Access the full text.
Sign up today, get DeepDyve free for 14 days.
H. Laukkanen, R. Julkunen-Tiitto, A. Hohtola (1997)
Effect of different nitrogen nutrients on the viability, protein synthesis and tannin production of Scots pine callusPhysiologia Plantarum, 100
H. Claus, Z. Filip (1990)
Effects of clays and other solids on the activity of phenoloxidases produced by some fungi and actinomycetesSoil Biology & Biochemistry, 22
C. Palm, P. Sánchez (1990)
Decomposition and nutrient release patterns of the leaves of three tropical legumesBiotropica, 22
Inderjit, A. Mallik (1999)
Nutrient status of black spruce (Picea mariana [Mill.] BSP) forest soils dominated by Kalmia angustifolia L.Acta Oecologica-international Journal of Ecology, 20
R. Northup, Zengshou Yu, R. Dahlgren, K. Vogt (1995)
Polyphenol control of nitrogen release from pine litterNature, 377
A. Page, R. Miller, D. Keeney (1982)
Chemical and microbiological properties
O. Zackrisson, M. Nilsson (1992)
Allelopathic effects by Empetrumhermaphroditum on seed germination of two boreal tree speciesCanadian Journal of Forest Research, 22
A. Pind, Chris Freeman, Maurice Lock (1994)
Enzymic degradation of phenolic materials in peatlands — measurement of phenol oxidase activityPlant and Soil, 159
D. Read (2005)
The structure and function of the vegetative mycehum of ectomycorrhizal plants V. Foraging behaviour and translocation of nutrients from exploited litter
G. Bending, D. Read (1995)
The structure and function of the vegetative mycelium of ectomycorrhizal plants. VI: Activities of nutrient mobilizing enzymes in birch litter colonized by Paxillus involutus (Fr.) FrNew Phytologist, 130
C. Nichols-orians (1991)
Condensed tannins, attine ants, and the performance of a symbiotic fungusJournal of Chemical Ecology, 17
J. Oades (1988)
The retention of organic matter in soilsBiogeochemistry, 5
Robert Muller, P. Kalisz, Thomas Kimmerer (1987)
Intraspecific variation in production of astringent phenolics over a vegetation-resource availability gradientOecologia, 72
J. Horner, J. Gosz, R. Cates (1988)
The Role of Carbon-Based Plant Secondary Metabolites in Decomposition in Terrestrial EcosystemsThe American Naturalist, 132
P. Hook, I. Burke, W. Lauenroth (1991)
Heterogeneity of soil and plant N and C associated with individual plants and openings in North American shortgrass steppePlant and Soil, 138
J. Bryant, F. Chapin, D. Klein (1983)
Carbon/nutrient balance of boreal plants in relation to vertebrate herbivoryOikos, 40
J. Schimel, K. Cleve, R. Cates, Thomas Clausen, P. Reichardt (1996)
Effects of balsam poplar (Populus balsamifera) tannins and low molecular weight phenolics on microbial activity in taiga floodplain soil: implications for changes in N cycling during successionBotany, 74
L. Aguilera, J. Gutiérrez, P. Meserve (1999)
Variation in soil micro-organisms and nutrients underneath and outside the canopy of Adesmia bedwellii (Papilionaceae) shrubs in arid coastal Chile following drought and above average rainfallJournal of Arid Environments, 42
D. Whitehead, Hazel Dibb, R. Hartley (1982)
Phenolic Compounds in Soil as Influenced by the Growth of Different Plant SpeciesJournal of Applied Ecology, 19
R. Northup, R. Dahlgren, Zengshou Yu (1995)
Intraspecific variation of conifer phenolic concentration on a marine terrace soil acidity gradient; a new interpretationPlant and Soil, 171
J. Koricheva, S. Larsson, E. Haukioja, M. Keinänen (1998)
Regulation of Woody Plant Secondary Metabolism by Resource Availability: Hypothesis Testing by Means of Meta-AnalysisOikos, 83
D. Nelson, L. Sommers (1982)
Total Carbon, Organic Carbon, and Organic Matter 1
G. Farquhar, J. Ehleringer, K. Hubick (1989)
Carbon Isotope Discrimination and Photosynthesis, 40
H. Kowarzyk (1910)
Structure and Function.Nature, 84
V. Nicolai (1988)
Phenolic and mineral content of leaves influences decomposition in European forest ecosystemsOecologia, 75
(1996)
Soil sampling, preparations and analysis
(1984)
Allelopathy, 2nd edn
R. Northup, R. Dahlgren, J. Mccoll (1998)
Polyphenols as Regulators of Plant-litter-soil Interactions in Northern California's Pygmy Forest: A Positive Feedback?Biogeochemistry, 42
A. Kuiters (1990)
Role of phenolic substances from decomposing forest litter in plant–soil interactions, 39
Athanassios Boufalis, F. Pellissier (1994)
Allelopathic effects of phenolic mixtures on respiration of two spruce mycorrhizal fungiJournal of Chemical Ecology, 20
U. Blum (1998)
Effects of Microbial Utilization of Phenolic Acids and their Phenolic Acid Breakdown Products on Allelopathic InteractionsJournal of Chemical Ecology, 24
N. Fierer, J. Schimel, R. Cates, Jiping Zou (2001)
Influence of balsam poplar tannin fractions on carbon and nitrogen dynamics in Alaskan taiga floodplain soilsSoil Biology & Biochemistry, 33
S. Shafer, U. Blum (1991)
Influence of Phenolic acids on microbial populations in the rhizosphere of cucumberJournal of Chemical Ecology, 17
J. Hamilton, A. Zangerl, E. DeLucia, M. Berenbaum (2001)
The carbon–nutrient balance hypothesis: its rise and fallEcology Letters, 4
U. Blum, S. Shafer (1988)
Microbial populations and phenolic acids in soilSoil Biology & Biochemistry, 20
J. Glyphis, G. Puttick (1989)
Phenolics, nutrition and insect herbivory in some garrigue and maquis plant speciesOecologia, 78
S. Sugai, J. Schimel (1993)
Decomposition and biomass incorporation of 14c-labeled glucose and phenolics in taiga forest floor: effect of substrate quality, successional state, and seasonSoil Biology & Biochemistry, 25
G. Sparling, B. Ord, D. Vaughan (1981)
Changes in microbial biomass and activity in soils amended with phenolic acidsSoil Biology & Biochemistry, 13
(1973)
Sur une m thode de fractionnement et d’estimation des compos s ph noliques chez les v g taux
M. Vinton, I. Burke (1995)
INTERACTIONS BETWEEN INDIVIDUAL PLANT SPECIES AND SOIL NUTRIENT STATUS IN SHORTGRASS STEPPEEcology, 76
P. Feeny (1970)
SEASONAL CHANGES IN OAK LEAF TANNINS AND NUTRIENTS AS A CAUSE OF SPRING FEEDING BY WINTER MOTH CATERPILLARSEcology, 51
I. Schmidt, A. Michelsen, S. Jonasson (1997)
Effects of labile soil carbon on nutrient partitioning between an arctic graminoid and microbesOecologia, 112
P. Waterman, S. Mole (1994)
Analysis of Phenolic Plant Metabolites
D. Herms, W. Mattson (1992)
The Dilemma of Plants: To Grow or DefendThe Quarterly Review of Biology, 67
J. Leake, D. Read (1990)
Proteinase activity in mycorrhizal fungi: I. The effect of extracellular pH on the production and activity of proteinase by ericoid endophytes from soils of contrasted pH.The New phytologist, 115 2
J. Leake, D. Read (1991)
Proteinase activity in mycorrhizal fungi III.New Phytologist, 117
H. Appel (1993)
Phenolics in ecological interactions: The importance of oxidationJournal of Chemical Ecology, 19
C. Tang, Wei Cai, K. Kohl, R. Nishimoto (1994)
Plant Stress and Allelopathy
P. Coley, J. Bryant, F. Chapin (1985)
Resource Availability and Plant Antiherbivore DefenseScience, 230
Stephan Hättenschwiler, P. Vitousek (2000)
The role of polyphenols in terrestrial ecosystem nutrient cycling.Trends in ecology & evolution, 15 6
J. Gershenzon (1984)
Changes in the Levels of Plant Secondary Metabolites Under Water and Nutrient Stress
The effects of the Mediterranean shrub Cistus albidus on N cycling were studied in two siliceous (granitic-derived and schistic-derived) and one calcareous soil differentiated by their texture and acidity. We aimed to find out whether soils under C. albidus were affected by the release of C compounds from the canopy, and whether phenolic compound production in C. albidus changed depending on the soil N availability. Calcareous soils, with higher clay content and polyvalent cations, had a higher organic matter content but lower net N mineralization rates than siliceous soils, and C. albidus growing therein were characterized by lower foliar N and phenolic compound concentrations. Under C. albidus, all types of soils had higher phenolic compound concentrations and polyphenol oxidase activity. C. albidus presence and leachate addition decreased net N mineralization and increased soil respiration in siliceous soils, and these changes were related to a higher soil C/N ratio under the canopy. In calcareous soils, however, no significant effects of plant presence on N cycling were found. In the studied plant-soil system it is not likely that higher phenolic compound concentrations were selected during evolution to enhance nutrient conservation in soil because (1) higher phenolic compound concentrations were not associated with lower soil fertilities, (2) C compounds released from C. albidus accelerated N cycling by increasing N immobilization and no evidence was found for decreased gross N mineralization, and (3) soil organic N content was more related to soil chemical and physical properties than to the effects of the C. albidus canopy.
Oecologia – Springer Journals
Published: Apr 15, 2003
Read and print from thousands of top scholarly journals.
Already have an account? Log in
Bookmark this article. You can see your Bookmarks on your DeepDyve Library.
To save an article, log in first, or sign up for a DeepDyve account if you don’t already have one.
Copy and paste the desired citation format or use the link below to download a file formatted for EndNote
Access the full text.
Sign up today, get DeepDyve free for 14 days.
All DeepDyve websites use cookies to improve your online experience. They were placed on your computer when you launched this website. You can change your cookie settings through your browser.