Physiological and morphological responses of seedlings of <i>Guazuma ulmifolia</i> (Malvaceae) grown under phosphorus levels

Silva, Patrícia Oliveira da; Costa, Andreia Mendes da; Silva, Adinan Alves da; Rodrigues, Carlos Ribeiro; Carlos, Leandro

doi:10.1590/2175-7860202273102

Abstract

Phosphorus (P) is one of the nutrients most required by plants, especially in the initial phase, however, there are species whose growth effects promoted by phosphorus are still unknown. Therefore, this study aimed to test whether increasing levels of phosphorus influence the physiological and morphological behavior and the quality of seedlings of Guazuma ulmifolia. For that purpose, the seedlings were grown in a substrate produced only with Dystrophic RED LATOSOL (Oxisol) under a completely randomized design and subjected to five levels of phosphorus (0, 100, 200, 300, and 400 mg dm-3 ). At 120 days, the biometric and physiological evaluations were performed, and the chlorophyll indices, biomass, allometric relationships, Dickson Quality Index, and the phosphorus content were determined. The data were subjected to analysis of variance by the F-test and subsequently to regression analysis and Pearson’s linear correlation. Phosphorus fertilization promoted significant gains (p ? 0.05) for all variables morphological e physiological, except for the specific leaf area and allometric relationships. The phosphorus content was positively correlated with all tested variables. Based on the results obtained, it is concluded that the seedlings responded positively to phosphorus fertilization. Furthermore, phosphorus fertilization promoted better physiological and morphological performance and higher seedling quality.

Keywords:
fertilizer; mutambo ; phosphorus; specie

Resumo

O fósforo (P) é um dos nutrientes mais exigidos pelas plantas, principalmente, na fase inicial, no entanto, existem espécies cujos efeitos de crescimento promovidos pelo fósforo ainda são desconhecidos. Portanto, este trabalho teve como objetivo testar se níveis crescentes de fósforo influenciam no comportamento fisiológico e morfológico e na qualidade das mudas de Guazuma ulmifolia. Para tanto, as mudas foram cultivadas em substrato produzido apenas com LATOSSOLO VERMELHO distrófico, em delineamento inteiramente casualizado e submetido a cinco níveis de fósforo (0, 100, 200, 300 e 400 mg dm-3 ). Aos 120 dias, as avaliações biométricas e fisiológicas foram realizadas, e os índices de clorofila, biomassa, relações alométricas, Índice de Qualidade de Dickson e o teor de fósforo foram determinados. Os dados foram submetidos à análise de variância pelo teste F e posteriormente à análise de regressão e correlação linear de Pearson. A fertilização com fósforo promoveu ganhos significativos (p ? 0,05) à todas as variáveis morfológicas e fisiológicas, exceto para a área foliar específica e relações alométricas. O conteúdo de fósforo foi positivamente correlacionado com todas as variáveis testadas. Com base nos resultados obtidos, conclui-se que as mudas responderam positivamente à fertilização com fósforo. Além disso, a fertilização com fósforo promoveu melhor desempenho fisiológico e morfológico e maior qualidade das mudas.

Palavras-chave:
fertilizante; mutamba; fósforo; espécies

Introduction

The production of quality seedlings is related to a series of factors, among which fertilization is one of the most important since it is performed to promote plant nutrition: when appropriate and balanced, it provides higher plant growth and development (Natale et al. 2018Natale W, Lima Neto AJ, Rozane DE, Parent LE & Corrêa MCM (2018) Mineral nutrition evolution in the formation of fruit tree rootstocks and seedlings. Revista Brasileira de Fruticultura 40: 1-15.). Among mineral fertilizations, phosphorus fertilization is extremely important as it relates to vital plant processes, such as photosynthesis and respiration. Furthermore, phosphorus (P) is a constituent of nucleic acids, phospholipids, proteins, phosphate esters, and adenosine triphosphate (Dechen & Nachtigall 2007Dechen AR & Nachtigall GR (2007) Elementos necessários para nutrição de plantas. In: Novais RF, Alvarez VVH, Barros NF, Fontes RLF, Cantarutti RB & Neves JCL (eds.) Fertilidade do solo. Sociedade Brasileira de Ciência do Solo, Viçosa. Pp. 91-132.). Therefore, P participates directly in several plant physiological processes and provides energy to trigger several cellular metabolic processes. Thus, this nutrient is essential in plant growth and development (Malhotra et al. 2018Malhotra H, Vandana SS & Pandey R (2018) Phosphorus nutrition: plant growth in response to deficiency and excess. In: Hasanuzzaman M, Fujita M, Oku H, Nahar K & Hawrylak-Nowak B (eds.) Plant nutrients and abiotic stress tolerance. Springer, Singapore. Pp. 171-190.), especially in the early development stage.

P is one of the nutrients that deserve attention in seedling production, not only for the role it plays in plants but also for the low availability of this element in the soil under natural conditions (Silva et al. 2018Silva OMC, Santana LS & Macedo RLG (2018) Influência da adubação mineral no desenvolvimento inicial de Schinus terebinthifolius Raddi. Agrarian Academy 5: 112-120.). This occurs because the soils of tropical regions are naturally acid and highly weathered. Soils with these characteristics show high P adsorption capacity, which results in the low availability of this nutrient to plants (Guedes et al. 2016Guedes RS, Melo LCA, Vergütz L, Rodríguez-Vila A, Covelo EF & Fernandes AR (2016) Adsorption and desorption kinetics and phosphorus hysteresis in highly weathered soil by stirred flow chambre experiments. Soil & Tillage Research 162: 46-54.). Considering that this condition compromises the initial growth of plants, since many still die in the juvenile stage and because they do not reach the adult stage, this interferes with seed dispersal and natural production of new individuals, thus affecting the distribution of the species. It is essential to understand how P availability affects the morphological and physiological performance of seedlings of forest species, as this can help in their preservation, preventing possible future extinctions.

In view of the previous considerations, several studies aimed to evaluate the effects of P fertilization on the production of seedlings of numerous species. The results obtained vary as the plants have distinct needs and also variable quality standards. However, in general, P fertilization has promoted positive effects on the early growth of many species (Freitas et al. 2017aFreitas ECS, Paiva HN, Leite HGON & Silvio N (2017a) Effect of phosphate fertilization and base saturation of substrate on the seedling’s growth and quality of Plathymenia foliolosa Benth. Revista Árvore 41: 1-9.; Andrade et al. 2018Andrade RHM, Freitas ECS, Paiva HN & Medeiros RA (2018) Adubação fosfatada na produção de mudas de Cassia ferruginea e Cassia grandis. Nucleus 15: 41-50.; Moreira et al. 2018Moreira RCL, Brito MEB, Fernandes PD, Sá FVAS, Silva LA, Oliveira CJA, Veloso LLSA & Queiroga TB (2018) Growth and physiology of Annona squamosa L. under different irrigation depths and phosphate fertilization. Bioscience Journal 35: 389-397.; Santos et al. 2019Santos PAR, Freitas ECS & Paiva HN (2019) Growth and quality of Leucochloron incuriale seedlings subjected to liming and phosphorus. Floresta e Ambiente 26: 1-9.). Although P fertilization benefits are widely publicized, there are still no studies of this nature for some species of food and medicinal importance, such as Guazuma ulmifolia Lam. (Malvaceae), commonly known in Brazil as mutambo.

Guazuma ulmifolia is widely distributed throughout Mexico, Central, and South America, and in the Brazilian territory, it occurs in all phytogeographic domains (Colli-Silva 2019Colli-Silva M (2019) Guazuma in Flora do Brasil 2020 (continuously updated) Jardim botânico do Rio de Janeiro. Available at Available at <http://reflora.jbrj.gov.br/reflora/floradobrasil/FB9065> . Access on 7 August 2019.
http://reflora.jbrj.gov.br/reflora/flora... ). In medicinal terms, the bark extract is antimicrobial, antioxidant, and cardioprotective (Santos et al. 2018bSantos JM, Alfredo TM, Antunes KA, Cunha JSM, Costa EMA, Lima ES, Silva DB, Carollo CA, Schmitz WO, Boleti APA, Santos EL & Souza KP (2018b) Guazuma ulmifolia Lam. Decreases oxidative stress in blood cells and prevents doxorubicin-induced cardiotoxicity. Oxidative Medicine and Cellular Longevity 2018: 1-16.). The plant also shows activity against parasites such as Leishmania brasiliensis, L. infantum, and Trypanosoma cruzi (Calixto Júnior et al. 2016Calixto Júnior JT, Moraes SM, Gomez CV, Molas CC, Rolon M, Boligon AA, Athayde ML, Morais Oliveira CD, Tintino SR, Henrique D & Coutinho M (2016) Phenolic composition and antiparasitic activity of plants from the Brazilian Northeast ‘‘Cerrado”. Saudi Journal of Biological Sciences 23: 434-440.). The tea or juice of the leaves of G. ulmifolia has been indicated by several doctors in Brazil and Venezuela as an alternative treatment for HIV patients (Gouveia 2018Gouveia PAR (2018) Therapeutic use extract of Guazuma ulmifolia Lam of Northern Brazil. Journal of Microbiology & Infectious Diseases 2: 1-8.; Folha de São Paulo 2018Folha de São Paulo (2018). Portadores de HIV da Venezuela recorrem a folhas de árvore por falta de antirretrovirais. Folha de S. Paulo, São Paulo, 13 dez. 2018. Available at <https://agenciaaids.com.br/noticia/portadores-de-hiv-da-venezuela-recorrem-a-folhas-de-arvore-por-falta-de-antirretrovirais/>. Access on 12 February 2020.
https://agenciaaids.com.br/noticia/porta... ; Singer 2018Singer F (2018)Acondenação à morte dos pacientes deAids na Venezuela. El Pais, Madrid, 07 set. 2018. Available at <Available at <https://brasil.elpais.com/brasil/2018/09/06/internacional/1536258399_684413.html >. Access on 9 February 2020.
https://brasil.elpais.com/brasil/2018/09... ; Macedo 2019Macedo L (2019) Falta de exames, tratamento irregular, “remédio caseiro”: venezuelanos com HIV contam como enfrentam crise em seu país. G1, [s. l.], 23 maio 2019. Availabe at < Availabe at <https://g1.globo.com/mundo/noticia/2019/05/23/falta-de-exames-tratamento-irregular-e-remedio-caseiro-portadores-de-hiv-contam-como-enfrentam-a-crise-na-venezuela.ghtml >. Access on 12 February 2020.
https://g1.globo.com/mundo/noticia/2019/... ). The fruits are consumed by birds and primates (Carvalho 2007Carvalho PER (2007) Mutamba (Guazuma ulmifolia), Taxonomia e nomenclatura. Circular técnica EMBRAPA. Colombo, Paraná. Pp. 1-13.), highlighting their importance for reforestation programs (Calzavara et al. 2017Calzavara AK, Rocha JS, Lourenço G, Sanada K, Medri C, Bianchini E, Pimenta JA, Stolf-Moreira R & Oliveira HC (2017) Acclimation responses to high light by Guazuma ulmifolia Lam. (Malvaceae) leaves at different stages of development. Plant Biology 19: 720-727.), and can also be consumed by humans due to their high dietary fiber content and bioactive phenolic compounds (Pereira et al. 2020Pereira GA, Arruda HS, Morais DR, Araújo NMP & Pastore GM (2020) Mutamba (Guazuma ulmifolia Lam.) fruit as a novel source of dietary fibre and phenolic compounds. Food Chemistry 310: 1-35.).

As seen above, the species has the potential for wide exploitation by the industrial sector, either as food or as a therapeutic plant (Pereira et al. 2019Pereira GA, Araújo NMP, Arruda HS, Farias DF, Molina G & Pastore GM (2019) Phytochemicals and biological activities of mutamba (Guazuma ulmifolia Lam.): a review. Food Research International 126: 1-53.). However, silvicultural studies for this species are still scarce. Therefore, this study aimed to evaluate the growth and development of seedlings of G. ulmifolia produced with different levels of P to test the hypothesis that the seedlings of G. ulmifolia, when produced with P fertilization, show better physiological and morphological performance and, as a consequence, higher quality.

Material and Methods

Study area and growing conditions

The present study was conducted in a plant nursery of the Goiano Federal Institute - Campus Rio Verde, municipality of Rio Verde, Goiás, Brazil, under a completely randomized design composed of five treatments (0, 100, 200, 300, and 400 mg dm-3 of P) and four replications. The soil used as substrate was a dystrophic RED LATOSOL (Oxisol) (Santos et al. 2018aSantos HG, Jacomine PKT, Anjos LHC, Oliveira VA, Lumbreras JF, Coelho MR, Almeida JÁ, Araújo Filho JC, Oliveira JB & Cunha TJF (2018a) Sistema brasileiro de classificação de solos. Embrapa, Brasília. 356p.) collected at the 0.0 to 0.20 m depth layer, used for its low P content. Samples from this soil were collected and sent to the Solotech Cerrado LLC Laboratory for chemical characterization. The result of the natural conditions of the soil used in this study is shown in Table 1.

Base saturation was increased to 60% (Raij 1997Raij B van, Cantarella H, Quaggio JA & Furlani AMC (1997) Recomendações de adubação e calagem para o estado de São Paulo. Instituto Agronômico/ Fundação IAC, Campinas. 285p.) with the soil correctives Ca and Mg carbonate at a 4:1 ratio. Monoammonium phosphate (MAP) was used as a P source, and basic fertilization (mg dm-3) was applied ten days before establishing the

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Table 1
Chemical and physical characterization of the natural soil used as substrate for the production of seedlings of Guazuma ulmifolia Lam. (Malvaceae).

treatments. Basic fertilization is generally applied so that the absence of other nutrients does not interfere with the treatments of the one tested, in this case, those of P. Therefore, basic fertilization (mg dm-3) was performed 30 days after liming by providing 180 mg dm-3 nitrogen (N), 150 mg dm-3 potassium, 40 mg dm-3 sulfur, 1.33 mg dm-3 copper, 0.81 mg dm-3 boron, and 4 mg dm-3 zinc, using as sources: urea and ammonium sulfate, potassium sulfate and potassium chloride, copper sulfate, boric acid, and zinc sulfate, respectively (Carlos et al. 2015Carlos L, Venturin N, Farias ES, Venturin RP & Macedo RLG (2015) Growth and mineral nutrition in seedlings of Jacarandá-da-bahia subjected to nutrient deprivation. Floresta 45: 107-116.). Since the MAP has both N and P in its constitution, a balancing was performed to match the amount of N in all P treatments.

Seed collection and dormancy breaking

The seeds of G. ulmifolia were collected from ten parent plants located in the orchard of the University Federal of Lavras, municipality of Lavras, state of Minas Gerais, between August and September. Seed dormancy was overcome with hot water at 70 °C for approximately 30 minutes or until the water temperature was reduced to 50 °C (Nunes et al. 2006Nunes YRF, Fagundes L, Santos MR, Braga RF & Gonzaga APD (2006) Germinação de sementes de Guazuma ulmifolia Lam. (Malvaceae) e Heteropterys byrsonimifolia A. Juss (Malpighiaceae) sob diferentes tratamentos de escarificação tegumentar. Unimontes Cientifica 8: 43-52.). Sowing was performed in non-perforated 4-liter pots 45 days after acidity correction. Irrigation was performed daily, maintaining the substrate at 60% of field capacity by weighing the pots with the plants and directly irrigating the soil.

Biometric assessments

The biometric evaluations were performed 120 days after sowing by measuring the plant height (H) with a millimeter rule, between the stem and stem apex, while the base diameter (D) was obtained with a digital caliper. The number of fully expanded leaves (NF) was also counted.

Gas exchange assessments

At 115 days after sowing, the gas exchange analyses were performed using a portable infrared gas analyzer (Model Li-6800xt, Li- Cor, Nebraska, USA), with constant irradiance with photosynthetically active radiation (PAR) of 1.500 µmol photons m-2 s-1, atmospheric concentration of CO2 (Ca) de ~400 μmol mol-1, temperature of ~25 °C and humidity of ~50%, between 8:00 a.m. and 11 a.m., the gas exchange analyses were determined on a leaf of the second pair from the apex of the plant, by evaluating the variables: photosynthetic rate [A, µmol (CO2) m-2 s-1)], transpiration rate [E, mmol (H2O) m-2 s-1], stomatal conductance [gs, mol (H2O) m-2 s-1]. The electron transport rate (ETR, μmol m-2 s-1) was established through the fluorescence of the chlorophyll a from seedling leaves.

Chlorophyll Index

At 115 days after sowing, the photosynthetic pigments were analyzed by measuring the Falker® Chlorophyll Index (Chl a and Chl b) on the same leaf in which the gas exchange analyses were performed. A ClorofiLOG chlorophyll meter was used for this analysis (model CFL1030, Falker Automação Agrícola, Porto Alegre, BRA). The total chlorophyll index was obtained through the sum of chlorophyll a and b.

Biomass and allometric ratios

At 120 days after sowing, the seedlings were removed from the pots, cleaned, separated into leaves, stems, and roots, and dried in a forced-air oven at 65 ºC until constant weight. Finally, the material was weighed in a digital balance, thus obtaining the biomass variables: leaves dry mass (LDM), stem dry mass (SDM), and root dry mass (RDM). The sum of these three variables resulted in the total dry mass (TDM), after which the allometric relationships were also calculated: foliar mass ratio (LDM/TDM, g g-1), stem mass ratio (SDM/TDM, g g-1), and root mass ratio (RDM/TDM, g g-1).

Dickson Quality Index

The leaf area (LA) was calculated with photographic records made with Smartphone (12 megapixels) of the leaves from each experimental unit, obtained when the experiment was dismantled, using the software Image J® (HIN, Bethesda, Maryland, USA). With the LA and LDM data, it was possible to calculate the specific leaf area (SLA) through the formula: LA/LDM. Based on the growth and biomass data, it was also possible to calculate the Dickson Quality Index (DQI) (Dickson et al. 1960Dickson A, Leaf A & Hosner JF (1960) Quality appraisal of white spruce and white pine seedling stock in nurseries. Forest Chronicle 36: 10-13.), following the formula below:

\[DQI = TDM / (H/D) + (APDM/RDM)\]

TDM = total dry mass; H = height; D = diameter; APDM = aerial part dry mass; RDM = root dry mass.

P content

The shoot P content of the seedlings (leaves and stems) was determined by colorimetry following the methodology by Santos et al. (2009Santos AD, Coscione AR, Vitti AC, Boaretto AE, Coelho AM, van Raij B, Silva CA, Abru Junior CH & Carmo CAFS (2009) Manual de análises químicas de solos, plantas e fertilizantes. 2a ed. rev. ampl. Embrapa Informação Tecnológica, Brasília. 627p.), and the reading was performed by spectrophotometry.

Statistical analysis

The data obtained were tested regarding the assumptions of normality and homogeneity, and posteriorly subjected to analysis of variance (ANOVA) and when the results were significant (F test, p < 0.05) it was evaluated linear and quadratic regression analysis to verify the adjustment of the data to the models. The choice of the model occurred according to the significance of each equation and determination coefficient (R2). Such statistical analyzes were performed using software SISVAR (Ferreira 2014Ferreira DF (2014) Sisvar: a guide for its bootstrap procedures in multiple comparisons. Ciência e Agrotecnologia 38: 109-112.). Pearson’s linear correlation coefficient was calculated by involving the variables with each other, utilizing software BioEstat (Ayres et al. 2007Ayres M, Ayres JRM, Ayres DL & Santos AAS (2007) BioEstat: aplicações estatísticas nas áreas das ciências biológicas e médicas. Sociedade Civil Mamirauá, Belém. 364p.).

Results

The supply of P promoted a significant increase (p ≤ 0.05) in the shoot P content of the seedlings of G. ulmifolia. The 400 mg dm-3 level promoted the highest value among the tested levels, reaching 14 g of P kg of plant tissue (Fig. 1).

Figure 1
Phosphorus content of seedlings of Guazuma ulmifolia Lam. (Malvaceae) as a function of phosphorus levels at 120 days after sowing.

P fertilization promoted a significant effect on the chlorophyll indices of the seedlings of G. ulmifolia. The data obtained fit the quadratic model, and the 400 mg dm-3 P level promoted the highest values for these variables, reaching the indices of 31.5 for chlorophyll a, 10 for chlorophyll b, 41.5 for total chlorophylls (Fig. 2a-c). On the other hand, for chl a/chl b ratio, there was a decrease in the function of increasing doses of P, with a dose of 200 mg dm-3 being the one that promoted the highest chl a/chl b ratio; 3.72 (Fig. 2d).

The P levels significantly influenced the physiological variables. The data obtained fit the quadratic model, although, the highest level tested (400 mg dm-3) was also the one that promoted the highest values for these variables, reaching 17 and 93.5 µmol m-² s-¹ for A and ETR, respectively (Fig. 3a-d), and 0.41 mol m-² s-¹ for gs and 0.01 mmol m-² s-¹ for E (Fig. 3b-c).

The biometric variables also showed significant gains with the phosphorus levels. The highest P level tested, 400 mg dm-³, promoted the highest values, and the plants showed, on average, 49 cm height, 9 mm diameter, 22 leaves, and 800 cm2 of leaf area (Fig. 4a-d). However, for specific leaf area, P levels do not promote the difference.

The biomass variables were significantly affected by the P levels. For all biomass variables obtained, the highest values were found at the highest P level tested, 400 mg dm-3. The seedlings showed, on average, 10.5 g of LDM, 4.6 g of SDM, 35 g of RDM, and 50 g of TDM (Fig. 5a- d). However, for the allometric relationships, the treatments promoted no differences.

P fertilization promoted a significant effect on the DQI of the seedlings of G. ulmifolia. The equation that best fit was the linear model, and the highest P level tested, 400 mg dm-3, promoted the highest index, 9 (Fig. 6).

Figure 2
a-d. Falker® chlorophyll indices of seedlings of Guazuma ulmifolia Lam. (Malvaceae) as a function of phosphorus levels at 115 days after sowing - a.chlorophyll a; b.chlorophyll b; c.total of chlorophylls; d. ratio between chlorophyll a and b.

Figure 3
a-d. Physiological variables of seedlings of Guazuma ulmifolia Lam (Malvaceae) as a function of phosphorus levels at 115 days after sowing – a. photosynthetic rate; b. stomatal conductance; c. transpiration rate; d. electron transport rate.

Figure 4
a-d. Biometric variables of seedlings of Guazuma ulmifolia Lam. (Malvaceae) as a function of phosphorus levels at 120 days after sowing - a. height; b. diameter; c. number of leaves; d. leaf area.

Figure 5
a-d. Biomass variables of seedlings of Guazuma ulmifolia Lam. (Malvaceae) as a function of phosphorus levels at 120 days after sowing - a. leaf dry mass; b. stem dry mass; c. root dry mass; d. total dry mass.

Figure 6
Dickson Quality Index of seedlings of Guazuma ulmifolia Lam. (Malvaceae) as a function of phosphorus levels at 120 days after sowing.

All significant correlations found were positive. And, the P level was strongly correlated with all studied variables. The photosynthetic rate correlated with the shoot P level of the seedlings as well as with the variables of growth, biomass accumulation, chlorophylls, and DQI. The DQI also showed to be highly correlated with the biometric variables and biomass, while what the ETR correlated with the chlorophylls a and b and with all physiological variables (Tab. 2).

Discussion

The results found in the present study show that the increasing phosphorus levels promoted better physiological and morphological performance and higher-quality seedlings of G. ulmifolia. The specie showed to be highly responsive to the application of P to the soil since a significant influence was verified for all studied variables, except for the specific leaf area and allometric relationships. Among the P levels tested, the 400 mg dm-3 level promoted the highest values for all variables. This high P requirement in the early stage is associated with the pioneer character of the specie (Herrera-Peraza et al. 2016Herrera-Peraza RA, Bever JD, De Miguel JM, Gómez- Sal A, Herrera P, García EE, Oviedo R, Torres- Arias Y, Delgado F, Valdés-Lafont O, Muñoz BC & Sánchez JA (2016) A new hypothesis on humid and dry tropical forest succession. Acta Botânica Cubana 215: 232-280.), and for showing a rapid growth (Silva et al. 2016Silva DL, Luz GR, Veloso MDM, Fernandes GW & Nunes YRF (2016) Emergência e estabelecimento de plântulas de Guazuma ulmifolia Lam. em função de diferentes tratamentos pré-germinativos. Ciência Florestal 26: 763-772.). As a function of the improvement in soil fertility, there is greater investment in seedling growth as the seedlings require greater amounts of nutrients to meet the nutritional demand, allowing an increase in the biomass production potential of species with a high early growth (Silva et al. 1997Silva IR, Furtini Neto AE, Curi N & Vale FR (1997) Crescimento inicial de quatorze espécies florestais nativas em resposta à adubação potássica. Pesquisa Agropecuária Brasileira 32: 205-212.).

The greater P uptake by the seedlings allowed them to increase the Falker® indices of chlorophylls a and b, the number of leaves, and the leaf area. The higher indices of leaf photosynthetic pigments (chlorophylls) can be attributed to the increased P concentration in the tissues, which, in theory, accelerated the energetic metabolism and cell division (Marschner 2012Marschner P (2012) Marschner’s mineral nutrition of higher plants. 3rd ed. Academic Press, London. 672p.), also stimulating the increase in the leaf area. Chlorophylls are extremely important as they are responsible for light capture during photosynthesis, resulting in the excitement of the electrons used to boost the reduction of nicotinamide adenine dinucleotide phosphate (NADP) and chemical energy in the form of adenosine triphosphate (ATP) (Croft et al. 2017Croft H, Chen JM, Luo X, Bartlett P, Chen B & Staebler RM (2017) Leaf chlorophyll content as a proxy for leaf photosynthetic capacity. Global Change Biology 23: 3513-3524.). The number of leaves and the leaf area are related to the ability to intercept solar radiation and boost CO₂ assimilation with allowing to accumulate dry matter (Crous et al. 2015Crous KY, Ósvaldsson A & Ellsworth DS (2015) Is phosphorus limiting in a Mature Eucalyptus woodland? Phosphorus fertilization stimulates stem growth. Plant Soil 391: 293-305.; Huang et al. 2016Huang J, Sedano F, Huang Y, Ma H, Li X, Liang S, Tian L, Zhang XF, Fan J & Wenbin W (2016) Assimilating a synthetic Kalman filter leaf area index series into the WOFOST model to improve regional winter wheat yield estimation. Agricultural and Forest Meteorology 216: 188-202.). Berghetti et al. (2019Berghetti ALP, Araújo MM, Tabaldi LA, Rorato DG, Aimi SC & Fárias JG (2019) Growth and physiological attributes of Cordia trichotoma seedlings in response to fertilization with phosphorus and potassium. Floresta 49: 133-142.) and Silva et al. (2020Silva CF, Souza RC, Pereira MG, Alves GC, Ferreira DHAA & Melo LA (2020) Production of Eucalyptus urophylla x Eucalyptus grandis seedlings with different fertilizers. Floresta 50: 1231-1238.) found similar results to the present study, also verifying higher chlorophyll indices and increased leaf area in seedlings of Cordia trichotoma and Eucalyptus urophylla x Eucalyptus grandis, respectively, with the increase in the P levels.

With higher chlorophyll indices, number of leaves, leaf area, and shoot P concentration, the seedlings of G. ulmifolia were able to increase the efficiency photosynthetic, showing higher stomatal conductance, transpiration, electron transport rate, and higher photosynthetic rates. Berghetti et al. (2019Berghetti ALP, Araújo MM, Tabaldi LA, Rorato DG, Aimi SC & Fárias JG (2019) Growth and physiological attributes of Cordia trichotoma seedlings in response to fertilization with phosphorus and potassium. Floresta 49: 133-142., 2021Berghetti ALP, Araújo MM, Tabaldi LA, Turchetto F, Aimi SC, Rorato DG, Marchezan C, Griebeler AM, Barbosa FM & Brunetto G (2021) Morphological, physiological and biochemical traits of Cordia trichotoma under phosphorous application and a water-retaining polymer. Journal of Forestry Research 1: 1-11.) also verified that the high concentrations of chlorophylls a and b and the increase in the leaf area as a function of the high P availability reflected higher photosynthetic rates. This increase in the photosynthetic process of the seedlings is also essential as plants with an adequate leaf P supply show an increase in CO₂ assimilation, carboxylation efficiency, and in the photochemical process, influencing the gain of biomass by plants (Warren 2011Warren CR (2011) How does P affect photosynthesis and metabolite profiles of Eucalyptus globules? Tree Physiology 31: 727-739.). In this case, the seedlings of G. ulmifolia could specifically invest in height and diameter. Considering that P deficiency is one of the greatest limitations in the development of forest species (Zhu et al. 2018Zhu J, LI M & Whelan M (2018) Phosphorus activators contribute to legacy phosphorus availability in agricultural soils: a review. Science of the Total Environment 612: 522-537.) since this nutrient plays a central role in plant growth, several studies have demonstrated that tropical tree species respond positively to the increase in the P levels, which is largely due to the low P levels in tropical soils (Fernandes et al. 2013Fernandes AR, Braz MAS, Maia PR & Viégas IJM (2013) Phosphorus fertilization and base saturation in the formation of Swietenia macrophyla seedlings. Revista de Ciências Agrárias 56: 261- 267.).

The seedlings of G. ulmifolia also accumulated biomass as a function of the phosphorus levels. The results obtained in this study show that the seedlings showed greater vigor at higher P levels, indicating that the specie requires high P levels during its early growth, such as occurs with Senna macranthera (DC. ex Collad.) H.S. Irwin & Barneby (Cruz et al. 2011Cruz CAF, Paiva HN, Cunha ACM & Neves JCL (2011) Crescimento e qualidade de mudas de fedegoso cultivadas em Latossolo Vermelho-Amarelo em resposta a macronutrientes. Scientia Forestalis 39: 21-33.), Cassia grandis L. f. (Andrade et al. 2018Andrade RHM, Freitas ECS, Paiva HN & Medeiros RA (2018) Adubação fosfatada na produção de mudas de Cassia ferruginea e Cassia grandis. Nucleus 15: 41-50.), and Dalbergia nigra (Vell.)

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Table 2
Pearson’s linear correlation coefficient (r) between the variables of seedlings of Guazuma ulmifolia Lam. (Malvaceae) subjected to phosphorus levels. H = height (cm); D = diameter (mm); NF = number of leaves; LA = leaf area (cm²); LDM = leaf dry mass (g); SDM = stem dry mass (g); RDM = root dry mass (g); DQI = Dickson Quality Index; Chl a = Chlorophyll a; Chl b = Chlorophyll b; A = photosynthetic rate (µmol (CO₂) m-2 s-1); gs = stomatal conductance (mol (H₂O) m-2 s-1); E = transpiration rate (mmol (H₂O) m-2 s-1); ETR = electron transport rate (µmol m-2 s-1); P = shoot phosphorus content (g Kg-1).

Fr. All. ex Benth (Gonçalves et al. 2014Gonçalves EO, Paiva HN, Nevesm JCL, Klippel VH & Caldeira MVW (2014) Crescimento de jacaranda-da-bahia (Dalbergia nigra ((Vell.) Fr. Todos. ex Benth)) sob diferentes níveis de NPK. Cerne 20: 493-500.; Carlos et al. 2018Carlos L, Venturin N, Venturin RP, Alves JM & Silva PO (2018) Liming and phosphating in Dalbergia nigra (Vell.) Allemão ex Benth. Seedlings. Floresta e Ambiente 25: 1-10.). Biomass is one of the best features to determine seedling quality as it correlates with plant vigor (Cruz et al. 2011Cruz CAF, Paiva HN, Cunha ACM & Neves JCL (2011) Crescimento e qualidade de mudas de fedegoso cultivadas em Latossolo Vermelho-Amarelo em resposta a macronutrientes. Scientia Forestalis 39: 21-33.), and, even if destructive, it reflects the investment made by the plant in biomass (Fernandes et al. 2019Fernandes MCOC, Freitas ECS, Paiva HN & Oliveira Neto SN (2019) Crescimento e qualidade de mudas de Citharexylum myrianthum em resposta à fertilização nitrogenada. Advances in Forestry 6: 507-513.) and is also highly associated with the ability to survive in the field. Furthermore, the dry matter data (biomass) should be taken into account as they help reduce the erroneous classification of seedling quality, in the case of seedlings that are taller due to etiolation (Freitas et al. 2017aFreitas ECS, Paiva HN, Leite HGON & Silvio N (2017a) Effect of phosphate fertilization and base saturation of substrate on the seedling’s growth and quality of Plathymenia foliolosa Benth. Revista Árvore 41: 1-9.).

Consequently, the phosphorus levels influenced the Dickson Quality Index the seedlings of G. ulmifolia. This index determines seedling quality based on several morphological features, minimizing the possible errors that may occur by using only one or two features (Vieira et al. 2019Vieira LM, Gomes EN, Brown TA, Constantino V & Zanette F (2019) Growth and quality of Brazilian pine tree seedlings as affected by container type and volume. Ornamental Horticulture 25: 276-286.). Therefore, with the results obtained, it is safe to affirm that the P levels increased the quality of the seedlings of G. ulmifolia. However, this was already foreseen as it also occurred for the variables needed to calculate this index, which agrees with the verified for other variables. This reinforces the high need for P that the seedlings require in the early stage in order to reach maximum growth, development, and vigor, with these being the most desirable features when the subject is seedling production.

Regarding the correlations found between the studied variables, values above 0.75 indicate that one variable allows inferring about the others (Freitas et al. 2017bFreitas ECS, Paiva HN, Leite HG & Oliveira Neto SN (2017b) Crescimento e qualidade de mudas de Cassia grandis Linnaeus f. em resposta à adubação fosfatada e calagem. Ciência Florestal 27: 509-519.); therefore, it is valid to say that the studied variables are strongly and positively interlinked as all significant correlations were positive. In physiological terms, the photosynthetic capacity is usually positively correlated with the P concentration, both in the soil and in the leaves (Bloomfield et al. 2014Bloomfield KJ, Domingues TF, Saiz G, Bird MI, Crayn DM, Ford A, Metcalfe DJ, Farquhar GD & Lloyd J (2014) Contrasting photosynthetic characteristics of forest vs. savanna species (Far North Queensland, Austrália). Biogeosciences 11: 7331-7347.; Bahar et al. 2017Bahar NHA, Yshida FY, Weerasinghe LK, Guerrieri R, O’Sullivan OS, Bloomfield KJ, Asner GP, Martin RB, Lloyd J, Malhi Y, Phillips OL, Meir P, Salinas N, Cosio EG, Domingues TF, Quesada CA, Sinca F, Vega AE, Ccorimanya PPZ, Aguila- Pasquel J, Huaypar KQ, Torres IC, Loayza RB, Tapia YP, Ovalle JH, Long BM, Evans JR & Atkin OK (2017) Leaf-level photosynthetic capacity in lowland Amazonian and high-elevation Andean tropical moist forests of Peru. New Phytologist 214: 1002-1018.), as leaf P is essential for the adjustment of net photosynthesis through the regulation of the main carbon metabolism intermediates (ATP, NADPH, and sugar phosphates, including ribulose 1-5 bisphosphate) (Bahar et al. 2017Bahar NHA, Yshida FY, Weerasinghe LK, Guerrieri R, O’Sullivan OS, Bloomfield KJ, Asner GP, Martin RB, Lloyd J, Malhi Y, Phillips OL, Meir P, Salinas N, Cosio EG, Domingues TF, Quesada CA, Sinca F, Vega AE, Ccorimanya PPZ, Aguila- Pasquel J, Huaypar KQ, Torres IC, Loayza RB, Tapia YP, Ovalle JH, Long BM, Evans JR & Atkin OK (2017) Leaf-level photosynthetic capacity in lowland Amazonian and high-elevation Andean tropical moist forests of Peru. New Phytologist 214: 1002-1018.). In terms of growth, the correlations were high because the P levels lead to growth increments and a marked development in pioneer species, in addition to improving the physiological capacity of the seedlings, which reflects in their morphological behavior (Resende et al. 1999Resende AV, Furtini Neto AE, Muniz JA, Curi N & Faquin V (1999) Crescimento inicial de espécies florestais de diferentes grupos sucessionais em resposta a doses de fósforo. Pesquisa agropecuária brasileira 34: 2071-2081.).

Based on the results obtained, it is concluded that the seedlings of G. ulmifolia responded positively to P fertilization. The P level of 400 mg dm-3 promoted seedlings with better physiological and morphological performance and higher quality.

Acknowledgments

This study was financed in part by the Coordenação de Aperfeiçoamento de Pessoal de Nível Superior - Brasil (CAPES) - Finance Code 001. We are grateful to the Goiano Federal Institute - Campus Rio Verde (IF Goiano - Rio Verde); and to the Postgraduate Program in Agricultural Sciences - Agronomy (PPGCA - AGRO), for their financial support and facilities provided to carry out this research.

References

Andrade RHM, Freitas ECS, Paiva HN & Medeiros RA (2018) Adubação fosfatada na produção de mudas de Cassia ferruginea e Cassia grandis Nucleus 15: 41-50.
Ayres M, Ayres JRM, Ayres DL & Santos AAS (2007) BioEstat: aplicações estatísticas nas áreas das ciências biológicas e médicas. Sociedade Civil Mamirauá, Belém. 364p.
Bahar NHA, Yshida FY, Weerasinghe LK, Guerrieri R, O’Sullivan OS, Bloomfield KJ, Asner GP, Martin RB, Lloyd J, Malhi Y, Phillips OL, Meir P, Salinas N, Cosio EG, Domingues TF, Quesada CA, Sinca F, Vega AE, Ccorimanya PPZ, Aguila- Pasquel J, Huaypar KQ, Torres IC, Loayza RB, Tapia YP, Ovalle JH, Long BM, Evans JR & Atkin OK (2017) Leaf-level photosynthetic capacity in lowland Amazonian and high-elevation Andean tropical moist forests of Peru. New Phytologist 214: 1002-1018.
Berghetti ALP, Araújo MM, Tabaldi LA, Rorato DG, Aimi SC & Fárias JG (2019) Growth and physiological attributes of Cordia trichotoma seedlings in response to fertilization with phosphorus and potassium. Floresta 49: 133-142.
Berghetti ALP, Araújo MM, Tabaldi LA, Turchetto F, Aimi SC, Rorato DG, Marchezan C, Griebeler AM, Barbosa FM & Brunetto G (2021) Morphological, physiological and biochemical traits of Cordia trichotoma under phosphorous application and a water-retaining polymer. Journal of Forestry Research 1: 1-11.
Bloomfield KJ, Domingues TF, Saiz G, Bird MI, Crayn DM, Ford A, Metcalfe DJ, Farquhar GD & Lloyd J (2014) Contrasting photosynthetic characteristics of forest vs. savanna species (Far North Queensland, Austrália). Biogeosciences 11: 7331-7347.
Calixto Júnior JT, Moraes SM, Gomez CV, Molas CC, Rolon M, Boligon AA, Athayde ML, Morais Oliveira CD, Tintino SR, Henrique D & Coutinho M (2016) Phenolic composition and antiparasitic activity of plants from the Brazilian Northeast ‘‘Cerrado”. Saudi Journal of Biological Sciences 23: 434-440.
Calzavara AK, Rocha JS, Lourenço G, Sanada K, Medri C, Bianchini E, Pimenta JA, Stolf-Moreira R & Oliveira HC (2017) Acclimation responses to high light by Guazuma ulmifolia Lam. (Malvaceae) leaves at different stages of development. Plant Biology 19: 720-727.
Carlos L, Venturin N, Farias ES, Venturin RP & Macedo RLG (2015) Growth and mineral nutrition in seedlings of Jacarandá-da-bahia subjected to nutrient deprivation. Floresta 45: 107-116.
Carlos L, Venturin N, Venturin RP, Alves JM & Silva PO (2018) Liming and phosphating in Dalbergia nigra (Vell.) Allemão ex Benth. Seedlings. Floresta e Ambiente 25: 1-10.
Carvalho PER (2007) Mutamba (Guazuma ulmifolia), Taxonomia e nomenclatura. Circular técnica EMBRAPA. Colombo, Paraná. Pp. 1-13.
Colli-Silva M (2019) Guazuma in Flora do Brasil 2020 (continuously updated) Jardim botânico do Rio de Janeiro. Available at Available at <http://reflora.jbrj.gov.br/reflora/floradobrasil/FB9065> Access on 7 August 2019.
» http://reflora.jbrj.gov.br/reflora/floradobrasil/FB9065
Croft H, Chen JM, Luo X, Bartlett P, Chen B & Staebler RM (2017) Leaf chlorophyll content as a proxy for leaf photosynthetic capacity. Global Change Biology 23: 3513-3524.
Crous KY, Ósvaldsson A & Ellsworth DS (2015) Is phosphorus limiting in a Mature Eucalyptus woodland? Phosphorus fertilization stimulates stem growth. Plant Soil 391: 293-305.
Cruz CAF, Paiva HN, Cunha ACM & Neves JCL (2011) Crescimento e qualidade de mudas de fedegoso cultivadas em Latossolo Vermelho-Amarelo em resposta a macronutrientes. Scientia Forestalis 39: 21-33.
Dechen AR & Nachtigall GR (2007) Elementos necessários para nutrição de plantas. In: Novais RF, Alvarez VVH, Barros NF, Fontes RLF, Cantarutti RB & Neves JCL (eds.) Fertilidade do solo. Sociedade Brasileira de Ciência do Solo, Viçosa. Pp. 91-132.
Dickson A, Leaf A & Hosner JF (1960) Quality appraisal of white spruce and white pine seedling stock in nurseries. Forest Chronicle 36: 10-13.
Fernandes AR, Braz MAS, Maia PR & Viégas IJM (2013) Phosphorus fertilization and base saturation in the formation of Swietenia macrophyla seedlings. Revista de Ciências Agrárias 56: 261- 267.
Fernandes MCOC, Freitas ECS, Paiva HN & Oliveira Neto SN (2019) Crescimento e qualidade de mudas de Citharexylum myrianthum em resposta à fertilização nitrogenada. Advances in Forestry 6: 507-513.
Ferreira DF (2014) Sisvar: a guide for its bootstrap procedures in multiple comparisons. Ciência e Agrotecnologia 38: 109-112.
Freitas ECS, Paiva HN, Leite HGON & Silvio N (2017a) Effect of phosphate fertilization and base saturation of substrate on the seedling’s growth and quality of Plathymenia foliolosa Benth. Revista Árvore 41: 1-9.
Freitas ECS, Paiva HN, Leite HG & Oliveira Neto SN (2017b) Crescimento e qualidade de mudas de Cassia grandis Linnaeus f. em resposta à adubação fosfatada e calagem. Ciência Florestal 27: 509-519.
Guedes RS, Melo LCA, Vergütz L, Rodríguez-Vila A, Covelo EF & Fernandes AR (2016) Adsorption and desorption kinetics and phosphorus hysteresis in highly weathered soil by stirred flow chambre experiments. Soil & Tillage Research 162: 46-54.
Gonçalves EO, Paiva HN, Nevesm JCL, Klippel VH & Caldeira MVW (2014) Crescimento de jacaranda-da-bahia (Dalbergia nigra ((Vell.) Fr. Todos. ex Benth)) sob diferentes níveis de NPK. Cerne 20: 493-500.
Gouveia PAR (2018) Therapeutic use extract of Guazuma ulmifolia Lam of Northern Brazil. Journal of Microbiology & Infectious Diseases 2: 1-8.
Herrera-Peraza RA, Bever JD, De Miguel JM, Gómez- Sal A, Herrera P, García EE, Oviedo R, Torres- Arias Y, Delgado F, Valdés-Lafont O, Muñoz BC & Sánchez JA (2016) A new hypothesis on humid and dry tropical forest succession. Acta Botânica Cubana 215: 232-280.
Huang J, Sedano F, Huang Y, Ma H, Li X, Liang S, Tian L, Zhang XF, Fan J & Wenbin W (2016) Assimilating a synthetic Kalman filter leaf area index series into the WOFOST model to improve regional winter wheat yield estimation. Agricultural and Forest Meteorology 216: 188-202.
Macedo L (2019) Falta de exames, tratamento irregular, “remédio caseiro”: venezuelanos com HIV contam como enfrentam crise em seu país. G1, [s. l.], 23 maio 2019. Availabe at < Availabe at <https://g1.globo.com/mundo/noticia/2019/05/23/falta-de-exames-tratamento-irregular-e-remedio-caseiro-portadores-de-hiv-contam-como-enfrentam-a-crise-na-venezuela.ghtml >. Access on 12 February 2020.
» https://g1.globo.com/mundo/noticia/2019/05/23/falta-de-exames-tratamento-irregular-e-remedio-caseiro-portadores-de-hiv-contam-como-enfrentam-a-crise-na-venezuela.ghtml
Malhotra H, Vandana SS & Pandey R (2018) Phosphorus nutrition: plant growth in response to deficiency and excess. In: Hasanuzzaman M, Fujita M, Oku H, Nahar K & Hawrylak-Nowak B (eds.) Plant nutrients and abiotic stress tolerance. Springer, Singapore. Pp. 171-190.
Marschner P (2012) Marschner’s mineral nutrition of higher plants. 3rd ed. Academic Press, London. 672p.
Moreira RCL, Brito MEB, Fernandes PD, Sá FVAS, Silva LA, Oliveira CJA, Veloso LLSA & Queiroga TB (2018) Growth and physiology of Annona squamosa L. under different irrigation depths and phosphate fertilization. Bioscience Journal 35: 389-397.
Natale W, Lima Neto AJ, Rozane DE, Parent LE & Corrêa MCM (2018) Mineral nutrition evolution in the formation of fruit tree rootstocks and seedlings. Revista Brasileira de Fruticultura 40: 1-15.
Nunes YRF, Fagundes L, Santos MR, Braga RF & Gonzaga APD (2006) Germinação de sementes de Guazuma ulmifolia Lam. (Malvaceae) e Heteropterys byrsonimifolia A. Juss (Malpighiaceae) sob diferentes tratamentos de escarificação tegumentar. Unimontes Cientifica 8: 43-52.
Pereira GA, Araújo NMP, Arruda HS, Farias DF, Molina G & Pastore GM (2019) Phytochemicals and biological activities of mutamba (Guazuma ulmifolia Lam.): a review. Food Research International 126: 1-53.
Pereira GA, Arruda HS, Morais DR, Araújo NMP & Pastore GM (2020) Mutamba (Guazuma ulmifolia Lam.) fruit as a novel source of dietary fibre and phenolic compounds. Food Chemistry 310: 1-35.
Folha de São Paulo (2018). Portadores de HIV da Venezuela recorrem a folhas de árvore por falta de antirretrovirais. Folha de S. Paulo, São Paulo, 13 dez. 2018. Available at <https://agenciaaids.com.br/noticia/portadores-de-hiv-da-venezuela-recorrem-a-folhas-de-arvore-por-falta-de-antirretrovirais/>. Access on 12 February 2020.
» https://agenciaaids.com.br/noticia/portadores-de-hiv-da-venezuela-recorrem-a-folhas-de-arvore-por-falta-de-antirretrovirais/
Raij B van, Cantarella H, Quaggio JA & Furlani AMC (1997) Recomendações de adubação e calagem para o estado de São Paulo. Instituto Agronômico/ Fundação IAC, Campinas. 285p.
Resende AV, Furtini Neto AE, Muniz JA, Curi N & Faquin V (1999) Crescimento inicial de espécies florestais de diferentes grupos sucessionais em resposta a doses de fósforo. Pesquisa agropecuária brasileira 34: 2071-2081.
Santos AD, Coscione AR, Vitti AC, Boaretto AE, Coelho AM, van Raij B, Silva CA, Abru Junior CH & Carmo CAFS (2009) Manual de análises químicas de solos, plantas e fertilizantes. 2a ed. rev. ampl. Embrapa Informação Tecnológica, Brasília. 627p.
Santos HG, Jacomine PKT, Anjos LHC, Oliveira VA, Lumbreras JF, Coelho MR, Almeida JÁ, Araújo Filho JC, Oliveira JB & Cunha TJF (2018a) Sistema brasileiro de classificação de solos. Embrapa, Brasília. 356p.
Santos JM, Alfredo TM, Antunes KA, Cunha JSM, Costa EMA, Lima ES, Silva DB, Carollo CA, Schmitz WO, Boleti APA, Santos EL & Souza KP (2018b) Guazuma ulmifolia Lam. Decreases oxidative stress in blood cells and prevents doxorubicin-induced cardiotoxicity. Oxidative Medicine and Cellular Longevity 2018: 1-16.
Santos PAR, Freitas ECS & Paiva HN (2019) Growth and quality of Leucochloron incuriale seedlings subjected to liming and phosphorus. Floresta e Ambiente 26: 1-9.
Silva CF, Souza RC, Pereira MG, Alves GC, Ferreira DHAA & Melo LA (2020) Production of Eucalyptus urophylla x Eucalyptus grandis seedlings with different fertilizers. Floresta 50: 1231-1238.
Silva DL, Luz GR, Veloso MDM, Fernandes GW & Nunes YRF (2016) Emergência e estabelecimento de plântulas de Guazuma ulmifolia Lam. em função de diferentes tratamentos pré-germinativos. Ciência Florestal 26: 763-772.
Silva IR, Furtini Neto AE, Curi N & Vale FR (1997) Crescimento inicial de quatorze espécies florestais nativas em resposta à adubação potássica. Pesquisa Agropecuária Brasileira 32: 205-212.
Silva OMC, Santana LS & Macedo RLG (2018) Influência da adubação mineral no desenvolvimento inicial de Schinus terebinthifolius Raddi. Agrarian Academy 5: 112-120.
Singer F (2018)Acondenação à morte dos pacientes deAids na Venezuela. El Pais, Madrid, 07 set. 2018. Available at <Available at <https://brasil.elpais.com/brasil/2018/09/06/internacional/1536258399_684413.html >. Access on 9 February 2020.
» https://brasil.elpais.com/brasil/2018/09/06/internacional/1536258399_684413.html
Warren CR (2011) How does P affect photosynthesis and metabolite profiles of Eucalyptus globules? Tree Physiology 31: 727-739.
Vieira LM, Gomes EN, Brown TA, Constantino V & Zanette F (2019) Growth and quality of Brazilian pine tree seedlings as affected by container type and volume. Ornamental Horticulture 25: 276-286.
Zhu J, LI M & Whelan M (2018) Phosphorus activators contribute to legacy phosphorus availability in agricultural soils: a review. Science of the Total Environment 612: 522-537.

Edited by

Area Editor:

Dr. Nelson Santos Junior

Publication Dates

Publication in this collection
06 Jan 2023
Date of issue
2022

History

Received
01 Oct 2021
Accepted
08 June 2022

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

[1] Andrade RHM, Freitas ECS, Paiva HN & Medeiros RA (2018) Adubação fosfatada na produção de mudas de Cassia ferruginea e Cassia grandis Nucleus 15: 41-50.

[2] Ayres M, Ayres JRM, Ayres DL & Santos AAS (2007) BioEstat: aplicações estatísticas nas áreas das ciências biológicas e médicas. Sociedade Civil Mamirauá, Belém. 364p.

[3] Bahar NHA, Yshida FY, Weerasinghe LK, Guerrieri R, O’Sullivan OS, Bloomfield KJ, Asner GP, Martin RB, Lloyd J, Malhi Y, Phillips OL, Meir P, Salinas N, Cosio EG, Domingues TF, Quesada CA, Sinca F, Vega AE, Ccorimanya PPZ, Aguila- Pasquel J, Huaypar KQ, Torres IC, Loayza RB, Tapia YP, Ovalle JH, Long BM, Evans JR & Atkin OK (2017) Leaf-level photosynthetic capacity in lowland Amazonian and high-elevation Andean tropical moist forests of Peru. New Phytologist 214: 1002-1018.

[4] Berghetti ALP, Araújo MM, Tabaldi LA, Rorato DG, Aimi SC & Fárias JG (2019) Growth and physiological attributes of Cordia trichotoma seedlings in response to fertilization with phosphorus and potassium. Floresta 49: 133-142.

[5] Berghetti ALP, Araújo MM, Tabaldi LA, Turchetto F, Aimi SC, Rorato DG, Marchezan C, Griebeler AM, Barbosa FM & Brunetto G (2021) Morphological, physiological and biochemical traits of Cordia trichotoma under phosphorous application and a water-retaining polymer. Journal of Forestry Research 1: 1-11.

[6] Bloomfield KJ, Domingues TF, Saiz G, Bird MI, Crayn DM, Ford A, Metcalfe DJ, Farquhar GD & Lloyd J (2014) Contrasting photosynthetic characteristics of forest vs. savanna species (Far North Queensland, Austrália). Biogeosciences 11: 7331-7347.

[7] Calixto Júnior JT, Moraes SM, Gomez CV, Molas CC, Rolon M, Boligon AA, Athayde ML, Morais Oliveira CD, Tintino SR, Henrique D & Coutinho M (2016) Phenolic composition and antiparasitic activity of plants from the Brazilian Northeast ‘‘Cerrado”. Saudi Journal of Biological Sciences 23: 434-440.

[8] Calzavara AK, Rocha JS, Lourenço G, Sanada K, Medri C, Bianchini E, Pimenta JA, Stolf-Moreira R & Oliveira HC (2017) Acclimation responses to high light by Guazuma ulmifolia Lam. (Malvaceae) leaves at different stages of development. Plant Biology 19: 720-727.

[9] Carlos L, Venturin N, Farias ES, Venturin RP & Macedo RLG (2015) Growth and mineral nutrition in seedlings of Jacarandá-da-bahia subjected to nutrient deprivation. Floresta 45: 107-116.

[10] Carlos L, Venturin N, Venturin RP, Alves JM & Silva PO (2018) Liming and phosphating in Dalbergia nigra (Vell.) Allemão ex Benth. Seedlings. Floresta e Ambiente 25: 1-10.

[11] Carvalho PER (2007) Mutamba (Guazuma ulmifolia), Taxonomia e nomenclatura. Circular técnica EMBRAPA. Colombo, Paraná. Pp. 1-13.

[12] Colli-Silva M (2019) Guazuma in Flora do Brasil 2020 (continuously updated) Jardim botânico do Rio de Janeiro. Available at Available at <http://reflora.jbrj.gov.br/reflora/floradobrasil/FB9065> Access on 7 August 2019.
» http://reflora.jbrj.gov.br/reflora/floradobrasil/FB9065

[13] Croft H, Chen JM, Luo X, Bartlett P, Chen B & Staebler RM (2017) Leaf chlorophyll content as a proxy for leaf photosynthetic capacity. Global Change Biology 23: 3513-3524.

[14] Crous KY, Ósvaldsson A & Ellsworth DS (2015) Is phosphorus limiting in a Mature Eucalyptus woodland? Phosphorus fertilization stimulates stem growth. Plant Soil 391: 293-305.

[15] Cruz CAF, Paiva HN, Cunha ACM & Neves JCL (2011) Crescimento e qualidade de mudas de fedegoso cultivadas em Latossolo Vermelho-Amarelo em resposta a macronutrientes. Scientia Forestalis 39: 21-33.

[16] Dechen AR & Nachtigall GR (2007) Elementos necessários para nutrição de plantas. In: Novais RF, Alvarez VVH, Barros NF, Fontes RLF, Cantarutti RB & Neves JCL (eds.) Fertilidade do solo. Sociedade Brasileira de Ciência do Solo, Viçosa. Pp. 91-132.

[17] Dickson A, Leaf A & Hosner JF (1960) Quality appraisal of white spruce and white pine seedling stock in nurseries. Forest Chronicle 36: 10-13.

[18] Fernandes AR, Braz MAS, Maia PR & Viégas IJM (2013) Phosphorus fertilization and base saturation in the formation of Swietenia macrophyla seedlings. Revista de Ciências Agrárias 56: 261- 267.

[19] Fernandes MCOC, Freitas ECS, Paiva HN & Oliveira Neto SN (2019) Crescimento e qualidade de mudas de Citharexylum myrianthum em resposta à fertilização nitrogenada. Advances in Forestry 6: 507-513.

[20] Ferreira DF (2014) Sisvar: a guide for its bootstrap procedures in multiple comparisons. Ciência e Agrotecnologia 38: 109-112.

[21] Freitas ECS, Paiva HN, Leite HGON & Silvio N (2017a) Effect of phosphate fertilization and base saturation of substrate on the seedling’s growth and quality of Plathymenia foliolosa Benth. Revista Árvore 41: 1-9.

[22] Freitas ECS, Paiva HN, Leite HG & Oliveira Neto SN (2017b) Crescimento e qualidade de mudas de Cassia grandis Linnaeus f. em resposta à adubação fosfatada e calagem. Ciência Florestal 27: 509-519.

[23] Guedes RS, Melo LCA, Vergütz L, Rodríguez-Vila A, Covelo EF & Fernandes AR (2016) Adsorption and desorption kinetics and phosphorus hysteresis in highly weathered soil by stirred flow chambre experiments. Soil & Tillage Research 162: 46-54.

[24] Gonçalves EO, Paiva HN, Nevesm JCL, Klippel VH & Caldeira MVW (2014) Crescimento de jacaranda-da-bahia (Dalbergia nigra ((Vell.) Fr. Todos. ex Benth)) sob diferentes níveis de NPK. Cerne 20: 493-500.

[25] Gouveia PAR (2018) Therapeutic use extract of Guazuma ulmifolia Lam of Northern Brazil. Journal of Microbiology & Infectious Diseases 2: 1-8.

[26] Herrera-Peraza RA, Bever JD, De Miguel JM, Gómez- Sal A, Herrera P, García EE, Oviedo R, Torres- Arias Y, Delgado F, Valdés-Lafont O, Muñoz BC & Sánchez JA (2016) A new hypothesis on humid and dry tropical forest succession. Acta Botânica Cubana 215: 232-280.

[27] Huang J, Sedano F, Huang Y, Ma H, Li X, Liang S, Tian L, Zhang XF, Fan J & Wenbin W (2016) Assimilating a synthetic Kalman filter leaf area index series into the WOFOST model to improve regional winter wheat yield estimation. Agricultural and Forest Meteorology 216: 188-202.

[28] Macedo L (2019) Falta de exames, tratamento irregular, “remédio caseiro”: venezuelanos com HIV contam como enfrentam crise em seu país. G1, [s. l.], 23 maio 2019. Availabe at < Availabe at <https://g1.globo.com/mundo/noticia/2019/05/23/falta-de-exames-tratamento-irregular-e-remedio-caseiro-portadores-de-hiv-contam-como-enfrentam-a-crise-na-venezuela.ghtml >. Access on 12 February 2020.
» https://g1.globo.com/mundo/noticia/2019/05/23/falta-de-exames-tratamento-irregular-e-remedio-caseiro-portadores-de-hiv-contam-como-enfrentam-a-crise-na-venezuela.ghtml

[29] Malhotra H, Vandana SS & Pandey R (2018) Phosphorus nutrition: plant growth in response to deficiency and excess. In: Hasanuzzaman M, Fujita M, Oku H, Nahar K & Hawrylak-Nowak B (eds.) Plant nutrients and abiotic stress tolerance. Springer, Singapore. Pp. 171-190.

[30] Marschner P (2012) Marschner’s mineral nutrition of higher plants. 3rd ed. Academic Press, London. 672p.

[31] Moreira RCL, Brito MEB, Fernandes PD, Sá FVAS, Silva LA, Oliveira CJA, Veloso LLSA & Queiroga TB (2018) Growth and physiology of Annona squamosa L. under different irrigation depths and phosphate fertilization. Bioscience Journal 35: 389-397.

[32] Natale W, Lima Neto AJ, Rozane DE, Parent LE & Corrêa MCM (2018) Mineral nutrition evolution in the formation of fruit tree rootstocks and seedlings. Revista Brasileira de Fruticultura 40: 1-15.

[33] Nunes YRF, Fagundes L, Santos MR, Braga RF & Gonzaga APD (2006) Germinação de sementes de Guazuma ulmifolia Lam. (Malvaceae) e Heteropterys byrsonimifolia A. Juss (Malpighiaceae) sob diferentes tratamentos de escarificação tegumentar. Unimontes Cientifica 8: 43-52.

[34] Pereira GA, Araújo NMP, Arruda HS, Farias DF, Molina G & Pastore GM (2019) Phytochemicals and biological activities of mutamba (Guazuma ulmifolia Lam.): a review. Food Research International 126: 1-53.

[35] Pereira GA, Arruda HS, Morais DR, Araújo NMP & Pastore GM (2020) Mutamba (Guazuma ulmifolia Lam.) fruit as a novel source of dietary fibre and phenolic compounds. Food Chemistry 310: 1-35.

[36] Folha de São Paulo (2018). Portadores de HIV da Venezuela recorrem a folhas de árvore por falta de antirretrovirais. Folha de S. Paulo, São Paulo, 13 dez. 2018. Available at <https://agenciaaids.com.br/noticia/portadores-de-hiv-da-venezuela-recorrem-a-folhas-de-arvore-por-falta-de-antirretrovirais/>. Access on 12 February 2020.
» https://agenciaaids.com.br/noticia/portadores-de-hiv-da-venezuela-recorrem-a-folhas-de-arvore-por-falta-de-antirretrovirais/

[37] Raij B van, Cantarella H, Quaggio JA & Furlani AMC (1997) Recomendações de adubação e calagem para o estado de São Paulo. Instituto Agronômico/ Fundação IAC, Campinas. 285p.

[38] Resende AV, Furtini Neto AE, Muniz JA, Curi N & Faquin V (1999) Crescimento inicial de espécies florestais de diferentes grupos sucessionais em resposta a doses de fósforo. Pesquisa agropecuária brasileira 34: 2071-2081.

[39] Santos AD, Coscione AR, Vitti AC, Boaretto AE, Coelho AM, van Raij B, Silva CA, Abru Junior CH & Carmo CAFS (2009) Manual de análises químicas de solos, plantas e fertilizantes. 2a ed. rev. ampl. Embrapa Informação Tecnológica, Brasília. 627p.

[40] Santos HG, Jacomine PKT, Anjos LHC, Oliveira VA, Lumbreras JF, Coelho MR, Almeida JÁ, Araújo Filho JC, Oliveira JB & Cunha TJF (2018a) Sistema brasileiro de classificação de solos. Embrapa, Brasília. 356p.

[41] Santos JM, Alfredo TM, Antunes KA, Cunha JSM, Costa EMA, Lima ES, Silva DB, Carollo CA, Schmitz WO, Boleti APA, Santos EL & Souza KP (2018b) Guazuma ulmifolia Lam. Decreases oxidative stress in blood cells and prevents doxorubicin-induced cardiotoxicity. Oxidative Medicine and Cellular Longevity 2018: 1-16.

[42] Santos PAR, Freitas ECS & Paiva HN (2019) Growth and quality of Leucochloron incuriale seedlings subjected to liming and phosphorus. Floresta e Ambiente 26: 1-9.

[43] Silva CF, Souza RC, Pereira MG, Alves GC, Ferreira DHAA & Melo LA (2020) Production of Eucalyptus urophylla x Eucalyptus grandis seedlings with different fertilizers. Floresta 50: 1231-1238.

[44] Silva DL, Luz GR, Veloso MDM, Fernandes GW & Nunes YRF (2016) Emergência e estabelecimento de plântulas de Guazuma ulmifolia Lam. em função de diferentes tratamentos pré-germinativos. Ciência Florestal 26: 763-772.

[45] Silva IR, Furtini Neto AE, Curi N & Vale FR (1997) Crescimento inicial de quatorze espécies florestais nativas em resposta à adubação potássica. Pesquisa Agropecuária Brasileira 32: 205-212.

[46] Silva OMC, Santana LS & Macedo RLG (2018) Influência da adubação mineral no desenvolvimento inicial de Schinus terebinthifolius Raddi. Agrarian Academy 5: 112-120.

[47] Singer F (2018)Acondenação à morte dos pacientes deAids na Venezuela. El Pais, Madrid, 07 set. 2018. Available at <Available at <https://brasil.elpais.com/brasil/2018/09/06/internacional/1536258399_684413.html >. Access on 9 February 2020.
» https://brasil.elpais.com/brasil/2018/09/06/internacional/1536258399_684413.html

[48] Warren CR (2011) How does P affect photosynthesis and metabolite profiles of Eucalyptus globules? Tree Physiology 31: 727-739.

[49] Vieira LM, Gomes EN, Brown TA, Constantino V & Zanette F (2019) Growth and quality of Brazilian pine tree seedlings as affected by container type and volume. Ornamental Horticulture 25: 276-286.

[50] Zhu J, LI M & Whelan M (2018) Phosphorus activators contribute to legacy phosphorus availability in agricultural soils: a review. Science of the Total Environment 612: 522-537.

cmolc dm -3					mg dm-3	%	g dm-3		%
Ca	Mg	Al	K	pH	P	V	O.M	Clay	Sand	Silt
1.06	0.49	0.05	0.32	5.1	2.6	47	41.3	48	40	12

Brasil