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Bacterial solubilization of mineral phosphates: Historical perspective and future prospects

Published online by Cambridge University Press:  13 November 2009

Alan H. Goldstein
Alan H. Goldstein
Affiliation:
Assistant Professor, Department of Plant Sciences, University of Arizona, Tucson, AZ 85721.
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Abstract

Maximum crop yields require sufficient phosphorus fertilization. Only phosphate in a soluble ionic form (Pi) is effective as a mineral nutrient. Current fertilizer technology supplies the soil solution with Pi via the application of large amounts of phosphate salts. Problems with this technology include energy-intensive production processes, the need for large scale mechanical application with associated environmental consequences, and reprecipitation of the phosphate into insoluble mineral complexes. It has been estimated that in some soils up to 75% of applied phosphate fertilizer may be lost to the plant because of mineral phase reprecipitation. Many approaches, ranging from cultural practices to biological inoculants such as mycorrhizal fungi, are being employed to enhance P-use efficiency. One area that is currently under-investigated is the ability of certain types of bacteria to solubilize mineral and organic phosphates. A review of the literature in the area of bacterial phosphate solubilization confirms that this trait is displayed by a wide range of bacteria. The phosphate starvation inducible (PSI) organic phosphate-solubilizing capability of E. coli is a component of a coordinately regulated gene system: the pho regulon. It has long been known that bacteria are also capable of solubilizing mineral phosphates such as hydroxyapatite. To date there has been no systematic study of the genetics of this phenomenon. Data from my laboratory indicate that the bacterial mineral phosphate-solubilizing (MPS) trait is regulated by the external level of Pi This conclusion is supported by results obtained from several types of molecular genetic studies. It is proposed that bacteria have mineral phosphate solubilizing (mps) genes. The potential agronomic applications of bacterial mineral and organic P solubilizing systems are discussed.

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Articles
Information
American Journal of Alternative Agriculture , Volume 1 , Issue 2 , Spring 1986 , pp. 51 - 57
Copyright
Copyright © Cambridge University Press 1986

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References

1.Anderson, G. 1980. Assessing organic phosphorus in soils. In: The Role of Phosphorus in Agriculture, Khasawneh, F. E., Sample, E. C., and Kamprath, E. J. (eds.), pp. 411431. American Society of Agronomy, Madison, WI.Google Scholar
2.Arnon, D. I. 1953. The physiology and biochemistry of phosphorus in green plants. In: Soil and Fertilizer Phosphorus in Crop Nutrition, Pierce, W. H. and Norman, A. G. (eds.), pp. 39. Academic Press, New York, NY.Google Scholar
3.Barrow, N. J. 1980. Evaluation and utilization of residual phosphorus in soils. In: The Role of Phosphorus in Agriculture. Khasawneh, F. E., Sample, E. C., and Kamprath, E. J. (eds.), pp. 333355. American Society of Agronomy, Madison, WI.Google Scholar
4.Bencini, D. A., Shanley, M. S., Wild, J. R., and O'Donovan, G. A.. 1983. New assay for enzymatic phosphate release: Application to aspartate transcarbamylase and other enzymes. Anal. Biochem. 132:259264.Google Scholar
5.Duff, R. B. and Webley, D. M.. 1959. 2-Ketogluconic acid as a natural chelator produced by soil bacteria. Chem. and Ind. Oct. 31. pp. 13761377.Google Scholar
6.Engelstad, P. P. and Terman, G. L.. 1980. Agronomic effectiveness of phosphate fertilizers. In: The Role of Phosphorus in Agriculture, Khasawneh, F. E., Sample, E. C., and Kamprath, E. J. (eds.), pp. 311329. American Society of Agronomy, Madison, WI.Google Scholar
7.Epstein, E. 1972. Mineral nutrition of plants, pp. 44. J. Wiley and Sons, Inc., New York, NY.Google Scholar
8.Fried, M. and Broeshart, H.. 1967. The soil-plant system in relation to inorganic mineral nutrition, pp. 545. Academic Press, New York, NY.Google Scholar
9.Gerretsen, F. C. 1948. The influence of microorganisms on the phosphate intake by the plant. Plant and Soil (1):5181.CrossRefGoogle Scholar
10.Goldstein, A. H. and Liu, S. T.. 1986. Molecular cloning and regulation of a mineral phosphate solubilizing (MPS) gene from Erwinia herbicola. Bio/Technology. (In press).CrossRefGoogle Scholar
11.Horwitz, W. (ed.) 1980. Methods of Analysis of the Association of Official Agricultural and Food Chemists. Phosphorus. Thirteenth Edition pp. 914. AOAC, Washington, D.C.Google Scholar
12.Kamprath, E. J. and Watson, M. E.. 1980. Conventional soil and tissue tests for assessing the phosphorus status of soils. In: The Role of Phosphorus in Agriculture, Khasawneh, F. E., Sample, E. C., and Kamprath, E. J. (eds.), pp. 433464. American Society of Agronomy, Madison, WI.Google Scholar
13.Katznelson, H. and Bose, B.. 1959. Metabolic activity and phosphate-dissolving capability of bacterial isolates from wheat roots, rhizophere and non-rhizophere soil. Can. J. Microbiol. 5:7985.CrossRefGoogle Scholar
14.Katznelson, H., Peterson, E. A., and Rouatt, J. W.. 1962. Phosphate-dissolving microorganisms on seed and in the root zone of plants. Can. J. Bot. 40:11811186.CrossRefGoogle Scholar
15.Long, S. R., Buikema, W. J. and Ausubel, F. M.. 1982. Cloning of Rhizobium meliloti nodulation genes by direct complementation of Nod mutants. Nature 298:485488.CrossRefGoogle Scholar
16.Louw, H. A. and Webley, D. M.. 1959. The bacteriology of the root region of the oat plant grown under controlled pot culture conditions. J. Appl. Bact. 22(2):216226.CrossRefGoogle Scholar
17.Louw, H. A. and Webley, D. M.. 1959. A study of soil bacteria dissolving certain mineral phosphate fertilizers and related compounds. J. Appl. Bact. 22(2):227233.CrossRefGoogle Scholar
18.Moghimi, A., Lewis, G., and Oades, J. M.. 1978a. Release of phosphate from calcium phosphates by rhizophere products. Soil Biol. Biochem. 10:277282.CrossRefGoogle Scholar
19.Moghimi, A., Tate, M. E., and Oades, J. M.. 1978b. Characterization of rhizosphere products especially 2-Ketogluconic acid. Soil Biol. Biochem. 10:283287.CrossRefGoogle Scholar
20.Moghimi, A., Tate, M. E., and Oades, J. M.. 1980. Does 2-Ketogluconate chelate calcium in the pH range 2.4 to 6.4? Soil Biol. Biochem. 10:289292.Google Scholar
21.Ozanne, P. B. 1980. Phosphate nutrition of plants - a general treatise. In: The Role of Phosphorus in Agriculture, Khasawneh, F. E., Sample, E. C., and Kamprath, E. J. (eds.), pp. 559585. American Society of Agronomy, Madison, WI.Google Scholar
22.Raghu, K. and Macrae, I. C.. 1966. Occurrence of phosphate dissolving micro-organisms in the rhizosphere of rice plants and in submerged soils. J. Appl. Bact. 29(3):582586.CrossRefGoogle ScholarPubMed
23.Rajan, S. S. S. 1981. Use of low grade phosphate rocks as biosuper fertilizer. Fertilizer Research 2:199210.CrossRefGoogle Scholar
24.Rajan, S. S. S. and Fox, R. L.. 1973. Phosphate adsorption by soils: II. Reactions in tropical acid soils. Soil Sci. Am. Proc. 39:846851.CrossRefGoogle Scholar
25.Rovira, A. D. and Davey, C. B.. 1974. Biology of the rhizosphere. In: The Plant Root and Its Environment, Carson, E. W. (ed.), pp. 153204. Univ. Press of Virginia, Charlottesville, VA.Google Scholar
26.Sackett, W. G., Patten, A. J., and Brown, C. W.. 1908. The solvent action of soil bacteria upon the insoluble phosphates of raw bone meal and natural raw rock phosphate. Central bl. Bakteriol. 20:688703.Google Scholar
27.Sample, E. C., Soper, R. J., and Racz, G. C.. 1980. Reactions of phosphate fertilizers in soils. In: The Role of Phosphorus in Agriculture, Khasawneh, F. E., Sample, E. C., and Kamprath, E. J. (eds.), pp. 263304. American Society of Agronomy, Madison, WI.Google Scholar
28.Sperber, J. I. 1957. Solution of mineral phosphates by soil bacteria. Nature 180:994995.CrossRefGoogle ScholarPubMed
29.Sperber, J. I. 1958. The incidence of apatite-solubilizing organisms in the rhizosphere and soil. Aust. J. Agric. Res. 9:778781.CrossRefGoogle Scholar
30.Subba Rao, N. S. 1982a. Biofertilizers. Interdisciplinary Science Reviews 7(3):220229.Google Scholar
31.Subba Rao, N. S. 1982b. Phosphate solubilization by soil microorganisms. In: Advances In Agricultural Microbiology, Rao, N. S. Subba (ed.), pp. 295305. Butterworth, Boston, MA.Google Scholar
32.U.S. Department of Agriculture. 1962. Phosphobacterin as a soil inoculant. Technical Bulletin No. 1263, 23pp.Google Scholar
33.Tinker, P. B. 1980. The role of the rhizosphere in phosphorus uptake by plants. In: The Role of Phosphorus in Agriculture, Khasawneh, F. E., Sample, E. C., and Kamprath, E. J. (eds.), pp. 617647. American Society of Agronomy, Madison, WI.Google Scholar
34.Tisdale, S. L. and Nelson, W. L.. 1975. Soil fertility and fertilizers, pp. 225. MacMillan Publishing Co., New York, NY.Google Scholar
35.Torriani, A. and Ludtke, D.. 1985. The pho regulon of E coli K12. In: The Molecular Biology of Bacterial Growth, M. Schaechter, F. C. Neidhardt, J. Ingrahm, and N. O. Kjeldgaard (eds.), Jones and Barlett. (In press)Google Scholar
36.Wanner, B. L. and McSharry, R.. 1982. Phosphatecontrolled gene expression in E. coli K12 using Mud 1-directed lac Z fusions. J. Mol. Biol. 158:347363.Google Scholar
37.Wanner, B. L. 1983. Overlapping and separate controls on the phosphate regulon in E coli K12. J. Mol. Biol. 166:283308.CrossRefGoogle Scholar
38.Wild, A. 1950. The retention of phosphate by soil. J. Soil Sci. 1:221238.CrossRefGoogle Scholar