AMA1 also contains a transmembrane domain, which spans the plasma

AMA1 also contains a transmembrane domain, which spans the plasma membrane and anchors the protein to the cell surface. Two glycosylation mutants (GM) of AMA1 were constructed by mutation of putative N-glycosylation sites (Fig. 1a). Alignment of all known P. falciparum AMA1 genes revealed that most of the glycosylation sites were conserved. For AMA-GM1, the glycosylation sites that were not conserved between isolates were modified to be similar to the rare non-glycosylated isolates and glycosylation sites that were conserved were modified such that the asparagine (N) residue

was replaced with a glutamine (Q). In AMA1-GM2, all of the potential glycosylation sites were removed by substitutions with amino acids present in other selleck chemicals AMA1 alleles among different species of Plasmodium [34] and [39]. Both GM forms retained the native signal sequence. In the intracellular form of AMA1, AMA1-IC, the signal sequence was deleted to retain the protein within the cytoplasm after translation in transduced cells. All forms of AMA1 were engineered for expression from E1/E3/E4-deleted Ad5 vectors with expression cassettes driven by the murine cytomegalovirus (mCMV) immediate early gene promoter inserted at the site of the E4 deletion ( Fig. 1b). The glycosylation status of the four AMA1 variants was monitored by gel migration following digestion with

enzymes that cleave the carbohydrate moieties of glycosylated proteins. We observed a shift in mobility of

the native, but not the modified (GM1, GM2, and IC) AMA1 antigens following treatment of infected Bumetanide cell lysates with Afatinib PNGase F (Fig. 1c). These results indicate that the native AMA1 antigen is N-glycosylated when expressed in mammalian cells following adenovector delivery and that the mutants with altered glycosylation sites or a deleted signal sequence are not N-glycosylated. To determine the cellular localization of the various adenovectors expressing AMA1, we transduced A549 cells with the adenovectors and then assayed for cell location by immunofluorescence in the presence or in the absence of saponin, using the conformational specific anti-AMA1 monoclonal antibody 4G2. Comparison of the staining pattern in the presence or in the absence of saponin showed that the native as well as the GM1 and GM2 versions of AMA1 are located at the cell surface and that most AMA1-IC is located intracellularly (Fig. 2). To evaluate the immunogenicity of adenovectors expressing the different forms of AMA1, mice were immunized with one or two doses of vector. AMA1-specific T cell responses were evaluated by interferon-γ ELIspot with freshly isolated splenocytes as effectors and transfected A20 target cells as target APCs. Following a single dose of adenovector, all cell surface associated forms of AMA1 induced better T cell responses compared to the intracellular form; there was little difference between the glycosylated or non-glycosylated forms (Fig. 3a).

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