Your search keyword '"Leybourne, Daniel J."' showing total 16 results

1. Thresholds and prediction models to support the sustainable management of herbivorous insects in wheat. A review

Author

Leybourne, Daniel J., Storer, Kate E., Marshall, Abigail, Musa, Nasamu, Telling, Samuel, Abel, Laurie, White, Sacha, Ellis, Steve, Yang, Po, and Berry, Pete M.

Published

2024

2. How does vector diversity influence the transmission efficiency of yellow dwarf virus? Perspectives from a review.

Author

Leybourne, Daniel J.

Subjects

*BARLEY yellow dwarf viruses, *PHYTOPLASMAS, *PLANT viruses, *BIOLOGICAL variation, *PLANT diseases

Abstract

Cereals are some of the most important global crops that contribute directly and indirectly to the production of food for human consumption. Cereal aphids can cause significant damage to wheat, barley and oats, particularly via the transmission of plant viruses that cause devastating plant diseases, such as yellow dwarf disease. High levels of yellow dwarf disease can result in yield losses of around 20%, rising to 80% if infection is severe. Yellow dwarf disease is caused by multiple viruses, including viruses within the families Tombusviridae and Solemoviridae. These include yellow dwarf virus species within the genus Luteovirus (Barley yellow dwarf virus) and Polerovirus (Cereal yellow dwarf virus, Wheat yellow dwarf virus, Maize yellow dwarf virus). Some yellow dwarf virus species are primarily vectored by one aphid species whereas others can be transmitted by multiple vectors. Biological diversity within a given vector species (e.g., genotype, biotype) can influence virus transmission efficiency. However, it is unclear what biological factors drive this variation within a given vector species. Understanding how biological variation in vector populations influences virus transmission efficiency can help to identify biological traits that underpin successful transmission in competent vector populations. Here, the available literature on yellow dwarf virus transmission efficiency is synthesized and significant variation in yellow dwarf virus transmission efficiency is detected between different populations for several vector species. Three biological mechanisms that potentially underpin this variation are proposed. [ABSTRACT FROM AUTHOR]

Published

2024

3. Can artificial intelligence be integrated into pest monitoring schemes to help achieve sustainable agriculture? An entomological, management and computational perspective.

Author

Leybourne, Daniel J., Musa, Nasamu, and Yang, Po

Abstract

Recent years have seen significant advances in artificial intelligence (AI) technology. This advancement has enabled the development of decision support systems that support farmers with herbivorous pest identification and pest monitoring. In these systems, the AI supports farmers through the detection, classification and quantification of herbivorous pests. However, many of the systems under development fall short of meeting the demands of the end user, with these shortfalls acting as obstacles that impede the integration of these systems into integrated pest management (IPM) practices. There are four common obstacles that restrict the uptake of these AI‐driven decision support systems. Namely: AI technology effectiveness, functionality under field conditions, the level of computational expertise and power required to use and run the system and system mobility. We propose four criteria that AI‐driven systems need to meet in order to overcome these challenges: (i) The system should be based on effective and efficient AI; (ii) The system should be adaptable and capable of handling ‘real‐world’ image data collected from the field; (iii) Systems should be user‐friendly, device‐driven and low‐cost; (iv) Systems should be mobile and deployable under multiple weather and climate conditions. Systems that meet these criteria are likely to represent innovative and transformative systems that successfully integrate AI technology with IPM principles into tools that can support farmers. [ABSTRACT FROM AUTHOR]

Published

2024

4. Priorities for action in the coming decades

Author

Luke, Sarah H., Roy, Helen E., Thomas, Chris D., Tilley, Luke A. N., Ward, Simon, Watt, Allan, Carnaghi, Manuela, Jaworski, Coline C., Tercel, Maximillian P. T. G., Woodrow, Charlie, Aown, Susmita, Banfield-Zanin, Jennifer A., Barnsley, Sarah L., Berger, Iris, Brown, Mark J. F., Bull, James C., Campbell, Heather, Carter, Ruth A. B., Charalambous, Magda, Cole, Lorna J., Ebejer, Martin J., Farrow, Rachel A., Fartyal, Rajendra S., Grace, Miriam, Highet, Fiona, Hill, Jane K., Hood, Amelia S. C., Kent, Eleanor S., Krell, Frank Thorsten, Leather, Simon R., Leybourne, Daniel J., Littlewood, Nick A., Lyons, Ashley, Matthews, Graham, Mc Namara, Louise, Menéndez, Rosa, Merrett, Peter, Mohammed, Sajidha, Murchie, Archie K., Noble, Michael, Paiva, Maria Rosa, Pannell, Michael J., Phon, Chooi Khim, Port, Gordon, Powell, Charlotte, Rosell, Stewart, Sconce, Francisca, Shortall, Chris R., Slade, Eleanor M., Sutherland, Jamie P., Weir, Jamie C., Williams, Christopher D., Zielonka, Natalia B., Dicks, Lynn V., and CENSE - Centro de Investigação em Ambiente e Sustentabilidade

Subjects

education, conservation, land use, insect taxonomy, funding and research priorities, climate change, SDG 3 - Good Health and Well-being, disease vector, Insect Science, SDG 13 - Climate Action, insect biodiversity, ecosystem services, SDG 2 - Zero Hunger, pest control, Ecology, Evolution, Behavior and Systematics, SDG 15 - Life on Land

Abstract

Funding Information: Royal Entomological Society; UKRI Natural Environment Research Council, Grant/Award Number: NE/V006533/1; Rural & Environment Science & Analytical Services Division of the Scottish Government; ; Alexander von Humboldt Foundation; Department of Agriculture, Environment & Rural Affairs; Center for Environmental and Sustainability Research; FCT/MCTES, Grant/Award Number: UID/AMB/04085/2020; UKRI Biotechnology and Biological Sciences Research Council, Grant/Award Number: BBS/E/C/000J0200; UKRI Biotechnology and Biological Sciences Research Council Norwich Research Park Biosciences Doctoral Training Partnership, Grant/Award Number: BB/M011216/1; UKRI Natural Environment Research Council, Grant/Award Number: NE/N014472/2 Funding information Funding Information: This study was approved by the University of Cambridge Psychology Research Ethics Committee (permit number PRE.2020.103). The exercise was funded by the Royal Entomological Society (RES). Helen E. Roy acknowledges support from UK Natural Environment Research Council grant NE/V006533/1 GLobal Insect Threat‐Response Synthesis (GLiTRS): a comprehensive and predictive assessment of the pattern and consequences of insect declines. Lorna J. Cole's time was funded by the Rural & Environment Science & Analytical Services Division of the Scottish Government. Daniel J. Leybourne was supported by the Alexander von Humboldt Foundation through a postdoctoral research fellowship. Sajidha Mohammed thanks the RES for providing 1‐year of free student membership which allowed them to contribute to the workshop. Archie K. Murchie was supported by the Agri‐Food & Biosciences Institute which is sponsored by the Department of Agriculture, Environment & Rural Affairs (NI). Maria‐Rosa Paiva receives support from CENSE (Center for Environmental and Sustainability Research), which is financed by national funds from FCT/MCTES (UID/AMB/04085/2020). Chris R. Shortall was supported by the Rothamsted Insect Survey, a National Capability, which is funded by the Biotechnology and Biological Sciences Research Council under the Core Capability Grant BBS/E/C/000J0200. Christopher D. Williams thanks the Faculty of Science at Liverpool John Moores University for funding attendance at various Royal Entomological Society meetings. Natalia B. Zielonka was supported by the UKRI Biotechnology and Biological Sciences Research Council Norwich Research Park Biosciences Doctoral Training Partnership (BB/M011216/1). Lynn V. Dicks's time was funded by the Natural Environment Research Council (grant code: NE/N014472/2). For the purpose of Open Access, the authors have applied a CC BY public copyright licence to any author accepted manuscript version arising from this submission. We sincerely thank all survey participants for contributing their ideas, knowledge and time. The authors thank four anonymous reviewers, Manu Saunders and Raphael Didham for their comments on an earlier version of the manuscript. For one of our co‐authors and workshop participants, Professor Simon Leather Hon. FRES, this is a posthumous publication. We dedicate this paper to him, as a heartfelt tribute to his incredible contributions to entomological research, higher education and public engagement. Publisher Copyright: © 2023 The Authors. Insect Conservation and Diversity published by John Wiley & Sons Ltd on behalf of Royal Entomological Society. Entomology is key to understanding terrestrial and freshwater ecosystems at a time of unprecedented anthropogenic environmental change and offers substantial untapped potential to benefit humanity in a variety of ways, from improving agricultural practices to managing vector-borne diseases and inspiring technological advances. We identified high priority challenges for entomology using an inclusive, open, and democratic four-stage prioritisation approach, conducted among the membership and affiliates (hereafter ‘members’) of the UK-based Royal Entomological Society (RES). A list of 710 challenges was gathered from 189 RES members. Thematic analysis was used to group suggestions, followed by an online vote to determine initial priorities, which were subsequently ranked during an online workshop involving 37 participants. The outcome was a set of 61 priority challenges within four groupings of related themes: (i) ‘Fundamental Research’ (themes: Taxonomy, ‘Blue Skies’ [defined as research ideas without immediate practical application], Methods and Techniques); (ii) ‘Anthropogenic Impacts and Conservation’ (themes: Anthropogenic Impacts, Conservation Options); (iii) ‘Uses, Ecosystem Services and Disservices’ (themes: Ecosystem Benefits, Technology and Resources [use of insects as a resource, or as inspiration], Pests); (iv) ‘Collaboration, Engagement and Training’ (themes: Knowledge Access, Training and Collaboration, Societal Engagement). Priority challenges encompass research questions, funding objectives, new technologies, and priorities for outreach and engagement. Examples include training taxonomists, establishing a global network of insect monitoring sites, understanding the extent of insect declines, exploring roles of cultivated insects in food supply chains, and connecting professional with amateur entomologists. Responses to different challenges could be led by amateur and professional entomologists, at all career stages. Overall, the challenges provide a diverse array of options to inspire and initiate entomological activities and reveal the potential of entomology to contribute to addressing global challenges related to human health and well-being, and environmental change. publishersversion published

Published

2023

5. Common facultative endosymbionts do not influence sensitivity of cereal aphids to pyrethroids.

Author

Leybourne, Daniel J., Melloh, Petra, and Martin, Emily A.

Subjects

*PYRETHROIDS, *RHOPALOSIPHUM padi, *APHIDS, *INSECTICIDE resistance, *CROP yields

Abstract

Cereal aphids, including the bird cherry‐oat aphid, Rhopalosiphum padi, and the grain aphid, Sitobion avenae, can transmit viruses that significantly reduce crop yields. To mitigate against yield losses, insecticides are routinely used to manage aphid populations.Aphids can form relationships with endosymbionts that confer fitness benefits or consequences to the aphid. Recent artificial inoculation experiments indicate that endosymbionts could increase aphid susceptibility to insecticides, but this has not been explored using aphid populations naturally infected with endosymbionts.Here, we sampled aphids from an important cereal production region in Lower Saxony, Germany. We characterized the endosymbiont profile of these aphid populations and conducted pyrethroid dose–response assays to test the hypothesis that facultative endosymbionts increase aphid susceptibility to insecticides.We find that the level of insecticide susceptibility is highly variable in S. avenae and we identify populations that are sensitive and tolerant to pyrethroids, including populations collected from the same field. For R. padi, we find evidence for decreased sensitivity to pyrethroids, representing the first report of reduced sensitivity to pyrethroids in R. padi sampled from Central Europe.We detected high endosymbiont infection frequencies in the aphid populations. 84% of aphids carry one facultative endosymbiont and 9% of aphids carry two facultative endosymbionts. We detected associations with Regiella insecticola, Fukatsia symbiotica, and Hamiltonella defensa. However, we do not identify a link between endosymbiont infection and insecticide susceptibility, indicating that other factors may govern the development of insecticide resistance and the need for alternative management strategies. [ABSTRACT FROM AUTHOR]

Published

2023

6. To tolerate drought or resist aphids? A new challenge to plant science is on the horizon.

Author

Ramírez, Claudio C, Gundel, Pedro E, Karley, Alison J, and Leybourne, Daniel J

Subjects

DROUGHTS, BOTANY, APHIDS, DROUGHT management, DROUGHT tolerance, PLANT breeding, PLANT variation

Abstract

Aphids are important herbivorous insects that can cause significant crop damage, leading to yield reduction and economic loss. One avenue being explored to reduce aphid impacts is the development of aphid-resistant plants. Under projected climate scenarios, it is expected that plants will be exposed to greater biotic and abiotic stress, including increased herbivorous insect infestation and exposure to prolonged periods of environmental stress, particularly drought. In response to these projections, plant–aphid interactions under drought conditions have been a subject of growing interest; however, few studies have looked at the impact of drought stress on plant resistance to aphids despite the potential importance for plant breeding. Here, we examine the latest scientific advances regarding variation in plant resistance to aphids under drought, emphasizing underlying mechanisms and functional trade-offs and propose a conceptual model relating plant tolerance to drought with plant resistance to aphids. [ABSTRACT FROM AUTHOR]

Published

2023

7. Drought stress increases the expression of barley defence genes with negative consequences for infesting cereal aphids.

Author

Leybourne, Daniel J, Valentine, Tracy A, Binnie, Kirsty, Taylor, Anna, Karley, Alison J, and Bos, Jorunn I B

Subjects

*DROUGHTS, *RHOPALOSIPHUM padi, *RUSSIAN wheat aphid, *APHIDS, *OATS, *BARLEY, *PLANT physiology

Abstract

Crops are exposed to myriad abiotic and biotic stressors with negative consequences. Two stressors that are expected to increase under climate change are drought and infestation with herbivorous insects, including important aphid species. Expanding our understanding of the impact drought has on the plant–aphid relationship will become increasingly important under future climate scenarios. Here we use a previously characterized plant–aphid system comprising a susceptible variety of barley, a wild relative of barley with partial aphid resistance, and the bird cherry-oat aphid to examine the drought–plant–aphid relationship. We show that drought has a negative effect on plant physiology and aphid fitness, and provide evidence to suggest that plant resistance influences aphid responses to drought stress. Furthermore, we show that the expression of thionin genes, plant defensive compounds that contribute to aphid resistance, increase in susceptible plants exposed to drought stress but remain at constant levels in the partially resistant plant, suggesting that they play an important role in determining the success of aphid populations. This study highlights the role of plant defensive processes in mediating the interactions between the environment, plants, and herbivorous insects. [ABSTRACT FROM AUTHOR]

Published

2022

8. Development of a pest threshold decision support system for minimising damage to winter wheat from wheat bulb fly, Delia coarctata.

Author

Leybourne, Daniel J., Storer, Kate E., Berry, Pete, and Ellis, Steve

Subjects

*WINTER wheat, *DECISION support systems, *PESTS, *WHEAT, *SEED treatment, *AGRICULTURAL pests

Abstract

Wheat bulb fly, Delia coarctata, is an important pest of winter wheat in the UK, causing significant damage of up to 4 t/ha. Accepted population thresholds for D. coarctata are 250 eggs/m2 for crops sown up to the end of October and 100 eggs/m2 for crops sown from November. Fields with populations of D. coarctata that exceed the thresholds are at higher risk of experiencing economically damaging infestations. In the UK, recent withdrawal of insecticides means that only a seed treatment (Signal 300 ES) is available for chemical control of D. coarctata; however, this is only effective for late‐sown crops and accurate estimations of annual population levels are required to ensure a seed treatment is applied if needed. As a result of the lack of postdrilling control strategies, the management of D. coarctata is becoming reliant on nonchemical methods of control. Control strategies that are effective in managing similar stem‐boring pests of wheat include sowing earlier and using higher seed rates to produce crops with greater pest tolerance. In this study, we develop two predictive models that can be used for integrated D. coarctata management. The first is an updated pest level prediction model that predicts D. coarctata populations from meteorological parameters with a predictive accuracy of 70%, a significant improvement on previous prediction models. Our second model predicts the maximum number of shoots for a winter wheat crop that would be expected at the terminal spikelet development stage. This shoot number model uses information about the thermal time from plant emergence to terminal spikelet, leaf phyllochron length, plant population and sowing date to predict the degree of tolerance a crop will have against D. coarctata. The shoot number model was calibrated against data collected from five field experiments and tested against data from four experiments. Model testing demonstrated that the shoot number model has a predictive accuracy of 65.7%. The foundation for a future decision support system using these models for the sustainable management of D. coarcata risk is described. It should be noted that these models represent a stepping‐stone towards a decision support system and that further model validation over a wider geographic range is required. [ABSTRACT FROM AUTHOR]

Published

2022

9. Drought has negative consequences on aphid fitness and plant vigor: Insights from a meta‐analysis.

Author

Leybourne, Daniel J., Preedy, Katharine F., Valentine, Tracy A., Bos, Jorunn I. B., and Karley, Alison J.

Subjects

*DROUGHTS, *DROUGHT management, *APHIDS, *VITALITY, *CROPS, *HOST plants, *PLANT defenses, *CONCEPTUAL models

Abstract

Aphids are abundant in natural and managed vegetation, supporting a diverse community of organisms and causing damage to agricultural crops. Due to a changing climate, periods of drought are anticipated to increase, and the potential consequences of this for aphid–plant interactions are unclear.Using a meta‐analysis and synthesis approach, we aimed to advance understanding of how increased drought incidence will affect this ecologically and economically important insect group and to characterize any potential underlying mechanisms. We used qualitative and quantitative synthesis techniques to determine whether drought stress has a negative, positive, or null effect on aphid fitness and examined these effects in relation to (a) aphid biology, (b) geographical region, and (c) host plant biology.Across all studies, aphid fitness is typically reduced under drought. Subgroup analysis detected no difference in relation to aphid biology, geographical region, or the aphid–plant combination, indicating the negative effect of drought on aphids is potentially universal. Furthermore, drought stress had a negative impact on plant vigor and increased plant concentrations of defensive chemicals, suggesting the observed response of aphids is associated with reduced plant vigor and increased chemical defense in drought‐stressed plants.We propose a conceptual model to predict drought effects on aphid fitness in relation to plant vigor and defense to stimulate further research. [ABSTRACT FROM AUTHOR]

Published

2021

10. Plant resistance in different cell layers affects aphid probing and feeding behaviour during non-host and poor-host interactions.

Author

Escudero-Martinez, Carmen, Leybourne, Daniel J., and Bos, Jorunn I.B.

Subjects

*APHIDS, *GREEN peach aphid, *RHOPALOSIPHUM padi, *CROP losses, *HOST plants, *BARLEY

Abstract

Aphids are phloem-feeding insects that cause economic losses to crops globally. Whilst aphid interactions with susceptible plants and partially resistant genotypes have been well characterized, the interactions between aphids and non-host species are not well understood. Unravelling these non-host interactions can identify the mechanisms which contribute to plant resistance. Using contrasting aphid-host plant systems, including the broad host range pest Myzus persicae (host: Arabidopsis; poor-host: barley) and the cereal pest Rhopalosiphum padi (host: barley; non-host: Arabidopsis), we conducted a range of physiological experiments and compared aphid settling and probing behaviour on a host plant vs either a non-host or poor-host. In choice experiments, we observed that around 10% of aphids selected a non-host or poor-host plant species after 24 h. Using the Electrical Penetration Graph technique, we showed that feeding and probing behaviours differ during non-host and poor-host interactions when compared with a host interaction. In the Arabidopsis non-host interaction with the cereal pest R. padi aphids were unable to reach and feed on the phloem, with resistance likely residing in the mesophyll cell layer. In the barley poor-host interaction with M. persicae, resistance is likely phloem-based as phloem ingestion was reduced compared with the host interaction. Overall, our data suggest that plant resistance to aphids in non-host and poor-host interactions with these aphid species likely resides in different plant cell layers. Future work will take into account specific cell layers where resistances are based to dissect the underlying mechanisms and gain a better understanding of how we may improve crop resistance to aphids. [ABSTRACT FROM AUTHOR]

Published

2021

11. Learning‐induced switching costs in a parasitoid can maintain diversity of host aphid phenotypes although biocontrol is destabilized under abiotic stress.

Author

Preedy, Katharine F., Chaplain, Mark A. J., Leybourne, Daniel J., Marion, Glenn, Karley, Alison J., and Tate, Ann

Subjects

SWITCHING costs, ABIOTIC stress, DROUGHT management, APHIDS, DELAY differential equations, EFFECT of stress on crops, BIOLOGICAL pest control, BIOLOGICAL control of insects

Abstract

Aphid populations frequently include phenotypes that are resistant to parasitism by hymenopterous parasitoid wasps, which is often attributed to the presence of 'protective' facultative endosymbionts residing in aphid tissues, particularly Hamiltonella defensa. In field conditions, under parasitoid pressure, the observed coexistence of aphids with and without protective symbionts cannot be explained by their difference in fitness alone.Using the cereal aphid Rhopalosiphum padi as a model, we propose an alternative mechanism whereby parasitoids are more efficient at finding common phenotypes of aphid and experience a fitness cost when switching to the less common phenotype.We construct a model based on delay differential equations and parameterize and validate the model with values within the ranges obtained from experimental studies. We then use it to explore the possible effects on system dynamics under conditions of environmental stress, using our existing data on the effects of drought stress in crops as an example.We show the 'switching penalty' incurred by parasitoids leads to stable coexistence of aphids with and without H. defensa and provides a potential mechanism for maintaining phenotypic diversity among host organisms. We show that drought‐induced reduction in aphid development time has little impact. However, greater reduction in fecundity on droughted plants of symbiont‐protected aphids can cause insect population cycles when the system would be stable in the absence of drought stress.The stabilizing effect of the increased efficiency in dealing with more commonly encountered host phenotypes is applicable to a broad range of consumer–resource systems and could explain stable coexistence in competitive environments. The loss of stable coexistence when drought has different effects on the competing aphid phenotypes highlights the importance of scenario testing when considering biocontrol for pest management. [ABSTRACT FROM AUTHOR]

Published

2020

12. The price of protection: a defensive endosymbiont impairs nymph growth in the bird cherry‐oat aphid, Rhopalosiphum padi.

Author

Leybourne, Daniel J., Bos, Jorunn I. B., Valentine, Tracy A., and Karley, Alison J.

Subjects

*HORDEUM, *RHOPALOSIPHUM padi, *BIRD growth, *OATS, *CHERRIES, *MICROSATELLITE repeats, *RICE, *HOST plants

Abstract

Bacterial endosymbionts have enabled aphids to adapt to a range of stressors, but their effects in many aphid species remain to be established. The bird cherry‐oat aphid, Rhopalosiphum padi (Linnaeus), is an important pest of cereals worldwide and has been reported to form symbiotic associations with Serratia symbiotica and Sitobion miscanthi L‐type symbiont endobacteria, although the resulting aphid phenotype has not been described. This study presents the first report of R. padi infection with the facultative bacterial endosymbiont Hamiltonella defensa. Individuals of R. padi were sampled from populations in Eastern Scotland, UK, and shown to represent seven R. padi genotypes based on the size of polymorphic microsatellite markers; two of these genotypes harbored H. defensa. In parasitism assays, survival of H. defensa‐infected nymphs following attack by the parasitoid wasp Aphidius colemani (Viereck) was 5 fold higher than for uninfected nymphs. Aphid genotype was a major determinant of aphid performance on two Hordeum species, a modern cultivar of barley H. vulgare and a wild relative H. spontaneum, although aphids infected with H. defensa showed 16% lower nymph mass gain on the partially resistant wild relative compared with uninfected individuals. These findings suggest that deploying resistance traits in barley will favor the fittest R. padi genotypes, but symbiont‐infected individuals will be favored when parasitoids are abundant, although these aphids will not achieve optimal performance on a poor quality host plant. [ABSTRACT FROM AUTHOR]

Published

2020

13. Defence gene expression and phloem quality contribute to mesophyll and phloem resistance to aphids in wild barley.

Author

Leybourne, Daniel J, Valentine, Tracy A, Robertson, Jean A H, Pérez-Fernández, Estefania, Main, Angela M, Karley, Alison J, and Bos, Jorunn I B

Subjects

*RUSSIAN wheat aphid, *BARLEY, *GENE expression, *HORDEUM, *PHLOEM, *RHOPALOSIPHUM padi, *AGRICULTURAL pests

Abstract

Aphids, including the bird cherry-oat aphid (Rhopalosiphum padi), are significant agricultural pests. The wild relative of barley, Hordeum spontaneum 5 (Hsp5), has been described to be partially resistant to R. padi , with this resistance proposed to involve higher thionin and lipoxygenase gene expression. However, the specificity of this resistance to aphids and its underlying mechanistic processes are unknown. In this study, we assessed the specificity of Hsp5 resistance to aphids and analysed differences in aphid probing and feeding behaviour on Hsp5 and a susceptible barley cultivar (Concerto). We found that partial resistance in Hsp5 to R. padi extends to two other aphid pests of grasses. Using the electrical penetration graph technique, we show that partial resistance is mediated by phloem- and mesophyll-based resistance factors that limit aphid phloem ingestion. To gain insight into plant traits responsible for partial resistance, we compared non-glandular trichome density, defence gene expression, and phloem composition of Hsp5 with those of the susceptible barley cultivar Concerto. We show that Hsp5 partial resistance involves elevated basal expression of thionin and phytohormone signalling genes, and a reduction in phloem quality. This study highlights plant traits that may contribute to broad-spectrum partial resistance to aphids in barley. [ABSTRACT FROM AUTHOR]

Published

2019

14. Genetic diversity in vector populations influences the transmission efficiency of an important plant virus.

Author

Leybourne DJ, Whitehead MA, and Will T

Subjects

Animals, Symbiosis, Aphids virology, Aphids genetics, Genetic Variation, Insect Vectors virology, Insect Vectors genetics, Plant Diseases virology, Luteovirus genetics, Luteovirus physiology

Abstract

The transmission efficiency of aphid-vectored plant viruses can differ between aphid populations. Intra-species diversity (genetic variation, endosymbionts) is a key determinant of aphid phenotype; however, the extent to which intra-species diversity contributes towards variation in virus transmission efficiency is unclear. Here, we use multiple populations of two key aphid species that vector barley yellow dwarf virus (BYDV) strain PAV (BYDV-PAV), the grain aphid ( Sitobion avenae ) and the bird cherry-oat aphid ( Rhopalosiphum padi ), and examine how diversity in vector populations influences virus transmission efficiency. We use Illumina sequencing to characterize genetic and endosymbiont variation in multiple Si. avenae and Rh. padi populations and conduct BYDV-PAV transmission experiments to identify links between intra-species diversity in the vector and virus transmission efficiency. We observe limited variation in the transmission efficiency of Si. avenae, with transmission efficiency consistently low for this species. However, for Rh. padi, we observe a range of transmission efficiencies and show that BYDV transmission efficiency is influenced by genetic diversity within the vector, identifying 542 single nucleotide polymorphisms that potentially contribute towards variable transmission efficiency in Rh. padi . Our results represent an important advancement in our understanding of the relationship between genetic diversity, vector-virus interactions, and virus transmission efficiency.

Published

2024

15. Grand challenges in entomology: Priorities for action in the coming decades.

Author

Luke SH, Roy HE, Thomas CD, Tilley LAN, Ward S, Watt A, Carnaghi M, Jaworski CC, Tercel MPTG, Woodrow C, Aown S, Banfield-Zanin JA, Barnsley SL, Berger I, Brown MJF, Bull JC, Campbell H, Carter RAB, Charalambous M, Cole LJ, Ebejer MJ, Farrow RA, Fartyal RS, Grace M, Highet F, Hill JK, Hood ASC, Kent ES, Krell FT, Leather SR, Leybourne DJ, Littlewood NA, Lyons A, Matthews G, Mc Namara L, Menéndez R, Merrett P, Mohammed S, Murchie AK, Noble M, Paiva MR, Pannell MJ, Phon CK, Port G, Powell C, Rosell S, Sconce F, Shortall CR, Slade EM, Sutherland JP, Weir JC, Williams CD, Zielonka NB, and Dicks LV

Abstract

Entomology is key to understanding terrestrial and freshwater ecosystems at a time of unprecedented anthropogenic environmental change and offers substantial untapped potential to benefit humanity in a variety of ways, from improving agricultural practices to managing vector-borne diseases and inspiring technological advances.We identified high priority challenges for entomology using an inclusive, open, and democratic four-stage prioritisation approach, conducted among the membership and affiliates (hereafter 'members') of the UK-based Royal Entomological Society (RES).A list of 710 challenges was gathered from 189 RES members. Thematic analysis was used to group suggestions, followed by an online vote to determine initial priorities, which were subsequently ranked during an online workshop involving 37 participants.The outcome was a set of 61 priority challenges within four groupings of related themes: (i) 'Fundamental Research' (themes: Taxonomy, 'Blue Skies' [defined as research ideas without immediate practical application], Methods and Techniques); (ii) 'Anthropogenic Impacts and Conservation' (themes: Anthropogenic Impacts, Conservation Options); (iii) 'Uses, Ecosystem Services and Disservices' (themes: Ecosystem Benefits, Technology and Resources [use of insects as a resource, or as inspiration], Pests); (iv) 'Collaboration, Engagement and Training' (themes: Knowledge Access, Training and Collaboration, Societal Engagement).Priority challenges encompass research questions, funding objectives, new technologies, and priorities for outreach and engagement. Examples include training taxonomists, establishing a global network of insect monitoring sites, understanding the extent of insect declines, exploring roles of cultivated insects in food supply chains, and connecting professional with amateur entomologists. Responses to different challenges could be led by amateur and professional entomologists, at all career stages.Overall, the challenges provide a diverse array of options to inspire and initiate entomological activities and reveal the potential of entomology to contribute to addressing global challenges related to human health and well-being, and environmental change., Competing Interests: Luke A. N. Tilley, Sajidha Mohammed, and Francisca Sconce are employed by the Royal Entomological Society (RES); Helen E. Roy, Chris D. Thomas, Simon Ward, Allan Watt, Lynn V. Dicks and Jane K. Hill play senior roles in the management of the RES, including as trustees, president, or former president; and the majority of co‐authors are members of the RES., (© 2023 The Authors. Insect Conservation and Diversity published by John Wiley & Sons Ltd on behalf of Royal Entomological Society.)

Published

2023

16. A fitness cost resulting from Hamiltonella defensa infection is associated with altered probing and feeding behaviour in Rhopalosiphum padi .

Author

Leybourne DJ, Valentine TA, Bos JIB, and Karley AJ

Subjects

Animals, Aphids genetics, Aphids growth & development, Feeding Behavior, Nymph genetics, Nymph growth & development, Nymph physiology, Aphids physiology, Enterobacteriaceae physiology, Genetic Fitness, Symbiosis

Abstract

Many herbivorous arthropods, including aphids, frequently associate with facultative endosymbiotic bacteria, which influence arthropod physiology and fitness. In aphids, endosymbionts can increase resistance against natural enemies, enhance aphid virulence and alter aphid fitness. Here, we used the electrical penetration graph technique to uncover physiological processes at the insect-plant interface affected by endosymbiont infection. We monitored the feeding and probing behaviour of four independent clonal lines of the cereal-feeding aphid Rhopalosiphum padi derived from the same multilocus genotype containing differential infection (+/-) with a common facultative endosymbiont, Hamiltonella defensa Aphid feeding was examined on a partially resistant wild relative of barley known to impair aphid fitness and a susceptible commercial barley cultivar. Compared with uninfected aphids, endosymbiont-infected aphids on both plant species exhibited a twofold increase in the number of plant cell punctures, a 50% reduction in the duration of each cellular puncture and a twofold higher probability of achieving sustained phloem ingestion. Feeding behaviour was also altered by host plant identity: endosymbiont-infected aphids spent less time probing plant tissue, required twice as many probes to reach the phloem and showed a 44% reduction in phloem ingestion when feeding on the wild barley relative compared with the susceptible commercial cultivar. Reduced feeding success could explain the 22% reduction in growth of H. defensa -infected aphids measured on the wild barley relative. This study provides the first demonstration of mechanisms at the aphid-plant interface contributing to physiological effects of endosymbiont infection on aphid fitness, through altered feeding processes on different quality host plants., Competing Interests: Competing interestsThe authors declare no competing or financial interests., (© 2020. Published by The Company of Biologists Ltd.)

Published

2020