Alvey S, Bagayoko M, Neumann G, Buerkert A (2001) Cereal/legume rotations affect chemical properties and biological activities in two West African soils. Plant Soil 231: 45-54.
An GH, Kobayashi S, Enoki H, Sonobe K, Muraki M, Karasawa T, Ezawa T (2010) How does arbuscular mycorrhizal colonization vary with host plant genotype? An example based on maize (Zea mays) germplasms. Plant Soil 327: 441-453.
Bardgett RD, Mommer L, De Vries FT (2014) Going underground: root traits as drivers of ecosystem processes. Trends Ecol Evol 29: 692-699.
Bergmann J, Weigelt A, van Der Plas F, Laughlin DC, Kuyper TW, Guerrero-Ramirez NR, Valverde-Barrantes OJ, Bruelheide H, Freschet GT, Iversen CM, Kattge J, Mccormack ML, Meier IC, Rillig MC, Roumet C, Semchenko M, Sweeney CJ, van Ruijven J, York LM, Mommer L (2020) The fungal collaboration gradient dominates the root economics space in plants. Sci Adv 6: article eaba3756.
Blaas H, Kroeze C (2016) Excessive nitrogen and phosphorus in European rivers: 2000–2050. Ecol Indic 67: 328-337.
Cely MVT, de Oliveira AG, de Freitas VF, de Luca MB, Barazetti AR, dos Santos IMO, Gionco B, Garcia GV, Prete CEC, Andrade G (2016) Inoculant of arbuscular mycorrhizal fungi (Rhizophagus clarus) increase yield of soybean and cotton under field conditions. Front Microbiol 7: article 720.
Chen BL, Wang QH, Bucking H, Sheng JD, Luo J, Chai ZP, Kafle A, Hou YY, Feng G (2019) Genotypic differences in phosphorus acquisition efficiency and root performance of cotton (Gossypium hirsutum) under low-phosphorus stress. Crop Pasture Sci 70: 344-358.
Chu Q, Wang XX, Yang Y, Chen FJ, Zhang FS, Feng G (2013) Mycorrhizal responsiveness of maize (Zea mays L.) genotypes as related to releasing date and available P content in soil. Mycorrhiza 23: 497-505.
Damodaran PN, Udaiyan K, Roh KS (2012) Mycorrhizal dependency in certain Indian cotton cultivars. Res Plant Biol 2: 55-66.
Eskandari S, Guppy CN, Knox OGG, Backhouse D, Haling RE (2018) Understanding the impact of soil sodicity on mycorrhizal symbiosis: Some facts and gaps identified from cotton systems. Applied Soil Ecology 126: 199-201.
Eskandari S, Guppy CN, Knox OGG, Flavel RJ, Backhouse D, Haling RE (2017) Mycorrhizal contribution to phosphorus nutrition of cotton in low and highly sodic soils using dual isotope labelling (32P and 33P). Soil Biol Biochem 105: 37-44.
Fageria NK (2014) Growth, nutrient uptake, and use efficiency in dry bean in tropical upland soil. J Plant Nutr 37: 2085-2093.
Fageria NK, Gheyi HR, Carvalho MCS, Moreira A (2016) Root growth, nutrient uptake and use efficiency by roots of tropical legume cover crops as influenced by phosphorus fertilization. J Plant Nutr 39: 781-792.
Galván GA, Kuyper TW, Burger K, Keizer LCP, Hoekstra RF, Kik C, Scholten OE (2011) Genetic analysis of the interaction between Allium species and arbuscular mycorrhizal fungi. Theor Appl Genet 122: 947-960.
Gao XP, Kuyper TW, Zou CQ, Zhang FS, Hoffland E (2007) Mycorrhizal responsiveness of aerobic rice genotypes is negatively correlated with their zinc uptake when nonmycorrhizal. Plant Soil 290: 283-291.
Gill MA, Sabir M, Ashraf S, Rahmatullah., Aziz T (2005) Effect of P-stress on growth, phosphorus uptake and utilization efficiency of different cotton cultivars. Pak J Agr Sci 42: 42-47.
Guerrero-Ramirez NR, Mommer L, Freschet GT, Iversen CM, McCormack ML, Kattge J, Poorter H, van der Plas F, Bergmann J, Kuyper TW, York LM, Bruelheide H, Laughlin DC, Meier IC, Roumet C, Semchenko M, Sweeney CJ, van Ruijven J, Valverde-Barrantes OJ, Aubin I, Catford JA, Manning P, Martin A, Milla R, Minden V, Pausas JG, Smith SW, Soudzilovskaia NA, Ammer C, Butterfield B, Craine J, Cornelissen JHC, de Vries FT, Isaac ME, Kramer K, Konig C, Lamb EG, Onipchenko VG, Penuelas J, Reich PB, Rillig MC, Sack L, Shipley B, Tedersoo L, Valladares F, van Bodegom P, Weigelt P, Wright JP, Weigelt A (2021) Global root traits (GRooT) database. Global Ecol Biogeogr 30: 25-37.
Hodge A, Berta G, Doussan C, Merchan F, Crespi M (2009) Plant root growth, architecture and function. Plant Soil 321: 153-187.
Jakobsen I, Abbott LK, Robson AD (1992) External hyphae of vesicular arbuscular mycorrhizal fungi associated with Trifolium subterraneum l. 2. Hyphal transport of 32P over defined distances. New Phytol 120: 509-516.
Janos DP (2007) Plant responsiveness to mycorrhizas differs from dependence upon mycorrhizas. Mycorrhiza 17: 75-91.
Kaeppler SM, Parke JL, Mueller SM, Senior L, Stuber C, Tracy WF (2000) Variation among maize inbred lines and detection of quantitative trait loci for growth at low phosphorus and responsiveness to arbuscular mycorrhizal fungi. Crop Sci 40: 358-364.
Kidd DR, Ryan MH, Haling RE, Lambers H, Sandral GA, Yang Z, Culvenor RA, Cawthray GR, Stefanski A, Simpson RJ (2015) Rhizosphere carboxylates and morphological root traits in pasture legumes and grasses. Plant Soil: 1-13.
Kuyper TW, Wang XX, Muchane MN (2021) The interplay between roots and arbuscular mycorrhizal fungi influencing water and nutrient acquisition and use efficiency. In: Rengel Z, Djalovic I (eds) The Root Systems in Sustainable Agricultural Intensification. John Wiley & Sons Inc, New Jersey, USA.
Lambers H, Shane MW, Cramer MD, Pearse SJ, Veneklaas EJ (2006) Root structure and functioning for efficient acquisition of phosphorus: matching morphological and physiological traits. Ann Bot 98: 693-713.
Lehmann A, Barto EK, Powell JR, Rillig MC (2012) Mycorrhizal responsiveness trends in annual crop plants and their wild relatives—a meta analysis on studies from 1981 to 2010. Plant Soil 355: 231-250.
Lekberg Y, Koide RT (2005) Is plant performance limited by abundance of arbuscular mycorrhizal fungi? A meta-analysis of studies published between 1988 and 2003. New Phytol 168: 189-204.
Li H, Ma Q, Li H, Zhang F, Rengel Z, Shen J (2014) Root morphological responses to localized nutrient supply differ among crop species with contrasting root traits. Plant Soil 376: 151-163.
Liu SL, Guo XL, Feng G, Maimaitiaili B, Fan JL, He XH (2016) Indigenous arbuscular mycorrhizal fungi can alleviate salt stress and promote growth of cotton and maize in saline fields. Plant Soil 398: 195-206.
Liu Y, Villalba G, Ayres RU, Schroder H (2008) Global phosphorus flows and environmental impacts from a consumption perspective. J Ind Ecol 12: 229-247.
Lynch JP (2019) Root phenotypes for improved nutrient capture: an underexploited opportunity for global agriculture. New Phytol undefined: undefined.
Lyu Y, Tang HL, Li HG, Zhang FS, Rengel Z, Whalley WR, Shen JB (2016) Major crop species show differential balance between root morphological and physiological responses to variable phosphorus supply. Front Plant Sci 7: article 1939.
Mai W, Xue X, Feng G, Yang R, Tian C (2018) Can optimization of phosphorus input lead to high productivity and high phosphorus use efficiency of cotton through maximization of root/mycorrhizal efficiency in phosphorus acquisition? Field Crop Res 216: 100-108.
Martin-Robles N, Morente-Lopez J, Freschet GT, Poorter H, Roumet C, Milla R (2019) Root traits of herbaceous crops: Pre-adaptation to cultivation or evolution under domestication? Funct Ecol 33: 273-285.
McMichael BL, Burke JJ, Berlin JD, Hatfield JL, Quisenberry JE (1985) Root vascular bundle arrangements among cotton strains and cultivars. Environ Exp Bot 25: 23-30.
Murphy J, Riley JP (1962) A modified single solution method for the determination of phosphate in natural waters. Anal Chim Acta 27: 31-36.
Nehl DB, McGee PA (2010) Ecophysiology of arbuscular mycorrhizas in cotton. In: Stewart JM, Oosterhuis DM, Heitholt JJ, Mauney JR (eds) Physiology of Cotton. Springer Netherlands, Dordrecht. 206-212.
Neumann G (2006) Quantitative determination of acid phosphatase activity in the rhizosphere and on the root surface. In: Luster, J, Finlay, R (Eds), Handbook of Methods used in Rhizosphere Research: 418-442.
Ostonen I, Püttsepp Ü, Biel C, Alberton O, Bakker M, Lõhmus K, Majdi H, Metcalfe D, Olsthoorn A, Pronk A (2007) Specific root length as an indicator of environmental change. Plant Biosyst 141: 426-442.
Pang J, Yang J, Lambers H, Tibbett M, Siddique KHM, Ryan MH (2015) Physiological and morphological adaptations of herbaceous perennial legumes allow differential access to sources of varyingly soluble phosphate. Physiol Plantarum 154: 511-525.
Raghothama KG (1999) Phosphate acquisition. Annu Rev Plant Phys 50: 665-693.
Reich PB (2014) The world-wide 'fast-slow' plant economics spectrum: a traits manifesto. J Ecol 102: 275-301.
Ryan MH, Tibbett M, Edmonds-Tibbett T, Suriyagoda LDB, Lambers H, Cawthray GR, Pang J (2012) Carbon trading for phosphorus gain: the balance between rhizosphere carboxylates and arbuscular mycorrhizal symbiosis in plant phosphorus acquisition. Plant Cell Environ 35: 2170-2180.
Salgado FHM, Moreira FMD, Siqueira JO, Barbosa RH, Paulino HB, Carneiro MAC (2017) Arbuscular mycorrhizal fungi and colonization stimulant in cotton and maize. Cienc Rural 47.
Sawers RJH, Gebreselassie MN, Janos DP, Paszkowski U (2010) Characterizing variation in mycorrhiza effect among diverse plant varieties. Theor Appl Genet 120: 1029-1039.
Sawers RJH, Gutjahr C, Paszkowski U (2008) Cereal mycorrhiza: an ancient symbiosis in modern agriculture. Trends Plant Sci 13: 93-97.
Seifert EK, Bever JD, Maron JL (2009) Evidence for the evolution of reduced mycorrhizal dependence during plant invasion. Ecology 90: 1055-1062.
Trouvelot A, Kough, Gianiazzi-Pearson V (1986) Mesure du taux de mycorrhization VA d’un système radiculaire. Recherche de methodsd’estimation ayant une signification fonctionnelle. In: Gianinazzi-Pearson V and Gianinazzi S (eds.). Physiological Genetical Aspects of Mycorrhizae. INRA Press, Paris, France. pp. 217-221.
Valverde-Barrantes OJ, Horning AL, Smemo KA, Blackwood CB (2016) Phylogenetically structured traits in root systems influence arbuscular mycorrhizal colonization in woody angiosperms. Plant Soil 404: 1-12.
Vance CP, Uhde-Stone C, Allan DL (2003) Phosphorus acquisition and use: critical adaptations by plants for securing a nonrenewable resource. New Phytol 157: 423-447.
Veneklaas EJ, Stevens J, Cawthray GR, Turner S, Grigg AM, Lambers H (2003) Chickpea and white lupin rhizosphere carboxylates vary with soil properties and enhance phosphorus uptake. Plant Soil 248: 187-197.
Wang XJ, Tang CX, Guppy CN, Sale PWG (2010) Cotton, wheat and white lupin differ in phosphorus acquisition from sparingly soluble sources. Environ Exp Bot 69: 267-272.
Wang XX, Li HB, Chu Q, Feng G, Kuyper TW, Rengel Z (2020a) Mycorrhizal impacts on root trait plasticity of six maize varieties along a phosphorus supply gradient. Plant Soil 448: 71-86.
Wang XX, van der Werf W, Yu Y, Hoffland E, Feng G, Kuyper TW (2020b) Field performance of different maize varieties in growth cores at natural and reduced mycorrhizal colonization: Yield gains and possible fertilizer savings in relation to phosphorus application. Plant Soil 450: 613-624.
Wen ZH, Li HB, Shen Q, Tang XM, Xiong CY, Li HG, Pang JY, Ryan MH, Lambers H, Shen JB (2019) Trade-offs among root morphology, exudation and mycorrhizal symbioses for phosphorus-acquisition strategies of 16 crop species. New Phytol 223: 882-895.
Xiao S, Liu LT, Zhang YJ, Sun HC, Zhang K, Bai ZY, Dong HZ, Li CD (2020) Fine root and root hair morphology of cotton under drought stress revealed with RhizoPot. J Agron Crop Sci 206: 679-693.
Yan Z, Liu P, Li Y, Ma L, Alva A, Dou Z, Chen Q, Zhang F (2013) Phosphorus in China's intensive vegetable production systems: overfertilization, soil enrichment, and environmental implications. J Environ Qual 42: 982-989.
Zak JC, McMichael B, Dhillion S, Friese C (1998) Arbuscular-mycorrhizal colonization dynamics of cotton (Gossypium hirsutum L.) growing under several production systems on the Southern High Plains, Texas. Agr Ecosyst Environ 68: 245-254.
Zhang WF, Ma WQ, Ji YX, Fan MS, Oenema O, Zhang FS (2008) Efficiency, economics, and environmental implications of phosphorus resource use and the fertilizer industry in China. Nutr Cycl Agroecosys 80: 131-144.
Zhu JM, Lynch JP (2004) The contribution of lateral rooting to phosphorus acquisition efficiency in maize (Zea mays) seedlings. Funct Plant Biol 31: 949-958.