about
Evolutionary context for understanding and manipulating plant responses to past, present and future atmospheric [CO2How do leaf veins influence the worldwide leaf economic spectrum? Review and synthesisInfluences of environmental factors on leaf morphology of Chinese jujubesAn evolutionary perspective on leaf economics: phylogenetics of leaf mass per area in vascular plantsA fully traits-based approach to modeling global vegetation distribution.Inferring Bounded Evolution in Phenotypic Characters from Phylogenetic Comparative Data.Sensitive Indicators of Zonal Stipa Species to Changing Temperature and Precipitation in Inner Mongolia Grassland, ChinaBiogeography of species richness gradients: linking adaptive traits, demography and diversification.Leaf mass per area is independent of vein length per area: avoiding pitfalls when modelling phenotypic integration (reply to Blonder et al. 2014).A common genetic basis to the origin of the leaf economics spectrum and metabolic scaling allometry.Experimental evidence that the Ornstein-Uhlenbeck model best describes the evolution of leaf litter decomposability.Resource-use strategies of native and invasive plants in Eastern North American forests.Species adaptive strategies and leaf economic relationships across serpentine and non-serpentine habitats on Lesbos, eastern Mediterranean.Using Plant Functional Traits and Phylogenies to Understand Patterns of Plant Community Assembly in a Seasonal Tropical Forest in Lao PDR.Leaf economics of evergreen and deciduous tree species along an elevational gradient in a subtropical mountainConvergent production and tolerance among 107 woody species and divergent production between shrubs and trees.Plant chemical defense allocation constrains evolution of tolerance to community change across a range boundaryUsing phylogeny and functional traits for assessing community assembly along environmental gradients: A deterministic process driven by elevation.Economic and hydraulic divergences underpin ecological differentiation in the Bromeliaceae.Adaptive differentiation of traits related to resource use in a desert annual along a resource gradient.Highly local environmental variability promotes intrapopulation divergence of quantitative traits: an example from tropical rain forest trees.Improvement of crop yield in dry environments: benchmarks, levels of organisation and the role of nitrogen.A worldview of root traits: the influence of ancestry, growth form, climate and mycorrhizal association on the functional trait variation of fine-root tissues in seed plants.Inclusion of vein traits improves predictive power for the leaf economic spectrum: a response to Sack et al. (2013).Phylogenetic structural equation modelling reveals no need for an 'origin' of the leaf economics spectrum.Long-term impact of Ophiostoma novo-ulmi on leaf traits and transpiration of branches in the Dutch elm hybrid 'Dodoens'.Testing models for the leaf economics spectrum with leaf and whole-plant traits in Arabidopsis thaliana.Changes in specific leaf area of dominant plants in temperate grasslands along a 2500-km transect in northern China.Predicting the establishment success of introduced target species in grassland restoration by functional traitsDoes investment in leaf defenses drive changes in leaf economic strategy? A focus on whole-plant ontogeny.The physiological basis for genetic variation in water use efficiency and carbon isotope composition in Arabidopsis thaliana.Novel evidence for within-species leaf economics spectrum at multiple spatial scales.Leaf traits within communities: context may affect the mapping of traits to function.Ontogeny strongly and differentially alters leaf economic and other key traits in three diverse Helianthus species.Evolution of the leaf economics spectrum in herbs: Evidence from environmental divergences in leaf physiology across Helianthus (Asteraceae).Independent genetic control of maize (Zea mays L.) kernel weight determination and its phenotypic plasticity.Stomatal Biology of CAM Plants.The evolutionary ecology of roots.Ecological interactions and the fitness effect of water-use efficiency: Competition and drought alter the impact of natural MPK12 alleles in Arabidopsis.A broader perspective on plant domestication and nutrient and carbon cycling.
P2860
Q27003923-702276C1-54C5-4AE7-9395-715C160113F4Q27010469-40D9DE71-A60F-4652-AD38-397EDCCD5553Q28646897-064F86C6-3EF8-4312-A759-23B699A88093Q28654619-CA7A7ABF-D8D3-4171-A720-CBA8A79BBAA0Q30851768-CBF00C0F-2B14-4AB6-96FD-5357A9A1B6BCQ31044215-0C78D984-3B58-49E0-86CB-4E62B8640C42Q31048377-4B9633A3-0B97-402F-8952-CAF6952F333BQ34086939-73594E8B-EAE6-4EC9-9F23-666428DE7570Q34149470-6C79D636-B117-4BB6-BC14-E7AA64E8C097Q34362728-03B72AE9-0C5F-4DC6-AF59-E9F32DDD7865Q34494763-C959CD11-9D2E-4F3B-A555-5C3946E8678BQ34787726-F9916385-AB7E-4B5B-9EB3-F4F397B44580Q35163606-5E2F84B5-1D87-4B95-81A2-1F33CB238E5FQ35675816-B7AFF334-6259-4C8A-834C-294D06297BC3Q36063165-0F5310EC-26E3-460A-8860-4F039E5C77FDQ36555550-5F08FCAB-877A-4589-BEB6-56AAC8CADF29Q37377224-2A15CC4C-3B38-4622-BA8D-009D09473DC2Q38645477-492CC0C1-5DAA-4965-9EC4-E18E62795708Q38873698-D921C285-0A73-4A28-AF84-262325F022A6Q38922519-61519795-E2BB-44D9-8FC3-B757AFBB1585Q38922561-76072B6D-6387-4DCB-8411-E831F2A87327Q39419216-D28808B1-F72E-4CD3-BA86-7A00737027C6Q39546886-BD409EB0-4229-4CF7-A6C0-1526853CFEF2Q39720985-6D50AD24-AA83-439E-89E0-4A108585CBE6Q40326254-FE88967F-93E2-4C92-92D1-DD346F4CBAA2Q40350150-D7D3525F-6DE7-4FDF-B4E8-659AAEBD132BQ40957909-DE46249F-A6F8-4281-B289-A1D815D41837Q41545612-1446C033-72CB-44CE-9BFB-785BB3E3174DQ41696027-BAA8A914-A3E8-4A40-A1E6-0E4645BF982EQ41722223-571A25D5-54F0-4DA7-85A6-B5325CF09D40Q41867173-291A21C6-C690-4DD7-9C28-83BABC7B433BQ42180468-EC0A40E2-B8E3-4836-8D83-435507F42AF1Q44505446-604FDF33-36EA-4DA4-A321-437E19844F3AQ45360245-1CA9164A-F733-4C4B-BB5E-D11AF76E07CDQ46674313-7AE9C292-2010-434C-83C9-51CBDE1C3B46Q47172072-B45C53D4-2657-46D9-B003-1A2B2AD09526Q48189090-A470C7F2-AF9C-4592-9443-3F17D827630BQ51147589-259287ED-6A8D-4E35-8916-73143DAA7742Q51154192-0F07DE4F-2E92-4CAA-A218-C2CC8F50F6D2Q51534786-5011F4BE-F5F2-415C-B218-304338C08C79
P2860
description
article científic
@ca
article scientifique
@fr
articolo scientifico
@it
artigo científico
@pt
bilimsel makale
@tr
scientific article published on 31 December 2010
@en
vedecký článok
@sk
vetenskaplig artikel
@sv
videnskabelig artikel
@da
vědecký článek
@cs
name
The evolution of the worldwide leaf economics spectrum.
@en
The evolution of the worldwide leaf economics spectrum.
@nl
type
label
The evolution of the worldwide leaf economics spectrum.
@en
The evolution of the worldwide leaf economics spectrum.
@nl
prefLabel
The evolution of the worldwide leaf economics spectrum.
@en
The evolution of the worldwide leaf economics spectrum.
@nl
P2093
P50
P1476
The evolution of the worldwide leaf economics spectrum.
@en
P2093
Hafiz Maherali
Hans de Kroon
Heidrun Huber
P356
10.1016/J.TREE.2010.11.011
P577
2010-12-31T00:00:00Z