Characterization of a Plasmodium falciparum PHISTc protein, PF3D7_0801000, in blood- stage malaria parasites.

During intraerythrocytic development Plasmodium falciparum deploys numerous proteins to support erythrocyte invasion, intracellular growth and development, as well as host immune evasion. Since these proteins are key for parasite intraerythrocytic survival and propagation, they represent attractive targets for antimalarial vaccines. In this study we sought to characterize a member of the PHISTc family of proteins, PF3D7_0801000, as a potential vaccine target. Using the wheat germ cell-free system we expressed the N-terminal region of PF3D7_0801000 (G93-L494, PF3D7_0801000N) and generated specific immune sera. We observed that PF3D7_0801000 localizes in merozoites, and antibodies against PF3D7_0801000N modestly inhibit P. falciparum parasite growth in in vitro culture. Sliding window analysis of the coding sequence revealed that pf3d7_0801000n is relatively conserved among African parasite isolates. Antibody profiles in a malaria-exposed Ugandan population revealed that PF3D7_0801000N is strongly immunoreactive with antibody acquisition increasing with age. Taken together, these findings suggest the need for further evaluation of PF3D7_0801000 for its role in merozoite invasion and utility as an asexual blood-stage vaccine candidate antigen.

Disulfide bond mapping of Pfs25, a recombinant malaria transmission blocking vaccine candidate.

A liquid chromatography tandem-mass spectrometry method was developed to map the eleven disulfide bonds in Pfs25, a malaria transmission-blocking vaccine candidate. The compact and complex nature of Pfs25 has led to difficulties in prior peptide mapping efforts. Here, we report confirmation of proper disulfide pairing of a recombinant Pfs25, by optimizing denaturation and digestion with trypsin/Lys-C. The digested peptides were separated by reversed phase HPLC to obtain the peptide map and elucidate the disulfide linkages. MSE fragmentation confirmed the digested peptides and disulfide bonds. The eleven disulfide bonds and locations matched the predicted Pvs25 crystal structure, a Pfs25 homologue.

A Method for Producing Protein Nanoparticles with Applications in Vaccines.

A practical method is described for synthesizing conjugated protein nanoparticles using thioether (thiol-maleimide) cross-linking chemistry. This method fills the need for a reliable and reproducible synthesis of protein conjugate vaccines for preclinical studies, which can be adapted to produce comparable material for clinical studies. The described method appears to be generally applicable to the production of nanoparticles from a variety of soluble proteins having different structural features. Examples presented include single-component particles of the malarial antigens AMA1, CSP and Pfs25, and two component particles comprised of those antigens covalently cross-linked with the immunogenic carrier protein EPA (a detoxified form of exotoxin A from Pseudomonas aeruginosa). The average molar masses (Mw) of particles in the different preparations ranged from 487 kDa to 3,420 kDa, with hydrodynamic radii (Rh) ranging from 12.1 nm to 38.3 nm. The antigenic properties and secondary structures of the proteins within the particles appear to be largely intact, with no significant changes seen in their far UV circular dichroism spectra, or in their ability to bind conformation-dependent monoclonal antibodies. Mice vaccinated with mixed particles of Pfs25 or CSP and EPA generated significantly greater antigen-specific antibody levels compared with mice vaccinated with the respective unmodified monomeric antigens, validating the potential of antigen-EPA nanoparticles as vaccines.

Recent advances in the development of a chemically synthesised anti-malarial vaccine.

INTRODUCTION: Obtaining an effective antimalarial vaccine has represented one of the biggest public health challenges over the last 50 years. Despite efforts by many laboratories around the world using whole-organism, recombinant proteins and genome-based approaches, the results have been disappointing. One of the main problems when designing an antimalarial vaccine is the poor immunogenicity induced by the functionally relevant and conserved protein regions of the parasite. AREAS COVERED: This review focuses on the logical and rational methodology followed to identify Plasmodium falciparum conserved functional regions with the ability to bind to target cells conserved high activity binding peptides (cHABPs) and the physicochemical and immunological characteristics that should be taken into account for modifying them into highly immunogenic and protection-inducing peptides (mHABPs) into highly immunogenic and protection-inducing in Aotus monkeys. EXPERT OPINION: The functional approach taken to develop a fully protective, minimal subunit-based, multiantigenic, multistage and synthetic peptide-based antimalarial vaccine has shown promising results. The clear relationship observed between mHABPs structure and their immunological properties highlights the challenges and opportunities arising from this methodology, as well as the universal principles and rules derived therefrom.

Plasmodium falciparum synthetic LbL microparticle vaccine elicits protective neutralizing antibody and parasite-specific cellular immune responses.

Epitopes of the circumsporozoite (CS) protein of Plasmodium falciparum, the most pathogenic species of the malaria parasite, have been shown to elicit protective immunity in experimental animals and human volunteers. The mechanisms of immunity include parasite-neutralizing antibodies that can inhibit parasite motility in the skin at the site of infection and in the bloodstream during transit to the hepatocyte host cell and also block interaction with host cell receptors on hepatocytes. In addition, specific CD4+ and CD8+ cellular mechanisms target the intracellular hepatic forms, thus preventing release of erythrocytic stage parasites from the infected hepatocyte and the ensuing blood stage cycle responsible for clinical disease. An innovative method for producing particle vaccines, layer-by-layer (LbL) fabrication of polypeptide films on solid CaCO3 cores, was used to produce synthetic malaria vaccines containing a tri-epitope CS peptide T1BT comprising the antibody epitope of the CS repeat region (B) and two T-cell epitopes, the highly conserved T1 epitope and the universal epitope T. Mice immunized with microparticles loaded with T1BT peptide developed parasite-neutralizing antibodies and malaria-specific T-cell responses including cytotoxic effector T-cells. Protection from liver stage infection following challenge with live sporozoites from infected mosquitoes correlated with neutralizing antibody levels. Although some immunized mice with low or undetectable neutralizing antibodies were also protected, depletion of T-cells prior to challenge resulted in the majority of mice remaining resistant to challenge. In addition, mice immunized with microparticles bearing only T-cell epitopes were not protected, demonstrating that cellular immunity alone was not sufficient for protective immunity. Although the microparticles without adjuvant were immunogenic and protective, a simple modification with the lipopeptide TLR2 agonist Pam3Cys increased the potency and efficacy of the LbL vaccine candidate. This study demonstrates the potential of LbL particles as promising malaria vaccine candidates using the T1BT epitopes from the P. falciparum CS protein.

[Immunization against malaria]. / Vaccination contre le paludisme. Si près du but, l'argent ne doit pas manquer!

Malaria is a great endemic infectious disease, as well as HIV and tuberculosis, responsible world-wide for millions of deaths every year, especially in children. Despite vector control intensification, significant epidemiological improvement and arrival of new and effective antimalarials, malaria remains a major public health issue. The development of a vaccine is still a public health priority because it would considerably modify malaria epidemiology in a relatively near future if associated with vector control and improvement of diagnosis and treatment, in the sixties, several studies have assessed vaccine-candidates targeting different stages of Plasmodium falciparum cycle with different approaches depending on targets. Some aiming a reduction of morbidity and mortality, others a transmission disruption (through vaccine specific of the pre-erythrocytic stage using the circumsporozoite protein with promising phase 3 studies). Other vaccine targets are being studied with hopefully an effective knowledge of the immunological mechanisms.

Adjuvant-like effect of vaccinia virus 14K protein: a case study with malaria vaccine based on the circumsporozoite protein.

Development of subunit vaccines for malaria that elicit a strong, long-term memory response is an intensive area of research, with the focus on improving the immunogenicity of a circumsporozoite (CS) protein-based vaccine. In this study, we found that a chimeric protein, formed by fusing vaccinia virus protein 14K (A27) to the CS of Plasmodium yoelii, induces strong effector memory CD8(+) T cell responses in addition to high-affinity Abs when used as a priming agent in the absence of any adjuvant, followed by an attenuated vaccinia virus boost expressing CS in murine models. Moreover, priming with the chimeric protein improved the magnitude and polyfunctionality of cytokine-secreting CD8(+) T cells. This fusion protein formed oligomers/aggregates that led to activation of STAT-1 and IFN regulatory factor-3 in human macrophages, indicating a type I IFN response, resulting in NO, IL-12, and IL-6 induction. Furthermore, this vaccination regimen inhibited the liver stage development of the parasite, resulting in sterile protection. In summary, we propose a novel approach in designing CS based pre-erythrocytic vaccines against Plasmodium using the adjuvant-like effect of the immunogenic vaccinia virus protein 14K.

Development of vaccines to prevent malaria in pregnant women: WHO MALVAC meeting report.

The major public health consequences of malaria in pregnancy have long been acknowledged. However, further information is still required for development and implementation of a malaria vaccine specifically directed to prevent malaria in pregnant women and improve maternal, fetal and infant outcomes. The WHO Malaria Vaccine Advisory Committee (MALVAC) provides guidance to the WHO on strategic priorities and research needs for development of vaccines to prevent malaria. Here we summarize the discussions and conclusions of a MALVAC scientific forum meeting on considerations in the development of vaccines to prevent malaria in pregnant women. This report includes brief summaries of what is known, and major knowledge gaps in disease burden estimation, pathogenesis and immunity, and the challenges with current preventive strategies for malaria in pregnancy. We conclude with the formulation of a conceptual framework for research and development for vaccines to prevent malaria in pregnant women.

Developing novel strategies to prevent parasitic infections.

The 49th Annual Spring Meeting of the British Society of Parasitology was held at Nottingham University, UK, on 11-14 April 2011. Although a meeting of a national parasitological society, the meeting attracted approximately 375 delegates from 30 countries worldwide. Of the various themes at this meeting, two were focused on the biology, etiology and development of therapeutics for the parasitic diseases; malaria and schistosomiasis. Here we report on three aspects of this meeting that are focused on the development of novel therapeutics to address the significant health burden imposed by these tropical diseases.

[Synthetic peptide vaccines].

This review considers the stages of the development of synthetic peptide vaccines against infectious agents, novel approaches and technologies employed in this process, including bioinformatics, genomics, proteomics, large-scale peptide synthesis, high-throughput screening methods, the use of transgenic animals for modelling human infections. An important role for the development and selection of efficient adjuvants for peptide immunogens is noted. Examples of synthetic peptide vaccine developments against three infectious diseases (malaria, hepatitis C, and foot-and-mouth disease) are given.

Development of designed site-directed pseudopeptide-peptido-mimetic immunogens as novel minimal subunit-vaccine candidates for malaria.

Synthetic vaccines constitute the most promising tools for controlling and preventing infectious diseases. When synthetic immunogens are designed from the pathogen native sequences, these are normally poorly immunogenic and do not induce protection, as demonstrated in our research. After attempting many synthetic strategies for improving the immunogenicity properties of these sequences, the approach consisting of identifying high binding motifs present in those, and then performing specific changes on amino-acids belonging to such motifs, has proven to be a workable strategy. In addition, other strategies consisting of chemically introducing non-natural constraints to the backbone topology of the molecule and modifying the α-carbon asymmetry are becoming valuable tools to be considered in this pursuit. Non-natural structural constraints to the peptide backbone can be achieved by introducing peptide bond isosters such as reduced amides, partially retro or retro-inverso modifications or even including urea motifs. The second can be obtained by strategically replacing L-amino-acids with their enantiomeric forms for obtaining both structurally site-directed designed immunogens as potential vaccine candidates and their Ig structural molecular images, both having immuno-therapeutic effects for preventing and controlling malaria.

Multiple antigen peptide vaccines against Plasmodium falciparum malaria.

The multiple antigen peptide (MAP) approach is an effective method to chemically synthesize and deliver multiple T-cell and B-cell epitopes as the constituents of a single immunogen. Here we report on the design, chemical synthesis, and immunogenicity of three Plasmodium falciparum MAP vaccines that incorporated antigenic epitopes from the sporozoite, liver, and blood stages of the life cycle. Antibody and cellular responses were determined in three inbred (C57BL/6, BALB/c, and A/J) strains, one congenic (HLA-A2 on the C57BL/6 background) strain, and one outbred strain (CD1) of mice. All three MAPs were immunogenic and induced both antibody and cellular responses, albeit in a somewhat genetically restricted manner. Antibodies against MAP-1, MAP-2, and MAP-3 had an antiparasite effect that was also dependent on the mouse major histocompatibility complex background. Anti-MAP-1 (CSP-based) antibodies blocked the invasion of HepG2 liver cells by P. falciparum sporozoites (highest, 95.16% in HLA-A2 C57BL/6; lowest, 11.21% in BALB/c). Furthermore, antibodies generated following immunizations with the MAP-2 (PfCSP, PfLSA-1, PfMSP-1(42), and PfMSP-3b) and MAP-3 (PfRAP-1, PfRAP-2, PfSERA, and PfMSP-1(42)) vaccines were able to reduce the growth of blood stage parasites in erythrocyte cultures to various degrees. Thus, MAP-based vaccines remain a viable option to induce effective antibody and cellular responses. These results warrant further development and preclinical and clinical testing of the next generation of candidate MAP vaccines that are based on the conserved protective epitopes from Plasmodium antigens that are widely recognized by populations of divergent HLA types from around the world.

An autologous falciparum vaccine using the erythrocyte's band 3 molecule.

Protection against the serious complications of falciparum malaria is provided to people with the minor forms of hematological conditions such as sickle cell disease and thalassemia and as a result natural selection has increased their incidence in malaria endemic areas. The explanation for this has thus far not been determined but experimental evidence that is now available suggest an explanation that also has therapeutic implications. The hypothesis presented suggests that the erythrocytes of these blood disorders experience premature senescence and are then eliminated by the same process that normally disposes of senescent erythrocytes. Erythrocytes express approximately one million widely dispersed band 3 molecules on their surface but when these erythrocytes age they form band 3 clusters that are recognized by the immune system which results in their elimination. In addition to senescent erythrocytes, both sickle and falciparum infected erythrocytes also display these clusters suggesting that band 3 antibodies contribute to their erythrocytes removal. Supporting band 3's involvement in falciparum erythrocyte elimination are the facts that band 3 specific antibodies are elevated in falciparum endemic areas and the documentation that the falciparum erythrocytes displaying these clusters are rapidly phagocytized. Both sickle and falciparum infected erythrocytes adhere to endothelium and band 3 antibodies and adhesive band 3 peptides block this adhesion. This proves that the band 3 molecule is responsible for at least some of the endothelial adhesion and implies that band 3 antibodies are active in eliminating falciparum infected erythrocytes. It is proposed that the band 3 peptides could be used to develop a vaccine to reduce the lethality of falciparum infections. A conjugate vaccine using these peptides in early infancy may allow those infants to survive a falciparum infection and develop comprehensive natural immunity to the local endemic parasite.

Evaluation of two long synthetic merozoite surface protein 2 peptides as malaria vaccine candidates.

Merozoite surface protein 2 (MSP2) is a promising vaccine candidate against Plasmodium falciparum blood stages. A recombinant 3D7 form of MSP2 was a subunit of Combination B, a blood stage vaccine tested in the field in Papua New Guinea. A selective effect in favour of the allelic family not represented by the vaccine argued for a MSP2 vaccine consisting of both dimorphic variants. An alternative approach to recombinant manufacture of vaccines is the production of long synthetic peptides (LSP). LSP exceeding a length of well over 100 amino acids can now be routinely synthesized. Synthetic production of vaccine antigens cuts the often time-consuming steps of protein expression and purification short. This considerably reduces the time for a candidate to reach the phase of clinical trials. Here we present the evaluation of two long synthetic peptides representing both allelic families of MSP2 as potential vaccine candidates. The constructs were well recognized by human immune sera from different locations and different age groups. Furthermore, peptide-specific antibodies in human immune sera were associated with protection from clinical malaria. The synthetic fragments share major antigenic properties with native MSP2. Immunization of mice with these antigens yielded high titre antibody responses and monoclonal antibodies recognized parasite-derived MSP2. Our results justify taking these candidate poly-peptides into further vaccine development.

World Malaria Day 2009: what malaria knows about the immune system that immunologists still do not.

Malaria kills >1 million children each year, and there is little doubt that an effective vaccine would play a central role in preventing these deaths. However, the strategies that proved so successful in developing the vaccines we have today may simply not be adequate to confront complex, persistent infectious diseases, including malaria, AIDS, and tuberculosis. We believe that the development of a highly effective vaccine will require a better understanding of several features of the immune response to malaria. At the top of the list is the complex and ancient relationship between the parasite that causes malaria and the immune system that enables the parasite to persist in an otherwise functional immune system. A close second is the antigenic targets in malaria and how to overcome the enormous polymorphism of these targets. Meeting these challenges represents a call to arms of basic immunologists to advance our knowledge of malaria immunity.

Strategies for developing multi-epitope, subunit-based, chemically synthesized anti-malarial vaccines.

An anti-malarial vaccine against the extremely lethal Plasmodium falciparum is desperately needed. Peptides from this parasite's proteins involved in invasion and having high red blood cell-binding ability were identified; these conserved peptides were not immunogenic or protection-inducing when used for immunizing Aotus monkeys. Modifying some critical binding residues in these high-activiy binding peptides' (HABPs') attachment to red blood cells (RBC) allowed them to induce immunogenicity and protection against experimental challenge and acquire the ability to bind to specific HLA-DRp1* alleles. These modified HABPs adopted certain characteristic structural configurations as determined by circular dichroism (CD) and 1H nuclear magnetic resonance (NMR) associated with certain HLA-DRbeta1* haplotype binding activities and characteristics, such as a 2-angstroms-distance difference between amino acids fitting into HLA-DRp1 Pockets 1 to 9, residues participating in binding to HLA-DR pockets and residues making contact with the TCR, suggesting haplotype and allele-conscious TCR. This has been demonstrated in HLA-DR-like genotyped monkeys and provides the basis for designing high effective, subunit-based, multi-antigen, multi-stage, synthetic vaccines, for immediate human use, malaria being one of them.

Structural and immunological analysis of circumsporozoite protein peptides: a further step in the identification of potential components of a minimal subunit-based, chemically synthesised antimalarial vaccine.

The Plasmodium falciparum circumsporozoite protein is considered a major antimalarial-vaccine target due to its involvement in sporozoite invasion of mosquito's salivary glands and human hepatocytes. The 4383, 4388 and 4389 CSP-conserved high activity hepatocyte binding peptides and their modified analogues were synthesised and their immunogenicity was tested in Aotus monkeys. Peptide 4388 modified analogues induced higher and more permanent antibody titers against sporozoites in approximately 40% of immunised monkeys; whilst peptides 4383 and 4389 modified analogues elicited high, long-lasting antibody titers as well as short-lived antibodies. (1)H NMR studies showed that native peptides displayed random conformations, whereas most modified immunogenic HABPs contained type I, II and IV beta-turn structures. HLA-DRbeta1* molecule binding assays revealed that 4383 modified HABPs bound to HLA-DRbeta1*0701/HLA-DRbeta1*0401 molecules, whilst 4388 and 4389 modified HABPs bound to HLA-DRbeta1*0401/HLA-DRbeta1*0101, respectively. The results support these high-immunogenic CSP-derived modified peptides' inclusion in a multi-antigenic, multistage, minimal subunit-based synthetic antimalarial vaccine.

Immunological profile of a Plasmodium vivax AMA-1 N-terminus peptide-carbon nanotube conjugate in an infected Plasmodium berghei mouse model.

We have covalently conjugated an N-terminus Plasmodium vivax apical membrane antigen-1 (AMA-1) peptide to functionalized carbon nanotubes (f-CNT). Immunological characterization of this molecular conjugate revealed that the immunogen-AMA-1 peptide was appropriately presented after being conjugated to CNTs as well as being recognized by BALB/c polyclonal antibodies. Subsequent experiments lead us to assess the AMA-1 peptide alone, as well as the CNT-peptide conjugate regarding rodent malarial infection. Remarkably, the peptide effectively controlled and delayed Plasmodium berghei-challenged animals' parasitaemia. The peptide-CNT conjugate displayed similar immunological properties to the peptide alone by protecting or delaying malarial infection. The peptide presentation by f-CNT to the immune system thus constitutes a promising approach for synthetic malarial vaccine formulation since the immunogen peptide conformation is well preserved.