Forecasting virus disease in seed potatoes using flight activity data of aphid vectors

Steinger, Thomas; Goy, G.; Gilliand, H.; Hebeisen, Thomas; Derron, J.

doi:10.1111/aab.12190

Cited by 22 publications

(7 citation statements)

References 39 publications

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“…For example, Congdon et al [22] developed an empirical model to forecast pea seed-borne mosaic virus (PSbMV) incidence in field pea crops using pre-growing season rainfall to calculate an index of aphid abundance which is used in combination with the virus infection level in the sown seed, to provide forecasts before sowing to allow sufficient time to implement control recommendations. Similarly, Steinger et al [23] observed that the post-harvest incidence of potato virus Y (PVY) in seed potato in Switzerland could be accurately predicted by the cumulative abundance of Brachycaudus helichrysi (from first appearance in spring up to mid-June) and that this abundance was positively correlated to the mean daily winter temperature (January-February) indicating that winter conditions could be used as an early warning signal for PVY risk in the current season. Therefore, regarding our pathosystem, forecasting A. gossypii spring flying patterns as a function of winter climatic conditions could be worth investigating in order to deploy strategic control measures before planting.…”

Section: Discussionmentioning

confidence: 98%

Can Winged Aphid Abundance Be a Predictor of Cucurbit Aphid-Borne Yellows Virus Epidemics in Melon Crop?

Schoeny

Rimbaud

Gognalons

et al. 2020

Viruses

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Aphid-borne viruses are frequent yield-limiting pathogens in open field vegetable crops. In the absence of curative methods, virus control relies exclusively on measures limiting virus introduction and spread. The efficiency of control measures may greatly benefit from an accurate knowledge of epidemic drivers, in particular those linked with aphid vectors. Field experiments were conducted in southeastern France between 2010 and 2019 to investigate the relationship between the epidemics of cucurbit aphid-borne yellows virus (CABYV) and aphid vector abundance. Winged aphids visiting melon crops were sampled daily to assess the abundance of CABYV vectors (Aphis gossypii, Macrosiphum euphorbiae and Myzus persicae) and CABYV was monitored weekly by DAS-ELISA. Epidemic temporal progress curves were successfully described by logistic models. A systematic search for correlations was undertaken between virus variables including parameters µ (inflection point of the logistic curve) and γ (maximum incidence) and aphid variables computed by aggregating abundances on periods relative either to the planting date, or to the epidemic peak. The abundance of A. gossypii during the first two weeks after planting was found to be a good predictor of CABYV dynamics, suggesting that an early control of this aphid species could mitigate the onset and progress of CABYV epidemics in melon crops.

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Section: Discussionmentioning

confidence: 98%

Can Winged Aphid Abundance Be a Predictor of Cucurbit Aphid-Borne Yellows Virus Epidemics in Melon Crop?

Schoeny

Rimbaud

Gognalons

et al. 2020

Viruses

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“…Forecast models are available for potatoes predicting the spread of a Potato virus Y in the current season using trap data of aphid flights ( Steinger et al., 2015 ) to optimize virus control in seed potato production. Qi et al.…”

Section: Modeling and Forecastingmentioning

confidence: 99%

From identification to forecasting: the potential of image recognition and artificial intelligence for aphid pest monitoring

Batz¹,

Will

Thiel³

et al. 2023

Front. Plant Sci.

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Insect monitoring has gained global public attention in recent years in the context of insect decline and biodiversity loss. Monitoring methods that can collect samples over a long period of time and independently of human influences are of particular importance. While these passive collection methods, e.g. suction traps, provide standardized and comparable data sets, the time required to analyze the large number of samples and trapped specimens is high. Another challenge is the necessary high level of taxonomic expertise required for accurate specimen processing. These factors create a bottleneck in specimen processing. In this context, machine learning, image recognition and artificial intelligence have emerged as promising tools to address the shortcomings of manual identification and quantification in the analysis of such trap catches. Aphids are important agricultural pests that pose a significant risk to several important crops and cause high economic losses through feeding damage and transmission of plant viruses. It has been shown that long-term monitoring of migrating aphids using suction traps can be used to make, adjust and improve predictions of their abundance so that the risk of plant viruses spreading through aphids can be more accurately predicted. With the increasing demand for alternatives to conventional pesticide use in crop protection, the need for predictive models is growing, e.g. as a basis for resistance development and as a measure for resistance management. In this context, advancing climate change has a strong influence on the total abundance of migrating aphids as well as on the peak occurrences of aphids within a year. Using aphids as a model organism, we demonstrate the possibilities of systematic monitoring of insect pests and the potential of future technical developments in the subsequent automated identification of individuals through to the use of case data for intelligent forecasting models. Using aphids as an example, we show the potential for systematic monitoring of insect pests through technical developments in the automated identification of individuals from static images (i.e. advances in image recognition software). We discuss the potential applications with regard to the automatic processing of insect case data and the development of intelligent prediction models.

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“…Uit buitenlands onderzoek (Sigvald, 1992;Basky, 2002;Kirchner et al, 2011;Steinger et al, 2015) Het belangrijkste resultaat is dat duidelijk is geworden dat aardappelen de belangrijkste virusbron zijn voor de verspreiding van PVY, dit gegeven leidt tot hernieuwde aandacht voor oude adviezen en nieuwe aandachtspunten, waaronder:…”

Section: Veldonderzoek Irs Bietenvergelingsziekte In Suikerbietenunclassified

Virus- en vectorbeheersing in pootaardappelen en suikerbieten : eindverslag PPS TU18049

Verbeek,

van Rozen,

de Wolf

et al. 2023

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Forecasting virus disease in seed potatoes using flight activity data of aphid vectors

Cited by 22 publications

References 39 publications

Can Winged Aphid Abundance Be a Predictor of Cucurbit Aphid-Borne Yellows Virus Epidemics in Melon Crop?

Can Winged Aphid Abundance Be a Predictor of Cucurbit Aphid-Borne Yellows Virus Epidemics in Melon Crop?

From identification to forecasting: the potential of image recognition and artificial intelligence for aphid pest monitoring

Virus- en vectorbeheersing in pootaardappelen en suikerbieten : eindverslag PPS TU18049

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