Abstract
Historically, monitoring nematode movement and mortality in response to various potential nematicide treatments usually involved tedious manual microscopic analysis. High-content analysis instrumentation enables rapid and high-throughput collection of experimental data points on large numbers of individual worms simultaneously. The high-throughput platform outlined here should accelerate discovery of unique classes and types of promising lead molecules and sample types to control these plant pests. Also, the ability to automate the data analysis pipeline rather than relying on manual scoring reduces a potential source of data variance. Here we describe a high-throughput process based on high-content imaging. We demonstrate the use of time-lapse image acquisition to measure movement, and viability staining to confirm nematode mortality (versus paralysis) in targeted plant-pathogenic nematodes. We present screening results from a microbial-exudate library generated from approximately 2,300 microbial fermentations that demonstrate the robustness of this high-throughput process. The described methods should be applicable to other relevant nematode parasites with human, crop, or animal hosts.
Highlights
Nematode infection of commercial crops is a wide-spread economic and food security issue resulting in yield loss worldwide[1]
We found that by utilizing the timelapse capabilities of our high content analysis (HCA) instrument, along with image analysis, we could measure the movement of each worm at micron resolution
Using our colocalization measurements on individual worms, we identified a dose-dependent range of movement for ivermectin-treated Root Knot Nematode Meloidogyne incognita (RKN) and Soybean Cyst Nematodes Heterodera glycines (SCN)
Summary
Nematode infection of commercial crops is a wide-spread economic and food security issue resulting in yield loss worldwide[1]. Two main factors have hampered control of these crop pathogens: nematode populations have developed resistance to pesticides, and efficacious chemical pesticides have been removed from the market due to general environmental toxicity [2]. For these reasons, much of the research targeting methods of regulation of nematode infections has shifted focus to alternative control strategies that utilize naturally occurring / endogenous soil microbial and fungal strains [3,4]. The specific roles of all authors are articulated in the ‘author contributions’ section
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