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Expression of Rickettsia Adr2 protein in E. coli is sufficient to promote resistance to complement-mediated killing, but not adherence to mammalian cells

PLoS ONE (2017) 12(6)
DOI: 10.1371/journal.pone.0179544
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Abstract

Bacteria exposed to host serum are subject to the antibacterial effects to the complement system. However, pathogenic microorganisms have evolved mechanisms of evading this immune attack. We have previously demonstrated that at least two R. conorii antigens, RC1281/Adr1 and OmpB β-peptide, contribute to the evasion of complement-mediated killing by binding the complement regulatory proteins vitronectin and factor H. RC1282/Adr2, a protein related to Adr1, is predicted to share similar structural features, suggesting that this protein may also contribute to evasion of complement-mediated killing. Interestingly, the R. prowazekii Adr1 and Adr2(RP828) proteins were originally found to interact with host cell surface proteins, suggesting their putative roles as adhesins in this pathogenic rickettsial species. In this study, we expressed both R. conorii and R. prowazekii Adr2 on the surface of a non-adherent, serum-sensitive strain of E. coli to examine the potential role of this protein to mediate evasion of complement-mediated killing and adherence to host cells. We demonstrate that, similar to R. conorii Adr1, R. conorii and R. prowazekii Adr2 are sufficient to mediate serum resistance and to promote interaction with the host complement regulator vitronectin. Furthermore, we demonstrate that expression of Adr2 in a non-adherent strain of E. coli is insufficient to mediate adherence to cultured mammalian endothelial cells. Together, our data demonstrate that the R. conorii and R. prowazekii Adr2 protein does not participate in the interactions with mammalian cells, but rather, participates in the evasion of killing by complement.

Figures

  • Fig 1. Adr2 is highly conserved among pathogenic rickettsial species. (A) ClustalW alignment of Adr2 homologs from rickettsial species in both Spotted Fever Group (R. conorii, R. rickettsii) and Typhus Group (R. prowazekii). Predicted β-sheets and surface exposed loops are indicated in yellow and purple dashed lines, respectively. (B) Phyre2 predicted structure of R. conorii Adr2 demonstrates of 8 transmembrane β-sheets configured in a “barrel”-like structure with possible surface exposed loops.
  • Fig 2. Outer-membrane expression of Adr2 in R. conorii. (A) Western blot analysis using rabbit-anti-Adr2 antiserum confirms the expression in R. conorii Malish 7 and R. rickettsii Sheila Smith whole cell lysate (WCL). (B) Flow cytometry confirmed the expression of Adr2 at the surface of R. conorii. A shift in fluorescence is observed when fixed R. conorii was incubated with primary and secondary antibodies (orange) compared to samples prepared with only primary or secondary (red and blue, respectively). A sample is incubated with Anti-R. conorii serum (green) as a positive control of the flow cytometer. (C) Western blot analysis of R. conorii whole cell lysates (WCL) and outer-membrane(OM) preparations using antibodies against OmpB (mAb 6B6.6) or Adr2 demonstrates the presence of reactive species in both WCL and OM preparations. Anti-RplF (50s ribosomal protein L6) is used a control for cytoplasmic contents.
  • Fig 3. Expression of Adr2 at the E. coli outer-membrane is sufficient to mediate resistance to serumkilling. (A) OM preparations or WCL from E. coli transformed with the empty vector (pET22b) or the plasmid encoding for R. conorii His6-tagged Adr2 are separated by SDS-PAGE. Subsequent silver staining demonstrates similar protein loading and migration. Anti-E. coli RNA Polymerase alpha (RNAP) is used to demonstrate the presence of cytoplasmic contents. (B) Flow cytometry analysis reveals the expression of Adr2 at the surface of E. coli. A shift in fluorescence was observed in BL21(pSRK-2 [R. conorii Adr2]) in cultures incubated with both primary and secondary antibodies (orange) compared to primary(red) or secondary(blue) alone. (C) Expression of R. conorii Adr2(pSRK-2) in E. coli (BL21) is sufficient to mediate serum-killing to normal human serum. R. conorii Adr1(pJP01) is used as a positive control. Results are shown as the mean ± SD (P values: *** = 0.0007). (D) Serum-sensitive E. coli (pET22b) and cultures expressing Adr2 or Adr1 survive when incubated with heat-inactivated normal human serum.
  • Fig 4. R. conorii Adr2 binds complement regulatory protein vitronectin. (A) E. coli BL21 harboring the empty vector pET22b, the plasmid encoding R. conorii His6-tagged Adr2 (pSRK-2) or R. conorii His-tagged Adr1 (pJPO1) were incubated with normal human serum. Western immunoblot analysis revealed a reactive band at approximately 75 kDa in all lanes except for the empty vector when probed with antibody raised against vitronectin. Expression of both Adr2 and Adr1 was confirmed by anti-His6, and equal loading was demonstrated with anti-E. coli RNA Polymerase alpha (RNAP). (B) Western immunoblot analysis of multimeric vitronectin binding to E. coli expressing Adr1 derivative mutant (pAF17) or R. conorii Adr2. Expression of both the Adr1 derivative and Adr2 was confirmed by anti-His6, and equal loading was verified using anti-E. coli RNA polymerase alpha (RNAP).
  • Fig 5. R. prowazekii Madrid E Adr2 confers acquisition of vitronectin and resistance in serum. (A) E. coli BL21(DE3) harboring the empty vector pET22b or the plasmid encoding R. prowazekii Madrid E His6-tagged Adr2 (pRP828) were incubated with normal human serum. Western immunoblot analysis revealed a reactive band at approximately 75 kDa in the lane with R. prowazekii Adr2 only when probed with antibody raised against vitronectin. Expression of Adr2 was confirmed by anti-His6, and equal loading was demonstrated with anti-E. coli RNA Polymerase alpha (RNAP). (B) Western immunoblot analysis of multimeric vitronectin binding to E. coli expressing Adr1 derivative mutant (pAF17) or R. conorii Adr2. Expression of both the Adr1 derivative and Adr2 was confirmed by anti-His6, and equal loading was verified using anti-E. coli RNA polymerase alpha (RNAP). (C) Expression of R. prowazekii Adr2 in E. coli BL21(DE3) is sufficient to mediate resistance in the presence of serum. Results are shown as the mean ± SD (P value: ** = 0.0024) and E. coli harboring R. conorii Adr1 (pJP01) was used as a positive control. (D) OM preparations or WCL from E. coli transformed with the empty vector (pET22b) or the plasmid encoding for R. prowazekii His6-tagged Adr2 are separated by SDS-PAGE. Subsequent silver staining demonstrates similar protein loading and migration. Anti-His6 was used to demonstrate expression of R. prowazekii Adr2. A reactive band at approximately 25 kDa was observed when probed with anti-R. conorii Adr2.
  • Fig 6. Adherence potential of R. conorii Adr2 expressing E. coli. Expression of R. conorii Adr2 in E. coli (BL21) is not sufficient to mediate cell adherence to EA.hy926 cells. The results are expressed as percentages of recovered adherent bacteria based on the total bacterial input. Results are shown as the mean ± SD (P values: *** <0.0001).
  • Fig 7. Adherence potential of R. prowazekii Adr2 expressing E. coli. Expression of R. prowazekii Adr2 in E. coli (BL21) is not sufficient to mediate cell adherence to EA.hy926 cells. The results are expressed as percentages of recovered adherent bacteria based on the total bacterial input. Results are shown as the mean ± SD (P values: * = 0.0123).

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Garza, D. A., Riley, S. P., & Martinez, J. J. (2017). Expression of Rickettsia Adr2 protein in E. coli is sufficient to promote resistance to complement-mediated killing, but not adherence to mammalian cells. PLoS ONE, 12(6). https://doi.org/10.1371/journal.pone.0179544

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