key: cord-0926253-k7chhpif authors: Mooij, Petra; García-Arriaza, Juan; Pérez, Patricia; Lázaro-Frías, Adrian; Verstrepen, Babs E.; Böszörményi, Kinga P.; Mortier, Daniella; Fagrouch, Zahra; Kiemenyi-Kayere, Gwendoline; Niphuis, Henk; Acar, Roja Fidel; Meijer, Lisette; Stammes, Marieke A.; Kondova, Ivanela; Verschoor, Ernst J.; GeurtsvanKessel, Corine H.; de Bruin, Erwin; Sikkema, Reina S.; Luczkowiak, Joanna; Delgado, Rafael; Montenegro, Dolores; Puentes, Eugenia; Rodríguez, Esteban; Bogers, Willy M. J. M.; Koopman, Gerrit; Esteban, Mariano title: Poxvirus MVA Expressing SARS-CoV-2 S Protein Induces Robust Immunity and Protects Rhesus Macaques From SARS-CoV-2 date: 2022-03-16 journal: Front Immunol DOI: 10.3389/fimmu.2022.845887 sha: 06d7982d8ee44f4b9e0f3173c3969512931c301c doc_id: 926253 cord_uid: k7chhpif Novel safe, immunogenic, and effective vaccines are needed to control the COVID-19 pandemic, caused by SARS-CoV-2. Here, we describe the safety, robust immunogenicity, and potent efficacy elicited in rhesus macaques by a modified vaccinia virus Ankara (MVA) vector expressing a full-length SARS-CoV-2 spike (S) protein (MVA-S). MVA-S vaccination was well tolerated and induced S and receptor-binding domain (RBD)-binding IgG antibodies and neutralizing antibodies against SARS-CoV-2 and several variants of concern. S-specific IFNγ, but not IL-4, -producing cells were also elicited. After SARS-CoV-2 challenge, vaccinated animals showed a significant strong reduction of virus loads in bronchoalveolar lavages (BAL) and decreased levels in throat and nasal mucosa. Remarkably, MVA-S also protected macaques from fever and infection-induced cytokine storm. Computed tomography and histological examination of the lungs showed reduced lung pathology in MVA-S-vaccinated animals. These findings favor the use of MVA-S as a potential vaccine for SARS-CoV-2 in clinical trials. Severe acute respiratory syndrome coronavirus 2 (SARS-CoV-2), which emerged in 2019 in Wuhan, China, has rapidly spread across the globe, infecting more than 262 million people, and over 5.2 million people have died due to the coronavirus disease 2019 . Several vaccines have now been approved for human use, including mRNA vaccines (BioNTech/Pfizer, Moderna), adenovirus-vector-based vaccines (AstraZeneca, Johnson & Johnson, CanSino Biologics, Gamaleya), and inactivated virus vaccines (Sinovac Biotech and Sinopharm). These vaccines have shown a good safety profile, potent immunogenicity, high efficacy, and relative durability of immune responses (1) . The current vaccines against COVID-19 either express the full-length S protein (AstraZeneca, CanSino Biologics, Gamaleya), or a stabilized prefusion form of the S protein with prolinestabilizing mutations and/or mutation of the furin cleavage site (Pfizer/BioNTech, Moderna, Johnson & Johnson) (1) (2) (3) (4) (5) (6) . The emergence of variants of concern (VOC), particularly beta and delta variants that showed more resistance to current vaccines than other variants (6) (7) (8) (9) (10) (11) , together with the inability to fully protect against reinfection and transmission in vaccinees (12) , highlights the need for novel optimized SARS-CoV-2 vaccines. In addition, the reported adverse cases of thrombosis with the adenovirus vaccines (13) and myocarditis with the mRNA vaccines particularly in young individuals (14) indicate that a deeper understanding of the mechanisms of action of the vaccines should be undertaken. We and others have developed several COVID-19 vaccine candidates based on the poxvirus-modified vaccinia virus Ankara (MVA) vector expressing the S protein that have shown a potent immunogenicity profile and full efficacy in several animal models, such as mice (15) (16) (17) (18) (19) (20) (21) , hamsters (22) , and non-human primates (NHPs) (20) . MVA is a highly attenuated strain of vaccinia virus, with a well-established safety, immunogenicity, and protective profile in preclinical and clinical research as a vaccine candidate against several infectious diseases and cancer (23) (24) (25) . MVA-based vaccines are safe and well tolerated, induce potent and durable antibody and CD4 + and CD8 + T-cell responses, even after a single immunization, are stable, and can be produced at high titer (26) (27) (28) . Furthermore, MVA-based vaccines can be used for boosting DNA, mRNA, and adenovirus or other viral vector-based vaccines (26, (29) (30) (31) . In the present study, we evaluated the safety, immunogenicity, and efficacy in rhesus macaques of a novel MVA-based vaccine candidate expressing a human codon-optimized full-length SARS-CoV-2 S protein (MVA-S), which was previously reported to induce potent B-and T-cell responses and full efficacy in mice (16, 17, 19) . The MVA-S vaccine was well tolerated, and strong binding IgG antibody responses, neutralizing antibodies against parental SARS-CoV-2 and VOC and S-specific IFNg-producing cells, were induced. Upon SARS-CoV-2 challenge, the MVA-S-immunized animals were protected against virus replication in the lungs, had reduced the levels of pro-inflammatory cytokines in serum and BAL samples, and had less lung pathology, compared to control MVA-wild-type (WT)-inoculated macaques. These results reinforce the use of MVA-S as a potential vaccine in clinical trials either alone or in combination with other vaccines. The study was performed in twelve adult female rhesus macaques (Macaca mulatta) that were divided into two groups of six animals each (MVA-S and MVA-WT groups). The animals underwent a full physical examination prior to entering the study. All individuals were healthy with normal clinical chemistry and hematology levels and free of pathogens. They were negative for antibodies to simian T-cell leukemia virus and simian retrovirus, and negative for binding antibodies to the RBD of the S protein of SARS-CoV2. The study was reviewed and approved by the Dutch "Centrale Commissie Dierproeven" (AVD5020020209404-2) according to Dutch law, article 10a of the "Wet op de Dierproeven" and BPRC's Animal Welfare Body (IvD). The study was conducted under the number CCD 028K. Approval by the Dutch Committee on the use of Genetically Modified Organisms to use MVA-S was granted (GGO IG 19-257_III-007). At first vaccination, the age of the animals ranged from 5 to 12 years old, and they weighed 5.6 to 9.9 kg. Four weeks before the study start, a telemetric device (AnipillV2 temperature implant, 1.7 g, BodyCAP, Heŕouville Saint Clair, France) was surgically placed in the abdominal cavity of the animals, to accurately record/transmit body temperature every 15 min. The normal circadian pattern was recorded over a 7-day period (days [8] [9] [10] [11] [12] [13] [14] before the first immunization, and for each 15-min time period of the day the mean value and 95% confidence interval were calculated. These values (mean plus 95% confidence interval) were subtracted from the temperatures recorded after immunization or infection, as described previously (32, 33) . Body weight was measured every time the animals were sedated for biotechnical procedures. General behavior and stool consistency were checked daily during the immunization period. During the course of SARS-CoV-2 infection, animals were checked twice a day and scored for clinical symptoms according to a previously published scoring system (skin and fur abnormalities, posture, eye and nasal discharge, sneezing and coughing, and respiration rate) (34) . A numeric score of 35 or more was predetermined to serve as an endpoint and justification for euthanasia. The MVA-S vaccine candidate expresses a human codonoptimized full-length SARS-CoV-2 S protein (Wuhan strain), and its generation was previously described (16) . The MVA-S vaccine candidate was manufactured according to current Good Manufacturing Practice by the company Biofabri (Spain), and its generation is a cost-effective system that could be scaled up for larger production. The MVA-S virus was grown in cultured chicken cells (DF-1), harvested, clarified and purified by Tangential Flow Filtration, vialed, and stored at -15°C-30°C. The MVA-WT virus was grown in DF-1 cells and purified by centrifugation through two 36% (wt/vol) sucrose cushions in 10 mM Tris-HCl (pH 9). MVA virus titers were determined by immunostaining, as previously described (35) . Twelve animals (six per group) were immunized twice, with a 4week interval, with 2 × 10 8 PFUs/animal of MVA-S vaccine candidate or MVA-WT, by intramuscular route (500 µl in the deltoid muscle of both upper arms). Local reactions at the immunization sites were recorded on days 1, 2, 3, and 4 following each immunization by Draize scoring. Clinical chemistry and hematology measurements were performed to monitor systemic adverse effects. Then, 4 weeks after the second immunization, all 12 animals were exposed to 10 6 TCID 50 of SARS-CoV-2 (isolate BetaCoV/German/BavPat1/2020, similar to the Wuhan strain but containing the D614G mutation, European Virus Archive, Germany) via the combined intranasal (0.25 ml/nostril) and intratracheal (4.5 ml) route. Infection was monitored for 2 weeks, daily for the first 7 days, and then at days 10, 12, and 14 post-challenge. Individual serum samples obtained from rhesus macaques at weeks 0 and 4 after the first immunization, 2 weeks after the second immunization (week 6), and on days 10 and 14 after SARS-CoV-2 challenge (week 10) were tested for the presence of binding IgG antibodies against SARS-CoV-2 S and RBD proteins using an enzyme-linked immunosorbent assay (ELISA), as previously described (16) . The S and RBD proteins used to coat the plates derived from the Wuhan strain (GenBank accession number MN908947.3) and were previously described (16) . In the S protein (residues 1 to 1,208), the furin-recognition motif (RRAR) was replaced by the GSAS sequence, and it also contained the A942P, K986P, and V987P substitutions in the S2 portion. The RBD protein spans residues 332 to 534 of the S protein. Total binding IgG titers were measured as the last serum dilution that gives an absorbance value at 450 nm at least three times higher the absorbance of serum from week 0 (pre-immune serum). Live-virus SARS-CoV-2 neutralizing antibodies were measured using a microneutralization test (MNT) assay in a BSL-3 laboratory. Serially two-fold diluted serum samples in DMEM-2% fetal bovine serum (FBS) medium were incubated at a 1:1 ratio with 100 TCID 50 of SARS-CoV-2 MAD6 isolate (having the D614G mutation in the S protein) in 96-well tissue culture plates for 1 h at 37°C. Then, mixtures of serum samples and SARS-CoV-2 were added in duplicate to Vero-E6 cell monolayers seeded in 96-well plates at 30,000 cells/well, and plates were incubated at 37°C, in a 5% CO 2 incubator for 3 days. Then, cells were fixed with 10% formaldehyde for 1 h and stained with crystal violet. When plates were dried, crystal violet was diluted in H 2 O-10% SDS and optical density was measured in a luminometer at 570 nm. Neutralizing titer 50 (NT 50 ) was calculated as the reciprocal dilution resulting in 50% inhibition of cell death following a methodology previously described (36) . A WHO International Standard containing pooled plasma obtained from eleven individuals recovered from SARS-CoV-2 infection (NIBSC code: 20/136) was used for the calibration and harmonization of the serological assay detecting anti-SARS-CoV-2 neutralizing antibodies. The capacity of serum samples obtained to neutralize different SARS-CoV-2 VOC was tested by using SARS-CoV-2-pseudotyped vesicular stomatitis viruses (VSV) expressing SARS-CoV-2 S protein, which were produced as described elsewhere (37) . The SARS-CoV-2 S variants used were S_614D, S_614G, alpha (B.1.1.7), beta (B.1.351), gamma (P.1), and delta (B.1.617.2). SARS-CoV-2 S mutant D614G was generated by site-directed mutagenesis (Q5 Site-Directed Mutagenesis Kit; New England Biolabs) following the manufacturer's instructions and using as an input DNA a pcDNA3.1 expression vector encoding SARS-CoV-2 S_614D (16). SARS-CoV-2 VOC alpha (B.1.1.7; GISAID: EPI_ISL_608430), beta (B.1.351; GISAID: EPI_ISL_712096), gamma (P.1; GISAID: E P I _ I S L _ 8 3 3 1 4 0 ) , a n d d e l t a ( B . 1 . 6 1 7 . 2 ; G I S A I D : EPI_ISL_1970335) were optimized, synthesized, and cloned into pcDNA3.1 by GeneArt (Thermo Fisher Scientific, GeneArt GmbH, Regensburg, Germany). The neutralization activity of serum samples was tested by triplicates at several two-fold dilutions. For neutralization experiments, viruscontaining transfection supernatants were normalized for infectivity to a multiplicity of infection of 0.5-1 PFU/cell and incubated with the dilutions of serum samples at 37°C for 1 h in 96-well plates. After the incubation time, 2 × 10 4 Vero-E6 cells were seeded onto the virus-serum mixture and incubated at 37°C for 24 h. Cells were then lysed and assayed for luciferase expression; NT 50 titers of neutralizing antibodies were determined as the highest serum dilution which resulted in a 50% reduction of luciferase units compared with pseudotyped viruses not incubated with serum. Moreover, neutralizing antibodies against several live SARS-CoV-2 VOC were also measured by plaque reduction neutralization tests (PRNT), as described previously (38) . SARS-CoV-2 viruses used were D614G (clade B; isolate Bavpat-1; European Virus Archive Global #026 V-03883), beta (B.1.351, GenBank accession number OM286905), and delta (B.1.617.2, GenBank accession number OM287123). In brief, serially diluted serum samples were incubated with 400 PFUs of different SARS-CoV-2 VOC. After 1 h at 37°C, the virus-serum mixtures were transferred onto the human airway cell line Calu-3 and incubated for 8 h. Subsequently, cells were fixed and permeabilized. Plaques were stained with polyclonal rabbit anti-SARS-CoV-2 nucleocapsid antibody (Sino Biological) and a secondary peroxidase-labeled goat anti-rabbit IgG (Dako). Plaques were visualized with the precipitate-forming 3,3′,5,5′tetramethylbenzidine substrate (TrueBlue; Kirkegaard & Perry Laboratories) and enumerated on the ImmunoSpot Image Analyzer (CTL Europe GmbH). Next, 50% plaque reduction neutralization (PRNT 50 ) titers were calculated. Recombinant proteins were produced for the S1 subunit (OC43, 229E, HKU1, NL63, MERS, SARS, and SARS-CoV-2) and S ectodomain (same as S1 except 229E) in HEK293 cells, as described before (39) . A protein microarray was used to detect in serum samples binding IgG antibodies to those recombinant proteins as described before (40) . Briefly, recombinant proteins were printed on nitrocellulose-coated glass slides (Sartorius, Göttingen, Germany) using a non-contact printer (Scienion, Berlin, Germany). After drying and blocking slides against non-specific binding using Blocker Blotto (Thermo Fisher Scientific, USA), serum was incubated in dilution series, starting from a 1 in 20 dilution in Blocker Blotto containing 0.1% Surfact-Amps (Thermo Fisher Scientific, USA), at 37°C for 1 h. After washing, slides were incubated for 1 h at 37°C using goat anti-human IgG (Fab specific, conjugated to AF647, Jackson ImmunoResearch, Ely, UK) 1 in 1,300 diluted in Blocker Blotto containing 0.1% Surfact-Amps. After washing, slides were dried and scanned using a PowerScanner (Tecan Group Ltd., Männedorf, Switzerland). Fluorescent values were analyzed using ImaGene 8.0 software (BioDiscovery, El Segundo, CA, USA). Titers were calculated from the inflection point of the serum dilution series at 50% of the maximum fluorescent signal using GraphPad prism (version 9.0.0, USA). Detection of specific IFN-g-and IL-4-secreting cells was performed by ELISpot assay (U-CyTech, Utrecht, Netherlands), as described previously (41) . In brief, 2.4 × 10 6 PBMCs were stimulated for 16 h with 1 µg/ml of SARS-CoV-2 peptides, divided over two pools, covering the S glycoprotein (PepMix SARS-CoV-2 Spike glycoprotein, pp1 158 peptides, pp2 157 peptides, Cat no PM-WCPV-S-2, JPT innovative peptide solutions, Berlin, Germany). After stimulation, non-adherent cells were collected and plated out (2 × 10 5 cells/well) in triplicate in PVDF ELISpot plates (Millipore, MA, USA) (including stimulus) that previously had been coated with either anti-IFN-g or anti-IL-4 monoclonal antibodies (U-CyTech). The negative control was medium alone, and the positive control a PMA/ionomycin mixture. SARS-CoV-2 Sspecific responses were calculated by subtracting the mean and two times the standard deviation of the number of spots measured in the medium control wells from the mean number of spots measured in the peptide stimulated wells and are expressed as spot-forming units (SFU) per million PBMCs. Spots were counted using the Automated ELISA-Spot assay video analysis systems (AELVIS GmbH, Hannover, Germany) reader with the aid of ELISpot reader system software. Tracheal, nasal, and anal swabs as well as BAL samples were analyzed for the presence of sgmRNA of the SARS-CoV-2 E gene using a quantitative real-time PCR, as previously described (42) . Viral RNA was isolated using a QIAamp Viral RNA Mini Kit (Qiagen Benelux BV, Venlo, Netherlands) following the manufacturer's instructions. The RT-qPCR assay was carried out using the Brilliant II QRT-PCR Core Reagent Kit, 1-Step Kit (Agilent Technologies BV, Amstelveen, Netherlands), according to the instructions provided by the manufacturer in a 25-ml volume with final concentrations of 600 nM for both primers, 200 nM for the probe, and 5 nM MgCl 2 , using 10 ml RNA, extracted from a 140-ml sample volume. RNA was reverse transcribed for 30 minutes at 50°C. Then, after a 10-min incubation at 95°C, the cDNA was amplified for 45 cycles, consisting of 30-s denaturation at 95°C, followed by a 1-min annealing-extension step at 60°C. All the reactions were carried out with an iQ5 Multicolor Real-Time PCR Detection System (Bio-Rad Laboratories BV, Veenendaal, Netherlands). The amount of RNA was quantified based on a standard curve made via in vitro transcription of a synthetic target sequence. Non-invasive, free-breathing, CT data were acquired preinfection and 2, 7, and 15-16 days post-challenge using a MultiScan Large Field of View Extreme Resolution Research Imager (LFER) 150 PET-CT (Mediso Medical Imaging Systems Ltd., Budapest, Hungary). The macaques were positioned head first supine with the arms up and fixated in a vacuum pillow. A single CT of the chest takes 35 s by which respiratory motion is inevitable. To mitigate the impact of respiratory motion and improve the image quality, respiratory gating was applied. The respiratory amplitude was detected with a gating pad placed next to the umbilicus. For the final reconstruction, the inspiration phases were automatically selected using MATLAB (43) . CT scans of the lung were evaluated blindly by two experienced CT operators and scored, as described previously (44, 45) . Quantification of CT lesions was performed based on the sum of the lobar scores. The score was normalized for preexisting abnormalities scored on day 0. The degree of involvement in each zone was scored as 0 for no involvement, 1 for <5%, 2 for 5%-24%, 3 for 25%-49%, 4 for 50%-74%, and 5 for ≥75% involvement. An additional increase or decrease of 0.5 was used to indicate alterations in CT density of the lesions. By using this scoring system, a maximum score of 35 for could be reached for the combined lobes per timepoint. Tissue samples from all pulmonary lobes, the upper respiratory tract (nasal mucosa, oro/nasopharynx, trachea, left and right bronchus), heart, kidney, liver, ileum, and colon were collected for histopathology and preserved by immersion in 10% neutralbuffered formalin for 72 to 96 h. Specimens for microscopic examination were processed and embedded in paraffin, and sections of 4 µm were stained with hematoxylin and eosin (H&E). The lesions were quantified as follows: 0 = no lesions, 1 = minimal, 2 = mild, 3 = moderate, 4 = severe, using a pulmonary histopathology scoring system for SARS-CoV-2 infection in macaques, as described (46) . Serum samples and BAL fluid were tested for the presence of cytokines and chemokines CXCL9, CXCL10, CXCL11, CCL2, CCL3, CCL4, CCL5, CCL11, IL1-b, IL-6, IL-8, IFNg, and TNFa using the LEGENDplex assay (BioLegend LEGENDplex ™ NHP Chemokine/Cytokine Panel, 13-plex, art. nr. 740317) according to the manufacturer's manual. Samples were measured on an Aurora flow cytometer (Cytek, Fremont, CA, USA) and analyzed by using company software. Statistical significance of differences between groups was calculated by using the Mann-Whitney test. A two-sided a level of 0.05 was used to determine significance. The correlation between binding IgG antibodies against RBD and virus-neutralizing antibodies and between virus-neutralizing antibodies and virus load in BAL samples was calculated by the Pearson correlation test performed on log-transformed data. To test the safety, immunogenicity, and protective capacity of the MVA-S vaccine candidate expressing the SARS-CoV-2 fulllength S protein, we immunized rhesus macaques (n = 6/ group) with the MVA-S vaccine at weeks 0 and 4 using an intramuscular dose of 2 × 10 8 plaque-forming units (PFUs)/ animal. Macaques inoculated with MVA-WT were used as a control group ( Figure 1A) . At week 8 (4 weeks after the boost), all animals were challenged intranasally and intratracheally with live SARS-CoV-2 (BetaCoV/German/BavPat1/2020 isolate; 1 × 10 6 TCID 50 /animal). To initially determine the safety of the vaccine administration, different parameters were evaluated during the immunization period. The results showed that the MVA-S vaccine candidate was well tolerated with no adverse events detected. Local reactions at the immunization site were not observed during the observation period of 4 days after each immunization. Animals showed normal behavior and appetite, and the body weight remained stable during the immunization period. Overall, hematology and clinical chemistry levels were in the normal range (data not shown). Although body temperature increased by 1°C-2°C 12 h after the first immunization, this increase was similar in both MVA-S-and MVA-WT-inoculated animals and only transient, as normal body temperatures were reached after approximately 20 h ( Figure 1B, left panel) . After the second immunization, the temperature increase showed similar kinetics in both MVA-S and MVA-WT groups as after the first immunization, but at a much lower magnitude ( Figure 1B, right panel) . Induces Robust Binding IgG Antibodies Against S and RBD, Potent Titers of Neutralizing Antibodies, and T-Cell Immune Responses Next, we analyzed the SARS-CoV-2-specific immunogenicity elicited in rhesus macaques by the MVA-S vaccine candidate at weeks 0, 4, and 6 (post-vaccination) and at 10 and 14 days post-challenge (pc). Four weeks after the first MVA-S immunization, five out of six MVA-S-vaccinated animals showed IgG antibodies to SARS-CoV-2 S protein, which were significantly boosted to high levels by the second MVA-S immunization in all macaques (week 6; 2 weeks after the second dose) (Figure 2A) . IgG antibodies to the RBD were mainly induced after two MVA-S immunizations, but with high levels and in all animals ( Figure 2B ). MVA-WT immunization did not induce SARS-CoV-2 binding IgG antibodies. After SARS-CoV-2 challenge, binding IgGs to S and RBD proteins increased (day 10 pc) in MVA-S-immunized macaques but then did not increase further (day 14 pc) (Figures 2A, B) . In MVA- WT animals, these SARS-CoV-2-binding IgGs were of a significantly lower magnitude (Figures 2A, B) . This increase in SARS-CoV-2-specific humoral responses after challenge reflected an anamnestic response, due to a SARS-CoV-2 breakthrough infection. Further profiling of SARS-CoV-2specific binding antibody responses measured at day 14 pc by protein microarray showed that responses were directed against the S1 domain, as well as against the ectodomain of the S protein, in agreement with the ELISA data (Figures 2A, B) , and were of a significantly higher magnitude in MVA-S-immunized macaques than in animals that received MVA-WT (Figures 2C, D) . Furthermore, positive cross-reactive antibody responses were detected against the SARS-CoV S1 region and ectodomain of the S protein, while almost no reactivity against Middle East respiratory syndrome coronavirus (MERS-CoV) and no reactivity against common cold a (229E, NL63) or b (OC43, HKU1) coronaviruses was observed (Figures 2C, D) . Neutralizing antibodies against live SARS-CoV-2 MAD6 strain (having the D614G mutation) were already detected in all animals after one MVA-S immunization (week 4) and again were highly boosted by the second MVA-S immunization ( Figure 3A) . Similar results were obtained against Wuhan strain (data not shown). At week 6, binding and neutralizing antibody titers showed a positive correlation in MVA-Simmunized animals (r = 0.97, p = 0.002, Pearson correlation test, log-transformed data). MVA-WT immunization did not induce SARS-CoV-2-neutralizing antibodies. After SARS-CoV-2 challenge, there was an enhancement in neutralizing antibody titers in MVA-S-immunized animals ( Figure 3A ). While after infection neutralizing antibodies were also observed in the nonvaccinated animals, they were significantly lower than in the MVA-S-vaccinated animals (10 pc and 14 pc) ( Figure 3A) . Neutralizing activity against VOCs was next assayed initially by using VSV-luciferase recombinant viruses pseudotyped with SARS-CoV-2 S_614D (parental Wuhan strain), S_614G, alpha, beta, gamma, and delta S variants. Animals immunized with MVA-S showed at week 6 comparable neutralizing antibody titers against the Wuhan S_614D (data not shown), Wuhan S_614G, and the alpha and delta variants, while lower titers against the gamma variant and no apparent neutralization of the beta variant were observed (Figures 3B-F) . Neutralization assays using live VOC confirmed these results and showed that at week 6 post-boost vaccination with MVA-S, similar higher levels of neutralizing antibodies were elicited against SARS-CoV-2 D614G and VOC alpha and delta, but lower levels of neutralizing antibodies that were now detected against VOC beta ( Figure 3G ). Neutralizing antibodies against all VOC, except for the beta variant, increased after SARS-CoV-2 challenge (at day 14 pc) and were higher in MVA-Simmunized animals than in MVA-WT animals ( Figures 3B-F) . Next, the analysis of SARS-CoV-2-specific T-cell immune responses elicited by MVA-S after stimulation of PBMCs with S peptide pools in an ELISpot assay showed that at 2 weeks after the second immunization (week 6), MVA-S, in contrast to MVA- WT, induced high levels of SARS-CoV-2-specific IFNg-secreting cells that were mainly directed to the first part of the S protein (peptide pool 1, pp1) ( Figure 4A) . Remarkably, no induction of SARS-CoV-2-specific IL-4-secreting cells was observed ( Figure 4B) , reflecting a Th1-dominant response, and not a Th2 response. At 2 weeks post-challenge (day 14 pc), SARS-CoV-2-specific IFNg-secreting cells were slightly, but not significantly, decreased in MVA-S-vaccinated macaques compared to the pre-challenge levels ( Figure 4A ). MVA-WT animals developed only very low SARS-CoV-2-specific IFNg responses after challenge ( Figure 4A) . Again, after challenge no SARS-CoV-2-specifi c IL-4-secreting cells were produced ( Figure 4B ). Upon intranasal and intratracheal SARS-CoV-2 challenge, we measured at different days post-challenge the levels of viral subgenomic mRNA (sgmRNA) to determine the presence of replicating virus in the lung (BAL fluid), throat, and nose swabs ( infected, as SARS-CoV-2 sgmRNA was detected at high levels in BAL and throat swabs of all animals, and in nose swabs from five out of six animals, with a peak of sgmRNA at day 2 pc that then declined with time ( Figure 5A ) Moreover, at the time of euthanasia (14 days post-challenge), several body organs and tissues were harvested (nasal mucosa, oro/nasopharynx, trachea, left and right bronchus, seven lung lobes, heart, kidney, liver, gastrointestinal tract (ileum and colon) and cerebrospinal fluid) and processed for SARS-CoV-2 viral load analysis by RT-qPCR measuring the sgmRNA (Supplementary Table 1 ). At that time, most of the tissues were virus negative. In only 2 animals (one from each group), a very small amount (10 3 copies/gram tissue) of SARS-CoV-2 sgmRNA was detected in one of the seven lung lobes. All other tissues from these and other animals were virus negative (Supplementary Table 1 ). Fecal samples were not examined for the presence of SARS-CoV-2 sgmRNA during the experiment, since the animals were housed in pairs, and it would be difficult to distinguish between stools. Moreover, anal swabs were taken before challenge and at 1, 2, 3, 4, 5, 6, 7, 10, 12, and 14 days post-challenge, and replicating virus was not found in anal swabs at any time point, as measured by SARS-CoV-2 sgmRNA analysis (Supplementary Table 2 ). However, at days 2 and 3 post-challenge, low levels (10 2 -10 4 copies/ml) of genomic SARS-CoV-2 RNA were detected in anal swabs from three MVA-WT control animals and at day 3 in two MVA-Svaccinated animals (10 2 copies/ml) (Supplementary Table 2 ), most probably representing virus shedding. After SARS-CoV-2 challenge, no significant clinical symptoms, changes in behavior, or weight loss were observed in any of the animals at any timepoint (Supplementary Tables 3, 4) . However, in MVA-WT animals, a slight body temperature increase was observed at 1-3 days pc that was not observed in MVA-S-immunized animals (p = 0.0357, Mann-Whitney test) ( Figure 6A ). Next, we measured lung pathology after challenge by computed tomography (CT). Areas with increased lung density were scored semiquantitatively, as described (44, 45, 47) . Modest lesions were observed at day 2 pc in four of the MVA-WT-and three of the MVA-S-vaccinated animals. These lesions were almost entirely resolved by day 7 pc in MVA-S-vaccinated animals, while lesions were still present in five of the six MVA-WT control animals ( Figure 6B , p = 0.0152 Mann-Whitney; Supplementary Figure 1 ). At the time of euthanasia (day 15 or 16 pc), all lung lesions had resolved in all animals. After euthanasia, one of the MVA-S-vaccinated animals (r10067) showed marked vascular congestion with moderate alveolar edema and moderate to severe alveolar hemorrhage, which were demonstrated to be typical barbiturate-euthanasiainduced artifacts (48) . Due to these artifacts, a proper assessment of COVID-19-related changes in the lungs was not possible for this animal and it was excluded from further pathological assessment. After euthanasia, at day 15 or 16 pc all 7 pulmonary lobes (upper, middle, lower, accessory right and upper, middle, lower left) were processed for histopathological analyses. The microscopic examination showed that MVA-S-vaccinated animals had lower overall lung pathology scores compared with MVA-WT control animals ( Figures 6C, D, Supplementary Tables 5, 6 ). In particular, MVA-S-vaccinated animals showed significant decreased levels of peribronchiolar inflammatory infiltrates, alveolar cellular exudate and edema, and alveolar septal inflammatory cells, while there was no difference in perivascular inflammatory infiltrates compared to control animals ( Figures 6C, D) . In summary, these findings support a beneficial role of MVA-S vaccination in reducing lung pathology. Additionally, histopathological examination of various extrapulmonary tissues, including nasal mucosa, oro/ nasopharynx, trachea, left and right bronchus, heart, kidney, liver, and gastrointestinal tract (small intestine and colon), was done. Significant histological lesions in the upper respiratory tract tissues and other examined extrapulmonary organs in control and vaccinated animals were not observed (data not shown). It has been described that in humans and NHPs, SARS-CoV-2 induced a robust expression of proinflammatory cytokines and chemokines in BAL and serum samples (20, (49) (50) (51) . Thus, to know whether MVA-S vaccination could reduce the cytokine storm associated with SARS-CoV-2 infection, we have analyzed the levels of several inflammatory cytokines and chemokines in BAL and serum samples at different timepoints post-challenge. In serum samples, there was a transient increase (mainly at days 1-2 pc) in levels of CXCL10 (IP-10), CXCL11 (I-TAC), CCL2 (MCP-1), CCL4 (MIP-1b), and CCL11 (eotaxin) in all MVA-WT control animals, while this increase was either absent or only seen at low levels in the MVA-S-vaccinated group ( Figure 7A ). IL-6 showed a peak expression on day 1 pc in three animals of the MVA-WT control group, but in none of the animals of the MVA-S vaccine group. For CCL2 and CCL11, there was a second increase from day 6 pc onward, but this was similarly observed in both groups ( Figure 7A ). IL-1b, TNFa, and IFNg levels were below 10 pg/ml in all animals at all timepoints and did not show any clear pattern of change, while levels of IL-8 were too high and fell above the limit of detection (data not shown). CXCL9 (MIG) showed only one peak on day 10 pc in one animal of the MVA-S vaccine group and one animal of the control group (data not shown). CCL3 (MIP-1a) and CCL5 (RANTES) were observed in all pre-and post-infection sera without any specific change in expression level (data not shown). Additionally, we also observed that MVA-S immunization protected all animals from the cytokine storm in the lung (BAL samples) ( Figure 7B) . A transient increase, peaking at day 2 pc, was observed in IL-6, CXCL10, and CXCL11 levels in animals from the control MVA-WT group, while this increase was either absent or only seen at low levels in the MVA-S-vaccinated group at any timepoint ( Figure 7B ). CCL11 levels peaked on day 4 pc in three of the six animals of the MVA-WT group, but none of the animals of the MVA-S-vaccinated group. IL-8 levels in the MVA-WT control group also peaked at day 4 pc, with no levels in the MVA-S-vaccinated group at any time point ( Figure 7B ). CXCL9 peaked on day 2 pc in one animal from the MVA-WT group, and a late increase at day 7 pc was observed in four other animals of this group, but no increase was observed in any of the MVA-S-vaccinated animals ( Figure 7B ). CCL5, IL-1b, TNFa, and IFNg were below 10 pg/ml in all animals at all timepoints, while CCL2, CCL3, and CCL4 levels were variable and without any clear pattern of change (data not shown). Regarding changes in leukocytes post-challenge, we observed that while the number of granulocytes transiently increased in all MVA-WT control animals, this only occurred in two of the six MVA-S-immunized animals (Supplementary Figure 2) . In this investigation, we evaluated the safety, immunogenicity, and efficacy in rhesus macaques of a COVID-19 vaccine candidate based on the poxvirus MVA vector expressing a human codon-optimized full-length SARS-CoV-2 S protein (MVA-S), which was previously reported to induce potent Band T-cell immune responses and full efficacy in mice (16, 17, 19) . Due to the close relatedness of NHPs to humans, inoculation of rhesus macaques with SARS-CoV-2 has been used for current vaccines as a preclinical animal model system, as it leads to a respiratory disease, with virus replication in lungs and in the upper and lower respiratory tracts (52) . The MVA-S vaccine candidate was safe and well tolerated, showing only a transient increase in temperature by 12 h post first immunization, but comparable to the increase induced by control MVA-WT animals. The transient increase in body temperature was similar to most of the current vaccines being administered worldwide, and this effect is likely related to the inflammatory response produced by the MVA vector at the site of virus inoculation, with vector expression being restricted to 24-48 h post inoculation (53, 54) . Neutralizing antibody responses are highly predictive of immune protection against symptomatic SARS-CoV-2 infection in humans (55, 56) and were described to be inversely correlated with virus production in BAL samples from macaques (57, 58) . Here, we demonstrated that vaccine candidate MVA-S triggered strong humoral immune responses, mainly after two doses, as defined by binding IgG antibodies to the S and RBD components, as well as of high neutralizing antibodies against live SARS-CoV-2 expressing an S protein containing the D614G mutation (Wuhan D614G and MAD6 isolates). Neutralizing antibody titers were inversely correlated with virus production in BAL samples from MVA-S-immunized macaques. VOC alpha and delta were also well neutralized, while responses against the gamma variant were slightly lower and further lower neutralization against the beta variant was observed. This resistance could be related to the nature of mutations in the RBD domain of the beta variant. With the recent appearance of a beta variant, named Ómicron, with multiple mutations within the S protein, there is concern that the virus spreads rapidly and manifests more resistance to current vaccines. Hence, vaccines with multiple modes of action are needed. Following SARS-CoV-2 challenge, binding and neutralizing antibodies against live SARS-CoV-2 (containing the D614G mutation in the S protein) as well as against VOC alpha, gamma, and delta were further enhanced. This is most likely due to a breakthrough virus infection, reflecting an anamnestic response. Surprisingly, by the S-VSV pseudovirus assay levels of neutralizing antibodies against the beta variant were only observed after challenge in MVA-WT control animals, but not in MVA-S-immunized animals. These antibodies were apparently only triggered by virus infection and not by immunization, which is at variation with induction of broad virus-neutralizing antibody responses upon breakthrough infection in humans (59) . In contrast, a recent publication describes induction of broadly SARS-CoV-2-neutralizing antibodies upon immunization of rhesus macaques with recombinant a prefusion-stabilized S protein in saponin adjuvant, while such responses were not observed in S-mRNAvaccinated or SARS-CoV-2-infected humans or in mice immunized with S protein (60) . In macaques, most of the broadly neutralizing antibodies expressed a heavy chain derived from the germline IGHV3-73 gene and targeted a relatively conserved region proximal to the RBD. This is different from the epitopes usually targeted by human antibodies. Our study could indicate that such a relatively broader response may also have been triggered by the viral infection, but this needs further investigation. Moreover, analysis of post-challenge sera showed that SARS-CoV-2specific antibody responses were directed against the S1 region and ectodomain of the S protein, also with cross-reactive antibody responses against SARS-CoV, but almost no reactivity against MERS and no reactivity against common cold aor bcoronavirus S proteins, as also shown in human COVID-19 (61) . The analysis of cell responses showed that S-specific IFN-gsecreting cells predominantly directed against the S1 subunit (pp1) were induced in MVA-S-vaccinated animals 2 weeks after vaccination, but not in the MVA-WT control group. After SARS-CoV-2 challenge, cell responses were maintained in the vaccinated group with minimal responses in the control group. In contrast, almost no S-specific IL-4-secreting cells were detected, reflecting the absence of a T helper 2 response. Thus, this T helper 1 (Th1) skewed response together with the induction of virus-neutralizing antibodies implies that the potential risk for vaccine-associated enhanced respiratory disease is very low. There have been reports of adverse effects of MVA vectors expressing the SARS-CoV-1 S protein when tested in NHPs, with an antibody-dependent enhancement (ADE) effect after SARS-CoV-1 infection (62) and with liver damage in ferrets (63) . However, such adverse events have not been observed in this NHP study or in any of the preclinical studies performed to date with MVA vectors expressing SARS-CoV-2 S antigens (15) (16) (17) (18) (19) (20) (21) (22) . This is likely related to the distinct biology of the SARS-CoV-2 infection and the antigenic nature of the viral protein components. The potent immune responses (both humoral and T cell) induced by MVA vectors expressing SARS-CoV-2 S antigens, as shown here and by others (15) (16) (17) (18) (19) (20) (21) (22) , will have a major impact in reducing virus loads in tissues and disease progression. We next evaluated the extent of SARS-CoV-2 infection and replication in various tissues by measuring viral sgmRNA. In animals immunized with MVA-S, there was no detectable SARS-CoV-2 replication in BAL in three animals and virus replication was reduced in the other three animals relative to the MVA-WT control animals. Moreover, a significant reduction of viral sgmRNA was also observed in the throat of vaccinated macaques. In addition, virus was cleared faster from the throat and nasal cavity of vaccinated animals, which could be important in reducing viral spread. Hence, the high protective efficacy of the MVA-S vaccine is comparable to other vaccine modalities evaluated in macaques (57, 64, 65) or to secondary infection (66) and possibly superior to other studies where the infection may have been less stringent, as it was cleared faster in the control group (67, 68) . Furthermore, a significant reduction in fever was observed in MVA-S-vaccinated animals upon challenge, as previously also reported for the Ad26.COV2-S vaccine (64) . A feature of SARS-CoV-2 infection is an enhancement of pathophysiological changes associated with disease, like pulmonary lesions with edema and induction of a cytokine storm leading to death of infected individuals (69, 70) . The evaluation of lung lesions by CT at various timepoints after virus challenge showed a strong significant inhibition of lung lesions (CT scores) in all MVA-S-vaccinated animals by day 7 postchallenge, compared to MVA-WT control animals. At day 15 or 16 post-challenge, only modest histopathological changes were observed after the autopsy in all the animals of the study, where mild clinical disease was observed, which agrees with other SARS-CoV-2 infection studies in macaques (52) . This is also in agreement with other studies, showing that typical pathological features of viral pneumonia in rhesus macaques (71, 72) also spontaneously resolve by day 14 postinfection (46) . However, at day 15 or 16 post-challenge there was a significant reduction in interstitial septal inflammatory cells, alveolar cellular exudate, and peribronchiolar inflammatory infiltrates in MVA-Svaccinated animals relative to control macaques. Similar mild histopathological lung lesions were described in efficacy studies in SARS-CoV-2-infected macaques previously vaccinated with SARS-CoV-2 vaccines based on mRNA (67, 73) , adenovirus (68, 74) , inactivated viruses (75) , or MVA (20), among others. An important feature of MVA-S vaccine efficacy was the total prevention in serum and BAL samples of the acute inflammatory cytokine response typically induced by SARS-CoV-2 infection in macaques (71, 76) that was observed in the control animals of this study. These cytokines are known to drive the development of severe COVID-19 in humans (77) , and preventing such cytokine release is an important aspect of vaccine efficacy. We and other groups have generated MVA vectors expressing the S protein of SARS-CoV-2, showing in mice or hamsters induction of humoral and T-cell immune responses and efficacy in lung tissues, throat, and nose (15) (16) (17) (18) (19) (20) (21) (22) . Moreover, the immunogenicity and efficacy were also defined in NHPs with an MVA vector expressing a prefusion-stabilized S protein, where robust humoral and cellular immune responses and high efficacy against SARS-CoV-2 infection were reported (20) . Instead, our study evaluated the immunogenicity and efficacy of an MVA vector expressing a full-length non-stabilized S protein. Both the full-length non-stabilized S protein and a stabilized prefusion form of the S protein have been applied in current vaccines against COVID-19. There is currently no indication that either one of these strategies might result in lower vaccine efficacy in humans against either the Wuhan strain or the alpha or beta VOC, although in mice we have observed higher neutralization capacity against VOC of serum from animals vaccinated with a prefusion-stabilized S over non-stabilized S protein (19) . Nonetheless, such differences could arise for other newly emerging VOC. We showed that MVA-S did induce neutralizing antibodies against VOC alpha, gamma, beta, and delta, while this has not yet been described for the MVA vector expressing a prefusion-stabilized S protein evaluated by Routhu et al. (20) . A difference with Routhu et al. (20) was not only in the virus promoter and site of insertion of the S gene within the MVA genome, but in the dose of SARS-CoV-2 used for challenge, 5 × 10 4 PFU/animal while we used 1 × 10 6 TCID50/ animal, which could explain the higher efficacy observed with lower doses of the challenge virus. Together, all these studies highlight the benefit of MVA vectors as vaccine candidates against SARS-CoV-2. By the nature of the biology of the recombinant MVA vector and its impact on the host cell immune system, this type of poxvirus-based vaccine could induce, upon inoculation of preferably two doses, robust, broad, and durable protective memory B-and T-cell immune responses. In addition, it has been established that a heterologous combination of poxvirus vectors with other vaccines potently enhances the immune responses and efficacy against pathogens (26, (29) (30) (31) 78) . In particular, clinical trials have shown an enhancement of immune responses against the S protein of SARS-CoV-2 by the combination of adenovirus vaccines (AstraZeneca) and mRNA vaccines (79) (80) (81) (82) ; clinical studies with various combinations of vaccines are currently ongoing. As such, the MVA-S vaccine deserves a consideration to enter phase 1/2 clinical trials either alone or in combination with other vaccines. In conclusion, our findings demonstrate that the MVA-S vaccine is safe and well tolerated in rhesus macaques, being highly immunogenic with the induction of potent levels of binding and neutralizing antibodies against several SARS-CoV-2 VOC, as well as Th1-skewed cell responses. Remarkably, this vaccine provides protection from SARS-CoV-2 challenge, reducing virus replication in the upper and lower respiratory tracts, lung pathology, and cytokine storm. All these results support the entering of the MVA-S vaccine into clinical trials to evaluate its safety, immunogenicity, and efficacy. The original contributions presented in the study are included in the article/Supplementary Material. Further inquiries can be directed to the corresponding authors. The study was reviewed and approved by the Dutch "Centrale Commissie Dierproeven" (AVD5020020209404-2) according to Dutch law, article 10a of the "Wet op de Dierproeven" and BPRC's Animal Welfare Body (IvD). The study was conducted under the number CCD 028K. Approval by the Dutch Committee on the use of Genetically Modified Organisms to use MVA-S was granted (GGO IG 19-257_III-007). Progress of the COVID-19 Vaccine Effort: Viruses, Vaccines and Variants Versus Efficacy, Effectiveness and Escape Efficacy and Safety of the mRNA-1273 SARS-CoV-2 Vaccine Safety and Immunogenicity of the ChAdOx1 Ncov-19 Vaccine Against SARS-CoV-2: A Preliminary Report of a Phase 1/2, Single-Blind, Randomised Controlled Trial An mRNA Vaccine Against SARS-CoV-2 -Preliminary Report Safety and Efficacy of the BNT162b2 mRNA Covid-19 Vaccine Safety and Efficacy of Single-Dose Ad26.Cov2.S Vaccine Against Covid-19 National Study Group for C-V. Effectiveness of the BNT162b2 Covid-19 Vaccine Against the B.1.1.7 and B.1.351 Variants Definition and Risks of Cytokine Release Syndrome in 11 Critically Ill COVID-19 Patients With Pneumonia: Analysis of Disease Characteristics mRNA Vaccine-Elicited Antibodies to SARS-CoV-2 and Circulating Variants Serum Neutralizing Activity Elicited by mRNA-1273 Vaccine Evidence of Escape of SARS-CoV-2 Variant B.1.351 From Natural and Vaccine-Induced Sera Effect of Vaccination on Transmission of SARS-CoV-2 Vaccine-Induced Immune Thrombosis and Thrombocytopenia Syndrome Following Adenovirus-Vectored Severe Acute Respiratory Syndrome Coronavirus 2 Vaccination: A Novel Hypothesis Regarding Mechanisms and Implications for Future Vaccine Development Myocarditis After BNT162b2 and mRNA-1273 Vaccination Development of a Multi-Antigenic SARS-CoV-2 Vaccine Candidate Using a Synthetic Poxvirus Platform COVID-19 Vaccine Candidates Based on Modified Vaccinia Virus Ankara Expressing the SARS-CoV-2 Spike Induce Robust T-and B-Cell Immune Responses and Full Efficacy in Mice Full Efficacy and Long-Term Immunogenicity Induced by the SARS-CoV-2 Vaccine Candidate MVA-CoV2-S in Mice One or Two Injections of MVA-Vectored Vaccine Shields Hace2 Transgenic Mice From SARS-CoV-2 Upper and Lower Respiratory Tract Infection A Single Dose of an MVA Vaccine Expressing a Prefusion-Stabilized SARS-CoV-2 Spike Protein Neutralizes Variants of Concern and Protects Mice From a Lethal SARS-CoV-2 Infection A Modified Vaccinia Ankara Vector-Based Vaccine Protects Macaques From SARS-CoV-2 Infection, Immune Pathology, and Dysfunction in the Lungs Immunogenicity and Efficacy of the COVID-19 Candidate Vector Vaccine MVA-SARS-2-S in Preclinical Vaccination Vaccinia Virus-Based Vaccines Confer Protective Immunity Against SARS-CoV-2 Virus in Syrian Hamsters Clinical Development of Modified Vaccinia Virus Ankara Vaccines MVA and NYVAC as Vaccines Against Emergent Infectious Diseases and Cancer Modified Vaccinia Virus Ankara: History, Value in Basic Research, and Current Perspectives for Vaccine Development Control of a Mucosal Challenge and Prevention of AIDS by a Multiprotein DNA/MVA Vaccine A Single Dose of Modified Vaccinia Ankara Expressing Ebola Virus Like Particles Protects Nonhuman Primates From Lethal Ebola Virus Challenge Specificity and 6-Month Durability of Immune Responses Induced by DNA and Recombinant Modified Vaccinia Ankara Vaccines Expressing HIV-1 Virus-Like Particles Vaccine Protection Against Acquisition of Neutralization-Resistant SIV Challenges in Rhesus Monkeys DNA-Launched RNA Replicon Vaccines Induce Potent Anti-Ebolavirus Immune Responses That can be Further Improved by a The Combined Vaccination Protocol of DNA/MVA Expressing Zika Virus Structural Proteins as Efficient Inducer of T and B Cell Immune Responses Correlation Between Virus Replication and Antibody Responses in Macaques Following Infection With Pandemic Influenza A Virus Pandemic Swine-Origin H1N1 Influenza Virus Replicates to Higher Levels and Induces More Fever and Acute Inflammatory Cytokines in Cynomolgus Versus Rhesus Monkeys and Can Replicate in Common Marmosets Thoracic Radiography as a Refinement Methodology for the Study of H1N1 Influenza in Cynomologus Macaques (Macaca Fascicularis) Biology of Attenuated Modified Vaccinia Virus Ankara Recombinant Vector in Mice: Virus Fate and Activation of B-and T-Cell Immune Responses in Comparison With the Western Reserve Strain and Advantages as a Vaccine Evaluation of SARS-CoV-2 Neutralizing Antibodies Using a CPE-Based Colorimetric Live Virus Micro-Neutralization Assay in Human Serum Samples Dc/L-SIGN Recognition of Spike Glycoprotein Promotes SARS-CoV-2 Trans-Infection and can be Inhibited by a Glycomimetic Antagonist Divergent SARS CoV-2 Omicron-Reactive T-and B Cell Responses in COVID-19 Vaccine Recipients Severe Acute Respiratory Syndrome Coronavirus 2-Specific Antibody Responses in Coronavirus Disease Patients Middle East Respiratory Syndrome Coronavirus Neutralising Serum Antibodies in Dromedary Camels: A Comparative Serological Study Needle-Free Delivery of DNA: Targeting of Hemagglutinin to MHC Class II Molecules Protects Rhesus Macaques Against H1N1 Influenza Virological Assessment of Hospitalized Patients With COVID-2019 Refined Acquisition of High-Resolution Chest CTs in Macaques by Free Breathing The Post-Acute Phase of SARS-CoV-2 Infection in Two Macaque Species Is Associated With Signs of Ongoing Virus Replication and Pathology in Pulmonary and Extrapulmonary Tissues Time Course of Lung Changes at Chest CT During Recovery From Coronavirus Disease Comparison of Rhesus and Cynomolgus Macaques as an Infection Model for COVID-19 Characteristic and Quantifiable COVID-19-Like Abnormalities in CT-and PET/CT-Imaged Lungs of SARS-CoV-2-Infected Crab-Eating Macaques (Macaca Fascicularis) Barbiturate Euthanasia Solution-Induced Tissue Artifact in Nonhuman Primates Baricitinib Treatment Resolves Lower-Airway Macrophage Inflammation and Neutrophil Recruitment in SARS-CoV-2-Infected Rhesus Macaques Single-Cell Landscape of Bronchoalveolar Immune Cells in Patients With COVID-19 Single-Cell RNA Sequencing Reveals SARS-CoV-2 Infection Dynamics in Lungs of African Green Monkeys Animal Models for COVID-19 Virus Distribution of the Attenuated MVA and NYVAC Poxvirus Strains in Mice Immune Profiles Identification by Vaccinomics After MVA Immunization in Randomized Clinical Study Analysis of Humoral Immune Responses in Patients With Severe Acute Respiratory Syndrome Coronavirus 2 Infection Neutralizing Antibody Levels are Highly Predictive of Immune Protection From Symptomatic SARS-CoV-2 Infection Low-Dose Ad26.COV2.S Protection Against SARS-CoV-2 Challenge in Rhesus Macaques Single-Shot Ad26 Vaccine Protects Against SARS-CoV-2 in Rhesus Macaques SARS-CoV-2 Breakthrough Infections Elicit Potent, Broad, and Durable Neutralizing Antibody Responses Broadly Neutralizing Antibodies to SARS-Related Viruses can be Readily Induced in Rhesus Macaques Homologous and Heterologous Antibodies to Coronavirus 229E, NL63, OC43, HKU1, SARS, MERS and SARS-CoV-2 Antigens in an Age Stratified Cross-Sectional Serosurvey in a Large Tertiary Hospital in The Netherlands Anti-Spike IgG Causes Severe Acute Lung Injury by Skewing Macrophage Responses During Acute SARS-CoV Infection Evaluation of Modified Vaccinia Virus Ankara Based Recombinant SARS Vaccine in Ferrets Immunogenicity and Efficacy of One and Two Doses of S COVID Vaccine in Adult and Aged NHP DNA Vaccine Protection Against SARS-CoV-2 in Rhesus Macaques SARS-CoV-2 Infection Protects Against Rechallenge in Rhesus Macaques mRNA-1273 Protects Against SARS-CoV-2 Beta Infection in Nonhuman Primates ChAdOx1 Ncov-19 Vaccine Prevents SARS-CoV-2 Pneumonia in Rhesus Macaques An Inflammatory Cytokine Signature Predicts COVID-19 Severity and Survival Clinical Features of Severe Patients Infected With 2019 Novel Coronavirus: A Systematic Review and Meta-Analysis Respiratory Disease in Rhesus Macaques Inoculated With SARS-CoV-2 Comparative Pathogenesis of COVID-19, MERS, and SARS in a Nonhuman Primate Model BNT162b Vaccines Protect Rhesus Macaques From SARS-CoV-2 An Adenovirus-Vectored COVID-19 Vaccine Confers Protection From SARS-COV-2 Challenge in Rhesus Macaques Immunogenicity and Protective Efficacy of Inactivated SARS-CoV-2 Vaccine Candidate, BBV152 in Rhesus Macaques Responses to Acute Infection With SARS-CoV-2 in the Lungs of Rhesus Macaques, Baboons and Marmosets Imbalanced Host Response to SARS-CoV-2 Drives Development of COVID-19 Priming With Recombinant Influenza Virus Followed by Administration of Recombinant Vaccinia Virus Induces CD8+ T-Cell-Mediated Protective Immunity Against Malaria Immunogenicity and Reactogenicity of BNT162b2 Booster in ChAdOx1-S-Primed Participants (CombiVacS): A Multicentre, Open-Label, Randomised, Controlled, Phase 2 Trial Mix-And-Match COVID Vaccines Trigger Potent Immune Response Safety and Immunogenicity of Heterologous Versus Homologous Prime-Boost Schedules With an Adenoviral Vectored and mRNA COVID-19 Vaccine (Com-COV): A Single-Blind, Randomised, non-Inferiority Trial Immunogenicity and Reactogenicity of Heterologous ChAdOx1 Ncov-19/mRNA Vaccination We acknowledge the CSIC and MCIN for continuous support. This study was possible through an agreement between CSIC and BPRC. We thank the Animal Science Department at the BPRC, especially the animal caretakers and veterinarians, for excellent care of the animals, clinical observations, and performing of the experimental procedures. We also thank JoséMarıá Casasnovas (CNB-CSIC, Madrid, Spain) for providing S and RBD proteins used in ELISA and Francisca van Hassel for her assistance with figure editing. The Supplementary Material for this article can be found online at: https://www.frontiersin.org/articles/10.3389/fimmu.2022.845887/ full#supplementary-material Conflict of Interest: Author EP was employed by Biofabri.The remaining authors declare that the research was conducted in the absence of any commercial or financial relationships that could be construed as a potential conflict of interest.Publisher's Note: All claims expressed in this article are solely those of the authors and do not necessarily represent those of their affiliated organizations, or those of the publisher, the editors and the reviewers. Any product that may be evaluated in this article, or claim that may be made by its manufacturer, is not guaranteed or endorsed by the publisher. . 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