Background
African swine fever (ASF) is a highly contagious viral disease, a disease that must be reported to the World Organization for Animal Health (OIE) [
1]. ASF was first reported in Kenya in 1921 [
2], and then gradually spread to neighboring countries, in 2007–2017 to Georgia, Russia, Romania, and other European countries [
3], and in 2018 to China, Mongolia, Vietnam, Cambodia, Laos, North Korea, and South Korea and other Asian countries [
4,
5]. The disease is caused by the ASF virus (ASFV), a double-stranded DNA virus with a large genome (170–193 kb) [
6]. ASFV has 151–167 open reading frames (ORFs) and encodes 54 structural proteins and more than 100 non-structural proteins [
7‐
10]. ASFV is the only known DNA arbovirus, has 24 genotypes and 8 serotypes, and sole member of the
Asfarviridae family [
10,
11]. A species of soft tick (
Ornithodoros moubata) is the natural host of ASFV. The virulent ASFV strains can cause acute hemorrhagic fever and lead to up to 100% mortality in domestic pigs and wild boar (
Sus scrofa) [
6,
12]. Currently, there is no commercial vaccine to prevent ASF, and the epidemic is still spreading.
At present, various types of vaccines are under development to prevent ASF, including inactivated vaccines, live attenuated vaccines, subunit vaccines, DNA vaccines, virus vector vaccines, etc. Studies have shown that either traditional inactivated vaccines alone or with new adjuvants can produce specific antibodies but has no protective effect [
13,
14]. The single or combination of ASFV CD2v, P30, P54, and other subunit vaccines show some protective effects [
15,
16]. The "cocktail" immunization by using adenovirus vector vaccines carrying EP402R Δ PRR, p54, p72, and so on, and the recombinant B646l (p72), EP153R and EP402R (CD2v) vaccinia virus vaccines can all induce strong humoral and cellular immunity [
17,
18].
Cytotoxic T lymphocyte (CTL) immune response plays an important role in protecting ASFV [
19]. Most DNA vaccines, such as a DNA vaccine expressing the ubiquitin (Ub)/CD2v/P54/P30 fusion protein, can effectively activate CTL immune response and provide partial protection after immunization in pigs [
20,
21]. A vaccine that contains 80 ORFs of ASFV (Ba71V) fused with ubiquitin can provide 60% protection after immunization, and the specific CTL immune response can be induced after the virus challenge [
22]. Natural attenuated strains or improved live viruses show good protective effects, but most live attenuated vaccines only had a protective effect on the homologous strains [
23‐
26]. Besides, most live attenuated vaccines lack high-yield cell lines. ASFV mainly infects the host monocyte-macrophage system through megapinocytosis and cytophagocytosis mediated by grid protein, and the production is low in the primary monocytes/macrophages [
27,
28]. Besides, attenuated ASFV can produce adverse side effects, such as lymphadenopathy, recurrent fever, chronic viremia, persistent chronic infections and the possibility of virulence recovery [
23]. These adverse factors hamper their development as usable vaccines. In contrast, subunit vaccines, DNA vaccines, and viral vector-based vaccines show advantages in terms of safety and productivity and are likely better options to be developed for preventing ASF.
Pseudorabies virus (PRV),
Alphaherpesvirinae subfamily of the
Herpesviridae, is the pathogen of swine
Aujeszky's disease, a double-stranded DNA virus with a genome size of 145 kb. Domestic pigs and wild boars are the natural hosts of PRV [
29,
30]. PRV can infect pigs of all ages, but the symptoms appear different. Infection of PRV in adult pigs will lead to abortion and respiratory symptoms, while in piglets will lead to fatal encephalitis, which has caused huge economic losses in the global pig breeding industry [
31]. Other mammals, such as rodents, can also be infected by PRV, and the host systemic inflammatory response, especially neuroinflammation, can cause severe itching and acute death in infected mice [
32].
The PRV Bartha-K61 vaccine has been used to protect pigs from PRV infection. However, in recent years, a new PRV clade which belongs to the genotype II has been found in the pigs immunized with Bartha-K61, which belongs to genotype I. Thereby, the Bartha-K61 vaccine does not provide complete protection for the type II virus [
30,
33] and new vaccines are needed to prevent the emergence of new epidemics. Several new vaccine strains, such as PRV TK
−/gE
−/gI
− (Fa) [
34], JS-2012-ΔgE/gI [
29], gE
−/gI
−/TK
− PRV (HeN1) [
35], have all showed good protection capabilities, and PRV TK
−/gE
−/gI
− (Fa) has been commercially used for the prevention of pseudorabies. PRV has more than 70 ORFs that encode 70–100 proteins, but only about 50 proteins are contained in mature virus particles. Many genes are unnecessary for PRV replication, such as TK, gE, and gI, which can be replaced by foreign genes [
36‐
38]. Therefore, PRV is often used as a viral vector to carry foreign genes to develop recombinant vaccines. Many PRV recombinant strains, such as JS-2012-ΔgE/gI-E2 (expressing classical swine fever virus E2 protein) [
39], PRV SA215/VP2 (expressing parvovirus VP12 protein) [
40], PRV-P12A3C (expressing foot-and-mouth disease virus P12A and 3C proteins) [
41], show good immunogenicity and safety.
The outer envelope protein CD2v of ASFV, encoded by the EP402R gene, is highly similar to the host CD2 protein in structure and function and is the key protein that mediates the ASFV binding with red blood cells and causes their adsorption [
42]. ASFV infection can inhibit the proliferation of peripheral blood lymphocytes in vitro, which can be rescued by the EP402R gene deletion [
43]. Deletion of CD2v can strongly inhibit ASFV proliferation by 100–1000 times in lymphoid tissue and bone marrow, and ameliorate viremia [
43]. Thus, CD2v is likely to be involved in the immune escape, tissue phagocytosis of ASFV, and immunosuppressive effects. Blocking CD2v may revoke the host immunosuppressive effect, thereby enhancing the host's antiviral ability. CD2v has been developed as subunit, DNA, and virus vector vaccines, to provides partial protection [
15,
20,
44]. At present, there is no report on the recombinant multivalent vaccine that recombinantly expresses the ASFV gene using PRV as a vector. In this study, we constructed a recombinant pseudorabies virus, PRV-ΔgE/ΔgI/ΔTK-(CD2v), that expresses the ASFV CD2v protein by using the CRISPR/Cas9 technology, and its safety and ability to produce humoral and cellular immune responses were evaluated in mice to provide evidence for the future vaccine development to prevent both African swine fever and Pseudorabies.
Materials and methods
Cells, virus, and mouse
All cell culture reagents were purchased from Life Technologies (CA, USA) unless otherwise indicated. Human embryonic kidney (HEK 293 T) cells and Vero cells were cultured in Dulbecco's Modified Eagle Medium (DMEM) containing 10% FBS (GIBCO), 100 U/ml penicillin, 100 mg/ml streptomycin, and 5% CO2 at 37 °C. The peripheral blood lymphocytes of mice were cultured in RPMI 1640 medium. EXPi293 cells were purchased from Thermofisher (CA, USA) and cultured in a constant temperature shaker with OPM-293 CD03 medium under 8% CO2, 37 °C, 220 rpm/min. PRV was obtained from Fujian Academy of Agricultural Sciences (Fujian, China) and expanded in Vero cells. The viral titer was determined by the Karber method as follows: 2 × 104 Vero cells in 90 μl DMEM were mixed with 10 μl virus solution and plated onto 96-well plates for tenfold gradient dilution, and 8 multiple wells were set for each dilution gradient. The cytopathic effect was observed every 24 h until no change appeared in any well. The titer's calculation formula is lgTCID50 = L-D (S-0.5), where L is the logarithm of the highest dilution, D is the difference between the logarithm of dilution, and S is the sum of the proportion of positive wells.
Four-week-old SPF-ICR mice were purchased from Wushi Experimental Animal Trade Co., Ltd (Jiangsu, China). The animal experiments were performed under the Guide for the Care and Use of Laboratory Animals approved by Fujian Provincial Office for Managing Laboratory Animals and were overseen by the Fujian Normal University Animal Care and Use Committee (SYXK: 2015-0004).
Plasmids and viruses construction
Construction of the knockout (KO) plasmids used the pX459 plasmid vector (purchased from Addgene, MA, USA, digest with BpiI (37 °C, 15 min) (purchased from Thermo Fisher Scientific, MA, USA)) and sgRNA sequences (Table
1) targeting the PRV gE, gI and TK genes according to the website (
https://www.e-crisp.org/e-crisp/designcrispr.html). After transformation into DH5α
E. coli, the recombinant plasmids were isolated and verified by sequencing.
Table 1
The sgRNA sequences target PRV-Fa gE, gI, TK genes
PRV-TK-sgRNA-F | 5′-caccgTGCCCGAGCCGATGGCGTGC-3′ |
PRV-TK-sgRNA-R | 5′-aaacGCACGCCATCGGCTCGGGCAc-3′ |
PRV-gE-sgRNA-F | 5′-caccgGCCGGCGACGATGACCTCGA-3′ |
PRV-gE-sgRNA-R | 5′-aaacTCGAGGTCATCGTCGCCGGCc-3′ |
PRV-gI-sgRNA-F | 5′-caccgCGCGGGGTCGTACGTGCTGC-3′ |
PRV-gI-sgRNA-R | 5′-aaacGCAGCACGTACGACCCCGCGc-3′ |
The eukaryotic expression vector pcDNA3.4-(N-CD2v)-His was constructed using pcDNA3.4 (purchased from Addgene, MA, USA). The extracellular region of CD2v (46–615 bp, encoding 16-205aa) synthesized by the Wuhan GeneCreate Biological Engineering (Hubei, China) was inserted into pcDNA3.4 and fused with the His-tag at the C-terminus. The full-length CD2v gene (based on pig/HLJ/2018 [
1] strain) was synthesized by Wuhan GeneCreate Biological Engineering (Hubei, China) and used to make pcDNA3.1-EGFP-Flag-CD2v-Flag. The recombinant vectors were transformed into
E. coli DH5α (DE3). All plasmids were extracted using a kit (DP118-02) purchased from TIANGEN BIOTECH (Beijing, China).
To generate gene-deleted PRVs, the KO plasmids targeting PRV gE, gI, TK were transfected into 5 × 10
5 HEK 293 T cells. Six h after transfection, 1 × 10
5 TCID
50 PRV-Fa was added. The virus culture was harvested when the cytopathic effect reached 90% or more. The sgRNA-induced mutation was determined by PCR and sequencing by the primers as shown in Table
2. Four rounds of plaque purification were performed in Vero cells to obtain pseudorabies gE, gI double gene deletion strain PRV-ΔgE/ΔgI and gE, gI, TK triple gene deletion strain PRV-ΔgE/ΔgI/ΔTK.
Table 2
Primers for verifying viral genes mutation
PRV-TK-KO-F | 5′-TCGTAGAAGCGGTTGTGG-3′ |
PRV-TK-KO-R | 5′-CGACCAGGACGAACAGG-3′ |
PRV-gE-KO-F | 5′-AAAAGGTGGTGTTTGCATAATT-3′ |
PRV-gE-KO-R | 5′-TCGGTGGTGATGTAGAACG-3′ |
PRV-gI-KO-F | 5′-GTGGGCGTGTGCGTCTA-3′ |
PRV-gI-KO-R | 5′-CGGACGGAGATAAAACGC-3′ |
To generate recombinant PRV (PRV-ΔgE/ΔgI/ΔTK-(CD2v)), 5 μg of plasmid and 1 μg of the homologous recombinant fragment were co-transfected into HEK 293 T cells. Six h after transfection, 5 × 105 TCID50 of PRV-ΔgE/ΔgI was added. The virus culture was harvested when 90% of the cells were assured of having cytopathic effects. Finally, the recombinant PRV-ΔgE/ΔgI/ΔTK-(CD2v) strain expressing ASFV CD2v was amplified and purified in Vero cells by four rounds of phagocytosis.
Immunofluorescence
HEK 293 T cells (2 × 105) were cultured for 24 h, and transfected with pcDNA3.1-EGFP-Flag-CD2v-Flag or infected with 5 × 104 TCID50 viruses for 36 h. The cells were fixed with 1 ml 4% paraformaldehyde, penetrated with 1 ml 0.1% Triton X-100 (Sangon Biotech, Shanghai, China), incubated by mouse anti-Flag monoclonal antibody (TransGen Biotech, China) followed by Goat anti-mouse IgG H & L (Alexa fluor ® 488) preadsorbed (ab150117), and the images were obtained by scanning with ZEISS LSM700 microscope.
Western blot analysis
HEK 293 T cells were cultured for 24 h, and transfected with the plasmid pcDNA3.1-EGFP-Flag-CD2v-Flag or infected with 1 × 106 TCID50 of PRV-ΔgE/ΔgI/ΔTK-(CD2v). Samples were collected 48 h after transfection or viral infection. The protein concentration was determined by a BCA protein concentration test kit (from Beyotime Biotechnology, Shanghai, China)). Sixty μg of proteins were loaded for SDS–polyacrylamide gel electrophoresis and transferred to the PVDF membrane. The membrane was sealed with 5% skim milk at room temperature for 2 h, then incubated with the mouse anti-Flag monoclonal antibody (1:1000 dilution, ProteinFind® Anti-DYKDDDDK Mouse Monoclonal Antibody HT201-01 (TransGen Biotech, (Beijing, China)) or GAPDH (14C10) Rabbit mAb (Cell Signaling Technology, USA) in 5% skimmed milk plus 100 mg/L NaN3 at 4 °C for 8 h, washed with TBST buffer for 3 times, followed by incubation with secondary antibody IRDye 800cw donkey anti-mouse IgG (LI-COR) (1:10,000) at room temperature for 2 h. The membrane was washed with TBST and visualized by using LI-COR Odyssey infrared fluorescence scanning imager.
Virus growth and pathogenicity analyses
To determine the growth kinetics of the virus, 5 × 105 Vero cells in 2 ml DMEM were seeded onto each well of 6-well plates, 1 × 103 TCID50 viruses was added into each well, and the sample was collected at 12, 24, 36, 48 h post-infection, and virus titer was calculated by the Karber method.
The growth of plaques in Vero cells was observed by doubled-blinded crystal violet staining. Vero cells (5 × 105/each well) in the 6-well plates were infected with PRV-Fa, PRV-ΔgE/ΔgI/ΔTK, PRV-ΔgE/ΔgI/ΔTK-(CD2v) of 50 TCID50 for 48 h, and fixed with 4% paraformaldehyde for 30 min, stained with 2.5% crystal violet. Ten plaques were randomly selected to measure their areas under the microscope.
For the pathogenicity test, 4-week-old SPF grade ICR mice were fed adaptively for 1 week. The survival of mice was observed by injecting 5 × 105 TCID50 into the right hind leg muscle, and the survival curve was drawn accordingly.
(N-CD2v)-His purification
The EXPi 293 cells were transfected with pcDNA3.4-(N-CD2v)-His plasmid, collected after 7 days of culture, and lysed with RIPA (about 500 μl of RIPA per 1 × 107 cells). The (N-CD2v)-His protein was enriched with a nickel column and eluted with Elution Buffer (300 mM imidazole, 1 mM PMSF, 25 μl β-mercaptoethanol). The eluate was vacuum dried, dissolved in pH7.4 PBS, and used for SDS polyacrylamide gel electrophoresis. The purity of the recombinant protein was determined by Coomassie staining.
Virus copy analyses in mice
When the control PRV-Fa-infected mice group began to scratch (about 72 h postinoculation), the mice in all groups were euthanized by CO2 inhalation. The heart, brain, lung, liver, spleen and kidney tissues were collected, and the corresponding DNA was extracted. Real-time quantitative polymerase chain reaction (qPCR) was used to determine viral genome copies in infected cells and tissues. The PRV UL42 gene was used for standard control and was inserted into the pCDH plasmid to make pCDH-UL42. The UL42 gene was also amplified from the genomic DNA of the PRV-Fa strain using the forward primer 5′-ATGTCGCTGTTCGACGAC-3′ and the reverse primer 5′-TTAGAATAAATCTCCGTAGGCG-3′. Viral and tissue genomic DNA was extracted and purified by using a DNA Extraction Kit DP304 (TIANGEN BIOTECH (BEIJING)), and the PCR products were purified using FastPure Gel DNA Extraction Mini Kit DC301 (Vazyme Biotech, Jiangsu, China).
The virus copy number was also examined in feces. The feces of mice were picked up every 24 h after the virus challenge. One gram of feces was mixed with 5 ml of phosphate buffer saline (PBS) and soaked for 2 h, and the supernatant was collected by centrifugation at 3000 g for 10 min and used for extracting the genome DNA for qPCR determination of virus nucleic acid copies. The primers were: forward (5′-AACGTCACCTTCGAGGTGTA-3′) and reverse (5′-AGTCTGAACTCGTGCTTG-3′).
The virus copy number was calculated as follows: the average molecular weight (Dalton) of pCDH-UL42 = base number × 600 (Base pair average molecular weight), the length of pCDH-UL42 = 8542 bp (pCDH) + 1158 bp (PRV-UL42) = 9700 bp, and the copy number of 1 ng pCDH-UL42 = 6.02 × 1023 × (1 × 10–9/(9700 × 600)) ≈1.0 × 108. The standard curve was generated using the copy number of pCDH-UL42 as the ordinate, and the CT values determine the corresponding CT value as the abscissa and the copy number of the PRV genome.
Cytokine expression analyses in mice
The heart, brain, lung, liver, spleen and kidney tissues from the virus-infected mice were collected, and the total RNA was extracted. The RNA was extracted using Trizol Gamma Reagent (Thermo Fisher Scientific, CA, USA). cDNA was generated by reverse transcription using MonScript™ RTII All-in-One Mix with dsDNase Kit (Mona Biotech, Jiangsu, China) according to the manufacturer's instruction. The RNA expression of cytokines (see Table
3 for cytokine primers) was analyzed by reverse transcription qPCR.
Table 3
Primers for RT-qPCR
MUS-IL6-q-PCR-F | 5′-CTGCAAGAGACTTCCATCCAG-3′ |
MUS-IL6-q-PCR-R | 5′-AGTGGTATAGACAGGTCTGTTGG-3′ |
MUS-IL1β-q-PCR-F | 5′-GAAATGCCACCTTTTGACAGTG-3′ |
MUS-IL1β-q-PCR-R | 5′-TGGATGCTCTCATCAGGACAG-3′ |
MUS-TNFα-q-PCR-F | 5′-CAGGCGGTGCCTATGTCTC-3′ |
MUS-TNFα-q-PCR-R | 5′-CGATCACCCCGAAGTTCAGTAG-3′ |
MUS-IFNβ-q-PCR-F | 5′-AGCTCCAAGAAAGGACGAACA-3′ |
MUS-IFNβ-q-PCR-R | 5′-GCCCTGTAGGTGAGGTTGAT-3′ |
For testing interferon-γ (IFNγ), on day 7 after mice second immunization, peripheral blood lymphocytes (PBMCs) were obtained by collecting 1 ml of cardiac blood following the treatment with red cell lysate (Beyotime Biotechnology, China). PBMCs (1 × 106) were cultured for 12 h and treated with 10 μg recombinant protein (N-CD2v)-His for 72 h. The cells were then harvested, and the IFNγ transcription level was measured by qRT-PCR. The primers used for analyses were: IFNγ-Forward (5′-GCCACGCACAGTGATTGA-3′); IFNγ-Reverse (5′-TGCTGATGCCTGATTTGTCTT-3′).
Flow cytometry analysis of CD3/CD4/CD8/CD69 peripheral blood lymphocytes
When the control PRV-Fa group began to scratch (about 72 hpi), about 300 μl of blood was collected from the mouse orbit for analyses of CD3+, CD3+CD4+, CD3+CD8+, CD3+CD69+, CD4+CD69+, CD8+CD69+ peripheral blood lymphocytes by flow cytometry. Two hundred μl of blood was mixed with 1 μl of antibody (BV421 Hamster Anti-Mouse CD3ε, FITC Rat Anti-Mouse CD4, PerCP-CY 5.5 Rat Anti-Mouse CD8α, PE Hamster Anti-Mouse CD69 (BD pharmaceuticals, CA, USA) for 30 min in the dark at 25 °C, incubated with 600 μl of RBC lysate (Shanghai Biyuntian Biotechnology, China) for 5 min. The cells were collected by centrifugation and suspended in PBS containing 2% FBS followed by flow cytometry analyses (BD FACSymphony™ A5, BD Bioscience, CA, USA).
Immunization and challenge
Five-week-old SPF mice (ICR) were injected with either PRV-ΔgE/ΔgI/ΔTK or PRV-ΔgE/ΔgI/ΔTK-(CD2v) (100 μl each, 1 × 105 TCID50) via the i.m. route, and strengthened by the second immunization one week later. Seven days later, the mice were challenged by PRV-Fa with 5 × 105 TCID50. The control group was injected with 100 μL DMEM.
Enzyme-linked immunosorbent assay (ELISA) for Flag IgG
About 300 μl of blood was collected from the mouse orbit 0, 7 and 14 days after the first immunization. The supernatant was collected by centrifugation at 3000 rpm/min for 5 min after the blood was placed at room temperature for 10 min, and used for detecting the Flag IgG by ELISA using SBJ-M0915-96 T Flag-tag AB ELISA Kit (SenBeiJia Biological Technology, Jiangsu, China).
Hematoxylin–Eosin staining
Mouse tissues were fixed with 4% paraformaldehyde for 12 h. The samples were treated with 30% ethanol, 50% ethanol, 70% ethanol, 90% ethanol, 95% ethanol and anhydrous ethanol for 30 min each, followed by transparent treatment with the mixture of ethanol and xylene (1:1), and xylene to replace the ethanol in the tissues. The tissues were treated with a mixture of paraffin and xylene (1:1) overnight, then embedded into the paraffin. The tissues were cut to the 7 μm slices followed by staining with hematoxylin and eosin, and the morphological changes were checked by Zeiss Axio Imager A2/D2/m2/Z2.
Data statistical analysis and image processing
Images for Western blotting, H&E staining, crystal violet staining and immunofluorescence were processed by Adobe Illustrator CS6, and the sequence data were analyzed by BioEdit. All experiments were repeated at least 3 times independently. Unpaired t-test or two-way ANOVA (Graphpad Prism 5.0, Graphpad Software, San Diego, CA, USA) was used to analyze data differences between groups. Data are presented as the mean ± SEM in the same treatment.
Discussion
The outbreak of ASF has seriously threatened the development of the pig breeding industry, but there is no effective vaccine to prevent the disease. Various ASFV vaccines have been made, but none has been commercially used [
14,
16,
20,
25]. Although some viral vector vaccines have good in vitro proliferation capacity, low production costs, and can effectively activate T cell immune responses [
44], many other vaccines have suffered from low yields, high production costs, many side effects, and poor protection capabilities [
7,
12,
23]. Pseudorabies virus is a good example of many replication nonessential genes such as gE, gI, TK and so on in its huge genome. While replaced by foreign genes, the virulent virus can become a safe and effective recombinant virus vector vaccine such as JS-2012-ΔgE/gI-E2, PRV SA215/VP2, and PRV-P12A3C [
39‐
41]. The alpha-herpes virus thymidine kinase (TK) gene is unnecessary for virus replication but is a gene related to virulence. It is usually the target gene of choice for constructing live attenuated vaccines with gene deletions and genetically engineered vector vaccines with foreign genes inserted and expressed.
The TK, gE, and gI three-gene deletion strain (PRV TK
−/gE
−/gI
− (Fa)) has been developed and commercially used as a live attenuated vaccine in China. Compared with current epidemic PRV strains, its safety has been accepted [
30]. Currently, the vaccines can target both genotype I and II strains, while type II is the prevalent strain in China. CD2v plays a major role in ASFV immune escape and tissue phagocytosis. As a key virulence gene, CD2v is usually deleted in the development of live attenuated vaccines [
45]. Numerous studies have shown that CD2v to provides partial protection as a subunit vaccine, DNA vaccine, and viral vector vaccine, indicating that CD2v can induce immune protection [
44]. In this study, we inserted the ASFV EP402R (CD2v) gene into the TK gene site of PRV-ΔgE/ΔgI to generate PRV-ΔgE/ΔgI/ΔTK-(CD2v) by the CRISPR/Cas9 technology [
46‐
48]. This virus strain is quite stable since CD2v is still expressed in infected Vero cells after 20 generations of passages. Previous studies suggest that CD2v processing is mainly depended on the infection of ASFV since the CD2v protein is not processed in uninfected cells [
42]. In contrast, we observed several CD2v processed isoforms in pcDNA3.1-EGFP-Flag-CD2v-Flag plasmid transfected and PRV-ΔgE/ΔgI/ΔTK-(CD2v) infected HEK 293 T cells. Thereby, we suggest that the processing of CD2v does not depend on the infection of ASFV, but may be related to cell types and cell death process.
CD2v is related to ASFV tissue phagocytosis [
49]. To test whether the insertion of CD2v would change the tissue pathology of PRV-ΔgE/ΔgI/ΔTK, we examined the viral copy number of mouse organ tissues. We found virus nucleic acid only in the various tissues, including the brain of the mice infected with PRV-Fa, but not PRV-ΔgE/ΔgI/ΔTK) or PRV-ΔgE/ΔgI/ΔTK-(CD2v) at 72 hpi. Extending the infection time to 200 h, we detected viral nucleic acids in the brain and lung tissues of mice in the PRV-ΔgE/ΔgI/ΔTK group or PRV-ΔgE/ΔgI/ΔTK-(CD2v) group. But unlike PRV-Bartha, after prolonging the infection time, the viral load in the mouse brain is not higher than that of the virulent strain [
32], suggesting that the virulence of the recombinant strain is weaker than PRV-Bartha. Unlike PRV-Fa, the infection with PRV-ΔgE/ΔgI/ΔTK and PRV-ΔgE/ΔgI/ΔTK-(CD2v) in mice did not cause pruritus and death. Systemic inflammation, especially neuroinflammation caused by virulent strains is the major cause of death in mice. IL6 is a major sign of systemic inflammation which can be induced by virulent virus infection such as PRV-Becker infection [
32]. But, PRV-ΔgE/ΔgI/ΔTK or PRV-ΔgE/ΔgI/ΔTK-(CD2v) did not cause an IL6 increase in infected mice's tissues and sera. Besides, H&E staining showed that only the PRV-Fa strain could cause brain inflammation in mice. Therefore, the insertion of CD2v does not change the virulence and tissue phagocytosis of the attenuated strain (PRV-ΔgE/ΔgI/ΔTK), and the recombinant strain is safe for mice.
CD2v is a decisive factor for ASFV infection of peripheral blood lymphocytes in
vitro to inhibit lymphocyte proliferation in response to mitogens [
43]. Whether CD2v will inhibit T cell proliferation in
vivo is still unknown. When we extracted the mouse organs, we found the splenomegaly in the mice inoculated with PRV-ΔgE/ΔgI/ΔTK or PRV-ΔgE/ΔgI/ΔTK-(CD2v), suggesting that the immunization of the attenuated strains activate the mouse immune system leading to the splenomegaly. We found that the spleen congestion filled with a large number of lymphocytes, and the inoculation of these attenuated strains increase CD3
+, CD3
+CD4
+ T cells. However, the ability of PRV-ΔgE/ΔgI/ΔTK-(CD2v) to induce T cell proliferation is weaker than PRV-ΔgE/ΔgI/ΔTK, which is mainly manifested as inhibition of CD8
+ T cells, suggesting that CD2v in the recombinant strain can still interfere with the proliferation of T cells in vivo, but with less capability. The structure and function of ASFV CD2v protein resemble that of the host CD2 [
45]. CD2 can activate T cells after binding to its ligands [
50]. Whether CD2v can activate T cells in vivo has not been reported previously. CD69
+ cells are a major indicator of T cell activation [
51]. We analyzed the T cell subtype and found that the recombinant strain can activate T cells after immunization; both CD4
+ and CD8
+ T cells are activated, but PRV-ΔgE/ΔgI/ΔTK cannot activate T cells at 72 hpi. PRV-ΔgE/ΔgI/ΔTK can also activate T cells, but this occurs at the late stage (200 hpi) of infection. These data suggest that CD2v can activate T cells in vivo. CD4
+ delayed-type hypersensitivity-like effector cells are a crucial effector mechanism for protective immunity against PRV [
52]. Compared with PRV-ΔgE/ΔgI/ΔTK, the recombinant strain can activate more CD4
+ T cells. Therefore, the recombinant strain is more suitable for the prevention of pseudorabies.
Adenovirus, vaccinia virus Ankara and alphavirus are often used to develop ASFV virus vector vaccines. They can induce specific antibody production or T cell immune response, but most of their protection capabilities have not been verified [
5]. In this study, the production of the specific antibody targeting CD2v has also been manifested by the indirect examination of the anti-Flag antibody production since CD2v is fused with the Flag-tag and the detection of the anti-Flag antibody can represent the expression antigenicity of CD2v protein. But, we can not exclude the other possibilities that may interfere with the CD2v expression or the inability of antibody production associated with CD2v production, processing, or antigen-presenting, so on. It has shown that CD2v protein can protect piglets from the ASFV challenge, even the neutralizing antibody is not present, which implicates the other factors that may be involved in counteracting the viral infection [
15]. Previous studies have shown that pigs with depleted CD8
+ T cells are not immune protected and suggested that a vaccine that can stimulate T-cell-mediated response may also reserve its ability to protect against ASFV infection [
19,
53].
Interestingly, our data show that PRV-ΔgE/ΔgI/ΔTK-(CD2v) can effectively activate the immune system to produce specific antibodies with strong immunogenicity. Besides, purified CD2v protein can also induce IFNγ expression, IFNγ is a major marker for T cell activation. Therefore, the PRV-ΔgE/ΔgI/ΔTK-(CD2v) strain can effectively activate specific T cell immune responses.
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