Serum antibodies induced by intranasal immunization of mice with Plasmodium vivax Pvs25 co-administered with cholera toxin completely block parasite transmission to mosquitoes

Transmission-blocking vaccines (TBVs) targeting ookinete surface proteins expressed on sexual-stage malaria parasites are considered one promising strategy for malaria control. To evaluate the prospect of developing non-invasive and easy-to-administer mucosal malaria transmission-blocking vaccines, mice were immunized intranasally with a Plasmodium vivax ookinete surface protein, Pvs25 with a mucosal adjuvant cholera toxin (CT). Immunization induced significant serum IgG with high IgG1/IgG2a ratio (indicative of Th-2 type immune response). Feeding Anopheles dirus mosquitoes with mixtures of immune sera and gametocytemic blood derived from vivax-infected volunteer patients in Thailand significantly reduced both the number of midgut oocysts as well as the percentage of infected mosquitoes. The observed transmission-blocking effect was dependent on immune sera dilution. This study demonstrates for the first time that the mucosally induced mouse immune sera against a human malaria ookinete surface protein can completely block parasite transmission to vector mosquitoes, suggesting the possibility of non-invasive mucosal vaccines against mucosa-unrelated important pathogens like malaria.     

Current status of synthetic hemozoin adjuvant: A preliminary safety evaluation

Although adjuvants are a “must-have” component of successful vaccines, there are very few adjuvants licensed for use in humans, there is therefore an urgent need to develop new and safer adjuvants. Synthetic hemozoin (sHZ), a chemical analog of hemozoin which is produced by the malaria parasite, exhibits a potent adjuvant effect which enhances antigen-specific immune responses to vaccines. The potency of sHZ adjuvanticity is not limited to malaria specific vaccines, it has also been demonstrated to be effective in influenza and dog allergy models. While the synthesis of uniformly sized sHZ with consistent characteristics has proven difficult, we have recently successfully optimized the manufacture of sHZ product with an optimal adjuvant effect. Here, we summarize recent developments on the adjuvant properties of optimized sHZ adjuvant, including its good laboratory practice (GLP) non-clinical safety profile in animals. These studies ensure the safety of optimized sHZ product to be readily used as vaccine adjuvant beforehand in veterinary medicine.     

TLR4 ligand formulation causes distinct effects on antigen-specific cell-mediated and humoral immune responses

The formulation of TLR ligands and other immunomodulators has a critical effect on their vaccine adjuvant activity. In this work, the synthetic TLR4 ligand GLA was formulated with three distinct vaccine delivery system platforms (aqueous suspension, liposome, or oil-in-water emulsion). The effect of the different formulations on the adaptive immune response to protein subunit vaccines was evaluated in the context of a recombinant malaria antigen, Plasmodium berghei circumsporozoite protein (PbCSP). Antibody responses in vaccinated mice were similar for the different formulations of GLA. However, cell-mediated responses differed significantly depending on the adjuvant system; in particular, the emulsion formulation of the TLR4 ligand induced significantly enhanced cellular IFN-γ and TNF-α responses compared to the other formulations. The effects of differences in adjuvant formulation composition and physical characteristics on biological activity are discussed. These results illustrate the importance of formulation of immunostimulatory adjuvants (e.g. TLR ligands) on the resulting immune responses to adjuvanted vaccines and may play a critical role for combating diseases where T cell immunity is advantageous.     

Primary immunodeficiencies

Increased understanding of the nature and variety of immunodeficiency states in man is rapidly accumulating both from studies of human patients and from experimental work on the immune response in animals. Progress is evident in the development of diagnostic tests for deficiencies in both humoral and cellular mechanisms of immunity, and in the introduction of new forms of therapy—for example, the grafting of lymphoid cells. Studies of immunodeficiency provide the most direct evidence concerning the nature of the immune response in man, and hence are of wide general interest. In this paper, current knowledge and concepts are summarized, a logical classification is presented, and recommendations are made for the investigation and treatment of these disorders.     

Use of quinocide in treatment and prophylaxis of vivax malaria

The discovery of antimalarial properties of derivatives of 8-aminoquinolines which combine high activity against the tissue stages of the malaria parasite with satisfactory tolerance by man can be said to have marked the final stage in the search for a radical cure of vivax malaria. Since its synthesis in the USSR in 1952, quinocide—an 8-aminoquinoline drug—has been subjected by Soviet workers to intensive research, an outline of which is presented in this paper. The results of their investigations, which ranged from laboratory and clinical studies of tolerance to the drug, through small-scale trials of its parasiticidal activity, to large-scale studies on the effectiveness of its mass administration are very encouraging. Both for anti-relapse treatment and for pre-epidemic prophylaxis, a short (10- or 14-day) course of quinocide proved as effective as a lengthy course of acriquine with plasmocide. Side-effects were infrequent, and most of those that occurred were transient and did not necessitate the suspension of treatment. It is suggested that the mass administration of quinocide would, in certain cases, be a useful adjunct to insecticidal measures in the clearance of malaria foci.     

Recent advances in recombinant protein-based malaria vaccines

Plasmodium parasites are the causative agent of human malaria, and the development of a highly effective vaccine against infection, disease and transmission remains a key priority. It is widely established that multiple stages of the parasite's complex lifecycle within the human host and mosquito vector are susceptible to vaccine-induced antibodies. The mainstay approach to antibody induction by subunit vaccination has been the delivery of protein antigen formulated in adjuvant. Extensive efforts have been made in this endeavor with respect to malaria vaccine development, especially with regard to target antigen discovery, protein expression platforms, adjuvant testing, and development of soluble and virus-like particle (VLP) delivery platforms. The breadth of approaches to protein-based vaccines is continuing to expand as innovative new concepts in next-generation subunit design are explored, with the prospects for the development of a highly effective multi-component/multi-stage/multi-antigen formulation seeming ever more likely. This review will focus on recent progress in protein vaccine design, development and/or clinical testing for a number of leading malaria antigens from the sporozoite-, merozoite- and sexual-stages of the parasite's lifecycle–including PfCelTOS, PfMSP1, PfAMA1, PfRH5, PfSERA5, PfGLURP, PfMSP3, Pfs48/45 and Pfs25. Future prospects and challenges for the development, production, human delivery and assessment of protein-based malaria vaccines are discussed.     

Development of a cell line-based in vitro assay for assessment of Diphtheria,Tetanus and acellular Pertussis (DTaP)-induced inflammasome activation

Safety and potency assessment for batch release testing of established vaccines still relies partly on animal tests. An important avenue to move to batch release without animal testing is the consistency approach. This approach is based on thorough characterization of the vaccine to identify critical quality attributes that inform the use of a comprehensive set of non-animal tests to release the vaccine, together with the principle that the quality of subsequent batches follows from their consistent production. Many vaccine antigens are by themselves not able to induce a protective immune response. The antigens are therefore administered together with adjuvant, most often by adsorption to aluminium salts. Adjuvant function is an important component of vaccine potency, and an important quality attribute of the final product. Aluminium adjuvants are capable of inducing NLRP3 inflammasome activation. The aim of this study was to develop and evaluate an in vitro assay for NLRP3 inflammasome activation by aluminium-adjuvanted vaccines. We evaluated the effects of Diphtheria-Tetanus-acellular Pertussis combination vaccines from two manufacturers and their respective adjuvants, aluminium phosphate (AP) and aluminium hydroxide (AH), in an in vitro assay for NLRP3 inflammasome activation. All vaccines and adjuvants tested showed a dose-dependent increase in IL-1β production and a concomitant decrease in cell viability, suggesting NLRP3 inflammasome activation. The results were analysed by benchmark dose modelling, showing a similar 50% effective dose (ED50) for the two vaccine batches and corresponding adjuvant of manufacturer A (AP), and a similar ED50 for the two vaccine batches and corresponding adjuvant of manufacturer B (AH). This suggests that NLRP3 inflammasome activation is determined by the adjuvant only. Repeated freeze-thaw cycles reduced the adjuvant biological activity of AH, but not AP. Inflammasome activation may be used to measure adjuvant biological activity as an important quality attribute for control or characterization of the adjuvant.     

Alpha-C-galactosylceramide as an adjuvant for a live attenuated influenza virus vaccine

There is a substantial need to develop better influenza virus vaccines that can protect populations that are not adequately protected by the currently licensed vaccines. While live attenuated influenza virus vaccines induce superior immune responses compared to inactivated vaccines, the manufacturing process of both types of influenza virus vaccines is time consuming and may not be adequate during a pandemic. Adjuvants would be particularly useful if they could enhance the immune response to live attenuated influenza virus vaccines so that the amount of vaccine needed for a protective dose could be reduced. The glycolipid, alpha-galactosylceramide (alpha-GalCer), has recently been shown to have adjuvant activity for both inactivated and replicating recombinant vaccines. The goal of these experiments was to determine whether a derivative of alpha-GalCer, alpha-C-galactosylceramide (alpha-C-GalCer) can enhance the immune response elicited by a live attenuated influenza virus vaccine containing an NS1 protein truncation and reduce the amount of vaccine required to provide protection after challenge. Our results indicated that the adjuvant reduced both morbidity and mortality in BALB/c mice after challenge with wild type influenza virus. The adjuvant also increased the amount of influenza virus specific total IgG, IgG1, and IgG2a antibodies as well as IFN-γ secreting CD8⁺ T cells. By using knockout mice that are not able to generate NKT cells, we were able to demonstrate that the mechanism of adjuvant activity is dependent on NKT cells. Thus, our data indicate that stimulators of NKT cells represent a new avenue of adjuvants to pursue for live attenuated virus vaccines.     

Increased immunogenicity of recombinant Ad35-based malaria vaccine through formulation with aluminium phosphate adjuvant

Previously, we have shown the potency of recombinant Adenovirus serotype 35 viral vaccines (rAd35) to induce strong immune response against the circumsporozoite protein (CS) of the plasmodium parasite. To further optimize immunogenicity of Ad35-based malaria vaccines we formulated rAd35.CS vaccine with aluminium phosphate adjuvant (AlPO(4)). In contrast to the conventional protein based vaccines no absorption to aluminium adjuvant was observed and rAd35 viral in vitro infectivity in mammalian cells was preserved. Immunization with Ad35.CS formulated with AlPO(4) resulted in significantly higher CS specific T and B cell responses in mice upon either single or prime-boost vaccination regimens as compared to rAd35.CS alone. With these results we report for the first time the feasibility of using an AlPO(4) adjuvant to increase the potency of a live adenovirus serotype 35-based vaccine.     

Reduced antibody responses against Plasmodium falciparum vaccine candidate antigens in the presence of Trichuris trichiura

Background

Helminth infections are highly prevalent in the tropics and may have an effect on immune responses to vaccines due to their immunomodulatory effect. The prevalence of helminth infections in young children, the target group for malaria and most other vaccines, is high. Therefore we assessed the influence of helminth infection on vaccine-induced immune responses in a phase I clinical trial of the malaria vaccine candidate GMZ2.

Methods

Twenty Gabonese preschool-age children were vaccinated with GMZ2, a blood stage malaria vaccine candidate. Humoral immune response against the vaccine antigens and parasitological status were assessed. Vaccine-specific antibody concentrations and memory B-cell numbers were compared in worm infected and non-infected participants.

Results

Antibody response to GMZ2 was 3.4-fold (95% confidence interval: 1.6, 7.4) higher in Trichuris trichiura negative subjects compared to positive participants, whereas immunoglobulin subclass distribution was similar. Memory B-cell response was moderately increased in T. trichiura negative individuals, although the difference was not significant.

Conclusions

Future malaria vaccine development programs need to account for worm-mediated hyporesponsiveness of immune reactions.     

Immunogenicity generated by mRNA vaccine encoding VZV gE antigen is comparable to adjuvanted subunit vaccine and better than live attenuated vaccine in nonhuman primates

Shingles is a painful, blistering rash caused by reactivation of latent varicella-zoster virus (VZV) and most frequently occurs in elderly and immunocompromised individuals. Currently, two approved vaccines for the prevention of shingles are on the market, a live attenuated virus vaccine ZOSTAVAX® (Merck & Co., Inc., Kenilworth, NJ, USA) and an AS01_B adjuvanted subunit protein vaccine Shingrix™ (Glaxo Smith Kline, Rockville, MD, USA). Human clinical immunogenicity and vaccine efficacy data is available for these two benchmark vaccines, offering a unique opportunity for comparative analyses with novel vaccine platforms and animal model translatability studies.The studies presented here utilized non-human primates (NHP) to evaluate humoral and cellular immune response by three vaccine modalities: the new platform of lipid nanoparticle (LNP) formulated mRNA encoding VZV gE antigen (VZV gE mRNA/LNP) as compared with well-established platforms of live attenuated VZV (VZV LAV) and adjuvanted VZV gE subunit protein (VZV gE protein/adjuvant). The magnitude of response to vaccination with a single 100–200 μg mRNA dose or two 50 μg mRNA doses of VZV gE mRNA/LNP were comparable to two 50 μg protein doses of VZV gE protein/adjuvant, suggesting the VZV gE mRNA/LNP platform has the potential to elicit a robust immune response, and both modalities generated markedly higher responses than VZV LAV. Additionally, the slopes of decay for VZV-specific antibody titers were roughly similar across all three vaccines, indicating the magnitude of peak immunogenicity was the driving force in determining immune response longevity. Finally, vaccine-induced immunogenicity with VZV LAV and VZV gE protein/adjuvant in NHP closely resembled human clinical trials immune response data for ZOSTAVAX® and Shingrix™, helping to validate NHP as an appropriate preclinical model for evaluating these vaccines.     

A systematic review and meta-analysis on the safety of newly adjuvanted vaccines among children

IntroductionNew adjuvants such as the AS- or the MF59-adjuvants improve vaccine efficacy and facilitate dose-sparing. Their use in influenza and malaria vaccines has resulted in a large body of evidence on their clinical safety in children.MethodsWe carried out a systematic search for safety data from published clinical trials on newly adjuvanted vaccines in children ≤10 years of age. Serious adverse events (SAEs), solicited AEs, unsolicited AEs and AEs of special interest were evaluated for four new adjuvants: the immuno-stimulants containing adjuvant systems AS01 and AS02, and the squalene containing oil-in-water emulsions AS03 and MF59. Relative risks (RR) were calculated, comparing children receiving newly adjuvanted vaccines to children receiving other vaccines with a variety of antigens, both adjuvanted and unadjuvanted.ResultsTwenty-nine trials were included in the meta-analysis, encompassing 25,056 children who received at least one dose of the newly adjuvanted vaccines. SAEs did not occur more frequently in adjuvanted groups (RR 0.85, 95%CI 0.75–0.96). Our meta-analyses showed higher reactogenicity following administration of newly adjuvanted vaccines, however, no consistent pattern of solicited AEs was observed across adjuvant systems. Pain was the most prevalent AE, but often mild and of short duration. No increased risks were found for unsolicited AEs, febrile convulsions, potential immune mediated diseases and new onset of chronic diseases.ConclusionsOur meta-analysis did not show any safety concerns in clinical trials of the newly adjuvanted vaccines in children ≤10 years of age. An unexplained increase of meningitis in one Phase III AS01-adjuvanted malaria trial and the link between narcolepsy and the AS03-adjuvanted pandemic vaccine illustrate that continued safety monitoring is warranted.     

Prospects for the development of malaria vaccines

The collection of epidemiological data on malaria in man dates from the time of the discovery of the human-pathogenic plasmodia, and, in retrospect, many of these observations can be seen to have an immunological connotation. This circumstantial evidence of the immunological phenomena in malaria was obtained during the first quarter of this century through the analysis of parasitological, clinical, and epidemiological data. The second quarter brought confirmation of the existence of a variety of immune phenomena in the naturally infected host, and the development of a number of animal models which proved to be useful in immunological studies. Also during that period the first successful attempts at inducing immune protection in experimental hosts were recorded. This work was considerably expanded during the 1970s and culminated in the evidence of sterilizing protective immunity against homologous challenge in human subjects immunized with irradiated sporozoites of Plasmodium falciparum and P. vivax. The development of immunodiagnostic methods, including serological techniques, made rapid progress during the same period. Recently, the application of the cell-fusion (hybridoma) technique to malaria has made it possible to produce pure, monoclonal antibodies, some of which have proved to be protective. These monoclonal antibodies should be useful in the isolation of pure, specific antigens and the use of gene cloning, and recombinant DNA techniques seems to offer realistic prospects of success in mass production. Development in this area has gathered momentum rapidly and the fact that specialized industries are now interested in the production of malaria vaccines is evidence enough that such vaccines have moved into the sphere of possibility.     

Modified Vaccinia virus Ankara: Innate immune activation and induction of cellular signalling

Attenuated poxviruses are currently under development as vaccine vectors against a number of diseases including, influenza, HIV, malaria and tuberculosis. Modified Vaccinia virus Ankara (MVA) is an attenuated, replication deficient vaccinia virus (VACV) strain which, similar to replication competent VACV, is highly immunogenic. The lack of productive viral replication further improves the safety profile of MVA as a vector, minimizing the potential for reversion to virulent forms particularly if used in immunocompromised individuals. Despite its inability to replicate in most mammalian cells, MVA still efficiently expresses viral and recombinant genes making it a potent antigen delivery platform. Moreover, due to the loss of various immunomodulatory factors MVA infection leads to rapid local immune responses, fulfilling a requirement of an adjuvant. In this review we take a look at the immunostimulatory properties of MVA, paying particular attention to the signalling of the innate immune system in response to MVA and VACV infection. Understanding the cellular and molecular mechanisms modulated by VACV will help in the future design and engineering of new vaccines and may provide insight into previously unknown mechanisms of dominant virus–host interactions.     

Spectroscopic characterization of antibodies adsorbed to aluminium adjuvants: correlation with antibody vaccine immunogenicity

MMA383 is an anti-idiotypic antibody designed as an immunogenic surrogate for the cancer specific Lewis Y antigen. Lewis Y is expressed in 70-90% of tumours of epithelial origin with limited expression in normal tissue. Five different MMA383 vaccines were prepared by mixing a MMA383 antibody solution with an Alhydrogel aluminium hydroxide adjuvant and tested on the biological activity in a rat model. The immunogenicity increased when: (i) the adjuvant was sterilized at 121 degrees C compared to no sterilization, (ii) the adjuvant was suspended in a phosphate buffer compared to water and (iii) the MMA383 solution was at a pH of 7.2. The immunogenicity of a ready-to-use MMA383 aluminium hydroxide suspension was the lowest. The in vivo data show that small differences in vaccine formulations before injection can generate significant changes in immunogenicity. Prior to mixing with the adjuvant, the physical and chemical characteristics of MMA383 antibodies were the same in all vaccines. Fluorescence and light scattering methods were developed to characterize antibodies in the presence of the adjuvant. Compared to the least active vaccines, the two most biologically active vaccines showed an increase in the antibody Trp fluorescence intensity, anisotropy, fluorescence lifetime, 90 degrees light-scatter, sedimentation velocity and rotational correlation time. Analysis of the 90 degrees light-scatter sedimentation kinetics indicates that stronger immune responses of vaccines can be related to the stronger binding of the antibodies to the adjuvants and the formation of more compact and condensed particles. Taken together, these results show a correlation between the in vitro fluorescence and light-scatter data and the in vivo immune response of the five MMA383 vaccines. The spectroscopic techniques described offer a new in vitro approach for the prediction of immune responses of different vaccine formulations.     

Potentiation by a novel alkaloid glycoside adjuvant of a protective cytotoxic T cell immune response specific for a preerythrocytic malaria vaccine candidate antigen.

We have recently demonstrated that the novel glycoalkaloid tomatine, derived from leaves of the wild tomato Lycopersicon pimpinellifolium, can act as a powerful adjuvant for the elicitation of antigen-specific CD8+ T cell responses. Here, we have extended our previous investigation with the model antigen ovalbumin to an established malaria infection system in mice and evaluated the cellular immune response to a major preerythrocytic stage malaria vaccine candidate antigen when administered with tomatine. The defined MHC H-2kd class I-binding 9-mer peptide (amino acids 252-260) from Plasmodium berghei circumsporozoite (CS) protein was prepared with tomatine to form a molecular aggregate formulation and this used to immunise BALB/c (H-2kd) mice. Antigen-specific IFN-gamma secretion and cytotoxic T lymphocyte activity in vitro were both significantly enhanced compared to responses detected from similarly stimulated splenocytes from naive and tomatine-saline-immunised control mice. Moreover, when challenged with P. berghei sporozoites, mice immunised with the CS 9-mer-tomatine preparation had a significantly delayed onset of erythrocytic infection compared to controls. The data presented validate the use of tomatine to potentiate a cellular immune response to antigenic stimulus by testing in an important biologically relevant system. Specifically, the processing of the P. berghei CS 9-mer as an exogenous antigen and its presentation via MHC class I molecules to CD8+ T cells led to an immune response that is an in vitro correlate of protection against preerythrocytic malaria. This was confirmed by the protective capacity of the 9-mer-tomatine combination upon in vivo immunisation. These findings merit further work to optimise the use of tomatine as an adjuvant in malaria vaccine development.     

Tests for the existence of genetic variability in the tendency of Anopheles culicifacies species B to rest in houses and to bite man

Experiments were carried out in Sri Lanka on the malaria vector Anopheles culicifacies using the mark—release—recapture technique. Collections were made in cattle-baited huts fitted with exit traps, and in nightbiting catches on human subjects. The same individual mosquitos were caught biting cattle and man on different occasions and the numbers caught demonstrated an overall preference for the cattle. The mean interval between successive blood meals in the field was estimated to be 2.3 days.     

ISCOMATRIX adjuvant: a potent inducer of humoral and cellular immune responses

ISCOMATRIX adjuvant is capable of inducing broad and potent humoral and cellular immune responses. The components are well defined and the manufacturing process is simple and robust. Many vaccines containing the ISCOMATRIX adjuvant have been tested in a range of animal models, including human and non-human primates. Strong antibody and T cell responses have been induced in these studies. The antibody response is often achieved with lesser amounts of antigen than other adjuvant systems and the maximal responses have also been reached more quickly. Both CD4+ and CD8+ T cell responses are induced with the cytotoxic T lymphocyte responses being very long lived. Additionally, ISCOMATRIX adjuvant can be used in vaccines for induction of mucosal immune responses. This review provides an overview of the immune responses that can be elicited using ISCOMATRIX vaccines and the current state of knowledge regarding the mechanism of action of this adjuvant.     

Advances in saponin-based adjuvants

Saponins are natural glycosides of steroid or triterpene which exhibited many different biological and pharmacological activities. Notably, saponins can also activate the mammalian immune system, which have led to significant interest in their potential as vaccine adjuvants. The most widely used saponin-based adjuvants are Quil A and its derivatives QS-21, isolated from the bark of Quillaja saponaria Molina, which have been evaluated in numerous clinical trials. Their unique capacity to stimulate both the Th1 immune response and the production of cytotoxic T-lymphocytes (CTLs) against exogenous antigens makes them ideal for use in subunit vaccines and vaccines directed against intracellular pathogens as well as for therapeutic cancer vaccines. However, Quillaja saponins have serious drawbacks such as high toxicity, undesirable haemolytic effect and instability in aqueous phase, which limits their use as adjuvant in vaccination. It has driven much research for saponin-based adjuvant from other kinds of natural products. This review will summarize the current advances concerning adjuvant effects of different kinds of saponins. The structure–activity relationship of saponin adjuvants will also be discussed in the light of recent findings. It is hoped that the information collated here will provide the reader with information regarding the adjuvant potential applications of saponins and stimulate further research into these compounds.     

Malaria along the southernmost fringe of its distribution in Africa: epidemiology and control

After more than thirty years of malaria control in northern Transvaal with residual insecticides, malaria prevalence has been reduced to a low level. However, low-grade transmission of Plasmodium falciparum continues, with periodic focal outbreaks after abnormally high rainfall. From October 1973 to September 1976, the operational and epidemiological factors involved in this residual transmission were studied in over 17 000 people of an area of northern Transvaal. Incidence surveys based on the screening of fever cases revealed 42 autochthonous cases of malaria in 1974-75 and 10 cases in 1975-76. Parasite prevalence surveys were not sensitive enough to assess the malaria situation, and serological testing indicated different levels of infection according to the method used. One of the two principal vectors of malaria in Africa—Anopheles funestus Giles—was not detected in the project area, and the A. gambiae group (species A and B) was found in extremely low numbers, so that it could not have accounted for the low-grade transmission in the area. A recently discovered member of the A. funestus group somewhat resembling A. aruni Sobti, and a species hitherto undiscovered in the Transvaal, which is abundant in the area and is indistinguishable from A. flavicosta Edwards, may be involved. Both were found biting man—mostly outdoors during the four hours following dusk, when people frequently gather outside their houses and are thus vulnerable to mosquito bites.