<i>Urochloa decumbens</i> growth and P uptake as affected by long-term phosphate fertilization, mycorrhizal inoculation and historical land use in contrasting Oxisols of the Brazilian Cerrado

Motta, Paulo Emílio Ferreira da; Siqueira, José Oswaldo; Ribeiro, Bruno Teixeira; Silva, Sérgio Henrique Godinho; Poggere, Giovana Clarice; Curi, Nilton

doi:10.1590/1413-70542017412042516

ABSTRACT

In the fertility management of highly weathered-leached Brazilian Oxisols, P is the most limiting macronutrient. A greenhouse experiment was conducted with the objective to evaluate the influence of the interaction between P doses, mycorrhizal inoculation and historical land use on Urochloa decumbens growth and P uptake in four Oxisols with contrasting chemical, physical and mineralogical properties. The plants were cultivated in plastic pots containing 4 kg of soil in a completely randomized design, four replications and 2x2x2 factorial scheme: with two P doses; with and without mycorrhizal inoculation; soils cultivated for long periods and non-cultivated (under native vegetation). There were two plantings of ten weeks each. Shoot dry mater, concentration and accumulation of P in the shoot were evaluated. In the first planting, the Urochloa response was greater in non-cultivated soils associated with inoculation and P addition. However, in the second planting, the inoculation had a greater effect in all soils compared to the first planting associated with the lowest P dose. As the P concentration in the soil increased, P in the shoot dry matter increases. The inoculation did not affect the P concentration and accumulation in the shoot of Urochloa. The growth of Urochloa decumbens was strongly influenced by the interaction among soil class x history of land use x dose of P x inoculation.

Index terms:
Long-term cultivation; Latosols; available P.

RESUMO

No manejo da fertilidade de Latossolos brasileiros altamente intemperizados e lixiviados, o P é o macronutriente mais limitante. Assim, conduziu-se um experimento em casa de vegetação, objetivando-se avaliar a influência da interação entre doses de P, inoculação micorrízica e histórico de uso do solo no crescimento de Urochloa decumbens e absorção de P, em quatro Latossolos com atributos químicos, físicos e mineralógicos contrastantes. As plantas foram cultivadas em vasos contendo 4 kg de solo, dispostos em um delineamento inteiramente casualizado, com quatro repetições e esquema fatorial 2x2x2: duas doses de P; com e sem inoculação micorrízica; solos cultivados por longos períodos e não cultivados (sob vegetação nativa). Realizaram-se dois cultivos com duração de 10 semanas cada. Após cada cultivo avaliaram-se a matéria seca da parte aérea, teor e acúmulo de P na parte aérea. No primeiro cultivo, maior resposta ao P aconteceu nos solos sob vegetação nativa em associação à inoculação e adição de P. No segundo cultivo, a inoculação teve maior efeito em todos os solos, associada à menor dose de P. O aumento do P no solo aumenta a concentração desse nutriente na parte aérea. A inoculação não teve efeito na concentração e no acúmulo de P na parte aérea de Urochloa. O crescimento de Urochloa decumbens foi fortemente influenciado pela interação entre classe de solo x histórico de uso da terra x dose de P x inoculação.

Termos para indexação:
Cultivo por longos períodos; Latossolos; P-disponível.

INTRODUCTION

In Brazil, it is estimated that 70% of pasture areas (140 million hectares) are formed by species of the genus Urochloa (synonym Brachiaria), 50% constituted by the species U. decumbens, followed by U. brizantha, U. humidicola, U. ruziziensis, U. dictyoneura, U. mutica and U. arrecta (Alvim; Botrel; Xavier, 2002ALVIM, M. J.; BOTREL, M. A.; XAVIER, D. F. As principais espécies de braquiária utilizadas no país. Empresa Brasileira de Pesquisa Agropecuária, Juiz de Fora, 2002. 4p. (Comunicado Técnico 22). ). Although most of them are native to Africa, the species were well adapted to Brazilian soils and weather conditions, particularly in the Midwest and Southeast of Brazil - Cerrado biome. Most of the Brazilian pastures are degraded or under a degradational phase and one of the major causes for that is the lack of management of soil fertility. In the Brazilian Cerrado, a well-known limitation to cultivation of plants is the low availability of P (Lopes; Guilherme; Ramos, 2012LOPES, A. S.; GUILHERME, L. R. G.; RAMOS, S. J. The saga of agricultural development of the Brazilian Cerrado. International Potash Institute, 32:29-56, 2012.) due to the high adsorption of this nutrient by iron and aluminum oxides (Bortoluzzi et al., 2015BORTOLUZZI, E. C. et al. Occurrence of iron and aluminum sesquioxides and their implications for the P sorption in subtropical soils. Applied Clay Science, 104:196-204, 2015.; Motta et al., 2002MOTTA, P. E. F. et al. Adsorção e formas de fósforo em Latossolos: Influência da mineralogia e histórico de uso. Revista Brasileira de Ciência do Solo , 26(2):349-359, 2002.), mainly in Oxisols, making P less available to plants.

The symbiotic association between mycorrhizal fungi and plant roots increases P uptake capacity (Bressan et al., 2001BRESSAN, W. et al. Fungos micorrízicos e fósforo, no crescimento, nos teores de nutrientes e na produção de sorgo e soja consorciados. Pesquisa Agropecuária Brasileira, 36(2):315-323, 2001.; Rooney et al., 2011ROONEY, D. C. et al. Effect of arbuscular mycorrhizal colonization on the growth and phosphorus nutrition of Populuseur americana c.v. Ghoy. Biomass Bioenergy, 35:4605-4612, 2011.; Sharif; Classssen, 2011SHARIF, M.; CLAASSEN, N. Action mechanisms of arbuscular mycorrhizal fungi in phosphorus uptake by Capsicum annum L. Pedosphere, 21(4):502-511, 2011.; Smith et al., 2011SMITH, S. E. et al. Roles of arbuscular mycorrhizas in plant phosphorus nutrition: Interactions between pathways of phosphorus uptake in arbuscular mycorrhizal roots have important implications for understanding and manipulating plant phosphorus acquisition. Plant Physiology , 156:1050-1057, 2011.), resistance to water stress (Alizadeh; Zare; Nasr, 2011ALIZADEH, O.; ZARE, M.; NASR, A. H. Evaluation effect of Mycorrhiza inoculate under drought stress condition on grain yield of sorghum (Sorghum bicolor). Advances of Environmental Biology, 5:2361-2364, 2011.), biological nitrogen fixation (Veresoglou; Chen; Rillig, 2012VERESOGLOU, S. D.; CHEN, B.; RILLIG, M. C. Arbuscular mycorrhiza and soil nitrogen cycling. Soil Biology Biochemistry, 46:53-62, 2012.), plants resistence to heavy metals (Abdelmoneim; Almaghrabi, 2013ABDELMONEIM, T. S.; ALMAGHRABI, O. A. Improved tolerance of maize plants to heavy metals stress by inoculation with arbuscular mycorrhizal fungi. Archives des Sciences, 66:155-67, 2013.; Gucwa-Przepióra et al., 2016GUCWA-PRZEPIÓRIA, E. et al. Enzymatic activities and arbuscular mycorrhizal colonization of Plantago lanceolata and Plantago major in a soil root zone under heavy metal stress. Environmental Science and Pollution Research International, 23:4742-4755, 2016.), soil aggregation (Tisdall; Oades, 1982TISDALL, J. M.; OADES, J. M. Organic matter and water stable aggregates in soil. Journal of Soil Science, 32(1):141-163, 1982.) and other favorable soil conditions (Nadeem et al., 2014NADEEM, S. M. et al. The role of mycorrhizae and plant growth promoting rhizobacteria (PGPR) in improving crop productivity under stressful environments. Biotechnology Advances, 32:429-448, 2014.). Similarly to many cultivated plants, Urochloa also responds to mycorrhizal inoculation, which can be a good alternative in the management of pastures (Canizares et al., 2015CANIZARES, P. J. G. et al. Contribución de la inoculación micorrízica arbuscular a la reducción de la fertilización fosfórica en Brachiaria decumbens. Cultivos Tropicales, 36(1):135-142, 2015. ; Costa et al., 1997COSTA, N. L. et al. Resposta de Brachiaria humidicola à inoculação de micorrizas arbusculares e à aplicação de fontes e doses de fósforo. Pesquisa Agropecuária Gaúcha, 3(2):109-114, 1997. ; Costa et al., 2012COSTA, N. L. et al. Efeito de micorrizas arbusculares sobre o crescimento e nutrição mineral de Brachiaria brizantha cv. Marandu. Ciência Animal Brasileira, 13(4):406-411, 2012.; Santos et al., 2002SANTOS, I. P. A. et al. Influência do fósforo, micorriza e nitrogênio no conteúdo de minerais de Brachiaria brizantha e Arachis pintoi consorciados. Revista Brasileira de Zootecnia, 31(2):605-616, 2002.; Kanno et al., 2006KANNO, T. et al. Importance of indigenous arbuscular mycorrhiza for growth and phosphorus uptake In tropical forage grasses growing on an acid, infertile soil from the Brazilian savannas. Tropical Grasslands, 40:91-101, 2006.).

The response of a plant to inoculation with mycorrhizal fungi depends on a complex interaction of several factors, such as soil properties (Hart; Forsythe, 2012HART, M. M.; FORSYTHE, J. A. Using arbuscular mycorrhizal fungi to improve the nutrient quality of crops: Nutritional benefits in addition to phosphorus. Science Horticulturae, 148:206-214, 2012.), historical land use, sources and doses of P applied to soils (Costa et al., 1997COSTA, N. L. et al. Resposta de Brachiaria humidicola à inoculação de micorrizas arbusculares e à aplicação de fontes e doses de fósforo. Pesquisa Agropecuária Gaúcha, 3(2):109-114, 1997. ; Covacevich; Marino; Echeverría, 2006COVACEVICH, F.; MARINO, M. A.; ECHEVERRÍA, H. E. The phosphorus source determines the arbuscular mycorrhizal potential and the native mycorrhizal colonization of tall fescue and wheatgrass. European Journal of Soil Biology, 42:27-138, 2006.), P content in soil (Bressan et al., 2001BRESSAN, W. et al. Fungos micorrízicos e fósforo, no crescimento, nos teores de nutrientes e na produção de sorgo e soja consorciados. Pesquisa Agropecuária Brasileira, 36(2):315-323, 2001.; Covacevich; Echeverría; Aguirrezabal, 2007COVACEVICH, F.; ECHEVERRÍA, H. E.; AGUIRREZABAL, L. A. N. Soil available phosphorus status determines indigenous mycorrhizal colonization of field and glasshouse grown spring wheat from Argentina. Applied Soil Ecology, 35:1-9, 2007.; Xie et al., 2014XIE, X. et al. Effects of arbuscular mycorrhizal inoculation and phosphorus supply on the growth and nutrient uptake of Kandelia obovata (Sheue, Liu & Yong) seedlings in autoclaved soil. Applied Soil Ecology , 75:162-171, 2014.), plant nutritional status (Kiriachek et al., 2009KIRIACHEK, S. G. et al. Regulação do desenvolvimento de micorrizas arbusculares. Revista Brasileira de Ciência do Solo, 33:1-16, 2009.) and the inoculum (Costa et al., 2012COSTA, N. L. et al. Efeito de micorrizas arbusculares sobre o crescimento e nutrição mineral de Brachiaria brizantha cv. Marandu. Ciência Animal Brasileira, 13(4):406-411, 2012.).

In this context, the objective of this study was to evaluate the growth of Urochloa decumbens and P uptake influenced by phosphorus fertilization with and without mycorrhizal inoculation in four Oxisols with contrasting chemical, physical and mineralogical properties, and different historical land use conditions (long time under cultivation and non-cultivated under native vegetation).

MATERIAL AND METHODS

Samples of four Latosols, including those with a long period of cultivations and those non-cultivated, with contrasting chemical, physical and mineralogical properties were collected. Table 1 presents historical land uses of each soil collected. For each soil, composite samples were collected at a depth of 0-20 cm under cerrado as native vegetation (non-cultivated - NC) and under cultivated areas (cultivated - C) for physical, chemical and mineralogical characterization (Donagemma et al., 2011DONAGEMMA, G. H. et al. Manual de métodos de análise de solo. Rio de Janeiro: Solos, 2011. 230p. ). Physical characterization involved the determination of clay, silt and sand by the pipette method (Gee; Bauder, 1986GEE, G. W.; BAUDER, J. W. Particle-size analysis. In: KLUTE, A. (ed.). Methods of soil analysis. 2.ed. Madison: American Society of Agronomy, 1986. p.383-412.).

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Table 1:
Information and historical land use of the studied Latosols.

The chemical characterization involved determination of the following soil attributes: pH in water, P-Mehlich 1, P-resin, Ca²⁺, Mg²⁺, Al³⁺, K⁺, H⁺ + Al³⁺, organic carbon and B, Cu, Fe, Mn, Zn and S. These determinations were performed in triplicate and the original methods are compiled in (1997). The clay fraction was evaluated regarding the following attributes: iron extracted by sodium dithionite-citrate-bicarbonate (Fed); iron extracted by ammonium acid oxalate (Feo); hematite and goethite ratio by X-ray diffraction after concentration of iron oxides; kaolinite and gibbsite contents by differential thermal analysis in samples after removal of iron oxides. Contents of SiO₂, Al₂O₃, Fe₂O₃, TiO₂ and P₂O₅ were determined in each soil after sulfuric acid digestion. The maximum phosphate adsorption capacity (MPAC) of each soil was determined according to Olsen and Watanabe (1957OLSEN, S. R.; WATANABE, F. S. A method to determine a phosphorus adsorption maximum capacity of soils as measured by the Langmuir isotherm. Soil Science Society of America Proceedings, 21:144-149, 1957.), with more details of the methodology described in Motta et al. (2002MOTTA, P. E. F. et al. Adsorção e formas de fósforo em Latossolos: Influência da mineralogia e histórico de uso. Revista Brasileira de Ciência do Solo , 26(2):349-359, 2002.). The physical, chemical and mineralogical properties of the studied Latosols can be found in Motta et al. (2002)MOTTA, P. E. F. et al. Adsorção e formas de fósforo em Latossolos: Influência da mineralogia e histórico de uso. Revista Brasileira de Ciência do Solo , 26(2):349-359, 2002..

For the planting of Urochloa decumbens, an experiment was conducted in pots in a greenhouse, adopting a completely randomized design with four replications and in a 2x2x2 factorial scheme, namely: i) factor H (historical land use): uncultivated (NC) and cultivated for long periods (C); P factor (P doses): P1 (lower dose) and P2 (higher dose); factor I (mycorrhizal fungi): no inoculation (NI) and inoculation (I).

For assemblage of pots, initially liming was carried out in soils in order to raise the bases saturation up to 60%, using dolomitic lime with Ca:Mg ratio of 4: 1 and total neutralizing power of 100%. The soil remained incubated for 45 days while maintaining the moisture content equivalent to 60% of the total pore volume. A basic fertilization with nutrient solutions for macro- and micronutrients was carried out in order to achieve the following nutrient content in soil (mg kg^-1): K (80); S (35); B (0.8); Fe (3.0); Cu (1.5); Mn (3.6); Zn (5.0); and Mo (0.15). For that, the following P.A. sources of nutrients were used: NH₄H₂PO₄ NH₄NO₃, K₂SO₄, H₃BO₃, FeSO₄.7H₂O, CuSO₄.5H₂O, MnSO₄.H₂O, ZnSO₄.7H₂O and (NH₄) 6Mo₇O₂₄.4H₂O. During the preparation of the nutrient solutions, we proceeded the balancing of the accompanying elements. Ca and Mg were supplied via liming.

The P doses applied in each soil were based on maximum phosphorus dose required for maximum dry matter production of corn, obtained in preliminary test under greenhouse conditions (data not published). The doses of P used for each case can be found in Motta et al. (2016MOTTA, P. E. F. et al. Long-term phosphate fertilization, mycorrhizal inoculation and historical land use influence on soybean growth and P uptake. Ciência e Agrotecnologia, 40(4):418-431, 2016.). The highest P dose (P2) corresponds to 50% of the dose required for maximum production and the lowest P dose (P1) corresponds to 5%. These doses have been established to avoid inhibiting the development of mycorrhizae (Paula; Siqueira, 1987PAULA, M. A.; SIQUEIRA, J. O. Efeito de micorrizas vesicular-arbusculares no crescimento, nodulação e acúmulo de nitrogênio pela soja. Pesquisa Agropecuária Brasileira , 22(2):171-178, 1987. ) regarding the highest dose, and a minimum quantity to not limit plant growth compared to the lowest dose.

Following the application of the treatments and incubation, the fumigation of soil materials with methyl bromide was performed. After the period of ventilation, the mycorrhizal fungi inoculation was performed in half of the total number of pots using 1 mL suspension containing spores of mycorrhizal fungus Glomus etunicatum, prepared by the method of Gerdermann and Nicolson (1963)GERDEMANN, J. W.; NICOLSON, T. H. Spores of mycorrhizal Endogone species extracted from soil by wet sieving and decanting. Transactions of the British Mycological Society, 46:235-244, 1963.. We applied 300 spores per pot in holes where seeds were placed. Initially ten seeds were used per pot, but only two plants were allowed to grow. After planting, we performed the partial recovery of the original microbiota in all pots, via inoculation with filtered extract prepared from the same soils in conditions prior to fumigation.

The experiment included two plantings, maintaining the moisture of the soil corresponding to 60% of the total pore volume. After the first planting that lasted 10 weeks, the plants were cut close to the ground, washed and dried in an oven with forced air circulation for 72 hours at 60 °C. The roots were removed for evaluation of root colonization by mycorrhizae (Giovanette; Mosse, 1980GIOVANNETTI, M.; MOSSE, B. An evaluation of techniques for measuring vesicular-arbuscular mycorrhizal infection in roots. New Phytology, 84:484-500, 1980.). Also, soil samples were collected from the pots for chemical characterization.

In the soil remaining from the first planting, K and S contents were increased by applying 80 mg kg^-1 of K₂SO₄, performing a new seedling and a second planting that was also conducted for 10 weeks. The plants were then collected to be obtained the shoot dry matter and P content, in addition to evaluation of root colonization by mycorrhizae and collection of soil from the pots for chemical characterization.

Analysis of variance and test of Tukey were conducted to assess the statistical differences (p<0.05) of the effects of interaction between P doses, mycorrhizal inoculation and non-inoculation, and historical of land use (cultivated or non-cultivated soils) on Urochloa shoot dry matter, concentration of P in shoot dray matter and total accumulated phosphorus (1^st + 2^nd plantings).

RESULTS AND DISCUSSION

Shoot dry matter (SDM)

In the first planting, the maximum SDM occurred with the greater dose of P in non-cultivated LAx and LAd and with this very same dose in inoculated LVw and LVdf (Table 2). The minimum production of SDM occurred at the lowest dose of P in LAx and LVdf regardless the land use history. In LAd and LVw, the minimum production occurred at the lowest dose of P in non-cultivated soils. In the second planting, the maximum SDM was obtained in LAx, LAd and LVdf with the highest dose of P (cultivated or not), but in LVw, it only occurred when previously cultivated. The minimum production occurred at the lowest dose of P in non-cultivated LAx and LVw and in non-inoculated LAd and LVdf.

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Table 2:
Urochloa decumbens shoot dry matter in the 1^st and 2^nd plantings as affected by P doses and mycorrhizal inoculation.

The response to the addition of P had great variation among the Latosols being influenced by the history of land use as well as inoculation and planting (1^st or 2^nd) (Table 2). In the first planting in all soils, response to P was greater when plants were grown in soils that had not been previously cultivated due to the low natural content of P in the soil (Motta et al., 2002MOTTA, P. E. F. et al. Adsorção e formas de fósforo em Latossolos: Influência da mineralogia e histórico de uso. Revista Brasileira de Ciência do Solo , 26(2):349-359, 2002.). Only in the cultivated LAx there was no positive response to doses with increasing P content, which can be attributed to sufficient content of this nutrient available for maximum development of the plant.

However, in the LVw, the SDM increased from 10.83 g to 41.07 g (+ 280%) as the P content in non-cultivated soil increased. In this condition, the initial P content in the soil by Mehlich-1 was 3 mg dm^-3 (Table 3), but when this soil was pre-cultivated (initial P content equal to 54 mg dm^-3), SDM increased from 29.36 g to 36.34 g (+23%). Similar results were found for the clayey Yellow Latosol (available P equal to 2 mg kg^-1), in which phosphate fertilization, associated or not with mycorrhizal inoculation, significantly increased the SDM of Urochloa humidicola (Costa et al., 1997COSTA, N. L. et al. Resposta de Brachiaria humidicola à inoculação de micorrizas arbusculares e à aplicação de fontes e doses de fósforo. Pesquisa Agropecuária Gaúcha, 3(2):109-114, 1997. ).

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Table 3:
Soil available P (mg dm^-3) before 1^st planting and after 1^st and 2^nd plantings.

Regarding the effect of the inoculation, there was a greater effect on the SDM when the LAx had not been previously cultivated and when received the highest dose of P. In LAd there was only the effect of inoculation when it had been cultivated previously. In LVw (cultivated and non-cultivated), when received the highest dose of P, inoculation increased the SDM of Urochloa. In LVdf there was only an effect of inoculation when application of the highest dose of P occurred. Moreover, the response to the highest dose of P was greater with inoculation in LAx, LAd and LVdf, while in LVw had no difference. In a clayey Dystroferric Red Latosol treated with single superphosphate (12.5 mg kg^-1), a significant effect was found with inoculation in DSM of four grasses, including U. decumbens (Kanno et al., 2006KANNO, T. et al. Importance of indigenous arbuscular mycorrhiza for growth and phosphorus uptake In tropical forage grasses growing on an acid, infertile soil from the Brazilian savannas. Tropical Grasslands, 40:91-101, 2006.).

In the second planting, the response to the highest dose of P in LAx, LAd, and LVw was similar to the first planting, and greater in those soils not previously cultivated. However, it is important to highlight that the LVw presented the greatest response (approximately +570%) (Table 2). Unlike the first planting, the response was greater without inoculation, except for the LVdf that did not have significant responses in the presence of inoculation. The response in LVdf was low in the absence of inoculation and not significant for all other conditions, despite the expected reduction in available P due to the large production of SDM for the first planting. Except for the LVdf, responses were higher in the second planting. In LVw, the increase of SDM in NC, which was 279% in the first planting, increased to 570% in the second planting. In LAx, it increased from 36 to 186% and, in LAd, from 89 to 139%.

The response of Urochloa to inoculation varied with the history of land use and the dose of P (Table 2). In the first planting, there was no effect of inoculation in LAx for the non-cultivated soil and also when applying the highest dose of P; in LAd, it occurred only for the cultivated soil; in LVw there was no effect only when applying the lowest dose of P, whereas in LVdf, the effect was only with the highest dose of P (Table 2). In the second planting, the effect of inoculation was greater in all soils, especially with the application of the lowest dose of P. For LAx, with the lowest dose of P, in which there was no effect in the first planting, inoculation increased the SDM from 12.01 g to 16.56 g (+38%) (Table 2). In this soil (non-cultivated), the P contents in the soil before the second planting were 5 and 53 mg dm^-3 (Table 3), for P1 and P2, occurring 30% and 4% of colonization, respectively (Table 4). When under planting, the P contents were 19 and 76 mg dm^-3, respectively for P1 and P2, and there was no mycorrhizae colonization found.

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Table 4:
Mycorrhizal colonization of Urochloa decumbens roots (%) as affected by historical land use and P doses (1^st and 2^nd planting).

In LAd, there was no effect of inoculation in the application of the highest dose of P, although there was a colonization of 7% in non-cultivated soil (Table 4). In LVw, there was no effect of inoculation when non-cultivated and a small effect when grown previously. In the cultivated soil, while with the highest and lowest P doses applied the contents of P in the soil reached relatively close values, 79 and 50 mg dm^-3, colonization was inhibited only in the former, similarly to the first planting, resulting in a colonization of 41 % in the latter. The effect of the inoculation was greatest at the lowest dose of P, therefore, there was no reduction in the SDM with the highest dose of P. In LVdf, there was an effect of inoculation only when the lowest dose of P was applied. The greater levels of P tend to reduce or inhibit the effect of inoculation, even if colonization has occurred. As found for LVw, the mycorrhizal association did not contribute to plant development in the presence of high contents of available P in the soil and it could even cause a negative effect, because it constitutes a drain of photosynthates of the plant (Sharif; Claassen, 2011SHARIF, M.; CLAASSEN, N. Action mechanisms of arbuscular mycorrhizal fungi in phosphorus uptake by Capsicum annum L. Pedosphere, 21(4):502-511, 2011.).

Mycorrhizal dependency and the response of the plants appear to be most significant in adverse soil conditions (Kanno et al., 2006KANNO, T. et al. Importance of indigenous arbuscular mycorrhiza for growth and phosphorus uptake In tropical forage grasses growing on an acid, infertile soil from the Brazilian savannas. Tropical Grasslands, 40:91-101, 2006.). This seems to meet the results obtained by Canizares et al. (2015CANIZARES, P. J. G. et al. Contribución de la inoculación micorrízica arbuscular a la reducción de la fertilización fosfórica en Brachiaria decumbens. Cultivos Tropicales, 36(1):135-142, 2015. ). In their study, doses of 30, 60 and 90 kg ha^-1 P₂O₅ were applied, with and without inoculation, and no differences were observed among the treatments, which means the inoculation with the lowest dose of P provided the same result when associated with a greater dose of P, suggesting lesser influence of phosphate fertilization. In a clayey Yellow Latosol, soil inoculation with Acaulospora muricata associated with natural phosphate promoted significant increase in dry matter of Urochloa humidicola when compared to treatments in which only an application of phosphate or inoculation was carried out, however, increasing the P content in the presence of inoculation had no effect (Costa et al., 1997COSTA, N. L. et al. Resposta de Brachiaria humidicola à inoculação de micorrizas arbusculares e à aplicação de fontes e doses de fósforo. Pesquisa Agropecuária Gaúcha, 3(2):109-114, 1997. ). The interactions between P and mycorrhizal associations are summarized by Bethlenfalvay et al. (1982BETHLENFALVAY, G. J. et al. Interactions between nitrogen fixation, mycorrhizal colonization, and host-plant growth in the Phaseolus-Rhizobium-Glomus symbiosis. Plant Physiology, 70:446-450, 1982.) and Sharif and Claassen (2011SHARIF, M.; CLAASSEN, N. Action mechanisms of arbuscular mycorrhizal fungi in phosphorus uptake by Capsicum annum L. Pedosphere, 21(4):502-511, 2011.) as follows: the response to inoculation will depend on the P supply; if P content in soil is very low, the growth of symbionts is inhibited; if P exists in the soil (even low) it will promote growth of the host; and if the soil P content is high, the development of fungus can occur in detriment to the host.

Concentration and accumulation of P in Urochloa shoot

In the first planting, the maximum concentration of P in the shoot took place with the highest dose of P in LAd and LVdf (Table 5), and in non-inoculated LAx and LVw (Table 6). Minimum values occurred at the lowest dose of P in LAd and LVdf (Table 5), and with the same dose in LVw and LAx both non-cultivated (Table 6).

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Table 5:
P concentration in the Urochloa decumbens shoot dry matter (1^st and 2^nd plantings) as affected by P doses and mycorrhizal inoculation in the Dystrophic Yellow Latosol (LAd) and Dystroferric Red Latosol (LVdf).

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Table 6:
P concentration in the Urochloa decumbens shoot dry matter (1^st and 2^nd plantings) as affected by P doses and mycorrhizal inoculation in the Dystrocohesive Yellow Latosol (LAx) and Acric Red Latosol (LVw).

In the second planting, the highest P concentration in the shoot were found with the greatest dose in LAd and LVdf (Table 5) as well as in LVdf when not cultivated previously. In LAx, the maximum concentration of P occurred with the highest dose of P when cultivated and in LVw, with the lowest dose when non-cultivated (Table 6). The lower contents occurred at the lowest dose in LAd and LVdf (Table 5); and with the same dose in LAx non-cultivated and in LVw cultivated (Table 6).

In the first planting, the increase of P dose increased the P content in the shoot of Urochloa in all soils, being influenced by the history of land use and inoculation. In LAx and LVw, the response of Urochloa was greater when these soils had not been previously cultivated, and not having an effect of inoculation. In LAd and LVdf, where only simple effects occurred with these factors, the response was little. In the second planting, there was a reduction of responses, mentioning, for example, LAx that had double interactions occurring in both plantings. In the first planting, increases of P, which were correspondent to 64% (cultivated) and 108% (non-cultivated), became 58% (cultivated) and 53% (non-cultivated). Increases of 80% and 87%, noted for plants inoculated and non-inoculated in the first planting, were reduced to 59% and 54% during the second planting, the same pattern occurred in LAd and LVdf. Unlike the other soils, in LVw there was a reduction in the concentration of P in the shoot when not cultivated previously, which decreased from 1.58 to 0.99 g kg^-1 (-60%), in agreement with the great SDM increase observed in the order of 570% (a dilution effect).

In the first planting, there was no effect of inoculation for LAd, although there was colonization of 19% and 37% (Table 4) with the application of the lowest dose of P in cultivated and non-cultivated soils, respectively. In cultivated LVw, inoculation increased 11% the SDM with the lowest dose of P (Table 2), and the dilution effect caused a reduction in P content in the shoot from 1.29 to 1.09 g kg^-1 (Table 6). In this case, the P content in the soil was 55 mg dm^-3 (Table 3) and a colonization of 8% occurred (Table 4). With the highest dose of P, the P content in the soil reached 111 mg P dm^-3, and there was inhibition on mycorrhizal fungi, which, therefore, did not have an effect of inoculation. In non-cultivated soil, inoculation increased the SDM in 13% with the highest dose of P and also, by dilution effect, a reduction of P in the shoot occurred, decreasing from 1.64 to 1.43 g kg^-1. The P content in the soil was 30 mg dm^-3 and there was colonization of 9%.

In the second planting, there was no effect of inoculation in LAd and LVdf (Table 5). The deleterious effect of inoculation on P in the shoot in cultivated LVw and also with the highest dose of P in the first planting disappeared in the second planting, where there was no effect of treatment (Table 6). Similar facts happened to the LVdf, whose reduction of 17% in the first planting was annulled in the second planting.

The highest accumulations of P (1^st + 2^nd plantings) occurred with the higher dose of P in non-cultivated LAd and LVdf (Table 7), LAx and LVw (Table 8). Lower accumulations occurred with the lowest dose of P in LAd and LVdf (Table 7), and with the lowest dose of P in non-cultivated LAx and LVw (Table 8).

Thumbnail

Table 7:
Accumulated P in the Urochloa decumbens shoot dry matter (1^st and 2^nd plantings) as affected by P doses and mycorrhizal inoculation in the Dystrophic Yellow Latosol (LAd) and Dystroferric Red Latosol (LVdf).

Thumbnail

Table 8:
Accumulated P in the Urochloa decumbens shoot dry matter (1^st and 2^nd plantings) as affected by P doses and mycorrhizal inoculation in the Dystrocohesive Yellow Latosol (LAx) and Acric Red Latosol (LVw).

The elevation of P dose increased the P uptake in shoot of Urochloa in all soils. In LAx (Table 8), the response was influenced by the history of land use, occurring increases of 218% and 85% for non-cultivated and cultivated, respectively. The effect of inoculation was not significative. In LVw, the response varied with a history of land use and inoculation, being greater in non-cultivated (531%) than in the cultivated (103%) and in the non-inoculated (235%) than in the inoculated (186%) (Table 8). The lesser response in cultivated soils is probably due to the already existing high P content in these soils, 55 mg dm^-3 (Table 3), before the first planting. The elevation of P dose also increased the accumulated P in 111% in LAd and only 32% in LVdf (Table 7), which is also due to the higher available P. Over all soils, we did not observe any effect of inoculation on P accumulation in the plant. According to Bago (2000BAGO, B. Putative sites for nutrient uptake in arbuscular mycorrhizal fungi. Plant Soil, 226:263-274, 2000.), fungal hyphae can absorb P from the soil, but not necessarily increase passage of P to the interior of the roots.

Canizares et al. (2015CANIZARES, P. J. G. et al. Contribución de la inoculación micorrízica arbuscular a la reducción de la fertilización fosfórica en Brachiaria decumbens. Cultivos Tropicales, 36(1):135-142, 2015. ) found no effect of inoculation associated with different doses of P in the Urochloa decumbens shoot. In contrast, Santos et al. (2002SANTOS, I. P. A. et al. Influência do fósforo, micorriza e nitrogênio no conteúdo de minerais de Brachiaria brizantha e Arachis pintoi consorciados. Revista Brasileira de Zootecnia, 31(2):605-616, 2002.) found a higher accumulation of P in Urochloa brizantha when P levels were associated with mycorrhization. It is noteworthy, however, to highlight that the greatest effect of mycorrhization happened with the lowest doses of P used. Costa et al. (1997COSTA, N. L. et al. Resposta de Brachiaria humidicola à inoculação de micorrizas arbusculares e à aplicação de fontes e doses de fósforo. Pesquisa Agropecuária Gaúcha, 3(2):109-114, 1997. ) concluded that inoculation and application of P promoted greater uptake of nitrogen and phosphorus by Urochloa humidicola.

CONCLUSIONS

The growth of Urochloa decumbens was strongly influenced by the interaction among soil class x history of land use x dose of P x inoculation. When planted for the first time, in general, the greater response to P occurred in soils under native vegetation and when the inoculation was associated with P addition. When planted for the second time, inoculation provided a greater effect in all soils with the application of the lowest dose of P. The application of P tends to increase the concentration of P in the shoot of Urochloa. In this study, inoculation did not affect the concentration and accumulation of P in the shoot of Urochloa decumbens.

REFERENCES

ALVIM, M. J.; BOTREL, M. A.; XAVIER, D. F. As principais espécies de braquiária utilizadas no país. Empresa Brasileira de Pesquisa Agropecuária, Juiz de Fora, 2002. 4p. (Comunicado Técnico 22).
ABDELMONEIM, T. S.; ALMAGHRABI, O. A. Improved tolerance of maize plants to heavy metals stress by inoculation with arbuscular mycorrhizal fungi. Archives des Sciences, 66:155-67, 2013.
ALIZADEH, O.; ZARE, M.; NASR, A. H. Evaluation effect of Mycorrhiza inoculate under drought stress condition on grain yield of sorghum (Sorghum bicolor). Advances of Environmental Biology, 5:2361-2364, 2011.
BAGO, B. Putative sites for nutrient uptake in arbuscular mycorrhizal fungi. Plant Soil, 226:263-274, 2000.
BORTOLUZZI, E. C. et al. Occurrence of iron and aluminum sesquioxides and their implications for the P sorption in subtropical soils. Applied Clay Science, 104:196-204, 2015.
BETHLENFALVAY, G. J. et al. Interactions between nitrogen fixation, mycorrhizal colonization, and host-plant growth in the Phaseolus-Rhizobium-Glomus symbiosis. Plant Physiology, 70:446-450, 1982.
BRESSAN, W. et al. Fungos micorrízicos e fósforo, no crescimento, nos teores de nutrientes e na produção de sorgo e soja consorciados. Pesquisa Agropecuária Brasileira, 36(2):315-323, 2001.
CANIZARES, P. J. G. et al. Contribución de la inoculación micorrízica arbuscular a la reducción de la fertilización fosfórica en Brachiaria decumbens Cultivos Tropicales, 36(1):135-142, 2015.
COVACEVICH, F.; ECHEVERRÍA, H. E.; AGUIRREZABAL, L. A. N. Soil available phosphorus status determines indigenous mycorrhizal colonization of field and glasshouse grown spring wheat from Argentina. Applied Soil Ecology, 35:1-9, 2007.
COVACEVICH, F.; MARINO, M. A.; ECHEVERRÍA, H. E. The phosphorus source determines the arbuscular mycorrhizal potential and the native mycorrhizal colonization of tall fescue and wheatgrass. European Journal of Soil Biology, 42:27-138, 2006.
COSTA, N. L. et al. Resposta de Brachiaria humidicola à inoculação de micorrizas arbusculares e à aplicação de fontes e doses de fósforo. Pesquisa Agropecuária Gaúcha, 3(2):109-114, 1997.
COSTA, N. L. et al. Efeito de micorrizas arbusculares sobre o crescimento e nutrição mineral de Brachiaria brizantha cv. Marandu. Ciência Animal Brasileira, 13(4):406-411, 2012.
DONAGEMMA, G. H. et al. Manual de métodos de análise de solo. Rio de Janeiro: Solos, 2011. 230p.
EMPRESA BRASILEIRA DE PESQUISA AGROPECUÁRIA - . CENTRO NACIONAL DE PESQUISAS DE SOLOS. Manual de métodos de análises de solos. 2.ed. Rio de Janeiro, Solos, 1997. 212p.
GEE, G. W.; BAUDER, J. W. Particle-size analysis. In: KLUTE, A. (ed.). Methods of soil analysis. 2.ed. Madison: American Society of Agronomy, 1986. p.383-412.
GERDEMANN, J. W.; NICOLSON, T. H. Spores of mycorrhizal Endogone species extracted from soil by wet sieving and decanting. Transactions of the British Mycological Society, 46:235-244, 1963.
GIOVANNETTI, M.; MOSSE, B. An evaluation of techniques for measuring vesicular-arbuscular mycorrhizal infection in roots. New Phytology, 84:484-500, 1980.
GUCWA-PRZEPIÓRIA, E. et al. Enzymatic activities and arbuscular mycorrhizal colonization of Plantago lanceolata and Plantago major in a soil root zone under heavy metal stress. Environmental Science and Pollution Research International, 23:4742-4755, 2016.
HART, M. M.; FORSYTHE, J. A. Using arbuscular mycorrhizal fungi to improve the nutrient quality of crops: Nutritional benefits in addition to phosphorus. Science Horticulturae, 148:206-214, 2012.
KANNO, T. et al. Importance of indigenous arbuscular mycorrhiza for growth and phosphorus uptake In tropical forage grasses growing on an acid, infertile soil from the Brazilian savannas. Tropical Grasslands, 40:91-101, 2006.
KIRIACHEK, S. G. et al. Regulação do desenvolvimento de micorrizas arbusculares. Revista Brasileira de Ciência do Solo, 33:1-16, 2009.
LOPES, A. S.; GUILHERME, L. R. G.; RAMOS, S. J. The saga of agricultural development of the Brazilian Cerrado. International Potash Institute, 32:29-56, 2012.
MOTTA, P. E. F. et al. Adsorção e formas de fósforo em Latossolos: Influência da mineralogia e histórico de uso. Revista Brasileira de Ciência do Solo , 26(2):349-359, 2002.
MOTTA, P. E. F. et al. Long-term phosphate fertilization, mycorrhizal inoculation and historical land use influence on soybean growth and P uptake. Ciência e Agrotecnologia, 40(4):418-431, 2016.
NADEEM, S. M. et al. The role of mycorrhizae and plant growth promoting rhizobacteria (PGPR) in improving crop productivity under stressful environments. Biotechnology Advances, 32:429-448, 2014.
OLSEN, S. R.; WATANABE, F. S. A method to determine a phosphorus adsorption maximum capacity of soils as measured by the Langmuir isotherm. Soil Science Society of America Proceedings, 21:144-149, 1957.
PAULA, M. A.; SIQUEIRA, J. O. Efeito de micorrizas vesicular-arbusculares no crescimento, nodulação e acúmulo de nitrogênio pela soja. Pesquisa Agropecuária Brasileira , 22(2):171-178, 1987.
ROONEY, D. C. et al. Effect of arbuscular mycorrhizal colonization on the growth and phosphorus nutrition of Populuseur americana c.v. Ghoy. Biomass Bioenergy, 35:4605-4612, 2011.
SANTOS, I. P. A. et al. Influência do fósforo, micorriza e nitrogênio no conteúdo de minerais de Brachiaria brizantha e Arachis pintoi consorciados. Revista Brasileira de Zootecnia, 31(2):605-616, 2002.
SHARIF, M.; CLAASSEN, N. Action mechanisms of arbuscular mycorrhizal fungi in phosphorus uptake by Capsicum annum L. Pedosphere, 21(4):502-511, 2011.
SMITH, S. E. et al. Roles of arbuscular mycorrhizas in plant phosphorus nutrition: Interactions between pathways of phosphorus uptake in arbuscular mycorrhizal roots have important implications for understanding and manipulating plant phosphorus acquisition. Plant Physiology , 156:1050-1057, 2011.
TISDALL, J. M.; OADES, J. M. Organic matter and water stable aggregates in soil. Journal of Soil Science, 32(1):141-163, 1982.
VERESOGLOU, S. D.; CHEN, B.; RILLIG, M. C. Arbuscular mycorrhiza and soil nitrogen cycling. Soil Biology Biochemistry, 46:53-62, 2012.
XIE, X. et al. Effects of arbuscular mycorrhizal inoculation and phosphorus supply on the growth and nutrient uptake of Kandelia obovata (Sheue, Liu & Yong) seedlings in autoclaved soil. Applied Soil Ecology , 75:162-171, 2014.

Publication Dates

Publication in this collection
Mar-Apr 2017

History

Received
03 Nov 2016
Accepted
05 Dec 2016

This is an open-access article distributed under the terms of the Creative Commons Attribution License

[1] ALVIM, M. J.; BOTREL, M. A.; XAVIER, D. F. As principais espécies de braquiária utilizadas no país. Empresa Brasileira de Pesquisa Agropecuária, Juiz de Fora, 2002. 4p. (Comunicado Técnico 22).

[2] ABDELMONEIM, T. S.; ALMAGHRABI, O. A. Improved tolerance of maize plants to heavy metals stress by inoculation with arbuscular mycorrhizal fungi. Archives des Sciences, 66:155-67, 2013.

[3] ALIZADEH, O.; ZARE, M.; NASR, A. H. Evaluation effect of Mycorrhiza inoculate under drought stress condition on grain yield of sorghum (Sorghum bicolor). Advances of Environmental Biology, 5:2361-2364, 2011.

[4] BAGO, B. Putative sites for nutrient uptake in arbuscular mycorrhizal fungi. Plant Soil, 226:263-274, 2000.

[5] BORTOLUZZI, E. C. et al. Occurrence of iron and aluminum sesquioxides and their implications for the P sorption in subtropical soils. Applied Clay Science, 104:196-204, 2015.

[6] BETHLENFALVAY, G. J. et al. Interactions between nitrogen fixation, mycorrhizal colonization, and host-plant growth in the Phaseolus-Rhizobium-Glomus symbiosis. Plant Physiology, 70:446-450, 1982.

[7] BRESSAN, W. et al. Fungos micorrízicos e fósforo, no crescimento, nos teores de nutrientes e na produção de sorgo e soja consorciados. Pesquisa Agropecuária Brasileira, 36(2):315-323, 2001.

[8] CANIZARES, P. J. G. et al. Contribución de la inoculación micorrízica arbuscular a la reducción de la fertilización fosfórica en Brachiaria decumbens Cultivos Tropicales, 36(1):135-142, 2015.

[9] COVACEVICH, F.; ECHEVERRÍA, H. E.; AGUIRREZABAL, L. A. N. Soil available phosphorus status determines indigenous mycorrhizal colonization of field and glasshouse grown spring wheat from Argentina. Applied Soil Ecology, 35:1-9, 2007.

[10] COVACEVICH, F.; MARINO, M. A.; ECHEVERRÍA, H. E. The phosphorus source determines the arbuscular mycorrhizal potential and the native mycorrhizal colonization of tall fescue and wheatgrass. European Journal of Soil Biology, 42:27-138, 2006.

[11] COSTA, N. L. et al. Resposta de Brachiaria humidicola à inoculação de micorrizas arbusculares e à aplicação de fontes e doses de fósforo. Pesquisa Agropecuária Gaúcha, 3(2):109-114, 1997.

[12] COSTA, N. L. et al. Efeito de micorrizas arbusculares sobre o crescimento e nutrição mineral de Brachiaria brizantha cv. Marandu. Ciência Animal Brasileira, 13(4):406-411, 2012.

[13] DONAGEMMA, G. H. et al. Manual de métodos de análise de solo. Rio de Janeiro: Solos, 2011. 230p.

[14] EMPRESA BRASILEIRA DE PESQUISA AGROPECUÁRIA - . CENTRO NACIONAL DE PESQUISAS DE SOLOS. Manual de métodos de análises de solos. 2.ed. Rio de Janeiro, Solos, 1997. 212p.

[15] GEE, G. W.; BAUDER, J. W. Particle-size analysis. In: KLUTE, A. (ed.). Methods of soil analysis. 2.ed. Madison: American Society of Agronomy, 1986. p.383-412.

[16] GERDEMANN, J. W.; NICOLSON, T. H. Spores of mycorrhizal Endogone species extracted from soil by wet sieving and decanting. Transactions of the British Mycological Society, 46:235-244, 1963.

[17] GIOVANNETTI, M.; MOSSE, B. An evaluation of techniques for measuring vesicular-arbuscular mycorrhizal infection in roots. New Phytology, 84:484-500, 1980.

[18] GUCWA-PRZEPIÓRIA, E. et al. Enzymatic activities and arbuscular mycorrhizal colonization of Plantago lanceolata and Plantago major in a soil root zone under heavy metal stress. Environmental Science and Pollution Research International, 23:4742-4755, 2016.

[19] HART, M. M.; FORSYTHE, J. A. Using arbuscular mycorrhizal fungi to improve the nutrient quality of crops: Nutritional benefits in addition to phosphorus. Science Horticulturae, 148:206-214, 2012.

[20] KANNO, T. et al. Importance of indigenous arbuscular mycorrhiza for growth and phosphorus uptake In tropical forage grasses growing on an acid, infertile soil from the Brazilian savannas. Tropical Grasslands, 40:91-101, 2006.

[21] KIRIACHEK, S. G. et al. Regulação do desenvolvimento de micorrizas arbusculares. Revista Brasileira de Ciência do Solo, 33:1-16, 2009.

[22] LOPES, A. S.; GUILHERME, L. R. G.; RAMOS, S. J. The saga of agricultural development of the Brazilian Cerrado. International Potash Institute, 32:29-56, 2012.

[23] MOTTA, P. E. F. et al. Adsorção e formas de fósforo em Latossolos: Influência da mineralogia e histórico de uso. Revista Brasileira de Ciência do Solo , 26(2):349-359, 2002.

[24] MOTTA, P. E. F. et al. Long-term phosphate fertilization, mycorrhizal inoculation and historical land use influence on soybean growth and P uptake. Ciência e Agrotecnologia, 40(4):418-431, 2016.

[25] NADEEM, S. M. et al. The role of mycorrhizae and plant growth promoting rhizobacteria (PGPR) in improving crop productivity under stressful environments. Biotechnology Advances, 32:429-448, 2014.

[26] OLSEN, S. R.; WATANABE, F. S. A method to determine a phosphorus adsorption maximum capacity of soils as measured by the Langmuir isotherm. Soil Science Society of America Proceedings, 21:144-149, 1957.

[27] PAULA, M. A.; SIQUEIRA, J. O. Efeito de micorrizas vesicular-arbusculares no crescimento, nodulação e acúmulo de nitrogênio pela soja. Pesquisa Agropecuária Brasileira , 22(2):171-178, 1987.

[28] ROONEY, D. C. et al. Effect of arbuscular mycorrhizal colonization on the growth and phosphorus nutrition of Populuseur americana c.v. Ghoy. Biomass Bioenergy, 35:4605-4612, 2011.

[29] SANTOS, I. P. A. et al. Influência do fósforo, micorriza e nitrogênio no conteúdo de minerais de Brachiaria brizantha e Arachis pintoi consorciados. Revista Brasileira de Zootecnia, 31(2):605-616, 2002.

[30] SHARIF, M.; CLAASSEN, N. Action mechanisms of arbuscular mycorrhizal fungi in phosphorus uptake by Capsicum annum L. Pedosphere, 21(4):502-511, 2011.

[31] SMITH, S. E. et al. Roles of arbuscular mycorrhizas in plant phosphorus nutrition: Interactions between pathways of phosphorus uptake in arbuscular mycorrhizal roots have important implications for understanding and manipulating plant phosphorus acquisition. Plant Physiology , 156:1050-1057, 2011.

[32] TISDALL, J. M.; OADES, J. M. Organic matter and water stable aggregates in soil. Journal of Soil Science, 32(1):141-163, 1982.

[33] VERESOGLOU, S. D.; CHEN, B.; RILLIG, M. C. Arbuscular mycorrhiza and soil nitrogen cycling. Soil Biology Biochemistry, 46:53-62, 2012.

[34] XIE, X. et al. Effects of arbuscular mycorrhizal inoculation and phosphorus supply on the growth and nutrient uptake of Kandelia obovata (Sheue, Liu & Yong) seedlings in autoclaved soil. Applied Soil Ecology , 75:162-171, 2014.

Soil	Particle size distribution	Parent material	Location	Use	Management practices
LAx	Clayey	Sediments of the Barreiras Formation	Aracruz (ES)	NC: Tropical semiperennial forest	---
				C: Annual crops (corn and bean) for 11 years. Soil was maintained covered with Panicum maximum grass during the last 3 years prior to the sampling	Annual phosphate fertilization and occasional liming
LAd	Clayey	Product of the alteration of granitic gneiss	Lavras (MG)	NC: Tropical semicaducifolious forest	---
				C: Annual crops for more than 10 years	Annual phosphate fertilization and occasional liming
LVw	Very clayey	Sediments from the Tertiary	Uberlândia (MG)	NC: Semicaducifolious tropical cerrado	---
				C: Annual crops for more than 10 years	Strong annual phosphate fertilization and liming
LVdf	Clayey	Product of the alteration of tuffite	Patos de Minas (MG)	NC: Tropical semicaducifolious forest	---
				C: Annual crops for more than 15 years. Soil was maintained covered with Urochloa decumbens grass during the last 5 years prior to the sampling.	Annual phosphate fertilization and occasional liming

	1^st planting				2^nd planting
	Dose of P		Inoculation		Dose of P		Inoculation
	P1	P2	NI	I	P1	P2	NI	I
	LAx
NC	36.43aB	49.64aA	40.65aB	45.42aA	8.94bB	25.53aA	15.21bB	19.27bA
C	34.97aA	37.38bA	35.27bA	37.08bA	19.63aB	25.00aA	21.54aA	23.09aA
P1	---	---	34.78bA	36.62bA	---	---	12.01bB	16.56bA
P2	---	---	41.14aB	45.88aA	---	---	24.74aA	25.80aA
	LAd
NC	23.28bB	44.00aA	34.11aA	33.17bA	10.86bB	25.93aA	15.93aB	20.86aA
C	32.32aB	40.27bA	34.62aB	37.96aA	14.51aB	26.40aA	18.52aB	22.39aA
P1	---	---	28.07bA	27.53bA	---	---	8.91bB	16.47bA
P2	---	---	40.66aA	43.61aA	---	---	25.55aA	26.78aA
	LVw
NC	10.83bB	41.07aA	24.10bB	27.81bA	3.41bB	22.88bA	14.11bA	12.18bA
C	29.36aB	36.34bA	31.10aB	34.59aA	18.57aB	28.71aA	22.14aB	25.14aA
P1	---	---	18.91bA	21.28bA	---	---	9.16bB	12.82bA
P2	---	---	36.29aB	41.13aA	---	---	27.08aA	24.50aB
	LVdf
NC	42.90aB	51.66aA	46.46aA	48.09aA	28.53aA	30.98aA	28.45aA	31.06aA
C	42.86aB	48.23aA	43.89aA	47.20aA	26.75aA	30.14aA	26.83aA	30.06aA
P1	---	---	42.52bA	43.23bA	---	---	25.49bB	29.79aA
P2	---	---	47.82aB	52.06aA		---	29.79aA	31.34aA

	P in the shoot (mg kg^-1)
	1^st planting		2^nd planting
	LAd	LVdf	LAd	LVdf
NC	0.90a	1.40a	1.06a	1.22a
C	0.86a	1.00b	1.02a	1.05b
P1	0.70b	1.01b	0.95b	1.05b
P2	1.05a	1.39a	1.14a	1.22a
NI	0.91a	1.31a	1.05a	1.16a
I	0.84a	1.09b	1.04a	1.11a

	P in the shoot (mg kg^-1)
	1^st planting				2^nd planting
	Dose of P		Inoculation		Dose of P		Inoculation
	P1	P2	NI	I	P1	P2	NI	I
	LAx
NC	0.75bB	1.56aA	1.18aA	1.12aA	0.80bB	1.23bA	1.04bA	0.99bA
C	0.93aB	1.52aA	1.28aA	1.18aA	1.01aB	1.60aA	1.32aA	1.29aA
P1	---	---	0.86bA	0.82bA	---	---	0.93bA	0.88bA
P2	---	---	1.60aA	1.48aA	---	---	1.43aA	1.40aA
	LVw
NC	0.79aB	1.55aA	1.22aA	1.12aA	1.58aA	0.99aB	1.32aA	1.25aA
C	0.86aB	1.52aA	1.29aA	1.09aB	0.88bB	1.01aA	0.95bA	0.94bA
P1	---	---	0.87bA	0.78bA	---	---	1.27aA	1.19aA
P2	---	---	1.64aA	1.43aB	---	---	1.00bA	1.00bA

	Accumulated P (mg)
	LAd	LVdf
NC	51.64a	103.27a
C	53.57a	75.97b
P1	31.17b	72.24b
P2	65.81a	95.11a
NI	51.13a	92.36a
I	54.08a	86.88a

Brasil

Brasil

Urochloa decumbens growth and P uptake as affected by long-term phosphate fertilization, mycorrhizal inoculation and historical land use in contrasting Oxisols of the Brazilian Cerrado

Crescimento e absorção de P por Urochloa decumbens afetado por longos períodos de adubação fosfatada, inoculação micorrízica e histórico de uso em Latossolos contrastantes do Cerrado brasileiro

ABSTRACT

RESUMO

INTRODUCTION

MATERIAL AND METHODS

RESULTS AND DISCUSSION

Shoot dry matter (SDM)

Concentration and accumulation of P in Urochloa shoot

CONCLUSIONS

REFERENCES

Publication Dates

History

H/P/I	Before 1^st planting			After 1^st planting			After 2^nd planting
H/P/I	M-1	M-3	R	M-1	M-3	R	M-1	M-3	R
LAx
NC P2 I	---	---	---	53	73	50	41	57	30
NC P2 NI	81	119	80	53	74	49	49	62	32
NC P1 I	---	---	---	5	11	10	4	7	5
NC P1 NI	11	16	16	6	13	10	4	8	6
C P2 I	---	---	---	72	104	95	69	87	56
C P2 NI	111	157	97	80	107	78	66	86	54
C P1 I	---	---	---	20	26	17	16	22	15
C P1 NI	29	40	33	18	25	18	17	21	14
LAd
NC P2 I	---	---	---	28	47	35	19	37	26
NC P2 NI	42	64	63	25	48	33	19	39	28
NC P1 I	---	---	---	3	8	6	2	5	7
NC P1 NI	5	10	14	4	8	6	2	5	7
C P2 I	---	---	---	29	41	50	23	38	36
C P2 NI	41	58	82	30	41	55	22	39	38
C P1 I	---	---	---	11	12	19	9	12	12
C P1 NI	14	16	80	11	10	21	9	13	15
LVw
NC P2 I	---	---	---	13	26	40	10	27	27
NC P2 NI	32	53	84	16	29	43	11	28	29
NC P1 I	---	---	---	3	4	8	2	6	6
NC P1 NI	3	6	14	3	4	9	2	5	6
C P2 I	---	---	---	79	52	107	103	58	82
C P2 NI	109	75	114	82	54	114	74	56	77
C P1 I	---	---	---	50	19	49	47	19	37
C P1 NI	54	25	63	49	18	53	47	20	38
LVdf
NC P2 I	---	---	---	106	77	107	94	103	119
NC P2 NI	128	102	146	109	80	123	97	110	113
NC P1 I	---	---	---	69	58	61	60	78	75
NC P1 NI	80	62	121	68	53	58	58	81	75
C P2 I	---	---	---	97	66	89	90	98	127
C P2 NI	123	88	178	105	74	83	97	96	125
C P1 I	---	---	---	62	41	56	55	58	90
C P1 NI	71	45	109	58	41	56	59	60	77

Soil	Historical land use	Dose of P	1^st planting	2^nd planting
LAx	NC	P2	0	4
LAx	NC	P1	22	30
LAx	C	P2	0	0
LAx	C	P1	0	0
LAd	NC	P2	0	7
LAd	NC	P1	37	41
LAd	C	P2	0	0
LAd	C	P1	19	25
LVw	NC	P2	9	9
LVw	NC	P1	38	71
LVw	C	P2	0	0
LVw	C	P1	8	41
LVdf	NC	P2	0	17
LVdf	NC	P1	17	50
LVdf	C	P2	0	0
LVdf	C	P1	11	40

	Accumulated P (mg)
	Dose of P		Inoculation
	P1	P2	NI	I
	LAx
NC	34.04bB	108.25aA	68.09aA	74.20aA
C	52.17aB	96.60bA	74.30aA	74.46aA
P1	---	---	41.33bA	44.88bA
P2	---	---	101.05aA	103.79aA
	LVw
NC	13.61bB	85.80aA	49.76bA	49.65bA
C	41.26aB	83.75aA	62.55aA	62.46aA
P1	---	---	25.84bA	29.03bA
P2	---	---	86.47aA	83.08aA