about
Adaptive shoot and root responses collectively enhance growth at optimum temperature and limited phosphorus supply of three herbaceous legume speciesPutting the P in Ptilotus: a phosphorus-accumulating herb native to Australia.Update on phosphorus nutrition in Proteaceae. Phosphorus nutrition of proteaceae in severely phosphorus-impoverished soils: are there lessons to be learned for future crops?The role of root exuded low molecular weight organic anions in facilitating petroleum hydrocarbon degradation: current knowledge and future directions.A review of germination and early growth as a proxy for plant fitness under petrogenic contamination - knowledge gaps and recommendations.Moderating mycorrhizas: arbuscular mycorrhizas modify rhizosphere chemistry and maintain plant phosphorus status within narrow boundaries.Commensalism in an agroecosystem: hydraulic redistribution by deep-rooted legumes improves survival of a droughted shallow-rooted legume companion.Fine root endophytes under scrutiny: a review of the literature on arbuscule-producing fungi recently suggested to belong to the Mucoromycotina.Multiple adaptive responses of Australian native perennial legumes with pasture potential to grow in phosphorus- and moisture-limited environments.Mechanisms for tolerance of very high tissue phosphorus concentrations in Ptilotus polystachyus.Peppermint trees shift their phosphorus-acquisition strategy along a strong gradient of plant-available phosphorus by increasing their transpiration at very low phosphorus availability.Physiological and morphological adaptations of herbaceous perennial legumes allow differential access to sources of varyingly soluble phosphate.Leaf transpiration plays a role in phosphorus acquisition among a large set of chickpea genotypes.Fine endophytes (Glomus tenue) are related to Mucoromycotina, not Glomeromycota.Phosphorus- and nitrogen-acquisition strategies in two Bossiaea species (Fabaceae) along retrogressive soil chronosequences in south-western Australia.A mycorrhizal revolution.Low Light Availability Alters Root Exudation and Reduces Putative Beneficial Microorganisms in Seagrass Roots.Variation in morphological and physiological parameters in herbaceous perennial legumes in response to phosphorus supplyThe diversity of arbuscular mycorrhizas of selected AustralianFabaceaePlant Responses to Limited Moisture and Phosphorus AvailabilityGrowth, carboxylate exudates and nutrient dynamics in three herbaceous perennial plant species under low, moderate and high phosphorus supplyAbove- and below-ground interactions of grass and pasture legume species when grown together under drought and low phosphorus availabilityFrom controlled environments to field simulations: Developing a growth model for the novel perennial pasture legume Cullen australasicumLittle evidence that farmers should consider abundance or diversity of arbuscular mycorrhizal fungi when managing cropsCitrate and malonate increase microbial activity and alter microbial community composition in uncontaminated and diesel-contaminated soil microcosmsRhizosphere 3: where plants meet soils down-underBelowground solutions to global challenges: special issue from the 9th symposium of the International Society of Root ResearchDrought resistance at the seedling stage in the promising fodder plant tedera (Bituminaria bituminosa var. albomarginata)Effects of leaf development and phosphorus supply on the photosynthetic characteristics of perennial legume species with pasture potential: modelling photosynthesis with leaf developmentPlant and microbial strategies to improve the phosphorus efficiency of agricultureSoil phosphorus supply affects nodulation and N:P ratio in 11 perennial legume seedlingsStrategies and agronomic interventions to improve the phosphorus-use efficiency of farming systemsPronounced surface stratification of soil phosphorus, potassium and sulfur under pastures upstream of a eutrophic wetland and estuarine systemDo arbuscular mycorrhizas or heterotrophic soil microbes contribute toward plant acquisition of a pulse of mineral phosphate?Contrasting responses to drought stress in herbaceous perennial legumesVariation in seedling growth of 11 perennial legumes in response to phosphorus supplyRoot distributions of Australian herbaceous perennial legumes in response to phosphorus placementImplications of co-contamination with aged heavy metals and total petroleum hydrocarbons on natural attenuation and ecotoxicity in Australian soilsCRISPR-Cas systems: ushering in the new genome editing eraThe carboxylate-releasing phosphorus-mobilizing strategy can be proxied by foliar manganese concentration in a large set of chickpea germplasm under low phosphorus supply
P50
Q34357432-820C7944-A831-4CC0-920E-8D5A64DD4DA0Q37255105-A725F9A4-EF67-4A54-94E4-09D98A8B80B0Q37865978-2364F607-1F4F-4F16-A39D-2FE3D9345BEBQ38169533-855C9B2D-E6A7-4442-A4D6-F3AA3B0FF4E5Q38735600-6920DF4D-2905-41DF-919A-707157107558Q39335599-53F35897-60DF-498D-83AF-B27F494A10C2Q39336629-F924AF8F-B9E6-4838-8274-384E6AADD446Q39358860-446EF7E9-9D9F-4A7A-9D7E-D9D4336E5961Q39499740-F7315426-128B-4189-B82C-B0C4C7D2535EQ41607408-89EAF57D-0B05-4504-848B-3E423DF0787BQ46304721-5AEFF780-DF51-434E-A58C-BE268C07F155Q46828622-9532EA48-FB77-475A-A69B-28AB19C71D3CQ47724988-05897A46-011D-4010-826B-DB4B229143D4Q47853737-F226D2F4-2448-48DD-B72C-472F5FC2ECA3Q48506697-F51EE0D2-8772-453F-B665-A033E7EB96EFQ49384648-7B8B87D8-5F8A-4054-B631-A3E047C4554DQ49583740-CEBFE668-B103-4B79-A237-801882C6D453Q56767688-2C9CB50B-5A1F-45B3-A6C6-8B0D1E483018Q56776323-AC654134-00B9-4D77-9753-EAA637E4D258Q56950745-053DCF5F-0B4D-4086-95BB-D5203453439EQ56950793-C28C4F3C-B5ED-4E4C-BD24-99B73AA84744Q56950878-0B496DE9-1E84-49C4-B933-3B36D2CB53DAQ56950944-AE38408B-2481-4A7B-9076-3ADBF65F114DQ57176644-75D65AFB-EB36-4E4F-8CFC-973091B623DFQ57878359-FBA53646-FD53-4314-8172-D58458601A0AQ57879059-B953B0E0-2FD0-4623-B1B7-B69DC33F0CC8Q58039408-AD9EDAAA-7C88-469E-8C3B-A86B906558A3Q60233066-A524811E-A2CF-4E9A-829A-4ACB64CC58CCQ60233072-65252AFF-D7D6-4317-B9E6-B14B482F16CEQ60233109-BA793829-820F-4915-9FEA-2B7B81E9292DQ60233110-55A2C6B1-CD17-4308-A327-2641DCB9BC94Q60233113-63C923E0-DEF8-426C-B3BC-4CFF6ED2B2CEQ60319292-F93AAE56-DD85-457F-9A27-4AFDE38E28A4Q60319360-99036DDC-83A6-43C2-8983-DE3414958745Q60319404-52EBE2CF-17FE-46C3-89ED-385C3A060B99Q60319426-BCF0EA36-5B07-429D-8E1F-6321DBACC528Q60319510-3ADB8DEE-BB9E-45A4-BAB4-1D9219ECFCB3Q60547667-9DC37AF1-2723-42F9-B79D-64AE9B68DA9FQ60547668-305241B4-E392-465B-B08D-BA017DE25339Q60547669-E7FEB847-01A8-4A1C-A683-983FFAEF855B
P50
description
researcher
@en
researcher
@en-gb
wetenschapper
@nl
հետազոտող
@hy
name
Megan H Ryan
@ast
Megan H Ryan
@en
Megan H Ryan
@en-gb
Megan H Ryan
@es
Megan H Ryan
@nl
Megan H Ryan
@sl
type
label
Megan H Ryan
@ast
Megan H Ryan
@en
Megan H Ryan
@en-gb
Megan H Ryan
@es
Megan H Ryan
@nl
Megan H Ryan
@sl
prefLabel
Megan H Ryan
@ast
Megan H Ryan
@en
Megan H Ryan
@en-gb
Megan H Ryan
@es
Megan H Ryan
@nl
Megan H Ryan
@sl
P1153
P106
P1153
56874273000
57198145440
57200114586
7403184635
P31
P496
0000-0003-0749-0199