作物科学研究室

Ueda R, Yano K (2023) Endophytic N2 fixation in sweet potato: responses to N, P, and K inputs and visualization of 15N2 utilizing bacterial cells via Raman spectroscopy. Biology and Fertility of Soils 59, 275–283. DOI

Yi Y, Yano K (2022) Verification of water-use efficiency estimates via carbon isotope discrimination in potato under varying nutrient statuses and CO2 conditions. Physiologia Plantarum 174, e13660. DOI

矢野勝也・関谷信人 ( 2012) 作物の生理生態研究ツールとしての安定同位体：水素，炭素，窒素. 日本作物学会紀事 81, 460-465. DOI

Sekiya N, Yano K (2008) Stomatal density of cowpea correlates carbon isotope discrimination in different phosphorus, water and CO2 environments. New Phytologist 179, 799–807. DOI

Yano K, Sekiya N, Samson BK, Mazid MA, Yamauchi A, Kono Y, Wade LJ (2006) Hydrogen isotope composition of soil water above and below the hardpan in a rainfed lowland rice field. Field Crops Research 96, 477–480. DOI

Tanaka Y, Yano K (2005) Nitrogen delivery to maize via mycorrhizal hyphae depends on the form of N supplied. Plant, Cell & Environment 28, 1247–1254. DOI

Yi Y, Yano K (2025) Sugar accumulation drives elevated CO2-induced senescence in Solanum tuberosum. Physiologia Plantarum 177, e70470. DOI

Yi Y, Yano K (2024) Accelerate senescence reversed CO2-fertilization effect under elevated CO2 in potato: a weak relationship with nitrogen acquisition. Journal of Agronomy and Crop Science 210, e12731. DOI

Yi Y, Yano K (2023) Nocturnal versus diurnal transpiration in rice plants: Analysis of five genotypes grown under different atmospheric CO2 and soil moisture conditions. Agricultural Water Management 286,108397. DOI

Igarashi M, Yi Y, Yano K (2021) Revisiting why plants become N deficient under elevated CO2: importance to meet N demand regardless of the fed-form. Frontiers in Plant Science 12, 726186. DOI

Yi Y, Yano K (2021) Plant growth and water economy of Solanum tuberosum in response to doubled CO2: interaction between potassium and phosphorus. Journal of Agronomy and Crop Science 210, 901–912. DOI

Yi Y, Sugiura D, Yano K (2020) Nitrogen and water demands for maximum growth of Solanum tuberosum under doubled CO2: interaction with phosphorus based on the demands. Environmental and Experimental Botany 176, 104089. DOI

Yi Y, Sugiura D, Yano K (2019) Quantifying phosphorus and water demand to attain maximum growth of Solanum tuberosum in a CO2-enriched environment. Frontiers in Plant Science 10, 1417. DOI

Sekiya N, Araki H, Yano K (2011) Applying hydraulic lift in an agroecosystem: forage plants with shoots removed supply water to neighboring vegetable crops. Plant and Soil 341, 39-50. DOI

Yano K, Sekiya N, Samson BK, Mazid MA, Yamauchi A, Kono Y, Wade LJ (2006) Hydrogen isotope composition of soil water above and below the hardpan in a rainfed lowland rice field. Field Crops Research 96, 477–480. DOI

Sekiya N, Yano K (2006) Water-extraction by split-roots of sesbania and pigeon pea exposed to spatially heterogeneous distribution of soil water. Plant Production Science 9, 191–199

Sekiya N, Yano K (2004) Do pigeon pea and sesbania supply groundwater to intercropped maize through hydraulic lift? –Hydrogen stable isotope investigation of xylem waters. Field Crops Research 86, 167–173. DOI

Sekiya N, Yano K (2002) Water acquisition from rainfall and groundwater by legume crops developing deep rooting systems determined with stable hydrogen isotope compositions of xylem waters. Field Crops Research 78, 133–139. DOI

Tanaka Y, Yano K (2005) Nitrogen delivery to maize via mycorrhizal hyphae depends on the form of N supplied. Plant, Cell & Environment 28, 1247–1254. DOI

Yano K, Takaki M (2005) Mycorrhizal alleviation of acid soil stress in the sweet potato (Ipomoea batatas). Soil Biology & Biochemistry 37, 1569–1572. DOI

Shibata R, Yano K (2003) Phosphorus acquisition from non-labile sources in peanut and pigeonpea with mycorrhizal interaction. Applied Soil Ecology 24, 133–141. DOI

McGonigle TP, Yano K, Shinhama T (2003) Mycorrhizal phosphorus enhancement of plants in undisturbed soil differs from phosphorus uptake stimulation by arbuscular mycorrhizae over non-mycorrhizal controls. Biology and Fertility of Soils 37, 268–273. DOI

Yano K, Yamauchi A, Iijima M, Kono Y (1998) Arbuscular mycorrhizal formation in undisturbed soil counteracts compacted soil stress for pigeon pea. Applied Soil Ecology 10, 95–102. DOI

Yano K, Yamauchi A, Kono Y (1996) Localized alteration in lateral root development in roots colonized by an arbuscular mycorrhizal fungus. Mycorrhiza 6, 409–415. DOI

Sekiya N, Fukujyu R, Yano K (2013) Effects of seed P-enrichment and localized P-fertilizer application on soil-grown wheat. Plant Production Science 16, 199-202. DOI

Sekiya N, Yano K (2010) Seed P-enrichment as an effective P suppy to wheat. Plant and Soil 327, 347–354. DOI

Kume T, Sekiya N, Yano K (2006) Heterogeneity in spatial P-distribution and foraging capability by Zea mays: effects of patch size and barriers to restrict root proliferation within a patch. Annals of Botany 98, 1271–1277. DOI

Yano K, Kume T (2005) Root morphological plasticity for heterogeneous phosphorus supply in Zea mays L. Plant Production Science 8, 427–432. DOI

Shibata R, Yano K (2003) Phosphorus acquisition from non-labile sources in peanut and pigeonpea with mycorrhizal interaction. Applied Soil Ecology 24, 133–141. DOI

McGonigle TP, Yano K, Shinhama T (2003) Mycorrhizal phosphorus enhancement of plants in undisturbed soil differs from phosphorus uptake stimulation by arbuscular mycorrhizae over non-mycorrhizal controls. Biology and Fertility of Soils 37, 268–273. DOI

Okamoto K, Yano K (2017) Al resistance and mechanical impedance to roots in Zea mays: reduced Al toxicity via enhanced mucilage production. Rhizosphere 3, 60–66. DOI

Yano K, Takaki M (2005) Mycorrhizal alleviation of acid soil stress in the sweet potato (Ipomoea batatas). Soil Biology & Biochemistry 37, 1569–1572. DOI

Rao TP, Yano K, Iijima M, Yamauchi A, Tatsumi J (2002) Regulation of rhizosphere acidification by photosynthetic activity in cowpea (Vigna unguiculata L. Walp.) seedlings. Annals of Botany 89, 213–220. DOI

Rao TP, Yano K, Yamauchi A, Tatsumi J (2000) Rhizosphere pH changes induced by exposure of shoot to light. Plant Production Science 3, 101–107. DOI

Rao TP, Yano K, Yamauchi A, Tatsumi J (2000) A simple method for quantitative estimation of rhizosphere pH along root axes through visualization. Plant Production Science 3, 94–100. DOI