Crossref Citations
This article has been cited by the following publications. This list is generated based on data provided by
Crossref.
El-Sharkawy, M. A.
2005.
How can calibrated research-based models be improved for use as a tool in identifying genes controlling crop tolerance to environmental stresses in the era of genomics-from an experimentalist's perspective.
Photosynthetica,
Vol. 43,
Issue. 2,
p.
161.
El-Sharkawy, M.A.
2006.
International research on cassava photosynthesis, productivity, eco-physiology, and responses to environmental stresses in the tropics.
Photosynthetica,
Vol. 44,
Issue. 4,
p.
481.
El-Sharkawy, M. A.
and
De Tafur, S. M.
2007.
Genotypic and within canopy variation in leaf carbon isotope discrimination and its relation to short-term leaf gas exchange characteristics in cassava grown under rain-fed conditions in the tropics.
Photosynthetica,
Vol. 45,
Issue. 4,
p.
515.
Setter, Tim L.
and
Fregene, Martin A.
2007.
Advances in Molecular Breeding Toward Drought and Salt Tolerant Crops.
p.
701.
Sakurai, Tetsuya
Plata, Germán
Rodríguez-Zapata, Fausto
Seki, Motoaki
Salcedo, Andrés
Toyoda, Atsushi
Ishiwata, Atsushi
Tohme, Joe
Sakaki, Yoshiyuki
Shinozaki, Kazuo
and
Ishitani, Manabu
2007.
Sequencing analysis of 20,000 full-length cDNA clones from cassava reveals lineage specific expansions in gene families related to stress response.
BMC Plant Biology,
Vol. 7,
Issue. 1,
Oguntunde, Philip G.
and
Alatise, Michael O.
2007.
Environmental regulation and modelling of cassava canopy conductance under drying root‐zone soil water.
Meteorological Applications,
Vol. 14,
Issue. 3,
p.
245.
El-Sharkawy, M. A.
Lopez, Y.
and
Bernal, L. M.
2008.
Genotypic variations in activities of phosphoenolpyruvate carboxylase and correlations with leaf photosynthetic characteristics and crop productivity of cassava grown in low-land seasonally-dry tropics.
Photosynthetica,
Vol. 46,
Issue. 2,
El-Sharkawy, M. A.
2009.
Pioneering research on C<sub>4</sub> leaf anatomical, physiological, and agronomic characteristics of tropical monocot and dicot plant species: Implications for crop water relations and productivity in comparison to C<sub>3</sub> cropping systems.
Photosynthetica,
Vol. 47,
Issue. 2,
p.
163.
Gleadow, Roslyn M.
Evans, John R.
McCaffery, Stephanie
and
Cavagnaro, Timothy R.
2009.
Growth and nutritive value of cassava (Manihot esculenta Cranz.) are reduced when grown in elevated CO2.
Plant Biology,
Vol. 11,
Issue. s1,
p.
76.
Q. Subere, Juvy Oliva
Bolatete, Dioscoro
Bergantin, Reynaldo
Pardales, Andreu
Belmonte, Jedi Jim
Mariscal, Algerico
Sebidos, Rodrigo
and
Yamauchi, Akira
2009.
Genotypic Variation in Responses of Cassava (Manihot esculentaCrantz) to Drought and Rewatering: Root System Development.
Plant Production Science,
Vol. 12,
Issue. 4,
p.
462.
El-Sharkawy, M. A.
and
De Tafur, S. M.
2010.
Comparative photosynthesis, growth, productivity, and nutrient use efficiency among tall- and short-stemmed rain-fed cassava cultivars.
Photosynthetica,
Vol. 48,
Issue. 2,
p.
173.
El-Sharkawy, Mabrouk A.
2012.
Stress-Tolerant Cassava: The Role of Integrative Ecophysiology-Breeding Research in Crop Improvement.
Open Journal of Soil Science,
Vol. 02,
Issue. 02,
p.
162.
Sakurai, Tetsuya
Mochida, Keiichi
Yoshida, Takuhiro
Akiyama, Kenji
Ishitani, Manabu
Seki, Motoaki
Shinozaki, Kazuo
and
Aerts, Jan
2013.
Genome-Wide Discovery and Information Resource Development of DNA Polymorphisms in Cassava.
PLoS ONE,
Vol. 8,
Issue. 9,
p.
e74056.
Pinheiro, Diego Garrido
Streck, Nereu Augusto
Richter, Gean Leonardo
Langner, Josana Andreia
Winck, José Eduardo Minussi
Uhlmann, Lilian Osmari
and
Zanon, Alencar Junior
2014.
Limite crítico no solo para transpiração e crescimento foliar em mandioca em dois períodos com deficiência hídrica.
Revista Brasileira de Ciência do Solo,
Vol. 38,
Issue. 6,
p.
1740.
Santa Brígida, Ailton Borges
dos Reis, Sávio Pinho
de Nazaré Monteiro Costa, Carinne
Cardoso, Cristina Michiko Yokoyama
Lima, Aline Medeiros
and
de Souza, Cláudia Regina Batista
2014.
Molecular cloning and characterization of a cassava translationally controlled tumor protein gene potentially related to salt stress response.
Molecular Biology Reports,
Vol. 41,
Issue. 3,
p.
1787.
Gabriel, Luana F.
Streck, Nereu A.
Uhlmann, Lilian O.
Silva, Michel R. da
and
Silva, Stefanía D. da
2014.
Mudança climática e seus efeitos na cultura da mandioca.
Revista Brasileira de Engenharia Agrícola e Ambiental,
Vol. 18,
Issue. 1,
p.
90.
Polthanee, Anan
Taboonmuan, Rangrong
and
Manaonok, Jawapa
2015.
Root Yield and Nutrient Removal of Four Cassava Cultivars Planted in Early Rainy Season of Northeastern Thailand: Crop Experienced to Drought at Mid-Growth Stage.
Asian Journal of Crop Science,
Vol. 8,
Issue. 1,
p.
24.
Brown, Alicia L.
Cavagnaro, Timothy R.
Gleadow, Ros
and
Miller, Rebecca E.
2016.
Interactive effects of temperature and drought on cassava growth and toxicity: implications for food security?.
Global Change Biology,
Vol. 22,
Issue. 10,
p.
3461.
De Souza, Amanda P.
Massenburg, Lynnicia N.
Jaiswal, Deepak
Cheng, Siyuan
Shekar, Rachel
and
Long, Stephen P.
2017.
Rooting for cassava: insights into photosynthesis and associated physiology as a route to improve yield potential.
New Phytologist,
Vol. 213,
Issue. 1,
p.
50.
Jolayemi, Okanlawon Lekan
Opabode, Jelili Titilola
and
Badara, Gueye
2018.
In vitro response of three contrasting cassava (Manihot esculenta Crantz) varieties to mannitol-induced drought stress.
Agricultura Tropica et Subtropica,
Vol. 51,
Issue. 3,
p.
125.