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Fossil leaf economics quantified: calibration, Eocene case study, and implications

Published online by Cambridge University Press:  08 April 2016

Dana L. Royer ,
Lawren Sack ,
Peter Wilf ,
Bárbara Cariglino ,
Christopher H. Lusk ,
Ian J. Wright ,
Mark Westoby ,
Gregory J. Jordan ,
Ülo Niinemets  and
Phyllis D. Coley
...Show all authors
Dana L. Royer
Affiliation:
Department of Earth and Environmental Sciences, Wesleyan University, Middletown, Connecticut 06459. E-mail: [email protected]
Lawren Sack
Affiliation:
Department of Botany, University of Hawai'i at Mānoa, Honolulu, Hawai'i 96822
Peter Wilf
Affiliation:
Department of Geosciences, Pennsylvania State University, University Park, Pennsylvania 16802
Bárbara Cariglino
Affiliation:
Department of Geosciences, Pennsylvania State University, University Park, Pennsylvania 16802
Christopher H. Lusk
Affiliation:
Department of Biological Sciences, Macquarie University, Sydney, New South Wales 2109, Australia
Ian J. Wright
Affiliation:
Department of Biological Sciences, Macquarie University, Sydney, New South Wales 2109, Australia
Mark Westoby
Affiliation:
Department of Biological Sciences, Macquarie University, Sydney, New South Wales 2109, Australia
Gregory J. Jordan
Affiliation:
School of Plant Science, University of Tasmania, Private Bag 55, Hobart 7001, Australia
Ülo Niinemets
Affiliation:
Institute of Agricultural and Environmental Sciences, Estonian University of Life Sciences, Tartu 51014, Estonia
Phyllis D. Coley
Affiliation:
Department of Biology, University of Utah, Salt Lake City, Utah 84112
Asher D. Cutter
Affiliation:
Department of Paleobiology, Smithsonian Institution, Washington, D.C. 20013
Conrad C. Labandeira
Affiliation:
Department of Paleobiology, Smithsonian Institution, Washington, D.C. 20013
Matthew B. Palmer
Affiliation:
Department of Paleobiology, Smithsonian Institution, Washington, D.C. 20013
Kirk R. Johnson
Affiliation:
Department of Earth Sciences, Denver Museum of Nature and Science, Denver, Colorado 80205
Angela T. Moles
Affiliation:
Department of Biological Sciences, Macquarie University, Sydney, New South Wales 2109, Australia
Fernando Valladares
Affiliation:
Centro de Ciencias Medioambientales, CSIC, E-28006 Madrid, Spain
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Abstract

Leaf mass per area (MA) is a central ecological trait that is intercorrelated with leaf life span, photosynthetic rate, nutrient concentration, and palatability to herbivores. These coordinated variables form a globally convergent leaf economics spectrum, which represents a general continuum running from rapid resource acquisition to maximized resource retention. Leaf economics are little studied in ancient ecosystems because they cannot be directly measured from leaf fossils. Here we use a large extant data set (65 sites; 667 species-site pairs) to develop a new, easily measured scaling relationship between petiole width and leaf mass, normalized for leaf area; this enables MA estimation for fossil leaves from petiole width and leaf area, two variables that are commonly measurable in leaf compression floras. The calibration data are restricted to woody angiosperms exclusive of monocots, but a preliminary data set (25 species) suggests that broad-leaved gymnosperms exhibit a similar scaling. Application to two well-studied, classic Eocene floras demonstrates that MA can be quantified in fossil assemblages. First, our results are consistent with predictions from paleobotanical and paleoclimatic studies of these floras. We found exclusively low-MA species from Republic (Washington, U.S.A., 49 Ma), a humid, warm-temperate flora with a strong deciduous component among the angiosperms, and a wide MA range in a seasonally dry, warm-temperate flora from the Green River Formation at Bonanza (Utah, U.S.A., 47 Ma), presumed to comprise a mix of short and long leaf life spans. Second, reconstructed MA in the fossil species is negatively correlated with levels of insect herbivory, whether measured as the proportion of leaves with insect damage, the proportion of leaf area removed by herbivores, or the diversity of insect-damage morphotypes. These correlations are consistent with herbivory observations in extant floras and they reflect fundamental trade-offs in plant-herbivore associations. Our results indicate that several key aspects of plant and plant-animal ecology can now be quantified in the fossil record and demonstrate that herbivory has helped shape the evolution of leaf structure for millions of years.

Type
Articles
Information
Paleobiology , Volume 33 , Issue 4 , Fall 2007 , pp. 574 - 589
Copyright
Copyright © The Paleontological Society 

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References

Literature Cited

Ackerly, D. D., and Reich, P. B. 1999. Convergence and correlations among leaf size and function in seed plants: a comparative test using independent contrasts. American Journal of Botany 86: 12721281.CrossRefGoogle ScholarPubMed
Beck, A. L., and Labandeira, C. C. 1998. Early Permian insect folivory on a gigantopterid-dominated riparian flora from north-central Texas. Palaeogeography, Palaeoclimatology, Palaeoecology 142: 139173.CrossRefGoogle Scholar
Brentnall, S. J., Beerling, D. J., Osborne, C. P., Harland, M., Francis, J. E., Valdes, P. J., and Wittig, V. E. 2005. Climatic and ecological determinants of leaf lifespan in polar forests of the high CO2 Cretaceous ‘greenhouse’ world. Global Change Biology 11: 21772195.Google Scholar
Chaloner, W. G., and Creber, G. T. 1990. Do fossil plants give a climatic signal? Journal of the Geological Society, London 147: 343350.Google Scholar
Chapin, F. S. 2003. Effects of plant traits on ecosystem and regional processes: a conceptual framework for predicting the consequences of global change. Annals of Botany 91: 455463.Google Scholar
Coley, P. D. 1983. Herbivory and defensive characteristics of tree species in a lowland tropical forest. Ecological Monographs 53: 209233.CrossRefGoogle Scholar
Cornelissen, J. H. C., Lavorel, S., Garnier, E., Díaz, S., Buchmann, N., Gurvich, D. E., Reich, P. B., ter Steege, H., Morgan, H. D., van der Heijden, M. G. A., Pausas, J. G., and Poorter, H. 2003. A handbook of protocols for standardised and easy measurement of plant functional traits worldwide. Australian Journal of Botany 51: 335380.CrossRefGoogle Scholar
Díaz, S., Hodgson, J. G., Thompson, K., Cabido, M., Cornelissen, J. H. C., Jalili, A., Montserrat-Martí, G., Grime, J. P., Zarrinkamar, F., Asri, Y., Band, S. R., Basconcelo, S., Castro-Díez, P., Funes, G., Hamzehee, B., Khoshnevi, M., Pérez-Harguindeguy, N., Pérez-Rontomé, M. C., Shirvany, F. A., Vendramini, F., Yazdani, S., Abbas-Azimi, R., Bogaard, A., Boustani, S., Charles, M., Dehghan, M., de Torres-Espuny, L., Falczuk, V., Guerrero-Campo, J., Hynd, A., Jones, G., Kowsary, E., Kazemi-Saeed, F., Maestro-Martinez, M., Romo-Díez, A., Shaw, S., Siavash, B., Villar-Salvador, P., and Zak, M. R. 2004. The plant traits that drive ecosystems: evidence from three continents. Journal of Vegetation Science 15: 295304.Google Scholar
Falcon-Lang, H. J. 2000a. A method to distinguish between woods produced by evergreen and deciduous coniferopsids on the basis of growth ring anatomy: a new palaeoecological tool. Palaeontology 43: 785793.Google Scholar
Falcon-Lang, H. J. 2000b. The relationship between leaf longevity and growth ring markedness in modern conifer woods and its implications for palaeoclimatic studies. Palaeogeography, Palaeoclimatology, Palaeoecology 160: 317328.CrossRefGoogle Scholar
Falster, D. S., Warton, D. I., and Wright, I. J. 2003. (S)MATR: standardised major axis tests and routines. Version 1.0. http://www.bio.mq.edu.au/ecology/SMATR.Google Scholar
Greenwood, D. R., Archibald, S. B., Mathewes, R. W., and Moss, P. T. 2005. Fossil biotas from the Okanagan Highlands, southern British Columbia and northeastern Washington State: climates and ecosystems across an Eocene landscape. Canadian Journal of Earth Sciences 42: 167185.Google Scholar
Grime, J. P. 1974. Vegetation classification by reference to strategies. Nature 250: 2631.Google Scholar
Grubb, P. J. 1998. A reassessment of the strategies of plants which cope with shortages of resources. Perspectives in Plant Ecology, Evolution and Systematics 1: 331.CrossRefGoogle Scholar
Huff, P. M., Wilf, P., and Azumah, E. J. 2003. Digital future for paleoclimate estimation from fossil leaves? Preliminary results. Palaios 18: 266274.Google Scholar
Kazakou, E., Vile, D., Shipley, B., Gallet, C., and Garnier, E. 2006. Co-variations in litter decomposition, leaf traits and plant growth in species from a Mediterranean old-field succession. Functional Ecology 20: 2130.CrossRefGoogle Scholar
Kobe, R. K., Lepczyk, C. A., and Iyer, M. 2005. Resorption efficiency decreases with increasing green leaf nutrients in a global data set. Ecology 86: 27802792.Google Scholar
Kowalski, E. A., and Dilcher, D. L. 2003. Warmer paleotemperatures for terrestrial ecosystems. Proceedings of the National Academy of Sciences USA 100: 167170.Google Scholar
Labandeira, C. C. 1998. Early history of arthropod and vascular plant associations. Annual Review of Earth and Planetary Sciences 26: 329377.CrossRefGoogle Scholar
Labandeira, C. C. 2002. Paleobiology of middle Eocene plant-insect associations from the Pacific Northwest: a preliminary report. Rocky Mountain Geology 37: 3159.CrossRefGoogle Scholar
MacGinitie, H. D. 1969. The Eocene Green River flora of northwestern Colorado and northeastern Utah. University of California Publications in Geological Sciences 83: 1202.Google Scholar
McMahon, T. A., and Bonner, J. T. 1983. On size and life. Scientific American Library, New York.Google Scholar
Moles, A. T., and Westoby, M. 2000. Do small leaves expand faster than large leaves, and do shorter expansion times reduce herbivore damage? Oikos 90: 517524.Google Scholar
Nardini, A., Gortan, E., and Salleo, S. 2005. Hydraulic efficiency of the leaf venation system in sun- and shade-adapted species. Functional Plant Biology 32: 953961.CrossRefGoogle Scholar
New, M., Lister, D., Hulme, M., and Makin, I. 2002. A high-resolution data set of surface climate over global land areas. Climate Research 21: 125 (data available at http://www.cru.uea.ac.uk/cru/data/tmc.htm).Google Scholar
Niinemets, Ü. 2001. Global-scale climatic controls of leaf dry mass per area, density, and thickness in trees and shrubs. Ecology 82: 453469.Google Scholar
Niinemets, Ü., Valladares, F., and Ceulemans, R. 2003. Leaf-level phenotypic variability and plasticity of invasive Rhododendron ponticum and non-invasive Ilex aquifolium co-occurring at two contrasting European sites. Plant, Cell and Environment 26: 941956.Google Scholar
Niinemets, Ü., Portsmuth, A., Tena, D., Tobias, M., Matesanz, S., and Valladares, F. 2007. Do we underestimate the importance of leaf size in plant economics? Disproportionate scaling of support costs within the spectrum of leaf physiognomy. Annals of Botany 100: 283303.CrossRefGoogle Scholar
Niklas, K. J. 1978. Morphometric relationships and rates of evolution among Paleozoic vascular plants. Evolutionary Biology 11: 509543.Google Scholar
Niklas, K. J. 1991a. The elastic-moduli and mechanics of Populus tremuloides (Salicaceae) petioles in bending and torsion. American Journal of Botany 78: 989996.Google Scholar
Niklas, K. J. 1991b. Flexural stiffness allometries of angiosperm and fern petioles and rachises: evidence for biomechanical convergence. Evolution 45: 734750.Google Scholar
Niklas, K. J. 1994. Plant allometry: the scaling of form and function. University of Chicago Press, Chicago.Google Scholar
Niklas, K. J. 1996. Differences between Acer saccharum leaves from open and wind-protected sites. Annals of Botany 78: 6166.CrossRefGoogle Scholar
Niklas, K. J. 1998. The influence of gravity and wind on land plant evolution. Review of Palaeobotany and Palynology 102: 114.Google Scholar
Niklas, K. J. 1999. A mechanical perspective on foliage leaf form and function. New Phytologist 143: 1931.Google Scholar
Parton, W., Silver, W. L., Burke, I. C., Grassens, L., Harmon, M. E., Currie, W. S., King, J. Y., Adair, E. C., Brandt, L. A., Hart, S. C., and Fasth, B. 2007. Global-scale similarities in nitrogen release patterns during long-term decomposition. Science 315: 361364.Google Scholar
Peters, R. H. 1983. The ecological implications of body size. Cambridge University Press, Cambridge.CrossRefGoogle Scholar
Poorter, L., and Bongers, F. 2006. Leaf traits are good predictors of plant performance across 53 rain forest species. Ecology 87: 17331743.CrossRefGoogle ScholarPubMed
Poorter, L., van de Plassche, M., Willems, S., and Boot, R. G. A. 2004. Leaf traits and herbivory rates of tropical tree species differing in successional status. Plant Biology 6: 746754.Google Scholar
Radtke, M. G., Pigg, K. B., and Wehr, W. C. 2005. Fossil Corylopsis and Fothergilla leaves (Hamamelidaceae) from the lower Eocene flora of Republic, Washington, USA, and their evolutionary and biogeographic significance. International Journal of Plant Sciences 166: 347356.Google Scholar
Reich, P. B., Walters, M. B., and Ellsworth, D. S. 1997. From tropics to tundra: global convergence in plant function. Proceedings of the National Academy of Sciences USA 94: 1373013734.Google Scholar
Rex, G. M. 1986. Further experimental investigations on the formation of plant compression fossils. Palaios 19: 143159.Google Scholar
Rex, G. M., and Chaloner, W. G. 1983. The experimental formation of plant compression fossils. Palaeontology 26: 231252.Google Scholar
Royer, D. L., Osborne, C. P., and Beerling, D. J. 2002. High CO2 increases the freezing sensitivity of plants: implications for paleoclimatic reconstructions from fossil floras. Geology 30: 963966.Google Scholar
Royer, D. L., Wilf, P., Janesko, D. A., Kowalski, E. A., and Dilcher, D. L. 2005. Correlating climate and plant ecology with leaf size and shape: potential proxies for the fossil record. American Journal of Botany 92: 11411151.Google Scholar
Sack, L., and Frole, K. 2006. Leaf structural diversity is related to hydraulic capacity in tropical rainforest trees. Ecology 87: 483491.Google Scholar
Sack, L., Melcher, P. J., Zwieniecki, M. A., and Holbrook, N. M. 2002. The hydraulic conductance of the angiosperm leaf lamina: a comparison of three measurement methods. Journal of Experimental Botany 53: 21772184.Google Scholar
Sack, L., Cowan, P. D., Jaikumar, N., and Holbrook, N. M. 2003. The ‘hydrology’ of leaves: co-ordination of structure and function in temperate woody species. Plant, Cell and Environment 26: 13431356.Google Scholar
Sack, L., Tyree, M. T., and Holbrook, N. M. 2005. Leaf hydraulic architecture correlates with regeneration irradiance in tropical rainforest trees. New Phytologist 167: 403413.Google Scholar
Salisbury, E. J. 1913. The determining factors in petiolar structure. New Phytologist 12: 281289.CrossRefGoogle Scholar
Schmidt-Nielsen, K. 1984. Scaling. Cambridge University Press, Cambridge.Google Scholar
Shipley, B., Vile, D., and Garnier, É. 2006. From plant traits to plant communities: a statistical mechanistic approach to biodiversity. Science 314: 812814.Google Scholar
Small, E. 1972. Photosynthetic rates in relation to nitrogen recycling as an adaptation to nutrient deficiency in peat bog plants. Canadian Journal of Botany 50: 22272233.Google Scholar
Smith, M. E., Carroll, A. R., and Singer, B. S. 2007. Synoptic reconstruction of a major ancient lake system: Eocene Green River Formation, Western United States. Geological Society of America Bulletin (in press).Google Scholar
Sokal, R. R., and Rohlf, F. J. 1995. Biometry, 3d ed. W.H. Freeman, New York.Google Scholar
Spicer, R. A. 1981. The sorting and deposition of allochthonous plant material in a modern environment at Silwood Lake, Silwood Park, Berkshire, England. U.S. Geological Survey Professional Paper 1143: 177.Google Scholar
Spicer, R. A., and Parrish, J. T. 1986. Paleobotanical evidence for cool north polar climates in middle Cretaceous (Albian-Cenomanian) time. Geology 14: 703706.Google Scholar
Thomas, S. C., and Winner, W. E. 2002. Photosynthetic differences between saplings and adult trees: an integration of field results by meta-analysis. Tree Physiology 22: 117127.Google Scholar
Villar, R., and Merino, J. 2001. Comparison of leaf construction costs in woody species with differing leaf life-spans in contrasting ecosystems. New Phytologist 151: 213226.Google Scholar
Walton, J. 1936. On the factors which influence the external form of fossil plants; with descriptions of the foliage of some species of the Palaeozoic equisetalean genus Annularia Sternberg. Philosophical Transactions of the Royal Society of London B 226: 219237.Google Scholar
Warton, D. I., Wright, I. J., Falster, D. S., and Westoby, M. 2006. Bivariate line-fitting methods for allometry. Biological Reviews 81: 259291.CrossRefGoogle ScholarPubMed
Westoby, M., Falster, D. S., Moles, A. T., Vesk, P. A., and Wright, I. J. 2002. Plant ecological strategies: some leading dimensions of variation between species. Annual Review of Ecology and Systematics 33: 125159.CrossRefGoogle Scholar
Whittaker, R. 1975. Communities and ecosystems. Macmillan, New York.Google Scholar
Wilf, P., and Labandeira, C. C. 1999. Response of plant-insect associations to Paleocene-Eocene warming. Science 284: 21532156.CrossRefGoogle ScholarPubMed
Wilf, P., Wing, S. L., Greenwood, D. R., and Greenwood, C. L. 1998. Using fossil leaves as paleoprecipitation indicators: an Eocene example. Geology 26: 203206.2.3.CO;2>CrossRefGoogle Scholar
Wilf, P., Labandeira, C. C., Johnson, K. R., Coley, P. D., and Cutter, A. D. 2001. Insect herbivory, plant defense, and early Cenozoic climate change. Proceedings of the National Academy of Sciences USA 98: 62216226.Google Scholar
Wilf, P., Labandeira, C. C., Johnson, K. R., and Cúneo, N. R. 2005. Richness of plant-insect associations in Eocene Patagonia: a legacy for South American biodiversity. Proceedings of the National Academy of Sciences USA 102: 89448948.Google Scholar
Wing, S. L., and Greenwood, D. R. 1993. Fossils and fossil climate: the case for equable continental interiors in the Eocene. Philosophical Transactions of the Royal Society London B 341: 243252.Google Scholar
Wolfe, J. A. 1987. Late Cretaceous-Cenozoic history of deciduousness and the terminal Cretaceous event. Paleobiology 13: 215226.Google Scholar
Wolfe, J. A., and Upchurch, G. R. 1987. Leaf assemblages across the Cretaceous-Tertiary boundary in the Raton Basin, New Mexico and Colorado. Proceedings of the National Academy of Sciences USA 84: 50965100.Google Scholar
Wolfe, J. A., and Wehr, W. C. 1987. Middle Eocene dicotyledonous plants from Republic, northeastern Washington. U.S. Geological Survey Bulletin 1597: 125.Google Scholar
Wright, I. J., and Westoby, M. 2002. Leaves at low versus high rainfall: coordination of structure, lifespan and physiology. New Phytologist 155: 403416.CrossRefGoogle ScholarPubMed
Wright, I. J., Reich, P. B., and Westoby, M. 2001. Strategy-shifts in leaf physiology, structure and nutrient content between species of high and low rainfall, and high and low nutrient habitats. Functional Ecology 15: 423434.Google Scholar
Wright, I. J., Reich, P. B., Westoby, M., Ackerly, D. D., Baruch, Z., Bongers, F., Cavender-Bares, J., Chapin, T., Cornelissen, J. H. C., Diemer, M., Flexas, J., Garnier, E., Groom, P. K., Gulias, J., Hikosaka, K., Lamont, B. B., Lee, T., Lee, W., Lusk, C., Midgley, J. J., Navas, M.-L., Niinemets, Ü., Oleksyn, J., Osada, N., Poorter, H., Poot, P., Prior, L., Pyankov, V. I., Roumet, C., Thomas, S. C., Tjoelker, M. G., Veneklaas, E. J., and Villar, R. 2004. The worldwide leaf economics spectrum. Nature 428: 821827.Google Scholar
Wright, I. J., Reich, P. B., Cornelissen, J. H. C., Falster, D. S., Groom, P. K., Hikosaka, K., Lee, W., Lusk, C. H., Niinemets, Ü., Oleksyn, J., Osada, N., Poorter, H., Warton, D. I., and Westoby, M. 2005. Modulation of leaf economic traits and trait relationships by climate. Global Ecology and Biogeography 14: 411421.Google Scholar
Yamada, T., Suzuki, E., and Yamakura, T. 1999. Scaling of petiole dimensions with respect to leaf size for a tropical tree, Scaphium macropodum (Sterculiaceae), in Borneo. Journal of Plant Research 112: 6166.CrossRefGoogle Scholar
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