key: cord-1006178-z5iimjd1 authors: Warimwe, George M.; Francis, Michael J.; Bowden, Thomas A.; Thumbi, Samuel M.; Charleston, Bryan title: Using cross-species vaccination approaches to counter emerging infectious diseases date: 2021-06-17 journal: Nat Rev Immunol DOI: 10.1038/s41577-021-00567-2 sha: 570ce5450351576b89f436c64864e778556700fd doc_id: 1006178 cord_uid: z5iimjd1 Since the initial use of vaccination in the eighteenth century, our understanding of human and animal immunology has greatly advanced and a wide range of vaccine technologies and delivery systems have been developed. The COVID-19 pandemic response leveraged these innovations to enable rapid development of candidate vaccines within weeks of the viral genetic sequence being made available. The development of vaccines to tackle emerging infectious diseases is a priority for the World Health Organization and other global entities. More than 70% of emerging infectious diseases are acquired from animals, with some causing illness and death in both humans and the respective animal host. Yet the study of critical host–pathogen interactions and the underlying immune mechanisms to inform the development of vaccines for their control is traditionally done in medical and veterinary immunology ‘silos’. In this Perspective, we highlight a ‘One Health vaccinology’ approach and discuss some key areas of synergy in human and veterinary vaccinology that could be exploited to accelerate the development of effective vaccines against these shared health threats. Vaccination to control infectious diseases has had a major direct impact on human health and welfare and has also secured food supply by improving animal health and controlling zoonotic diseases. For instance, childhood vaccination prevents more than 2 million deaths every year, with vaccination coverage being a strong indicator of the incidence of vaccine-preventable diseases in humans (for example, measles, yellow fever and polio) 1 . Similarly, veterinary vaccination against endemic diseases increases survival and productivity in food-producing animals such as cattle and poultry, with net gains in disposable household income and access to protein-rich animal source foods improving human nutrition [2] [3] [4] [5] . However, despite these and many other examples of vaccine impact, very little interaction occurs between human and animal vaccine developers and policymakers. The development pipelines for human and animal vaccines are similar processes, including biological and scientific parallels in vaccine design and evaluation, as well adjuvant combinations to inform 'go' or 'no-go' decisions with regard to subsequent development of promising vaccine candidates (Fig. 1) . Most human infectious diseases have an animal origin, with more than 70% of emerging infectious diseases that affect humans initially crossing over from animals 8 . Generating wider knowledge of how pathogens behave in animals can give indications of how to develop control strategies for human diseases, and vice versa. 'One Health vaccinology' , a concept in which synergies in human and veterinary immunology are identified and exploited for vaccine development, could transform our ability to control such emerging infectious diseases. Due to similarities in host-pathogen interactions, the natural animal hosts of a zoonotic infection may be the most appropriate model to study the disease and evaluate vaccine performance 9 . This could result in a scenario where a cross-species vaccine is feasible, such as Louis Pasteur's live attenuated rabies vaccine that was protective in dogs and humans 10 although different products are now used for rabies vaccination in humans and dogs 11 -or our own group's Rift Valley fever vaccine, which is in co-development for use in humans and multiple livestock species 12 . Effective control of zoonotic diseases may require vaccination within reservoir animal hosts to break transmission to humans, and in humans to prevent disease 13 , making One Health vaccinology relevant for disease control policy. This strategy is already used for prevention and elimination of rabies, where mass dog vaccination remains the most cost-effective strategy for breaking disease transmission to humans 14, 15 . However, due to the difficulty in predicting spillover events for new infections from animals to humans 16 , implementing a cross-species vaccination programme may only be feasible where the domestic animal reservoir of human infection is known (see Table 1 for some examples), but a cost-benefit analysis would be necessary to inform implementation. For non-zoonotic illnesses, the natural course of infection and acquisition of immunity against closely related pathogens may be similar between animals and humans, allowing accelerated development as common bottlenecks that influence the success of vaccine development programmes 6 (Fig. 1) . However, there are differences in the complexity of the vaccine pipelines, largely due to the differing types of clinical data and regulatory requirements for licensure and the associated bottlenecks that are unique to the animal or human vaccine pipeline 6 . One example is the need for vaccine safety and efficacy data as assessed by experimental infection of vaccinated and unvaccinated target animal species in the veterinary field; in humans, phase II and phase III randomized controlled studies for estimation of vaccine efficacy against natural exposure are used, although human infection studies are now used for some vaccine programmes 7 . Despite these differences, the solutions to address bottlenecks in the animal and human vaccine development pipelines tend to be similar 6 Abstract | Since the initial use of vaccination in the eighteenth century, our understanding of human and animal immunology has greatly advanced and a wide range of vaccine technologies and delivery systems have been developed. The COVID-19 pandemic response leveraged these innovations to enable rapid development of candidate vaccines within weeks of the viral genetic sequence being made available. The development of vaccines to tackle emerging infectious diseases is a priority for the World Health Organization and other global entities. More than 70% of emerging infectious diseases are acquired from animals, with some causing illness and death in both humans and the respective animal host. Yet the study of critical host-pathogen interactions and the underlying immune mechanisms to inform the development of vaccines for their control is traditionally done in medical and veterinary immunology 'silos'. In this Perspective, we highlight a 'One Health vaccinology' approach and discuss some key areas of synergy in human and veterinary vaccinology that could be exploited to accelerate the development of effective vaccines against these shared health threats. NATure reVIewS | Immunology 0123456789();: of vaccines that target similar protective mechanisms. For example, bovine and human respiratory syncytial viruses, which cause pneumonia in young calves and children, respectively, are closely related genetically and are targeted by the same types of immune mechanisms, suggesting that vaccine strategies exploiting the same underlying mechanism of immunity may work for both species 17, 18 . The most widely used human vaccine, bacille Calmette-Guérin (BCG) against tuberculosis, is essentially an attenuated strain of the cattle-infecting bacterium Mycobacterium bovis that is avirulent in a wide range of animal species 19 . BCG was developed through close collaboration between medical and veterinary practitioners more than 100 years ago 19 , and the extensive experience of its use in humans is now informing vaccination strategies to control tuberculosis in cattle 20 . A recent study found that BCG vaccination in humans also confers protection against other non-tuberculous infections in early childhood 21 ; we are aware of no studies of non-specific effects of BCG vaccination in cattle, but this clearly warrants investigation. Edward Jenner's observation that milkmaids exposed to the cowpox virus were protected against smallpox is perhaps the earliest example of exploiting pathogen relatedness for vaccine development and was the basis of the vaccine that was used for eradication of smallpox 22 . Early manufacture of Jenner's smallpox vaccine involved serial propagation of the cowpox virus in calves reared in 'vaccine farms' 23 . Vaccine manufacture has advanced considerably but animal-sourced materials are still used for production of human vaccines; for example, embryonated chicken eggs are routinely used for the manufacture of influenza and yellow fever vaccines 24, 25 . New highly scalable platform technologies and delivery systems are accelerating vaccine development such that it is now possible to go from the pathogen genetic sequence encoding an immunogen of choice to a vaccine candidate in a matter of weeks 26 . Bioinformatic analyses, X-ray crystallography and cryo-electron microscopy continue to be leveraged for the identification and optimization of protective antigens for human and veterinary vaccines [27] [28] [29] . These new technologies are being applied to emerging infectious diseases such as COVID-19 or stubborn persistent challenges, including malaria and brucellosis [30] [31] [32] [33] . In this Perspective, we highlight some key areas of synergy in human and veterinary vaccinology that could be exploited to accelerate the development and deployment of effective vaccines against zoonotic diseases. We focus on comparative immunology, applications of current vaccine technologies, and regulatory and operational considerations for vaccine deployment. The overall structure and composition of the innate and adaptive immune systems of humans and animal species are broadly similar, and comparing their responses to inoculation or infection with similar antigens or pathogens can inform vaccine development 34 . Allometric scaling is an important consideration, and the body size and physiology of livestock species are more similar to those of humans than to those of rodents. While rodents may be convenient for laboratory studies due to the ready availability of specific immunological reagents, lower purchase and maintenance costs and ease of handling, they may not reproduce the pathology and immunological attributes that would be observed in a natural animal host of infection 9 . The similarities between humans and livestock species may be most important when one is comparing the responses to aerosol delivery of antigens or pathogens 35 . Clearly, non-human primates are ideal species to predict responses in humans, but their availability is limited and certainly not possible for field studies. Nevertheless, the differences between the immune systems of humans and animals are important, and a cautious approach is justified when one is drawing detailed conclusions from animal studies. Some of the most striking differences between the immune systems of humans and animals relate to their T cell populations and antibody structures (Fig. 2) . Pigs are increasingly used to study vaccine candidates, in particular influenza vaccines [36] [37] [38] . However, there are key differences between pigs and humans that should be kept in mind. For example, three distinct subpopulations of CD8 + T cells have been identified in pigs by flow cytometry: a bright-staining population that expresses the CD8αβ heterodimer, a population that expresses the CD8αα homodimer and a CD8 + population that co-expresses CD4 (reFs [39] [40] [41] ). Ongoing studies indicate that most memory T cells in pigs are present in the double-positive population and that this population is the predominant source of interferon-γ (IFNγ) in recall responses to live viral vaccines 39, 42 . Peripheral CD4 + CD8 + T cells have been characterized in many different species but the proportion of these cells in the total T cell population differs greatly, from 1-2% in humans to 10-20% in pigs. In humans, the number and function of this subpopulation change in response to a range of infectious and neoplastic diseases 43 . Recently, these double-positive human T cells were shown to exhibit a memory phenotype 44 , similar to the double-positive T cells in pigs. The impact on responses to vaccination and infection due to the marked difference in the proportion of these double-positive cells in different species is yet to be resolved. Another striking difference is the large percentage of circulating γδ T cells in young pigs and ruminants. γδ T cells constitute up to 60% of circulating lymphocytes in young cattle 45 and pigs 46 . Even in adulthood, 30% of the peripheral blood mononuclear cells found in these species are γδ T cells 47 , whereas in humans only approximately 4% of peripheral blood mononuclear cells are γδ T cells 48 . Despite this difference between humans and ruminants, the results of protection studies in ruminants can provide valuable evidence to support the development of human vaccines; for example, the protection of calves from bovine respiratory syncytial virus by a stabilized prefusion F protein vaccine may guide the development of human vaccines against respiratory syncytial virus 49 . There is a case to be made that the results of vaccine efficacy and safety studies in large animals can provide important information to help shape vaccine development programmes in humans, but the precise immune mechanisms conferring that resistance may be different between species. The similarities between human and bovine tuberculosis offer a potential opportunity for cross-species development of novel vaccines against the diseases. A BCG challenge model has been used to investigate the protective immune response in humans. Genes linked to protective responses included IFNG and IL17F, together with other genes associated with these cytokines that those two genes encode, such as NOD2, IL22, IL23A and FCGR1B 50 . A recent review highlights the potential role of IL-22 in the protective response to Mycobacterium tuberculosis infection in cattle and humans 51 . In cattle, IL-22 and IFNγ produced by purified protein derivative-stimulated peripheral blood mononuclear cells were identified as the primary predictors of vaccine-induced protection in an M. bovis challenge model 52 . Furthermore, BCG vaccination in children and young calves provides protection against tuberculosis, with activation of natural killer cells being a key immune mechanism in the induction of protective immunity in both species 53, 54 . Therefore, there are elements of the protective immune response to tuberculosis that are consistent between cattle and humans, including humoral responses 55 . The similarities in different species of immune responses to closely related pathogens may help identify protective vaccine responses. Another example where studying comparative immunology may improve our understanding of protective immune responses is in determining the role of antibodies with long heavy chain complementarity-determining region 3 (CDR H3) gene segments. Human antibody CDR H3 ranges between 8 and 16 amino acids in length, although antibodies with longer CDR H3 have been observed (for example, 18 amino acids 56 and 28 amino acids 57 ) and seem to play an important role in cross-protective immune responses to HIV-1 (reFs 56, 57 ). However, such long CDR H3 antibodies are rare in humans, which makes some investigations more challenging 58 . By contrast, cattle have a larger population of antibodies (more than 10% of antibodies) with long and ultralong (more than 70 amino acids) CDR H3 gene segments 59 , and the study of these ultralong cattle antibodies may prove useful for the development of human interventions. For instance, immunizing cattle with HIV envelope glycoprotein results in rapid induction of broadly neutralizing ultralong CDR H3 antibodies, whereas it takes many years for such broadly neutralizing antibodies to develop in humans following HIV infection 60 . These bovine antibodies may be engineered for prophylactic or therapeutic use, and determining the immune mechanisms that underlie their induction could inform vaccine design. Conversely, the antibody repertoire in dromedary camels is composed of both conventional IgG molecules and heavy chain-only IgG antibodies (HCAb) molecules, with the latter accounting for more than 70% of the repertoire 61 . These smaller HCAb molecules are better adapted for binding cryptic epitopes on pathogens that may be inaccessible to conventional IgG molecules 62 , allowing their use in diverse applications in diagnostics, therapy and research 62 . However, very little is They are also reservoirs of Middle East respiratory syndrome coronavirus, which emerged in 2012 and is associated with high case fatality in humans 63 . Understanding how different species are able to mount protective immunity against common pathogens, despite profound differences in IgG structures, could transform approaches to vaccine design and development. These differences in antibody structure can be exploited to identify different mechanisms of protection: for example, long CDR H3 antibodies penetrating viral glycan shields 64 . Importantly, a single vaccine platform can induce protection across multiple species 12 , including humans 65 , despite these differences in immune response. Veterinary vaccinology has made a substantial contribution to the broad knowledge base to develop vaccines and understand how they work, but there may be a difference in the response to similar vaccine platforms in different species. It may also be the case that some platforms may work well in humans and not some other species. However, within each species, individual heterogeneity in mounting immune responses does occur, and this might be due to factors such as chronic underlying illnesses, genetics and age 66 . Performing comparative studies to identify the common protective mechanisms across species, while accounting for individual within-species heterogeneity, will move the field beyond identifying correlates of protection to defining protective mechanisms. The goals of vaccination programmes in humans and animals are similar, and include global disease eradication (permanent worldwide reduction of the incidence of a specific disease to zero), elimination of target diseases from a specified region with deliberate measures to prevent re-establishment, prevention of epidemic cycles and minimization of mortality and morbidity associated with infectious diseases. To date, vaccination has resulted in the eradication of smallpox in humans and rinderpest in cattle 22, 67 . Although focused on two separate species, the two eradication programmes used similar vaccine deployment strategies combining mass vaccination campaigns to achieve herd immunity, intensive surveillance systems to identify and contain outbreaks promptly, and surveillance reporting and sharing of new knowledge that allowed eradication in stubborn pockets of each disease 67, 68 . The endgame for these programmes required innovative strategies that included house-to-house case searches for smallpox and containment of outbreaks, and participatory community-based surveillance approaches to identify the hidden rinderpest disease pockets and deploy the vaccines. The key similarities in the deployment of vaccines and cross-learning from the medical and veterinary fields go beyond these disease eradication programmes to the control and elimination of current vaccine-preventable diseases. Vaccination for the control of zoonoses has dual benefits for both human and animal health. A good example is the control of rabies, a viral zoonosis transmitted to humans through dog bites, which is responsible for about 60,000 human deaths annually 15 . A global elimination goal for human deaths from rabies has been set for 2030 (reF. 14 ). The key strategies for achieving this goal are mass dog vaccinations to break the dog-dog and dog-human transmission cycles, prompt provision of postexposure prophylaxis to prevent clinical rabies among bite patients and enhanced surveillance systems to detect areas where the virus circulates and targeting the rabies interventions 14 . Whereas provision of rabies postexposure prophylaxis prevents clinical disease and death in people, elimination of human deaths from rabies is only cost-effective when combined with mass dog vaccinations 69, 70 . Similarly, animal vaccination against brucellosis (a bacterial zoonosis transmitted to humans by livestock) reduces the incidence of human brucellosis, while improving milk production and other production indices among vaccinated livestock 71 . Animal vaccination against epidemic zoonoses is a key strategy to limit human illness. The design and implementation of vaccine programmes for this purpose requires interaction between veterinary and public health personnel. Ideally, such collaboration needs to be in place before the occurrence of an epidemic, rather than being reactive 72 . In Kenya, the Zoonotic Disease Unit, a national entity co-led by medical and veterinary epidemiologists for the purpose of zoonotic disease surveillance, may provide an exemplar framework through which vaccine programmes to tackle endemic/ epidemic zoonoses can be implemented 73 . For instance, through extant surveillance for key disease syndromes in livestock, the most recent Rift Valley fever outbreak in Kenya was detected in humans within a fortnight of confirmed livestock cases 74 . In such a scenario, Rift Valley fever vaccination could be implemented among susceptible animals (licensed vaccines are already available) and humans (when a vaccine is available) within a radius in proximity to the initial cases. Such a 'ring vaccination' approach has its roots in the control of disease outbreaks in livestock 75 and has been used successfully to control Ebola virus disease epidemics 76 . However, not all zoonoses of public health importance cause clinical disease in animals. For instance, domestic ruminants such as sheep and goats are key animal hosts of CCHF virus, which results in asymptomatic infection only in these species 77 . By contrast, CCHF is a highly fatal disease in humans and is among the diseases prioritized by the World Health Organization for urgent development of countermeasures 72 . Investigating the pathophysiology and immunology of CCHF virus in ruminant species may provide clues towards identifying therapeutic targets and aid the development of vaccines against human CCHF. Furthermore, assessment of vaccine efficacy against CCHF virus infection in livestock field trials could support development of human CCHF vaccines by providing a stringent test for ranking the performance of candidate vaccines outside a high-containment laboratory environment. Due to the lack of clinical disease in animals, estimation of vaccine efficacy following natural exposure could rely on serological detection of responses to virus components that are not part of a vaccine, thereby allowing distinction of infected animals from vaccinated animals, a concept well known in veterinary vaccinology. Following widespread COVID-19 vaccine use, a similar serological monitoring strategy could be useful for tracking population-level severe acute respiratory syndrome coronavirus 2 (SARS-CoV-2) exposure, based on detection of antibodies against antigens absent from approved vaccines. There are several licensed veterinary vaccines against coronavirus infections in domestic animals (box 1; Table 2 ); the experience with licensure and use of these products provides insights into the likely performance of vaccines against COVID-19 and other coronavirus infections in humans but has rarely been discussed in the medical debate on vaccine development. The target product profile for any vaccine, whether human or veterinary, needs to incorporate an efficient manufacturing strategy, the design of optimal vaccination regimens and consideration of deployment requirements very early in the development pipeline. All these factors influence the final cost per vaccine dose and, after consideration of the potential benefit of using the product, inform go versus no-go decisions on vaccine implementation programmes and policy. The business case for the development of vaccines against many of the known zoonotic pathogens with epidemic potential is poor 78 . This is largely due to the sporadic nature of the epidemics they cause -for example, there are typically intervals of 5-15 years between epidemics of Rift Valley fever, and there are even longer intervals between epidemics of CCHF and other diseases -in addition to their restricted geography and poor data on their economic costs, which make the design of cost-effective vaccine implementation plans challenging. The costs associated with vaccine development and manufacture (Fig. 1) mean that returns on investments made by vaccine developers for such diseases are unlikely to be high. Initiatives such as the Coalition for Epidemic Preparedness Innovations (CEPI) are de-risking the human vaccine development process through provision of funding to support early-stage to late-stage development of vaccines against epidemics, including clinical evaluation that is crucial for licensure 79 . Funding schemes to advance veterinary vaccine development are also available, although none exclusively targets epizootic diseases. The Global Alliance for Livestock Veterinary Medicines (GALVmed) was founded in 2004 with a primary focus on supporting the development and eventual registration of control interventions for a wide range of livestock diseases in lowincome and middle-income countries (LMICs) 80 ; the CEPI now plays a similar role for human vaccines. All major domestic animal species are susceptible to coronavirus (CoV) infection, typically resulting in clinical symptoms involving the respiratory system or the gastrointestinal system. Several licensed veterinary vaccines against CoV-associated disease are available (see Table 2 for examples), and these are predominantly composed of live attenuated CoV or whole inactivated virions that are administered in an adjuvant. However, subunit, viral-vectored and other types of recombinant vaccines are in development. Some examples of licensed animal CoV vaccines and some key immunological observations are summarized below, with further details available in recent reviews of animal CoV vaccines [89] [90] [91] . Key observations from veterinary use of CoV vaccines 89-91 : • Virus-neutralizing antibodies directed to the surface spike (S) protein play a major role in protective immunity. • The duration of vaccine-induced immunity is variable but can last for at least 12 months, with annual boosters required to maintain protective levels of immunity. • Vaccines can be highly protective against severe illness resulting from CoV infection yet show limited protection against mild disease or infection. • Passive transfer of maternal antibodies from vaccinated dams can provide protective immunity against both enteric and respiratory CoV infections, as has been demonstrated in cattle. • T cell responses play an active role in the control of CoV infections. For instance, adoptive transfer of CD8 + T cells from immune chickens into unvaccinated chicks provides protection from acute infectious bronchitis, with epitopes mapped on the nucleocapsid and spike protein. • Different routes of administration can be used for CoV vaccination. Some veterinary vaccines have been deployed for use orally (for example, infectious bronchitis vaccines in poultry), intranasally (for example, bovine CoV vaccines in calves) or as an oral prime followed by an intramuscular boost (for example, transmissible gastroenteritis vaccines in pigs). Induction of mucosal immunity, mediated by IgA, is thought to increase the protective efficacy of vaccines. • The emergence of CoV spike protein variants may impact vaccine performance, resulting in insufficient protection and necessitating updates to vaccine immunogens. The strategies used to increase the breadth of the protective immune response against different CoV variants include (1) prime-boost regimens using vaccines incorporating different CoV variants (that is, vaccinating with one strain and boosting with another) and (2) inclusion of multiple CoV strains within a single vaccine. • Antibody-dependent enhancement of CoV infection following vaccination and virus exposure can be readily demonstrated in cats. This may provide a useful model to understand the antibody-dependent enhancement phenomenon. • Monitoring of CoV antibody seroprevalence in poultry has been used to inform decisions on whether to implement a vaccination programme on the basis of the levels of flock immunity. This is primarily aimed at achieving a cost-efficient disease control programme but could also be used in a scenario where vaccine supply is limited. For veterinary vaccines, the ideal cost per dose for ruminants should be less than US$0.5 to allow cost-effective use in LMICs 81 . The per dose cost of human vaccines tends to be much higher and highly variable from product to product 82 . However, although higher human vaccine costs can be tolerated, especially in high-income countries, vaccine cost remains a key factor that underlies the demand, affordability and implementation of immunization programmes in LMICs 83 . To further reduce deployment costs, most veterinary vaccines are multivalent, composed of different immunogens co-formulated to target two or more diseases with a single vaccination (see Table 2 for coronavirus vaccines as an example). Co-administration of different immunogens in a single product (for example, the childhood pentavalent vaccine that targets diphtheria, tetanus, pertussis, hepatitis B and Haemophilus influenzae type b) is commonplace for the Expanded Programme on Immunization in children, which accounts for the bulk of global vaccine use. Cross-learning between the veterinary and medical fields from their respective experiences relating to vaccine development and implementation of programmes based on multivalent or co-administered products could be of mutual benefit. Where a single vaccine is developed for use in both animals and humans, the same vaccine master seed stock could be used to generate bulk material that is then processed in parallel for human and animal use in accordance with the respective manufacturing requirements to derive a livestock product and one for use in humans from the same manufacturing run. Bulk material could be stockpiled, with downstream processing initiated as soon as the need for vaccination arises. However, this strategy would be successful only if the bulk material was stable in the long term and a regulatory approval strategy incorporating veterinary and human considerations was in place. Harmonized regulatory processes allowing mutual recognition of vaccine registration procedures between countries are already in place, aiming to address operational bottlenecks that limit rapid access to licensed human and veterinary vaccines 84, 85 . Studying animal pathogens, diseases and protective immune responses has had a major impact on controlling human diseases over the past century. It is usually the case that new vaccine platforms are deployed more rapidly in veterinary species than in humans. Veterinary vaccines commonly undergo rigorous safety and efficacy testing in the target hosts using challenge models before registration and widespread use. Safety testing and pharmacovigilance are especially important in food-producing animals. Also, developing cost-effective manufacturing at scale is essential for animal vaccines. In the past few decades, the widespread use of safe and effective vaccines in livestock has given confidence to develop the same platforms or indeed the same active substances for use in human vaccines. However, there remain untapped opportunities to leverage advances in human and veterinary immunology for the development of vaccines, as well as operational experiences to inform vaccine deployment. Effective control of zoonotic infections, which account for the bulk of public health emergencies, require One Health approaches with complementary interventions in both animal hosts and humans. The success of the One Health approach in eliminating disease burden also requires attention to the challenges associated with eradication of zoonotic diseases in natural reservoirs. 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Review of vaccine price data (WHO Challenges in ensuring global access to COVID-19 vaccines: production, affordability, 0123456789();: allocation, and deployment A policy scoping study on harmonization of registration requirements for veterinary products for mutual recognition among East African community partner states (Global Alliance for Livestock Veterinary Medicines Harmonization of medical products regulation: a key factor for improving regulatory capacity in the East African community Structure of HIV-1 gp120 V1/V2 domain with broadly neutralizing antibody PG9 The origin of enantioselectivity in aldolase antibodies: crystal structure, site-directed mutagenesis, and computational analysis Selection of nanobodies with broad neutralizing potential against primary HIV-1 strains using soluble subtype C gp140 envelope trimers The coronaviruses of animals and birds: their zoonosis, vaccines, and models for SARS-CoV and SARS-CoV2 Vaccination against coronaviruses in domestic animals Lessons from animal coronaviruses The authors are grateful to P. Bejon and M. Hamaluba for helpful discussions and comments on the manuscript. G.M.W. is supported by a fellowship from the Oak Foundation and grants from the Wellcome Trust (220991/Z/20/Z and 203077/Z/16/Z). T.A.B. is supported by the UK Medical Research Council (MR/S007555/1) and by the Wellcome Trust through the Wellcome Centre for Human Genetics (203141/Z/16/Z). As the authors are supported by the Wellcome Trust, for the purpose of open access, the authors have applied a CC-BY public copyright licence to any author accepted manuscript version arising from this submission. The authors contributed equally to all aspects of the article. The authors declare no competing interests. Nature Reviews Immunology thanks the anonymous reviewers for their contribution to the peer review of this work. Springer Nature remains neutral with regard to jurisdictional claims in published maps and institutional affiliations.