Airborne Pheromone Quantification in Treated Vineyards with Different Mating Disruption Dispensers against Lobesia botrana

Mating disruption (MD) is widely used against the European grapevine moth (EGVM), Lobesia botrana (Denis and Schiffermüller; Lepidoptera: Tortricidae), by installing passive dispensers or aerosol devices. The present work reports a new sampling and quantification methodology to obtain absolute data about field airborne pheromone concentration based on air samplings and sensitive chromatographic-spectroscopic methods. Samplings were performed in fields treated with passive dispensers or aerosol devices at different moments throughout the crop cycle to study how they act and how the disruption is triggered. Moreover, pheromone adsorption and releasing capacity of vine leaves were studied to elucidate their role in the disruption. Although both types of dispensers were effective in limiting the damage inflicted by EGVM, they performed differently and provided different airborne pheromone concentration profiles. Results also proved that leaves were able to adsorb and release part of the airborne pheromone acting as subsequent and additional pheromone sources. This fact could explain the different concentration profiles. Moreover, our results suggest that lower pheromone emission than that of the current passive dispensers still could provide an adequate performance in the field. Competitive mechanisms involved in MD using both dispensers, the dynamics of the airborne pheromone throughout the time and the importance of the canopy are discussed.

Open source computational simulation for a moth-inspired navigation algorithm

Olfactory navigation in insects, for instance when males search for mates, is a navigational problem of a self-propelled agent with limited sensor capabilities in a scalar field (odor) convected and diffused by turbulent wind. There are numerous navigation strategies proposed to explain the navigation paths of insects to food (flowers) or mating partners (females). In a search for a mate, the males use airborne pheromone puffs in turbulent environments around trees and vegetation. It is difficult to compare the various strategies because of a lack of a single simulation framework that can change a single parameter in time and test all the strategies against a controlled environment. This work aims at closing this gap, suggesting an open source, freely accessible simulation framework, abbreviated MothPy. We implement the simulation framework using another open source package (“pompy”) that recreates a state-of-the-art puff-based odor plume model of Farrell et al. [1]. We add four different navigation strategies to the simulation framework based on and extending the previously published models [2, 3], and compare their performance with different wind and odor spread parameters. We test a sensitivity analysis of the navigation strategies to the plume meandering and to increased turbulence levels that are effectively expressed as the elevated puff spread rates. The simulations are compared statistically and provide an interesting view on the robustness and effectiveness of various strategies. This benchmarking-ready simulation framework could be useful for the biology-oriented, as well as engineering-oriented studies, assisting to deduce the evolutionary efficient strategies and improving self-propelled autonomous systems in complex environments.

MATING BEHAVIOR OF SPRUCE BUDWORM MOTHS, CHORISTONEURA FUMIFERANA (CLEM.) (LEPIDOPTERA: TORTRICIDAE)

The mating behavior of spruce budworm [Choristoneura fumiferana (Clem.)] moths was studied in a wind tunnel. Of 88 contacts between male and female moths, 64 (73%) resulted in successful copulation. Failures were a result of males losing contact during courtship (11%), and females walking or flying, either when first contacted (7%) or when males attempted copulation (9%). Females showed no overt behavior other than moving away. Removal of the male labial palps had no effect on responses, which indicates that these structures have no role in courtship. Males with antennae completely removed did not respond to airborne pheromone and, therefore, none copulated. Removal of one antenna or half of both antennae of the males did not reduce the numbers of males that located females, but did result in slower responses and fewer matings. It also resulted in changes in male courtship behavior, which suggest that males depend upon their antennae to position themselves appropriately alongside the female when attempting to copulate. Analyses of male response to models of female moths constructed from glass rods with wings of male spruce budworm or male white-marked tussock moth [Orgyia leucostigma (J.E. Smith)] attached showed that males position themselves approximately halfway along me wing length of the model, with no dependance on its wing size or the length of the male’s antennae. Responses were equally high to both spruce budworm and to tussock moth wings, but no males responded to glass rods in the absence of wings.