Ito, O. Person

selected publications

• article

  • Dynamics of Fertilizer Nitrogen Applied to Sweet Sorghum ( Sorghum bicolor (L.) Moench) in the Semi-Arid Tropics.  Jarq-japan Agricultural Research Quarterly.  49:409-418. 2015
  • Scope for improvement of yield under drought through the root traits in chickpea (Cicer arietinum L.).  Field Crops Research.  170:47-54. 2015
  • Genetic Dissection of Drought and Heat Tolerance in Chickpea through Genome-Wide and Candidate Gene-Based Association Mapping Approaches.  PLOS ONE.  9:1-12. 2014
  • CALIBRATING CHLOROPHYLL METER (SPAD-502) READING BY SPECIFIC LEAF AREA FOR ESTIMATING LEAF NITROGEN CONCENTRATION IN SWEET SORGHUM.  International plant nutrition colloquium. 10.  36:1640-1646. 2013
  • Effects of Nitrogen Application on Sweet Sorghum (Sorghum bicolor (L.) Moench) in the Semi-Arid Tropical Zone of India.  Jarq-japan Agricultural Research Quarterly.  47:65-73. 2013
  • Fertilizer induced nitrous oxide emissions from Vertisols and Alfisols during sweet sorghum cultivation in the Indian semi-arid tropics..  Science of The Total Environment.  438:9-14. 2012
  • Identification of plant genetic resources with high potential contribution to soil fertility enhancement in the Sahel, with special interest in fallow vegetation 2011
  • Broader leaves result in better performance of indica rice under drought stress..  Journal of Plant Physiology.  167:1066-1075. 2010
  • Biological nitrification inhibition (BNI) - is there potential for genetic interventions in the Triticeae?.  Breeding Science.  59:529-545. 2009
  • Biological nitrification inhibition (BNI) - is there potential for genetic interventions in the Triticeae 2009
  • Can biological nitrification inhibition (BNI) genes from perennial Leymus racemosus (Triticeae) combat nitrification in wheat farming.  Plant and Soil.  299:55-64. 2007
  • Biological nitrification inhibition (BNI)—is it a widespread phenomenon?.  Plant and Soil.  294:5-18. 2007
  • Relationships between Transpiration Efficiency and Carbon Isotope Discrimination in Chickpea (C. arietinum L) 2006
  • Characterization of Root Systems with Respect to Morphological Traits and Nitrogen-Absorbing Ability in the New Plant Type of Tropical Rice Lines.  International plant nutrition colloquium. 10.  28:835-850. 2005
  • Root-shoot interaction as a limiting factor of biomass productivity in new tropical rice lines.  Soil Science and Plant Nutrition.  50:545-554. 2004
  • Importance of active oxygen-scavenging system in the recovery of rice seedlings after submergence.  Plant Science.  165:85-93. 2003
  • Comparison of Adaptability to Flash Flood between Rice Cultivars Differing in Flash Flood Tolerance.  Soil Science and Plant Nutrition.  48:659-665. 2002
  • Physiological evaluation of responses of rice (Oryza sativa L.) to water deficit.  Plant Science.  163:815-827. 2002
  • Metabolic changes in rice seedlings with different submergence tolerance after desubmergence.  Environmental and Experimental Botany.  47:195-203. 2002
  • Varietal differences in root growth as related to nitrogen uptake by sorghum plants in low-nitrogen environment.  Plant and Soil.  245:17-24. 2002
  • Enhancement of Submergence Tolerance in Transgenic Rice Overproducing Pyruvate Decarboxylase.  Journal of Plant Physiology.  156:516-521. 2000
  • Analysis of Relationship between Root Length Density and Water Uptake by Roots of Five Crops Using Minirhizotron in the Semi-Arid Tropics 2000
  • Root Behavior and Nitrogen Balance Sheet in Four Pigeonpea-Based Intercropping Systems on a Deep Alfisol in the Semi-Arid Tropics.  Japanese journal of tropical agriculture.  43:181-187. 1999
  • Effects of NPK fertilizer combinations on yield and nitrogen balance in sorghum or pigeonpea on a vertisol in the semi-arid tropics.  Soil Science and Plant Nutrition.  45:143-150. 1999
  • Remobilization of nitrogen from senescing leaves of pigeonpea (Cajanus cajan (L.) Millsp.): genotypic differences across maturity groups?.  Journal of Experimental Botany.  49:853-862. 1998
  • Seedling characteristics and retention of current photosynthates in leaves in relation to initial growth in pigeonpea (Cajanus cajanL. Millsp.) and cowpea (Vigna sinensisEndl.) 1998
  • Timing of N fertilization on N2 fixation, N recovery and soil profile nitrate dynamics on sorghum/pigeonpea intercrops on Alfisols on the semi-arid tropics.  Nutrient Cycling in Agroecosystems.  48:197-208. 1997
  • Nitrogen Management in Sorghum/Pigeonpea Intercrop 1997
  • Nitrogen fertilizer management in pigeonpea/sorghum intercropping on an Alfisol in the semi-arid tropics 1997
  • Nitrogen management and biological nitrogen fixation in sorghum / pigeonpea intercropping on Alfisols of the semi-arid tropics 1997
  • Nitrogen management and biological nitrogen fixation in sorghum/pigeonpea intercropping on Alfisols of the semi-arid tropics.  Soil Science and Plant Nutrition.  43:1061-1066. 1997
  • Estimation of Soil Nitrogen Status in Intercropping Through Soil Solution 1996
  • Nitrogen balance and root behavior in four pigeonpea-based intercropping systems 1995
  • Response Of The Pigeonpea (Cajanus Cajan (L.) Millspaugh) To Nitrogen Application And Temporary Waterlogging 1992
  • Availability to Rice Plants of Nitrogen Fixed byAzolla 1985
  • THE RELATIONSHIP BETWEEN COMBINED NITROGEN UPTAKES AND NITROGEN FIXATION IN AZOLLA‐ANABAENA SYMBIOSIS.  New Phytologist.  95:647-654. 1983
  • Immobilization, mineralization and availability to rice plants of nitrogen derived from heterotrophic nitrogen fixation in flooded soil.  Soil Science and Plant Nutrition.  27:169-176. 1981
  • Fixation of Dinitrogen-15 Associated with Rice Plants.  Applied and Environmental Microbiology.  39:554-558. 1980
  • Dual culture of rice and azolla and its effect to rice yield 1980
  • Nitrogen fixation in wetland soils and its availability to rice plants measured by 15N tracer method 1979
  • Incorporation of14CO2and15NH4into amino acids of the two subunits of fraction 1 protein in spinach leaves.  Soil Science and Plant Nutrition.  24:581-586. 1978

• document

  • Biological nitrification inhibition (BNI): a dual benefit for agriculture and the environment 2009
  • Biological nitrification inhibition byBrachiaria humidicolaroots varies with soil type and inhibits nitrifying bacteria, but not other major soil microorganisms 2009
  • Detection, isolation and characterization of a root-exuded compound, methyl 3-(4-hydroxyphenyl) propionate, responsible for biological nitrification inhibition by sorghum (Sorghum bicolor) 2008
  • Is there a genetic strategy to control nitrification and N2O emissions from agricultural systems? - biological Nitrification Inhibition (BNI) 2008
  • Root exudates of Brachiaria humidicola, a tropical pasture grass, and its effect on nitrification and soil microorganisms 2007
  • Nitrification Inhibition (NI) compounds from Brachiaria humidicola, a tropical grass 2006
  • Improving adoption of agricultural technologies : How participatory research can complement conventional research approaches: Resources from a training workshop, 4-8 March, 2002, Tsukuba, Japan 2002
  • Improvement of Soil and Fertilizer Nitrogen Use Efficiency in Sorghum/Pigeonpea Intercropping 1996
  • Inorganic Nitrogen In Soil Water Collected From Soil Under Intercrop Components Sorghum And Pigeonpea - A Pot Experiment 1992
  • Rooting Behavior Of Intercropped Pigeonpea (Cajanus Cajan (L.) Millspaugh) And Sorghum (Sorghum Bicolor (L.) Moench) 1992

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  • RETRACTED: Strategies for Producing More Rice with Less Water.  Advances in Agronomy. 351-388. 2009
  • Physiological basis of submergence tolerance in rainfed lowland rice ecosystem.  Field Crops Research. 75-90. 1999