Book contents
- Frontmatter
- Contents
- Contributors
- Preface
- Chapter One The integrative roles of plant secondary metabolites in natural systems
- Chapter Two Natural selection for anti-herbivore plant secondary metabolites
- Chapter Three Temporal changes in plant secondary metabolite production
- Chapter Four Mixtures of plant secondary metabolites
- Chapter Five The herbivore’s prescription
- Chapter Six Volatile isoprenoids and abiotic stresses
- Chapter Seven Atmospheric change, plant secondary metabolites and ecological interactions
- Chapter Eight The role of plant secondary metabolites in freshwater macrophyte–herbivore interactions
- Chapter Nine The soil microbial community and plant foliar defences against insects
- Chapter Ten Phytochemicals as mediators of aboveground–belowground interactions in plants
- Chapter Eleven Plant secondary metabolites and the interactions between plants and other organisms
- Chapter Twelve Integrating the effects of PSMs on vertebrate herbivores across spatial and temporal scales
- Chapter Thirteen Plant secondary metabolite polymorphisms and the extended chemical phenotype
- Chapter Fourteen From genes to ecosystems
- Chapter Fifteen Asking the ecosystem if herbivory-inducible plant volatiles (HIPVs) have defensive functions
- Chapter Sixteen Dynamics of plant secondary metabolites and consequences for food chains and community dynamics
- Index
- Plate Section
- References
Chapter Four - Mixtures of plant secondary metabolites
metabolic origins and ecological benefits
Published online by Cambridge University Press: 05 August 2012
Book contents
- Frontmatter
- Contents
- Contributors
- Preface
- Chapter One The integrative roles of plant secondary metabolites in natural systems
- Chapter Two Natural selection for anti-herbivore plant secondary metabolites
- Chapter Three Temporal changes in plant secondary metabolite production
- Chapter Four Mixtures of plant secondary metabolites
- Chapter Five The herbivore’s prescription
- Chapter Six Volatile isoprenoids and abiotic stresses
- Chapter Seven Atmospheric change, plant secondary metabolites and ecological interactions
- Chapter Eight The role of plant secondary metabolites in freshwater macrophyte–herbivore interactions
- Chapter Nine The soil microbial community and plant foliar defences against insects
- Chapter Ten Phytochemicals as mediators of aboveground–belowground interactions in plants
- Chapter Eleven Plant secondary metabolites and the interactions between plants and other organisms
- Chapter Twelve Integrating the effects of PSMs on vertebrate herbivores across spatial and temporal scales
- Chapter Thirteen Plant secondary metabolite polymorphisms and the extended chemical phenotype
- Chapter Fourteen From genes to ecosystems
- Chapter Fifteen Asking the ecosystem if herbivory-inducible plant volatiles (HIPVs) have defensive functions
- Chapter Sixteen Dynamics of plant secondary metabolites and consequences for food chains and community dynamics
- Index
- Plate Section
- References
Summary
Introduction
Plants produce a large variety of secondary metabolites which are usually considered to function as defences against herbivores and pathogens, as many other contributions to this volume attest. Among the most characteristic features of these compounds are their vast number and enormous chemical diversity. Reports on plant secondary metabolites (PSMs) are replete with phrases describing their ‘tremendous array’ (Morrissey, 2009), ‘bewildering proliferation’ (Schoonhoven et al., 2005) or ‘extraordinary diversity’ (Howe & Jander, 2008). The diversity of secondary metabolites is apparent not only in their chemical structures, but also in their distribution in plants. The composition of secondary metabolites in plants varies at many levels of organisation, such as among different plant taxa (Wink, 2003), among different populations of the same taxon (Kliebenstein et al., 2001a) and between individuals of the same species (Pakeman et al., 2006). Within a plant, there is also variation among different organs (Brown et al., 2003), developmental stages (Lambdon et al., 2003) and environmental conditions (Engelen-Eigles et al., 2006), as well as the frequent presence of complex mixtures of secondary metabolites in individual organs. Most secondary metabolites, including alkaloids (Waffo et al., 2007), phenolics (Ashihara et al., 2010) and terpenes (Köllner et al., 2004), invariably occur in mixtures rather than as individual, isolated substances. The chemistry and distribution of secondary metabolites is so diverse that being able to explain the patterns of diversity seems an essential requirement for understanding their roles in plants.
This review will consider both the generation of secondary metabolite chemical diversity by the plant’s biosynthetic machinery and the functional importance of such diversity. We focus on the function of secondary metabolites in defence against herbivores, because this has received the most attention from researchers. Since there are so many levels of diversity in secondary metabolites, we will limit ourselves to just one: the occurrence of mixtures of a single class of compounds, such as alkaloids or terpenes, in individual organs.
- Type
- Chapter
- Information
- The Ecology of Plant Secondary MetabolitesFrom Genes to Global Processes, pp. 56 - 77Publisher: Cambridge University PressPrint publication year: 2012
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