ARBUSCULAR MYCORRHIZAL FUNGI ON THE INITIAL GROWTH AND NUTRITION OF Parkia Platycephala BENTH. UNDER WATER STRESS

Porto, Dayara Lins; Arauco, Adriana Miranda de Santana; Boechat, Cácio Luiz; Silva, Adriano de Oliveira; Moitinho, Mara Regina; Farias, Séfora Gil Gomes de

doi:10.1590/01047760202026012671

ABSTRACT

Parkia platycephala Benth. (Fava-de-bolota) found in areas of Cerrado-Caatinga transition, is a species with potential for feeding ruminants in arid regions. The objective of this study was to evaluate the effect of inoculation of arbuscular mycorrhizal fungi (AMF) on the initial growth and nutrition of P. platycephala Benth. seedlings under water stress. The experimental design was a randomized block design in a 2 × 6 factorial scheme with five replications, consisting of two water regime conditions (with and without stress), four AMF strains (Gigaspora rosea, Gigaspora margarita, Acaulospora koskei, and Acaulospora morrowiae), one treatment with associated inoculum (Mix), and one control. At 120 days after sowing, the morphological variables height (H), stem diameter (SD), number of leaves (NL), root length (RL), total root volume (TRV), shoot dry mass (SDM), root dry mass (SDM) and total dry mass (TDM) were evaluated. Nutrient contents and mycorrhizal colonization rate were also evaluated. The variables NL, SDM and TDM presented significant interaction between inoculation with the fungi and the studied water conditions. For the contents of P, Mg and Mn there was also interaction, being the best results with the strains A. koskei, Mix, A. morrowiae and control, respectively, in the condition without water stress. Mycorrhizal fungi favored plant growth as well as the absorption of P, Mg, Mn and Zn.

Keywords:
Mycorrhizal association; Fava-de-bolota; Inoculation; Water condition

INTRODUCTION

Cerrado is the second largest biome in South America, occupying an area of approximately 2 million km², which corresponds to 23.92% of the Brazilian territory, while the Caatinga biome occupies an area of 800,000 km², equivalent to 9.92% of the territory, both showing a rich and vast biodiversity, with the main Brazilian forest formations (Oliveira et al., 2012OLIVEIRA, TM; ALVES, AR; AMARAL, CG, ALMEIDA, KND; SOUZA, KB; AGUIAR, AS; ARAÚJO, EF.; FARIAS, SGG. Análise da estrutura vegetacional em uma área de transição Cerrado-Caatinga no município de Bom Jesus-PI. Scientia Plena, v. 8, n. 4, 2012.; Instituto Brasileiro de Geográfica e Estatística, 2004 INSTITUITO BRASILEIRO DE GEOGRAFIA E ESTATÍSTICA. Disponível em Disponível em https://ww2.ibge.gov.br/home/presidencia/noticias/21052004biomashtml.shtm . Acesso em: 15 de Novembro de 2018.
https://ww2.ibge.gov.br/home/presidencia... ; Food and Agriculture Organization, 2005FOOD AND AGRICULTURE ORGANIZATION OF THE UNITED NATIONS. Disponível em: Disponível em: http://www.fao.org/3/a-ai822e.pdf . Acesso em: 15 de Novembro de 2018.
http://www.fao.org/3/a-ai822e.pdf... ; Ministério do Meio Ambiente, 2018MINISTÉRIO DO MEIO AMBIENTE. Bioma Caatinga. Disponível em: Disponível em: http://www.mma.gov.br/biomas/caatinga . Acesso em: 10 maio 2018.
http://www.mma.gov.br/biomas/caatinga... ).

Among the several species of trees in these biomes is the Parkia platycephala Benth., a tree legume with good qualities for afforestation and pods usually used in forage for feeding ruminants (Lorenzi, 2002LORENZI, H. Árvores brasileiras: manual de identificação e cultivo de plantas arbóreas nativas do Brasil. Nova Odessa: Instituto Plantarum, 2002. 174p.) in scarcity periods. In the literature there are few information known on the adaptive characteristics and environmental conditions since water stress in periods of more severe droughts cause physiological and morphological changes to plants (Pelegrini et al., 2013PELEGRINI, LL; BORCIONI, E; NOGUEIRA, AC; KOEHLER; QUOIRIN, MGG. Efeito do estresse hídrico simulado com NaCl, manitol e PEG (6000) na germinação de sementes de Erythrina falcata Benth. Ciência Florestal , v. 23, n. 2, p. 511-519, 2013.) by reducing their metabolic activity and causing deficiency in the translocation of mineral nutrients, affecting growth and productivity (Silveira et al., 2016SILVEIRA, OS; CUSTÓDIO, JPC; SILVA, FCMda; NASCENTE, ACSde; MONTEIRO, CL; MATOS, FS. A ação dos brassinosteróides no crescimento de mudas de Pinhão manso sob déficit hídrico. Agriculture environmental sciences, v. 2, n. 1, p. 52-61, 2016.).

Arbuscular mycorrhizal fungi (AMF) have marked and consistent effects on plant growth, especially under conditions of soil nutrient deficiency and water stress (Faria et al., 2013FARIA, M.T.; SCABORA, M.H.; MALTONI, K.L.; CASSIOLATO, A.M.R. Micorrização e crescimento de progênies de Hymenaea stignocarpa Mart. ex. Hayne em subsolo de área degradada. Ciência Florestal , v. 23, n. 1, p. 233-243, 2013.). AMF are obligate biotrophic organisms, which establish symbiosis with roots of most terrestrial plants, working as an expansion of the plant root system and providing a higher water and nutrient absorption (Silva et al., 2004SILVA, MA; CAVALCANTE, UMT; SILVA, FSBda; SOARES, SAG; MAIA, LC. Crescimento de mudas de Maracujazeiro-doce (Passiflora alata Curtis) associados a fungos micorrízicos arbusculares (Glomeromycota). Acta Botânica Brasilica, v. 18, n. 4, p. 981-985, 2004.). According to Farias et al. (2008FARIAS, S.G.G; FREIRE, A.L.O.; SANTOS, D.R.; SILVA, R.B.; FREIRE, J.L.O. Respostas de plantas de Moringa (Moringa oleifera Lam.) inoculadas com fungos micorrízicos e submetidos ao estresse hídrico. Engenharia Ambiental, v. 5, n. 3, p. 36-46, 2008. ) and Soares and Carneiro (2010SOARES, CRFS; CARNEIRO, MAC. Micorrizas arbusculares na recuperação de áreas degradadas. In: SIQUEIRA, J. O. Micorrizas: 30 anos de pesquisa no Brasil. UFLA, 2010. p. 441-474.), plants produce a higher amount of root dry matter when inoculated with AMF, favoring their adaptation and survival in an environment under stress.

AMF increase nutrient absorption, especially phosphorus (P), due to their mycorrhizal activity (Brito et al., 2017BRITO, V.N.; TELLECHEA, F.R.F.; HEITOR, L.C.; FREITAS, M.S.M.; MARTINS, M.A. Fungos micorrízicos arbusculares e adubação fosfatada na produção de mudas de Paricá. Ciência Florestal, v. 27, n. 2, p. 485-497, 2017.). In addition to improving nutritional status, AMF increase the tolerance to root diseases (Borges et al., 2007BORGES, A.J.S.; TRINDADE, A.V.; MATOS, A.P.; PEIXOTO, M.F.S. Reduction of fusarium wilt of “banana-maçã” by inoculation of arbuscular mycorrhizal fungi. Pesquisa Agropecuária Brasileira, v. 42, n. 1, p. 35-41, 2007.), accelerate growth, improve seedling vigor in their formation phase (Nunes et al., 2008NUNES, JLS; SOUZA, PVD; MARODIN, GAB; FACHINELLO, JC. Inoculação de fungos micorrizicos arbusculares em porta-enxerto de pessegueiro Cv okinawa. Revista Brasileira de Fruticultura, v. 30, n. 4, p. 1100-1106, 2008.; Soares et al., 2012SOARES, ACF; SOUSA, CSda; GARRIDO, MSda; LIMA, FSde. Fungos micorrízicos arbusculares no crescimento e nutrição de mudas de Jenipapeiro. Revista Ciência Agronômica , v. 43, n. 1, p. 47-54, 2012.), and contribute to the formation and maintenance of soil structure by aggregating soil particles by extra-radicular hyphae through exudates and residues (Folli-Pereira et al., 2012PEREIRA, JWL; FILHO, PAM; ALBUQUERQUE, MB; NOGUEIRA, RJMC; SANTOS, RC. Mudanças bioquímicas em genótipos de Amendoim submetidos a déficit hídrico moderado. Revista Ciência Agronômica, v. 43, n. 04, p. 766-773, 2012.).

In this context, the hypothesis of this study is that the association of mycorrhizal fungi with the tree species acorn bean positively influences plants submitted to water stress conditions. Thus, considering that this association provides an expansion of the root system, favoring higher water and nutrient absorption, this study aimed to assess the effect of inoculating arbuscular mycorrhizal fungi on the initial growth and nutrition of P. platycephala Benth. under water stress, and this way contributing with information on quality seedling production of this species in transition areas of the Cerrado and Caatinga biomes.

MATERIAL AND METHODS

Study location

The experiment was conducted in a greenhouse located in the Brazilian semi-arid region at the geographical coordinates 09°04′ S and 44°21′ W, with 277 m of average altitude. According to Koppen, regional climate is classified as Aw, i.e. a tropical warm and humid climate with two well-defined seasons: a dry season from May to October and a rainy season from November to April (Medeiros et al., 2016MEDEIROS, RM.; SILVA, VMAde., MELO, VSda., MENEZES, HEA; MENEZES, HEA. Diagnóstico e tendência da precipitação pluvial em Bom Jesus- Piauí, Brasil. Revista Verde de Agroecologia e Desenvolvimento Sustentável, v. 11, n. 3, p. 115-121, 2016.).

Soil preparation

The soil used in the experiment was classified as Quartzipsamment (Neossolo Quartzarênico Órtico típico, Brazilian Soil Classification System) (Santos et al., 2013SANTOS, HGdos; JACOMINE, PKT; ANJOS, LHCdos; OLIVEIRA, VAde; LUMBRERAS, JF; COELHO, MR; ALMEIDA, JAde; CUNHA, TJF; OLIVEIRA, JBde. Sistema Brasileiro de Classificação de Solos. Embrapa Solos. 2013. 353p.). Soil samples were collected at a depth of 0-20 cm and submitted to physicochemical analysis according to the methodology described by Silva (2009). The average values of these soil attributes are shown in Table 1.

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TABLE 1
Descriptive statistics of the data groups.

Before the experiment setup, the soil was air-dried, decloded, sieved in a 2 mm mesh sieve, and packed in fiber bags to be autoclaved at 121 °C and at 1 atm for 30 minutes. Black PVC pots with a 3 L capacity were drilled in the bottom and filled with 400 g of rock fragments to facilitate water flow. These rocks were covered with a fabric and 3 kg of soil were added. This soil was corrected according to the recommendations of soil corrective for the Cerrado biome, raising base saturation to 50% (Sousa and Lobato, 2004SOUSA, DMG; LOBATO, E (Ed.). Cerrado: correção do solo e adubação. Embrapa Informação Tecnológicas, 2004. 416p. ), with the incorporation of dolomitic limestone with the following composition: 32% CaO, 47% CaO+MgO, 15% MgO, CaCO3 band A, 94.5% neutralizing power, 91% relative power of total neutralization, and moisture of 3%. No chemical fertilization was performed in this soil.

Species under study and seed preparation

Seeds from P. platycephala Benth. were donated, being collected from 15 matrix trees in native area, free from pathogens and injuries were selected and then submitted to mechanical scarification to overcome the integumentary dormancy and treated with 5% sodium hypochlorite solution, according to procedures by Silva et al. (2017SILVA, RB; MATOS, VP; FARIAS, SGGde; SENA, LHM de; SILVA, DYOde. Germinação e vigor de plântulas de Parkia platycephala Benth. em diferentes substratos e temperaturas. Revista Ciência Agronômica , v. 48, n. 1, p. 142-150, 2017.).

Experimental Design

The experimental design was a randomized block design arranged in a 2 × 6 factorial scheme, which consisted of two water regime conditions (with and without stress) and six inoculation treatments, with five replications. Treatments consisted of the isolated strains Gigaspora rosea SPL 101A, Gigaspora margarita SCT 077A, Acaulospora koskei SCT 042A, and Acaulospora morrowiae SCT 048B, a consortium of strains (mix of the four strains), and a control (without inoculation).

Planting and inoculation of arbuscular mycorrhizal fungi (AMFs)

Planting was carried out manually using 5 seeds per pot. The inoculation was performed with 5 g of AMF of the 4 individual strains and 1.25 g of AMF of each strain for the consortium (Mix). After the complete emergence, thinning was carried out and only two visually more vigorous seedlings remained per experimental unit.

The arbuscular mycorrhizal fungi (AMFs) strains used were provided by the International Glomeromycota Culture Collection (CICG) of the Regional University of Blumenau (FURB), Blumenau, Santa Catarina, Brazil.

Water stress application

For water stress, soil moisture was maintained around 60% of the pot capacity, being determined by the water content removed from soil after saturation, by capillarity, until the drainage is finished. Irrigation of pots was controlled by means of periodic weighings, using a precision balance with a capacity of 10 kg, followed by the replacement of the evapotranspirated water in the period and keeping the pots close to field capacity.

FIGURE 1
Overview of treatments with different water regimes (a), water stress treatment (b), treatment without water stress (c).

Water stress was applied in treatments by suspending the daily irrigation both with 30 plants. Plants under water stress underwent three periods without irrigation. The days under water stress were defined according to leaf rolling and plant growth. The other plants were irrigated to maintain soil moisture close to 60% of the pot capacity. Irrigation was suspended for the first time at 35 days after sowing for 12 days, for the second time at 70 days after sowing for nine days, and for the third time at 105 days after sowing for seven days.

Evaluation

Growth

The following biometric analyses were performed at 120 days after sowing (end of the experiment): plant height (HP) with a measuring tape, stem diameter (SD) with a digital caliper, root length (RL) with a measuring tape, and the number of leaves (NL) by counting. Roots were washed in running water to remove the adhered material and then the following variables were measured: shoot dry matter (SDM), root dry matter (RDM), total dry matter (TDM), mycorrhizal colonization rate (MC), and total root volume (TRV), which was obtained using the methodology proposed by Peixoto et al., (2010), in which the roots are immersed in water in a measuring cylinder, being observed the displaced volume of water. Seedlings were separated into roots and shoot and taken to a forced air circulation oven at 65 °C until constant weight in order to assess the dry mass. Subsequently, the material was weighed to determine RDM and SDM.

Mycorrhizal colonization rate

The mycorrhizal colonization rate was assessed according to the methodology proposed by Koske and Gemma (1989). For this, 1 g of fresh fine roots were weighed and then clarified and pigmented. Fungal structures were counted by the gridline intersection procedure proposed by Giovannetti and Mosse (1980GIOVANNETTI, M; MOSSE, B. An evaluation of techniques for measuring vesicular arbuscular mycorrhizal infection in roo0ts. New Phytologist, v. 84, n. 3, p. 489-500, 1980.).

Nutritional contents

The contents of macro and micronutrients (P, K, Ca, Mg, S, Cu, Fe, Mn, and Zn) of plant shoot were determined according to the methodology described in Silva (2009). For this, the nutrient extraction method by means of the wet digestion by nitric (65%) and perchloric acid (72%) was used.

Data analysis

The data were submitted to the F-test by means of analysis of variance (ANOVA). When significant, the means were submitted to the Scott-Knott test at 5% of probability, being the data of the mycorrhizal colonization rate and manganese content transformed into square root of x+1. Simultaneously with the statistical analyses, the basic assumptions of ANOVA, normality of errors, and homogeneity of variances were tested for all the analyzed variables. All the procedures performed were conducted in the software R (R Core Team, 2016).

RESULTS AND DISCUSSION

Biometric and morphological parameters

The number of leaves (NL) presented a significant interaction between fungal species and conditions (with and without stress). The NL was significantly higher in the condition stress without. Only treatments with the inoculum G. rosea and the Mix showed no significant difference due to the water conditions of the soil (Table 2).

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TABLE 2
Average values of biometric variables of seedlings of Parkia platycephala inoculated with arbuscular mycorrhizal fungi (AMF) under water stress.

A similar result was observed by Martins et al. (2008MARTINS, F.B.; STRECK, N.A.; SILVA, J.C; MORAIS, W.W.; SUSIN, F.; NAVROSKI, M.C.; VIVIAN, M.A. Deficiência hídrica no solo e seu efeito sobre transpiração, crescimento e desenvolvimento de mudas de duas espécies de eucalipto. Revista Brasileira de Ciência do Solo , v. 32, p. 1297-1306, 2008.) evaluating water stress in two species of eucalyptus observed that the number of leaves were affected in response to the reduction of water in the soil, which indicates that the stress should affect the metabolism of the plant and cause a decrease in the growth and development of the seedlings.

According to Couto et al. (2009), NL is considered one of the most important characteristics for seedling transplanting in the field, i.e. the higher the number of leaves the plants have, the higher is their establishment in the field since they are structures responsible for capturing solar energy by photosynthesis and producing organic matter.

Mazzuchelli et al. (2014MAZZUCHELLI, EHL.; SOUZA, GM.; PACHECO, AC. Rustificação de mudas de eucalipto via aplicação de ácido salicílico. Pesquisa Agropecuária Tropical, v. 44, n. 4, p. 443-450, 2014.) attribute that in order to make plants more resistant to variations in environmental conditions and the need to perform seedling rustification, because in this process the effect of water stress induced by water suspension can give a prediction of how plants respond to stress in adverse conditions in the field.

Regardless of the inoculation, plants of P. platycephala showed a reduction in height (HP) and stem diameter (SD) when submitted to water stress (Table 2), indicating a detrimental effect in these variables with a reduction in the water regime. These variables are important because they are associated with dry matter production. Thus, water stress may have interfered with growth variables (height, stem diameter, and number of leaves). Matos et al. (2018aMATOS, FS; FREITAS, IAS; SOUZA, BR; LOPES, VA; ROSA, VR. Crescimento de plantas de Tectona grandis sob restrição hídrica. Agrarian, v. 11, n. 39, p. 14-21, 2018a.) and Matos et al. (2018b)MATOS, F; FREITAS, IAS; SANTOS, LVB; VENÂNCIO, DG; SILVEIRA, PA. Initial growth of Dipteryx alata plants under water deficit. Revista Árvore, v. 42, n. 1, 2018b. assessed height, stem diameter, and number of leaves in plants of Tectona grandis and Dipteryx alata and observed a marked reduction in their vegetative growth when submitted to different levels of water stress. These authors reported that water stress could directly affect plant growth variables, reducing cell expansion, cell wall formation, and carbohydrate availability, which influence the production of growth regulators.

In this sense, the water stress applied to seedlings of P. platycephala resulted in lower water availability for cell expansion and plant metabolism, leading to low plant growth (Table 2). In addition, no significant difference (p>0.05) was observed for root length (RL) and total root volume (TRV) when treatments and water condition were assessed (Table 2).

The joint application of the studied water condition and AMF may result in a positive synergic effect on root dry matter (RDM) and total dry matter (TDM) in the plants (Table 3). The parameters RDM and TDM presented a significant interaction between mycorrhizal fungal strains and the condition with and without water stress (Table 3). Plants presented a difference in RDM and TDM when both water conditions were assessed in the strains A. morrowiae and G. rosea and in the inoculum Mix. Under the condition without water stress, the inoculation with the strain A. morrowiae provided a significant effect for RDM, with an average value of 0.40 g, differing from the other treatments. Regarding TDM, also under the condition without stress, the strains A. morrowiae and G. rosea and the inoculum Mix presented the highest average values, i.e. 1.37, 1.20, and 1.10 g, respectively (Table 3).

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TABLE 3
Average values of morphological variables of seedlings of Parkia platycephala inoculated with arbuscular mycorrhizal fungi (AMF) under water stress.

Under the condition without water stress, plants had higher values of SDM regardless of the treatment (Table 3). This same behavior was found by Farias et al. (2008FARIAS, S.G.G; FREIRE, A.L.O.; SANTOS, D.R.; SILVA, R.B.; FREIRE, J.L.O. Respostas de plantas de Moringa (Moringa oleifera Lam.) inoculadas com fungos micorrízicos e submetidos ao estresse hídrico. Engenharia Ambiental, v. 5, n. 3, p. 36-46, 2008. ) when assessing plants of Moringa oleifera Lam., in which the water stress effect may have contributed to a reduction in shoot dry matter of plants influenced by leaf abscission. According to Taiz et al. (2017TAIZ, L; MOLLER, EZM; MURPHY, A. Fisiologia e Desenvolvimento Vegetal. Artmed, 2017. 857p. ), a lower soil water availability can lead plants to water stress, causing morphological and physiological changes and, consequently, a lower dry matter gain by plants, reduction in cell expansion and leaf area, and a decrease in the root to shoot biomass ratio.

Sugai et al. (2011SUGAI, MAA.; COLLIER, LS.; SAGGIN-JÚNIOR, OJ. Inoculação micorrízica no crescimento de mudas de Angico em solo de cerrado. Revista Bragantia, v. 70, n. 2, p. 416-423, 2011.) in similar studies evaluating the growth of Anadenanthera macrocarpa (Benth.) Brenan seedlings under the effect of inoculation of arbuscular mycorrhizal fungi (AMFs) in preserved and anthropized soil, warned favorable results in plant growth, as well as in the nutritional part of the plant with the inoculation of different species of AMFs, regardless of the soil used. Since, the AMFs, play a fundamental role in the maintenance of forest systems, which can assist in the absorption of nutrients from the soil and directly influence the growth of plants.

Mycorrhizal colonization rate

The colonization rate reached 23.3% with the inoculation of the strain A. morrowiae (Figure 2). The percentage of mycorrhizal colonization in roots of plants of P. platycephala was influenced by AMF regardless of the studied water condition. The strains A. morrowiae, G. margarita, and G. rosea and the Mix differed (p<0.05) from A. koskei and control (without inoculation), but did not differ from each other. The strain A. koskei and control did not differ from each other, being less efficient regarding the mycorrhizal colonization rate in relation to the others (Figure 2).

FIGURE 2
Mycorrhizal colonization rate in plants of Parkia platycephala inoculated with arbuscular mycorrhizal fungi (AMF) under water stress. *Data transformed into square root of x+1. Means followed by the same letter do not differ from each other by Scott-Knott test at 5% probability.

Balota et al. (2010) and Brito et al. (2017BRITO, V.N.; TELLECHEA, F.R.F.; HEITOR, L.C.; FREITAS, M.S.M.; MARTINS, M.A. Fungos micorrízicos arbusculares e adubação fosfatada na produção de mudas de Paricá. Ciência Florestal, v. 27, n. 2, p. 485-497, 2017.) observed that the differential effect among AMF species occurs due to their ability to infect, colonize, and benefit the host plant and due to efficiency of absorbing P. In addition, when associated with host plants, AMF increase root surface area, giving the plant a higher capacity of water and nutrient absorption, favoring a higher growth and resistance rates.

According to the literature, our study presented a low colonization rate in plants of P. platycephala, which is in accordance with plants from the Caatinga biome, which reach around 50%. In this sense, the species Mimosa sp. has a colonization rate ranging from 19 to 32% and Mimosa caesalpiniaefolia Benth. has a colonization rate from 36 to 54% (Siqueira et al., 2010).

Nutritional contents of the plant shoot

In general, macro and micronutrients presented a decreasing order of K>Ca>Mg>P and Fe>Zn>Cu>Mn, respectively. These data show the order of preference of nutrients by P. platycephala, being possible to reach more balanced fertilization (Table 4). For macro and micronutrient contents in the shoot of P. platycephala, an interaction was observed between strains and conditions (with and without water stress) in the contents of P, Mg, and Mn (Table 4).

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TABLE 4
Macro and micronutrients in seedlings of Parkia platycephala inoculated with arbuscular mycorrhizal fungi (AMF) under water stress.

The best results for P were found in the treatments with G. rosea and inoculum of Mix under both stress condition, with an increase in P content from 236 to 282% under water stress in relation to the control (without inoculation). Under the condition without stress, the inoculation with these same strains showed an increase from 252 to 229% (Table 4).

Rodrigues et al. (2018RODRIGUES, LA.; BARROSO, DG.; FIQUEIREDO, FAMM de A. Fungos micorrízicos arbusculares no crescimento e na nutrição mineral de mudas de Tectona grandis L.F. RevistaCiência Florestal , v. 28, n. 1, p. 25-34, 2018.) in an analogous study when evaluating the effect of inoculation of mycorrhizal fungi on the growth and mineral nutrition of Tectona grandis seedlings in unsterilized soil, observed the P content in the leaves of the uninoculated seedlings (control) were higher than in plants inoculated with the tested AMFs inoculants, differing from the present study.

Muller et al. (2017MULLER, C.; HODECKER, BER.; MERCHANT, A.; BARROS, NF. Nutritional Efficiency of Eucalyptus Clones Under Water Stress. Revista Brasileira de Ciência do Solo , v. 41, n. e0160528, p. 1-17, 2017.) assessed nutrient absorption in plants of Eucalyptus citriodora and E. grandis under different moisture regimes and observed that plants that underwent water stress had lower averages of macro and micronutrients accumulated in the shoot. In this case, nutrient availability was reduced in the soil solution when plants were under stress, which is in accordance with the results found in our study. In addition, soil solution volume is reduced, which reduces the absorption rate by plants under water stress due to a higher water tension retained in the micropores and a dependence of high energy expenditure on plants (Scalon et al., 2011SCALON, SPQ; MUSSURY, RM; EUZÉBIO, VLMde; KODAMA, FM; KISSMANN, C. Estresse hídrico no metabolismo de crescimento inicial de mudas de Mutambo (Guazuma ulmifolia Lam.). Ciência Florestal , v. 21, n. 4. p. 655-662, 2011.).

For Mn content, treatments did not differ from each other under stress condition. However, under the condition without stress, only the control differed from the other treatments. For Mg content, the inoculum Mix and the control (without inoculation) presented the highest values in relation to the condition without water stress (Table 4). According to Stürmer et al. (2009)STÜRMER, SL; SIQUEIRA, JO. Species richness and spore abundance of arbuscular ycorrhizal fungi across distinct land uses in Western Brazilian Amazon. Mycorrhiza, v. 21, n. 4, p. 255-267, 2011., fungal hyphae capture several mineral nutrients, which are used in the physiological process of plants.

The highest contents of Cu and Fe were found in plants under the condition without water stress, regardless of the treatments. For Cu, the values found were 3.63 and 4.64 g kg⁻¹ under the conditions of stress and without stress, respectively. For Fe, the contents were 196.68 g kg⁻¹ under stress condition and 237.77 g kg⁻¹ without stress (Table 4). For Zn, no difference was observed for the studied water conditions. However, a difference was observed regarding treatments and the highest contents were observed in the strains A. morrowiae and G. rosea and in the inoculum Mix. No difference was observed in the contents of K and Ca regarding the different treatments under the assessed water conditions (Table 4).

Saboya et al. (2012SABOYA, RCC; JÚNIOR, AFC; MONETIRO, FPR; SANTOS, GR; ERASMO, EAL; CHAGAS, LFB. Fungos micorrízicos arbusculares afetando a produção de mudas de Pinhão-manso na região Sul do Estado de Tocantins, Brasil. Revista Ceres, v. 59, n. 1, p. 142-146, 2012.) assessed the production of seedlings of Jatropha curcas L. inoculated with Scutellospora calospora, Glomus clarum, G. margarita, A. morrowiae, and mycorrhizal species (Mix) and observed that the contents of micronutrients in the plant shoot did not present significant differences for Fe and Zn. This result differs from that found in our study in relation to Zn, which presented a difference between treatments with inoculation. The authors observed that Mn and Mg contents presented better results when plants were inoculated with the strain A. morrowiae even without full fertilization, showing the efficiency of AMF even with the inoculation in isolation.

According to Miranda et al. (2008MIRANDA, JCC. Cerrado: Micorriza arbuscular - ocorrência e manejo. Embrapa Cerrados, 2008. 169p. ) and Faria et al. (2013FARIA, M.T.; SCABORA, M.H.; MALTONI, K.L.; CASSIOLATO, A.M.R. Micorrização e crescimento de progênies de Hymenaea stignocarpa Mart. ex. Hayne em subsolo de área degradada. Ciência Florestal , v. 23, n. 1, p. 233-243, 2013.), AMF maximize the absorption efficiency of low-mobility nutrients in the soil, especially P and Zn, making them more available to plants, reaching the roots through the diffusion process and allowing plant growth even in extremely poor soils.

Information on the mycorrhizal association with P. platycephala and the relationship with edaphoclimatic conditions in the Cerrado-Caatinga transition area is still limited. However, the data obtained in this study can be used in further studies, being important for the interest and motivation in the sustainable agricultural system.

CONCLUSION

The morphological variables plant height, stem diameter, and shoot dry matter of plants presented a reduction when submitted to water stress. In addition, an interaction was observed between AMF and the studied water condition for the variables number of leaves, root dry matter, and total dry matter.

Plants with water stress presented a lower absorption of macro and micronutrients in relation to the condition without stress. An interaction was observed for P, Mg, and Mn. The inoculation with mycorrhizal fungi provided a difference in Zn contents in the leaves of P. platycephala.

The mycorrhizal colonization rate of P. platycephala was influenced by AMF regardless of water conditions, being considered low at 120 days of cultivation under the studied conditions.

ACKNOWLEDGEMENTS

To the Coordination for the Improvement of Higher Education Personnel (Capes) and the Federal University of Piauí (UFPI) for financial support and collaboration in this study.

To the Regional University of Blumenau (FURB) for donate the arbuscular mycorrhizal fungi strains.

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HIGHLIGHTS

Plants with water stress presented a lower absorption of macro and micronutrients in relation to the condition without stress.
Mycorrhizal fungi favored plant growth as well as the absorption of nutrients.
The mycorrhizal colonization rate of P. platycephala was influenced by AMF regardless of water conditions.

Publication Dates

Publication in this collection
17 June 2020
Date of issue
Jan-Mar 2020

History

Received
17 Oct 2019
Accepted
21 Jan 2020

/This is an open-access article distributed under the terms of the Creative Commons Attribution License, which permits unrestricted use, distribution, and reproduction in any medium, provided the original work is properly cited.

[1] ALVAREZ, V.V.H; RIBEIRO, A.C. Recomendações para o uso de corretivos e fertilizantes em Minas Gerais. In: RIBEIRO, AC. et al. UFV, 1999. p. 43-60.

[2] BORGES, A.J.S.; TRINDADE, A.V.; MATOS, A.P.; PEIXOTO, M.F.S. Reduction of fusarium wilt of “banana-maçã” by inoculation of arbuscular mycorrhizal fungi. Pesquisa Agropecuária Brasileira, v. 42, n. 1, p. 35-41, 2007.

[3] BRITO, V.N.; TELLECHEA, F.R.F.; HEITOR, L.C.; FREITAS, M.S.M.; MARTINS, M.A. Fungos micorrízicos arbusculares e adubação fosfatada na produção de mudas de Paricá. Ciência Florestal, v. 27, n. 2, p. 485-497, 2017.

[4] CANEIRO, R.F.V.; JÚNIOR, F.M.C.; ARAÚJO, A.S.F.; FILHO, C.H.A.R.; SOUSA, R.F. Atributos dos fungos micorrízicos arbusculares como indicadores de áreas degradadas e em recuperação no estado do Piauí. Revista Brasileira de Agroecologia, v. 11, n. 2, p. 61-69, 2016.

[5] COSTA, A.S.; FREIRE, A.L.O.; BAKKE, I.A.; PEREIRA, F.H.F.Respostas fisiológicas e bioquímicas de plantas de aroeira (myracrodruon urundeuva allemão) ao déficit hídrico e posterior recuperação. Irriga, v. 20, n. 4, p. 705-717, 2015.

[6] DUARTE, E.A.; FILHO, P.A.M.; SANTOS, R.C. Características agronômicas e índice de colheita de diferentes genótipos de amendoim submetidos a estresse hídrico. Revista Brasileira de Engenharia Agrícola e Ambiental, v. 17, n. 8, p. 843-847, 2013.

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pH (H2O)	H+Al	Al	Ca	Mg	Ca+Mg	K	SB	CEC	P
	---------------- cmolc.dm⁻³ ---------------								mg.dm⁻³
4.6	3.47	0.2	0.53	0.13	0.66	0.1	0.77	4.23	1.75
Cu	Fe	Mn	Zn	V	m	SOM	Clay	Silt	Sand
------mg.dm⁻³------				----%----		-----g.kg⁻¹ -------
0.97	85.37	7.13	1.75	18.1	20.7	6	69	11	920

Fungus	HP			SD			NL			RL			TRV
	S(1)	WS(2)	Mean	S	WS	Mean	S	WS	Mean	S	WS	Mean	S	WS	Mean
	---------- cm ----------			---------- mm ---------			------ leaves plant⁻¹ -----			-------- cm ---------			---------- mL ----------
Control	16.7	19.0	17.8	2.1	2.3	2.2	5.9Bb	6.9Aa	6.4	25.2	25.7	25.4	1.0	1.0	1.0
A. koskei	17.9	20.2	19.0	2.3	2.5	2.4	5.5Bb	6.6Aa	6.1	25.9	28.2	27.0	1.0	1.8	1.4
A. morrowiae	17.9	25.3	21.6	2.1	2.8	2.4	6.2Bb	7.5Aa	6.9	27.2	26.2	26.7	1.1	0.83	0.96
G. margarita	17.4	18.9	18.1	2.2	2.5	2.5	5.7Bb	6.8Aa	6.2	27.8	28.7	28.3	0.8	1.0	0.91
G. rosea	18.8	21.8	20.2	2.3	2.4	2.3	7.3Aa	7.3Aa	7.3	27.8	25.7	26.7	1.2	1.4	1.3
Mix	17.2	21.9	19.5	2.0	2.4	2.2	6.3Ba	6.5Aa	6.4	24.9	26.3	25.6	0.76	0.8	0.78
Mean	17.6b	21.2a		2.2b	2.5a		6.2	6.9		26.5	26.8		0.98	1.1
F (analysis of variance)
Fungus (F)	1.94ns			1.9ns			2.28ns			0.75ns			1.83ns
Condition (C)	16.83**			28.48**			36.12**			0.12ns			0.78ns
F × C	1.07ns			0.08ns			2.82*			0.44ns			0.61ns
CV Fungus (%)	16			10			14			14			52
CV Condition (%)	17			8			8			14			68

Fungus	SDM		Mean	RDM		Mean	TDM		Mean
Fungus	S(1)	WS(1)	Mean	S	WS	Mean	S	WS	Mean
	----------------------------------- g -------------------------------------
Control	0.46	0.78	0.62	0.15Aa	0.22Ba	0.19	0.61Aa	0.66Ba	0.64
A. koskei	0.58	0.77	0.68	0.21Aa	0.28Ba	0.24	0.79Aa	0.85Ba	0.82
A. morrowiae	0.51	0.97	0.74	0.18Ab	0.40Aa	0.29	0.69Ab	1.37Aa	1.03
G. margarita	0.55	0.66	0.60	0.20Aa	0.26Ba	0.23	0.75Aa	0.92Ba	0.83
G. rosea	0.61	0.91	0.76	0.19Ab	0.29Ba	0.24	0.80Ab	1.20Aa	1.00
Mix	0.48	0.80	0.64	0.15Ab	0.30Ba	0.23	0.63Ab	1.10Aa	0.87
Mean	0.53b	0.81a		0.18	0.29		0.71	1.02
	F (analysis of variance)
Fungus (F)	0.53ns			1.90ns			5.63**
Condition (C)	19.05**			54.30**			36.00**
F × C	0.55ns			3.00*			3.97**
CV F (%)	42			33			22
CV C (%)	37			25			23

MACRONUTRIENTS
Fungus	P		Mean	K		Mean	Ca		Mean	Mg	Mean
	S(1)	WS(2)	Mean	S	WS	Mean		S	Mean	WS	Mean	S	WS
	------------------------------------- g.kg⁻¹ -------------------------------------------
Control	0.11Cb	0.21Da	0.31	25.70	19.61	22.65	9.40	10.48	9.94	2.46Aa	3.12Aa	2.80
A. koskei	0.22Bb	0.43Ca	0.34	29.10	22.82	28.96	9.89	10.36	10.13	2.62Aa	2.66Ba	2.64
A. morrowiae	0.24Bb	0.58Ba	0.55	29.40	26.50	27.95	10.25	10.32	10.28	2.81Aa	2.35Ba	2.58
G. margarita	0.28Bb	0.17Da	0.19	18.70	21.85	20.27	10.01	8.26	9.14	2.61Aa	2.15Ba	2.38
G. rosea	0.37Ab	0.74Aa	0.55	31.64	30.51	31.07	11.86	10.66	11.26	2.78Aa	2.42Ba	2.60
Mix	0.42Ab	0.69Aa	0.49	22.50	29.57	26.03	8.16	9.69	8.93	2.25Ab	3.23Aa	2.74
Mean	0.33	0.56		26.17	26.14		9.93	9.96		2.59	2.66
	F (analysis of variance)
Fungus (F)	74.73**			1.83ns			0.33ns			0.48ns
Condition (C)	3.15*			0.02ns			0.00ns			0.21ns
F × C	13.85**			0.90ns			0.53ns			3.05*
CV F (%)	16			36			24			25
CV C (%)	21			29			28			22
MICRONUTRIENTS
	Cu		Mean	Mn#			Mean	Fe		Mean	Zn	Mean
	S(1)	WS(2)	Mean	S	WS	S	Mean	WS	S	Mean	WS	Mean
-------------------------------------- mg.kg⁻¹ -----------------------------------------
Control	4.13	5.46	4.80	0.80Ab	1.85Aa	1.32	183.21	289.44	236.33	13.62	10.18	11.90B
A. koskei	3.68	3.89	3.79	1.17Aa	1.17Ba	1.17	214.91	236.10	225.51	11.63	13.17	12.40B
A. morrowiae	4.35	3.93	4.64	0.80Ab	1.55Bb	1.18	226.68	225.81	226.25	16.75	18.87	17.81A
G. margarita	2.77	4.00	3.39	1.02Aa	1.08Ba	1.05	174.07	218.01	196.04	9.88	14.96	12.42B
G. rosea	3.73	5.15	4.44	0.80Aa	0.80Ba	0.80	209.60	294.49	252.05	19.19	21.96	20.58A
Mix	3.14	4.40	3.77	1.00Aa	0.80Ba	0.90	171.60	162.75	167.18	13.99	11.83	12.91A
Mean	3.63b	4.64a		1.12	1.45		196.68b	237.77a		14.18	15.16
	F (analysis of variance)
Fungus (F)	0.77ns			1.73ns			196.68b	1.10ns			15.16	3.66**
Condition (C)	5.56*			0.25ns			4.60*			14.18	0.42ns
F × C	0.22ns			3.85**			0.98ns			0.74ns
CV F (%)	49			44			42			41
CV C (%)	40			37			34			40