RESUMEN
BACKGROUND: Fluensulfone is a nematicide with a novel mode of action against plant parasitic nematodes. Here, we utilize in vitro hatching assays to investigate fluensufone's ability to inhibit Globodera pallida hatching, relative to the efficacy of other distinct classes of nematicides. RESULTS: Fluensulfone, abamectin, aldicarb and fluopyram inhibit G. pallida hatching from cysts more potently than from isolated eggs. At 1 µM for cysts, the order of potency is fluensulfone> fluopyram> abamectin> aldicarb. At low concentrations of fluensulfone, inhibition of hatching is reversible, however, more than 50% of the juveniles that hatch from cysts pre-treated with fluensulfone have reduced motility. This is observed to a lesser extent with abamectin, fluopyram and aldicarb. When cysts are exposed to higher concentrations of fluensulfone (≥500 µM), abamectin (≥100 µM) and fluopyram (≥50 µM) inhibition of hatching is irreversible. This results from the loss of encysted juvenile structure giving rise to a granulated appearance consistent with necrosis, suggesting a nematicidal effect. Intriguingly, hatching initiated by root diffusate is arrested when egg populations are subsequently exposed to fluensulfone. CONCLUSION: Fluensulfone, abamectin, fluopyram and aldicarb inhibit G. pallida hatching. Fluensulfone is a potent inhibitor of hatching and impacts on the viability of the J2 s emerging from the cysts. This activity, and the previously described impaired motility and metabolism of hatched juveniles, show that fluensulfone's distinct mode of action among existing nematicides intersects at two pivotal steps of the parasitic life cycle.
Asunto(s)
Aldicarb , Tylenchoidea , Animales , Benzamidas , Ivermectina/análogos & derivados , Piridinas , Sulfonas , TiazolesRESUMEN
INTRODUCTION: Our ability to document insect preference for semiochemicals is pivotal in pest control as these agents can improve monitoring and be deployed within integrated pest management programmes for more efficacious control of pest species. However, methods used to date have drawbacks that limit their utility. We present and test a new concept for determining insect motivation to move towards, or away from, semiochemicals by noting direction and speed of movement as animals work against a defined energy landscape (environmentally dependent variation in the cost of transport) requiring different powers to negotiate. We conducted trials with the pine weevils Hylobius abietis and peach-potato aphids Myzus persicae exposed to various attractants and repellents and placed so that they either moved up defined slopes against gravity or had to travel over variously rough surfaces. RESULTS: Linear Mixed Models demonstrated clear reductions in travel speed by insects moving along increasingly energetically taxing energy landscapes but also that responses varied according to different semiochemicals, thus highlighting the value of energy landscapes as a new concept to help measure insect motivation to access or avoid different attractants or repellents across individuals. CONCLUSIONS: New sensitive, detailed indicators of insect motivation derived from this approach should prove important in pest control across the world.