Nitrogen-fixing bacteria and arbuscular mycorrhizal fungi in <i>Piptadenia gonoacantha</i> (Mart.) Macbr.

Oliveira, Joel Quintino de; Jesus, Ederson da Conceição; Lisboa, Francy Junio; Berbara, Ricardo Luis Louro; Faria, Sergio Miana de

doi:10.1016/j.bjm.2016.10.013

Abstract

The family Leguminosae comprises approximately 20,000 species that mostly form symbioses with arbuscular mycorrhizal fungi (AMF) and nitrogen-fixing bacteria (NFB). This study is aimed at investigating and confirming the dependence on nodulation and biological nitrogen fixation in the specie Piptadenia gonoacantha (Mart.) Macbr., which belongs to the Piptadenia group. Two consecutive experiments were performed in a greenhouse. The experiments were fully randomized with six replicates and a factorial scheme. For the treatments, the two AMF species and three NFB strains were combined to nodulate P. gonoacantha in addition to the control treatments. The results indicate this species’ capacity for nodulation without the AMF; however, the AMF + NFB combinations yielded a considerable gain in P. gonoacantha shoot weight compared with the treatments that only included inoculating with bacteria or AMF. The results also confirm that the treatment effects among the AMF + NFB combinations produced different shoot dry weight/root dry weight ratios. We conclude that AMF is not necessary for nodulation and that this dependence improves species development because plant growth increases upon co-inoculation.

Keywords:
Synergy; Nodulation; Biological nitrogen fixation; “Pau-jacaré”

Introduction

The family Leguminosae comprises approximately 3000 species throughout Brazil and is the third largest angiosperm family, with approximately 20,000 species and 700 genera,¹1 Lewis G, Schirire BD, Mackinder BA, Lock JM. Legumes in the World. Kew, UK: Royal Botanic Gardens; 2005. only surpassed by Orchidaceae and Asteraceae.²2 Moreira FMS, Siqueira JO. Microbiologia e Bioquímica do Solo. 2ed. Lavras: Editora UFLA; 2006. Most species are associated with nitrogen-fixing microorganisms and arbuscular mycorrhizal fungi (AMF),³3 Carneiro MAC, Siqueira JO, Moreira FMS, Carvalho D, Botelho SA, Saggin-Junior OJ. Micorriza arbuscular em espécies arbóreas e arbustivas nativas de ocorrência no sudeste do Brasil. Cerne. 1998;4:129-145.^,⁴4 de Faria SM, Diedhiou AG, Lima HC, et al. Evaluation the nodulation status of leguminous species from the Amazonian forest of Brazil. J Exp Bot. 2010;62:3119-3127. which are the two main symbiotic microorganisms in terrestrial plants. New microbial species and rhizobia plant infection mechanisms were discovered through studying this bacterial diversity.⁵5 Moulin L, Munive A, Dreyfus B, Boivin-Masson C. Nodulation of legumes by members of the β-subclass of Proteobacteria. Nature. 2001;411:948-950.^,⁶6 Chen WM, James EK, Prescott AR, Kierans M, Sprent JI. Nodulation of Mimosa spp. by the β-proteobacterium Ralstonia taiwanensis. Mol Plant-Microbe Interact. 2003;16:1051-1061. Certain native legume species in the subfamily Mimosoideae exhibit atypical characteristics with a high exploitation potential for the two symbioses. Synergy between the symbionts has also been reported; mycorrhizal fungi can aid in increasing biological nitrogen fixation, and nitrogen-fixing bacteria influence mycorrhizal colonization.⁷7 Berbara RLL, Souza FA, Fonseca HMAC. Fungos Micorrízicos Arbusculares: Muito Além da Nutrição. In: Fernandes MS, ed. Nutrição Mineral de Plantas. Viçosa, MG: SBCS; 2006:355–374.^,⁸8 Bournaud C. Biodiversité des rhizobiums et interactions tripartites dans le groupe Piptadenia (tribu des Mimoseae). Universite Montpellier 2. Sciences et Techniques du Languedoc; 2012.

The species studied herein, Piptadenia gonoacantha (Mart.) J. F. Macbr., is arboreal and naturally occurs in southern and southeastern Brazil. It is economically and socially useful because it is used in the furniture construction, energy, cellulose, and paper sectors, among other fields.¹⁰10 Carvalho PER. Pau Jacaré-Piptadenia gonoacantha. Colombo, PR: Embrapa Florestas. (Circular Técnica 91); 2004. This species is also used considerably in degraded site restoration projects because it can biologically fix nitrogen.¹¹11 Jesus EC, Schiavo JA, de Faria SM. Dependência de micorrizas para a nodulação de leguminosas arbóreas tropicais. R Árvore. 2005;29:545-552.

A recent discovery showed that the legumes P. gonoacantha and Piptadenia paniculata, both Atlantic Rainforest natives,¹²12 Lorenzi H. Árvores brasileiras: manual de identificação e cultivo de plantas arbóreas nativas do Brasil I. Harri Lorenzi. Nova Odessa, SP: Editora Plantarum; 1992. did not nodulate in pots with soil and sand as substrates when they were not co-inoculated with AMF.¹¹11 Jesus EC, Schiavo JA, de Faria SM. Dependência de micorrizas para a nodulação de leguminosas arbóreas tropicais. R Árvore. 2005;29:545-552. Asai¹³13 Asai T. About mycorrhizas and leguminous plants. Jpn J Bot. 1944;13:463-483. reported this observation and indicated that certain legumes do not nodulate in autoclaved soils without co-inoculation by mycorrhizal fungi. Crush¹⁴14 Crush JR. Plant growth responses to vesicular-arbuscular mycorrhizas. VII. Growth and nodulation of some herbage legumes. New Phytol. 1974;73:743-749. provided the first conclusive observations on this synergistic effect.

However, the effects of the substrates on symbiosis formation remains uncertain; most likely, an underabundance of phosphorus limits symbiosis formation even if mycorrhizae are necessary for nodulation because phosphorus is important for forming nodules in the root system. In addition to affecting nodulation, the mycorrhizal fungus aids in better development of the plant species because biological nitrogen fixation demands high levels of energy, which is provided by the plant as ATP. However, the great phosphorus deficiency in tropical soils limits the maximum development of the symbiosis. Thus, increased phosphorus absorption by AMF yields increased fixation.²2 Moreira FMS, Siqueira JO. Microbiologia e Bioquímica do Solo. 2ed. Lavras: Editora UFLA; 2006.^,⁸8 Bournaud C. Biodiversité des rhizobiums et interactions tripartites dans le groupe Piptadenia (tribu des Mimoseae). Universite Montpellier 2. Sciences et Techniques du Languedoc; 2012.

The synergistic effect between the symbionts is evident from the phosphorus concentration in the nodules, which is up to three times higher than in other organs.¹⁵15 Vadez V, Beck DP, Lasso JH, Drevon JJ. Utilization of the acetylene reduction assay to screenfor tolerance of symbiotic N2 fixation to limiting P nutrition in common bean. Physiol Plant. 1997;99:227-232. This link is also attributed to the number of genes and root exudates that the symbioses share. This evidence supports the hypothesis that the symbioses formed with legume family species were inherited from mycorrhizal fungi because two forms of symbiosis emerged at different evolutionary times during colonization by terrestrial plants.¹⁶16 Fougnies L, Renciot S, Muller F, et al. Arbuscular mycorrhizal colonization and nodulation improve flooding tolerance in Pterocarpus officinalis Jacq. seedings. Mycorrhiza. 2006;7(1):159-166. From a functional perspective, bacterial and AMF compatibility can also alter symbiotic efficiency because the combination of inoculating with AMF and bacterial strains can either reduce or increase efficiency in certain bacterial strains.¹⁷17 Siqueira JO, Souza FA, Cardoso EJBN, Tsai SM. Micorrizas: 30 anos de pesquisa no Brasil. Lavras: Editora UFLA; 2010, 716 pp.^,⁸8 Bournaud C. Biodiversité des rhizobiums et interactions tripartites dans le groupe Piptadenia (tribu des Mimoseae). Universite Montpellier 2. Sciences et Techniques du Languedoc; 2012.^,⁹9 Bonfante P, Anca I-A. Plants, Mycorrhizal Fungi and Bacteria A network of interactions. Annu Rev Microbiol. 2009;63:363-383.

This study is based on the hypothesis that the species P. gonoacantha depends on the mycorrhizal fungus for nodule formation, hypothesis described by the author Jesus et al.¹¹11 Jesus EC, Schiavo JA, de Faria SM. Dependência de micorrizas para a nodulação de leguminosas arbóreas tropicais. R Árvore. 2005;29:545-552. Thereby, the article aimed at investigate and confirm the dependence of the specie on arbuscular mycorrhizal fungi for nodulation and biological nitrogen fixation.

Materials and methods

The experiments were conducted in a greenhouse located at Embrapa Agrobiology (Embrapa Agrobiologia), Seropédica, Rio de Janeiro (RJ), Brazil. The species P. gonoacantha (Mart.) Macbr. was used. The bacterial strains BR 4802, BR 4812, and BSP1 were obtained from the Centro de Recursos Biológicos Johanna Döbereiner at the Embrapa Agrobiology and were grown for two days in tryptone yeast (TY) liquid medium at 28 °C and 150 rpm. Thereafter, the cultures were centrifuged at 10,000 rpm and 4 °C for 10 min. The pellet was resuspended in a 10 mM manganese sulfate solution (MgSO₄·7H₂O). This centrifugation step was repeated three times. The optical density of the strains was adjusted to 1.0, which corresponds to 10⁸ cells mL⁻¹.

The AMF inocula were obtained from the Arbuscular Mycorrhizal Fungi Collection of the Embrapa Agrobiology (Coleção de Fungos Micorrízicos Arbusculares da Embrapa Agrobiologia - COFMEA), and two species were selected: Gigaspora margarita W.N. Becker & I.R. Hall (A1 CNPAB 001) and Dentiscutata heterogama T.H. Nicolson & Gerd. Sieverd (A2 CNPAB 02). The spores were extracted using the wet sieving method¹⁸18 Gedermann JW, Nicolson TH. Spores of Mycorrhizal Endogene species extracted from soil by wet sieving and decanting. Trans Br Mycol Soc. 1963;46:235-244. and centrifuged with sucrose.¹⁹19 Daniels BA, Skipper HD. Methods for the recovery and quantitative estimation of propagules from soil. In: Schenk NC, ed. Methods and Principles of Mycorrhizal Research. St. Paul: American Phytopathological Society; 1982:29–35.^,²⁰20 Nicolson TH. Spores of Mycorrhizal Endogene species extracted from soil by wet sieving and decanting. Trans Br Mycol Soc. 1963;46:235-244. The spores were separated into Petri dishes, and the inocula purity was verified using a stereoscopic microscope. The spores were disinfected following the method described by Colozzi-Filho.²¹21 Colozzi-Filho A, Siqueira JO, Oliveira E. Desinfestação de esporos de fungos micorrízicos vesicular-arbusculares I - Efeito da concentração e tempo de exposição de agentes desinfestantes e antibióticos. Pesqui Agropecu Brasil. 1994;29:1119-1127. The sterilized spores were maintained in the Petri dishes with 79 medium²²22 Vincent JM. A Manual for the Practical Study of Root-nodule Bacteria. IBP Handbook 15. Oxford: Blackwell Scientific Publications; 1970. for one week to verify the disinfection efficiency. The spores were applied to pots by diluting the spores extracted in distilled water. The spore quantity was standardized to 50 spores per mL, and 1.0 mL of this solution was applied to each pot. The P. gonoacantha (Mart.) Macbr. seeds were surface disinfected with 30% hydrogen peroxide for two minutes and then germinated in Petri dishes with filter paper and cotton for four days at 28 °C in a germinating chamber under constant light.

Two experiments using P. gonoacantha (Mart.) Macbr. were performed. The first experiment featured a completely randomized design with eight treatments and six replicates. This experiment comprised treatments with the following inoculants: a mycorrhizal fungus, the bacterial strains, and a combination of both microorganisms (mycorrhizal fungus + bacterial strains). In addition to the treatments, control experiments were performed (an absolute control, a nitrogen control, and a nitrogen control with AMF). The Burkholderia sp strains BR 4802 and BR 4812 were used. The mycorrhizal fungus G. margarita (Gig.marg) was used.

The experiment was performed in a greenhouse in Magenta pots (pots transparent acrylic, square base and with the volume of 400 mL) containing sterile sand and vermiculite at a 1:1 ratio (v:v) and a nitrogen-free nutrient solution. Every two weeks, each seedling was fertilized with 100 mL of a nutrient solution containing the following (mg L⁻¹): 2 mM CaCl₂(H₂O)₂, 1 mM MgSO4(H₂O)₇, 3 mM KCl, 0.9 µM ZnSO₄(H₂O)₇, 4 µM H₃BO₃, 1 µM CuSO₄(H₂O)₅, 6 µM MnSO₄H₂O, 0.1 µM NaMoO₄(H₂O)₂, and 1.66% Fe EDTA.²³23 Bertrand H, Plassard C, Pinochet X, Touraine B, Normand P, Cleyet-Marel JC. Stimulation of the ionic transport system in Brassica napus by a plant growth-promoting rhizobacterium (Achromobacter sp.). Can J Microbiol. 2000;46:229-236. The plants were watered to maintain a moisture content near the 70% field capacity of the containers. Each pot received two seeds. Before planting the seeds, each hole was inoculated with 10⁸ cells of each bacterial strain and 50 mycorrhizal fungal spores and then with seeds. Thinning was performed soon thereafter to homogenize the species’ development. The nitrogen controls received 100 mg of N/plant (ammonium nitrate solution - NH₄NO₃) until the end of the experiment. The experimental plants were harvested 150 days after sowing.

The second experiment featured a fully randomized design with eleven treatments and six replicates. It comprised treatments with the following inoculants: mycorrhizal fungi, bacterial strains, and a combination of both microorganisms (mycorrhizal fungi + bacterial strains). In addition to the treatments, we also used two different controls (an absolute control and a nitrogen control with AMF). The Burkholderia sp strains BR 4802 and BSP1 were used, and the mycorrhizal fungi G. margarita (Gig.marg) and D. heterogama (Dent.het) were used.

The experiment was performed in a greenhouse in Magenta pots containing sterile sand and vermiculite at a 1:1 ratio (v:v) and a N-free nutrient solution. The seeds were inoculated with 10⁸ cells of each bacterial strain and 50 spores of each mycorrhizal fungal species. The nitrogen controls received 70 mg of N/plant (ammonium nitrate solution - NH₄NO₃) throughout the experiment. The experimental plants were harvested 77 days after sowing. We added N to a separate solution at 5 mg of N/plant. Initially, 20 mg of N, 4 mL of the solution, was applied.

The following were determined in both experiments: shoot dry weight, root dry weight, nodule dry weight, and mycorrhization rate. The number of replicates was divided among the variables root dry weight and mycorrhization rate, three for each analysis. The six replicates were used to evaluate shoot dry weight.

The data were transformed due to an absence of normality; we used the following formula: the square root of the variable plus one. The shoot dry weight of each inoculation treatment was compared with the absolute control weight that did not receive a treatment, which was used to calculate the efficiency. The shoot dry weight of each inoculation treatment was compared with the nitrogen control that induced the highest weight increase, which was used to determine the efficacy.

The efficiency and efficacy of each inoculation treatment were calculated using the following formulas¹¹11 Jesus EC, Schiavo JA, de Faria SM. Dependência de micorrizas para a nodulação de leguminosas arbóreas tropicais. R Árvore. 2005;29:545-552.:

Efficiency = (\frac{Treat SDW}{Abscontrol SDW}) \times 100

where Treat SDW = shoot dry weight of the inoculated treatment, and Abscontrol SDW = shoot dry weight of the absolute control;

Efficacy = (\frac{Treat SDW}{Nitrocontrol SDW}) \times 100

where Treat SDW = shoot dry weight of the inoculated treatment, and Nitrocontrol SDW = shoot dry weight of the nitrogen control.

Next, the data were subjected to analyses of variance (ANOVA), and the means were compared with Tukey's test at a 5% probability using the SISVAR software.²⁴24 Ferreira DF. Sistema para análise de variância para dados balanceados (Sisvar). versão 4.3. Lavras: UFLA; 2003.

Root colonization was evaluated in fine root samples that were clarified and stained using the methods from Koske and Gemma²⁵25 Koske RE, Gemma JN. A modified procedure for staining roots to detect VA mycorrhizas. Mycol Res. 1989;92:486-488. and Grace and Stribley.²⁶26 Grace C, Stribley DP. A safer procedure for routine staining of vesicular-arbuscular mycorrhizal fungi. Mycol Res. 1991;95:1160-1162. Mycorrhization was evaluated using the root/grid intersect method from Giovannetti and Mosse,²⁷27 Giovanetti M, Mosse B. An evaluation of techniques for measuring vesicular-arbuscular mycorrhizal infection in roots. New Phytol. 1980;64(3):489-500. which was adapted from the root length measurement method in Newman.²⁸28 Newman EI. A method of estimating the total length of root in a sample. J Appl Ecol. 1966;3(2):139-145.

Results

First experiment

The inoculated plants only nodulated with the BR 4802 strain, regardless of whether the mycorrhizal fungus was present. The highest accumulated shoot dry weight was measured when the plants were co-inoculated with G. margarita and the BR 4802 strain. This treatment also exhibited the highest symbiotic efficiency (Table 1). The plants only responded to nitrogen fertilizer in the presence of AMF. The colonization rates were 12, 18, and 28% for the G. margarita inoculation, with and without N, and G. margarita and BR 4802 strain co-inoculation treatments, respectively.

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Table 1
The effect of co-inoculation on Piptadenia gonoacantha development. Mean of three replicates.

Second experiment

Root colonization by D. heterogama was greater when the bacterial strains were present. The fewest nodules were observed with the D. heterogama + BSP1 treatment. This strain exhibited variable behavior; it promoted greater nodulation without the mycorrhizal fungus. The G. margarita + BSP1 treatment promoted approximately three times more nodules than the D. heterogama + BSP1 treatment. This effect with the different fungal species was not observed for symbiosis with the other strain. The species G. margarita promoted different effects between the strains, reducing the number of nodules with the BSP1 strain and increasing the number of nodules with the BR 4802 strain upon co-inoculation (Table 2).

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Table 2
Nodule number, nodule dry weight (NDW), and mycorrhizal colonization rate in the inoculation treatments with without adding the mycorrhizal fungus of the second experiment using Piptadenia gonoacantha and the mycorrhization rate. Mean of three replicates.

The co-inoculation treatments using the BSP1 and BR 4802 strains as well as D. heterogama increased the shoot dry weight; however, the nodule weights were low. The species D. heterogama (T.H. Nicolson & Gerd.) interacted positively with both bacterial strains, which suggests greater genetic compatibility. The treatments co-inoculated with the D. heterogama fungus and the bacteria, respectively, exhibited 10× and 8× more accumulated dry weight than the absolute control as indicated by the efficiency values and 7× and 6× more accumulated dry weight than the control upon inoculation with D. heterogama and the mineral N as indicated by the efficacy values (Table 3).

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Table 3
The effect of co-inoculation on Piptadenia gonoacantha development. Mean of three replicates. Means followed by the same letter in the column do not differ at a 5% probability level by Tukey's test.

The SDW/ROOT ratios significantly differed, ranging between 0.48 and 2.16. The treatments that included BSP1 strain inoculation combined with the two mycorrhizal fungal species exhibited the highest SDW/ROOT ratios. The G. margarita + BSP1 treatment exhibited a ratio close to 2, which suggests that co-inoculation favors greater shoot development. This same fungal species yielded lower ratios than the absolute control when co-inoculated with the BR 4802 strain. When this same strain was co-inoculated with the two mycorrhizal fungal species, we observed development equivalent to that of the absolute control (Table 4).

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Table 4
Comparative analysis between the SDW/ROOT ratios and between the treatments that yielded the greatest weight gain with the species Piptadenia gonoacantha. Mean of three replicates. Means followed by the same letter in the column did not differ at a 5% probability level using the Scott Knott test.

Discussion

Jesus et al.¹¹11 Jesus EC, Schiavo JA, de Faria SM. Dependência de micorrizas para a nodulação de leguminosas arbóreas tropicais. R Árvore. 2005;29:545-552. indicated that P. gonoacantha is highly dependent on AMF, especially for nodulation. However, the present study suggests otherwise because plants from this species nodulated without the mycorrhizal fungus, which was also observed by Bornaud et al.⁸8 Bournaud C. Biodiversité des rhizobiums et interactions tripartites dans le groupe Piptadenia (tribu des Mimoseae). Universite Montpellier 2. Sciences et Techniques du Languedoc; 2012. Most likely, the different substrates in the studies affected the results; however, the phosphorus source may have been more crucial to the results than the substrate. Jesus et al.¹¹11 Jesus EC, Schiavo JA, de Faria SM. Dependência de micorrizas para a nodulação de leguminosas arbóreas tropicais. R Árvore. 2005;29:545-552. used a small quantity of a slightly soluble source, rock phosphate; however, a nutrient solution with readily available phosphorus was used herein.

Analyzed together, the results of these two experiments indicate that “pau-jacaré”(P. gonoacantha (Mart.) J. F. Macbr) greatly depends on mycorrhizae for growth and requires AMF when phosphorus is a limiting factor. However, when phosphorus is readily available, the plant no longer depends on the fungus to grow and can nodulate without it. However, this does not mean that co-inoculation is not important because visual observations of the nodules from plants not inoculated with AMF indicate that these nodules are amorphous. This amorphous characteristic indicates that the fungus leads to morphological changes and altered efficiency in these nodules, as demonstrated by the acetylene reduction assay in plants with and without the mycorrhizal fungus. Further, this characteristic is evident in the scientific literature, which indicates a positive interaction between the fungus and bacteria; bacteria favor colonization of P. gonoacantha roots by AMF,⁸8 Bournaud C. Biodiversité des rhizobiums et interactions tripartites dans le groupe Piptadenia (tribu des Mimoseae). Universite Montpellier 2. Sciences et Techniques du Languedoc; 2012. and the fungus favors bacterial efficiency.²⁹29 Barea JM, Azcón R, Azcón-Aguilar C. Vesicular-Arbuscular Mycorrhizal fungi in nitrogen fixing system. In: Norris JR, Read DJ, Varma AK, eds. Methods in Microbiology: Techniques for Study of Mycorrhizae. London: Academic Press; 1992:391–416.

The different results for the different bacteria-AMF combinations indicate that certain combinations are more efficient than others, which suggests a certain specificity between the symbiotic microorganisms. These data corroborate Bournaud,⁸8 Bournaud C. Biodiversité des rhizobiums et interactions tripartites dans le groupe Piptadenia (tribu des Mimoseae). Universite Montpellier 2. Sciences et Techniques du Languedoc; 2012. who observed that the mycorrhizal colonization rate of P. gonoacantha roots varied due to a co-inoculated rhizobial strain. The colonization rate in the different experiments may reflect strategic mycorrhizal colonization because D. heterogama should promote higher colonization of the root system compared with the fungal species with larger diameter spores relative to the duration of each experiment (G. margarita). The short duration of the experiments may have produced the different results for the different strategies. Fungal species under the K strategy establish in the root system over a longer time period due to the longer duration required for germination and development as well as the low number of spores produced, which was observed for G. margarita (W.N. Becker & I.R. Hall), exhibiting the lowest colonization rates.

According to the efficiency and efficacy results in the second experiment, the D. heterogama and BSP1 strain combination promoted an approximately 10× higher gain in shoot weight, which demonstrates a high recommendation potential.³⁰30 Bethlenfalvay JG, Pacovsky JG, Bayne GH, Stafford AE. Interactions between nitrogen fixation, mycorrhizal colonization, and host-plant growth in the phaseolus-rhizobium-glomus symbiosis. Plant Physiol. 1982;70:446-450. These results corroborate results from Bournaud et al.,⁸8 Bournaud C. Biodiversité des rhizobiums et interactions tripartites dans le groupe Piptadenia (tribu des Mimoseae). Universite Montpellier 2. Sciences et Techniques du Languedoc; 2012. who observed that the BSP1 strain provides the highest shoot growth, nodulation, and efficiency in co-inoculated P. gonoacantha plants. However, the author used Rhizophagus clarus (T.H. Nicolson & N.C. Schenck) C. Walker & A. Schübler. The plants inoculated with the BSP1 strain exhibited slightly higher root mycorrhization than plants inoculated with the same fungus plus the BR 4802 strain. These data also corroborate the results from Bournaud et al.,⁸8 Bournaud C. Biodiversité des rhizobiums et interactions tripartites dans le groupe Piptadenia (tribu des Mimoseae). Universite Montpellier 2. Sciences et Techniques du Languedoc; 2012. who observed that the BSP1 strain encourages root colonization by AMF and consequently increases nodule efficiency. Here, the effect observed for R. clarus was observed for D. heterogama. However, the accumulated dry weight and mycorrhizal colonization values were lower in plants inoculated with G. margarita, which indicates that the different fungus-bacteria combinations may not necessarily exhibit a positive effect on P. gonoacantha plant development.

Co-inoculation does not ensure better development as observed herein. For example, Patreze et al.³¹31 Patreze CM, Cordeiro L. Nitrogen-fixing and vesicular-arbuscular mycorrhizal symbioses in some tropical legume trees of tribe Mimoseae. For Ecol Manag. 2004;196:275-285. and Carneiro et al.³3 Carneiro MAC, Siqueira JO, Moreira FMS, Carvalho D, Botelho SA, Saggin-Junior OJ. Micorriza arbuscular em espécies arbóreas e arbustivas nativas de ocorrência no sudeste do Brasil. Cerne. 1998;4:129-145. observed low colonization for the species Anadenanthera colubrina (0-14%), A. falcata (20-49%), and A. peregrina (1-19%). In addition to nutritional factors, the variable infection rate results may be associated with specificity between the host plants and AMF.

An analysis of the nitrogen controls (NC and AMF + NC) indicates the importance of the mycorrhizal fungus for better absorption of the added nitrogen. These results were confirmed during the second experiment, where the gain in shoot dry weight of the plants inoculated with G. margarita (W.N. Becker & I.R. Hall) was twice the weight gain as in plants that only received N. These observations highlight the mycorrhizal dependence of the P. gonoacantha species, not only for phosphorus absorption but also for other nutrients.³²32 Chen X, Tang JJ, Zhi GY, HU SJ. Arbuscular mycorrhizal colonization and phosphorus acquisition of plants: effects of coexisting plant species. Appl Soil Ecol. 2005;28:259-269.^,³³33 Tavasolee A, Aliasgharzad N, Jouzani GS, Mardi M, Asgharzadeh A. Interactive effects of arbuscular mycorrhizal fungi and rhizobial strains on chickpea growth and nutrient content in plant. Afr J Biotechnol. 2011;10:7585-7591.

Three groups of means formed upon analyzing the SDW/ROOT ratio in the species P. gonoacantha; the BSP1 strain without co-inoculation exhibited inferior behavior compared with the strain that contacts the two AMF species in the experiment. This contact altered the ratio in favor of greater shoot development. The analysis allows us to discern a range of possible responses between the microorganisms and their respective combinations.

Conclusions

This article concluded that mycorrhizal fungi are not necessary for nodulation in the species P. gonoacantha, which highlights the effect of a substrate on forming any symbiotic association because the substrate used herein was different.

The co-inoculated P. gonoacantha plants produced a higher shoot weight with D. heterogama and BSP1 strain. This combination was very promising for P. gonoacantha inoculation in the future for seedlings.

These results stress the relevance of studies of inoculation in tree species used in reforestation and land reclamation.

References

¹
Lewis G, Schirire BD, Mackinder BA, Lock JM. Legumes in the World Kew, UK: Royal Botanic Gardens; 2005.
²
Moreira FMS, Siqueira JO. Microbiologia e Bioquímica do Solo 2ed. Lavras: Editora UFLA; 2006.
³
Carneiro MAC, Siqueira JO, Moreira FMS, Carvalho D, Botelho SA, Saggin-Junior OJ. Micorriza arbuscular em espécies arbóreas e arbustivas nativas de ocorrência no sudeste do Brasil. Cerne 1998;4:129-145.
⁴
de Faria SM, Diedhiou AG, Lima HC, et al. Evaluation the nodulation status of leguminous species from the Amazonian forest of Brazil. J Exp Bot. 2010;62:3119-3127.
⁵
Moulin L, Munive A, Dreyfus B, Boivin-Masson C. Nodulation of legumes by members of the β-subclass of Proteobacteria. Nature 2001;411:948-950.
⁶
Chen WM, James EK, Prescott AR, Kierans M, Sprent JI. Nodulation of Mimosa spp. by the β-proteobacterium Ralstonia taiwanensis. Mol Plant-Microbe Interact 2003;16:1051-1061.
⁷
Berbara RLL, Souza FA, Fonseca HMAC. Fungos Micorrízicos Arbusculares: Muito Além da Nutrição. In: Fernandes MS, ed. Nutrição Mineral de Plantas Viçosa, MG: SBCS; 2006:355–374.
⁸
Bournaud C. Biodiversité des rhizobiums et interactions tripartites dans le groupe Piptadenia (tribu des Mimoseae). Universite Montpellier 2 Sciences et Techniques du Languedoc; 2012.
⁹
Bonfante P, Anca I-A. Plants, Mycorrhizal Fungi and Bacteria A network of interactions. Annu Rev Microbiol 2009;63:363-383.
¹⁰
Carvalho PER. Pau Jacaré-Piptadenia gonoacantha Colombo, PR: Embrapa Florestas. (Circular Técnica 91); 2004.
¹¹
Jesus EC, Schiavo JA, de Faria SM. Dependência de micorrizas para a nodulação de leguminosas arbóreas tropicais. R Árvore 2005;29:545-552.
¹²
Lorenzi H. Árvores brasileiras: manual de identificação e cultivo de plantas arbóreas nativas do Brasil I. Harri Lorenzi Nova Odessa, SP: Editora Plantarum; 1992.
¹³
Asai T. About mycorrhizas and leguminous plants. Jpn J Bot 1944;13:463-483.
¹⁴
Crush JR. Plant growth responses to vesicular-arbuscular mycorrhizas. VII. Growth and nodulation of some herbage legumes. New Phytol. 1974;73:743-749.
¹⁵
Vadez V, Beck DP, Lasso JH, Drevon JJ. Utilization of the acetylene reduction assay to screenfor tolerance of symbiotic N2 fixation to limiting P nutrition in common bean. Physiol Plant. 1997;99:227-232.
¹⁶
Fougnies L, Renciot S, Muller F, et al. Arbuscular mycorrhizal colonization and nodulation improve flooding tolerance in Pterocarpus officinalis Jacq. seedings. Mycorrhiza 2006;7(1):159-166.
¹⁷
Siqueira JO, Souza FA, Cardoso EJBN, Tsai SM. Micorrizas: 30 anos de pesquisa no Brasil. Lavras: Editora UFLA; 2010, 716 pp.
¹⁸
Gedermann JW, Nicolson TH. Spores of Mycorrhizal Endogene species extracted from soil by wet sieving and decanting. Trans Br Mycol Soc 1963;46:235-244.
¹⁹
Daniels BA, Skipper HD. Methods for the recovery and quantitative estimation of propagules from soil. In: Schenk NC, ed. Methods and Principles of Mycorrhizal Research St. Paul: American Phytopathological Society; 1982:29–35.
²⁰
Nicolson TH. Spores of Mycorrhizal Endogene species extracted from soil by wet sieving and decanting. Trans Br Mycol Soc 1963;46:235-244.
²¹
Colozzi-Filho A, Siqueira JO, Oliveira E. Desinfestação de esporos de fungos micorrízicos vesicular-arbusculares I - Efeito da concentração e tempo de exposição de agentes desinfestantes e antibióticos. Pesqui Agropecu Brasil. 1994;29:1119-1127.
²²
Vincent JM. A Manual for the Practical Study of Root-nodule Bacteria. IBP Handbook 15 Oxford: Blackwell Scientific Publications; 1970.
²³
Bertrand H, Plassard C, Pinochet X, Touraine B, Normand P, Cleyet-Marel JC. Stimulation of the ionic transport system in Brassica napus by a plant growth-promoting rhizobacterium (Achromobacter sp.). Can J Microbiol. 2000;46:229-236.
²⁴
Ferreira DF. Sistema para análise de variância para dados balanceados (Sisvar). versão 4.3 Lavras: UFLA; 2003.
²⁵
Koske RE, Gemma JN. A modified procedure for staining roots to detect VA mycorrhizas. Mycol Res 1989;92:486-488.
²⁶
Grace C, Stribley DP. A safer procedure for routine staining of vesicular-arbuscular mycorrhizal fungi. Mycol Res 1991;95:1160-1162.
²⁷
Giovanetti M, Mosse B. An evaluation of techniques for measuring vesicular-arbuscular mycorrhizal infection in roots. New Phytol. 1980;64(3):489-500.
²⁸
Newman EI. A method of estimating the total length of root in a sample. J Appl Ecol 1966;3(2):139-145.
²⁹
Barea JM, Azcón R, Azcón-Aguilar C. Vesicular-Arbuscular Mycorrhizal fungi in nitrogen fixing system. In: Norris JR, Read DJ, Varma AK, eds. Methods in Microbiology: Techniques for Study of Mycorrhizae London: Academic Press; 1992:391–416.
³⁰
Bethlenfalvay JG, Pacovsky JG, Bayne GH, Stafford AE. Interactions between nitrogen fixation, mycorrhizal colonization, and host-plant growth in the phaseolus-rhizobium-glomus symbiosis. Plant Physiol 1982;70:446-450.
³¹
Patreze CM, Cordeiro L. Nitrogen-fixing and vesicular-arbuscular mycorrhizal symbioses in some tropical legume trees of tribe Mimoseae. For Ecol Manag. 2004;196:275-285.
³²
Chen X, Tang JJ, Zhi GY, HU SJ. Arbuscular mycorrhizal colonization and phosphorus acquisition of plants: effects of coexisting plant species. Appl Soil Ecol. 2005;28:259-269.
³³
Tavasolee A, Aliasgharzad N, Jouzani GS, Mardi M, Asgharzadeh A. Interactive effects of arbuscular mycorrhizal fungi and rhizobial strains on chickpea growth and nutrient content in plant. Afr J Biotechnol 2011;10:7585-7591.

Publication Dates

Publication in this collection
Jan-Mar 2017

History

Received
24 Jan 2016
Accepted
31 Aug 2016

This is an Open Access article distributed under the terms of the Creative Commons Attribution Non-Commercial No Derivative License, which permits unrestricted non-commercial use, distribution, and reproduction in any medium provided the original work is properly cited and the work is not changed in any way.

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Berbara RLL, Souza FA, Fonseca HMAC. Fungos Micorrízicos Arbusculares: Muito Além da Nutrição. In: Fernandes MS, ed. Nutrição Mineral de Plantas Viçosa, MG: SBCS; 2006:355–374.

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Bonfante P, Anca I-A. Plants, Mycorrhizal Fungi and Bacteria A network of interactions. Annu Rev Microbiol 2009;63:363-383.

[10] ¹⁰
Carvalho PER. Pau Jacaré-Piptadenia gonoacantha Colombo, PR: Embrapa Florestas. (Circular Técnica 91); 2004.

[11] ¹¹
Jesus EC, Schiavo JA, de Faria SM. Dependência de micorrizas para a nodulação de leguminosas arbóreas tropicais. R Árvore 2005;29:545-552.

[12] ¹²
Lorenzi H. Árvores brasileiras: manual de identificação e cultivo de plantas arbóreas nativas do Brasil I. Harri Lorenzi Nova Odessa, SP: Editora Plantarum; 1992.

[13] ¹³
Asai T. About mycorrhizas and leguminous plants. Jpn J Bot 1944;13:463-483.

[14] ¹⁴
Crush JR. Plant growth responses to vesicular-arbuscular mycorrhizas. VII. Growth and nodulation of some herbage legumes. New Phytol. 1974;73:743-749.

[15] ¹⁵
Vadez V, Beck DP, Lasso JH, Drevon JJ. Utilization of the acetylene reduction assay to screenfor tolerance of symbiotic N2 fixation to limiting P nutrition in common bean. Physiol Plant. 1997;99:227-232.

[16] ¹⁶
Fougnies L, Renciot S, Muller F, et al. Arbuscular mycorrhizal colonization and nodulation improve flooding tolerance in Pterocarpus officinalis Jacq. seedings. Mycorrhiza 2006;7(1):159-166.

[17] ¹⁷
Siqueira JO, Souza FA, Cardoso EJBN, Tsai SM. Micorrizas: 30 anos de pesquisa no Brasil. Lavras: Editora UFLA; 2010, 716 pp.

[18] ¹⁸
Gedermann JW, Nicolson TH. Spores of Mycorrhizal Endogene species extracted from soil by wet sieving and decanting. Trans Br Mycol Soc 1963;46:235-244.

[19] ¹⁹
Daniels BA, Skipper HD. Methods for the recovery and quantitative estimation of propagules from soil. In: Schenk NC, ed. Methods and Principles of Mycorrhizal Research St. Paul: American Phytopathological Society; 1982:29–35.

[20] ²⁰
Nicolson TH. Spores of Mycorrhizal Endogene species extracted from soil by wet sieving and decanting. Trans Br Mycol Soc 1963;46:235-244.

[21] ²¹
Colozzi-Filho A, Siqueira JO, Oliveira E. Desinfestação de esporos de fungos micorrízicos vesicular-arbusculares I - Efeito da concentração e tempo de exposição de agentes desinfestantes e antibióticos. Pesqui Agropecu Brasil. 1994;29:1119-1127.

[22] ²²
Vincent JM. A Manual for the Practical Study of Root-nodule Bacteria. IBP Handbook 15 Oxford: Blackwell Scientific Publications; 1970.

[23] ²³
Bertrand H, Plassard C, Pinochet X, Touraine B, Normand P, Cleyet-Marel JC. Stimulation of the ionic transport system in Brassica napus by a plant growth-promoting rhizobacterium (Achromobacter sp.). Can J Microbiol. 2000;46:229-236.

[24] ²⁴
Ferreira DF. Sistema para análise de variância para dados balanceados (Sisvar). versão 4.3 Lavras: UFLA; 2003.

[25] ²⁵
Koske RE, Gemma JN. A modified procedure for staining roots to detect VA mycorrhizas. Mycol Res 1989;92:486-488.

[26] ²⁶
Grace C, Stribley DP. A safer procedure for routine staining of vesicular-arbuscular mycorrhizal fungi. Mycol Res 1991;95:1160-1162.

[27] ²⁷
Giovanetti M, Mosse B. An evaluation of techniques for measuring vesicular-arbuscular mycorrhizal infection in roots. New Phytol. 1980;64(3):489-500.

[28] ²⁸
Newman EI. A method of estimating the total length of root in a sample. J Appl Ecol 1966;3(2):139-145.

[29] ²⁹
Barea JM, Azcón R, Azcón-Aguilar C. Vesicular-Arbuscular Mycorrhizal fungi in nitrogen fixing system. In: Norris JR, Read DJ, Varma AK, eds. Methods in Microbiology: Techniques for Study of Mycorrhizae London: Academic Press; 1992:391–416.

[30] ³⁰
Bethlenfalvay JG, Pacovsky JG, Bayne GH, Stafford AE. Interactions between nitrogen fixation, mycorrhizal colonization, and host-plant growth in the phaseolus-rhizobium-glomus symbiosis. Plant Physiol 1982;70:446-450.

[31] ³¹
Patreze CM, Cordeiro L. Nitrogen-fixing and vesicular-arbuscular mycorrhizal symbioses in some tropical legume trees of tribe Mimoseae. For Ecol Manag. 2004;196:275-285.

[32] ³²
Chen X, Tang JJ, Zhi GY, HU SJ. Arbuscular mycorrhizal colonization and phosphorus acquisition of plants: effects of coexisting plant species. Appl Soil Ecol. 2005;28:259-269.

[33] ³³
Tavasolee A, Aliasgharzad N, Jouzani GS, Mardi M, Asgharzadeh A. Interactive effects of arbuscular mycorrhizal fungi and rhizobial strains on chickpea growth and nutrient content in plant. Afr J Biotechnol 2011;10:7585-7591.

Treatment	SDW (mg)^a a Shoot dry weight.		NDW (mg)^b b Nodule dry weight.		Efficiency (%)^c c Efficiency = (treat SDW/abscontrol SDW × 100).	Efficacy (%)^d d Efficacy = (treat SDW/NT(NH4NO3) SDW × 100).
Gigaspora margarita + BR 4812	20.00	b	0.00	b	50	18.2
BR 4812	30.00	b	0.00	b	75	27.3
Gigaspora margarita	40.00	b	0.00	b	102.5	36.4
Abs control	40.00	b	0.00	b	100	36.4
Nitrogen control	50.00	b	0.00	b	125	45.45
BR 4802	90.00	ab	14.12	a	225	81.82
Gigaspora margarita + N	110.00	ab	0.00	b	275	100
Gigaspora margarita + BR 4802	261.00	a	122.37	a	652.5	237.2
CV (%)	176.1		264.9

Treatment	Nodule no.	NDW (mg)	Myc. rate (%)
Gigaspora margarita + BR 4802	73	14.01	16
Gigaspora margarita + BSP1	73	13.11	11
Dentiscutata heterogama + BR 4802	71	14.12	18
Dentiscutata heterogama + BSP1	21	5.20	25
BR 4802	52	11.33	-
BSP1	99	14.45	-

Treatment	SDW (mg)^a a Shoot dry weight.		NDW (mg)^b b Nodule dry weight.		Efficiency (%)^c c Efficiency = (treat SDW/abscontrol SDW × 100).	Efficacy (%)^d d Efficacy = (treat SDW/NT(NH4NO3) SDW × 100).
Gig.marg	60.86	c	0.00	b	68.39	45.30
Dentiscutata heterogama	82.41	c	0.00	b	92.58	61.33
Abs control	89.11	c	0.00	b	100	66.32
Gigaspora margarita + BSP1	131.33	c	14.51	a	147.57	97.74
Dentiscutata heterogama + BSP1	925.11	a	8.36	ab	1039.33	688.53
Dentiscutata heterogama + BR 4802	746.33	b	11.01	a	838.58	555.47
BSP1	98.93	c	14.43	a	111.16	73.63
Gigaspora margarita + BR 4802	107.76	c	16.4	a	121.09	80.20
BR 4802	92.61	c	10.23	a	104.04	68.92
Dentiscutata heterogama + N	108.81	c	0.00	b	122.25	80.98
Gigaspora margarita + N	134.36	c	0.00	b	150.97	100.00
CV(%)	122.36		96.24

Treatment	SDW/ROOT ratio
Gigaspora margarita + BR 4802	0.48c
BSP1	1.51b
Gigaspora margarita	1.61b
Gigaspora margarita + N	1.71b
Dentiscutata heterogama + N	1.75b
Dentiscutata heterogama + BR 4802	1.83b
Absolute control	1.84b
BR 4802	1.87b
Dentiscutata heterogama + BSP1	2.05a
Gigaspora margarita + BSP1	2.16a
CV (%)	12.66

Brasil

Brasil

Nitrogen-fixing bacteria and arbuscular mycorrhizal fungi in Piptadenia gonoacantha (Mart.) Macbr.

Abstract

Introduction

Materials and methods

Results

First experiment

Second experiment

Discussion

Conclusions

References

Publication Dates

History