MAAP: Malarial adhesins and adhesin‐like proteins predictor

Ansari, Faraz Alam; Kumar, Naveen; Subramanyam, Mekapati Bala; Gnanamani, Muthiah; Ramachandran, Srinivasan

doi:10.1002/prot.21568

Cited by 34 publications

(31 citation statements)

References 39 publications

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“…Potential vaccine candidate characterization of 25 ORFs were carried out using various computational tools, such as Vaxijen [21,22], MAPP [23], SPAAN [24], TargetP [25], SignalP [26], TMHMM [27], and Algpred [28] algorithms. The similarity to human and mouse reference proteins and other related Plasmodium species were searched through the BLAST-P (National Center for Biotechnology Information) Web server [29] and OrthoMCL database [30].…”

Section: Vaccine Candidate Characterization Toolsmentioning

confidence: 99%

Computational characterization of Plasmodium falciparum proteomic data for screening of potential vaccine candidates

2010

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Section: Vaccine Candidate Characterization Toolsmentioning

confidence: 99%

Computational characterization of Plasmodium falciparum proteomic data for screening of potential vaccine candidates

2010

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“…All of the currently available information has been integrated into an accessible data base, PlasmoDB (Aurrecoechea et al 2009), which provides substantial information for the selection of antigens with vaccine potential. Among them, several novel P. vivax theoretical adhesins and adhesion-like molecules have been recently identified (Ansari et al 2008), which would expand the list of potential P. vivax vaccine candidates.…”

Section: Novel Approaches For Parasite Antigen Discoverymentioning

confidence: 99%

Platform for Plasmodium vivax vaccine discovery and development

Valencia

Rodríguez

Acero

et al. 2011

Mem. Inst. Oswaldo Cruz

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Plasmodium vivax is the most prevalent malaria parasite on the American continent. It generates a global burden of 80–100 million cases annually and represents a tremendous public health problem, particularly in the American and Asian continents. A malaria vaccine would be considered the most cost-effective measure against this vector-borne disease and it would contribute to a reduction in malaria cases and to eventual eradication. Although significant progress has been achieved in the search for Plasmodium falciparum antigens that could be used in a vaccine, limited progress has been made in the search for P. vivax components that might be eligible for vaccine development. This is primarily due to the lack of in vitro cultures to serve as an antigen source and to inadequate funding. While the most advanced P. falciparum vaccine candidate is currently being tested in Phase III trials in Africa, the most advanced P. vivax candidates have only advanced to Phase I trials. Herein, we describe the overall strategy and progress in P. vivax vaccine research, from antigen discovery to preclinical and clinical development and we discuss the regional potential of Latin America to develop a comprehensive platform for vaccine development.

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“…SURFIN 4.2 localizes to Maurer’s clefts and has been reported to be trafficked to the surface of the iRBC together with RIFIN and PfEMP1 [14]. Thus, SURFIN/PvSTP proteins are potential immune targets and malaria vaccine candidates [16, 17]. For another member SURFIN 4.1 , the N-terminal 50 amino acids, transmembrane domain, and adjacent intracellular region contain sufficient information for recruiting a recombinant protein into the classical ER/Golgi secretory pathway, and for efficient translocation across the PVM to the Maurer’s clefts [18].…”

Section: Introductionmentioning

confidence: 99%

Tryptophan-rich domains of Plasmodium falciparum SURFIN4.2 and Plasmodium vivax PvSTP2 interact with membrane skeleton of red blood cell

Zhu

Liang

et al. 2017

Malar J

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Background Plasmodium falciparum dramatically alters the morphology and properties of the infected red blood cells (iRBCs). A large group of exported proteins participate in these parasite-host interactions occurring at the iRBC membrane skeleton. SURFIN4.2 is one of iRBC surface protein that belongs to surface-associated interspersed protein (SURFIN) family. Although the intracellular tryptophan-rich domain (WRD) was proposed to be important for the translocation of SURFINs from Maurer’s clefts to iRBC surface, the molecular basis of this observation has yet to be defined. The WRDs of P. falciparum SURFIN proteins and their orthologous Plasmodium vivax subtelomeric transmembrane proteins (PvSTPs) show homology to the intracellular regions of PfEMP1 and Pf332, both of which are involved in RBC membrane skeleton interactions, and contribute to malaria pathology.MethodsTwo transfected lines expressing recombinant SURFINs (NTC-GFP and NTC-4.2WRD2-GFP) of the 3D7 sequence were generated by transfection in P. falciparum. In vitro binding assays were performed by using recombinant WRDs of SURFIN4.2/PvSTP2 and inside-out vesicles (IOVs). The interactions between the recombinant WRDs of SURFIN4.2/PvSTP2 with actin and spectrin were evaluated by the actin spin down assay and an enzyme-linked immunosorbent assay based binding assays, respectively.ResultsThe recombinant SURFINs (NTC-4.2WRD2-GFP), in which the second WRD from SURFIN4.2 was added back to NTC-GFP, show diffused pattern of fluorescence in the iRBC cytosol. Furthermore, WRDs of SURFIN4.2/PvSTP2 were found to directly interact with the IOVs of RBC, with binding affinities ranging from 0.26 to 0.68 μM, values that are comparable to other reported parasite proteins that bind to the RBC membrane skeleton. Further experiments revealed that the second WRD of SURFIN4.2 bound to F-actin (K d = 5.16 μM) and spectrin (K d = 0.51 μM).ConclusionsBecause PfEMP1 and Pf332 also bind to actin and/or spectrin, the authors propose that the interaction between WRD and RBC membrane skeleton might be a common feature of WRD-containing proteins and may be important for the translocation of these proteins from Maurer’s clefts to the iRBC surface. The findings suggest a conserved mechanism of host-parasite interactions and targeting this interaction may disrupt the iRBC surface exposure of Plasmodium virulence-related proteins.Electronic supplementary materialThe online version of this article (doi:10.1186/s12936-017-1772-5) contains supplementary material, which is available to authorized users.

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MAAP: Malarial adhesins and adhesin‐like proteins predictor

Cited by 34 publications

References 39 publications

Computational characterization of Plasmodium falciparum proteomic data for screening of potential vaccine candidates

Computational characterization of Plasmodium falciparum proteomic data for screening of potential vaccine candidates

Platform for Plasmodium vivax vaccine discovery and development

Tryptophan-rich domains of Plasmodium falciparum SURFIN4.2 and Plasmodium vivax PvSTP2 interact with membrane skeleton of red blood cell

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