Phenotypic, genetic and symbiotic characterization of <i>Erythrina velutina</i> rhizobia from Caatinga dry forest

Rodrigues, Dalila Ribeiro; Silva, Aleksandro Ferreira da; Cavalcanti, Maria Idaline Pessoa; Escobar, Indra Elena Costa; Fraiz, Ana Carla Resende; Ribeiro, Paula Rose de Almeida; Ferreira Neto, Reginaldo Alves; Freitas, Ana Dolores Santiago de; Fernandes-Júnior, Paulo Ivan

doi:10.1016/j.bjm.2017.09.007

Abstract

Erythrina velutina ("mulungu") is a legume tree from Caatinga that associates with rhizobia but the diversity and symbiotic ability of "mulungu" rhizobia are poorly understood. The aim of this study was to characterize "mulungu" rhizobia from Caatinga. Bacteria were obteined from Serra Talhada and Caruaru in Caatinga under natural regeneration. The bacteria were evaluated to the amplification of nifH and nodC and to metabolic characteristics. Ten selected bacteria identified by 16S rRNA sequences. They were tested in vitro to NaCl and temperature tolerance, auxin production and calcium phosphate solubilization. The symbiotic ability were assessed in an greenhouse experiment. A total of 32 bacteria were obtained and 17 amplified both symbiotic genes. The bacteria showed a high variable metabolic profile. Bradyrhizobium (6), Rhizobium (3) and Paraburkholderia (1) were identified, differing from their geographic origin. The isolates grew up to 45 °C to 0.51 mol L^-1 of NaCl. Bacteria which produced more auxin in the medium with l-tryptophan and two Rhizobium and one Bradyrhizobium were phosphate solubilizers. All bacteria nodulated and ESA 90 (Rhizobium sp.) plus ESA 96 (Paraburkholderia sp.) were more efficient symbiotically. Diverse and efficient rhizobia inhabit the soils of Caatinga dry forests, with the bacterial differentiation by the sampling sites.

Keywords:
Biological nitrogen fixation; "Mulungu"; Diversity; Inoculant; 16S rRNA

Introduction

Caatinga (etymology: white forest) is the main phytophysiognomy occurring in Brazilian Semi-Arid region, occupying more than 70% of Brazilian Northeastern. These lands encompasses several dry forests that shows, as the main characteristics, low rainfall (below 800 mm yr^-1) concentrated in the firsts 3-4 months of the year and high temperature averages.¹1 de Albuquerque UP, de Lima Araújo E, El-Deir ACA, et al. Caatinga revisited: ecology and conservation of an important seasonal dry forest. Sci World J. 2012;2012:1-18. The plant biodiversity in Caatinga is very high with the predominance of Fabaceae (Leguminosae) family, with 82 genera and 617 already cataloged species.²2 Zappi DC, Ranzato Filardi FL, Leitman P, et al. Growing knowledge: an overview of seed plant diversity in Brazil. Rodriguesia. 2015;66(4):1085-1113. The historical use of lands in Caatinga for shifting agriculture practices leaded to several lands in fallow, where the natural regeneration occur. Nowadays Caatinga dry forests are a great mosaic of fallow lands with different stages of natural regeneration.³3 Pereira IM, Andrade LA, Sampaio EVSB, Barbosa MRA. Use-history effects on structure and flora of Caatinga. Biotropica. 2003;:154-165.^,⁴4 Sampaio EVSB, Araújo EL, Salcedo IH, Tiessen H. Regeneração da vegetação de Caatinga após corte e queima, em Serra Talhada, PE. Pesqui Agropecu Bras. 1998;33:621-632. In this process, plants belonging to Fabaceae are the pioneers colonizers and can present an important ecological role.³3 Pereira IM, Andrade LA, Sampaio EVSB, Barbosa MRA. Use-history effects on structure and flora of Caatinga. Biotropica. 2003;:154-165.

4 Sampaio EVSB, Araújo EL, Salcedo IH, Tiessen H. Regeneração da vegetação de Caatinga após corte e queima, em Serra Talhada, PE. Pesqui Agropecu Bras. 1998;33:621-632.

5 de Souza LQ, de Freitas ADS, Sampaio EVSB, Moura PM, Menezes RSC. How much nitrogen is fixed by biological symbiosis in tropical dry forests? 1. Trees and shrubs. Nutr Cycl Agroecosyst. 2012;94(2):171-179.^-⁶6 Silva AF, de Freitas ADS, Costa TL, et al. Biological nitrogen fixation in tropical dry forests with different legume diversity and abundance. Nutr Cycl Agroecosyst. 2017;:1-14.

Several leguminous pioneers colonizing the Caatinga natural regeneration lands are able to associate with indigenous rhizobia from the soils of the region. Rhizobia are root and/or stem nodulating, nitrogen-fixing, classified within α and β-proteobacteria subclasses. They hold the nitrogenase enzymatic complex, able to reduce the atmospheric N₂ to ammonium. The biological nitrogen fixation (BNF) is the main source of nitrogen incorporation in the food webs, mainly by the association between legumes and rhizobia.⁷7 Boyd ES, Peters JW. New insights into the evolutionary history of biological nitrogen fixation. Front Microbiol. 2013;4:201. BNF is exploited in agriculture and forestry by the production and application of rhizobial inoculants that reduces the costs and environmental impacts of plant production, in addition to yield increase.⁸8 Hungria M, Menna P, Delamuta JRM. Bradyrhizobium, the ancestor of all rhizobia: phylogeny of housekeeping and nitrogen-fixation genes. In: de Bruijn FR, ed. Biological Nitrogen Fixation. 1st ed. New Jersey: John Wiley & Sons, Inc.; 2015:191–202. The continuous selection of new and more efficient rhizobial strains is important to obtain bacteria with higher agronomic performance and agricultural applications.⁸8 Hungria M, Menna P, Delamuta JRM. Bradyrhizobium, the ancestor of all rhizobia: phylogeny of housekeeping and nitrogen-fixation genes. In: de Bruijn FR, ed. Biological Nitrogen Fixation. 1st ed. New Jersey: John Wiley & Sons, Inc.; 2015:191–202.^,⁹9 Moreira FMS, Siqueira JO. Microbiologia E Bioquímica Do Solo. 2nd ed. Lavras: UFLA; 2006. In natural regeneration lands, the selection of native and adapted rhizobia can help to improve the regeneration process due to their use in the production and application of more adapted and healthy seedlings.

Besides the nitrogen fixation, rhizobia are able to directly induce the plant growth by other mechanisms, such as the phytohormone production (auxin, for example) and release of soil insoluble nutrients (e.g. phosphorus and iron) among several others.¹⁰10 de Souza R, Ambrosini A, Passaglia LMP. Plant growth-promoting bacteria as inoculants in agricultural soils. Genet Mol Biol. 2015;38(4):401-419.^,¹¹11 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(5):1231-1240. These mechanisms can easily be in vitro evaluated by simple and low costs techniques, showing correlation with the bacterial performance in plant inoculation experiments.¹²12 Kumari BS, Ram MR, Mallaiah KV. Studies on exopolysaccharide and indole acetic acid production by Rhizobium strains from Indigofera. Afr J Microbiol Res. 2009;3(1):10-14.^,¹³13 Lira MA Jr, Nascimento LRS, Fracetto GGM. Legume-rhizobia signal exchange: promiscuity and environmental effects. Front Microbiol. 2015, http://dx.doi.org/10.3389/fmicb.2015.00945.
http://dx.doi.org/10.3389/fmicb.2015.009... At the same way, the evaluation of rhizobial tolerance to environmental stresses, such as the salinity and temperature tolerance, also can be easily performed in vitro¹⁴14 Fernandes Júnior PI, Lima AA, Passos SR, et al. Phenotypic diversity and amylolytic activity of fast growing rhizobia from pigeonpea [Cajanus cajan (L.) MILLSP.]. Braz J Microbiol. 2012;43(4):1604-1612. and can be correlated to the results of plant inoculation experiments.¹³13 Lira MA Jr, Nascimento LRS, Fracetto GGM. Legume-rhizobia signal exchange: promiscuity and environmental effects. Front Microbiol. 2015, http://dx.doi.org/10.3389/fmicb.2015.00945.
http://dx.doi.org/10.3389/fmicb.2015.009... The evaluation of in vitro environmental stresses are important to the selection of bacteria that are (likely) more tolerant and also to better understand the bacteria biology.¹⁵15 del Cerro P, Pérez-Montaño F, Gil-Serrano A, et al. The Rhizobium tropici CIAT 899 NodD2 protein regulates the production of Nod factors under salt stress in a flavonoid-independent manner. Sci Rep. 2017;7(March):46712. These features are particularly interesting to be evaluated in studies of rhizobia from tropical dry lands with low rainfall and high temperature averages.

Recent studies showed that Erythrina velutina Willd., commonly known as "mulungu", is able to establish symbiotic association with rhizobia in soils from the Brazilian Semi-Arid.¹⁶16 Menezes KAS, Escobar IEC, Fraiz ACR, Martins LMV, Fernandes-Júnior PI. Genetic variability and symbiotic efficiency of Erythrina velutina willd. Root nodule bacteria from the semi-arid region in Northeastern Brazil. Rev Bras Cienc do Solo. 2017;41:1-13.^,¹⁷17 Menezes KAS, Nunes GFO, Sampaio AA, et al. Diversity of new root nodule bacteria from Erythrina velutina Willd., a native legume from the Caatinga dry forest (Northeastern Brazil). Rev Cienc Agrárias. 2016;39(2):222-233.E. velutina, classified within the Papilionoidae clade and Phaseoleae tribe, is a naturally inhabiting tree from the Northeast region of Brazil. This species is used as wood, timber, ornamental applications and sources of bioactive compounds with pharmacological applications.¹⁸18 Souza VC, Lorenzi H. Botânica Sistemática: Guia Ilustrado Para Identificação Das Famílias de Fanerógamas Nativas E Exóticas No Brasil, Baseado Em APG II. 2nd ed. Nova Odessa: Instituto Plantarum; 2008.^,¹⁹19 Ozawa M, Honda K, Nakai I, Kishida A, Ohsaki A. Hypaphorine, an indole alkaloid from Erythrina velutina, induced sleep on normal mice. Bioorg Med Chem Lett. 2008;18(14):3992-3994. In addition, due to the fast growth and adaptive characteristic to the Semi-Arid environment, "mulungu" seedlings should be applied in land regeneration projects.²⁰20 Ribeiro-Reis RC. Tolerância a estresses abióticos em sementes de Erythrina velutina Willd, (Leguminosae – Papilionoideae) nativa da Caatinga. Feira de Santana: UEFS; 2012.

Despite the potential use of this native species for several applications, there are not official recommendations of rhizobial strains for E. velutina in Brazil. The selection of native nitrogen-fixing isolates can help to the inclusion of the "mulungu" bacteria in the list of officially recommended strains to inoculant production by the Brazilian Ministry of Agriculture, Livestock and Food Supply (MAPA). The application of selected efficient rhizobia is useful to the development of improved "mulungu" seedlings, more healthy and with better nutrition, increasing the probability of the successful establishment in the fields, especially in non-favorable environments, such as the Caatinga degraded lands.²¹21 Zahran HH. Rhizobia from wild legumes: diversity, taxonomy, ecology, nitrogen fixation and biotechnology. J Biotechnol. 2001;91:143-153. Thus, we hypothesized that the Caatinga soils under natural regeneration in the Semi-Arid region of Pernambuco State harbor a diversity of efficient "mulungu" rhizobia. The aim of the present study was to characterize the "mulungu" rhizobia from the semi-arid region of Pernambuco State regarding their phenotypical, molecular and symbiotic characteristics.

Materials and methods

Origin of the bacterial isolates

The bacteria were isolated from soils collected from the 0 to 20 cm superficial layer in areas of Caatinga vegetation under natural regeneration in Caruaru, in the Agreste zone of Pernambuco state, and Serra Talhada, in the Sertão zone of the same state. The plant cover an both zones are different as already pointed by Silva and Rodal.²²22 Silva MCNA, Rodal MJN. Padrões das síndromes de dispersão de plantas em áreas com diferentes graus de pluviosidade, PE, Brasil. Acta Bot Brasilica. 2009;23(4):1040-1047. The location and edaphoclimatic conditions of both areas are described in Table 1.

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Table 1
Characteristics of Caatinga under natural regeneration and their soils in Caruaru and Serra Talhada (Pernambuco State, Brazil).

For bacterial isolation, a trap-host pot experiment was implemented using "mulungu" (E. velutina) as trap plant. Polystyrene pots (500 mL) were filled with the soil samples and four seeds were sowed per pot. Ten days after the emergence (DAE) a single plant was left per pot. The pots were daily irrigated with 100 mL of distilled water and the experiment was harvested at 85 DAE. The roots and shoots were separated and the nodules detached. For isolation, nodules were superficially disinfected with 96 °GL ethanol for 30 s; sodium hypochlorite (2.5%, v/v) for five minutes followed by 10 washes in sterile distilled water. The nodules were crushed in yeast extract-mannitol-agar (YMA) medium with congo red²³23 Vincent JM. A Manual for the Practical Study of Root-Nodule Bacteria. [Published for the] International Biological Programme [by] Blackwell Scientific; 1970. and incubated in a growth chamber at 28 °C. The rise of typical rhizobial colonies were daily evaluated during ten days. The colonies were purified in YMA medium with bromothymol blue and stored in YM medium + glycerol (2.5% v/v) at -80 °C and deposited in the Culture Collection of Agricultural Interests Micro-organisms at Embrapa Semiárido (CMISA).

Amplification of symbiotic genes

The bacterial isolates were grown in liquid YM medium for three days for the fast-growing isolates and six days for the slow-growing. An aliquot of 1 mL of each broth was used for the DNA extraction using the Wizard^® Genomic DNA Purification System (Promega, USA) according to the manufacturer's instructions. nifH and nodC genes were co-amplified in a duplex-PCR reaction as described by Fernandes Júnior et al.²⁴24 Fernandes Júnior PI, Morgante CV, Gava CAT, Santos CAF, Barboza JAC, Martins LMV. Duplex PCR Para a Amplificação Simultânea de Fragmentos Dos Genes nifH E nodC Em Bactérias Isoladas de Nódulos de Leguminosas. Petrolina: Embrapa Semiárido; 2013. For the nifH, the primers PolF (TGCGAYCCSAARGCBGACTC) and PolR (ATSGCCATCATYTCRCCGGA)²⁵25 Poly F, Monrozier LJ, Bally R. Improvement in the RFLP procedure for studying the diversity of nifH genes in communities of nitrogen fixers in soil. Res Microbiol. 2001;152(3):95-103. were used. For nodC, the primers NodCF (AYGTHGTYGAYGACGGTTC) and NodCR(I) (CGYGACAGCCANTCKCTATTG)²⁶26 Laguerre G, Nour SM, Macheret V, Sanjuan J, Drouin P, Amarger N. Classification of rhizobia based on nodC and nifH gene analysis reveals a close phylogenetic relationship among Phaseolus vulgaris symbionts. Microbiology. 2001;147:981-993. were applied. For a single isolate that showed positive amplification of the nifH amplicon, a complementary uniplex-PCR was performed with the primers nodCForB (CTCAATGTACACARNGCRTA) and nodCRevB (GAYATGGARTAYTGGYT)⁵⁷57 Elliott GN, Chen WM, Bontemps C, et al. Nodulation of Cyclopia spp. (Leguminosae Papilionoideae) by Burkholderia tuberum. Ann Bot. 2007;100(7):1403-1411. targeting the nodC amplification of β-rhizobia.

The reactions were performed in a Veriti 96-well thermocycler (Applied Biosystems, USA) and the PCR products were submitted to horizontal electrophoresis in agarose gel (0.8%, w/v). The gel was stained with Gel Red (Biotium) and visualized in a UV chamber. The bacterial isolates positive for both amplicons were selected for the next steps.

Metabolic characterization using the API 20 NE^® kit

Enzymatic activities and the carbon sources utilization profiles were performed using the API 20 NE^® strips (BioMérieux, France) according to the manufacturer's instructions. The incubation time was three days for the fast-growing isolates, and six days for the slow-growing, at 28 °C.

The results were transformed in a binary matrix and the bacteria clustered according to the enzymatic activity characteristics and utilization of different carbon sources in a similarity dendrogram obtained applying the Jaccard similarity coefficient and the UPGMA clustering algorithm with the aid of the BioNumerics v. 7.5 software package (Applied Maths, Belgium). The clustering analysis was used to select the bacterial isolates for further evaluations.

16S rRNA gene sequence analyses

The 16S rRNA gene was amplified using the universal primers 27F (AGAGTTTGATCMTGGCTCAG) and 1492R (TACGGYTACCTTGTTACGACTT).²⁷27 Weisburg WG, Barns SM, Pelletier DA, Lane DJ. 16S ribosomal DNA amplification for phylogenetic study. J Bacteriol. 1991;173(2):697-703. To evaluate the success of PCR, the products were submitted to a gel electrophoresis as described above. The PCR products were purified with the Wizard^® SV Gel and PCR Clean-Up System (Promega, USA) commercial kit, following manufacturer's instructions. The products were sequenced with both forward and reverse primers in a 3730 xl genetic analyzer (Applied Biosystems, USA) at Macrogen (Seoul, South Korea).

The quality of the sequences was verified using the Sequence Scanner Software v. 2.0 (Applied Biosystems, USA). Good quality sequences were used to construct the contigs for the bacterial identification through comparison with the sequences available at the EzBioCloud database (http://www.ezbiocloud.net/).²⁸28 Yoon S-H, Ha S-M, Kwon S, et al. Introducing EzBioCloud: a taxonomically united database of 16S rRNA and whole genome assemblies. Int J Syst Evol Microbiol. 2017;67:1613-1617. Sequences from closest type strains were downloaded and used to perform the phylogenetic tree. The alignment of the sequences was carried out by MUSCLE and the Neighbor-Joining tree made with the Jakes-Cantor model using the bootstrap phylogeny test with 1000 replications. The sequence alignments and phylogenetic tree construction were carried out in MEGA 6.0 software.²⁹29 Tamura K, Stecher G, Peterson D, Filipski A, Kumar S. MEGA6: molecular evolutionary genetics analysis version 6.0. Mol Biol Evol. 2013;30(12):2725-2729. The sequences were deposited in the GenBank, database of the National Center for Biotechnology Information (www.ncbi.nlm.nih.gov/Genbank), under the accession numbers MF288754 to MF288763.

Salt and temperature tolerance

Strains were analyzed for salt and high temperature tolerance, following the methodology described by Fernandes Júnior et al.¹⁴14 Fernandes Júnior PI, Lima AA, Passos SR, et al. Phenotypic diversity and amylolytic activity of fast growing rhizobia from pigeonpea [Cajanus cajan (L.) MILLSP.]. Braz J Microbiol. 2012;43(4):1604-1612. with some modifications, briefly described below. To the evaluation of salt tolerance, the strains were inoculated in Petri dishes with YMA medium supplemented with zero (control), 0.085, 0.17, 0.34 and 0.51 mol L^-1 of NaCl and incubated in a growth chamber at 28 °C. To evaluate the growth ability of the strains submitted to different incubation temperatures the isolates were inoculated in Petri dishes containing original YMA medium and incubated at 28 (control), 35, 40 and 45 °C, in different growth chambers. In both experiments, conducted within a completely randomized design with three replications, the strains were incubated for three and six days for the fast-growing and slow-growing, respectively.

Auxin production and solubilization of calcium phosphate

The in vitro production of auxin was evaluated according to the colorimetric method described by Sarwar and Kremer³⁰30 Sarwar M, Kremer RJ. Determination of bacterially derived auxins using a microplate method. Lett Appl Microbiol. 1995;20(5):282-285. with modifications, briefly described below. The strains were grown in YMA medium and were checked for purity. Pure colonies were inoculated in YM medium (3 mL), and after three days for the fast-growing isolates and six days for the slow growing, the bacterial broth were adjusted to OD₅₄₀ = 0.5 with distilled autoclaved water (DAW). An aliquot of 1 mL of each adjusted broth were centrifuged (6000 × g for 5 min), the supernatant discarded and pellet re-suspended with 1 mL of distilled autoclaved water.

To evaluate the metabolic pathways enrolled in the in vitro auxin production, aliquots of 150 µL of the re-suspended bacteria were inoculated in standard liquid YM culture medium, without bromothymol blue, supplemented or not with 168 mg L^-1 of l-tryptophan (l-try). The media were incubated at 28 °C (±1 °C) in an orbital shaker with constant stirring at 120 rpm, for four and seven days to the fast and slow-growing bacteria, respectively. After the incubation period, the cultures were adjusted to an OD₅₄₀ = 0.5 as described above. Aliquots of standardized bacterial solutions (1 mL) were centrifuged at 6.000 × g for 5 min. Aliquots of 200 µL of supernatant were placed in 96-well ELISA microplates and mixed with 100 µL of Salkowski solution (1 mL of FeCl₃ 0.5 mol L^-1 + 49 mL of HClO₄ 6 mol L^-1). The ELISA plates were incubated in the dark for 30 min. The intensity of red color was determined in a MultiSkan GO spectrophotometer (Thermo Scientific, Germany) at 530 nm. The concentration of auxin was estimated using a standard curve previously prepared with a range of 0 to 500 µg L^-1 of synthetic indole-3-acetic acid (Sigma-Aldrich, USA).

The isolates were evaluated for their capacity to in vitro solubilize calcium phosphate in the solid GL medium supplied with insoluble CaHPO₄.³¹31 Sylvester-Bradley R, Asakawa N, La Torraca S, Magalhães FMM, Oliveira LA, Pereira RM. Levantamento quantitativo de microrganismos solubilizadores de fosfatos na rizosfera de gramíneas e leguminosas forrageiras na Amazônia. Acta Amaz. 1982;12(1):15-22. The bacteria were grown in liquid YM medium, OD adjusted, centrifuged, and re-suspended as described above. Three aliquots of 10 µL were dropped in equidistant points in the center of the Petri dishes. The bacteria were incubated at 28 °C for seven days for the fast-growing and fifteen days for the slow growing. After the incubation period, the diameter of the colonies and the translucent zone surrounding the colonies were measured in millimeters (mm) with a ruler. This data were used to calculate the Solubilization Index (SI) = diameter of translucent zone/diameter of colony.³²32 Berraquero FR, Baya B, Cormenzana AR. Establecimiento de índices para el estudio de la solubilización de fosfatos por bacterias del suelo. Ars Pharm. 1976;17:399-406.

The experiments of in vitro auxin production and calcium phosphate solubilization were performed in a completely randomized design with three replications.

Symbiotic efficiency in "mulungu" plants

The symbiotic efficiency of the isolates were evaluated under gnotobiotic conditions in a greenhouse. The experiment was carried out at the Embrapa Semiárido facilities in Petrolina, Pernambuco state. For this assay, the dormancy of "mulungu" seeds was broken by mechanical scarification of the tegument. The seeds were surface disinfected with ethanol 96° GL for 30 s, sodium hypochlorite 2.5% (v/v) for five minutes, followed by eight washes with DAW.²³23 Vincent JM. A Manual for the Practical Study of Root-Nodule Bacteria. [Published for the] International Biological Programme [by] Blackwell Scientific; 1970. The substrate was washed and sterilized sand (autoclaved twice, at 120 °C and 1.5 atm for 1 h, with 72 h between the sterilizations). The experiment was set up in polystyrene pots (500 mL), which were disinfected by washing with sodium hypochlorite 2.5% (v/v), followed by three washes with DAW. Pots were carefully filled with the sterile sand and four seeds per pot were sown soon after filling.

For inoculation, bacteria were grown in YM medium up to the end of the exponential growth phase (around 10⁹ cells mL^-1), for three days for the fast-growing strains and six days for the slow-growing, in an orbital shaker at 28 °C, as described above. Right after sowing, the inoculation was performed by the drop of 2 mL of the bacterial broth on each seed. At twenty DAE a thinning was performed and a single plant was left per pot. The pots were daily supplied with 100 mL of DAW, and after the cotyledon drop (around 25-28 DAE), 50 mL of nitrogen free nutrient solution, described by Norris and T'Mannetje,³³33 Norris DO, Mannetje L'. The symbiotic specialization of african Trifolium Spp. in relation to their taxonomy and their agronomic use. East Afr Agric For J. 1964;29(3):214-235. was applied once a week.¹⁶16 Menezes KAS, Escobar IEC, Fraiz ACR, Martins LMV, Fernandes-Júnior PI. Genetic variability and symbiotic efficiency of Erythrina velutina willd. Root nodule bacteria from the semi-arid region in Northeastern Brazil. Rev Bras Cienc do Solo. 2017;41:1-13.

The experimental treatments consisted of the inoculation of ten bacteria (single inoculation of each isolate), a positive control inoculated with Bradyrhizobium elkanii BR 5609 (SEMIA 6100), strain officially recommended by MAPA in Brazil for use as inoculant for Erytrina verna and Falcataria mollucanna, and two uninoculated controls: one supplied with NH₄NO₃ (70 mg N plant^-1 week^-1) applied after 35 DAE; and one without nitrogen supplementation.

The plants were harvested at 92 DAE for the determination of the nodule number (NN), nodule dry matter (NDM), shoot dry matter (SDM), root dry matter (RDM) and nitrogen accumulation in the shoot (total N). For the NN evaluation, the nodules were detached from the roots and counted. For the NDM, SDM and RDM, respectively, the nodules, shoots and roots were separately in paper bags and dried in a forced-air oven at 65 °C for seven days and weighted. The shoots were grounded for determination of shoot nitrogen concentration by the dry combustion method in a TruSpec CN elemental analyzer (Leco, USA). These values were used for calculation of total accumulation of nitrogen in the shoot (Total N) through the multiplication of the nitrogen concentration by the SDM.

Statistical analyses

For the solubilization of calcium phosphate, IAA production, and symbiotic efficiency in greenhouse experiments, the normal distribution of the errors were evaluated by the Shapiro-Wilk test, thus the data for the greenhouse experiment were transformed by (x + 1)^0.5 to reach the normal distribution.

The experimental data were submitted to variance analysis (ANOVA) and the averages were compared by the Scott-Knott's mean range test (p < 0.05). The data were analyzed using the statistical package Sisvar v 5.0.³⁴34 Ferreira DF. Sisvar: a computer statistical analysis system. Cienc Agrotecnol. 2011;35:1039-1042.

Results

Isolation and symbiotic gene amplification

The isolation process retrieved 32 bacteria, 17 from Caruaru soils and 15 from Serra Talhada. The duplex-PCR reaction to nifH and nodC resulted in the positive reaction for both genes to seven (47%) bacterial isolates from Serra Talhada and 10 (59%) bacteria from Caruaru, including ESA 96, a single fast-growing isolate that did not amplify the nodC at the duplex-PCR reaction but amplified the nodC when a primer pair to β-rhizobia was applied.

Among these bacteria, ten were slow (seven from Caruaru and three from Serra Talhada) and seven were fast-growing (four from Caruaru and three from Serra Talhada), respectively. All 15 isolates that did not amplify the symbiotic genes were fast-growing bacteria.

Metabolic profile of the bacterial isolates

Regarding metabolism of the 12 carbon sources available at the API 20 NE strips, a large variability at the metabolic profile were observed in the 17 bacteria evaluated. All bacterial isolates grew in d-glucose, l-arabinose, d-mannose and d-mannitol, as sole carbon sources. None of the bacteria grew using capric acid. Around 83% grew with N-acetyl-glucosamine, d-maltose and potassium gluconate. Around 76 and 70% used respectively, trisodium citrate and malic acid as sole carbon sources. The bacteria ESA 95, ESA 103 and ESA 99 showed the best ability to metabolize the carbon sources since they grew in all sources, excepting the capric acid. These bacteria were also the only isolates that grew using adipic acid and phenylacetic acid (Fig. 1).

Fig. 1
Cluster analysis of the metabolic profile of 17 bacterial isolates of Erythrina velutina based on the results of 12 carbon sources assimilation and 8 enzymes activities in the API 20 NE strips. First 12 columns: carbon sources metabolism. Last 8 columns: Enzymatic activity. Indole, indole formation; GluFerm, glucose fermentation; ArgDH, arginine dehydrogenase. Red squares: positive activity; Green squares: negative activity. Numbers in the nodes are the cophenetic correlation. Key, Bacterial isolate.

For the enzymatic activity, the isolates showed different profiles. All bacterial isolates did not presented activity of glucose fermentation. Excepting the isolate ESA 89, all bacterial isolates were positive to urease and, excepting the ESA 99 and ESA 103, all isolates were positive to esculin hydrolysis. An amount of 65% of the bacterial isolates was positive to β-Galactosidase. Variable profiles were achieved from the evaluations of nitrate reductase, indol formation, arginine DiHydrolase, and gelatinase.

All metabolic results were tabulated in a binary matrix and used to the cluster analysis of all bacteria. The similarity dendrogram (Fig. 1) presents the formation of nine clusters at the threshold of 90% (Jaccard coefficient). Based on the cluster analysis, ten bacterial isolates were selected for further steps.

16S rRNA gene sequence analyses

The sequences of 16S rRNA gene were compared with those available at the EzBioCloud database. The comparison indicated that among the five bacterial isolates from Caruaru, four of them were classified as α-rhizobia and clustered within the Bradyrhizobium in the B. elkanii clade II. The isolate ESA 96 was classified as a β-rhizobia related to Paraburkholderia diazotrophica. The five bacteria from Serra Talhada were classified as α-rhizobia. The isolates ESA 92 and ESA 93 were classified within Rhizobum in the R. etli clade. The bacteria ESA 90 was classified in the same genus but in the R. tropici clade. The isolates ESA 89 and ESA 91 were classified within the Bradyrhizobium japonicum clade, closely related to Bradyrhizobium subterraneum (Fig. 2).

Fig. 2
Neighbor-joining phylogenetic tree using a Jukes-Cantor model based on the partial 16S rRNA gene sequence (1165 nt) of ten rhizobial isolates from root nodules of Erythrina velutina and 16 type strains. Numbers in the nodes of branches correspond to the bootstrap value from 1000 replications. Bootstrap values lower than 60% are not shown.

In vitro temperature and salt tolerance

Two isolates (ESA 89 and ESA 92) grown under the incubation temperature of 40 °C. The bacterial isolates ESA 98 and ESA 99 grew when incubated at 45 °C. The other bacterial isolates grew only under the incubation temperature of 35 °C (Table 2). For the tolerance to different NaCl concentrations, the bacteria grew in the YMA medium supplemented with 0.085-0.51 mol L^-1 of NaCl. The isolates ESA 90, ESA 91 and ESA 98 grew positively in the medium supplemented with NaCl 0.34 mol L^-1 while the bacteria ESA 89, ESA 97 and ESA 99, grew in the medium with NaCl 0.51 mol L^-1. The isolates ESA 100, ESA 93, ESA 92 and ESA 96 were the less tolerant to salinity and grew only with the lower NaCl concentration in the medium (0.085 mol L^-1).

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Table 2
In vitro temperature and NaCl tolerance, calcium phosphate solubilization and auxin production of ten rhizobial isolates from Erythrina velutina root nodules, obtained from "Caatinga" dry forest soils, in Pernambuco state, Brazil.

Solubilization of calcium phosphate and production of auxin in vitro

The isolates ESA 90, ESA 93 and ESA 97, were able solubilize calcium phosphate, highlighting the isolate ESA 93, statistically superior (p < 0.05) than the other two bacteria. Six and five isolates produced auxin in the presence and absence of l-try supplementation, respectively. In the medium with l-try, ESA 100 and ESA 98 were in the highest cluster in the mean range test comparison. This group was followed by the isolate ESA 93 that was higher than other group with the isolate ESA 99 and the reference strain BR 3299^T. Considering the auxin production in YM medium without l-try, the isolates ESA 93 and ESA 97 showed the best performance, comparing to the other isolates and the reference strain.

Symbiotic efficiency in "mulungu" plants

At the symbiotic efficiency experiment in gnotobiotic conditions, all replications of the non-inoculated controls (both the absolute and the nitrogen supplied controls) did not nodulate, being inferred that contaminations did not occur in the experiment. The positive control inoculated with the reference strain of B. elkanii, and the other 10 treatments inoculated with the new bacterial isolates induced nodule formation in "mulungu" roots (Table 3).

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Table 3
Averages for the nodule number (NN), nodule dry matter (NDM), shoot dry matter (SDM), root dry matter (RDM), and accumulation of nitrogen in the shoot (total N) of Erythrina velutina inoculated with new rhizobial isolates in a gnotobiotic conditions experiment.

No differences were found for the variables SDM and RDM, in all treatments. For the nodulation variables, NN and NDM indicated that the reference strain BR 5609 was higher than the other treatments. Considering the new bacteria, the isolates ESA 97 and ESA 98 stood out, showing higher values comparing to the other eight isolates (p < 0.05). For the total nitrogen, plants inoculated with ESA 90, ESA 96 and BR 5609 were not statistically different than plants supplied with NH₄NO₃ (p > 0.05).

Discussion

Among the typical rhizobial colonies obtained, around 53% were positive for the amplification of both symbiotic genes. The bacteria that did not showed positive results for nifH and nodC amplification are probably non-rhizobial endophytes, already observed in cowpea nodules at the Brazilian semi-arid region.³⁵35 Leite J, Fischer D, Rouws LFM, et al. Cowpea nodules harbor non-rhizobial bacterial communities that are shaped by soil type rather than plant genotype. Front Plant Sci. 2017;7(January):1-11. The simultaneous amplification of symbiotic genes is a feasible tool to select the bacterial isolates which are probably rhizobia, indicating that this technique can be successfully applied for preliminary rhizobial selection.²⁴24 Fernandes Júnior PI, Morgante CV, Gava CAT, Santos CAF, Barboza JAC, Martins LMV. Duplex PCR Para a Amplificação Simultânea de Fragmentos Dos Genes nifH E nodC Em Bactérias Isoladas de Nódulos de Leguminosas. Petrolina: Embrapa Semiárido; 2013. Among the selected bacteria, slow and fast growth characteristic were observed, which is common in soils from dry lands that harbor a large diversity of rhizobia, nodulating both crops and native species.³⁶36 Freitas ADS, Borges WL, Andrade MMM, et al. Characteristics of nodule bacteria from Mimosa spp grown in soils of the Brazilian semiarid region. Afr J Microbiol Res. 2014;8(8):788-796.^,³⁷37 Zahran HZ. Rhizobium-legume symbiosis and nitrogen fixation under severe conditions and in an arid climate. Microbiol Mol Biol Rev. 1999;63(4):968-989. Particularly in Brazil, a large cultural diversity of root nodule bacteria were obtained from soils at the semi-arid regions of the Pernambuco,³⁸38 Leite J, Seido SL, Passos SR, Xavier GR, Rumjanek NG, Martins LMV. Biodiversity of rhizobia associated with cowpea cultivars in soils of the lower half of the São Francisco River Valley. Rev Bras Cienc do Solo. 2009;33(5):1215-1226.^,³⁹39 Xavier GR, Martins LMV, Rumjanek NG, Neves MCP. Tolerância de rizóbio de feijão-caupi à salinidade e à temperatura em condição in vitro. Caatinga. 2007;20:1-9. Paraíba³⁶36 Freitas ADS, Borges WL, Andrade MMM, et al. Characteristics of nodule bacteria from Mimosa spp grown in soils of the Brazilian semiarid region. Afr J Microbiol Res. 2014;8(8):788-796. and Bahia¹⁷17 Menezes KAS, Nunes GFO, Sampaio AA, et al. Diversity of new root nodule bacteria from Erythrina velutina Willd., a native legume from the Caatinga dry forest (Northeastern Brazil). Rev Cienc Agrárias. 2016;39(2):222-233.^,³⁸38 Leite J, Seido SL, Passos SR, Xavier GR, Rumjanek NG, Martins LMV. Biodiversity of rhizobia associated with cowpea cultivars in soils of the lower half of the São Francisco River Valley. Rev Bras Cienc do Solo. 2009;33(5):1215-1226.^,³⁹39 Xavier GR, Martins LMV, Rumjanek NG, Neves MCP. Tolerância de rizóbio de feijão-caupi à salinidade e à temperatura em condição in vitro. Caatinga. 2007;20:1-9. states.

The 17 bacterial isolates evaluated by the API 20 NE strips metabolized several carbon sources and presented a variable enzymatic activity profile. Some isolates used 11 of the 12 carbon sources available at the API 20 NE strips, while other bacteria showed positive results only for four sources. Furthermore, some bacterial isolates showed positive enzymatic activities for six of the eight available substrates whilst other isolates were positive only for two enzymes. These results showed a large metabolic diversity of mulungu rhizobia, and possibly their adaptation in different environments.³⁷37 Zahran HZ. Rhizobium-legume symbiosis and nitrogen fixation under severe conditions and in an arid climate. Microbiol Mol Biol Rev. 1999;63(4):968-989.

The clustering of bacterial isolates through the analysis of their metabolic characteristics was also related to the origin (location). The cluster 1 encompassed four isolates, among which three were isolated from Serra Talhada and only one from Caruaru. The three bacteria from Serra Talhada were classified within the Rhizobium genus. Evaluating the cluster 2, all five clustered bacteria were obtained from Caruaru and two isolates were classified within the Bradyrhizobium genus and related to B. elkanii clade. The cluster 4 also grouped two isolates from Caruaru (one Bradyrhizobium). The other clusters presented only one isolate each.

The metabolic characteristics were closely related to the differentiation of taxonomic clusters, but did not show phylogenetic relationship. This characteristic was probably observed due to the functional redundancy of the bacterial isolates, where bacteria belonging to different taxa show similar metabolic profiles, indicating the ability of bacteria from different taxonomic cluster to occupy the same ecological niche.⁴⁰40 Miki T, Yokokawa T, Matsui K. Biodiversity and multifunctionality in a microbial community: a novel theoretical approach to quantify functional redundancy. Proc R Soc B Biol Sci. 2013;281(1776):20132498.^,⁴¹41 Gilbert JA, Field D, Swift P, et al. The taxonomic and functional diversity of microbes at a temperate coastal site: a "multi-omic" study of seasonal and diel temporal variation. PLoS ONE. 2010;5(11):. This results indicate the importance to evaluate the diversity of rhizobia metabolic characteristics from the Brazilian Semi-Arid, to better understand their functional diversity, complementary to the molecular taxonomic assessment. Regarding the technique, the metabolic profiling of rhizobia using the API strips is widely applied in studies of new species description.⁴²42 Sheu SY, Chou JH, Bontemps C, et al. Burkholderia diazotrophica sp. nov., isolated from root nodules of Mimosa spp.. Int J Syst Evol Microbiol. 2013;63(PART2):435-441.

43 Delamuta JRM, Ribeiro RA, Ormeño-Orrillo E, et al. Bradyrhizobium tropiciagri sp. nov. and Bradyrhizobium embrapense sp. nov nitrogenfixing symbionts of tropical forage legumes. Int J Syst Evol Microbiol. 2015;65(12):4424-4433.^-⁴⁴44 Shamseldin A, Carro L, Peix A, Velázquez E, Moawad H, Sadowsky MJ. The symbiovar trifolii of Rhizobium bangladeshense and Rhizobium aegyptiacum sp. nov. nodulate Trifolium alexandrinum in Egypt. Syst Appl Microbiol. 2016;39(4):275-279. This is a fast and easy test that reveals several metabolic characteristics of plant-associated bacteria,⁴⁵45 Dias A, Pacheco RS, Gomes S, Santos DOS, Ribeiro G. Screening of fluorescent rhizobacteria for the biocontrol of soilborne plant pathogenic fungi. Caatinga. 2014;27(2):1-9. been applied to the characterization of rhizobial collections.

Martins at al.⁴⁶46 Martins PGS, Lira Junior MA, Fracetto GGM, Silva MLRB, Vincentin RP, Lyra MCCP. Mimosa caesalpiniifolia rhizobial isolates from different origins of the Brazilian Northeast. Arch Microbiol. 2015;197(3):459-469. did not observed a clear distribution of Paraburkholderia isolates from Mimosa caesalpinifolia in different regions of the Brazilian semi-arid. The geographic differentiation of Bradyrhizobium isolates from nodules of field grown Chamaecrista spp. in the Semi-Arid region of the Bahia State (Northeastern, Brazil) was also not clear.⁴⁷47 dos Santos JMF, Casaes Alves PA, Silva VC, Kruschewsky Rhem MF, James EK, Gross E. Diverse genotypes of Bradyrhizobium nodulate herbaceous Chamaecrista (Moench) (Fabaceae, Caesalpinioideae) species in Brazil. Syst Appl Microbiol. 2017;40(2):69-79. On the other hand, the differentiation of Bradyrhizobium isolates was observed in several crop species along the Okavango Valley, from Botswana to Angola.⁴⁸48 Grönemeyer JL, Kulkarni A, Berkelmann D, Hurek T, Reinhold-Hurek B. Rhizobia indigenous to the okavango region in sub-saharan Africa: diversity, adaptations, and host specificity. Appl Environ Microbiol. 2014;80(23):7244-7257.

For "mulungu" rhizobia in the Semi-Arid region of Brazil, there are local edaphoclimatic patterns that drives the occurrence of "mulungu" rhizobia. Menezes et al.¹⁶16 Menezes KAS, Escobar IEC, Fraiz ACR, Martins LMV, Fernandes-Júnior PI. Genetic variability and symbiotic efficiency of Erythrina velutina willd. Root nodule bacteria from the semi-arid region in Northeastern Brazil. Rev Bras Cienc do Solo. 2017;41:1-13. evaluating "mulungu" rhizobia from soils of Juazeiro municipality (Bahia, State) from the Brazilian Semi-Arid region, observed the presence of Bradyrhizobium from the clade B. japonicum and Rhizobium within the R. tropici clade, in addition to a β-rhizobia, pointing to the occurrence of certain "mulungu" rhizobia groups according to the sampling location at the Brazilian Semi-Arid. The rhizobia found in the soils of Juazeiro by those authors are closely related to those obtained from Serra Talhada in the present study. These cities are located about 300 km away. Despite the distance, the climatic characteristics of the cities are very similar regarding the temperature averages, rainfall and the plant coverage.²²22 Silva MCNA, Rodal MJN. Padrões das síndromes de dispersão de plantas em áreas com diferentes graus de pluviosidade, PE, Brasil. Acta Bot Brasilica. 2009;23(4):1040-1047. Caruaru is located at 260 km from Serra Talhada, but shows lower temperatures averages and higher rainfall (Table 1), changing the plant communities in the Caatinga sites,²²22 Silva MCNA, Rodal MJN. Padrões das síndromes de dispersão de plantas em áreas com diferentes graus de pluviosidade, PE, Brasil. Acta Bot Brasilica. 2009;23(4):1040-1047. resulting in different soil rhizobial communities. The data obtained in this study reinforce the hypothesis that edapho-climatic conditions drive the "mulungu" rhizobial community in Brazilian Semi-Arid soils.

The bacterial isolates showed variable behavior in face of the temperature and salinity. The isolates ESA 98 and ESA 99, both B. elkanii like isolates, grew up to 45 °C of incubation temperature. The isolates ESA 89 (close to B. subterraneum), ESA 97 and ESA 99 (both close to B. elkanii) highlighted due to their positive growth when inoculated in the medium supplemented with NaCl 0.51 mol L^-1. Surprisingly, the fast growing rhizobia was not the most tolerant bacteria to temperature and salinity. Data available in the literature refers the bacteria from genus Rhizobium and other fast growers as the most tolerant isolates,¹³13 Lira MA Jr, Nascimento LRS, Fracetto GGM. Legume-rhizobia signal exchange: promiscuity and environmental effects. Front Microbiol. 2015, http://dx.doi.org/10.3389/fmicb.2015.00945.
http://dx.doi.org/10.3389/fmicb.2015.009... ^,¹⁴14 Fernandes Júnior PI, Lima AA, Passos SR, et al. Phenotypic diversity and amylolytic activity of fast growing rhizobia from pigeonpea [Cajanus cajan (L.) MILLSP.]. Braz J Microbiol. 2012;43(4):1604-1612. probably due to their capacity to produce mucus, which provide cellular protection.⁴⁹49 Bushby HVA, Marshall KC. Desiccation-induced damage to the cell envelope of root-nodule bacteria. Soil Biol Biochem. 1977;9(3):149-152.

The type strains of B. subterraneum⁵⁰50 Grönemeyer JL, Chimwamurombe P, Reinhold-Hurek B. Bradyrhizobium subterraneum sp. nov., a symbiotic nitrogen-fixing bacterium from root nodules of groundnuts. Int J Syst Evol Microbiol. 2015;65(10):3241-3247. and B. tropiciagri⁴³43 Delamuta JRM, Ribeiro RA, Ormeño-Orrillo E, et al. Bradyrhizobium tropiciagri sp. nov. and Bradyrhizobium embrapense sp. nov nitrogenfixing symbionts of tropical forage legumes. Int J Syst Evol Microbiol. 2015;65(12):4424-4433. did not tolerate high incubation temperature grown when incubated at 37 °C. Regarding the NaCl tolerance, this type of strains tolerated lower than 0.17 mol L^-1. Generally, the bacterial isolates from semi-arid region, including the slow growing rhizobia, show higher tolerance to in vitro environmental stresses, as already observed for cowpea rhizobia regarding their tolerance to salt and temperature³⁹39 Xavier GR, Martins LMV, Rumjanek NG, Neves MCP. Tolerância de rizóbio de feijão-caupi à salinidade e à temperatura em condição in vitro. Caatinga. 2007;20:1-9. and antibiotics.⁵¹51 Xavier GR, Martins LMV, Neves MCP, Rumjanek NG. Edaphic factors as determinants for the distribution of intrinsic antibiotic resistance in a cowpea rhizobia population. Biol Fertil Soils. 1998;27(4):386-392. Nevertheless, the data obtained in this study indicates that our Bradyrhizobium were more tolerant to temperature and salinity than the Bradyrhizobium evaluated by Menezes et al.,¹⁷17 Menezes KAS, Nunes GFO, Sampaio AA, et al. Diversity of new root nodule bacteria from Erythrina velutina Willd., a native legume from the Caatinga dry forest (Northeastern Brazil). Rev Cienc Agrárias. 2016;39(2):222-233. strengthening the hypothesis of differences among the "mulungu" rhizobia in the Brazilian Semi-Arid. Temperatures above 40 °C are common in the Brazilian tropical soils, and the evaluation of the in vitro bacterial tolerance capacity to this conditions are useful to select bacterial isolates with higher resistance to harsh field conditions.

Several isolates did not solubilize the calcium phosphate in vitro. Three bacteria were positive to this characteristic, pointing out the isolate ESA 93, a Rhizobium sp. from Serra Talhada. The data obtained in this study corroborated with previous results, since low calcium phosphate solubilization are found in rhizobial collections evaluated in solid medium.⁵²52 Marra LM, Sousa Soares CRF, de Oliveira SM, et al. Biological nitrogen fixation and phosphate solubilization by bacteria isolated from tropical soils. Plant Soil. 2012;357(1):289-307.

The higher rates of auxin production were achieved in the medium with l-tryptophan. The bacteria ESA 98 and ESA 100, both Bradyrhizobium from Caruaru, produced significantly more auxin in the medium with l-try than the other bacteria. Differing from our study, the bacterial isolates evaluated by Menezes et al.¹⁷17 Menezes KAS, Nunes GFO, Sampaio AA, et al. Diversity of new root nodule bacteria from Erythrina velutina Willd., a native legume from the Caatinga dry forest (Northeastern Brazil). Rev Cienc Agrárias. 2016;39(2):222-233. showed that Burkholderia and Bradyrhizobium were the best auxin producers. l-try amino-acid is the main precursor of auxin and the supplementation of culture medium generally induces the auxin production by the bacterial isolates.⁵³53 Spaepen S, Vanderleyden J, Remans R. Indole-3-acetic acid in microbial and microorganism-plant signaling. FEMS Microbiol Rev. 2007;31(4):425-448.^,⁵⁴54 Duca D, Lorv J, Patten CL, Rose D, Glick BR. Indole-3-acetic acid in plant-microbe interactions. Antonie Van Leeuwenhoek. 2014;106(1):85-125. In the medium without l-try, the bacterial isolates can produce auxin if they present other metabolic pathway for auxin production. The calcium phosphate solubilizers ESA 93 (Rhizobium sp. from Serra Talhada) and ESA 97 (Bradyrhizobium sp. from Caruaru) produced more auxin than the other bacteria in medium without l-try, showing that this isolates presents different pathways to produce auxin, a desirable characteristic regarding the plant growth promotion.¹²12 Kumari BS, Ram MR, Mallaiah KV. Studies on exopolysaccharide and indole acetic acid production by Rhizobium strains from Indigofera. Afr J Microbiol Res. 2009;3(1):10-14.

Bradyrhizobium, Rhizobium and Paraburkholderia genera are well known for their ability to efficiently nodulate legumes in several ecological regions, including the Brazilian Semi-Arid,¹⁶16 Menezes KAS, Escobar IEC, Fraiz ACR, Martins LMV, Fernandes-Júnior PI. Genetic variability and symbiotic efficiency of Erythrina velutina willd. Root nodule bacteria from the semi-arid region in Northeastern Brazil. Rev Bras Cienc do Solo. 2017;41:1-13.^,⁴⁶46 Martins PGS, Lira Junior MA, Fracetto GGM, Silva MLRB, Vincentin RP, Lyra MCCP. Mimosa caesalpiniifolia rhizobial isolates from different origins of the Brazilian Northeast. Arch Microbiol. 2015;197(3):459-469.^,⁴⁷47 dos Santos JMF, Casaes Alves PA, Silva VC, Kruschewsky Rhem MF, James EK, Gross E. Diverse genotypes of Bradyrhizobium nodulate herbaceous Chamaecrista (Moench) (Fabaceae, Caesalpinioideae) species in Brazil. Syst Appl Microbiol. 2017;40(2):69-79.^,⁵⁵55 Martins LMV, Xavier GR, Rangel FW, et al. Contribution of biological nitrogen fixation to cowpea: a strategy for improving grain yield in the semi-arid region of Brazil. Biol Fertil Soils. 2003;38(6):333-339.^,⁵⁶56 Marinho RCN, Ferreira LVD, Silva AF, Nóbrega RSA, Martins LMV, Fernandes-Júnior PI. Symbiotic and agronomic efficiency of new cowpea rhizobia from Brazilian Semi-Arid. Bragantia. 2017;71(2):273-281. as observed in the present study. The plant inoculation experiment showed that the reference strain BR 5609 of B. elkanii, and the isolates ESA 96 and ESA 97, two B. elkanii like from Caruaru, pointed out the nodulation parameters. Other bacteria, such as the Paraburkholderia sp. ESA 96 and the Rhizobium sp. ESA 90, as well as the reference strain BR 5609, induced the same nitrogen accumulation in the shoots than the plants supplied with mineral nitrogen, indicating high symbiotic efficiency. The data reinforces the efficiency of the strain BR 5609 to E. velutina as already shown for this specie and to Erythrina falcata and E. verna. The data obtained in the present study confirm the presence of efficient "mulungu" rhizobia in the soils from semi-arid region of Brazil.¹⁶16 Menezes KAS, Escobar IEC, Fraiz ACR, Martins LMV, Fernandes-Júnior PI. Genetic variability and symbiotic efficiency of Erythrina velutina willd. Root nodule bacteria from the semi-arid region in Northeastern Brazil. Rev Bras Cienc do Solo. 2017;41:1-13. The data also support the selection of the isolates ESA 90, ESA 96 and ESA 97, along with BR 5609, for further evaluations aiming the official recommendation for E. velutina.

Few studies had been carried out evaluating at the same time the phenotypic diversity, taxonomic classification and the symbiotic efficiency of tree species in Brazilian Semi-Arid. To our knowledge, the data obtained in the present study are the first report of the concomitantly characterization of bacteria from "mulungu" at phenotypic, molecular and symbiotic levels. In this context, the data confirm our hypothesis that the soils of different dry lands regions of Pernambuco State, under natural Caatinga regeneration harbor a diverse and efficient nitrogen-fixing bacterial community.

Further assays are needed to get a better understand of the taxonomy and the present bacteria and their potential to promote the "mulungu" growth under non-sterile conditions. In the same context, more extensive isolation experiments are needed to understand the bio-geographical patterns of rhizobial distribution in the semi-arid region of the Pernambuco State.

Conclusions

Both α and β-rhizobia are able to occupy the E. velutina root nodules in soils of the Caatinga dry forests at the Pernambuco state (Northeastern, Brazil). The bacteria obtained showed metabolic versatility, tolerance to abiotic stresses and in vitro plant growth promotion mechanisms and the ability to induce high nitrogen accumulation in the shoots. This data set points to the potential of these bacteria to act as plant growth promoters by different ways. Furthermore, some bacteria can be selected for further studies aiming the official recommendation of the bacterial isolates for E. velutina, mainly the isolates ESA 96 and ESA 90, due to their performance in the in vivo experiment.

Acknowledgments

To the Brazilian Council for Scientific and Technological Development (CNPq-process 406327/2013-0 and 472997/2012-2) and the Brazilian Agricultural Research Corporation (Embrapa) for providing the financial support. To the Coordination of Improvement of Higher Education Personnel (CAPES) for the first to sixth authors scholarships. To the Science foundation of the Pernambuco State (FACEPE), for the scholarship to the seventh author.

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Leite J, Fischer D, Rouws LFM, et al. Cowpea nodules harbor non-rhizobial bacterial communities that are shaped by soil type rather than plant genotype. Front Plant Sci 2017;7(January):1-11.
³⁶
Freitas ADS, Borges WL, Andrade MMM, et al. Characteristics of nodule bacteria from Mimosa spp grown in soils of the Brazilian semiarid region. Afr J Microbiol Res 2014;8(8):788-796.
³⁷
Zahran HZ. Rhizobium-legume symbiosis and nitrogen fixation under severe conditions and in an arid climate. Microbiol Mol Biol Rev 1999;63(4):968-989.
³⁸
Leite J, Seido SL, Passos SR, Xavier GR, Rumjanek NG, Martins LMV. Biodiversity of rhizobia associated with cowpea cultivars in soils of the lower half of the São Francisco River Valley. Rev Bras Cienc do Solo 2009;33(5):1215-1226.
³⁹
Xavier GR, Martins LMV, Rumjanek NG, Neves MCP. Tolerância de rizóbio de feijão-caupi à salinidade e à temperatura em condição in vitro. Caatinga 2007;20:1-9.
⁴⁰
Miki T, Yokokawa T, Matsui K. Biodiversity and multifunctionality in a microbial community: a novel theoretical approach to quantify functional redundancy. Proc R Soc B Biol Sci 2013;281(1776):20132498.
⁴¹
Gilbert JA, Field D, Swift P, et al. The taxonomic and functional diversity of microbes at a temperate coastal site: a "multi-omic" study of seasonal and diel temporal variation. PLoS ONE 2010;5(11):.
⁴²
Sheu SY, Chou JH, Bontemps C, et al. Burkholderia diazotrophica sp. nov., isolated from root nodules of Mimosa spp.. Int J Syst Evol Microbiol 2013;63(PART2):435-441.
⁴³
Delamuta JRM, Ribeiro RA, Ormeño-Orrillo E, et al. Bradyrhizobium tropiciagri sp. nov. and Bradyrhizobium embrapense sp. nov nitrogenfixing symbionts of tropical forage legumes. Int J Syst Evol Microbiol 2015;65(12):4424-4433.
⁴⁴
Shamseldin A, Carro L, Peix A, Velázquez E, Moawad H, Sadowsky MJ. The symbiovar trifolii of Rhizobium bangladeshense and Rhizobium aegyptiacum sp. nov. nodulate Trifolium alexandrinum in Egypt. Syst Appl Microbiol 2016;39(4):275-279.
⁴⁵
Dias A, Pacheco RS, Gomes S, Santos DOS, Ribeiro G. Screening of fluorescent rhizobacteria for the biocontrol of soilborne plant pathogenic fungi. Caatinga 2014;27(2):1-9.
⁴⁶
Martins PGS, Lira Junior MA, Fracetto GGM, Silva MLRB, Vincentin RP, Lyra MCCP. Mimosa caesalpiniifolia rhizobial isolates from different origins of the Brazilian Northeast. Arch Microbiol. 2015;197(3):459-469.
⁴⁷
dos Santos JMF, Casaes Alves PA, Silva VC, Kruschewsky Rhem MF, James EK, Gross E. Diverse genotypes of Bradyrhizobium nodulate herbaceous Chamaecrista (Moench) (Fabaceae, Caesalpinioideae) species in Brazil. Syst Appl Microbiol 2017;40(2):69-79.
⁴⁸
Grönemeyer JL, Kulkarni A, Berkelmann D, Hurek T, Reinhold-Hurek B. Rhizobia indigenous to the okavango region in sub-saharan Africa: diversity, adaptations, and host specificity. Appl Environ Microbiol 2014;80(23):7244-7257.
⁴⁹
Bushby HVA, Marshall KC. Desiccation-induced damage to the cell envelope of root-nodule bacteria. Soil Biol Biochem 1977;9(3):149-152.
⁵⁰
Grönemeyer JL, Chimwamurombe P, Reinhold-Hurek B. Bradyrhizobium subterraneum sp. nov., a symbiotic nitrogen-fixing bacterium from root nodules of groundnuts. Int J Syst Evol Microbiol 2015;65(10):3241-3247.
⁵¹
Xavier GR, Martins LMV, Neves MCP, Rumjanek NG. Edaphic factors as determinants for the distribution of intrinsic antibiotic resistance in a cowpea rhizobia population. Biol Fertil Soils 1998;27(4):386-392.
⁵²
Marra LM, Sousa Soares CRF, de Oliveira SM, et al. Biological nitrogen fixation and phosphate solubilization by bacteria isolated from tropical soils. Plant Soil 2012;357(1):289-307.
⁵³
Spaepen S, Vanderleyden J, Remans R. Indole-3-acetic acid in microbial and microorganism-plant signaling. FEMS Microbiol Rev 2007;31(4):425-448.
⁵⁴
Duca D, Lorv J, Patten CL, Rose D, Glick BR. Indole-3-acetic acid in plant-microbe interactions. Antonie Van Leeuwenhoek 2014;106(1):85-125.
⁵⁵
Martins LMV, Xavier GR, Rangel FW, et al. Contribution of biological nitrogen fixation to cowpea: a strategy for improving grain yield in the semi-arid region of Brazil. Biol Fertil Soils 2003;38(6):333-339.
⁵⁶
Marinho RCN, Ferreira LVD, Silva AF, Nóbrega RSA, Martins LMV, Fernandes-Júnior PI. Symbiotic and agronomic efficiency of new cowpea rhizobia from Brazilian Semi-Arid. Bragantia 2017;71(2):273-281.
⁵⁷
Elliott GN, Chen WM, Bontemps C, et al. Nodulation of Cyclopia spp. (Leguminosae Papilionoideae) by Burkholderia tuberum. Ann Bot 2007;100(7):1403-1411.

Edited by

Associate Editor: Ieda Mendes

Publication Dates

Publication in this collection
Jul-Sep 2018

History

Received
22 June 2017
Accepted
5 Sept 2017

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

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[35] ³⁵
Leite J, Fischer D, Rouws LFM, et al. Cowpea nodules harbor non-rhizobial bacterial communities that are shaped by soil type rather than plant genotype. Front Plant Sci 2017;7(January):1-11.

[36] ³⁶
Freitas ADS, Borges WL, Andrade MMM, et al. Characteristics of nodule bacteria from Mimosa spp grown in soils of the Brazilian semiarid region. Afr J Microbiol Res 2014;8(8):788-796.

[37] ³⁷
Zahran HZ. Rhizobium-legume symbiosis and nitrogen fixation under severe conditions and in an arid climate. Microbiol Mol Biol Rev 1999;63(4):968-989.

[38] ³⁸
Leite J, Seido SL, Passos SR, Xavier GR, Rumjanek NG, Martins LMV. Biodiversity of rhizobia associated with cowpea cultivars in soils of the lower half of the São Francisco River Valley. Rev Bras Cienc do Solo 2009;33(5):1215-1226.

[39] ³⁹
Xavier GR, Martins LMV, Rumjanek NG, Neves MCP. Tolerância de rizóbio de feijão-caupi à salinidade e à temperatura em condição in vitro. Caatinga 2007;20:1-9.

[40] ⁴⁰
Miki T, Yokokawa T, Matsui K. Biodiversity and multifunctionality in a microbial community: a novel theoretical approach to quantify functional redundancy. Proc R Soc B Biol Sci 2013;281(1776):20132498.

[41] ⁴¹
Gilbert JA, Field D, Swift P, et al. The taxonomic and functional diversity of microbes at a temperate coastal site: a "multi-omic" study of seasonal and diel temporal variation. PLoS ONE 2010;5(11):.

[42] ⁴²
Sheu SY, Chou JH, Bontemps C, et al. Burkholderia diazotrophica sp. nov., isolated from root nodules of Mimosa spp.. Int J Syst Evol Microbiol 2013;63(PART2):435-441.

[43] ⁴³
Delamuta JRM, Ribeiro RA, Ormeño-Orrillo E, et al. Bradyrhizobium tropiciagri sp. nov. and Bradyrhizobium embrapense sp. nov nitrogenfixing symbionts of tropical forage legumes. Int J Syst Evol Microbiol 2015;65(12):4424-4433.

[44] ⁴⁴
Shamseldin A, Carro L, Peix A, Velázquez E, Moawad H, Sadowsky MJ. The symbiovar trifolii of Rhizobium bangladeshense and Rhizobium aegyptiacum sp. nov. nodulate Trifolium alexandrinum in Egypt. Syst Appl Microbiol 2016;39(4):275-279.

[45] ⁴⁵
Dias A, Pacheco RS, Gomes S, Santos DOS, Ribeiro G. Screening of fluorescent rhizobacteria for the biocontrol of soilborne plant pathogenic fungi. Caatinga 2014;27(2):1-9.

[46] ⁴⁶
Martins PGS, Lira Junior MA, Fracetto GGM, Silva MLRB, Vincentin RP, Lyra MCCP. Mimosa caesalpiniifolia rhizobial isolates from different origins of the Brazilian Northeast. Arch Microbiol. 2015;197(3):459-469.

[47] ⁴⁷
dos Santos JMF, Casaes Alves PA, Silva VC, Kruschewsky Rhem MF, James EK, Gross E. Diverse genotypes of Bradyrhizobium nodulate herbaceous Chamaecrista (Moench) (Fabaceae, Caesalpinioideae) species in Brazil. Syst Appl Microbiol 2017;40(2):69-79.

[48] ⁴⁸
Grönemeyer JL, Kulkarni A, Berkelmann D, Hurek T, Reinhold-Hurek B. Rhizobia indigenous to the okavango region in sub-saharan Africa: diversity, adaptations, and host specificity. Appl Environ Microbiol 2014;80(23):7244-7257.

[49] ⁴⁹
Bushby HVA, Marshall KC. Desiccation-induced damage to the cell envelope of root-nodule bacteria. Soil Biol Biochem 1977;9(3):149-152.

[50] ⁵⁰
Grönemeyer JL, Chimwamurombe P, Reinhold-Hurek B. Bradyrhizobium subterraneum sp. nov., a symbiotic nitrogen-fixing bacterium from root nodules of groundnuts. Int J Syst Evol Microbiol 2015;65(10):3241-3247.

[51] ⁵¹
Xavier GR, Martins LMV, Neves MCP, Rumjanek NG. Edaphic factors as determinants for the distribution of intrinsic antibiotic resistance in a cowpea rhizobia population. Biol Fertil Soils 1998;27(4):386-392.

[52] ⁵²
Marra LM, Sousa Soares CRF, de Oliveira SM, et al. Biological nitrogen fixation and phosphate solubilization by bacteria isolated from tropical soils. Plant Soil 2012;357(1):289-307.

[53] ⁵³
Spaepen S, Vanderleyden J, Remans R. Indole-3-acetic acid in microbial and microorganism-plant signaling. FEMS Microbiol Rev 2007;31(4):425-448.

[54] ⁵⁴
Duca D, Lorv J, Patten CL, Rose D, Glick BR. Indole-3-acetic acid in plant-microbe interactions. Antonie Van Leeuwenhoek 2014;106(1):85-125.

[55] ⁵⁵
Martins LMV, Xavier GR, Rangel FW, et al. Contribution of biological nitrogen fixation to cowpea: a strategy for improving grain yield in the semi-arid region of Brazil. Biol Fertil Soils 2003;38(6):333-339.

[56] ⁵⁶
Marinho RCN, Ferreira LVD, Silva AF, Nóbrega RSA, Martins LMV, Fernandes-Júnior PI. Symbiotic and agronomic efficiency of new cowpea rhizobia from Brazilian Semi-Arid. Bragantia 2017;71(2):273-281.

[57] ⁵⁷
Elliott GN, Chen WM, Bontemps C, et al. Nodulation of Cyclopia spp. (Leguminosae Papilionoideae) by Burkholderia tuberum. Ann Bot 2007;100(7):1403-1411.

Characteristics	Caruaru	Serra Talhada
Mesoregion	Agreste	Sertão
Regeneration time (under fallow)	21 years	24 years
Most abundant legume species	Bauhinia cheilantha Senna cf. spectabilis Poincianella pyramidalis Anadenanthera colubrina Mimosa arenosa Piptadenia stipulacea	Poincianella pyramidalis Anadenanthera colubrina Mimosa ophtalmocentra Mimosa tenuiflora Amburana cearenses
Coordinates	08º13'54" S and 35º55'13" W	7º57'29" S and 38º23'37" W
Altitude (ma s l)	561	443
Average annual rainfall (mm)	764	686
Average annual temperature (ºC)	21.7	26.0
Soil type	Ultisol	Luvisol
pH (H₂O)	5.96	6.22
P (mg dm^-3)	8.78	10.9
Ca²⁺ (cmol_c dm^-3)	2.78	3.64
Mg²⁺ (cmol_c dm^-3)	1.42	2.85
Na⁺ (cmol_c dm^-3)	0.04	0.05
K⁺ (cmol_c dm^-3)	0.50	0.81
Al³⁺ (cmol_c dm^-3)	0.00	0.00
Sand (g kg^-1)	684	599
Silt (g kg^-1)	229	232
Clay (g kg^-1)	87	169

Treatments	NN	NDM	SDM	RDM	Total N
	nodules plant^-1	mg plant^-1	g plant^-1		mg N plant^-1
ESA 89	9 c^a a Averages followed by the same letter within each column are not significantly different according to the Scott-Knott's test (p < 0.05).	12.50 d	1.40	1.82	27.12 b
ESA 96	5 d	35.70 c	1.96	1.34	72.32 a
ESA 90	10 c	44.65 c	1.87	1.89	61.53 a
ESA 91	6 d	37.90 c	1.05	1.29	18.12 b
ESA 92	4 d	21.85 d	0.84	1.18	18.42 b
ESA 93	4 d	28.40 c	1.58	1.29	25.46 b
ESA 97	19 b	76.70 b	1.61	1.61	25.66 b
ESA 98	20 b	67.15 b	1.52	1.12	37.37 b
ESA 99	14 c	48.43 c	0.90	1.33	24.55 b
ESA 100	12 c	50.47 c	1.07	1.16	31.09 b
BR 5609	31 a	105.75 a	2.22	1.3	48.26 a
N control	0 e	0.00 d	0.98	1.82	49.32 a
Abs Control	0 e	0.00 d	1.03	1.6	22.68 b
CV (%)	19.9	42.9	38.6	47.8	21.8

Bacteria	Temperature^b b Maximum incubation temperature with positive growth.	NaCl^c c Maximum NaCl concentration in culture medium with positive bacterial growth.	Solubilization index^d d S.I., translucent zone diameter (mm)/colony diameter (mm).	Auxin^e e Auxin production (+l-try, add of 168 mg of l-tryptophan in 1 L of culture medium; -l-try, no add of l-tryptophan); -, not detected; nd, not determined.
	(ºC)	mol L^-1	(SI)	-Try	+Try
ESA 89	40	0.51	-	10.08 b	16.9 d
ESA 96	35	0.085	-	-	-
ESA 90	35	0.34	0.15 b^f f Averages followed by the same letter within each column are not significantly different according to the Scott-Knott's test (p < 0.05).	-	-
ESA 91	35	0.34	-	-	19.11 d
ESA 92	40	0.085	-	-	-
ESA 93	35	0.085	0.35 a	20.16 a	114.0 b
ESA 97	35	0.51	0.07 b	23.63 a	-
ESA 98	45	0.34	-	11.10 b	150.1 a
ESA 99	45	0.51	-	-	44.0 c
ESA 100	35	0.085	-	12.00 b	163.6 a
BR 3299^a a Reference strain: Microvirga vignae BR 3299T.	nd	nd	0.62 a	14.16 b	55.8 c

Brasil

Brasil

Phenotypic, genetic and symbiotic characterization of Erythrina velutina rhizobia from Caatinga dry forest

Abstract

Introduction

Materials and methods

Origin of the bacterial isolates

Amplification of symbiotic genes

Metabolic characterization using the API 20 NE® kit

16S rRNA gene sequence analyses

Salt and temperature tolerance

Auxin production and solubilization of calcium phosphate

Symbiotic efficiency in "mulungu" plants

Statistical analyses

Results

Isolation and symbiotic gene amplification

Metabolic profile of the bacterial isolates

16S rRNA gene sequence analyses

In vitro temperature and salt tolerance

Solubilization of calcium phosphate and production of auxin in vitro

Symbiotic efficiency in "mulungu" plants

Discussion

Conclusions

Acknowledgments

References

Edited by

Publication Dates

History

Metabolic characterization using the API 20 NE^® kit