Caracterização imunológica da formulação vacinal baseada em VLP (Virus Like Particle) da Proteína Circumsporozoíta de Plasmodium vivax / Immunological characterization of the VLP (Virus Like Particle) vaccine formulation fused to Circumsporozoite Protein of Plasmodium vivax

O Plasmodium vivax é a espécie mais comum de parasita causador da malária humana encontrada fora da África, com maior endemicidade na Ásia, América Central e do Sul e Oceania. Embora o Plasmodium falciparum cause a maioria do número de mortes, o P. vivax pode levar à malária grave e resultar em morbimortalidade significativa. O desenvolvimento de uma vacina protetora será um passo importante para a eliminação da malária. Recentemente, uma formulação contendo as três variantes alélicas da proteína circumsporozoíta de P. vivax (PvCSP - All epitopes) induziu proteção parcial em camundongos após desafio com esporozoíto híbrido Plasmodium berghei (Pb), no qual as repetições centrais do PbCSP foram substituídas por repetições PvCSP-VK210 (esporozoítos Pb/Pv). No presente estudo, a proteína quimérica PvCSP contendo as variantes alélicas (VK210, VK247 e P. vivax-like) fusionadas com a proteína de nucleocapsídeo do vírus da caxumba (formando partículas semelhantes a nucleocapsídeos ou do inglês, NLP - Núcleo Like Particles) na ausência (NLP-CSPR) ou na presença do domínio C-terminal (CT) conservado da PvCSP (NLP-CSPCT). Para a realização do estudo selecionamos os adjuvantes Poly (I:C), um RNA sintético de dupla fita, agonista do receptor Toll do tipo 3 (TLR3) ou o adjuvante Montanide ISA 720, uma emulação óleo em agua. Para obter uma forte resposta imune, a levedura Pichia pastoris foi usada para expressar as proteínas recombinantes na forma de NLPs. Camundongos foram imunizados com cada uma das proteínas recombinantes em combinação com os adjuvantes citados. Embora ambas as NLPs tenham sido capazes de gerar uma forte resposta imune, com altos níveis de títulos e longevidade, apenas a formulação contendo a proteína NLP-CSPCT na presença do adjuvante Poly (I:C) foi selecionada para ser explorada em experimentos futuros. Esta proteína em combinação com o adjuvante Poly (I:C) induziu alta frequência de células secretoras de anticorpos específicas para o antígeno homólogo nos dias 5 e 30, no baço e na medula óssea, respectivamente. Altos títulos de IgG contra as 3 variantes de PvCSP foram detectados nos soros. Posteriormente camundongos imunizados com NLP-CSPCT foram desafiados com esporozoítos Pb/Pv e a parasitemia no 5º dia demonstrou proteção estéril em 30% dos camundongos desafiados. Portanto, a formulação vacinal gerada neste estudo tem potencial para ser explorada no desenvolvimento de uma vacina universal contra a malária causada por P. vivax

Plasmodium vivax is the most common species of human malaria parasite found outside Africa, with high endemicity in Asia, Central and South America, and Oceania. Although Plasmodium falciparum causes the majority of deaths, P. vivax can lead to severe malaria and result in significant morbidity and mortality. The development of a protective vaccine will be a major step toward malaria elimination. Recently, a formulation containing the three allelic variants of the P. vivax circumsporozoite protein (PvCSP--All epitopes) showed partial protection in mice after a challenge with the hybrid Plasmodium berghei (Pb) sporozoite, in which the PbCSP central repeats were replaced by the VK210 PvCSP repeats (Pb/Pv sporozoite). In the present study, the chimeric PvCSP allelic variants (VK210, VK247, and P. vivax-like) were fused with the mumps virus nucleocapsid protein (assembling into nucleo like particles - NLP) in the absence (NLP-CSPR) or presence of the conserved C-terminal (CT) domain of PvCSP (NLP-CSPCT). To carry out the study, we selected the adjuvants Poly (I:C), a synthetic double-stranded RNA, Toll-like receptor 3 (TLR3) agonist or Montanide ISA 720 adjuvant, an oil-water emulation. To elicit stronger immune response, Pichia pastoris yeast was used to produce the NLPs. Mice were immunized with each recombinant protein in combination with above. Although both NLPs were able to generate stronger immune response, with high antibodies titer levels and longevity, formulation containing NLP-CSPCT in the presence of Poly (I:C) was selected to be explored in future experiments. NLP-CSPCT with Poly (I:C) adjuvant presented a high frequency of antigen-specific antibody-secreting cells (ASCs) on days 5 and 30, respectively, in the spleen and bone marrow. Moreover, high IgG titers against all PvCSP variants were detected in the sera. Later, immunized mice with NLP-CSPCT were challenged with Pb/Pv sporozoites. Sterile protection was observed in 30% of the challenged mice. Therefore, this vaccine formulation use has the potential to be a good candidate for the development of a universal vaccine against P. vivax malaria.

A closer look at multiple-clone Plasmodium vivax infections: detection methods, prevalence and consequences

The naturally occurring clonal diversity among field isolates of the major human malaria parasite Plasmodium vivax remained unexplored until the early 1990s, when improved molecular methods allowed the use of blood samples obtained directly from patients, without prior in vitro culture, for genotyping purposes. Here we briefly review the molecular strategies currently used to detect genetically distinct clones in patient-derived P. vivax samples, present evidence that multiple-clone P. vivax infections are commonly detected in areas with different levels of malaria transmission and discuss possible evolutionary and epidemiological consequences of the competition between genetically distinct clones in natural human infections. We suggest that, when two or more genetically distinct clones are present in the same host, intra-host competition for limited resources may select for P. vivax traits that represent major public health challenges, such as increased virulence, increased transmissibility and antimalarial drug resistance.

Plasmodium falciparum: detection and strain identification of Indian isolates by polymerase chain reaction.

The polymerase chain reaction (PCR) was employed for detection and strain identification of P. falciparum in a comparative field study of Indian isolates. The primers were selected from highly conserved regions flanking the variable, tandemly repeated regions of highly polymorphic cell surface antigens, major merozoite surface antigen-1 (MSP-1), major surface antigen-2 (MSP-2), circumsporozoite surface antigen (CSP) and ring-infected erythrocyte surface antigen (RESA). Out of the 52 microscopically positive P. falciparum infected field samples, 47 samples were positive by PCR. Variation in the size of the amplified products was observed using MSP-1, MSP-2 specific primers respectively in different field isolates of P. falciparum, but CSP and RESA did not exhibit any variation in size of the amplified product. The multiplex PCR results demonstrated that amplified products from these surface antigens vary in size and there is a specific pattern for each strain and this could be utilized to identify a particular field isolate. One P. falciparum infected field sample detected by the above PCR method was found to be a mixed infection by two different strains. Five microscopically positive P. vivax infeced samples were also analyzed by PCR method using P. falciparum cell surface antigen (MSP-2) specific primers. PCR results showed one P. vivax infected sample was positive when P. falciparum specific primers were used, this could be due to inaccurate and reduced limit of detection of Plasmodial species by microscopic examination.

Antigenic diversity of Plasmodium vivax and their geographic distribution in Thailand.

Fifty-eight monoclonal antibodies (MAbs) raised against the erythrocytic stages of Plasmodium vivax were selected for typing of 501 P. vivax isolates from different geographic locations throughout Thailand. Based on their reactivities in the indirect fluorescent antibody test, these MAbs were classified into five groups: group I MAbs showing generalized staining of all blood stages; group II MAbs reacting with merozoites and their organelles; group III MAbs reacting with the surface membrane of merozoites; Group V MAbs reacting with the surface membrane of trophozoites and schizonts; and group VII MAbs reacting with internal components of the parasites. Sixteen MAbs reacted with more than 95% of the isolates; the epitopes recognized by these MAbs were considered as being invariant. The remaining MAbs reacted with 30-90% of the isolates, and the epitopes recognized by these MAbs were regarded as being variable. The variant epitopes were associated with > 200-, 135-, and 100-kilodalton (kDa) molecules of all blood stages, the 95-kDa molecule on merozoite organelles, the 200-kDa molecule on the surface of trophozoites and schizonts, and the 85-kDa molecule of the parasite internal components. Antigenic diversity occurred among the P. vivax population in the endemic areas of Thailand and was shown to vary from place to place and was highest in the area with the highest rate of transmission along the Myanmar border in western Thailand and along the Cambodian border in eastern Thailand, including Trat (48.4%), Tak (41.7%), Chantaburi (36.5%), and Mae Hong Son (36.4%). Demonstration of antigenic diversity of P. vivax parasites signals a note of caution in the development of vaccines for vivax malaria. The vaccines should be directed against protective, conserved and not against variant epitopes.

Antigenic disparity of Plasmodium vivax causing initial symptoms and causing relapse.

Relapse infections are an important obstacle to the successful treatment and control of Plasmodium vivax malaria, but little is known about the nature of the relapse. To provide insight into the antigenic disparity of the parasites causing initial clinical symptoms and causing relapse, a panel of 58 monoclonal antibodies (MAbs) against erythrocytic stages of Plasmodium vivax was tested by indirect fluorescent antibody test in five relapse cases. The initial and relapse strains from three patients (R3, R4, and R5) exhibited similar IFA reactivity with all MAbs tested, whereas the isolates from two relapse cases (R1 and R2) showed different patterns of reactivity and were seen only with 15 MAbs In case R1, different IFA reactivities were observed with 12 MAbs, nine of which reacted with the initial (RPV261) but not the relapse (RPV393) isolates, whereas the other three MAbs reacted only with the relapse isolates. With regards to the second relapse case (R2) in whom two relapses occurred, different IFA reactivities were demonstrated with seven MAbs that reacted only with the initial isolate (RPV 182) and with the isolate from the first relapse (RPV 240) but not with the isolate from the second relapse (RPV 300). The antibody responses from patients who developed primary clinical symptoms and relapse were detected by Western immunoblotting. In cases R3, R4 and R5, there was no difference in the spectrum of antigens from initial and relapse sera recognized by the antibodies. In contrast, in cases R1 and R2, the molecules recognized by antibodies in initial and relapse sera were markedly altered. In case R1, the series of molecules of P. vivax antigens recognized by initial (RPV 261) and relapse (RPV 393) sera were 21, 25, 31, 39, 42, 61, 95, 115, 200, > 200 kDa and 21, 24, 31, 35, 57, 75, 200, > 200 kDa, respectively. In case R2, the initial serum (RPV 182) recognized P. vivax antigens with molecular weights of 23, 30, 52, 57, 68, 75, 85, 95, 115, and 195 kDa while the first relapse (RPV 240) and the second relapse sera recognized P. vivax antigens with molecular weights of 23, 30, 52, 85, 95,115 kDa and 30, 57, 68, 75, 85,195 kDa, respectively.

Plasmodium Vivax resistente a la Cloroquina en la Consulta Externa Pediátrica de Villavicencio

Se revisaron las hostirias clínicas de 671 pacientes quienes asistieron a la consulta externa de pediatría y presentaron como diagnóstico malaria, en un período de 36 meses comprendido entre el 1 de enero de 1993 y 31 de diciembre de 1995. El diagnóstico de malaria se llevó a cabo por parasitemia positiva en gota gruesa y/o extendido de sangre periférica mediante la coloración de Field. Se hallaron 166 pacientes quienes cursaron con malaria por Plasmodium falciparum y 505 por Plasmo-dium vivax de los cuales 9 presentaron resistencia clínica al tratamiento con cloroquina, para lo cual nos basamos en los criterios propuestos por la Organización Mundial de la Salud en 1967. Se analizó en estos 9 pacientes su distribución por sexo, edad, procedencia, tipo de resistencia y respuesta al tratamiento. Proponemos un manejo terapéutico para el Plasmodium vivax resistente a la cloroquina que nos fue efectivo en la totalidad de los casos, sin la necesidad de utilizar nuevas drogas