Insect thermal tolerance: what is the role of ontogeny, ageing and senescence?
about
Predicting organismal vulnerability to climate warming: roles of behaviour, physiology and adaptationThermal limits of wild and laboratory strains of two African malaria vector species, Anopheles arabiensis and Anopheles funestus.Temperature variation makes ectotherms more sensitive to climate changeEdge effects reverse facilitation by a widespread foundation species.The impact of seasonality in temperature on thermal tolerance and elevational range size.Transient receptor potential is essential for high temperature tolerance in invasive Bemisia tabaci Middle East Asia minor 1 cryptic speciesIncreased survival and prolonged longevity mainly contribute to the temperature-adaptive evolutionary strategy in invasive Bemisia tabaci (Hemiptera: Aleyrodidae) Middle East Asia Minor 1.Trade-offs between survival, longevity, and reproduction, and variation of survival tolerance in Mediterranean Bemisia tabaci after temperature stress.Impact of hot events at different developmental stages of a moth: the closer to adult stage, the less reproductive output.Stage-specific heat effects: timing and duration of heat waves alter demographic rates of a global insect pest.Biologically Based Methods for Pest Management in Agriculture under Changing Climates: Challenges and Future DirectionsHeat resistance throughout ontogeny: body size constrains thermal tolerance.Local adaptation of reproductive performance during thermal stress.Effects of Thermal Regimes, Starvation and Age on Heat Tolerance of the Parthenium Beetle Zygogramma bicolorata (Coleoptera: Chrysomelidae) following Dynamic and Static Protocols.Comparative transcriptome profiling of a thermal resistant vs. sensitive silkworm strain in response to high temperature under stressful humidity condition.Environmental effects on temperature stress resistance in the tropical butterfly Bicyclus anynanaTemperature tolerance and stress proteins as mechanisms of invasive species success.Ageing and thermal performance in the sub-Antarctic wingless fly Anatalanta aptera (Diptera: Sphaeroceridae): older is betterBasal cold but not heat tolerance constrains plasticity among Drosophila species (Diptera: Drosophilidae).Reproducibility and consistency of proteomic experiments on natural populations of a non-model aquatic insectThermal limits of two biting midges, Culicoides imicola Kieffer and C. bolitinos Meiswinkel (Diptera: Ceratopogonidae).Simulated climate change conditions unveil the toxic potential of the fungicide pyrimethanil on the midge Chironomus riparius: a multigeneration experiment.Heat stress impedes development and lowers fecundity of the brown planthopper Nilaparvata lugens (Stål).Mortality, temporary sterilization, and maternal effects of sublethal heat in bed bugs.The Effects of Temperature and Diet during Development, Adulthood, and Mating on Reproduction in the Red Flour Beetle.Reduction of Optimal Thermal Range in Aging Western Cherry Fruit Flies (Diptera: Tephritidae)Costs and benefits of thermal acclimation for codling moth, Cydia pomonella (Lepidoptera: Tortricidae): implications for pest control and the sterile insect release programme.Thermal tolerance and survival responses to scenarios of experimental climatic change: changing thermal variability reduces the heat and cold tolerance in a fly.Physiological Limits along an Elevational Gradient in a Radiation of Montane Ground BeetlesDifferential tolerance capacity to unfavourable low and high temperatures between two invasive whiteflies.Age-specific variation in immune response in Drosophila melanogaster has a genetic basis.Variation in adult stress resistance does not explain vulnerability to climate change in copper butterflies.Selection and validation of reference genes for qRT-PCR analysis during biological invasions: The thermal adaptability of Bemisia tabaci MED.Comparative assessment of the thermal tolerance of spotted stemborer, Chilo partellus (Lepidoptera: Crambidae) and its larval parasitoid, Cotesia sesamiae (Hymenoptera: Braconidae).Effects of desiccation and starvation on thermal tolerance and the heat-shock response in forest ants.Molecular cloning and characterization of the first caspase in the Striped Stem Borer, Chilo suppressalis.Physiological niche and geographical range in European diving beetles (Coleoptera: Dytiscidae).Evolutionary diversification of bruchine beetles: climate-dependent traits and development associated with pest status.Carried over: Heat stress in the egg stage reduces subsequent performance in a butterfly.High summer temperatures affect the survival and reproduction of olive fruit fly (Diptera: Tephritidae).
P2860
Q28730012-ABDA8646-E233-474F-8269-0E6B4DC343FDQ30528672-12CDE03A-067E-4087-844F-74BF70B9C617Q30620539-AF733067-2918-45C2-9521-D283E1227EE1Q30829486-E2E7B201-7842-449C-B15A-0A217C3FA98BQ30852498-4E9ADCCD-35DA-4822-9C87-257DE7F32380Q30855115-E9677BE4-85FD-49F0-95F3-E69DD1D4AB1FQ30864183-45237696-AB77-406C-B18A-D3BE993F3653Q30867304-30C17770-9333-42C2-A179-C1C459BFAACCQ30956874-DCA665AD-7265-41E6-9B87-F344A7AF64C7Q30985925-C3D4F108-8B4E-428B-9F02-B13ED6BC57A2Q31004952-E817063F-08DD-4716-AD69-ECC74C6B596CQ31111945-86B76BDD-3B61-4C4D-8CDF-C1C2FFCBEBBBQ31143245-DC452D9A-780C-48AE-BAB2-071CEFF9C52DQ31152643-1CBAC396-C26D-4C2C-B109-870697AD7A97Q33703736-7536037C-49B8-46B8-A177-5355B5D33C4AQ33781140-5A9675A6-A915-4D6E-A0BF-9DC94F3B9BDCQ33889327-53AF1111-202D-4752-94BD-2C14FDA61D75Q33891402-24605F14-7CEF-4A14-92FD-61AFF15B1FB8Q33928057-AE2CC2A5-DA26-415B-96F2-9B085C2AFC18Q34061520-E635C96A-FD41-4636-8531-81AB5976E2A1Q34116355-B81AF67B-E721-4418-9668-788393F7981AQ34191391-999868FB-8866-4416-9196-689CA4B1AE14Q34448248-25A0FAFB-C5E4-438F-9D1B-1ADE20B7F899Q35634608-92052B1D-B3B4-4B35-8029-5509B71078A5Q35766914-ECC870CF-2743-468E-8B20-E3E4CD83658BQ35950660-3D994CAB-0ACE-4788-B7BE-E98401EEC5D8Q35960809-282E9757-F7DD-4E33-AD2E-9E432C9DEF34Q35966186-438660FA-EC0C-4299-97A8-3773AFB36E3DQ35979141-CA3D10BD-4194-4D83-9B21-0982668A69A8Q35990682-0F5E71D9-87D8-42C5-BE83-584754BAF449Q36076943-06D79D5E-2796-423C-AA52-6918F6AB07BEQ36308281-84DAF1A7-429C-48DD-8778-8A390ED9AE3EQ36316325-2D3E3567-B6B2-47C4-B9FF-155E8CE70432Q36333499-D09614C2-741C-41E2-B734-0F539A0CA8ABQ36355911-29771BB0-5257-4317-9E89-6DB7E9EE26C8Q36913726-3F088421-3AF6-4167-8EE0-1ADF50EFE7E5Q37078318-D38561A1-2947-4CCC-AAB0-297735C5ED24Q37829484-3AF1286C-8000-4070-A4BF-1A7B8845229AQ38369269-65EC610F-9DFF-4B55-834D-415099901D7FQ38433865-86A597EE-9EFA-4A6A-A20D-D736F661C67F
P2860
Insect thermal tolerance: what is the role of ontogeny, ageing and senescence?
description
article científic
@ca
article scientifique
@fr
articolo scientifico
@it
artigo científico
@pt
bilimsel makale
@tr
scientific article published on August 2008
@en
vedecký článok
@sk
vetenskaplig artikel
@sv
videnskabelig artikel
@da
vědecký článek
@cs
name
Insect thermal tolerance: what is the role of ontogeny, ageing and senescence?
@en
Insect thermal tolerance: what is the role of ontogeny, ageing and senescence?
@nl
type
label
Insect thermal tolerance: what is the role of ontogeny, ageing and senescence?
@en
Insect thermal tolerance: what is the role of ontogeny, ageing and senescence?
@nl
prefLabel
Insect thermal tolerance: what is the role of ontogeny, ageing and senescence?
@en
Insect thermal tolerance: what is the role of ontogeny, ageing and senescence?
@nl
P2860
P1433
P1476
Insect thermal tolerance: what is the role of ontogeny, ageing and senescence?
@en
P2093
John S Terblanche
Ken Bowler
P2860
P304
P356
10.1111/J.1469-185X.2008.00046.X
P577
2008-08-01T00:00:00Z