Toprak Mikroorganizmalarının Bitki Büyümesinin İyileştirilmesinde ve Ekosistemin Sürdürülebilirliğindeki Rolleri
Özet
Referanslar
Grandy AS, Robertson GP, Thelen KD. Do productivity and environmental trade-offs justify periodically cultivating No-till cropping systems? Agronomy Journal; 2006, 98: 1377-1383.
Urquiaga S, Jantalia CP, Alves BJR, Boddey RM. In: Monzón de Asconegui MA, García de Salamone IE, Miyazaki SS (eds.). Biología del Suelo. Transformación de la materia orgánica. Usos y biodiversidad de los organismos edáficos. Editoral FAUBA. Universidad de Buenos Aires; 2004. p. 1-6.
Scow KM. In: Jackson LE (ed.). Ecology in Agriculture, Physiological Ecology Series, Agricultural and Biological Sciences, Academic Press; 1997. p. 367-413.
Whitman WB, Coleman DC, Wiebe WJ. Prokaryotes: The unseen majority. Proceeding of the National Academy of Sciences USA; 1998, 95: 6578-6583.
Barea JM. In: Monzón de Asconegui, MA, García de Salamone IE, Miyazaki SS (eds.). Biología del suelo. Transformaciones de la materia orgánica, usos y biodiversidad de los organismos edáficos. Editorial FAUBA. Universidad de Buenos Aires, Argentina; 2004. p. 7-11.
Andrén O, Hansson A, Végh C, Barley K. Nutrient uptake, root growth and depth distribution in two soil types in a rhizotron with vertical and horizontal minirhizotrons. Swedish Journal of Agricultural Research; 1993, 23: 115–126.
Triplett GB, Dick WA. No-Tillage Crop Production: A Revolution in Agriculture!. Agronmy Journal; 2008, 100: 153-165.
Jackson LE, Calderonb FJ, Steenwertha KL, Scow KM, Rolston DE. Responses of soil microbial processes and community structure to tillage events and implications for soil quality. Geoderma; 2003,114: (3-4): 305-317.
Doran JW, Zeiss MR. Soil health and sustaintability: managing the biotic component of soil quality. Applied Soil Ecology; 2000, 15: 3-11.
Michelena R, Rivero E, Rorig M, Schung, E. Stuble evaluation in no-tillage and nutrient availability in soil plant system. 12 th World Fertilizer Congress. International Scientific Centre – The Chinese Academy of Science. Beijing, China. 2001.
García de Salamone IE, Bordato F, Michelena R. Indicadores microbianos de calidad de suelo luego de la aplicación de compactación sobre un suelo Haplustol éntico bajo siembra directa. V Reunión Nacional Científico-Técnica de Biología de Suelos y V Encuentro sobre Fijación Biológica de Nitrógeno, San Salvador de Jujuy, Argentina. 6-8 de Julio. 2005.
Cheng W, Jonson DW, Shenglei F. Rhizosphere effects on decomposition: Control of plant species, phenology and fertilization. American Journal of Soil Sciences Society; 2003, 67: 1418-1427.
García de Salamone IE, Rorig M, Di Salvo L, Michelena R. Comunidades microbianas en capas superficiales de un suelo Haplustol éntico bajo siembra directa. XX Congreso Argentino de la Ciencia del Suelo. Salta, Argentina. 19-22 de Setiembre. 2006.
Schlesinger WH. Biogeochemistry: An Analysis of Global Change. Academic Press, San Diego, CA. 1991.
Paul EA, Clark FE. Soil Microbiology and Biochemistry. Academic Press, Inc., San Diego, CA. 340 pp. 1996.
Maddonni GA, Vilariño P, García de Salamone IE. In: Satorre E, Benech Arnold R, Slafer GA, de la Fuente EB, Miralles DJ, Otegui ME, Savin R. (eds.). Producción de Granos, Bases funcionales para su manejo. Editorial FAUBA, Universidad de Buenos Aires; 2004. p. 441-477.
Naeem S, Thompson L, Lawler S, Lawton JH, Woodfin RM. Emprirical evidence that declining species diversity may alter the performance of terrestrial ecosystems. Phil. Trans. R. Soc. Lond. B. 1995, 345: 249-262.
Anderson TH. Microbial eco-physiological indicators to asses soil quality. Agriculture, Ecosystem and Environment; 2003, 98: 285-293.
Bashan Y, Holguin G, de-Bashan LE. Azospirillum-plant relationships: physiological, molecular, agricultural and environmental advances (1997-2003). Canadian Journal of Microbiology; 2004, 50: 521-577.
Díaz-Zorita M, Fernandez Canigia MV. In: Cassan F, Garcia de Salamone IE. (eds.). Azospirillum sp.: Cell physiology, plant interactions and agronomic research in Argentina. Asociación Argentina de Microbiologia, Buenos Aires, Argentina; 2008. p. 155-166.
Naiman AD, Latrónico AE, García de Salamone IE. Inoculation of Wheat with Azospirillum brasilense and Pseudomonas fluorescens: impact on the production and rhizospheric microflora. European Journal of Soil Biology; 2009, 45: 44-51.
Wardle D. Communities and ecosystems: Linking the aboveground and belowground components. Princeton Univ. Press, Princeton, N.J. 2002.
Antoun H, Prevost D. In: Siddiqui ZA. (ed.). PGPR: Biocontrol and Biofertilization. Springer, Dordrecht; 2006. p. 1–38.
Catroux G. Uso de microorganismos en agricultura: sueño y realidad. In: XV Congreso de AAPRESID, Rosario, Argentina. 2007.
Cassan FD, García de Salamone IE. Azospirillum sp.: Cell physiology, plant interactions and agronomic research in Argentina. Asociación Argentina de Microbiología. Buenos.Aires; 2008.
Glick BR. The enhancement of plant growth by free living bacteria. Canadian Journal of Microbiology; 1995, 41: 109-117.
Baldani VL, Baldani JI, Döbereiner J. Inoculation of field-grown wheat (Triticum aestivum) whith Azospirillum spp. In Brazil. Biology & Fertility of Soil; 1987, 4: 37-40.
Okon Y. Azospirillum/Plant association. CRC Press, Boca Raton, Florida, USA. 1994.
Caballero-Mellado J, Carcaño-Montiel M, Mascarúa-Esparza MA. Field inoculation of wheat (Triticum aestivum) with Azospirillum brasilense under temperate climate. Symbiosis; 1992, 13: 243-253.
Caballero Mellado J. In: de Asconegui MA, García de Salamone IE, Miyazaki SS. (eds.). Biología del Suelo. Transformación de la materia orgánica. Usos y biodiversidad de los organismos edáficos. FAUBA. Universidad de Buenos Aires. Argentina; 2004. p. 45-49.
Bashan Y, Harrison SK, Whitmoyer RE. Enhanced growth of wheat and soybean plants inoculated with Azospirillum brasilense is not necessarily due to general enhancement of mineral uptake. Applied and Environmental Microbiology; 1990, 56: 769-775.
García de Salamone IE, Di Salvo LP, Escobar Ortega JS, Boa Sorte MP, Urquiaga S, Dos Santos Teixeira KR. Field response of rice paddy crop to inoculation with Azospirillum: physiology of rhizosphere bacterial communities and the genetic diversity of endophytic bacteria in different parts of the plants. Plant & Soil; 2010, 336: 351–362.
Rodriguez H, Fraga R, Gonzalez T, Bashan Y. Genetics of phosphate solubilization and its potencial applications for improving plant growth-promoting bacteria. Plant & Soil; 2006, 287: 15-21.
Kloepper JWE. In: Metting FB. (ed.). Soil Microbial Ecology. Applications in agricultural and environmental management. Marcel Dekker. N.Y; U.S.A; 1993. p. 255-274.
García de Salamone IE, Döbereiner J, Urquiaga S, Boddey RM. Biological Nitrogen Fixation in Azospirillum strain-maize genotype associations as evaluated by 15N isotope dilution technique. Biology & Fertility of Soil; 1996, 23: 249-256.
Boddey RM. Methods for quantification of nitrogen fixation associated with gramineae. CRC Critical Review Plant Science, Boca Raton, v.6, 1987.
Alves BJR, Oliveira OC, Boddey RM, Urquiaga S. In: de A. Santos G, da Silva LS, Canellas LP, Camargo FAO. (eds.). Fundamentos da matéria orgânica dio solo: ecossistemas tropicais e subtropicais. Editora Metrópole, Porto Alegre; 2008. p. 229-242.
D´Auria F, Escobar Ortega J, López de Sabando M, García de Salamone IE, Pérez M, Zubillaga MM. Mineralización de nitrógeno y microorganismos asociados en un cultivo de trigo de Buenos Aires, Argentina. VIII Reunión Nacional Científico-Técnica de Biología de Suelos. 6-8 Julio. Salta, Argentina. 2011.
García de Salamone IE, Cassan FD. Taller Internacional sobre Rizosfera, Biodiversidad y Agricultura Sustentable. Libro de Resúmenes. 2010.
García de Salamone IE, Di Salvo LP, Escobar Ortega JS, Boa Sorte MP, Urquiaga S, Dos Santos Teixeira KR. Field response of rice paddy crop to inoculation with Azospirillum: physiology of rhizosphere bacterial communities and the genetic diversity of endophytic bacteria in different parts of the plants. Plant & Soil; 2010, 336: 351–362.
Reed MLE, Glick BR. Applications of free living plant growth-promoting rhizobacteria. Antonie van Leewenhoek; 2004, 86: 1-25.
Referanslar
Grandy AS, Robertson GP, Thelen KD. Do productivity and environmental trade-offs justify periodically cultivating No-till cropping systems? Agronomy Journal; 2006, 98: 1377-1383.
Urquiaga S, Jantalia CP, Alves BJR, Boddey RM. In: Monzón de Asconegui MA, García de Salamone IE, Miyazaki SS (eds.). Biología del Suelo. Transformación de la materia orgánica. Usos y biodiversidad de los organismos edáficos. Editoral FAUBA. Universidad de Buenos Aires; 2004. p. 1-6.
Scow KM. In: Jackson LE (ed.). Ecology in Agriculture, Physiological Ecology Series, Agricultural and Biological Sciences, Academic Press; 1997. p. 367-413.
Whitman WB, Coleman DC, Wiebe WJ. Prokaryotes: The unseen majority. Proceeding of the National Academy of Sciences USA; 1998, 95: 6578-6583.
Barea JM. In: Monzón de Asconegui, MA, García de Salamone IE, Miyazaki SS (eds.). Biología del suelo. Transformaciones de la materia orgánica, usos y biodiversidad de los organismos edáficos. Editorial FAUBA. Universidad de Buenos Aires, Argentina; 2004. p. 7-11.
Andrén O, Hansson A, Végh C, Barley K. Nutrient uptake, root growth and depth distribution in two soil types in a rhizotron with vertical and horizontal minirhizotrons. Swedish Journal of Agricultural Research; 1993, 23: 115–126.
Triplett GB, Dick WA. No-Tillage Crop Production: A Revolution in Agriculture!. Agronmy Journal; 2008, 100: 153-165.
Jackson LE, Calderonb FJ, Steenwertha KL, Scow KM, Rolston DE. Responses of soil microbial processes and community structure to tillage events and implications for soil quality. Geoderma; 2003,114: (3-4): 305-317.
Doran JW, Zeiss MR. Soil health and sustaintability: managing the biotic component of soil quality. Applied Soil Ecology; 2000, 15: 3-11.
Michelena R, Rivero E, Rorig M, Schung, E. Stuble evaluation in no-tillage and nutrient availability in soil plant system. 12 th World Fertilizer Congress. International Scientific Centre – The Chinese Academy of Science. Beijing, China. 2001.
García de Salamone IE, Bordato F, Michelena R. Indicadores microbianos de calidad de suelo luego de la aplicación de compactación sobre un suelo Haplustol éntico bajo siembra directa. V Reunión Nacional Científico-Técnica de Biología de Suelos y V Encuentro sobre Fijación Biológica de Nitrógeno, San Salvador de Jujuy, Argentina. 6-8 de Julio. 2005.
Cheng W, Jonson DW, Shenglei F. Rhizosphere effects on decomposition: Control of plant species, phenology and fertilization. American Journal of Soil Sciences Society; 2003, 67: 1418-1427.
García de Salamone IE, Rorig M, Di Salvo L, Michelena R. Comunidades microbianas en capas superficiales de un suelo Haplustol éntico bajo siembra directa. XX Congreso Argentino de la Ciencia del Suelo. Salta, Argentina. 19-22 de Setiembre. 2006.
Schlesinger WH. Biogeochemistry: An Analysis of Global Change. Academic Press, San Diego, CA. 1991.
Paul EA, Clark FE. Soil Microbiology and Biochemistry. Academic Press, Inc., San Diego, CA. 340 pp. 1996.
Maddonni GA, Vilariño P, García de Salamone IE. In: Satorre E, Benech Arnold R, Slafer GA, de la Fuente EB, Miralles DJ, Otegui ME, Savin R. (eds.). Producción de Granos, Bases funcionales para su manejo. Editorial FAUBA, Universidad de Buenos Aires; 2004. p. 441-477.
Naeem S, Thompson L, Lawler S, Lawton JH, Woodfin RM. Emprirical evidence that declining species diversity may alter the performance of terrestrial ecosystems. Phil. Trans. R. Soc. Lond. B. 1995, 345: 249-262.
Anderson TH. Microbial eco-physiological indicators to asses soil quality. Agriculture, Ecosystem and Environment; 2003, 98: 285-293.
Bashan Y, Holguin G, de-Bashan LE. Azospirillum-plant relationships: physiological, molecular, agricultural and environmental advances (1997-2003). Canadian Journal of Microbiology; 2004, 50: 521-577.
Díaz-Zorita M, Fernandez Canigia MV. In: Cassan F, Garcia de Salamone IE. (eds.). Azospirillum sp.: Cell physiology, plant interactions and agronomic research in Argentina. Asociación Argentina de Microbiologia, Buenos Aires, Argentina; 2008. p. 155-166.
Naiman AD, Latrónico AE, García de Salamone IE. Inoculation of Wheat with Azospirillum brasilense and Pseudomonas fluorescens: impact on the production and rhizospheric microflora. European Journal of Soil Biology; 2009, 45: 44-51.
Wardle D. Communities and ecosystems: Linking the aboveground and belowground components. Princeton Univ. Press, Princeton, N.J. 2002.
Antoun H, Prevost D. In: Siddiqui ZA. (ed.). PGPR: Biocontrol and Biofertilization. Springer, Dordrecht; 2006. p. 1–38.
Catroux G. Uso de microorganismos en agricultura: sueño y realidad. In: XV Congreso de AAPRESID, Rosario, Argentina. 2007.
Cassan FD, García de Salamone IE. Azospirillum sp.: Cell physiology, plant interactions and agronomic research in Argentina. Asociación Argentina de Microbiología. Buenos.Aires; 2008.
Glick BR. The enhancement of plant growth by free living bacteria. Canadian Journal of Microbiology; 1995, 41: 109-117.
Baldani VL, Baldani JI, Döbereiner J. Inoculation of field-grown wheat (Triticum aestivum) whith Azospirillum spp. In Brazil. Biology & Fertility of Soil; 1987, 4: 37-40.
Okon Y. Azospirillum/Plant association. CRC Press, Boca Raton, Florida, USA. 1994.
Caballero-Mellado J, Carcaño-Montiel M, Mascarúa-Esparza MA. Field inoculation of wheat (Triticum aestivum) with Azospirillum brasilense under temperate climate. Symbiosis; 1992, 13: 243-253.
Caballero Mellado J. In: de Asconegui MA, García de Salamone IE, Miyazaki SS. (eds.). Biología del Suelo. Transformación de la materia orgánica. Usos y biodiversidad de los organismos edáficos. FAUBA. Universidad de Buenos Aires. Argentina; 2004. p. 45-49.
Bashan Y, Harrison SK, Whitmoyer RE. Enhanced growth of wheat and soybean plants inoculated with Azospirillum brasilense is not necessarily due to general enhancement of mineral uptake. Applied and Environmental Microbiology; 1990, 56: 769-775.
García de Salamone IE, Di Salvo LP, Escobar Ortega JS, Boa Sorte MP, Urquiaga S, Dos Santos Teixeira KR. Field response of rice paddy crop to inoculation with Azospirillum: physiology of rhizosphere bacterial communities and the genetic diversity of endophytic bacteria in different parts of the plants. Plant & Soil; 2010, 336: 351–362.
Rodriguez H, Fraga R, Gonzalez T, Bashan Y. Genetics of phosphate solubilization and its potencial applications for improving plant growth-promoting bacteria. Plant & Soil; 2006, 287: 15-21.
Kloepper JWE. In: Metting FB. (ed.). Soil Microbial Ecology. Applications in agricultural and environmental management. Marcel Dekker. N.Y; U.S.A; 1993. p. 255-274.
García de Salamone IE, Döbereiner J, Urquiaga S, Boddey RM. Biological Nitrogen Fixation in Azospirillum strain-maize genotype associations as evaluated by 15N isotope dilution technique. Biology & Fertility of Soil; 1996, 23: 249-256.
Boddey RM. Methods for quantification of nitrogen fixation associated with gramineae. CRC Critical Review Plant Science, Boca Raton, v.6, 1987.
Alves BJR, Oliveira OC, Boddey RM, Urquiaga S. In: de A. Santos G, da Silva LS, Canellas LP, Camargo FAO. (eds.). Fundamentos da matéria orgânica dio solo: ecossistemas tropicais e subtropicais. Editora Metrópole, Porto Alegre; 2008. p. 229-242.
D´Auria F, Escobar Ortega J, López de Sabando M, García de Salamone IE, Pérez M, Zubillaga MM. Mineralización de nitrógeno y microorganismos asociados en un cultivo de trigo de Buenos Aires, Argentina. VIII Reunión Nacional Científico-Técnica de Biología de Suelos. 6-8 Julio. Salta, Argentina. 2011.
García de Salamone IE, Cassan FD. Taller Internacional sobre Rizosfera, Biodiversidad y Agricultura Sustentable. Libro de Resúmenes. 2010.
García de Salamone IE, Di Salvo LP, Escobar Ortega JS, Boa Sorte MP, Urquiaga S, Dos Santos Teixeira KR. Field response of rice paddy crop to inoculation with Azospirillum: physiology of rhizosphere bacterial communities and the genetic diversity of endophytic bacteria in different parts of the plants. Plant & Soil; 2010, 336: 351–362.
Reed MLE, Glick BR. Applications of free living plant growth-promoting rhizobacteria. Antonie van Leewenhoek; 2004, 86: 1-25.
