Vladimir Corredor scite author profile

Plasmodium merozoites are covered by a complex coat of surface proteins. Several of the Merozoite Surface Proteins (MSPs) that make up this coat have been proposed as vaccine candidates although some of the MSPs are known to be highly polymorphic. We present here the first survey and analysis of the polymorphism in the recently characterized P. vivax surface protein PvMSP-3alpha. Full length or partial sequences were obtained for the Pvmsp-3alpha gene from isolates originating in Central and South America, Asia and the Pacific. The Pvmsp-3alpha sequence is remarkably diverse, but this extensive diversity is largely restricted to certain domains of the encoded protein. An acidic C-terminal domain and a smaller hydrophilic N-terminus are relatively conserved, while a central domain containing coiled-coil heptad repeats is highly polymorphic and in some isolates of P. vivax is partially deleted. Unlike other MSPs, there is no evidence of allelic families of PvMSP-3alpha gene sequences, and no evidence that certain patterns of polymorphism group within isolates of similar geographical origin. The distribution and nature of polymorphism suggest that there are functional restrictions on mutations in this gene, and have implications for inclusion of PvMSP-3alpha as a candidate in a P. vivax vaccine.

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Dramatic Difference in Diversity Between Plasmodium Falciparum and Plasmodium Vivax Reticulocyte Binding-Like Genes

Rayner

Tran

Corredor

et al. 2005

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Malaria parasite proteins involved in erythrocyte invasion are considered important vaccine targets. Members of the reticulocyte binding-like (RBL) family of Plasmodium merozoite proteins are found in human, simian, and rodent malaria parasites and function in the initial steps of erythrocyte selection and invasion. The RBL genes are large, ranging in size from 7.7 to 10 kb, and the extent of any sequence diversity in parasite populations is unknown. We present the first assessment of sequence diversity within RBL genes from the two major human malaria parasites: Plasmodium falciparum and P. vivax. Polymorphism within the RBL genes is generally limited, except for P. vivax reticulocyte binding protein 2 (PvRBP2), which has nucleotide diversity levels 25-fold higher than the other RBL genes. The PvRBP2 haplotypes appear to fall into two distinct classes of alleles, suggesting large-scale dimorphism in this gene. Polymorphisms were frequently clustered, suggesting that different RBL domains may be evolving under different selection and functional pressures.

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Spatio-temporal dynamics of Plasmodium falciparum transmission within a spatial unit on the Colombian Pacific Coast

Knudson

González-Casabianca

Feged-Rivadeneira

et al. 2020

Sci Rep

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As malaria control programmes concentrate their efforts towards malaria elimination a better understanding of malaria transmission patterns at fine spatial resolution units becomes necessary. Defining spatial units that consider transmission heterogeneity, human movement and migration will help to set up achievable malaria elimination milestones and guide the creation of efficient operational administrative control units. Using a combination of genetic and epidemiological data we defined a malaria transmission unit as the area contributing 95% of malaria cases diagnosed at the catchment facility located in the town of Guapi in the South Pacific Coast of Colombia. We provide data showing that P. falciparum malaria transmission is heterogeneous in time and space and analysed, using topological data analysis, the spatial connectivity, at the micro epidemiological level, between parasite populations circulating within the unit. To illustrate the necessity to evaluate the efficacy of malaria control measures within the transmission unit in order to increase the efficiency of the malaria control effort, we provide information on the size of the asymptomatic reservoir, the nature of parasite genotypes associated with drug resistance as well as the frequency of the Pfhrp2/3 deletion associated with false negatives when using Rapid Diagnostic tests.Sustained global malaria control and elimination initiatives, driven by local and international funding agencies, regional malaria control programmes, and the World Health Organisation (WHO), have led to a dramatic decrease in malaria mortality and case incidence in the last 15 years. Worldwide, there has been a reduction in case incidence of 18% and reduction in mortality of 48%, with significant impact in Africa 1 . Although the 2019 WHO Malaria Report suggests that progress may be slowing, malaria elimination is still an active target for many Colombia, represents relatively high gametocytemia 39,40 . More than 96% of malaria cases diagnosed at the Guapi malaria health facility originated within a 25 km radius of the town of Guapi. We therefore define the Guapi malaria transmission unit as the area where the catchment facility captures 95% of cases ( Fig. S1 4). Scientific RepoRtS |(2020) 10:3756 | https://doi.

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Spleen-Dependent Regulation of Antigenic Variation in Malaria Parasites: Plasmodium knowlesi SICAvar Expression Profiles in Splenic and Asplenic Hosts

et al. 2013

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BackgroundAntigenic variation by malaria parasites was first described in Plasmodium knowlesi, which infects humans and macaque monkeys, and subsequently in P. falciparum, the most virulent human parasite. The schizont-infected cell agglutination (SICA) variant proteins encoded by the SICAvar multigene family in P. knowlesi, and Erythrocyte Membrane Protein-1 (EMP-1) antigens encoded by the var multigene family in P. falciparum, are expressed at the surface of infected erythrocytes, are associated with virulence, and serve as determinants of naturally acquired immunity. A parental P. knowlesi clone, Pk1(A+), and a related progeny clone, Pk1(B+)1+, derived by an in vivo induced variant antigen switch, were defined by the expression of distinct SICA variant protein doublets of 210/190 and 205/200 kDa, respectively. Passage of SICA[+] infected erythrocytes through splenectomized rhesus monkeys results in the SICA[-] phenotype, defined by the lack of surface expression and agglutination with variant specific antisera.Principal FindingsWe have investigated SICAvar RNA and protein expression in Pk1(A+), Pk1(B+)1+, and SICA[-] parasites. The Pk1(A+) and Pk1(B+)1+ parasites express different distinct SICAvar transcript and protein repertoires. By comparison, SICA[-] parasites are characterized by a vast reduction in SICAvar RNA expression, the lack of full-length SICAvar transcript signals on northern blots, and correspondingly, the absence of any SICA protein detected by mass spectrometry.SignificanceSICA protein expression may be under transcriptional as well as post-transcriptional control, and we show for the first time that the spleen, an organ central to blood-stage immunity in malaria, exerts an influence on these processes. Furthermore, proteomics has enabled the first in-depth characterization of SICA[+] protein phenotypes and we show that the in vivo switch from Pk1(A+) to Pk1(B+)1+ parasites resulted in a complete change in SICA profiles. These results emphasize the importance of studying antigenic variation in the context of the host environment.

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