Distinct phyllosphere bacterial communities on Arabidopsis wax mutant leavesEpicuticular wax crystals of Wollemia nobilis: morphology and chemical compositionSlippery surfaces of pitcher plants: Nepenthes wax crystals minimize insect attachment via microscopic surface roughnesspH-dependent permeation of amino acids through isolated ivy cuticles is affected by cuticular water sorption and hydration shell size of the solute.Phyllosphere bacterial communities of trichome-bearing and trichomeless Arabidopsis thaliana leaves.Plant surface properties in chemical ecology.Slippery ant-plants and skilful climbers: selection and protection of specific ant partners by epicuticular wax blooms in Macaranga (Euphorbiaceae).Ecophysiological relevance of cuticular transpiration of deciduous and evergreen plants in relation to stomatal closure and leaf water potential.A central role of abscisic acid in drought stress protection of Agrobacterium-induced tumors on Arabidopsis.Very-long-chain aldehydes promote in vitro prepenetration processes of Blumeria graminis in a dose- and chain length-dependent manner.Aqueous pathways dominate permeation of solutes across Pisum sativum seed coats and mediate solute transport via diffusion and bulk flow of water.Mechanisms of cuticular uptake of xenobiotics into living plants: 1. Influence of xenobiotic dose on the uptake of three model compounds applied in the absence and presence of surfactants into Chenopodium album, Hedera helix and Stephanotis floribunTwo sides of a leaf blade: Blumeria graminis needs chemical cues in cuticular waxes of Lolium perenne for germination and differentiation.The ecophysiology of leaf cuticular transpiration: are cuticular water permeabilities adapted to ecological conditions?Localization of the Transpiration Barrier in the Epi- and Intracuticular Waxes of Eight Plant Species: Water Transport Resistances Are Associated with Fatty Acyl Rather Than Alicyclic Components.What do microbes encounter at the plant surface? Chemical composition of pea leaf cuticular waxes.Comparison of sorption and diffusion by pyridate and its polar metabolite in isolated cuticular wax of Chenopodium album and Hordeum vulgare.Characterization of hydrophilic and lipophilic pathways of Hedera helix L. cuticular membranes: permeation of water and uncharged organic compounds.Noninvasive evaluation of the degree of ripeness in grape berries (vitis vinifera L. Cv. Bacchus and silvaner) by chlorophyll fluorescence.Host surface properties affect prepenetration processes in the barley powdery mildew fungus.Tomato fruit cuticular waxes and their effects on transpiration barrier properties: functional characterization of a mutant deficient in a very-long-chain fatty acid beta-ketoacyl-CoA synthase.Chemical Composition and Water Permeability of Fruit and Leaf Cuticles of Olea europaea L.The developmental pattern of tomato fruit wax accumulation and its impact on cuticular transpiration barrier properties: effects of a deficiency in a beta-ketoacyl-coenzyme A synthase (LeCER6).Appressorium morphogenesis and cell cycle progression are linked in the grass powdery mildew fungus Blumeria graminis.Deficiency in a very-long-chain fatty acid β-ketoacyl-coenzyme a synthase of tomato impairs microgametogenesis and causes floral organ fusion.The positional sterile (ps) mutation affects cuticular transpiration and wax biosynthesis of tomato fruits.Mechanisms of cuticular uptake of xenobiotics into living plants: evaluation of a logistic-kinetic penetration model.Development of plant cuticles: fine structure and cutin composition of Clivia miniata Reg. leaves.Accumulation and transport of (2,4-dichlorophenoxy)acetic acid in plant cuticles. II. Permeability of the cuticular membrane.Raman spectroscopic study of spatial distribution of propolis in comb of Apis mellifera carnica (Pollm.).Leaf surface wax layers of Brassicaceae lack feeding stimulants for Phaedon cochleariaeEpidermal transmittance of leaves of Vicia faba for UV radiation as determined by two different methodsThe Mode of Action of Adjuvants—Relevance of Physicochemical Properties for Effects on the Foliar Application, Cuticular Permeability, and Greenhouse Performance of PinoxadenDirect Effects of Physcion, Chrysophanol, Emodin, and Pachybasin on Germination and Appressorium Formation of the Barley (Hordeum vulgare L.) Powdery Mildew Fungus Blumeria graminis f. sp. hordei (DC.) SpeerAbscisic acid mediates the formation of a suberized stem scar tissue in tomato fruitsWax matters: absence of very-long-chain aldehydes from the leaf cuticular wax of the glossy11 mutant of maize compromises the prepenetration processes of Blumeria graminisCuticular wax composition in Cocos nucifera L.: physicochemical analysis of wax components and mapping of their QTLs onto the coconut molecular linkage mapComparative study on epicuticular leaf waxes of Araucaria araucana, Agathis robusta and Wollemia nobilis (Araucariaceae)Ecophysiological adaptations of water relations of Teucrium chamaedrys L. to the hot and dry climate of xeric limestone sites in Franconia (Southern Germany)Matroclinal inheritance of cuticular waxes in reciprocal hybrids of Rosa species, sect. Caninae (Rosaceae)
P50
Q28534850-6CA9B84D-841A-48DC-8BB6-6B3A9805CEEEQ28751785-0CE394BC-ED4E-4BAE-9C42-27416D809242Q29038443-DFAF7B47-5733-45B9-B700-9A20E8336F70Q30479595-20C93026-5EEB-46F6-82B8-D63315EF4D8DQ34073624-5C014076-8AB0-4A17-A3AE-2C6CB54FAA19Q34562401-BB2CE52A-F161-45A4-B564-20B668CAA571Q38900560-E3248161-69F6-455A-ABE8-804FDE58793CQ38926210-861A89E0-272B-4882-A850-5BE9EBB0E2D0Q38982689-2C7F9694-EE94-4564-9431-70AC90292090Q42929063-F8381983-F52E-4346-BD26-8F9526511DAEQ44940768-CDF09092-F651-41FB-93CA-FAB018CCE6DAQ45143588-EFB064D7-FCB4-4552-AA06-FD8A3B632D7EQ45217423-988058F4-FAAB-40F1-977E-AF2D30572B4DQ46284303-E3DB5FDC-E4F5-4708-BFF9-9EF28ED0F10EQ46627085-035BC066-6885-4838-A804-09B16BEE011FQ46661346-48B0EC9E-D14A-470B-94C7-6D3FBCCEC997Q46677166-F214EE39-521E-4D02-962B-E8CE473B1718Q46688416-AF212400-78D8-4787-B958-43DDF85A8A1DQ46897119-DE9FC856-D264-42AD-823A-1262A12744B4Q46949858-FB006276-1439-467B-BB74-F0102C95D5B7Q47633182-D858EBD9-F890-4A0E-9E5A-05CD0CC841E2Q47896830-6604600F-5474-449D-A65C-2FCABCD78915Q50686726-E6769F32-17CB-42C3-98E5-6DAE365709C6Q50792073-C6BCE9C6-642B-4130-B932-8BC9D46E36B4Q50795248-E1FF95C8-7D8E-45D2-A3D5-69CE61C5B437Q51891149-4F3FF1F3-D262-44EB-B40A-02F9F92B3BB8Q51943936-EE896FD3-FF21-4591-BE9D-5253A68C4430Q52251981-CCC5CD01-A9B9-4C3B-9544-8B31FF3C2107Q52430883-B1576F63-E60C-4873-A148-C129BC8D1460Q52608768-C04DA5FD-8025-4576-B616-EA2AEED31268Q57031929-F8565F5C-6145-453E-AE44-3AC972041F6AQ57146384-52CF87A3-5840-46F7-9A99-818D1F0470CAQ59163833-B7E2E109-B8AA-44E2-B5D6-CCB966A58862Q59163836-10FF2063-FFF2-4248-9105-B9DF25857DDFQ59163846-3FD006A6-D0BD-4A4C-AFC7-38B525D9177EQ59163855-7A8835CA-40F4-46E7-989D-BB2DCAF867EAQ59163859-75B69D0B-7212-4D72-A9BF-4CD18F4FEEFCQ59163864-93A136D6-E74F-40EB-A4A9-70D04F710A0EQ59163865-C281F3EB-A289-418B-97AB-6C618D067631Q59163869-EF563C45-71E4-4661-BD88-065495AC277E
P50
description
Duits botanicus
@nl
German botanist
@en
German botanist
@en-ca
German botanist
@en-gb
Saksamaa botaanik
@et
botanico tedesco
@it
botanikari alemaniarra
@eu
botanist german
@ro
botanist gjerman
@sq
botaniste allemand
@fr
name
Markus Riederer
@ast
Markus Riederer
@ca
Markus Riederer
@da
Markus Riederer
@de
Markus Riederer
@en
Markus Riederer
@es
Markus Riederer
@fr
Markus Riederer
@it
Markus Riederer
@nb
Markus Riederer
@nl
type
label
Markus Riederer
@ast
Markus Riederer
@ca
Markus Riederer
@da
Markus Riederer
@de
Markus Riederer
@en
Markus Riederer
@es
Markus Riederer
@fr
Markus Riederer
@it
Markus Riederer
@nb
Markus Riederer
@nl
prefLabel
Markus Riederer
@ast
Markus Riederer
@ca
Markus Riederer
@da
Markus Riederer
@de
Markus Riederer
@en
Markus Riederer
@es
Markus Riederer
@fr
Markus Riederer
@it
Markus Riederer
@nb
Markus Riederer
@nl
P1006
P1015
P214
P227
P244
P268
P269
P1006
P1015
P1053
B-5540-2008
P106
P1153
7005689254
P1207
n2010043232
P19
P21
P213
0000 0000 7249 9534