Open Access is an initiative that aims to make scientific research freely available to all. To date our community has made over 100 million downloads. It’s based on principles of collaboration, unobstructed discovery, and, most importantly, scientific progression. As PhD students, we found it difficult to access the research we needed, so we decided to create a new Open Access publisher that levels the playing field for scientists across the world. How? By making research easy to access, and puts the academic needs of the researchers before the business interests of publishers.
We are a community of more than 103,000 authors and editors from 3,291 institutions spanning 160 countries, including Nobel Prize winners and some of the world’s most-cited researchers. Publishing on IntechOpen allows authors to earn citations and find new collaborators, meaning more people see your work not only from your own field of study, but from other related fields too.
To purchase hard copies of this book, please contact the representative in India:
CBS Publishers & Distributors Pvt. Ltd.
www.cbspd.com
|
customercare@cbspd.com
The recombinant vaccinia–rabies vaccine, now known as Raboral®, has been widely used in Europe and North America to control/eliminate rabies in the principal wildlife vectors, and thus prevent human transmission. The origins of this vaccine are sometimes forgotten, although the formulation has not changed substantially in almost four decades. This groundbreaking vaccine was assembled by a team at a very young (at that time) genetic engineering company, Transgène, in Strasbourg, France. The joint leaders of the rabies vaccine team reflect, 36 years later, on the trials and tribulations that went hand in hand with the construction of the vaccine.
Division of Infection Medicine, University of Edinburgh Medical School, UK
Marie Paule Kieny*
Institut National de la Santé et de la Recherche Médicale (INSERM), France
*Address all correspondence to: richard.lathe@ed.ac.uk and marie-paule.kieny@inserm.fr
1. Introduction
Rabies is a devastating disease that is inexorably fatal, unless – as Louis Pasteur demonstrated [1] – it is rapidly treated by immunization. Even so, the vaccination regimen that Pasteur recommended is punishing, and brought its own risks of hyperinflammation. In the mid-20th century rabies was widespread among wildlife (principally foxes in Europe and raccoons in North America), and even in developed countries the bite of an infected animal was a death warrant if not immediately and intensively treated.
With the advent of genetic engineering (GE) technologies in the 1980s, the renowned Institut Mérieux in Lyon, France – established in 1897 by Marcel Mérieux, one of Louis Pasteur’s assistants – brought a new task to the newly established GE company Transgène in Strasbourg: make a rabies vaccine. This chore was handed down to ourselves, two young postdoctoral scientists in the company.
Transgène, founded by Pierre Chambon and Philippe Kourilsky in 1979/1980, although being allocated half a floor in Pierre Chambon’s institute at the University of Strasbourg (Figure 1), was not quite ready: all available resources, at the very beginning, were allocated to setting up all the essential GE ingredients – oligonucleotide synthesis, DNA sequencing (done manually on thin polyacrylamide gels using radiophosphorus), basic sequence analysis, simple expression vectors in bacteria, yeast, and mammalian cells, even making our own restriction enzymes. Other GE companies were well ahead, and had cloned and expressed key molecules such as growth hormone, interferons, and hepatitis B surface antigen. We were both over-optimistic and underweight.
Figure 1.
Transgène and the Wistar Institute. (Left) The Laboratoire de Génétique Moléculaire des Eukaryotes (LGME) under Pierre Chambon at the Faculty of Medicine, University of Strasbourg (founded 1538), France, where Transgène was housed (6th floor) during the development of the rabies vaccine (1980s). The building was constructed in 1964 and was demolished in 2011 {https://www.archi-wiki.org/Adresse:Facult%C3%A9_de_m%C3%A9decine_(Strasbourg)}. (Right) Wistar Institute of Anatomy, Philadelphia, USA. The Wistar was founded in 1892, and the Wistar Institute Building was opened in 1894. Image courtesy Jeffrey M. Vinocur 2006. Images are reproduced under Wikipedia Creative Commons Attribution-ShareAlike License.
But we set to. The Scientific Director of Transgène, Jean-Pierre Lecocq, established a collaboration with researchers at the Wistar Institute (Figure 1) under Hilary Koprowski (Philadelphia) who had obtained, for the first time, a cDNA copy of rabies virus glycoprotein at the end of 1981 [2, 3] – the key antigenic determinant of this virus. Beginning in early 1982, we expressed the cDNA in E. coli, B. subtilis, yeast, mammalian cells (reviewed in [4]). The pressure was on, we worked 7 days a week, so did our key technical staff; we were fuelled by Martha Argerich interpreting J.S. Bach on the tape player until long after the sun set over the Vosges hills (Box 1). The extracts were sent to the rabies expert in Philadelphia, Tadeusz Wiktor. He systematically vaccinated lab animals (mostly mice and hamsters) with the extracts, and then challenged them with street rabies virus. None survived.
It is singularly appropriate that the recombinant rabies vaccine should have been developed in Strasbourg, the central town of the province of Alsace, France. Louis Pasteur, famed for the first rabies vaccine, was born in the Jura hills (the southern extension of the Vosges – the hills of Alsace) and was Professor of Chemistry at Strasbourg University (formerly known as the Université Louis Pasteur) from 1849 to 1854, where he married Marie (also known as Louise) Laurent (the daughter of the Rector of the University), who for many years acted as his scientific assistant. The first patient to be treated against rabies, Joseph Meister (9 years old), traveled from Alsace to Pasteur’s laboratory (then in Paris) for treatment [1]. The first fox to be inoculated with the new recombinant vaccine was in Malzéville, over the Vosges hills just 100 km from Strasbourg.
We were dismayed, and ready to give up. Two developments changed everything. First, at a chance meeting with Peter Curtis (Wistar) he advised that there was a possible problem with his cDNA sequence – there appeared to be a mutation. Second, we were impressed by the growing achievements of recombinant vaccinia virus (the basis of the smallpox vaccine), inspired by Enzo Paoletti in 1983 [5], in eliciting immunity beyond what could be obtained with bacteria, yeasts, or even mammalian cells.
The mutation in the rabies glycoprotein cDNA was indeed suspect – a Pro to Leu mutation near the beginning of the mature protein sequence at a position that (to our minds) seemed to resemble known mutations at the beginning of the oncoprotein RAS (Gly to Asp, or Gly to Val) that entirely transform the structure and activity of the protein. The first thing we did was to correct the mutation. Something we had never done before, and this took months. In the key Nature paper the reader will see that, because our techniques were challenged, we took advantage of an artificial site for Dam methylase (that governs mismatch repair in E. coli) site to tip the balance in our favor (unheard of today) (Figure 2A). But it worked! We wonder how many rabies glycoprotein sequences circulating in the GE world today bear that same signature alteration.
Figure 2.
Construction and Activity of the Vaccinia-Based Recombinant Rabies Virus Raboral® VR-G. The recombinant was variously known as VR-G, VVTGgRAB-26D3, and VR-Gpro8. (A) Correction of a mutation in the N-terminus of the rabies glycoprotein coding sequence. Panel adapted, with permission, from [6]. (B) Protection from rabies using the live recombinant vaccine [6]. Mice were inoculated (intradermal) with 5 × 105 PFU of VR-G or wild-type vaccinia, and challenged on day 15 by intracerebral inoculation of CDC culture-adapted street rabies virus (2400 LD50 units). All vaccinated animals survived. Panel adapted, with permission, from [6]. (C). Protection of rabbits and mice: inoculation was with 2 × 108 PFU (intradermal) or 5 × 107 (footpad) of VR-G; intracerebral challenge at day 14 was with 2400 (mice) or 24 000 (rabbits) mouse LD50 units of MD5951 street rabies virus. Panel adapted, with permission, from [7]. (D) Protection using inactivated VR-G. Vaccines were inactivated with β-propionolactone before intraperitoneal administration into mice. Challenge at day 14 was with 240 LD50 units of MD5951. Panel adapted, with permission, from [7].
The second thing we did was to get vaccinia up and running as a vehicle. We got into collaboration with Robert Drillien and Danièle Spehner at the Institut de Virologie on the same campus, and they supplied us with a microgram of vaccinia virus DNA. The key thymidine kinase gene – required for recombinational exchange with the vaccinia genome – had already been cloned by Robert, but we lacked a promoter to drive expression. We wanted the 7.5 K gene promoter, that had been worked up by researchers in the USA, but starting with only 1 microgram of DNA (the vaccinia genome is ~190 kb in length), given the state of the technology, cloning was near to impossible. In the event we turned to calculations of insert size, vector size, and absolute concentrations based on the physicochemistry of ligation [8, 9], and brewed up an optimum ligase mix. Only four clones were obtained. Two were 7.5 K in one orientation, and two were the same promoter in the other orientation! Were we lucky? No, in retrospect we would have got nothing had we not used the mathematics of the ligation reaction to get what we needed.
From there it moved quite rapidly. Ligate the promoter to the modified rabies G coding sequence, insert the construct into the vaccinia TK gene on a plasmid – then transfect the recombinant (TK-negative) plasmid into vaccinia virus-infected cells, and select chemically using bromodeoxyuridine (that kills TK-positive viruses). And we had our first vaccinia–rabies recombinant (‘26D3’).
This sped off to Tad Wiktor in Philadelphia. We waited what seems like an eternity, but he reported quickly back with his preliminary results: ‘this is the best rabies vaccine I have ever seen’ – it protected mice against severe rabies challenge (Figure 2B–D) better than any other rabies vaccine. And so it turned out – first published in September 1984 ([6, 7]; reviewed in [10, 11, 12]).
What lessons can be drawn, if any? Our first thought is that we worked as a team, there was no academic infighting, no bickering about authorships that is too common today, and we all worked day and night to see the project through. Even technical staff were there late in the evening and at weekends. Second, collaboration is essential: we could not have done this project without the participation of scientists both near (Robert Drillien and Danièle Spehner) and far {Tadeusz Wiktor (Figure 3A), Peter Curtis, and Hilary Koprowski}. Third, we wonder whether Martha Argerich and J.S. Bach played a role. In this day of P values, we would need to run the entire project again with a different musical background.
Figure 3.
Pioneering Rabies Vaccination. (A) Tadeusz J. Wiktor (1920–1985), rabies expert, Wistar Institute, who first tested the recombinant for efficacy. Photo courtesy of the Wistar Institute. (B) Loading vaccine baits into a helicopter during the first wildlife vaccination campaigns (Belgium, ca 1988; image collection M.P.K.).
The vaccine was originally envisaged for human use, and steps were taken in this direction in collaboration with the Institut Mérieux. However, there was reluctance to introduce a new vaccinia-based vaccine for human use because smallpox, the original target of vaccinia, had recently been declared eradicated by the World Health Organization (WHO) [13]. A committee of international experts including WHO representatives, who met in Bethesda, MD, in November 1984, did not envisage early human use [14]. However, because rabies is transmitted to humans principally from domestic dogs – that themselves acquire the infection from foxes (in Europe), and from raccoons and coyotes (in North America) – the next step was to try the new vaccine out for efficacy in animals. With support from Philippe Desmettre at the Institut Mérieux, Transgène was in touch with Pierre-Paul Pastoret in Belgium and colleagues at the French Ministry of Agriculture Rabies Research Station in Malzéville close to Nancy, and this was soon followed by the demonstration that oral administration of the vaccine (108 pfu) to foxes (Figure 4) gave complete protection against lethal challenge, and almost complete protection following administration in home-made bait [15], quickly followed by oral protection of raccoons in the USA by colleagues at the Wistar Institute [16].
Figure 4.
Experimental vaccination of foxes, Malzéville, France, ca 1986 (image collection M.P.K.).
This was expanded to small-trials followed by large-scale campaigns to eradicate sylvatic rabies in Europe and North America by dropping baits (e.g., chicken heads or artificial baits) seeded with live recombinant virus from helicopters (Figure 3B) according to a carefully planned routine (taking in mind the number of wildlife species per square kilometer, and the transmission factor R – what percentage of animals do we need to vaccinate to block propagation? – of current interest given the COVID pandemic). It worked. The first trials (Figure 5) demonstrated wide uptake by foxes and downturn of rabies cases. Using this vaccine, rabies has now been widely eliminated in many European countries; substantial reductions in rates of rabies in wildlife have been achieved in several areas of Eastern USA and Canada (Table 1) where active vaccination campaigns are ongoing (http://www.raboral.com/about-rabies/raboral-v-rg). Over 250 million doses of Raboral® have been distributed worldwide [19]. Although highly successful in Europe [18], campaigns in the USA and Canada are constrained because of rabies re-emergence through long-distance movements of carrier species such as arctic foxes [19].
Figure 5.
First wildlife vaccination campaigns. Baits containing VRG were prepared from fish oil and protein. (A) Test areas in Belgium, 1987–1988. Vaccines were distributed at 15–50 baits per km2; uptake ranged from 27% at day 4 to 94% at day 223 (image collection M.P.K.). (B) Larger-scale field trial in a 2200 km2 area of Belgium; distribution was at 15 baits per km2; the area was vaccinationed three times (1990–1991). Baits contained a tetracycline biomarker, and uptake determined from the presence of tetracycline (Tet; UV fluorescence in jaw) was 81% after the third phase. The single rabid fox detected after the campaign, at the periphery of the baited area, was Tet-negative. Image adapted, with permission, from [17].
In many cases Raboral® was used in conjunction with conventional attenuated viruses, although Raboral® is the only vaccine licensed for use in the USA (http://www.raboral.com/about-rabies/raboral-v-rg). Data: key reviews are by Freuling et al. [18] and Maki et al. [19].
The vaccina–rabies recombinant has never been approved for human use, even though vaccinia virus has been used widely across the world in our populations to eradicate smallpox, and the vaccinia–rabies recombinant is very much attenuated compared to standard strains of vaccinia. Notwithstanding, intense efforts have been made to develop vaccinia as an anticancer agent for direct prophylactic or curative use in human [20, 21, 22, 23], but for recombinants expressing viral antigens few clinical trials have been carried out (with some exceptions; e.g., [24]). Efforts in the 1990s were invested into the development of viral vectors based on vaccinia derivatives such as modified virus Ankara (MVA) [25], or fowlpox or canarypox [26]. More recently., high levels of protective antibodies have been obtained against SARS coronavirus using vaccinia recombinants in experimental animals (e.g., [27, 28, 29]), and, given the threat of COVID-19, MVA-based recombinants are being actively explored in California [30] and Germany (https://www.vfa.de/de/englische-inhalte/vaccines-to-protect-against-covid-19) as potential vaccines against SARS-COV-2, the etiologic agent of COVID-19.
One potential way to circumvent safety concerns may be to employ inactivated recombinant vaccinia virions that display viral antigens at their surface: very substantial levels of protection were observed with chemically inactivated recombinant vaccinia–rabies virus [7], and this might afford an entry route for new human vaccines based on vaccinia – perhaps even at some stage including Raboral® or further attenuated derivatives, given that rabies in human remains a major concern in several regions such as India [31].
We acknowledge with appreciation the pivotal contributions of all our colleagues who made this work possible, notably Peter Curtis, Bill Wunner, Algis Anilionis, and Hilary Koprowski who provided the first rabies glycoprotein cDNA, Robert Drillien and Danièle Spehner for key help with vaccinia, Doris Schmitt and Karin Dott for superb technical assistance, all the teams at Transgène who helped with DNA sequencing, oligonucleotide synthesis, microbial gene expression systems, Tadeusz Wiktor for performing all the in vivo rabies challenge studies in Philadelphia, Pierre-Paul Pastoret in Belgium and Philippe Desmettre in France (and Charles Rupprecht and many others at the Wistar Institute) for enthusiastically speeding the transition to wildlife, the Institut Mérieux for sponsoring this work, and Jean-Pierre Lecocq, Philippe Kourilsky, and Pierre Chambon for supporting the project since inception.
The views expressed herein are solely those of the authors and do not reflect the views of the WHO, Transgène SA, the INSERM, or of any other institution with which the authors are or have been associated.
References
1.Nicolle J (1961) Louis Pasteur: A Master of Scientific Enquiry. Hutchinson, London
2.Anilionis A, Wunner WH, Curtis PJ (1981) Structure of the glycoprotein gene in rabies virus. Nature 294:275-278
3.Anilionis A, Wunner WH, Curtis PJ (1982) Amino acid sequence of the rabies virus glycoprotein deduced from its cloned gene. Comp Immunol Microbiol Infect Dis 5:27-32
4.Lecocq JP, Kieny MP, Lemoine Y, Drillien R, Wiktor T, Koprowski H, Lathe R (1985) New rabies vaccines: recombinant DNA approaches. In: Koprowski H, Plotkin SA (eds) World's Debt to Pasteur. Alan R. Liss, New York, pp. 259-271
5.Panicali D, Davis SW, Weinberg RL, Paoletti E (1983) Construction of live vaccines by using genetically engineered poxviruses: biological activity of recombinant vaccinia virus expressing influenza virus hemagglutinin. Proc Natl Acad Sci U S A 80:5364-5368
7.Wiktor TJ, MacFarlan RI, Reagan KJ, Dietzschold B, Curtis PJ, Wunner WH, Kieny MP, Lathe R, Lecocq JP, Mackett M, et al. (1984) Protection from rabies by a vaccinia virus recombinant containing the rabies virus glycoprotein gene. Proc Natl Acad Sci U S A 81:7194-7198
8.Dugaiczyk A, Boyer HW, Goodman HM (1975) Ligation of EcoRI endonuclease-generated DNA fragments into linear and circular structures. J Mol Biol 96:171-184
9.Shore D, Langowski J, Baldwin RL (1981) DNA flexibility studied by covalent closure of short fragments into circles. Proc Natl Acad Sci U S A 78:4833-4837
10.Lathe R, Kieny MP, Lecocq JP, Drillien R, Wiktor T, Koprowski H (1985) Immunization against rabies using a vaccinia-rabies recombinant virus expressing the surface glycoprotein. In: Lerner RA, Chanock RM, Brown F (eds) Vaccines 85. Cold Spring Harbor Laboratory, New York, pp. 157-162
11.Kieny MP, Desmettre P, Soulebot JP, Lathe R (1987) Rabies vaccine: traditional and novel approaches. Prog Vet Microbiol Immunol 3:73-111
12.Wiktor TJ, Kieny MP, Lathe R (1988) New generation of rabies vaccine: vaccinia-rabies glycoprotein recombinant virus. In: Kurstak E, Marusyk RG, Murphy FA, Van Regenmortel MHV (eds) Applied Virology Research. Plenum Press, New York, pp. 69-90
13.Fenner F, Henderson DA, Arita I, Jezek Z, Ladnyi ID (1988) Smallpox and Its Eradication. World Health Organization, Geneva
14.Ada GL, Brown F, et al. (1985) Recombinant vaccinia viruses as live virus vectors for vaccine antigens: memorandum from a WHO/USPHS/NIBSC meeting. Bull World Health Organ 63:471-477
15.Blancou J, Kieny MP, Lathe R, Lecocq JP, Pastoret PP, Soulebot JP, Desmettre P (1986) Oral vaccination of the fox against rabies using a live recombinant vaccinia virus. Nature 322:373-375
16.Rupprecht CE, Wiktor TJ, Johnston DH, Hamir AN, Dietzschold B, Wunner WH, Glickman LT, Koprowski H (1986) Oral immunization and protection of raccoons (Procyon lotor) with a vaccinia-rabies glycoprotein recombinant virus vaccine. Proc Natl Acad Sci U S A 83:7947-7950
18.Freuling CM, Hampson K, Selhorst T, Schröder R, Meslin FX, Mettenleiter TC, Müller T (2013) The elimination of fox rabies from Europe: determinants of success and lessons for the future. Philos Trans R Soc Lond B Biol Sci 368:20120142
19.Maki J, Guiot AL, Aubert M, Brochier B, Cliquet F, Hanlon CA, King R, Oertli EH, Rupprecht CE, Schumacher C, Slate D, Yakobson B, Wohlers A, Lankau EW (2017) Oral vaccination of wildlife using a vaccinia-rabies-glycoprotein recombinant virus vaccine (RABORAL V-RG®): a global review. Vet Res 48:57
20.Lathe R, Kieny MP, Gerlinger P, Clertant P, Guizani I, Cuzin F, Chambon P (1987) Tumour prevention and rejection with recombinant vaccinia. Nature 326:878-880
21.Hareuveni M, Gautier C, Kieny MP, Wreschner D, Chambon P, Lathe R (1990) Vaccination against tumor cells expressing breast cancer epithelial tumor antigen. Proc Natl Acad Sci U S A 87:9498-9502
22.Meneguzzi G, Cerni C, Kieny MP, Lathe R (1991) Immunization against human papillomavirus type 16 tumor cells with recombinant vaccinia viruses expressing E6 and E7. Virology 181:62-69
23.Quoix E, Lena H, Losonczy G, Forget F, Chouaid C, Papai Z, Gervais R, Ottensmeier C, Szczesna A, Kazarnowicz A, Beck JT, Westeel V, Felip E, Debieuvre D, Madroszyk A, Adam J, Lacoste G, Tavernaro A, Bastien B, Halluard C, Palanché T, Limacher JM (2016) TG4010 immunotherapy and first-line chemotherapy for advanced non-small-cell lung cancer (TIME): results from the phase 2b part of a randomised, double-blind, placebo-controlled, phase 2b/3 trial. Lancet Oncol 17:212-223
24.Pitisuttithum P, Rerks-Ngarm S, Bussaratid V, Dhitavat J, Maekanantawat W, Pungpak S, Suntharasamai P, Vanijanonta S, Nitayapan S, Kaewkungwal J, Benenson M, Morgan P, O'Connell RJ, Berenberg J, Gurunathan S, Francis DP, Paris R, Chiu J, Stablein D, Michael NL, Excler JL, Robb ML, Kim JH (2011) Safety and reactogenicity of canarypox ALVAC-HIV (vCP1521) and HIV-1 gp120 AIDSVAX B/E vaccination in an efficacy trial in Thailand. PLoS One 6:e27837
25.Mayr A (1999) Historical review of smallpox, the eradication of smallpox and the attenuated smallpox MVA vaccine (article in German). Berl Munch Tierarztl Wochenschr 112:322-328
26.Taylor J, Tartaglia J, Rivière M, Duret C, Languet B, Chappuis G, Paoletti E (1994) Applications of canarypox (ALVAC) vectors in human and veterinary vaccination. Dev Biol Stand 82:131-135
27.Bisht H, Roberts A, Vogel L, Bukreyev A, Collins PL, Murphy BR, Subbarao K, Moss B (2004) Severe acute respiratory syndrome coronavirus spike protein expressed by attenuated vaccinia virus protectively immunizes mice. Proc Natl Acad Sci U S A 101:6641-6646
28.Chen Z, Zhang L, Qin C, Ba L, Yi CE, Zhang F, Wei Q, He T, Yu W, Yu J, Gao H, Tu X, Gettie A, Farzan M, Yuen KY, Ho DD (2005) Recombinant modified vaccinia virus Ankara expressing the spike glycoprotein of severe acute respiratory syndrome coronavirus induces protective neutralizing antibodies primarily targeting the receptor binding region. J Virol 79:2678-2688
29.Ishii K, Hasegawa H, Nagata N, Mizutani T, Morikawa S, Suzuki T, Taguchi F, Tashiro M, Takemori T, Miyamura T, Tsunetsugu-Yokota Y (2006) Induction of protective immunity against severe acute respiratory syndrome coronavirus (SARS-CoV) infection using highly attenuated recombinant vaccinia virus DIs. Virology 351:368-380
30.Chiuppesi F, Salazar MD, Contreras H, Nguyen VH, Martinez J, Park Y, Nguyen J, Kha M, Iniguez A, Zhou Q, Kaltcheva T, Levytskyy R, Ebelt ND, Kang TH, Wu X, Rogers TF, Manuel ER, Shostak Y, Diamond DJ, Wussow F (2020) Development of a multi-antigenic SARS-CoV-2 vaccine candidate using a synthetic poxvirus platform. Nat Commun 11:6121
31.Chatterjee P (2009) India's ongoing war against rabies. Bull World Health Organ 87:890-891
Written By
Richard Lathe and Marie Paule Kieny
Submitted: 03 January 2021Reviewed: 19 March 2021Published: 26 April 2021
Open access peer-reviewed chapter
