Abstract
A manipulation experiment was carried out on a field population of the aphid Acyrthosiphon svalbardicum near Ny Ålesund, on the high arctic island of Spitsbergen, using cloches to raise temperature. An average rise in temperature of 2.8 deg. C over the summer season markedly advanced the phenology of both the host plant Dryas octopetala and the aphid. Advanced aphid phenology, with concomitant increases in reproductive output and survival, and successful completion of the life-cycle led to an eleven-fold increase in the number of overwintering eggs. Thermal budget requirements in day degrees above 0°C were calculated for key life-cycle stages of the aphid. Temperature data from Ny Ålesund over the past 23 years were used to calculate thermal budgets for the field site over the same period and these were compared with the requirements of the aphid. Each estimated thermal budget was then adjusted to simulate the effect of a +2, +4, and −2deg. C change in average temperature on aphid performance. This retrospective analysis (i) confirms that the life-cycle of A. svalbardicum is well suited to exploit higher summer temperatures, (ii) indicates that the annual success of local populations are sensitive to small changes in temperature and (iii) suggests that the aphid is living at the limits of its thermal range at Ny Ålesund based on its summer thermal budget requirements.
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References
Acreman SJ, Dixon AFG (1989) The effects of temperature and host quality on the rate of increase of the grain aphid (Sitobian avenae) on wheat. Ann Appl Biol 115:3–9
Barlow CA (1962) The influence of temperaure on the growth of experimental populations of Myzus persicae (Sulzer) and Macrosiphon euphorbiea (Thomas). Can J Zool 40:145–438
Bazzaz FA (1990) The response of natural ecosystems to the rising global CO2 levels. Annu Rev Ecol Syst 21:167–196
Billings WD, Mooney HA (1968) The ecology of arctic and alpine plants. Biol Rev 43:481–529
Bolin B, Doos BR, Jager J, Warrick R (1986) The Greenhouse Effect, Climate Change and Ecosystems. Wiley, London and New York
Campbell A, Frazer BD, Gilbert N, Gutierrez AP, Mackauer M (1974) Temperature requirements of some aphids and their parasites. J Appl Ecol 11:431–438
Chapin FS III, Shaver GR (1985) Individualistic growth response of tundra plants to environmental manipulations in the field. Ecology 66:564–576
Coulson S, Hodkinson ID, Strathdee A, Bale JS, Block W, Worland MR, Webb NR (1993) Simulated climate change: the interaction between vegetation type and microhabitat temperature at Ny Ålesund, Svalbard. Polar Biol 13:67–70
Eamus D, Jarvis PG (1989) The direct effects of increase in global atmpspheric CO2 concentrations on natural and commercial temperate trees and forests. Advances in Ecological Research 19:1–57
Fajer ED (1989) The effects of enriched CO2 atmospheres on plantinsect herbivore interactions: growth responses of larvae of the specialist butterfly, Junonia coenia (Lepidoptera: Nymphalidae) Oecologia 81:514–520
Fajer ED, Bowers MD, Bazzaz FA (1989) The effects of enriched carbon dioxide atmospheres on plant-insect herbivore interactions. Science 243:1198–1200
Harrewijn P (1970) Reproduction of the aphid Myzus persicae related to the mineral nutrition of potato plants. Ent Exp Appl 13:307–319
Havström M, Callaghan TV, Jonasson S (1993) Differential growth responses of Cassiope tetragona, an arctic dwarf shurb, to environmental perturbations among three contrasting high-and subarctic sites. Oikos 66:389–402
Larcher W (1980) Klimastress im Gebirge-Adaptationstraining und Selektionsfilter fur Pflanzen. Vortr Reinisch-Westf Akad Wiss 291:49–88
Maltais JB (1959) Feeding the pea aphid Acyrthosiphon pisum (Harr.) (Homoptera: Aphididae) on plant cuttings in organic nutrient solutions. Can Entomol 91:336–340
Maxwell B (1992) Arctic climate: potential for change under global warming. In: Chapin III FS, Jefferies RL, Reynolds JF, Shaver GR, Svoboda J (eds) Arctic Ecosystems in a Changing Climate Academic Press, Inc., San Diego pp 11–34
Meehl GA, Washington WM (1990) CO2 climate sensitivity and snow-sea-ice albedo parametization. Climate Change 15:284–307
Messenger PS (1964) The influence of rhythmically fluctuating temperatures on the development and reproduction of the spotted alfalfa aphid, Therioaphis maculata. J Econ Entomol 57:71–76
Michels GJ and Behle RW (1989). Influence of temperature on reproduction, development and intrinsic rate of increase of russian wheat aphid, greenbug, and bird cherry-oat aphid (Homoptera: Aphididae) J Econ Entomol 82:439–444
Mitchell JFB, Manabe S, Meleshko V, Tokioka T (1990) Equilibrium climate change-and its implications for the future. In: Houghton JT, Jenkins GJ, Ephraums JJ (eds) Climate Change, the IPCC Scientific Assessment Cambridge University Press. pp 283–310
Parkinson JA, Allen SE (1975) A wet oxidation procedure for the determination of nitrogen and mineral nutrient in biological material. Commun Soil Sci Plant Anal 6:1–11
Sakai A, Larcher W (1987) Frost Survival of Plants. In: Sakai A, Larcher W (eds) Springer Berlin Heidelberg New York pp
Sakai A, Otsuka K (1970) Freezing resistance in alpine plants. Ecology 51:665–675
Shaver GR, Kummerow J (1992) Phenology, resource allocation, and growth of the arctic vascular plants. In: Chapin III FS, Jefferies RL, Reynolds JF, Shaver GR, Svoboda J (eds) Arctic Ecosystems in a Changing Climate. Academic Press, Inc., San Diego pp 11–34
Shu-sheng L, Hughes RD (1987) The influence of temperature and photoperiod on the development, survival and reproduction of the sowthistle aphid, Hyperomyzus lactucae. Entomol Exp Appl 43:31–38
Strathdee AT, Bale JS (in press) A method for ameliorating temperature in polar terrestrial ecosystems. Polar Biol
Strathdee AT, Bale JS, Hodkinson ID, Block WC, Webb NR, Coulson SJ (1993) Identification of three previously unknown morphs of Acyrthosiphon svalbardicum Heikinheimo (Hemiptera: Aphididae) on Spitsbergen Ent Scand 24:43–47
Strathdee AT, Bale JS, Block WC, Webb NR, Hodkinson ID, Coulson SJ (1993) Extreme adaptive life-cycle in a high arctic aphid. Ecol Ent 18:254–258
Summers CG, Coviello RL, Gutierrez AP (1984) Influence of constant temperatures on the development and reproduction of A. cyrthosiphon kondoi (Homoptera: Aphididae) Env Entomol 13:236–242
Tenow O, Nilssen A (1990) Egg cold hardiness and topoclimatic limitations to outbreaks of Eppirrita autumnata in northern Fennoscandia. J Appl Ecol 27:723–734
Tissue DT, Oechel WC (1990) Response of Eriophorum vaginatum to elevated CO2 and temperature in the Alaskan tussock tundra. Ecology 68:401–410
Ulmer W (1937) Über den Jahresgang der Frosthärte einiger immergrünner Arten der alpinen Stufe, sowie der Zirbe und der Fichte. Jahrb Wiss Bot 84:553–592
Woodward FI (1987) Climate and Plant Distribution. Cambridge University Press. Cambridge
Woodward FI, Thompson GF, MacKee IF (1991) The effects of elevated concentration of carbon dioxide on individual plants, populations, communities and ecosystems. Ann Bot 67:23–38
Wookey PA, Parsons AN, Welker JM, Potter JA, Callaghan TV, Lee JA, Press MC (1993) Comparative responses of phenology and reproductive development to simulated environmental change in sub-arctic and high arctic plants. Oikos 67: 490–507
Wynn-Williams DD (1987) Microbial colonisation processes in Antarctic fellfield sites-an experimental overview. Proceedings of the National Institute of Polar Research Symposium on Polar Biol 3:164–178
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Strathdee, A.T., Bale, J.S., Block, W.C. et al. Effects of temperature elevation on a field population of Acyrthosiphon svalbardicum (Hemiptera: Aphididae) on Spitsbergen. Oecologia 96, 457–465 (1993). https://doi.org/10.1007/BF00320502
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DOI: https://doi.org/10.1007/BF00320502