An experimental test of the hypothesis of non-homeostatic consumer stoichiometry in a plant litter-microbe system.
about
(A)synchronous Availabilities of N and P Regulate the Activity and Structure of the Microbial Decomposer CommunityTradeoffs in microbial carbon allocation may mediate soil carbon storage in future climates.Soil microbial and nutrient responses to 7 years of seasonally altered precipitation in a Chihuahuan Desert grassland.Flexible Carbon-Use Efficiency across Litter Types and during Decomposition Partly Compensates Nutrient Imbalances-Results from Analytical Stoichiometric Models.Comparing the Ecological Stoichiometry in Green and Brown Food Webs - A Review and Meta-analysis of Freshwater Food WebsStoichiometric flexibility in diverse aquatic heterotrophic bacteria is coupled to differences in cellular phosphorus quotas.Leaf Litter Chemistry Drives the Structure and Composition of Soil Testate Amoeba Communities in a Tropical Montane Rainforest of the Ecuadorian Andes.Resource stoichiometry and availability modulate species richness and biomass of tropical litter macro-invertebrates.Stoichiometry patterns in the androdioecious Acer tegmentosum.Stoichiometric imbalances between terrestrial decomposer communities and their resources: mechanisms and implications of microbial adaptations to their resources.Environmental microbiology as a mosaic of explored ecosystems and issues.A genomic perspective on stoichiometric regulation of soil carbon cycling.Land-use and soil depth affect resource and microbial stoichiometry in a tropical mountain rainforest region of southern Ecuador.Aquatic heterotrophic bacteria have highly flexible phosphorus content and biomass stoichiometry.Stoichiometric plasticity of microbial communities is similar between litter and soil in a tropical rainforestLeaf and root C-to-N ratios are poor predictors of soil microbial biomass C and respiration across 32 tree species.Optimal metabolic regulation along resource stoichiometry gradients.Changes in nutrient stoichiometry, elemental homeostasis and growth rate of aquatic litter-associated fungi in response to inorganic nutrient supply.Dietary and taxonomic controls on incorporation of microbial carbon and phosphorus by detritivorous caddisflies.Rhizosphere stoichiometry: are C : N : P ratios of plants, soils, and enzymes conserved at the plant species-level?C, N and P fertilization in an Amazonian rainforest supports stoichiometric dissimilarity as a driver of litter diversity effects on decomposition.Applying foliar stoichiometric traits of plants to determine fertilization for a mixed pine-oak stand in the Qinling Mountains, China.Direct and legacy effects of plant-traits control litter decomposition in a deciduous oak forest in Mexico.Nutrient limitation of soil microbial processes in tropical forestsAbove- and belowground linkages of a nitrogen and phosphorus co-limited tropical mountain pasture system – responses to nutrient enrichmentStoichiometry of microbial carbon use efficiency in soilsDecay rates of leaf litters from arbuscular mycorrhizal trees are more sensitive to soil effects than litters from ectomycorrhizal treesStage-specific response of litter decomposition to N and S amendments in a subtropical forest soil
P2860
Q28603185-C459B51C-06C4-4F39-932C-B522F26F0ED1Q30666399-A166BAFB-1158-43A1-9236-F65A8E07E828Q30675871-0DE0B865-411F-40EA-AA80-8329D21391D7Q33603550-88716C2A-76DE-4641-BB87-9A8915C514E4Q33849341-5FA00558-99A2-452B-A555-5C1347199553Q35128516-9B4983D8-D800-4CDF-A108-4A265F21E6D6Q36340621-9610384E-FCA1-40F0-A0FE-43640847E291Q36371893-52D4E17A-8B14-4160-971C-E658D5F37FBBQ37325426-0BB6FFEF-045D-4A23-865E-BCF78D1FE011Q38189355-F967E51C-E91B-41BD-A4D8-A47753585FF6Q38574523-AD8C04F1-696D-493E-96DC-61D5796510EEQ38668210-1499045D-012F-4492-BA32-87F8B2C77DA4Q39525956-2DF73B2C-C750-4AE6-A5EC-4C4D27499FA9Q41179357-44C65586-2EE4-49BD-A3AD-7AFAA80975FDQ42040078-A8415B2A-B12B-4FF4-883A-2F90DCDDEEDAQ46245643-259C07F3-9722-4195-B268-D130B6BDF2E7Q46328755-25C54F6F-83D3-4FD4-9E4F-7B2857E726F8Q46332699-2D720B6D-8AF2-42EF-9463-1BEC130766F4Q46649561-6DDCAB26-F9ED-4183-8314-B4AF4FAA648BQ46983981-0269F1A0-C607-427F-99BC-ABFCCB863F77Q51401509-74BC9D90-1A16-43E5-B6BC-C664BAF8EA9EQ55344598-A75E111B-ECED-47BB-8A72-5A359BCAB757Q55517031-0C12DB9F-D627-4CD6-AE24-6D33C23C8A22Q57012698-61EB2757-6146-4F5D-AB8F-65893574D2BEQ57012841-24D83E59-F623-43C4-BCB4-39FF3803BB7EQ57249858-DC6E3C78-1FAC-446E-9E88-89A384488AF9Q58319894-D6AE31A2-DEBC-4753-BDBB-C6134C2E7F4CQ58463901-87EFDCE3-3A48-49C2-8A78-C6B4C537CF07
P2860
An experimental test of the hypothesis of non-homeostatic consumer stoichiometry in a plant litter-microbe system.
description
2013 nî lūn-bûn
@nan
2013年の論文
@ja
2013年学术文章
@wuu
2013年学术文章
@zh
2013年学术文章
@zh-cn
2013年学术文章
@zh-hans
2013年学术文章
@zh-my
2013年学术文章
@zh-sg
2013年學術文章
@yue
2013年學術文章
@zh-hant
name
An experimental test of the hy ...... a plant litter-microbe system.
@en
An experimental test of the hy ...... a plant litter-microbe system.
@nl
type
label
An experimental test of the hy ...... a plant litter-microbe system.
@en
An experimental test of the hy ...... a plant litter-microbe system.
@nl
prefLabel
An experimental test of the hy ...... a plant litter-microbe system.
@en
An experimental test of the hy ...... a plant litter-microbe system.
@nl
P2093
P356
P1433
P1476
An experimental test of the hy ...... a plant litter-microbe system.
@en
P2093
Bruno Buatois
Nicolas Fanin
Stephan Hättenschwiler
P304
P356
10.1111/ELE.12108
P407
P577
2013-03-25T00:00:00Z