Plants allocate carbon to enhance performance and to increase plant fitness

CO2 Plants allocate carbon to enhance performance and to increase plant fitness Plant Ecology in a Changing World Jim Ehleringer, University of Utah http://plantecology.net

Plants allocate resources to enhance performance Plants as integrated systems with repetitive modules repeating modules unlike growth in most animals (leaves, xylem/phloem, roots, flowers, etc.) models of carbon acquisition, storage, and utilization currency integration concepts economic principles of cost-benefit analysis consideration of limiting factor concept temporal and spatial integration (within plant) - root - shoot ratio - leaf longevity and phenology

Part 1 Plant carbon balance and carbon allocation

Carbon balance is used as an integrative approach for assessing the consequence of different plant characteristics on plant performance

Growth rates are more similar within a life form than among life forms

Plant growth rate is inversely proportional to leaf life span Leaf tissues are a primary target of herbivores, because of their high protein content. The longer the lifetime of a tissue, the greater the overall requirement to allocate resources for maintenance respiration and for defense. spinach leaf bristlecone pine needle

Constraints and tradeoffs in resource acquisition and utilization gas exchange constraints imposed by root and hydraulic characteristics [conductance is not infinite] biomass distribution constraints imposed root - shoot allocation patterns [allocation of a resource to one tissue means that resource is not allocated to another tissue or organ] growth constraints imposed by non-storage and storage [there is a finite volume in a cell; increased tissue or organ size requires additional support, defense, maintenance resources] constraints imposed by multiple functions of an organ (e.g., water versus nutrient uptake by roots or storage versus conduction by shoots

Carbon is the currency Carbon is frequently used as the currency for quantifying the adaptive significance of variations in phenological, physiological, and/or morphological features among plants carbon-carbon bonds are the vehicle for energy transfer within the plant [sugars, carbohydrates, amino acids] energy from oxidation of carbon-carbon bonds is used for construction and maintenance of resource capturing structures (leaves, roots) storage of energy over time is in carbon bonds [lipids, carbohydrates]

Construction costs to build tissues depend on biochemical composition Energy requirements for construction are based on glucose equivalents Energy requirements for construction: lipids > proteins > carbohydrates Stems, roots, and leaves are primarily based on carbohydrates. Construction costs are highest in lipid-prominent tissue types.

Root-to-shoot ratio is one integrating concept, especially when we recognize a plant as an aggregation of repeating modules Consider the need for balance in resources uptake and loss (e.g., transpiration, nutrients)

Carbon allocation patterns often show predictable patterns, such as annual winter/summer cycles associated with dormancy seedling establishment responses to water deficit

Part 2 Plants as an assemblage of repeating modules

Aboveground plant growth is a repeating sequence of vegetative and reproductive modules, with the apical or axillary meristems determining module development. Allocation to reproduction comes at the cost of allocation to new vegetative growth.

Growth as a repetition of similar modular units, while maintaining a specific root/shoot ratio almond

Lifetime reproductive output of annual plants is a proxy measure of fitness and is usually proportional to plant biomass Death Valley annuals

Reproductive timing deterministic, opportunistic, or both? What are the controls on reproductive timing? What are the controls on reproductive frequency? What are the controls on reproductive duration? What influences are determined by pollinators? How does the accumulated storage of carbon and nutrients influence reproduction? What are masting years?

Masting in trees synchronous seed production Reproduction in oak trees

Reproductive tendencies

Part 3 Herbivory impacts on plant allocation patterns

Carbon balance involves the capture of carbon (photosynthesis) and its subsequent allocation as well as the losses to maintenance, construction, and herbivory carbon allocation carbon loss

Hemizonia subspecies exhibit life history tradeoffs with respect to drought vs herbivory Herbivores are spring active, increasing herbivory on vegetative and reproductive tissues However, drought enhances summer mortality rates

Defense against herbivory can represent a substantial construction and maintenance cost (investments in alkaloids, tannins, other deterrents) cell wall C proteins lipids chemical defense

Plant growth rate is slower when more of the carbon gain is allocated to defense

Plants may allocate as up to 25% of leaf mass to chemical defense against herbivores Percent Dry Weight 0 5 10 15 20 25 30 Phenolics Gaps Understory Inga species NS I. pezizifera I. multijuga I. umbellifera I. marginata Bixenmann et al 2010

Summary 1. Carbon balance is a useful integration or currency concept, especially since energy for plant growth is contained within carbon-carbon bonds. 2. The cost to construct tissues depends on the chemical composition, with lipids being the most carbon expensive component, carbohydrate the least expensive, and proteins intermediate. 3. Root-to-shoot ratio is a unifying concept, especially since plants are composed of repetitive modules. 4. Carbon allocation often involves tradeoffs related to phenology, life history, tissue life expectancy. 5. Plant growth rate is inversely proportional to leaf life span. 6. Defense against herbivory increases with leaf life expectancy.

Sources and acknowledgment of data and illustrations used in the presentation: original materials http://ehleringer.net/publications.html http://bonsaitonight.files.wordpress.com/2009/10/bristlecone-pine-1.jpg http://echolife.files.wordpress.com/2011/09/baby-spinach-leaves.jpg http://www.calflora.org/cgi-bin/species_query.cgi?where-taxon=hemizonia+congesta+ssp.+luzulifolia http://www.difossombrone.it/images/piantemedicinali/prunus_dulcis.jpg http://plants.usda.gov/gallery/pubs/hecol3_002_php.jpg http://www.wpclipart.com/plants/assorted/c/carrot_bw.png http://www.rgbstock.com/cache1nsu9z/users/a/ay/ayla87/300/mlfzias.jpg http://www.extension.umn.edu/garden/landscaping/implement/images/planting_fig1a.gif https://upload.wikimedia.org/wikipedia/commons/thumb/4/47/pikiwiki_israel_4042_almond_tree.jpg/640px-pikiwiki_israel_4042_almond_tree.jpg https://upload.wikimedia.org/wikipedia/commons/2/2a/giant_cabbage_flower_-_geograph.org.uk_-_1551584.jpg https://upload.wikimedia.org/wikipedia/commons/thumb/3/33/narcissus_gaditanus_01.jpg/637px-narcissus_gaditanus_01.jpg Kelly et al Ecology Letters 2012 Koenig et al Ecology 2015 Bixenmann et al., 2010 Chiariello Mooney and Gulmon Reich et al.