J. B. Whittaker scite author profile

This review examines the direct effects of climate change on insect herbivores. Temperature is identified as the dominant abiotic factor directly affecting herbivorous insects. There is little evidence of any direct effects of CO2 or UVB. Direct impacts of precipitation have been largely neglected in current research on climate change. Temperature directly affects development, survival, range and abundance. Species with a large geographical range will tend to be less affected. The main effect of temperature in temperate regions is to influence winter survival; at more northerly latitudes, higher temperatures extend the summer season, increasing the available thermal budget for growth and reproduction. Photoperiod is the dominant cue for the seasonal synchrony of temperate insects, but their thermal requirements may differ at different times of year. Interactions between photoperiod and temperature determine phenology; the two factors do not necessarily operate in tandem. Insect herbivores show a number of distinct life‐history strategies to exploit plants with different growth forms and strategies, which will be differentially affected by climate warming. There are still many challenges facing biologists in predicting and monitoring the impacts of climate change. Future research needs to consider insect herbivore phenotypic and genotypic flexibility, their responses to global change parameters operating in concert, and awareness that some patterns may only become apparent in the longer term.

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Metabolic and faunal activity in litters of tree mixtures compared with pure stands

Chapman¹,

Whittaker

Heal³

1988

Agriculture, Ecosystems & Environment

193

126

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Direct and indirect effects of climate change on insect herbivores: Auchenorrhyncha (Homoptera)

Masters

Brown

Clarke

et al. 1998

Ecological Entomology

133

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1. Novel manipulations of local climate were employed to investigate how warmer winters with either wetter or drier summers would affect the Auchenorrhyncha, a major component of the insect fauna of grasslands. Direct and indirect effects of climate manipulation were found. 2. Supplemented summer rainfall resulted in an increase in vegetation cover, leading to an increase in the abundance of the Auchenorrhyncha. 3. Summer drought, however, caused a decrease in vegetation cover, but this did not lead to a corresponding decrease in the abundance of the Auchenorrhyncha. 4. Egg hatch and the termination of nymphal hibernation occurred earlier in winter warmed plots; however, the rate of nymphal development was unaffected.

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Predicting responses to climate change: the effect of altitude and latitude on the phenology of the Spittlebug Neophilaenus lineatus

Fielding¹,

Whittaker²,

Butterfield³

et al. 1999

Functional Ecology

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1. The phenology of Neophilaenus lineatus (Homoptera: Cercopidae) was studied along altitudinal and latitudinal transects in the UK. The response of the life cycle to these existing temperature gradients has been used to predict the likely effects of future climatic warming. 2. The date of spring egg hatch varied by a maximum of 4 weeks across the altitudinal gradient (440 m) and by 2 weeks in different years of the study. Autumn and winter temperatures do not determine hatching date because the eggs are in diapause during this period. It is only when the eggs terminate diapause in early spring that temperature differences between years and altitudes (or as a result of climatic warming) start to affect the date of egg hatch. 3. The delayed egg hatching with increasing altitude meant that the start of nymphal development was later at higher altitudes. The development rate of nymphs at higher altitudes was not significantly different from that at lower altitudes because the altitudinal lag in temperature was partially compensated for by the more advanced state of the season. Annual differences in spring and summer temperatures resulted in variations in nymphal development rate between years, with a 1 °C temperature rise shortening nymphal development by 3·5 days. 4. The appearance of adults was delayed by 5·6 days for every 100 m increase in altitude, largely as a consequence of the later egg hatch at higher altitudes. The later appearance of the adults at higher altitudes and in colder years, reduces the length of the potential oviposition period as females are killed by autumn frosts. Climatic warming would expand the length of the oviposition period and thus increase the upper altitude limits of N. lineatus. 5. A 4·5 ° latitude difference within the UK appeared to have little effect on the timing of development in N. lineatus, possibly as a result of a geographical cline in temperature or photoperiod response. 6. Annual insects, such as N. lineatus, are likely to show a relatively small geographical displacement as a consequence of climatic warming. This is because of the temperature mitigating responses of diapause and the relative stability of the length of the development period over wide altitudinal and latitudinal ranges.

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J. B. Whittaker

Herbivory in global climate change research: direct effects of rising temperature on insect herbivores

Metabolic and faunal activity in litters of tree mixtures compared with pure stands

Direct and indirect effects of climate change on insect herbivores: Auchenorrhyncha (Homoptera)

Predicting responses to climate change: the effect of altitude and latitude on the phenology of the Spittlebug Neophilaenus lineatus

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