The<i>sim</i>Operon Facilitates the Transport and Metabolism of Sucrose Isomers in<i>Lactobacillus casei</i>ATCC 334

Solid experimental evidence indicates that EBA-175 is used as a ligand by the Plasmodium falciparum merozoite to bind to human RBC, via different binding processing fragments. Using synthetic peptides and specific receptor-ligand interaction methodology, we have identified 6 high-activity binding sequences from the EBA-175 CAMP strain; peptide 1758 (KSYGTPDNIDKNMSLIHKHN), located in the so-called region I for which no binding activity has been reported before, peptides 1779 (NIDRIYDKNLLMIKEHILAI) and 1783 (HRNKKNDKLYRDEWWKVIKK), located in region II, in a sub-region known as 5' Cys F2, previously reported as being a binding region, and peptides 1814 (DRNSNTLHLKDYRNEENERH), 1815 (YTNQNINISQERDLQKHGFH) and 1818 (NNNFNNIPSRYNLYDKKLDL), in region III-V where antibodies inhibit merozoite invasion of erythrocytes. The affinity constants were between 60 and 180 nM and the critical amino acids involved in the binding were identified. The binding of these peptides to enzyme-treated RBC was analysed; binding of peptide 1814, located in the III-V region, was found to be sialic acid dependent. Some of these high binding peptides were able to inhibit in vitro merozoite invasion and to block the binding of recombinant RII-EBA to RBC. Several of these peptides are located in regions recognized by protective immune clusters of merozoites (ICMs) eluted antibodies.

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Functional, structural, and immunological compartmentalisation of malaria invasive proteins

Reyes

Patarroyo²,

Vargas³

et al. 2007

Biochemical and Biophysical Research Communications

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Structural Modifications Enable Conserved Peptides to Fit into MHC Molecules thus Inducing Protection against Malaria

et al. 2004

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Developing a rational methodology for obtaining vaccines against P. falciparum malaria (the disease's most lethal form, afflicting more than 250 million people around the world per year and killing about 2 million of them) [1] has become one of the main objectives of public health authorities around the world. [2] A multiantigenic vaccine, containing molecules from the parasite's different developmental stages, is required due to the parasite's remarkable complexity and adaptability. [3] The first such approach (the SPf66 synthetic vaccine), [4,5] which used peptides from molecules from different parasite stages, conferred limited protective efficacy in Aotus monkey studies and in field trials carried out on human volunteers around the world. [6] [a] Prof.

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Orientating Peptide Residues and Increasing the Distance between Pockets to Enable Fitting into MHC−TCR Complex Determine Protection against Malaria

Cifuentes

Espejo²,

Vargas³

et al. 2004

Biochemistry

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The erythrocyte binding antigen EBA-175 is a 175-kDa Plasmodium falciparum protein, which has been shown to be involved in the process of invasion of erythrocytes. It has been found that conserved peptide 1818 belonging to this protein has high red blood cell binding capacity and plays an important role in the invasion process. This peptide is neither immunogenic nor protective. Peptide 1818 analogues had some of their previously recognized critical red blood cell binding residues substituted for amino acids having similar volume or mass but different polarity to make them fit into HLA-DRbeta(1)*1101 molecules; these 1818 peptide analogues were then synthesized and inoculated into Aotus nancymaae monkeys, generating different immunogenic and/or protective immune responses. Short structures such as 3(10)-helix, classical, or distorted type-III beta-turns were found in the immunogenic and protective peptides once the secondary structure had been analyzed by NMR and its structure correlated with its immunological properties. These data suggest that peptide flexibility may lead to better fitting into immune system molecules, therefore making them excellent candidates for consideration as components of a subunit-based, multicomponent synthetic antimalarial vaccine.

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Modifying RESA protein peptide 6671 to fit into HLA-DRβ1* pockets induces protection against malaria

Alba

Salazar

Vargas

et al. 2004

Biochemical and Biophysical Research Communications

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Luis Eduardo Vargas

Plasmodium falciparum EBA-175 kDa protein peptides which bind to human red blood cells

Functional, structural, and immunological compartmentalisation of malaria invasive proteins

Structural Modifications Enable Conserved Peptides to Fit into MHC Molecules thus Inducing Protection against Malaria

Orientating Peptide Residues and Increasing the Distance between Pockets to Enable Fitting into MHC−TCR Complex Determine Protection against Malaria

Modifying RESA protein peptide 6671 to fit into HLA-DRβ1* pockets induces protection against malaria

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