A simian-adenovirus-vectored rabies vaccine suitable for thermostabilisation and clinical development for low-cost single-dose pre-exposure prophylaxis

Chuan Wang; Pawan Dulal; Xiangyang Zhou; Zhiquan Xiang; Hooman Goharriz; Ashley Banyard; Nicky Green; Livia Brunner; Roland Ventura; Nicolas Collin; Simon J. Draper; Adrian V. S. Hill; Rebecca Ashfield; Anthony R. Fooks; Hildegund C. Ertl; Alexander D. Douglas

doi:10.1371/journal.pntd.0006870

Abstract

Background

Estimates of current global rabies mortality range from 26,000 to 59,000 deaths per annum. Although pre-exposure prophylaxis using inactivated rabies virus vaccines (IRVs) is effective, it requires two to three doses and is regarded as being too expensive and impractical for inclusion in routine childhood immunization programmes.

Methodology/ Principal findings

Here we report the development of a simian-adenovirus-vectored rabies vaccine intended to enable cost-effective population-wide pre-exposure prophylaxis against rabies. ChAdOx2 RabG uses the chimpanzee adenovirus serotype 68 (AdC68) backbone previously shown to achieve pre-exposure protection against rabies in non-human primates. ChAdOx2 differs from AdC68 in that it contains the human adenovirus serotype 5 (AdHu5) E4 orf6/7 region in place of the AdC68 equivalents, enhancing ease of manufacturing in cell lines which provide AdHu5 E1 proteins in trans.

We show that immunogenicity of ChAdOx2 RabG in mice is comparable to that of AdC68 RabG and other adenovirus serotypes expressing rabies virus glycoprotein. High titers of rabies virus neutralizing antibody (VNA) are elicited after a single dose. The relationship between levels of VNA activity and rabies virus glycoprotein monomer-binding antibody differs after immunization with adenovirus-vectored vaccines and IRV vaccines, suggesting routes to further enhancement of the efficacy of the adenovirus-vectored candidates. We also demonstrate that ChAdOx2 RabG can be thermostabilised using a low-cost method suitable for clinical bio-manufacture and ambient-temperature distribution in tropical climates. Finally, we show that a dose-sparing effect can be achieved by formulating ChAdOx2 RabG with a simple chemical adjuvant. This approach could lower the cost of ChAdOx2 RabG and other adenovirus-vectored vaccines.

Conclusions/ Significance

ChAdOx2 RabG may prove to be a useful tool to reduce the human rabies death toll. We have secured funding for Good Manufacturing Practice- compliant bio-manufacture and Phase I clinical trial of this candidate.

Author summary

Rabies was, after smallpox, the second human disease for which an efficacious vaccine was developed, by Pasteur in 1885. Although it is eminently preventable, with highly efficacious vaccines available for both humans and animals, it still causes considerable mortality in low and middle-income countries. It is a particular problem in areas with the weakest healthcare and veterinary infrastructure, where achieving prompt post-exposure prophylaxis or high-coverage dog vaccination are challenging. Here, we report the development of a new candidate rabies vaccine, designed to enable low-cost single-dose pre-exposure human rabies prophylaxis in such settings. ChAdOx2 RabG is based upon a simian adenovirus-vectored candidate previously shown to achieve protection after a single dose in non-human primates, now modified to allow clinical-grade bio-manufacture. We show that it induces a potent immune response in mice, that this response can be further enhanced by a clinically-relevant adjuvant, and that we can stabilise it such that it can withstand temperatures of up to 45 °C for a month. We will be performing a clinical trial of this candidate in the near future.

Citation: Wang C, Dulal P, Zhou X, Xiang Z, Goharriz H, Banyard A, et al. (2018) A simian-adenovirus-vectored rabies vaccine suitable for thermostabilisation and clinical development for low-cost single-dose pre-exposure prophylaxis. PLoS Negl Trop Dis 12(10): e0006870. https://doi.org/10.1371/journal.pntd.0006870

Editor: Charles E. Rupprecht, Wistar Institute, UNITED STATES

Received: July 30, 2018; Accepted: September 24, 2018; Published: October 29, 2018

Copyright: © 2018 Wang et al. This is an open access article distributed under the terms of the Creative Commons Attribution License, which permits unrestricted use, distribution, and reproduction in any medium, provided the original author and source are credited.

Data Availability: All relevant data are within the paper.

Funding: This work has been supported by the UK Medical Research Council including Confidence in Concept (grants MC_PC_13073 and MR/P017339/1). SJD, AVSH and ADD are Jenner Investigators; SJD is also a Lister Institute Research Prize Fellow and a Wellcome Trust Senior Fellow (grant 106917/Z/15/Z). ADD is supported by the Wellcome Trust (grant 201477/Z/16/Z). The funders had no role in study design, data collection and analysis, decision to publish, or preparation of the manuscript.

Competing interests: AVSH and ADD are named inventors on a patent application relating to the development of the ChAdOx2 vector. AVSH and SJD are named inventors on a patent relating to the use of the intron-containing promoter used in ChAdOx2 RabG. The University of Oxford and the Wistar Institute have entered into a partnership to share any future revenue from development of the ChAdOx2 RabG vaccine.

Introduction

Despite the development of an efficacious rabies vaccine by Pasteur in 1885, estimates of current global annual human rabies mortality range from 24,000 to 59,000 [1–3]. Among the neglected tropical diseases, the burden of mortality due to rabies is exceeded only by that due to leishmaniasis [1]. Across large and populous areas of Africa and Asia, rabies-attributable mortality rates exceed 1 per 100,000 people per year [3]. More than 200 million individuals live in countries with rabies-attributable mortality rates exceeding 5 per 100,000 per year, corresponding to a lifetime risk of death due to rabies exceeding 0.1% [3]. Such death rates exceed those attributable to some diseases included in the Expanded Programme on Immunization (EPI) and/or supported by GAVI. Calculations suggest that, in such settings, a highly-effective, simple to deliver pre-exposure prophylactic intervention costing less than USD 4 per recipient would have a cost per death averted of less than USD 4000 and a cost per DALY of less than USD 200, competitive with GAVI-funded interventions [4].

Most human cases of rabies are the result of dog bites [5]. There is a strong argument for investment in dog vaccination: feasibility and cost-effectiveness of rabies control and human rabies elimination by dog vaccination has been demonstrated in some low and middle income country (LMIC) settings [6, 7]. However, the countries with the highest rabies incidence are those which are least developed and most politically unstable, including Somalia, the Democratic Republic of the Congo, and Afghanistan. It remains doubtful whether adequate coverage (>60% in a canine population which turns over approximately every two years [7]) is achievable in such settings. Similarly, implementation of a robust programme of human post-exposure prophylaxis (PEP) is likely to be challenging in such settings. Following a dog bite, PEP is needed urgently and requires repeated vaccination and the administration of expensive rabies immune globulin (RIG). Achieving continuous local availability of PEP to meet such urgent yet unpredictable and intermittent demand is substantially more challenging than implementing intermittent planned mass vaccination campaigns. Concerns about the complexity of implementation of such an ‘as-needed’ intervention were the basis of GAVI’s 2013 decision not to fund PEP, despite analysis suggesting that the cost per death averted could compare favourably to that of other GAVI-funded interventions; review of this decision is expected in the near future [4].

Licensed human rabies vaccines are all based upon inactivated rabies virus (IRV), and may be used either for pre-exposure prophylaxis (PrEP) as well as PEP. PrEP regimes have until recently involved three doses of IRV vaccine spread over 28 days with typical costs of around USD 25 per vaccinee [8]. The WHO recently endorsed the use of a PrEP regime involving intradermal administration of two smaller doses on each of two visits, separated by seven days: such intradermal regimes can reduce cost substantially, but still require a total of four injections over two visits and are not licensed in some countries [9, 10]. Although there are data suggesting that IRVs can be stable for a few weeks at 37 °C, their regulator-approved labels mandate refrigerated storage at 2–8 °C [11–14]. As a result of these cost and delivery characteristics, rabies PrEP is not included in routine childhood immunization programmes in most rabies-endemic areas [15].

It is recommended that previous PrEP recipients who then receive a dog bite should still receive PEP, but this ‘post-PrEP PEP’ is an abbreviated and much less expensive course over one or two visits, without RIG [9]. Importantly, data suggest that PrEP alone—without any PEP—can achieve potentially protective antibody titers lasting many years [16, 17]. This suggests that PrEP may provide substantial benefit even in contexts in which the reliable availability of PEP cannot be assured. Given the substantial proportion of children in rabies-endemic areas who receive dog bites and for whom PEP is then indicated (estimated to exceed 30% across a typical childhood in some areas [8]), it is estimated that routine PrEP could be not only more effective but cost-saving relative to PEP-based strategies in many contexts, particularly if the cost of PrEP is beneath USD 4 per child [8, 18].

Child-population-wide PrEP is thus an attractive intervention in areas in which Expanded Programme on Immunization (EPI) vaccines are delivered but which have otherwise limited capacity for reliable urgent PEP or for control of rabies-transmitting animals. This role for mass PrEP has been recognised, for example, in the Peruvian Amazon: in this setting, vampire bat rabies is problematic and difficult to control, access to PEP is limited, and a PrEP programme appears to have been successful [15].

Here, we have set out to develop a tool intended to enable cost-effective PrEP against rabies within routine population-wide immunization programmes. The immunological mechanism of vaccine-induced immunity against rabies is well characterised. A virus neutralizing antibody (VNA) titer exceeding 0.5 international units per milliliter (IU/mL) is accepted as a marker of adequate immunization [19]. This threshold is thought by many to signify clinical efficacy: indeed, in animal challenge studies, 100% protection is achieved at 0.1–0.2 IU/mL, with incomplete but substantial protection at even lower titers [20]. Simian adenovirus-vectored vaccines are an attractive platform technology for induction of antibody responses, circumventing the problem of pre-existing anti-vector antibody to human adenovirus serotypes and readily manufacturable at large scale and low cost [21, 22]. A chimpanzee adenovirus serotype 68 (AdC68)-vectored rabies vaccine and the ability of a single low dose of this vaccine to achieve long-lasting protection against rabies challenge in non-human macaques has been reported previously [23, 24]. We now describe the development of a closely-related simian-adenovirus-vectored rabies vaccine, ChAdOx2 RabG, which is suitable for good manufacturing practice (GMP)-compliant production. We also describe additional approaches which may make this particularly suitable for use in low-income settings, namely thermostabilisation of the vaccine and dose-sparing adjuvantation. ChAdOx2 RabG may prove to be suitable for PrEP in highly rabies-endemic settings which have adequate infrastructure to achieve appreciable levels of childhood immunization coverage [25] but which currently lack capacity for reliable dog vaccination or PEP.

Methods

Plasmid and adenovirus production

Plasmid pC68 010-Rabgp comprising the E1- and E3-deleted AdC68 genome with the full-length ERA strain rabies virus glycoprotein coding sequence under a human cytomegalovirus immediate-early (HCMV-IE) promoter was constructed based on a virus obtained from ATCC (ATCC VR-594, Genbank accession: FJ025918.1). The wildtype AdC68 was propagated in HEK 293 cells and purified by CsCl gradient centrifugation, followed by viral genomic DNA purification as described [26]. To generate the E1-deleted AdC68 molecular clone, the 5’ right inverted terminal repeat (ITR) was amplified by PCR and cloned into the pNEB193 vector. Using restriction enzyme sites that are unique in assembly but not necessarily unique to the full AdC68 genome, approximately 2.6 Kb of the E1 region between SnaBI and NdeI sites (from 455bp to 3028bp) were removed and replaced with a linker which contains the rare enzyme sites of I-CeuI and PI-SceI. The resultant was the pC68 000 plasmid. To delete the E3 domain, a 3.6 kb fragment was excised using AvrII and NruI (from 27793bp to 31409bp): briefly, the pC68 000 was digested by AvrII, the 5.8kb fragment was subcloned into a pUC19-like backbone (generating pXY-AvrII), and NruI was used to excise a 1.4 kb fragment (generating pXY-E3 deleted). Later, pXY-E3 deleted (insert donor) was digested with AvrII and SpeI and the insert was ligated into pAdC68 000, to produce plamid pC68 010. The HCMV-IE promoter—rabies virus glycoprotein cassette was inserted as previously reported [23], generating pC68 010-Rabgp (differing from previously published constructs, notably in the deletion of the E3 region).

To construct a vector for transient mammalian expression of rabies virus glycoprotein and as a precursor to adenovirus vector production, the full-length coding sequence was PCR amplified from pC68 010-Rabgp using oligonucleotides providing flanking Acc65I (5’) and NotI (3’) restriction enzyme sites. This permitted restriction-enzyme mediated cloning of the PCR product into pENTR4 LPTOS, a plasmid providing HCMV-IE promoter with intron A and tetracycline operator elements [27, 28]. This transgene is referred to henceforth as SP_rab-G_native, or simply ‘G’.

A codon-optimized version of the ERA strain glycoprotein gene in which the viral signal peptide was replaced by that of the human tissue plasminogen activator (tPA) was synthesized by ThermoFisher and cloned into pENTR4 LPTOS similarly; this transgene is referred to henceforth as SP_tPA-G_opt. A third pENTR4 LPTOS plasmid in which the codon-optimized gene was preceded by the viral signal peptide was generated by InFusion cloning (Takara); this transgene is referred to henceforth as SP_rab-G_opt.

To produce the ChAdOx2 RabG adenoviral vector, Gateway LR recombination (ThermoFisher) was then used to transfer the SP_rab-G_native transgene cassette into the ChAdOx2 parent bacterial artificial chromosome (BAC) [21]. Adenoviral destination vectors for the expression of RabG by AdHu5, chimpanzee adenovirus serotype 63 (ChAd63) and ChAdOx1 were produced similarly, using previously described viral backbones [29, 30] and a full-length non-codon-optimized glycoprotein gene, with the exception that the transgene used was derived from the SAD B19 strain (Addgene plasmid 15785, a kind gift of Miguel Sena-Esteves [31]). SAD B19 and ERA were both derived from the Street Alabama Dufferin (SAD) isolate; their glycoprotein genes differ at only 4 of 524 amino acid loci [32].

AdHu5, AdC68-010, ChAd63, ChAdOx1, and ChAdOx2 adenoviruses were produced from the plasmids/ BACs described above (and subsequently titered) by the Jenner Institute Viral Vector Core Facility, as previously described [27].

Prior to genetic stability studies, ChAdOx2 RabG was subjected to two rounds of plaque picking. Virus was then propagated on adherent HEK293 cells (Oxford Clinical Biomanufacturing Facility proprietary cell bank) for five passages, prior to caesium chloride (CsCl) purification, phenol-chloroform DNA extraction and enzymatic restriction analysis, as previously described [33].

Assessment of G expression in transiently transfected cells

G expression from the three ERA G transgene constructs in mammalian cells was assessed by flow cytometry. Two or three independent DNA preparations of each pENTR4 LPTOS plasmid were produced and transfected into HEK293E cells (National Research Council, Canada) using 25kDa linear polyethylene-imine (Polysciences), as previously described [34]. Identical cells were incubated either with serum from AdHu5 RabG-immunized mice, or with naïve mouse serum (negative control), and then with Alexa488-conjugated goat-anti-mouse secondary antibody (ThermoFisher). The ratio of median fluorescence intensity (MFI) in fully-stained versus negative controls was used to quantify glycoprotein expression.

Expression of codon-optimized G constructs (G_opt, i.e. SP_tPA-G_opt and SP_rab-G_opt) was compared to that of the base-case construct (SP_rab-G_native) by dividing the G_opt MFI ratio by that obtained in the same experiment with SP_rab-G_native.

Ethics statement

All animal work was performed in accordance with the U.K. Animals (Scientific Procedures) Act 1986 (ASPA), and was approved by the University of Oxford Animal Welfare and Ethical Review Body (in its review of the application for the U.K. Home Office Project Licenses PPL 30/2889 and P9804B4F1).

Animals, vaccine preparation and immunization

Female CD-1 outbred mice (Harlan, Charles River and Envigo) were used throughout. Mice were housed in a specific-pathogen-free facility and were 6–7 weeks old at the initiation of each experiment.

All adenovirus vaccine doses were calculated on the basis of infective unit (IU) titers, but viral particle (VP) titers and hence particle: infectivity (P:I) ratios were also measured. In viral preparations used for mouse immunization, P:I ratios were 23 for AdHu5, 132 for ChAd63, 65 for ChAdOx1, 63 for AdC68, and 173 for ChAdOx2. The range of P:I ratios seen here is typical of our experience with these vectors: P:I ratio is known to vary both between preparations of the same adenovirus-vectored vaccine and between serotypes, in some cases by orders of magnitude [30, 35]. Standardization of IU dose and VP dose (and hence P:I ratio) is not possible, but immunogenicity has previously been shown to correlate with the IU dose (30).

Addavax was purchased (Invivogen). SWE, a non-branded squalene-in-water emulsion was prepared at the Vaccine Formulation Laboratory in Lausanne, using a GMP-compatible manufacturing process as previously described [36]. Both adjuvants were used at a dose of 25 μL per mouse, mixed by vortexing for two seconds with the appropriate adenovirus dose (diluted to 25 μL in phosphate buffered saline [PBS]) 1–2 hours prior to administration.

As comparators, we used two IRV vaccines. Rabipur (Novartis) consists of a liquid formulation of unadjuvanted inactivated Flury LEP strain rabies virus, produced on purified chick embryo cells (PCEC), licensed for human use, and with a potency of >2.5 IU/mL in the NIH mouse potency assay, as described [37]. Nobivac Rabies (MSD Animal Health) consists of a liquid formulation of aluminium phosphate adjuvanted inactivated Pasteur strain rabies virus, produced on BHK-21 cells, licensed for animal use, and with a potency of >2 IU/mL.

Vaccine doses used for each experiment are set out in the corresponding figure legends. All vaccinations were diluted in PBS to a total volume of 50 μL (with the exception of the highest doses of Rabipur and Nobivac Rabies [used in Fig 2]). The highest doses of Rabipur and Nobivac Rabies were limited by the maximum volume permitted for intramuscular injections in mice within our institution to 100 μL of undiluted vaccine (i.e. 1/10 of the 1 mL human or companion-animal dose). Vaccine was administered intramuscularly, split equally between the gastrocnemius muscles of each hind limb. Serum samples were obtained by tail bleeding at timepoints as indicated in figure legends. Upon completion of experiments, mice were euthanized by cervical dislocation.

Virus neutralizing antibody (VNA) assay

Coded serum samples were assayed for VNA.

For data shown in Fig 2, the fluorescent antibody virus neutralization (FAVN) assay was performed at the Animal and Plant Health Agency (APHA) as previously described, with quadruplicate serum dilutions and pre-determined acceptance criteria for virus dose as measured by back titration [38].

For data shown in Fig 3, the rapid fluorescent focus inhibition test (RFFIT) was performed at the Wistar Institute, again as previously described [39], using MNA cells.

Both assays used the CVS-11 reference rabies virus strain and the WHO international reference standard to derive titers expressed in IU/mL. The two methods are known to correlate closely [38].

ELISA

To produce soluble rabies virus glycoprotein (RabG_sol) for ELISA plate coating, the sequence encoding amino acids 1–453 of the SAD B19 strain G protein (MVPQ…DLGL) was PCR-amplified from Addgene plasmid 15785 (as above). The primers used added a 5’ Acc65I site and 3’ sequence encoding a C-tag and NotI site [40], enabling cloning into pENTR4 LPTOS (as described above for adenovirus generation). This plasmid was then transfected into Expi293 cells using Expifectamine (both from ThermoFisher), in accordance with the manufacturer’s instructions. The RabG_sol protein was purified using a CaptureSelect C-tag column (ThermoFisher), appearing as a band of c. 55 kDa on Coomassie blue-stained reducing SDS-PAGE and detected by Western blot using serum from Rabipur-immunized mice.

The ELISA was performed as described previously [41]. In brief, plates were coated with RabG_sol protein (100 ng/well in 50 μL PBS). Dilutions of test sera (in triplicate) and a standard curve produced using serial dilutions of an in-house reference serum pool from mice immunized with AdHu5 RabG, were added to the plate. Washing, secondary Ab binding, final washing, and detection were all as previously described [41], with the exception that the secondary Ab used was alkaline-phosphatase–conjugated goat anti-mouse IgG (Sigma-Aldrich). The OD₄₀₅ was quantified using ELx800 or Clariostar plate readers (Bio-Tek and BMG respectively). Results were expressed in arbitrary antibody units (AU), defined using the in-house reference standard, by interpolation of OD₄₀₅ readings on the standard curve. Negative control sera (from mice immunised with AdHu5 expressing ovalbumin [42]) gave no detectable response.

Thermostabilisation

Sugar-matrix thermostabilisation (SMT) was performed essentially as previously described [43]. In brief, adenovirus was formulated in thermostabilisation buffer (0.4M trehalose, 0.1M sucrose). Virus was applied to Whatman Standard-14 paper (GE Healthcare) at a ratio of 50 μL/cm². The virus-loaded paper was then dried for 48 hours in a glovebox (Coy Laboratory Products) at room temperature (24 +/- 2 °C) and controlled humidity (% relative humidity <5%) before being transferred to airtight vials.

Moisture content of the dried product was measured by Karl-Fischer analysis using an 851 Titrando coulometer equipped with 860 Thermoprep oven (Metrohm), in accordance with the manufacturer’s instructions. The mass of water measured per cm² of product was used to estimate percentage moisture content of the sugar glass, based upon the calculated 9.3mg mass of solute present in 50 μL of the thermostabilisation buffer.

As a comparator for the stability of SMT product, virus was formulated in the liquid buffer ‘A438’ (10 mM Histidine, 7.5% sucrose, 35 mM NaCl, 1 mM MgCl₂, 0.1% PS-80, 0.1 mM EDTA, 0.5% (v/v) Ethanol pH 6.6) [44].

Thermostabilised vaccine was reconstituted by the addition of 500 μL/cm² of phosphate buffered saline and vortexing for 2 seconds. The IU titer of recovered virus was measured as described for adenovirus production.

Data analysis

Prism 7 software (Graphpad) was used for data analysis and production of graphs. Statistical analyses are described in full where reported in the Results section and Figure legends. All analyses used log_10-transformed ELISA and VNA data; where negative ELISA results were obtained, they were assigned an arbitrary value of 3 AU (just below the detection limit) to permit log₁₀ transformation and analysis.

Results

ChAdOx2 RabG is a simian adenovirus-vectored rabies vaccine suitable for GMP manufacturing and clinical development

A promising AdC68-vectored rabies vaccine has previously been described [23, 45]. ChAdOx2 RabG differs from the previously reported vaccine in the following respects:

In addition to deletion of the E1 region, the E3 region of the adenovirus has been deleted. The E3 region is non-essential in vitro but encodes protein products involved in subversion of the host immune response and viral persistence [46]. Its deletion is customary in the majority of adenoviruses used in clinical studies and will strengthen confidence in the relevance to the current vaccine of the growing body of literature regarding safety of E1- and E3- deleted adenovirus vectors.
The promoter used is the Intron A-containing HCMV-IE promoter which we have previously reported to enhance immunogenicity relative to a non-intron containing version of the promoter [28].
The promoter includes tetracycline operator elements, resulting in repression of transgene expression in cell lines expressing the tetracycline repressor protein [33]. The use of such ‘tet-repressing’ cell lines in some GMP manufacturing facilities minimises transgene-induced effects upon adenoviral growth, enhancing the predictability of viral growth characteristics and minimising selective pressure for the outgrowth of mutant viruses [33].
The ChAdOx2 vector backbone contains the AdHu5 E4 orf6/7 region in place of the AdC68 equivalents. Adenoviral E4 orf6 protein forms a complex with the E1B 55K protein; the complex has multiple functions in viral growth [47]. Replacement of non-AdHu5 vectors’ E4 orf6 sequence with the AdHu5 equivalent has previously been shown to enhance viral yield in cell lines supplying AdHu5 E1 proteins [30, 48]. We have previously reported that ChAdOx2 virus yields are 2 to 10-fold higher than those with AdC68 [21].

We also explored the possibility of modifying the RabG transgene by codon optimisation for mammalian cells and the incorporation of the human tissue plasminogen activator signal peptide. We have previously observed enhanced levels of transgene expression and immunogenicity upon making similar changes to transgenes in other adenovirus vectored vaccines. In the case of RabG, we observed no beneficial impact of such changes upon transgene expression (Fig 1A and 1B). ChAdOx2 RabG thus uses the unmodified transgene (SP_rab-G_native, henceforth simply ‘G’).

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Fig 1. Choice of G transgene construct and demonstration of genetic stability.

Panel A shows level of cell-surface expression of rabies virus glycoprotein after transient transfection of cells with the SP_rab-G_native and SP_rab-G_opt expression plasmids; legend indicates the combination of plasmid and staining conditions indicated by each line. Histograms are shown to illustrate the derivation of the data represented in Panel B: those shown here are the median results for each plasmid of three transfections with independent DNA preparations. Panel B summarizes G expression levels from the three tested constructs. Each point represents an independent transfection using an independent DNA preparation; line indicates median for each construct. SP_tPA-G_opt and SP_rab-G_opt were tested in separate experiments, each including the SP_rab-G_native as a comparator. Because absolute fluorescence data are not comparable between experiments (fluorescence intensity varies between experiments despite using the same conditions), expression was calculated using MFIs, normalized to the SP_rab-G_native MFI used in each experiment (see Methods), Separate SP_rab-G_native data are thus shown for each comparison. Panel C shows the banding pattern of restriction-enzyme digested ChAdOx2 RabG DNA following the five-passage genetic stability study. Banding patterns were as expected. With Hind III: bands of 21974, 4451, 3349, 2645 base pairs (bp) were seen; a predicted 562bp band was faintly visible but not seen here; a predicted 96bp fragment was, as expected, not visible. With KpnI: bands of 14510, 9370, 3223, 2644, 2329 and 960bp were seen. With SalI: pairs of fragments of 10711 and 9563bp and of 4845 and 4787bp were seen as doublets; fragments of 1656 and 897bp were seen individually; a predicted 474bp band was faintly visible but not seen here; and a predicted 145bp fragment was, as expected, not visible.

https://doi.org/10.1371/journal.pntd.0006870.g001

To ensure suitability for manufacture in non-transgene-repressing cells (which are often used for GMP manufacture but in which production of some adenoviruses is frequently problematic [33]), we assessed virus yield in HEK293A cells (ATCC). In two independent preparations results were as follows:

Yield of 5.0x10¹² VP / 9.0x10¹⁰ IU (P:I ratio = 54) from 5x10⁷ cells
Yield of 1.9x10¹³ VP / 2.1x10¹¹ IU (P:I ratio = 92) from 1.5x10⁸ cells

Yield was thus approximately 1x10⁵ VP per cell, favourably comparable to our experience with other viruses and with yields reported in the literature for other adenoviruses [49].

Following 5 passages in HEK293A cells, CsCl purification and DNA extraction, enzymatic restriction analysis demonstrated a banding pattern consistent with the starting virus sequence (Fig 1C). Although this clearly does not rule out point mutations, it does confirm genetic stability of the vector to the level required for GMP-compliant manufacture for early phase clinical trials.

ChAdOx2 RabG elicits rabies virus neutralizing antibody in mice

To assess the immunogenicity of our adenovirus-vectored vaccine candidates, we immunized mice with one of a range of adenovirus serotypes expressing rabies virus glycoprotein, or one of the licenced IRVs Rabipur (unadjuvanted) and Nobivac Rabies (alum-adjuvanted). For each vaccine, dose-response was assessed. In the case of the adenoviruses, the highest dose tested was 1x10⁸ IU (c. 5x10⁹ VP, dependent upon P:I ratio). This is around 1/10 of a typical human dose of 5x10¹⁰ VP. In the case of the IRVs, the highest dose tested was similarly 1/10 of the manufacturer’s recommended human or dog/cat dose, i.e. >0.25 IU for Rabipur and >0.2 IU for Nobivac: this was the highest dose which could be given within the constraints of a 100 μL intramuscular injection volume.

Vaccines were assessed in two groups in separate experiments. In an initial exploratory experiment, (prior to the availability of the ChAdOx2 vector), we assessed AdHu5, ChAd63, ChAdOx1 and the IRVs. Induction of RabG_sol-binding antibody, as measured by ELISA, was apparent for all adenovirus vectors, regardless of the dose used (though it should be noted that all vaccines were given as a single dose rather than the repeated dosing used for IRVs in humans) (Fig 2A). While responses to the IRVs did not rise beyond the initial timepoint (4 weeks), the adenovirus-vectored vaccines induced antibody responses which gradually rose over 12 weeks (Fig 2B). We previously observed a similar kinetic with AdC68.rabgp in macaques [23]. In this initial experiment, VNA was assessed at week 12 for the highest-dose groups. All vaccines induced high VNA titers (Fig 2C). Interestingly, the relationship between RabG_sol-binding antibody ELISA response and VNA titer was markedly different for adenovirus-vectored vaccines and IRVs (Fig 2D).

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Fig 2. Immunogenicity of first-generation adenovirus-vectored rabies vaccines and IRVs.

In all panels, points indicate results from individual mice; lines in panels A-C indicate/connect group medians. Panel A shows ELISA-measured antibody induction at 4 weeks post-immunization by AdHu5, ChAd63, and ChAdOx1 adenovirus-vectored rabies vaccines as compared to Rabipur and Nobivac IRVs. Panel B shows kinetic of antibody responses induced by ChAdOx1 (1x10⁷ IU dose group) and Rabipur (1/50 recommended human dose group); similar kinetics were seen for adenovirus-vectored vaccines and IRVs respectively, across different doses and vaccine subtypes (S1 Fig). For paired two-tailed t-test comparing week 4 and week 12 responses, p = 0.002 for ChAdOx1; p = 0.58 for Rabipur. Panel C shows VNA titers measured from week 12 samples in the groups receiving the highest doses of each vaccine (1x10⁸ IU i.e. c. 1/10 typical human dose for adenovirus-vectored vaccines, 1/10 human/dog dose for IRVs). Panel D shows relationship between ELISA-measured antibody levels and VNA titers. Filled symbols indicate adenovirus-vaccinated mice; open symbols indicate IRV-vaccinated mice. Solid line indicates fitted linear regression trend-line for adenovirus-vaccinated mice; dashed line indicates fitted regression trend-line for IRV-vaccinated mice. p = 0.008 for identical intercept of the two lines, analysed by ANCOVA (no significant difference in slopes [p = 0.65]).

https://doi.org/10.1371/journal.pntd.0006870.g002

In a subsequent experiment, we compared the immunogenicity of the ChAdOx2 RabG vector with AdC68.010.rabgp. Differences between the ChAdOx2 RabG vector, the previously reported AdC68.rabgp vector [24] and AdC68.010.rabgp are described above; the removal of E3 from AdC68.010.rabgp is not expected to affect immunogenicity. Mice receiving 1x10⁷ IU ChAdOx1 RabG were included as a group for bridging/ comparison with the previous experiment. ELISA and VNA responses induced by ChAdOx2 RabG were significantly higher than those induced by AdC68.010.rabgp (Fig 3). Interestingly the dose-response relationships differed markedly, with similar responses to the two vectors at high dose (1x10⁸ IU), but substantially stronger responses to ChAdOx2 than AdC68.010 at lower doses.

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Fig 3. Immunogenicity of ChAdOx2 and AdC68.010 adenovirus-vectored vaccines.

Panel A shows ELISA-measured antibody induction by ChAdOx2, AdC68.010 and ChAdOx1 adenovirus-vectored rabies vaccines. ChAdOx2 and AdC68.010 vaccines were given at a range of doses, as indicated on the x-axis. Serum was collected four weeks after immunization. Panel B shows VNA results for the same samples shown in panel A. In both panels, points indicate results from individual mice; lines indicate group medians.** indicates p = 0.002, * indicates p = 0.01 for comparisons of ELISA and VNA responses by two-tailed Mann Whitney test.

https://doi.org/10.1371/journal.pntd.0006870.g003

A dose-sparing effect can be achieved by formulation of adenovirus-vectored rabies vaccines with a chemical adjuvant

Chemical adjuvants are widely used with protein and inactivated-virus vaccines, both to induce stronger immune responses and to achieve an antigen-dose-sparing effect. The cost-of-goods of adenovirus-vectored vaccines is likely to be relatively low (as a result of the development of high-yielding scalable manufacturing processes). Nonetheless, any reduction in the adenovirus dose required to achieve a protective response would be valuable as it could enhance the cost-efficacy of population-wide vaccination campaigns in low-income settings. We therefore sought to explore whether responses to our adenovirus-vectored rabies vaccines could be enhanced using a chemical adjuvant. We have previously reported that co-administration of adenovirus-vectored vaccines with certain adjuvants could enhance CD8⁺ T cell responses but, in contrast with others’ observations, we had not seen such effects upon antibody responses to viral vectors in the absence of co-administered protein antigen [42, 50, 51].

Here, we focussed upon squalene oil-in-water adjuvants which, to our knowledge, have not previously been explored in combination with adenovirus-vectored vaccines. In particular, we evaluated Addavax (Invivogen) and SWE (produced at VFL, Lausanne, Switzerland): both of these have a composition similar to MF59 (previously developed by Novartis and now marketed by GSK), which has been given to millions of people in licensed vaccines and has an excellent safety record [52]. We observed a beneficial impact of such squalene emulsion adjuvants upon immunogenicity of our vaccines in each of three independent experiments, together encompassing ChAdOx1, ChAdOx2, Addavax and SWE (Fig 4). The enhancement in ELISA response at doses ≥1x10⁶ IU was small (statistically significant increases of c. 2-fold in antibody titer in two experiments- Fig 4A and 4B; not detectable in one of the three experiments- Fig 4C, right-hand side). A more marked benefit of adjuvant was apparent when very low doses of vaccine (≤5x10⁴ IU) were used (Fig 4C, left-hand side and Fig 4D); remarkably, in the presence of adjuvant, 11/12 mice detectably sero-converted with a dose of 5x10³ IU (approximately 100,000-fold below a typical human adenovirus-vectored vaccine dose). These data suggest that the use of squalene oil-in-water emulsions with this vaccine- or indeed other adenovirus-vectored vaccines- may achieve either a modest increase in immunogenicity at high dose, or perhaps more likely a substantial dose-sparing and hence cost-reducing effect.

Download:

Fig 4. Adjuvantation of ChAdOx1 RabG and ChAdOx2 RabG.

Panel A shows effect upon ELISA-measured antibody responses of addition of Addavax to ChAdOx1 RabG. p = 0.02 for effect of adjuvant by 2-way ANOVA performed upon log₁₀-transformed data. Panel B shows effect upon ELISA-measured antibody responses of addition of Addavax to ChAdOx2 RabG. Data for mice not receiving the adjuvant is as shown for ChAdOx2 in Fig 3A. p = 0.03 for effect of adjuvant by 2-way ANOVA performed upon log₁₀-transformed data. Panel C shows effect upon ELISA-measured antibody responses of addition of SWE to ChAdOx2 RabG. Data shown combines results from three mouse cohorts: cohort A at doses 5x10³, 5x10⁴ and 5x10⁵ IU; cohort B at doses 5x10³ and 5x10⁴ IU; cohort C at doses 1x10⁶ to 1x10⁸ IU. Each experiment included 6 mice at each dose level, hence 12 individual results are shown for doses 5x10³ and 5x10⁴ IU. Stars indicate significant effect of adjuvant at a single dose level, pooling all data (p = 0.05 at dose = 5x10³ IU, p = 0.01 at dose = 5x10⁴ IU, both by two-tailed Mann-Whitney test). 2-way ANOVA was not performed across the full dose-range in view of the lack of adjuvant effect at high dose (i.e. a dose-adjuvant statistical interaction). Panel D shows the data from all mice receiving the 5x10³ and 5x10⁴ IU doses in cohorts A and B. This is the same data shown in panel C, but separating the two cohorts to show consistency of effect across experiments. P = 0.0002 for effect of adjuvant by 3-way ANOVA performed upon log₁₀-transformed data, with P = 0.001 for effect of dose and P = 0.0006 for effect of experiment; in keeping with the consistent trend of effect of adjuvant between doses and experiments, no statistical interaction between parameters was observed. Throughout, points indicate results from individual mice; lines indicate group medians. All results shown are from serum samples collected 4 weeks after immunization. Units are arbitrary.

https://doi.org/10.1371/journal.pntd.0006870.g004

ChAdOx2 RabG can be thermostabilized

We have previously described a simple method for thermostabilization of adenovirus-vectored vaccines by formulating the virus in a disaccharide-based solution and drying it onto a fibrous pad [43, 53]. The materials required for this SMT technique are inexpensive (<USD 0.10 per dose) and the method is suitable for adaptation to GMP production. In-process losses of viral infectivity are close to zero. Other reported approaches to adenoviral thermostabilization include optimisation of liquid buffers [54, 55], lyophilization [56] and spray-drying [57, 58]. To our knowledge, SMT is the only method reported to achieve adenoviral stability at temperatures in excess of 40 °C, such as may be encountered during ambient-temperature distribution in some low-income countries.

The SMT technique has not previously been applied to AdC68 or ChAdOx2 vectors. Here, we tested the ability of the technique to stabilize our ChAdOx2 RabG vector. Water content of the vitrified sugar-glass in the SMT product was 3.7% (median, n = 3, range 3.4–3.8%). We observed excellent stability over 1 month at 45 °C, considerably out-performing virus formulated in the liquid buffer A438 [44]: median log₁₀ IU titer loss was 0.4 in the SMT product (Fig 5). No viable virus remained detectable in the A438. We are not aware of any other liquid buffer formulation which out-performs A438 for the stabilization of species E adenoviruses such as AdC68/ChAdOx2.

Download:

Fig 5. Sugar-matrix thermostabilization of ChAdOx2 RabG.

ChAdOx2 RabG was dried using the SMT method or formulated in A438 liquid buffer before being stored at the indicated temperature for 30 days. IU titer was measured after drying (for SMT formulation) or after storage. Titer loss during storage was calculated by comparison to the titer of virus stored at -80 °C (in liquid formulation). Points indicate independent samples (i.e. separate vials); line indicates median for each condition.

https://doi.org/10.1371/journal.pntd.0006870.g005

Discussion

Global rabies mortality remains unacceptable for a disease which is technically straightforward to prevent- there is no immunological mystery regarding how to achieve protection against rabies. The obstacles to its control are primarily practical and economic. It is clear that increased effort and investment in existing methods of canine rabies control is both necessary and likely to prove productive. Nonetheless, the fact that rabies is concentrated in the least developed parts of the least developed countries poses significant challenges. In some such settings, there may be a role for pre-exposure vaccination of children against rabies, enabled by established infrastructure for the delivery of other childhood immunizations. We have therefore aimed to develop a technology which may render such an approach practical and cost-effective.

Here, we have built upon recent encouraging data with a closely related vaccine [23] to develop an iteratively improved candidate, ChAdOx2 RabG. We have shown that this has suitable genetic stability for GMP manufacture (Fig 1 and Results). Adenovirus vector yield can vary widely for multiple reasons: transgene-specific inhibition of virus replication is a major factor [33]. Here, even without transgene repression, we obtained preliminary indications of yield favourably comparable to other adenoviruses reported in the literature [49]. Scalable adenovirus manufacturing platforms capable of producing virus titers exceeding 1x10¹² VP per mL of culture have been developed [22, 59]; this corresponds to a yield of 20 doses per mL at the typically-used human dose of 5x10¹⁰ VP, or 1000 doses per mL at the dose of 1x10⁹ VP at which AdC68.rabgp was protective in macaques [23]. Such productivity is likely to be compatible with low-cost manufacturing.

In mice, a single dose of ChAdOx2 RabG reliably induced rabies virus neutralizing antibody (Fig 3). Responses to ChAdOx2 RabG compared favourably to those to AdC68.010 rabgp, the latter being closely related to the vector which achieved robust protection in a macaque-rabies virus challenge study [23]. It is unclear why ChAdOx2 RabG appeared to outperform AdC68.010 rabgp at low vector doses; of the differences between the vectors, the one most likely to explain differing immunogenicity (as opposed to differing manufacturing characteristics) is the altered (intron-A containing) promoter used in ChAdOx2 RabG, which has previously been shown to enhance immunogenicity of other adenoviruses [28]. This possibility could be investigated further by in vitro assays of transgene expression from cells transfected with plasmids carrying the two transgene cassettes.

Our hope is that the ability of adenoviruses to achieve reliable, single-dose seroconversion in humans [60, 61] will enable ChAdOx2 RabG to achieve similar results in clinical trials, and hence to offer a single-dose alternative to existing PrEP regimes. The relatively slow-rising kinetic of acquisition of antibody responses after ChAdOx2 RabG immunization (Fig 2B) may be related to ongoing antigen expression from adenovirus-transduced cells. Antigen expression has been shown to remain detectable for a number of weeks after immunization with other adenovirus vectors, and we have previously observed stronger transgene antigen-specific germinal centre reactions five weeks after adenovirus-vector immunization than after protein/adjuvant vaccination [41, 62]. While these phenomena probably contribute to the eventual responses to adenovirus-vectored immunization, the slowness to achieve peak titers may make the candidate less suitable for use in the PEP context, when urgent seroconversion is needed; indeed results were disappointing when AdC68.rabgp was used for PEP in non-human primates [23].

We were interested to observe that the relationship between ELISA-measured antibody and VNA titers differed for adenovirus-vectored and IRV vaccines (Fig 2D). We thus relied upon this ELISA assay only for relative immunogenicity comparisons between different adenovirus-vectored immunizations, not between adenovirus-vectored and IRV vaccines: the ELISA is clearly not a substitute for the VNA assay of functional antibody induction. Importantly, satisfactory VNA activity was achieved by the adenovirus-vectored vaccines (Fig 2C). Nonetheless, this altered relationship suggests that the adenovirus-vectored vaccines may be inducing a considerable amount of antibody which is detected by ELISA (i.e. binds soluble glycoprotein) but which does not neutralize the virus. Secreted soluble G (lacking the transmembrane domain) is known to adopt a conformation differing from that of the pre-fusion native G trimer, notably in that soluble G is predominantly monomeric [63]. The antigen expressed by the adenovirus vectors is the full length (transmembrane-domain-containing) glycoprotein and would therefore be expected to form trimers on the surface of vector-infected cells. The epitopes displayed to B cells by such cells are still likely to differ from those displayed by rabies virions, not least in their spatial arrangement and, perhaps, steric accessibility of membrane-proximal regions. This observation suggests that, despite the good VNA results achieved with the current adenovirus-vectored vaccines, there may yet be scope for improvement in their efficacy, for example by engineering of the expressed antigen to focus the B cell response towards neutralizing epitopes.

We are encouraged by the observation that a dose-sparing effect may be achievable by formulating ChAdOx2 RabG with a squalene oil-in-water emulsion. Such adjuvants have an excellent clinical safety record and there are no longer intellectual property barriers to their use in most countries [52, 64]. Their raw materials cost cents per dose; manufacturing processes are published and sufficiently simple for transfer to academic or small commercial manufacturing organisations [36]. The effect we have observed in mice is modest yet statistically significant and consistent across experiments with different vectors. Assessing whether such an effect is seen in humans would be relatively simple and low in cost, given access to existing GMP-grade adjuvant and adenovirus-vectored vaccine. Attainment of a 5 or 10-fold virus-dose-sparing effect using an inexpensive adjuvant could make a significant difference to the economic case for adoption of this or other adenovirus-based vaccines in low-resource settings.

As well as manufacturing cost, a further obstacle to vaccine delivery in such settings is the maintenance of a cold chain. This is particularly pertinent when considering the deployment of a live (albeit replication-deficient) viral-vectored vaccine. We have therefore sought to ‘build in’ thermostability from the early stages of development of the ChAdOx2 RabG candidate. Here, we demonstrated stabilization of ChAdOx2 resulting in ability to withstand 45 °C for 1 month with modest infectivity loss (0.4 log₁₀-fold). This modest loss would be expected to have minimal effect upon immunogenicity (eg see the shallow dose-response curves in Fig 3A), but does suggest caution regarding longer-term storage at such temperatures. In its current form, SMT is probably adequate to allow adenovirus-vectored vaccines to meet the requirements for distribution via the WHO’s ‘controlled temperature chain’ (CTC) programme (i.e. maintenance of compliance with product specification after a single exposure to at least 40 °C for a minimum of 3 days just prior to administration) and/or use with chromogenic vaccine vial monitors [65, 66]. There remains scope for further improvement of the SMT approach to enable true long-term ambient-temperature storage of such vaccines: we are currently pursuing a number of optimization strategies.

We have recently secured funding for GMP bio-manufacture and Phase I clinical trial of ChAdOx2 RabG in both liquid and SMT formulations. We hope ChAdOx2 RabG may eventually enable low-cost rabies PrEP in low-income settings. It may also have a role in PrEP for travellers to such settings (potentially facilitating clinical development by providing a ‘dual market’ in high-income as well as low/middle-income countries). The SMT technology is applicable to multiple adenovirus-vectored vaccines and other vaccine platforms [43, 53]; we thus hope that, as well as developing a tool with potential for rabies control, this trial will advance a technology with broad utility for the delivery of vaccination to the millions of individuals who live in resource-poor settings.

This work coincides with resurgent interest in the possibility of shortened vaccination regimes using licensed IRVs. The same WHO position paper which recently recommended two-visit PrEP also discussed completed and ongoing trials of single-visit PrEP: this is currently only recommended under circumstances inapplicable to programmatic use in low-income countries (last-minute travel not permitting two visits, prompt access to PEP, and administration of a second dose on return) [9, 67]. Currently available evidence suggests that single-visit IRV regimes achieve VNA >0.5 IU/mL in most (but by no means all) recipients, and robust recall responses upon simulated PEP in all recipients, but that without boosting, VNA in many recipients falls below 0.5 IU/mL within a year [68, 69]. These results suggest scope for improvement, particularly for use in contexts where PEP is not reliably available. We hope that our work, alongside ongoing studies to further characterise the efficacy of single-dose IRV regimes, may assist further movement towards low-cost and practical PrEP regimes suitable for resource-poor contexts.

Supporting information

S1 Fig. Kinetic of antibody responses across all groups shown in Fig 2A.

Panel A shows ELISA-measured antibody induction following immunization by AdHu5, ChAd63, and ChAdOx1 adenovirus-vectored rabies vaccines as compared to Rabipur and Nobivac Rabies IRVs. Individual mice are represented by points, with lines linking the week 4 (left, circles) and week 12 (right, crosses) measurements for each animal. P-values obtained from repeat measures two-way ANOVA were as tabulated in Panel B. For all vaccines, P<0.0001 for effect of matching of repeated measures.

https://doi.org/10.1371/journal.pntd.0006870.s001

(PDF)

Acknowledgments

We are grateful for the assistance of the Jenner Institute Viral Vector Core Facility in the production of adenoviruses, for assistance with ELISA from Kunitaka Yoshida and Gilles Augusto, and for critical review of the manuscript by Adam Ritchie.

References

1. Hotez PJ, Alvarado M, Basanez MG, Bolliger I, Bourne R, Boussinesq M, et al. The global burden of disease study 2010: interpretation and implications for the neglected tropical diseases. PLoS Negl Trop Dis. 2014;8(7):e2865. pmid:25058013
- View Article
- PubMed/NCBI
- Google Scholar
2. Global, regional, and national age–sex specific all-cause and cause-specific mortality for 240 causes of death, 1990–2013: a systematic analysis for the Global Burden of Disease Study 2013. The Lancet. 2015;385(9963):117–71.
- View Article
- Google Scholar
3. Hampson K, Coudeville L, Lembo T, Sambo M, Kieffer A, Attlan M, et al. Estimating the global burden of endemic canine rabies. PLoS Negl Trop Dis. 2015;9(4):e0003709. pmid:25881058
- View Article
- PubMed/NCBI
- Google Scholar
4. GAVI. Vaccine Investment Strategy 2013 [http://www.gavi.org/library/gavi-documents/strategy/final-vis-analysis-2013—rabies/. Accessed 01 July 2018]
5. Fooks AR, Cliquet F, Finke S, Freuling C, Hemachudha T, Mani RS, et al. Rabies. Nature Reviews Disease Primers. 2017;3:17091. pmid:29188797
- View Article
- PubMed/NCBI
- Google Scholar
6. Lembo T, Hampson K, Kaare MT, Ernest E, Knobel D, Kazwala RR, et al. The feasibility of canine rabies elimination in Africa: dispelling doubts with data. PLoS Negl Trop Dis. 2010;4(2):e626. pmid:20186330
- View Article
- PubMed/NCBI
- Google Scholar
7. Cleaveland S. A dog rabies vaccination campaign in rural Africa: impact on the incidence of dog rabies and human dog-bite injuries. Vaccine. 2003;21(17–18):1965–73. pmid:12706685
- View Article
- PubMed/NCBI
- Google Scholar
8. Chulasugandha P, Khawplod P, Havanond P, Wilde H. Cost comparison of rabies pre-exposure vaccination with post-exposure treatment in Thai children. Vaccine. 2006;24(9):1478–82. pmid:16221511
- View Article
- PubMed/NCBI
- Google Scholar
9. Rabies vaccines: WHO position paper—April 2018. WHO Weekly Epidemiological Record. 2018;93(16):201–20.
10. Soentjens P, Andries P, Aerssens A, Tsoumanis A, Ravinetto R, Heuninckx W, et al. Pre-exposure intradermal rabies vaccination: a non-inferiority trial in healthy adults on shortening the vaccination schedule from 28 to 7 days. Clinical Infectious Diseases. 2018.
- View Article
- Google Scholar
11. Milstien JB, Galazka AM, Kartoglu Ü, Zaffran M, World Health Organization. Dept. of Immunization Vaccines and Biologicals. Temperature sensitivity of vaccines. Geneva: World Health Organization; 2006. ix, 62 p. p.
12. PATH. Summary of Stability Data for Licensed Vaccines 2012 [http://www.path.org/publications/files/TS_vaccine_stability_table.pdf. Accessed 01 July 2018]
13. Barth R, Bijok U, Grushkau H, Smerdel J, Vodopija J. Purified chicken embryo cell rabies vaccine for human use. Lancet. 1983;1(8326 Pt 1):700.
- View Article
- Google Scholar
14. Lankester FJ, Wouters P, Czupryna A, Palmer GH, Mzimbiri I, Cleaveland S, et al. Thermotolerance of an inactivated rabies vaccine for dogs. Vaccine. 2016;34(46):5504–11. pmid:27729174
- View Article
- PubMed/NCBI
- Google Scholar
15. Kessels JA, Recuenco S, Navarro-Vela AM, Deray R, Vigilato M, Ertl H, et al. Pre-exposure rabies prophylaxis: a systematic review. Bulletin of the World Health Organization. 2017;95(3):210–9C. pmid:28250534
- View Article
- PubMed/NCBI
- Google Scholar
16. Briggs DJ, Schwenke JR. Longevity of rabies antibody titre in recipients of human diploid cell rabies vaccine. Vaccine. 1992;10(2):125–9. pmid:1539465
- View Article
- PubMed/NCBI
- Google Scholar
17. Mansfield KL, Andrews N, Goharriz H, Goddard T, McElhinney LM, Brown KE, et al. Rabies pre-exposure prophylaxis elicits long-lasting immunity in humans. Vaccine. 2016;34(48):5959–67. pmid:27997343
- View Article
- PubMed/NCBI
- Google Scholar
18. Liu Q, Ertl HC. Preventative childhood vaccination to rabies. Expert opinion on biological therapy. 2012;12(8):1067–75. pmid:22724389
- View Article
- PubMed/NCBI
- Google Scholar
19. Plotkin SA. Vaccines: correlates of vaccine-induced immunity. Clinical Infectious Diseases. 2008;47(3):401–9. pmid:18558875
- View Article
- PubMed/NCBI
- Google Scholar
20. Aubert MF. Practical significance of rabies antibodies in cats and dogs. Rev Sci Tech. 1992;11(3):735–60. pmid:1472723
- View Article
- PubMed/NCBI
- Google Scholar
21. Morris SJS Sarah; Spencer Alexandra J.; Gilbert Sarah C. Simian adenoviruses as vaccine vectors. Future Virology. 2016;11(9):649–59. pmid:29527232
- View Article
- PubMed/NCBI
- Google Scholar
22. Vellinga J, Smith JP, Lipiec A, Majhen D, Lemckert A, van Ooij M, et al. Challenges in manufacturing adenoviral vectors for global vaccine product deployment. Hum Gene Ther. 2014;25(4):318–27. pmid:24593243
- View Article
- PubMed/NCBI
- Google Scholar
23. Xiang ZQ, Greenberg L, Ertl HC, Rupprecht CE. Protection of non-human primates against rabies with an adenovirus recombinant vaccine. Virology. 2014;450–451:243–9. pmid:24503087
- View Article
- PubMed/NCBI
- Google Scholar
24. Xiang Z, Gao G, Reyes-Sandoval A, Cohen CJ, Li Y, Bergelson JM, et al. Novel, chimpanzee serotype 68-based adenoviral vaccine carrier for induction of antibodies to a transgene product. J Virol. 2002;76(6):2667–75. pmid:11861833
- View Article
- PubMed/NCBI
- Google Scholar
25. WHO. Progress and Challenges with Achieving Universal Immunization Coverage: 2016 Estimates of Immunization Coverage 2016 [http://www.who.int/entity/immunization/monitoring_surveillance/who-immuniz.pdf?ua=1. Accessed 01 July 2018]
26. Farina SF, Gao GP, Xiang ZQ, Rux JJ, Burnett RM, Alvira MR, et al. Replication-defective vector based on a chimpanzee adenovirus. J Virol. 2001;75(23):11603–13. pmid:11689642
- View Article
- PubMed/NCBI
- Google Scholar
27. Douglas AD, Williams AR, Illingworth JJ, Kamuyu G, Biswas S, Goodman AL, et al. The blood-stage malaria antigen PfRH5 is susceptible to vaccine-inducible cross-strain neutralizing antibody. Nat Commun. 2011;2:601. pmid:22186897
- View Article
- PubMed/NCBI
- Google Scholar
28. Sridhar S, Reyes-Sandoval A, Draper SJ, Moore AC, Gilbert SC, Gao GP, et al. Single-dose protection against Plasmodium berghei by a simian adenovirus vector using a human cytomegalovirus promoter containing intron A. J Virol. 2008;82(8):3822–33. pmid:18256155
- View Article
- PubMed/NCBI
- Google Scholar
29. Reyes-Sandoval A, Berthoud T, Alder N, Siani L, Gilbert SC, Nicosia A, et al. Prime-boost immunization with adenoviral and modified vaccinia virus Ankara vectors enhances the durability and polyfunctionality of protective malaria CD8+ T-cell responses. InfectImmun. 2010;78(1):145–53.
- View Article
- Google Scholar
30. Dicks MD, Spencer AJ, Edwards NJ, Wadell G, Bojang K, Gilbert SC, et al. A novel chimpanzee adenovirus vector with low human seroprevalence: improved systems for vector derivation and comparative immunogenicity. PLoS One. 2012;7(7):e40385. pmid:22808149
- View Article
- PubMed/NCBI
- Google Scholar
31. Sena-Esteves M, Tebbets JC, Steffens S, Crombleholme T, Flake AW. Optimized large-scale production of high titer lentivirus vector pseudotypes. J Virol Methods. 2004;122(2):131–9. pmid:15542136
- View Article
- PubMed/NCBI
- Google Scholar
32. Geue L, Schares S, Schnick C, Kliemt J, Beckert A, Freuling C, et al. Genetic characterisation of attenuated SAD rabies virus strains used for oral vaccination of wildlife. Vaccine. 2008;26(26):3227–35. pmid:18485548
- View Article
- PubMed/NCBI
- Google Scholar
33. Cottingham MG, Carroll F, Morris SJ, Turner AV, Vaughan AM, Kapulu MC, et al. Preventing spontaneous genetic rearrangements in the transgene cassettes of adenovirus vectors. Biotechnol Bioeng. 2012;109(3):719–28. pmid:22252512
- View Article
- PubMed/NCBI
- Google Scholar
34. Durocher Y, Perret S, Kamen A. High-level and high-throughput recombinant protein production by transient transfection of suspension-growing human 293-EBNA1 cells. Nucleic Acids Res. 2002;30(2):E9. pmid:11788735
- View Article
- PubMed/NCBI
- Google Scholar
35. Tatsis N, Tesema L, Robinson ER, Giles-Davis W, McCoy K, Gao GP, et al. Chimpanzee-origin adenovirus vectors as vaccine carriers. Gene Ther. 2006;13(5):421–9. pmid:16319951
- View Article
- PubMed/NCBI
- Google Scholar
36. Ventura R, Brunner L, Heriyanto B, de Boer O, O’Hara M, Huynh C, et al. Technology transfer of an oil-in-water vaccine-adjuvant for strengthening pandemic influenza preparedness in Indonesia. Vaccine. 2013;31(12):1641–5. pmid:22884665
- View Article
- PubMed/NCBI
- Google Scholar
37. Seligmann EB Jr. Laboratory techniques in rabies: the NIH test for potency. Monogr Ser World Health Organ. 1973(23):279–86. pmid:4219494
- View Article
- PubMed/NCBI
- Google Scholar
38. Cliquet F, Aubert M, Sagne L. Development of a fluorescent antibody virus neutralisation test (FAVN test) for the quantitation of rabies-neutralising antibody. J Immunol Methods. 1998;212(1):79–87. pmid:9671155
- View Article
- PubMed/NCBI
- Google Scholar
39. Louie RE, Dobkin MB, Meyer P, Chin B, Roby RE, Hammar AH, et al. Measurement of rabies antibody: comparison of the mouse neutralization test (MNT) with the rapid fluorescent focus inhibition test (RFFIT). J Biol Stand. 1975;3(4):365–73. pmid:1102548
- View Article
- PubMed/NCBI
- Google Scholar
40. De Genst EJ, Guilliams T, Wellens J, O’Day EM, Waudby CA, Meehan S, et al. Structure and properties of a complex of alpha-synuclein and a single-domain camelid antibody. J Mol Biol. 2010;402(2):326–43. pmid:20620148
- View Article
- PubMed/NCBI
- Google Scholar
41. Wang C, Hart M, Chui C, Ajuogu A, Brian IJ, de Cassan SC, et al. Germinal Center B Cell and T Follicular Helper Cell Responses to Viral Vector and Protein-in-Adjuvant Vaccines. J Immunol. 2016;197(4):1242–51. pmid:27412417
- View Article
- PubMed/NCBI
- Google Scholar
42. de Cassan SC, Forbes EK, Douglas AD, Milicic A, Singh B, Gupta P, et al. The requirement for potent adjuvants to enhance the immunogenicity and protective efficacy of protein vaccines can be overcome by prior immunization with a recombinant adenovirus. J Immunol. 2011;187(5):2602–16. pmid:21813775
- View Article
- PubMed/NCBI
- Google Scholar
43. Dulal P, Wright D, Ashfield R, Hill AV, Charleston B, Warimwe GM. Potency of a thermostabilised chimpanzee adenovirus Rift Valley Fever vaccine in cattle. Vaccine. 2016;34(20):2296–8. pmid:27020712
- View Article
- PubMed/NCBI
- Google Scholar
44. Evans R, Volkin D, Isopi L. Adenovirus formulations. US patent number: US 7456,009 B2, 25 Nov 2008.
45. Xiang Z, Gao G, Reyes-Sandoval A, Cohen CJ, Li Y, Bergelson JM, et al. Novel, Chimpanzee Serotype 68-Based Adenoviral Vaccine Carrier for Induction of Antibodies to a Transgene Product. Journal of Virology. 2002;76(6):2667–75. pmid:11861833
- View Article
- PubMed/NCBI
- Google Scholar
46. Tatsis N, Ertl HC. Adenoviruses as vaccine vectors. Mol Ther. 2004;10(4):616–29. pmid:15451446
- View Article
- PubMed/NCBI
- Google Scholar
47. Rubenwolf S, Schutt H, Nevels M, Wolf H, Dobner T. Structural analysis of the adenovirus type 5 E1B 55-kilodalton-E4orf6 protein complex. J Virol. 1997;71(2):1115–23. pmid:8995632
- View Article
- PubMed/NCBI
- Google Scholar
48. Havenga M, Vogels R, Zuijdgeest D, Radosevic K, Mueller S, Sieuwerts M, et al. Novel replication-incompetent adenoviral B-group vectors: high vector stability and yield in PER.C6 cells. J Gen Virol. 2006;87(Pt 8):2135–43. pmid:16847108
- View Article
- PubMed/NCBI
- Google Scholar
49. Nadeau I, Kamen A. Production of adenovirus vector for gene therapy. Biotechnol Adv. 2003;20(7–8):475–89. pmid:14550017
- View Article
- PubMed/NCBI
- Google Scholar
50. De Cassan S, Douglas A, Draper S, Forbes E, Goodman A, Hill A, et al. Viral vector immunogenic compositions. US Patent Application, Publication number US 2014/0127258 A1, 08 May 2014.
51. Ophorst OJ, Radosevic K, Klap JM, Sijtsma J, Gillissen G, Mintardjo R, et al. Increased immunogenicity of recombinant Ad35-based malaria vaccine through formulation with aluminium phosphate adjuvant. Vaccine. 2007;25(35):6501–10. pmid:17646036
- View Article
- PubMed/NCBI
- Google Scholar
52. O’Hagan DT. MF59 is a safe and potent vaccine adjuvant that enhances protection against influenza virus infection. Expert review of vaccines. 2007;6(5):699–710. pmid:17931151
- View Article
- PubMed/NCBI
- Google Scholar
53. Alcock R, Cottingham MG, Rollier CS, Furze J, De Costa SD, Hanlon M, et al. Long-Term Thermostabilization of Live Poxviral and Adenoviral Vaccine Vectors at Supraphysiological Temperatures in Carbohydrate Glass. Science Translational Medicine. 2010;2(19).
- View Article
- Google Scholar
54. Evans RK, Nawrocki DK, Isopi LA, Williams DM, Casimiro DR, Chin S, et al. Development of stable liquid formulations for adenovirus-based vaccines. J Pharm Sci. 2004;93(10):2458–75. pmid:15349956
- View Article
- PubMed/NCBI
- Google Scholar
55. Jezek J, Buckler A. Stable aqueous formulations of adenovirus vectors. US Patent number: US 9.254,332 B2, 9 Feb 2016.
56. Croyle MA, Cheng X, Wilson JM. Development of formulations that enhance physical stability of viral vectors for gene therapy. Gene Ther. 2001;8(17):1281–90. pmid:11571564
- View Article
- PubMed/NCBI
- Google Scholar
57. LeClair DA, Cranston ED, Xing Z, Thompson MR. Evaluation of excipients for enhanced thermal stabilization of a human type 5 adenoviral vector through spray drying. Int J Pharm. 2016;506(1–2):289–301. pmid:27130366
- View Article
- PubMed/NCBI
- Google Scholar
58. Jin TH, Tsao E, Goudsmit J, Dheenadhayalan V, Sadoff J. Stabilizing formulations for inhalable powders of an adenovirus 35-vectored tuberculosis (TB) vaccine (AERAS-402). Vaccine. 2010;28(27):4369–75. pmid:20444437
- View Article
- PubMed/NCBI
- Google Scholar
59. Luitjens A, Lewis JA. Method for the production of adenoviral vectors. US Patent number: US 10,041,049 B2; 07 Aug 2018.
60. Ewer K, Rampling T, Venkatraman N, Bowyer G, Wright D, Lambe T, et al. A Monovalent Chimpanzee Adenovirus Ebola Vaccine Boosted with MVA. N Engl J Med. 2016;374(17):1635–46. pmid:25629663
- View Article
- PubMed/NCBI
- Google Scholar
61. Payne RO, Silk SE, Elias SC, Miura K, Diouf A, Galaway F, et al. Human vaccination against RH5 induces neutralizing antimalarial antibodies that inhibit RH5 invasion complex interactions. JCI Insight. 2017;2(21).
- View Article
- Google Scholar
62. Geiben-Lynn R, Greenland JR, Frimpong-Boateng K, Letvin NL. Kinetics of recombinant adenovirus type 5, vaccinia virus, modified vaccinia ankara virus, and DNA antigen expression in vivo and the induction of memory T-lymphocyte responses. Clin Vaccine Immunol. 2008;15(4):691–6. pmid:18272665
- View Article
- PubMed/NCBI
- Google Scholar
63. Gaudin Y, Moreira S, Benejean J, Blondel D, Flamand A, Tuffereau C. Soluble ectodomain of rabies virus glycoprotein expressed in eukaryotic cells folds in a monomeric conformation that is antigenically distinct from the native state of the complete, membrane-anchored glycoprotein. J Gen Virol. 1999;80 (Pt 7):1647–56.
- View Article
- Google Scholar
64. Fox CB. Squalene emulsions for parenteral vaccine and drug delivery. Molecules. 2009;14(9):3286–312. pmid:19783926
- View Article
- PubMed/NCBI
- Google Scholar
65. WHO. Controlled Temperature Chain: Strategic Roadmap for Priority Vaccines 2017 [http://www.who.int/immunization/programmes_systems/supply_chain/ctc_strategic_roadmap_priority_vaccines.pdf; accessed 01 July 2018].
66. Kartoglu U, Milstien J. Tools and approaches to ensure quality of vaccines throughout the cold chain. Expert review of vaccines. 2014;13(7):843–54. pmid:24865112
- View Article
- PubMed/NCBI
- Google Scholar
67. WHO Expert Consultation on Rabies, Third Report. Geneva: World Health Organization; 2018.
68. Khawplod P, Jaijaroensup W, Sawangvaree A, Prakongsri S, Wilde H. One clinic visit for pre-exposure rabies vaccination (a preliminary one year study). Vaccine. 2012;30(19):2918–20. pmid:22178519
- View Article
- PubMed/NCBI
- Google Scholar
69. Jonker EFF, Visser LG. Single visit rabies pre-exposure priming induces a robust anamnestic antibody response after simulated post-exposure vaccination: results of a dose-finding study. J Travel Med. 2017;24(5).
- View Article
- Google Scholar

[ref1] 1. Hotez PJ, Alvarado M, Basanez MG, Bolliger I, Bourne R, Boussinesq M, et al. The global burden of disease study 2010: interpretation and implications for the neglected tropical diseases. PLoS Negl Trop Dis. 2014;8(7):e2865. pmid:25058013
View Article
PubMed/NCBI
Google Scholar

[2] View Article

[3] PubMed/NCBI

[4] Google Scholar

[ref2] 2. Global, regional, and national age–sex specific all-cause and cause-specific mortality for 240 causes of death, 1990–2013: a systematic analysis for the Global Burden of Disease Study 2013. The Lancet. 2015;385(9963):117–71.
View Article
Google Scholar

[6] View Article

[7] Google Scholar

[ref3] 3. Hampson K, Coudeville L, Lembo T, Sambo M, Kieffer A, Attlan M, et al. Estimating the global burden of endemic canine rabies. PLoS Negl Trop Dis. 2015;9(4):e0003709. pmid:25881058
View Article
PubMed/NCBI
Google Scholar

[9] View Article

[10] PubMed/NCBI

[11] Google Scholar

[ref4] 4. GAVI. Vaccine Investment Strategy 2013 [http://www.gavi.org/library/gavi-documents/strategy/final-vis-analysis-2013—rabies/. Accessed 01 July 2018]

[ref5] 5. Fooks AR, Cliquet F, Finke S, Freuling C, Hemachudha T, Mani RS, et al. Rabies. Nature Reviews Disease Primers. 2017;3:17091. pmid:29188797
View Article
PubMed/NCBI
Google Scholar

[14] View Article

[15] PubMed/NCBI

[16] Google Scholar

[ref6] 6. Lembo T, Hampson K, Kaare MT, Ernest E, Knobel D, Kazwala RR, et al. The feasibility of canine rabies elimination in Africa: dispelling doubts with data. PLoS Negl Trop Dis. 2010;4(2):e626. pmid:20186330
View Article
PubMed/NCBI
Google Scholar

[18] View Article

[19] PubMed/NCBI

[20] Google Scholar

[ref7] 7. Cleaveland S. A dog rabies vaccination campaign in rural Africa: impact on the incidence of dog rabies and human dog-bite injuries. Vaccine. 2003;21(17–18):1965–73. pmid:12706685
View Article
PubMed/NCBI
Google Scholar

[22] View Article

[23] PubMed/NCBI

[24] Google Scholar

[ref8] 8. Chulasugandha P, Khawplod P, Havanond P, Wilde H. Cost comparison of rabies pre-exposure vaccination with post-exposure treatment in Thai children. Vaccine. 2006;24(9):1478–82. pmid:16221511
View Article
PubMed/NCBI
Google Scholar

[26] View Article

[27] PubMed/NCBI

[28] Google Scholar

[ref9] 9. Rabies vaccines: WHO position paper—April 2018. WHO Weekly Epidemiological Record. 2018;93(16):201–20.

[ref10] 10. Soentjens P, Andries P, Aerssens A, Tsoumanis A, Ravinetto R, Heuninckx W, et al. Pre-exposure intradermal rabies vaccination: a non-inferiority trial in healthy adults on shortening the vaccination schedule from 28 to 7 days. Clinical Infectious Diseases. 2018.
View Article
Google Scholar

[31] View Article

[32] Google Scholar

[ref11] 11. Milstien JB, Galazka AM, Kartoglu Ü, Zaffran M, World Health Organization. Dept. of Immunization Vaccines and Biologicals. Temperature sensitivity of vaccines. Geneva: World Health Organization; 2006. ix, 62 p. p.

[ref12] 12. PATH. Summary of Stability Data for Licensed Vaccines 2012 [http://www.path.org/publications/files/TS_vaccine_stability_table.pdf. Accessed 01 July 2018]

[ref13] 13. Barth R, Bijok U, Grushkau H, Smerdel J, Vodopija J. Purified chicken embryo cell rabies vaccine for human use. Lancet. 1983;1(8326 Pt 1):700.
View Article
Google Scholar

[36] View Article

[37] Google Scholar

[ref14] 14. Lankester FJ, Wouters P, Czupryna A, Palmer GH, Mzimbiri I, Cleaveland S, et al. Thermotolerance of an inactivated rabies vaccine for dogs. Vaccine. 2016;34(46):5504–11. pmid:27729174
View Article
PubMed/NCBI
Google Scholar

[39] View Article

[40] PubMed/NCBI

[41] Google Scholar

[ref15] 15. Kessels JA, Recuenco S, Navarro-Vela AM, Deray R, Vigilato M, Ertl H, et al. Pre-exposure rabies prophylaxis: a systematic review. Bulletin of the World Health Organization. 2017;95(3):210–9C. pmid:28250534
View Article
PubMed/NCBI
Google Scholar

[43] View Article

[44] PubMed/NCBI

[45] Google Scholar

[ref16] 16. Briggs DJ, Schwenke JR. Longevity of rabies antibody titre in recipients of human diploid cell rabies vaccine. Vaccine. 1992;10(2):125–9. pmid:1539465
View Article
PubMed/NCBI
Google Scholar

[47] View Article

[48] PubMed/NCBI

[49] Google Scholar

[ref17] 17. Mansfield KL, Andrews N, Goharriz H, Goddard T, McElhinney LM, Brown KE, et al. Rabies pre-exposure prophylaxis elicits long-lasting immunity in humans. Vaccine. 2016;34(48):5959–67. pmid:27997343
View Article
PubMed/NCBI
Google Scholar

[51] View Article

[52] PubMed/NCBI

[53] Google Scholar

[ref18] 18. Liu Q, Ertl HC. Preventative childhood vaccination to rabies. Expert opinion on biological therapy. 2012;12(8):1067–75. pmid:22724389
View Article
PubMed/NCBI
Google Scholar

[55] View Article

[56] PubMed/NCBI

[57] Google Scholar

[ref19] 19. Plotkin SA. Vaccines: correlates of vaccine-induced immunity. Clinical Infectious Diseases. 2008;47(3):401–9. pmid:18558875
View Article
PubMed/NCBI
Google Scholar

[59] View Article

[60] PubMed/NCBI

[61] Google Scholar

[ref20] 20. Aubert MF. Practical significance of rabies antibodies in cats and dogs. Rev Sci Tech. 1992;11(3):735–60. pmid:1472723
View Article
PubMed/NCBI
Google Scholar

[63] View Article

[64] PubMed/NCBI

[65] Google Scholar

[ref21] 21. Morris SJS Sarah; Spencer Alexandra J.; Gilbert Sarah C. Simian adenoviruses as vaccine vectors. Future Virology. 2016;11(9):649–59. pmid:29527232
View Article
PubMed/NCBI
Google Scholar

[67] View Article

[68] PubMed/NCBI

[69] Google Scholar

[ref22] 22. Vellinga J, Smith JP, Lipiec A, Majhen D, Lemckert A, van Ooij M, et al. Challenges in manufacturing adenoviral vectors for global vaccine product deployment. Hum Gene Ther. 2014;25(4):318–27. pmid:24593243
View Article
PubMed/NCBI
Google Scholar

[71] View Article

[72] PubMed/NCBI

[73] Google Scholar

[ref23] 23. Xiang ZQ, Greenberg L, Ertl HC, Rupprecht CE. Protection of non-human primates against rabies with an adenovirus recombinant vaccine. Virology. 2014;450–451:243–9. pmid:24503087
View Article
PubMed/NCBI
Google Scholar

[75] View Article

[76] PubMed/NCBI

[77] Google Scholar

[ref24] 24. Xiang Z, Gao G, Reyes-Sandoval A, Cohen CJ, Li Y, Bergelson JM, et al. Novel, chimpanzee serotype 68-based adenoviral vaccine carrier for induction of antibodies to a transgene product. J Virol. 2002;76(6):2667–75. pmid:11861833
View Article
PubMed/NCBI
Google Scholar

[79] View Article

[80] PubMed/NCBI

[81] Google Scholar

[ref25] 25. WHO. Progress and Challenges with Achieving Universal Immunization Coverage: 2016 Estimates of Immunization Coverage 2016 [http://www.who.int/entity/immunization/monitoring_surveillance/who-immuniz.pdf?ua=1. Accessed 01 July 2018]

[ref26] 26. Farina SF, Gao GP, Xiang ZQ, Rux JJ, Burnett RM, Alvira MR, et al. Replication-defective vector based on a chimpanzee adenovirus. J Virol. 2001;75(23):11603–13. pmid:11689642
View Article
PubMed/NCBI
Google Scholar

[84] View Article

[85] PubMed/NCBI

[86] Google Scholar

[ref27] 27. Douglas AD, Williams AR, Illingworth JJ, Kamuyu G, Biswas S, Goodman AL, et al. The blood-stage malaria antigen PfRH5 is susceptible to vaccine-inducible cross-strain neutralizing antibody. Nat Commun. 2011;2:601. pmid:22186897
View Article
PubMed/NCBI
Google Scholar

[88] View Article

[89] PubMed/NCBI

[90] Google Scholar

[ref28] 28. Sridhar S, Reyes-Sandoval A, Draper SJ, Moore AC, Gilbert SC, Gao GP, et al. Single-dose protection against Plasmodium berghei by a simian adenovirus vector using a human cytomegalovirus promoter containing intron A. J Virol. 2008;82(8):3822–33. pmid:18256155
View Article
PubMed/NCBI
Google Scholar

[92] View Article

[93] PubMed/NCBI

[94] Google Scholar

[ref29] 29. Reyes-Sandoval A, Berthoud T, Alder N, Siani L, Gilbert SC, Nicosia A, et al. Prime-boost immunization with adenoviral and modified vaccinia virus Ankara vectors enhances the durability and polyfunctionality of protective malaria CD8+ T-cell responses. InfectImmun. 2010;78(1):145–53.
View Article
Google Scholar

[96] View Article

[97] Google Scholar

[ref30] 30. Dicks MD, Spencer AJ, Edwards NJ, Wadell G, Bojang K, Gilbert SC, et al. A novel chimpanzee adenovirus vector with low human seroprevalence: improved systems for vector derivation and comparative immunogenicity. PLoS One. 2012;7(7):e40385. pmid:22808149
View Article
PubMed/NCBI
Google Scholar

[99] View Article

[100] PubMed/NCBI

[101] Google Scholar

[ref31] 31. Sena-Esteves M, Tebbets JC, Steffens S, Crombleholme T, Flake AW. Optimized large-scale production of high titer lentivirus vector pseudotypes. J Virol Methods. 2004;122(2):131–9. pmid:15542136
View Article
PubMed/NCBI
Google Scholar

[103] View Article

[104] PubMed/NCBI

[105] Google Scholar

[ref32] 32. Geue L, Schares S, Schnick C, Kliemt J, Beckert A, Freuling C, et al. Genetic characterisation of attenuated SAD rabies virus strains used for oral vaccination of wildlife. Vaccine. 2008;26(26):3227–35. pmid:18485548
View Article
PubMed/NCBI
Google Scholar

[107] View Article

[108] PubMed/NCBI

[109] Google Scholar

[ref33] 33. Cottingham MG, Carroll F, Morris SJ, Turner AV, Vaughan AM, Kapulu MC, et al. Preventing spontaneous genetic rearrangements in the transgene cassettes of adenovirus vectors. Biotechnol Bioeng. 2012;109(3):719–28. pmid:22252512
View Article
PubMed/NCBI
Google Scholar

[111] View Article

[112] PubMed/NCBI

[113] Google Scholar

[ref34] 34. Durocher Y, Perret S, Kamen A. High-level and high-throughput recombinant protein production by transient transfection of suspension-growing human 293-EBNA1 cells. Nucleic Acids Res. 2002;30(2):E9. pmid:11788735
View Article
PubMed/NCBI
Google Scholar

[115] View Article

[116] PubMed/NCBI

[117] Google Scholar

[ref35] 35. Tatsis N, Tesema L, Robinson ER, Giles-Davis W, McCoy K, Gao GP, et al. Chimpanzee-origin adenovirus vectors as vaccine carriers. Gene Ther. 2006;13(5):421–9. pmid:16319951
View Article
PubMed/NCBI
Google Scholar

[119] View Article

[120] PubMed/NCBI

[121] Google Scholar

[ref36] 36. Ventura R, Brunner L, Heriyanto B, de Boer O, O’Hara M, Huynh C, et al. Technology transfer of an oil-in-water vaccine-adjuvant for strengthening pandemic influenza preparedness in Indonesia. Vaccine. 2013;31(12):1641–5. pmid:22884665
View Article
PubMed/NCBI
Google Scholar

[123] View Article

[124] PubMed/NCBI

[125] Google Scholar

[ref37] 37. Seligmann EB Jr. Laboratory techniques in rabies: the NIH test for potency. Monogr Ser World Health Organ. 1973(23):279–86. pmid:4219494
View Article
PubMed/NCBI
Google Scholar

[127] View Article

[128] PubMed/NCBI

[129] Google Scholar

[ref38] 38. Cliquet F, Aubert M, Sagne L. Development of a fluorescent antibody virus neutralisation test (FAVN test) for the quantitation of rabies-neutralising antibody. J Immunol Methods. 1998;212(1):79–87. pmid:9671155
View Article
PubMed/NCBI
Google Scholar

[131] View Article

[132] PubMed/NCBI

[133] Google Scholar

[ref39] 39. Louie RE, Dobkin MB, Meyer P, Chin B, Roby RE, Hammar AH, et al. Measurement of rabies antibody: comparison of the mouse neutralization test (MNT) with the rapid fluorescent focus inhibition test (RFFIT). J Biol Stand. 1975;3(4):365–73. pmid:1102548
View Article
PubMed/NCBI
Google Scholar

[135] View Article

[136] PubMed/NCBI

[137] Google Scholar

[ref40] 40. De Genst EJ, Guilliams T, Wellens J, O’Day EM, Waudby CA, Meehan S, et al. Structure and properties of a complex of alpha-synuclein and a single-domain camelid antibody. J Mol Biol. 2010;402(2):326–43. pmid:20620148
View Article
PubMed/NCBI
Google Scholar

[139] View Article

[140] PubMed/NCBI

[141] Google Scholar

[ref41] 41. Wang C, Hart M, Chui C, Ajuogu A, Brian IJ, de Cassan SC, et al. Germinal Center B Cell and T Follicular Helper Cell Responses to Viral Vector and Protein-in-Adjuvant Vaccines. J Immunol. 2016;197(4):1242–51. pmid:27412417
View Article
PubMed/NCBI
Google Scholar

[143] View Article

[144] PubMed/NCBI

[145] Google Scholar

[ref42] 42. de Cassan SC, Forbes EK, Douglas AD, Milicic A, Singh B, Gupta P, et al. The requirement for potent adjuvants to enhance the immunogenicity and protective efficacy of protein vaccines can be overcome by prior immunization with a recombinant adenovirus. J Immunol. 2011;187(5):2602–16. pmid:21813775
View Article
PubMed/NCBI
Google Scholar

[147] View Article

[148] PubMed/NCBI

[149] Google Scholar

[ref43] 43. Dulal P, Wright D, Ashfield R, Hill AV, Charleston B, Warimwe GM. Potency of a thermostabilised chimpanzee adenovirus Rift Valley Fever vaccine in cattle. Vaccine. 2016;34(20):2296–8. pmid:27020712
View Article
PubMed/NCBI
Google Scholar

[151] View Article

[152] PubMed/NCBI

[153] Google Scholar

[ref44] 44. Evans R, Volkin D, Isopi L. Adenovirus formulations. US patent number: US 7456,009 B2, 25 Nov 2008.

[ref45] 45. Xiang Z, Gao G, Reyes-Sandoval A, Cohen CJ, Li Y, Bergelson JM, et al. Novel, Chimpanzee Serotype 68-Based Adenoviral Vaccine Carrier for Induction of Antibodies to a Transgene Product. Journal of Virology. 2002;76(6):2667–75. pmid:11861833
View Article
PubMed/NCBI
Google Scholar

[156] View Article

[157] PubMed/NCBI

[158] Google Scholar

[ref46] 46. Tatsis N, Ertl HC. Adenoviruses as vaccine vectors. Mol Ther. 2004;10(4):616–29. pmid:15451446
View Article
PubMed/NCBI
Google Scholar

[160] View Article

[161] PubMed/NCBI

[162] Google Scholar

[ref47] 47. Rubenwolf S, Schutt H, Nevels M, Wolf H, Dobner T. Structural analysis of the adenovirus type 5 E1B 55-kilodalton-E4orf6 protein complex. J Virol. 1997;71(2):1115–23. pmid:8995632
View Article
PubMed/NCBI
Google Scholar

[164] View Article

[165] PubMed/NCBI

[166] Google Scholar

[ref48] 48. Havenga M, Vogels R, Zuijdgeest D, Radosevic K, Mueller S, Sieuwerts M, et al. Novel replication-incompetent adenoviral B-group vectors: high vector stability and yield in PER.C6 cells. J Gen Virol. 2006;87(Pt 8):2135–43. pmid:16847108
View Article
PubMed/NCBI
Google Scholar

[168] View Article

[169] PubMed/NCBI

[170] Google Scholar

[ref49] 49. Nadeau I, Kamen A. Production of adenovirus vector for gene therapy. Biotechnol Adv. 2003;20(7–8):475–89. pmid:14550017
View Article
PubMed/NCBI
Google Scholar

[172] View Article

[173] PubMed/NCBI

[174] Google Scholar

[ref50] 50. De Cassan S, Douglas A, Draper S, Forbes E, Goodman A, Hill A, et al. Viral vector immunogenic compositions. US Patent Application, Publication number US 2014/0127258 A1, 08 May 2014.

[ref51] 51. Ophorst OJ, Radosevic K, Klap JM, Sijtsma J, Gillissen G, Mintardjo R, et al. Increased immunogenicity of recombinant Ad35-based malaria vaccine through formulation with aluminium phosphate adjuvant. Vaccine. 2007;25(35):6501–10. pmid:17646036
View Article
PubMed/NCBI
Google Scholar

[177] View Article

[178] PubMed/NCBI

[179] Google Scholar

[ref52] 52. O’Hagan DT. MF59 is a safe and potent vaccine adjuvant that enhances protection against influenza virus infection. Expert review of vaccines. 2007;6(5):699–710. pmid:17931151
View Article
PubMed/NCBI
Google Scholar

[181] View Article

[182] PubMed/NCBI

[183] Google Scholar

[ref53] 53. Alcock R, Cottingham MG, Rollier CS, Furze J, De Costa SD, Hanlon M, et al. Long-Term Thermostabilization of Live Poxviral and Adenoviral Vaccine Vectors at Supraphysiological Temperatures in Carbohydrate Glass. Science Translational Medicine. 2010;2(19).
View Article
Google Scholar

[185] View Article

[186] Google Scholar

[ref54] 54. Evans RK, Nawrocki DK, Isopi LA, Williams DM, Casimiro DR, Chin S, et al. Development of stable liquid formulations for adenovirus-based vaccines. J Pharm Sci. 2004;93(10):2458–75. pmid:15349956
View Article
PubMed/NCBI
Google Scholar

[188] View Article

[189] PubMed/NCBI

[190] Google Scholar

[ref55] 55. Jezek J, Buckler A. Stable aqueous formulations of adenovirus vectors. US Patent number: US 9.254,332 B2, 9 Feb 2016.

[ref56] 56. Croyle MA, Cheng X, Wilson JM. Development of formulations that enhance physical stability of viral vectors for gene therapy. Gene Ther. 2001;8(17):1281–90. pmid:11571564
View Article
PubMed/NCBI
Google Scholar

[193] View Article

[194] PubMed/NCBI

[195] Google Scholar

[ref57] 57. LeClair DA, Cranston ED, Xing Z, Thompson MR. Evaluation of excipients for enhanced thermal stabilization of a human type 5 adenoviral vector through spray drying. Int J Pharm. 2016;506(1–2):289–301. pmid:27130366
View Article
PubMed/NCBI
Google Scholar

[197] View Article

[198] PubMed/NCBI

[199] Google Scholar

[ref58] 58. Jin TH, Tsao E, Goudsmit J, Dheenadhayalan V, Sadoff J. Stabilizing formulations for inhalable powders of an adenovirus 35-vectored tuberculosis (TB) vaccine (AERAS-402). Vaccine. 2010;28(27):4369–75. pmid:20444437
View Article
PubMed/NCBI
Google Scholar

[201] View Article

[202] PubMed/NCBI

[203] Google Scholar

[ref59] 59. Luitjens A, Lewis JA. Method for the production of adenoviral vectors. US Patent number: US 10,041,049 B2; 07 Aug 2018.

[ref60] 60. Ewer K, Rampling T, Venkatraman N, Bowyer G, Wright D, Lambe T, et al. A Monovalent Chimpanzee Adenovirus Ebola Vaccine Boosted with MVA. N Engl J Med. 2016;374(17):1635–46. pmid:25629663
View Article
PubMed/NCBI
Google Scholar

[206] View Article

[207] PubMed/NCBI

[208] Google Scholar

[ref61] 61. Payne RO, Silk SE, Elias SC, Miura K, Diouf A, Galaway F, et al. Human vaccination against RH5 induces neutralizing antimalarial antibodies that inhibit RH5 invasion complex interactions. JCI Insight. 2017;2(21).
View Article
Google Scholar

[210] View Article

[211] Google Scholar

[ref62] 62. Geiben-Lynn R, Greenland JR, Frimpong-Boateng K, Letvin NL. Kinetics of recombinant adenovirus type 5, vaccinia virus, modified vaccinia ankara virus, and DNA antigen expression in vivo and the induction of memory T-lymphocyte responses. Clin Vaccine Immunol. 2008;15(4):691–6. pmid:18272665
View Article
PubMed/NCBI
Google Scholar

[213] View Article

[214] PubMed/NCBI

[215] Google Scholar

[ref63] 63. Gaudin Y, Moreira S, Benejean J, Blondel D, Flamand A, Tuffereau C. Soluble ectodomain of rabies virus glycoprotein expressed in eukaryotic cells folds in a monomeric conformation that is antigenically distinct from the native state of the complete, membrane-anchored glycoprotein. J Gen Virol. 1999;80 (Pt 7):1647–56.
View Article
Google Scholar

[217] View Article

[218] Google Scholar

[ref64] 64. Fox CB. Squalene emulsions for parenteral vaccine and drug delivery. Molecules. 2009;14(9):3286–312. pmid:19783926
View Article
PubMed/NCBI
Google Scholar

[220] View Article

[221] PubMed/NCBI

[222] Google Scholar

[ref65] 65. WHO. Controlled Temperature Chain: Strategic Roadmap for Priority Vaccines 2017 [http://www.who.int/immunization/programmes_systems/supply_chain/ctc_strategic_roadmap_priority_vaccines.pdf; accessed 01 July 2018].

[ref66] 66. Kartoglu U, Milstien J. Tools and approaches to ensure quality of vaccines throughout the cold chain. Expert review of vaccines. 2014;13(7):843–54. pmid:24865112
View Article
PubMed/NCBI
Google Scholar

[225] View Article

[226] PubMed/NCBI

[227] Google Scholar

[ref67] 67. WHO Expert Consultation on Rabies, Third Report. Geneva: World Health Organization; 2018.

[ref68] 68. Khawplod P, Jaijaroensup W, Sawangvaree A, Prakongsri S, Wilde H. One clinic visit for pre-exposure rabies vaccination (a preliminary one year study). Vaccine. 2012;30(19):2918–20. pmid:22178519
View Article
PubMed/NCBI
Google Scholar

[230] View Article

[231] PubMed/NCBI

[232] Google Scholar

[ref69] 69. Jonker EFF, Visser LG. Single visit rabies pre-exposure priming induces a robust anamnestic antibody response after simulated post-exposure vaccination: results of a dose-finding study. J Travel Med. 2017;24(5).
View Article
Google Scholar

[234] View Article

[235] Google Scholar

Figures

Abstract

Background

Methodology/ Principal findings

Conclusions/ Significance

Author summary

Introduction

Methods

Plasmid and adenovirus production

Assessment of G expression in transiently transfected cells

Ethics statement

Animals, vaccine preparation and immunization

Virus neutralizing antibody (VNA) assay

ELISA

Thermostabilisation

Data analysis

Results

ChAdOx2 RabG is a simian adenovirus-vectored rabies vaccine suitable for GMP manufacturing and clinical development

ChAdOx2 RabG elicits rabies virus neutralizing antibody in mice

A dose-sparing effect can be achieved by formulation of adenovirus-vectored rabies vaccines with a chemical adjuvant

ChAdOx2 RabG can be thermostabilized

Discussion

Supporting information

S1 Fig. Kinetic of antibody responses across all groups shown in Fig 2A.

Acknowledgments

References