Your search keyword '"Ian J, Wright"' showing total 5 results

1. Corrigendum to: New handbook for standardised measurement of plant functional traits worldwide

Author

Eric Garnier, Peter B. Reich, Joseph M. Craine, Fabien Quétier, Guillermo Funes, Carlos Urcelay, H. D. Morgan, Lucas Enrico, Juli G. Pausas, Ian J. Wright, Sandra Díaz, A. C. de Vos, Sandra Lavorel, S. Aquino, Lourens Poorter, John G. Hodgson, Natalia Pérez-Harguindeguy, P. Ray, Lawren Sack, Hendrik Poorter, Nina Buchmann, Diego E. Gurvich, M.S. Bret-Harte, Pedro Jaureguiberry, Ken Thompson, William K. Cornwell, H. ter Steege, Benjamin Blonder, Erik J. Veneklaas, A. C. Staver, Johannes H. C. Cornelissen, Georgina Conti, Maria Victoria Vaieretti, and Peter Poschlod

Subjects

0106 biological sciences, Environmental change, Ecology, Range (biology), Forest management, Biodiversity, Plant Science, Biology, 010603 evolutionary biology, 01 natural sciences, Plant ecology, Botany, Trait, Ecosystem, Ecology, Evolution, Behavior and Systematics, 010606 plant biology & botany, Trophic level

Abstract

Plant functional traits are the features (morphological, physiological, phenological) that represent ecological strategies and determine how plants respond to environmental factors, affect other trophic levels and influence ecosystem properties. Variation in plant functional traits, and trait syndromes, has proven useful for tackling many important ecological questions at a range of scales, giving rise to a demand for standardised ways to measure ecologically meaningful plant traits. This line of research has been among the most fruitful avenues for understanding ecological and evolutionary patterns and processes. It also has the potential both to build a predictive set of local, regional and global relationships between plants and environment and to quantify a wide range of natural and human-driven processes, including changes in biodiversity, the impacts of species invasions, alterations in biogeochemical processes and vegetation–atmosphere interactions. The importance of these topics dictates the urgent need for more and better data, and increases the value of standardised protocols for quantifying trait variation of different species, in particular for traits with power to predict plant- and ecosystem-level processes, and for traits that can be measured relatively easily. Updated and expanded from the widely used previous version, this handbook retains the focus on clearly presented, widely applicable, step-by-step recipes, with a minimum of text on theory, and not only includes updated methods for the traits previously covered, but also introduces many new protocols for further traits. This new handbook has a better balance between whole-plant traits, leaf traits, root and stem traits and regenerative traits, and puts particular emphasis on traits important for predicting species' effects on key ecosystem properties. We hope this new handbook becomes a standard companion in local and global efforts to learn about the responses and impacts of different plant species with respect to environmental changes in the present, past and future.

Published

2016

2. Why are non-photosynthetic tissues generally 13C enriched compared with leaves in C3 plants? Review and synthesis of current hypotheses

Author

David G. Williams, Claudia Keitel, Guillaume Tcherkez, Lucas A. Cernusak, Todd E. Dawson, Graham D. Farquhar, William K. Cornwell, Peter B. Reich, Howard Griffiths, David S. Ellsworth, Margaret M. Barbour, Alexander Knohl, Ian J. Wright, and Louis S. Santiago

Subjects

Ecophysiology, Respiration, Botany, Carbon fixation, Heterotroph, food and beverages, Plant Science, Biology, Herbaceous plant, Photosynthesis, Phosphoenolpyruvate carboxylase, Agronomy and Crop Science, Woody plant

Abstract

Non-photosynthetic, or heterotrophic, tissues in C3 plants tend to be enriched in 13C compared with the leaves that supply them with photosynthate. This isotopic pattern has been observed for woody stems, roots, seeds and fruits, emerging leaves, and parasitic plants incapable of net CO2 fixation. Unlike in C3 plants, roots of herbaceous C4 plants are generally not 13C-enriched compared with leaves. We review six hypotheses aimed at explaining this isotopic pattern in C3 plants: (1) variation in biochemical composition of heterotrophic tissues compared with leaves; (2) seasonal separation of growth of leaves and heterotrophic tissues, with corresponding variation in photosynthetic discrimination against 13C; (3) differential use of day v. night sucrose between leaves and sink tissues, with day sucrose being relatively 13C-depleted and night sucrose 13C-enriched; (4) isotopic fractionation during dark respiration; (5) carbon fixation by PEP carboxylase; and (6) developmental variation in photosynthetic discrimination against 13C during leaf expansion. Although hypotheses (1) and (2) may contribute to the general pattern, they cannot explain all observations. Some evidence exists in support of hypotheses (3) through to (6), although for hypothesis (6) it is largely circumstantial. Hypothesis (3) provides a promising avenue for future research. Direct tests of these hypotheses should be carried out to provide insight into the mechanisms causing within-plant variation in carbon isotope composition.

Published

2009

3. Short Communication: Leaf trait relationships in Australian plant species

Author

Byron B. Lamont, E.-D. Schulze, Peter B. Reich, Erik J. Veneklaas, Mark Westoby, Ian J. Wright, Pieter Poot, Philip K. Groom, and Lynda D. Prior

Subjects

Taxon, Perennial plant, Habitat, Specific leaf area, Ecology, Range (biology), Sclerophyll, fungi, Trait, Plant Science, Biology, Agronomy and Crop Science, Photosynthetic capacity

Abstract

Leaf trait data were compiled for 258 Australian plant species from several habitat types dominated by woody perennials. Specific leaf area (SLA), photosynthetic capacity, dark respiration rate and leaf nitrogen (N) and phosphorus (P) concentrations were positively correlated with one another and negatively correlated with average leaf lifespan. These trait relationships were consistent with previous results from global datasets. Together, these traits form a spectrum of variation running from species with cheap but frequently replaced leaves to those with strategies more attuned to a nutrient-conserving lifestyle. Australian species tended to have SLAs at the lower end of the spectrum, as expected in a dataset dominated by sclerophyllous species from low fertility or low rainfall sites. The existence of broad-scale, 'global' relationships does not imply that the same trait relationships will always be observed in small datasets. In particular, the probability of observing concordant patterns depends on the range of trait variation in a dataset, which, itself, may vary with sample size or species-sampling properties such as the range of growth forms, plant functional 'types', or taxa included in a particular study. The considerable scatter seen in these broad-scale trait relationships may be associated with climate, physiology and phylogeny.

Published

2004

4. Geographic Variation in Eucalyptus diversifolia (Myrtaceae) and the Recognition of New Subspecies E. diversifolia subsp. hesperia and E. diversifolia subsp. megacarpa

Author

Pauline Y. Ladiges and Ian J. Wright

Subjects

Taxon, Plant genetics, Botany, Myrtaceae, Systematic Botany, Plant Science, Biology, Subspecies, Disjunct, Eucalyptus diversifolia, Plant taxonomy, biology.organism_classification, Ecology, Evolution, Behavior and Systematics

Abstract

Patterns of geographic variation in morphological and chemical characters are documented in Eucalyptus diversifolia Bonpl. (soap mallee, white coastal mallee). This species is found in coastal and subcoastal Australia from southern Western Australia to Cape Nelson (western Victoria), with a number of disjunctions in the intervening region. Morphological data from adult plants collected at field localities and seedlings grown under uniform conditions were analysed using univariate and multivariate methods, including oneway ANOVA, multiple comparison tests, non-metric multidimensional scaling (NMDS), nearest neighbour networks, and minimum spanning trees. Seedling material was tested for isozyme polymorphism, and adult leaf flavonoids were analysed using liquid chromatography. Morphological and chemical characters are also documented in E. aff. diversifolia, a closely related but unnamed taxon restricted to ironstone outcrops near Norseman (WA), and putative E. diversifolia- E. baxteri hybrids from Cape Nelson. Congruent patterns in data sets distinguish three groups of E. diversifolia adults and progeny: (1) those to the west of the Nullarbor disjunction; (2) South Australian populations to the east of this disjunction; and (3) those from Cape Nelson. Formal taxonomic recognition of the three forms at subspecific level is established, namely E. diversifolia subsp. diversifolia, E. diversifolia subsp. hesperia, and E. diversifolia subsp. megacarpa. Patterns of geographic affinity between populations are consistent with a hypothesis of genetic exchange between normally disjunct regional populations of E. diversifolia via coastal land-bridges exposed during periodic times of low sea level since the mid Tertiary.

Published

1997

5. Why are non-photosynthetic tissues generally 13C enriched compared with leaves in C3 plants? Review and synthesis of current hypotheses.

Author

Lucas A. Cernusak, Guillaume Tcherkez, Claudia Keitel, William K. Cornwell, Louis S. Santiago, Alexander Knohl, Margaret M. Barbour, David G. Williams, Peter B. Reich, David S. Ellsworth, Todd E. Dawson, Howard G. Griffiths, Graham D. Farquhar, and Ian J. Wright

Subjects

PLANT cells & tissues, CARBON isotopes, PHOTOSYNTHATES, LEAF physiology, CARBON dioxide adsorption, PLANT variation

Abstract

Non-photosynthetic, or heterotrophic, tissues in C3plants tend to be enriched in 13C compared with the leaves that supply them with photosynthate. This isotopic pattern has been observed for woody stems, roots, seeds and fruits, emerging leaves, and parasitic plants incapable of net CO2fixation. Unlike in C3plants, roots of herbaceous C4plants are generally not 13C-enriched compared with leaves. We review six hypotheses aimed at explaining this isotopic pattern in C3plants: (1) variation in biochemical composition of heterotrophic tissues compared with leaves; (2) seasonal separation of growth of leaves and heterotrophic tissues, with corresponding variation in photosynthetic discrimination against 13C; (3) differential use of day v. night sucrose between leaves and sink tissues, with day sucrose being relatively 13C-depleted and night sucrose 13C-enriched; (4) isotopic fractionation during dark respiration; (5) carbon fixation by PEP carboxylase; and (6) developmental variation in photosynthetic discrimination against 13C during leaf expansion. Although hypotheses (1) and (2) may contribute to the general pattern, they cannot explain all observations. Some evidence exists in support of hypotheses (3) through to (6), although for hypothesis (6) it is largely circumstantial. Hypothesis (3) provides a promising avenue for future research. Direct tests of these hypotheses should be carried out to provide insight into the mechanisms causing within-plant variation in carbon isotope composition. [ABSTRACT FROM AUTHOR]

Published

2009