Effects of Temperature on Physiology and Reproductive Success of a Montane Leaf Beetle: Implications for Persistence of Native Populations Enduring Climate Change

Effects of Temperature on Physiology and Reproductive Success of a Montane Leaf Beetle: Implications for Persistence of Native Populations Enduring Climate Change

Understanding how climate change impacts natural systems requires investigations of the effects of environmental variation on vulnerable species and documentation of how populations respond to change. The willow beetleChrysomela aeneicollisis ideal for such studies. It lives in California’s Sierra N...

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Bibliographic Details
Published in:Physiological and biochemical zoology Vol. 81; no. 6; pp. 718 - 732
Main Authors: Dahlhoff, Elizabeth P., Fearnley, Shannon L., Bruce, Douglas A., Gibbs, Allen G., Stoneking, Robin, McMillan, David M., Deiner, Kristy, Smiley, John T., Rank, Nathan E.
Format: Journal Article
Language:English
Published: United States The University of Chicago Press 01-11-2008
Subjects:
Alleles
Animals
Beetles
Chrysomela aeneicollis
Chrysomelidae
Climate change
Coleoptera - genetics
Coleoptera - physiology
Demography
Ecosystem
Fecundity
Female
Female animals
Gene Expression Regulation - physiology
Gene frequency
Genotypes
Greenhouse Effect
HSP70 Heat-Shock Proteins - metabolism
Male
Metabolism
Population dynamics
Population genetics
Reproduction - physiology
Temperature
Canada, British Columbia, Rock Creek
USA, California
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Summary:Understanding how climate change impacts natural systems requires investigations of the effects of environmental variation on vulnerable species and documentation of how populations respond to change. The willow beetleChrysomela aeneicollisis ideal for such studies. It lives in California’s Sierra Nevada on the southern edge of its worldwide range. Beetles experience elevated air temperatures during summertime egg laying and larval development. Exposure to these temperatures causes physiological stress, which may reduce reproductive success and endanger populations. The glycolytic enzyme phosphoglucose isomerase (PGI) is a marker of temperature adaptation inC. aeneicollis. PGI allele frequency varies across a latitudinal gradient: allele 1 is common in Rock Creek (RC), which is cooler and to the north, and allele 4 is common in Big Pine Creek (BPC), which is warmer and to the south. In populations that are intermediate in geography and climate (e.g., Bishop Creek [BC]), PGI‐4 frequency increases from north to south such that alleles 1 and 4 are in relatively equal frequency in southern BC. Over the past decade, Sierra Nevada beetle populations have colonized high elevations and have become extinct at lower elevations where they were once common. In BC, the magnitude of PGI allele frequency fluctuations among life‐history stages is related to maximal air temperature, with the frequency of PGI‐4 increasing after the hottest part of summer. To identify mechanisms that may cause shifts in PGI allele frequency, we measured metabolic rate and fecundity for beetles collected at BC. Metabolic rate of males and females was measured at 20° and 36°C using flow‐through respirometry. To measure laboratory fecundity, mating pairs were acclimated for 4 h each afternoon at a control temperature (20°C) or at mildly elevated temperatures (26° or 32°C) and number of eggs laid was counted daily for 24 d, after which tissue levels of 70‐kD heat shock proteins (Hsp70) were determined. Previous studies had demonstrated differences in Hsp70 expression among PGI genotypes at these temperatures. To measure field fecundity, mating pairs from BC were transplanted to similar elevations in BPC, BC, and RC and were monitored in situ for 24 d. Metabolic rate was higher for PGI 4‐4 genotypes than for PGI 1‐4 or PGI 1‐1 individuals at 36°C but not at 20°C. In contrast, laboratory fecundity was greatest for females possessing PGI‐1, independent of acclimation temperature. At the end of the laboratory fecundity experiment, Hsp70 expression was positively related to fecundity, suggesting minimal reproductive cost of upregulation of heat shock proteins in response to mild heat stress. In the field, fecundity was highest for PGI 1‐1 and PGI 1‐4 individuals in RC and PGI 4‐4 individuals in BPC and was similar for all genotypes in BC. Thus, fecundity in nature was greatest for the genotypes that were most common in each area. Taken together, data reported here suggest that hot, dry summers in the Sierra Nevada may result in an increase in frequency of the PGI‐4 allele and shifts to higher elevations forC. aeneicollispopulations.
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ISSN:1522-2152
1537-5293
DOI:10.1086/590165