Abraham Addo‐Bediako scite author profile

The greater latitudinal extents of occurrence of species towards higher latitudes has been attributed to the broadening of physiological tolerances with latitude as a result of increases in climatic variation. While there is some support for such patterns in climate, the physiological tolerances of species across large latitudinal gradients have seldom been assessed. Here we report findings for insects based on published upper and lower lethal temperature data. The upper thermal limits show little geographical variation. In contrast, the lower bounds of supercooling points and lower lethal temperatures do indeed decline with latitude. However, this is not the case for the upper bounds, leading to an increase in the variation in lower lethal limits with latitude. These results provide some support for the physiological tolerance assumption associated with Rapoport's rule, but highlight the need for coupled data on species tolerances and range size.

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Metabolic cold adaptation in insects: a large‐scale perspective

Addo‐Bediako

2002

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Summary1. Despite its significance from both life-history and physiological perspectives, metabolic cold adaptation (MCA) in insects remains controversial. Although several smallscale studies have provided support for such adaptation, many others have not. 2. Using a global-scale analysis of the standard metabolic rates of 346 species, it is shown that after removing the effects of trial temperature and body mass, environmental temperature significantly influences interspecific variation in metabolic rate, such that insects from colder environments tend to have higher, whole-organism, metabolic rates. Although this effect is weak, it does provide evidence in favour of MCA in this important terrestrial group. 3. Although data from the Southern Hemisphere are limited, we show that this adaptation also takes the form of an increase in the slope of the metabolic rate-temperature relationship in Northern, but not in Southern, Hemisphere species. 4. Metabolic cold adaptation and its variation among the hemispheres should be counted among the causes of interspecific variation in metabolic rate.

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Climatic variability and the evolution of insect freeze tolerance

Addo‐Bediako²,

2003

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Insects may survive subzero temperatures by two general strategies: Freeze-tolerant insects withstand the formation of internal ice, while freeze-avoiding insects die upon freezing. While it is widely recognized that these represent alternative strategies to survive low temperatures, and mechanistic understanding of the physical and molecular process of cold tolerance are becoming well elucidated, the reasons why one strategy or the other is adopted remain unclear. Freeze avoidance is clearly basal within the arthropod lineages, and it seems that freeze tolerance has evolved convergently at least six times among the insects (in the Blattaria, Orthoptera, Coleoptera, Hymenoptera, Diptera and Lepidoptera). Of the pterygote insect species whose cold-tolerance strategy has been reported in the literature, 29% (69 of 241 species studied) of those in the Northern Hemisphere, whereas 85 % (11 of 13 species) in the Southern Hemisphere exhibit freeze tolerance. A randomization test indicates that this predominance of freeze tolerance in the Southern Hemisphere is too great to be due to chance, and there is no evidence of a recent publication bias in favour of new reports of freeze-tolerant species. We conclude from this that the specific nature of cold insect habitats in the Southern Hemisphere, which are characterized by oceanic influence and climate variability must lead to strong selection in favour of freeze tolerance in this hemisphere. We envisage two main scenarios where it would prove advantageous for insects to be freeze tolerant. In the first, characteristic of cold continental habitats of the Northern Hemisphere, freeze tolerance allows insects to survive very low temperatures for long periods of time, and to avoid desiccation. These responses tend to be strongly seasonal, and insects in these habitats are only freeze tolerant for the overwintering period. By contrast, in mild and unpredictable environments, characteristic of habitats influenced by the Southern Ocean, freeze tolerance allows insects which habitually have ice nucleators in their guts to survive summer cold snaps, and to take advantage of mild winter periods without the need for extensive seasonal cold hardening. Thus, we conclude that the climates of the two hemispheres have led to the parallel evolution of freeze tolerance for very different reasons, and that this hemispheric difference is symptomatic of many wide-scale disparities in Northern and Southern ecological processes.

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Revisiting water loss in insects: a large scale view

Addo‐Bediako

Chown

Gaston

2001

Journal of Insect Physiology

159

144

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Physiological variation in insects: large-scale patterns and their implications

Chown

Addo‐Bediako

Gaston

2002

Comparative Biochemistry and Physiology Part B: Biochemistry an

133

116

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