Multiplicity of infection of Plasmodium knowlesi in Malaysia: an application of Pkmsp-1 block IV

@#In Malaysia presently, the main cause of human malaria is by the zoonotic monkey parasite Plasmodium knowlesi. A previous study has suggested that the P. knowlesi merozoite surface protein 1 (Pkmsp-1) block IV to be a suitable multiplicity of infection (MOI) genotyping marker for knowlesimalaria. This study therefore aimed to investigate the usefulness of Pkmsp-1 block IV in assessing the MOI of P. knowlesi in clinical isolates from Malaysia. Two allele-specific PCR primer pairs targeting the two allelic families of block IV (T1 and T2) were designed, and used to genotype P. knowlesi in 200 blood samples (100 from Peninsular Malaysia and 100 from Malaysian Borneo). Results showed that the mean MOI in Malaysian Borneo was slightly higher as compared to Peninsular Malaysia (1.58 and 1.40, respectively). Almost half of the total blood samples from Malaysian Borneo (52%) had polyclonal infections (i.e., more than one allele of any family type) as compared to Peninsular Malaysia (33%) samples. The T1 allelic family was more prevalent in Peninsular Malaysia (n=75) than in Malaysian Borneo (n=60). The T2 allelic family, however, was more prevalent in the Malaysian Borneo (n=87 vs n=53 respectively). This study shows that the single locus Pkmsp-1 block IV can serve as a simple alternative genetic marker for estimating knowlesi malaria MOI in a population. Future MOI studies should focus on macaque populations as macaques are the natural host of P. knowlesi.

PCR-RFLP Based genetic diversity of Plasmodium vivax genotypes in district Mardan, Pakistan / Diversidade genética baseada em PCR RFLP de genótipos de Plasmodium vivax no distrito de Mardan, Paquistão

Plasmodium vivax is the most common human malaria parasite in Asian countries including Pakistan. Present study was designed to explore the genetic diversity of plasmodium vivax genotypes based on Pvmsp-3α and Pvmsp-3βgenes using allelic specific nested PCR and RFLP assays markers from field isolates in district Mardan, Pakistan. Blood samples of 200 P. vivax malarial patients were collected after taking their written informed consent. Genetic diversity in nested PCR products was determined by Restriction Fragment Length Polymorphism (RFLP) utilizing Alu1 and PstI restriction enzymes for alpha and beta gene products digestion, respectively. For analysis the genetic diversity of the sub allelic variants of Pvmsp3α and Pvmsp3β genes, Chi-Square test was performed by utilizing Minitab programming software 18. The P value 0.05 was considered as statistically significant. For Pvmsp 3α genes after gel electrophoresis of digested products, four distinct genotypes were obtained from total of 50 samples; type A: 35 (70%) (1.5-2.0 kb), 12 of type B (24%) (1.5-1.7 kb), 2 of type C (4%) (0.5-1.5) and one for type D (2%) (0.5-0.65 kb) which could be characterized into 9 allelic pattern (A1-A4, B1-B3, C1, D), in which A3 remained the most predominant. For Pvmsp-3βgenes, three distinct genotypes were obtained from 50 samples; 40(80%) of type A (1.5-2.5 kb), 9 (18%) of type B (1.0-1.5kb) and 1(2%) of type C (0.65 kb) which could be characterized into 6 allelic patterns (A1-A3, B1-B2, and C1). Most dominant one in Type A was A1 alleles which were noted (46%), while in Type B, the most dominant were B1 (10%).This study is the first ever report of molecular epidemiology and genetic variation in Pvmsp-3α and Pvmsp-3β genes of P. vivax isolates by using PCR/RFLP from District Mardan and [...].

O Plasmodium vivax é o parasita da malária humana mais comum nos países asiáticos, incluindo o Paquistão. O presente estudo foi desenhado para explorar a diversidade genética de genótipos de Plasmodium vivax baseados nos genes Pvmsp-3α e Pvmsp-3β, usando marcadores de ensaios alélicos nested PCR e RFLP de isolados de campo no distrito de Mardan, Paquistão. Amostras de sangue de 200 pacientes com malária por P. vivax foram coletadas após assinatura do termo de consentimento livre e esclarecido. A diversidade genética em produtos de PCR nested foi determinada por polimorfismo de fragmento de restrição (RFLP) utilizando as enzimas de restrição Alu1 e PstI para a digestão dos produtos dos genes alfa e beta, respectivamente. Para análise da diversidade genética das variantes subalélicas dos genes Pvmsp3α e Pvmsp3β, o teste Qui-quadrado foi realizado utilizando o software de programação Minitab 18. O valor P = 0,05 foi considerado estatisticamente significativo. Para os genes Pvmsp 3α, após eletroforese em gel de produtos digeridos, quatro genótipos distintos foram obtidos de um total de 50 amostras; tipo A: 35 (70%) (1,5-2,0 kb), 12 do tipo B (24%) (1,5-1,7 kb), 2 do tipo C (4%) (0,5-1,5) e um para o tipo D (2%) (0,5-0,65 kb), que podem ser caracterizados em nove padrões alélicos (A1-A4, B1-B3, C1, D), em que A3 permaneceu como o mais predominante. Para Pvmsp-3βgenes, três genótipos distintos foram obtidos a partir de 50 amostras; 40 (80%) do tipo A (1,5-2,5 kb), 9 (18%) do tipo B (1,0-1,5 kb) e 1 (2%) do tipo C (0,65 kb), que podem ser caracterizados em seis padrões alélicos (A1-A3, B1-B2 e C1). Os mais dominantes no tipo A foram o alelo A1, observados em 46%, enquanto, no tipo B, os mais dominantes foram B1 (10%). Este estudo é o primeiro relato de epidemiologia molecular e variação genética em Pvmsp-3α. Os genes Pvmsp-3β de isolados de P. vivax utilizando PCR/RFLP do Distrito Mardan mostraram um nível notável de diversidade genética nos genes estudados [...].

PCR-RFLP Based genetic diversity of Plasmodium vivax genotypes in district Mardan, Pakistan

Abstract Plasmodium vivax is the most common human malaria parasite in Asian countries including Pakistan. Present study was designed to explore the genetic diversity of plasmodium vivax genotypes based on Pvmsp-3 and Pvmsp-3genes using allelic specific nested PCR and RFLP assays markers from field isolates in district Mardan, Pakistan. Blood samples of 200 P. vivax malarial patients were collected after taking their written informed consent. Genetic diversity in nested PCR products was determined by Restriction Fragment Length Polymorphism (RFLP) utilizing Alu1 and PstI restriction enzymes for alpha and beta gene products digestion, respectively. For analysis the genetic diversity of the sub allelic variants of Pvmsp3 and Pvmsp3 genes, Chi-Square test was performed by utilizing Minitab programming software 18. The P value 0.05 was considered as statistically significant. For Pvmsp-3 genes after gel electrophoresis of digested products, four distinct genotypes were obtained from total of 50 samples; type A: 35 (70%) (1.5-2.0 kb), 12 of type B (24%) (1.5-1.7 kb), 2 of type C (4%) (0.5-1.5) and one for type D (2%) (0.5-0.65 kb) which could be characterized into 9 allelic pattern (A1-A4, B1-B3, C1, D), in which A3 remained the most predominant. For Pvmsp-3genes, three distinct genotypes were obtained from 50 samples; 40(80%) of type A (1.5-2.5 kb), 9 (18%) of type B (1.0-1.5kb) and 1(2%) of type C (0.65 kb) which could be characterized into 6 allelic patterns (A1-A3, B1-B2, and C1). Most dominant one in Type A was A1 alleles which were noted (46%), while in Type B, the most dominant were B1 (10%).This study is the first ever report of molecular epidemiology and genetic variation in Pvmsp-3 and Pvmsp-3 genes of P. vivax isolates by using PCR/RFLP from District Mardan and showed a remarkable level of genetic diversity in the studied genes of circulating parasites in the study area. The results of this study will contribute in future studies about the genetic structure of parasite and vaccine development against the malaria.

Resumo O Plasmodium vivax é o parasita da malária humana mais comum nos países asiáticos, incluindo o Paquistão. O presente estudo foi desenhado para explorar a diversidade genética de genótipos de Plasmodium vivax baseados nos genes Pvmsp-3 e Pvmsp-3, usando marcadores de ensaios alélicos nested PCR e RFLP de isolados de campo no distrito de Mardan, Paquistão. Amostras de sangue de 200 pacientes com malária por P. vivax foram coletadas após assinatura do termo de consentimento livre e esclarecido. A diversidade genética em produtos de PCR nested foi determinada por polimorfismo de fragmento de restrição (RFLP) utilizando as enzimas de restrição Alu1 e PstI para a digestão dos produtos dos genes alfa e beta, respectivamente. Para análise da diversidade genética das variantes subalélicas dos genes Pvmsp3 e Pvmsp3, o teste Qui-quadrado foi realizado utilizando o software de programação Minitab 18. O valor P = 0,05 foi considerado estatisticamente significativo. Para os genes Pvmsp-3, após eletroforese em gel de produtos digeridos, quatro genótipos distintos foram obtidos de um total de 50 amostras; tipo A: 35 (70%) (1,5-2,0 kb), 12 do tipo B (24%) (1,5-1,7 kb), 2 do tipo C (4%) (0,5-1,5) e um para o tipo D (2%) (0,5-0,65 kb), que podem ser caracterizados em nove padrões alélicos (A1-A4, B1-B3, C1, D), em que A3 permaneceu como o mais predominante. Para Pvmsp-3genes, três genótipos distintos foram obtidos a partir de 50 amostras; 40 (80%) do tipo A (1,5-2,5 kb), 9 (18%) do tipo B (1,0-1,5 kb) e 1 (2%) do tipo C (0,65 kb), que podem ser caracterizados em seis padrões alélicos (A1-A3, B1-B2 e C1). Os mais dominantes no tipo A foram o alelo A1, observados em 46%, enquanto, no tipo B, os mais dominantes foram B1 (10%). Este estudo é o primeiro relato de epidemiologia molecular e variação genética em Pvmsp-3. Os genes Pvmsp-3 de isolados de P. vivax utilizando PCR/RFLP do Distrito Mardan mostraram um nível notável de diversidade genética nos genes estudados de parasitas circulantes na área de estudo. Os resultados desse estudo contribuirão em estudos futuros sobre a estrutura genética do parasita e o desenvolvimento de vacinas contra a malária.

PCR-RFLP Based genetic diversity of Plasmodium vivax genotypes in district Mardan, Pakistan / Diversidade genética baseada em PCR-RFLP de genótipos de Plasmodium vivax no distrito de Mardan, Paquistão

Plasmodium vivax is the most common human malaria parasite in Asian countries including Pakistan. Present study was designed to explore the genetic diversity of plasmodium vivax genotypes based on Pvmsp-3α and Pvmsp-3ßgenes using allelic specific nested PCR and RFLP assays markers from field isolates in district Mardan, Pakistan. Blood samples of 200 P. vivax malarial patients were collected after taking their written informed consent. Genetic diversity in nested PCR products was determined by Restriction Fragment Length Polymorphism (RFLP) utilizing Alu1 and PstI restriction enzymes for alpha and beta gene products digestion, respectively. For analysis the genetic diversity of the sub allelic variants of Pvmsp3α and Pvmsp3ß genes, Chi-Square test was performed by utilizing Minitab programming software 18. The P value 0.05 was considered as statistically significant. For Pvmsp3α genes after gel electrophoresis of digested products, four distinct genotypes were obtained from total of 50 samples; type A: 35 (70%) (1.5-2.0 kb), 12 of type B (24%) (1.5-1.7 kb), 2 of type C (4%) (0.5-1.5) and one for type D (2%) (0.5-0.65 kb) which could be characterized into 9 allelic pattern (A1-A4, B1-B3, C1, D), in which A3 remained the most predominant. For Pvmsp-3ßgenes, three distinct genotypes were obtained from 50 samples; 40(80%) of type A (1.5-2.5 kb), 9 (18%) of type B (1.0-1.5kb) and 1(2%) of type C (0.65 kb) which could be characterized into 6 allelic patterns (A1-A3, B1-B2, and C1). Most dominant one in Type A was A1 alleles which were noted (46%), while in Type B, the most dominant were B1 (10%).This study is the first ever report of molecular epidemiology and genetic variation in Pvmsp-3α and Pvmsp-3ß genes of P. vivax isolates by using PCR/RFLP from District Mardan and showed a remarkable level of genetic diversity in the studied genes of circulating parasites in the study area. The results of this study will contribute in future studies about the genetic structure of parasite and vaccine development against the malaria.

O Plasmodium vivax é o parasita da malária humana mais comum nos países asiáticos, incluindo o Paquistão. O presente estudo foi desenhado para explorar a diversidade genética de genótipos de Plasmodium vivax baseados nos genes Pvmsp-3α e Pvmsp-3ß, usando marcadores de ensaios alélicos nested PCR e RFLP de isolados de campo no distrito de Mardan, Paquistão. Amostras de sangue de 200 pacientes com malária por P. vivax foram coletadas após assinatura do termo de consentimento livre e esclarecido. A diversidade genética em produtos de PCR nested foi determinada por polimorfismo de fragmento de restrição (RFLP) utilizando as enzimas de restrição Alu1 e PstI para a digestão dos produtos dos genes alfa e beta, respectivamente. Para análise da diversidade genética das variantes subalélicas dos genes Pvmsp3α e Pvmsp3ß, o teste Qui-quadrado foi realizado utilizando o software de programação Minitab 18. O valor P = 0,05 foi considerado estatisticamente significativo. Para os genes Pvmsp3α, após eletroforese em gel de produtos digeridos, quatro genótipos distintos foram obtidos de um total de 50 amostras; tipo A: 35 (70%) (1,5-2,0 kb), 12 do tipo B (24%) (1,5-1,7 kb), 2 do tipo C (4%) (0,5-1,5) e um para o tipo D (2%) (0,5-0,65 kb), que podem ser caracterizados em nove padrões alélicos (A1-A4, B1-B3, C1, D), em que A3 permaneceu como o mais predominante. Para Pvmsp-3ßgenes, três genótipos distintos foram obtidos a partir de 50 amostras; 40 (80%) do tipo A (1,5-2,5 kb), 9 (18%) do tipo B (1,0-1,5 kb) e 1 (2%) do tipo C (0,65 kb), que podem ser caracterizados em seis padrões alélicos (A1-A3, B1-B2 e C1). Os mais dominantes no tipo A foram o alelo A1, observados em 46%, enquanto, no tipo B, os mais dominantes foram B1 (10%). Este estudo é o primeiro relato de epidemiologia molecular e variação genética em Pvmsp-3α. Os genes Pvmsp-3ß de isolados de P. vivax utilizando PCR/RFLP do Distrito Mardan mostraram um nível notável de diversidade genética nos genes estudados de parasitas circulantes na área de estudo. Os resultados desse estudo contribuirão em estudos futuros sobre a estrutura genética do parasita e o desenvolvimento de vacinas contra a malária.

Low Levels of Polymorphisms and Negative Selection in Plasmodum knowlesi Merozoite Surface Protein 8 in Malaysian Isolates

Human infections due to the monkey malaria parasite Plasmodium knowlesi is increasingly being reported from most Southeast Asian countries specifically Malaysia. The parasite causes severe and fatal malaria thus there is a need for urgent measures for its control. In this study, the level of polymorphisms, haplotypes and natural selection of full-length pkmsp8 in 37 clinical samples from Malaysian Borneo along with 6 lab-adapted strains were investigated. Low levels of polymorphism were observed across the full-length gene, the double epidermal growth factor (EGF) domains were mostly conserved, and non-synonymous substitutions were absent. Evidence of strong negative selection pressure in the non-EGF regions were found indicating functional constrains acting at different domains. Phylogenetic haplotype network analysis identified shared haplotypes and indicated geographical clustering of samples originating from Peninsular Malaysia and Malaysian Borneo. This is the first study to genetically characterize the full-length msp8 gene from clinical isolates of P. knowlesi from Malaysia; however, further functional characterization would be useful for future rational vaccine design.

Receptores del hospedero implicados en la invasión del merozoito de Plasmodium falciparum: revisión / Host receptors involved in the invasion of Plasmodium falciparum merozoite: Review / Receptores do hospedeiro envolvidos na invasão do merozoíto de Plasmodium falciparum: revisão

Introducción. La malaria es un problema de salud pública a nivel mundial y es causada por 5 especies de parásitos apicomplejos del género Plasmodium. La invasión exitosa de los merozoítos al glóbulo rojo es una etapa fundamental en el ciclo de vida del parásito, el cual usa un variado repertorio de ligandos que interactúan de forma específica con receptores presentes en la membrana del glóbulo rojo. Objetivo. Revisar las características moleculares y estructurales de los receptores expresados en la superficie de los glóbulos rojos, implicados en el proceso de invasión del merozoito de Plasmodium falciparum. Método. Revisión descriptiva sobre las características moleculares y estructurales de los receptores de la superficie del glóbulo rojo, los cuales juegan un papel fundamental durante la invasión del merozoíto de Plasmodium falciparum. Esta revisión empezó por la búsqueda de literatura publicada hasta el año 2019 en bases de datos electrónicas, especializadas en la divulgación de investigación biomédica. Se encontraron 127 documentos, de los cuales se seleccionaron 111 y se excluyeron 33 por no cumplir los criterios de inclusión; en total, se analizaron 78 referencias. Conclusión. En esta revisión se resumieron las características moleculares y estructurales de los receptores presentes en el glóbulo rojo importantes en el proceso de invasión del merozoito de P. falciparum. También, se resaltó la importancia de elucidar las diferentes vías de invasión del parásito y así, poder desarrollar alternativas profilácticas o terapéuticas que conduzcan a mitigar o eliminar la malaria

Introduction. Malaria is a public health problem worldwide. It is caused by 5 species of the Apicomplexa genus Plasmodium. The successful invasion of the erythrocyte by Plasmodium merozoites is a critical stage in the life cycle of the parasite, which uses a broad repertoire of ligands that interact in a specific way with receptors expressed on the membrane of the erythrocyte. Objective. To review the molecular and structural characteristics of the receptors expressed on the erythrocyte surface, involved in the process of merozoite invasion by Plasmodium falciparum. Method. Here, we descriptively review of the molecular and structural characteristics of the red blood cell surface receptors, which play a key role during the invasion of Plasmodum falciparum merozoite. To this purpose, we searched the literature published until 2019 in electronic databases specialized in biomedical research. 127 documents were found, of these, 111 were selected, 33 were excluded and 78 references were analyzed. Conclusion. In this review, the molecular and structural characteristics of the receptors expressed on the erythrocytes and important in the process of invasion of P. falciparum merozoites were discussed. With this, we highlight the importance of elucidating the different invasion pathways the parasite, in order to develop prophylactic or therapeutic alternatives that could lead to mitigate or eliminate malaria.

Introdução. A malária é um problema de saúde pública a nível mundial, é causada por 5 espécies de parasitos do Filo Apicomplexa, do gênero Plasmodium. A invasão bem-sucedida de merozoítos nas hemácias, é uma etapa fundamental no ciclo de vida do parasita, que usa um repertório variado de ligandos que interatuam especificamente com receptores presentes na membrana dos glóbulos vermelhos. Objetivo. Revisão descritiva das características moleculares e estruturais dos receptores da superfície dos glóbulos vermelhos, que desempenham um papel fundamental durante a invasão do merozoíto de Plasmodium falciparum. Método. Revisão descritiva das características moleculares e estruturais dos receptores da superfície dos glóbulos vermelhos, que desempenham um papel fundamental durante a invasão do merozoíto de Plasmodium falciparum. Esta revisão foi baseada na pesquisa de literatura publicada até 2019 nas bases de dados eletrônicas especializadas na divulgação de pesquisas biomédicas. Foram encontrados 127 documentos, dos quais 111 foram selecionados e 33 foram excluídos por não apresentarem os critérios de inclusão, analisando um total de 78 referências. Conclusão. Nesta revisão, foram resumidas as características moleculares e estruturais dos receptores presentes nos glóbulos vermelhos, importantes no processo de invasão do merozoíto de P. falciparum. Também foi destacada a importância de elucidar as diferentes vias de invasão do parasita, a fim de desenvolver alternativas profiláticas ou terapêuticas que levem a mitigar ou eliminar a malária.

Diagnosis of Malarial infection on Mongolian Troops who working UN mission in Africa / Эрүүл мэндийн лаборатори

Abstract@#Malaria is an ancient disease caused by parasites of the genus <i>Plasmodium</i> and transmitted by several species of female anopheline mosquitoes. The term „malaria‟ originates from <i>mal’aria</i> (Italian) –signifying „bad air‟ or miasmas arising from marshes. </br> Cognizant of the burden of the disease in antiquity, several efforts have been made to understand the disease notably, the detection of the <i>Plasmodium</i> parasite in the blood of infected humans in 1880, as well as proof of the complete life cycle of malaria parasites in mosquitoes in 1897. </br> Among 200 <i>Plasmodium</i> species identified <i>P. falciparum, P. vivax, P. ovale, P. malariae and P. knowlesi </i>are known to be responsible for human malaria, while mortality due to malaria is mostly attributed to infections with <i>P. falciparum.</i></br> The <i>Anopheles</i> mosquito bites a human and injects sporozoite forms. These move to the liver and invade hepatocytes, in which they develop to produce exoerythrocytic merozoite forms that are released into the blood stream. Merozoites invade erythrocytes and grow into trophozoites and mature schizonts. Merozoites are released that reinvade new erythrocytes.</br> Gametocytes, formed from the asexual blood stage, are taken up by a feeding mosquito into the gut where they mature to form male and female gametes. The fertilized zygote develops to an ookinete and an oocyst and finally sporozoites that migrate to the salivary glands.</br> Malaria transmission exits in 99 countries throughout world, and the greater burden of the disease is carried by African countries. According to the World Health Organization (WHO), the estimated cases of and deaths due to malaria in 2016 were 219 million and 660,000, respectively with malaria deaths steadily decreasing since 1980. Despite the decline in the burden of malaria with the scaling-up of interventions the fact that the estimated (uncertainty exists) number of malaria deaths in 2016 exceeded that of 1980 calls for more efforts in the prevention and control of the disease.</br> Mongolian troops have been participating at UN mission since 2003. They work very complicated condition. One of the simple risks is Malaria. We had approximately 80 cases who had been infected by malaria at the mission area. </br> Mongolia is land without malaria infection. But our tourists can visit all of the world and troops works on mission area in Africa. They have a risk of malaria and our doctors have to be diagnosis and treat to malaria cases. This article provides an overview of malaria laboratory diagnosis and epidemiological data that will lead to the development of strategies to diagnose and reduce infection.

Genetic Diversity and Natural Selection in 42 kDa Region of Plasmodium vivax Merozoite Surface Protein-1 from China-Myanmar Endemic Border

Plasmodium vivax merozoite surface protein-1 (PvMSP1) gene codes for a major malaria vaccine candidate antigen. However, its polymorphic nature represents an obstacle to the design of a protective vaccine. In this study, we analyzed the genetic polymorphism and natural selection of the C-terminal 42 kDa fragment within PvMSP1 gene (Pv MSP142) from 77 P. vivax isolates, collected from imported cases of China-Myanmar border (CMB) areas in Yunnan province and the inland cases from Anhui, Yunnan, and Zhejiang province in China during 2009–2012. Totally, 41 haplotypes were identified and 30 of them were new haplotypes. The differences between the rates of non-synonymous and synonymous mutations suggest that PvMSP142 has evolved under natural selection, and a high selective pressure preferentially acted on regions identified of PvMSP133. Our results also demonstrated that PvMSP142 of P. vivax isolates collected on China-Myanmar border areas display higher genetic polymorphisms than those collected from inland of China. Such results have significant implications for understanding the dynamic of the P. vivax population and may be useful information towards China malaria elimination campaign strategies.

Characterization of Pv92, a Novel Merozoite Surface Protein of Plasmodium vivax

The discovery and understanding of antigenic proteins are essential for development of a vaccine against malaria. In Plasmodium falciparum, Pf92 have been characterized as a merozoite surface protein, and this protein is expressed at the late schizont stage, but no study of Pv92, the orthologue of Pf92 in P. vivax, has been reported. Thus, the protein structure of Pv92 was analyzed, and the gene sequence was aligned with that of other Plasmodium spp. using bioinformatics tools. The recombinant Pv92 protein was expressed and purified using bacterial expression system and used for immunization of mice to gain the polyclonal antibody and for evaluation of antigenicity by protein array. Also, the antibody against Pv92 was used for subcellular analysis by immunofluorescence assay. The Pv92 protein has a signal peptide and a sexual stage s48/45 domain, and the cysteine residues at the N-terminal of Pv92 were completely conserved. The N-terminal of Pv92 was successfully expressed as soluble form using a bacterial expression system. The antibody raised against Pv92 recognized the parasites and completely merged with PvMSP1-19, indicating that Pv92 was localized on the merozoite surface. Evaluation of the human humoral immune response to Pv92 indicated moderate antigenicity, with 65% sensitivity and 95% specificity by protein array. Taken together, the merozoite surface localization and antigenicity of Pv92 implicate that it might be involved in attachment and invasion of a merozoite to a new host cell or immune evasion during invasion process.

Cocktail of Theileria equi antigens for detecting infection in equines

Objective: To use two diagnostic antigens belonging to the frequently associated in Theileria domain, Theileria equi (T. equi) protein 82 (Te 82) and T. equi 104 kDa microneme-rhoptry antigen precursor (Te 43), to diagnose T. equi infection in horses as compared with equi merozoite antigen-2 (EMA-2). Methods: In the current study, we applied a cocktail-ELISA containing two antigens (EMA-2+Te 82) to diagnose T. equi infection either in experimentally infected horses or in field infection. Results: Our findings have revealed that a cocktail formula of EMA-2+Te 82 provided a more practical and sensitive diagnostic candidate for diagnosing T. equi infection in horses as compared with Te 82 or Te 43 alone. Conclusions: The ELISA technique using a cocktail formula of EMA-2+Te 82 offers a practical and sensitive diagnostic tool for diagnosing T. equi infection in horses and using of this promising cocktail formula will be applicable for epidemiological surveys and will help control the infection in horses.

Immunogenicity of the merozoite surface protein-1 (msp-1) of human plasmodium sp

Malaria is a major cause of mortality and morbidity globally. Great efforts have been made in the prevention and the elimination of malaria, especially in controlling the malaria vector, the mosquito. Another promising approach would be the development of malaria vaccines. Malaria vaccine studies can be focused on the pre-erythrocytic-stage antigens and the blood-stage antigens, and on the transmission blocking agents targeting the malaria gametocytes. The blood-stage antigens are the leading candidates in malaria vaccine development, as the blood-stage parasites are responsible for causing symptomatic malaria. Human acquired immunity largely targets on blood-stage antigens. This review focuses on one of the most extensively studied blood-stage antigen, the merozoite surface protein-1 (MSP-1), specifically on its evaluation and immunogenicity in rodents and primate models, and its safety and immunogenicity in human clinical trials.

Allelic Diversity and Geographical Distribution of the Gene Encoding Plasmodium falciparum Merozoite Surface Protein-3 in Thailand

Merozoite surface proteins (MSPs) of malaria parasites play critical roles during the erythrocyte invasion and so are potential candidates for malaria vaccine development. However, because MSPs are often under strong immune selection, they can exhibit extensive genetic diversity. The gene encoding the merozoite surface protein-3 (MSP-3) of Plasmodium falciparum displays 2 allelic types, K1 and 3D7. In Thailand, the allelic frequency of the P. falciparum msp-3 gene was evaluated in a single P. falciparum population in Tak at the Thailand and Myanmar border. However, no study has yet looked at the extent of genetic diversity of the msp-3 gene in P. falciparum populations in other localities. Here, we genotyped the msp-3 alleles of 63 P. falciparum samples collected from 5 geographical populations along the borders of Thailand with 3 neighboring countries (Myanmar, Laos, and Cambodia). Our study indicated that the K1 and 3D7 alleles coexisted, but at different proportions in different Thai P. falciparum populations. K1 was more prevalent in populations at the Thailand-Myanmar and Thailand-Cambodia borders, whilst 3D7 was more prevalent at the Thailand-Laos border. Global analysis of the msp-3 allele frequencies revealed that proportions of K1 and 3D7 alleles of msp-3 also varied in different continents, suggesting the divergence of malaria parasite populations. In conclusion, the variation in the msp-3 allelic patterns of P. falciparum in Thailand provides fundamental knowledge for inferring the P. falciparum population structure and for the best design of msp-3 based malaria vaccines.

Limited genetic diversity among Plasmodium falciparium isolates using nested PCR in Jazan Area, Saudi Arabia

Objective: To establish molecular characterization of Plasmodium falciparum field isolates in Jazan Area of Saudi Arabia measured with highly polymorphic genetic marker, i.e. the merozoite surface protein 2 (MSP 2). Methods: Blood samples were collected from 128 clinically suspected patients attending both Jazan and Sabia hospitals, Kingdom of Saudi Arabia. Both hospitals reflected urban and rural settings respectively. Analysis of central polymorphic region of MSP 2 (3D7 and FC27 allelic families) was performed using nested PCR for malaria patients. Results: For MSP 2 allelic families of Plasmodium falciparum, 16 cases (53.3%) carried FC27 type and 14 cases (46.7%) carried 3D7 type, whereas no malaria cases harbored both allelic types. The present study showed that in urban area, 80% of FC27 fragments were 500 bp while in rural area it was 45.5% (P = 0.08). The FC27 400 bp allele was more prevalent in patients from rural than those from the urban area (P = 0.08). The most prevalent infecting 3D7 allele was the 3D7 300 bp in both areas. In the present study, there were no multiple infections. Conclusions: The limited genetic diversity which was observed in Jazan (considered as an endemic area) may be attributed to the small sample size or sustained malaria control program.

Cocktail of Theileria equi antigens for detecting infection in equines

Objective: To use two diagnostic antigens belonging to the frequently associated in Theileria domain, Theileria equi (T. equi) protein 82 (Te 82) and T. equi 104 kDa microneme-rhoptry antigen precursor (Te 43), to diagnose T. equi infection in horses as compared with equi merozoite antigen-2 (EMA-2). Methods: In the current study, we applied a cocktail-ELISA containing two antigens (EMA-2 + Te 82) to diagnose T. equi infection either in experimentally infected horses or in field infection. Results: Our findings have revealed that a cocktail formula of EMA-2 + Te 82 provided a more practical and sensitive diagnostic candidate for diagnosing T. equi infection in horses as compared with Te 82 or Te 43 alone. Conclusions: The ELISA technique using a cocktail formula of EMA-2 + Te 82 offers a practical and sensitive diagnostic tool for diagnosing T. equi infection in horses and using of this promising cocktail formula will be applicable for epidemiological surveys and will help control the infection in horses.

Evolution of Genetic Polymorphisms of Plasmodium falciparum Merozoite Surface Protein (PfMSP) in Thailand

Plasmodium falciparum malaria is a major public health problem in Thailand due to the emergence of multidrug resistance. The understanding of genetic diversity of malaria parasites is essential for developing effective drugs and vaccines. The genetic diversity of the merozoite surface protein-1 (PfMSP-1) and merozoite surface protein-2 (PfMSP-2) genes was investigated in a total of 145 P. falciparum isolates collected from Mae Sot District, Tak Province, Thailand during 3 different periods (1997-1999, 2005-2007, and 2009-2010). Analysis of genetic polymorphisms was performed to track the evolution of genetic change of P. falciparum using PCR. Both individual genes and their combination patterns showed marked genetic diversity during the 3 study periods. The results strongly support that P. falciparum isolates in Thailand are markedly diverse and patterns changed with time. These 2 polymorphic genes could be used as molecular markers to detect multiple clone infections and differentiate recrudescence from reinfection in P. falciparum isolates in Thailand.

Current scenario of malaria vaccine.

Malaria is one of the deadliest infectious diseases that affects millions of people worldwide including India. As an addition to chemoprophylaxis and other antimalarial interventions malaria vaccine is under extensive research since decades. The vaccine development is more difficult to predict than drug development and presents a unique challenge as already there has been no vaccine effective against a parasite. Effective malaria vaccine could help eliminate and eradicate malaria; there are currently 63 vaccine candidates, 41 in preclinical and clinical stages of development. Vaccines are being designed to target pre-erythrocytic stages, erythrocytic stage or the sexual stages of Plasmodium taken up by a feeding mosquito, or the multiple stages. Two vaccines in preclinical and clinical development target P. falciparum; and the most advanced candidate is the pre-erythrocytic vaccine RTS,S which is in phase-III clinical trials. It is likely that world’s first malaria vaccine will be available by 2015 at the country level. More efficacious second generation malaria vaccines are on the way to development. Safety, efficacy, cost and provision of the vaccine to all communities are major concerns in malaria vaccine issue.

Molecular and phylogenetic analysis of the partial tams1 gene sequence of a vaccine strain of Theileria annulata

The polypeptide Tams1 is an immunodominant major merozoite piroplasm surface antigen of the protozoan parasite Theileria annulata and is highly variable. In this study, the partial nucleotide (nt) sequence of the Tams1 (522 nt) gene of Iranian vaccine strain (Vaccine-ir68) recovered from an outbreak of disease in Iran was determined and compared with the corresponding sequences of eighteen previously published Tams1 genes. According to sequencing result, a novel amino acid substitution at the Tams1 region (K→Q) was found exclusively in isolate Vaccine-ir68. Genetic distance values, estimated from the sequence data, revealed striking sequence homology (approximately 99 percent) between Vaccine-ir68 isolate and Tunisian isolates, showing that they were same isolates of T. annulata which were spread in these areas. The phylogenetic tree constructed based on the sequence alignment of 19 Tams1 coding regions was distinctly divided into five lineages. There might be some unknown tick carrier birds immigrating to the different geographical regions. These birds have an effective role to distribute the T. annulata species in North Africa, Palestine and Iran.

Naturally acquired antibodies to merozoite surface protein (MSP)-1(19) and cumulative exposure to Plasmodium falciparum and Plasmodium vivax in remote populations of the Amazon Basin of Brazil

To infer recent patterns of malaria transmission, we measured naturally acquired IgG antibodies to the conserved 19-kDa C-terminal region of the merozoite surface protein (MSP)-1 of both Plasmodium vivax (PvMSP-1(19)) and Plasmodium falciparum (PfMSP-1(19)) in remote malaria-exposed populations of the Amazon Basin. Community-based cross-sectional surveys were carried out between 2002 and 2003 in subjects of all age groups living along the margins of the Unini and Jaú rivers, Northwestern Brazil. We found high prevalence rates of IgG antibodies to PvMSP-1(19) (64.0 - 69.6 percent) and PfMSP-1(19) (51.6 - 52.0 percent), with significant differences in the proportion of subjects with antibodies to PvMSP-1(19) according to age, place of residence and habitual involvement in high-risk activities, defining some groups of highly exposed people who might be preferential targets of malaria control measures. In contrast, no risk factor other than age was significantly associated with seropositivity to PfMSP-1(19). Only 14.1 percent and 19.3 percent of the subjects tested for antibodies to PvMSP-1(19) and PfMSP-1(19) in consecutive surveys (142 - 203 days apart) seroconverted or had a three fold or higher increase in the levels of antibodies to these antigens. We discuss the extent to which serological data correlated with the classical malariometric indices and morbidity indicators measured in the studied population at the time of the seroprevalence surveys and highlight some limitations of serological data for epidemiological inference.

Comparative recognition by human IgG antibodies of recombinant proteins representing three asexual erythrocytic stage vaccine candidates of Plasmodium vivax

In previous immuno-epidemiological studies of the naturally acquired antibody responses to merozoite surface protein-1 (MSP-1) of Plasmodium vivax, we had evidence that the responses to distinct erythrocytic stage antigens could be differentially regulated. The present study was designed to compare the antibody response to three asexual erythrocytic stage antigens vaccine candidates of P. vivax. Recombinant proteins representing the 19 kDa C-terminal region of MSP-1(PvMSP19), apical membrane antigen n-1 ectodomain (PvAMA-1), and the region II of duffy binding protein (PvDBP-RII) were compared in their ability to bind to IgG antibodies of serum samples collected from 220 individuals from the state of Pará, in the North of Brazil. During patent infection with P. vivax, the frequency of individuals with IgG antibodies to PvMSP1(19), PvAMA-1, and PvDBP-RII were 95, 72.7, and 44.5 percent respectively. Although the frequency of responders to PvDBP-RII was lower, this frequency increased in individuals following multiple malarial infections. Individually, the specific antibody levels did not decline significantly nine months after treatment, except to PvMSP1(19). Our results further confirm a complex regulation of the immune response to distinct blood stage antigens. The reason for that is presently unknown but it may contribute to the high risk of re-infection in individuals living in the endemic areas.

Merozoite surface protein 2 allelic variation influences the specific antibody response during acute malaria in individuals from a Brazilian endemic area

The antibody response to Plasmodium falciparum parasites of naturally infected population is critical to elucidate the role of polymorphic alleles in malaria. Thus, we evaluated the impact of antigenic diversity of repetitive and family dimorphic domains of the merozoite surface protein 2 (MSP-2) on immune response of 96 individuals living in Peixoto de Azevedo (MT-Brazil), by ELISA using recombinant MSP-2 proteins. The majority of these individuals were carrying FC27-type infections. IgG antibody responses were predominantly directed to FC27 parasites and were correlated to the extension of polymorphism presented by each MSP-2 region. This finding demonstrated the impact of the genetic polymorphism on antibody response and therefore, its importance on malaria vaccine efficacy.