ANTIBODY-DRUG CONJUGATE THERAPY AGAINST S. AUREUS IMPLANT-ASSOCIATED INFECTION IN A MURINE MODEL

Aim

Infections represent a serious threat to the successful utilization of implants in modern medicine. Implant-associated infections are difficult to treat, because they involve biofilms that protect bacteria from the immune system and harbour antibiotic-tolerant persister cells.

In this work, we developed an antibody-drug conjugate (ADC) containing the anti-neoplastic drug mitomycin C (MMC) as a novel treatment paradigm for implant-associated infections. MMC was chosen as it is a potent antimicrobial against biofilms and its synthesis into an ADC was chosen to alleviate toxicity. Following development and synthesis of the ADC, stability and release of MMC was measured. We then used the ADC to kill bacteria in suspension and in biofilms, in vitro and in vivo.

Method

Mitomycin C was conjugated to a commercially available antibody against S. aureus via a disulfide linkage, with a drug release occurred via thiol-disulfide exchange.

ADC as tested against S. aureus under various growth conditions (planktonic, persisters and biofilm). In vitro toxicity of ADC vs MMC was measured using a human cell line (MOLT-4).

Finally, two independent in vivo experiments were performed in a murine implant-associated osteomyelitis model. In experiment one ADC treatment was compared NaCl, vancomycin and vancomycin + ADC (n=10 for all groups). Subsequently, ADC was compared to NaCl, the antibody used in the ADC construction, MMC and a novel ADC constructed with a non-S. aureus antibody (n=10 for all groups). All treatments were started day 7 post inoculation and were administered for 3 days. CFU enumeration was done following sonication to quantify bacterial load.

Results

Drug release could be triggered on demand with N-acetyl cysteine and release occurred, once in contact with free thiols on S. aureus cell surface.

The ADCs exhibited a concentration-dependent antimicrobial effect against S. aureus with doses exceeding 0.5 mg/l reducing amount of CFU to below detection limit (p< 0.001). 15 minutes exposure to ADC resulted in an approx. 2 log CFU/ml reduction compared to untreated biofilms (p < 0.01).

In vivo ADC treatment was effective compared to NaCl treatment and the vancomycin treatment (p≤ 0.001). Further ADC and MMC treatment were comparable in efficacy, but both were superior than NaCl, pure antibody and the non-specific ADC (p≤ 0.05). Finally, in vitro cytotoxicity was significantly lower for ADC than MMC.

Conclusions

In this study we have demonstrated that ADCs can be a novel treatment approach to combat implant-associated infections caused by S. aureus.