Single-Injection Vaccine Protects Nonhuman Primates against Infection with Marburg Virus and Three Species of Ebola Virus

Vaccine vectors and challenge virus.The recombinant VSVs expressing the glycoprotein (GP) of ZEBOV (strain Mayinga) (VSVΔG/ZEBOVGP), the GP of SEBOV (strain Boniface) (VSVΔG/SEBOVGP), or the GP of MARV (strain Musoke) (VSVΔG/MARVGP) were generated using the infectious clone for the VSV Indiana serotype, as described recently (11, 15). CIEBOV was isolated from the human case from the Republic of Côte d'Ivoire in 1994 (21); SEBOV (strain Boniface) was isolated from a patient from the SEBOV outbreak in Sudan in 1976 (36); ZEBOV (strain Kikwit) was isolated from a patient from the ZEBOV outbreak in Kikwit, Democratic Republic of the Congo, in 1995 (19); and MARV (strain Musoke) was isolated from a human case in 1980 in Kenya (27).

Animal studies with single injection of a blended filovirus vaccine.Twenty filovirus-naïve cynomolgus monkeys (Macaca fascicularis) were randomized into five experimental groups (experimental groups 1, 2, 3, 4, and 5), consisting of three monkeys per group (experimental groups 1, 4, and 5), two monkeys per group (experimental group 2), or one monkey per group (experimental group 3), and four control groups (control groups 1, 2, 3, and 4), consisting of five monkeys per group (control group 1) or one monkey per group (control groups 2, 3, and 4) (Fig. 1). Control group 1 included five animals, as there have been no studies to date to evaluate the pathogenic potential of CIEBOV in nonhuman primates, whereas control groups 2 to 4 consisted of one animal per group, as historical studies have shown that ZEBOV, SEBOV, and MARV are uniformly lethal in cynomolgus monkeys (6, 18, 20, 28-31, 35). Animals in four experimental groups (experimental groups 1, 2, 4, and 5) were vaccinated by intramuscular (i.m.) injection of ∼1 × 10⁷ PFU of VSVΔG/SEBOVGP, 1 × 10⁷ PFU of VSVΔG/ZEBOVGP, and 1 × 10⁷ PFU of VSVΔG/MARVGP-Musoke (total dose of ∼3 × 10⁷ PFU), while the single animal in experimental group 3 was vaccinated with 3 × 10⁷ PFU of VSVΔG/ZEBOVGP only. The animals in control groups 2 to 4 were injected in parallel with an equivalent dose (∼3 × 10⁷ PFU) of a VSV vector encoding a nonfilovirus GP (VSVΔG/LASVGPC [LASVGPC is a Lassa virus glycoprotein precursor]) (17), while the control animals in control group 1 were not vaccinated. The dose of ∼1 × 10⁷ PFU of each vaccine component was chosen because it is comparable to that used in our previous preventive-vaccine studies with these vectors in nonhuman primates (6, 12, 14, 20). Four weeks after vaccination, all animals were exposed to infectious filoviruses via i.m. injection as follows: animals in experimental group 1 and control group 1 were exposed to 1,000 PFU of CIEBOV; animals in experimental groups 2 and 3 and control group 2 were exposed to 1,000 PFU of SEBOV; animals in experimental group 4 and control group 3 were exposed to 1,000 PFU of ZEBOV; and animals in experimental group 5 and control group 4 were exposed to 1,000 PFU of MARV.

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FIG. 1.

Immunization and challenge of nonhuman primates. Flow chart (top) and table (bottom) of experimental design. Arrows indicate days of sampling. Cont, control group; Exp, experimental group; No., number of monkeys in group.

Animals were closely monitored for evidence of clinical illness (e.g., temperature, weight loss, changes in complete blood count, and blood chemistry) during both the vaccination and the filovirus challenge portion of the study. In addition, VSV and filovirus viremia were analyzed after vaccination and challenge, respectively. Animals were given physical exams and blood was collected on days 2, 14, and 28 after vaccination and on days 3, 6, 10, 14, and 28 after filovirus challenge (Fig. 1).

Animal studies with separate injections of filovirus vaccines.Four filovirus-naïve rhesus monkeys (Macaca mulatta) were randomized into an experimental group of three animals (experimental group 6) and a control group of one animal (control group 5) (Fig. 2). The three animals in the experimental group were vaccinated with ∼1 × 10⁷ PFU of VSVΔG/SEBOVGP by i.m. injection. After 2 weeks, we vaccinated these animals with a blend of ∼1 × 10⁷ PFU of VSVΔG/ZEBOVGP and 1 × 10⁷ PFU of VSVΔG/MARVGP (Musoke strain). Three weeks after this second vaccination, all three animals and a single unvaccinated control animal were challenged by i.m. injection with 1,000 PFU of SEBOV. Surviving animals were back-challenged 38 days after the SEBOV challenge by i.m. injection with 1,000 PFU of MARV (strain Musoke). Animals were given physical exams and blood was collected at the time of vaccination and on days 3, 6, 10, 14 or 15, and 28 after filovirus challenge (Fig. 2).

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FIG. 2.

Immunization, challenge, and rechallenge of nonhuman primates. Flow chart (top) and table (bottom) of experimental design. Arrows indicate days of sampling. *, the two-injection VSV-based vaccine consisted of a recombinant VSV-based SEBOV vaccine and subsequently a combination of a recombinant VSV-based ZEBOV vaccine and a VSV-based MARV vaccine, given as indicated. For definitions of abbreviations, see the legend for Fig. 1.

Animal studies performed in biosafety level 4 biocontainment facilities at USAMRIID were approved by the USAMRIID Laboratory Animal Use Committee. Animal research was conducted in compliance with the Animal Welfare Act and other federal statutes and regulations relating to animals and experiments involving animals and adhered to the principles stated in the Guide for the Care and Use of Laboratory Animals (21a). The facilities used are fully accredited by the Association for Assessment and Accreditation of Laboratory Animal Care International. Animal studies performed in biosafety level 4 containment facilities at the Public Health Agency of Canada were performed under an approved animal use document according to the guidelines of the Canadian Council on Animal Care.

Hematology and serum biochemistry.Total white blood cell counts, white blood cell differentials, red blood cell counts, platelet counts, hematocrit values, total hemoglobin concentrations, mean cell volumes, mean corpuscular volumes, and mean corpuscular hemoglobin concentrations were determined from blood samples collected in tubes containing EDTA by using a laser-based hematologic analyzer (Coulter Electronics, Hialeah, FL). Determination of the white blood cell differentials was performed manually with Wright-stained blood smears. Serum samples were tested for concentrations of albumin, amylase, alanine aminotransferase (ALT), aspartate aminotransferase (AST), alkaline phosphatase (ALP), gamma-glutamyltransferase (GGT), glucose, cholesterol, total protein, total bilirubin (TBIL), blood urea nitrogen (BUN), and creatinine (CRE) by using a Piccolo point-of-care blood analyzer (Abaxis, Sunnyvale, CA).

Detection of VSV and filoviruses.RNA was isolated from plasma and swabs using Tripure reagent (Invitrogen, Grand Island, NY). RNA was also isolated from peripheral blood mononuclear cells of animals challenged with CIEBOV, as this was the first evaluation of CIEBOV in nonhuman primates. Quantitative reverse transcriptase PCR (RT-PCR) assays were used for detection of RNA. VSV was detected using primers/probes targeting the nucleoprotein gene (nucleotide [nt] positions 1146 to 1201, GenBank accession no. AM690337). ZEBOV and CIEBOV were detected using primers/probes targeting the glycoprotein genes (for ZEBOV, nt positions 7720 to 7783, GenBank accession no. AF086833; for CIEBOV, nt positions 6962 to 7037, GenBank accession no. FJ217162). SEBOV and MARV RNAs were detected using primers/probes targeting the L genes (for SEBOV, nt positions 13465 to 13534, GenBank accession no. AY729654; for MARV, nt positions 13419 to 13483, GenBank accession no. AY358025). The limit of detection for these assays is 0.1 PFU/ml of plasma. Virus titration was performed by plaque assay with Vero E6 cells from all blood samples. Briefly, increasing 10-fold dilutions of the samples were adsorbed to Vero E6 monolayers in duplicate wells (0.2 ml per well); thus, the limit for detection was 25 PFU/ml.

Humoral immune response.Immunoglobulin G (IgG) antibodies against CIEBOV, SEBOV, ZEBOV, or MARV were detected with an enzyme-linked immunosorbent assay (ELISA) using purified virus particles as an antigen source, as previously described (6, 12, 14, 20, 29).

Evaluation of a single-injection blended vaccine as a panfilovirus vaccine.No animal showed any evidence of clinical illness as a result of vaccination (Table 1), and VSV RNA was detected only in the day 2 postimmunization sample from one animal (data not shown). None of the specifically vaccinated animals in experimental group 1, 4, or 5 showed any evidence of clinical illness after the filovirus challenge (Table 1), and all animals in these groups survived (Fig. 3). We were unable to detect filovirus viremia in any of these animals by plaque assay or PCR (Table 2). The single animal in experimental group 3 (subject 6) became clinically ill with symptoms consistent with SEBOV HF and succumbed to the SEBOV challenge on day 10 (Fig. 3). The two animals in experimental group 2 (subjects 4 and 5) developed mild clinical signs of illness by day 6, including fever, lymphopenia, and mild anorexia; however, both animals recovered quickly and appeared healthy by day 10. Surprisingly, we were unable to detect SEBOV viremia in either of these animals by plaque assay or PCR (Table 2).

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FIG. 3.

Kaplan-Meier survival curves for cynomolgus macaques vaccinated with a blended recombinant VSV vaccine and challenged with CIEBOV, ZEBOV, or MARV at day 28 after vaccination (A) or with a blended recombinant VSV vaccine or a monovalent ZEBOV vaccine (*) and challenged with SEBOV at day 28 after vaccination (B).

All control animals followed a typical filovirus disease course and developed macular rashes, lymphopenia, thrombocytopenia, and elevated levels of liver enzymes (Table 1). This included the five CIEBOV-infected macaques, of which three succumbed to death on day 12 (two animals) or day 14 (one animal) and two survived after a long convalescence (controls 2 and 5) (Table 1; Fig. 3). A detailed description of the pathology and pathogenesis of CIEBOV in cynomolgus monkeys will be reported separately. The remaining control animals in this study died on days 8 (SEBOV and ZEBOV) and 10 (MARV-Musoke strain) (Table 1; Fig. 3). Other than the control animals, the only animal in which we were able to detect the presence of circulating filovirus viremia was the single animal in experimental group 3 (subject 6) (Table 2). Unlike the other experimental-group animals in this study, which received the blended vaccine, this animal was vaccinated with the monovalent VSVΔG/ZEBOVGP vaccine and challenged with SEBOV to confirm that there is no cross-protection between ZEBOV and SEBOV.

Evaluation of humoral immune responses.The antibody responses of the cynomolgus macaques immunized with the blended vector vaccine were evaluated after vaccination (day 14 and day 28) and after filovirus challenge (day 14 and day 28) by IgG ELISA. All of the animals developed modest IgG titers against SEBOV, ZEBOV, and MARV (range, 1:32 to 1:100) at the day of filovirus challenge (Table 3). Prechallenge titers were consistent with those from previous studies in which macaques were vaccinated with VSV vectors expressing a single filovirus GP (VSVΔG/ZEBOVGP or VSVΔG/MARVGP) (6, 12, 20). As noted in previous studies, IgG titers against filoviruses often increased after filovirus challenge (Table 3). We are uncertain as to whether this increase is a result of undetected virus replication at undetermined sites or whether the high dose of the challenge virus (1,000 PFU, approximately 30,000 virus particles) boosted the immune response.

Back-challenge of control macaques that survived CIEBOV infection.Previous studies have suggested that immunity to one species of EBOV does not confer protection against another species of EBOV. For example, macaques that are immune to SEBOV are not protected against challenge with ZEBOV, while macaques immune to ZEBOV are not protected against challenge with SEBOV (1, 20). In the current study, there were two macaques that survived CIEBOV challenge (controls 2 and 5) (Table 1; Fig. 3). One of the two cynomolgus monkeys that survived CIEBOV challenge was back-challenged by i.m. injection with 1,000 PFU of heterologous ZEBOV 131 days after initial CIEBOV exposure. Surprisingly, this animal did not become clinically ill or viremic and remained healthy. This animal was then challenged by i.m. injection with 1,000 PFU of heterologous SEBOV 38 days after the ZEBOV back-challenge. Again, this animal did not become clinically ill or viremic and remained healthy. The second control cynomolgus macaque that survived CIEBOV challenge was then back-challenged 43 days after the initial CIEBOV challenge by i.m. injection with 1,000 PFU of heterologous SEBOV. As with the previous back-challenge of an CIEBOV-immune macaque, we were surprised that this animal showed no evidence of clinical illness and did not become viremic. In summary, one CIEBOV-immune macaque survived back-challenge with heterologous ZEBOV and a second back-challenge with heterologous SEBOV, while a second CIEBOV-immune macaque survived back-challenge with heterologous SEBOV. A second back-challenge with ZEBOV was not performed on this animal, as the study protocol had expired.

Vaccination with VSVΔG/SEBOVGP followed by vaccination with VSVΔG/ZEBOVGP and VSVΔG/MARVGP.It appeared that there may have been some weak interference between VSVΔG/SEBOVGP and the other VSV vectors in the single-vaccination, blended-vaccine study (Table 1, subjects 4 and 5). This may be due to the slower replication kinetics of VSVΔG/SEBOVGP than of VSVΔG/ZEBOVGP or VSVΔG/ MARVGP-Musoke (T. W. Geisbert and H. Feldmann, unpublished observation), or it may be a result of other causes, such as the affinity of the specific filovirus GPs for the antigen-presenting cells of the host. To begin to evaluate this finding, we next vaccinated three rhesus monkeys with ∼1 × 10⁷ PFU of VSVΔG/SEBOVGP by i.m. injection. Rhesus monkeys were used because of availability and since the filovirus species and strains employed in this study cause uniform lethality in both macaque species (reviewed in reference 16). After 2 weeks, we vaccinated these animals with ∼1 × 10⁷ PFU of VSVΔG/ZEBOVGP and 1 × 10⁷ PFU of VSVΔG/MARVGP. Three weeks after this second vaccination, all three animals and a single control animal were challenged by i.m. injection with 1,000 PFU of SEBOV (Fig. 2). All three vaccinated animals showed no clinical evidence of SEBOV HF and remained healthy. In contrast, the control animal became severely ill and developed classic symptoms of SEBOV HF, including dehydration, anorexia, and the presence of a macular rash; this animal died on day 17. SEBOV was detected in plasma of this animal on days 6, 10, 14, and 17 by plaque assay and RT-PCR, while no evidence of SEBOV was detected in plasma of any of the three specifically vaccinated animals at any time point (data not shown). We next back-challenged the three surviving animals 38 days after the initial SEBOV challenge with 1,000 PFU of MARV-Musoke to determine whether the vaccine regimen employed in this study could confer protection against challenge with a different filovirus (Fig. 2). All three animals showed no clinical evidence of infection or viremia and survived the MARV back-challenge. As observed in the single-vaccine study (described above), all three vaccinated animals in this study developed modest IgG titers against SEBOV, ZEBOV, and/or MARV (range, 1:32 to 1:100) at the day of filovirus challenge (Table 4), with titers increasing after challenge. In summary, vaccination with VSVΔG/SEBOVGP followed 2 weeks later by vaccination with a mixture of VSVΔG/ZEBOVGP and VSVΔG/MARVGP conferred complete protection against both SEBOV and MARV-Musoke. This study also shows the reusability of these recombinant VSV vectors.