Abstracts

1. INTRODUCTION

Ectomycorrhizal fungal (EMF) can act with variable efficiency on plant growth, especially those belonging to Eucalyptus genus (SAWYER et al., 2003SAWYER, N. A.; CHAMBERS, S. M.; CAIRNEY, J. W. G. Utilisation of inorganic and organic phosphorus sources by isolates of Amanita muscaria and Amanita species native to temperate eastern Australia. Australian Journal of Botany, v.51, n.2, p.151-158, 2003.). Generally, during ectomycorrhizal formation, roots undergo through profound morphological and physiological changes, starting to act in an integrated and congruous manner with the fungus, with gains in adaptability and survival of these symbionts (BARKER et al., 1998BARKER, S. J.; TAGU, D.; DELP, G. Regulation of root and fungal morphogenesis in mycorrhizal symbioses. Plant Physiology, v.116, n.4, p.1021-1207, 1998.).

Ectomycorrhizal fungi can provide the host plant increased tolerance to toxic substances in soil (GRAZZIOTTI et al., 2003GRAZZIOTTI, P. H.; SIQUEIRA, J. O.; MOREIRA, F. M. S. Espécies arbóreas e ectomicorrizas em relação ao excesso de metais pesados. Tópicos em Ciência do Solo, v.5, p.55-105, 2003.), resistance to water stress, extreme values of temperature and soil acidity (POZO; AZCON-AGUILAR, 2007POZO, M. J.; AZCON-AGUILAR, C. Unraveling mycorrhiza-induced resistance. Current Opinion in Plant Biology, v.10, n.4, p.393-398, 2007.) and pathogens of root system (BAUMERT et al., 1997BAUMERT, A.; SCHUMANN, B.; PORZEL, A.; SCHMIDT, J.; STRACK, D. Triterpenoids from Pisolithus tinctorius isolates and ectomycorrhizas. Phytochemistry, v.45, n.3, p.499-504, 1997.). Yet the main effect is the increase of root absorption surface, allowing better use of water and nutrients such as N, K and especially P, which is less mobile in soil (BOUGHER et al., 1990BOUGHER, N. L.; GROVE, T. S.; MALAJCZUK, N. Growth and phosphorus acquisition of karri (Eucalyptus diversicolor B. Muell.) seedlings inoculated with ectomycorrhizal fungi in relation to phosphorus supply. New Phytologist, v.114, n.1, p.77-85, 1990.; SAWYER et al., 2003SAWYER, N. A.; CHAMBERS, S. M.; CAIRNEY, J. W. G. Utilisation of inorganic and organic phosphorus sources by isolates of Amanita muscaria and Amanita species native to temperate eastern Australia. Australian Journal of Botany, v.51, n.2, p.151-158, 2003.).

Overall, these benefits obtained under ectomycorrhizal association are variable and dependent on soluble P availability in soil, which in large amounts can limit association and its scarcity affects plant growth and yield. When P is extremely limited, growth of both symbionts is impared (DIGTHON et al., 1993DIGHTON, J.; POSKITT, J. M.; BROWN, T. K. Phosphate influx into ectomycorrhizal and saprotrophic fungal hyphae in relation to phosphate supply: a potencial method for selection of efficient mycorrhizal species. Mycological Research, v.97, n.3, p.355-358, 1993.). Low P availability in soil increases host growth by fungal action. In addition, higher P levels promote fungus growth to the detriment of plant (BOUGHER et al., 1990BOUGHER, N. L.; GROVE, T. S.; MALAJCZUK, N. Growth and phosphorus acquisition of karri (Eucalyptus diversicolor B. Muell.) seedlings inoculated with ectomycorrhizal fungi in relation to phosphorus supply. New Phytologist, v.114, n.1, p.77-85, 1990.). Although low symbiotic efficiency, high P content did not fully prevent root colonization (QUORESHI; KHASA, 2008QUORESHI, A. M.; KHASA, D. P. Effectiveness of mycorrhizal inoculation in the nursery on root colonization, growth, and nutrient uptake of aspen and balsam poplar. Biomass and Bioenergy, v.32, n.5, p.381-391, 2008.); however, most symbiotic efficiency between Eucalyptus and EMF isolates occurs in sub-optimal P levels (SOARES et al., 1990SOARES, I.; BORGES, A. C.; BARROS, N. F.; BELLEI, M. M. Níveis de fósforo na formação de ectomicorrizas em mudas de eucalipto. Revista Brasileira de Ciência do Solo, v.14, n.3 p.327-332, 1990.; SOUZA et al, 2004SOUZA, L. A. B.; SILVA FILHO, G. N.; OLIVEIRA, V. L. Eficiência de fungos ectomicorrízicos na absorção de fósforo e na promoção do crescimento de eucalipto. Pesquisa Agropecuária Brasileira, v.39, n.4, p.349-355, 2004.). For Eucalyptus dunnii seedlings inoculated with four EMF and grown in fertilized substrates with 0 to 8 mg P per plant, the doses above 4 mg per plant completely inhibited EMF colonization for three isolates (SOUZA et al., 2004SOUZA, L. A. B.; SILVA FILHO, G. N.; OLIVEIRA, V. L. Eficiência de fungos ectomicorrízicos na absorção de fósforo e na promoção do crescimento de eucalipto. Pesquisa Agropecuária Brasileira, v.39, n.4, p.349-355, 2004.).

Studies of ectomycorrhizal formation in laboratory have helped in understanding this process, since each association-forming stage is highly regulated by molecular interactions that result in morphological and physiological alterations in both organisms (BARKER et al., 1998BARKER, S. J.; TAGU, D.; DELP, G. Regulation of root and fungal morphogenesis in mycorrhizal symbioses. Plant Physiology, v.116, n.4, p.1021-1207, 1998.). In vitro assays for different fungus and plant species, which are able to establish ectomycorrhizal association, is essential for controlled mycorrhization process. Mycorrhization control is based on inoculation of soil specific fungi into plants, taking as basis the mutualistic relationship between these organisms (GARBAYE, 1990GARBAYE, J. Utilisation des mycorhizes en sylvicuture. In: STRULLU, D.G. (Ed). Les mycorhizes des arbres et plantes cultivées. Paris: Lavoisier, 1990. p.197-248.). This process begins with the selection of the most effective fungal isolates and involves the test of ectomycorrhizal isolate ability to form this symbiosis, which can be performed by in vitro synthesis.

In this way, the target points of this study were to evaluate the effect of P concentrations on ectomycorrhizal formation, then use assessment of mycorrhizal effectiveness and the promotion of plant growth in vitro for pre-selection of ectomycorrhizal isolate obtained from commercial eucalypts plantations.

2. MATERIALS AND METHODS

2.1. Ectomycorrhizal synthesis in vitro in substrate with P doses

2.1.1. Experimental design

The experiment was carried out in an entirely randomized design in a 5 x 3 factorial scheme, using D3, D26, D51 and D72 isolates of Pisolithus sp., plus one non-inoculated (control) and P dosed of 0.87, 1.16 and 1.72 mg plant^-1. The supplied phosphorus amounts were obtained from dibasic potassium phosphate (KH₂PO₄) reduction of Melin-Norkrans modified culture medium (MNM) (MARX, 1969MARX, D. H. The influence of ectotrophic mycorrhizal fungi on the resistance of pine roots to pathogenic infections. I. Antagonism of mycorrhizal fungi to root pathogenic fungi and soil bacteria. Phytopathology, v.59, n.2, p.153-163, 1969.) added into the substrate used for Eucalyptus urophylla seedling growth.

2.1.2. Experiment assembling and conduction

The Pisolithus sp. used isolates were obtained from EMF collection of the Laboratory of Soil Microbiology - UFVJM. Pure isolate cultures were originally obtained from basidiomas sampled in Eucalyptusspp. plantations in Vale do Jequitinhonha - Minas Gerais, which had already known effectiveness with this plant by preliminary assays. Each fungal inoculum was obtained from isolate transferring to solid MNM culture medium (MARX, 1969MARX, D. H. The influence of ectotrophic mycorrhizal fungi on the resistance of pine roots to pathogenic infections. I. Antagonism of mycorrhizal fungi to root pathogenic fungi and soil bacteria. Phytopathology, v.59, n.2, p.153-163, 1969.) and incubated for 20 days at 25 ºC.

Eucalyptus urophylla ST Blake seedlings from surface-disinfected seeds were treated by placing them on a sieve and washing three times with a 50% alcohol solution, rinsing with sterile distilled water, and immersing in a 0.5% sodium hypochlorite solution for one minute and again rinsed three times in sterile distilled water. After this treatment, they were sown into Petri dishes (∅ = 100 mm) containing three sterile germination paper moistened with sterile distilled water. The entire process was carried out under aseptic conditions in a laminar flow cabinet. The seeds were incubated for two weeks at 25 °C and 12-hour photoperiod. During this period, sterile distilled water was added to maintain moisture level.

Test tubes of 20-cm height and 2.5 cm diameter were coated internally with germination paper from base up to 11.4 cm high, and added 56-cm³ peat: vermiculite mix (1:20, v/v) and 10-ml distilled water. Then, the tubes were closed with two layers of cellophane tape and sterilized twice for 20 minutes at 121 °C. After cooling, we added 10 mL MNM liquid medium at pH 5.3, and the tubes were sterilized again afterwards.

Two-week after sowing, E. urophylla seedlings had total height between 0.8 and 1 cm, and they were transferred to the test tubes. Each tube has received one seedling, placing roots between germination paper and the tube wall, so it was possible to visualize them periodically. The tubes were wrapped in foil covering in all substrate area and subsequently incubated for two days at 25 °C and 12-hour photoperiod in a BOD oven, until the inoculation.

For inoculation of fungal isolates into plants, we used 5-mm diameter culture medium discs, mycelium detached from borders of isolate colonies with 20-day growth on solid MNM medium. These discs were placed on MNM solid medium within Petri dishes to reactivate the mycelium damaged by cuts and check absence of contamination. After two days, the viable discs were used for plant inoculations by placing one disc on either side of the roots, also between the germination paper and tube wall. The non-inoculated (control) one was prepared by using the same disc medium without mycelium. The tubes were again placed in the growth chamber where they remained for 40 days at 25 °C and 12-hour photoperiod.

2.1.3. Evaluations and statistical analysis

Plant height was measured at 10, 20, 30 and 40 days after being transferred to the tubes. Additionally, at 40 days, the plant shoot was removed at root collar region and weighed to determine shoot fresh weight (SFW). Roots were immersed in water and washed with squeeze bottle to facilitate its separation from substrate. Then, the root system of each plant was fixed in FAA (100 ml alcohol, 100 ml distilled water, 13 ml formalin and 5 ml acetic acid) solution, which was used to determine the percentage of root tips colonized by direct counting in stereomicroscope with 30x magnification (BRUNDRET et al., 1996BRUNDRET, M.; BOUGHER, N. L.; DELL, B.; GROVE, T.; MALAJCZUK, N. Working with mycorrhizas in forestry an agriculture. Canberra: Australian Centre for International Agricultural Research, 1996. 374p.).

For microscopic characterization, mycorrhizae were cut into 20 to 30-μm-thick sections using a microtome and placed on glass slides for microscopy. Next, they were mounted in a mixture containing a drop of polyvinyl alcohol-lacto-glycerol (16.6 g of polyvinyl alcohol + 100 ml of distilled water + 100 ml lactic acid + 10 ml glycerin) and one drop of cotton blue solution (0.05%) in lacto-glycerol (0.04 g methylene blue + 10 ml lactic acid + 20 ml glycerin + 10 ml distilled water). Subsequently, they were visualized under the microscope at 400x to 1,000x, sections were photographed and classified as follows: (-) no colonization, (+) with fungal mantle colonization, (++) with Hartig net and fungal mantle, (+++) with Hartig net and thick fungal mantle according to Figure 1.

The statistical analysis was performed by analysis of variance, and for the plant height, it was considered as a source of variation growth times after inoculation (10, 20, 30 and 40 days), P doses and isolates. Thus, for this variable, it was analyzed: the triple factorial 5 X 3 X 4 referring to isolates, doses, time after inoculation, respectively. When significant for height, isolate effect was compared by regression equations. Means of SFW and percentage of root tip colonization were compared by Tukey test at 5% probability.

2.2. In vitro selection of ectomycorrhizal fungi

2.2.1. Experimental desig

The experiment was arranged in a totally randomized design. The treatments were the isolates D1, D4, D5, D6, D7, D10, D12, D13, D14, D15, D17, D20, D23, D26, D27, D29, D46, D50, D52, D57, D58, D61, D63, D70, D76, D77, D81, D82, UFVJM4, and UFVJM5 of Pisolithus sp.; ITA06 of Pisolithus microcarpus; AM16 of Amanita muscaria; SC129 of Scleroderma areolatum, a non-inoculated one, with five replications and experimental plots composed by one plant. The Pisolithus sp. isolates were obtained from basidiomas sampled from commercial Eucalyptus sp. plantations in Jequitinhonha Valley in Minas Gerais State, Brazil, which had been donated by the Laboratory of Soil Microbiology of the UFVJM. The P. microcarpus, A. muscaria and S. areolatum fungi were isolated from commercial Eucalyptus sp. plantations in Santa Catarina State and had been donated by the Department of Microbiology, Immunology and Parasitology of the Federal University of Santa Catarina.

2.2.2. Experiment assembling and conduction

The experiment assembling and conduction were performed as described above for earlier essay; however, by using only 1.72 mg P dose per plant. This dose has been chosen due to its great previous performance for isolate effectiveness to colonize roots and has promoted height increase.

2.2.3. Evaluation and statistical analysis

Forty days after seedlings transfer into tubes, it was evaluated height, plant fresh weight (PFW) and percentage colonized root tips. Newly, ectomycorrhizal were characterized for presence or absence of fungal mantle and Hartig net as described formerly.

Data statistical analysis was performed by variance analysis and, when significant, means were compared by Scott Knott test at 5% probability.

3. RESULTS

3.1. In vitro synthesis of ectomycorrhizal fungi in substrate with P doses

Plant height has increased differently (p d ≤ 0.01) between Pisolithus sp. isolates and P doses (Figure 2). In general, height growth ceased after 30 days of inoculation, what was more pronounced at the highest P dose. Plants inoculated with D3, D26, and D72 isolates at the lowest P dose and for non-inoculated at the intermediate dose (1.16 g plant^-1 P), the plant height increased linearly up to the 40^th day.

At the lowest P dose (0.87 mg plant^-1 P), plant height has also increased linearly for plants inoculated with isolates D3, D26 and D72 and quadratically for plants inoculated with D51 and non-inoculated (Figure 2a). In the latter, growth stabilized at the 30^th day (Figure 2a). At 40 days, D26 and D51 inoculated plants were on average 23.6% higher than non-inoculated, while those inoculated with D3 and D72 were always lower than non-inoculated.

At the dose of 1.16 mg plant^-1, height of plants inoculated with all isolates showed a quadratic behavior reducing its increase after 30 days (Figure 2b). While non-inoculated plants had a linear behavior. The heights of plants inoculated with D26 and D72 were always higher than non-inoculated with a difference of 34.6% at 30 days for plants inoculated with D26. Those inoculated with D51 were always lower, and D3 inoculated plants were smaller than non-inoculated only at the end of the evaluation period (Figure 2b).

For the highest P dose (1.72 mg plant^-1), only D26 increased plant height compared to non-inoculated plants; however, at 40 days, this effect was not seen anymore. At 30 days, D26 inoculated plants were 7.7% higher than non-inoculated ones. Moreover, the D3 inoculated plants were, at the end of 40 days, 32.8% lower than non-inoculated ones (Figure 2c). Plant height increased quadratically, both the inoculated as non-inoculated plants, and from 30 days on, the plants presented reduced growth rate (Figure c). Height increase by inoculating D26, D51 and D72 isolates, in relation to non-inoculated plants, reduced at the highest P dose.

SFW and the percentage of colonized root tips were influenced by inoculation of Pisolithus sp. isolates and not by P doses (p < 0.05) (Figure 3a, b). SFW mean of plants inoculated with D26 and D72 was 1.4 times higher than those inoculated with D3, but all were equal to D51 inoculated and non-inoculated ones (Figure 3a).

All isolates formed typical ectomycorrhizae, with Hartig net and fungal mantle (++ or +++), on E. urophylla roots at the three evaluated P doses. At the lowest dose, ectomycorrhizae formed by D51 and D72 had Hartig net and thick fungal mantle (+++) and, at the other doses, only those formed by D51 remained this standard. The percentage of colonized root tips was similar in inoculated plants, with an average of 51.9%, and absent in non-inoculated ones (Figure 3b).

3.2. In vitro pre-selection of ectomycorrhizal fungi

E. urophylla seedling height, plant fresh weight and colonized root tip percentage were related to species and fungal isolate (p < 0.01) (Figure 4). Sixteen out of 33 studied isolates had height and PFW increased compared to non-inoculated plants (D4, D5, D6, D10, D12, D13, D14, D15, D20, D23, D27, D46, D52, D61 of Pisolithus sp., ITA06 of P. Microcarpus and SC129 of S. areolatum) (Figure 4a, b). Besides these, D82 of Pisolithus sp. raised only plant height, plus D17 and D58 had effect on PFW singly.

In descending order, EMF promoted greater percentage of colonized root tips being D63 = D77 = D70 = D81 > D26 = UFVJM4 = D58 = D17 = D50 = UFVJM5 = D7 = D27 = D20 > ITA06 = D52 = D15 = D12 = SC129 = to the others in which colonization was not observed (Figure 4c).

Thirteen of the 18 EMF, in which colonization was observed (D7, D15, D17, D26, D50, D58, D63, D70, D77, D81, ITA06, UFVJM4 and UFVJM5) showed typical ectomycorrhizae with Hartig net and fungal mantle, and five of them (D12, SC129, D20, D27, D52) had solely the mantle (Table 1). From the first thirteen isolate, nine (D7, D15, D17, D26, D50, D58, D63, D77, and D81) presented thick fungal mantle.

Among isolates with greater root colonization (D63 = D77 = D70 = D81), none of them promoted plant growth (height and PFW) and, from the 16 that increased height and PFW, 14 isolates presented non-typical ectomycorrhizae (D4, D5, D6, D10, D12, D13, D14, D20, D23, D27, D46, D52, D61 and SC129). The others obtained less than 29% of root tip colonization (Figure 4). Among isolates that showed some colonization, D12, D15, D20, D27, D52, ITA06 and SC129 raised height and PFW. In addition, D58 and D17 had only effect on PFW.

4. DISCUSSION

4.1. In vitro synthesis of ectomycorrhizae in substrate with different P doses

The differentiated ability among EMF species (SOUZA et al., 2004SOUZA, L. A. B.; SILVA FILHO, G. N.; OLIVEIRA, V. L. Eficiência de fungos ectomicorrízicos na absorção de fósforo e na promoção do crescimento de eucalipto. Pesquisa Agropecuária Brasileira, v.39, n.4, p.349-355, 2004.; JHA et al., 2008JHA, B. N.; SHARMA, G. H.; SHUKLA, A. K. Effect of ectomycorrhizal development on growth in pines seedlings. Journal of Plant Sciences, v.3, n.1, p.77-84, 2008.) and Pisolithus sp. isolates (ANDREAZZA et al., 2004ANDREAZZA, R.; ANTONIOLLI, Z. I.; SILVA, R. F.; LONGHI, S. J. Espécies de Pisolithus sp. na produção de mudas de Eucalyptus grandis Hill ex Maiden em solo arenoso. Ciência Florestal, v.14, n.2, p.51-59, 2004.) to promote plant growth at varied P doses was also observed in this study. The height of Eucalyptus grandis plants grown under greenhouse conditions and inoculated with F1-RS isolate of Pisolithus sp. was higher than those with FSE-S of Pt Silv.1, when grown in substrate with 8 mg kg^-1 P. Nevertheless, in substrates with 30 mg kg^-1 of P, plant heights were equal (ANDREAZZA et al., 2004ANDREAZZA, R.; ANTONIOLLI, Z. I.; SILVA, R. F.; LONGHI, S. J. Espécies de Pisolithus sp. na produção de mudas de Eucalyptus grandis Hill ex Maiden em solo arenoso. Ciência Florestal, v.14, n.2, p.51-59, 2004.). The reduction of inoculation beneficial effect that was observed for plants with D26, D51 and D72 isolates compared to the non-inoculated ones with increasing P doses is reported in literature (SILVA et al., 2003SILVA, R. F.; ANTONIOLLI, Z. I.; ANDREAZZA, R.; LONGHI, S. J. Fungos ectomicorrízicos no desenvolvimento de mudas de Eucalyptus grandisHill ex Maiden. Biosciense Journal, v.19, n.3, p.9-17, 2003.; SOUZA et al., 2004SOUZA, L. A. B.; SILVA FILHO, G. N.; OLIVEIRA, V. L. Eficiência de fungos ectomicorrízicos na absorção de fósforo e na promoção do crescimento de eucalipto. Pesquisa Agropecuária Brasileira, v.39, n.4, p.349-355, 2004.; JHA et al., 2008JHA, B. N.; SHARMA, G. H.; SHUKLA, A. K. Effect of ectomycorrhizal development on growth in pines seedlings. Journal of Plant Sciences, v.3, n.1, p.77-84, 2008.). In contrast, at the highest dose, D26 has still increased height up to 30^th day set against non-inoculated plants. This fact indicates that the P dose that reduces inoculation effects depends on the isolate type. However, the P absence effect on SFW is diverged from results observed for eucalypts cultivated in vases (SILVA et al., 2003SILVA, R. F.; ANTONIOLLI, Z. I.; ANDREAZZA, R.; LONGHI, S. J. Fungos ectomicorrízicos no desenvolvimento de mudas de Eucalyptus grandisHill ex Maiden. Biosciense Journal, v.19, n.3, p.9-17, 2003.; ANDREAZZA et al., 2004ANDREAZZA, R.; ANTONIOLLI, Z. I.; SILVA, R. F.; LONGHI, S. J. Espécies de Pisolithus sp. na produção de mudas de Eucalyptus grandis Hill ex Maiden em solo arenoso. Ciência Florestal, v.14, n.2, p.51-59, 2004.). This divergence may be due to the low plant growing period and, or low fertility of used substrate.

Fungal mantle and Hartig net presence demonstrate that the studied isolates established a symbiotic relationship with E. urophylla plants. The percentage of colonized root tips (51.9%) can be considered high since it was higher than the colonization mean (10.2 - 36.2%) observed for E. globulusand E. grandis (LU et al., 1998LU, X.; MALAJCZUK, N.; DELL, B. Mycorrhiza formation and growth of Eucalyptus globulus seedlings inoculated with spores of various ectomycorrhizal fungi. Mycorrhiza, v.8, n.2, p.81-86, 1998.; SILVA et al., 2003SILVA, R. F.; ANTONIOLLI, Z. I.; ANDREAZZA, R.; LONGHI, S. J. Fungos ectomicorrízicos no desenvolvimento de mudas de Eucalyptus grandisHill ex Maiden. Biosciense Journal, v.19, n.3, p.9-17, 2003.; ANDREAZZA et al., 2004ANDREAZZA, R.; ANTONIOLLI, Z. I.; SILVA, R. F.; LONGHI, S. J. Espécies de Pisolithus sp. na produção de mudas de Eucalyptus grandis Hill ex Maiden em solo arenoso. Ciência Florestal, v.14, n.2, p.51-59, 2004.; SOUZA et al., 2012SOUZA, E. L.; ANTONIOLLI, Z. I.; MACHADO, R. G.; ECKHARDT, D. P.; DAHMER, S. F. B.; SCHIRMER, G. K. Efeito da inoculação com isolados de fungos ectomicorrízicos sobre o desenvolvimento de mudas de Eucalyptus grandis Hill ex Maiden. Ciência Florestal, v.22, n.2, p.251-261, 2012.). Nonetheless, equality among ability of Pisolithus sp. isolates to colonize eucalypts effectively (Figure 3b) and the differences of fungal mantle thickness has not related with the effects on plant growth (Figure 2). Plants inoculated with D3 exhibited similar colonization to the others (Figure 3b). On the other hand, this isolate has generally showed the lowest height and SFW (Figure 2). This may suggest less compatibility between this isolate and the symbiotic plant under the studied conditions.

The lack of interaction between the percentage of colonized root tips and P doses promoted by Pisolithus sp. isolates (Figure 3) differed from most studies reported in the literature (SOARES et al., 1990SOARES, I.; BORGES, A. C.; BARROS, N. F.; BELLEI, M. M. Níveis de fósforo na formação de ectomicorrizas em mudas de eucalipto. Revista Brasileira de Ciência do Solo, v.14, n.3 p.327-332, 1990.; SILVA et al., 2003SILVA, R. F.; ANTONIOLLI, Z. I.; ANDREAZZA, R.; LONGHI, S. J. Fungos ectomicorrízicos no desenvolvimento de mudas de Eucalyptus grandisHill ex Maiden. Biosciense Journal, v.19, n.3, p.9-17, 2003.; ANDREAZZA et al., 2004ANDREAZZA, R.; ANTONIOLLI, Z. I.; SILVA, R. F.; LONGHI, S. J. Espécies de Pisolithus sp. na produção de mudas de Eucalyptus grandis Hill ex Maiden em solo arenoso. Ciência Florestal, v.14, n.2, p.51-59, 2004.; SOUZA et al., 2004SOUZA, L. A. B.; SILVA FILHO, G. N.; OLIVEIRA, V. L. Eficiência de fungos ectomicorrízicos na absorção de fósforo e na promoção do crescimento de eucalipto. Pesquisa Agropecuária Brasileira, v.39, n.4, p.349-355, 2004.). This effect is probably because all used P doses generally near to the ideal range to match root colonization and eucalypts growth (SOUZA et al., 2004SOUZA, L. A. B.; SILVA FILHO, G. N.; OLIVEIRA, V. L. Eficiência de fungos ectomicorrízicos na absorção de fósforo e na promoção do crescimento de eucalipto. Pesquisa Agropecuária Brasileira, v.39, n.4, p.349-355, 2004.). Even the highest dose (1.72 mg plant^-1) cannot be considered high for seedling production, as in commercial nurseries each plant can receive around 30 mg P throughout the nursery stage as routine, which was the reason of using the higher dose in pre-selection experiment.

Previously, plant height results has particularly demonstrated that D26, D51 and D72 have potential to promote eucalypts growth, and the beneficial effect of the latter two isolates were restricted to a specific P dose while the first promoted growth in the three studied doses. This result shows that P negative effect on ectomycorrhizal symbiosis in eucalyptus can depend on isolate types. This has great importance for EMF selection for inoculation in large commercial eucalypts nurseries, since P fertilization reduction might imply in increased length of the time that the seedlings stay in nursery, and thus higher costs. The existence of isolates that can colonize and even benefit the seedling growth, even with increased P levels in growth substrate, may facilitate EMF use as biotechnological technique in eucalypts cultivation in Minas Gerais, Brazil. Inoculation advantages of these isolates may be due to greater P absorption by inoculated plants, but as observed for higher P doses. This gain was minimized after 30 days, what may be caused by some other nutrient growth limitation, despite the noncompliance of any deficiency symptoms. Following this line, further studies aiming to determine the optimal conditions for eucalypts growth and ectomycorrhizal synthesis could contribute to ectomycorrhizal fungus research.

4.2. In vitro pre-selection of ectomycorrhizal fungi

EMF ability to promote symbiotic plant growth differs among species and isolate types, as observed in the previous experiment and others (LU et al., 1998LU, X.; MALAJCZUK, N.; DELL, B. Mycorrhiza formation and growth of Eucalyptus globulus seedlings inoculated with spores of various ectomycorrhizal fungi. Mycorrhiza, v.8, n.2, p.81-86, 1998.; REDDY; SATYANARAYANA, 1998REDDY, M. S.; SATYANARAYANA, T. Inoculation of micropropagated plantlets of Eucalyptus tereticornis with ectomycorrhizal fungi. New Forests, v.16, n.3, p.273-279, 1998.; SOUZA et al., 2012SOUZA, E. L.; ANTONIOLLI, Z. I.; MACHADO, R. G.; ECKHARDT, D. P.; DAHMER, S. F. B.; SCHIRMER, G. K. Efeito da inoculação com isolados de fungos ectomicorrízicos sobre o desenvolvimento de mudas de Eucalyptus grandis Hill ex Maiden. Ciência Florestal, v.22, n.2, p.251-261, 2012.). The proportion of isolates able to form ectomycorrhizal colonies in E. urophylla related to the total studied isolates (54.5%) (Figure 4c) was lower than the one found in Picea glehnii (70%) (KASUYA et al., 1996KASUYA, M. C. M.; IGARASHI T. In vitro ectomycorrhizal formation in Picea glehnii seedlings. Mycorrhiza, v.6, n.5, p.451-454, 1996.) and the one observed in E. grandis (100%) (COSTA et al., 2010COSTA, M. D.; CAMPOS, A. N. R.; SANTOS, M. L. S.; BORGES, A. C. In vitro ectomycorrhiza formation by monokaryotic and dikaryotic isolates of Pisolithus microcarpus in Eucalyptus grandis. Revista Árvore, v.34, n.3, p.377-387, 2010.), which was also in vitro culture. These results demonstrate the importance of constant selection of EMF isolates for inoculation in commercial nurseries and point out in vitro synthesis assays to reduce cost in selection programs of ectomycorrhizal fungi. It is still interesting to highlight that different species or even isolates should be recommended at different regions or companies due to environmental conditions or seedling handlings, respectively. Therefore, in vitro synthesis may be useful in previous selection of EMF isolates; however, for mass use, the preselected isolates should be evaluated in commercial nursery conditions, mainly by evaluating seedling survival rate and growth in the field.

The greatest plant height and PFW was observed for those inoculated with Pisolithus sp. isolates with non-typical ectomycorrhizal formation (D4, D5, D6, D10, D13, D14, D23, D46, D61, D76 and D82) (Figure 4), which corroborates with findings in E. globulus inoculated with 18 EMF genera (LU et al., 1998LU, X.; MALAJCZUK, N.; DELL, B. Mycorrhiza formation and growth of Eucalyptus globulus seedlings inoculated with spores of various ectomycorrhizal fungi. Mycorrhiza, v.8, n.2, p.81-86, 1998.). The explanations about these results are not still clear, although it can be a consequence of fungal activity within root system even without symbiosis establishment at a detectable level (SOUZA et al., 2004SOUZA, L. A. B.; SILVA FILHO, G. N.; OLIVEIRA, V. L. Eficiência de fungos ectomicorrízicos na absorção de fósforo e na promoção do crescimento de eucalipto. Pesquisa Agropecuária Brasileira, v.39, n.4, p.349-355, 2004.). Conversely, for isolates that colonized roots, but have not promoted plant evident gains under the studied conditions, the increased colonization could have proportionated greater demand for photoassimilates, decreasing plant growth during that period. However, the growth gain observed since pre-selection stage may indicate the most promising isolates, the ability to colonize roots should be taken into consideration as an important result for strain pre-selection since mycorrhizae are the ones that will provide significant gains, mainly in adaptation stage after seedling transplantation to the field (MALAJCZUK et al., 1975MALAJCZUK, N.; McCOMB, A. J.; LONERAGAN, J. F. Phosphorus uptake and growth of mycorrhizal and uninfected seedling of Eucalyptus calophylla. Australian Juornal Botany, v.23, n.2, p.231-238, 1975.).

In this sense, the most promising isolates for use in other mycorrhizal control phases were the D15, D17, D58 and ITA06, since, among the 19 isolates that promoted height and PFW gains, they have colonized roots with typical ectomycorrhizal. However, other fungi that have also colonized roots can promote plant growth later, for example, D63 = D77 = D70 = D81 isolates, which had the highest percentage colonized root tips and typical ectomycorrhizal fungi with thick fungal mantle.

5. CONCLUSIONS

Root colonization by suitable isolates was high, showing that in vitrocultivation can be used to reduce costs of ectomycorrhizal fungus selection.

Phosphorus rates did not influence shoot fresh weight and root colonization because they were low, but the benefits of inoculation in plant height were dependent on isolate type and P dose.

Ectomycorrhizal colonization of Eucalyptus urophylla roots and its effects on this plant growth depend on fungal species and isolate.

D15, D17 and D58 isolates of Pisolithus sp. and ITA06 of Pisolithus microcarpus are promising to be used in controlled mycorrhization programs.

6.ACKNOWLEDGEMENTS

We want to thank the Foundation of Research Support of Minas Gerais State (FAPEMIG) and the Foundation of Research and Innovation Support of Santa Catarina State (FAPESC) by this research financial support.

7. REFERENCES

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