Non-labile phosphorus acquisition by Brachiaria

References

• Ae, N. A. J., K. Okada, T. Yoshihara, and C. Johansen. 1990. Phosphorus uptake by pigeon pea and its role in cropping systems of the Indian subcontinent. Science 248: 477–480.
   PubMed Web of Science ®Google Scholar
• Atkinson, R. J., A. M. Posner, and J. P. Quirk. 1972. Kinetics of heterogeneous isotopic exchange reactions: Exchange of phosphate at the alpha-FeOOH-aqueous solution interface. Indian Journal of Nuclear Chemistry 34: 2201–2211.
   Web of Science ®Google Scholar
• Gahoonia, T. S., N. E. Nielsen, and O. B. Lyshede. 1999. Phosphorus acquisition of cereal cultivars in the field at three levels of P fertilization. Plant and Soil 211: 265–281.
   Web of Science ®Google Scholar
• Gardner, W. K., D. A. Barber, and D. G. Parberry. 1983. The acquisition of phosphorus by Lupinus albus L. III. The probable mechanism by which phosphorus movement in the soil/root interface is enhanced. Plant and Soil 70: 107–114.
   Web of Science ®Google Scholar
• Gerke, J., L. Beissner, and W. Römer. 2000. The quantitative effect of chemical phosphate mobilisation by carboxylate anions on P uptake by single root. I. The basic concept and determination of soil parameters. Journal of Plant Nutrition and Soil Science 163: 207–212.
   Web of Science ®Google Scholar
• Grierson, P. F. 1992. Organic acids in the rhizosphere of Banksia integrifolia. Plant and Soil 44: 259–65.
   Web of Science ®Google Scholar
• Grundy, S. P., D. L. Jones, and D. L. Godbold. 2002. Organic acid root-tip tissue-concentration in Brachiaria decumbens and Brachiaria ruziziensis. Developments in Plant and Soil Sciences 92: 506–507.
   Google Scholar
• He, Z. L., K. N. Yuan, Z. X. Zhu, and Q. Z. Zhang. 1991. Assessing the fixation and availability of sorbed phosphate in soil using an isotopic exchange method. Journal of Soil Science 42: 661–669.
   Google Scholar
• Hedley, M. J., J. W. B. Stewart, and B. S. Chauhan. 1982. Changes in inorganic and organic soil phosphorus fractions induced by cultivation practices and by laboratory incubations. Soil Science Society of America Journal 46: 970–976.
   Web of Science ®Google Scholar
• Hinsinger, P., E. Betencourt, L. Bernard, A. Brauman, C. Plassard, J. Shen, X. Tang, and F. Zhang. 2011. P for two, sharing a scarce resource: soil phosphorus acquisition in the rhizosphere of intercropped species. Plant Physiology 156: 1078–1086.
   PubMed Web of Science ®Google Scholar
• Hoffland, E. 1992. Quantitative evaluation of the role of organic-acid exudation in the mobilization of rock phosphate by rape. Plant and Soil 140: 279–289.
   Web of Science ®Google Scholar
• Hoffland, E., G. R. Findenegg, and J. A. Nelemans. 1989. Solubilization of rock phosphate by rape. Plant and Soil 113: 155–160.
   Web of Science ®Google Scholar
• Johnson, J. F., D. L. Allan, C. P. Vance, and G. Weiblen. 1996. Root carbon dioxide fixation by phosphorus-deficient Lupinus albus: contribution to organic-acid exudation by proteoid roots. Plant Physiology 112: 19–30.
   PubMed Web of Science ®Google Scholar
• Kamh, M., W. J. Horst, F. Amer, A. Mostafa, and P. Maier. 1999. Mobilization of soil and fertilizer phosphate by cover crops. Plant and Soil 211: 19–27.
   Web of Science ®Google Scholar
• Li, L., F. Zhang, X. Li, P. Christie, J. Sun, S. Yang, and C. Tang. 2003. Interspecific facilitation of nutrient uptake by intercropped maize and faba bean. Nutrient Cycling in Agroecosystems 65: 61–71.
   Web of Science ®Google Scholar
• Lipton, D. S., R. W. Blanchar, and D. G. Blevins. 1987. Citrate, malate, and succinate concentration in exudates from P-sufficient and P-stressed Medicago sativa L. seedlings. Plant Physiology 85: 315–317.
   PubMed Web of Science ®Google Scholar
• Lynch, J. P., and S. E. Beebe. 1995. Adaptation of beans (Phaseolus vulgaris L.) to low phosphorus availability. Horticultural Science 30: 1165–1171.
   Google Scholar
• McLaughlin, J. R., J. C. Ryden, and J. K. Syers. 1981. Sorption of inorganic phosphate by iron- and aluminum-containing components. Journal of Soil Science 32: 365–377.
   Google Scholar
• Murphy, J., and J. P. Riley. 1962. A modified single solution method for the determination of phosphate in natural waters. Analalityca Chimica Acta 27: 31–36.
   Web of Science ®Google Scholar
• Nanamori, M., T. Shinano, J. Wasaki, T. Yamamura, I. M. Rao, and M. Osaki. 2004. Low phosphorus tolerance mechanisms: phosphorus recycling and photosynthate partitioning in the tropical forage grass, Brachiaria hybrid cultivar Mulato compared with rice. Plant and Cell Physiology 45: 460–469.
   PubMed Web of Science ®Google Scholar
• Pavinato, P. S., A. Merlin, and C. A. Rosolem. 2008. Organic compounds from plant extracts and their effect on soil phosphorus availability. Pesquisa Agropecuária Brasileira 43: 1379–1388.
   Web of Science ®Google Scholar
• Pearse, S. J., E. J. Veneklaas, G. R. Cawthray, M. D. A. Bolland, and H. Lambers. 2007. Carboxylate composition of root exudates does not relate consistently to a crop species' ability to use phosphorus from aluminium, iron or calcium phosphate sources. New Phytologist 173: 181–190.
   PubMed Web of Science ®Google Scholar
• Rao, I. M. 2002. Role of physiology in improving crop adaptation to abiotic stresses in the tropics: The case of common bean and tropical forages. In: Handbook of Plant and Crop Physiology, ed. M. Pessarakli, pp. 583–613. New York: Marcel Dekker.
   Google Scholar
• Rao, I. M., A. L. Fredeen, and N. Terry. 1993. Influence of phosphorus limitation on photosynthesis, carbon allocation and partitioning in sugar beet and soybean grown with a sort photoperiod. Plant Physiology and Biochemistry 31: 223–231.
   Web of Science ®Google Scholar
• Rao, I. M., D. K. Friesen, and M. Osaki. 1999. Plant adaptation to phosphorus-limited tropical soils. In: Handbook of Plant and Crop Stress, ed. M. Pessarakli, pp. 61–96. New York: Marcel Dekker.
   Google Scholar
• Rao, I. M., P. C. Kerridge, and M. Macedo. 1996. Nutritional requirements of Brachiaria and adaptation to acid soils. In: Brachiaria: Biology, Agronomy and Improvement, eds. J. W. Miles, B. L. Maass, and C. B. DoValle, pp. 53–71. Cali, Colombia: CIAT.
   Google Scholar
• Rao, I. M., J. W. Miles, and J. C. Granobles. 1998. Differences in tolerance to infertile acid soil stress among germplasm accessions and genetic recombinants of the tropical forage grass genus Brachiaria. Field Crops Research 59: 43–52.
   Web of Science ®Google Scholar
• Richardson, A. E., J. P. Lynch, P. R. Ryan, E. Delhaize, F. A. Smith, S. E. Smith, P. R. Harvey, M. H. Ryan, E. J. Veneklaas, H. Lambers, A. Oberson, R. A. Culvenor, and R. J. Simpson. 2011. Plant and microbial strategies to improve the phosphorus efficiency of agriculture. Plant and Soil 349: 121–156.
   Web of Science ®Google Scholar
• Rosolem, C. A., J. P. T. Witacker, S. Vanzolini, and V. J. Ramos. 1999. The significance of root growth on cotton nutrition in an acid low-P soil. Plant and Soil 212: 185–190.
   Web of Science ®Google Scholar
• Shen, J., L. Yuan, J. Zhang, H. Li, Z. Bai, X. Chen, W. Zhang, and F. Zhanf. 2011. Phosphorus dynamics: from soil to plant. Plant Physiology 156: 997–1005.
   PubMed Web of Science ®Google Scholar
• Vance, C. P., C. Uhde-Stone, and D. L. Allan. 2003. Phosphorus acquisition and use: Critical adaptations by plants for securing a nonrenewable resource. New Phytologist 157: 423–447.
   PubMed Web of Science ®Google Scholar
• Zhang, F., J. Shen, J. Zhang, Y. Zuo, L. Li, and X. Chen. 2010. Rhizosphere processes and management for improving nutrient use efficiency and crop productivity: Implications for China. Advances in Agronomy 107: 1–32.
   Web of Science ®Google Scholar