THE RESURRECTION PLANT <i>TRIPOGON SPICATUS</i> (POACEAE) HARBORS A DIVERSITY OF PLANT GROWTH PROMOTING BACTERIA IN NORTHEASTERN BRAZILIAN CAATINGA

Fernandes-Júnior, Paulo Ivan; Aidar, Saulo de Tarso; Morgante, Carolina Vianna; Gava, Carlos Alberto Tuão; Zilli, Jerri Édson; Souza, Layane Silva Barbosa de; Marinho, Rita de Cássia Nunes; Nóbrega, Rafaela Simão Abrahão; Brasil, Marivaine da Silva; Seido, Sirando Lima; Martins, Lindete Míria Vieira

doi:10.1590/01000683rbcs20140646

Abstracts

Plant species that naturally occur in the Brazilian Caatinga(xeric shrubland) adapt in several ways to these harsh conditions, and that can be exploited to increase crop production. Among the strategic adaptations to confront low water availability, desiccation tolerance stands out. Up to now, the association of those species with beneficial soil microorganisms is not well understood. The aim of this study was to characterize Tripogon spicatusdiazotrophic bacterial isolates from the Caatingabiome and evaluate their ability to promote plant growth in rice. Sixteen bacterial isolates were studied in regard to their taxonomic position by partial sequencing of the 16S rRNA gene, putative diazotrophic capacity, in vitro indole-acetic acid (IAA) production and calcium phosphate solubilization, metabolism of nine different C sources in semi-solid media, tolerance to different concentrations of NaCl to pHs and intrinsic resistance to nine antibiotics. Finally, the ability of the bacterial isolates to promote plant growth was evaluated using rice (Oryza sativa) as a model plant. Among the 16 isolates evaluated, eight of them were classified as Enterobacteriaceae members, related to Enterobacter andPantoea genera. Six other bacteria were related toBacillus, and the remaining two were related toRhizobium and Stenotrophomonas. The evaluation of total N incorporation into the semi-solid medium indicated that all the bacteria studied have putative diazotrophic capacity. Two bacteria were able to produce more IAA than that observed for the strain BR 11175^Tof Herbaspirillum seropedicae. Bacterial isolates were also able to form a microaerophilic pellicle in a semi-solid medium supplemented with different NaCl concentrations up to 1.27 mol L^-1. Intrinsic resistance to antibiotics and the metabolism of different C sources indicated a great variation in physiological profile. Seven isolates were able to promote rice growth, and two bacteria were more efficient than the reference strainAzospirillum brasilense, Ab-V5. The results indicate the potential of T. spicatus as native plant source of plant growth promoting bacteria.

biological nitrogen fixation; inoculant; diazotrophic bacteria; Semi-arid; desiccation tolerant plants

As espécies vegetais que ocorrem naturalmente na Caatinga brasileira apresentam diversas adaptações às condições adversas que podem ser exploradas para aumentar a produção vegetal. Entre essas estratégias adaptativas para o enfrentamento da baixa disponibilidade hídrica, a tolerância à dessecação pode ser destacada. Até o momento, a associação entre essas espécies e os microrganismos benéficos do solo não é bem entendida. Os objetivos deste trabalho foram caracterizar bactérias diazotróficas de Tripogon spicatus e avaliar a capacidade de promoção do crescimento delas em plantas de arroz. Dezesseis isolados bacterianos foram estudados quanto a seu posicionamento taxonômico por meio do sequenciamento parcial do gene 16S rRNA, potencial diazotrófico, produção de ácido indol acético (AIA) e solubilização de fosfato de cálcio in vitro, metabolismo de nove diferentes fontes de C em meio semissólido, tolerância a diferentes concentrações de NaCl a pHs e resistência intrínseca a nove antibióticos. A habilidade em promover o crescimento vegetal foi avaliada utilizando o arroz (Oryza sativa) como planta-modelo. Dentre os 16 isolados avaliados, oito foram classificados como pertencentes à família Enterobacteriaceae, relacionados aos gêneros Enterobacter e Pantoea. Seis outros isolados foram relacionados a Bacillus e outros dois a Rhizobium e Stenotrophomonas. A avaliação da incorporação do N ao meio semissólido demonstrou o potencial diazotrófico de todos os isolados. Duas bactérias produziram mais AIA do que a estirpe BR 11175^T de Herbaspirillum seropedicae. Isolados bacterianos foram capazes de formar película em meio semissólido suplementado com concentrações de NaCl de até 1.27 mol L^-1. A resistência intrínseca a antibióticos e o metabolismo de diferentes fontes de C indicaram um perfil fisiológico muito variável. Sete isolados foram capazes de aumentar o crescimento das plantas de arroz, mais eficientemente do que a estirpe de referência Ab-V5 de Azospirillum brasilense. Os resultados indicaram o potencial de T. spicatus como uma espécie nativa fonte de bactérias promotoras de crescimento vegetal.

fixação biológica do nitrogênio; inoculante; bactérias diazotróficas; Semiárido; plantas tolerantes à dessecação

INTRODUCTION

The natural biome which encompasses most of the Northeast region of Brazil is the Brazilian Steppic Savanna, known as the Caatinga biome. The main features of this natural environment are the short and concentrated rainy season associated with high incident solar radiation that causes high diurnal temperatures and water deficit (Ab’Saber, 2006Ab’Saber AN. Ecossistemas do Brasil. São Paulo: Metalivros; 2006.). Due to these environmental characteristics, plant species inhabiting theCaatinga exhibit several adaptations to drought and other abiotic stresses for successful colonization of the biome.

Among drought tolerant plants, a few of them can survive long periods of severe desiccation. This group is called “desiccation tolerant plants” or “resurrection plants” (Gaff, 1987Gaff DF. Desiccation tolerant plants in South-America. Oecologia. 1987;74:133-6.). These species are able to maintain viable quiescent vegetative tissues throughout long desiccation periods due to the activation of several mechanisms, including strong light protection of leaf tissues (Aidar et al., 2010Aidar ST, Meirelles ST, Pocius O, Delitti WBC, Souza GM, Gonçalves AN. Desiccation tolerance in Pleurostima purpurea(Velloziaceae). Plant Growth Reg. 2010;62:193-202., 2014Aidar ST, Meirelles ST, Oliveira RF, Chaves ARM, Fernandes-Júnior PI. Changes of photosynthetic responses in the poikilochlorophyllous desiccation tolerant plant Pleurostima purpurea (Velloziaceae). Photosynthetica. 2014;52:24-133.), synthesis of osmoprotectants, membrane and protein stabilizers (Morse et al., 2011Morse M, Rafudeen MS, Farrant JM. An overview of the current understanding of desiccation tolerance in the vegetative tissues of higher plants. Adv Bot Res. 2011;57:319-47.).Tripogon spicatus Ekman Nees is a resurrection grass naturally occurring in the Americas from the south of Texas (USA) to the Patagonia Desert (Argentina). In Brazil, this species is found in the Semi-arid (Northeast) and seasonally flooded Pantanal (Central-West) regions (Gaff, 1987Gaff DF. Desiccation tolerant plants in South-America. Oecologia. 1987;74:133-6.). The recovery of photosynthetic activity of T. spicatus soon after rehydration may involve association with microorganisms that facilitate some important functions.

In addition to physiological mechanisms, plant tolerance to harsh environmental conditions can be influenced by plant association with soil plant growth promoting bacteria (PGPB), which are able to fix nitrogen release insoluble nutrients, secrete analogs to plant hormones, and control soil-borne pathogens, among other mechanisms (Kuss et al., 2007Kuss AV, Kuss VV, Lovato T, Flores ML. Fixação de nitrogênio e produção de ácido indolacético in vitro por bactérias diazotróficas endofíticas Pesq Agropec Bras. 2007;42:1459-65.; Puente et al., 2009Puente ME, Li CY, Bashan Y. Endophytic bacteria in cacti seeds can improve the development of cactus seedlings. Environ Exp Bot. 2009;66:402-8.; Grover et al., 2011Grover M, Ali SZ, Sandhya V, Rasul A, Venkateswarlu B. Role of microorganisms in adaptation of agriculture crops to abiotic stresses. World J Microbiol Biotechnol. 2011;27:1231-40.; Gumiere et al., 2014Gumiere T, Ribeiro CM, Vasconcellos RLF, Cardoso EJBN. Indole-3-acetic acid producing root-associated bacteria on growth of Brazil Pine (Araucaria angustifolia) and Slash Pine (Pinus elliottii). Anton Leeuw. 2014;105:663-9.;Santos et al., 2015Santos JS, Viana TO, Jesus CM, Baldani VLD, Ferreira JS. Inoculation and isolation of plant growth-promoting bacteria in maize grown in Vitória da Conquista, Bahia, Brazil. R Bras Ci Solo. 2015;39:78-85.). Several studies that isolated and evaluated the diversity and biotechnological potential of PGPB in Brazil have already been carried out on crop species, mainly with grasses such as maize, rice, wheat, and sugar cane (Baldani et al., 2009Baldani JI, Teixeira KRS, Schwab S, Olivares FL, Hemerly AS, Urquiaga S, Reis VM, Nogueira EM, Araújo JLS, Baldotto LEB, Soares LHB, Vinagre F, Baldani VLD, Carvalho TLG, Alves, BJR, James EK, Jantalia CP, Ferreira PCG, Vidal MS, Boddey RM. Fixação biológica de nitrogênio em plantas da família Poaceae (antiga gramineae). Tópicos Ci Solo. 2009;7:203-71.; Hungria et al., 2010Hungria M, Campo RJ, Souza EM, Pedrosa FO. Inoculation with selected strains of Azospirillum brasilense and A. lipoferumimproves yields of maize and wheat in Brazil. Plant Soil. 2010;331:413-25.).

Regarding wild non-legume species, the search for bacterial isolates able to promote plant growth has been carried out worldwide since the 1980’s (Reinhold et al., 1987Reinhold B, Hurek T, Fendrik I, Pot B, Gillis M, Kersters K, Thielemans S, Deley J. Azospirillum halopraeferens sp-nov, a nitrogen-fixing organism associated with roots of kallar grass (Leptochloa fusca (L) Kunth). Inter J Syst Bacteriol. 1987; 37:43-51.; Bilal et al., 1990Bilal R, Rasul G, Mahmood K, Malik KA. Nitrogenase activity and nitrogen-fixing bacteria associated with the roots of Atriplexspp growing in saline sodic soils of Pakistan. Biol Fertil Soils. 1990;9:315-20.; Doty et al., 2009Doty SL, Oakley B, Xin G, Kang JW, Singleton G, Khan Z, Vajzovic A, Staley JT. Diazotrophic endophytes of native black cottonwood and willow. Symbiosis. 2009;47:23-33.;Lopez et al., 2011Lopez BR, Bashan Y, Bacilio M. Endophytic bacteria ofMammillaria fraileana, an endemic rock-colonizing cactus of the southern Sonoran Desert. Arch Microbiol. 2011;193:527-41.; Jha et al., 2012Jha B, Gontia I, Hartmann A. The roots of the halophyteSalicornia brachiata are a source of new halotolerant diazotrophic bacteria with plant growth-promoting potential. Plant Soil. 2012;356:265-77.; Zahid et al., 2015Zahid M, Abbasi MK, Hameed S, Rahim N. Isolation and identification of indigenous plant growth promoting rhizobacteria from Himalayan region of Kashmir and their effect on improving growth and nutrient contents of maize (Zea mays L.). Front Microbiol. 2015;6:207. doi: 10.3389/fmicb.2015.00207). In Brazil, few plant groups have been studied only in the last few years (Costa and Melo, 2012Costa FEC, Melo IS. Endophytic and rhizospheric bacteria fromOpuntia ficus-indica mill and their ability to promote plant growth in cowpea, Vigna unguiculata (L.) Walp. Afr J Microbiol Res. 2012;6:1345-53.; Fernandes Júnior et al., 2013Fernandes Júnior PI, Pereira GMD, Perin L, Silva LM, Barauna AC, Alves FM, Passos SR, Zilli JE. Diazotrophic bacteria isolated from wild riceOryza glumaepatula (Poaceae) in the Brazilian Amazon. R Biol Trop. 2013;61:991-9.; Kavamura et al., 2013Kavamura VN, Santos SN, Silva JL, Parma MM, Ávila LA, Visconti A, Zucchi TD, Taketani RG, Andreote FD, Melo IS. Screening of Brazilian cacti rhizobacteria for plant growth promotion under drought. Microbiol Res. 2013;168:183-91.). Recently, bacteria from native cactus species growing in the Caatinga were isolated, and evaluation of their physiological features and ability to promote plant growth indicated the presence of bacteria with biotechnological applications that promote the growth of cowpea (Costa and Melo, 2012Costa FEC, Melo IS. Endophytic and rhizospheric bacteria fromOpuntia ficus-indica mill and their ability to promote plant growth in cowpea, Vigna unguiculata (L.) Walp. Afr J Microbiol Res. 2012;6:1345-53.) and maize (Kavamura et al., 2013Kavamura VN, Santos SN, Silva JL, Parma MM, Ávila LA, Visconti A, Zucchi TD, Taketani RG, Andreote FD, Melo IS. Screening of Brazilian cacti rhizobacteria for plant growth promotion under drought. Microbiol Res. 2013;168:183-91.). In spite of those physiologically peculiar characteristics, the resurrection plants inhabiting the Caatinga biome have not yet been evaluated in regard to the presence of PGPB.

Isolation and characterization of the PGPB from T. spicatus can advance the understanding of the physiology and ecology of this resurrection plant. In addition, evaluation of the biotechnological potential of those bacteria can indicate isolates to be applied as inoculants to crops. In this study, the physiological characteristics and taxonomic position of putative diazotrophic bacteria from T. spicatus collected in theCaatinga biome were evaluated, as well as their ability to promote the growth of rice.

MATERIAL AND METHODS

Bacterial isolates and partial 16S rRNA gene sequencing

The bacterial isolates used in the present study were previously isolated by Fernandes Júnior et al. (2012a). They were obtained from healthyTripogon spicatus plants collected in the municipality of Lagoa Grande (Pernambuco, Brazil), from 8º 48’ 11.6” and 8º 48’ 23.9” S and from 40º 14’ 48.4” and 40º 14’ 58.7” W in an area of Caatinga, in the rainy seazon of 2011. To obtain putative diazotrophic isolates, the authors adopted an isolation strategy using a semi-solid medium (Döbereiner et al., 1995Döbereiner J, Baldani JI, Baldani VLD. Como isolar e identificar bactérias diazotróficas de plantas não leguminosas. Brasília: Embrapa-SPI; Seropédica: Embrapa Agrobiologia; 1995.; Baldani et al., 2014Baldani JI, Reis VM, Videira SS, Boddey LH, Baldani VLD. The art of isolating nitrogen-fixing bacteria from non-leguminous plants using N-free semi-solid media: a practical guide for microbiologists. Plant Soil. 2014;348:413-31.). Isolation was carried out by crushing the washed and surface disinfected roots of T. spicatus in 0.15 mol L^-1 NaCl and inoculating them in BMGM semi-solid culture medium (Estrada-De Los Santos et al., 2001Estrada de Los Santos P, Bustillos-Cristales R, Caballero-Mellado J.Burkholderia, a genus rich in plant-associated nitrogen fixers with wide environmental and geographic distribution. Appl Environ Microbiol. 2001;67:2790-8.).

Amplifications were conducted using the universal 27F and 1492R for partial 16S rRNA gene sequencing (Weisburg et al., 1991Weisburg WG, Barns SM, Pelletier DA, Lane DJ. 16S ribosomal DNA amplification for phylogenetic study. J Bacteriol. 1991;173:697-703.). The PCR products were purified using the commercial HiYield^TM PCR DNA Mini Kit (Real Biotech Corp, Taipei, Taiwan). Sequencing was carried out using the 27F primer in a 3730 xlsequencer (Applied Biosystems, Drive Foster City, CA, USA) according to manufacturer’s instructions.

The quality of the sequences was verified using the Sequence Scanner Software v. 2.0 (Applied Biosystems). Good quality sequences with no less than 400 bases were used for bacterial identification (Silva et al., 2013Silva MCP, Figueiredo AF, Andreote FD, Cardoso EJBN. Plant growth promoting bacteria in Brachiaria brizantha. World J Microbiol Biotechnol. 2013;29:163-71.). The sequences were compared through the GenBank sequences database (National Center for Biotechnology Information) by means of the Basic Local Alignment Search Tool (BLASTn) (http://www.ncbi.nlm.nih.gov/Genbank) (Altschul et al., 1990Altschul S, Gish W, Miller W, Myers E, Lipman D. Basic local alignment search tool. J Mol Biol. 1990;215:403-10.). The sequences were deposited in the GenBank under the accession numbers from KF878276 to KF878293.

Plant growth promotion (PGP) traits: putative diazotrophic capacity,in vitro production of indole-acetic acid (IAA) analogs and calcium phosphate solubilization

The bacteria were grown in liquid DYGS medium (Rodrigues Neto et al., 1986) for three days at 120 rpm in an orbital shaker for assessment of bacterial plant growth promoting traits and other phenotypic evaluations. The bacterial broth was centrifuged (6,000 g for 3 min), the supernatant was discarded and the pellet was re-suspended in saline solution (0.15 mol L^-1 NaCl). Cell suspensions were used for inoculation in solid, semi-solid, or liquid medium for all phenotypic evaluations described below.

The diazotrophic capacity of the bacterial isolates grown in semi-solid medium was assessed through quantification of total N content after pellicle formation of the putative diazotrophic bacteria (Kuss et al., 2007Kuss AV, Kuss VV, Lovato T, Flores ML. Fixação de nitrogênio e produção de ácido indolacético in vitro por bactérias diazotróficas endofíticas Pesq Agropec Bras. 2007;42:1459-65.; Silva et al., 2013Silva MCP, Figueiredo AF, Andreote FD, Cardoso EJBN. Plant growth promoting bacteria in Brachiaria brizantha. World J Microbiol Biotechnol. 2013;29:163-71.). The bacteria were grown in vials containing 10 mL of BMGM semi-solid medium at 28 °C in a growing chamber for 7 days. After the incubation period, the medium were homogenized handly, frozen at -20 °C, and heated in a microwave oven for 2 min. The medium was homogenized again and a 5 mL aliquot was taken for quantification of total N content in the medium by the modifiedsemi-micro Kjeldahl method (Liao, 1981Liao CFH. Devarda alloy method for total nitrogen determination. Soil Sci Soc Am J. 1981;45:852-5.). A positive control treatment with the diazotrophicA. brasilense (Ab-V5) and a negative control treatment with the non-pellicle forming strain CIAT 899^T of Rhizobium tropici were also evaluated. An aliquot of non-inoculated culture medium was also digested and distilled as blank to calculate the N concentration in the culture medium.

The production of indole-acetic acid (IAA) analogs in vitro was evaluated according to the spectrophotometric method described by Sarwar and Kremer (1995)Sarwar M, Kremer RJ. Determination of bacterially derived auxins using a microplate method. Lett Appl Microbiol. 1995;20:282-5. at 520 nm reading wavelength. The cell suspensions (100 µL) were inoculated in NFb liquid medium (Döbereiner et al., 1995Döbereiner J, Baldani JI, Baldani VLD. Como isolar e identificar bactérias diazotróficas de plantas não leguminosas. Brasília: Embrapa-SPI; Seropédica: Embrapa Agrobiologia; 1995.) supplemented with 168 mg L^-1 of synthetic L-tryptophan (Vetec Química Fina, Rio de Janeiro, Brazil) without bromothymol blue. The bacterial isolates were grown under constant shaking for five days. To construct the calibration curve, solutions with known concentrations of synthetic IAA (Sigma Aldrich, St Louis, USA) were prepared with ultra-pure water, mixed with the Salkowski solution, incubated, and read as described for the samples.

Solubilization of calcium phosphate was assessed according to Sylvester-Bradley et al. (1982)Sylvester-Bradley R, Asakawa N, La Torraca S, Magalhães FMM, Oliveira LA, Pereira RM. Quantitative survey of phosphate solubilizing microorganisms in the rhizosphere of grasses and legumes in the Amazon. Acta Amaz. 1982;12:15-22. using the GL medium supplied with CaCl₂ (150 mL at 0.1 mol L^-1) and KH₂PO₄ (150 mL at 0.75 mol L^-1). Aliquots of 10 μL of the bacterial suspensions were inoculated at equidistant points in each of the Petri dishes containing the GL medium. The inoculated plates were incubated at 28 °C for 5 days, and the solubilization index was calculated by the ratio between the diameter of the translucent area surrounding the colony and the colony diameter.

These experiments were performed in a completely randomized design with three replications.

In vitro growth in the semi-solid BMGM medium under different conditions and intrinsic antibiotic resistance

For assessment of bacterial growth in a semi-solid medium, as described above, the cell suspension was inoculated at the same time in BMGM semi-solid medium, modified by the conditions described below and incubated in a growth chamber at 28 °C for 7 days.

To assess the growth of the isolates at different salt concentrations, a 10 μL aliquot of the cell suspension was inoculated in BMGM semi-solid medium, supplemented with 0.09, 0.17, 0.52, 0.87, and 1.27 mol L^-1 of NaCl. Tolerance to different pHs was also assessed through bacterial inoculation in a semi-solid BMGM medium with pHs adjusted to 4.0 and 9.0. Bacterial growth using different C sources was also analyzed using semi-solid BMGM medium supplemented with mannitol, glucose, malic acid, sucrose, fructose, maltose, xylose, arabinose, or citric acid (Vetec Química Fina, Rio de Janeiro, Brazil) as sole carbon sources.

For these experiments, the vials with pellicle formation, which characterizes microaerophilic diazotrophic ability of the associative bacteria were considered as “positive” and the non-forming tubes were considered “negative”. The assays were conducted with three replications in a completely randomized design. Those treatments in which positive or negative results were not observed in all three replications were repeated to ensure consistency of the results.

Intrinsic antibiotic resistance was assessed by the diffusion disc method. The cell suspensions were prepared as described above. The suspensions were optically adjusted with the aid of the MacFarland scale (point 0.5) and a 100 μL aliquot of the adjusted broth was inoculated in Petri dishes containing solid DYGS medium and spread using a Drigalski loop. At the inoculated plates were added three antibiotics filter paper discs (to avoid the overlap of the inhibition zones). Nine antibiotics were evaluated: Erythromycin (15 μg), Rifampicin (30 μg), Gentamicin (10 μg), Neomycin (30 μg), Streptomycin (10 μg), Chloramphenicol (30 μg), Vancomycin (30 μg), Ampicillin (10 μg) and Nalidixic acid (30 μg) (Cefar Diagnósticos Ltda., São Paulo, Brazil). The plate dishes were incubated for 5 days and antibiotic susceptibility or resistance was determined by the presence or absence of the inhibition zone around the discs, respectively.

Growth promotion of rice (Oryza sativa L.) in greenhouse conditions

Rice (Oryza sativa L.) cv. BRS Tropical was used as a model plant, and the experiment was set up using non-sterile soil as a substrate under greenhouse conditions. The soil sample was collected from the soil surface horizon (0.0-0.2 m) in a Argissolo Amarelo (Ultisol). The fertility characteristics of the soil were: pH(H₂O) 6.3; electrical conductivity 0.11 dS m^-1; organic matter 12.3 g kg^-1; P 44.62 mg kg^-1 (Mehlich-1); K 140 mg dm^-3 (Mehlich-1); Ca²⁺ 2.0 cmol_c dm^-3 (1 mol L^-1KCl); Mg²⁺ 0.4 cmol_c dm^-3 (1 mol L^-1KCl); Al³⁺ 0.05 cmol_c dm^-3 (1 mol L^-1 KCl); H+Al 0.66 cmol_c dm^-3; cation exchange capacity 3.44 cmol_c dm^-3; base saturation 81 %. The soil was placed in 500 mL pots for planting. The surface of the seeds was disinfected with hydrogen peroxide and washed 10 times in autoclaved distilled water before sowing the seeds. The surface disinfected seeds were then pre-germinated in Petri dishes with agar-water for 3 days. The germinated seeds were then sown in the pots (three seeds per pot) and inoculated with 1 mL of the bacterial culture broth previously grown in liquid NFb medium (around 10⁹ cells per mL).

Inoculated plants received a NH₄NO₃ solution at the rate of 50 mg/plant of N (50 % of the amount required by rice) 7 days after the planting. The following experimental treatments were evaluated: single inoculation with the 16 bacteria isolated from T. spicatus(from ESA 0001 to ESA 0016); single inoculation of Azospirillum brasilense strain Ab-V5 (1); non-inoculated controls with full N application (100 mg/plant) (1); and non-inoculated control with 50 mg/plant N. On the 12^th day after emergence, the plants were thinned, leaving only one plant per pot. The experiment was conducted until the 50^thday after plant emergence. The parameters evaluated were shoot dry weight, root dry weight, and total dry weight (shoots + roots). A completely randomized experimental design with four replications was used.

Statistical analysis

The data from all quantitative evaluations of the plant growth promoting traits and the greenhouse condition experiment were analyzed by ANOVA and the Scott-Knott mean comparison test through the Sisvar software v. 5.0.

RESULTS

Identification of bacterial isolates by partial 16S rRNA gene sequence

Among the 16 bacterial isolates analyzed, nine were related to the Enterobacteriaceae family, showing the closest relation to the genusEnterobacter or Pantoea, with sequence similarities from 99 to 100 % (Table 1). Five isolates showed similarities from 99 to 100 % with the 16S rRNA sequences of the Bacillus genus in the GenBank database. The isolate ESA 0009 was most closely related to the Stenotrophomonas genus (99 % of similarity), and the isolate ESA 0015 showed similarity of 100 % with theRhizobium genus.

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Table 1
Identification of 16 bacterial isolates from Tripogon spicatus by comparison of its partial 16S rRNA gene sequence with the sequences available in the GenBank database

In vitro plant growth promotion traits

The diazotrophic capacity of the isolates was confirmed by determination of the total N content incorporated in the culture medium (Table 2). Of the 16 isolates, 13 exhibited similar N incorporation when compared statistically to the diazotrophic A. brasilense reference strain, ranging from 23.3, for the isolates ESA 0002 and ESA 0004, to 42.0 μg of N per mL of medium (μg mL^-1), for ESA 0014. Three other isolates (ESA 0001, ESA 0003, and ESA 0009) showed lower N incorporated in the medium, ranging from 14.0 to 17.5 μg mL^-1, although these values were significantly higher than those observed for the non-pellicle forming R. tropici (3.5 μg mL^-1), indicating the diazotrophic capacity of these three isolates. The slight increase in N in the culture medium inoculated withR. tropici can be attributed to the N content in the inoculated cells and N remaining from cell suspension.

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Table 2
Nitrogen incorporation in the culture medium, in vitro indole-acetic acid production, and calcium phosphate solubilization by 16 bacterial isolates fromTripogon spicatus and reference strains. Data are means of three replications.

Regarding in vitro IAA production, the isolates ESA 0015 (82 μg mL^-1 of IAA) and ESA 0012 (51.7 μg mL^-1 of IAA) were ranked as the two highest clusters by the Scott-Knott mean range test (p<0.01), being statistically superior to the reference strain H. seropedicae BR 11175^T. Four other isolates also produced high amounts of IAA analogs, ranging from 36.8 to 42.7 μg mL^-1 of IAA, and were ranked within the same group as the reference IAA-producing strain. IAA production was not detected for the isolate ESA 0009 by the method applied, but all other isolates exhibited production of at least 5.8 μg mL^-1 of IAA.

Solubilization of calcium phosphate was observed for only four isolates. The nitrogen-fixing and IAA-producing isolate ESA 0003 showed the highest solubilization index, followed by the isolates ESA 0016, ESA 0001, and ESA 0009. The other isolates and the strains that used CIAT899^T and Ab-V5 grew in the GL medium but did not exhibit visible calcium phosphate solubilization.

Physiological characterization

The evaluation of diazotrophic ability, based on pellicle formation in the culture medium, showed that there is a number of high halotolerant bacteria among the isolates evaluated. The isolates ESA 0001, ESA 0003, ESA 0005, ESA 0007, ESA 0010, ESA 0012, ESA 0013, and ESA 0016 showed diazotrophic capacity in the BMGM semi-solid culture medium supplemented with up to 1.27 mol L^-1 of NaCl. The bacteria ESA 0006, ESA 0011, and ESA 0015 exhibited a diazotrophic character in the medium with a maximum concentration of 0.86 mol L^-1 of NaCl (Table 3). Low halotolerance was observed only for ESA 0008, which showed diazotrophic capacity in microaerophilic conditions in the medium supplemented with 0.09 mol L^-1 of NaCl, in addition to the control treatment. The pH of the medium influenced pellicle formation for six isolates and ten bacteria were able to fix nitrogen microaerophilically at both pHs evaluated. By combining these evaluations, the isolates ESA 0005, ESA 007, ESA 0011, ESA 0013, and ESA 0016 stand out for their diazotrophic ability, both under salt and pH stress conditions.

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Table 3
Tolerance to different concentrations of NaCl and pHs in vitro, ability to metabolize nine carbon sources, and intrinsic resistance to different antibiotics for 16 bacteria isolated from Tripogon spicatus

Pellicle formation in culture media supplemented with nine C sources revealed a variable profile. Half of the bacteria evaluated were able to show diazotrophic ability in the culture medium supplemented with seven or more C sources evaluated (Table 3). In contrast, six bacteria showed the ability to form the pellicle in the modified BMGM semi-solid medium supplemented with four or fewer C sources. In regard to C sources, all supplemented media allowed the growth of more than nine isolates, except for fructose. All bacterial isolates showed microaerophilic growth in the culture medium supplemented with mannitol, malic acid, or glucose, the three C sources of the original BMGM medium.

Regarding the antibiotic resistance of the bacteria, the bacterial isolates ESA 0006 and ESA 0014 showed intrinsic resistance for a large number of antibiotics, being susceptible only to gentamicin and neomycin, respectively (Table 3). In addition, the isolate ESA 0007 was resistant only to ampicillin and susceptible to all other antibiotics tested. All bacterial isolates were resistant to ampicillin, while the antibiotics least tolerated by the isolates evaluated were gentamicin and neomycin, to which only three and four bacteria were resistant, respectively.

Ability to promote rice growth

Among the bacterial isolates, seven were able to increase rice root and/or shoot growth compared to the control treatments. Among these bacteria, five promoted the same plant growth as that observed in the plants inoculated with the Ab-V5 reference strain (Table 4). Surprisingly, two bacterial isolates were statistically higher than the treatment inoculated with the reference strain and equal to those treatments that received full N fertilization. Considering those two isolates, ESA 0001 stood out; it was the only one able to promote the growth of the shoots, roots, and complete plant at the same rate that was observed in the plants that received full mineral N fertilization. The dry biomass increase as a result of inoculation with the isolate ESA 0001 was 82 and 51 % when compared to non-inoculated plants and to the plants inoculated with Ab-V5 strain, respectively.

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Table 4
Growth of ‘BRS Tropical’ rice (Oryza sativa) plants as a result of inoculation of plant growth promoting bacteria isolated from Tripogon spicatus. Data are means of four replications.

Together with ESA 0001, the isolates ESA 0016 and ESA 0015 are notable for their ability to promote plant growth. These bacteria were able to increase the shoot and total plant weight more than the increase promoted by inoculation with the Ab-V5 strain.

DISCUSSION

Identification of the bacterial isolates indicated the predominance of bacteria belonging to Enterobacteriaceae and Bacillus. Other species native to the Caatinga, for example cactus species, also harbor plant growth promoting bacteria related to those taxa, belonging to thePantoea and Bacillus genera (Kavamura et al., 2013Kavamura VN, Santos SN, Silva JL, Parma MM, Ávila LA, Visconti A, Zucchi TD, Taketani RG, Andreote FD, Melo IS. Screening of Brazilian cacti rhizobacteria for plant growth promotion under drought. Microbiol Res. 2013;168:183-91.). Furthermore, related bacteria were also isolated from Cactaceae and Poaceae at different sites around the world, including dry land environments (Peng et al., 2009Peng G, Zhang W, Luo H, Xie H, Lai W, Tang Z. Enterobacter oryzae sp nov., a nitrogen-fixing bacterium isolated from the wild rice species Oryza latifolia. Inter J Syst Evol Microbiol. 2009:59:1650-5.; Puente et al., 2009Puente ME, Li CY, Bashan Y. Endophytic bacteria in cacti seeds can improve the development of cactus seedlings. Environ Exp Bot. 2009;66:402-8.; Lopez et al., 2011Lopez BR, Bashan Y, Bacilio M. Endophytic bacteria ofMammillaria fraileana, an endemic rock-colonizing cactus of the southern Sonoran Desert. Arch Microbiol. 2011;193:527-41.). In the present study, among the 16 bacterial isolates evaluated, only two were not related to Enterobacteriaceae or Firmicutes, and they were classified asRhizobium and Stenotrophomonas. Both genera are known to include PGPB associated with non-legume crops and wild species (Ferrara et al., 2012Ferrara FIS, Oliveira ZM, Soto Gonzales HH, Floh EIS, Barbosa HR. Endophytic and rhizospheric enterobacteria isolated from sugar cane have different potentials for producing plant growth-promoting substances. Plant Soil. 2012;353:409-17.; Jha et al., 2012Jha B, Gontia I, Hartmann A. The roots of the halophyteSalicornia brachiata are a source of new halotolerant diazotrophic bacteria with plant growth-promoting potential. Plant Soil. 2012;356:265-77.; Silva et al., 2013Silva MCP, Figueiredo AF, Andreote FD, Cardoso EJBN. Plant growth promoting bacteria in Brachiaria brizantha. World J Microbiol Biotechnol. 2013;29:163-71.).

Characterization of the bacterial isolates regarding their plant growth promoting (PGP) traits revealed that some isolates showed more than one feature. For example, the highest IAA analog producing isolate, ESA 0015, which belongs to theRhizobium genus, was also clustered in the highest nitrogen-fixing group, according the statistical analysis. The same characteristics were observed in the Bacillus sp. isolate ESA 0014. These results corroborate results from other studies, in which efficient diazotrophic and phytohormone producing bacteria were isolated from cultivated (Kuss et al., 2007Kuss AV, Kuss VV, Lovato T, Flores ML. Fixação de nitrogênio e produção de ácido indolacético in vitro por bactérias diazotróficas endofíticas Pesq Agropec Bras. 2007;42:1459-65.; Ferrara et al., 2012Ferrara FIS, Oliveira ZM, Soto Gonzales HH, Floh EIS, Barbosa HR. Endophytic and rhizospheric enterobacteria isolated from sugar cane have different potentials for producing plant growth-promoting substances. Plant Soil. 2012;353:409-17.; Silva et al., 2013Silva MCP, Figueiredo AF, Andreote FD, Cardoso EJBN. Plant growth promoting bacteria in Brachiaria brizantha. World J Microbiol Biotechnol. 2013;29:163-71.;Santos et al., 2015Santos JS, Viana TO, Jesus CM, Baldani VLD, Ferreira JS. Inoculation and isolation of plant growth-promoting bacteria in maize grown in Vitória da Conquista, Bahia, Brazil. R Bras Ci Solo. 2015;39:78-85.) and wild species (Doty et al., 2009Doty SL, Oakley B, Xin G, Kang JW, Singleton G, Khan Z, Vajzovic A, Staley JT. Diazotrophic endophytes of native black cottonwood and willow. Symbiosis. 2009;47:23-33.; Jha et al., 2012Jha B, Gontia I, Hartmann A. The roots of the halophyteSalicornia brachiata are a source of new halotolerant diazotrophic bacteria with plant growth-promoting potential. Plant Soil. 2012;356:265-77.).

Bacterial isolates with the capacity to fix atmospheric N and produce high amounts of IAA analogs can be applied in the field and help in seed germination and initial root development (Gumiere et al., 2014Gumiere T, Ribeiro CM, Vasconcellos RLF, Cardoso EJBN. Indole-3-acetic acid producing root-associated bacteria on growth of Brazil Pine (Araucaria angustifolia) and Slash Pine (Pinus elliottii). Anton Leeuw. 2014;105:663-9.). At this point, the isolates ESA 0015 and ESA 0014 can be tested for this application. The ability of the PGPB to use several mechanisms to promote plant growth is desirable regarding commercial inoculant production. In this case, the same isolate can promote growth in its host by means of different mechanisms and at different phases of plant development and establishment in the field.

However, considering the three in vitro PGP characteristics evaluated in the present study, none of the bacterial isolates performed best in all of them. This observation indicates that for the T. spicatus roots there is likely more than one microorganism acting concomitantly to promote plant growth with different and complementary mechanisms (Marasco et al., 2012Marasco R, Rolli E, Ettoumi B, Vigani G, Mapelli F, Borin S, Abou-Hadid AF, El-Behairy UA, Sorlini C, Cherif A, Zocchi G, Daffonchio D. A drought resistance-promoting microbiome is selected by root system under desert farming. PlosOne, 2012;7:e48479. doi: 10.1371/journal.pone.0048479; Philippot et al., 2013Philippot L, Raaijmakers JM, Lemanceau P, van der Putten WH. Going back to the roots: the microbial ecology of the rhizosphere. Nat Rev Microbiol. 2013;11:789-99.).

Regarding their physiological features, the ability of eight isolates to fix N under microaerophilic conditions in culture media supplemented up to 1.27 mol L^-1 of NaCl (75 g L^-1) indicates that some bacteria evaluated are highly halotolerant. The halotolerance of diazotrophic associative bacteria was already shown for isolates, especially for halophyte hosts such asLeptochloa fusca (kallar grass) (Reinhold et al., 1987Reinhold B, Hurek T, Fendrik I, Pot B, Gillis M, Kersters K, Thielemans S, Deley J. Azospirillum halopraeferens sp-nov, a nitrogen-fixing organism associated with roots of kallar grass (Leptochloa fusca (L) Kunth). Inter J Syst Bacteriol. 1987; 37:43-51.), Atriplex sp. (Bilal et al., 1990Bilal R, Rasul G, Mahmood K, Malik KA. Nitrogenase activity and nitrogen-fixing bacteria associated with the roots of Atriplexspp growing in saline sodic soils of Pakistan. Biol Fertil Soils. 1990;9:315-20.), and Salicornia brachiata (Jha et al., 2012Jha B, Gontia I, Hartmann A. The roots of the halophyteSalicornia brachiata are a source of new halotolerant diazotrophic bacteria with plant growth-promoting potential. Plant Soil. 2012;356:265-77.). Of the eight highest diazotrophic halotolerant bacteria found in the present study, seven belong to the Enterobacteriaceae group, and only one (ESA 0005) was classified as Bacillus sp. The other two Enterobacteriaceae characterized here were able to grow microerophilically in the semi-solid medium supplemented with up to 0.85 mol L^-1 NaCl (50 g L^-1), and can also be considered as highly halotolerant. Among the Bacillus related isolates, halotolerance was variable since one isolate grew in the medium with 1.27 mol L^-1 NaCl, two bacteria grew microaerophilically in the semi-solid medium supplemented with 0.52 mol L^-1 NaCl, and one grew in the medium supplemented with up to 0.09 and 0.17 mol L^-1 NaCl.

Halotolerance under diazotrophic conditions of Enterobacteriaceae and Firmicutes is quite variable and can range from total inhibition, through the addition of low concentrations of salt in the culture medium, to no effect (Bilal et al., 1990Bilal R, Rasul G, Mahmood K, Malik KA. Nitrogenase activity and nitrogen-fixing bacteria associated with the roots of Atriplexspp growing in saline sodic soils of Pakistan. Biol Fertil Soils. 1990;9:315-20.; Sorokin et al., 2008Sorokin ID, Kravchenko IK, Doroshenko EV, Boulygina ES, Zadorina EV, Tourova TP, Sorokin DY. Haloalkaliphilic diazotrophs in soda solonchak soils. FEMS Microbiol Ecol. 2008;65:425-33.; Jha et al., 2012Jha B, Gontia I, Hartmann A. The roots of the halophyteSalicornia brachiata are a source of new halotolerant diazotrophic bacteria with plant growth-promoting potential. Plant Soil. 2012;356:265-77.). High tolerance to salts in vitro can indicate promising bacteria for plant inoculation in saline field environments. The other physiological characteristics evaluated showed great metabolic variability of the isolates and indicated 10 bacteria that are able to fix N in a semi-solid medium under a wide range of pH, eight isolates able to fix N in a culture medium supplemented with at least seven different C sources, and great variability in regard to intrinsic antibiotic resistance.

Combining all physiological results, the data suggest that the isolates are able to persist in the soil or in the desiccated tissues of T. spicatus due to their tolerance to harsh environments and metabolic versatility in regard to the ability to metabolize different C sources and tolerance to antibiotics that may be produced by other soil micro-organisms (Fernandes Júnior et al., 2012bFernandes Júnior PI, Lima AA, Passos SR, Gava CAT, Oliveira PJ, Rumjanek NG, Xavier GR. Phenotypic diversity and amylolytic activity of fast growing rhizobia from pigeonpea Cajanus cajan (L.) Millsp. Braz J Microbiol. 2012b;43:1604-12.; Jha et al., 2012Jha B, Gontia I, Hartmann A. The roots of the halophyteSalicornia brachiata are a source of new halotolerant diazotrophic bacteria with plant growth-promoting potential. Plant Soil. 2012;356:265-77.).

The ability of these isolates to promote rice growth showed that some bacteria can increase plant biomass at higher rates than those observed for the Ab-V5 strain that is currently used for production of commercial inoculants for rice in Brazil. Among the isolates evaluated, the N-fixing, halotolerant, and phosphate solubilizingPantoea sp. ESA 0001 and Enterobacter sp. ESA 0016 stood out through their performance. The ability of these isolates to increase rice growth at the same rate observed for the plants that received 100 mg of N indicates that, in this experiment, these bacteria may be acting with more mechanisms to help plant development than the plants supplied with only N.

Furthermore, two other Enterobacter sp., twoBacillus sp., and a Rhizobium sp. were also able to promote rice growth. It is likely that, in the soils of theCaatinga where the plant samples were taken, those bacteria can colonize the naturally occurring plants (e.g., T. spicatus) and act together with different mechanisms to promote plant growth (Philippot et al., 2013Philippot L, Raaijmakers JM, Lemanceau P, van der Putten WH. Going back to the roots: the microbial ecology of the rhizosphere. Nat Rev Microbiol. 2013;11:789-99.). For biotechnological applications, the use of inoculants that contain more than one PGPB may also be a strategy for increasing crop growth (Schultz et al., 2014Schultz N, Silva JA, Sousa JS, Monteiro RC, Oliveira RP, Chaves VA, Silva MF, Baldani JI, Boddey RM, Reis VM, Urquiaga S. Inoculation of sugarcane with diazotrophic bacteria. R Bras Ci Solo. 2014;38:407-14.).

There are results in the scientific literature showing the characteristics and application (in crop inoculation) of diazotrophic isolates obtained from wild species, for example halophytes (Jha et al., 2012Jha B, Gontia I, Hartmann A. The roots of the halophyteSalicornia brachiata are a source of new halotolerant diazotrophic bacteria with plant growth-promoting potential. Plant Soil. 2012;356:265-77.), cacti (Puente et al., 2009Puente ME, Li CY, Bashan Y. Endophytic bacteria in cacti seeds can improve the development of cactus seedlings. Environ Exp Bot. 2009;66:402-8.;Costa and Melo, 2012Costa FEC, Melo IS. Endophytic and rhizospheric bacteria fromOpuntia ficus-indica mill and their ability to promote plant growth in cowpea, Vigna unguiculata (L.) Walp. Afr J Microbiol Res. 2012;6:1345-53.; Kavamura et al., 2013Kavamura VN, Santos SN, Silva JL, Parma MM, Ávila LA, Visconti A, Zucchi TD, Taketani RG, Andreote FD, Melo IS. Screening of Brazilian cacti rhizobacteria for plant growth promotion under drought. Microbiol Res. 2013;168:183-91.), and relatives to crop species (Doty et al., 2009Doty SL, Oakley B, Xin G, Kang JW, Singleton G, Khan Z, Vajzovic A, Staley JT. Diazotrophic endophytes of native black cottonwood and willow. Symbiosis. 2009;47:23-33.; Fernandes Júnior et al., 2013Fernandes Júnior PI, Pereira GMD, Perin L, Silva LM, Barauna AC, Alves FM, Passos SR, Zilli JE. Diazotrophic bacteria isolated from wild riceOryza glumaepatula (Poaceae) in the Brazilian Amazon. R Biol Trop. 2013;61:991-9.), including the bacteria isolated by Kavamura et al. (2013)Kavamura VN, Santos SN, Silva JL, Parma MM, Ávila LA, Visconti A, Zucchi TD, Taketani RG, Andreote FD, Melo IS. Screening of Brazilian cacti rhizobacteria for plant growth promotion under drought. Microbiol Res. 2013;168:183-91.and Costa and Melo (2012)Costa FEC, Melo IS. Endophytic and rhizospheric bacteria fromOpuntia ficus-indica mill and their ability to promote plant growth in cowpea, Vigna unguiculata (L.) Walp. Afr J Microbiol Res. 2012;6:1345-53. from theCaatinga biome. Most of those studies were conducted in the last few years, indicating that prospection of diazotrophic bacteria associated with wild species is a new area of research, especially in Brazil. To our knowledge, the present study is the first report for characterization of diazotrophic bacteria associated with the resurrection plant T. spicatus, a promising source of PGP bacteria with biotechnological applications. To assure the potential of these bacteria as candidates for application in commercial inoculants, as well as to get a better understanding of their role in plant establishment inCaatinga soils, further inoculation experiments with crops and native species needs to be carried out.

CONCLUSIONS

Bacteria with plant growth promoting characteristics and a very diverse metabolic profile belonging to the genera Enterobacter,Bacillus, Rhizobium,Stenotrophomonas, and Pantoea are colonizingTripogon spicatus roots.

The isolates ESA 0001 (Pantoea sp.) and ESA 0016 (Rhizobiumsp.) stood out for their PGP ability for rice plants, indicating the resurrection plant Tripogon spicatus as a putative source of efficient plant growth promoting bacteria.

ACKNOWLEDGMENTS

The authors would like to thank the Empresa Brasileira de Pesquisa Agropecuária (Embrapa), the Coordenação de Aperfeiçoamento de Pessoal de Nível Superior (CAPES), the Fundação de Amparo à Ciência e Tecnologia do Estado de Pernambuco (FACEPE), and the Conselho Nacional de Desenvolvimento Científico e Tecnológico (CNPq) for financial support.

REFERENCES

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Aidar ST, Meirelles ST, Pocius O, Delitti WBC, Souza GM, Gonçalves AN. Desiccation tolerance in Pleurostima purpurea(Velloziaceae). Plant Growth Reg. 2010;62:193-202.
Aidar ST, Meirelles ST, Oliveira RF, Chaves ARM, Fernandes-Júnior PI. Changes of photosynthetic responses in the poikilochlorophyllous desiccation tolerant plant Pleurostima purpurea (Velloziaceae). Photosynthetica. 2014;52:24-133.
Altschul S, Gish W, Miller W, Myers E, Lipman D. Basic local alignment search tool. J Mol Biol. 1990;215:403-10.
Baldani JI, Reis VM, Videira SS, Boddey LH, Baldani VLD. The art of isolating nitrogen-fixing bacteria from non-leguminous plants using N-free semi-solid media: a practical guide for microbiologists. Plant Soil. 2014;348:413-31.
Baldani JI, Teixeira KRS, Schwab S, Olivares FL, Hemerly AS, Urquiaga S, Reis VM, Nogueira EM, Araújo JLS, Baldotto LEB, Soares LHB, Vinagre F, Baldani VLD, Carvalho TLG, Alves, BJR, James EK, Jantalia CP, Ferreira PCG, Vidal MS, Boddey RM. Fixação biológica de nitrogênio em plantas da família Poaceae (antiga gramineae). Tópicos Ci Solo. 2009;7:203-71.
Bilal R, Rasul G, Mahmood K, Malik KA. Nitrogenase activity and nitrogen-fixing bacteria associated with the roots of Atriplexspp growing in saline sodic soils of Pakistan. Biol Fertil Soils. 1990;9:315-20.
Costa FEC, Melo IS. Endophytic and rhizospheric bacteria fromOpuntia ficus-indica mill and their ability to promote plant growth in cowpea, Vigna unguiculata (L.) Walp. Afr J Microbiol Res. 2012;6:1345-53.
Döbereiner J, Baldani JI, Baldani VLD. Como isolar e identificar bactérias diazotróficas de plantas não leguminosas. Brasília: Embrapa-SPI; Seropédica: Embrapa Agrobiologia; 1995.
Doty SL, Oakley B, Xin G, Kang JW, Singleton G, Khan Z, Vajzovic A, Staley JT. Diazotrophic endophytes of native black cottonwood and willow. Symbiosis. 2009;47:23-33.
Estrada de Los Santos P, Bustillos-Cristales R, Caballero-Mellado J.Burkholderia, a genus rich in plant-associated nitrogen fixers with wide environmental and geographic distribution. Appl Environ Microbiol. 2001;67:2790-8.
Fernandes Júnior PI, Aidar ST, Gava CAT, Zilli JÉ, Martins LMV. Caracterização fenotípica de bactérias diazotróficas associadas aTripogon spicatus no Bioma Caatinga. Petrolina: Embrapa Semiárido; 2012a.
Fernandes Júnior PI, Lima AA, Passos SR, Gava CAT, Oliveira PJ, Rumjanek NG, Xavier GR. Phenotypic diversity and amylolytic activity of fast growing rhizobia from pigeonpea Cajanus cajan (L.) Millsp. Braz J Microbiol. 2012b;43:1604-12.
Fernandes Júnior PI, Pereira GMD, Perin L, Silva LM, Barauna AC, Alves FM, Passos SR, Zilli JE. Diazotrophic bacteria isolated from wild riceOryza glumaepatula (Poaceae) in the Brazilian Amazon. R Biol Trop. 2013;61:991-9.
Ferrara FIS, Oliveira ZM, Soto Gonzales HH, Floh EIS, Barbosa HR. Endophytic and rhizospheric enterobacteria isolated from sugar cane have different potentials for producing plant growth-promoting substances. Plant Soil. 2012;353:409-17.
Gaff DF. Desiccation tolerant plants in South-America. Oecologia. 1987;74:133-6.
Grover M, Ali SZ, Sandhya V, Rasul A, Venkateswarlu B. Role of microorganisms in adaptation of agriculture crops to abiotic stresses. World J Microbiol Biotechnol. 2011;27:1231-40.
Gumiere T, Ribeiro CM, Vasconcellos RLF, Cardoso EJBN. Indole-3-acetic acid producing root-associated bacteria on growth of Brazil Pine (Araucaria angustifolia) and Slash Pine (Pinus elliottii). Anton Leeuw. 2014;105:663-9.
Hungria M, Campo RJ, Souza EM, Pedrosa FO. Inoculation with selected strains of Azospirillum brasilense and A. lipoferumimproves yields of maize and wheat in Brazil. Plant Soil. 2010;331:413-25.
Jha B, Gontia I, Hartmann A. The roots of the halophyteSalicornia brachiata are a source of new halotolerant diazotrophic bacteria with plant growth-promoting potential. Plant Soil. 2012;356:265-77.
Kavamura VN, Santos SN, Silva JL, Parma MM, Ávila LA, Visconti A, Zucchi TD, Taketani RG, Andreote FD, Melo IS. Screening of Brazilian cacti rhizobacteria for plant growth promotion under drought. Microbiol Res. 2013;168:183-91.
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Reinhold B, Hurek T, Fendrik I, Pot B, Gillis M, Kersters K, Thielemans S, Deley J. Azospirillum halopraeferens sp-nov, a nitrogen-fixing organism associated with roots of kallar grass (Leptochloa fusca (L) Kunth). Inter J Syst Bacteriol. 1987; 37:43-51.
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Silva MCP, Figueiredo AF, Andreote FD, Cardoso EJBN. Plant growth promoting bacteria in Brachiaria brizantha World J Microbiol Biotechnol. 2013;29:163-71.
Sorokin ID, Kravchenko IK, Doroshenko EV, Boulygina ES, Zadorina EV, Tourova TP, Sorokin DY. Haloalkaliphilic diazotrophs in soda solonchak soils. FEMS Microbiol Ecol. 2008;65:425-33.
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Publication Dates

Publication in this collection
Jul-Aug 2015

History

Received
2 Oct 2014
Accepted
17 Apr 2015

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

[1] Ab’Saber AN. Ecossistemas do Brasil. São Paulo: Metalivros; 2006.

[2] Aidar ST, Meirelles ST, Pocius O, Delitti WBC, Souza GM, Gonçalves AN. Desiccation tolerance in Pleurostima purpurea(Velloziaceae). Plant Growth Reg. 2010;62:193-202.

[3] Aidar ST, Meirelles ST, Oliveira RF, Chaves ARM, Fernandes-Júnior PI. Changes of photosynthetic responses in the poikilochlorophyllous desiccation tolerant plant Pleurostima purpurea (Velloziaceae). Photosynthetica. 2014;52:24-133.

[4] Altschul S, Gish W, Miller W, Myers E, Lipman D. Basic local alignment search tool. J Mol Biol. 1990;215:403-10.

[5] Baldani JI, Reis VM, Videira SS, Boddey LH, Baldani VLD. The art of isolating nitrogen-fixing bacteria from non-leguminous plants using N-free semi-solid media: a practical guide for microbiologists. Plant Soil. 2014;348:413-31.

[6] Baldani JI, Teixeira KRS, Schwab S, Olivares FL, Hemerly AS, Urquiaga S, Reis VM, Nogueira EM, Araújo JLS, Baldotto LEB, Soares LHB, Vinagre F, Baldani VLD, Carvalho TLG, Alves, BJR, James EK, Jantalia CP, Ferreira PCG, Vidal MS, Boddey RM. Fixação biológica de nitrogênio em plantas da família Poaceae (antiga gramineae). Tópicos Ci Solo. 2009;7:203-71.

[7] Bilal R, Rasul G, Mahmood K, Malik KA. Nitrogenase activity and nitrogen-fixing bacteria associated with the roots of Atriplexspp growing in saline sodic soils of Pakistan. Biol Fertil Soils. 1990;9:315-20.

[8] Costa FEC, Melo IS. Endophytic and rhizospheric bacteria fromOpuntia ficus-indica mill and their ability to promote plant growth in cowpea, Vigna unguiculata (L.) Walp. Afr J Microbiol Res. 2012;6:1345-53.

[9] Döbereiner J, Baldani JI, Baldani VLD. Como isolar e identificar bactérias diazotróficas de plantas não leguminosas. Brasília: Embrapa-SPI; Seropédica: Embrapa Agrobiologia; 1995.

[10] Doty SL, Oakley B, Xin G, Kang JW, Singleton G, Khan Z, Vajzovic A, Staley JT. Diazotrophic endophytes of native black cottonwood and willow. Symbiosis. 2009;47:23-33.

[11] Estrada de Los Santos P, Bustillos-Cristales R, Caballero-Mellado J.Burkholderia, a genus rich in plant-associated nitrogen fixers with wide environmental and geographic distribution. Appl Environ Microbiol. 2001;67:2790-8.

[12] Fernandes Júnior PI, Aidar ST, Gava CAT, Zilli JÉ, Martins LMV. Caracterização fenotípica de bactérias diazotróficas associadas aTripogon spicatus no Bioma Caatinga. Petrolina: Embrapa Semiárido; 2012a.

[13] Fernandes Júnior PI, Lima AA, Passos SR, Gava CAT, Oliveira PJ, Rumjanek NG, Xavier GR. Phenotypic diversity and amylolytic activity of fast growing rhizobia from pigeonpea Cajanus cajan (L.) Millsp. Braz J Microbiol. 2012b;43:1604-12.

[14] Fernandes Júnior PI, Pereira GMD, Perin L, Silva LM, Barauna AC, Alves FM, Passos SR, Zilli JE. Diazotrophic bacteria isolated from wild riceOryza glumaepatula (Poaceae) in the Brazilian Amazon. R Biol Trop. 2013;61:991-9.

[15] Ferrara FIS, Oliveira ZM, Soto Gonzales HH, Floh EIS, Barbosa HR. Endophytic and rhizospheric enterobacteria isolated from sugar cane have different potentials for producing plant growth-promoting substances. Plant Soil. 2012;353:409-17.

[16] Gaff DF. Desiccation tolerant plants in South-America. Oecologia. 1987;74:133-6.

[17] Grover M, Ali SZ, Sandhya V, Rasul A, Venkateswarlu B. Role of microorganisms in adaptation of agriculture crops to abiotic stresses. World J Microbiol Biotechnol. 2011;27:1231-40.

[18] Gumiere T, Ribeiro CM, Vasconcellos RLF, Cardoso EJBN. Indole-3-acetic acid producing root-associated bacteria on growth of Brazil Pine (Araucaria angustifolia) and Slash Pine (Pinus elliottii). Anton Leeuw. 2014;105:663-9.

[19] Hungria M, Campo RJ, Souza EM, Pedrosa FO. Inoculation with selected strains of Azospirillum brasilense and A. lipoferumimproves yields of maize and wheat in Brazil. Plant Soil. 2010;331:413-25.

[20] Jha B, Gontia I, Hartmann A. The roots of the halophyteSalicornia brachiata are a source of new halotolerant diazotrophic bacteria with plant growth-promoting potential. Plant Soil. 2012;356:265-77.

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Bacteria	N content	IAA content	Solubilization index
	µg mL^-1

CIAT 899^T	3.5 c	nd	-
BR 11175^T	nd	37.3 c	nd
Ab-V5	35.0 a	nd	-
ESA 0001	14.0 b	5.9 g	1.2 b
ESA 0002	23.3 a	42.7 c	-
ESA 0003	17.5 b	36.8 c	2.1 a
ESA 0004	23.3 a	6.9 g	-
ESA 0005	31.5 a	30.8 d	-
ESA 0006	35.0 a	8.6 g	-
ESA 0007	25.7 a	5.9 g	-
ESA 0008	25.7 a	6.8 g	-
ESA 0009	14.0 b	-	1.1 b
ESA 0010	30.3 a	25.7 e	-
ESA 0011	30.3 a	40.8 c	-
ESA 0012	30.3 a	51.7 b	-
ESA 0013	30.3 a	5.8 g	-
ESA 0014	42.0 a	41.1 c	-
ESA 0015	30.3 a	87.0 a	-
ESA 0016	35.0 a	12.1 f	1.3 b
CV (%)	19.2	6.5	5.6

Inoculation treatment	Dry weight
Inoculation treatment	Shoot	Root	Whole plant
	g/plant

ESA 0001	1.10 a	0.61 a	1.71 a
ESA 0016	0.77 b	0.46 a	1.23 a
ESA 0015	0.74 b	0.46 a	1.20 b
ESA 0007	0.70 c	0.50 a	1.20 b
ESA 0014	0.66 c	0.49 a	1.15 b
ESA 0011	0.57 c	0.57 a	1.14 b
ESA 0013	0.63 c	0.41 b	1.04 b
ESA 0004	0.62 c	0.41 b	1.03 c
ESA 0003	0.61 c	0.40 b	1.01 c
ESA 0012	0.58 c	0.39 b	0.97 c
ESA 0005	0.52 c	0.40 b	0.92 c
ESA 0008	0.53 c	0.39 b	0.92 c
ESA 0010	0.48 c	0.31 b	0.79 c
ESA 0006	0.48 c	0.30 b	0.78 c
ESA 0009	0.47 c	0.28 b	0.75 c
ESA 0002	0.42 c	0.31 b	0.73 c
Ab-V5	0.58 c	0.54 a	1.13 b
50 mg/plant of N	0.58 c	0.36 b	0.94 c
100 mg/plant of N	1.00 a	0.65 a	1.65 a
CV (%)	13.25	13.46	12.21

Brasil

Brasil

THE RESURRECTION PLANT TRIPOGON SPICATUS (POACEAE) HARBORS A DIVERSITY OF PLANT GROWTH PROMOTING BACTERIA IN NORTHEASTERN BRAZILIAN CAATINGA

A PLANTA REVIVESCENTE TRIPOGON SPICATUS (POACEAE) ABRIGA UMA DIVERSIDADE DE BACTÉRIAS PROMOTORAS DE CRESCIMENTO VEGETAL NA CAATINGA, REGIÃO NORDESTE DO BRASIL

Abstracts

INTRODUCTION

MATERIAL AND METHODS

Bacterial isolates and partial 16S rRNA gene sequencing

Plant growth promotion (PGP) traits: putative diazotrophic capacity,in vitro production of indole-acetic acid (IAA) analogs and calcium phosphate solubilization

In vitro growth in the semi-solid BMGM medium under different conditions and intrinsic antibiotic resistance

Growth promotion of rice (Oryza sativa L.) in greenhouse conditions

Statistical analysis

RESULTS

Identification of bacterial isolates by partial 16S rRNA gene sequence

In vitro plant growth promotion traits

Physiological characterization

Ability to promote rice growth

DISCUSSION

CONCLUSIONS

ACKNOWLEDGMENTS

REFERENCES

Publication Dates

History

Isolate	Fragment length	Genus	Similarity	e value
	bp		%
ESA 0001	725	Pantoea sp.	99	0.0
ESA 0002	673	Bacillus sp.	100	0.0
ESA 0003	711	Enterobacter sp.	100	0.0
ESA 0004	690	Enterobacter sp.	99	0.0
ESA 0005	693	Enterobacter sp.	99	0.0
ESA 0006	714	Enterobacter sp.	99	0.0
ESA 0007	593	Bacillus sp.	99	0.0
ESA 0008	703	Stenotrophomonas sp.	99	0.0
ESA 0009	693	Pantoea sp.	100	0.0
ESA 0010	673	Enterobacter sp.	99	0.0
ESA 0011	567	Enterobacter sp.	99	0.0
ESA 0012	534	Bacillus sp.	100	0.0
ESA 0013	704	Bacillus sp.	99	0.0
ESA 0014	678	Bacillus sp.	100	0.0
ESA 0015	768	Rhizobium sp.	100	0.0
ESA 0016	770	Bacillus sp.	99	0.0

	ESA	ESA	ESA	ESA	ESA	ESA	ESA	ESA	ESA	ESA	ESA	ESA	ESA	ESA	ESA	ESA
	0001	0002	0003	0004	0005	0006	0007	0008	0009	0010	0011	0012	0013	0014	0015	0016
	Maximum NaCl concentration with microaerophilic growth (mol L^-1)
	1.27	0.17	1.27	0.52	1.27	0.86	1.27	0.09	0.17	1.27	0.86	1.27	1.27	0.52	0.86	1.27
pH of the medium
4	-	+	-	+	+	+	+	+	+	-	-	+	+	+	+	+
9	-	-	+	+	+	-	+	+	+	+	+	+	+	+	+	+
Metabolism of carbon source⁽¹⁾
Malic acid	-	+	+	+	+	+	+	+	+	+	+	+	-	+	+	+
Glucose	+	-	-	+	-	-	+	+	-	-	+	+	+	+	-	+
Mannitol	+	-	-	+	-	-	+	+	+	+	+	+	-	+	-	+
Arabinose	-	+	+	+	+	-	+	+	+	-	+	+	+	+	+	+
Citric acid	-	+	-	+	-	+	+	-	+	-	+	+	+	+	+	+
Maltose	+	-	-	+	-	+	+	-	+	-	+	+	+	+	-	+
Xylose	-	+	+	+	-	-	+	+	+	-	+	+	+	+	+	-
Sucrose	+	-	+	+	-	+	+	-	+	-	+	-	+	+	-	+
Fructose	-	-	-	+	-	-	-	-	+	+	-	-	+	+	-	-
Intrinsic antibiotic resistance⁽²⁾
Nalidixic Acid	-	+	+	-	+	+	-	+	+	-	-	-	+	+	-	+
Streptomycin	+	+	+	-	-	+	-	-	+	+	+	+	+	+	-	+
Ampicillin	+	+	+	+	+	+	+	+	+	+	+	+	+	+	+	+
Gentamicin	-	-	-	+	-	-	-	-	-	-	-	-	+	+	-	-
Vancomycin	+	-	-	-	-	+	-	-	-	-	-	-	+	+	+	+
Chloramphenicol	+	+	-	+	+	+	-	+	+	+	+	-	-	+	+	+
Erythromycin	+	+	+	+	+	+	-	+	+	+	+	+	-	+	-	+
Neomycin	-	-	-	+	-	+	-	-	-	+	-	-	+	-	-	-
Riphampicin	+	+	-	+	+	+	-	+	+	+	-	-	+	+	+	+