C3 grasses have higher nutritional quality than C4 grasses under ambient and elevated atmospheric CO2
暂无分享,去创建一个
[1] D. Lincoln,et al. Antiherbivore defense mutualism under elevated carbon dioxide levels : A fungal endophyte and grass , 1996 .
[2] J. Reid,et al. Reserve Polysaccharides Other Than Starch in Higher Plants , 1982 .
[3] B. Tyler,et al. Incidence of endophytes in seeds from collections of Lolium and Festuca species , 1987 .
[4] W. J. Mattson,et al. Herbivory in relation to plant nitrogen content , 1980 .
[5] J. Scheirs,et al. A TEST OF THE C3-C4 HYPOTHESIS WITH TWO GRASS MINERS , 2001 .
[6] W. Laetsch. The C4 Syndrome: A Structural Analysis , 1974 .
[7] A. Erhardt,et al. IN SITU DEVELOPMENT OF A SATYRID BUTTERFLY ON CALCAREOUS GRASSLAND EXPOSED TO ELEVATED CARBON DIOXIDE , 2002 .
[8] S. N. Stephenson,et al. Photosynthetic Pathways and Selective Herbivory: A Hypothesis , 1973, The American Naturalist.
[9] B. Drake,et al. MORE EFFICIENT PLANTS: A Consequence of Rising Atmospheric CO2? , 1997, Annual review of plant physiology and plant molecular biology.
[10] W. Ruhland. Encyclopedia of plant physiology. , 1958 .
[11] C. Jones,et al. Biosynthesis of plant phenolic compounds in elevated atmospheric CO2 , 2000 .
[12] J. Nagy,et al. Influence of enhanced CO2 concentration and irrigation on sudangrass digestibility , 1994 .
[13] C. Körner,et al. Soil moisture effects determine CO2 responses of grassland species , 2000, Oecologia.
[14] E. Kellogg,et al. Growth Responses of C4Grasses of Contrasting Origin to Elevated CO2 , 1999 .
[15] H. W. Hunt,et al. The response of mycorrhizal colonization to elevated CO2 and climate change in Pascopyrum smithii and Bouteloua gracilis , 1994, Plant and Soil.
[16] E. Bernays,et al. Relative nutritional quality of C3 and C4 grasses for a graminivorous lepidopteran, Paratrytone melane (Hesperiidae) , 1992, Oecologia.
[17] R. Barbehenn. Measurement of protein in whole plant samples with ninhydrin , 1995 .
[18] C. J. Nelson,et al. Secondary cell wall deposition causes radial growth of fibre cells in the maturation zone of elongating tall fescue leaf blades. , 2002, Annals of botany.
[19] F. Bazzaz,et al. The response of plants to elevated CO2 , 1984, Oecologia.
[20] Donald L. DeAngelis,et al. The global carbon cycle. , 1990 .
[21] K. Milton,et al. Nitrogen-to-protein conversion factors for tropical plant samples , 1981 .
[22] R. Barbehenn,et al. Performance of a generalist grasshopper on a C3 and a C4 grass: compensation for the effects of elevated CO2 on plant nutritional quality , 2004, Oecologia.
[23] S. Wand,et al. Responses of wild C4 and C3 grass (Poaceae) species to elevated atmospheric CO2 concentration: a meta‐analytic test of current theories and perceptions , 1999 .
[24] E. Bernays,et al. Head size and shape in relation to grass feeding in Acridoidea (Orthoptera) , 1987 .
[25] J. Ehleringer,et al. Digestion and passage rates of grass hays by llamas, alpacas, goats, rabbits, and horses , 2003 .
[26] A. J. Cairns,et al. Fructan metabolism in grasses and cereals , 1991 .
[27] J. Roy,et al. The effect of elevated CO2 on the chemical composition and construction costs of leaves of 27 C3 species , 1997 .
[28] J. Ehleringer,et al. Atmospheric CO2 as a Global Change Driver Influencing Plant-Animal Interactions1 , 2002, Integrative and comparative biology.
[29] P. Lucas,et al. Leaf fracture toughness and sclerophylly: their correlations and ecological implications , 1992 .
[30] A. Crane. Possible effects of rising C02 on climate , 1985 .
[31] M. V. D. van der Heijden,et al. Arbuscular mycorrhizal fungi influence life history traits of a lepidopteran herbivore , 2000, Oecologia.
[32] R. Barbehenn. Silicon: an indigestible marker for measuring food consumption and utilization by insects , 1993 .
[33] J. Morgan,et al. Growth, gas exchange, leaf nitrogen and carbohydrate concentrations in NAD-ME and NADP-ME C4 grasses grown in elevated CO2 , 1998 .
[34] A. Knapp,et al. 9 – Ecosystem-Level Responses of Tallgrass Prairie to Elevated CO2 , 1996 .
[35] W. R. Windham,et al. Influence of Leaf Anatomy on the Dry Matter Digestibility of C3, C4, and C3/C4 Intermediate Types of Panicum Species1 , 1983 .
[36] D. H. Seimens,et al. Species-Specific Response of Glucosinolate Content to Elevated Atmospheric CO2 , 1997, Journal of Chemical Ecology.
[37] K. H. Asay,et al. Carbohydrate Partitioning in 185 Accessions of Gramineae Grown Under Warm and Cool Temperatures , 1989 .
[38] G. O. Batzli,et al. The integrated processing response of voles to fibre content of natural diets , 1998 .
[39] P. Leadley,et al. An open top chamber for field studies of elevated atmospheric CO2 concentration on saltmarsh vegetation , 1989 .
[40] D. Hendrix. Rapid Extraction and Analysis of Nonstructural Carbohydrates in Plant Tissues , 1993 .
[41] T. Sharkey,et al. Effects of CO2 enrichment on four Great Basin grasses , 1987 .
[42] W. Wright,et al. A comparative study of the fracture properties of five grasses , 1995 .
[43] H. Allred,et al. Conservation, Development, and Use of the World's Rangelands. , 1968 .
[44] P. V. Soest. Nutritional Ecology of the Ruminant , 1994 .
[45] R. Barbehenn,et al. Effects of elevated atmospheric CO2 on the nutritional ecology of C3 and C4 grass-feeding caterpillars , 2004, Oecologia.
[46] J. Scheirs,et al. A Test of the C 3 -C 4 Hypothesis with Two Grass Miners , 2001 .
[47] P. V. Soest,et al. Methods for dietary fiber, neutral detergent fiber, and nonstarch polysaccharides in relation to animal nutrition. , 1991, Journal of dairy science.
[48] W. R. Windham,et al. Effect of free-air CO2 enrichment (FACE) on forage quality of wheat , 1995 .
[49] D. Lincoln,et al. Plant-insect herbivore interactions in elevated CO(2) environments. , 1993, Trends in ecology & evolution.
[50] J. A. Teeri,et al. Climatic patterns and the distribution of C4 grasses in North America , 1976, Oecologia.
[51] H. Mooney,et al. 7 – CO2-Mediated Changes in Tree Chemistry and Tree-Lepidoptera Interactions , 1996 .
[52] Dale M. Smith. INFLUENCE OF DRYING AND STORAGE CONDITIONS ON NONSTRUCTURAL CARBOHYDRATE ANALYSIS OF HERBAGE TISSUE—A REVIEW , 1973 .
[53] Hendrik Poorter. Interspecific variation in the growth response of plants to an elevated ambient CO2 concentration , 2004, Vegetatio.
[54] M. Press,et al. Elevated CO2 Induces Biochemical and Ultrastructural Changes in Leaves of the C4 Cereal Sorghum , 2000 .
[55] D. D. Wolf,et al. Respiration during Drying of Alfalfa Herbage1 , 1973 .
[56] B. Strain,et al. Effect of carbon dioxide enrichment on chlorophyll content, starch content and starch grain structure in Trifolium subterraneum leaves , 1981 .
[57] B. Kimball,et al. Increased Accumulation of Carbohydrates and Decreased Photosynthetic Gene Transcript Levels in Wheat Grown at an Elevated CO2 Concentration in the Field , 1995, Plant physiology.
[58] J. M. Scriber. Limiting effects of low leaf-water content on the nitrogen utilization, energy budget, and larval growth ofHyalophora cecropia (Lepidoptera: Saturniidae) , 1977, Oecologia.
[59] H. Thomas. Enzymes of nitrogen mobilization in detached leaves of Lolium temulentum during senescence , 2004, Planta.