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Nitrogen Nutrition of the Tuberous Sundew Drosera erythrorhiza Lindl. With Special Reference to Catch of Arthropod Fauna by Its Glandular Leaves
KW Dixon, JS Pate and WJ Bailey
28(3) pp.283 - 297
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The utilization of nitrogen from insect capture by different growth forms of Drosera from Southwest Australia
Schulze E. -D.,
Gebauer G.,
Schulze W., Pate J. S.
Oecologia. 1991 87(2). p.240
Digestive mutualism, an alternate pathway in plant carnivory
Anderson B., Midgley J.J.
Oikos. 2003 102(1). p.221
Annual Plant Reviews Volume 42 (2010)
The mycorrhizal association: just one of many nutrient acquiring specializations in natural ecosystems
Pate J. S.
Plant and Soil. 1994 159(1).
Annual Plant Reviews online (2018)
Arthropod associates and macronutrient status of the red‐ink sundew (Drosera erythrorhiza Lindl.)
WATSON A. P.,
MATTHIESSEN J. N., SPRINGETT B. P.
Australian Journal of Ecology. 1982 7(1). p.13
Leaf absorption of mineral nutrients in carnivorous plants stimulates root nutrient uptake
Adamec Lubomír
New Phytologist. 2002 155(1). p.89
FITNESS RESPONSES OF A CARNIVOROUS PLANT IN CONTRASTING ECOLOGICAL SCENARIOS
Zamora Regino,
Gómez José M., Hódar José A.
Ecology. 1998 79(5). p.1630
Patterns of prey capture and prey availability among populations of the carnivorous plant Pinguicula moranensis (Lentibulariaceae) along an environmental gradient
Alcalá Raúl E., Domínguez César A.
American Journal of Botany. 2003 90(9). p.1341
Carnivorous plants: the role of
Chalk Phillip M.,
Hu Hang-Wei, Cook Garry
Australian Journal of Botany. 2022 70(2). p.103
Progress in Botany / Fortschritte der Botanik (1993)
Biochemical and mesophyll diffusional limits to photosynthesis are determined by prey and root nutrient uptake in the carnivorous pitcher plant Nepenthes × ventrata
Capó-Bauçà Sebastià,
Font-Carrascosa Marcel,
Ribas-Carbó Miquel,
Pavlovič Andrej, Galmés Jeroni
Annals of Botany. 2020 126(1). p.25
Breeding and Cytogenetic Characterizations of New Hexaploid Drosera Strains Colchicine-Induced from Triploid Hybrid of D. rotundifolia and D. spatulata
Tungkajiwangkoon Santhita,
Shirakawa Junichi,
Azumatani Masako, Hoshi Yoshikazu
CYTOLOGIA. 2016 81(3). p.263
Mutualists or parasites? Context-dependent influence of symbiotic fly larvae on carnivorous investment in the Albany pitcher plant
Lymbery Samuel J.,
Didham Raphael K.,
Hopper Stephen D., Simmons Leigh W.
Royal Society Open Science. 2016 3(11). p.160690
How dangerous is a Drosera? Limb autotomy increases passive predation risk in crickets
Cross A. T., Bateman P. W.
Journal of Zoology. 2018 306(4). p.217
Contrasting effects of supplementary feeding of insects or mineral nutrients on the growth and nitrogen and phosphorous economy of pygmy species of Drosera
Karlsson P. S., Pate J. S.
Oecologia. 1992 92(1). p.8
Plant Physiological Ecology (2019)
Segregation of habitat and prey in two sympatric carnivorous plant species, Drosera rotundifolia and Drosera intermedia
Thum M.
Oecologia. 1986 70(4). p.601
A new carnivorous plant lineage (Triantha) with a unique sticky-inflorescence trap
Lin Qianshi,
Ané Cécile,
Givnish Thomas J., Graham Sean W.
Proceedings of the National Academy of Sciences. 2021 118(33).
Evolution of Carnivory in Lentibulariaceae and the Lamiales
Müller K.,
Borsch T.,
Legendre L.,
Porembski S.,
Theisen I., Barthlott W.
Plant Biology. 2004 6(4). p.477
Tentacles of in vitro-grown round-leaf sundew (Drosera rotundifoliaL.) show induction of chitinase activity upon mimicking the presence of prey
Matušíková Ildikó,
Salaj Ján,
Moravčíková Jana,
Mlynárová Ludmila,
Nap Jan-Peter, Libantová Jana
Planta. 2005 222(6). p.1020
Metabolism of [15N]glycine and [13C]glycine by Dionaea muscipula studied by gas chromatography‐mass spectrometry
GREENAWAY W.,
MAY J.,
ENGLISH S., WHATLEY F. R.
New Phytologist. 1990 114(4). p.581
All Flesh Is Grass (2010)
A new plant-animal mutualism involving a plant with sticky leaves and a resident hemipteran insect
Ellis A. G., Midgley J. J.
Oecologia. 1996 106(4). p.478
The feeding ecology of a carnivorous plant (Pinguicula nevadense): prey analysis and capture constraints
Zamora Regino
Oecologia. 1990 84(3). p.376
Mechanisms for enhancing nutrient uptake in plants, with particular reference to mediterranean South Africa and Western Australia
Lamont Byron
The Botanical Review. 1982 48(3). p.597
Minor pollinator–prey conflict in the carnivorous plant, Drosera anglica
Murza Gillian L.,
Heaver Joanne R., Davis Arthur R.
Plant Ecology. 2006 184(1). p.43
A novel insight into the cost–benefit model for the evolution of botanical carnivory
Pavlovič Andrej, Saganová Michaela
Annals of Botany. 2015 115(7). p.1075
Biogeochemistry (2013)
Biogeochemistry (1991)
The significance of carnivory for the fitness of Drosera in its natural habitat
Thum Martin
Oecologia. 1988 75(3). p.472
Mediterranean-Type Ecosystems (1983)
Physiological Plant Ecology III (1983)
Energetics and the evolution of carnivorous plants—Darwin's ‘most wonderful plants in the world’
Ellison Aaron M., Gotelli Nicholas J.
Journal of Experimental Botany. 2009 60(1). p.19
Trapping efficiency of three carnivorous Pinguicula species
Karlsson P. S.,
Nordell K. O.,
Eirefelt S., Svensson A.
Oecologia. 1987 73(4). p.518
Nutrient Limitation and Stoichiometry of Carnivorous Plants
Ellison A. M.
Plant Biology. 2006 8(6). p.740
Biogeochemistry (2020)
Prey capture by three Pinguicula species in a subarctic environment
Karlsson P. S.,
Thor�n L. M., Hanslin H. M.
Oecologia. 1994 99(1-2). p.188
Relationship between types of prey captured and growth form in Drosera in southwestern Australia
VERBEEK N. A. M., BOASSON R.
Australian Journal of Ecology. 1993 18(2). p.203
Plant Physiological Ecology (2008)
Plastome-Wide Rearrangements and Gene Losses in Carnivorous Droseraceae
Nevill Paul G,
Howell Katharine A,
Cross Adam T,
Williams Anna V,
Zhong Xiao,
Tonti-Filippini Julian,
Boykin Laura M,
Dixon Kingsley W,
Small Ian, Sloan Daniel
Genome Biology and Evolution. 2019 11(2). p.472
Recent Progress in Understanding the Evolution of Carnivorous Lentibulariaceae (Lamiales)
Müller K. F.,
Borsch T.,
Legendre L.,
Porembski S., Barthlott W.
Plant Biology. 2006 8(6). p.748
Mineral nutrient uptake from prey and glandular phosphatase activity as a dual test of carnivory in semi-desert plants with glandular leaves suspected of carnivory
Płachno Bartosz Jan,
Adamec Lubomír, Huet Hervé
Annals of Botany. 2009 104(4). p.649
The Leaf: A Platform for Performing Photosynthesis (2018)
Nitrogen uptake from prey and substrate as affected by prey capture level and plant reproductive status in four carnivorous plant species
Hanslin H. M., Karlsson P. S.
Oecologia. 1996 106(3). p.370
Application of radiotracers in an exotic field of botany: How to feed carnivorous plants
Steinhauser G.,
Adlassnig W.,
Peroutka M.,
Musilek A.,
Sterba J. H.,
Bichler M., Lichtscheidl I. K.
Journal of Radioanalytical and Nuclear Chemistry. 2007 274(2). p.403
Biogeochemistry (2020)
Biogeochemistry: an Analysis of Global Change (1991)
An ecological perspective on ‘plant carnivory beyond bogs’: nutritional benefits of prey capture for the Mediterranean carnivorous plant Drosophyllum lusitanicum
Skates Laura M,
Paniw Maria,
Cross Adam T,
Ojeda Fernando,
Dixon Kingsley W,
Stevens Jason C, Gebauer Gerhard
Annals of Botany. 2019 124(1). p.65
Mixotrophy everywhere on land and in water: the grand écart hypothesis
Selosse Marc‐André,
Charpin Marie,
Not Fabrice, Jeyasingh Punidan
Ecology Letters. 2017 20(2). p.246
The contribution of insect prey to the total nitrogen content of sundews (Drosera spp.) determined in situ by stable isotope analysis
Millett Jonathan,
Jones Roger I., Waldron Susan
New Phytologist. 2003 158(3). p.527
All Flesh Is Grass (2010)
Plant Physiological Ecology (1998)
Uptake and translocation of prey‐derived 15N and 32P in Utricularia vulgaris L.
FRIDAY LAURIE, QUARMBY CHRIS
New Phytologist. 1994 126(2). p.273
Is the evolution of carnivory connected with genome size reduction?
Veleba Adam,
Zedek František,
Horová Lucie,
Veselý Pavel,
Srba Miroslav,
Šmarda Petr, Bureš Petr
American Journal of Botany. 2020 107(9). p.1253
Feeding on prey increases photosynthetic efficiency in the carnivorous sundew Drosera capensis
Pavlovič Andrej,
Krausko Miroslav,
Libiaková Michaela, Adamec Lubomír
Annals of Botany. 2014 113(1). p.69
Mineral nutrition of carnivorous plants: A review
Adamec Lubomír
The Botanical Review. 1997 63(3). p.273
Aestivation organ structure in Drosera subgen. Ergaleium (Droseraceae): corms or tubers; roots or shoots?
Conran John G.
Australian Journal of Botany. 2008 56(2). p.144
Progress in Botany (1986)
