2). Antigens that did not contain the T helper cell epitopes elicited minimal responses to the block 2 antigens except for antigen 5 that elicited some response to the 3D7 and R033 antigens. As with the murine responses, sera from each of five rabbits immunized with the full
polyvalent hybrid protein showed antibody reactivity against each of the 3D7, R033 and Wellcome block 2 recombinant antigens when tested by ELISA (data not find more shown). To test if there was a skew towards particular murine IgG subclass responses, each serum was tested against the full polyvalent hybrid protein (antigen 6) by ELISA. The responses elicited by each of the six immunizing antigens contained a predominance of IgG1 and IgG2a, rather than IgG2b or IgG3 (Fig. 3). Murine antibodies induced by each polyvalent hybrid protein were tested against cultured P. falciparum lines each containing a distinct block 2 allelic type, 3D7 (K1-like allele), Wellcome (MAD20-like), and R033 ( Fig. 4A–F, respectively showing titres in animals immunized with antigens 1–6). Murine antibody responses to the full polyvalent hybrid protein (antigen 6) showed high titre reactivity by IFA to the three different parasite isolates ( Fig. 4F). Mice immunized with the remaining five comparative polyvalent antigens
produced antibodies reactive with at least one block 2 allele, but failed to achieve a similar high titre response against all three isolates ( Fig. 4A–E). Antigens GDC-0068 solubility dmso 2, 4 and 5, each missing the N-terminal T-cell epitopes, elicited poor antibody responses, although these were higher against R033 than against the other isolates ( Fig. 4B, D and E). Sera from rabbits immunized with antigen 6 were tested against an expanded panel of 10 P. falciparum isolates with more diverse alleles (containing more representatives of
the K1-like and MAD20-like types) ( Fig. 5). Each of the five Edoxaban sera showed strong IFA reactivity against all isolates, with titres ranging from 1/3200 to 1/1,638,400 ( Fig. 5). The titres were expected to be higher than those elicited in the mice, due to the use of a multiple immunization schedule with Freund’s adjuvant in the rabbits. Antigenic diversity and poor immunogenicity of candidate malaria antigens present significant hurdles for the development of malaria vaccines. Inadequate design could potentially lead to survival and selection of parasites with heterologous alleles not covered by a vaccine construct [25] and [26]. Hybrid recombinant protein subunit vaccines are one promising approach to circumventing these hurdles. Hybrid proteins as malaria vaccines have been advocated when combining two or more unrelated proteins [27], [28] and [29].
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