Direct nocturnal water transfer from oaks to their mycorrhizal symbionts during severe soil drying.
about
The fungal fast lane: common mycorrhizal networks extend bioactive zones of allelochemicals in soilsWater release through plant roots: new insights into its consequences at the plant and ecosystem levelDo mycorrhizal network benefits to survival and growth of interior Douglas-fir seedlings increase with soil moisture stress?Application of network theory to potential mycorrhizal networks.Topographic position modulates the mycorrhizal response of oak trees to interannual rainfall variability.Ectomycorrhizal fungal communities on seedlings and conspecific trees of Pinus mugo grown on the coastal dunes of the Curonian Spit in Lithuania.Rapid nitrogen transfer from ectomycorrhizal pines to adjacent ectomycorrhizal and arbuscular mycorrhizal plants in a California oak woodland.Unraveling environmental drivers of a recent increase in Swiss fungi fruiting.Hydraulic redistribution of water from Pinus ponderosa trees to seedlings: evidence for an ectomycorrhizal pathway.Architecture of the wood-wide web: Rhizopogon spp. genets link multiple Douglas-fir cohorts.Plant Clonal Integration Mediates the Horizontal Redistribution of Soil Resources, Benefiting Neighboring Plants.Redistribution of soil water by a saprotrophic fungus enhances carbon mineralizationSagebrush carrying out hydraulic lift enhances surface soil nitrogen cycling and nitrogen uptake into inflorescencesEctomycorrhizas and water relations of trees: a review.The magnitude of hydraulic redistribution by plant roots: a review and synthesis of empirical and modeling studies.Fungal aquaporins: cellular functions and ecophysiological perspectives.Revisiting the 'Gadgil effect': do interguild fungal interactions control carbon cycling in forest soils?Bidirectional water flows through the soil-fungal-plant mycorrhizal continuum.Importance of internal hydraulic redistribution for prolonging the lifespan of roots in dry soil.Native root xylem embolism and stomatal closure in stands of Douglas-fir and ponderosa pine: mitigation by hydraulic redistribution.Efflux of hydraulically lifted water from mycorrhizal fungal hyphae during imposed drought.Hydraulic redistribution under moderate drought among English oak, European beech and Norway spruce determined by deuterium isotope labeling in a split-root experiment.Hydraulic redistribution in dwarf Rhizophora mangle trees driven by interstitial soil water salinity gradients: impacts on hydraulic architecture and gas exchange.Water sources and controls on water-loss rates of epigeous ectomycorrhizal fungal sporocarps during summer drought.Do hydraulic redistribution and nocturnal transpiration facilitate nutrient acquisition in Aspalathus linearis?Growth, root colonization and nutrient status of Helianthemum sessiliflorum Desf. inoculated with a desert truffle Terfezia boudieri Chatin.The aquaporin gene family of the ectomycorrhizal fungus Laccaria bicolor: lessons for symbiotic functions.Species Introductions and Their Cascading Impacts on Biotic Interactions in desert riparian ecosystems.In situ high-frequency observations of mycorrhizas.Bacterial microbiomes of individual ectomycorrhizal Pinus sylvestris roots are shaped by soil horizon and differentially sensitive to nitrogen addition.Hydraulic conductivity and aquaporin transcription in roots of trembling aspen (Populus tremuloides) seedlings colonized by Laccaria bicolor.Vitamin B2 (riboflavin) increases drought tolerance of Agaricus bisporus.In situ separation of root hydraulic redistribution of soil water from liquid and vapor transport.Hydraulic redistribution in a Douglas-fir forest: lessons from system manipulations.The effect of hydraulic lift on organic matter decomposition, soil nitrogen cycling, and nitrogen acquisition by a grass species.Hydraulic redistribution by plants and nutrient stoichiometry: Shifts under global changeArbuscular mycorrhizal fungi negatively affect soil seed bank viabilitySoil hypha-mediated movement of allelochemicals: arbuscular mycorrhizae extend the bioactive zone of jugloneArbuscular mycorrhizae and terrestrial ecosystem processesGlomalin-related soil protein and water relations in mycorrhizal citrus (Citrus tangerina) during soil water deficit
P2860
Q21134972-BD23583E-A7D1-4DEC-BBD8-EE1CA6A80ACDQ27023201-65006B5E-621A-4C43-AA00-4D4BA566CA48Q28731732-D326D6F5-F036-4064-AD62-D6301455A17BQ30791155-4B4D48F8-448F-4404-9175-89CD15354DEFQ33425998-EC8E3B38-1CE4-4D98-A808-087DA9F405CBQ33715451-EBEA99DF-79A7-447E-86BD-7AD4B9FE34BCQ34502362-50C5ED59-FE57-4F44-9DEF-0EDBA357A27AQ34728312-15F5239D-9A89-450E-B629-97C6503772D3Q34754974-029BFFD0-C10F-418F-9A31-D63B6F5201ADQ35010579-A27A62A4-68C1-4436-B472-2BFF1810D404Q35931917-27AC0078-D8FB-43D0-B726-3AF1B2EF4F5FQ36332115-357A9263-6F5B-42E8-8CC5-AE4ADBCEDDB4Q37340723-355B91DB-E191-4D1B-9607-DE80A690D08CQ37817841-417B44ED-ACB3-4D43-9CAF-A5110C32519CQ37993612-130D5413-F717-45D1-9435-86DDF962E29BQ38248536-E66C74FD-1FB2-418A-AE4F-578248033D5CQ38586168-B50D215C-DD1D-4CA3-B35C-774296F4963BQ38869860-45521236-0A4B-4B12-80B8-2129F4649D8DQ38897334-490C3E39-BE38-4136-86C7-080D337E7797Q38975517-51D11C42-4003-403D-9404-7832194E400AQ38982859-50E05C68-D085-40AF-BE46-79B11F016509Q39040979-A17A3C97-CD6E-4C7D-879D-5B2C0739A59EQ39045285-EAD72A62-6E14-4E88-9E82-8EF6C79CD8DFQ39179629-C1C359EC-C14A-41EB-8876-FA9942F590B9Q39224838-7892F22A-9874-46FC-9D63-C4A2641989EEQ39470128-EED3444D-217C-42AE-B3E9-A8A10394551FQ44354700-88D9E97F-F6C2-4968-B868-8DEC0DF0ACB3Q46085819-44863EE8-BA89-49A2-976E-7B72FCD56CECQ46195903-8D41DD8C-FB98-473B-BBE0-52AB3747EC37Q46297427-CFB3F074-6094-4C00-BE08-C81461D1F3C5Q46598264-F2B950ED-C6EC-4898-8C2B-19C00A4BF752Q51151008-CE2573F5-1618-41C0-AA2C-5232D61F8285Q51592948-9D21BC04-A61A-490F-8301-0322AD91D0F2Q51718608-0800FCD0-133A-47B1-A2BF-A210EA155E3EQ54649137-03C5EC6B-929A-4C54-B435-0E0110983DD6Q56455885-DDBFCE8D-A487-4299-9F2D-5394B5049A3DQ57012771-77ACD534-AE31-4325-8AEA-36776B1E7E9CQ57013020-E75EDC6C-874E-4EA1-A4FA-D13D55C69E49Q57013379-38288508-6C2E-4595-84C4-2357690717E1Q57252160-4BA78F53-F88E-4E5E-909B-710DDD5A8E10
P2860
Direct nocturnal water transfer from oaks to their mycorrhizal symbionts during severe soil drying.
description
2002 nî lūn-bûn
@nan
2002年の論文
@ja
2002年学术文章
@wuu
2002年学术文章
@zh-cn
2002年学术文章
@zh-hans
2002年学术文章
@zh-my
2002年学术文章
@zh-sg
2002年學術文章
@yue
2002年學術文章
@zh
2002年學術文章
@zh-hant
name
Direct nocturnal water transfe ...... nts during severe soil drying.
@en
Direct nocturnal water transfe ...... nts during severe soil drying.
@nl
type
label
Direct nocturnal water transfe ...... nts during severe soil drying.
@en
Direct nocturnal water transfe ...... nts during severe soil drying.
@nl
prefLabel
Direct nocturnal water transfe ...... nts during severe soil drying.
@en
Direct nocturnal water transfe ...... nts during severe soil drying.
@nl
P2093
P1433
P1476
Direct nocturnal water transfe ...... nts during severe soil drying.
@en
P2093
José Ignacio Querejeta
Louise M Egerton-Warburton
Michael F Allen
P2888
P356
10.1007/S00442-002-1078-2
P407
P577
2002-10-18T00:00:00Z