Journal of Agriculture Biotechnology

All processes and functions taking place in the rhizosphere are dominated by the activities of plant roots, rhizosphere microorganisms and root-microorganism interactions, and enzymes are recognized as main actors of all activities occurring in rhizosphere environments. Rhizosphere enzymes have, in general, a higher activity than those operating in bulk soil, as the rhizosphere soil is richer in organic C substrates. Enzymes, produced and released by both roots and microorganisms concur to altering the availability of nutrients in the rhizosphere, being implied in the hydrolysis of C-substrates and organic forms of nutrients such as N, P and S.

The production and activity of rhizosphere enzymes is controlled by several factors, in turn depending on soil-plant-microorganism interactions. In general, higher activity of rhizosphere enzymes can be interpreted as a greater functional diversity of the microbial community. An interesting aspect is their involvement in the possible removal of both inorganic and organic pollutants from the terrestrial food chain.

The lack of satisfying methodologies for measuring the location and activity of rhizosphere enzymes has often hampered a clear knowledge of their properties and functions. Sophisticated technologies, now available, will be helpful to reveal the origins, locations and activities of enzymes in rhizosphere.

The main scope of the present paper is to cover briefly general and specific concepts about rhizosphere enzymes and their role in soil processes. Examples chosen among those published recently, supporting and confirming properties, features, and functions of rhizosphere enzymes will be illustrated.

Abhilash, P.C., Jamil, S., Singh, N. 2009. Transgenic plants for enhanced biodegradation and phytoremediation oforganic xenobiotics. Biotechnol. Adv. 27, 474–488. Ai, C., Liang, G., Sun, J., Wang, X., Zhou, W. 2012. Response of ectracellular enzyme activities and microbial community in both the rhizosphere and bulk soil to long-term fertilization practices in a fluvo-aquic soil. Geoderma. 173–174, 330-33. Bell, C, Carrillo, Y., Boot, C.M., Rocca, J.D., Pendall, E., Wallenstein, M.D. 2014. Rhizosphere stoichiometry: Are C: N: P ratios of plants, soils, and enzymes conserved at the plant species-level?. New Phytolog. 201, 505–517.

Brzostek, E.R., Greco, A., Drake, J.E., Finzi, A.C. 2013. Root carbon inputs to the rhizosphere stimulate extracellular enzyme activity and increase nitrogen availability in temperate forest soils. Biogeochemistry. 115, 65–76.

Caldwell, B.A. 2005. Enzyme activities as a component of soil biodiversity: A review. Pedobiologia. 49, 637-644. Chroma, L., Mackovam, M., Kucerovam, P., Der Wiesche, C., Burkhard, J., Macek, T. 2002. Enzymes in plant metabolism of PCBs and PAHs. Acta Biotechnol. 22, 35-41. Dick, R.P. 1994. Soil enzymes activities as indicators of soil quality. In: J.W. Doran, D.C. Coleman, D.F. Bezdicek, B.A. Stewart (eds). Defining soil quality for a sustainable environment. SSSA Special Publication: Madison, Wl, USA, vol. 35, pp 107-124. Dick, R.P. 1997. Soil enzyme activities as integrative indicators of soil health. In: C.E. Pankhurst, B.M. Doube, V.V.S.R. Gupta (eds.), Biological indicators of soil health. CAB International, Wallingford, pp. 121-156. Egamberdieva, D., Renella, G., Wirth, S., Islam, R. 2011. Enzyme Activities in the Rhizosphere of Plants. In G. Shukla, A. Varma (ed). Soil Enzymology. Soil Biology. Vol. 22, Springer Verlag, pp. 149-165. Ebersberger, D., Niklaus, P.A, Kandeler, E. 2003. Long term CO2enrichment stimulates N-mineralisation and enzyme activities in calcareous grassland. Soil Biol. Biochem. 35, 965-972. Fontaine, S., Mariotti, A., Abbadie, L. 2003. The priming effect of organic matter: a question of microbial competition?. Soil Biol. Biochem.35, 837-843. Gartner, T.B., Treseder, K.K., Malcolm, G.M., Sinsabaugh, R.L. 2012. Extracellular enzyme activity in the mycorrhizospheres of a boreal fire chronosequence. Pedobiologia. 55, 121-127. George, T.S., Gregory, P.J., Wood, M., Read, D., Buresh, R.J. 2002. Phosphatase activity and organic acids in the rhizosphere of potential agroforestry species and maize. Soil Biol. Biochem. 34, 1487–1494. George, T.S., Gregory, P.J., Hocking, P., George, T.S. 2008. Variation in root-associated phosphatase activities in wheat contributes to the utilization of organic P substrates in vitro, but does not explain differences in the P-nutrition of plants when grown in soils. Environ. Experim. Botany. 64, 239-249. George, T.S., Richardson, A.E., Simpson, R.J. 2005. Behaviour of plant-derived extracellular phytase upon addition to soil. Soil Biol. Biochem. 37, 977–988. George, T.S., Richardson, A.E. , Li, S.S., Gregory, P.J., Daniell, T.J. 2009. Extracellular release of a heterologous phytase from roots of transgenic plants: does manipulation of rhizosphere biochemistry impact microbial community structure?. FEMS Microbiol. Ecol. 70, 433–445. Gianfreda, L., Bollag, J.M. 1996. Influence of natural and anthropogenic factors on enzyme activity in soil. In G. Stotzky, J.-M .Bollag, (eds), Soil biochemistry. Marcel Dekker vol 9, New York, pp. 123-194. Gianfreda, L., Rao, M.A. 2004. Potential of extra cellular enzymes in remediation of polluted soils: a review. Enz. Microb. Technol. 35, 339-354. Gianfreda, L., Ruggiero, P. 2006. Enzymeactivities in soil. In P.Nannipieri, K.Smalla (eds) Nucleic acids and proteins in soil. Series Soil Biology, Vol. 8. Springer-Verlag, Berlin, Germany, p. 257-311.

Gianfreda, L., Mora, M.L., Diez, M.C. 2006. Restoration of polluted soils by means of microbial and enzymatic processes. J. Soil Sci. Plant Nut. 6, 20-40. Gramss, G., Voigt, K.D., Kirsche, B. 1999. Degradation of polycyclic aromatics hydrocarbons with three to seven aromatic rings by higher fungi in sterile and unsterile soils. Biodegradation 10, 51-62. Haase, S., Philippot, L., Neumann, G., Marhan, S., Kandeler, E. 2008. Local response of bacterial densities and enzyme activities to elevated atmospheric CO2 and different N supply in the rhizosphere of Phaseolus vulgaris L. Soil Biol. Biochem. 40, 1225-1234. Haichar, F.Z., Santaella, C., Heulin, T., Achouak, W. 2014. Root exudates mediated interactions belowground. Soil Biol. Biochem.77,69-80. Harvey, P.J., Xiang, M., Palmer, J.M. 2002. Extracellular enzymes in the rhizosphere. Proc. Inter-Cost Workshop on soil-microbe-root interactions: maximising phytoremediation/bioremediation. Grainau, Germany, 23-25. Hinsinger, P., Plassard, C., Jaillard, B. 2006. Rhizosphere: A new frontier for soil biogeochemistry, J. Geochem. Explor. 88, 210-213. Hinsinger, P., Bravin, M.N., Devau, N., Gérard, F., Le Cadre, E., Jaillard, B. 2008. Soil-Root-Microbe Interactions in the Rhizosphere - A Key to Understanding and Predicting Nutrient Bioavailability to Plants. J. Soil Sci. Plant Nutr. 8, 39-47. Insam, H., Parkinson, D., Domsch, K.H. 1989. Influence of macroclimate on soil microbial biomass. Soil Biol. Biochem. 21, 211-221. Jorquera, M., Martinez, O., Maruyama, F., Marschner, P., Mora, M.L. 2008. Current and Future Biotechnological Applications of Bacterial Phytases and Phytase-Producing Bacteria. Microbes Environ. 23, 182–191. Kim, S., Jung, S., Kang, H., Lee, I. 2010. Effects of elevated CO2 on growth of Pinus densiflora seedling and enzyme activities in soil. J. Ecol. Field Biol. 33, 133-139. Knauff, U., Schulz, M.W., Heinrich, S. 2003. Arylsufatase activity in the rhizosphere and roots of different crop species. Europ. J. Agron. 19, 215-223. Kumar, S, Chaudhuri, S., Maiti, S.K. 2011. Phosphatase activity in natural and mined soil - A review. Indian J. Environ. Prot. 31, 955-962. Kuzyakov, Y., Friedel, J.K., Stahr, K. 2000. Review of mechanisms and quantification of priming effects. Soil Biol. Biochem. 32, 1485–1498. Li, Y., Sun, H., Li, H., Yang, L., Ye, B., Wang, W. 2013. Dynamic changes of rhizosphere properties and antioxidant enzyme responses of wheat plants (Triticum aestivum L.). Chemosphere. 93, 972-977. Li, Y.-S., Gao, Y., Tian, Q.-Y., Shi, F.-L., Li, L.-H., Zhang, W.-H. 2011. Stimulation of root acid phosphatase by phosphorus deficiency is regulated by ethylene in Medicago falcate. Environ. Experim. Botany. 71, 114-120. Ma, X.-F., Wright, E., Ge, Y., Bell, J., Xi, Y., Bouton, J. H., Wang, Z.-Y. 2009. Improving phosphorus acquisition of white clover (Trifolium repens L.) by transgenic expression of plant-derived phytase and acid phosphatase genes. Plant Sci. 176, 479-488. Marinari, S., Moscatelli, C., Grego, S. 2014.Enzymes at Plant-Soil Interface. In: L. Gianfreda, M.A. Rao, (eds.) Enzymes in agricultural sciences OMICS eBooks Group, pp. 94-109.

Marschner, P., Crowley, D., Rengel, Z. 2011. Rhizosphere interactions between microorganisms and plants govern iron and phosphorus acquisition along the root axis : model and research methods. Soil Biol. Biochem. 43, 883-894. Maseko, S.T., Dakora, F.D. 2013. Rhizosphere acid and alkaline phosphatase activity as a marker of Pb nutrition in nodulated Cyclopia and Aspalathus species in the Cape fynbos of South Africa. South African J. Bot. 89,289-295. Menezes-Blackburn, D., Jorquera, M.A., Greiner, R., Gianfreda, L., Mora, M.L. 2013. Phytases and Phytase-Labile Organic Phosphorus in Manures and Soils. Critic. Rev. Environm. Sci. Technol. 43, 916-954. Menezes-Blackburn, D., Jorquera, M.A., Gianfreda, L., Mora, M.L., Greiner, R., Garrido, E. 2011. Activity stabilization of Aspergillus niger and Escherichia coli phytases immobilized on allophanic synthetic compounds and montmorillonite nanoclays. Biores. Technol. 102, 9360-9367. Mudge, S.R., Smith, F.W., Richardson, A.E. 2003. Root-specific and phosphate-regulated expression of phytase under the control of a phosphate transporter promoter enables Arabidopsis to grow on phytate as a sole P source. Plant Sci. 165, 871-878. Muratova, A., Pozdnyakova, N., Golubev, S., Wittenmayer, L., Makarov, O., Merbach, W., Turkovskaya, O. 2009. Oxidoreductase activity of sorghum root exudates in a phenanthrene-contaminated environment. Chemosphere. 74, 1031-1036. Muratova, A., Golubev, S., Wittenmayer, L., Dmitrieva, T., Bondarenkova, A., Hirche, F., Merbach, W., Turkovskaya, O. 2009. Effect of the polycyclic aromatic hydrocarbon phenanthrene on root exudation of Sorghum bicolor (L.) Moench. Environm. Experim Bot. 66, 514-521. Naseby, D.C., Linch, J.M. 1997. Rhizosphere soil enzymes as indicators of perturbations caused by enzyme substrate addition and inoculation of a genetically modified strain of Pseudomonas Fluorescens on wheat seed. Soil Biol. Biochem. 29, 1353-1362. Naseby, D.C., Linch, J.M. 1998. Impact of wild-type and genetically modified Pseudomonas Fluorescens on soil enzyme activities and microbial population structure in the rhizosphere of pea. Mol. Ecol. 7, 617-625. Naseby, D.C., Linch, J.M. 2002. Enzymes and microorganisms in the rhizosphere. In R.G. Burns R.P. Dick (eds) Enzymes in the environment. Activity, ecology and applications. Marcel Dekker, New York, pp. 109-123. Naseby, D.C., Moënne-Loccoz, J.P., O,Gara, F., Lynch, J.M. 1998. Soil enzyme activities in the rizosphere of field-grown sugar beet inoculated with the biocontrol agent Pseudomonas Fluorescens F113. Biol. Fertil. Soils. 27, 39-43. Neumann, G., George, T.S., Plassard, C. 2009. Strategies and methods for studying the rhizosphere—the plant science toolbox. Plant Soil. 321, 431–456. Nuruzzaman, M., Lambers, H., Bolland, M.D.A. 2006. Distribution of carboxylates ad acid phosphatase and depletion of different phosphorus fractions in the rhizosphere of a cereal and three grain legumes. Plant Soil. 281, 109-120.

Raaijmakers, J.M., Paulitz, T.C., Steinberg, C., Alabouvette, C., Moënne-Loccoz, Y. 2009. The rhizosphere: a playground and battlefield for soilborne pathogens and beneficial microorganisms. Plant Soil. 321, 341–361. Rao, M.A., Scelza, R., Gianfreda, L. 2014. Soil Enzymes. In: L. Gianfreda, M.A. Rao (eds.) Enzymes in agricultural sciences OMICS eBooks Group, pp. 10-43. Renella, G., Landi, L., Valori, F., Nannipieri, P. 2007. Microbial and hydrolase activity after release of low molecular weight organic compounds by a model root surface in a clayey and a sandy soil. Appl. Soil Ecol. 36, 124–129. Renella, G., Landi, L., Garcia Mina, J.M., Giagnoni, L., Nannipieri, P. 2011. Microbial and hydrolase activity after release of indoleacetic acid and ethylene–polyamine precursors by a model root surface. Appl. Soil Ecol. 47, 106–110. Rodr??guez, H., Fraga, R. 1999. Phosphate solubilizing bacteria and their role in plant growth promotion. Biotechnol. Adv. 17, 319-339. Sanaullah, M., Blagodatskaya, E., Chabbi, A., Rumpel, C., Kuzyakov, Y. 2011. Drought effects on microbial biomass and enzyme activities in the rhizosphere of grasses depend on plant community composition. Appl. Soil Ecol. 48, 38-44. Siciliano, S.D., Germida, J.J. 1998. Mechanism of phytoremediation: biochemical and ecological interactions between plants and bacteria. Environm. Rev. 6, 65-79. Sinsabaugh, R., Follstad Shah, J.J. 2011. Ecoenzymatic stoichiometry of recalcitrant organic matter decomposition: the growth rate hypothesis in reverse. Biogeochemistry. 102, 31-43. Sinsabaugh, R, Follstad Shah, J.J. 2012. Ecoenzymatic stoichiometry and ecological theory. Ann. Rev. Ecol. Evol. Syst. 43, 313-343. Sinsabaugh, R., Hill, B., Shah, J. 2009. Ecoenzymatic stoichiometry of microbial organic nutrient acquisition in soil and sediment. Nature. 462, 795-799. Sinsabaugh, R., Lauber, C., Weintraub, M., Ahmed, B., Allison, S., Crenshaw, C., Contosta, A.R., Cusack, D., Frey, S., Gallo, M.E., Gartner, T.B., Hobbie, S.E., Holland, K., Keeler, B.L., Powers, J.S., Stursova, M., Takacs-Vesbach, C., Waldrop, M.P., Wallenstein, M.D., Zak, D.R., Zeglin, L.H. 2008. Stoichiometry of soil enzyme activity at global scale. Ecol. Lett. 11, 1252-1264. Song, F., Han, X., Zhu, X., Herbert, S.J. 2012. Response to water stress of soil enzymes and root exudates from drought and non-drought tolerant corn hybrids at different growth stages. Can. J. Soil Sci. 92, 501-507. Spohn, M., Carminati, A., Kuzyakov, Y. 2013. Soil zymography :A novel in situ method for mapping distribution of enzyme activity in soil. Soil Biol. Biochem. 58, 275-280. Spohn, M., Kuzyakov, Y. 2013. Distribution of microbial- and root-derived phosphatase activities in the rhizosphere depending on P availability and C allocation – Coupling soil zymography with 14C imaging. Soil Biol. Biochem. 67, 106-113. Spohn, M., Kuzyakov, Y. 2014. Spatial and temporal dynamics of hotspots of enzyme activity in soil as affected by living and dead roots: a soil zymography analysis. Plant Soil. 379, 67–77.

Tarafdar, J.C., Marschner, H. 1994. Phosphatase activity in the rhizosphere and hyposphere of VA mycorrhizal wheat supplied with inorganic and organic phosphorus. Soil Biol. Biochem. 26, 387-395. Vázquez, M., César, S., Azcón, R., Barea, J.M. 2000. Interactions between arbuscularmycorrhizal fungi and other microbial inoculants (Azospirillum, Pseudomonas, Trichoderma) and their effects on microbial population and enzyme activities in the rhizosphere of maize plants. Appl. Soil Ecol. 15, 261-272. Vong, P.-C., Dedourge, O., Lasserre-Joulin, F., Guckert, A. 2003. Immobilized- S, microbial biomass-S and soil arylsulfatase activity in the rhizosphere soil of rape and barley as affected by labile substrate C and N additions. Soil Biol. Biochem. 35, 1651-1661. Walton, B.T., Hoylman, A.M., Perez, M.M., Anderson, T.A., Johnson, T.R., Guthrie, E.A., Christmas, R.F. 1994. Rizhospheremicrobical community as a plant defense against toxic substances in soils. In: T.A. Anderson, J.R.Coats. (eds.) Bioremediation through rizhosphere technology American Schemical Society: Washington D.C., pp. 82-92. Welc, M., Frossard, E., Egli, S, Bünemann, E.K., Jansa, J. 2014. Rhizosphere fungal assemblages and soil enzymatic activities in a 110- years alpine chronosequence. Soil Biol. Biochem. 74, 21-30.

Wu, Q.S., He, X.H., Zou, Y.N., He, K.P.. Sun, Y.H. 2012. Spatial distribution of glomalin-related soil protein and its relationships with root mycorrhization, soil aggregates, carbohydrates, activity of protease and ?-glucosidase in the rhizosphere of Citrus unshiu. Soil Biol. Biochem. 45, 181-183. Yadav, B.K., Tarafdar, J.C. 2003. Phytase and phosphatase producing fungi in arid and semi-arid soils and their efficiency in hydrolyzing different organic P compounds. Soil Biol. Biochem. 35, 745-751. Yadav, B.K., Tarafdar, J.C. 2004. Phytase activity in the rhizosphere of crops, trees and grasses under arid environment. J. Arid Environm. 58, 285–293. Yuan, X., Lin, X., Chu, H., Yin, R., Zhang, H., Hu, J., Zhu, J. 2006. Effects of elevated atmospheric CO2 on soil enzyme activities at different nitrogen application treatments. Acta Ecol. Sinica. 26, 48-53. Zak, J.C., Willig, M.R., Moorhead, D.L., Wildman, H.G. 1994. Functional diversity of microbial communities: A quantitative approach. Soil Biol. Biochem. 26, 1101-1108. Zhu, B., Gutknecht, J.L.M., Herman, D.J., Keck, D.C., Firestone, M.K., Cheng, W. 2014. Rhizosphere priming effects on soil carbon and nitrogen mineralization. Soil Biol. Biochem. 76, 183-192.

Zhuang, X., Chen, J., Shim, H., Bai, Z. 2007. New advances in plant growth-promoting rhizobacteria for bioremediation. Environm. Intern. 33, 406–413.