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Author: Sulav Paudel
Publisher:
ISBN:
Category :
Languages : en
Pages :
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Book Description
Predicting the impact of climate change is one of the leading challenges of current times. Despite the potential to substantially impact crops economically, overall impacts of elevated temperature on insect-plant interactions are poorly understood, especially in agricultural systems. The goal of this dissertation is to investigate the impact of climate warming on insect herbivores, on their host plants and the interactions between them using the case of the corn earworm on tomatoes. First, the interactive effects of elevated temperature on insect herbivory (Helicoverpa zea) and resistance/tolerance traits of tomato (Solanum lycopersicum var Better Boy) were evaluated using artificial warming. In addition to an asymmetric responses between plant and insects, novel mechanisms were identified explaining how varying temperature affected the biosynthesis of insect elicitors and the ability of insects to trigger plant defense responses; insects reared at a warmer temperatures produced significantly less glucose oxidase (GOX), which paralleled a lower level of induction of plant defensive proteins, polyphenol oxidase (PPO) and trypsin protease inhibitors (TPI). Similarly, induction of plant defenses and plant resistance to the insect herbivore was highest in plants grown at above optimum temperatures but varied between damaged and undamaged leaves; herbivore growth was significantly reduced when fed on damaged leaves compared to undamaged control. These findings add an exciting new dimension to how climate change may alter plant-insect interactions. Second, using elevation as a proxy for temperature change, a field study in Nepal and greenhouse experiments at Penn State on tomato accessions from the Andes were tested to evaluate changes to plant herbivore interactions approximating the impacts of climate warming. The field study was conducted at various elevations in the Himalayan Mountains of Nepal in farmers fields to simulate climate change. Temperature varied with elevation in the field and significantly affected both insect populations and plant damage. At higher elevation, natural herbivore populations and plant damage from herbivory were significantly increased compared to low-elevation counterparts. In greenhouse experiments, changes in plant defense strategies and resistance to insect herbivory along an elevational gradient was also established by using tomato accessions adapted to a specific elevation range in South America. Plant resistance and defensive chemicals (e.g.,total phenolics content) to insect herbivory was enhanced in accessions from higher elevation. Results from both field and greenhouse experiments indicated a great deal of plasticity and variability in plant defense responses to both biotic and abiotic stresses. Last, the variation in induced plant defensive traits and strategies between wild and cultivated tomato genotypes was also investigated. Three different tomato genotypes were used; Solanum pimpinellifolium L. (accession LA 2093), b) cherry tomato, S. lycopersicum L. var. cerasiforme (accession Matts Wild Cherry), and c) cultivated tomato, S. lycopersicum L. var. Better Boy). Multiple chemical (plant volatiles, phenolics, defense proteins) and physical defenses (trichomes) in the cultivated tomato and its closest progenitors were measured. As expected, the wild species of tomato show higher levels of constitutive defenses, but the novel finding is that the cultivated tomato demonstrated the highest level of induced defenses (Paudel et al., 2019). While crop losses are expected to increase with global warming, elevated temperatures in this study produced asymmetric responses between insects and plants, indicating a more complicated response of plants and their herbivores under a climate change scenario. A plasticity in plant defense mechanisms were observed in the elevational studies which may possibly determine the amount of plant damages with expected geographical shift of insect pests towards higher elevations. Similarly, a large variation in plant defense mechanisms were demonstrated between wild and domesticated tomato genotypes which could be exploited as a component of sustainable crop protection in the face of climate change. Moving forward, we cannot assume that all of these crop-pest relationships will change in the same way due to climate warming. Therefore, future studies should include a wide range of host plants, insect herbivores (using both individual plant/herbivore pairs and groupings) and tri-trophic interactions complemented by field studies to provide more realistic assessments.
Author: Sulav Paudel
Publisher:
ISBN:
Category :
Languages : en
Pages :
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Book Description
Predicting the impact of climate change is one of the leading challenges of current times. Despite the potential to substantially impact crops economically, overall impacts of elevated temperature on insect-plant interactions are poorly understood, especially in agricultural systems. The goal of this dissertation is to investigate the impact of climate warming on insect herbivores, on their host plants and the interactions between them using the case of the corn earworm on tomatoes. First, the interactive effects of elevated temperature on insect herbivory (Helicoverpa zea) and resistance/tolerance traits of tomato (Solanum lycopersicum var Better Boy) were evaluated using artificial warming. In addition to an asymmetric responses between plant and insects, novel mechanisms were identified explaining how varying temperature affected the biosynthesis of insect elicitors and the ability of insects to trigger plant defense responses; insects reared at a warmer temperatures produced significantly less glucose oxidase (GOX), which paralleled a lower level of induction of plant defensive proteins, polyphenol oxidase (PPO) and trypsin protease inhibitors (TPI). Similarly, induction of plant defenses and plant resistance to the insect herbivore was highest in plants grown at above optimum temperatures but varied between damaged and undamaged leaves; herbivore growth was significantly reduced when fed on damaged leaves compared to undamaged control. These findings add an exciting new dimension to how climate change may alter plant-insect interactions. Second, using elevation as a proxy for temperature change, a field study in Nepal and greenhouse experiments at Penn State on tomato accessions from the Andes were tested to evaluate changes to plant herbivore interactions approximating the impacts of climate warming. The field study was conducted at various elevations in the Himalayan Mountains of Nepal in farmers fields to simulate climate change. Temperature varied with elevation in the field and significantly affected both insect populations and plant damage. At higher elevation, natural herbivore populations and plant damage from herbivory were significantly increased compared to low-elevation counterparts. In greenhouse experiments, changes in plant defense strategies and resistance to insect herbivory along an elevational gradient was also established by using tomato accessions adapted to a specific elevation range in South America. Plant resistance and defensive chemicals (e.g.,total phenolics content) to insect herbivory was enhanced in accessions from higher elevation. Results from both field and greenhouse experiments indicated a great deal of plasticity and variability in plant defense responses to both biotic and abiotic stresses. Last, the variation in induced plant defensive traits and strategies between wild and cultivated tomato genotypes was also investigated. Three different tomato genotypes were used; Solanum pimpinellifolium L. (accession LA 2093), b) cherry tomato, S. lycopersicum L. var. cerasiforme (accession Matts Wild Cherry), and c) cultivated tomato, S. lycopersicum L. var. Better Boy). Multiple chemical (plant volatiles, phenolics, defense proteins) and physical defenses (trichomes) in the cultivated tomato and its closest progenitors were measured. As expected, the wild species of tomato show higher levels of constitutive defenses, but the novel finding is that the cultivated tomato demonstrated the highest level of induced defenses (Paudel et al., 2019). While crop losses are expected to increase with global warming, elevated temperatures in this study produced asymmetric responses between insects and plants, indicating a more complicated response of plants and their herbivores under a climate change scenario. A plasticity in plant defense mechanisms were observed in the elevational studies which may possibly determine the amount of plant damages with expected geographical shift of insect pests towards higher elevations. Similarly, a large variation in plant defense mechanisms were demonstrated between wild and domesticated tomato genotypes which could be exploited as a component of sustainable crop protection in the face of climate change. Moving forward, we cannot assume that all of these crop-pest relationships will change in the same way due to climate warming. Therefore, future studies should include a wide range of host plants, insect herbivores (using both individual plant/herbivore pairs and groupings) and tri-trophic interactions complemented by field studies to provide more realistic assessments.
Author: M.S. Sai Reddy
Publisher:
ISBN:
Category : Electronic books
Languages : en
Pages : 0
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Book Description
The most dynamic and global environmental issue to date is climate change. The consequences of greenhouse effect and climate change from rising temperatures, frequent droughts, irregular rainfall, etc. are already evident. Insects and plants are affected by climate change and extreme weather events and the direct impact of anthropogenic climate change has been reported on every continent, in every ocean and in most major taxonomic groups. In the modern period, as a result of natural cycles and anthropogenic activities and their effects on the global climate, plants are typically susceptible to new environmental factors, i.e. higher levels solar radiation, rise in temperatures, greenhouse effect and changes in rainfall patterns over the seasons. Increased temperatures, CO2 and rapid changes in rainfall patterns can dramatically alter the biochemistry of plants and thus plant defence responses. This can have important implications in insect fertility, feeding rates, survival, population size, and dispersal. The relationships between plants and insects are thus changed with significant consequences for food security and natural ecosystems. Similarly, mismatches between plants and insect pollinators are caused by the acceleration of plant phenology by warming. Human nutrition which depends on insect pollination can be affected with reduction in plant reproduction and fitness. Thus, understanding abiotic stress reactions in plants and insects is relevant and challenging in agriculture. In the preparation and implementation of effective strategies for future insect pest management programmes, the impact of climate change on crop production, mediated by changes in the populations of extreme insect pests should be carefully considered.
Author: Habib Ali
Publisher: CRC Press
ISBN: 1003818285
Category : Science
Languages : en
Pages : 403
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Book Description
Key points - 1 Reviews the effects of climate change on plant-insect interactions 2 Includes topics such insect biodiversity informatics and conservation 3 Discusses food security, pest management, and beneficial and social insects 4 Covers topics like precision agriculture and climate-smart agriculture 5 Provides insights on the relation between agriculture intensification and insect biodiversity
Author: Daniel González-Tokman
Publisher: Oxford University Press
ISBN: 0192864165
Category : Nature
Languages : en
Pages : 401
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Book Description
An advanced textbook that reviews the conceptual approaches and the most important advances in our current understanding of insect physiology, ecology, evolution and conservation, in the ongoing and rapidly developing context of global anthropogenic climate change.
Author: Dr. Rashmi Sharma
Publisher: Shineeks Publishers
ISBN:
Category : Education
Languages : en
Pages : 68
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Book Description
Insects and Climate Change: Adapting to a Warming World explores the profound impact of climate change on insects and their remarkable ability to adapt. This book delves into the strategies employed by insects as they navigate rising temperatures, altered rainfall patterns, and shifting environments. Through scientific insights and captivating narratives, readers gain a deeper understanding of the resilience and adaptability of these crucial creatures. Insects serve as indicators of broader ecological patterns, highlighting the urgent need to address climate change. This book serves as a call to action, urging us to recognize the value of insects and take steps to protect their habitats. Join this exploration of insect resilience and their vital role in a warming world.
Author: Pedro Barbosa
Publisher: John Wiley & Sons
ISBN: 9780471832768
Category : Technology & Engineering
Languages : en
Pages : 388
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Book Description
Presents the first efforts to explore ecological interactions between insects and plants across several trophic levels, with special focus on mediation of complex interactions by plant allelochemicals. First section looks at effects of plant allelochemicals on predator-prey and host-parasitoid interactions. Second section reveals the role of microorganisms as mediators of interactions between insects and plants. Third section unifies and extends current theory to examine the effects of allelochemicals on the second and third trophic levels. Final section traces the physiological effects of plant allelochemicals in animal behavior, population regulation, maintenance of mimicry systems, and evolution of host range.
Author: J.R Miller (ed)
Publisher:
ISBN: 9781071600603
Category :
Languages : en
Pages : 342
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Book Description
Author: Elizabeth A. Bernays
Publisher: CRC Press
ISBN: 1351361287
Category : Science
Languages : en
Pages : 349
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Book Description
Volume 5 of "Insect-Plant Interactions" is a volume in a series that presents research in the field. Topics covered include chemical changes in plants as a result of insects feeding on their leaves, dynamic elements of the use and avoidance of host plants by tephritid flies as a result of the presence of other flies, floral volatiles in insect biology, endophytic fungi as mediators of plant insect interactions, the cost of chemical defence against herbivory, and life history traits on insect herbivores in relation to host quality. The book also presents the first available review on physicochemical conditions of the gut lumen from an ecological perspective.
Author:
Publisher: Academic Press
ISBN: 012803324X
Category : Science
Languages : en
Pages : 424
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Book Description
Insect-Plant Interactions, the latest edition in the Advances in Botanical Research series, which publishes in-depth and up-to-date reviews on a wide range of topics in the plant sciences, features several reviews by recognized experts on all aspects of plant genetics, biochemistry, cell biology, molecular biology, physiology, and ecology. Publishes in-depth and up-to-date reviews on a wide range of topics in plant sciences Presents the latest information on artificial photosynthesis Features a wide range of reviews by recognized experts on all aspects of plant genetics, biochemistry, cell biology, molecular biology, physiology, and ecology
Author: Christer Bjorkman
Publisher: CABI
ISBN: 1780643780
Category : Science
Languages : en
Pages : 293
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Book Description
Insects, being poikilothermic, are among the organisms that are most likely to respond to changes in climate, particularly increased temperatures. Range expansions into new areas, further north and to higher elevations, are already well documented, as are physiological and phenological responses. It is anticipated that the damage by insects will increase as a consequence of climate change, i.e. increasing temperatures primarily. However, the evidence in support of this common “belief” is sparse. Climate Change and Insect Pests sums up present knowledge regarding both agricultural and forest insect pests and climate change in order to identify future research directions.
