Abstract
Currently, aluminum salts and MF59 are the only vaccine adjuvants approved for human use. With the development of new-generation vaccines (including recombinant subunit and mucosal vaccines) that are less immunogenic, the search for more potent vaccine adjuvants has intensified. Of the novel compounds recently evaluated in human trials, immunostimulatory molecules such as the lipopolysaccharide derived MPL and the saponin derivative QS21 appear most promising, although doubts have been raised as to their safety in humans. Preclinical work with particulate adjuvants, such as the MF59 microemulsion and lipid–particle immune-stimulating complexes (Iscoms), suggest that these molecules are also potent elicitors of humoral and cellular immune responses. In addition, preclinical data on CpG oligonucleotides appear to be encouraging, particularly with respect to their ability to selectively manipulate immune responses. While all these adjuvants show promise, further work is needed to better define the mechanisms of adjuvant action. Ultimately, the development of more potent adjuvants may allow vaccines to be used as therapeutic, rather than prophylactic, agents.
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Vaccines have traditionally consisted of live attenuated pathogens, whole inactivated organisms, or inactivated toxins. Although these have proved successful in the past, several drawbacks have limited their use against more challenging diseases such as hepatitis C or AIDS. First, certain live-attenuated vaccines can cause disease in immunosuppressed individuals by reverting to a more virulent phenotype. Second, whole inactivated vaccines (e.g., Bordetella pertussis) contain reactogenic components that can cause undesirable side effects. Third, some pathogens are difficult or even impossible to grow in culture (e.g., hepatitis B, hepatitis C, and human papillomavirus), making preparation of a vaccine problematic.
In the past decade, several new approaches to vaccine development have emerged that may have significant advantages over traditional approaches. These new approaches include recombinant protein subunits, synthetic peptides, and plasmid DNA. Although they offer advantages such as reduced toxicity, they are poorly immunogenic when administered alone. This is particularly true for vaccines based on recombinant proteins or peptides. Traditional vaccines are heterogeneous and contain many epitopes, some of which can provide additional T-cell help or function as adjuvants (e.g., bacterial DNA in whole-cell vaccines). Therefore, a great need exists for immunological adjuvants that are potent, safe, and compatible with new-generation vaccines, including DNA vaccines.
Immunological adjuvants were originally described by Ramon1 as "substances used in combination with a specific antigen that produce more immunity than the antigen alone." This broad definition encompasses a very wide range of materials2. However, despite extensive evaluation over many years, the only adjuvants currently approved by the US Food & Drug Administration (Rockville, MD) are aluminum-based mineral salts (generically called alum). Alum has a good safety record, but comparative studies show that it is a weak adjuvant for antibody induction to protein subunits and a poor adjuvant for cell-mediated immunity3. Moreover, alum adjuvants can induce immunoglobulin E (IgE) antibody responses and have been associated with some allergic reactions in human subjects3,4.
The most important issue in adjuvant development is safety, which has restricted the development of adjuvants since alum was first introduced more than 50 years ago5. Many experimental adjuvants have advanced to clinical trials and some have demonstrated high potency, but most have proved too toxic for routine clinical use. For standard prophylactic immunization in healthy individuals, only adjuvants that induce minimal side effects will prove acceptable. In contrast, for adjuvants that are designed to be used in life-threatening situations (e.g., cancer), the acceptable level of adverse events is likely to be higher. Additional issues that are important for adjuvant development include biodegradability, stability, ease of manufacture, cost, and applicability to a wide range of vaccines. Ideally, for ease of administration and patient compliance, an adjuvant should allow a vaccine to be given by a mucosal route. Examples of adjuvants that have been evaluated in clinical trials are shown in Table 1. Although the mechanisms of action of adjuvants are often poorly understood2,5, they can be broadly classified on the basis of their principal mode of action. However, these classifications become more arbitrary as immunostimulatory adjuvants are added to vaccine delivery systems and adjuvants are combined in single formulations.
The role of adjuvants in vaccine development
Adjuvants can be used to improve the immune response to vaccine antigens in many different ways: they can increase the immunogenicity of weak antigens; they can be used to enhance the speed and duration of the immune response; they can modulate antibody avidity, specificity, isotype, or subclass distribution; they can stimulate cell-mediated immunity; they can promote the induction of mucosal immunity; they can enhance immune responses in immunologically immature, or senescent individuals; they can decrease the dose of antigen and reduce vaccine costs; or they can help overcome antigen competition in combination vaccines.
The mechanisms of adjuvant action are currently only poorly understood, which has hampered rational design of new adjuvant compounds. Immunization often activates several complex cascades of immune effectors, only some of which are relevant to the induction of an antigen-specific response. Often, ascertaining the exact effectors enhanced by a particular adjuvant is difficult to clearly define in vivo.
That said, adjuvants can mediate their effects by any of the following mechanisms: increasing cellular infiltration, inflammation, and trafficking to the injection site—particularly for antigen-presenting cells (APCs); promoting the activation state of APCs by upregulating costimulatory signals or major histocompatibility complex (MHC) expression; enhancing antigen presentation; or inducing cytokine release for indirect effects. The most appropriate adjuvant for a given vaccine antigen will depend to a large extent on the type of immune response that is required for protective immunity. However, for many infectious diseases, the types of responses required for protective immunity have yet to be established. Unfortunately, in these situations, adjuvant selection becomes somewhat empirical.
A simplified representation of the immune response to an injected vaccine antigen is shown in Figure 1. Two major subsets of CD4+ T cells (T-helper 1 [Th1] and Th2) have been identified in mouse and human, based on their secretion of different cytokine patterns6,7,8. Th1 responses are typically characterized by the induction of delayed-type hypersensitivity responses, and secretion of interferon-Îł (IFN-Îł), interleukin 2 (IL-2), and IL-12. In contrast, Th2 responses are characterized by the induction of circulating or secretory antibodies and the secretion of IL-4, IL-5, IL-6, and IL-10. The different cytokine secretion patterns are mutually antagonistic, and upregulation of one type of response normally results in downregulation of the alternative. In mice, the production of the IgG2a antibody isotype is widely recognized as characteristic of a Th1 response9, whereas a Th2 response is associated with the induction of IgG1.
Although different adjuvants may induce comparable levels of functional antibodies, the respective cytokine profiles and antibody isotypes may differ (M. Singh, D. O'Hagan, unpublished data). In certain situations, the type of response induced (Th1 or Th2) may have a significant impact on the protective efficacy of a vaccine. Alternative adjuvants do tend to favor specific types of responses, and this may provide some degree of guidance in adjuvant selection. However, adjuvant choice is complicated by commercial constraints and availability. In addition, some adjuvants need to be manufactured using specialized techniques and equipment that are not generally available or suitable for all antigens (e.g., see Iscoms below).
Immunostimulatory adjuvants
Immunostimulatory adjuvants are thought to exert their effects predominantly at the cytokine level through the activation of MHC molecules, through costimulatory signals, or through related intracellular signaling pathways. One class of immunostimulatory adjuvants is derived from the lipopolysaccharide (LPS) of Gram-negative bacteria. The most extensively evaluated member of this family, monophosphoryl Lipid A (MPL), is obtained from Salmonella minnesota. Although the mechanism of action of MPL has not been clearly defined, it is likely to be similar to LPS. Recent evidence suggests that LPS-mediated immune activation occurs as a consequence of the interaction of LPS with toll-like receptors (TLR), following binding to soluble serum factors, including CD1410,11,12. Human TLR2 is involved in activation by LPS11,12 and triggers cells to produce proinflammatory cytokines via NF-ÎşB, an important element of the response of the innate immune system to infection.
In several preclinical studies, MPL has been shown to induce the synthesis and release of cytokines, particularly IFN-Îł, which promotes the generation of Th1 responses13,14. As a single adjuvant, MPL does not appear to be very potent for antibody induction, although it appears effective for the induction of CD4+ T-cell mediated immunity. Clinically, MPL has often been used in complex formulations, including liposomes and emulsions, and has also been used in adjuvant combinations with alum and QS2115. One problem with such combination studies is that it is difficult to discriminate the contribution of MPL to the overall adjuvant effect. Not only has MPL been clinically evaluated in more than 10,000 subjects (T. Ulrich, personal communication) combined with vaccines for both cancer (melanoma and breast) and infectious disease vaccines (herpes, hepatitis B virus, malaria, or human papilloma virus), with an acceptable profile of adverse effects, but it has also been used as an adjuvant for DNA vaccines16.
A second group of immunostimulatory adjuvants are the triterpenoid glycosides, or saponins, derived from Quillaja saponaria (Chilean soap bark tree). Saponins have been used as adjuvants for many years in veterinary vaccines. However, they are surface-active agents and cause hemolysis of red blood cells in vitro, although hemolysis does not appear to correlate with adjuvant activity17. In 1995, Kensil and colleagues18 isolated a pure fraction of Quil A saponin with low toxicity (QS21) and defined the structural moieties responsible for adjuvant activity. QS21 has been shown to be a potent adjuvant for cytotoxic T-lymphocyte (CTL) induction, inducing Th1 cytokines (IL-2 and IFN-Îł) and antibodies of the IgG2a isotype17.
Saponins have been shown to intercalate into cell membranes, through interaction with cholesterol, forming pores19. Although it is not known whether the adjuvant effect of saponins is related to pore formation, this seems a likely means to allow antigens to gain access to the cytoplasm for CTL induction. A number of clinical trials have been performed using QS21 as an adjuvant, initially for cancer vaccines (melanoma, breast, and prostate) and subsequently for infectious diseases (HIV-1, influenza, herpes, malaria, or hepatitis B)20. Doses of 200 ÎĽg or higher of QS21 have been associated with significant local reactions15, but lower doses appear to be better tolerated. More than 1,600 volunteers have been immunized with QS21-containing vaccines, the most common side effect being pain/tenderness at the injection site, which is dose related and usually of short duration20,21.
QS21 is likely to prove optimally effective as an adjuvant for vaccines against pathogens that require a potent CTL response as an important component of protective immunity. However, the balance of potency versus adverse events is key for this adjuvant, and an effective adjuvant dose that is tolerable needs to be established in humans for each vaccine indication. QS21 has also been used as an adjuvant for DNA vaccines, following both systemic and mucosal administration22.
Bacterial DNA, but not vertebrate DNA, also has direct immunostimulatory effects on immune cells in vitro23,24. The immunostimulatory effect is due to the presence of unmethylated CpG dinucleotides25, which are underrepresented and methylated in vertebrate DNA26. Unmethylated CpGs in the context of selective flanking sequences are thought to be recognized by cells of the immune system to allow discrimination of pathogen-derived DNA from self DNA26. Bacterial DNA and CpGs trigger cells of the innate immune system, including macrophages and dendritic cells (DCs), to upregulate MHC class II and costimulatory molecules, transcribe cytokine mRNAs, and secrete proinflammatory cytokines27.
The exact mechanism of cellular uptake and activation for CpGs remains unclear, although nonspecific endocytosis may be involved and endosomal maturation appears necessary for the activation of stress kinase pathways, resulting in the release of proinflammatory cytokines28. Hence, CpGs bring about conversion of immature DCs into mature APCs and therefore represent a promising new adjuvant29. CpG is most potent for the induction of Th1 responses, mainly through stimulating tumor necrosis factor α (TNFα), IL-1, IL-6, and IL-12, and through the expression of costimulatory molecules29,30.
CpGs also appear to have significant potential as mucosally administered adjuvants31,32. Their adjuvant effect appears to be maximized by conjugation to protein antigens33. Importantly, CpGs also appear to have significant potential for the modulation of existing immune responses, which may be useful in various clinical settings, including allergies34. Nevertheless, to date, CpGs have mainly been evaluated only in rodent models and with murine cells; thus their potency and safety in humans remains to be established. Although it is too early to know in which situations CpGs might prove most advantageous, their apparent ability to selectively manipulate immune responses is intriguing.
As an alternative to the use of cytokine-inducing adjuvants, cytokines may also be used directly. Most cytokines have the ability to modify and redirect the immune response. Molecules that have been evaluated most extensively as adjuvants include IL-1, IL-2, IFN-Îł, IL-12, and granulocyte-macrophage colony-stimulating factor (GM-CSF)35. All of these molecules exhibit dose-related toxicity and, because of their proteinaceous nature, have stability problems, a short in vivo half-life, and a relatively high cost of manufacture. Therefore, it is unlikely that cytokines will ever prove feasible as adjuvants in routine vaccination. Nevertheless, considerable progress has been made in the use of cytokines for the immunotherapy of cancer36.
Particulate adjuvants
The use of particulate adjuvants as alternatives to immunostimulatory adjuvants has been evaluated by several groups. Particulate adjuvants (e.g., emulsions, microparticles, Iscoms, liposomes, virosomes, and virus-like particles [VLPs]) have comparable dimensions to the pathogens that the immune system evolved to combat (Table 2). Therefore, particulate adjuvants are naturally targeted for uptake by APCs to facilitate the induction of potent immune responses. Immunostimulatory adjuvants may also be included to enhance the level of immune activation, or to focus the response through a desired pathway (e.g., Th1 or Th2).
In the 1980s, a potent oil-in-water (o/w) adjuvant formulation (SAF)37 was developed using a biodegradable oil (squalane). This proved too toxic for widespread use in humans, however, because of the presence of a muramyl dipeptide (MDP) derivative5. Subsequently, a squalane o/w emulsion has been developed (MF59) without the presence of additional immunostimulators, and this formulation has proved to be a potent adjuvant with an acceptable safety profile38,39. MF59 enhances the immunogenicity of influenza vaccine40,41,42 and has been shown to be a more potent adjuvant than alum for hepatitis B vaccine in baboons43. MF59 has also been shown to be an effective adjuvant for a polysaccharide–protein conjugate in infant baboons44. Studies with labeled MF59 have confirmed the ability of the adjuvant to target macrophages and dendritic cells, both at the site of injection and in local lymph nodes45.
Experience in the clinic (to date, >30,000 subjects have been immunized) with several vaccines (including HIV, herpes simplex virus, cytomegalovirus, hepatitis B virus and influenza) has shown that MF59 is safe and well tolerated in humans46,47. MF59 was judged to be sufficiently safe to allow the vaccination of newborn infants in a HIV vaccine trial. In summary, MF59 is an effective adjuvant in humans and can be recommended for the induction of potent antibody responses. It has recently been included in a licensed vaccine product in Europe and is expected to be included in additional vaccines under development.
Oil/water emulsions have also been used as delivery systems for immunostimulatory adjuvants (MPL and QS21) in a malaria vaccine trial. This approach allowed immunostimulatory adjuvants to be targeted for enhanced uptake by APCs. The level of protection induced in mice by the adjuvants was comparable to, or better than, the levels of protection induced with the Plasmodium yoelii antigen in Freund's complete adjuvant, which, though potent, is too toxic for human use48. One adjuvant formulation subsequently showed protective efficacy against an experimental challenge in human volunteers with infected mosquitoes (Plasmodium falciparum)49. Nevertheless, the safety of this adjuvant formulation in humans remains to be further evaluated.
Another class of particulate compounds, the liposomes, has been evaluated both as adjuvants and as delivery systems for antigens and adjuvants50,51. It has been difficult to determine their contribution to the overall adjuvant effect because they are often used in complex formulations, for example when in combination with MPL. Nevertheless, a liposomal hepatitis A vaccine (virosome), without additional immunostimulators, has been extensively evaluated in the clinic and is currently undergoing commercial development in Europe52. In addition, a virosome-based influenza vaccine has already been introduced onto the market. Modified liposomal structures termed "cochleates" are also being evaluated as systemic and mucosal adjuvants in small-animal models53. The development of polymerized liposomes, which show enhanced stability in the gut, also offers potential for the development of mucosal vaccines54.
The immunostimulatory fractions from Q. saponaria (Quil A) have been incorporated into lipid particles, comprising cholesterol, phospholipids, and cell membrane antigens termed Iscoms55. The mechanism of activity of the adjuvant Quil A is thought to be very similar to QS21, which, as previously discussed, is a purified single fraction from Quil A. In a study in macaques, an influenza Iscom vaccine was more immunogenic than a classical subunit vaccine and induced enhanced protective efficacy56. A similar formulation is currently being evaluated in a human clinical trial.
The principal advantage of the preparation of Iscoms is to allow a reduction in the dose of the hemolytic Quil A adjuvant and to target the formulation directly to APCs. A recent study has indicated that the adjuvant effect of Iscoms is mediated by the induction of IL-1257. At present, Iscoms are generally considered to be the most potent adjuvant for the induction of CTL responses in preclinical models. However, their efficacy and safety needs to be established in humans. An added problem with Iscoms is that inclusion of antigens into the adjuvant is often difficult, and may require extensive modification for many antigens.
An alternative approach to target antigens to APCs is represented by the synthesis of biodegradable polymeric microparticles, or the use of polymers or proteins that self-assemble into particulates.
The biodegradable and biocompatible polyesters, poly(lactide-co-glycolides) (PLGs), are the primary candidates for the development of microparticles as adjuvants, as they have been used in humans for many years as suture material and as controlled-release delivery systems58,59. However, the adjuvant effect achieved through the encapsulation of antigens into PLG microparticles has been demonstrated only relatively recently60,61,62,63. Microparticles appear to mediate their effects largely as a consequence of their uptake into DCs, macrophages, and local lymph nodes following intramuscular injection (M. Dupuis, unpublished data). In contrast to alum, PLG microparticles are effective for the induction of CTL responses in rodents64,65,66. Microparticles also appear to have significant potential as an adjuvant for DNA vaccines67.
A particularly attractive feature of microparticles is their ability to control the rate of release of entrapped antigens68,69. Controlled release of antigen may allow the development of single-dose vaccines, which would result in improved vaccine compliance, particularly in the developing world, an area where PLG microparticles probably have their greatest long-term potential. However, much more work is needed on the issue of the stability of antigens in microparticles. Alternative polymers that self-associate into particulates (poloxamers)70, or soluble polymers (polyphosphazenes)71 may also be used as adjuvants, but the safety of these compounds remains to be further evaluated. The adjuvant effect of polyphosphazene polymers has recently been reported in a clinical trial72.
Recombinant proteins that naturally self-assemble into particulates can also enhance delivery of antigens to APCs. The first recombinant protein vaccine that was developed, based on hepatitis B surface antigen (HBsAg), was expressed in yeast as a particulate73. Recombinant HBsAg is potently immunogenic and can be used to prime CTL responses in vivo74. HBsAg and other VLPs can also be used as adjuvants for coexpressed proteins. For example, recombinant Ty VLPs from Saccharomyces cerevisiae carrying a string of up to 15 CTL epitopes from Plasmodium species have been shown to prime protective CTL responses in mice following a single immunization75. In addition, Ty VLPs have also been shown to induce CTL activity in macaques against coexpressed simian immunodeficiency virus (SIV) p2776. Clinical trials of Ty VLPs have shown them to be safe and immunogenic in humans77. Nevertheless, the scale-up, manufacture, and purification of VLPs as adjuvants presents formidable difficulties.
Alternative routes of immunization
Although most vaccines have traditionally been administered by intramuscular injection, mucosal administration of vaccines offers several important advantages. These include easier administration, reduced side effects, and the potential for frequent boosting. In addition, local immunization induces mucosal immunity at the sites where the majority of pathogens initially establish infection of hosts. Oral immunization would be particularly advantageous in isolated communities, where access to health care professionals is difficult. Moreover, this route of immunization would avoid the potential problem of infection due to the re-use of needles. A wide range of approaches are currently being evaluated for the mucosal delivery of vaccines78.
In mice, oral immunization with PLG microparticles has been shown to induce potent mucosal and systemic immunity to entrapped antigens79,80,81,82. Furthermore, mucosal immunization with microparticles induced protection against challenge with Bordetella pertussis83,84,85, Chlamydia trachomatis86, and Salmonella typhimurium87. In primates, mucosal immunization with inactivated SIV in microparticles induced protective immunity against intravaginal challenge88. Also in primates, mucosal immunization with microparticles induced protection against aerosol challenge with staphylococcal enterotoxin B89.
Comparative studies have indicated that microparticles are one of the most potent adjuvants available for mucosal delivery of vaccines90. In recent studies, microparticles also have shown some promise for the oral delivery of DNA91,92. However, optimal responses are likely to be achieved with microparticle formulations that have been modified to maintain the integrity of entrapped DNA93. The ability of microparticles to perform as effective adjuvants following mucosal administration is largely a consequence of their uptake into the specialized mucosal associated lymphoid tissue (MALT)94. While microparticles have significant potential for mucosal delivery of vaccines, their potency may be improved by their combination with additional adjuvants.
Many alternative adjuvants have been evaluated for mucosal delivery of vaccines, including the toxins from Vibrio cholerae (CT) and Escherichia coli (LT), which are the most potent mucosal adjuvants available. However, since CT and LT are too toxic for use in humans, they have been genetically manipulated to reduce toxicity95,96,97. Single amino acid substitutions in the enzymatic A subunit of LT allowed the development of mutant toxins that retained potent adjuvant activity, but showed negligible or dramatically reduced toxicity98,99,100. Recent studies have shown that LT mutants can induce protective immunity in mice against challenge with Helicobacter pylori101. Moreover, intranasal delivery of HIV-1 p24 gag with a nontoxic LT mutant induced potent CTL activity in mouse splenocytes. In contrast, several alternative adjuvants were ineffective for CTL induction in the same study (M. Singh, D. O'Hagan, unpublished data). Although the mechanisms of action of CT and LT mutants remain to be fully defined, it appears that there are important contributions to the adjuvant effect from the B binding domain, from the presence of an intact A subunit, which interacts with regulatory proteins inside cells, and also from the enzymatic activity of the A1 subunit102.
Recent studies have indicated that potent mucosal adjuvants such as CT may also allow vaccination following topical application to the skin103. In another recent development, mucosal immunization may also be achieved through the ingestion of transgenic plants expressing antigens and adjuvants104.
Application to therapeutic vaccines
It seems likely that novel adjuvants may prove sufficiently potent to allow the development of therapeutic vaccines. Rather than prevent infection, therapeutic vaccines would be designed to eliminate or ameliorate existing diseases, including chronic infectious diseases (e.g., those caused by herpes simplex virus (HSV), HIV, hepatitis B virus, hepatitis C virus, human papilloma virus, or H. pylori), tumors (e.g., melanoma, breast, or colon cancer), and allergic or autoimmune disorders (e.g., multiple sclerosis, type I diabetes, and rheumatoid arthritis). For example, a preliminary clinical study in subjects infected with HSV-2 showed a therapeutic benefit following vaccination with an adjuvanted recombinant vaccine105.
The level of toxicity acceptable for an adjuvant to be used in a therapeutic situation is likely to be higher than for a prophylactic vaccine designed to be used in healthy individuals, especially if the vaccine is designed to treat cancer or a life-threatening infectious disease. However, the acceptable safety profile for any new vaccine–adjuvant combination needs to be established in the clinic. Many adjuvants, including MPL106, QS2121, and cytokines107, are currently being evaluated for the development of cancer vaccines.
Therapeutic vaccines may also be developed for mucosal administration, since an LT mutant has been shown to eradicate an established infection with H. pylori in mice108. In addition, preliminary studies indicate that oral administration of antigens can result in the amelioration of autoimmune diseases109.
Future developments
A desirable feature of an adjuvant is that it should specifically enhance the immune response to the vaccine antigen with which it is coadministered. An adjuvant with broad nonspecific effects has more potential for the induction of adverse immunological events. To achieve a specific effect, site-specific delivery, or adjuvant targeting may be advantageous. Targeting may be achieved at several different levels to include organ-specific delivery to local lymph nodes, cell-specific targeting to APCs within lymph nodes or in the peripheral tissues, or targeting to subcellular compartments (e.g., the proteosome to promote class I presentation or the nucleus for DNA vaccines).
Microparticles are "passively" targeted to MALT following mucosal delivery because of their particulate nature110. However, "active" targeting has also been achieved through the use of lectins, which have successfully targeted antigens111, liposomes112, and microparticles113 to the M cells of MALT. In addition, lectin targeting has also been used to enhance the extent of uptake of microparticles following oral delivery114. This is a potentially important approach, as it is clear that the extent of particle uptake is low and targeting may improve the efficiency of mucosal delivery of vaccines. Particulate adjuvants are also passively targeted to APCs following systemic immunization, as one of the natural roles of these cells is to recognize and process pathogen particles. Even so, more effective targeting to APCs may be achieved through the use of specific ligands. For example, the mannose receptor has recently been used to target liposomes to APCs115.
Further developments in the delivery of adjuvants will be achieved through the identification of specific receptors on APCs (e.g., the recently identified TLR), which are thought to provide a link between the innate and adaptive immune responses116. As described, CpGs have been shown to promote the activation and maturation of DCs27,28. Although CpGs are reportedly taken up by nonspecific endocytosis, their possible interaction with an intracellular receptor offers another opportunity for site-specific delivery117.
Agren et al.118,119 have described an approach for targeting APCs that involves coexpression of two linked proteins with a targeting component and an adjuvant signal. They created a gene fusion of the A1 subunit of CT and the immunoglobulin binding domain of protein A from Staphylococcus aureus118,119. The construct was shown to be a potent adjuvant, following both mucosal and systemic administration, because of its ability to both bind B cells and upregulate CD86 and costimulatory signals. In addition, the approach promoted B-cell proliferation and prevented apoptosis. This gene construct illustrates a new strategy for the targeted delivery of adjuvant activity to a selected group of cells. However, a possible limitation of this approach is that targeting of antigen to a specific subset of APCs (B cells) may not induce a sufficiently broad immune response. For example, it remains to be determined whether CTL responses are also induced by targeting to B cells.
An alternative approach to vaccine targeting for CTL induction has also been described using a fusion protein of antigen with a bacterial toxin to deliver the antigen specifically to the MHC class I processing pathway120. Targeting of adjuvants to a subset of APCs has also been achieved through the topical application of vaccines, which allows antigen to gain access to the Langerhans cells in the superficial layers of the skin103.
Future adjuvants will probably exploit more site-specific delivery systems for both mucosal and systemic administration. In addition, the identification of specific receptors on APCs is likely to allow targeting of adjuvants for the optimal induction of potent and specific immune responses. However, further developments in novel adjuvants will likely be driven by a better understanding of the mechanism of action of currently available adjuvants, and this is an area of research that requires much additional work.
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Acknowledgements
We would like to acknowledge the contributions of our colleagues in Chiron Corporation to the ideas contained in this review, particularly Rino Rappuoli, John Donnelly, Margaret Liu, and Gary Ott. We would also like to thank Peter Anderson and Nelle Cronen for help in the manuscript preparation.We are grateful to Terry Ulrich and Charlotte Read-Kensil for the provision of clinical data on MPL and QS21 adjuvants, respectively.
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Singh, M., O'Hagan, D. Advances in vaccine adjuvants. Nat Biotechnol 17, 1075–1081 (1999). https://doi.org/10.1038/15058
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DOI: https://doi.org/10.1038/15058
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