Articles citing this paper
Crassulacean Acid Metabolism and Diurnal Variations of Internal CO2 and O2 Concentrations in Sedum praealtum DC
MH Spalding, DK Stumpf, MSB Ku, RH Burris and GE Edwards
6(4) pp.557 - 567
67 articles found in Crossref database.
Photosynthesis (1982)
The Calvin-Benson-Bassham cycle in C4 and Crassulacean acid metabolism species
Ludwig Martha,
Hartwell James,
Raines Christine A., Simkin Andrew J.
Seminars in Cell & Developmental Biology. 2024 155 p.10
A meta-analysis of plant tissue O2 dynamics
Herzog Max,
Pellegrini Elisa,
Pedersen Ole, Zeng Fanrong
Functional Plant Biology. 2023 50(7). p.519
Superoxide dismutase activity in C3 and C3/CAM intermediate species of Clusia
Miszalski Z.,
Kornas A.,
Gawronska K.,
Ślesak I.,
Niewiadomska E.,
Kruk J.,
Christian A. L.,
Fischer-Schliebs E.,
Krisch R., Lüttge U.
Biologia plantarum. 2007 51(1). p.86
Overexpression of C4‐cycle enzymes in transgenic C3 plants: a biotechnological approach to improve C3‐photosynthesis
Häusler Rainer E.,
Hirsch Heinz‐Josef,
Kreuzaler Fritz, Peterhänsel Christoph
Journal of Experimental Botany. 2002 53(369). p.591
CO2 and O2 dynamics in leaves of aquatic plants with C3 or CAM photosynthesis – application of a novel CO2 microsensor
Pedersen Ole,
Colmer Timothy D,
Garcia-Robledo Emilio, Revsbech Niels P
Annals of Botany. 2018 122(4). p.605
Antioxidant capacity along the leaf blade of the C3-CAM facultative bromeliad Guzmania monostachia under water deficit conditions
Abreu Maria E.,
Carvalho Victória, Mercier Helenice
Functional Plant Biology. 2018 45(6). p.620
Evolution along the crassulacean acid metabolism continuum
Silvera Katia,
Neubig Kurt M.,
Whitten W. Mark,
Williams Norris H.,
Winter Klaus, Cushman John C.
Functional Plant Biology. 2010 37(11). p.995
A morning peak in acidity during phase II crassulacean acid metabolism in Opuntia erinacea, echinocereus echinocereus and Mammillaria vivipara
Littlejohn R.O.,
Green J.M., Williams G.J.
Plant Science Letters. 1982 27(1). p.43
Net CO2 output by CAM plants in the light: the role of leaf conductance
Frimert Volker,
Kluge Manfred, Smith J. Andrew C.
Physiologia Plantarum. 1986 68(3). p.353
CARBON DIOXIDE AND WATER DEMAND: CRASSULACEAN ACID METABOLISM (CAM), A VERSATILE ECOLOGICAL ADAPTATION EXEMPLIFYING THE NEED FOR INTEGRATION IN ECOPHYSIOLOGICAL WORK
LÜTTGE U.
New Phytologist. 1987 106(4). p.593
Aerial roots of the leafless epiphytic orchid Taeniophyllum are specialized for performing crassulacean acid metabolism photosynthesis
Suetsugu Kenji,
Sugita Ryohei,
Yoshihara Akiko,
Okada Hidehito,
Akita Kae,
Nagata Noriko,
Tanoi Keitaro, Kobayashi Koichi
New Phytologist. 2023 238(3). p.932
Clusia (2007)
Crassulacean Acid Metabolism (1996)
Crassulacean acid metabolism in the epiphytic ferns Drymoglossum piloselloides and Pyrrosia longifolia: studies on responses to environmental signals
ONG B. L.,
KLUGE M., FRIEMERT V.
Plant, Cell & Environment. 1986 9(7). p.547
Progress in Botany 72 (2010)
The role of crassulacean acid metabolism (CAM) in the adaptation of plants to salinity*
LÜTTGE ULRICH
New Phytologist. 1993 125(1). p.59
Long‐term functioning of enucleate sieve elements: possible mechanisms of damage avoidance and damage repair
RAVEN J. A.
Plant, Cell & Environment. 1991 14(2). p.139
Relationships between CO2 concentration within the leaf and photosynthesis during deacidification in a CAM plant, Kalanchoë pinnatum
Nishida Kojiro
Physiologia Plantarum. 1982 54(4). p.451
Crassulacean Acid Metabolism May Alleviate Production of Reactive Oxygen Species in a Facultative CAM Plant, the Common Ice PlantMesembryanthemum crystallinumL.
Sunagawa Haruki,
Cushman John, Agarie Sakae
Plant Production Science. 2010 13(3). p.256
Activity of enzymes of carbon metabolism during the induction of Crassulacean acid metabolism in Mesembryanthemum crystallinum L.
Holtum Joseph A. M., Winter Klaus
Planta. 1982 155(1). p.8
Photosynthetic flexibility and ecophysiological plasticity: questions and lessons from Clusia, the only CAM tree, in the neotropics
Lüttge Ulrich
New Phytologist. 2006 171(1). p.7
Architectural Effects on Floral Traits in Sedum praealtum Dc. (Crassulaceae) in Mexico
Hernández-Ramírez Angélica María
Haseltonia. 2017 23 p.35
In situ studies of crassulacean acid metabolism in Kalanchoë beharensis Drake Del Castillo, a plant of the semi‐arid southern region of Madagascar
KLUGE MANFRED,
RAZANOELISOA BAKOARSINA,
RAVELOMANANA DIDIER, BRULFERT JEANNE
New Phytologist. 1992 120(3). p.323
Effect of drought on physiological aspects of Crassulacean acid metabolism in Doritaenopsis
Cui Yong-Yi,
Pandey Dev Mani,
Hahn Eun-Joo, Paek Kee-Yoeup
Plant Science. 2004 167(6). p.1219
Ability of crassulacean acid metabolism plants to overcome interacting stresses in tropical environments
Lüttge Ulrich
AoB PLANTS. 2010 2010
Progress in Botany 72 (2010)
Achievable productivities of certain CAM plants: basis for high values compared with C3 and C4 plants
NOBEL PARK S.
New Phytologist. 1991 119(2). p.183
Stomatal Responses to Light, CO2, and Mesophyll Tissue in Vicia faba and Kalanchoë fedtschenkoi
Santos Mauro G.,
Davey Phillip A.,
Hofmann Tanja A.,
Borland Anne,
Hartwell James, Lawson Tracy
Frontiers in Plant Science. 2021 12
Photosynthesis (1982)
Plant responses to high O2 concentrations: relevance to previous high O2 episodes
Raven John A.
Global and Planetary Change. 1991 5(1-2). p.19
High resilience to extreme climatic changes in the CAM epiphyte Tillandsia utriculata L. (Bromeliaceae)
Rosado‐Calderón Agatha T.,
Tamayo‐Chim Manuela,
de la Barrera Erick,
Ramírez‐Morillo Ivón M.,
Andrade José L.,
Briones Oscar, Reyes‐García Casandra
Physiologia Plantarum. 2020 168(3). p.547
Inhibition of deacidification (loss of titratable acidity by photosynthetic inhibitors in leaves of a cam plant
Nishida Kojiro, Hayashi Yokichi
Plant Science Letters. 1980 19(3). p.271
Rethinking the potential productivity of crassulacean acid metabolism by integrating metabolic dynamics with shoot architecture, using the example of Agave tequilana
Wang Yu,
Smith J. Andrew C.,
Zhu Xin‐Guang, Long Stephen P.
New Phytologist. 2023 239(6). p.2180
Crassulacean Acid Metabolism (1996)
Characterization and expression of a NADP‐malic enzyme cDNA induced by salt stress from the facultative crassulacean acid metabolism plant, Mesembryanthemum crystallinum
CUSHMAN John C.
European Journal of Biochemistry. 1992 208(2). p.259
Crassulacean Acid Metabolism (1996)
Diurnal patterns of carbon dioxide, water vapour, and energy fluxes in pineapple [Ananas comosus (L.) Merr. cv. Red Spanish] field using eddy covariance
San-José J.,
Montes R., Nikonova N.
Photosynthetica. 2007 45(3). p.370
Carbon isotope fractionation in plants
O'Leary Marion H.
Phytochemistry. 1981 20(4). p.553
Progress in Botany / Fortschritte der Botanik (1980)
Photosynthesis (1981)
Regulation of the Degree of Manifestation of Obligate CAM Pathway in Sedum dendroideum by Salinity
Rakhmankulova Z. F.,
Terletskaya N. V.,
Shuyskaya E. V.,
Saidova L. T.,
Prokofieva M. Yu.,
Kenzhebaeva Zh. A., Lapshin P. V.
Russian Journal of Plant Physiology. 2023 70(9).
Differential usage of storage carbohydrates in the CAM bromeliad Aechmea ‘Maya’ during acclimation to drought and recovery from dehydration
Ceusters Johan,
Borland Anne M.,
Londers Elsje,
Verdoodt Veerle,
Godts Christof, De Proft Maurice P.
Physiologia Plantarum. 2009 135(2). p.174
Seasonal variation of photosynthesis and photosynthetic efficiency in Phalaenopsis
Pollet B.,
Steppe K.,
Dambre P.,
Van Labeke M. C., Lemeur R.
Photosynthetica. 2010 48(4). p.580
Redox control of oxidative stress responses in the C3–CAM intermediate plant Mesembryanthemum crystallinum
Ślesak Ireneusz,
Miszalski Zbigniew,
Karpinska Barbara,
Niewiadomska Ewa,
Ratajczak Rafael, Karpinski Stanislaw
Plant Physiology and Biochemistry. 2002 40(6-8). p.669
High‐Resolution Chlorophyll Fluorescence Imaging Serves as a Non‐Invasive Indicator to Monitor the Spatio‐Temporal Variations of Metabolism during the Day‐Night Cycle and during the Endogenous Rhythm in Continuous Light in the CAM Plant Kalanchoë daigremontiana
Rascher U., Lüttge U.
Plant Biology. 2002 4(6). p.671
Clusia (2007)
Photosynthesis (1981)
Are the metabolic components of crassulacean acid metabolism up-regulated in response to an increase in oxidative burden?
Borland Anne,
Elliott Stewart,
Patterson Susan,
Taybi Tahar,
Cushman John,
Pater Beata, Barnes Jeremy
Journal of Experimental Botany. 2006 57(2). p.319
INTERACTIONS BETWEEN INTERNAL AND EXTERNAL CO2 POOLS IN THE PHOTOSYNTHESIS OF THE AQUATIC CAM PLANTS LITTORELLA UNIFLORA (L.) ASCHERS AND ISOETES LACUSTRIS L.
MADSEN TOM VINDBÆK
New Phytologist. 1987 106(1). p.35
Le vie fotosintetiche C3, C4e CAM nel contesto ecologico
De Santo Amalia Virzo
Giornale botanico italiano. 1986 120(1-6). p.119
Induction of Crassulacean acid metabolism by water limitation
Cushman J. C., Borland A. M.
Plant, Cell & Environment. 2002 25(2). p.295
Light period of Crassulacean Acid Metabolism: Control of carbon transfer from malic acid to carbohydrates by CO2 concentration
Fischer A., Kluge M.
Physiologia Plantarum. 1985 63(3). p.327
Discoveries in Photosynthesis (2005)
Progress in Botany Vol. 78 (2016)
Localization of carbonic anhydrase in crassulacean acid metabolism plants
Tsuzuki M.,
Miyachi S.,
Winter K., Edwards G.E.
Plant Science Letters. 1982 24(2). p.211
The evolution of the role of ABA in the regulation of water-use efficiency: From biochemical mechanisms to stomatal conductance
Negin Boaz, Moshelion Menachem
Plant Science. 2016 251 p.82
CO2 gas exchange and the occurrence of CAM in tropical woody hemiepiphytes
Zotz Gerhard,
Patino Sandra, Tyree Melvin T.
Flora. 1997 192(2). p.143
Stomatal regulation and water economy in crassulacean acid metabolism plants: an optimization model
Comins H.N., Farquhar G.D.
Journal of Theoretical Biology. 1982 99(2). p.263
Partial characterization and expression of leaf catalase in the CAM-inducible halophyte Mesembryanthemum crystallinum L.
Niewiadomska Ewa, Miszalski Zbigniew
Plant Physiology and Biochemistry. 2008 46(4). p.421
Stomatal responses to CO2 during a diel Crassulacean acid metabolism cycle in Kalanchoe daigremontiana and Kalanchoe pinnata
VON CAEMMERER SUSANNE, GRIFFITHS HOWARD
Plant, Cell & Environment. 2009 32(5). p.567
Thirty Years of Photosynthesis 1974–2004 (2006)
Effects of salinity, high irradiance, ozone, and ethylene on mode of photosynthesis, oxidative stress and oxidative damage in the C3/CAM intermediate plant Mesembryanthemum crystallinum L.
HURST A. C.,
GRAMS T. E. E., RATAJCZAK R.
Plant, Cell & Environment. 2004 27(2). p.187
CAM‐physiology and carbon gain of the orchid Phalaenopsis in response to light intensity, light integral and CO2
Hogewoning Sander W.,
van den Boogaart Stefan A.J.,
van Tongerlo Evelien, Trouwborst Govert
Plant, Cell & Environment. 2021 44(3). p.762
Plant responses to high O2 concentrations: relevance to previous high O2 episodes
Raven John A.
Palaeogeography, Palaeoclimatology, Palaeoecology. 1991 97(1-2). p.19
One Morphotype, Three Physiotypes: Sympatric Species of Clusia with Obligate C3 Photosynthesis, Obligate CAM and C3‐CAM Intermediate Behaviour
Lüttge U.
Plant Biology. 1999 1(2). p.138
Engineering crassulacean acid metabolism to improve water-use efficiency
Borland Anne M.,
Hartwell James,
Weston David J.,
Schlauch Karen A.,
Tschaplinski Timothy J.,
Tuskan Gerald A.,
Yang Xiaohan, Cushman John C.
Trends in Plant Science. 2014 19(5). p.327
