Mannosylated liposomes formulated with whole parasite P. falciparum blood-stage antigens are highly immunogenic in mice.

The development of a blood-stage malaria vaccine has largely focused on the subunit approach. However, the limited success of this strategy, mainly due to antigenic polymorphism and the failure to maintain potent parasite-specific immune responses, indicates that other approaches must be considered. Whole parasite (WP) vaccines offer many advantages over sub-units; they represent every antigen on the organism, thus limiting the effects of antigenic polymorphism, and similarly they compensate for individual Immune-Response (Ir) gene-regulated non-responsiveness to any particular antigen. From a development perspective, they negate the need to identify and compare the relative efficacies of individual candidate antigens. WP vaccines induce protective immunity that is largely cell-mediated. However, WP blood-stage vaccines present a number of challenges for the development pathway. Key issues are cryopreservation and storage and the possible induction of antibodies against red blood cell surface antigens, even if the parasites are grown in blood group O, Rh negative blood. Here, we used a novel adaptation of an immunomagnetic method from STEMCELL™ Technologies to remove the red cell membranes from human red blood cells parasitized with P. falciparum. We then used these antigens to construct liposomes which were modified to present mannose on their membrane to target the liposome to antigen presenting cells. We then compared the immunogenicity of freshly prepared and lyophilized liposome vaccines. Following vaccination of mice, liposomes induced significantly lower antibody responses to human red cells but potent strain- and species-transcending cell-mediated immune responses to parasite antigens. These data support transitioning the P. falciparum liposomal vaccine into clinical studies.

Controlled Infection Immunization Using Delayed Death Drug Treatment Elicits Protective Immune Responses to Blood-Stage Malaria Parasites.

Naturally acquired immunity to malaria is robust and protective against all strains of the same species of Plasmodium This develops as a result of repeated natural infection, taking several years to develop. Evidence suggests that apoptosis of immune lymphocytes due to uncontrolled parasite growth contributes to the slow acquisition of immunity. To hasten and augment the development of natural immunity, we studied controlled infection immunization (CII) using low-dose exposure to different parasite species (Plasmodium chabaudi, P. yoelii, or P. falciparum) in two rodent systems (BALB/c and C57BL/6 mice) and in human volunteers, with drug therapy commencing at the time of initiation of infection. CIIs with infected erythrocytes and in conjunction with doxycycline or azithromycin, which are delayed death drugs targeting the parasite's apicoplast, allowed extended exposure to parasites at low levels. In turn, this induced strong protection against homologous challenge in all immunized mice. We show that P. chabaudi/P. yoelii infection initiated at the commencement of doxycycline therapy leads to cellular or antibody-mediated protective immune responses in mice, with a broad Th1 cytokine response providing the best correlate of protection against homologous and heterologous species of PlasmodiumP. falciparum CII with doxycycline was additionally tested in a pilot clinical study (n = 4) and was found to be well tolerated and immunogenic, with immunological studies primarily detecting increased cell-associated immune responses. Furthermore, we report that a single dose of the longer-acting drug, azithromycin, given to mice (n = 5) as a single subcutaneous treatment at the initiation of infection controlled P. yoelii infection and protected all mice against subsequent challenge.

Vaccination with chemically attenuated Plasmodium falciparum asexual blood-stage parasites induces parasite-specific cellular immune responses in malaria-naïve volunteers: a pilot study.

BACKGROUND: The continuing morbidity and mortality associated with infection with malaria parasites highlights the urgent need for a vaccine. The efficacy of sub-unit vaccines tested in clinical trials in malaria-endemic areas has thus far been disappointing, sparking renewed interest in the whole parasite vaccine approach. We previously showed that a chemically attenuated whole parasite asexual blood-stage vaccine induced CD4+ T cell-dependent protection against challenge with homologous and heterologous parasites in rodent models of malaria. METHODS: In this current study, we evaluated the immunogenicity and safety of chemically attenuated asexual blood-stage Plasmodium falciparum (Pf) parasites in eight malaria-naïve human volunteers. Study participants received a single dose of 3 × 107 Pf pRBC that had been treated in vitro with the cyclopropylpyrolloindole analogue, tafuramycin-A. RESULTS: We demonstrate that Pf asexual blood-stage parasites that are completely attenuated are immunogenic, safe and well tolerated in malaria-naïve volunteers. Following vaccination with a single dose, species and strain transcending Plasmodium-specific T cell responses were induced in recipients. This included induction of Plasmodium-specific lymphoproliferative responses, T cells secreting the parasiticidal cytokines, IFN-γ and TNF, and CD3+CD45RO+ memory T cells. Pf-specific IgG was not detected. CONCLUSIONS: This is the first clinical study evaluating a whole parasite blood-stage malaria vaccine. Following administration of a single dose of completely attenuated Pf asexual blood-stage parasites, Plasmodium-specific T cell responses were induced while Pf-specific antibodies were not detected. These results support further evaluation of this chemically attenuated vaccine in humans. TRIAL REGISTRATION: Trial registration: ACTRN12614000228684 . Registered 4 March 2014.

Spectroscopic and molecular docking study on the interaction between salicylic acid and the induced disease-resistant protein OsAAA1 of rice.

The interaction between salicylic acid (SA) and the induced disease-resistant protein OsAAA1 in rice was studied using spectroscopy and molecular docking. Ultraviolet (UV) absorption spectroscopy demonstrated an interaction between OsAAA1 protein and SA. Spectroscopy showed that this interaction was a dynamic quenching process. Synchronous fluorescence spectroscopy (SFS) further revealed that this interaction caused changes in the microenvironment of tyrosine and tryptophan and that the interaction site was closer to the tryptophan residue. The structural model of protein OsAAA1 was determined by homology modeling method, and the molecular docking simulation diagram of OsAAA1 with SA was obtained. These models, in combination with a Ramachandran plot analysis, showed amino acid residues ranging from position 240 to position 420 as the possible site interacting with SA. Among them, Gly389, Lys257 and Glu425 might be three key amino acids that can form hydrogen bonds with SA.

Infectivity of Plasmodium falciparum in Malaria-Naive Individuals Is Related to Knob Expression and Cytoadherence of the Parasite.

Plasmodium falciparum is the most virulent human malaria parasite because of its ability to cytoadhere in the microvasculature. Nonhuman primate studies demonstrated relationships among knob expression, cytoadherence, and infectivity. This has not been examined in humans. Cultured clinical-grade P. falciparum parasites (NF54, 7G8, and 3D7B) and ex vivo-derived cell banks were characterized. Knob and knob-associated histidine-rich protein expression, CD36 adhesion, and antibody recognition of parasitized erythrocytes (PEs) were evaluated. Parasites from the cell banks were administered to malaria-naive human volunteers to explore infectivity. For the NF54 and 3D7B cell banks, blood was collected from the study participants for in vitro characterization. All parasites were infective in vivo However, infectivity of NF54 was dramatically reduced. In vitro characterization revealed that unlike other cell bank parasites, NF54 PEs lacked knobs and did not cytoadhere. Recognition of NF54 PEs by immune sera was observed, suggesting P. falciparum erythrocyte membrane protein 1 expression. Subsequent recovery of knob expression and CD36-mediated adhesion were observed in PEs derived from participants infected with NF54. Knobless cell bank parasites have a dramatic reduction in infectivity and the ability to adhere to CD36. Subsequent infection of malaria-naive volunteers restored knob expression and CD36-mediated cytoadherence, thereby showing that the human environment can modulate virulence.

Development of cultured Plasmodium falciparum blood-stage malaria cell banks for early phase in vivo clinical trial assessment of anti-malaria drugs and vaccines.

BACKGROUND: The ability to undertake controlled human malaria infection (CHMI) studies for preliminary evaluation of malaria vaccine candidates and anti-malaria drug efficacy has been limited by the need for access to sporozoite infected mosquitoes, aseptic, purified, cryopreserved sporozoites or blood-stage malaria parasites derived ex vivo from malaria infected individuals. Three different strategies are described for the manufacture of clinical grade cultured malaria cell banks suitable for use in CHMI studies. METHODS: Good Manufacturing Practices (GMP)-grade Plasmodium falciparum NF54, clinically isolated 3D7, and research-grade P. falciparum 7G8 blood-stage malaria parasites were cultured separately in GMP-compliant facilities using screened blood components and then cryopreserved to produce three P. falciparum blood-stage malaria cell banks. These cell banks were evaluated according to specific criteria (parasitaemia, identity, viability, sterility, presence of endotoxin, presence of mycoplasma or other viral agents and in vitro anti-malarial drug sensitivity of the cell bank malaria parasites) to ensure they met the criteria to permit product release according to GMP requirements. RESULTS: The P. falciparum NF54, 3D7 and 7G8 cell banks consisted of >78% ring stage parasites with a ring stage parasitaemia of >1.4%. Parasites were viable in vitro following thawing. The cell banks were free from contamination with bacteria, mycoplasma and a broad panel of viruses. The P. falciparum NF54, 3D7 and 7G8 parasites exhibited differential anti-malarial drug susceptibilities. The P. falciparum NF54 and 3D7 parasites were susceptible to all anti-malaria compounds tested, whereas the P. falciparum 7G8 parasites were resistant/had decreased susceptibility to four compounds. Following testing, all defined release criteria were met and the P. falciparum cell banks were deemed suitable for release. Ethical approval has been obtained for administration to human volunteers. CONCLUSIONS: The production of cultured P. falciparum blood-stage malaria cell banks represents a suitable approach for the generation of material suitable for CHMI studies. A key feature of this culture-based approach is the ability to take research-grade material through to a product suitable for administration in clinical trials.

PD-1 dependent exhaustion of CD8+ T cells drives chronic malaria.

Malaria is a highly prevalent disease caused by infection by Plasmodium spp., which infect hepatocytes and erythrocytes. Blood-stage infections cause devastating symptoms and can persist for years. Antibodies and CD4(+) T cells are thought to protect against blood-stage infections. However, there has been considerable difficulty in developing an efficacious malaria vaccine, highlighting our incomplete understanding of immunity against this disease. Here, we used an experimental rodent malaria model to show that PD-1 mediates up to a 95% reduction in numbers and functional capacity of parasite-specific CD8(+) T cells. Furthermore, in contrast to widely held views, parasite-specific CD8(+) T cells are required to control both acute and chronic blood-stage disease even when parasite-specific antibodies and CD4(+) T cells are present. Our findings provide a molecular explanation for chronic malaria that will be relevant to future malaria-vaccine design and may need consideration when vaccine development for other infections is problematic.

Malaria infection alters the expression of B-cell activating factor resulting in diminished memory antibody responses and survival.

Malaria is a major cause of morbidity worldwide with reports of over 200-500 million infected individuals and nearly 1 million deaths each year. Antibodies have been shown to play a critical role in controlling the blood stage of this disease; however, in malaria-endemic areas antibody immunity is slow to develop despite years of exposure to Plasmodium spp. the causative parasite. Using rodent Plasmodium yoelii YM, we provide evidence that malarial infections result in a decrease in the proportion of DCs that express the B-cell survival factor, BAFF, resulting in a decreased ability of these DCs to support memory B-cell differentiation into antibody secreting cells (ASCs) and/or the survival of ASCs. Further, compared with infected WT mice, ASC numbers were significantly increased in malaria-infected transgenic mice that either overexpressed BAFF or mice with BAFF-independent B-cell survival (B-cell-restricted TRAF3 deletion). Remarkably, BAFF-overexpressing mice were protected from lethal malaria infections, indicating the significance of the role BAFF plays in determining the outcome of malaria infections. These findings describe a previously unappreciated mechanism by which Plasmodium spp. can depress the generation of protective antibody responses.

Study on the interaction between methyl jasmonate and the coiled-coil domain of rice blast resistance protein Pi36 by spectroscopic methods.

Interaction between the coiled-coil domain of rice blast resistance protein Pi36 and methyl-jasmonate (MeJA) was studied by fluorescence and UV-vis spectroscopic techniques. The quenching mechanism of fluorescence of MeJA by this domain was discussed to be a static quenching procedure. Fluorescence quenching was explored to measure the number of binding sites n and apparent binding constants K. The thermodynamics parameters ΔH, ΔG, ΔS were also calculated. The results indicate the binding reaction was not entropy-driven but enthalpy-driven, and hydrophobic binding played major role in the interaction. The binding sites of MeJA with the coiled-coil structural domain of rice blast resistance protein Pi36 were found to approach the microenvironment of both Tyr and Trp by the synchronous fluorescence spectrometry. The distance r between donor (the coiled-coil domain of rice blast resistance protein Pi36) and acceptor (MeJA) was obtained according to Förster theory of non-radioactive energy transfer.

Rodent blood-stage Plasmodium survive in dendritic cells that infect naive mice.

Plasmodium spp. parasites cause malaria in 300 to 500 million individuals each year. Disease occurs during the blood-stage of the parasite's life cycle, where the parasite is thought to replicate exclusively within erythrocytes. Infected individuals can also suffer relapses after several years, from Plasmodium vivax and Plasmodium ovale surviving in hepatocytes. Plasmodium falciparum and Plasmodium malariae can also persist after the original bout of infection has apparently cleared in the blood, suggesting that host cells other than erythrocytes (but not hepatocytes) may harbor these blood-stage parasites, thereby assisting their escape from host immunity. Using blood stage transgenic Plasmodium berghei-expressing GFP (PbGFP) to track parasites in host cells, we found that the parasite had a tropism for CD317(+) dendritic cells. Other studies using confocal microscopy, in vitro cultures, and cell transfer studies showed that blood-stage parasites could infect, survive, and replicate within CD317(+) dendritic cells, and that small numbers of these cells released parasites infectious for erythrocytes in vivo. These data have identified a unique survival strategy for blood-stage Plasmodium, which has significant implications for understanding the escape of Plasmodium spp. from immune-surveillance and for vaccine development.

A novel synthetic adjuvant enhances dendritic cell function.

The lipid core peptide (LCP) is a novel, synthetic, self-adjuvanted vaccine delivery system that neatly incorporates the adjuvant, carrier and antigenic peptides of a vaccine into a single molecular entity. This system has been previously shown to efficiently deliver vaccines and induce immunity. Because adjuvants target sentinels of the immune response, such as dendritic cells (DCs), that are widely distributed throughout the body to initiate specific immune responses, we investigated the effects of the adjuvant on DCs. Here we show that LCP targets vaccines to DCs and induces their activation.

Soluble CD38 significantly prolongs the lifespan of memory B-cell responses.

The development and maintenance of memory B cells (MBC) is dependent on germinal centres (GC) with follicular dendritic cell (FDC) networks. We have previously shown that FDC networks within GC of the spleen express a novel ligand for CD38 and that the administration of soluble CD38 induces an expansion of these cellular structures. We therefore used adoptive transfer studies to investigate whether the expansion of FDC networks with soluble CD38 affected the generation and maintenance of antigen-specific MBC. These studies found that the administration of soluble CD38 significantly extended the period after which MBC could be activated and that the frequencies of these cells also were increased. In conclusion, soluble CD38 appears to significantly extend the lifespan of antibody memory by increasing the numbers of MBC.

Systemic tumor necrosis factor generated during lethal Plasmodium infections impairs dendritic cell function.

Dendritic cells (DCs) initiate innate and adaptive immune responses including those against malaria. Although several studies have shown that DC function is normal during malaria, other studies have shown compromised function. To establish why these studies had different findings, we examined DCs from mice infected with two lethal species of parasite, Plasmodium berghei or P. vinckei, and compared them to DCs from nonlethal P. yoelii 17XNL or P. chabaudi infections. These studies found that DCs from only the lethal infections became uniformly mature 7 days after infection and were functionally impaired as they were unable to endocytose latex particles, secrete IL-12, or present OVA to transgenic OTII T cells. These changes coincided with a peak in levels of systemic TNF-alpha. Because TNF-alpha is known to mature DCs, we used TNF-KO mice to determine the role of this cytokine in the loss of DC function. In the TNF-KO mice, phenotype, Ag presentation, and IL-12 secretion by DCs were restored to normal following both lethal infections. This study shows that the systemic production of TNF-alpha contributes to poor DC function during lethal infections. These studies may explain, at least in part, immunosuppression that is associated with malaria.

Plasmodium strain determines dendritic cell function essential for survival from malaria.

The severity of malaria can range from asymptomatic to lethal infections involving severe anaemia and cerebral disease. However, the molecular and cellular factors responsible for these differences in disease severity are poorly understood. Identifying the factors that mediate virulence will contribute to developing antiparasitic immune responses. Since immunity is initiated by dendritic cells (DCs), we compared their phenotype and function following infection with either a nonlethal or lethal strain of the rodent parasite, Plasmodium yoelii, to identify their contribution to disease severity. DCs from nonlethal infections were fully functional and capable of secreting cytokines and stimulating T cells. In contrast, DCs from lethal infections were not functional. We then transferred DCs from mice with nonlethal infections to mice given lethal infections and showed that these DCs mediated control of parasitemia and survival. IL-12 was necessary for survival. To our knowledge, our studies have shown for the first time that during a malaria infection, DC function is essential for survival. More importantly, the functions of these DCs are determined by the strain of parasite. Our studies may explain, in part, why natural malaria infections may have different outcomes.

Plasmodium yoelii can ablate vaccine-induced long-term protection in mice.

Malaria is a serious cause of morbidity and mortality for people living in endemic areas, but unlike many other infections, individuals exposed to the parasite do not rapidly become resistant to subsequent infections. High titers of Ab against the 19-kDa C-terminal fragment of the merozoite surface protein-1 can mediate complete protection in model systems; however, previous studies had not determined whether this vaccine generated long-term protection. In this study, we report that functional memory cells generated by merozoite surface protein-1, per se, do not offer any protection. This is because the parasite induces deletion of vaccine-specific memory B cells as well as long-lived plasma cells including those specific for bystander immune responses. Our study demonstrates a novel mechanism by which Plasmodium ablates immunological memory of vaccines, which would leave the host immuno-compromised.

Analysis of immunological nonresponsiveness to the 19-kilodalton fragment of merozoite surface Protein 1 of Plasmodium yoelii: rescue by chemical conjugation to diphtheria toxoid (DT) and enhancement of immunogenicity by prior DT vaccination.

The Plasmodium merozoite surface protein 1 (MSP1) is a leading vaccine candidate for protecting against the blood stage of malaria. Previous studies have shown that the 19-kDa carboxyl terminus of this protein is able to induce protective immunity in some monkey and mouse strains. We show that immunization with the recombinant Plasmodium yoelii 19-kDa fragment of MSP1 (MSP1(19)) expressed in Saccharomyces cerevisiae (yMSP1(19)) can induce protective antibodies in several inbred mouse strains and one outbred mouse strain. However, mice expressing the H-2(s) major histocompatibility complex haplotype are unable to generate yMSP1(19)-specific antibodies. While synthetic peptides derived from MSP1(19) are immunogenic in B10.S mice, they cannot function as helper epitopes, and immunization with yMSP1(19) does not induce T cells that recognize the recombinant protein or synthetic peptides corresponding to its sequence. Nonresponsiveness could be overcome by using chemical linkers to conjugate yMSP1(19) to diphtheria toxoid (DT), resulting in immunogens capable of inducing protective yMSP1(19)-specific antibodies in both MSP1(19)-responsive and otherwise nonresponsive mouse strains. The ability of sera from mice immunized with the conjugate to inhibit binding of a protective monoclonal antibody (MAb 302) to yMSP1(19) correlated strongly with a delay in the prepatent period. Chemical conjugation of yMSP1(19) to DT may be a preferred method to enhance immunogenicity, as carrier priming experiments demonstrated that an existing immune response to DT enhanced a subsequent antibody response to yMSP1(19) after vaccination with yMSP1(19)-DT. These results have important implications for the development of a malaria vaccine to protect a population with diverse HLAs.