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T-dependent B cell responses to Plasmodium induce antibodies that form a high-avidity multivalent complex with the circumsporozoite protein

PLoS Pathogens (2017) 13(7)
DOI: 10.1371/journal.ppat.1006469
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Abstract

The repeat region of the Plasmodium falciparum circumsporozoite protein (CSP) is a major vaccine antigen because it can be targeted by parasite neutralizing antibodies; however, little is known about this interaction. We used isothermal titration calorimetry, X-ray crystallography and mutagenesis-validated modeling to analyze the binding of a murine neutralizing antibody to Plasmodium falciparum CSP. Strikingly, we found that the repeat region of CSP is bound by multiple antibodies. This repeating pattern allows multiple weak interactions of single FABdomains to accumulate and yield a complex with a dissociation constant in the low nM range. Because the CSP protein can potentially cross-link multiple B cell receptors (BCRs) we hypothesized that the B cell response might be T cell independent. However, while there was a modest response in mice deficient in T cell help, the bulk of the response was T cell dependent. By sequencing the BCRs of CSP-repeat specific B cells in inbred mice we found that these cells underwent somatic hypermutation and affinity maturation indicative of a T-dependent response. Last, we found that the BCR repertoire of responding B cells was limited suggesting that the structural simplicity of the repeat may limit the breadth of the immune response.

Figures

  • Table 1. Thermodynamic parameters for interactions between 2A10 FAB, 2A10 and antigens.
  • Fig 1. ITC data for interactions between 2A10 FAB and antigens. (A) Titration of 2A10 FAB with (NANP)6. (B) Titration of 2A10 FAB with rCSP. (C) Titration of 2A10 (complete antibody) with rCSP. The upper panels represent baseline-corrected power traces. By convention, negative power corresponds to exothermic binding. The lower panels represent the integrated heat data fitted to the independent binding sites model.
  • Fig 2. Structures of the (NANP)6 peptide (A), the 2A10 FAB fragment (B) and the model of the FAB fragment-(NANP)6 complex (C).
  • Fig 3. Detailed view of the (NANP)6:2A10 FAB interface and site directed mutagenesis. (A) A model of the light chain:(NANP)6 interface. (B) ELISA results showing the effect of mutating light chain interface residues; error bars are based on technical replicates from one of two independent experiments. (C) A model of the heavy chain:(NANP)6 interface. (D) ELISA results showing the effect of mutating heavy chain interface residues; error bars are based on technical replicates from one of two independent experiments.
  • Fig 4. The multivalency of the NANP repeat region of the CSP protein. (A) An (NANP)6 peptide results in the presentation of two symmetrical epitopes, formed by alternating repeats (cyan and magenta), allowing binding by two FAB domains, in keeping with the stoichiometry observed by ITC. (B) The full 27-mer repeat region results in the presentation of at least 10 separate epitopes and the twist of the helix results in displacement along the length of the repeat region, which allows binding of up to 10 separate FAB fragments, consistent with 4 antibodies bound by both FAB domains, and two bound by a single FAB domain.
  • Fig 5. CSP-specific B cells enter the germinal center following sporozoite immunization. BALB/C mice were immunized with either 5 x 104 P. berghei CS5M (expressing the endogenous P. berghei CSP repeat) or 5 x 104 P. berghei CSPf (expressing the circumsporozoite protein from P. falciparum) live spoorzoites under CQ cover. 12 days later the B cell response was analyzed by flow cytometry and putative (NANP)n-specific cells were identified using PE and APC conjugated tetramers. (A) Representative flow cytometry plots showing the identification of (NANP)n-specific (Tetramer +) cells. (B) Representative flow cytometry plots showing the proportion of Tetramer+ cells that have class switched and entered a GC. (C) Quantification of the number of class switched Tetramer+ cells under different immunization conditions. (D) Quantification of the number of GC Tetramer+ cells under different immunization conditions. Data from a single representative experiment of 2 repeats, analyzed by one-way ANOVA with Tukey’s post test.
  • Fig 6. The B cell response to CSP has a T-independent component. CD28-/- and control C57BL/6 mice were immunized with P. berghei CSPf radiation attenuated sporozoites (RAS) or rCSP in alum. Sera were taken and the spleens analyzed for antigen specific B cells using tetramers 4, 7 and 27 days post-immunization. (A) IgM and IgG (NANP)n ELISA responses following RAS immunization (B) Representative flow cytometry plots 7 days post RAS immunization showing the gating of different B cell populations among Tetramer+ cells. (C) Absolute numbers of (i) total Tetramer+ IgD-ve (ii) Tetramer+ Plasmabalsts and (iii) Tetramer+ GC B cells post RAS immunization. (D) Antibody responses and (E) absolute numbers of Tetramer+ IgD- B cells 4 days post immunization with rCSP. Log-transformed data pooled from 2 independent experiments for each immunization (>3 mice/group/timepoint) were analyzed using linear mixed models with day and genotype/immunization as experimental factors and the individual experiment as a random factor; only significant differences are shown.
  • Fig 7. Limited diversity of (NANP)n specific antibodies. BCR sequences were amplified from Tetramer + cells sorted from BALB/C mice 35 days after immunization with live P. berghei CSPf sporozoites under CQ cover as well as bulk (B220+) B cells from naïve BALB/C mice (A) IGHV gene usage from among B cells from a representative naïve mouse (grey bars) and Tetramer + cells from immune mice (red, blue and yellow bars). (B) Shannon’s diversity calculated for the diversity of IGHV region usage among bulk B cells and Tetramer+ cells. (C) Circos plots showing the IGHV-IGHJ pairings in a representative naïve mice and 3 immune mice. (D) IGKV gene usage from among B cells from a representative naïve mouse (grey bars) and Tetramer+ cells from

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Fisher, C. R., Sutton, H. J., Kaczmarski, J. A., McNamara, H. A., Clifton, B., Mitchell, J., … Cockburn, I. A. (2017). T-dependent B cell responses to Plasmodium induce antibodies that form a high-avidity multivalent complex with the circumsporozoite protein. PLoS Pathogens, 13(7). https://doi.org/10.1371/journal.ppat.1006469

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