Fighting Staphylococcus aureus infections with light and photoimmunoconjugates
Mafalda Bispo, Andrea Anaya-Sanchez, Sabrina Suhani, Elisa J. M. Raineri, Marina López-Álvarez, Marjolein Heuker, Wiktor Szymański, Francisco Romero Pastrana, Girbe Buist, Alexander R. Horswill, Kevin P. Francis, Gooitzen M. van Dam, Marleen van Oosten, Jan Maarten van Dijl
Mafalda Bispo, Andrea Anaya-Sanchez, Sabrina Suhani, Elisa J. M. Raineri, Marina López-Álvarez, Marjolein Heuker, Wiktor Szymański, Francisco Romero Pastrana, Girbe Buist, Alexander R. Horswill, Kevin P. Francis, Gooitzen M. van Dam, Marleen van Oosten, Jan Maarten van Dijl
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Resource and Technical Advance Microbiology Therapeutics

Fighting Staphylococcus aureus infections with light and photoimmunoconjugates

Abstract

Infections caused by multidrug-resistant Staphylococcus aureus, especially methicillin-resistant S. aureus (MRSA), are responsible for high mortality and morbidity worldwide. Resistant lineages were previously confined to hospitals but are now also causing infections among healthy individuals in the community. It is therefore imperative to explore therapeutic avenues that are less prone to raise drug resistance compared with today’s antibiotics. An opportunity to achieve this ambitious goal could be provided by targeted antimicrobial photodynamic therapy (aPDT), which relies on the combination of a bacteria-specific targeting agent and light-induced generation of ROS by an appropriate photosensitizer. Here, we conjugated the near-infrared photosensitizer IRDye700DX to a fully human mAb, specific for the invariantly expressed staphylococcal antigen immunodominant staphylococcal antigen A (IsaA). The resulting immunoconjugate 1D9-700DX was characterized biochemically and in preclinical infection models. As demonstrated in vitro, in vivo, and in a human postmortem orthopedic implant infection model, targeted aPDT with 1D9-700DX is highly effective. Importantly, combined with the nontoxic aPDT-enhancing agent potassium iodide, 1D9-700DX overcomes the antioxidant properties of human plasma and fully eradicates high titers of MRSA. We show that the developed immunoconjugate 1D9-700DX targets MRSA and kills it upon illumination with red light, without causing collateral damage to human cells.

Authors

Mafalda Bispo, Andrea Anaya-Sanchez, Sabrina Suhani, Elisa J. M. Raineri, Marina López-Álvarez, Marjolein Heuker, Wiktor Szymański, Francisco Romero Pastrana, Girbe Buist, Alexander R. Horswill, Kevin P. Francis, Gooitzen M. van Dam, Marleen van Oosten, Jan Maarten van Dijl

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Figure 2

Photo-activated killing of S. aureus by 1D9-700DX.

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Photo-activated killing of S. aureus by 1D9-700DX. (A and B) Photo-acti...
(A and B) Photo-activated killing of S. aureus SH1000 WT versus MS001 ΔisaA (A) or Xen36 versus CA-MRSA AH4807 (B) grown to exponential phase (~1 × 107 CFU/mL) upon treatment with 1D9-700DX or without photosensitizer (A), or step-wise increasing concentrations of 1D9-700DX (0.7–9.8 μM) (B). Bacteria were irradiated with red light at a radiant exposure of 30 J.cm–2 (+) or kept in the dark (–). (C) Bacterial bioluminescence (open emission filter, 10-second exposure) and fluorescence of 1D9-700DX (emission filter, Cy5.5; excitation, 640 nm; 10-second exposure) recorded with the IVIS Lumina II upon aPDT of S. aureus Xen36 or AH4807 (~1 × 108 CFU/mL) with increasing concentrations of 1D9-700DX (0–2.6 μM). (D) Red light dose-response analysis of the killing of S. aureus Xen36 or CA-MRSA AH4807 grown to exponential phase and subjected to aPDT with 4.9 μM of 1D9-700DX or without photosensitizer. Bacteria were irradiated with red light for different periods of time (0.5–5 minutes) or kept in the dark (–). As a control, the bacteria were subjected to continuous (contin.) red light irradiation for 5 minutes. (E) H2O2 production upon aPDT of S. aureus Xen36 and AH4807 with 6 μM of 1D9-700DX or without photosensitizer. H2O2 was detected with 10 μM of an AquaSpark Peroxide Probe. In all experiments, irradiation was performed with a LED system that emits red light. Data are presented as mean ± SEM of 3 experiments performed in triplicates. Two-way ANOVA with subsequent Šidák multiple-comparison tests were used for statistical analysis. Significant differences compared with the negative control group (no 1D9-700DX and no light) are marked as follows: *P < 0.03; **P < 0.002; ***P < 0.0002; ****P < 0.0001.