but see Hunter and Elkinton 1999). As regards mortality of young larvae, in a greenhouse experi- ment where natural enemies and abiotic conditions were under control, the biggest difference in survival to the end of second instar was found between trees with low contents of both pro- teins and hydrolizable tannins (96 % of survivors) and trees with high levels of both proteins and hydrolizable tannins (70 %). Although the causes of this pat- tern are uncertain, likely, bound- ing of proteins was more effective when concentration of both pro- teins and tannins were in was high concentration (see Zucker 1983 for further discussion), this would decrease larval growth and subsequently the probabilities of dying increased. Interestingly, individuals who died were those recording lightest weight at the beginning of the instar. This last finding is particularly relevant when we try to extrapolate the results to natural conditions. Mortality in the greenhouse was unusually low in first instar com- pared to natural patterns (person- al observation) and causes of death during the second instar were presumably not the same as in the field. However, results sug- gest that the main effect of a poor food quality food is to weaken individuals feeding on it and this will probably interact with other abiotic factors such as tempera- ture and natural enemies (Virtanen and Neuvonen 1999). Acknowledgements I am grateful to the staff of Kevo Subarctic Institute Station and Satakunta Environmental Re- search Centre for their assistance during the experiments, to Erkki Haukioja for introducing me to the study system, to Seppo Neuvonen and Kai Ruohomaki for discussing SKÓGRÆKTARRITIÐ 2001 l.tbl. with me about ballooning experi- ments, to Marianna Riipi for her assistance during the greenhouse experiment, and to the organizers of the NSSE workshop for provid- ing me the opportunity to discuss References AYRES, M. 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Host plant preferences in the comma butterfly (Polygonia c-album): do parents and off- spring agree? Ecoscience 3: 285-289. OSSIPOV, V., LOPONEN, J„ OSSIPOVA, S„ HAUKIOJA, E. and PIHLAJA, K. 1997. these results. Seppo Neuvonen made useful comments on the paper. The study was founded by the European Commission through TMR-Marie Curie fellow- ship (ERBFMBICT983034). Gallotannins of birch Betula pubescens leaves: HPLC separation and quantifica- tion. Biochem. Syst. Ecol. 25:493-504. ROFF, D. A. 1990. The evolution of flightless- ness in insects. Ecol. Monogr. 60: 389-421. RUOHOMÁKI, K„ TANHUANPÁÁ, M„ AYRES, M. P„ KAITANIEMI, P„ TAM- MARU, T. and HAUKIOJA, E. 2000 |iw press]: Causes of cyclicity of Epirrita autum- nata (Lepidoptera, Geometridae) - grandiose theory and tedious practice. Pop. Ecol. 00: 0000-0000. SAS INSTITUTE. 1996. SAS/STAT software: changes and enhancements through Release 6.11. SAS Institute, Cary, North Carolina, USA. SUOMELA, J„ OSSIPOV, V. and HAUKIOJA, E. 1995. 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