IsdB antibody–mediated sepsis following S. aureus surgical site infection
Kohei Nishitani, Masahiro Ishikawa, Yugo Morita, Noriaki Yokogawa, Chao Xie, Karen L. de Mesy Bentley, Hiromu Ito, Stephen L. Kates, John L. Daiss, Edward M. Schwarz
Kohei Nishitani, Masahiro Ishikawa, Yugo Morita, Noriaki Yokogawa, Chao Xie, Karen L. de Mesy Bentley, Hiromu Ito, Stephen L. Kates, John L. Daiss, Edward M. Schwarz
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Research Article Bone biology Infectious disease

IsdB antibody–mediated sepsis following S. aureus surgical site infection

Abstract

Staphylococcus aureus is prevalent in surgical site infections (SSI) and leads to death in approximately 1% of patients. Phase IIB/III clinical trial results have demonstrated that vaccination against the iron-regulated surface determinant protein B (IsdB) is associated with an increased mortality rate in patients with SSI. Thus, we hypothesized that S. aureus induces nonneutralizing anti-IsdB antibodies, which facilitate bacterial entry into leukocytes to generate “Trojan horse” leukocytes that disseminate the pathogen. Since hemoglobin (Hb) is the primary target of IsdB, and abundant Hb-haptoglobin (Hb-Hp) complexes in bleeding surgical wounds are normally cleared via CD163-mediated endocytosis by macrophages, we investigated this mechanism in vitro and in vivo. Our results demonstrate that active and passive IsdB immunization of mice renders them susceptible to sepsis following SSI. We also found that a multimolecular complex containing S. aureus protein A–anti-IsdB–IsdB–Hb-Hp mediates CD163-dependent bacterial internalization of macrophages in vitro. Moreover, IsdB-immunized CD163–/– mice are resistant to sepsis following S. aureus SSI, as are normal healthy mice given anti-CD163–neutralizing antibodies. These genetic and biologic CD163 deficiencies did not exacerbate local infection. Thus, anti-IsdB antibodies are a risk factor for S. aureus sepsis following SSI, and disruption of the multimolecular complex and/or CD163 blockade may intervene.

Authors

Kohei Nishitani, Masahiro Ishikawa, Yugo Morita, Noriaki Yokogawa, Chao Xie, Karen L. de Mesy Bentley, Hiromu Ito, Stephen L. Kates, John L. Daiss, Edward M. Schwarz

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Figure 6

CD163 is required for multimolecular complex internalization of S. aureus by macrophages in vitro and dissemination following SSI in vivo.

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CD163 is required for multimolecular complex internalization of S. aureu...
Assessment of in vitro S. aureus infection of primary bone marrow–derived macrophages cultured with all components of the multimolecular complex was performed as described in the legend for Figure 5. Representative fluorescent images of GFP+ UAMS-1 in cultures of LysoTracker Red–labeled (A) WT macrophages, (B) CD163–/– macrophages, and (C) WT macrophages pretreated with anti-CD163 antibodies (original magnification, ×100; scale bar: 10 μm). (D) WT (C57BL/6) and CD163–/– mice in a C57BL/6 background were passively immunized with anti-IsdB and challenged with a MRSA-contaminated transtibial implant, as described in the legend for Figure 1. Total body weight over the 14-day infection period is presented as the fraction (%) of mice per group (n = 22). (E) Longitudinal BLI, with local (F) and systemic (G) CFU data per mouse (mean ± SD) per group are presented. (H) WT BALB/c mice were passively immunized with anti-IsdB mAb, as described in the legend for Figure 3, and treated with anti-CD163 mAb or irrelevant IgG before challenge with a MRSA-contaminated transtibial implant (n = 20). The percentage body weight change over the 14-day infection period is presented (mean ± SD) per group (*P < 0.05 on days 3, 10, and 14 via 2-way ANOVA). (I) BLI images are shown to illustrate the USA300LAC:lux dissemination in an irrelevant mAb control mouse, while no MRSA dissemination was detected in any of the mice treated with anti-CD163 mAb, as illustrated by the representative BLI image. (J) Longitudinal BLI, with local (K) and systemic (L) CFU data per mouse (mean ± SD) for each group are presented (lower limit of detection <50 [F and K]; <100 [G and L]).