Immunization is a cornerstone of public health policy and is demonstrably highly cost-effective when used to protect child health. Although it could be argued that immunology has not thus far contributed much to vaccine development, in that most of the vaccines we use today were developed and tested empirically, it is clear that there are major challenges ahead to develop new vaccines for difficult-to-target pathogens, for which we urgently need a better understanding of protective immunity. Moreover, recognition of the huge potential and challenges for vaccines to control disease outbreaks and protect the older population, together with the availability of an array of new technologies, make it the perfect time for immunologists to be involved in designing the next generation of powerful immunogens. This Review provides an introductory overview of vaccines, immunization and related issues and thereby aims to inform a broad scientific audience about the underlying immunological concepts.
Vaccines have transformed public health, particularly since national programmes for immunization first became properly established and coordinated in the 1960s. In countries with high vaccine programme coverage, many of the diseases that were previously responsible for the majority of childhood deaths have essentially disappeared1 (Fig. 1). The World Health Organization (WHO) estimates that 2–3 million lives are saved each year by current immunization programmes, contributing to the marked reduction in mortality of children less than 5 years of age globally from 93 deaths per 1,000 live births in 1990 to 39 deaths per 1,000 live births in 2018 (ref.2).
Vaccines exploit the extraordinary ability of the highly evolved human immune system to respond to, and remember, encounters with pathogen antigens. However, for much of history, vaccines have been developed through empirical research without the involvement of immunologists. There is a great need today for improved understanding of the immunological basis for vaccination to develop vaccines for hard-to-target pathogens (such as Mycobacterium tuberculosis, the bacterium that causes tuberculosis (TB))3 and antigenically variable pathogens (such as HIV)4, to control outbreaks that threaten global health security (such as COVID-19 or Ebola)5,6 and to work out how to revive immune responses in the ageing immune system7 to protect the growing population of older adults from infectious diseases.
In this Review, which is primarily aimed at a broad scientific audience, we provide a guide to the history (Box 1), development, immunological basis and remarkable impact of vaccines and immunization programmes on infectious diseases to provide insight into the key issues facing immunologists today. We also provide some perspectives on current and future challenges in continuing to protect the world’s population from common pathogens and emerging infectious threats. Communicating effectively about the science of vaccination to a sceptical public is a challenge for all those engaged in vaccine immunobiology but is urgently needed to realign the dialogue and ensure public health8. This can only be achieved by being transparent about what we know and do not know, and by considering the strategies to overcome our existing knowledge gaps.
What is in a vaccine?
A vaccine is a biological product that can be used to safely induce an immune response that confers protection against infection and/or disease on subsequent exposure to a pathogen. To achieve this, the vaccine must contain antigens that are either derived from the pathogen or produced synthetically to represent components of the pathogen. The essential component of most vaccines is one or more protein antigens that induce immune responses that provide protection. However, polysaccharide antigens can also induce protective immune responses and are the basis of vaccines that have been developed to prevent several bacterial infections, such as pneumonia and meningitis caused by Streptococcus pneumoniae, since the late 1980s9. Protection conferred by a vaccine is measured in clinical trials that relate immune responses to the vaccine antigen to clinical end points (such as prevention of infection, a reduction in disease severity or a decreased rate of hospitalization). Finding an immune response that correlates with protection can accelerate the development of and access to new vaccines10 (Box 2).
Vaccines are generally classified as live or non-live (sometimes loosely referred to as ‘inactivated’) to distinguish those vaccines that contain attenuated replicating strains of the relevant pathogenic organism from those that contain only components of a pathogen or killed whole organisms (Fig. 2). In addition to the ‘traditional’ live and non-live vaccines, several other platforms have been developed over the past few decades, including viral vectors, nucleic acid-based RNA and DNA vaccines, and virus-like particles (discussed in more detail later).
The distinction between live and non-live vaccines is important. The former may have the potential to replicate in an uncontrolled manner in immunocompromised individuals (for example, children with some primary immunodeficiencies, or individuals with HIV infection or those receiving immunosuppressive drugs), leading to some restrictions to their use11. By contrast, non-live vaccines pose no risk to immunocompromised individuals (although they may not confer protection in those with B cell or combined immunodeficiency, as explained in more detail later).
Live vaccines are developed so that, in an immunocompetent host, they replicate sufficiently to produce a strong immune response, but not so much as to cause significant disease manifestations (for example, the vaccines for measles, mumps, rubella and rotavirus, oral polio vaccine, the Mycobacterium bovis bacillus Calmette–Guérin (BCG) vaccine for TB and live attenuated influenza vaccine). There is a trade-off between enough replication of the vaccine pathogen to induce a strong immune response and sufficient attenuation of the pathogen to avoid symptomatic disease. For this reason, some safe, live attenuated vaccines require multiple doses and induce relatively short-lived immunity (for example, the live attenuated typhoid vaccine, Ty21a)12, and other live attenuated vaccines may induce some mild disease (for example, about 5% of children will develop a rash and up to 15% fever after measles vaccination)13.
The antigenic component of non-live vaccines can be killed whole organisms (for example, whole-cell pertussis vaccine and inactivated polio vaccine), purified proteins from the organism (for example, acellular pertussis vaccine), recombinant proteins (for example, hepatitis B virus (HBV) vaccine) or polysaccharides (for example, the pneumococcal vaccine against S. pneumoniae) (Fig. 2). Toxoid vaccines (for example, for tetanus and diphtheria) are formaldehyde-inactivated protein toxins that have been purified from the pathogen.
Non-live vaccines are often combined with an adjuvant to improve their ability to induce an immune response (immunogenicity). There are only a few adjuvants that are used routinely in licensed vaccines. However, the portfolio of adjuvants is steadily expanding, with liposome-based adjuvants and oil-in-water emulsions being licensed in the past few decades14. The mechanism of action of aluminium salts (alum), although extensively used as an adjuvant for more than 80 years, remains incompletely understood15, but there is increasing evidence that immune responses and protection can be enhanced by the addition of newer adjuvants that provide danger signals to the innate immune system. Examples of these novel adjuvants are the oil-in-water emulsion MF59, which is used in some influenza vaccines16; AS01, which is used in one of the shingles vaccines and the licensed malaria vaccine17; and AS04, which is used in a vaccine against human papillomavirus (HPV)18.
Vaccines contain other components that function as preservatives, emulsifiers (such as polysorbate 80) or stabilizers (for example, gelatine or sorbitol). Various products used in the manufacture of vaccines could theoretically also be carried over to the final product and are included as potential trace components of a vaccine, including antibiotics, egg or yeast proteins, latex, formaldehyde and/or gluteraldehyde and acidity regulators (such as potassium or sodium salts). Except in the case of allergy to any of these components, there is no evidence of risk to human health from these trace components of some vaccines19,20.
Vaccines induce antibodies
The adaptive immune response is mediated by B cells that produce antibodies (humoral immunity) and by T cells (cellular immunity). All vaccines in routine use, except BCG (which is believed to induce T cell responses that prevent severe disease and innate immune responses that may inhibit infection; see later), are thought to mainly confer protection through the induction of antibodies (Fig. 3). There is considerable supportive evidence that various types of functional antibody are important in vaccine-induced protection, and this evidence comes from three main sources: immunodeficiency states, studies of passive protection and immunological data.
Individuals with some known immunological defects in antibodies or associated immune components are particularly susceptible to infection with certain pathogens, which can provide insight into the characteristics of the antibodies that are required for protection from that particular pathogen. For example, individuals with deficiencies in the complement system are particularly susceptible to meningococcal disease caused by infection with Neisseria meningitidis21 because control of this infection depends on complement-mediated killing of bacteria, whereby complement is directed to the bacterial surface by IgG antibodies. Pneumococcal disease is particularly common in individuals with reduced splenic function22 (which may be congenital, resulting from trauma or associated with conditions such as sickle cell disease); S. pneumoniae bacteria that have been opsonized with antibody and complement are normally removed from the blood by phagocytes in the spleen, which are no longer present in individuals with hyposplenism. Antibody-deficient individuals are susceptible to varicella zoster virus (which causes chickenpox) and other viral infections, but, once infected, they can control the disease in the same way as an immunocompetent individual, so long as they have a normal T cell response23.
It has been clearly established that intramuscular or intravenous infusion of exogenous antibodies can provide protection against some infections. The most obvious example is that of passive transfer of maternal antibodies across the placenta, which provides newborn infants with protection against a wide variety of pathogens, at least for a few months after birth. Maternal vaccination with pertussis24, tetanus25 and influenza26 vaccines harnesses this important protective adaptation to reduce the risk of disease soon after birth and clearly demonstrates the role of antibodies in protection against these diseases. Vaccination of pregnant women against group B streptococci27 and respiratory syncytial virus (RSV)28 has not yet been shown to be effective at preventing neonatal or infant infection, but it has the potential to reduce the burden of disease in the youngest infants. Other examples include the use of specific neutralizing antibodies purified from immune donors to prevent the transmission of various viruses, including varicella zoster virus, HBV and measles virus29. Individuals with inherited antibody deficiency are without defence against serious viral and bacterial infections, but regular administration of serum antibodies from an immunocompetent donor can provide almost entirely normal immune protection for the antibody-deficient individual.
Increasing knowledge of immunology provides insights into the mechanisms of protection mediated by vaccines. For example, polysaccharide vaccines, which are made from the surface polysaccharides of invasive bacteria such as meningococci (N. meningitidis)30 and pneumococci (S. pneumoniae)31, provide considerable protection against these diseases. It is now known that these vaccines do not induce T cell responses, as polysaccharides are T cell-independent antigens, and thus they must mediate their protection through antibody-dependent mechanisms. Protein–polysaccharide conjugate vaccines contain the same polysaccharides from the bacterial surface, but in this case they are chemically conjugated to a protein carrier (mostly tetanus toxoid, or diphtheria toxoid or a mutant protein derived from it, known as CRM197)32,33,34. The T cells induced by the vaccine recognize the protein carrier (a T cell-dependent antigen) and these T cells provide help to the B cells that recognize the polysaccharide, but no T cells are induced that recognize the polysaccharide and, thus, only antibody is involved in the excellent protection induced by these vaccines35. Furthermore, human challenge studies offer the opportunity to efficiently assess correlates of protection (Box 2) under controlled circumstances36, and they have been used to demonstrate the role of antibodies in protection against malaria37 and typhoid38.
Vaccines need T cell help
Although most of the evidence points to antibodies being the key mediators of sterilizing immunity induced by vaccination, most vaccines also induce T cell responses. The role of T cells in protection is poorly characterized, except for their role in providing help for B cell development and antibody production in lymph nodes. From studies of individuals with inherited or acquired immunodeficiency, it is clear that whereas antibody deficiency increases susceptibility to acquisition of infection, T cell deficiency results in failure to control a pathogen after infection. For example, T cell deficiency results in uncontrolled and fatal varicella zoster virus infection, whereas individuals with antibody deficiency readily develop infection but recover in the same way as immunocompetent individuals. The relative suppression of T cell responses that occurs at the end of pregnancy increases the severity of infection with influenza and varicella zoster viruses39.
Although evidence for the involvement of T cells in vaccine-induced protection is limited, this is likely owing, in part, to difficulties in accessing T cells to study as only the blood is easily accessible, whereas many T cells are resident in tissues such as lymph nodes. Furthermore, we do not yet fully understand which types of T cell should be measured. Traditionally, T cells have been categorized as either cytotoxic (killer) T cells or helper T cells. Subtypes of T helper cells (TH cells) can be distinguished by their profiles of cytokine production. T helper 1 (TH1) cells and TH2 cells are mainly important for establishing cellular immunity and humoral immunity, respectively, although TH1 cells are also associated with generation of the IgG antibody subclasses IgG1 and IgG3. Other TH cell subtypes include TH17 cells (which are important for immunity at mucosal surfaces such as the gut and lung) and T follicular helper cells (located in secondary lymphoid organs, which are important for the generation of high-affinity antibodies (Fig. 3)). Studies show that sterilizing immunity against carriage of S. pneumoniae in mice can be achieved by the transfer of T cells from donor mice exposed to S. pneumoniae40, which indicates that further investigation of T cell-mediated immunity is warranted to better understand the nature of T cell responses that could be harnessed to improve protective immunity.
Although somewhat simplistic, the evidence therefore indicates that antibodies have the major role in prevention of infection (supported by TH cells), whereas cytotoxic T cells are required to control and clear established infection.
Features of vaccine-induced protection
Vaccines have been developed over the past two centuries to provide direct protection of the immunized individual through the B cell-dependent and T cell-dependent mechanisms described above. As our immunological understanding of vaccines has developed, it has become apparent that this protection is largely manifested through the production of antibody. Another important feature of vaccine-induced protection is the induction of immune memory. Vaccines are usually developed to prevent clinical manifestations of infection. However, some vaccines, in addition to preventing the disease, may also protect against asymptomatic infection or colonization, thereby reducing the acquisition of a pathogen and thus its onward transmission, establishing herd immunity. Indeed, the induction of herd immunity is perhaps the most important characteristic of immunization programmes, with each dose of vaccine protecting many more individuals than the vaccine recipient. Some vaccines may also drive changes in responsiveness to future infections with different pathogens, so called non-specific effects, perhaps by stimulating prolonged changes in the activation state of the innate immune system.
In encountering a pathogen, the immune system of an individual who has been vaccinated against that specific pathogen is able to more rapidly and more robustly mount a protective immune response. Immune memory has been shown to be sufficient for protection against pathogens when the incubation period is long enough for a new immune response to develop (Fig. 4a). For example, in the case of HBV, which has an incubation period of 6 weeks to 6 months, a vaccinated individual is usually protected following vaccination even if exposure to the virus occurs some time after vaccination and the levels of vaccine-induced antibody have already waned41. Conversely, it is thought that immune memory may not be sufficient for protection against rapidly invasive bacterial infections that can cause severe disease within hours or days following acquisition of the pathogen42 (Fig. 4b). For example, there is evidence in the case of both Haemophilus influenzae type B (Hib) and capsular group C meningococcal infection that individuals with vaccine-induced immune memory can still develop disease once their antibody levels have waned, despite mounting robust, although not rapid enough, memory responses43,44. The waning of antibody levels varies depending on the age of the vaccine recipient (being very rapid in infants as a result of the lack of bone marrow niches for B cell survival), the nature of the antigen and the number of booster doses administered. For example, the virus-like particles used in the HPV vaccine induce antibody responses that can persist for decades, whereas relatively short-term antibody responses are induced by pertussis vaccines; and the inactivated measles vaccine induces shorter-lived antibody responses than the live attenuated measles vaccine.
So, for infections that are manifest soon after acquisition of the pathogen, the memory response may be insufficient to control these infections and sustained immunity for individual protection through vaccination can be difficult to achieve. One solution to this is the provision of booster doses of vaccine through childhood (as is the case, for example, for diphtheria, tetanus, pertussis and polio vaccines), in an attempt to sustain antibody levels above the protective threshold. It is known that provision of five or six doses of tetanus45 or diphtheria46 vaccine in childhood provides lifelong protection, and so booster doses of these vaccines throughout adult life are not routine in most countries that can achieve high coverage with multiple childhood doses. Given that, for some infections, the main burden is in young children, continued boosting after the second year of life is not undertaken (for example, the invasive bacterial infections including Hib and capsular group B meningococci).
The exception is the pertussis vaccine, where the focus of vaccine programmes is the prevention of disease in infancy; this is achieved both by direct vaccination of infants as well as by the vaccination of other age groups, including adolescents and pregnant women in some programmes, to reduce transmission to infants and provide protection by antibody transfer across the placenta. Notably, in high-income settings, many countries (starting in the 1990s) have switched to using the acellular pertussis vaccine, which is less reactogenic than (and therefore was thought to be preferable to) the older whole-cell pertussis vaccine that is still used in most low-income countries. It is now apparent that acellular pertussis vaccine induces a shorter duration of protection against clinical pertussis and may be less effective against bacterial transmission than is the whole-cell pertussis vaccine47. Many high-income countries have observed a rise in pertussis cases since the introduction of the acellular vaccine, a phenomenon that is not observed in low-income nations using the whole-cell vaccine48.
By contrast, lifelong protection seems to be the rule following a single dose with some of the live attenuated viral vaccines, such as yellow fever vaccine49 (Fig. 4c), although it is apparent that protection is incomplete with others. In the case of varicella zoster and measles–mumps vaccines, some breakthrough cases are described during disease outbreaks among those individuals who have previously been vaccinated, although it is unclear whether this represents a group in whom immunity has waned (and who therefore needed booster vaccination) or a group for whom the initial vaccine did not induce a successful immune response. Breakthrough cases are less likely in those individuals who have had two doses of measles–mumps–rubella vaccine50 or varicella zoster vaccine51, and cases that do occur are usually mild, which indicates that there is some lasting immunity to the pathogen.
An illustration of the complexity of immune memory and the importance of understanding its underlying immunological mechanisms in order to improve vaccination strategies is provided by the concept of ‘original antigenic sin’. This phenomenon describes how the immune system fails to generate an immune response against a strain of a pathogen if the host was previously exposed to a closely related strain, and this has been demonstrated in several infections, including dengue52 and influenza53. This might have important implications for vaccine development if only a single pathogen strain or pathogen antigen is included in a vaccine, as vaccine recipients might then have impaired immune responses if later exposed to different strains of the same pathogen, potentially putting them at increased risk of infection or more severe disease. Strategies to overcome this include the use of adjuvants that stimulate innate immune responses, which can induce sufficiently cross-reactive B cells and T cells that recognize different strains of the same pathogen, or the inclusion of as many strains in a vaccine as possible, the latter approach obviously being limited by the potential of new strains to emerge in the future54.
Although direct protection of individuals through vaccination has been the focus of most vaccine development and is crucial to demonstrate for the licensure of new vaccines, it has become apparent that a key additional component of vaccine-induced protection is herd immunity, or more correctly ‘herd protection’ (Fig. 5). Vaccines cannot protect every individual in a population directly, as some individuals are not vaccinated for various reasons and others do not mount an immune response despite vaccination. Fortunately, however, if enough individuals in a population are vaccinated, and if vaccination prevents not only the development of disease but also infection itself (discussed in more detail below), transmission of the pathogen can be interrupted and the incidence of disease can fall further than would be expected, as a result of the indirect protection of individuals who would otherwise be susceptible.
For highly transmissible pathogens, such as those causing measles or pertussis, around 95% of the population must be vaccinated to prevent disease outbreaks, but for less transmissible organisms a lower percentage of vaccine coverage may be sufficient to have a substantial impact on disease (for example, for polio, rubella, mumps or diphtheria, vaccine coverage can be ≤86%). For influenza, the threshold for herd immunity is highly variable from season to season and is also confounded by the variability in vaccine effectiveness each year55. Modest vaccine coverage, of 30–40%, is likely to have an impact on seasonal influenza epidemics, but ≥80% coverage is likely to be optimal56. Interestingly, there might be a downside to very high rates of vaccination, as the absence of pathogen transmission in that case will prevent natural boosting of vaccinated individuals and could lead to waning immunity if booster doses of vaccine are not used.
Apart from tetanus vaccine, all other vaccines in the routine immunization schedule induce some degree of herd immunity (Fig. 5), which substantially enhances population protection beyond that which could be achieved by vaccination of the individual only. Tetanus is a toxin-mediated disease acquired through infection of breaks in the skin contaminated with the toxin-producing bacteria Clostridium tetani from the environment — so, vaccination of the community with the tetanus toxoid will not prevent an unvaccinated individual acquiring the infection if they are exposed. As an example of the success of herd immunity, vaccination of children and young adults (up to 19 years of age) with capsular group C meningococcal vaccine in a mass campaign in 1999 resulted in almost complete elimination of disease from the UK in adults as well as children57. Currently, the strategy for control of capsular groups A, C, W and Y meningococci in the UK is vaccination of adolescents, as they are mainly responsible for transmission and vaccine-mediated protection of this age group leads to community protection through herd immunity58. The HPV vaccine was originally introduced to control HPV-induced cervical cancer, with vaccination programmes directed exclusively at girls, but it was subsequently found to also provide protection against HPV infection in heterosexual boys through herd immunity, which led to a marked reduction in the total HPV burden in the population59,60.
Prevention of infection versus disease
Whether vaccines prevent infection or, rather, the development of disease after infection with a pathogen is often difficult to establish, but improved understanding of this distinction could have important implications for vaccine design. BCG vaccination can be used as an example to illustrate this point, as there is some evidence for the prevention of both disease and infection. BCG vaccination prevents severe disease manifestations such as tuberculous meningitis and miliary TB in children61 and animal studies have shown that BCG vaccination reduces the spread of M. tuberculosis bacteria in the blood, mediated by T cell immunity62, thereby clearly showing that vaccination has protective effects against the development of disease after infection. However, there is also good evidence that BCG vaccination reduces the risk of infection. In a TB outbreak at a school in the UK, 29% of previously BCG-vaccinated children had a memory T cell response to infection, as indicated by a positive interferon-γ release assay, as compared with 47% of the unvaccinated children63. A similar effect was seen when studying Indonesian household members of patients with TB, who had a 45% reduced chance of developing a positive interferon-γ release assay response to M. tuberculosis if they had previously been BCG vaccinated64. The lack of a T cell response in previously vaccinated individuals indicates that the BCG vaccine induces an innate immune response that results in ‘early clearance’ of the bacteria and prevents infection that induces an adaptive immune response. It will be hugely valuable for future vaccine development to better understand the induction of such protective innate immune responses so that they might be reproduced for other pathogens.
In the case of the current pandemic of the virus SARS-CoV-2, a vaccine that prevents severe disease and disease-driven hospitalization could have a substantial public health impact. However, a vaccine that could also block acquisition of the virus, and thus prevent both asymptomatic and mild infection, would have much larger impact by reducing transmission in the community and potentially establishing herd immunity.
Several lines of evidence indicate that immunization with some vaccines perturbs the immune system in such a way that there are general changes in immune responsiveness that can increase protection against unrelated pathogens65. This phenomenon has been best described in humans in relation to BCG and measles vaccines, with several studies showing marked reductions in all-cause mortality when these vaccines are administered to young children that are far beyond the expected impact from the reduction in deaths attributed to TB or measles, respectively66. These non-specific effects may be particularly important in high-mortality settings, but not all studies have identified the phenomenon. Although several immunological mechanisms have been proposed, the most plausible of which is that epigenetic changes can occur in innate immune cells as a result of vaccination, there are no definitive studies in humans that link immunological changes after immunization with important clinical end points, and it remains unclear how current immunization schedules might be adapted to improve population protection through non-specific effects. Of great interest in the debate, recent studies have indicated that measles disease casts a prolonged ‘shadow’ over the immune system, with depletion of existing immune memory, such that children who have had the disease have an increased risk of death from other causes over the next few years67,68. In this situation, measles vaccination reduces mortality from measles as well as the unconnected diseases that would have occurred during the ‘shadow’, resulting in a benefit that seems to be non-specific but actually relates directly to the prevention of measles disease and its consequences. This illustrates a limitation of vaccine study protocols: as these are usually designed to find pathogen-specific effects, the possibility of important non-specific effects cannot be assessed.
Factors affecting vaccine protection
The level of protection afforded by vaccination is affected by many genetic and environmental factors, including age, maternal antibody levels, prior antigen exposure, vaccine schedule and vaccine dose. Although most of these factors cannot be readily modified, age of vaccination and schedule of vaccination are important and key factors in planning immunization programmes. The vaccine dose is established during early clinical development, based on optimal safety and immunogenicity. However, for some populations, such as older adults, a higher dose might be beneficial, as has been shown for the influenza vaccine69,70. Moreover, intradermal vaccination has been shown to be immunogenic at much lower (fractional) doses than intramuscular vaccination for influenza, rabies and HBV vaccines71.
Age of vaccination
The highest burden of and mortality from infectious disease occur in the first 5 years of life, with the youngest infants being most affected. For this reason, immunization programmes have largely focused on this age group where there is the greatest benefit from vaccine-induced protection. Although this makes sense from an epidemiological perspective, it is somewhat inconvenient from an immunological perspective as the induction of strong immune responses in the first year of life is challenging. Indeed, vaccination of older children and adults would induce stronger immune responses, but would be of little value if those who would have benefited from vaccination have already succumbed to the disease.
It is not fully understood why immune responses to vaccines are not as robust in early infancy as they are in older children. One factor, which is increasingly well documented, is interference from maternal antibody72 — acquired in utero through the placenta — which might reduce antigen availability, reduce viral replication (in the case of live viral vaccines such as measles73) or perhaps regulate B cell responses. However, there is also evidence that there is a physiological age-dependent increase in antibody responses in infancy72. Furthermore, bone marrow niches to support B cells are limited in infancy, which might explain the very short-lived immune responses that are documented in the first year of life74. For example, after immunization with 2 doses of the capsular group C meningococcal vaccine in infancy, only 41% of infants still had protective levels of antibody by the time of the booster dose, administered 7 months later75.
In the case of T cell-independent antigens — in other words, plain polysaccharides from Hib, typhoid-causing bacteria, meningococci and pneumococci — animal data indicate that antibody responses depend on development of the marginal zone of the spleen, which is required for the maturation of marginal zone B cells, and this does not occur until around 18 months of age in human infants76. These plain polysaccharide vaccines do not induce memory B cells (Fig. 6) and, even in adults, provide protection for just 2–3 years, with protection resulting from antibody produced by plasma cells derived from marginal zone B cells77. However, converting plain polysaccharide vaccines into T cell-dependent protein–polysaccharide conjugate vaccines, which are immunogenic from 2 months of age and induce immune memory, has transformed prevention of disease caused by the encapsulated bacteria (pneumococci, Hib and meningococci) over the past three decades78. These are the most important invasive bacterial pathogens of childhood, causing most cases of childhood meningitis and bacterial pneumonia, and the development of the conjugate vaccine technology in the 1980s has transformed global child health9.
Immune responses are also poor in the older population and most of the vaccines used in older adults offer limited protection or a limited duration of protection, particularly among those older than 75 years of age. The decline in immune function with age (known as immunosenescence) has been well documented79 but, despite the burden of infection in this age group and the increasing size of the population, has not received sufficient attention so far amongst immunologists and vaccinologists. Interestingly, some have raised the hypothesis that chronic infection with cytomegalovirus (CMV) might have a role in immunosenescence through unfavourable effects on the immune system, including clonal expansion of CMV-specific T cell populations, known as ‘memory inflation’, and reduced diversity of naive T cells80,81.
In high-income countries, many older adults receive influenza, pneumococcal and varicella zoster vaccines, although data showing substantial benefits of these vaccines in past few decades in the oldest adults (more than 75 years of age) are lacking. However, emerging data following the recent development and deployment of new-generation, high-dose or adjuvanted influenza vaccines82 and an adjuvanted glycoprotein varicella zoster vaccine83 suggest that the provision of additional signals to the immune system by certain adjuvants (such as AS01 and MF59) can overcome immunosenescence. It is now necessary to understand how and why, and to use this knowledge to expand options for vaccine-induced protection at the extremes of life.
Schedule of vaccination
For most vaccines that are used in the first year of life, 3–4 doses are administered by 12 months of age. Conventionally, in human vaccinology, ‘priming’ doses are all those administered at less than 6 months of age and the ‘booster’ dose is given at 9–12 months of age. So, for example, the standard WHO schedule for diphtheria–tetanus–pertussis-containing vaccines (which was introduced in 1974 as part of the Expanded Programme on Immunization84) consists of 3 priming doses at 6, 10 and 14 weeks of age with no booster. This schedule was selected to provide early protection before levels of maternal antibody had waned (maternal antibody has a half-life of around 30–40 days85, so very little protection is afforded to infants from the mother beyond 8–12 weeks of age) and because it was known that vaccine compliance is better when doses are given close together. However, infant immunization schedules around the world are highly variable — few high-income or middle-income countries use the Expanded Programme on Immunization schedule — and were largely introduced with little consideration of how best to optimize immune responses. Indeed, schedules that start later at 8–12 weeks of age (when there is less interference from maternal antibody) and have longer gaps between doses (8 weeks rather than 4 weeks) are more immunogenic. A large number of new vaccines have been introduced since 1974 as a result of remarkable developments in technology, but these have generally been fitted into existing schedules without taking into account the optimal scheduling for these new products. The main schedules used globally for diphtheria–tetanus–pertussis vaccine are presented in Supplementary Table 1, and the changes to the UK immunization schedule since 1963 are presented in Supplementary Table 2. It should also be noted that surveys show vaccines are rarely delivered on schedule in many countries and, thus, the published schedule may not be how vaccines are actually delivered on the ground. This is particularly the case in remote areas (for example, where health professionals only visit occasionally) and regions with limited or chaotic health systems, leaving children vulnerable to infection.
Safety and side effects of vaccines
Despite the public impression that vaccines are associated with specific safety concerns, the existing data indicate that vaccines are remarkably safe as interventions to defend human health. Common side effects, particularly those associated with the early innate immune response to vaccines, are carefully documented in clinical trials. Although rare side effects might not be identified in clinical trials, vaccine development is tightly controlled and robust post-marketing surveillance systems are in place in many countries, which aim to pick these up if they do occur. This can make the process of vaccine development rather laborious but is appropriate because, unlike most drugs, vaccines are used for prophylaxis in a healthy population and not to treat disease. Perhaps because vaccines work so well and the diseases that they prevent are no longer common, there have been several spurious associations made between vaccines and various unrelated health conditions that occur naturally in the population. Disentangling incorrect claims of vaccine harm from true vaccine-related adverse events requires very careful epidemiological studies.
Common side effects
Licensure of a new vaccine normally requires safety studies involving from 3,000 to tens of thousands of individuals. Thus, common side effects are very well known and are published by the regulator at the time of licensure. Common side effects of many vaccines include injection site pain, redness and swelling and some systemic symptoms such as fever, malaise and headache. All of these side effects, which occur in the first 1–2 days following vaccination, reflect the inflammatory and immune responses that lead to the successful development of vaccine-induced protection. About 6 days after measles–mumps–rubella vaccination, about 10% of 12-month-old infants develop a mild viraemia, which can result in fever and rash, and occasionally febrile convulsions (1 in 3,000)86. Although these side effects are self-limiting and relatively mild — and are trivial in comparison with the high morbidity and mortality of the diseases from which the vaccines protect — they can be very worrying for parents and their importance is often underestimated by clinicians who are counselling families about immunization.
Immunodeficiency and vaccination
Most vaccines in current use are inactivated, purified or killed organisms or protein and/or polysaccharide components of a pathogen; as they cannot replicate in the vaccine recipient, they are thus not capable of causing any significant side effects, resulting in very few contraindications for their use. Even in immunocompromised individuals, there is no risk from use of these vaccines, although the induction of immunity may not be possible, depending on the nature of the immune system defect. More caution is required for the use of live attenuated, replicating vaccines (such as yellow fever, varicella zoster, BCG and measles vaccines) in the context of individuals with T cell immunodeficiency as there is a theoretical risk of uncontrolled replication, and live vaccines are generally avoided in this situation87. A particular risk of note is from the yellow fever vaccine, which is contraindicated in individuals with T cell immunodeficiency and occasionally causes a severe viscerotropic or neurotropic disease in individuals with thymus disease or after thymectomy, in young infants and adults more than 60 years of age88. In individuals with antibody deficiency, there may be some merit in the use of routine live vaccines, as T cell memory may be induced that, although unlikely to prevent future infection, could improve control of the disease if infection occurs.
The myth of antigenic overload
An important parental concern is that vaccines might overwhelm their children’s immune systems. In a telephone survey in the USA, 23% of parents agreed with the statement ‘Children get more immunizations than are good for them’, and 25% indicated that they were concerned that their child’s immune system could be weakened by too many immunizations89. However, there is ample evidence to disprove these beliefs. Although the number of vaccines in immunization programmes has increased, the total number of antigens has actually decreased from more than 3,200 to approximately 320 as a result of discontinuing the smallpox vaccine and replacing the whole-cell pertussis vaccine with the acellular vaccine90,91. Vaccines comprise only a small fraction of the antigens that children are exposed to throughout normal life, with rapid bacterial colonization of the gastrointestinal tract after birth, multiple viral infections and environmental antigens. Moreover, multiple studies have shown that children who received vaccinations had a similar, or even reduced, risk of unconnected infections in the following period92,93,94,95. Looking at children who presented to the emergency department with infections not included in the vaccine programme, there was no difference in terms of their previous antigen exposure by vaccination96.
Significant rare side effects
Serious side effects from vaccines are very rare, with anaphylaxis being the most common of these rare side effects for parenteral vaccines, occurring after fewer than one in a million doses97. Individuals with known allergies (such as egg or latex) should avoid vaccines that may have traces of these products left over from the production process with the specific allergen, although most cases of anaphylaxis are not predictable in advance but are readily managed if vaccines are administered by trained health-care staff.
Very rare side effects of vaccines are not usually observed during clinical development, with very few documented, and they are only recognized through careful surveillance in vaccinated populations. For example, there is a very low risk of idiopathic thrombocytopenic purpura (1 in 24,000 vaccine recipients) after measles vaccination86. From 1 in 55,000 to 1 in 16,000 recipients of an AS03-adjuvanted 2009 pandemic H1N1 influenza vaccine98,99, who had a particular genetic susceptibility (HLA DQB1*0602)100, developed narcolepsy, although the debate continues about whether the trigger was the vaccine, the adjuvant or some combination, perhaps with the circulating virus also having a role.
Despite widespread misleading reporting about links between the measles–mumps–rubella vaccine and autism from the end of the 1990s, there is no evidence that any vaccines or their components cause autism101,102. Indeed, the evidence now overwhelmingly shows that there is no increased risk of autism in vaccinated populations. Thiomersal (also known as thimerosal) is an ethyl mercury-containing preservative that has been used widely in vaccines since the 1930s without any evidence of adverse events associated with it, and there is also no scientific evidence of any link between thiomersal and autism despite spurious claims about this102. Thiomersal has been voluntarily withdrawn from most vaccines by manufacturers as a precautionary measure rather than because of any scientific evidence of lack of safety and is currently used mainly in the production of whole-cell pertussis vaccines.
The risk of hospitalization, death or long-term morbidity from the diseases for which vaccines have been developed is so high that the risks of common local and systemic side effects (such as sore arm and fever) and the rare more serious side effects are far outweighed by the massive reductions in disease achieved through vaccination. Continuing assessment of vaccine safety post licensure is important for the detection of rare and longer-term side effects, and efficient reporting systems need to be in place to facilitate this103. This is particularly important in a pandemic situation, such as the COVID-19 pandemic, as rapid clinical development of several vaccines is likely to take place and large numbers of people are likely to be vaccinated within a short time.
Challenges to vaccination success
Vaccines only work if they are used. Perhaps the biggest challenge to immunization programmes is ensuring that the strong headwinds against deployment, ranging from poor infrastructure and lack of funding to vaccine hesitancy and commercial priorities, do not prevent successful protection of the most vulnerable in society. It is noteworthy that these are not classical scientific challenges, although limited knowledge about which antigens are protective, which immune responses are needed for protection and how to enhance the right immune responses, particularly in the older population, are also important considerations.
Access to vaccines
The greatest challenge for protection of the human population against serious infectious disease through vaccination remains access to vaccines and the huge associated inequity in access. Access to vaccines is currently limited, to varying degrees in different regions, by the absence of a health infrastructure to deliver vaccines, the lack of convenient vaccine provision for families, the lack of financial resources to purchase available vaccines (at a national, local or individual level) and the marginalization of communities in need. This is perhaps the most pressing issue for public health, with global vaccine coverage having stalled; for example, coverage for diphtheria–tetanus–pertussis-containing vaccines has only risen from 84% to 86% since 2010 (ref.104). However, this figure hides huge regional variation, with near 100% coverage in some areas and almost no vaccinated children in others. For the poorest countries in the world, Gavi, the Vaccine Alliance provides funding to assist with new vaccine introductions and has greatly accelerated the broadening of access to new vaccines that were previously only accessible to high-income countries. However, this still leaves major financial challenges for countries that do not meet the criteria to be eligible for Gavi funding but still cannot afford new vaccines. Inequity remains, with approximately 14 million children not receiving any vaccinations and another 5.7 million children being only partially vaccinated in 2019 (ref.105).
Other important issues can compromise vaccine availability and access. For example, most vaccines must be refrigerated at 2–8 °C, requiring the infrastructure and capacity for cold storage and a cold chain to the clinic where the vaccine is delivered, which is limited in many low-income countries. The route of administration can also limit access; oral vaccines (such as rotavirus, polio or cholera vaccines) and nasal vaccines (such as live attenuated influenza vaccine) can be delivered rapidly on a huge scale by less-skilled workers, whereas most vaccines are injected, which requires more training to administer and takes longer. Nevertheless, these hurdles can be overcome: in Sindh Province, Pakistan, 10 million doses of injected typhoid conjugate vaccine were administered to children to control an outbreak of extensively drug-resistant typhoid in just a few weeks at the end of 2019 (ref.106).
The anti-vaccination movement
Despite access being the main issue affecting global vaccine coverage, a considerable focus is currently on the challenges posed by the anti-vaccination movement, largely as a result of worrying trends of decreasing vaccine coverage in high-income settings, leading to outbreaks of life-threatening infectious diseases, such as measles. In 2018, there were 140,000 deaths from measles worldwide, and the number of cases in 2019 was the highest in any year since 2006 (ref.107). Much has been written about the dangerous role of social media and online search engines in the spread of misinformation about vaccines and the rise of the anti-vaccination movement, but scientists are also at fault for failing to effectively communicate the benefits of vaccination to a lay public. If this is to change, scientists do not need to counter or engage with the anti-vaccination movement but to use their expertise and understanding to ensure effective communication about the science that underpins our remarkable ability to harness the power of the immune system through vaccination to defend the health of our children.
A third important issue is the lack of vaccines for some diseases for which there is no commercial incentive for development. Typically, these are diseases that have a restricted geographical spread (such as Rift Valley fever, Ebola, Marburg disease or plague) or occur in sporadic outbreaks and only affect poor or displaced communities (such as Ebola and cholera). Lists of outbreak pathogens have been published by various agencies including the WHO108, and recent funding initiatives, including those from US and European governments, have increased investment in the development of orphan vaccines. The Coalition for Epidemic Preparedness Innovations (CEPI) is set to have a major role in funding and driving the development of vaccines against these pathogens.
For other pathogens, there is likely to be a commercial market but there are immunological challenges for the development of new vaccines. For example, highly variable pathogens, including some with a large global distribution such as HIV and hepatitis C virus, pose a particular challenge. The genetic diversity of these pathogens, which occurs both between and within hosts, makes it difficult to identify an antigen that can be used to immunize against infection. In the case of HIV, antibodies can be generated that neutralize the virus, but the rapid mutation of the viral genome means that the virus can evade these responses within the same host. Some individuals do produce broadly neutralizing antibodies naturally, which target more conserved regions of the virus, leading to viral control, but it is not clear how to robustly induce these antibodies with a vaccine. Indeed, several HIV vaccines have been tested in clinical trials that were able to induce antibody responses (for example, RV144 vaccine showed 31% protection109) and/or T cell responses, but these vaccines have not shown consistent evidence of protection in follow-up studies, and several studies found an increased risk of infection among vaccine recipients110.
For other pathogens, such as Neisseria gonorrhoeae (which causes gonorrhoea) and Treponema pallidum (which causes syphilis), antigenic targets for protective immune responses have not yet been determined, partly owing to limited investment and a poor understanding of the mechanisms of immunity at mucosal surfaces, or have thus far only resulted in limited protection. For example, the licensed malaria vaccine, RTSS, provides only 30–40% protection and further work is needed to develop suitable products111. New malaria vaccines in development target more conserved antigens on the parasite surface or target different stages of the parasite life cycle. Combinations of these approaches in a vaccine (perhaps targeting multiple stages of the life cycle), together with anti-vector strategies such as the use of genetically modified mosquitoes or Wolbachia bacteria to infect mosquitoes and reduce their ability to carry mosquito parasites112, as well as mosquito-bite avoidance, have the potential to markedly reduce malaria parasite transmission.
Seasonal influenza vaccines have, in recent decades, been used to protect vulnerable individuals in high-income countries, including older adults, children and individuals with co-morbidities that increase risk of severe influenza. These vaccines are made from virus that is grown in eggs; purified antigen, split virions or whole virions can be included in the final vaccine product. The vaccines take around 6 months to manufacture and have highly variable efficacy from one season to another, partly owing to the difficulty in predicting which virus strain will be circulating in the next influenza season, so that the vaccine strain may not match the strain causing disease113. Another issue that is increasingly recognized is egg adaptation, whereby the vaccine strain of virus becomes adapted to the egg used for production, leading to key mutations that mean it is not well matched to, and does not protect against, the circulating viral strain114. Vaccine-induced protection might be improved by the development of mammalian or insect cell-culture systems for growing influenza virus to avoid egg adaptation, and the use of MF59-adjuvanted vaccines and high-dose influenza vaccines to improve immune responses. Because of the cost of purchasing seasonal influenza vaccines annually, and the problem of antigenic variability, the search for a universal influenza vaccine receives considerable attention, with a particular focus on vaccines that induce TH cells or antibodies to conserved epitopes115, but there are currently no products in late-stage development.
Although BCG is the most widely used vaccine globally, with 89% of the world population receiving it in 2018 (ref.105), there is still a huge global burden of TB and it is clear that more effective TB vaccines are needed. However, the optimal characteristics of a prophylactic TB vaccine, which antigens should be included and the nature of protective immunity remain unknown, despite more than 100 years of TB vaccine research. A viral vector expressing a TB protein, 85A, has been tested in a large TB-prevention trial in South Africa but this vaccine did not show protection, which was attributed by the authors to poor immunogenicity in the vaccinated children116. However, the publication of a study in 2019 showing that a novel TB vaccine, M72/AS01E (an AS01-adjuvanted vaccine containing the M. tuberculosis antigens MTB32A and MTB39A), could limit progression to active TB disease in latently infected individuals with efficacy of 50% over 3 years gives a glimmer of hope that TB control may be realized in the future by novel vaccine approaches117. Questions remain about the duration of the effect, but the demonstrated efficacy can now be interrogated thoroughly to determine the nature of protective immunity against TB.
Future vaccine development
There are several important diseases for which new vaccines are needed to reduce morbidity and mortality globally, which are likely to have a market in both high-income and low-income countries, including vaccines for group B Streptococcus (a major cause of neonatal meningitis), RSV and CMV. Group B Streptococcus vaccines are currently in trials of maternal vaccination, with the aim of inducing maternal antibodies that cross the placenta and protect the newborn passively118. RSV causes a lower respiratory tract infection, bronchiolitis, in infancy and is the commonest cause of infant hospitalization in developed countries and globally one of the leading causes of death in those less than 12 months of age. As many as 60 new RSV vaccine candidates are in development as either maternal vaccines or infant vaccines, or involving immunization with RSV-specific monoclonal antibodies that have an extended half-life. A licensed RSV vaccine would have a huge impact on infant health and paediatric hospital admissions. CMV is a ubiquitous herpesvirus that is responsible for a significant burden of disease in infants; 15–20% of congenitally infected children develop long-term sequelae, most importantly sensorineural hearing loss, and CMV thus causes more congenital disease than any other single infectious agent. A vaccine that effectively prevents congenital infection would provide significant individual and public health benefits. A lack of understanding of the nature of protective immunity against CMV has hampered vaccine development in the past, but the pipeline is now more promising119,120.
Another major line of development of new vaccines is to combat hospital-acquired infections, particularly with antibiotic-resistant Gram-positive bacteria (such as Staphylococcus aureus) that are associated with wound infections and intravenous catheters and various Gram-negative organisms (such as Klebsiella spp. and Pseudomonas aeruginosa). Progress has been slow in this field and an important consideration will be targeting products to the at-risk patient groups before hospital admission or surgery.
Perhaps the largest area of growth for vaccine development is for older adults, with few products aimed specifically at this population currently. With the population of older adults set to increase substantially (the proportion of the population who are more than 60 years of age is expected to increase from 12% to 22% by 2050 (ref.121)), prevention of infection in this population should be a public health priority. Efforts to better understand immunosenescence and how to improve vaccine responses in the oldest adults are a major challenge for immunologists today.
Important challenges to overcome in the following years are genetic diversity (for example, of viruses such as HIV, hepatitis C virus and influenza), the requirement for a broader immune response including T cells for protection against diseases such as TB and malaria, and the need to swiftly respond to emerging pathogens and outbreak situations. Traditionally, vaccine development takes more than 10 years122, but the COVID-19 pandemic has demonstrated the urgency for vaccine technologies that are flexible and facilitate rapid development, production and upscaling123.
Novel technologies to combat these hurdles will include platforms that allow for improved antigen delivery and ease and speed of production, application of structural biology and immunological knowledge to aid enhanced antigen design and discovery of better adjuvants to improve immunogenicity. Fortunately, recent advances in immunology, systems biology, genomics and bio-informatics offer great opportunities to improve our understanding of the induction of immune responses by vaccines and to transform vaccine development through increasingly rational design124.
New platforms include viral vectored vaccines and nucleic acid-based vaccines. Antigen-presenting cells such as dendritic cells, T cell-based vaccines and bacterial vectors are being explored as well, but are still at early stages of development for use against infectious pathogens. Whereas classic whole-organism vaccine platforms require the cultivation of the pathogen, next-generation viral vectored or nucleic acid-based vaccines can be constructed using the pathogen genetic sequence only, thereby significantly increasing the speed of development and manufacturing processes125.
Viral vectored vaccines are based on a recombinant virus (either replicating or not), in which the genome is altered to express the target pathogen antigen. The presentation of pathogen antigens in combination with stimuli from the viral vector that mimic natural infection leads to the induction of strong humoral and cellular immune responses without the need for an adjuvant. A potential disadvantage of viral vectored vaccines is the presence of pre-existing immunity when a vector such as human adenovirus is used that commonly causes infection in humans. This can be overcome by using vectors such as a simian adenovirus, against which almost no pre-existing immunity exists in humans126. Whether immune responses against the vector will limit its use for repeated vaccinations with different antigens will need to be investigated.
Nucleic acid-based vaccines consist of either DNA or RNA encoding the target antigen, which potentially allows for the induction of both humoral and cellular immune responses once the encoded antigens are expressed by the vaccine recipient after uptake of the nucleic acid by their cells. A huge advantage of these vaccines is that they are highly versatile and quick and easy to adapt and produce in the case of an emerging pathogen. Indeed, the SARS-CoV-2 mRNA-based vaccine mRNA-1273 entered clinical testing just 2 months after the genetic sequence of SARS-CoV-2 was identified127 and the BNT162b2 lipid nanoparticle-formulated, nucleoside-modified RNA vaccine was the first SARS-CoV-2 vaccine to be licensed128. One of the disadvantages of these vaccines is that they need to be delivered directly into cells, which requires specific injection devices, electroporation or a carrier molecule and brings with it a risk of low transfection rate and limited immunogenicity129. Furthermore, the application of RNA vaccines has been limited by their lack of stability and requirement for a cold chain, but constant efforts to improve formulations hold promise to overcome these limitations130,131.
A beautiful example of how immunological insight can revolutionize vaccine development is the novel RSV vaccine DS-Cav1. The RSV surface fusion (F) protein can exist in either a pre-fusion (pre-F) conformation, which facilitates viral entry, or a post-fusion (post-F) form. Whereas previous vaccines mainly contained the post-F form, insight into the atomic-level structure of the protein has allowed for stable expression of the pre-F protein, leading to strongly enhanced immune responses and providing a proof of concept for structure-based vaccine design132,133.
In addition to the novel vaccine platforms mentioned above, there are ongoing efforts to develop improved methods of antigen delivery, such as liposomes (spherical lipid bilayers), polymeric particles, inorganic particles, outer membrane vesicles and immunostimulating complexes. These, and other methods such as self-assembling protein nanoparticles, have the potential to optimally enhance and skew the immune response to pathogens against which traditional vaccine approaches have proven to be unsuccessful129,134. Furthermore, innovative delivery methods, such as microneedle patches, are being developed, with the potential advantages of improved thermostability, ease of delivery with minimal pain and safer administration and disposal135. An inactivated influenza vaccine delivered by microneedle patch was shown to be well tolerated and immunogenic in a phase I trial136. This might allow for self-administration, although it would be important for professional medical care to be available if there is a risk of severe side effects such as anaphylaxis.
Conclusions and future directions
Immunization protects populations from diseases that previously claimed the lives of millions of individuals each year, mostly children. Under the United Nations Convention on the Rights of the Child, every child has the right to the best possible health, and by extrapolation a right to be vaccinated.
Despite the outstanding success of vaccination in protecting the health of our children, there are important knowledge gaps and challenges to be addressed. An incomplete understanding of immune mechanisms of protection and the lack of solutions to overcome antigenic variability have hampered the design of effective vaccines against major diseases such as HIV/AIDS and TB. Huge efforts have resulted in the licensure of a partially effective vaccine against malaria, but more effective vaccines will be needed to defeat this disease. Moreover, it is becoming clear that variation in host response is an important factor to take into account. New technologies and analytical methods will aid the delineation of the complex immune mechanisms involved, and this knowledge will be important to design effective vaccines for the future.
Apart from the scientific challenges, sociopolitical barriers stand in the way of safe and effective vaccination for all. Access to vaccines is one of the greatest obstacles, and improving infrastructure, continuing education and enhancing community engagement will be essential to improve this, and novel delivery platforms that eliminate the need for a cold chain could have great implications. There is a growing subset of the population who are sceptical about vaccination and this requires a response from the scientific community to provide transparency about the existing knowledge gaps and strategies to overcome these. Constructive collaboration between scientists and between scientific institutions, governments and industry will be imperative to move forwards. The COVID-19 pandemic has indeed shown that, in the case of an emergency, many parties with different incentives can come together to ensure that vaccines are being developed at unprecedented speed but has also highlighted some of the challenges of national and commercial interests. As immunologists, we have a responsibility to create an environment where immunization is normal, the science is accessible and robust, and access to vaccination is a right and expectation.
World Health Organization. Global vaccine action plan 2011–2020. WHO https://www.who.int/immunization/global_vaccine_action_plan/GVAP_doc_2011_2020/en/ (2013).
World Health Organization. Child mortality and causes of death. WHO https://www.who.int/gho/child_health/mortality/mortality_under_five_text/en/ (2020).
Hatherill, M., White, R. G. & Hawn, T. R. Clinical development of new TB vaccines: recent advances and next steps. Front. Microbiol. 10, 3154 (2019).
Bekker, L. G. et al. The complex challenges of HIV vaccine development require renewed and expanded global commitment. Lancet 395, 384–388 (2020).
Matz, K. M., Marzi, A. & Feldmann, H. Ebola vaccine trials: progress in vaccine safety and immunogenicity. Expert Rev. Vaccines 18, 1229–1242 (2019).
Ahmed, S. F., Quadeer, A. A. & McKay, M. R. Preliminary identification of potential vaccine targets for the COVID-19 coronavirus (SARS-CoV-2) based on SARS-CoV immunological studies. Viruses 12, 254 (2020).
Pawelec, G. Age and immunity: what is “immunosenescence”? Exp. Gerontol. 105, 4–9 (2018).
Larson, H. J. The state of vaccine confidence. Lancet 392, 2244–2246 (2018).
Robbins, J. B. et al. Prevention of invasive bacterial diseases by immunization with polysaccharide–protein conjugates. Curr. Top. Microbiol. Immunol. 146, 169–180 (1989).
Plotkin, S. A. Updates on immunologic correlates of vaccine-induced protection. Vaccine 38, 2250–2257 (2020). This paper presents a review of immune correlates of protection for specific infections, their immunological basis and relevance for vaccinology.
Rubin, L. G. et al. 2013 IDSA clinical practice guideline for vaccination of the immunocompromised host. Clin. Infect. Dis. 58, e44–e100 (2014).
Milligan, R., Paul, M., Richardson, M. & Neuberger, A. Vaccines for preventing typhoid fever. Cochrane Database Syst. Rev. 5, CD001261 (2018).
WHO. Measles vaccines: WHO position paper — April 2017. Wkly. Epidemiol. Rec. 92, 205–227 (2017).
Rappuoli, R., Mandl, C. W., Black, S. & De Gregorio, E. Vaccines for the twenty-first century society. Nat. Rev. Immunol. 11, 865–872 (2011). This paper presents a review of the role of vaccines in the twenty-first century, with an emphasis on increased life expectancy, emerging infections and poverty.
Marrack, P., McKee, A. S. & Munks, M. W. Towards an understanding of the adjuvant action of aluminium. Nat. Rev. Immunol. 9, 287–293 (2009).
Wilkins, A. L. et al. AS03- and MF59-adjuvanted influenza vaccines in children. Front. Immunol. 8, 1760 (2017).
Kaslow, D. C. & Biernaux, S. RTS,S: toward a first landmark on the Malaria Vaccine Technology Roadmap. Vaccine 33, 7425–7432 (2015).
Pedersen, C. et al. Immunization of early adolescent females with human papillomavirus type 16 and 18 L1 virus-like particle vaccine containing AS04 adjuvant. J. Adolesc. Health 40, 564–571 (2007).
Mitkus, R. J., Hess, M. A. & Schwartz, S. L. Pharmacokinetic modeling as an approach to assessing the safety of residual formaldehyde in infant vaccines. Vaccine 31, 2738–2743 (2013).
Eldred, B. E., Dean, A. J., McGuire, T. M. & Nash, A. L. Vaccine components and constituents: responding to consumer concerns. Med. J. Aust. 184, 170–175 (2006).
Fijen, C. A., Kuijper, E. J., te Bulte, M. T., Daha, M. R. & Dankert, J. Assessment of complement deficiency in patients with meningococcal disease in The Netherlands. Clin. Infect. Dis. 28, 98–105 (1999).
Wara, D. W. Host defense against Streptococcus pneumoniae: the role of the spleen. Rev. Infect. Dis. 3, 299–309 (1981).
Gershon, A. A. et al. Varicella zoster virus infection. Nat. Rev. Dis. Prim. 1, 15016 (2015).
Sandmann, F. et al. Infant hospitalisations and fatalities averted by the maternal pertussis vaccination programme in England, 2012–2017: post-implementation economic evaluation. Clin. Infect. Dis. 71, 1984–1987 (2020).
Demicheli, V., Barale, A. & Rivetti, A. Vaccines for women for preventing neonatal tetanus. Cochrane Database Syst. Rev. 7, CD002959 (2015).
Madhi, S. A. et al. Influenza vaccination of pregnant women and protection of their infants. N. Engl. J. Med. 371, 918–931 (2014).
Madhi, S. A. & Dangor, Z. Prospects for preventing infant invasive GBS disease through maternal vaccination. Vaccine 35, 4457–4460 (2017).
Madhi, S. A. et al. Respiratory syncytial virus vaccination during pregnancy and effects in infants. N. Engl. J. Med. 383, 426–439 (2020).
Young, M. K. & Cripps, A. W. Passive immunization for the public health control of communicable diseases: current status in four high-income countries and where to next. Hum. Vaccin. Immunother. 9, 1885–1893 (2013).
Patel, M. & Lee, C. K. Polysaccharide vaccines for preventing serogroup A meningococcal meningitis. Cochrane Database Syst. Rev. 3, CD001093 (2005).
Moberley, S., Holden, J., Tatham, D. P. & Andrews, R. M. Vaccines for preventing pneumococcal infection in adults. Cochrane Database Syst. Rev. 1, CD000422 (2013).
Andrews, N. J. et al. Serotype-specific effectiveness and correlates of protection for the 13-valent pneumococcal conjugate vaccine: a postlicensure indirect cohort study. Lancet Infect. Dis. 14, 839–846 (2014).
Borrow, R., Abad, R., Trotter, C., van der Klis, F. R. & Vazquez, J. A. Effectiveness of meningococcal serogroup C vaccine programmes. Vaccine 31, 4477–4486 (2013).
Ramsay, M. E., McVernon, J., Andrews, N. J., Heath, P. T. & Slack, M. P. Estimating haemophilus influenzae type b vaccine effectiveness in England and Wales by use of the screening method. J. Infect. Dis. 188, 481–485 (2003).
Pollard, A. J., Perrett, K. P. & Beverley, P. C. Maintaining protection against invasive bacteria with protein-polysaccharide conjugate vaccines. Nat. Rev. Immunol. 9, 213–220 (2009). This paper presents a review of the mechanism of action of polysaccharide vaccines and their role in establishing long-term protection against invasive bacteria.
Darton, T. C. et al. Design, recruitment, and microbiological considerations in human challenge studies. Lancet Infect. Dis. 15, 840–851 (2015). This paper presents an overview of human challenge models, their potential use and their role in improving our understanding of disease mechanisms and host responses.
Suscovich, T. J. et al. Mapping functional humoral correlates of protection against malaria challenge following RTS, S/AS01 vaccination. Sci. Transl Med. 12, eabb4757 (2020).
Jin, C. et al. Efficacy and immunogenicity of a Vi–tetanus toxoid conjugate vaccine in the prevention of typhoid fever using a controlled human infection model of Salmonella Typhi: a randomised controlled, phase 2b trial. Lancet 390, 2472–2480 (2017).
Kourtis, A. P., Read, J. S. & Jamieson, D. J. Pregnancy and infection. N. Engl. J. Med. 370, 2211–2218 (2014).
Malley, R. et al. CD4+ T cells mediate antibody-independent acquired immunity to pneumococcal colonization. Proc. Natl Acad. Sci. USA 102, 4848–4853 (2005).
Henry, B. & Baclic, O. & National Advisory Committee on Immunization (NACI). Summary of the NACI update on the recommended use of hepatitis B vaccine. Can. Commun. Dis. Rep. 43, 104–106 (2017).
Kelly, D. F., Pollard, A. J. & Moxon, E. R. Immunological memory: the role of B cells in long-term protection against invasive bacterial pathogens. JAMA 294, 3019–3023 (2005).
McVernon, J., Johnson, P. D., Pollard, A. J., Slack, M. P. & Moxon, E. R. Immunologic memory in Haemophilus influenzae type b conjugate vaccine failure. Arch. Dis. Child. 88, 379–383 (2003).
McVernon, J. et al. Immunologic memory with no detectable bactericidal antibody response to a first dose of meningococcal serogroup C conjugate vaccine at four years. Pediatr. Infect. Dis. J. 22, 659–661 (2003).
World Health Organization. Tetanus vaccines: WHO position paper, February 2017 — recommendations. Vaccine 36, 3573–3575 (2018).
World Health Organization. Diphtheria vaccine: WHO position paper, August 2017 — recommendations. Vaccine 36, 199–201 (2018).
Chen, Z. & He, Q. Immune persistence after pertussis vaccination. Hum. Vaccin. Immunother. 13, 744–756 (2017).
Burdin, N., Handy, L. K. & Plotkin, S. A. What is wrong with pertussis vaccine immunity? The problem of waning effectiveness of pertussis vaccines. Cold Spring Harb. Perspect. Biol. 9, a029454 (2017).
WHO. Vaccines and vaccination against yellow fever: WHO Position Paper, June 2013 — recommendations. Vaccine 33, 76–77 (2015).
Paunio, M. et al. Twice vaccinated recipients are better protected against epidemic measles than are single dose recipients of measles containing vaccine. J. Epidemiol. Community Health 53, 173–178 (1999).
Zhu, S., Zeng, F., Xia, L., He, H. & Zhang, J. Incidence rate of breakthrough varicella observed in healthy children after 1 or 2 doses of varicella vaccine: results from a meta-analysis. Am. J. Infect. Control. 46, e1–e7 (2018).
Halstead, S. B., Rojanasuphot, S. & Sangkawibha, N. Original antigenic sin in dengue. Am. J. Trop. Med. Hyg. 32, 154–156 (1983).
Kim, J. H., Skountzou, I., Compans, R. & Jacob, J. Original antigenic sin responses to influenza viruses. J. Immunol. 183, 3294–3301 (2009).
Vatti, A. et al. Original antigenic sin: a comprehensive review. J. Autoimmun. 83, 12–21 (2017).
Statista Research Department. Herd immunity threshold for selected global diseases as of 2013. Statista https://www.statista.com/statistics/348750/threshold-for-herd-immunity-for-select-diseases/ (2013).
Plans-Rubio, P. The vaccination coverage required to establish herd immunity against influenza viruses. Prev. Med. 55, 72–77 (2012).
Trotter, C. L., Andrews, N. J., Kaczmarski, E. B., Miller, E. & Ramsay, M. E. Effectiveness of meningococcal serogroup C conjugate vaccine 4 years after introduction. Lancet 364, 365–367 (2004).
Trotter, C. L. & Maiden, M. C. Meningococcal vaccines and herd immunity: lessons learned from serogroup C conjugate vaccination programs. Expert. Rev. Vaccines 8, 851–861 (2009).
Tabrizi, S. N. et al. Assessment of herd immunity and cross-protection after a human papillomavirus vaccination programme in Australia: a repeat cross-sectional study. Lancet Infect. Dis. 14, 958–966 (2014).
Brisson, M. et al. Population-level impact, herd immunity, and elimination after human papillomavirus vaccination: a systematic review and meta-analysis of predictions from transmission-dynamic models. Lancet Public Health 1, e8–e17 (2016).
Trunz, B. B., Fine, P. & Dye, C. Effect of BCG vaccination on childhood tuberculous meningitis and miliary tuberculosis worldwide: a meta-analysis and assessment of cost-effectiveness. Lancet 367, 1173–1180 (2006).
Barker, L. & Hussey, G. The Immunological Basis for Immunization Series: Module 5: Tuberculosis (World Health Organization, 2011).
Eisenhut, M. et al. BCG vaccination reduces risk of infection with Mycobacterium tuberculosis as detected by γ interferon release assay. Vaccine 27, 6116–6120 (2009).
Verrall, A. J. et al. Early clearance of Mycobacterium tuberculosis: the INFECT case contact cohort study in Indonesia. J. Infect. Dis. 221, 1351–1360 (2020).
Pollard, A. J., Finn, A. & Curtis, N. Non-specific effects of vaccines: plausible and potentially important, but implications uncertain. Arch. Dis. Child. 102, 1077–1081 (2017).
Higgins, J. P. et al. Association of BCG, DTP, and measles containing vaccines with childhood mortality: systematic review. BMJ 355, i5170 (2016).
Mina, M. J. et al. Measles virus infection diminishes preexisting antibodies that offer protection from other pathogens. Science 366, 599–606 (2019).
Mina, M. J., Metcalf, C. J., de Swart, R. L., Osterhaus, A. D. & Grenfell, B. T. Long-term measles-induced immunomodulation increases overall childhood infectious disease mortality. Science 348, 694–699 (2015). This paper is an analysis of population-level data from high-income countries, showing a protective effect of measles vaccination on mortality from non-measles infectious diseases.
Falsey, A. R., Treanor, J. J., Tornieporth, N., Capellan, J. & Gorse, G. J. Randomized, double-blind controlled phase 3 trial comparing the immunogenicity of high-dose and standard-dose influenza vaccine in adults 65 years of age and older. J. Infect. Dis. 200, 172–180 (2009).
DiazGranados, C. A. et al. Efficacy of high-dose versus standard-dose influenza vaccine in older adults. N. Engl. J. Med. 371, 635–645 (2014).
Schnyder, J. L. et al. Fractional dose of intradermal compared to intramuscular and subcutaneous vaccination—a systematic review and meta-analysis. Travel. Med. Infect. Dis. 37, 101868 (2020).
Voysey, M. et al. The influence of maternally derived antibody and infant age at vaccination on infant vaccine responses: an individual participant meta-analysis. JAMA Pediatr. 171, 637–646 (2017).
Caceres, V. M., Strebel, P. M. & Sutter, R. W. Factors determining prevalence of maternal antibody to measles virus throughout infancy: a review. Clin. Infect. Dis. 31, 110–119 (2000).
Belnoue, E. et al. APRIL is critical for plasmablast survival in the bone marrow and poorly expressed by early-life bone marrow stromal cells. Blood 111, 2755–2764 (2008).
Pace, D. et al. Immunogenicity of reduced dose priming schedules of serogroup C meningococcal conjugate vaccine followed by booster at 12 months in infants: open label randomised controlled trial. BMJ 350, h1554 (2015).
Timens, W., Boes, A., Rozeboom-Uiterwijk, T. & Poppema, S. Immaturity of the human splenic marginal zone in infancy. Possible contribution to the deficient infant immune response. J. Immunol. 143, 3200–3206 (1989).
Peset Llopis, M. J., Harms, G., Hardonk, M. J. & Timens, W. Human immune response to pneumococcal polysaccharides: complement-mediated localization preferentially on CD21-positive splenic marginal zone B cells and follicular dendritic cells. J. Allergy Clin. Immunol. 97, 1015–1024 (1996).
Claesson, B. A. et al. Protective levels of serum antibodies stimulated in infants by two injections of Haemophilus influenzae type b capsular polysaccharide–tetanus toxoid conjugate. J. Pediatr. 114, 97–100 (1989).
Crooke, S. N., Ovsyannikova, I. G., Poland, G. A. & Kennedy, R. B. Immunosenescence and human vaccine immune responses. Immun. Ageing 16, 25 (2019).
Nikolich-Žugich, J. Ageing and life-long maintenance of T-cell subsets in the face of latent persistent infections. Nat. Rev. Immunol. 8, 512–522 (2008).
Kadambari, S., Klenerman, P. & Pollard, A. J. Why the elderly appear to be more severely affected by COVID-19: the potential role of immunosenescence and CMV. Rev. Med. Virol. 30, e2144 (2020).
Domnich, A. et al. Effectiveness of MF59-adjuvanted seasonal influenza vaccine in the elderly: a systematic review and meta-analysis. Vaccine 35, 513–520 (2017).
Lal, H. et al. Efficacy of an adjuvanted herpes zoster subunit vaccine in older adults. N. Engl. J. Med. 372, 2087–2096 (2015).
World Health Assembly. The Expanded Programme on Immunization: the 1974 resolution by the World Health Assembly. Assign. Child. 69-72, 87–88 (1985).
Voysey, M., Pollard, A. J., Sadarangani, M. & Fanshawe, T. R. Prevalence and decay of maternal pneumococcal and meningococcal antibodies: a meta-analysis of type-specific decay rates. Vaccine 35, 5850–5857 (2017).
Farrington, P. et al. A new method for active surveillance of adverse events from diphtheria/tetanus/pertussis and measles/mumps/rubella vaccines. Lancet 345, 567–569 (1995).
Pinto, M. V., Bihari, S. & Snape, M. D. Immunisation of the immunocompromised child. J. Infect. 72 (Suppl), S13–S22 (2016).
Seligman, S. J. Risk groups for yellow fever vaccine-associated viscerotropic disease (YEL-AVD). Vaccine 32, 5769–5775 (2014).
Gellin, B. G., Maibach, E. W. & Marcuse, E. K. Do parents understand immunizations? A national telephone survey. Pediatrics 106, 1097–1102 (2000).
Offit, P. A. et al. Addressing parents’ concerns: do multiple vaccines overwhelm or weaken the infant’s immune system? Pediatrics 109, 124–129 (2002).
Centers for Disease Control and Prevention. Multiple vaccinations at once. CDC https://www.cdc.gov/vaccinesafety/concerns/multiple-vaccines-immunity.html (2020).
Stowe, J., Andrews, N., Taylor, B. & Miller, E. No evidence of an increase of bacterial and viral infections following measles, mumps and rubella vaccine. Vaccine 27, 1422–1425 (2009).
Otto, S. et al. General non-specific morbidity is reduced after vaccination within the third month of life — the Greifswald study. J. Infect. 41, 172–175 (2000).
Griffin, M. R., Taylor, J. A., Daugherty, J. R. & Ray, W. A. No increased risk for invasive bacterial infection found following diphtheria–tetanus–pertussis immunization. Pediatrics 89, 640–642 (1992).
Aaby, P. et al. Non-specific beneficial effect of measles immunisation: analysis of mortality studies from developing countries. BMJ 311, 481–485 (1995).
Glanz, J. M. et al. Association between estimated cumulative vaccine antigen exposure through the first 23 months of life and non-vaccine-targeted infections from 24 through 47 months of age. JAMA 319, 906–913 (2018).
Bohlke, K. et al. Risk of anaphylaxis after vaccination of children and adolescents. Pediatrics 112, 815–820 (2003).
Nohynek, H. et al. AS03 adjuvanted AH1N1 vaccine associated with an abrupt increase in the incidence of childhood narcolepsy in Finland. PLoS ONE 7, e33536 (2012).
Miller, E. et al. Risk of narcolepsy in children and young people receiving AS03 adjuvanted pandemic A/H1N1 2009 influenza vaccine: retrospective analysis. BMJ 346, f794 (2013).
Hallberg, P. et al. Pandemrix-induced narcolepsy is associated with genes related to immunity and neuronal survival. EBioMedicine 40, 595–604 (2019).
DeStefano, F. & Shimabukuro, T. T. The MMR vaccine and autism. Annu. Rev. Virol. 6, 585–600 (2019).
DeStefano, F., Bodenstab, H. M. & Offit, P. A. Principal controversies in vaccine safety in the United States. Clin. Infect. Dis. 69, 726–731 (2019).
Moro, P. L., Haber, P. & McNeil, M. M. Challenges in evaluating post-licensure vaccine safety: observations from the Centers for Disease Control and Prevention. Expert Rev. Vaccines 18, 1091–1101 (2019).
Peck, M. et al. Global routine vaccination coverage, 2018. MMWR Morb. Mortal. Wkly. Rep. 68, 937–942 (2019).
World Health Organization. Immunization coverage. WHO https://www.who.int/news-room/fact-sheets/detail/immunization-coverage (2020).
World Health Organization. More than 9.4 million children vaccinated against typhoid fever in Sindh. WHO http://www.emro.who.int/pak/pakistan-news/more-than-94-children-vaccinated-with-typhoid-conjugate-vaccine-in-sindh.html (2019).
World Health Organization. More than 140,000 die from measles as cases surge worldwide. WHO https://www.who.int/news-room/detail/05-12-2019-more-than-140-000-die-from-measles-as-cases-surge-worldwide (2019).
World Health Organization. Disease outbreaks. WHO https://www.who.int/emergencies/diseases/en/ (2020).
Rerks-Ngarm, S. et al. Vaccination with ALVAC and AIDSVAX to prevent HIV-1 infection in Thailand. N. Engl. J. Med. 361, 2209–2220 (2009).
Fauci, A. S., Marovich, M. A., Dieffenbach, C. W., Hunter, E. & Buchbinder, S. P. Immunology. Immune activation with HIV vaccines. Science 344, 49–51 (2014).
Agnandji, S. T. et al. A phase 3 trial of RTS,S/AS01 malaria vaccine in African infants. N. Engl. J. Med. 367, 2284–2295 (2012).
Killeen, G. F. et al. Developing an expanded vector control toolbox for malaria elimination. BMJ Glob. Health 2, e000211 (2017).
Osterholm, M. T., Kelley, N. S., Sommer, A. & Belongia, E. A. Efficacy and effectiveness of influenza vaccines: a systematic review and meta-analysis. Lancet Infect. Dis. 12, 36–44 (2012).
Skowronski, D. M. et al. Low 2012–13 influenza vaccine effectiveness associated with mutation in the egg-adapted H3N2 vaccine strain not antigenic drift in circulating viruses. PLoS ONE 9, e92153 (2014).
Raymond, D. D. et al. Conserved epitope on influenza-virus hemagglutinin head defined by a vaccine-induced antibody. Proc. Natl Acad. Sci. USA 115, 168–173 (2018).
Tameris, M. D. et al. Safety and efficacy of MVA85A, a new tuberculosis vaccine, in infants previously vaccinated with BCG: a randomised, placebo-controlled phase 2b trial. Lancet 381, 1021–1028 (2013).
Tait, D. R. et al. Final analysis of a trial of M72/AS01(E) vaccine to prevent tuberculosis. N. Engl. J. Med. 381, 2429–2439 (2019).
Kobayashi, M. et al. WHO consultation on group B streptococcus vaccine development: report from a meeting held on 27–28 April 2016. Vaccine 37, 7307–7314 (2019).
Inoue, N., Abe, M., Kobayashi, R. & Yamada, S. Vaccine development for cytomegalovirus. Adv. Exp. Med. Biol. 1045, 271–296 (2018).
Schleiss, M. R., Permar, S. R. & Plotkin, S. A. Progress toward development of a vaccine against congenital cytomegalovirus infection. Clin. Vaccine Immunol. 24, e00268–e00317 (2017).
World Health Organization. Ageing and health. WHO https://www.who.int/news-room/fact-sheets/detail/ageing-and-health (2018).
Rauch, S., Jasny, E., Schmidt, K. E. & Petsch, B. New vaccine technologies to combat outbreak situations. Front. Immunol. 9, 1963 (2018).
Jeyanathan, M. et al. Immunological considerations for COVID-19 vaccine strategies. Nat. Rev. Immunol. 20, 615–632 (2020). This paper is an overview of COVID-19 vaccine development, with emphasis on underlying immunological mechanisms and potential scenarios for global development.
Koff, W. C. & Schenkelberg, T. The future of vaccine development. Vaccine 38, 4485–4486 (2020).
van Riel, D. & de Wit, E. Next-generation vaccine platforms for COVID-19. Nat. Mater. 19, 810–812 (2020).
Rollier, C. S., Reyes-Sandoval, A., Cottingham, M. G., Ewer, K. & Hill, A. V. Viral vectors as vaccine platforms: deployment in sight. Curr. Opin. Immunol. 23, 377–382 (2011).
Corbett, K. S. et al. SARS-CoV-2 mRNA vaccine design enabled by prototype pathogen preparedness. Nature 586, 567–571 (2020).
Polack, F. P. et al. Safety and efficacy of the BNT162b2 mRNA Covid-19 vaccine. N. Engl. J. Med. https://doi.org/10.1056/NEJMoa2034577 (2020).
Wallis, J., Shenton, D. P. & Carlisle, R. C. Novel approaches for the design, delivery and administration of vaccine technologies. Clin. Exp. Immunol. 196, 189–204 (2019).
Zhang, C., Maruggi, G., Shan, H. & Li, J. Advances in mRNA vaccines for infectious diseases. Front. Immunol. 10, 594 (2019).
Pardi, N., Hogan, M. J., Porter, F. W. & Weissman, D. mRNA vaccines — a new era in vaccinology. Nat. Rev. Drug Discov. 17, 261–279 (2018).
Crank, M. C. et al. A proof of concept for structure-based vaccine design targeting RSV in humans. Science 365, 505–509 (2019). This paper presents a phase I trial demonstrating enhanced immunogenicity of the pre-F conformation of RSV surface protein, thereby providing a proof of concept for successful structure-based vaccine design.
Mascola, J. R. & Fauci, A. S. Novel vaccine technologies for the 21st century. Nat. Rev. Immunol. 20, 87–88 (2020).
Kanekiyo, M., Ellis, D. & King, N. P. New vaccine design and delivery technologies. J. Infect. Dis. 219, S88–S96 (2019).
Peyraud, N. et al. Potential use of microarray patches for vaccine delivery in low- and middle-income countries. Vaccine 37, 4427–4434 (2019).
Rouphael, N. G. et al. The safety, immunogenicity, and acceptability of inactivated influenza vaccine delivered by microneedle patch (TIV-MNP 2015): a randomised, partly blinded, placebo-controlled, phase 1 trial. Lancet 390, 649–658 (2017).
Davenport, R. J., Satchell, M. & Shaw-Taylor, L. M. W. The geography of smallpox in England before vaccination: a conundrum resolved. Soc. Sci. Med. 206, 75–85 (2018).
The authors thank all those whose work in the development, policy and delivery of vaccines underpins immunization programmes to defend our health and the health of our children.
A.J.P. is Chair of the UK Department of Health and Social Care’s (DHSC) Joint Committee on Vaccination and Immunisation (JCVI), a member of the World Health Organization (WHO) Strategic Advisory Group of Experts on Immunization (SAGE) and a National Institute for Health Research (NIHR) Senior Investigator. The views expressed in this article do not necessarily represent the views of the DHSC, JCVI, NIHR or WHO. E.M.B. declares no competing interests. Oxford University has entered into a partnership with AstraZeneca for the development of a viral vectored coronavirus vaccine.
Peer review information
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.
Advisory Committee on Immunization Practices (ACIP): https://www.cdc.gov/vaccines/acip/index.html
Coalition for Epidemic Preparedness Innovations (CEPI): https://cepi.net/
Gavi, the Vaccine Alliance: https://www.gavi.org/
Joint Committee on Vaccination and Immunisation (JCVI): https://www.gov.uk/government/groups/joint-committee-on-vaccination-and-immunisation
Nature Milestones in Vaccines: https://www.nature.com/immersive/d42859-020-00005-8/index.html
The Green Book, information for public health professionals on immunisation, Public Health England: https://www.gov.uk/government/collections/immunisation-against-infectious-disease-the-green-book
Vaccine Knowledge Project: https://vk.ovg.ox.ac.uk/vk/
Vaccines 101: How new vaccines are developed: https://www.youtube.com/watch?v=2t_mQwTY4WQ&feature=emb_logo
Vaccines 101: How vaccines work: https://www.youtube.com/watch?v=4SKmAlQtAj8&feature=emb_logo
Parts of the pathogen (such as proteins or polysaccharides) that are recognized by the immune system and can be used to induce an immune response by vaccination.
The state in which an individual does not develop disease after being exposed to a pathogen.
A reduction in the virulence of a pathogen (through either deliberate or natural changes in virulence genes).
- Virus-like particles
Particles constructed of viral proteins that structurally mimic the native virus but lack the viral genome.
An agent used in a vaccine to enhance the immune response against the antigen.
- Danger signals
Molecules that stimulate a more robust immune response together with an antigen. Endogenous mediators that are released in response to infection or injury and that interact with pattern recognition receptors such as Toll-like receptors to activate innate immune cells such as dendritic cells.
- Innate immune system
The evolutionarily primitive part of the immune system that detects foreign antigens in a non-specific manner.
A liposome-based adjuvant containing 3-O-desacyl-4′-monophosphoryl lipid A and the saponin QS-21. AS01 triggers the innate immune system immediately after vaccination, resulting in an enhanced adaptive immune response.
An adjuvant consisting of aluminium salt and the Toll-like receptor agonist monophosphoryl lipid A.
- Complement system
A network of proteins that form an important part of the immune response by enhancing the opsonization of pathogens, cell lysis and inflammation.
A state of a pathogen in which antibodies or complement factors are bound to its surface.
- Opsonophagocytic antibodies
Antibodies that bind to a pathogen, which subsequently can be eliminated by phagocytosis.
- T cell-independent antigens
Antigens against which B cells can mount an antibody response without T cell help.
- T cell-dependent antigen
An antigen for which T cell help is required in order for B cells to mount an antibody response.
- Human challenge studies
Studies in which volunteers are deliberately infected with a pathogen, in a carefully conducted study, to evaluate the biology of infection and the efficacy of drugs and vaccines.
- Immune memory
The capacity of the immune system to respond quicker and more effectively when a pathogen is encountered again after an initial exposure that induced antigen-specific B cells and T cells.
- Incubation period
The period from acquisition of a pathogen to the development of symptomatic disease.
- Booster doses
Repeat administration of a vaccine after an initial priming dose, given in order to enhance the immune response.
- Interferon-γ release assay
An assay in which blood is stimulated with Mycobacterium tuberculosis antigens, after which levels of interferon-γ (produced by specific memory T cells if these are present) are measured.
- Epigenetic changes
Changes in the expression of genes that do not result from changes in DNA sequence.
A severe and potentially life-threatening reaction to an allergen.
- Parenteral vaccines
Vaccines that are administered by means avoiding the gastrointestinal tract (for example, by intramuscular, subcutaneous or intradermal routes).
- Idiopathic thrombocytopenic purpura
An acquired autoimmune condition characterized by low levels of platelets in the blood caused by antibodies to platelet antigens.
A rare chronic sleep disorder characterized by extreme sleepiness during the day and sudden sleep attacks.
- Orphan vaccines
Vaccines that are intended for a limited scope or targeting infections that are rare, as a result of which development costs exceed their market potential.
- Outer membrane vesicles
Blebs made from the outer membrane of Gram-negative bacteria, containing the surface proteins and lipids of the organism in the membrane.
About this article
Cite this article
Pollard, A.J., Bijker, E.M. A guide to vaccinology: from basic principles to new developments. Nat Rev Immunol 21, 83–100 (2021). https://doi.org/10.1038/s41577-020-00479-7
Nature Reviews Drug Discovery (2021)
Supplementary Therapeutic Possibilities to Alleviate Myocardial Damage Due to Microvascular Dysfunction in Coronavirus Disease 2019 (COVID-19)
Cardiology and Therapy (2021)
Pneumo News (2021)
Advances in Therapy (2021)
Immunologically relevant aspects of the new COVID-19 vaccines—an ÖGAI (Austrian Society for Allergology and Immunology) and AeDA (German Society for Applied Allergology) position paper
Allergo Journal International (2021)