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Books A COMING OF AGE FOR THE TRAIT-BASED APPROACH IN PLANT ECOLOGY Plant Functional Diversity: Organism Traits, Community Structure, and Ecosystem Properties. Eric Garnier, Marie-Laure Navas, Karl Grigulis. Oxford University Press, 2016. 231 pp., illus. $125.00 (ISBN: 9780198757368 cloth). E ric Garnier, at the Centre d’Ecologie Fonctionnelle et Evolutive (the premier French research institute in plant ecology), and Marie-Laure Navas, at Montpellier SupAgro (the French National Institute of Higher Education in Agricultural Sciences), have a long-standing and productive collaboration. They published a French-language monograph in 2013 on plant functional diversity. The present book, coauthored with Karl Grigulis, from the Université Joseph Fourier in Grenoble, is a significantly revised and updated translation of their original monograph. The book marks a coming of age for the trait-based approach in plant ecology, providing a concise summary of developments in the field as it has rapidly taken hold in the past decade. The trait-based approach follows from the premise that a focus on variation in the traits of plants can yield deeper insights into the scaling of function from individual plants to communities and ecosystems than can a simple tally of species diversity. In a sense, this book is a revision of the history of all plant ecology viewed through the prism of the trait-based perspective that breaks species into their functional parts. Themes come into discussion that can be traced back to nineteenth-century studies of plant form and function in Andreas Schimper’s 1898 Pflanzengeographie auf Physiologischer Grundlage, but the traditional focus on comparisons among species is set aside in favor of an emphasis on the response of selected “functional traits” to environmental conditions and the consequent effects at the level of communities and ecosystems. An emphasis on traits over species certainly is not alien to biologists; it figures centrally in studies of evolutionary adaptation, quantitative genetics, and somewhat ironically in the context of the trait-based perspective, taxonomy. In these disciplines, any discussion of species is filtered through the study of variation in the characteristics of individuals. Taxonomists seek traits that are stable under individual and environmental variation, hence providing reliable markers of species identity. Conversely, evolutionary biologists identify the values of a trait that are differentially favored in an environment and the degree to which favored variation in traits is heritable and therefore subject to natural selection. In the context of evolutionary biology, the trait-based approach in functional ecology opens a path to a novel synthesis, with recent developments in both community ecology (Vellend 2016) and ecoevolutionary dynamics (Hendry 2016). For the moment, that potential is somewhat limited by a lack of data, because trait-based analyses draw largely on only mean trait values even though functional responses along environmental gradients are expressed through not only interspecific but also intraspecific trait variation. Trait data are compiled as species means from an eclectic mix of past studies using reasonably well-standardized methods but with considerable disparity 1082 BioScience • December 2016 / Vol. 66 No. 12 in associated metadata on growing conditions, plant age, and other f actors that can influence trait values. Most of the collated studies also report only one or a few traits, making it difficult to assess the coordinated interactions among a suite of traits affecting a particular function, such as establishment, growth, or fecundity. The authors recognize these limitations of available trait data and provide both a review of the existing compilations and an authoritative summary of ways to strengthen the database on which the trait-based approach depends. Despite the constraints imposed by the presently available data, the trait-based approach has established the existence of broadly consistent tradeoff relationships among traits that serve as markers of key plant functions. The most definitive of these is a trade-off between the construction cost of leaves and their rates of carbon gain (Wright et al. 2004), the trigger for a burgeoning literature on the intrinsic architecture of plant function (Reich 2014, Diaz et al. 2016). This book effectively summarizes the functional ecology that inspired the trait-based approach and then turns to the question of whether an understanding of how traits affect plant function can in turn reveal aspects of community assembly and ecosystem function. Patterns of abundanceweighted trait values of the species constituting a community are shown to provide insights into the degree to which abiotic versus biotic factors affect community assembly, as well as the degree to which dominance versus complementarity effects influence ecosystem properties and the provision of ecosystem services. A chapter on the management of rangeland and crop ecosystems nicely illustrates the reciprocal utilitarian and scientific value of the trait-based approach to plant functional diversity. Finally, a closing chapter on future prospects for plant functional diversity touches on perhaps one of the more exciting paths forward in the trait-based approach: trait driver theory (Enquist http://bioscience.oxfordjournals.org Books How to Contact AIBS BioScience Advertising, print and online: [email protected] Classified advertising: [email protected] 855-895-5374 Online: http://bioscience.oxfordjournals.org Permissions: [email protected] Submission inquiries: [email protected] 703-674-2500 x. 326 Subscriptions: Individual [email protected] 703-674-2500 x. 247 AIBS ActionBioscience.org: [email protected] 703-674-2500 x. 326 Membership Records: [email protected] 703-674-2500 x. 247 Community Programs: [email protected] 703-674-2500 x. 247 et al. 2015), which uses the frequency distribution of traits to predict shifts in community composition and ecosystem function in response to environmental change. In conclusion, this book lays out with impressive clarity, depth, and breadth the conceptual framework of plant functional diversity as it stands today. The central ideas of the traitbased approach are firmly in place, rooted in the comparative ecology of species but consistently focused on trait variation and its effects on community assembly and ecosystem function. The review of relevant literature is selective but broadly representative, informatively blending European and Anglo-American perspectives on plant function. It is clear that the trait-based approach is not yet fully formed—the available trait database is a work in progress, and there are unresolved issues even in the nature of traits and their relationship to function—but the authors do a good job laying out the ambiguities and uncertainties of the approach, providing a well-referenced summary of the key issues. The book provides a definitive reading for a graduate-level seminar on plant functional diversity and an excellent desk reference for any biologist interested in the evolutionary and ecological implications of trait variation. Garnier, Navas, and Grigulis have laid an admirably solid foundation for the lines of inquiry that will lead to the maturation of the trait-based approach and its integration into a larger synthesis of ecological and evolutionary theory. References cited Díaz S, et al. 2016. The global spectrum of plant form and function. Nature 529: 167–171. Enquist BJ, Norberg J, Bonser SP, Violle C, Webb CT, Henderson A, Sloat LL, Savage VM. 2015. Scaling from traits to ecosystems: Developing a general trait driver theory via integrating trait-based and metabolic scaling theories. Advances in Ecological Research 52: 249–318. Hendry AP. 2016. Eco-Evolutionary Dynamics. Princeton University Press. Reich P. 2014. The world-wide “fast–slow” plant economics spectrum: A traits manifesto. Journal of Ecology 102: 275–301. Vellend M. 2016. The Theory of Ecological Communities. Princeton University Press. Wright IJ, et al. 2004. The worldwide leaf economics spectrum. Nature 428: 821–827. MARTIN J. LECHOWICZ Martin J. Lechowicz (http://biology. mcgill.ca/faculty/lechowicz) is a professor emeritus and Liber Ero Chair in Conservation Biology at McGill University, in Montréal, Québec. doi:10.1093/biosci/biw134 Public Policy Office: [email protected] 202-628-1500 x. 250 Scientific Peer-Review Services: [email protected] 703-674-2500 x. 202 Web/IT Services: [email protected] 703-674-2500 x. 107 http://bioscience.oxfordjournals.org December 2016 / Vol. 66 No. 12 • BioScience 1083