Nutrient retranslocation in forest species in the Brazilian Amazon

Machado, Murilo Rezende; Sampaio, Paulo de Tarso Barbosa; Ferraz, João; Camara, Rodrigo; Pereira, Marcos Gervasio

doi:10.4025/actasciagron.v38i1.26805

ABSTRACT.

Internal retranslocation is an important mechanism for nutrient conservation in plants, which depends on different factors. However, there are little data about this subject, especially on tropical forest species. This study aimed to evaluate the macronutrient retranslocation dynamic and the influence of ecological (P: pioneer x NP: non-pioneer) and phenological (ND: non-deciduous x D: semideciduous / deciduous) characteristics on the macronutrient content of leaves of five tree species on monospecific plantations in the Brazilian Amazon: Acacia mangium Willd., Parkia decussata Ducke, Dipteryx odorata (Aublet) Willd., Jacaranda copaia (Aubl.) D. Don and Swietenia macrophylla King. Photosynthetically active green leaves and senescent leaves (leaf litter) were collected. Retranslocation was estimated through an equation proposed by Attiwill, Guthrie and Leuning (1978). The pioneer species presented higher foliar contents of N; the non-pioneer species presented higher contents of K, Ca and S; and the results were inconclusive for P and Mg. The deciduous species presented higher foliar contents of K and of P, whereas the foliar contents of N, Ca, Mg and S were virtually identical between the phenological groups. The internal retranslocation of foliar nutrients in pioneer and non-deciduous species was higher than that of non-pioneer and deciduous species.

Keywords:
ecological groups; litterfall; nutrient cycling; phenological groups; plant nutrition

RESUMO.

A retranslocação interna é um importante mecanismo de conservação de nutrientes nas plantas, que depende de diferentes fatores. Contudo, ainda são incipientes os dados desta natureza, principalmente para espécies florestais tropicais. O presente trabalho objetivou avaliar a dinâmica de retranslocação de macronutrientes e a influência dos grupos ecológico (P: pioneiras x NP: não-pioneiras) e fenológico (ND: não-decíduas x D: semidecíduas / decíduas) nas concentrações foliares de macronutrientes em cinco espécies arbóreas em monocultivo na Amazônia brasileira: Acacia mangium Willd., Parkia decussata Ducke, Dipteryx odorata (Aublet) Willd., Jacaranda copaia (Aubl.) D. Don e Swietenia macrophylla King. Para tanto, foram coletadas folhas verdes fotossinteticamente ativas e folhas da serapilheira. A retranslocação foi estimada segundo a equação de Attiwill, Guthrie e Leuning (1978). As espécies pioneiras apresentaram maiores concentrações foliares de N; as não-pioneiras apresentaram maiores concentrações de K, Ca e S; e os resultados foram inconclusivos para P e Mg. As concentrações foliares de K e de P foram maiores nas espécies decíduas, enquanto que as de N, Ca, Mg e S foram praticamente idênticas entre os grupos fenológicos. No geral, as espécies pioneiras e as não-decíduas foram mais eficientes na retranslocação de nutrientes.

Palavras-chave:
grupos ecológicos; serapilheira; ciclagem de nutrientes; grupos fenológicos; nutrição de plantas

Introduction

Nutrients are monitored in forest plantations to identify and correct imbalances by means of plant tissue analysis. Therefore, the evaluation of foliar nutrient content is one of the most widely used techniques in forest nutrition research (Araújo & Haridasan, 2007Araújo, J. F., & Haridasan, H. (2007). Relação entre deciduidade e concentrações foliares de nutrientes em espécies lenhosas do cerrado. Revista Brasileira de Botânica30(3), 533-542.) as leaves are considered the most active and representative organs for plant nutritional status (Malavolta, 2006Malavolta, E. (2006). Manual de nutrição de plantas. São Paulo, SP: Agronômica Ceres.). Furthermore, foliar nutrient contents are influenced by their availability in the soil (Aerts, 1996Aerts, R. (1996). Nutrient resorption from senescing leaves of perennials: are there general patterns? The Journal of Ecology84(4), 597-608.). The mobile nutrients in

plants (N, P, K and Mg) are internally redistributed from senescent leaves before their abscission to growing regions such as new leaves (Bambi, Lobo, Dalmolin, & Dias, 2011Bambi, P., Lobo, F. A., Dalmolin, A. C., & Dias, C. A. A. (2011). Decomposição e redistribuição de nutrientes das folhas de espécies da floresta de transição Amazônia - Cerrado, MT. Ciência e Natura33(1), 17-31.; Almeida et al., 2014Almeida, C. X., Pita Junior, J. L., Rozane, D. E., Souza, H. A., Hernandes, A., Natale, W., & Ferraudo, A. S. (2014). Nutrient cycling in mango trees. Semina. Ciências Agrárias35(1), 259-266.). This internal retranslocation process is especially important because it conserves approximately 60 to 85% of the total content of the nutrients absorbed when the soil availability of the nutrient is low (Malavolta, 2006Malavolta, E. (2006). Manual de nutrição de plantas. São Paulo, SP: Agronômica Ceres.). Information on this process may contribute to a better understanding of the nutrient conservation strategy in plants and the adaptation of certain species to low-fertility soils (Magalhães & Blum, 1999Magalhães, L. M. S., & Blum, W. E. H. (1999). Concentração e distribuição de nutrientes nas folhas de espécies florestais, na Amazônia Ocidental. Floresta e Ambiente6(1), 127-137.).

Pioneer species colonize infertile soils likely through the combination of two characteristics, low nutrient requirements and the efficient use of these elements (Boeger & Wisniewski, 2003Boeger, M. R. T., & Wisniewski, C. (2003). Comparação da morfologia foliar de espécies arbóreas de três estádios sucessionais distintos de Floresta Ombrófila Densa (Floresta Atlântica) no Sul do Brasil. Revista Brasileira de Botânica 26(1), 61-72.), by increasing internal retranslocation, which is influenced by the continuous growth of these plants (Fife & Nambiar, 1997Fife, D. N., & Nambiar, E. K. S. (1997). Changes in the canopy and growth of Pinus radiata in response to nitrogen supply. Forest Ecology and Management93, 137-152.). Thus, pioneer species with fast growth may have higher nutrient retranslocation rates than the non-pioneer species in low-fertility soils. Therefore, pioneer tree species present lower nutrient contents in both green and senescent leaves (leaf litter) than the non-pioneer species (Boeger, Wisniewski, & Reissmann, 2005Boeger, M. R. T., Wisniewski, C., & Reissmann, C. B. (2005). Nutrientes foliares de espécies arbóreas de três estádios sucessionais de Floresta Ombrófila Densa no sul do Brasil. Acta Botanica Brasilica19(1), 167-181.; Pinto, Martins, Barros, & Dias, 2009Pinto, S. I. C., Martins, S. V., Barros, N. F., & Dias, H. C. T. (2009). Ciclagem de nutrientes em dois trechos de Floresta Estacional Semidecidual na Reserva Florestal Mata do Paraíso em Viçosa, MG, Brasil. Revista Árvore 33(4), 653-663.). Regarding plant phenology, it is known that deciduous or semideciduous plants generally have higher foliar nutrient contents because senescent leaves are lost before the internal retranslocation of nutrients compared with the non-deciduous phenological group in tropical or temperate forests (Aerts, 1996Aerts, R. (1996). Nutrient resorption from senescing leaves of perennials: are there general patterns? The Journal of Ecology84(4), 597-608.; Aerts & Chapin, 2000Aerts, R., & Chapin, F. S. (2000). The mineral nutrition in wild plants revisited: a reevaluation of processes and patterns. Advances in Ecological Research30, 1-67.; Franco et al., 2005Franco, A. C., Bustamante, M., Caldas, L. S., Goldstein, G., Meinzer, F. C., Kozovits, A. R., Coradin, V. T. R. (2005). Leaf functional traits of Neotropical savanna trees in relation to seasonal water deficit. Trees19, 326-335.; Araújo & Haridasan, 2007Araújo, J. F., & Haridasan, H. (2007). Relação entre deciduidade e concentrações foliares de nutrientes em espécies lenhosas do cerrado. Revista Brasileira de Botânica30(3), 533-542.). However, few studies have focused on nutritional retranslocation monitoring in forest plantations in the Amazon, especially related to native species (Magalhães & Blum, 1999Magalhães, L. M. S., & Blum, W. E. H. (1999). Concentração e distribuição de nutrientes nas folhas de espécies florestais, na Amazônia Ocidental. Floresta e Ambiente6(1), 127-137.). This study aimed to evaluate the influence of ecological and phenological groups on macronutrient foliar content and retranslocation in five tree species in monospecific plantations in the Brazilian Amazon: the exotic Acacia mangium Willd and the native species Parkia decussata Ducke, Dipteryx odorata (Aublet) Willd., Jacaranda copaia (Aubl.) D. Don and Swietenia macrophylla King.

Material and methods

The experimental area was located at the coordinates 2° 56' 13" S and 58º 55' 55" W, 250 km from the AM-010 State Road in Itacoatiara, Amazonas State, Brazil. The local climate was classified as Ami, defined by a high total annual rainfall with a short, less rainy period (Köppen, 1948Köppen, W. (1948). Climatologia: con un estudio de los climas de La tierra. México, MX: Fondo de Cultura Econômica.). The average rainfall is 2,551 mm yr^-1, and the annual average temperature is 25.9ºC. The local relief varies from flat to wavy, and the predominant soil is Oxisol. The original vegetation, an Ombrophilous Dense Forest (Veloso, Rangel Filho, & Lima, 1991Veloso, H. P., Rangel Filho, A. L. R., & Lima, J. C. A. (1991). Classificação da vegetação brasileira adaptada a um sistema universal. Rio de Janeiro, RJ: IBGE.), was intensively deforested to exploit the high economic value of some tree species, and the remaining vegetation was burned afterwards, followed by the establishment of Bracharia humidicula (Rendle) Schweickerdt pastures.

In December 2003, some areas on a farm called Nova Vida were selected for the establishment of the experimental monospecific forest plantations. The pits (40x40x40 cm) were opened manually with a post hole digger. Calcitic limestone was applied (300 g pit^-1), and a month later NPK (2-18-20) was also applied (200 g pit^-1) according to a previous soil analysis. Weed control was performed by hoeing and periodic herbicide spraying, and leaf-cutting ants were controlled by pesticide application (sulfluramida). Thereafter, three plots of 128 m² (384 m² total area) per monospecific plantation were selected, and three individuals per plot were evaluated. The individuals selected presented the following average diameter at breast height (DBH), with the standard deviation: A. mangium (DBH = 8.5±1.9 cm) and P. decussata (DBH = 9.8±1.6 cm), both pioneer and non-deciduous species; D. odorata (DBH = 5.2±1.1 cm), a non-pioneer and non-deciduous species; J. copaia (DBH = 10.9±2.7 cm), a pioneer and semideciduous species; and S. macrophylla (DBH = 7.1±1.4 cm), a non-pioneer and semideciduous species.

In December 2006, approximately twenty-five photosynthetically active green leaves (GL) were taken from the newest branches, in the middle of the canopy, of each individual. The GL were bulked to obtain a composite sample per plot (three composite samples per forest species). Senescent leaves (SL) were collected monthly with litterfall traps (1.0 m² and composed of shading screens) installed near the trees, one per individual (three traps per plot). The SL were also bulked to obtain composite samples per plot. The samples of both GL and SL were placed in separate paper bags and dried in a forced draught oven at 65°C for 72 hours to estimate the dry mass. The dried material was ground in a Willey mill, and a portion was subjected to sulfuric acid digestion to determine the nutrient content (g kg^-1) of the obtained extract (Tedesco, Gianello, Bissani, Bohnen, & Volkweiss, 1995Tedesco, M. J., Gianello, C., Bissani, C. A., Bohnen, H., & Volkweiss, S. J. (1995). Análise de solo, plantas e outros materiais (2a ed.). Porto Alegre, RS: UFRGS.).

The macronutrient contents in the GL and SL were compared considering the species categorization in the ecological groupings (P: pioneer, NP: non-pioneer species, which included secondary and climax species) and the phenological groupings (ND: non-deciduous, D: deciduous, which included semi-deciduous species). The macronutrient internal retranslocation was estimated according to Attiwill et al. (1978Attiwill, P. M., Guthrie, H. B., & Leuning, R. (1978). Nutrient cycling in a Eucalyptus oblique (L' Herit) forest. Australian Journal of Botany26(1), 79-91.): NR% = [(SL - GL) / GL] x 100, where: NR% = nutrient retranslocation; SL = nutrient content in senescent leaves (g kg^-1); GL = nutrient content in green leaves (g kg^-1). The more negative the NR% value, the higher the element internal retranslocation rate on the plant. On the other hand, positive or near zero NR% values indicated the absence of nutrient internal retranslocation with nutrient accumulation in senescent leaves.

Six simple soil samples per plot were collected using a screw auger at three depths: 0-5 cm, 5-10 cm and 10-30 cm. Sample points were randomly chosen, but the area where litter traps were installed was avoided. A bulked soil sample per plot was obtained by mixing the simple samples, which were air-dried, sieved (2.0 mm mesh) and subjected to chemical analyses (Empresa Brasileira de Pesquisa Agropecuária [Embrapa], 2009Empresa Brasileira de Pesquisa Agropecuária. (2009). Manual de análises químicas de solos, plantas e fertilizantes (2a ed.). Brasília, DF: Embrapa Informação Tecnológica.) that took place at the Soil and Plant Analysis Laboratory of the Embrapa Occidental Amazon. The results were subjected to an analysis of variance (ANOVA) and to the F test. The means were compared by the LSD test at 5% significance. Statistical analyses were performed using the software SAEG 5.0 (Statistical and Genetic Analysis System, Viçosa Federal University).

Results and discussion

According to the general means, the nutrient contents in both GL and SL leaves followed the same decreasing order: N> Ca> K> Mg> S> P (Table 1). This pattern was also observed for other forest species (Table 2). There were small variations regarding the P and Mg contents in the GL among the forest species (0.90-1.00 and 1.38-2.05 g kg^-1, respectively) (Table 1). This may be because there were no significant differences among the monospecific plantations in relation to the P and Mg availability in the soil (Table 3) as the foliar nutrient content may reflect the nutrient availability in the soil solutions (Aerts, 1996Aerts, R. (1996). Nutrient resorption from senescing leaves of perennials: are there general patterns? The Journal of Ecology84(4), 597-608.). However, the contents of N, K and Ca in the GL presented a wide variation among the forest species (N: 16.10-23.79 g kg^-1; K: 3.17-11.33 g kg^-1; Ca: 4.99-9.35 g kg^-1), although there were no differences among some plantations in relation to the availability of these nutrients in the soil. The contents of S also varied widely in GL (0.89-2.18 g kg^-1) (Table 1). There were no differences among the plantations regarding the pH, except for the J. copaia soil, which had a higher pH than A. mangium (0-5 cm) (Table 3).

A. mangium and J. copaia presented a higher N content in both GL and SL, with similar values for each (Table 1). For J. copaia, this result may be due to the higher availability of N found in the soil (0-5 cm) than for D. odorata and P. decussata (Table 3). There were no differences between the A. mangium and the other species regarding the N availability in the soil. However, the higher content of N in A. mangium leaves was expected because this species is from the Fabaceae (Leguminosae) family, which forms symbiosis with N-fixing bacteria (Schiavo & Martins, 2003Schiavo, J. A., & Martins, M. A. (2003). Produção de mudas de acácia colonizadas com micorrizas e rizóbio em diferentes recipientes. Pesquisa Agropecuária Brasileira38(2), 173-178.). Thus, these plants have this nutritional benefit, which manifests in a higher N content in both green and senescent leaves.

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Table 1
Mean nutrient content (standard deviation) in green leaves (GL) and senescent leaves (SL) and nutrient retranslocation (NR) in Acacia mangium, Dipteryx odorata, Jacaranda copaia, Parkia decussata and Swietenia macrophylla, distributed over different ecological groups (EG), P = pioneer, NP = non-pioneer species, and phenological groups (PG), ND = non-deciduous, D = semi-deciduous / deciduous species, at Itacoatiara-AM.

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Table 2
Mean nutrient content (standard deviation) in green leaves (GL) and senescent leaves (SL) and nutrient retranslocation (NR) in forest tree species belonging to different ecological groups (EG), P = pioneer, NP = non-pioneer species, and phenological groups (PG), ND = non-deciduous, D = semideciduous / deciduous species.

Nutrient input via leaf litter influences nutrient availability in the soil; however, it depends not only on the leaf litter nutrient content but also on the litterfall amount according to Jaramillo-Botero, Santos, Fardim, Pontes and Sarmiento (2008Jaramillo-Botero, C., Santos, R. H. S., Fardim, M. P., Pontes, T. M., & Sarmiento, F. (2008). Produção de serapilheira e aporte de nutrientes de espécies arbóreas nativas em um sistema agroflorestal na zona da Mata de Minas Gerais. Revista Árvore32(5), 869-877.). These authors observed that the higher input of N to the soil occurred via the leaf litter of the non-Fabaceae Joannesia princeps Vell. and Croton floribundus Spreng. because both presented higher leaf fall; however, higher contents of N occurred in the green and senescent leaves of the Fabaceae Senna macranthera (Colladon) Irwin and Barneby. The lack of differences between the monospecific plantations of Fabaceae and non-Fabaceae species regarding N availability in the soil was also verified in northwestern Costa Rica (Gei & Powers, 2013Gei, M. G., & Powers, J. S. (2013). Do legumes and non-legumes tree species affect soil properties in unmanaged forests and plantations in Costa Rican dry forests? Soil Biology & Biochemistry57, 264-272.).

Thus, the close relationship between soil attributes and leaf nutrient content had not been found in all evaluated forest species. This result may be influenced by the internal retranslocation of nutrients, which intensifies as the nutrient availability is limiting in the soil (Aerts, 1996Aerts, R. (1996). Nutrient resorption from senescing leaves of perennials: are there general patterns? The Journal of Ecology84(4), 597-608.), and by the ability of the plants to form efficient symbiotic associations with mycorrhizal fungi and N-fixing bacteria. As previously mentioned, this may be the case with A. mangium (Tables 1 and 3). The GL of A. mangium presented high N content, whereas the GL of S. macrophylla presented high contents of both K and S compared with other forest species from another works (Table 2). The GL of J. copaia also had relatively high contents of N, P and Mg.

On the other hand, the GL results presented low N contents for P. decussata and S. macrophylla; low P contents for D. odorata, P. decussata and S. macrophylla; low K contents for A. mangium, D. odorata, J. copaia and P. decussata; low S contents for A. mangium, D. odorata and J. copaia; and low Ca and Mg contents of for all evaluated species (Table 2). The low macronutrient content in the GL of P. decussata and D. odorata indicates macronutrients to be the most limiting nutrient in the studied area. This is more evident when the species does not have high nutrient retranslocation rates, as observed with the low retranslocation of N in P. decussata. In fact, the soil under this species presented low N, K and Ca contents compared with the soil under the other forest species studied.

Nutrient retranslocation followed the decreasing order: K> P> N> Mg> S (Table 1). This pattern is very similar to the ones found by different studies in relation to 15 other tree species, which differ in only the rank of K (P> K> N> Mg> S) (Table 2). The method used to estimate nutrient retranslocation had not considered the intensively leached quantities of K, which may have influenced the first position of K among the other nutrients in relation to the retranslocation in this work. Internal retranslocation rates of N, P, and K occurred in all studied species, with high variation (N: from -16.86 to -49.25% / mean value = -34.41%; P: from -48.89 to -74.47% / mean value = -60.48%/ K: from -39.98 to -77.60% / mean value = -62.90%) (Table 1). Internal retranslocation was a function of two factors: the low availability of these nutrients in all forest plantations soils (Table 3), which is frequently observed in most tropical soils, especially for N and P (Kobe, Lepczyk, & Iyer, 2005Kobe, R. K., Lepczyk, C. A., & Iyer, M. (2005). Resorption efficiency decreases with increasing green leaf nutrients in a global data set. Ecology86(10), 2780-2792.), and the high mobility of these nutrients in plant organisms.

Considering the available results of nutrient N, P and K retranslocation, of 18 forest species, N and P were both internally redistributed in 94% of the species and K in 89% (Table 2). It is believed that the rates of N retranslocation were lower than those of P and K because of the N input in the soil-plant system by rainfall. Forti and Moreira-Nordemann (1991Forti, M. C., & Moreira-Nordemann, L. M. (1991). Rainwater and throughfall chemistry in a "Terra Firme" Rain Forest: Central Amazonia. Journal of Geophysical Research96(4), 7415-7421.) estimated that the deposition of N-NH₄⁺ via rainfall was approximately 0.15 kg ha^-1 over 40 days in the rainy season and 0.34 kg ha^-1 N over 60 days in the dry season in a Dense Upland Rain Forest in the Ducke Reserve, Brazilian Amazon.

The internal retranslocation rate of N for A. mangium was intermediate and higher than that of J. copaia and P. decussata (Table 1). Lower values for A. mangium were expected due to the association of this species with N-fixing bacteria. This pattern of low rates of N internal retranslocation occurred for Acacia mearnsii De Wild (Caldeira et al., 1999Caldeira, M. V. W., Schumacher, M. V., Pereira, J. C., Della-Flora, J. B., & Santos, E. M. (1999). Concentração e redistribuição de nutrientes nas folhas e no folhedo em um povoamento de Acacia mearnsii de Wild no Rio Grande do Sul. Ciência Florestal9(1), 19-24.), a Fabaceae species that also forms symbiosis with N-fixing bacteria (Vargas et al., 2007Vargas, L. K., Lisboa, B. B., Scholles, D., Silveira, J. R. P., Jung, G. C., Granada, C. E., ... Negreiros, T. (2007). Diversidade genética e eficiência simbiótica de rizóbios noduladores de acácia-negra de solos do Rio Grande do Sul. Revista Brasileira de Ciência do Solo 31, 647-654.). Among the species presented in Table 2 with N retranslocation results, symbiosis was also confirmed for the Fabaceae species Cedrelinga catenaeformis Ducke and Dialium guianensis (Aubl.) Sandwith. (Magalhães, Magalhães, Oliveira, & Dobereiner, 1982Magalhães, F. M. M., Magalhães, L. M. S., Oliveira, L. A., & Dobereiner, J. (1982). Ocorrência de nodulação em leguminosas florestais de terra firme nativas da região de Manaus-AM. Acta Amazonica12(3), 509-514.). No information was found regarding this aspect for the Fabaceae species Andira anthelmintica Benth. The remaining 13 species form the non-Fabaceae group. The mean rate of N retranslocation (-27.80%) for Fabaceae was close to the non-Fabaceae group (-29.05%).

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Table 3
Soil chemical attributes (0-5, 5-10, 10-30 cm)^* in monospecific plantations of Acacia mangium, Dipteryx odorata, Jacaranda copaia, Parkia decussata and Swietenia macrophylla, at Itacoatiara-AM.

According to the results in Table 2, high retranslocation rates (> general mean) of P and N, the most limiting nutrients regarding availability to plants in tropical soils, occurred in A. mangium, D. odorata and S. macrophylla. Species that have nutrient retranslocation from dead leaves to other tissues before their abscission have a higher capacity to store them in their organism, which minimize losses and results in a litterfall with low nutrient content that slowly decomposes and mineralizes (Aerts & Chapin, 2000Aerts, R., & Chapin, F. S. (2000). The mineral nutrition in wild plants revisited: a reevaluation of processes and patterns. Advances in Ecological Research30, 1-67.). Thus, the nutrient content in the green leaves of these species may be relatively higher, not reflecting the limited availability in the soil (Aerts & Chapin, 2000Aerts, R., & Chapin, F. S. (2000). The mineral nutrition in wild plants revisited: a reevaluation of processes and patterns. Advances in Ecological Research30, 1-67.). Although high retranslocation rates of P were observed in P. decussata and J. copaia, these species performed low retranslocation rates of N. Therefore, A. mangium, D. odorata and S. macrophylla may be considered more suitable for cultivation in ecosystems with edaphoclimatic conditions similar to the studied area.

Internal retranslocation of S occurred in all studied species, with a high variation (rate ranging from -2.86 to -38.02% / mean value = -16.58%), and the retranslocation of Mg occurred in A. mangium, J. copaia and P. decussata (from -2.12 to -34.29% / mean value = -1.54%). The retranslocation of Ca was observed only in P. decussata, and the rate was considered very low (inferior than 6%), which may be due to the variation in the plant nutrient absorption capability (Table 1). According to the results of Ca, Mg and S available in Table 2, the retranslocation of S was observed in 64% of the forest species, whereas the retranslocation of Mg and Ca were observed in 53 and 22% of the species, respectively. Among the macronutrients, Mg and Ca are less mobile in plant organisms due to their structural role in cementing the middle lamella of the cell wall (Larcher, 2000Larcher, W. (2000). Ecofisiologia vegetal. São Carlos, SP: RiMa Artes e Textos.; Malavolta, 2006Malavolta, E. (2006). Manual de nutrição de plantas. São Paulo, SP: Agronômica Ceres.; Almeida et al., 2014Almeida, C. X., Pita Junior, J. L., Rozane, D. E., Souza, H. A., Hernandes, A., Natale, W., & Ferraudo, A. S. (2014). Nutrient cycling in mango trees. Semina. Ciências Agrárias35(1), 259-266.).

There was a trend of a higher N content in GL (21% higher) and SL (41%) in the pioneer species than in the non-pioneer group (Table 1). The opposite pattern, higher contents in the leaves of non-pioneer species group, tended to occur for the K, Ca and S contents in GL (37; 21; 25%, respectively) and SL (60; 41; 26%, respectively). There was not a clear pattern regarding the P and Mg contents in leaves because the differences between the ecologic groups were low (less than 20%).

The general mean obtained for all of the species in Table 2, including the species evaluated in this study (39 species total: 16 pioneer species and 23 non-pioneer species), shows that the pattern of Ca and S contents in GL (56 and 36% higher in non-pioneer species) were sustained. However, the contents of K and Mg were higher in GL from pioneer species (26 and 22%, respectively), whereas the differences between the ecological groups regarding N contents were low (5%).

This divergence occurred due to the wide variation among the species from the same ecological group regarding the N content in GL (pioneer species: 11.10-25.60 g kg^-1; non-pioneer species: 11.20-31.10 g kg^-1), K (pioneer species: 2.40-22.66 g kg^-1; non-pioneer species: 3.56-16.98 g kg^-1) and Mg (pioneer species: 1.40-11.14 g kg^-1; non-pioneer species: 1.10-4.20 g kg^-1). Pioneer species commonly present a higher Mg content in green leaves than non-pioneer species (Boeger et al., 2005Boeger, M. R. T., Wisniewski, C., & Reissmann, C. B. (2005). Nutrientes foliares de espécies arbóreas de três estádios sucessionais de Floresta Ombrófila Densa no sul do Brasil. Acta Botanica Brasilica19(1), 167-181.) because they have higher photosynthetic activity due to the increased exposure to solar radiation, which increases Mg requirement, an essential element for photosynthesis (Larcher, 2000Larcher, W. (2000). Ecofisiologia vegetal. São Carlos, SP: RiMa Artes e Textos.). Moreover, species in the early stages of succession usually present larger amounts of tissue with secondary walls in the leaves, where Mg accumulates, than do plants that feature the more advanced stages of succession (Boeger & Wisniewski, 2003Boeger, M. R. T., & Wisniewski, C. (2003). Comparação da morfologia foliar de espécies arbóreas de três estádios sucessionais distintos de Floresta Ombrófila Densa (Floresta Atlântica) no Sul do Brasil. Revista Brasileira de Botânica 26(1), 61-72.). P. decussata was the only pioneer species that did not fit this pattern.

The species evaluated in an Atlantic Forest fragment in the advanced stage of regeneration presented higher foliar contents of N, P and K, whereas no differences were found among the species present in three different successional stages regarding the Ca content in green leaves, according to Boeger, Wisniewski and Reissmann (2005Boeger, M. R. T., Wisniewski, C., & Reissmann, C. B. (2005). Nutrientes foliares de espécies arbóreas de três estádios sucessionais de Floresta Ombrófila Densa no sul do Brasil. Acta Botanica Brasilica19(1), 167-181.). These authors argued that this result was probably a reflection of the gradual increase of the litter layer thickness throughout the forest regeneration development, which was responsible for the increases in soil nutrients. However, comparing that study to the species in Table 2 has limitations because in that study some groups of pioneer and non-pioneer species occurred in two or three different successional stages, and the nutrient contents were calculated as a general mean for all species in the forest fragments.

The values of the P retranslocation rates were similar between the groups of pioneer and non-pioneer species studied (Table 1). However, non-pioneer species did not retranslocate Mg and had higher rates of N retranslocation, whereas pioneer species retranslocated Mg and had higher rates of K and S retranslocation. There was no retranslocation of Ca in any ecological groups. A global analysis including the studied species and species from other studies showed that the rates of K, S, P and N internal retranslocation was 69, 48, 30 and 24% higher in pioneer species, which also retranslocated Mg, whereas non-pioneer species did not retranslocate this nutrient (Table 2).

Nutrient retranslocation is a function of the continuous growth of new tissues (Fife & Nambiar, 1997Fife, D. N., & Nambiar, E. K. S. (1997). Changes in the canopy and growth of Pinus radiata in response to nitrogen supply. Forest Ecology and Management93, 137-152.) and their higher metabolic transpiration (Malavolta, 2006Malavolta, E. (2006). Manual de nutrição de plantas. São Paulo, SP: Agronômica Ceres.). The slow-growing non-pioneer species absorb the soil nutrients more slowly, which minimizes the nutritional depletion of soils (Chapin, 1980Chapin, F. S. (1980). The mineral nutrition of wild plants. Annual Review of Ecology and Systematics11, 233-260.). Therefore, it is believed that non-pioneer species, which have a slow growth rate compared with that of the pioneer species, would probably be more suited to low-fertility soils. When the soil nutrient availability is insufficient for plant growth, such elements are mobilized from the senescent leaves to growing regions such as meristems and young leaves to supply the demand for continuous growth (Chapin, 1980Chapin, F. S. (1980). The mineral nutrition of wild plants. Annual Review of Ecology and Systematics11, 233-260.). Thus, under the same edaphic condition of low fertility, the rates of internal nutrient retranslocation are higher in pioneer than in non-pioneer species.

In this work, the differences between phenological groups were low (less than 20%) regarding the contents of N, Ca, Mg and S in GL and SL and the contents of P in GL (Table 1). On the other hand, the deciduous species tended to present a higher K content in GL (29% higher) and SL (51%) and a higher P content in SL (33%), than the non-deciduous species. Considering the results in Table 2 (a total of 39 species which accounted by 26 evergreen and 13 deciduous, including the species in this work), the differences between the phenological groups regarding contents of N, P, K and S in both GL and SL, and Mg in SL were low (less than 20%). However, contents of Ca were 20% higher in GL of deciduous species, whereas contents of Mg 23% higher in GL of non-deciduous species.

According to some authors, non-deciduous plants usually present lower foliar macronutrient contents than deciduous species (Aerts, 1996Aerts, R. (1996). Nutrient resorption from senescing leaves of perennials: are there general patterns? The Journal of Ecology84(4), 597-608.; Aerts & Chapin, 2000Aerts, R., & Chapin, F. S. (2000). The mineral nutrition in wild plants revisited: a reevaluation of processes and patterns. Advances in Ecological Research30, 1-67.; Franco et al., 2005Franco, A. C., Bustamante, M., Caldas, L. S., Goldstein, G., Meinzer, F. C., Kozovits, A. R., Coradin, V. T. R. (2005). Leaf functional traits of Neotropical savanna trees in relation to seasonal water deficit. Trees19, 326-335.). This is a consequence of some strategies that minimize the nutritional demand and increase nutrient conservation by non-deciduous species, such as low growth rates and higher leaf longevity, allowing them to colonize low-fertility soils (Chapin, 1980Chapin, F. S. (1980). The mineral nutrition of wild plants. Annual Review of Ecology and Systematics11, 233-260.; Araújo & Haridasan, 2007Araújo, J. F., & Haridasan, H. (2007). Relação entre deciduidade e concentrações foliares de nutrientes em espécies lenhosas do cerrado. Revista Brasileira de Botânica30(3), 533-542.). However, this pattern is not a definite rule because a global analysis of the data from 92 studies conducted in different ecosystems indicated that there are no significant differences between deciduous and non-deciduous species regarding the N and P contents in green and senescent leaves (Kobe et al., 2005Kobe, R. K., Lepczyk, C. A., & Iyer, M. (2005). Resorption efficiency decreases with increasing green leaf nutrients in a global data set. Ecology86(10), 2780-2792.). This result may be expected due to the influence of different factors, such as variations even between species from the same phenological group (Wright & Westoby, 2003Wright, I. J., & Westoby, M. (2003). Nutrient concentration, resorption and lifespan: leaf traits of Australian sclerophyll species. Functional, Ecology17, 10-19.), phylogeny (plant family) (Villar, Robleto, Jong, & Poorter, 2006Villar, R., Robleto, J. R., Jong, Y., & Poorter, H. (2006). Differences in construction costs and chemical composition between deciduous and evergreen woody species are small as compared to differences among families. Plant, Cell and Environment29, 1629-1643.) and environment conditions (Franco et al., 2005Franco, A. C., Bustamante, M., Caldas, L. S., Goldstein, G., Meinzer, F. C., Kozovits, A. R., Coradin, V. T. R. (2005). Leaf functional traits of Neotropical savanna trees in relation to seasonal water deficit. Trees19, 326-335.; Araújo & Haridasan, 2007Araújo, J. F., & Haridasan, H. (2007). Relação entre deciduidade e concentrações foliares de nutrientes em espécies lenhosas do cerrado. Revista Brasileira de Botânica30(3), 533-542.).

This work demonstrated that non-deciduous species presented higher retranslocation rates of P and K and performed Mg retranslocation, whereas deciduous species did not retranslocate Mg, and the retranslocation rates of N and S were virtually identical to those of the non-deciduous species, because the differences between the phenological groups were less than 20% (Table 1). As expected, there was no evidence of Ca retranslocation in any of the phenological groups.

High rates of transpiration may increase nutrient absorption and retranslocation (Kerbauy, 2004Kerbauy, G. B. (2004). Fisiologia vegetal. Rio de Janeiro, RJ: Guanabara Koogan.). In Amazonia, the average precipitation and temperature are high. Thus, the leaf abscission performed by the deciduous species to avoid high rates of transpiration in higher temperature periods probably influenced the lower foliar retranslocation of the mobile nutrients P and K. This is the reason why deciduous plants generally present higher nutrients contents in senescent leaves (Aerts & Chapin, 2000Aerts, R., & Chapin, F. S. (2000). The mineral nutrition in wild plants revisited: a reevaluation of processes and patterns. Advances in Ecological Research30, 1-67.; Franco et al., 2005Franco, A. C., Bustamante, M., Caldas, L. S., Goldstein, G., Meinzer, F. C., Kozovits, A. R., Coradin, V. T. R. (2005). Leaf functional traits of Neotropical savanna trees in relation to seasonal water deficit. Trees19, 326-335.; Araújo & Haridasan, 2007Araújo, J. F., & Haridasan, H. (2007). Relação entre deciduidade e concentrações foliares de nutrientes em espécies lenhosas do cerrado. Revista Brasileira de Botânica30(3), 533-542.). A global analysis of all species in Table 2 indicated that higher rates of N retranslocation occurred for the non-deciduous species (22% higher), whereas the higher rates of S and K retranslocation were observed for the deciduous species (94 and 44% higher, respectively). The rates of both P and Mg retranslocation were virtually identical between the phenological groups (differences < 20%). Although the non-deciduous species presented lower contents of some nutrients in senescent leaves, this fact does not necessarily indicate that these species perform a more efficient nutrient retranslocation than the deciduous species because this ability depends more on the species (Aerts, 1996).

Conclusion

Pioneer species presented higher foliar contents of N, whereas higher foliar contents of K, Ca and S were found in the non-pioneer species. The differences between the ecological groups regarding P and Mg contents were low.

Deciduous species presented higher foliar contents of K and P, although the foliar contents of N, Ca, Mg and S were virtually identical between the phenological groups.

The retranslocation of foliar nutrients in pioneer and non-deciduous species was higher than in non-pioneer and deciduous species.

References

Aerts, R. (1996). Nutrient resorption from senescing leaves of perennials: are there general patterns? The Journal of Ecology84(4), 597-608.
Aerts, R., & Chapin, F. S. (2000). The mineral nutrition in wild plants revisited: a reevaluation of processes and patterns. Advances in Ecological Research30, 1-67.
Almeida, C. X., Pita Junior, J. L., Rozane, D. E., Souza, H. A., Hernandes, A., Natale, W., & Ferraudo, A. S. (2014). Nutrient cycling in mango trees. Semina. Ciências Agrárias35(1), 259-266.
Araújo, J. F., & Haridasan, H. (2007). Relação entre deciduidade e concentrações foliares de nutrientes em espécies lenhosas do cerrado. Revista Brasileira de Botânica30(3), 533-542.
Attiwill, P. M., Guthrie, H. B., & Leuning, R. (1978). Nutrient cycling in a Eucalyptus oblique (L' Herit) forest. Australian Journal of Botany26(1), 79-91.
Bambi, P., Lobo, F. A., Dalmolin, A. C., & Dias, C. A. A. (2011). Decomposição e redistribuição de nutrientes das folhas de espécies da floresta de transição Amazônia - Cerrado, MT. Ciência e Natura33(1), 17-31.
Boeger, M. R. T., & Wisniewski, C. (2003). Comparação da morfologia foliar de espécies arbóreas de três estádios sucessionais distintos de Floresta Ombrófila Densa (Floresta Atlântica) no Sul do Brasil. Revista Brasileira de Botânica 26(1), 61-72.
Boeger, M. R. T., Wisniewski, C., & Reissmann, C. B. (2005). Nutrientes foliares de espécies arbóreas de três estádios sucessionais de Floresta Ombrófila Densa no sul do Brasil. Acta Botanica Brasilica19(1), 167-181.
Caldeira, M. V. W., Schumacher, M. V., Pereira, J. C., Della-Flora, J. B., & Santos, E. M. (1999). Concentração e redistribuição de nutrientes nas folhas e no folhedo em um povoamento de Acacia mearnsii de Wild no Rio Grande do Sul. Ciência Florestal9(1), 19-24.
Chapin, F. S. (1980). The mineral nutrition of wild plants. Annual Review of Ecology and Systematics11, 233-260.
Cunha, G. M., Gama-Rodrigues, A. C., Gama-Rodrigues, E. F., & Velloso, A. C. X. (2009). Biomassa e estoque de carbono e nutrientes em Florestas Montanas da Mata Atlântica na região norte do Estado do Rio de Janeiro. Revista Brasileira de Ciência do Solo33, 1175-1185.
Empresa Brasileira de Pesquisa Agropecuária. (2009). Manual de análises químicas de solos, plantas e fertilizantes (2a ed.). Brasília, DF: Embrapa Informação Tecnológica.
Espig, S. A., Freire, F. J., Marangon, L. C., Ferreira, R. L. C., Freire, M. B. G. S., & Espig, D. B. (2008). Composição e eficiência da utilização biológica de nutrientes em fragmento de Mata Atlântica em Pernambuco. Ciência Florestal 18(3), 309-316.
Fife, D. N., & Nambiar, E. K. S. (1997). Changes in the canopy and growth of Pinus radiata in response to nitrogen supply. Forest Ecology and Management93, 137-152.
Forti, M. C., & Moreira-Nordemann, L. M. (1991). Rainwater and throughfall chemistry in a "Terra Firme" Rain Forest: Central Amazonia. Journal of Geophysical Research96(4), 7415-7421.
Franco, A. C., Bustamante, M., Caldas, L. S., Goldstein, G., Meinzer, F. C., Kozovits, A. R., Coradin, V. T. R. (2005). Leaf functional traits of Neotropical savanna trees in relation to seasonal water deficit. Trees19, 326-335.
Gei, M. G., & Powers, J. S. (2013). Do legumes and non-legumes tree species affect soil properties in unmanaged forests and plantations in Costa Rican dry forests? Soil Biology & Biochemistry57, 264-272.
Jaramillo-Botero, C., Santos, R. H. S., Fardim, M. P., Pontes, T. M., & Sarmiento, F. (2008). Produção de serapilheira e aporte de nutrientes de espécies arbóreas nativas em um sistema agroflorestal na zona da Mata de Minas Gerais. Revista Árvore32(5), 869-877.
Kerbauy, G. B. (2004). Fisiologia vegetal. Rio de Janeiro, RJ: Guanabara Koogan.
Kobe, R. K., Lepczyk, C. A., & Iyer, M. (2005). Resorption efficiency decreases with increasing green leaf nutrients in a global data set. Ecology86(10), 2780-2792.
Köppen, W. (1948). Climatologia: con un estudio de los climas de La tierra. México, MX: Fondo de Cultura Econômica.
Larcher, W. (2000). Ecofisiologia vegetal. São Carlos, SP: RiMa Artes e Textos.
Magalhães, F. M. M., Magalhães, L. M. S., Oliveira, L. A., & Dobereiner, J. (1982). Ocorrência de nodulação em leguminosas florestais de terra firme nativas da região de Manaus-AM. Acta Amazonica12(3), 509-514.
Magalhães, L. M. S., & Blum, W. E. H. (1999). Concentração e distribuição de nutrientes nas folhas de espécies florestais, na Amazônia Ocidental. Floresta e Ambiente6(1), 127-137.
Malavolta, E. (2006). Manual de nutrição de plantas. São Paulo, SP: Agronômica Ceres.
Pinto, S. I. C., Martins, S. V., Barros, N. F., & Dias, H. C. T. (2009). Ciclagem de nutrientes em dois trechos de Floresta Estacional Semidecidual na Reserva Florestal Mata do Paraíso em Viçosa, MG, Brasil. Revista Árvore 33(4), 653-663.
Protil, C. Z., Marques, R., & Protil, R. M. (2009). Variação sazonal e redistribuição de bioelementos de quatro espécies arbóreas em três tipologias florestais da Floresta Atlântica do Paraná. Floresta39(3), 699-717.
Schiavo, J. A., & Martins, M. A. (2003). Produção de mudas de acácia colonizadas com micorrizas e rizóbio em diferentes recipientes. Pesquisa Agropecuária Brasileira38(2), 173-178.
Tedesco, M. J., Gianello, C., Bissani, C. A., Bohnen, H., & Volkweiss, S. J. (1995). Análise de solo, plantas e outros materiais (2a ed.). Porto Alegre, RS: UFRGS.
Vargas, L. K., Lisboa, B. B., Scholles, D., Silveira, J. R. P., Jung, G. C., Granada, C. E., ... Negreiros, T. (2007). Diversidade genética e eficiência simbiótica de rizóbios noduladores de acácia-negra de solos do Rio Grande do Sul. Revista Brasileira de Ciência do Solo 31, 647-654.
Veloso, H. P., Rangel Filho, A. L. R., & Lima, J. C. A. (1991). Classificação da vegetação brasileira adaptada a um sistema universal. Rio de Janeiro, RJ: IBGE.
Viera, M., & Schumacher, M. V. (2009). Concentração e retranslocação de nutrientes em acículas de Pinus taeda L. Ciência Florestal 19(4), 375-382.
Villar, R., Robleto, J. R., Jong, Y., & Poorter, H. (2006). Differences in construction costs and chemical composition between deciduous and evergreen woody species are small as compared to differences among families. Plant, Cell and Environment29, 1629-1643.
Wright, I. J., & Westoby, M. (2003). Nutrient concentration, resorption and lifespan: leaf traits of Australian sclerophyll species. Functional, Ecology17, 10-19.

Publication Dates

Publication in this collection
Mar 2016

History

Received
24 Feb 2015
Accepted
11 June 2015

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

[1] Aerts, R. (1996). Nutrient resorption from senescing leaves of perennials: are there general patterns? The Journal of Ecology84(4), 597-608.

[2] Aerts, R., & Chapin, F. S. (2000). The mineral nutrition in wild plants revisited: a reevaluation of processes and patterns. Advances in Ecological Research30, 1-67.

[3] Almeida, C. X., Pita Junior, J. L., Rozane, D. E., Souza, H. A., Hernandes, A., Natale, W., & Ferraudo, A. S. (2014). Nutrient cycling in mango trees. Semina. Ciências Agrárias35(1), 259-266.

[4] Araújo, J. F., & Haridasan, H. (2007). Relação entre deciduidade e concentrações foliares de nutrientes em espécies lenhosas do cerrado. Revista Brasileira de Botânica30(3), 533-542.

[5] Attiwill, P. M., Guthrie, H. B., & Leuning, R. (1978). Nutrient cycling in a Eucalyptus oblique (L' Herit) forest. Australian Journal of Botany26(1), 79-91.

[6] Bambi, P., Lobo, F. A., Dalmolin, A. C., & Dias, C. A. A. (2011). Decomposição e redistribuição de nutrientes das folhas de espécies da floresta de transição Amazônia - Cerrado, MT. Ciência e Natura33(1), 17-31.

[7] Boeger, M. R. T., & Wisniewski, C. (2003). Comparação da morfologia foliar de espécies arbóreas de três estádios sucessionais distintos de Floresta Ombrófila Densa (Floresta Atlântica) no Sul do Brasil. Revista Brasileira de Botânica 26(1), 61-72.

[8] Boeger, M. R. T., Wisniewski, C., & Reissmann, C. B. (2005). Nutrientes foliares de espécies arbóreas de três estádios sucessionais de Floresta Ombrófila Densa no sul do Brasil. Acta Botanica Brasilica19(1), 167-181.

[9] Caldeira, M. V. W., Schumacher, M. V., Pereira, J. C., Della-Flora, J. B., & Santos, E. M. (1999). Concentração e redistribuição de nutrientes nas folhas e no folhedo em um povoamento de Acacia mearnsii de Wild no Rio Grande do Sul. Ciência Florestal9(1), 19-24.

[10] Chapin, F. S. (1980). The mineral nutrition of wild plants. Annual Review of Ecology and Systematics11, 233-260.

[11] Cunha, G. M., Gama-Rodrigues, A. C., Gama-Rodrigues, E. F., & Velloso, A. C. X. (2009). Biomassa e estoque de carbono e nutrientes em Florestas Montanas da Mata Atlântica na região norte do Estado do Rio de Janeiro. Revista Brasileira de Ciência do Solo33, 1175-1185.

[12] Empresa Brasileira de Pesquisa Agropecuária. (2009). Manual de análises químicas de solos, plantas e fertilizantes (2a ed.). Brasília, DF: Embrapa Informação Tecnológica.

[13] Espig, S. A., Freire, F. J., Marangon, L. C., Ferreira, R. L. C., Freire, M. B. G. S., & Espig, D. B. (2008). Composição e eficiência da utilização biológica de nutrientes em fragmento de Mata Atlântica em Pernambuco. Ciência Florestal 18(3), 309-316.

[14] Fife, D. N., & Nambiar, E. K. S. (1997). Changes in the canopy and growth of Pinus radiata in response to nitrogen supply. Forest Ecology and Management93, 137-152.

[15] Forti, M. C., & Moreira-Nordemann, L. M. (1991). Rainwater and throughfall chemistry in a "Terra Firme" Rain Forest: Central Amazonia. Journal of Geophysical Research96(4), 7415-7421.

[16] Franco, A. C., Bustamante, M., Caldas, L. S., Goldstein, G., Meinzer, F. C., Kozovits, A. R., Coradin, V. T. R. (2005). Leaf functional traits of Neotropical savanna trees in relation to seasonal water deficit. Trees19, 326-335.

[17] Gei, M. G., & Powers, J. S. (2013). Do legumes and non-legumes tree species affect soil properties in unmanaged forests and plantations in Costa Rican dry forests? Soil Biology & Biochemistry57, 264-272.

[18] Jaramillo-Botero, C., Santos, R. H. S., Fardim, M. P., Pontes, T. M., & Sarmiento, F. (2008). Produção de serapilheira e aporte de nutrientes de espécies arbóreas nativas em um sistema agroflorestal na zona da Mata de Minas Gerais. Revista Árvore32(5), 869-877.

[19] Kerbauy, G. B. (2004). Fisiologia vegetal. Rio de Janeiro, RJ: Guanabara Koogan.

[20] Kobe, R. K., Lepczyk, C. A., & Iyer, M. (2005). Resorption efficiency decreases with increasing green leaf nutrients in a global data set. Ecology86(10), 2780-2792.

[21] Köppen, W. (1948). Climatologia: con un estudio de los climas de La tierra. México, MX: Fondo de Cultura Econômica.

[22] Larcher, W. (2000). Ecofisiologia vegetal. São Carlos, SP: RiMa Artes e Textos.

[23] Magalhães, F. M. M., Magalhães, L. M. S., Oliveira, L. A., & Dobereiner, J. (1982). Ocorrência de nodulação em leguminosas florestais de terra firme nativas da região de Manaus-AM. Acta Amazonica12(3), 509-514.

[24] Magalhães, L. M. S., & Blum, W. E. H. (1999). Concentração e distribuição de nutrientes nas folhas de espécies florestais, na Amazônia Ocidental. Floresta e Ambiente6(1), 127-137.

[25] Malavolta, E. (2006). Manual de nutrição de plantas. São Paulo, SP: Agronômica Ceres.

[26] Pinto, S. I. C., Martins, S. V., Barros, N. F., & Dias, H. C. T. (2009). Ciclagem de nutrientes em dois trechos de Floresta Estacional Semidecidual na Reserva Florestal Mata do Paraíso em Viçosa, MG, Brasil. Revista Árvore 33(4), 653-663.

[27] Protil, C. Z., Marques, R., & Protil, R. M. (2009). Variação sazonal e redistribuição de bioelementos de quatro espécies arbóreas em três tipologias florestais da Floresta Atlântica do Paraná. Floresta39(3), 699-717.

[28] Schiavo, J. A., & Martins, M. A. (2003). Produção de mudas de acácia colonizadas com micorrizas e rizóbio em diferentes recipientes. Pesquisa Agropecuária Brasileira38(2), 173-178.

[29] Tedesco, M. J., Gianello, C., Bissani, C. A., Bohnen, H., & Volkweiss, S. J. (1995). Análise de solo, plantas e outros materiais (2a ed.). Porto Alegre, RS: UFRGS.

[30] Vargas, L. K., Lisboa, B. B., Scholles, D., Silveira, J. R. P., Jung, G. C., Granada, C. E., ... Negreiros, T. (2007). Diversidade genética e eficiência simbiótica de rizóbios noduladores de acácia-negra de solos do Rio Grande do Sul. Revista Brasileira de Ciência do Solo 31, 647-654.

[31] Veloso, H. P., Rangel Filho, A. L. R., & Lima, J. C. A. (1991). Classificação da vegetação brasileira adaptada a um sistema universal. Rio de Janeiro, RJ: IBGE.

[32] Viera, M., & Schumacher, M. V. (2009). Concentração e retranslocação de nutrientes em acículas de Pinus taeda L. Ciência Florestal 19(4), 375-382.

[33] Villar, R., Robleto, J. R., Jong, Y., & Poorter, H. (2006). Differences in construction costs and chemical composition between deciduous and evergreen woody species are small as compared to differences among families. Plant, Cell and Environment29, 1629-1643.

[34] Wright, I. J., & Westoby, M. (2003). Nutrient concentration, resorption and lifespan: leaf traits of Australian sclerophyll species. Functional, Ecology17, 10-19.

Brasil

Brasil

Nutrient retranslocation in forest species in the Brazilian Amazon

Retranslocação de nutrientes em espécies florestais na Amazônia Brasileira

ABSTRACT.

RESUMO.

Introduction

Material and methods

Results and discussion

Conclusion

References

Publication Dates

History