Zika and chikungunya viruses have caused major epidemics and are transmitted by Aedes aegypti and/or Aedes albopictus mosquitoes. The “Sementis Copenhagen Vector” (SCV) system is a recently developed vaccinia-based, multiplication-defective, vaccine vector technology that allows manufacture in modified CHO cells. Herein we describe a single-vector construct SCV vaccine that encodes the structural polyprotein cassettes of both Zika and chikungunya viruses from different loci. A single vaccination of mice induces neutralizing antibodies to both viruses in wild-type and IFNAR−/− mice and protects against (i) chikungunya virus viremia and arthritis in wild-type mice, (ii) Zika virus viremia and fetal/placental infection in female IFNAR−/− mice, and (iii) Zika virus viremia and testes infection and pathology in male IFNAR−/− mice. To our knowledge this represents the first single-vector construct, multi-pathogen vaccine encoding large polyproteins, and offers both simplified manufacturing and formulation, and reduced “shot burden” for these often co-circulating arboviruses.
The vaccinia vaccine (VACV) was highly immunogenic and effective at eradicating smallpox globally, and a number of vaccinia-based vaccines and vaccine vectors have subsequently been developed. For instance, a Modified Vaccinia Ankara (MVA) smallpox vaccine, IMVAMUNE®1, was recently approved in the European Union and Canada. We recently described the Sementis Copenhagen Vector (SCV) vaccine technology and its application to vaccine development2. The SCV platform was generated by deleting the D13L gene from the Copenhagen strain of VACV. D13L encodes an essential viral assembly protein (D13) and its deletion renders SCV incapable of generating viral progeny in vaccine recipients2. This approach to attenuation preserves genome amplification, thereby permitting late phase expression of vaccine antigens from the amplified vector genomes2. The second unique feature of the SCV vaccines is that it can be produced in a SCV cell substrate (SCS) cell line, which comprises Chinese hamster ovary (CHO) cells stably expressing D13 and CP77. In trans provision of D13 allows SCV assembly and the host-range protein, CP77, imparts VACV and SCV multiplication capability to SCS cells2. CHO cells are widely used in the biopharmaceutical industry, with SCV vaccine production in the SCS cell line avoiding many of the issues associated with vaccine manufacture in primary chicken embryo fibroblasts, the cells traditionally used for production of vaccinia-based vaccines2.
The SCV technology was used to develop a vaccine against chikungunya virus (CHIKV), with the SCV chikungunya vaccine (SCV-CHIK) encoding the structural gene cassette of CHIKV. A single vaccination with SCV-CHIK provided protection against CHIKV infection and arthritic diseases in a wild-type (C57BL/6) adult mouse model2, which recapitulates many aspects of human CHIKV disease3,4. CHIKV is a mosquito-borne alphavirus that is primarily associated with acute and chronic rheumatic symptoms, with occasional infections also resulting in severe disease manifestations and mortality5,6. Hospitalization rates for CHIKV patients range from ≈2.3 to ≈13%, with a 5 ± 7 day mean length of stay (in Reunion Island)7. Although CHIKV has in the past been associated with sporadic outbreaks around the world, in 2004 CHIKV re-emerged to produce the largest epidemic ever recorded for this virus, with millions of cases reported globally, primarily in Africa, Asia, and South and Central America5,6. Autochthonous transmission has also occurred in Europe and the USA. The primary mosquito vector species for CHIKV are Aedes aegypti and Aedes albopictus8, both are highly invasive and, due to human activity, have attained global distributions9.
Zika virus (ZIKV) (family Flaviviridae) represents another mosquito-borne virus that has recently caused global health concerns due to its association with congenital Zika syndrome (CZS). CZS encompasses a spectrum of predominantly neurological complications (including but not limited to microcephaly) arising from infection of fetal brains10,11. Although infected pregnant women often have no or only mild symptoms, the virus appears able to cross the placenta12,13 and infect and destroy (primarily) neural progenitor cells in the fetal central nervous system14. Although CZS has now been well documented for the outbreak in Brazil, there remains a question of whether similar manifestations have gone unnoticed in Africa15. ZIKV is also associated with Guillain-Barré syndrome. ZIKV is primarily transmitted by Aedes aegypti mosquitoes16. Some data suggests circulation of ZIKV in wild Aedes albopictus populations17, with laboratory vector competence studies also suggesting ZIKV can be transmitted by this mosquito species18. Sexual transmission of ZIKV has also been documented, with the virus able to infect, damage and persist in testes19.
Herein we described a SCV multi-pathogen vaccine26 where a single-vector construct encodes (from different loci) the complete structural polyprotein cassettes of both ZIKV (prME, 2016 nucleotides) and CHIKV (C-E3-E2-6K-E1, 3747 nucleotides). This SCV-ZIKA/CHIK vaccine provided protection against CHIKV infection and disease in the adult CHIKV mouse model. The vaccine also induced anti-ZIKV antibody responses in C57BL/6 and IFNAR−/− mice, and provided protection in three ZIKV models: (i) survival in IFNAR−/− mice infected with the mouse-adapted prototype African ZIKVMR766 strain of ZIKV, which is usually lethal in these GMO animals27; (ii) fetal outcomes in IFNAR−/− dams infected with ZIKVNatal, an unpassaged ZIKV isolate unequivocally associated with microcephaly27; and (iii) testes infection and pathology in IFNAR−/− males infected with ZIKVNatal.
Design rationale for the SCV-ZIKA/CHIK vaccine
The Copenhagen strain of VACV (VACV) was originally used as a smallpox vaccine in Denmark and the Netherlands and provides the source virus for SCV vaccines2. To construct SCV-ZIKA/CHIK, VACV-CHIK was first generated by replacing the A39R gene of VACV with the structural protein cassette of CHIKV (Capsid-E3-E2-6K-E1) to generate VACV-CHIK (Fig. 1a) as described2. The B7R-B8R genes of VACV-CHIK were then replaced with the structural protein cassette of ZIKV (prME) (Fig. 1a). (B8R encodes a secreted interferon-γ receptor homolog, with its deletion from VACV previously shown to attenuate the virus, whilst immunogenicity was retained28. B7R encodes a protein found in the endoplasmic reticulum, whose deletion in VACV resulted in smaller skin lesions in mice29). The multiplication-defective SCV-ZIKA/CHIK was ultimately generated by concurrent deletion of the D13L gene2 (Fig. 1a).
After vaccination, SCV-ZIKA/CHIK infects host cells and the SCV genome (which encodes the ZIKV and CHIKV immunogens) is amplified (to about ≈10,000 copies30,31) (Fig. 1b). No infectious progeny can be generated due to the absence of the assembly protein, D132 (Fig. 1b). Late gene expression from the amplified viral genomes then results in expression of the ZIKV and CHIKV structural protein immunogens (Fig. 1b).
Characterization of the SCV-ZIKA/CHIK vaccine construct
The insertion of the CHIKV genes into the A39R locus, the insertion of the ZIKV genes into the B7R-B8R locus, and the deletion of D13L were confirmed by PCR of SCV-ZIKA/CHIK-infected SCS cells (Fig. 1c). Lysates of SCV-ZIKA/CHIK-infected SCS and HeLa cells were also analyzed by immunobloting. This illustrated expression of authentically processed, polyprotein-derived ZIKV E (Fig. 1d) and CHIKV structural proteins (Fig. 1e) in SCS cells (D13L-expressing cells in which SCV-ZIKA/CHIK can generate viral progeny) and in human-derived HeLa cells (D13L-negative cells in which SCV-ZIKA/CHIK cannot generate viral progeny). Furthermore, CHIKV structural protein expression in SCV-ZIKA/CHIK-infected HeLa cells was not lower than in SCV-CHIK2 infected HeLa cells (Supplementary Fig. 1).
SCV-ZIKA/CHIK immunogen insert stability
To assess the stability of the immunogen inserts, SCV-ZIKA/CHIK was passaged 10 times in SCS cells (MOI = 0.01–0.001, 3 day culture per passage), with virus from passage 1 and passage 10 analyzed by PCR (Fig. 1f) and quantitative PCR (Fig. 1g). The correct size of (i) the CHIKV structural protein insert into the A39R locus, and (ii) the ZIKV prME insert into the B7R–B8R locus, was retained after 10 passages, with no evidence of deletions (Fig. 1f). In addition, quantitative PCR of ZIKV M protein DNA, normalized to the G1L gene of VACV32, showed no reduction in levels of M protein DNA over 10 passages.
Vaccination of C57BL/6 mice and CHIKV challenge
The timeline of vaccination, challenge and analyses is shown in Fig. 2a. SCV-ZIKA/CHIK, SCV-CHIK2, and SCV-cont (control SCV vector encoding DsRed2) were produced in SCS cells. The SCV vaccines were used to vaccinate C57BL/6 mice once (106 pfu) by the intramuscular route (Fig. 2a, week 0). Four weeks after vaccination, anti-ZIKV and anti-CHIKV IgG titers were determined by ELISA. SCV-ZIKA/CHIK, but not SCV-CHIK (or SCV-cont), induced significant antibody responses to ZIKV (Fig. 2b, anti-ZIKV), whereas both SCV-ZIKA/CHIK and SCV-CHIK (but not SCV-cont) induced significant responses to CHIKV (Fig. 2b, anti-CHIKV). SCV-ZIKA/CHIK, but not SCV-CHIK (or SCV-cont), also induced significant neutralizing responses to both ZIKVNatal and ZIKVMR766 (Fig. 2c), with both SCV-ZIKA/CHIK and SCV-CHIK inducing neutralizing antibody responses to CHIKV (Fig. 2d).
Vaccinated mice were challenged with CHIKV 6 weeks after vaccination (Fig. 2a, week 6). Both SCV-ZIKA/CHIK and SCV-CHIK vaccinated mice were protected against the development of a detectable CHIKV viremia (Fig. 2e) and the ensuing foot swelling (Fig. 2f), which is a measure of CHIKV-induced arthritis4.
Vaccination of IFNAR−/− mice and ZIKVMR766 challenge
The timeline of vaccination, challenge and analyses is shown in Fig. 3a. Significant anti-ZIKV ELISA titers were seen after a single SCV-ZIKA/CHIK vaccination of IFNAR−/− mice (Fig. 3b, anti-ZIKV) and significant anti-CHIK ELISA titers were seen after SCV-ZIKA/CHIK and SCV-CHIK vaccination (Fig. 3b, anti-CHIKV). Significant anti-ZIKVNatal and ZIKVMR766 neutralizing titers were also seen after SCV-ZIKA/CHIK vaccination (Fig. 3c), and significant anti-CHIKV neutralizing titers were seen after SCV-ZIKA/CHIK and SCV-CHIK vaccination (Fig. 3d).
After challenge with ZIKVMR766, SCV-ZIKA/CHIK vaccinated mice showed no detectable viremia (Fig. 3e) and showed 100% protection against mortality, whereas SCV-CHIK and SCV-cont vaccinated mice developed severe disease and were killed (Fig. 3f). SCV-ZIKA/CHIK vaccination thus provided complete protection against challenge with the generally lethal ZIKVMR766 strain of ZIKV27.
Vaccination of IFNAR−/− dams and ZIKVNatal challenge
The timeline of vaccination, challenge and analyses is shown in Fig. 4a. Following a single SCV-ZIKA/CHIK vaccination, significant anti-ZIKV ELISA titers were seen in female IFNAR−/− mice (Fig. 4b). Mice were then mated and after plug detection were weighed; if weight increased by >1 g at E6.5 (confirming pregnancy), dams were challenged with ZIKVNatal (at E6.5 or E12.5, nominally representing early and mid gestation, respectively). Viremia was significantly and substantially suppressed in SCV-ZIKA/CHIK vaccinated dams compared to SCV-cont vaccinated dams (Fig. 4c). ZIKVNatal infection was previously reported to be asymptomatic in IFNAR−/− female mice >8 weeks old27, and no symptoms were seen in infected dams in the current study.
At E17.5, dams were euthanized and fetal weights determined. SCV-ZIKA/CHIK vaccinated dams infected at E6.5 had fetuses with significantly higher weights at E17.5 when compared to SCV-cont vaccinated dams (t test, p < 0.001) (Fig. 4d, E6.5). Fetal weights were on average 17.3 % lower (0.8 ± SE 0.032 g, n = 33) in SCV-cont vaccinated dams when compared to SCV-ZIKA/CHIK vaccinated dams (0.97 ± SE 0.022 g, n = 36). (In humans birth weights are also often lower for neonates from ZIKV infected mothers33). The weight difference in the murine fetuses was not due to litter size differences as litter sizes were actually slightly larger in the SCV-ZIKA/CHIK vaccinated dams (8, 9, 9, and 10) compared with the SCV-cont vaccinated dams (7, 7, 9, 10) (Fig. 4d, E6.5, left to right). Fetal weights were not significantly different when dams were infected at E12.5; (litter sizes where 8, 11, 10, 10 and 8, 10, 11, 11, 9, Fig. 4d, E12.5 left to right).
Photographs of selected fetuses are shown in Fig. 4e, with the deformed fetuses and fetal/placental masses in the SCV-cont vaccinated animals indicated (Fig. 4e, *). Fetuses, placenta and fetal/placental masses were either analyzed for viral titers (Fig. 4f) or where subject to qRT PCR (Fig. 4g), with no virus or viral RNA detected in tissues from SCV-ZIKA/CHIK vaccinated mice.
Vaccination of IFNAR−/− males and ZIKVNatal challenge
The timeline of vaccination, challenge and analyses are shown in Fig. 5a. Following a single vaccination of IFNAR−/− male mice with SCV-ZIKA/CHIK, significant anti-ZIKV ELISA antibody responses were generated (Fig. 5b). SCV-ZIKA/CHIK vaccinated mice also showed a significant and substantial reduction in viremia after challenged with ZIKVNatal (Fig. 5c). On day 21 after challenge mice were euthanized and testes removed. Testes from SCV-cont vaccinated mice were overtly normal except one testis (out of 12, n = 6 mice per group) was slightly smaller (Fig. 5d, *) and another showed signs of hemorrhage (Fig. 5d, arrow).
Histology of testes from SCV-cont vaccinated mice (n = 6 mice, 1 testis from each mouse) showed lesions (hemorrhage, infiltrates and/or destruction of seminiferous tubules34) in 5/6 testes (from six mice) (Fig. 5e). In contrast, none of the testes from SCV-ZIKA/CHIK vaccinated mice (n = 7 mice, 1 testis from each mouse) showed any discernible lesions (Fig. 5f). Immunohistochemistry with 4G4 (pan-flavivirus anti-NS1 antibody27) illustrated strong staining in and around the lesions, with staining primarily localizing to seminiferous tubules (Fig. 5g; serial sections of the three testes shown top left in e). In contrast, testes from SCV-ZIKA/CHIK vaccinated mice showed minimal staining (Fig. 5h; serial sections of the three testes shown top left in f).
qRT PCR of the testes showed a significantly lower (p = 0.003, Kolmogorov–Smirnov test) level of ZIKA RNA in the testes from SCV-ZIKA/CHIK vaccinated mice compared with testes from SCV-cont mice (Fig. 5i). Levels in testes from SCV-ZIKA/CHIK vaccinated mice were no higher than those in uninfected mice (Fig. 5i), suggesting complete clearance of ZIKV RNA in testes from the former animals (mice were killed on day 21 after infection and for each SCV-vaccinated mouse, one testis was used for histology and the other for qRT PCR).
SCV-ZIKA/CHIK vaccination after CHIKV or VACV or SCV-CHIK
One might speculate that the ability of SCV-ZIKA/CHIK vaccination to induce anti-ZIKV responses might be compromised in individuals that have anti-CHIKV-immune responses due to a prior exposure to CHIKV35,36. To test this contention, C57/BL6 mice were infected with CHIKV and were then vaccinated with SCV-ZIKA/CHIK (Fig. 6a). After CHIKV infection, mice showed robust anti-CHIKV ELISA IgG responses (Fig. 6b), and after SCV-ZIKA/CHIK vaccination these responses increased (Fig. 6c, anti-CHIKV). Importantly, in CHIKV-immune mice, SCV-ZIKA/CHIK vaccination efficiently generated anti-ZIKV responses (Fig. 6c, anti-ZIKV). These latter responses were not significantly different from those obtained in mice with no prior CHIKV infection, when comparing either means (Fig. 6d) or medians (Fig. 6e). Anti-ZIKV antibody induction by SCV-ZIKA/CHIK was thus not compromised by pre-existing anti-CHIKV immunity.
Anti-vector immunity can compromise the ability of a recombinant vaccine vector effectively to induce immune responses. To test this for SCV, mice were either mock infected or infected with VACV (Fig. 6f), with the latter mice shown to have generated anti-VACV antibody responses (Fig. 6g). Mice were then vaccinated with SCV-ZIKA/CHIK and anti-ZIKV and anti-CHIKV ELISA titers determined (Fig. 6f). Neither anti-ZIKV (Fig. 6h) nor anti-CHIKV antibody responses (Fig. 6i) were significantly affected by prior VACV infection. These results are consistent with studies using recombinant MVA vaccines37,38 and argue that pre-existing anti-VACV immunity does not effectively suppress the ability of these poxvirus vaccines to induce antibody responses to recombinant immunogens. Prior vaccination with SCV-CHIK also did not significantly affect anti-ZIKV responses following SCV-ZIKA/CHIK vaccination (Fig. 6j,k), although anti-CHIKV responses were significantly boosted (Fig. 6l).
Herein we describe the application of the SCV vaccine technology to the development of a single vector, multi-pathogen, SCV-ZIKA/CHIK vaccine. The vaccine was able to prevent viremia and arthritic disease in a CHIKV wild-type mouse model and to mediate protection in three models of ZIKV infection using IFNAR−/− mice. A single vaccination protected against (i) lethal infection with ZIKVMR766, (ii) fetal/placental ZIKVNatal infection in pregnant IFNAR−/−dams, and (iii) ZIKVNatal infection and testes damage in male IFNAR−/− mice.
Vaccinia-based vaccines have a number of features that make them attractive for managing epidemics in resource poor settings, primarily cold chain-independent distribution capacity39 and long lasting immunity40. The inability of SCV vaccines to generate viral progeny in human cells or to cause disease in immunodeficient mice2 suggests SCV will have a similar safety profile as the replication-deficient, passage-attenuated MVA. MVA has an impeccable safety record, with more than 120,000 people vaccinated at the end of the smallpox eradication campaign without any serious adverse effects41. In addition, MVA was recently shown to be safe and well tolerated in individuals with atopic dermatitis or HIV42,43. The CHO-based SCS line also provides a rapid production and scale up capacity for SCV vaccine manufacture2.
Prior exposure to CHIKV did not significantly affect the ability of SCV-ZIKA/CHIK to induce antibody responses to ZIKV. Concepts related to “original antigenic sin”35 might raise concerns that pre-existing immune responses to CHIKV could inhibit induction of anti-ZIKV responses. However, the ZIKV and CHIKV polyproteins are expressed from separate loci in the SCV-ZIKA/CHIK vaccine, with these two immunogens not physically linked, a prerequisite for the classically described “sin” phenomenon35. Concerns that pre-existing anti-CHIKV cytotoxic T cell (CTL) responses44 might kill SCV-ZIKA/CHIK-infected cells before sufficient ZIKV antigens can be made, might be ameliorated by the recent insight that CTL killing activity in vivo is actually rather limited45, with poxviruses also deploying a plethora of strategies to inhibit apoptosis46. Prior infection with VACV had no significant impact on anti-ZIKV and anti-CHIKV antibody induction after SCV-ZIKA/CHIK vaccination, an observation consistent with studies on recombinant MVA vaccines37,38. Prior SCV-CHIK vaccination also had no significant impact on anti-ZIKV antibody induction after SCV-ZIKA/CHIK vaccination. Vaccinia deploys a series of strategies to avoid antibody neutralization47, and human studies have illustrated that although anti-VACV immunity effectively inhibits VACV dissemination, it is much less effective at inhibiting initial infection by VACV48. SCV vaccines do not disseminate in vivo2, with a single round infection sufficient to induce immunity.
When comparing the anti-CHIKV responses after SCV-ZIKA/CHIK and SCV-CHIK, no consistent significant difference was observed (for Figs. 2d and 3b,d, p = 0.06–0.3, Kolmogorov–Smirnov tests). Furthermore, anti-ZIKV antibody responses after SCV-ZIKA/CHIK and SCV-ZIKA vaccination were also not significantly different (Supplementary Fig. 2). Interference or interaction effects between the ZIKV and CHIKV immunogens thus appear to be minimal in this context.
To the best of our knowledge this represents the first efficacious single vector, multi-pathogen vaccine that encodes whole structural polyprotein gene cassettes from two unrelated viruses. The large payload capacity of poxvirus vectors (at least 25,000 bp49) is relatively unique, with most established virus vector systems unable to package genomes containing such large recombinant inserts. An immunogenic multi-pathogen VACV construct has previously been reported and encoded (from three insertion sites) single antigens from influenza, hepatitis B, and herpes simplex virus50. A recently reported multi-pathogen MVA vaccine, encoding hepatitis B and rabies virus immunogens under the control of a T7 promoter, required co-infection with a MVA encoding T7 polymerase, but failed to induce responses to the heterologous immunogens51. A trivalent MVA vaccine encoding three H5N1 influenza hemagglutinin genes was efficacious and used three different promoters and a single-insertion site52. Herein we used the poxvirus synthetic strong early late promoter53; one to drive CHIKV, and another to drive ZIKV, polyprotein expression. Despite the potential for homologous recombination, the SCV-ZIKA/CHIK construct remained stable over 10 passages. As these two identical 39 nucleotide long promoters are widely separated in the SCV genome, any intramolecular homologous recombination would delete the ≈21 kb of SCV genome sequence that lies between the A39R and B7R-B8R loci. This would result in a virus whose propagation in SCS cells would be non-viable due to the loss of ORFs coding for essential viral proteins.
Multi-pathogen vaccines can also be generated by delivering epitopes from multiple pathogens54,55; however, generating antibody responses to complex folded immunogens using such an approach is intrinsically difficult. An alternative approach is mixing, such as the recently developed hexavalent childhood vaccine (DTaP5-IPV-Hib-HepB)56. Another mixed vaccine is the tetravalent dengue vaccine, which compromises a mixture of four chimeric viral constructs covering the four dengue serotypes57. A SCV-ZIKA/CHIK vaccine would (like such mixed vaccines) reduce the “shot burden” and simplify immunization schedules. In addition, the single-vector construct simplifies manufacture, ensures equal delivery of immunogen genes to antigen producing cells in vivo, and avoids formulation issues associated with mixing.
All mouse work was conducted in accordance with the “Australian code for the care and use of animals for scientific purposes” as defined by the National Health and Medical Research Council of Australia. Animal experiments and associated statistical treatments were reviewed and approved by the QIMR Berghofer Medical Research Institute animal ethics committee (P2195, A1604-611M) and CHIKV work was conducted in biosafety level-3 facility at the QIMR Berghofer.
Cell lines and virus stocks
CHO cells (ATCC CCL-61) were used to generate the SCS cell line2. Vero (ATCC CCL-81) and C6/36 cells (ATCC CRL1660) were purchased from the European Collection of Authenticated Cell Cultures/Sigma in 2016 and were passaged no more than 20 times. Cell lines are routinely authenticated in-house by Short Tandem Repeat profiling and checked for mycoplasma using MycoAlert™ Mycoplasma Detection Kit (Lonza). Virus stocks were checked for mycoplasma as described58. Low endotoxin contamination status of fetal calf serum was confirmed as described59.
Construction of SCV-ZIKA/CHIK
The construction of VACV-CHIK from the Copenhagen strain of vaccinia (gifted by Dr Robert Drillien, Institute of Virology, Strasbourg, France) has been described previously2. SCV-ZIKA/CHIK was constructed by replacing the B7R-B8R ORF with a poxvirus expression cassette for ZIKV prME (Brazilian isolate ZikaSPH2015, Genbank: KU321639) and deleting the D13L ORF by homologous recombination (Fig. 1a). For insertion of the ZIKV prME expression cassette (by replacing the B7R-B8R ORFs), a homologous recombination cassette was constructed consisting of the following elements: (i) F1 homologous recombination targeting sequences upstream of the B7R gene, (ii) an expression cassette consisting of a vaccinia virus early/late promoter53 operatively linked to a protein coding sequence for a fluorescent blue protein fusion with Zeocin resistance protein (BFPzeo) and ending with a poxvirus early transcriptional stop sequence, (iii) a repeat of the F1 homologous recombination arm, (iv) an expression cassette consisting of a vaccinia virus early/late promoter operatively linked to a protein coding sequence for ZIKV prME followed by a poxvirus early transcriptional stop sequence and finally (v) F2 homologous recombination targeting sequences downstream of the B8R gene. The signal sequence for prME was the natural predicted sequence, which constitutes the C-terminal 18 amino acids of Capsid60. With the addition of the ATG start codon, the N-terminal sequence of prME becomes MGADTSVGIVGLLLTTAMA-AEVTRR (italics represents the beginning of pr). The nucleotide sequences of the ZIKA and CHIK immunogens and insertion sites, and the D13L deletion (see below) are provided in Supplementary Fig. 3.
The D13L ORF was replaced by DsRed/CP7761 (Fig. 1a) as described in the construction of SCV-CHIK2. Homologous recombination was performed by transfecting both the ZIKV prME and D13L homologous recombination cassettes into CHO+D13L cells2 previously infected with VACV-CHIK at an MOI of 0.01 PFU/cell. SCVDsRed/CP77-ZIKABFPzeo/CHIK was enriched from the homologous recombination infection by amplifying the virus in CHO+D13L cells in the presence of Zeocin (ThermoFisher Scientific) followed by a second infection of a fresh set of CHO+D13L cells in the presence of Zeocin with amplified virus. These infected cells were recovered and made into a single cell suspension by TrypLE Select digestion and then single cell sorted so that a single blue and red fluorescent cell was seeded into one well of a 96-well plate containing CHO+D13L cells using FACSAria Fusion flow cytometer (BD Biosciences). After incubation in the presence of Zeocin, wells containing a single blue and red fluorescent focus of infection were harvested and resuspended as single cell suspensions before single cell sorting and seeding into 96-well plates of fresh CHO+D13L cells. This single cell sorting and culturing in the presence of Zeocin was repeated five times in order to eliminated trace contamination with the original VACV-CHIK and produce clonal SCVDsRed/CP77-ZIKABFPzeo/CHIK. A number of clonally purified SCVDsRed/CP77-ZIKABFPzeo/CHIK vectors were amplified in SCS cells in the absence of Zeocin and were then subject to PCR analysis to confirm insertion of ZIKV prME into the B7R-B8R locus, retention of the CHIK expression cassette in the A39R locus, removal of D13L and absence of contaminating VACV-CHIK. Clones were amplified in SCS cells in the absence of Zeocin to encourage intramolecular recombination between the F1 homologous recombination sequence and the F1 repeat sequence resulting in the deletion of both BFPzeo and DsRed/CP77 expression cassettes. Single cell suspensions of these cultures were bulk sorted (FACSAria) and non-fluorescent cells retained. The PCR was repeated to confirm retention of inserts, removal of D13L, and loss of BFPzeo and DsRed/CP77. All SCV vaccine stocks were prepared in SCS cells and titred as described2.
PCR of SCV-ZIKA/CHIK-infected SCS cells
Construction and purity of SCV-ZIKA/CHIK was confirmed by PCR. SCS cells were infected with SCV-ZIKA/CHIK (MOI = 1) and after 24 h DNA was extracted using a DNAeasy kit (Qiagen). PCR reactions were performed using KAPA HiFi polymerase (Kapa Biosystems) with the following primer pairs: A39R locus, forward 5′-GTCGTACAATTCTGTACCTATCAAGG-3′ and reverse 5′-CGCATCTGTATCAAACGGAGG-3′; B7R-B8R locus, forward 5′-GGTGCTTCGTACATAAGTTGT-3′ and reverse 5′-GGAATCACTATTACTACTTGT-3′; and D13L locus, forward 5′-CGACACCCGTTTCATGGAACAA-3′ and reverse 5′-GGACGACGAGATACGTAGAGTGT-3′. PCR products were run on a 1% agarose gel and visualized using GelRed (Biotium). Uncropped images are provided in Supplementary Fig. 4.
Western blotting of SCV-ZIKA/CHIK-expressed immunogens
Western blotting of CHIKV antigens in lysates of SCV-ZIKA/CHIK-infected SCS cells (24 h, MOI = 1) and HeLa cells (MOI = 5) at the indicated time(s) was undertaken as described previously using anti-CHIKV polyclonal anti-sera2 (1 in 100 dilution) generated in-house by immunizing C57BL/6 mice twice with inactivated CHIKV. The lysates were also analyzed using an anti-ZIKV E protein mouse polyclonal serum, generated in-house by immunization with E. coli-derived purified recombinant ZIKV E protein formulated with Titremax Gold adjuvant (Sigma-Aldrich). Uncropped images are provided in Supplementary Fig. 4.
Assessment of SCV-ZIKA/CHIK insert stability
SCV-ZIKA/CHIK was passaged ten times in subconfluent SCS cells, with 3 days of culture for each passage. After each culture period, cells were collected by scraping and were homogenized (as described2) and reseeded at MOI = 0.01–0.001. The MOI was estimated by plaque formation in SCS cells. PCR of infected cells after passage 1 and passage 10 was performed for the A39R and B7R-B8R loci on cell lysates as described above. For quantitative PCR, DNA was extracted from lysates using the Magery Nagel Nucleospin tissue extraction kit (Scientifix, Vic, Australia). ZIKV M primers were F 3′ TTGGTCATGATACTGCTGATTGC 5′, R 3′ CCTTCCACAAAGTCCCTATTGC 5′ and VACV G1L primers were F 3′ TCGGTGTCTATAACGGAAC 5′, R 3′ GTTTAGTCGTGTCTACAAAAGG 5′. Quantitative PCR was undertaken (in duplicates) using the CFX 96 touch PCR detection system (Biorad) using the same cycling parameters for both sets of primers; 1 × 50 °C 2 min, 1 × 95 °C 2 min, 45 × 94 °C 5 s, 52 °C 10 s and 72 °C 40 s), with analysis using Biorad CFX Real Time Analysis software.
Vaccination and antibody responses
Groups of male or female (as indicated) 6–8-week-old C57BL/6J (ARC, Canning Vale, WA, Australia) or IFNAR−/− mice27 were vaccinated intramuscularly (50 μl into both quadriceps femoris muscles) with SCV-CHIK, SCV-ZIKA/CHIK or SCV-cont (a control SCV vaccine encoding dsRed2) in 10 mM Tris HCl pH 8. Serum antibody responses were determined by standard ELISA using (i) whole inactivated CHIKV as antigen as described62 and (ii) whole-ZIKVMR766 virus preparations purified from infected Vero cell supernatants by 8% polyethylene glycol precipitation and ultracentrifugation through a 20% sucrose cushion. CHIKV neutralization titers against the Reunion Island isolate (LR2006-OPY1) of CHIKV were determined as described63. As ZIKVNatal plaques poorly, ZIKV neutralizing antibody titers were determined (against ZIKVNatal and ZIKVMR766) by incubating dilutions of heat-inactivated mouse serum (in duplicate) with 100 CCID50 of virus for 3 h before adding Vero E6 cells (Sigma, ECACC Vero C1008) (104/well of a 96-well plate). After 5 days cells were fixed, stained with crystal violet and the reciprocal 50% neutralizing titers determined.
CHIKV and ZIKV challenge
Vaccinated C57BL/6 mice were challenged with 104 CCID50 of the Reunion Island CHIKV isolate subcutaneously into the feet, and the post-challenge viremia and foot swelling determined as described4,63. Vaccinated IFNAR−/− mice were challenged by s.c. infection with 103 CCID50 of ZIKVMR766 or 104 CCID50 ZIKVNatal and viremia assessed as described27. ZIKVMR766 infected female IFNAR−/− mice were killed when ethically defined end points were reached (primarily hind-limb paralysis). ZIKVNatal infection of pregnant IFNAR−/− dams was undertaken at E6.5 or E12.5 with viremia in dams measured as described27. At E17.5 dams were euthanized, fetuses weighted and photographed, and fetal heads and placenta were either (i) processed for determination of tissue titers27 or (ii) placed into RNAlater (Ambion, Austin TX, USA) and processed for qRT PCR63 using ZIKV M primers (as described above), with normalization to RPL13A27.
Male IFNAR−/− mice were infected with ZIKVNatal and viremia determined as described27. On day 21 post infection testes were removed and analyzed for qRT PCR as above, and H&E staining as described3. Immunohistochemistry was undertaken using the 4G4 monoclonal antibody generated in-house (and used as neat hybridoma supernatant) as described27,64 and Warp Red Chromogen kit (Biocare Medical, CA, USA).
Prior infection with VACV, CHIKV or SCV-CHIK
Female 6–8-week-old C57BL/6 mice were infected with VACV (replication competent Copenhagen strain of vaccine) 106 pfu i.p. or with CHIKV (LR2006-OPY1) 104 CCID50 s.c. in the feet4 or with SCV-CHIK 106 pfu i.m.
Statistical analysis of experimental data was performed using IBM SPSS Statistics for Windows, Version 19.0. Two-sample comparison using t test was performed when the difference in variances was <4, skewness was ≥2 and kurtosis was <2. Non-parametric data with difference in variances of <4 was analyzed using Mann–Whitney U test, if difference of variances was >4 the Kolmogorov–Smirnov test was employed. The log rank (Mantel–Cox) test was used for statistical analysis of surviving proportions.
The authors declare that the data supporting the findings of this study are available with the article and its Supplementary Information files, or are available from the authors upon request.
Tree, J. A. et al. Repeated high-dose (5 x 10(8) TCID50) toxicity study of a third generation smallpox vaccine (IMVAMUNE) in New Zealand white rabbits. Hum. Vaccin. Immunother. 12, 1795–1801 (2016).
Eldi, P. et al. Production of a chikungunya vaccine using a CHO cell and attenuated viral-based platform technology. Mol. Ther. 25, 2332–2344 (2017).
Wilson, J. A. et al. RNA-Seq analysis of chikungunya virus infection and identification of granzyme A as a major promoter of arthritic inflammation. PLoS Pathog. 13, e1006155 (2017).
Gardner, J. et al. Chikungunya virus arthritis in adult wild-type mice. J. Virol. 84, 8021–8032 (2010).
Wahid, B., Ali, A., Rafique, S. & Idrees, M. Global expansion of chikungunya virus: mapping the 64-year history. Int. J. Infect. Dis. 58, 69–76 (2017).
Suhrbier, A., Jaffar-Bandjee, M. C. & Gasque, P. Arthritogenic alphaviruses—an overview. Nat. Rev. Rheumatol. 8, 420–429 (2012).
Suhrbier, A. & Devine, G. Chikungunya virus, risks and responses for Australia. Aust. N. Z. J. Public. Health 40, 207–209 (2016).
Hugo, L. E., Prow, N. A., Tang, B., Devine, G. & Suhrbier, A. Chikungunya virus transmission between Aedes albopictus and laboratory mice. Parasit. Vectors 9, 555 (2016).
Shragai, T., Tesla, B., Murdock, C. & Harrington, L. C. Zika and chikungunya: mosquito-borne viruses in a changing world. Ann. N. Y. Acad. Sci. 1399, 61–77 (2017).
Duarte, G. et al. Zika virus infection in pregnant women and microcephaly. Rev. Bras. Ginecol. Obstet. 39, 235–248 (2017).
Aliota, M. T. et al. Zika in the Americas, year 2: What have we learned? What gaps remain? A report from the Global Virus Network. Antivir. Res. 144, 223–246 (2017).
Sheridan, M. A. et al. Vulnerability of primitive human placental trophoblast to Zika virus. Proc. Natl Acad. Sci. USA 114, E1587–E1596 (2017).
Aagaard, K. M. et al. Primary human placental trophoblasts are permissive for Zika virus (ZIKV) replication. Sci. Rep. 7, 41389 (2017).
Russo, F. B., Jungmann, P. & Beltrao-Braga, P. C. B. Zika infection and the development of neurological defects. Cell Microbiol. 19, e12744 (2017).
Nutt, C. & Adams, P. Zika in Africa-the invisible epidemic? Lancet 389, 1595–1596 (2017).
Liu, Y. et al. Evolutionary enhancement of Zika virus infectivity in Aedes aegypti mosquitoes. Nature 545, 482–486 (2017).
Grard, G. et al. Zika virus in Gabon (Central Africa)–2007: a new threat from Aedes albopictus? PLoS Negl. Trop. Dis. 8, e2681 (2014).
Ciota, A. T. et al. Effects of Zika virus strain and Aedes mosquito species on vector competence. Emerg. Infect. Dis. 23, 1110–1117 (2017).
Griffin, B. D. et al. DNA vaccination protects mice against Zika virus-induced damage to the testes. Nat. Commun. 8, 15743 (2017).
Fuller, T. L. et al. Behavioral, climatic, and environmental risk factors for Zika and Chikungunya virus infections in Rio de Janeiro, Brazil, 2015-16. PLoS ONE 12, e0188002 (2017).
Zambrano, H. et al. Zika virus and Chikungunya virus coinfections: a series of three cases from a single center in Ecuador. Am. J. Trop. Med. Hyg. 95, 894–896 (2016).
Waggoner, J. J. et al. Viremia and clinical presentation in Nicaraguan patients infected with Zika virus, Chikungunya virus, and Dengue virus. Clin. Infect. Dis. 63, 1584–1590 (2016).
Kutsuna, S. et al. A case of consecutive infection with Zika virus and Chikungunya virus in Bora Bora, French Polynesia. J. Infect. Chemother. 23, 114–116 (2017).
Villamil-Gomez, W. E. et al. Zika, dengue, and chikungunya co-infection in a pregnant woman from Colombia. Int. J. Infect. Dis. 51, 135–138 (2016).
Ruckert, C. et al. Impact of simultaneous exposure to arboviruses on infection and transmission by Aedes aegypti mosquitoes. Nat. Commun. 8, 15412 (2017).
Lauer, K. B., Borrow, R. & Blanchard, T. J. Multivalent and multipathogen viral vector vaccines. Clin. Vaccin. Immunol. 24, e00298-16 (2017).
Setoh, Y. X. et al. De novo generation and characterization of new Zika virus isolate using sequence data from a microcephaly case. mSphere 2, e00190–17 (2017).
Verardi, P. H., Jones, L. A., Aziz, F. H., Ahmad, S. & Yilma, T. D. Vaccinia virus vectors with an inactivated gamma interferon receptor homolog gene (B8R) are attenuated In vivo without a concomitant reduction in immunogenicity. J. Virol. 75, 11–18 (2001).
Price, N., Tscharke, D. C., Hollinshead, M. & Smith, G. L. Vaccinia virus gene B7R encodes an 18-kDa protein that is resident in the endoplasmic reticulum and affects virus virulence. Virology 267, 65–79 (2000).
Joklik, W. K. & Becker, Y. The replication and coating of vaccinia DNA. J. Mol. Biol. 10, 452–474 (1964).
Salzman, N. P. The rate of formation of vaccinia deoxyribonucleic acid and vaccinia virus. Virology 10, 150–152 (1960).
Ansarah-Sobrinho, C. & Moss, B. Vaccinia virus G1 protein, a predicted metalloprotease, is essential for morphogenesis of infectious virions but not for cleavage of major core proteins. J. Virol. 78, 6855–6863 (2004).
Meneses, J. D. A. et al. Lessons learned at the epicenter of Brazil’s congenital Zika epidemic: evidence from 87 confirmed cases. Clin. Infect. Dis. 64, 1302–1308 (2017).
Govero, J. et al. Zika virus infection damages the testes in mice. Nature 540, 438–442 (2016).
Etlinger, H. M. et al. Use of prior vaccinations for the development of new vaccines. Science 249, 423–425 (1990).
Sherritt, M. A. et al. Effect of pre-existing cytotoxic T lymphocytes on therapeutic vaccines. Eur. J. Immunol. 30, 671–677 (2000).
Yang, Z. Y. et al. Overcoming immunity to a viral vaccine by DNA priming before vector boosting. J. Virol. 77, 799–803 (2003).
Kannanganat, S. et al. Preexisting vaccinia virus immunity decreases SIV-specific cellular immunity but does not diminish humoral immunity and efficacy of a DNA/MVA vaccine. J. Immunol. 185, 7262–7273 (2010).
Alcock, R. et al. Long-term thermostabilization of live poxviral and adenoviral vaccine vectors at supraphysiological temperatures in carbohydrate glass. Sci. Transl. Med. 2, 19ra12–19ra12 (2010).
Amanna, I. J., Carlson, N. E. & Slifka, M. K. Duration of humoral immunity to common viral and vaccine antigens. N. Engl. J. Med. 357, 1903–1915 (2007).
Mayr, A., Stickl, H., Muller, H. K., Danner, K. & Singer, H. [The smallpox vaccination strain MVA: marker, genetic structure, experience gained with the parenteral vaccination and behavior in organisms with a debilitated defence mechanism (author’s transl)]. Zent. Bakteriol. B 167, 375–390 (1978).
Overton, E. T. et al Safety and immunogenicity of modified vaccinia Ankara-Bavarian Nordic smallpox vaccine in vaccinia-naive and experienced human immunodeficiency virus-infected individuals: an open-label, controlled clinical phase II trial. Open Forum Infect. Dis. 2, ofv040 (2015).
Greenberg, R. N. et al. A multicenter, open-label, controlled phase II study to evaluate safety and immunogenicity of MVA smallpox vaccine (IMVAMUNE) in 18-40 year old subjects with diagnosed atopic dermatitis. PLoS ONE 10, e0138348 (2015).
Wauquier, N. et al. The acute phase of Chikungunya virus infection in humans is associated with strong innate immunity and T CD8 cell activation. J. Infect. Dis. 204, 115–123 (2011).
Halle, S. et al. In vivo killing capacity of cytotoxic T cells is limited and involves dynamic interactions and T cell cooperativity. Immunity 44, 233–245 (2016).
Nichols, D. B., De Martini, W. & Cottrell, J. Poxviruses utilize multiple strategies to inhibit apoptosis. Viruses 9, 215 (2017).
Smith, G. L., Symons, J. A., Khanna, A., Vanderplasschen, A. & Alcami, A. Vaccinia virus immune evasion. Immunol. Rev. 159, 137–154 (1997).
Frey, S. E. et al. Clinical and immunologic responses to multiple doses of IMVAMUNE (Modified Vaccinia Ankara) followed by Dryvax challenge. Vaccine 25, 8562–8573 (2007).
Smith, G. L. & Moss, B. Infectious poxvirus vectors have capacity for at least 25 000 base pairs of foreign DNA. Gene 25, 21–28 (1983).
Perkus, M. E., Piccini, A., Lipinskas, B. R. & Paoletti, E. Recombinant vaccinia virus: immunization against multiple pathogens. Science 229, 981–984 (1985).
Lauer, K. B. et al. A novel strategy to express different antigens from one modified vaccinia Ankara vaccine vector. Preprint at https://doi.org/10.1101/191924 (2017).
Prabakaran, M. et al. Progress toward a universal H5N1 vaccine: a recombinant modified vaccinia virus Ankara-expressing trivalent hemagglutinin vaccine. PLoS ONE 9, e107316 (2014).
Chakrabarti, S., Sisler, J. R. & Moss, B. Compact, synthetic, vaccinia virus early/late promoter for protein expression. Biotechniques 23, 1094–1097 (1997).
Suhrbier, A. Polytope vaccines for the codelivery of multiple CD8 T-cell epitopes. Expert. Rev. Vaccin. 1, 207–213 (2002).
Rattanasena, P. et al. Prime-boost vaccinations using recombinant flavivirus replicon and vaccinia virus vaccines: an ELISPOT analysis. Immunol. Cell. Biol. 89, 426–436 (2011).
Lee, A. W., Jordanov, E., Boisnard, F. & Marshall, G. S. DTaP5-IPV-Hib-HepB, a hexavalent vaccine for infants and toddlers. Expert. Rev. Vaccin. 16, 85–92 (2017).
Guy, B., Briand, O., Lang, J., Saville, M. & Jackson, N. Development of the Sanofi Pasteur tetravalent dengue vaccine: one more step forward. Vaccine 33, 7100–7111 (2015).
La Linn, M., Bellett, A. J., Parsons, P. G. & Suhrbier, A. Complete removal of mycoplasma from viral preparations using solvent extraction. J. Virol. Methods 52, 51–54 (1995).
Johnson, B. J. et al. Heat shock protein 10 inhibits lipopolysaccharide-induced inflammatory mediator production. J. Biol. Chem. 280, 4037–4047 (2005).
Kuno, G. & Chang, G. J. Full-length sequencing and genomic characterization of Bagaza, Kedougou, and Zika viruses. Arch. Virol. 152, 687–696 (2007).
Liu, L. et al. Transient dominant host-range selection using Chinese hamster ovary cells to generate marker-free recombinant viral vectors from vaccinia virus. Biotechniques 62, 183–187 (2017).
Wang, D. et al. A complex adenovirus vaccine against chikungunya virus provides complete protection against viraemia and arthritis. Vaccine 29, 2803–2809 (2011).
Poo, Y. S. et al. Multiple immune factors are involved in controlling acute and chronic chikungunya virus infection. PLoS Negl. Trop. Dis. 8, e3354 (2014).
Prow, N. A. et al. The West Nile virus-like flavivirus Koutango is highly virulent in mice due to delayed viral clearance and the induction of a poor neutralizing antibody response. J. Virol. 88, 9947–9962 (2014).
We thank the QIMR B animal house staff for their assistance and supply of GMO mice, and Clay Winterford and his team at QIMR B for their help with histology and immunohistochemistry. We thank Dr I Anraku for his assistance in managing the BSL3 facility at QIMR B. Thanks also to Caitlin O’Brien (UQ) for help with the ZIKV antigen preparations. N.A.P. was supported by an Advance Queensland Research Fellowship from the Queensland Government, Australia. A.S. holds a Principal Research Fellowship from the National Health and Medical Research Council of Australia. This work was also supported in part by Sementis Ltd. via (i) Australian Department of Industry, Enterprise Connect Researchers in Business Fellowships for L.L. and T.H.C., (ii) a Science Industry Endowment Fund, STEM+ Business Fellowship for T.H.C and L.L. and (iii) an Australian Research Council Linkage grant LP160100633 awarded to J.D.H. and P.M.H. E.N. was supported in part by the Daiichi Sankyo Foundation of Life Science.
This research was supported in part by funding from Sementis Ltd. in which P.M.H. and J.D.H. are shareholders. A.S. is an unpaid member of the Sementis Ltd. Scientific Advisory Board and has undertaken contract R & D for Sementis Ltd. Part of the work described in this manuscript has been filed in a patent application PCT/AU2017/050879. The remaining authors declare no competing interests.
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Prow, N.A., Liu, L., Nakayama, E. et al. A vaccinia-based single vector construct multi-pathogen vaccine protects against both Zika and chikungunya viruses. Nat Commun 9, 1230 (2018). https://doi.org/10.1038/s41467-018-03662-6
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