune response in pigs. Herein, we investigate whether these adjuvants formulated with recombinant PEDV spike protein 1 (PEDVS1) protein as part of a PLGA NP can promote robust humoral and cell-mediated immunity (CMI) in pigs, even after a single i.m. dose. Using a single-dose vaccine that promotes protective immunity against infectious disease would significantly benefit the pig industry. Moreover, formulating vaccines so that they can be administered via the intramuscular (i.m.) route yet trigger uterine and systemic immunity would help protect pig reproductive health (19). Because the majority of commercial pigs are bred by artificial insemination (AI) (20), current husbandry practices allow routine access to the uterus during each reproductive cycle. Our previous research showed that rabbits administered a single i.m. subunit vaccine triggered very high systemic and mucosal (i.e., lungs, vaginal, and mucosal) immune responses to the vaccine antigen, although we did not judge protection against the disease (21). Our work has also shown that repeated administration of an intrauterine vaccine at breeding triggered robust mucosal and systemic immunity in gilts and partial protection of suckling piglets against PEDV when they were infected 3 days after birth (22). Our primary objective is to assess the effects of a single-dose i.m. NP vaccine formulated with two adjuvants and recombinant PEDVS1 protein on the gilt local and systemic humoral and cell-mediated immune responses. An important secondary objective is to determine if sufficient maternal neutralizing antibodies were transferred to suckling piglets to protect against disease. Our tertiary objective was to discern whether prior i.u. immunization impacted the

- Single-dose intramuscular vaccine alone or an intrauterine vaccine followed by an intramuscular vaccine can promote significant antigen-specific mucosal (uterine and colostral) and systemic antibodies, but it induced low-level colostral neutralizing antibodies. - With this dose and formulation, an intrauterine NP vaccine did not act as a priming vaccine to an intramuscular booster nor did it induce tolerance. - Neither vaccine was sufficient to promote protective suckling piglets against infectious PEDV.

INTRODUCTION The swine industry values high-reproductive performance by gilts and sows, as well as high-piglet survival and growth rates. Porcine Epidemic Diarrhea Virus (PEDV) affects all ages of animals, but it kills up to 90–100% of infected piglets within the first few days after birth if they do not receive passive immunity from their dams (1, 2). It is estimated that the net annual decrease for the U.S. economic welfare from PEDV summed across all ages of pig ranges from $900 million to $1.8 billion (3). The timely and effective immunization of gilts/sows to trigger passive protection for piglets is highly sought to improve swine health, protect against neonatal infectious diseases, and maintain a costeffective industry. Subunit vaccines are extremely safe options for livestock because they cannot revert to a pathogenic form. However, because subunit antigens are highly purified, they tend to be poorly immunogenic and must be formulated with adjuvants to induce strong immunity (4). We used the S1 portion of the PEDV spike protein that is essential for cellular entry, and three intramuscular immunizations with a soluble vaccine formulation in gilts in the 3rd trimester contributed to the passive protection to suckling piglets (5). Combination adjuvants can fine-tune and selectively direct the type of immune response or augment the magnitude of the immune response. Muramyl dipeptide (MDP) is a component in the bacterial cell wall component peptidoglycan. In eukaryotic cells, MDP is detected by NOD2, a cytoplasmic receptor belonging to the innate immune system (6). MDP has been shown to induce immune responses by increasing IFNγ and other cytokine production (7), stimulating the differentiation and proliferation of lymphocytes (8), and it has been shown to influence immune responses with other TLR ligands (9). ARC4 adjuvant is an MDP

Frontiers in Veterinary Science | www.frontiersin.org 2 August 2022 | Volume 9 | Article 931232 Choudhary et al. Pig Nanoparticle Intramuscular and Intrauterine Vaccines

response triggered by an i.m. vaccine administered 30 days later or whether initial i.u. exposure induced mucosal tolerance. TABLE 1 | Schematic of ARC4 and ARC7 and targets. MATERIALS AND METHODS ARC4

NOD2 ARC7 TLR4 Name Structure Target

Production of Recombinant Antigens Recombinant (r) PEDVS1 [amino acids 21–734 of PEDV spike protein (accession number AG058924) with carboxyl GSGSG(H)12 added] was expressed in the human embryonic kidney cells then affinity-purified as previously described (5) (same batch used herein).

Vaccine Formulation and Characterization ARC4 is a lapidated muramyl dipeptide (LMDP), and MDP is known for activating the NOD2 receptor in the immune stimulation mechanism. Similarly, ARC7 is a synthetic monophosphoryl lipid A (MPLA). MPLA is the smallest active component derived from lipid A of various bacteria and has been widely studied for its activation of the TLR4 receptor. ARC4 and ARC7 were synthesized and purified by the Alberta Research Chemicals Inc. (Edmonton, AB, Canada) through proprietary means and their structures are shown in Table 1. PLGA NPs were prepared by the emulsification solvent evaporation method, as mentioned previously (23). Briefly, rPEDVS1/PBS solution (10%) was emulsified (w/o) in PLGA/chloroform solution (25%) containing 7-Acyl in chloroform:methanol (2%) or ARC4 in chloroform:methanol (2%). The resulting mixtures were further emulsified in 5% of PVA to form a secondary emulsion (w/o/w), followed by stirring for 3 h to evaporate the solvents. The NPs were then collected by ultracentrifugation. We performed ultracentrifugation of the NPs at 15 min/15,000 rpm and 20 min at 18,000 rpm using a J2-21 Ultracentrifuge (Beckman, USA). The size distribution was determined to be 477.7 ± 4.2 nm when PEDVS1 was included and 212.3 ± 4.2 nm when the PLGA NPs did not include the antigen or adjuvant. Size distribution was determined using Malvern Zetasizer (Nano series, Montreal, Canada). The Zeta potential was quantified using Malvern Zetasizer (Nano series, Montreal, Canada), and it was shown to be −20.4 ± 1.2 when PEDVS1 was included and −11.6 ± 1.7 when the NPs did not include the antigen. In the final step, the NPs were freeze-dried and stored at −20◦ C for further use. To prepare the vaccine, certain amounts of NPs were mixed to obtain the required dose for immunization.

of 200 µl/min for a run-time of 2 min. Mass spectrometry showed that 1.79 ± 0.18 µg per 1 mg NP or ARC7 and 335 ± 0.10 ng per 1 mg NP of ARC4 were loaded into the NPs. Loaded PEDVS1 in NPs was extracted from the NP formulations and quantified using a BCA assay, according to our previous studies (15). The BCA analysis showed that in each mg of NP, we loaded 2.918 µg PEDVS1. For the first vaccination, we administered 180 µg of PEDVS1 per 2 ml, and for the second dose, we administered 90 µg PEDVS1 per 2 ml.

Evaluation of the Loading Efficiency The amounts of adjuvants encapsulated in the PLGA NPs were determined by LC-MS/MS using a pre-column guard. For ARC7 encapsulation, a previously published method from our group was applied (24). To analyze ARC4 encapsulation, a high-performance liquid chromatography (HPLC) system was interfaced with the mass spectrometer. The Applied Biosystems/MDS Sciex Analyst software (Version 1.6.0) was used for system control and quantification. A sample volume of 5 µL was injected using the 1,200 Agilent autoinjector set to 4◦ C and was delivered with an isocratic mobile phase consisting of methanol (0.1% formic acid) at a flow rate

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Breeding, Vaccine Formulation, Immunization Schedule, and Experimental Timeline Gilts were obtained from the Prairie Swine Centre (PSC; Saskatoon). Animal use was approved by the Animal Research Ethics Board, and all the interventions were carried out in accordance with the guidelines of the Canadian Council of Animal Care for Humane Animal Use. The timing of immunization is shown in Table 2. All gilts had their estrus cycles synchronized using oral progestin (Regu-Mate, Merck

3 August 2022 | Volume 9 | Article 931232 Choudhary et al. Pig Nanoparticle Intramuscular and Intrauterine Vaccines TABLE 2 | Schematic of vaccination schedule. Groups Mucosal vaccine dose Systemic vaccine dose

Total vaccine doses received i.u./i.m. At breeding into uterus during 2nd estrus i.m. vaccine administered 30 days after breeding and i.u. vaccination 2 i.m. – i.m. vaccine administered 30 days after breeding

1 Negative control – – None Challenge With Infectious PEDV and Piglet Sampling

Animal Health, USA) for 14 days. When they showed signs of returning to estrus (2nd estrus), gilts referred to as the “i.u./i.m. group” (n = 4) were inseminated by conventional AI with a standard semen dose that included a 2 ml of NP vaccine injected into the 80 ml commercial semen bag before the insemination. The i.m. vaccine group was administered empty NPs (ARC4/7 encapsulated in PLGA NP, without PEDVS1 antigen or adjuvants) with live semen dose at 2nd estrus. Negative control gilts (n = 4) were administered only the live semen dose as per routine husbandry procedures. After 30 days, gilts from the i.m. group and the i.u./i.m. group received the vaccine (2 ml NP vaccine) on their shoulder muscle. Negative control gilts did not receive any mock i.m. vaccine. On approximately day 114 gestation, gilts were administered Planate (1 ml injection in the vulvar mucosa in the morning and afternoon; Merck Animal Health) to induce labor. Colostrum was collected on the day of farrowing and mature milk was collected on day 6. No cross-fostering of piglets took place, and litters were randomly culled to 10 piglets per gilt. Archived colostrum from gilts challenged with low dose PEDV plus alum was used as positive reference samples for neutralizing antibodies and passive protection.

PEDV strain USA/Colorado/2013 (GenBank KF272920; GI:514483276) was obtained by the Diagnostic Virology Laboratory (NVLS, Ames, USA) and propagated as described previously (5). Piglets were weighed at 3 days of age, then they were challenged with infectious PEDV at 3 days of age, but their dams were also indirectly exposed because they remained with their piglets during the infection period. Clinical analyses were performed on piglets daily. For the challenge, piglets were allowed to suckle their dams, and on the 3rd day of their life, they were orally challenged with live PEDV (3 × 102 TCID50 per piglet) as detailed in Makadiya et al. (5). The piglets from the positive control gilts, from the vaccinated gilts and negative control gilts in the current trial, and the positive control gilts from a previous trial were challenged with the same lot of infectious PEDV. Clinical assessments of challenged piglets were performed as detailed in Choudhary et al. (22), with the exception that piglets that reached a cumulative score across depression, weight, and survival scores of 4 were euthanized.

Quantification of antigen-specific antibody ELISAs, colostral PEDVS1 IgG neutralizing antibody titers, IFNγ cytokine production from PBMCs in response to recall antigen, and quantitation of viral shedding in fecal samples were performed as detailed in Choudhary et al. (22).

The timing of sampling is detailed in Table 3. Serum was collected on days 1, 30, 60, 100, and approximately day 125/126 for experimental gilts. Anti-PEDVS1 IgG and IgA antibody titers in serum and uterine mucosa were quantified over time (22). PBMCs from the gilts were isolated on day 100 and 6 days after piglets were challenged with PEDV to measure antigen-specific recall IFNγ cytokine expression. Although gilts were not directly challenged with the virus, they were exposed to the virus from their suckling piglets. Colostrum and mature milk samples were processed as detailed in Polewicz et al. (25) before being investigated for anti-PEDVS1 IgG and IgA antibodies and virus-neutralizing antibodies. Gilts were euthanized with 50 ml of Euthanyl (240 mg/ml; BimedaMTC Animal Health Inc., Cambridge, ON) when all piglets succumbed to the disease or at day 125/126 (up to 10 days after challenge). To obtain uterine mucosa from gilts (i.e., scrapings), a glass slide was gently applied to the uterine lumen and the mucosa was removed with a gentle scraping motion. The animals were exsanguinated immediately after birth to remove the vast majority of blood-derived antibodies in tissues. The uterine sampling was taken on the luminal side of the tissues and care was taken to avoid any blood when the tissues were scraped.

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Statistics All statistical analyses were carried out using GraphPad Prism 8 (GraphPad Software, San Diego, CA). For all ELISAs and clinical data sets, we tested data for normal distribution within each assay. If the data sets in an assay were normally distributed as determined using the Shapiro-Wilk test or the Kolmogorov-Smirnov test, we performed parametric analysis (unpaired T-test or Ordinary one-way ANOVA using Dunn’s multiple comparisons, as appropriate). If the data were not normally distributed, we performed a non-parametric analysis (Mann-Whitney test or Kruskal-Wallis ANOVA using Dunn’s multiple comparisons, as appropriate). The Log-rank (MantelCox) test and the Gehan-Breslow-Wilcoxon test were used for the statistical comparison of survival curves. For the analysis of the PEDV clinical scores, differences between vaccinated and control animals were determined by unpaired t-test, using the Holm-Sidak correction for multiple comparisons.

Pig Nanoparticle Intramuscular and Intrauterine Vaccines TABLE 3 | Listing of animal numbers, assays, and groups. Groups Gilts Piglets Sample collections Assays NA

• Serum: Days 1, 30, 60, 100, and 125/126. • PBMCs: Days 100 and 125/126 • Uterine lining scraping and uterine luminal flush: Day 125/126 • Colostrum: Day of farrowing • Mature Milk: 6 days after farrowing

Antibody ELISA using serum, uterine lining scraping, uterine flush. Colostral antibody and neutralizing antibody ELISAs. Overall immune response to vaccine i.m. vaccinated gilts 4 i.u./i.m. vaccinated gilts

4 NA Negative control gilts 4 NA Positive control gilts 4 NA IFNγ cytokine ELISA from PBMC’s

Serum Days 1, 100, and 125/126 • PBMC’s • Uterine lining scraping and uterine luminal flush: Day 125/126 • Colostrum: Day of farrowing • Mature Milk: 6 days after farrowing Colostral neutralizing antibody ELISA

Vaccine efficacy in suckling piglets challenged with PEDV at 3 days of age From i.m. vaccinated gilts 4 40 Challenge with PEDV at 3 days of age From i.u./i.m. vaccinated gilts 4 40 Challenge with PEDV at 3 days of age

From Negative control gilts 4 40 Challenge with PEDV at 3 days of age RESULTS

IgG (Figure 1C) and -IgA (Figure 1D) in colostrum, as well as colostral virus-neutralizing antibodies (Figure 1E), to discern how much antibody-mediated immunity could be passively transferred to the suckling piglets. Colostrum antibodies were compared to the negative control animals, as well as archived colostrum from “Positive control” gilts that were previously immunized with anti-PEDVS1 attenuated viral vaccine and whose colostrum protected piglets against infectious PEDV challenge (data not shown). The anti-PEDVS1 IgG antibody titers from the i.m. group were significantly elevated relative to the titers from negative control animals, yet the median titers were ∼2-fold less than the titers in the colostrum from positive control gilts (Figure 1C). The i.u./i.m. vaccinated gilts showed colostral IgG titers that were not significantly different from the negative control gilts. Colostral anti-PEDVS1 IgA was relatively low across both vaccinated groups (Figure 1D). Neutralizing colostral IgG antibody titers were low across both vaccinated groups relative to the VN antibodies in the positive control colostrum, which were significantly elevated relative to the colostrum from the negative control gilts (Figure 1E). Mature milk was collected on day 6 after farrowing, and each vaccinated groups showed relatively low anti-PEDVS1 IgG (Median < 500 titers) and IgA (Median < 100 titers) titers (Figures 1F,G), respectively. Collectively, these results suggest that despite being collected several weeks post-immunization, significant colostral anti-PEDVS1 IgG titers were present in the colostrum from i.m vaccinated gilts and could be passively transferred to suckling piglets. However, the single i.u. vaccination failed to elevate colostral VN titers.

Systemic Humoral and Cell-Mediated Immune Response to Intramuscular and Joint Intrauterine/Intramuscular Vaccination We assessed the development of PEDVS1-specific antibodymediated immunity over time (Figure 1A) in vaccines consisting of PEDVS1 antigen along with ARC4 and ARC7 adjuvants formulated as a PLGA NP. Serum was collected from gilts at estrus and then again at day 30, 60, and 100 gestation. Gilts vaccinated 30 days after estrus via the i.m. route with PEDVS1-NP (i.m. group) showed significant anti-PEDVS1 IgG (Figure 1A) and IgA (Figure 1B) in serum at day 100 gestation, 70 days after the i.m. immunization. The gilts immunized first via the i.u. route at estrus followed by an i.m. vaccination 30 days later (i.u./i.m.) showed comparable significant anti-PEDVS1 IgG titers indicating that the intrauterine vaccine, at least with this formulation and/or dose, did not act as a priming vaccine (Figures 1A,B). However, it is also important to note that the i.u. route of immunization did not trigger mucosal tolerance to the i.m. vaccine. When the piglets were infected with PEDV, the gilts were indirectly infected. Serum anti-PEDVS1 IgG and IgA antibodies were quantified, and we observed that the i.m. group responded with significantly more anti-PEDVS1 IgA relative to the negative control pigs (Figure 1B). Both vaccinated groups showed significantly elevated anti-PEDVS1 IgG, but the results were comparable (Figure 1A). We then quantified anti-PEDVS1

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Piglets born, weighted at 3 days of age then challenged with PEDV. Clinical assessment and mortality scoring performed Piglets born, weighted at 3 days of age then challenged with PEDV. Clinical assessment and mortality scoring performed

5 August 2022 | Volume 9 | Article 931232 Choudhary et al. Pig Nanoparticle Intramuscular and Intrauterine Vaccines

FIGURE 1 | Serum and mucosal antibody titers from animals vaccinated through the intramuscular route with or without prior intrauterine vaccination. Serum IgG (A) and IgA (B) antibody titers were collected over time from gilts immunized with PEDVS1-NP 30 days after estrus (i.m. group) and from gilts immunized via the intrauterine route at breeding and followed by an i.m. vaccine 30 days later (i.u/i.m. group). Negative control gilts did not receive any vaccine. Positive control gilts were previously immunized with a live attenuated PEDVS1 vaccine and showed passive protection for piglets. IgG and IgA antibodies from colostrum [IgG and (C); IgA and (D)], colostral virus neutralizing antibodies [IgG and (E)], and mature milk [IgG and (F); IgA and (G)] were collected on the day of birth for colostrum and on day 6 for milk. At 9 days after farrowing, the uterine tissue was minced, and the mucosal antibodies were collected 48 h later to quantify uterine mucosal antibodies [IgG, (H); IgA and (I)], and the uterine luminal antibodies were collected at the time of tissue harvest after 50 ml flush with PBS [IgG and (J)]. Data are presented as median and standard deviation. Statistical analysis was carried out by the Kruskal-Wallis test and Dunn’s multiple comparisons test. Significant differences relative to the negative control gilt data are denoted by different asterisks (* p < 0.05, ** p < 0.01, *** p < 0.001).

The i.u./i.m. vaccinated gilts appeared to generate less colostral antibodies relative to the animals that received the i.m. dose alone. None of the immunization strategy promoted anti-PEDV IgA in colostrum or mature milk. When the piglets were challenged with PEDV at 3 days of age, their respective gilts became indirectly exposed to the virus while tending their piglets. When we euthanized the gilts 9 days later, we obtained scrapings from the uterine horn, which were subjected to anti-PEDVS1 antibody ELISAs. We observed that both groups of vaccinated gilts produced significant uterine mucosal anti-PEDVS1 IgG (Figure 1H) and anti-PEDVS1 IgA (Figure 1I) titers relative to the titers from the negative control gilts. Further, the uterus was flushed before scraping, and the anti-PEDVS1 IgG antibodies were measured. The i.m. and i.u/i.m. vaccinated gilts had significantly higher anti-PEDVS1 IgG titers relative to the titers from the negative control gilts (Figure 1J). However, the antibody titers were low relative to the titers obtained from the scraped

Frontiers in Veterinary Science | www.frontiersin.org tissue, suggesting that the antibodies were not at a high concentration in the lumen but they were elevated in the mucosa itself.

Cell-Mediated Immune Response To evaluate the potential of NP vaccines to elicit a systemic CMI response, PBMCs were obtained at day 100 gestation and on day 9 after farrowing, which is 6 days after the gilts were indirectly exposed to PEDV through their suckling and PEDV-challenged piglets. The PBMCs from the gilts were incubated with media or PEDVS1 protein for 2 days, followed by IFNγ ELISA analysis on the supernatants. The PEDVS1-specific IFNγ response from both groups of vaccinated gilts did not promote a recall response at day 100 gestation. After they were indirectly exposed to the virus through piglets for 6 days, PBMCs from the gilts showed an increase in IFNγ recall response, although the data did not meet the standards of statistical significance (P < 0.125). These data

Pig Nanoparticle Intramuscular and Intrauterine Vaccines

FIGURE 2 | Cell-mediated immune responses quantified by gilts vaccinated with a single i.m vaccine or a i.m vaccine primed with an i.u. vaccine at breeding. IFNγ production was established using a cytokine ELISA kit. PBMCs were isolated on day 100 gestation and on day 9 after farrowing, which is 6 days post indirect exposure to PEDV. Each symbol represents one animal. ELISAs were conducted in Immulon 2 U plates and were read using the SpectraMax plus microplate reader and the limit of detection (LOD) is 100 pg/ml. Cytokine titers were graphed in GraphPad Prism 9. The median value is denoted by a horizontal bar and statistical comparisons made to unstimulated cells and cells stimulated with recombinant PEDVS1 protein using a Wilcoxon test.

Assessment of Passive Protection for Suckling Piglets Born From Vaccinated Gilts suggest that at least at this dose, the i.m. and i.u./i.m. vaccine did not induce a robust CMI recall response (Figure 2).

PEDV Infection at 3 Days of Age Live Births and Growth Kinetics of Piglets Born to Vaccinated and Control Gilts

Vaccinated gilts remained in relatively tight synchronicity for farrowing and were moved to BSL3 animal containment at ∼100 days gestation. Piglets were orally challenged with infectious PEDV at 3 days of age (Day 0). Piglet weight loss scores and depression scores were tabulated each day until 9 days of age with the percentage being compared to the day of challenge for each group equaling 100% on day 0 (Table 2). The grading score was changed from a score of > 3 per criteria to a grading score of 4 or higher cumulative average, so comparisons across trials cannot be performed (Table 4). However, the majority of pigs from the vaccinated groups were euthanized on day 4, which suggests that they were not sufficiently protected against the infectious challenge (Figure 4). These results suggest that a single i.m. immunization or an i.u./i.m. immunization with PEDVS1 ARC4/7 PLGA NP did not provide passive protection to suckling offspring. These data show agreement with Langel et al.

We measured the number of live piglets born and stillbirths for both sets of vaccinated gilts relative to data from negative control and positive control gilts (Figure 3A). We observed no significant differences between the number of live births or stillborns delivered by the control gilts and vaccinated gilts, suggesting that i.m. vaccination with an NP with or without a priming vaccine at breeding did not negatively affect fertility. We next measured the weight of piglets at 3 days of age, and we observed that the weights of the piglets born from i.m. vaccinated gilts were significantly smaller compared to the other groups but that there are large amounts of variation in weights in piglets across gilts (Figure 3B). The number of gilts per group would need to be increased to subjectively be assured that the i.m. vaccination alone was impacting piglet birth weights.

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FIGURE 3 | Births and weights of piglets born to control gilts and gilts vaccinated through the intramuscular route with or without prior intrauterine vaccination. Gilts were immunized with PEDVS nanoparticle 30 days after estrus (i.m. group) or they were immunized via the intrauterine route at breeding and followed by an i.m. vaccine 30 days later (i.u./i.m. group). Negative control gilts did not receive any vaccine. Positive control gilts were previously immunized with a live attenuated PEDV vaccine and showed passive protection for piglets. (A) The number of live births per litter and the number of stillbirths per litter were recorded. Each symbol represents the number of piglets per gilt. The mean value is denoted by a horizontal bar with standard deviation indicated as error bars. (B) Piglets were weighed at 3 days of age (kg). Data are shown as the birth weights from all piglets born to each gilt with median weights shown by a horizontal line. Statistical comparisons were made between the control and vaccinated animals (A) and between all groups in (B) using the Kruskal-Wallis test and Dunn’s multiple comparisons test. Significant differences are denoted by different asterisks (*p < 0.05, **p < 0.01, ****p < 0.0001).

FIGURE 4 | Survival of piglets when challenged with infectious PEDV 3 days after birth. The majority of the piglets born from negative control gilts and piglets born from i.m. vaccinated gilts and i.u./i.m. vaccinated gilts were euthanized on day 4 when their cumulative depression and weight loss scores reached a score of 4.

Frontiers in Veterinary Science | www.frontiersin.org 8 August 2022 | Volume 9 | Article 931232 Choudhary et al. Pig Nanoparticle Intramuscular and Intrauterine Vaccines TABLE 4 | Clinical assessments of piglets after viral challenge. Criteria

Scores Groups Weight Scores Day 1 Day 2 i.m. i.u./ i.m. 0 34 39 1 5 1 5 1 24 23 2 1 3 i.m i.u./ i.m. Day 3 Day 4 i.m i.u./ i.m. 3 10 Day 5 i.m i.u./ i.m. i.m 1 2 3 5 2 Day 6 i.u./ i.m. i.m i.u./ i.m. 2 2 1

8 11 10 2 2 1 4 23 12 3 1 2 6 i.m i.u./ i.m. 1 3 13 Day 7 1 4 Dead/euthanized Depression scores 1 0 34 23 40 1 5 2 1 30 29 29 2 25 2 9 10 11 31 4 3 1 1 4 6 3 2 2 2 3 10 6 1 1 4 5

(1), which showed that piglet survival positively correlated with high PEDVS1 IgA antibodies and virus-neutralizing antibody in milk (1).

the host’s immunological maturity at time of exposure, the timing and the frequency of exposure, and the nature of the antigen (27, 29–33). We showed that a single exposure to a soluble i.u. vaccine consisting of 800 µg protein antigen with the VIDO triple adjuvant [TriAdj: 400 µg Poly I:C (polyinosinic:polycytidylic acid), 800 µg HDP (host defense peptide) and 400 µg PCEP (polyphophazene)] or binary ethylenimine inactivated (BEI) PPV (Porcine parovirus) virus formulated with TriAdj was not sufficient to promote strong antibody-mediated immunity in serum or mucosal tissues (34). In contrast, we also observed that 3 × i.u. immunization with soluble PEDVS1 plus TriAdj led to significant anti-PEDVS1 in serum, uterine mucosal, and colostrum response (22). In fact, colostral neutralizing antibodies were significantly induced relative to control gilts, but the titers were not sufficient to protect against infectious PEDV to suckling piglet’s response (22). However, the current trial showed that an i.u. NP vaccine coupled with an i.m. NP vaccine induced an ∼10× higher serum anti-PEDVS1 IgG response relative to the thrice immunization of the uterus with the soluble PEDVS1 vaccine in pigs (22). The colostral anti-PEDV IgG titers, but not the IgA titers, were significantly elevated, suggesting that an NP formulation may be a better immunization formulation and should be studied further. We previously investigated the immunization into the uterus followed by i.m. immunization in the pig triggers mucosal tolerance; however, the trial setup had important differences which could impact the interpretation of the results. Previous experiments in our laboratory have shown that a single i.u. immunization with soluble subunit protein with TriAdj followed up with 2 i.m. immunizations 3 weeks apart (22). The antiFliC serum IgG response was very low (∼400 anti-FliC IgG titers), such that we were not clear whether tolerance may have been induced. However, the i.u./2 × i.m. FliC-soluble vaccine regime did trigger significant and relatively high IFNγ titers suggesting induction of CMI immunity. However, the comparisons we made were to gilts immunized three times into the uterus with PEDV-soluble vaccine. The use of different

DISCUSSION Mucosal vaccines induce both systemic and mucosal immunity and have the potential to control pathogens at their point of entry. Systemic vaccines are generally not recognized as inducing immunity at mucosal sites, which is where an estimated 90% of all infectious pathogens invade. Therefore, there has been a push toward the development of mucosal vaccines that can protect systemic and mucosal sites. Furthermore, mucosal immunization and non-lethal challenge of gilts may lead to adequate colostral and milk antibodies to passively protect piglets against infections challenge. For example, Langel et al. (1) showed non-lethal PEDV infection of gilts in the second trimester resulted in significantly higher levels of circulating PEDVS1 IgA and IgG antibodies and antibody-secreting cells and PED virus neutralizing (VN) antibodies post-PEDV infection, coinciding with 100% survival rate of their PEDV-challenged piglets compared with 87.2, 55.%, and 5.7% for first, third, and mock litters, respectively (1). Mucosal tolerance is a major immunological process that occurs continuously at all mucosal sites designed to prevent local and peripheral overreaction to innocuous antigens (26, 27). Locally produced sIgA or sIgM bind antigens to mask their epitopes, thus preventing an inflammatory response, while also preventing microbial colonization and penetration of the gut wall (28). However, there may be biological consequences associated with prior non-infectious exposure to pathogens, which can impact response to vaccines. If an animal first encounters an antigen via a mucosal route, such as orally or in the urogenital tract with fomites, re-exposure to the antigen by a systemic route may result in suppression of immunity rather than induction of immunity, which is not ideal for vaccination. Factors influencing whether mucosal tolerance or immunity is induced in response to antigen include how antigens are presented to lymphocytes, Frontiers in Veterinary Science | www.frontiersin.org

Pig Nanoparticle Intramuscular and Intrauterine Vaccines antigens makes it difficult to establish whether differences in the measured immune response were due to the route or simply the immunogenicity of the antigen. Therefore, in the current trial, we wanted to establish whether an NP-based vaccine could impact the immune tolerance, and we used the same antigen in both groups of vaccinated gilts. We show that the anti-PEDVS1 titers in serum from the gilts immunized with the i.m vaccine or i.u./i.m. both triggered ∼10,000 anti-PEDVS IgG titers after 70 or 100 days post respective vaccination. In contrast, the PEDVS1-specific CMI response in the current trial was low at day 100 gestation regardless of whether the i.m. injection was preceded by an i.u. immunization or not. However, when the gilts became indirectly exposed to the virus from the challenged suckling pigs, we observed a trend toward the induction of PEDVS1-specific CMI response. Clearly, the NP formulation did not promote mucosal tolerance. Results also make it clear that repeated i.u. immunization alone with a soluble vaccine (22) or with i.m. injection NP did not significantly promote protective passive immunity. More experimentation is required with multiple doses (i.e., at each breeding cycle) with increased doses of antigen and/or different combinations of adjuvants are required before a suitable i.u. vaccine will protect piglets against neonatal diseases and gilts/sows against reproductive diseases. Vaccine strategies may need to be different depending on whether one is targeting a reproductive disease, such as PRRSV or PPV, or an enteric disease, such as PEDV. For example, i.u. priming followed by an i.m. boost may be necessary to protect against PRRSV as IgA antibody-secreting cells trafficking from the uterus to mature milk is not welldocumented. However, intestinal priming/infection with PEDV is demonstrated to produce robust anti-PEDV antibodies in mature milk leading to piglet protection (1), suggesting that priming of the intestine, not the uterus, may impact antibody levels in colostrum and milk. Others showed that three i.m. immunizations with PEDVS1 plus TriAdj administered starting 46 days before farrowing led to significant serum antibody titers and VN titers to protect piglets against infectious PEDV (5). Different strategies may be necessary to promote effective mucosal immunization, depending on the disease. PLGA NPs act as potential delivery systems for vaccine formulations. Modification of physical properties of PLGA could shift the delivery of encapsulated antigens to either cytoplasm (for MHC I presentation and CD8+ T cell activation) or the endosome (for MHC II presentation and CD4+ T cell activation). According to previous studies, cytoplasmic delivery of PLGA content is affected by differences in the molecular weight of PLGA (35). Mucosal delivery of PLGA NPs-based vaccine has been shown to elicit the immune response required to induce T-cell response and clear viremia in a pig model. Intranasal delivery of PLGA NP-entrapped sonicated PRRSV antigens from VR2332 strain (Nano-KAg) was reported to significantly increase the virus-neutralizing titers in the lungs compared to both unvaccinated and killed vaccine vaccinated pigs (36). The lung homogenate and sera of Nano-KAg vaccinated pigs had higher levels of IFN-γ and lower levels of TGF-β than the control groups and could complete clearance of viremia in just 2 weeks. In addition, inactivated influenza virus

Frontiers in Veterinary Science | www.frontiersin.org antigens encapsulated in PLGA-NPs reduced the clinical disease and induced a cross-protective cell-mediated immune response in a pig model (37). Moreover, Norovirus P particle containing the extracellular domain of matrix protein 2 chimera and highly conserved H1N1 peptides from pandemic 2009 and classical human influenza virus were encapsulated within PLGA-NPs (38). They were administered with or without the adjuvant Mycobacterium vaccae whole cell lysate. Pigs were administered with the vaccine intranasally as a mist, and the vaccine induced the virus-specific T-cell response in the lungs and reduced the virus load in the airway of pigs upon challenge. Thus, PLGA-NPs have been shown to be effective as a vaccine delivery vehicle to mucosal sites in pigs. In a mouse trial, we showed that OVA with ARC4/7 adjuvants formulated in polymeric PLGA NPs triggered robust antibodymediated immunity in serum and IFNγ CMI and significant lymphocyte proliferation relative to the mice immunized with the unadjuvanted vaccine (10). Others have shown the MPLA combined with Streptococcus suis proteins provides immunological protection in pigs (17). Pigs have also been shown to be responsive to MDP (18), so it is reasonable to assess whether these adjuvants will trigger an innate immune response in pigs. Our results showed that the NP vaccine failed to trigger a CMI response, although when the gilts were indirectly exposed to the virus through their piglets, the T cells appeared to show a trend toward induction of antigen-specific CMI. The purpose of this study was to evaluate whether a single i.m. vaccine with PLGA NP encapsulating a PEDVS1 antigen and adjuvants could trigger antigen-specific mucosal and systemic immunity in pigs resulting in passive protection for piglets. Results show that the NP vaccine triggered significant antiPEDVS1 IgG and IgA in serum and uterine tissue and IgG in colostrum but not mature milk. Despite the significant induction of immunity in the gilt, the concentration of virus-neutralizing antibodies the single administration of the i.m. NP vaccine, at least with this formulation, failed to generate sufficient passive immunity to protect against infectious disease. The protective immune response should be assessed with an antigen for PRRSV or PPV to see if the i.m. NP vaccine alone or primed with an i.u. vaccine may contribute to protective immunity in the gilts against reproductive diseases. Immunization of gilts at breeding alone or with a second systemic immunization would be viewed positively by the pig industry because it will reduce person-power (combining immunization with breeding) while still triggering protective immunity alone or after being coupled with a single needle-based injection.

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**原创研究** 发表日期:2022年8月3日 DOI:10.3389/fvets.2022.931232

**编辑:** Maxim C.-J. Cheeran,美国明尼苏达大学

**审稿人:** Renukaradhya J. Gourapura,美国俄亥俄州立大学 Scott Dee,Pipestone应用研究公司,美国 Bert Devriendt,比利时根特大学 Stephanie N. Langel,美国杜克大学 Cheryl Dvorak,美国明尼苏达大学双城分校

**通讯作者:** Heather L. Wilson heather.wilson@usask.ca

**专刊栏目:** 本文投稿至《兽医科学前沿》期刊"兽医传染病"栏目

**收稿日期:** 2022年4月28日 **接受日期:** 2022年6月15日 **发表日期:** 2022年8月3日

**引用格式:** Choudhary P, Khajavinia A, Mohammadi R, Ng SH, Bérubé N, Yalamati D, Haddadi A and Wilson HL (2022) 单次剂量肌肉注射纳米颗粒疫苗联合或不联合预先子宫内初免可在后备母猪中诱导特异性子宫和初乳黏膜抗体及免疫应答,但不能为哺乳仔猪提供被动保护。Front. Vet. Sci. 9:931232. doi: 10.3389/fvets.2022.931232

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**单次剂量肌肉注射纳米颗粒疫苗联合或不联合预先子宫内初免可在后备母猪中诱导特异性子宫和初乳黏膜抗体及免疫应答,但不能为哺乳仔猪提供被动保护**

Pooja Choudhary¹,Amir Khajavinia²,Ramin Mohammadi²,Siew Hon Ng¹,Nathalie Bérubé¹,Damayanthi Yalamati³,Azita Haddadi²,Heather L. Wilson¹⁴⁵*

¹ 萨斯喀彻温大学疫苗与传染病组织,萨斯卡通,萨斯喀彻温省,加拿大;² 萨斯喀彻温大学药学与营养学院药学系,萨斯卡通,萨斯喀彻温省,加拿大;³ 阿尔伯塔研究化学品公司,埃德蒙顿,阿尔伯塔省,加拿大;⁴ 萨斯喀彻温大学西方兽医学院兽医微生物学系,萨斯卡通,萨斯喀彻温省,加拿大;⁵ 萨斯喀彻温大学公共卫生学院疫苗学与免疫治疗学项目,萨斯卡通,萨斯喀彻温省,加拿大

一种能有效保护母体及其哺乳后代免受传染性疾病侵害的单次剂量疫苗将对家畜产生广泛的益处。我们评估了在配种后30天对后备母猪单次肌肉注射(i.m.)猪流行性腹泻病毒(PEDV)疫苗是否能产生黏膜和免疫应答,以及足够的初乳和常乳抗体来保护哺乳仔猪免受感染性攻击。该疫苗由聚合乳酸-羟基乙酸共聚物(PLGA)纳米颗粒(NP)包裹重组PEDV刺突蛋白1(PEDVS1)并与ARC4和ARC7佐剂联合组成,ARC4为胞壁酰二肽类似物,ARC7为单磷酰脂质A(MPLA)类似物(NP-PEDVS1)。为确定预先黏膜暴露是否能增强i.m.免疫反应和/或导致黏膜耐受,在配种时通过子宫内途径用NP-PEDVS1疫苗免疫后备母猪,30天后再进行i.m.疫苗接种。以低剂量PEDV加明矾攻毒的后备母猪的存档初乳作为中和抗体和被动保护的阳性参考样本。在妊娠第100天(i.m.免疫后70天),两个接种组在血清中以及安乐死当天采集的子宫组织中均显示出显著的PEDVS1特异性IgG和IgA。分娩时采集的初乳抗PEDVS1 IgG抗体滴度显著高于阴性对照组后备母猪,表明NP疫苗有效促进了初乳抗体的产生。分娩后6天采集的常乳中PEDVS1特异性IgA和抗PEDVS1 IgG及IgA抗体在两个接种组中均较低。接种组之间未观察到统计学差异,表明i.u.初免疫苗未诱导黏膜耐受。任一接种组的后备母猪所产仔猪未获得足够的中和抗体以在3日龄时抵御PEDV感染。总之,配种后30天单次i.m. NP疫苗以及配种时和配种后30天联合i.u./i.m.疫苗在全身和黏膜部位均诱导了显著的抗PEDVS1免疫,但未能为哺乳后代提供被动保护。

**关键词:** 猪,疫苗,子宫内,肌肉注射,纳米颗粒,佐剂

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ARC7是一种糖脂,为TLR4配体,也是单磷酰脂质A(MPLA)类似物。MPLA是脂多糖(LPS)的减毒衍生物,对先天免疫系统和适应性免疫系统具有免疫调节作用,已被用作人类疫苗佐剂(11)。最后,聚乳酸-羟基乙酸共聚物(PLGA)纳米颗粒(NPs)已被证明是免疫调节剂(12–16)、蛋白质和肽类(12, 15, 16)的潜在递送载体。我们的研究表明,用含有蛋白抗原加ARC4/7配制的聚乳酸-羟基乙酸共聚物(PLGA)NP疫苗皮下免疫小鼠,可触发强烈的抗原特异性IFNγ和IL-17A产生(10)。另有研究表明,MPLA与猪链球菌蛋白联合使用可在猪中提供免疫保护(17),且猪的先天免疫反应可在给予MDP后被诱导(18),因此评估这些佐剂是否能在猪中触发先天免疫反应是合理的。

在此,我们研究了这些佐剂与重组PEDV刺突蛋白1(PEDVS1)蛋白共同配制成PLGA NP后,能否在猪中促进强烈的体液免疫和细胞介导免疫(CMI),即使在单次i.m.剂量后也是如此。

使用能促进针对传染性疾病的保护性免疫的单次剂量疫苗将显著有利于养猪业。此外,将疫苗配制成可通过肌肉注射(i.m.)途径给药同时能诱导子宫和全身免疫的制剂,将有助于保护猪的生殖健康(19)。由于大多数商品猪通过人工授精(AI)繁殖(20),目前的养殖实践允许在每个繁殖周期中常规进入子宫。我们先前的研究表明,单次i.m.亚单位疫苗可在兔中触发极高的全身和黏膜(即肺、阴道和黏膜)免疫反应,尽管我们未评估对疾病的保护效果(21)。我们的研究还表明,在配种时反复给予子宫内疫苗可在后备母猪中诱导强烈的黏膜和全身免疫,并在出生3天后感染PEDV时为哺乳仔猪提供部分保护(22)。我们的主要目标是评估单次剂量i.m. NP疫苗(含两种佐剂和重组PEDVS1蛋白)对后备母猪局部和全身体液及细胞介导免疫反应的影响。一个重要的次要目标是确定是否向哺乳仔猪转移了足够的母体中和抗体以预防疾病。我们的第三目标是确定预先i.u.免疫是否影响30天后i.m.疫苗触发的反应,或初始i.u.暴露是否诱导了黏膜耐受。

**核心发现:** - 单次肌肉注射疫苗单独使用或子宫内疫苗后接肌肉注射疫苗均可促进显著的抗原特异性黏膜(子宫和初乳)和全身抗体,但诱导的初乳中和抗体水平较低。 - 在此剂量和配方下,子宫内NP疫苗既未作为肌肉注射加强疫苗的初免疫苗,也未诱导耐受。 - 两种疫苗均不足以保护哺乳仔猪抵御传染性PEDV。

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## 引言

养猪业重视后备母猪和经母猪的高繁殖性能,以及仔猪的高存活率和生长率。猪流行性腹泻病毒(PEDV)可影响所有年龄的动物,但如果仔猪未从母体获得被动免疫,可在出生后最初几天内导致高达90–100%的感染仔猪死亡(1, 2)。据估计,PEDV对美国经济福利的净年度影响(涵盖所有年龄段的猪)在9亿至18亿美元之间(3)。及时有效地对后备母猪/经母猪进行免疫以触发仔猪被动保护,对于改善猪群健康、预防新生仔猪传染病和维持具有成本效益的产业具有重大意义。

亚单位疫苗对于家畜来说是非常安全的选项,因为它们不能回复为致病形式。然而,由于亚单位抗原高度纯化,其免疫原性往往较差,必须与佐剂配制以诱导强烈的免疫反应(4)。我们使用了PEDV刺突蛋白的S1部分(对细胞进入至关重要),在妊娠第三季度对后备母猪进行三次可溶性疫苗制剂的肌肉注射免疫,有助于为哺乳仔猪提供被动保护(5)。组合佐剂可精细调节和选择性引导免疫反应的类型或增强免疫反应的强度。胞壁酰二肽(MDP)是细菌细胞壁成分肽聚糖的组成部分。在真核细胞中,MDP被先天免疫系统的胞质受体NOD2识别(6)。MDP已被证明可通过增加IFNγ和其他细胞因子的产生(7)、刺激淋巴细胞的分化和增殖(8)来诱导免疫反应,并已被证明可与其他TLR配体共同影响免疫反应(9)。ARC4佐剂是MDP的脂质化衍生物(10)。ARC7是TLR4配体的糖脂,也是单磷酰脂质A(MPLA)类似物。MPLA是LPS的减毒衍生物,对先天和适应性免疫系统具有免疫调节作用,已被用作人类疫苗佐剂(11)。PLGA纳米颗粒已被证明是免疫调节剂、蛋白质和肽类的潜在递送载体。我们的研究表明,用含蛋白抗原加ARC4/7配制的PLGA NP疫苗皮下免疫小鼠可触发强烈的抗原特异性IFNγ和IL-17A产生。

在此,我们研究了这些佐剂与重组PEDV刺突蛋白1(PEDVS1)蛋白共同配制成PLGA NP后,能否在猪中促进强烈的体液和细胞介导免疫,即使在单次i.m.剂量后也是如此。

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## 材料与方法

### 重组抗原的生产

重组(r)PEDVS1 [PEDV刺突蛋白(登录号AG058924)第21–734位氨基酸,添加羧基端GSGSG(H)₁₂] 在人胚胎肾细胞中表达,然后如前所述进行亲和纯化(5)(使用同一批次)。

### 疫苗配制与表征

ARC4是脂质化胞壁酰二肽(LMDP),MDP以其在免疫刺激机制中激活NOD2受体而闻名。类似地,ARC7是合成单磷酰脂质A(MPLA)。MPLA是从多种细菌脂质A中获得的最小活性成分,因其对TLR4受体的激活作用而被广泛研究。ARC4和ARC7由阿尔伯塔研究化学品公司(加拿大埃德蒙顿)通过专有方法合成和纯化,其结构如表1所示。PLGA NP通过乳化溶剂蒸发法制备,如前所述(23)。简言之,将rPEDVS1/PBS溶液(10%)在含7-酰基的PLGA/氯仿溶液(25%)(氯仿:甲醇,2%)或含ARC4的氯仿:甲醇(2%)中乳化(w/o)。将所得混合物在5% PVA中进一步乳化形成二级乳液(w/o/w),然后搅拌3小时以蒸发溶剂。通过超速离心收集NP。使用J2-21超速离心机(Beckman,美国)对NP进行超速离心,条件为15,000 rpm离心15分钟和18,000 rpm离心20分钟。当包含PEDVS1时,粒径分布测定为477.7 ± 4.2 nm;当PLGA NP不包含抗原或佐剂时,粒径分布为212.3 ± 4.2 nm。粒径分布使用Malvern Zetasizer(Nano系列,加拿大蒙特利尔)测定。Zeta电位使用Malvern Zetasizer(Nano系列,加拿大蒙特利尔)量化,包含PEDVS1时为−20.4 ± 1.2,不包含抗原时为−11.6 ± 1.7。在最后一步中,将NP冷冻干燥并在−20°C下保存以备后续使用。为制备疫苗,将特定量的NP混合以获得免疫所需的剂量。

**表1 | ARC4和ARC7的结构及靶点示意图**

| | ARC4 | ARC7 | |---|---|---| | 名称 | NOD2 | TLR4 | | 结构 | (略) | (略) | | 靶点 | NOD2 | TLR4 |

### 载药效率评估

PLGA NP中包封的佐剂含量通过LC-MS/MS使用预柱保护器测定。对于ARC7包封,采用我们团队先前发表的方法(24)。为分析ARC4包封,将高效液相色谱(HPLC)系统与质谱仪联用。使用Applied Biosystems/MDS Sciex Analyst软件(版本1.6.0)进行系统控制和定量。使用设定为4°C的1,200 Agilent自动进样器进样5 μL,以含0.1%甲酸的甲醇作为流动相,流速为200 μL/min,运行时间2分钟。质谱分析显示,每1 mg NP中加载了1.79 ± 0.18 μg ARC7和335 ± 0.10 ng ARC4。

如前所述(15),从NP制剂中提取NP中加载的PEDVS1,并使用BCA法进行定量。BCA分析显示,每mg NP中加载了2.918 μg PEDVS1。第一次免疫时,每2 ml给予180 μg PEDVS1;第二次免疫时,每2 ml给予90 μg PEDVS1。

### 配种、疫苗配制、免疫时间表和实验时间线

后备母猪来自草原猪中心(PSC;萨斯卡通)。动物使用经动物研究伦理委员会批准,所有操作均按照加拿大动物管理委员会人道动物使用指南进行。免疫时间如表2所示。所有后备母猪均使用口服孕激素(Regu-Mate,默克动物健康,美国)同步发情周期14天。当出现返情迹象(第二次发情)时,被称为"i.u./i.m.组"(n = 4)的后备母猪通过常规AI授精,使用标准精液剂量,在授精前将2 ml NP疫苗注入80 ml商业精液袋中。i.m.疫苗组在第二次发情时给予空NP(ARC4/7包封于PLGA NP中,不含PEDVS1抗原或佐剂)与活精液剂量。阴性对照组后备母猪(n = 4)仅按照常规养殖程序给予活精液剂量。30天后,i.m.组和i.u./i.m.组后备母猪在肩部肌肉接受疫苗(2 ml NP疫苗)。阴性对照组后备母猪未接受任何模拟i.m.疫苗。在妊娠约114天时,后备母猪给予Planate(外阴黏膜注射1 ml,早晚各一次;默克动物健康)以诱导分娩。在分娩当天采集初乳,在第6天采集常乳。未进行仔猪交叉寄养,每头后备母猪的仔猪随机调整为10头。以低剂量PEDV加明矾攻毒的后备母猪的存档初乳作为中和抗体和被动保护的阳性参考样本。

**表2 | 免疫时间表示意图**

| 组别 | 黏膜疫苗剂量 | 全身疫苗剂量 | 总疫苗剂量 | |---|---|---|---| | i.u./i.m. | 配种时(第二次发情)子宫内注射 | 配种后30天i.m.疫苗 | 2次 | | i.m. | – | 配种后30天i.m.疫苗 | 1次 | | 阴性对照 | – | – | 无 |

### 传染性PEDV攻毒与仔猪采样

PEDV毒株USA/Colorado/2013(GenBank KF272920;GI:514483276)由诊断病毒学实验室(NVLS,美国艾姆斯)获得,并如前所述进行增殖(5)。

在3日龄时对仔猪称重,然后在3日龄时用传染性PEDV攻毒,但由于攻毒期间母猪与仔猪在一起,母猪也间接暴露。每天对仔猪进行临床分析。攻毒时,允许仔猪哺乳其母猪,在出生第3天,口服活PEDV(每头仔猪3 × 10² TCID₅₀),详见Makadiya等(5)。来自阳性对照组后备母猪、当前试验中接种组和阴性对照组后备母猪以及先前试验中阳性对照组后备母猪的仔猪均使用同一批次的传染性PEDV进行攻毒。攻毒仔猪的临床评估如Choudhary等(22)所述进行,但达到抑郁、体重和存活评分累计评分4分的仔猪被安乐死。

抗原特异性抗体ELISA、初乳PEDVS1 IgG中和抗体滴度、PBMC对回忆抗原的IFNγ细胞因子产生以及粪便样本中病毒脱落定量均如Choudhary等(22)所述进行。

采样时间详见表3。在第1、30、60、100天以及约第125/126天采集实验后备母猪的血清。随时间量化血清和子宫黏膜中抗PEDVS1 IgG和IgA抗体滴度(22)。在第100天和仔猪PEDV攻毒后6天分离后备母猪的PBMC,以测量抗原特异性回忆IFNγ细胞因子表达。尽管后备母猪未直接攻毒病毒,但它们通过哺乳仔猪暴露于病毒。初乳和常乳样本如Polewicz等(25)所述进行处理,然后检测抗PEDVS1 IgG和IgA抗体及病毒中和抗体。当所有仔猪死于疾病时或在第125/126天(攻毒后最多10天),用50 ml Euthanyl(240 mg/ml;Bimeda-MTC动物健康公司,加拿大安大略省剑桥)对后备母猪实施安乐死。为获得后备母猪的子宫黏膜(即刮片),将载玻片轻轻贴附于子宫腔,通过轻柔刮取动作去除黏膜。动物在安乐死后立即放血以去除组织中绝大多数血液来源的抗体。子宫采样在组织的管腔侧进行,刮取组织时注意避免任何血液污染。

**表3 | 动物数量、检测项目和组别列表**

| 组别 | 后备母猪 | 仔猪 | 样本采集 | 检测项目 | |---|---|---|---|---| | i.m.接种后备母猪 | 4 | – | 血清:第1、30、60、100和125/126天;PBMC:第100和125/126天;子宫黏膜刮片和子宫管腔冲洗液:第125/126天;初乳:分娩当天;常乳:分娩后6天 | 血清、子宫黏膜刮片、子宫冲洗液的抗体ELISA;初乳抗体和中和抗体ELISA;PBMC的IFNγ细胞因子ELISA | | i.u./i.m.接种后备母猪 | 4 | – | 同上 | 同上 | | 阴性对照后备母猪 | 4 | – | 同上 | 同上 | | 阳性对照后备母猪 | 4 | – | 同上 | 初乳中和抗体ELISA | | 来自i.m.接种后备母猪的仔猪 | – | 40 | 3日龄时PEDV攻毒 | 临床评估和死亡率评分 | | 来自i.u./i.m.接种后备母猪的仔猪 | – | 40 | 3日龄时PEDV攻毒 | 临床评估和死亡率评分 | | 来自阴性对照后备母猪的仔猪 | – | 40 | 3日龄时PEDV攻毒 | 临床评估和死亡率评分 |

### 统计学分析

所有统计分析均使用GraphPad Prism 8(GraphPad Software,美国加利福尼亚州圣地亚哥)进行。对于所有ELISA和临床数据集,我们检测了每个检测中数据的正态分布。如果检测中的数据集通过Shapiro-Wilk检验或Kolmogorov-Smirnov检验确定为正态分布,则进行参数分析(非配对T检验或单因素方差分析,使用Dunn多重比较,视情况而定)。如果数据非正态分布,则进行非参数分析(Mann-Whitney检验或Kruskal-Wallis方差分析,使用Dunn多重比较,视情况而定)。Log-rank(Mantel-Cox)检验和Gehan-Breslow-Wilcoxon检验用于生存曲线的统计学比较。对于PEDV临床评分的分析,接种动物与对照动物之间的差异通过非配对t检验确定,使用Holm-Sidak校正进行多重比较。

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## 结果

### 全身和黏膜体液免疫反应

我们评估了随时间推移PEDVS1特异性抗体介导免疫的发展情况(图1A),疫苗由PEDVS1抗原与ARC4和ARC7佐剂共同配制成PLGA NP组成。在发情时采集后备母猪血清,然后在第30、60和100天妊娠时再次采集。在发情后30天通过i.m.途径用PEDVS1-NP接种的后备母猪(i.m.组)在妊娠第100天(i.m.免疫后70天)血清中显示出显著的抗PEDVS1 IgG(图1A)和IgA(图1B)。首先在发情时通过i.u.途径免疫、30天后进行i.m.接种的后备母猪(i.u./i.m.)显示出相当的抗PEDVS1 IgG滴度,表明子宫内疫苗(至少在此配方和/或剂量下)未起到初免疫苗的作用(图1A, B)。然而,同样重要的是要注意,i.u.免疫途径并未触发对i.m.疫苗的黏膜耐受。当仔猪感染PEDV时,后备母猪被间接感染。量化了血清抗PEDVS1 IgG和IgA抗体,我们观察到i.m.组相对于阴性对照猪产生了显著更多的抗PEDVS1 IgA(图1B)。两个接种组均显示出显著升高的抗PEDVS1 IgG,但结果相当(图1A)。

然后我们量化了初乳中的抗PEDVS1 IgG(图1C)和IgA(图1D)以及初乳病毒中和抗体(图1E),以确定有多少抗体介导的免疫可被动转移给哺乳仔猪。将初乳抗体与阴性对照动物以及来自"阳性对照"后备母猪的存档初乳进行比较,这些阳性对照后备母猪先前用抗PEDVS1减毒病毒疫苗免疫,其初乳保护了仔猪免受传染性PEDV攻毒(数据未显示)。i.m.组的抗PEDVS1 IgG抗体滴度相对于阴性对照动物的滴度显著升高,但中位数滴度比阳性对照后备母猪初乳中的滴度低约2倍(图1C)。i.u./i.m.接种后备母猪的初乳IgG滴度与阴性对照组后备母猪无显著差异。两个接种组的初乳抗PEDVS1 IgA均相对较低(图1D)。两个接种组的中和初乳IgG抗体滴度相对于阳性对照初乳中的VN抗体均较低,而阳性对照初乳中的VN抗体相对于阴性对照组后备母猪的初乳显著升高(图1E)。在分娩后第6天采集常乳,每个接种组的抗PEDVS1 IgG(中位数< 500滴度)和IgA(中位数< 100滴度)滴度均相对较低(图1F, G)。总之,这些结果表明,尽管在免疫后数周采集,i.m.接种后备母猪的初乳中仍存在显著的抗PEDVS1 IgG滴度,可被动转移给哺乳仔猪。然而,单次i.u.接种未能提高初乳VN滴度。

当仔猪在3日龄时用PEDV攻毒时,各自的母猪在照料仔猪期间间接暴露于病毒。在9天后对母猪实施安乐死后,获取子宫角刮片,进行抗PEDVS1抗体ELISA检测。我们观察到,两个接种组的后备母猪相对于阴性对照组后备母猪均产生了显著的子宫黏膜抗PEDVS1 IgG(图1H)和抗PEDVS1 IgA(图1I)滴度。此外,在刮片之前冲洗子宫,并测量抗PEDVS1 IgG抗体。i.m.和i.u./i.m.接种后备母猪的抗PEDVS1 IgG滴度相对于阴性对照组后备母猪显著更高(图1J)。然而,与刮片组织获得的滴度相比,抗体滴度较低,表明抗体在管腔中的浓度不高,但在黏膜本身中升高。

**图1 | 通过肌肉注射途径(有或无预先子宫内疫苗接种)接种的动物的血清和黏膜抗体滴度。** 血清IgG(A)和IgA(B)抗体滴度随时间从发情后30天用PEDVS1-NP免疫的后备母猪(i.m.组)以及在配种时通过子宫内途径免疫并30天后进行i.m.疫苗的后备母猪(i.u./i.m.组)采集。阴性对照组后备母猪未接受任何疫苗。阳性对照后备母猪先前用活PEDVS1减毒疫苗免疫,显示对仔猪的被动保护。初乳中的IgG(C)和IgA(D)、初乳病毒中和抗体(IgG)(E)和常乳中的IgG(F)和IgA(G)在分娩当天(初乳)和第6天(常乳)采集。分娩后9天,将子宫黏膜切碎,48小时后采集黏膜抗体以量化子宫黏膜抗体(IgG,H;IgA,I),并在用50 ml PBS冲洗后在组织采集时采集子宫管腔抗体(IgG,J)。数据以中位数和标准差表示。统计学分析通过Kruskal-Wallis检验和Dunn多重比较检验进行。相对于阴性对照后备母猪数据的显著差异用不同星号表示(* p < 0.05, ** p < 0.01, *** p < 0.001)。

i.u./i.m.接种后备母猪产生的初乳抗体似乎少于仅接受i.m.剂量的动物。没有一种免疫策略能在初乳或常乳中促进抗PEDV IgA的产生。

### 细胞介导免疫反应

为评估NP疫苗诱导全身CMI反应的潜力,在妊娠第100天和分娩后第9天(即后备母猪通过哺乳和PEDV攻毒的仔猪间接暴露于病毒6天后)获取PBMC。将后备母猪的PBMC与培养基或PEDVS1蛋白孵育2天,然后对培养上清液进行IFNγ ELISA分析。两个接种组后备母猪的PEDVS1特异性IFNγ反应在妊娠第100天未促进回忆反应。在通过仔猪间接暴露于病毒6天后,后备母猪的PBMC显示出IFNγ回忆反应增加,尽管数据未达到统计学显著性标准(P < 0.125)。这些数据表明,至少在此剂量下,i.m.和i.u./i.m.疫苗未诱导强烈的CMI回忆反应(图2)。

**图2 | 通过单次i.m.疫苗或配种时i.u.疫苗初免后接i.m.疫苗免疫的后备母猪的细胞介导免疫反应定量。** 使用细胞因子ELISA试剂盒测定IFNγ产生。在妊娠第100天和分娩后第9天(即间接暴露于PEDV后6天)分离PBMC。每个符号代表一只动物。ELISA在Immulon 2 U板中进行,使用SpectraMax plus微孔板读数仪读取,检测限(LOD)为100 pg/ml。细胞因子滴度在GraphPad Prism 9中绘图。中位数由水平条表示,使用Wilcoxon检验对未刺激细胞和用重组PEDVS1蛋白刺激的细胞进行统计学比较。

### 来自接种后备母猪的哺乳仔猪被动保护评估

#### 3日龄时PEDV感染——来自接种和对照后备母猪的仔猪活产和生长动力学

接种后备母猪的分娩时间保持相对紧密的同步性,在约100天妊娠时被转移到BSL3动物隔离设施。在3日龄时(第0天)用传染性PEDV对仔猪进行口服攻毒。每天记录仔猪体重下降评分和抑郁评分,直至9日龄,以攻毒当天各组百分比为100%进行比较(表2)。评分标准从每项标准> 3分改为累计平均4分或更高,因此无法进行跨试验比较(表4)。然而,接种组的大多数猪在第4天被安乐死,这表明它们未得到充分保护以抵御感染性攻击(图4)。这些结果表明,单次i.m.免疫或i.u./i.m.免疫(使用PEDVS1 ARC4/7 PLGA NP)未能为哺乳后代提供被动保护。这些数据与Langel等(1)的结果一致,后者表明仔猪存活与乳汁中高PEDVS1 IgA抗体和病毒中和抗体呈正相关(1)。

我们测量了两组接种后备母猪相对于阴性对照和阳性对照后备母猪的活产仔猪数和死产数(图3A)。我们观察到对照后备母猪和接种后备母猪所产活产或死产数量之间无显著差异,表明有或无配种时初免疫苗的i.m. NP疫苗接种对生育力无负面影响。我们接下来测量了3日龄仔猪的体重,观察到来自i.m.接种后备母猪的仔猪体重显著小于其他组,但各后备母猪所产仔猪的体重存在较大变异(图3B)。需要增加每组后备母猪的数量,以客观地确认i.m.疫苗接种本身是否影响仔猪出生体重。

**图3 | 对照后备母猪和通过肌肉注射途径(有或无预先子宫内疫苗接种)接种的后备母猪所产仔猪的出生数和体重。** 后备母猪在发情后30天用PEDVS纳米颗粒免疫(i.m.组),或在配种时通过子宫内途径免疫并30天后进行i.m.疫苗(i.u./i.m.组)。阴性对照组后备母猪未接受任何疫苗。阳性对照后备母猪先前用活PEDV减毒疫苗免疫,显示对仔猪的被动保护。(A)记录每窝活产数和每窝死产数。每个符号代表每头后备母猪的仔猪数。平均值由水平条表示,误差棒表示标准差。(B)在3日龄时对仔猪称重(kg)。数据显示为各后备母猪所产所有仔猪的出生体重,中位体重由水平线表示。使用Kruskal-Wallis检验和Dunn多重比较检验进行对照与接种动物(A)以及所有组(B)之间的统计学比较。显著差异用不同星号表示(*p < 0.05, **p < 0.01, ****p < 0.0001)。

**图4 | 出生3天后用传染性PEDV攻毒时仔猪的存活率。** 来自阴性对照组后备母猪、i.m.接种后备母猪和i.u./i.m.接种后备母猪的大多数仔猪在第4天被安乐死,此时其累计抑郁和体重下降评分达到4分。

**表4 | 病毒攻毒后仔猪的临床评估**

| 标准 | 评分 | 组别 | 第1天 | 第2天 | 第3天 | 第4天 | 第5天 | 第6天 | 第7天 | |---|---|---|---|---|---|---|---|---|---| | 体重评分 | 0 | i.m. | 34 | 39 | 3 | 10 | 1 | 2 | 1 | 死/安乐死 | | | | i.u./i.m. | 34 | 39 | 10 | 10 | 2 | 2 | 4 | | | | 1 | i.m. | 5 | 1 | 5 | 23 | 2 | 2 | 3 | | | | | i.u./i.m. | 5 | 1 | 5 | 12 | 3 | 1 | 4 | | | | 2 | i.m. | 1 | 24 | 23 | 1 | 5 | 2 | 1 | | | | | i.u./i.m. | 1 | 24 | 23 | 3 | 5 | 1 | 1 | | | | 3 | i.m. | 0 | 2 | 2 | 6 | 23 | 12 | 1 | | | | | i.u./i.m. | 0 | 2 | 2 | 6 | 12 | 1 | 1 | | | 抑郁评分 | 0 | i.m. | 34 | 23 | 40 | 1 | 1 | 1 | 1 | | | | | i.u./i.m. | 34 | 23 | 40 | 1 | 1 | 1 | 1 | | | | 1 | i.m. | 5 | 2 | 1 | 30 | 13 | 1 | 1 | | | | | i.u./i.m. | 5 | 2 | 1 | 29 | 13 | 3 | 1 | | | | 2 | i.m. | 1 | 25 | 29 | 29 | 10 | 6 | 1 | | | | | i.u./i.m. | 1 | 25 | 29 | 29 | 11 | 6 | 1 | | | | 3 | i.m. | 0 | 2 | 9 | 31 | 31 | 10 | 1 | | | | | i.u./i.m. | 0 | 2 | 9 | 31 | 31 | 10 | 1 | | | | 4 | i.m. | 0 | 0 | 10 | 4 | 6 | 5 | 1 | | | | | i.u./i.m. | 0 | 0 | 10 | 4 | 6 | 5 | 1 | |

宿主在暴露时的免疫成熟度、暴露的时间和频率以及抗原的性质(27, 29–33)。我们曾证明,单次经子宫内(i.u.)接种含800 µg蛋白抗原与VIDO三重佐剂[TriAdj:400 µg Poly I:C(聚肌苷酸-聚胞苷酸)、800 µg HDP(宿主防御肽)和400 µg PCEP(聚磷腈)]的可溶性疫苗,或以双乙烯亚胺灭活(BEI)的猪细小病毒(PPV)联合TriAdj配制的疫苗,不足以在血清或黏膜组织中诱导强效抗体介导的免疫应答(34)。相反,我们还观察到,使用可溶性PEDVS1联合TriAdj进行3次i.u.免疫后,可在血清、子宫黏膜和初乳中诱导显著的抗PEDVS1应答(22)。事实上,与对照组相比,初乳中的中和抗体显著升高,但其滴度仍不足以保护哺乳仔猪抵抗传染性PEDV感染(22)。然而,本试验表明,i.u.纳米颗粒(NP)疫苗联合肌内(i.m.)NP疫苗所诱导的血清抗PEDVS1 IgG应答水平,约为子宫三次接种可溶性PEDVS1疫苗的10倍(22)。初乳中抗PEDV IgG滴度显著升高,而IgA滴度未见显著变化,提示NP制剂可能是一种更优的免疫配方,值得进一步研究。

我们此前曾探究在猪体内先进行子宫内免疫再辅以肌内免疫是否会引发黏膜耐受;然而,该试验设计存在重要差异,可能影响对结果的解读。我们实验室先前的实验表明,单次i.u.接种可溶性亚单位蛋白联合TriAdj后,间隔3周再进行两次i.m.免疫(22),其诱导的抗FliC血清IgG应答极低(约400抗FliC IgG滴度),因此尚不清楚是否诱导了耐受。不过,i.u./2×i.m. FliC可溶性疫苗方案确实触发了显著且相对较高的IFNγ滴度,提示细胞介导免疫(CMI)被激活。然而,我们此前比较的对象是经子宫三次接种PEDV可溶性疫苗的后备母猪。由于所用抗原不同,难以判断所测免疫应答的差异究竟源于接种途径还是抗原本身的免疫原性。因此,在本试验中,我们希望明确基于NP的疫苗是否会影响免疫耐受,并在两组接种疫苗的后备母猪中使用相同抗原。结果显示,无论是单独i.m.接种还是i.u./i.m.联合接种,后备母猪在接种后第70天或第0天均诱导了约10,000抗PEDVS1 IgG滴度。相比之下,无论是否先行i.u.免疫,本试验中妊娠第100天时的PEDVS1特异性CMI应答均较低。然而,当后备母猪通过接触受挑战的仔猪而间接暴露于病毒时,我们观察到PEDVS1特异性CMI应答呈上升趋势。显然,NP制剂并未促进黏膜耐受。结果也清楚表明,仅重复i.u.接种可溶性疫苗(22)或联合i.m.注射NP疫苗,均未能显著促进保护性被动免疫。需进一步开展多剂量试验(如在每个繁殖周期接种),并增加抗原剂量或尝试不同佐剂组合,才能开发出能有效保护仔猪免受新生期疾病侵害、并保护后备母猪/经产母猪免受繁殖障碍疾病的i.u.疫苗。针对不同疾病,疫苗策略可能需有所调整:例如,针对PRRSV或PPPV等繁殖性疾病,可能需要i.u.初免联合i.m.加强,因为目前尚无充分证据表明子宫来源的IgA抗体分泌细胞可迁移至成熟乳汁;而针对PEDV等肠道疾病,已有研究表明肠道初免/感染可在成熟乳汁中诱导强效抗PEDV抗体,从而保护仔猪(1),提示肠道而非子宫的初免可能影响初乳和乳汁中的抗体水平。另有研究显示,在分娩前46天开始,经i.m.接种三次PEDVS1联合TriAdj,可诱导显著的血清抗体和中和抗体滴度,有效保护仔猪抵抗传染性PEDV(5)。因此,根据不同疾病特点,可能需要采取不同策略以促进有效的黏膜免疫。

PLGA纳米颗粒(NPs)可作为疫苗制剂的潜在递送系统。通过调控PLGA的物理性质,可将其包裹的抗原定向递送至胞质(用于MHC I类分子呈递并激活CD8+ T细胞)或内体(用于MHC II类分子呈递并激活CD4+ T细胞)。既往研究表明,PLGA内容物的胞质递送受其分子量差异的影响(35)。基于PLGA NPs的黏膜疫苗已在猪模型中证明可诱导所需的T细胞应答并清除病毒血症。例如,将VR2332株PRRSV超声抗原包封于PLGA NPs(Nano-KAg)后经鼻内接种,显著提高了猪肺部的病毒中和滴度,优于未接种组和灭活疫苗组(36)。Nano-KAg接种组猪的肺匀浆和血清中IFN-γ水平更高、TGF-β水平更低,且可在2周内完全清除病毒血症。此外,将灭活流感病毒抗原包封于PLGA NPs中,在猪模型中可减轻临床症状并诱导交叉保护性细胞介导免疫应答(37)。另有研究将含有基质蛋白2胞外域嵌合体和高度保守的H1N1大流行株及人流感病毒肽段的诺如病毒P颗粒包封于PLGA NPs中(38),无论是否联合分枝杆菌全细胞裂解物佐剂,经鼻雾化接种后均能在猪肺部诱导病毒特异性T细胞应答并降低攻毒后气道病毒载量。由此可见,PLGA NPs作为疫苗递送载体在猪的黏膜免疫中具有良好的应用前景。

在小鼠试验中,我们发现OVA联合ARC4/7佐剂并包封于PLGA聚合物NPs中,可诱导强效的血清抗体介导免疫、IFNγ相关的CMI及显著的淋巴细胞增殖,效果优于无佐剂疫苗组(10)。其他研究表明,MPLA联合猪链球菌蛋白可在猪中提供免疫保护(17);猪对MDP也有应答(18),因此评估这些佐剂是否能在猪体内触发固有免疫应答是合理的。本研究中,NP疫苗未能诱导CMI应答,但当后备母猪通过仔猪间接暴露于病毒时,T细胞显示出向抗原特异性CMI诱导的趋势。

本研究旨在评估单次肌内接种包封PEDVS1抗原及佐剂的PLGA NP疫苗,能否在猪体内诱导抗原特异性的黏膜和系统性免疫,从而为仔猪提供被动保护。结果显示,该NP疫苗可在血清和子宫组织中诱导显著的抗PEDVS1 IgG和IgA,并在初乳中诱导IgG,但在成熟乳汁中未观察到显著应答。尽管后备母猪体内免疫应答显著,但单次i.m.接种该NP疫苗所产生的病毒中和抗体浓度仍不足以提供针对传染性疾病所需的被动免疫保护。未来应使用PRRSV或PPV抗原评估该i.m. NP疫苗单独使用或经i.u.初免后,是否有助于在后备母猪中建立针对繁殖性疾病的保护性免疫。在配种时对后备母猪进行单次免疫,或辅以第二次系统性免疫,将受到养猪业的欢迎,因其可在减少人力投入(将免疫与配种操作结合)的同时,单独或与单次注射联合诱导保护性免疫。