DOI: 10.1093/milmed/usae184 ISSN: 0026-4075

Doxycycline-Mediated Inhibition of Snake Venom Phospholipase and Metalloproteinase

Daniel K Arens, Meaghan A Rose, Emelyn M Salazar, Merideth A Harvey, Eun Y Huh, April A Ford, Daniel W Thompson, Elda E Sanchez, Yoon Y Hwang

ABSTRACT

Introduction

Warfighters are exposed to life-threatening injuries daily and according to the Joint Trauma System Military Clinical Practice Guideline—Global Snake Envenomation Management snakebites are a concerning threat in all theaters of operation. Snake venom is a complex mixture of toxins including phospholipases A2 (PLA2) and snake venom metalloproteinases (SVMP) that produce myotoxic, hemotoxic, and cytotoxic injuries. Antibody-based antivenom is the standard of care but new approaches including small-molecule inhibitors have gained attention in recent years. Doxycycline is an effective inhibitor of human metalloproteinases and PLA2. The enzymatic activities of 3 phylogenetically distinct snakes: Agkistrodon piscivorus, Naja kaouthia, and Daboia russelii were tested under inhibitory conditions using doxycycline.

Materials and Methods

Enzymatic activity of PLA2 and SVMP was measured in N. kaouthia, D. russelii, and A. piscivorus venom alone and with doxycycline using EnzChek Phospholipase A2 and Gelatinase Assay Kits. A 1-way ANOVA with Tukey’s post-hoc test was used to conduct comparative analysis. The median lethal dose of the venoms, the effective dose of doxycycline, and creatine kinase (CK) inhibition levels were measured in a murine model with adult Bagg Albino (BALB/c) mice using intramuscular injections. Median lethal and effective doses were determined using Spearman-Karber’s method and a 1-way ANOVA with Tukey’s post-hoc test was used to compare CK inhibition levels.

Results

Phospholipases A2 activity was reduced to 1.5% to 44.0% in all 3 venoms in a dose-dependent manner using 0.32, 0.16, and 0.08 mg/mL doxycycline when compared to venom-only controls (P < .0001) (Fig. 1A). Snake venom metalloproteinases activity was reduced to 4% to 62% in all 3 venoms in a dose-dependent manner using 0.32, 0.16, and 0.08 mg/mL doxycycline (P < .0001) (Fig. 1B). The lethal dose (LD50) values of the venoms in the murine model were calculated as follows: A. piscivorus = 20.29 mg/kg (Fig. 2A), N. kaouthia = 0.38 mg/kg (Fig. 2B), and D. russelii = 7.92 mg/kg (Fig. 2C). The effective dose (ED50) of doxycycline in A. piscivorus was calculated to be 20.82 mg/kg and 72.07 mg/kg when treating D. russelii venom. No ED50 could be calculated when treating N. kaouthia venom (Fig. 3). Creatine kinase activity was significantly decreased in all 3 venoms treated with doxycycline (P < .0001) (Fig. 4).

Conclusion

Doxycycline reduced PLA2- and SVMP-related lethality, particularly in A. piscivorus envenomings and in a limited capacity with D. russelii revealing its promise as a treatment for snakebites. In addition, CK activity, a common indicator of muscle damage was inhibited in mice that received doxycycline-treated venom. The doxycycline concentrations identified in the ED50 studies correspond to 1,456 to 5,061 mg dosages for a 70 kg human. Factors including venom yield and snake species would affect the actual dosage needed. Studies into high-dose doxycycline safety and its effectiveness against several snake species is needed to fully translate its use into humans. Based on this work, doxycycline could be used as a treatment en route to higher echelons of care, providing protection from muscle damage and reducing lethality in different snake species.

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