Primary and secondary host plants differ in leaf-level photosynthetic response to herbivory: evidence from Alnus and Betula grazed by the alder beetle, Agelastica alni

J. OLEKSYN; P. KAROLEWSKI; M. J. GIERTYCH; R. ZYTKOWIAK; P. B. REICH; M. G. TJOELKER

doi:10.1046/j.1469-8137.1998.00270.x

Abstract

Field-grown trees of Alnus incana (L.) Moench, Alnus glutinosa (L.) Geartner and Betula pendula Roth displayed pronounced differences in responses of light-saturated net photosynthesis (Asat) to herbivory by the alder beetle (Agelastica alni L., Galerucinae), a specialized insect which primarily defoliates alders. We found that photosynthetic rates of grazed leaves increased following herbivory in Alnus but not in Betula. Area- and mass-based Asat of grazed leaves declined linearly with increasing amount of leaf perforation in B. pendula, by as much as 57%. By contrast Alnus glutinosa and Alnus incana increased area-based rates of Asat by 10–50% at all levels of leaf grazing. Given increased Asat in the remaining portion of grazed leaves, a net reduction in photosynthesis per leaf occurred only when the proportion of leaf area grazed exceeded 40% for Alnus incana and 23% for Alnus glutinosa. Since vein perforation by Agelastica alni was observed much more frequently in leaves of Betula than in Alnus, we hypothesized that declining Asat in herbivorized Betula was related to this disruption of water transport. A field experiment with artificial leaf perforation demonstrated a greater decline in Asat in vein-perforated Betula leaves than perforated leaves with midrib veins intact. However, regardless of leaf perforation regime, birch never showed post-perforation increases in Asat. In all species, rates of transpiration of grazed leaves linearly increased and water-use efficiency decreased with increased amount of leaf perforation. In grazed Alnus incana leaves, increasing leaf area consumption by Agelastica alni resulted in an increase of total phenols, a reduction in starch content and no changes in nitrogen concentration in the remaining portion. The increase in photosynthesis in Alnus incana might be related to declining leaf starch concentration or increasing stomatal conductance, but was unrelated to leaf nitrogen concentration. These gas exchange and leaf chemistry measurements suggest that in contrast to B. pendula, Alnus incana and Alnus glutinosa, which are the major host species for Agelastica alni, possess leaf-level physiological adaptations and defence mechanisms which can attenuate negative effects of herbivory by the alder leaf-beetle.

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Wilf, Peter and Labandeira, Conrad C. 1999. Response of Plant-Insect Associations to Paleocene-Eocene Warming. Science, Vol. 284, Issue. 5423, p. 2153.

Wilf, Peter and Labandeira, Conrad C. 2000. Effects of Paleocene—Eocene warming on insect herbivory. GFF, Vol. 122, Issue. 1, p. 178.

Tscharntke, Teja Thiessen, Sabine Dolch, Rainer and Boland, Wilhelm 2001. Herbivory, induced resistance, and interplant signal transfer in Alnus glutinosa. Biochemical Systematics and Ecology, Vol. 29, Issue. 10, p. 1025.

Zangerl, A. R. Hamilton, J. G. Miller, T. J. Crofts, A. R. Oxborough, K. Berenbaum, M. R. and de Lucia, E. H. 2002. Impact of folivory on photosynthesis is greater than the sum of its holes. Proceedings of the National Academy of Sciences, Vol. 99, Issue. 2, p. 1088.

Raimondo, Fabio Ghirardelli, Lia A. Nardini, Andrea and Salleo, Sebastiano 2003. Impact of the leaf miner Cameraria ohridella on photosynthesis, water relations and hydraulics of Aesculus hippocastanum leaves. Trees, Vol. 17, Issue. 4, p. 376.

Rudgers, Jennifer A. Hodgen, Jillian G. and White, J. Wilson 2003. Behavioral mechanisms underlie an ant-plant mutualism. Oecologia, Vol. 135, Issue. 1, p. 51.

Sack, Lawren Cowan, Peter D. and Holbrook, N. Michele 2003. The major veins of mesomorphic leaves revisited: tests for conductive overload in Acer saccharum (Aceraceae) and Quercus rubra (Fagaceae). American Journal of Botany, Vol. 90, Issue. 1, p. 32.

OZAKI, Kenichi SAITO, Hideyuki and YAMAMURO, Koji 2004. Compensatory photosynthesis as a response to partial debudding in ezo spruce, Picea jezoensis seedlings. Ecological Research, Vol. 19, Issue. 2, p. 225.

RETUERTO, R. FERNANDEZ‐LEMA, B. RODRIGUEZ‐ROILOA and OBESO, J. R. 2004. Increased photosynthetic performance in holly trees infested by scale insects. Functional Ecology, Vol. 18, Issue. 5, p. 664.

Ayres, Edward Heath, James Possell, Malcolm Black, Helaina I. J. Kerstiens, Gerhard and Bardgett, Richard D. 2004. Tree physiological responses to above‐ground herbivory directly modify below‐ground processes of soil carbon and nitrogen cycling. Ecology Letters, Vol. 7, Issue. 6, p. 469.

Li, Shuwen Martin, Lili T. Pezeshki, S. Reza and Shields, F. Douglas 2005. Responses of black willow (Salix nigra) cuttings to simulated herbivory and flooding. Acta Oecologica, Vol. 28, Issue. 2, p. 173.

ALDEA, MIHAI HAMILTON, JASON G. RESTI, JOSEPH P. ZANGERL, ARTHUR R. BERENBAUM, MAY R. and D eLUCIA, EVAN H. 2005. Indirect effects of insect herbivory on leaf gas exchange in soybean. Plant, Cell & Environment, Vol. 28, Issue. 3, p. 402.

DELANEY, KEVIN J. and HIGLEY, LEON G. 2006. An insect countermeasure impacts plant physiology: midrib vein cutting, defoliation and leaf photosynthesis. Plant, Cell & Environment, Vol. 29, Issue. 7, p. 1245.

Koike, Takayoshi Tobita, Hiroyuki Shibata, Takanori Matsuki, Sawako Konno, Kotaro Kitao, Mitsutoshi Yamashita, Naoko and Maruyama, Yutaka 2006. Defense characteristics of seral deciduous broad‐leaved tree seedlings grown under differing levels of CO2 and nitrogen. Population Ecology, Vol. 48, Issue. 1, p. 23.

Fernando, Silla Marina, Fleury Sonia, Mediavilla and Alfonso, Escudero 2008. Effects of simulated herbivory on photosynthesis and N resorption efficiency in Quercus pyrenaica Willd. saplings. Trees, Vol. 22, Issue. 6, p. 785.

Przybył, K. Karolewski, P. Oleksyn, J. Łabędzki, A. and Reich, P. B. 2008. Fungal Diversity of Norway Spruce Litter: Effects of Site Conditions and Premature Leaf Fall Caused By Bark Beetle Outbreak. Microbial Ecology, Vol. 56, Issue. 2, p. 332.

Delaney, K. J. Haile, F. J. Peterson, R. K. D. and Higley, L. G. 2008. Impairment of Leaf Photosynthesis After Insect Herbivory or Mechanical Injury on Common Milkweed,Asclepias syriaca. Environmental Entomology, Vol. 37, Issue. 5, p. 1332.

Sack, Lawren Dietrich, Elisabeth M. Streeter, Christopher M. Sánchez-Gómez, David and Holbrook, N. Michele 2008. Leaf palmate venation and vascular redundancy confer tolerance of hydraulic disruption. Proceedings of the National Academy of Sciences, Vol. 105, Issue. 5, p. 1567.

Delaney, K. J. Haile, F. J. Peterson, R. K. D. and Higley, L. G. 2008. Impairment of Leaf Photosynthesis After Insect Herbivory or Mechanical Injury on Common Milkweed, <I>Asclepias syriaca</I>. Environmental Entomology, Vol. 37, Issue. 5, p. 1332.

Delaney, Kevin J. 2008. Injured and uninjured leaf photosynthetic responses after mechanical injury on Nerium oleander leaves, and Danaus plexippus herbivory on Asclepias curassavica leaves. Plant Ecology, Vol. 199, Issue. 2, p. 187.

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Primary and secondary host plants differ in leaf-level photosynthetic response to herbivory: evidence from Alnus and Betula grazed by the alder beetle, Agelastica alni

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Primary and secondary host plants differ in leaf-level photosynthetic response to herbivory: evidence from Alnus and Betula grazed by the alder beetle, Agelastica alni

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