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Azospirillum sp . inoculation in wheat, barley and oats seeds greenhouse experiments

Abstracts

The aim of the present work was to evaluate the inoculation effects of Azospirillum sp. RAM-7 strain, in seeds of wheat, barley and oats cultures on yield and total nitrogen content of the grains in greenhouse experiments. Seeds inoculation with Azospirillum sp. RAM-7 strain enhanced grain yields, even so, the responses vary among the evaluated cultures. For wheat, significant increases were obtained when the inoculation was associated to 100% of the recommended nitrogen, although the treatment that received only inoculation produced 7.4% above the control, however this difference wasn't significant. For barley, the presence of the inoculant substituted 20% the recommended nitrogen fertilization. For oats the inoculation with Azospirillum sp. RAM-7 didn't provide a significant increase in grain yields. In relation to the total nitrogen content of the grains, for all studied cultures, significant differences were not observed among the evaluated treatments (p < 0.05).

Azospirillum; Wheat; Barley; Oats; Nitrogen fixation; Plant growth promotion


O presente trabalho teve por objetivo avaliar os efeitos da inoculação de Azospirillum sp. RAM-7, em sementes das culturas de trigo, cevada e aveia sobre a produtividade e teor de nitrogênio total dos grãos, em experimentos implantados em de casa-de-vegetação. A inoculação das sementes com Azospirillum sp. RAM-7 aumentou a produtividade, porém, estas respostas variam entre as culturas avaliadas. Para o trigo, aumentos significativos foram obtidos quando a inoculação foi associada a 100% do nitrogênio recomendado, já o tratamento que recebeu somente inoculação produziu 7,4% acima do controle, porém, esta diferença não foi significativa. Para a cevada, a presença do inoculante substituiu 20% da adubação recomendada de nitrogênio. Para a aveia, a inoculação com Azospirillum sp. RAM-7 não proporcionou aumento significativo na produtividade. Em relação ao teor de nitrogênio total dos grãos, para as três culturas, não foram observadas diferenças significativas entre os tratamentos avaliados (p<0,05).


AGRICULTURE, AGRIBUSINESS AND BIOTECHNOLOGY

Azospirillum sp . inoculation in wheat, barley and oats seeds greenhouse experiments

Osmar R. Dalla Santa; Ramona Fernández Hernández; Gergina L. Michelena Alvarez; Pedro Ronzelli Junior; Carlos Ricardo Soccol* * Author for correspondence

Laboratório de Processos Biotecnológicos; Universidade Federal do Paraná; C. P. 19031; 81531-970; soccol@ufpr.br; Universidade Federal do Paraná; Curitiba - PR - Brazil

ABSTRACT

The aim of the present work was to evaluate the inoculation effects of Azospirillum sp. RAM-7 strain, in seeds of wheat, barley and oats cultures on yield and total nitrogen content of the grains in greenhouse experiments. Seeds inoculation with Azospirillum sp. RAM-7 strain enhanced grain yields, even so, the responses vary among the evaluated cultures. For wheat, significant increases were obtained when the inoculation was associated to 100% of the recommended nitrogen, although the treatment that received only inoculation produced 7.4% above the control, however this difference wasn't significant. For barley, the presence of the inoculant substituted 20% the recommended nitrogen fertilization. For oats the inoculation with Azospirillum sp. RAM-7 didn't provide a significant increase in grain yields. In relation to the total nitrogen content of the grains, for all studied cultures, significant differences were not observed among the evaluated treatments (p < 0.05).

Key words: Azospirillum; Wheat; Barley; Oats; Nitrogen fixation; Plant growth promotion

RESUMO

O presente trabalho teve por objetivo avaliar os efeitos da inoculação de Azospirillum sp. RAM-7, em sementes das culturas de trigo, cevada e aveia sobre a produtividade e teor de nitrogênio total dos grãos, em experimentos implantados em de casa-de-vegetação. A inoculação das sementes com Azospirillum sp. RAM-7 aumentou a produtividade, porém, estas respostas variam entre as culturas avaliadas. Para o trigo, aumentos significativos foram obtidos quando a inoculação foi associada a 100% do nitrogênio recomendado, já o tratamento que recebeu somente inoculação produziu 7,4% acima do controle, porém, esta diferença não foi significativa. Para a cevada, a presença do inoculante substituiu 20% da adubação recomendada de nitrogênio. Para a aveia, a inoculação com Azospirillum sp. RAM-7 não proporcionou aumento significativo na produtividade. Em relação ao teor de nitrogênio total dos grãos, para as três culturas, não foram observadas diferenças significativas entre os tratamentos avaliados (p<0,05).

INTRODUCTION

In the current agriculture, nitrogen is a limitant nutrient for growth and consequently to the yield of cultures. This element (N2) is found in the gaseous form, constituting approximately 78% of the gases that form the atmospheric air, even so, plants and animals don't get to use it in this form for their metabolism (Döbereiner, 1997; Gyurján et al., 1995).

The plants obtain the nitrogen, mainly by the application of nitrogen fertilizers, industrially synthesized from the atmospheric dinitrogen (N2). This element, becomes also available for the plants by the biological fixation of nitrogen (BFN), realized by some bacteria denominated diazotrophic, which possesses an enzymatic apparatus capable to break the triple bound between two nitrogen atoms from the atmospheric nitrogen, forming ammonia that is similar to the industrial process, but without the expense of non-renewable energetic sources (Döbereiner and Baldani, 1998; Okon and Vanderleyden, 1998; Victoria et al., 1992).

The nitrogen, which is one of the essential elements, is absorbed in great quantities by the plants, needing to be available at high concentration in the soil (Pöttker, 2000). The nitrogen rate utilized for cultures vary according to the organic matter content of the soil, the previous culture and the utilized cultivar. Among the agricultural systems that contribute to the recycle of lost nitrogen to the atmosphere, the most important are the symbioses of bacterias with leguminous plants, although, other less specific associations with cereals and various Graminae are standing out (Döbereiner, 1992).

The knowledge of nitrogen biological fixation in non-leguminous plants, mainly in Graminae, among them several cereals, became one of the largest challenges, since these represent the more important alimentary base of the population, mainly in developing countries (Boddey and Döbereiner, 1994; Döbereiner, 1992).

The individual nitrogen need of the six billion inhabitants on earth is the average of 11 g.day-1, which is equivalent to 70 g of protein, or approximately 24 million tons of nitrogen a year. Nowadays, the biological fixation of nitrogen contributes with approximately 35% of the human diet of the necessary protein for everyone (Vance, 1999). The great importance of the nitrogen resides in the fact that it is an essential constituent of the proteins, nucleic acids and other compounds of nitrogen bases, essential to the vital processes of all live beings (Payne et al., 1981).

Microorganisms capable of fixing nitrogen in free life, in spite of important in number, in general contribute a little with fixed nitrogen. The effects of those bacterias are mainly in the promotion of plants root growth, as they produce growth-promoting substances. The great interest in the biological fixation of nitrogen in Graminea is related to the better utilization of water by these cultures, in relation to the leguminous plants and also by showing better photosynthetic effectiveness by its great majority. Being the Graminea broadly used as food by the man, even if, a part of the nitrogen was just supplied by the association with bacterias, the utilization of nitrogen fertilizers would save the same amount or it would be superior as the verified for leguminous plants, which can be self-sufficient in nitrogen (Döbereiner, 1992).

The genera Azospirillum, Herbaspirillum, Azobacter and Acetobacter show generalized occurrence in economically important cultures such as corn, wheat, rice, sorghum and sugar cane, like this being with frequency, in experiments seeking the agronomic utilization as biofertilizers (Döbereiner, 1997; Reinhold and Hurek, 1988; Sundaram et al., 1988). The bacterias of the Azospirillum genera presents application potential in agricultural systems, around 70% of the experiments up to 30% in productivity (Bashan and Holguin, 1997; Dalla Santa et al., 2004; Fani et al., 1995; Katupitiya et al., 1995; Machado et al., 1998; Sumner, 1990).

Azospirillum bacterias form different types of association in diverse vegetables species. Initially it was believed that they were found only at the rhizosphere, but later on they were isolated from the soil and also certain endophytic strains, which are capable to colonize internally the plant, supplying the nitrogen with more efficiency (Assmus, et al., 1995; Bashan and Levanony, 1990; Döbereiner et al., 1995; Fischer, et al., 2003; Hauwaerts, et al., 2002; Hecht-Buchholz, 1998; James, 2000; Kirchhof et al. 1997; Ramos, et al., 2002).

The promotion of plants growth inoculated with Azospirillum has been obtained in field conditions and greenhouse experiments, resulting in significant changes in several characteristics of the plants. The inoculation can cause increase in the dry weight and in the accumulation of total nitrogen of the plant, in the grain yields and in the weight of the grains, in the germination rate of the seeds and in changes in the duration of the plants growth stages (Boddey and Döbereiner, 1988; Fages, 1994; Fallik and Okon, 1996; Nur et al., 1980; Pandey et al 1998; Sumner, 1990).

The beneficial effects caused by the inoculation with Azospirillum are not only due to FBN in the rhizosphere, but mainly, for the best efficiency in the absorption of water and nutrients, which happens due to a more developed root system, increasing the soil area explored by the roots. This better development of the plants root system, inoculated with Azospirillum, is caused by the capacity that a lot of strains present in producing growth promoters substances of plants (Bashan and Holguin, 1997; Boddey et al., 1986; Döbereiner, 1992; Fallik and Okon, 1996; Kucey, 1988; Reis et al., 2000)

The Azospirillum inoculation responses in non-leguminous plants are still difficult to estimate. The results inconsistency in inoculation experiments is related with the inoculation techniques, inoculation rate, low survival of inoculated strains, physical and chemical characterization of the soil, physiological state of the bacteria, improper strain, plant genotype, presence of high number of native microorganisms and pesticides influence. (Bashan et al., 1995; Fages,1994; Itzigsohn et al. 1995).

The present work had as objective to verify the Azospirillum sp. RAM-7 inoculation effect in seeds of wheat, barley and oats on grain yield and nitrogen content of the grains by the representative importance of cost reduction with nitrogen fertilization in food production.

MATERIAL AND METHODS

Inoculant production

The strain of Azospirillum sp. RAM-7 was obtained from Instituto Cubano de Investigaciones de los Derivados de la Caña de Azúcar (ICIDCA). This strain present good biomass production, and in preliminary tests with other cultures increased de yield. The biomass of Azospirillum utilized as inoculant was produced in a MDL Marubishi fermenter, at Biotechnological Processes Laboratory of Federal University of Paraná. The fermentation conditions and the utilized composition of the culture media were the same as described by Fernández et al. (1999). The final concentration of Azospirillum sp. RAM-7 strain in the fermentation broth was of 1010 CFU.mL-1, this broth was maintained at 4º C until utilization as inoculant.

Greenhouse experiment

The experiments with wheat cultivars OR-1, barley BR-2 utilized for beer production and oats FAPA-1, were implemented in greenhouse at the Agronomic Sector of Federal University of Paraná. Different nitrogen fertilization levels associated or not with the inoculation of Azospirillum sp. RAM-7 strain were evaluated. The assay was composed of the following treatments: control (without nitrogen and uninoculated); inoculated (IN); IN associated to 20, 40, 60, 80 e 100% of nitrogen (N) recommended for each culture and the treatment with 100% nitrogen and uninoculated.

For wheat, the recommended ideal fertilization with nitrogen was 84 mg/dm3 of soil, for barley and oats 56 mg/dm3 of soil. The nitrogen fertilization with urea as N source was applied in portions during inoculation, and at the seed coating at the beginning of the sowing. The fertilization with phosphorus (P2O5) and potassium (K2O) were the same for all the treatments of the three cultures, being 350 and 80 mg/dm3 of soil, respectively at planting.

The inoculation with Azospirillum sp. RAM-7 was done immediately before planting by the method of seeds coating contamination by utilizing the fermentation broth with concentration of 109 CFU.mL-1. For the three cultures, the inoculation potential with Azospirillum sp. RAM-7 was 106 CFU.g-1 of seed.

The experimental unities were composed by pots containing 5 kg of previously sieved soil, disposed in complete randomized blocks with four repetitions for each treatment. In each experimental unit 10 seeds were planted, after germination three plants for experimental unity were aleatory selected. All the necessary treatments for adequate development of the cultures were realized, such as control of weeds, fungicide application and irrigation.

Analysis

The treatments effects on the assays with wheat, barley and oats were evaluated in relation to grain yield (grams per pot), and total nitrogen content of the grains was estimated by the Kjeldahl method (AOAC, 1996). The averages were statistically compared using Tukey multiple test at significance P = 0.05.

RESULTS AND DISCUSSION

Azospirillum sp. RAM-7 strain inoculation in wheat seeds, cultivar OR-1

The averages of grain yield and total nitrogen content of the experiment with wheat cultivar OR-1, are demonstrated in Table 1. The obtained data permitted to verify that the wheat seeds inoculated with Azospirillum sp. RAM-7 strain enhanced grain yield.

The treatment that received only inoculation produced 7.4% above the control, although this difference wasn't significant (p<0.05). When the inoculation was associated to 100% of the N recommended for the experiment, it was verified a significant augmentation in grains production, being 9.0% superior in relation to the treatment with 100% of N and uninoculated (p<0.05). Significant enhances in wheat grains yields, in treatments associating Azospirillum with mineral nitrogen fertilization are described in literature. Although, normally the greatest enhances on grain yield caused by Azospirillum sp. inoculation are obtained in association to doses of nitrogen inferior to greatest dose (Didonet et al., 1996; Millet et al., 1984; Raí and Guar, 1988; Sumner, 1990).

These grain yield increases, caused by the inoculation with Azospirillum are not just related with the capacity that these bacterias present in fix the atmospheric nitrogen but also, due to the production of plant growth promoting substances. These phytohormones promote the root growth of the plants, consequently increasing nutrients and water absorption areas (Barbieri et al., 1986; Creus et al., 1996; Kucey, 1988; Reis et al., 2000; Steenhoudt and Vanderleyden, 2000).

In relation to the accumulation of total nitrogen in the wheat grains, significant differences were not observed by the inoculation of Azospirillum sp. RAM-7 strain between the evaluated treatments (p<0.05).

Azospirillum sp. RAM-7 inoculation in barley seeds, cultivar BR-2 utilized for beer production

For barley, Azospirillum sp. RAM-7 strain provided an increase on grain yield. The averages of yield and total nitrogen content of the grains are demonstrated in Table 2. In spite of being statistically similar, the treatment that received only the inoculum (IN) had a superior productivity in relation to the control (C).

The positive effect caused by the bacteria inoculation on grain yield was also observed by comparing the treatments that received the ideal quantity of the recommended nitrogen fertilization for the experiment. The grain yield of the treatment in which the inoculation is associated to 100% of the N fertilization, was 6% superior, in relation to the treatment that received the same N fertilization content without inoculation (p<0.05). The production of the treatments inoculated and associated to 80% of N and with 100% of N without inoculation were statistically similar being, demonstrated in this case that the presence of the inoculant substituted 20% of the recommended N fertilization for this experiment.

In relation to total nitrogen content of the grains, it was observed that the nitrogen chemical supply was essential for a larger accumulation in the evaluated tissues. However, the inoculation with Azospirillum sp. RAM-7 didn't provide larger accumulation of nitrogen in the grains (Table 2). The greater accumulation of nitrogen in the grains, caused by the inoculation of bacterias of the genera Azospirillum, is due to a larger nitrogen offer for the plant. This larger offer can be consequence of nitrogen biological fixation process accomplished by the bacterias, or the capacity of certain strains in reducing the nitrate, or that the inoculated plants present a more developed root system, allowing the exploration of a larger soil area (Baldani et al., 1983; Boddey and Döbereiner, 1988; Boddey et al., 1986; Christiansen-Weniger and Van Veen, 1991; Didonet et al., 1996; Döbereiner, 1992; Fages, 1994; Ferreira et al., 1987; Kapulnik et al., 1981; Raí and Guar, 1988).

Few data of inoculant application with Azospirillum in barley is found. The inoculation of barley seeds with Azospirillum brasilense increased dry matter and barley grains yield, even so, this increase was not significant. Significant increases happened when the inoculation of the bacteria was associated to different endophytic fungi (Rao, 1981).

Azospirillum sp. RAM-7 strain inoculation in oats seeds, cultivar FAPA-1

For the oats, growing increases in yield were observed by the elevation of applied nitrogen doses, even so, the inoculation with Azospirillum sp. RAM-7, didn't provide a significant increase in yield and total nitrogen content of the grains (Table 3). These results were obtained even for the treatment that received only the inoculation as for the treatment associated to 100% of mineral nitrogen fertilization, recommended for this assay.

The effects of Azospirillum sp. RAM-7 inoculation were different in the three evaluated cultures. The specificity in the association of the plant and bacteria strain was observed in several experiments accomplished with different cultivars, as well as, among the different cultures (Millet et al., 1984). In this way, for the intensive use of inoculants with associative bacterias, it is needed a wide isolation, to select inside of the great existent diversity, the best combination between genotype of the plant and bacteria strain, as well as, the selection of efficient bacterias in the colonization of the roots, nitrate reducer, producer of phytohormones and capable to fix significant amounts of nitrogen (Baldani et al., 2002).

The agronomic use of Azospirillum is being extensively tested, and the results about the cultures yield are inconsistent. This inconsistency can be related with the not controlled field conditions, technique and inoculation rate, low survival of the inoculated strains, physical and chemical characteristics of the soil, physiologic state of the bacteria, inappropriate strain, plant genotype, presence of high number of native microorganisms and pesticides influence (Bashan et al., 1995; Chotte et al., 2002; Itzigsohn et al., 1995; Ramos et al., 2002). More consistent results are necessary, for the commercial development of inoculants with Azospirillum (Fages, 1994). Constant responses, caused by the inoculation of Azospirillum resulting in yield increases above 20% are considered commercially viable, for the current agriculture (Bashan and Levanony, 1990).

Received: July 23, 2003;

Revised: October 20, 2003;

Accepted: June 11, 2004.

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  • *
    Author for correspondence
  • Publication Dates

    • Publication in this collection
      14 Feb 2005
    • Date of issue
      Nov 2004

    History

    • Accepted
      11 June 2004
    • Reviewed
      20 Oct 2003
    • Received
      23 July 2003
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