Tsetse population dynamics.

Hargrove, John W.; Maudlin, I.; Holmes, Peter; Miles, Micah

doi:10.1079/9780851994758.0113

Cited by 85 publications

(188 citation statements)

References 63 publications

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“…Why metabolic rate should increase following exposure to a relatively low temperature in tsetse adults is not clear, but might contribute to the absence of this species (and G. morsitans) from low temperature areas. Elevated metabolic rates will result in increased use of lipid reserves, lower tolerance of starvation, and increased pressure for foraging, all of which are likely to enhance the chances of mortality (Rajagopal and Bursell, 1966), likely limiting the ability of the flies to survive in low temperature environments (though a lack of pupal development is also important for restricting flies to warmer areas; for reviews, see Hargrove, 2004;Rogers and Robinson, 2004).…”

Section: Discussionmentioning

confidence: 99%

“…Therefore, investigations of non-lepidopteran species are likely to provide a rapid way of determining how general previous findings are likely to be. Second, temperature and water availability are important correlates of the distribution of G. pallidipes and play major roles in influencing its population dynamics directly (Hargrove, 2004;Rogers and Robinson, 2004) and indirectly via metabolic rate (Bursell et al, 1974;Bursell and Taylor, 1980;Terblanche et al, 2004). Investigating the mechanistic bases of the responses of flies to their external environment is therefore a significant link in the causal chain of reasoning from environment to population dynamics.…”

Section: Introductionmentioning

confidence: 99%

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The relative contributions of developmental plasticity and adult acclimation to physiological variation in the tsetse fly, Glossina pallidipes (Diptera, Glossinidae)

Terblanche¹,

Chown²

2007

Comparative Biochemistry and Physiology Part A: Molecular &

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Recent reviews of the adaptive hypotheses for animal responses to acclimation have highlighted the importance of distinguishing between developmental and adult (nondevelopmental) phenotypic plasticity. There has been little work, however, on separating the effects of developmental plasticity from adult acclimation on physiological traits. Therefore, we investigated the relative contributions of these two distinct forms of plasticity to the environmental physiology of adult tsetse flies by exposing developing pupae or adult flies to different temperatures and comparing their responses. We also exposed flies to different temperatures during development and reexposed them as adults to the same temperatures, to investigate possible cumulative effects. Critical thermal maxima were relatively inflexible in response to acclimation temperatures (21, 25, 29°C) with plasticity type accounting for the majority of the variation (49-67%, nested ANOVA). By contrast, acclimation had a larger effect on critical thermal minima with treatment temperature accounting for most of the variance (84-92%). Surprisingly little of the variance in desiccation rate could be explained by plasticity type (30-47%). The only significant effect of acclimation temperature on standard (resting) metabolic rate of adult flies was at 21°C, resulting in treatment temperature, rather than plasticity type, accounting for the majority of the variance (30-76%). This study demonstrates that the stage at which acclimation takes place has significant, though often different, effects on several adult physiological traits in G. pallidipes, and therefore that it is not only important to consider the form of plasticity but also the direction of the response and its significance from a life-history perspective.

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Section: Discussionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

The relative contributions of developmental plasticity and adult acclimation to physiological variation in the tsetse fly, Glossina pallidipes (Diptera, Glossinidae)

Terblanche¹,

Chown²

2007

Comparative Biochemistry and Physiology Part A: Molecular &

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“…For example, Helmuth et al (2002) have shown that in Pacific intertidal mussels Mytilus californianus, tidal regime, wave height and local climate interact such that sites which might otherwise have been considered relatively temperate are associated with greater thermal stresses than apparently much warmer sites. In tsetse, Glossina morsitans and Glossina pallidipes, population dynamic investigations have demonstrated that high temperatures substantially increase daily instantaneous mortality rates (Hargrove 2004). Recent macrophysiological work has shown that a combination of direct high-temperature effects on survival and indirect effects via an increase in foraging-associated risk precipitated by elevated resting metabolic costs at high (but sub-lethal) temperatures are probably the source of the change in mortality rates .…”

Section: Climate Changementioning

confidence: 99%

Macrophysiology for a changing world

2008

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The Millennium Ecosystem Assessment (MA) has identified climate change, habitat destruction, invasive species, overexploitation and pollution as the major drivers of biodiversity loss and sources of concern for human well-being. Understanding how these drivers operate and interact and how they might be mitigated are among the most pressing questions facing humanity. Here, we show how macrophysiology-the investigation of variation in physiological traits over large geographical, temporal and phylogenetic scalescan contribute significantly to answering these questions. We do so by demonstrating, for each of the MA drivers, how a macrophysiological approach can or has helped elucidate the impacts of these drivers and their interactions. Moreover, we illustrate that a large-scale physiological perspective can provide insights into previously unrecognized threats to diversity, such as the erosion of physiological variation and stress tolerance, which are a consequence of the removal of large species and individuals from the biosphere. In so doing we demonstrate that environmental physiologists have much to offer the scientific quest to resolve major environmental problems.

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“…Although several factors may affect the range of vector-borne diseases in the short term, climate change is expected to heavily modify the suitable range of some parasitic diseases such as malaria, bluetongue, and trypanosomosis (Woolhouse 2006, Thornton 2010, Van Dijk et al 2010). Climate change is therefore a key cause in our case study (Table 1) because of the strong effect temperature has on the reproductive success and distribution of tsetse flies and the Trypanosoma parasites (Hargrove 2004, Moore et al 2012. Tsetse pupal development periods decrease with increasing temperatures, and larval production ceases altogether above a certain temperature threshold (Hargrove 2004).…”

Section: Causesmentioning

confidence: 99%

“…These unique conditions therefore create a telecoupled system among international importers and exporters of livestock products. However, because of a changing climate, temperatures are expected to rise to levels that are harmful to tsetse reproduction and survival as well as pathogen development (Hargrove 2004, Moore et al 2012. Recent work has shown that increasing temperatures during the next few decades will substantially reduce the geographic range of one species of the trypanosome parasite in Mozambique ( Fig.…”

Section: Cattle and Trypanosomamentioning

confidence: 99%

Climate change, cattle, and the challenge of sustainability in a telecoupled system in Africa

Easter¹,

Killion²,

Carter³

2018

E&S

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ABSTRACT. Information, energy, and materials are flowing over greater distances than in the past, changing the structure and feedbacks within and across coupled human and natural systems worldwide. The telecoupling framework was recently developed to understand the feedbacks and multidirectional flows characterizing social and environmental interactions between distant systems. We extend the application of the telecoupling framework to illustrate how flows in beef affect and are affected by social-ecological processes occurring between distant systems in Africa, and how those dynamics will likely change over the next few decades because of climate-induced shifts in a major bovine disease, trypanosomosis. The disease is currently wide-spread in Africa, affecting millions of cattle every year and resulting in massive economic losses. Increasing temperatures are predicted to substantially reduce the geographic range of the cattle disease by 2050 in regions of Africa, thereby potentially releasing cattle from disease control in those areas. Despite the societal and economic benefits, greater cattle production can also lead to significant environmental degradation. Our investigation takes a qualitative, yet systematic, approach to explore how changes in the regional distribution of cattle production, caused by shifts in the bovine disease, will affect the social and ecological conditions of the telecoupled system in the future. Doing so lays the groundwork to quantify telecouplings and improve decision making under uncertainty in the future.

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Tsetse population dynamics.

Cited by 85 publications

References 63 publications

The relative contributions of developmental plasticity and adult acclimation to physiological variation in the tsetse fly, Glossina pallidipes (Diptera, Glossinidae)

The relative contributions of developmental plasticity and adult acclimation to physiological variation in the tsetse fly, Glossina pallidipes (Diptera, Glossinidae)

Macrophysiology for a changing world

Climate change, cattle, and the challenge of sustainability in a telecoupled system in Africa

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