Drug susceptibility testing for oxygen-dependent and oxygen-independent resistance phenotypes in trichomonads.

Trichomonas vaginalis is the most prevalent, non-viral sexually transmitted human infection, causing 170 million cases of trichomoniasis annually. Since the 1950s, treatment has relied on 5-nitroimidazoles (5NIs), leading to increasing drug resistance. A similar drug resistance problem is present in the veterinary pathogen, Tritrichomonas foetus. There are currently no agreed standards for defining 5NI resistance, due in part to two distinct oxygen-dependent ("aerobic") and oxygen-independent ("anaerobic") resistance phenotypes. Diagnostic tools to detect 5NI resistance are lacking, and current assays used to phenotypically assess 5NI resistance in vitro are complicated by these two resistance phenotypes. We demonstrate that microaerophilic conditions support sufficient parasite growth to interrogate oxygen-dependent resistance of 5NIs against known resistant and susceptible isolates of T. vaginalis and T. foetus. We further demonstrate that microaerophilic conditions allow sufficient growth for compatibility with existing growth assays, including our TriTOX assay. Adopting microaerophilic conditions eliminates traditional 'by-eye' estimates of minimum inhibitory concentrations and opens up options for increased throughput and automation, scalable to higher-throughput analyses of 5NI resistance. This would further allow the development of quantitative phenotypic standards to benchmark oxygen-dependent or oxygen-independent trichomonad 5NI resistance towards standardised surveillance programs to combat drug resistance.

TriTOX: A novel Trichomonas vaginalis assay platform for high-throughput screening of compound libraries.

Trichomonas vaginalis is a neglected urogenital parasitic protist that causes 170 million cases of trichomoniasis annually, making it the most prevalent non-viral, sexually transmitted disease. Trichomoniasis treatment relies on nitroheterocyclics, such as metronidazole. However, with increasing drug-resistance, there is an urgent need for novel anti-trichomonals. Little progress has been made to translate anti-trichomonal research into commercialised therapeutics, and the absence of a standardised compound-screening platform is the immediate stumbling block for drug-discovery. Herein, we describe a simple, cost-effective growth assay for T. vaginalis and the related Tritrichomonas foetus. Tracking changes in pH were a valid indicator of trichomonad growth (T. vaginalis and T. foetus), allowing development of a miniaturised, chromogenic growth assay based on the phenol red indicator in 96- and 384-well microtiter plate formats. The outputs of this assay can be quantitatively and qualitatively assessed, with consistent dynamic ranges based on Z' values of 0.741 and 0.870 across medium- and high-throughput formats, respectively. We applied this high-throughput format within the largest pure-compound microbial metabolite screen (812 compounds) for T. vaginalis and identified 43 hit compounds. We compared these identified compounds to mammalian cell lines, and highlighted extensive overlaps between anti-trichomonal and anti-tumour activity. Lastly, observing nanomolar inhibition of T. vaginalis by fumagillin, and noting this compound has reported activity in other protists, we performed in silico analyses of the interaction of fumagillin with its molecular target methionine aminopeptidase 2 for T. vaginalis, Giardia lamblia and Entamoeba histolytica, highlighting potential for fumagillin as a broad-spectrum anti-protistal against microaerophilic protists. Together, this new platform will accelerate drug-discovery efforts, underpin drug-resistance screening in trichomonads, and contributing to a growing body of evidence highlighting the potential of microbial natural products as novel anti-protistals.