Abstract

Amongst the sustainable alternatives to increase maize production is the use of plant growth-promoting bacteria (PGPB). Azospirillum brasilense is one of the most well-known PGPB being able to fix nitrogen and produce phytohormones, especially indole-3-acetic acid - IAA. This work investigated if there is any contribution of the bacterium to the plant’s IAA levels, and how it affects the plant. To inhibit plant IAA production, yucasin, an inhibitor of the TAM/YUC pathway, was applied. Plantlets’ IAA concentration was evaluated through HPLC and dual RNA-Seq was used to analyze gene expression. Statistical differences between the group treated with yucasin and the other groups showed that A. brasilense inoculation was able to prevent the phenotype caused by yucasin concerning the number of lateral roots. Genes involved in the auxin and ABA response pathways, auxin efflux transport, and the cell cycle were regulated by the presence of the bacterium, yucasin, or both. Genes involved in the response to biotic/abiotic stress, plant disease resistance, and a D-type cellulose synthase changed their expression pattern among two sets of comparisons in which A. brasilense acted as treatment. The results suggest that A. brasilense interferes with the expression of many maize genes through an IAA-independent pathway.

Keywords:
Dual RNA-Seq; Zea mays; Plant Growth-Promoting Bacteria; ABA; yucasin

Introduction

Plant Growth-Promoting Bacteria (PGPB) are a group of beneficial microorganisms that can colonize the rhizosphere, the phyllosphere, the root’s surface, and the plant’s internal tissues stimulating plant growth (Verna et al., 2010Verna JP, Yadav J, Tiwari KN, Singh L and Singh V (2010) Impact of plant growth promoting rhizobacteria on crop production. Int J Agric Res 5:954-983.; Khabbaz et al., 2019Khabbaz KSE, Ladhalakshmi LD, Babu BM, Kandan A, Ramamoorthy V, Saravanakumar D, Al-Mughrabi T and Kandasamy S (2019) Plant Growth Promoting Bacteria (PGPB) - A versatile tool for plant health management. Can J Pestic Pest Manag. DOI:10.34195/can.j.ppm.2019.05.001.
https://doi.org/10.34195/can.j.ppm.2019.... ). It is believed that these bacteria can promote plant growth through the combination of several abilities, like biological nitrogen fixation, production of phytohormones (especially indole-3-acetic acid - IAA), vitamins, and growth factors (Babalola, 2010Babalola OO (2010) Beneficial bacteria of agricultural importance. Biotechnol Lett 32:1559-1570. ; Bashan and de-Bashan, 2010Bashan Y and de-Bashan LE (2010) How the plant growth-promoting bacterium Azospirillum promotes plant growth - A critical assessment. Adv Agron 108:77-136. ; Khabbaz et al., 2019Khabbaz KSE, Ladhalakshmi LD, Babu BM, Kandan A, Ramamoorthy V, Saravanakumar D, Al-Mughrabi T and Kandasamy S (2019) Plant Growth Promoting Bacteria (PGPB) - A versatile tool for plant health management. Can J Pestic Pest Manag. DOI:10.34195/can.j.ppm.2019.05.001.
https://doi.org/10.34195/can.j.ppm.2019.... ).

Azospirillum brasilense is one of the most well-known PGPB being widely used in South America as a cereal crop inoculant. Amongst the plant growth-promoting traits of this bacterium, the most studied are the ability to fix nitrogen and to produce phytohormones (IAA, gibberellins, ethylene, and polyamines) (Cassán et al., 2014Cassán F, Vanderleyden J and Spaepen S (2014) Physiological and agronomical aspects of phytohormone production by model Plant-Growth-Promoting Rhizobacteria (PGPR) belonging to the genus Azospirillum. J Plant Growth Regul 33:440-459. ; Cassán and Diaz-Zorita, 2016Cassán F and Diaz-Zorita M (2016) Azospirillum sp. in current agriculture: From the laboratory to the field. Soil Biol Biochem 103:117-130. ; Fukami et al., 2018Fukami J, Cerezini P and Hungria M (2018) Azospirillum: Benefits that go far beyond biological nitrogen fixation. AMB Express 8:73. ; Cassán et al., 2020Cassán F, Coniglio A, López G, Molina R, Nievas S, de Carlan CLN, Donadio F, Torres D, Rosas S, Pedrosa FO et al. (2020) Everything you must know about Azospirillum and its impact on agriculture and beyond. Biol Fert Soils 56:461-479. ). It is believed that these two characteristics are responsible for stimulating the increase of the final dry mass of the plants (Bashan and de-Bashan, 2010Bashan Y and de-Bashan LE (2010) How the plant growth-promoting bacterium Azospirillum promotes plant growth - A critical assessment. Adv Agron 108:77-136. ; Cassán et al., 2020Cassán F, Coniglio A, López G, Molina R, Nievas S, de Carlan CLN, Donadio F, Torres D, Rosas S, Pedrosa FO et al. (2020) Everything you must know about Azospirillum and its impact on agriculture and beyond. Biol Fert Soils 56:461-479. ). Among the phytohormones produced by PGPB and plants, auxins (mainly IAA) are the most studied (Spaepen et al., 2007Spaepen S, Vanderleyden J and Remans R (2007) Indole-3-acetic acid in microbial and microorganism-plant signaling. FEMS Microbiol Rev 31:425-448. ; Baudoin et al., 2010Baudoin E, Lerner A, Mirza MS, Zemrany HE, Prigent-Combaret C, Jurkevich E, Spaepen S, Vanderleyden J, Nazaret S, Okon Y et al. (2010) Effects of Azospirillum brasilense with genetically modified auxin biosynthesis gene ipdC upon the diversity of the indigenous microbiota of the wheat rhizosphere. Res Microbiol 161:219-226. ; Spaepen and Vanderleyden, 2010Spaepen S and Vanderleyden J (2010) Auxin and plant-microbe interactions. Cold Spring Harb Perspect Biol 3:a001438. ; Yue et al., 2014Yue J, Hu X and Huang J (2014) Origin of plant auxin biosynthesis. Trends Plant Sci 19:764-770. ). The main biosynthetic pathway in both plant and PGPB uses tryptophan (Trp) as a precursor for IAA synthesis (Spaepen et al., 2007Spaepen S, Vanderleyden J and Remans R (2007) Indole-3-acetic acid in microbial and microorganism-plant signaling. FEMS Microbiol Rev 31:425-448. ). In bacteria, this molecule is involved in the quorum-sensing process, which permits them to control their activities based on population density (Spaepen et al., 2007Spaepen S, Vanderleyden J and Remans R (2007) Indole-3-acetic acid in microbial and microorganism-plant signaling. FEMS Microbiol Rev 31:425-448. ; Duca et al., 2014Duca D, Lorv J, Patten CL, Rose D and Glick BR (2014) Indole-3-acetic acid in plant-microbe interactions. A Van Leeuw J Microb 106:85-125. ; Yue et al., 2014Yue J, Hu X and Huang J (2014) Origin of plant auxin biosynthesis. Trends Plant Sci 19:764-770. ). Although many studies show IAA’s importance in plant-growth promotion, others showed that the Azospirillum IAA biosynthesis alone cannot account for the overall plant growth-promoting effect observed (Spaepen et al., 2007Spaepen S, Vanderleyden J and Remans R (2007) Indole-3-acetic acid in microbial and microorganism-plant signaling. FEMS Microbiol Rev 31:425-448. ; Bashan and de-Bashan, 2010Bashan Y and de-Bashan LE (2010) How the plant growth-promoting bacterium Azospirillum promotes plant growth - A critical assessment. Adv Agron 108:77-136. ). Furthermore, according to Cassán et al. (2020Cassán F, Coniglio A, López G, Molina R, Nievas S, de Carlan CLN, Donadio F, Torres D, Rosas S, Pedrosa FO et al. (2020) Everything you must know about Azospirillum and its impact on agriculture and beyond. Biol Fert Soils 56:461-479. ), there is evidence that plant growth promoted by Azospirillum sp can be both IAA-dependent and IAA-independent. In plants, auxins are responsible for regulating various aspects of their development, such as cell growth and differentiation, the establishment of apical dominance, differentiation of xylem, suppression of abscission, and formation of apical and root meristem (Bishopp et al., 2006Bishopp A, Mahonen AP and Helariutta Y (2006) Signs of change: Hormone receptors that regulate plant development. Development 133:1857-1869. ; Yue et al., 2014Yue J, Hu X and Huang J (2014) Origin of plant auxin biosynthesis. Trends Plant Sci 19:764-770. ).

Over the years, several IAA biosynthetic pathways using Trp as a precursor have been proposed to explain how plants produce this hormone (Zhao, 2010Zhao Y (2010) Auxin biosynthesis and its role in plant development. Annu Rev Plant Biol 61:49-64.). Recently studies have indicated that the tryptophan aminotransferase (TAA) and the YUC-flavin monooxygenases families are part of the main pathway of IAA production in plants: TAA converts tryptophan to indole - 3 - pyruvate (IPA), which is converted into IAA by YUC (Mashiguchi et al., 2011Mashiguchi K, Tanaka K, Sakai T, Sugawara S, Kawaide H, Natsume M, Hanada A, Yaeno T, Shirasu K, Yao H et al. (2011) The main auxin biosynthesis pathway in Arabidopsis. P Natl Acad Sci-Biol 108:18512-18517. ; Won et al., 2011Won C, Shen X, Mashiguchi K, Zheng Z, Dai X, Cheng Y, Kasahara H, Kamiya Y, Chory J and Zhao Y (2011) Conversion of tryptophan to indole-3-acetic acid by tryptophan aminotransferases of Arabidopsis and YUCCAs in Arabidopsis. P Natl Acad Sci-Biol 108:18518-18523. ; Zhao, 2012Zhao Y (2012) Auxin biosynthesis: A simple two-step pathway converts tryptophan to indole-3-acetic acid in plants. Mol Plant 5:334-338. ; Zhao, 2014Zhao Y (2014) Auxin biosynthesis. Arabidopsis Book 12:e0173. ; Yue et al., 2014Yue J, Hu X and Huang J (2014) Origin of plant auxin biosynthesis. Trends Plant Sci 19:764-770. ). It was observed by Nishimura et al. (2014Nishimura T, Hayashi K, Suzuki H, Gyohda A, Takaoka C, Sakaguchi Y, Matsumoto S, Kasahara H, Sakai T, Kato J et al. (2014) Yucasin is a potent inhibitor of YUCCA, a key enzyme in auxin biosynthesis. Plant J 77:352-366. ) that yucasin [5-(4-chlorophenyl)-4H-1,2,4-triazol-3-thiol] is a competitive inhibitor of YUC, preventing IPA decarboxylation. Since yucasin inhibits the production of IAA by this route, it can be used in studies of modulation of IAA production by the plant over time (Zhao, 2014Zhao Y (2014) Auxin biosynthesis. Arabidopsis Book 12:e0173. ).

In the present work, the interaction between Azospirillum brasilense FP2 and maize was investigated under co-cultivation in the presence of the TAA/YUC pathway inhibitor, yucasin. The use of this inhibitor was made to access if there is any contribution of the bacterium to the IAA levels in the plant, and how it affects the plant. The plantlets’ IAA concentration was accessed by HPLC. Gene expression patterns of the bacterium and plant were analyzed by dual RNA-Seq, and data obtained from the sequencing of plant and bacterium transcriptomes were subjected to a combined analysis approach. The IAA concentration alongside the pattern of genes differentially expressed in maize brings to light evidence of the existence of an IAA-independent pathway for plant-growth promotion by the bacterium.

Material and Methods

Bacterial strain and growth curve conditions

A. brasilense strain FP2 is a natural mutant originating from strain Sp7 (ATCC29145) that presents resistance to nalidixic acid and streptomycin antibiotics (Pedrosa and Yates, 1984Pedrosa FO and Yates MG (1984) Regulation of nitrogen fixation (nif) genes of Azospirillum brasilense by nifA and ntr (gln) type gene products. FEMS Microbiol Lett 23:95-101.). A. brasilense FP2 growth curves were obtained by inoculation of 2 mL of 24 h bacterial pre-culture in 250 mL Erlenmeyer’s flask containing 100 mL of King B medium (Glickmann and Dessaux, 1995Glickmann E and Dessaux Y (1995) A critical examination of the specificity of the Salkowski reagent for indolic compounds produced by phytopathogenic bacteria. Appl Environ Microb 61:793-796.) supplemented or not with 50 µM of yucasin [5-(4-chlorophenyl)-4H-1,2,4-triazole-3-thiol; register number CAS: 26028-65-9] to reach an initial OD_600nm of 0.02. Cultures were incubated in an orbital shaker at 30^oC and 120 rpm. Samplings were taken after 2, 4, 6, 26, 30, and 32 h of bacterial growth for CFU calculation. To measure the bacterial indole compounds (ICs) production, as an indirect way of measuring IAA concentration, 2 mL of bacterial culture from each sampling time was centrifuged for 5 min at 12,000 g. The supernatant was collected and mixed with the Salkowski reagent at the proportion of 1:2, respectively (Glickmann and Dessaux, 1995Glickmann E and Dessaux Y (1995) A critical examination of the specificity of the Salkowski reagent for indolic compounds produced by phytopathogenic bacteria. Appl Environ Microb 61:793-796.). Bacterial ICs production was measured as described by Ambrosini et al. (2012Ambrosini A, Beneduzi A, Stefanski T, Pinheiro FG, Vargas LK and Passaglia LMP (2012) Screening of plant growth promoting rhizobacteria isolated from sunflower (Helianthus annuus L.). Plant Soil 356:245-264. ).

Seed inoculation, experimental conditions, and physiological experiment

The bacterial suspension was prepared by growing A. brasilense FP2 in 30 mL of NFb medium supplemented with 5 mg L^-1 of malic acid (Pedrosa and Yates, 1984Pedrosa FO and Yates MG (1984) Regulation of nitrogen fixation (nif) genes of Azospirillum brasilense by nifA and ntr (gln) type gene products. FEMS Microbiol Lett 23:95-101.) in an orbital shaker (30^oC, 120 rpm) until an OD₆₀₀ of 0.8 [~10⁸ cells mL^-1 (Faleiro et al., 2013Faleiro AL, Pereira TP, Espindula E, Brod FCA and Arisi ACM (2013) Real-time PCR detection targeting nifA gene of plant growth promoting bacteria Azospirillum brasilense strain FP2 in maize roots. Symbiosis 61:125-133. )]. Aliquots of 3 mL of the culture were centrifuged, and the pellets were suspended in NFb medium without nitrogen.

Zea mays (var. Santa Helena SHS4080) seeds were surface-sterilized by washing them three times with autoclaved ultrapure water, followed by submersion in 70% ethanol for 3 min and in a solution of 2% sodium hypochlorite and 2.5% Tween 20 for 30 min. Seeds were then washed three times with sterile distilled water by gentle shaking (Faleiro et al., 2013Faleiro AL, Pereira TP, Espindula E, Brod FCA and Arisi ACM (2013) Real-time PCR detection targeting nifA gene of plant growth promoting bacteria Azospirillum brasilense strain FP2 in maize roots. Symbiosis 61:125-133. ).

The experiment was divided into four groups: Ctr (control plantlets), Yuc {plantlets that received 50 µM of yucasin solution [concentration according to Nishimura et al. (2014Nishimura T, Hayashi K, Suzuki H, Gyohda A, Takaoka C, Sakaguchi Y, Matsumoto S, Kasahara H, Sakai T, Kato J et al. (2014) Yucasin is a potent inhibitor of YUCCA, a key enzyme in auxin biosynthesis. Plant J 77:352-366. )]}, Azo (plantlets inoculated withA. brasilense FP2), and AzoYuc (plantlets that received 50 µM of yucasin solution and were inoculated with A. brasilense FP2). For inoculation, seeds (0.1 g) were mixed with 0.5 mL of bacterial suspension containing ~3 x 10⁸ bacterial cells mL^-1 (Hungria et al., 2010Hungria M, Campo RJ, Souza EM and Pedrosa FO (2010) Inoculation with selected strains of Azospirillum brasilense and A. lipoferum improves yields of maize and wheat in Brazil. Plant Soil 331:413-425. ; Espindula et al., 2017Espindula E, Faleiro AC, Pereira TP, Amaral FP and Arisi ACM (2017) Azospirillum brasilense FP2 modulates respiratory burst oxidase gene expression in maize seedlings. Indian J Plant Physiol 22:316-323.) and incubated for 5 min in an orbital shaker at 100 rpm (Faleiro et al., 2013Faleiro AL, Pereira TP, Espindula E, Brod FCA and Arisi ACM (2013) Real-time PCR detection targeting nifA gene of plant growth promoting bacteria Azospirillum brasilense strain FP2 in maize roots. Symbiosis 61:125-133. ). Seeds inoculated or not were placed in a sterilized water-saturated paper and maintained for three days in a 25^oC growth chamber in the dark for germination. Maize seedlings were then transferred to pots containing sterilized sand wet with plant medium solution (Egener et al., 1999Egener T, Hurek T and Reinhold-Hurek B (1999) Endophytic expression of nif genes of Azoarcus sp strain BH72 in rice roots. Mol Plant Microbe In 12:813-819. ) without nitrogen. Azo and AzoYuc groups were formed with the inoculated seedlings and Ctr and Yuc with the non-inoculated ones. The plantlets were kept in a growing chamber for 10 days (25^oC, 16 h light/8 h dark, with active photosynthetic radiation of 150 μmol m²s^-1) (Faleiro et al., 2013Faleiro AL, Pereira TP, Espindula E, Brod FCA and Arisi ACM (2013) Real-time PCR detection targeting nifA gene of plant growth promoting bacteria Azospirillum brasilense strain FP2 in maize roots. Symbiosis 61:125-133. ; Espindula et al., 2017Espindula E, Faleiro AC, Pereira TP, Amaral FP and Arisi ACM (2017) Azospirillum brasilense FP2 modulates respiratory burst oxidase gene expression in maize seedlings. Indian J Plant Physiol 22:316-323.). After this period, each plant from Yuc and AzoYuc groups received 10 mL of an aqueous solution (autoclaved ultrapure water) of yucasin (50 µM final concentration), which was added directly to the soil. Plants from Ctr and Azo groups received only sterilized water. The experiment was carried out with three biological replicates. Each replicate consisted of 20 Z. mays plantlets. After five hours under yucasin treatment roots were washed twice with sterilized water, separated from the aerial part, and stored at -80^oC until RNA extraction and electron microscopy analysis.

To access the physiological effects of the yucasin on the plant’s development, another four groups of maize plantlets were prepared as previously described. Ten days plantlets from Yuc and AzoYuc groups were then daily supplemented with 50 µM of yucasin solution for additional five days, while plantlets from Ctr and Azo groups received only sterilized water. After this period, the lengths of the aerial parts and the main root (the longest one), and the number of lateral roots of each plantlet were evaluated.

Endogenous auxin quantification by High-Performance Liquid Chromatography (HPLC)

The quantification of endogenous auxin content of plantlets was performed according to Kim et al. (2006Kim YJ, Oh YJ and Park WJ (2006) HPLC-based quantification of indole-3-acetic acid in the primary root tip of maize. J Nanobiotechnol 3:40-45.) and Vilasboa et al. (2019Vilasboa J, Costa CT, Matsuura HN and Fett-Neto AG (2019) Rooting of cuttings of Passiflora suberosa, a medicinal passion fruit species: Characterization and modulation by external biochemical factors. Isr J Plant Sci 67:40-51. ), with the following modifications. Approximately 200 mg of maize roots were ground with liquid nitrogen and extracted with 100% methanol (2.5 mL g^-1 FW), followed by centrifugation for 10 min at 16,000 g at 4 °C. The supernatant was transferred to a new tube and concentrated in Speed Vac (Christ RVC 2-18 CDPlus) until approximately one-tenth of the initial volume. The remaining solution was resuspended in 200 μL of distilled and deionized water.

The pH of the solution was adjusted to above 9 with 1 M KOH and then partitioned against 100% ethyl acetate (1:1 v/v). The aqueous and organic phases were separated by centrifugation (16,000 g x 5 min). The lower aqueous phase was transferred to a new tube and the pH of the solution was lowered to below 3 with concentrated acetic acid to keep IAA in protonated form. After the solution was partitioned with 100% ethyl acetate (1:1 v/v) and the phases were separated by centrifugation. The upper organic phase was transferred to new tubes, completely dried in Speed Vac, and resuspended in 100 μL 100% HPLC grade methanol.

The samples and the calibration curve were analyzed using an HPLC system (Prominence, Shimadzu) equipped with a Kinetex-Phenomenex C₁₈ HPLC reverse-phase column (150 x 4.6 mm x 5 µm). The mobile phases were based on the proposed by Kim et al. (2006Kim YJ, Oh YJ and Park WJ (2006) HPLC-based quantification of indole-3-acetic acid in the primary root tip of maize. J Nanobiotechnol 3:40-45.) with some modifications, consisting of an aqueous solution of acetic acid at 0.3% v/v (mobile phase A), and a methanolic solution of acetic acid at 0.3% v/v (mobile phase B) at a flow rate of 1 mL min^-1. The gradient of the mobile phase was adopted as follows: 0 - 5 min using 15% of B; from 5 - 15 min mobile phase B was increased to 100% maintaining up to 17 min; returning to the initial condition at 22 min and maintaining this condition up to 30 min. The column oven temperature was kept at 30⁰C for all analyses. A fluorescence detector Shimadzu RF-20A (emission at 360 nm, excitation at 282 nm) was used to detect indole-3-acetic acid (IAA). A standard curve was generated using purified IAA (Neon) and 20 μL of each sample was analyzed using an autosampler Shimadzu SIL-20A. For this analysis, three biological replicates were analyzed for each experimental group.

Scanning electron microscopy (SEM)

To visualize A. brasilense cells attached to maize roots, two Zea mays roots from Azo and AzoYuc groups were fixed with Karnovsky’s (Karnovsky, 1964Karnovsky M (1964) A Formaldehyde-Glutaraldehyde fixative of high osmolality for use in electron microscopy. J Cell Biol 27:1A-149A.) fixative and washed in an alcoholic series (20, 40, 60,70, 80, 90, 96, and 100%) during 30 min at each concentration. After complete dehydration, the samples were dried at the critical point of CO₂ at the equipment Leica EM CDP 300 (Haddad et al., 2007Haddad A, Campos APC and Sesso A (2007) Técnicas de microscopia eletrônica aplicadas às ciências biológicas. Sociedade Brasileira de Microscopia, Rio de Janeiro.). The dried samples were attached to aluminum supports with the aid of double-sided carbon tape and were carbon-coated at Baltec’s Sputter Coater, model CED 005, for an ultrastructural study. The analysis was conducted in a Scanning Electron Microscope FEI, model Inspect F50, at the Central Laboratory for Microscopy and Microanalysis, Pontifical Catholic University of Rio Grande do Sul (LabCEMM-PUC/RS), Brazil.

RNA isolation, mRNA enrichment, cDNA synthesis, and sequencing

Total RNA was isolated from 0.1 g of plant tissue from a pool of 20 maize roots for each biological replicate from each treatment. There were three RNA extractions per experimental group, and one per biological replicate, totalizing 12 RNA samples. Total RNA was isolated by RNeasy Plant Mini Kit® (Qiagen, CA, USA). The RNA concentration and purity were determined by spectrophotometry at 260 nm and 280 nm (Jahn et al., 2008Jahn CE, Charkowski AO and Willis DK (2008) Evaluation of isolation methods and RNA integrity for bacterial RNA quantitation. J Microbiol Meth 75:318-324. ) measured in a Nanodrop LITE spectrophotometer (Thermo Fisher Scientific, Wilmington, DE, USA). Then, samples were first treated with DNaseI (Invitrogen), and the rRNA pool was depleted using the RiboMinus™ Plant Kit for RNA-Seq (Invitrogen). The cDNA libraries were constructed using the Ion Total RNA-Seq kit v2 for Whole Transcriptome Library. All RNA quantification and quality evaluation were performed at the Bioanalyzer™ - Agilent 2100 instrument. Each cDNA library obtained was sequenced using the Ion PI Template OT2 200 Kit v3 and the Ion PI Sequencing 200 Kit v3 at the IonTorrent® platform (Thermo FisherScientific, Wilmington, DE, USA). All kits and reagents were used according to the manufacturer’s instructions. The 12 cDNA libraries obtained in this work were deposited in GenBank under the numbers SAMN12391479 to SAMN12391490.

Data analysis and differential gene expression

The reference genomes and the respective annotations were downloaded from the National Center for Biotechnology Information (NCBI) site. All the cDNA libraries obtained and the reference genomes with annotations were uploaded into the CLC Genomics Workbench (v. 8.0). Reads smaller than 20 nucleotides and with low quality were removed from libraries using the standards setup of CLC Genomics. Ctr and Yuc groups cDNA libraries were mapped against the Z. mays cv. B73 (GCF_000005005.2) genome and the Azo and AzoYuc groups cDNA libraries were mapped against a Combined reference file formed by the merging of Z. mays cv. B73 and A. brasilense Sp7 (GCA_001315015.1) genomes. The mapping parameter used was 0.8 of minimum length fraction and 0.8 of minimum similarity fraction for inclusion as a mapped read. The mapped reads were extracted and counted using the respective annotated genome. The counting parameters used were: 0.8 of minimum length fraction and 0.8 of minimum similarity fraction; with a mismatch, insertion, and deletion costs of 2, 3, and 3, respectively, for inclusion as a mapped read, allowing a maximum of 10 hits, with the exclusion of the reads that mapped to intergenic regions (Espindula et al., 2019Espindula E, Sperb ER, Bach E and Passaglia LMP (2019) The combined analysis as the best strategy for Dual RNA-Seq mapping. Genet Mol Biol 42:e20190215. , with modifications).

Count files were analyzed with the DESeq2 v 3.8 (Love et al., 2014Love MI, Huber W and Anders S (2014) Moderated estimation of fold change and dispersion for RNA-seq data with DESeq2. Genome Biol 15:550. ) package of R software v 3.5.2 (R Development Core Team). Genes with p-values < 0.05 (Li et al., 2019Li Z, Xu M, Wei H, Wang L and Deng M (2019) RNA-seq analyses of antibiotic resistance mechanisms in Serratia marcescens. Mol Med Rep 20:745-754. ; Yoo et al., 2019Yoo Y-H, Kim M, Chandran AKN, Hong WJ, Ahn HR, Lee GT, Kang S, Suh D, Kim J, Kim YJ et al. (2019) Genome-wide transcriptome analysis of rice seedlings after seed dressing with Paenibacillus yonginensis DCY84 T and Silicon. Int J Mol Sci 20:5883. ) and log2fold-change [Lg2(FC)] ≥ |1.5| were considered as differentially expressed (Li et al., 2019Li Z, Xu M, Wei H, Wang L and Deng M (2019) RNA-seq analyses of antibiotic resistance mechanisms in Serratia marcescens. Mol Med Rep 20:745-754. , with modifications). Metabolic pathways were identified using the Kyoto Encyclopedia of Genes and Genomes (KEGG) database (https://www.genome.jp/kegg/). Annotations for the DEGs were made with the help of the MaizeMine, online version 1.3 (http://maizemine.rnet.missouri.edu:8080/maizemine/begin.do). Heatmaps were generated using the ComplexHeatmap (Gu et al., 2016Gu Z, Eils R and Schlesner M (2016) Complex heatmaps reveal patterns and correlations in multidimensional genomic data. Bioinformatics (Oxford, England) 32:2847-2849. ) package of R software v 3.5.2 (R Development Core Team).

Statistical analyses

For root and aerial parts length and number of lateral roots analysis, 10 biological repeats were used. Tukey test was used to detect differences among the means of the treatments for each physiological characteristic. For IAA quantification analysis, three biological repeats were used. Dunn’s test was used to detect differences among the means of the treatments.

For all statistical analyses, the package Agricolae was used on R software v 4.2.0 (R Development Core Team, https://www.r-project.org/).

Results

The presence of yucasin in the culture medium did not affect bacterial growth and indole compounds (ICs) production

To verify if the IAA inhibitor synthesis, yucasin, could interfere with the growth and ICs production of A. brasilense FP2, bacterial growth, and ICs production in the presence of this compound were analyzed. The results showed that the presence of yucasin in the King B medium affected neither ICs production (Figure 1A) nor A. brasilense FP2 growth (Figure 1B).

Quantification of the indole-3-acetic acid present in the plantlet’s roots

To determine the concentration of IAA present in the samples after the treatments, the endogenous auxin concentration in the plantlet’s roots was quantified by HPLC. The results showed that the IAA concentration in plantlets from the AzoYuc group was lower than those in plantlets from the Azo and Ctr groups, while the IAA concentration in the plantlets from the Yuc group was lower than the concentration presented in the plantlets from the Azo group (Figure 2).

The plant growth-promoting effect of Azospirillum was not affected by the presence of yucasin

To evaluate if the plant growth-promoting effect of Azospirillum brasilense could be affected by the presence of yucasin, maize seedlings were treated with yucasin 10 days after inoculation (DAI) with A. brasilense. The first measurement was made 5 hours after yucasin addition, and no significant result was observed for any parameter evaluated (Figure 3A). The next measurement was made 15 DAI, and some differences could be observed among the groups. Concerning the root lengths, although the average length of the roots of the Azo group was longer than those of the Ctr and Yuc groups, this difference was not significant. In its turn, plantlets from the AzoYuc group presented significantly longer roots than those from the Ctr and Yuc groups (Fig 3A). Concerning the length of the aerial part of plantlets (Figure 3B), the mean length from those of the AzoYuc group was statistically different from those of the Yuc group. We also evaluated the effect of the treatments on the number of lateral roots. At 15 DAI plantlets from the Yuc group presented a significantly lower number of lateral roots than plantlets from the other groups (Figure 3C). This result can also be observed in Figure 3D, in which plantlets from the Yuc group visually showed fewer lateral roots than plantlets from the other groups.

To confirm the presence of A. brasilense FP2 on maize’s root surface, scanning electron microscopy analysis was performed using samples from biological replicates of the Azo and AzoYuc groups from the first sampling time point (10 DAI). The bacterium was observed on the root surfaces of plants in both experimental groups (^{Figure S1} Figure S1 - Scanning electron microscopy of maize roots inoculated with A. brasilense strain FP2. ).

Transcriptome analysis

To investigate the gene expression pattern of maize and A. brasilense during their co-cultivation in the presence of the TAA/YUC pathway inhibitor, yucasin, biological samples of all experimental groups were used for RNA extraction. Total RNA was extracted from each biological replicate of each experimental group, generating 12 cDNA libraries. ^{Table S1} Table S1 - Library features and number of total reads attributed to Zea mays or the combined reference. shows a summary of library mapping for each experimental group.

Reads that mapped to the A. brasilense and Z. mays reference genomes were extracted from libraries of Azo and AzoYuc groups and reads counting was performed separately using the respective annotated genomes. Since Ctr and Yuc groups were not inoculated, reads that mapped to the Z. mays reference genome were extracted and counted using its annotated genome. All reads that aligned in the intergenic regions, tRNA, and rRNA sequences were eliminated, and only the reads that aligned to coding sequences (CDS) were further analyzed. As can be observed in Table 1, the majority of reads that mapped to the maize genome corresponded to multireads. According to Mortazavi et al. (2008Mortazavi A, Williams BA, McCue K, Schaeffer L and Wold B (2008) Mapping and quantifying mammalian transcriptomes by RNA-Seq. Nat Methods 5:621-628. ), multireads are reads that align equally well to several sites in the genome and are attributed to members of multigene families, duplicated genes, or segmental duplications. Since these reads aligned to CDS, and not to rRNA or tRNA, we concluded that the presence of multireads must be because Z. mays is an allopolyploid plant (Messing, 2009Messing J (2009) The polyploid origin of maize. In: Bennetzen JL and Hake S (eds) Handbook of maize: Genetics and genomics. Springer, New York, pp 221-238.), presenting several copies of many genes. Thus, these reads were used for further analyses since much of the transcriptional information could be lost if they were discarded (Mortazavi et al., 2008Mortazavi A, Williams BA, McCue K, Schaeffer L and Wold B (2008) Mapping and quantifying mammalian transcriptomes by RNA-Seq. Nat Methods 5:621-628. ). On the other hand, the majority of reads that mapped to the A. brasilense genome corresponded to unique mapped reads. This result was expected since prokaryote genomes are mostly formed by single-copy genes, except for rRNA and tRNA genes.

In maize, at least 650 differentially expressed genes (DEGs) were identified in pairwise comparisons between the experimental conditions (^{Table S2} Table S2 - Maize differentially expressed genes (DEGs) in all experimental conditions. ). The comparison between the transcriptional patterns from the Yuc and Azo groups with that of the Ctr group showed that several DEGs were down-regulated. For the other comparisons, the majority of the DEGs were up-regulated (Figure 4A and ^{Table S2} Table S2 - Maize differentially expressed genes (DEGs) in all experimental conditions. bottom).

Among all the comparisons analyzed, we identified a total of 763 uncharacterized loci being differentially expressed in at least one comparison (Figure 4B and ^{Table S3} Table S3 - Maize uncharacterized DEGs in all experimental conditions. ). Depending on the experimental condition, at least 83 loci presented a high difference in relative expression level [Log2(FC)> | 3 |] (^{Table S3} Table S3 - Maize uncharacterized DEGs in all experimental conditions. bottom). Most of them were down-regulated when comparing data from the Yuc and Azo groups with data from the Ctr group. On the other hand, when comparing data from the AzoYuc group with data from the other groups most of the uncharacterized differentially expressed genes were up-regulated (^{Table S3} Table S3 - Maize uncharacterized DEGs in all experimental conditions. bottom).

When analyzing our data, we noticed that some genes related to the maize auxin response pathway and auxin efflux transport were differentially expressed in response to the presence of A. brasilense and yucasin (Tables 2 and ^S2 Table S2 - Maize differentially expressed genes (DEGs) in all experimental conditions. ). Some of them are highlighted below.

When comparing data from the AzoYuc group with the Ctr one, Zmpin1c (GeneID: 103654258) was up-regulated [Log2(FC) 1.8]; and Zmpin1c and Zmpin1d (GeneID: 100285745) were up-regulated when comparing AzoYuc with Yuc [(Log2(FC) 1.56 and 3.16, respectively].

When comparing data from the Yuc group with data from the Ctr group, Zmarf4 (GeneID 100383226) gene was up-regulated [log2(FC) 2.85] and Zmarf16 (GeneID 103654892), and Zmarf19 (GeneID 100280136) genes were down-regulated [Log2(FC) -1.88 and -1.58, respectively, Tables 2 and ^S2 Table S2 - Maize differentially expressed genes (DEGs) in all experimental conditions. ]. In its turn, when comparing data from the AzoYuc group with the negative control (Ctr), Zmarf1 and Zmarf22 (GeneIDs 103642400 and 103629639, respectively) were up-regulated [Log2(FC) 1.55 and 1.75, respectively, Tables 2 and ^S2 Table S2 - Maize differentially expressed genes (DEGs) in all experimental conditions. ]. Comparing data from the AzoYuc group with the Yuc group, Zmarf25 (GeneID: 100273501) was down-regulated [Log2(FC) -1.63, Tables 2 and ^S2 Table S2 - Maize differentially expressed genes (DEGs) in all experimental conditions. ]. Zmarf7 and Zmarf18 (GeneID: 100857063 and 100502480, respectively) were up-regulated [Log2(FC) 1.51 for both, Tables 2 and ^S2 Table S2 - Maize differentially expressed genes (DEGs) in all experimental conditions. ] when comparing data from the AzoYuc group with the Azo group. Finally, Zmarf24 (GeneID: 103630727) was differentially expressed in two comparisons (Azo and AzoYuc groups with the Ctr group), being repressed in both [Lg2(FC) - 1.78 and -1.53, respectively, Tables 2 and ^S2 Table S2 - Maize differentially expressed genes (DEGs) in all experimental conditions. ].

Three Aux/IAA genes were observed being differently expressed, Zmiaa7 (GeneID: 100274580), Zmiaa10/rum1 (GeneID: 100284457), and Zmiaa27/bif1 (GeneID: 100194253). When comparing data from the AzoYuc group with Ctr, Zmiaa7 was up-regulated [Log2(FC) 1.93, Tables 2 and S2]. In two comparisons (AzoYuc group with Yuc and Azo ones), rum1 was up-regulated [Log2(FC) ≥ 2 in both, Tables 2 and ^S2 Table S2 - Maize differentially expressed genes (DEGs) in all experimental conditions. ]. Finally, Zmiaa27/bif1 was up-regulated when comparing data from the Azo group with the Ctr [Log2(FC) 3.14, Tables 2 and S2], but it was down-regulated when comparing data from the AzoYuc group with the Azo group [Log2(FC) -2.22, Tables 2 and ^S2 Table S2 - Maize differentially expressed genes (DEGs) in all experimental conditions. ].

Another gene that was strongly up-regulated [Log2(FC): 4.84, Tables 2 and ^S2 Table S2 - Maize differentially expressed genes (DEGs) in all experimental conditions. ] when comparing data from the Azo group with the Ctr group was Zmsaur41 (GeneID: 103653849); and Zmgh3.10 (GeneID: 100193303) was up-regulated when comparing data from the AzoYuc group with Ctr, Yuc and Azo ones [Log2(FC) 2.27, 2.05, and 1.59, respectively, Tables 2 and ^S2 Table S2 - Maize differentially expressed genes (DEGs) in all experimental conditions. ].

Genes involved in the cell division control were also observed to be differentially expressed (Tables 2 and ^S2 Table S2 - Maize differentially expressed genes (DEGs) in all experimental conditions. ). When comparing transcription data from the group that was inoculated with A. brasilense (Azo group) with data from the control group (Ctr group), we noticed that the gene cyclin 1 (cyc1, GeneID: 542307), was up-regulated [Log2(FC) 2.19, Tables 2 and ^S2 Table S2 - Maize differentially expressed genes (DEGs) in all experimental conditions. ]. However, when comparing data from the AzoYuc group with data from the Azo group this gene was down-regulated [Log2(FC) -2.42, Tables 2 and ^S2 Table S2 - Maize differentially expressed genes (DEGs) in all experimental conditions. ]. When comparing data from the AzoYuc group with the Yuc and Azo, another gene, Zmick4 (inhibitor of cyclin-dependent kinase 4, GeneID: 100193847) that codes for a protein involved in the cellular cycle regulation was differentially expressed. This gene was strongly up-regulated when comparing data from the AzoYuc group with the Yuc and Azo ones [Log2(FC) 3.16 and 2.77, respectively, Tables 2 and S2]. Another gene observed being differentially expressed was Zmdel1c (GeneID: 103627702). It was up-regulated when comparing data from the AzoYuc group with the Ctr, Yuc, and Azo groups [Log2(FC) 2.9, 2.77, and 3.19, respectively, Tables 2 and ^S2 Table S2 - Maize differentially expressed genes (DEGs) in all experimental conditions. ].

Genes involved in the abscisic acid (ABA) response pathway (Zmpyl7, Zmpp2c3, Zmpp2c4, and Zmpp2c14) were differentially regulated (Tables 2 and ^S2 Table S2 - Maize differentially expressed genes (DEGs) in all experimental conditions. ). Zmpyl7 was up-regulated when comparing data from the Yuc group with Ctr, and from the AzoYuc group with Ctr and Azo groups [log2(FC) 2.19, 2.38, and 3.39, respectively]. In its turn, the genes that code for the PP2Cs presented an interesting expression pattern. When comparing data from the Azo group with Ctr, Zmpp2c3, -c4, and -c14 were all up-regulated [log2(FC) 1.62, 2.33, and 2.11, respectively]. On the other hand, when comparing data from the AzoYuc group with Azo, those three genes became down-regulated [log2(FC) -1.73, -1.71, and -2.13, respectively].

Azospirillum brasilense promoted plant growth in the presence of yucasin by partially altering the maize transcriptional profile

Looking for an explanation of how A. brasilense could prevent the physiological effects of yucasin and promote plant growth in the presence of this inhibitor, we gave a close look into the set of genes that changed their expression pattern in the following comparisons: Yuc group vs Ctr, and AzoYuc group vs Yuc (Figure 4C and ^S2 Table S2 - Maize differentially expressed genes (DEGs) in all experimental conditions. , and ^{Table S4} Table S4 - Maize DEGs that changed their pattern of expression when comparing two experimental conditions (Yuc x Ctr and AzoYuc x Yuc). ). The comparison between data from Yuc and Ctr groups formed the control gene set, and the comparison between data from AzoYuc and Yuc groups function as the treatment set. Since the treatment with A. brasilense was only present in the AzoYuc group when we compare these two sets of comparisons, the observed change in the gene expression is probably due to the presence of the bacterium. In this scenario, 130 genes were differentially expressed: 48 genes changed their expression from being down- to up-regulated, and the other 82 changed from being up- to down-regulated (Figure 4C and ^S2 Table S2 - Maize differentially expressed genes (DEGs) in all experimental conditions. , and ^{Table S4} Table S4 - Maize DEGs that changed their pattern of expression when comparing two experimental conditions (Yuc x Ctr and AzoYuc x Yuc). ). Among these 130 genes, 42 were uncharacterized ones. Of these, 14 changed from being down- to up-regulated, and the remaining 28 changed from being up- to down-regulated (^{Table S4} Table S4 - Maize DEGs that changed their pattern of expression when comparing two experimental conditions (Yuc x Ctr and AzoYuc x Yuc). ). Looking into the genes that have annotations, were highlighted genes involved in the ABA biosynthesis pathway, in the response to biotic/abiotic stress, plant disease resistance (R) system, and a D-type cellulose synthase.

One gene involved in the Abscisic acid (ABA) biosynthesis pathway was identified in our samples, a member of the short-chain dehydrogenase/reductase family, Zmaba2 (aka short-chain alcohol dehydrogenase1 - sca1, GeneID: 100282128). In our data, Zmaba2 was up-regulated [Log2(FC) 1.87, Tables 2, ^S2 Table S2 - Maize differentially expressed genes (DEGs) in all experimental conditions. , and S4] in the presence of yucasin (Yuc group vs. Ctr), and down-regulated [Log2(FC) - 1.28, Tables 2 and ^S2 Table S2 - Maize differentially expressed genes (DEGs) in all experimental conditions. ] in the presence of the bacterium (AzoYuc group vs Yuc). Although this gene was below the established threshold for Log2(FC) in the second comparison, it presented a valid p-value (0.022, ^{Table S2} Table S2 - Maize differentially expressed genes (DEGs) in all experimental conditions. ). Since it is an important gene in the ABA synthesis pathway, we decided to include it in our analysis.

Concerning the genes involved in the response to biotic/abiotic stress, genes coding for mitogen-activated protein kinase 5 (Zmmpk5, GeneID 541618) and mitogen-activated protein kinase kinase 5 (Zmmkk5, GeneID 109946070) were identified. The expression analysis showed that the presence of the bacterium modified their expression pattern from being up-regulated [Log2(FC) 1.95 and 3.51, respectively] to down-regulated [(Log2(FC) - 2.37 and - 2.37, respectively] (^{Figure S2} Figure S2 - Genes that switched the expression pattern when analyzing two experimental comparisons (Yuc x Ctr and AzoYuc x Yuc). and ^{Table S4} Table S4 - Maize DEGs that changed their pattern of expression when comparing two experimental conditions (Yuc x Ctr and AzoYuc x Yuc). ).

Two genes that code for endoplasmic reticulum transmembrane proteins belonging to TLC (TRAM/LAG/CRN8) family were affected by the treatment with yucasin and the inoculation with A. brasilense (Zmtlc9 and -17). Zmtlc9 (GeneID 100274425) presented remarkable expression variation in the compared conditions, being strongly repressed [Log2(FC) - 17] by yucasin (Yuc group vs Ctr) while the inoculation with A. brasilense completely rescued its expression [Log2(FC) 20 in AzoYuc vs Yuc comparison]. On the other hand, Zmtlc17 (GeneID 100277080) was up-regulated in the presence of yucasin [Log2(FC) 4.64] but down-regulated when A. brasilense was added [Log2(FC) - 3.14].

Another gene with an opposite expression pattern was the roothairless 6 (rth6, GeneID 103637736). In our experiment, rth6 was down-regulated [Log2(FC) - 1.74] when the plantlets were treated with yucasin (Yuc group vs Ctr), while its expression was up-regulated [Log2(FC) 2.28] when comparing data from the AzoYuc group with Yuc group. Another interesting finding was revealed by comparing data from the AzoYuc group with Azo. In this comparison, this gene was also up-regulated (Log2(FC) 1.67, Tables 2, ^S2 Table S2 - Maize differentially expressed genes (DEGs) in all experimental conditions. , and ^S4 Table S4 - Maize DEGs that changed their pattern of expression when comparing two experimental conditions (Yuc x Ctr and AzoYuc x Yuc). , and ^{Figure S2} Figure S2 - Genes that switched the expression pattern when analyzing two experimental comparisons (Yuc x Ctr and AzoYuc x Yuc). ).

A. brasilense genes expressed in maize roots

Although rRNA was the most abundant transcript presented in our samples (Table 1), we still were able to detect three genes of A. brasilense being differentially expressed when comparing data from the AzoYuc group with Azo (^{Table S5} Table S5 - Azospirillum brasilense DEGs in the experimental condition evaluated. ). They are the oxIT, which codes for an oxalate/formate antiporter, 4-(cytidine 5’-diphosphosphate)-2-C-methyl-D-erythritol kinase, and the PrKA family serine protein kinase coding genes. All three were highly up-regulated in our analysis [Log2(FC) > 4, ^{Table S5} Table S5 - Azospirillum brasilense DEGs in the experimental condition evaluated. ]. The identified genes are part of general metabolic pathways and their presence indicated that the bacteria were metabolically active.

Discussion

Azospirillum brasilense plant-growth promotion prevented yucasin physiological effect on the maize plantlets

It is well known that bacteria belonging to the genus Azospirillum, specifically A. brasilense, can produce phytohormones and other substances during plant-bacterium interaction (Cassán et al., 2014Cassán F, Vanderleyden J and Spaepen S (2014) Physiological and agronomical aspects of phytohormone production by model Plant-Growth-Promoting Rhizobacteria (PGPR) belonging to the genus Azospirillum. J Plant Growth Regul 33:440-459. , 2020Cassán F, Coniglio A, López G, Molina R, Nievas S, de Carlan CLN, Donadio F, Torres D, Rosas S, Pedrosa FO et al. (2020) Everything you must know about Azospirillum and its impact on agriculture and beyond. Biol Fert Soils 56:461-479. ). Among them are the auxins, especially the indole-3-acetic acid, IAA (Cassán et al., 2014Cassán F, Vanderleyden J and Spaepen S (2014) Physiological and agronomical aspects of phytohormone production by model Plant-Growth-Promoting Rhizobacteria (PGPR) belonging to the genus Azospirillum. J Plant Growth Regul 33:440-459. , 2020Cassán F, Coniglio A, López G, Molina R, Nievas S, de Carlan CLN, Donadio F, Torres D, Rosas S, Pedrosa FO et al. (2020) Everything you must know about Azospirillum and its impact on agriculture and beyond. Biol Fert Soils 56:461-479. ). However, according to Cassán et al. (2020Cassán F, Coniglio A, López G, Molina R, Nievas S, de Carlan CLN, Donadio F, Torres D, Rosas S, Pedrosa FO et al. (2020) Everything you must know about Azospirillum and its impact on agriculture and beyond. Biol Fert Soils 56:461-479. ), there is evidence that plant growth promoted by Azospirillum sp can be both IAA-dependent and IAA-independent. In plants, IAA is involved in plant development (Casanova-Sáez and Voß, 2019Casanova-Sáez R and Voß U (2019) Auxin metabolism controls developmental decisions in land plants. Trends Plant Sci 24:741-754. ), and as already mentioned, yucasin can inhibit its production in plants (Nishimura et al., 2014Nishimura T, Hayashi K, Suzuki H, Gyohda A, Takaoka C, Sakaguchi Y, Matsumoto S, Kasahara H, Sakai T, Kato J et al. (2014) Yucasin is a potent inhibitor of YUCCA, a key enzyme in auxin biosynthesis. Plant J 77:352-366. ). The results observed for root and aerial lengths suggest that yucasin did not interfere in the plant-microbe interaction, because plantlets from the AzoYuc presented longer lengths than those of the Yuc group and no difference was observed when comparing plantlets from the AzoYuc group with those from the Azo one. On the other hand, the presence of yucasin inhibited the formation of lateral roots in maize plantlets (Yuc group), and previous inoculation with A. brasilense was able to prevent the yucasin effect on this plant phenotype. These results, combined with the fact that the plantlets from the AzoYuc and Yuc groups presented lower IAA concentrations than those of the Azo group but no difference among them (Figure 2), suggest that A. brasilense was able to prevent the phenotypic effects of yucasin using an IAA-independent plant growth promotion pathway.

Transcriptome analysis

Eukaryotic mitogen-activated protein kinase (MAPK) cascades transduce of environmental and developmental signals in intracellular responses (Rodriguez et al., 2010Rodriguez MCS, Petersen M and Mundy J (2010) Mitogen-Activated Protein Kinase Signaling in Plants. Annu Rev Plant Biol 61:621-649. ). In a general model, MAPK kinase kinase (MAP3Ks; also called MAPKKKs or MEKKs) or MAPK kinase kinase kinase (MAP4Ks) are activated by stimulated plasma membrane receptors, and then, through sequential phosphorylation, activate downstream MAP kinase kinase (MAP2K, also called MKKs or MEKs), which in turn activates MAPKs. Specifically, MAP3Ks (or MAPKKKs) are serine or threonine kinases that phosphorylate MAP2Ks at a conserved S/T-X_3−5-S/T motif, and MAP2Ks phosphorylate MAPKs on threonine and tyrosine residues at a conserved T-X-Y motif (Rodriguez et al., 2010Rodriguez MCS, Petersen M and Mundy J (2010) Mitogen-Activated Protein Kinase Signaling in Plants. Annu Rev Plant Biol 61:621-649. ; Kong et al., 2013Kong X, Pan J, Zhang D, Jiang S, Cai G, Wang L and Li D (2013) Identification of mitogen-activated protein kinase kinase gene family and MKK-MAPK interaction network in maize. Biochem Bioph Res Co 441:964-969. ; Sun et al., 2015Sun W, Chen H, Wang J, Sun HW, Yang SK, Sang YL, Lu XB and Xu XH (2015) Expression analysis of genes encoding mitogen-activated protein kinases in maize provides a key link between abiotic stress signaling and plant reproduction. Funct Integr Genomic 15:107-120. ). The active MAPKs interact with various effector proteins in the cytoplasm and nucleus, which include other kinases, enzymes, or transcription factors (Rodriguez et al., 2010Rodriguez MCS, Petersen M and Mundy J (2010) Mitogen-Activated Protein Kinase Signaling in Plants. Annu Rev Plant Biol 61:621-649. ; Kong et al., 2013Kong X, Pan J, Zhang D, Jiang S, Cai G, Wang L and Li D (2013) Identification of mitogen-activated protein kinase kinase gene family and MKK-MAPK interaction network in maize. Biochem Bioph Res Co 441:964-969. ; Sun et al., 2015Sun W, Chen H, Wang J, Sun HW, Yang SK, Sang YL, Lu XB and Xu XH (2015) Expression analysis of genes encoding mitogen-activated protein kinases in maize provides a key link between abiotic stress signaling and plant reproduction. Funct Integr Genomic 15:107-120. ). According to KEGG, ZmMPK5 and ZmMKK5 [whose respective genes have changed their pattern of expression due to the presence of the bacterium, from being up-regulated (Yuc vs. Ctr) to down-regulated (AzoYuc vs. Yuc)] participate in the cascade that perceives the apoplastic H₂O₂, leading to its higher production and cell death. They also participate in the cascade that triggers the early and late defense response against pathogens. Besides that, ZmMPK5 is also indicated as part of the defense responses mediated by ethylene and in the ethylene synthesis in response to reactive oxygen species (ROS). Ma et al. (2016Ma F, Ni L, Liu L, Li X, Zhang H, Zhang A, Tan M and Jiang M (2016) ZmABA2, an interacting protein of ZmMPK5, is involved in abscisic acid biosynthesis and functions. Plant Biotechnol J 14:771-782. ) identified a member of the short-chain dehydrogenase/reductase family, Zmaba2 (aka short-chain alcohol dehydrogenase1 - sca1, GeneID: 100282128), as a target of ZmMPK5. According to these authors and KEGG (https://www.genome.jp/kegg-bin/show_pathway?zma00906+100282128), the Zmaba2 product participates in the ABA synthesis pathway and is responsible for the conversion of xanthoxin into an abscisic aldehyde. In our data, Zmaba2 was up-regulated in the presence of yucasin (Yuc vs. Ctr), and down-regulated in the presence of the bacterium (AzoYuc vs Yuc). According to Ma et al. (2016Ma F, Ni L, Liu L, Li X, Zhang H, Zhang A, Tan M and Jiang M (2016) ZmABA2, an interacting protein of ZmMPK5, is involved in abscisic acid biosynthesis and functions. Plant Biotechnol J 14:771-782. ), ZmABA2 is phosphorylated by ZmMPK5 at its S173 position, which increases ZmABA2 stability and ABA production. Since the overexpression of both genes or the overexpression of Zmaba2 in the presence of PEG or NaCl leads to increased levels of ABA (Ma et al., 2016Ma F, Ni L, Liu L, Li X, Zhang H, Zhang A, Tan M and Jiang M (2016) ZmABA2, an interacting protein of ZmMPK5, is involved in abscisic acid biosynthesis and functions. Plant Biotechnol J 14:771-782. ), the up-regulation of Zmmpk5 and Zmaba2 probably led to increased levels of this hormone in response to the presence of yucasin. On the other hand, Zmmpk5 and Zmaba2 down-regulation in the presence of the bacterium (AzoYuc vs. Yuc) probably reduced these levels.

TLC genes are part of the plant disease resistance (R) system and confer resistance to pathogenic toxins. They codify endoplasmic reticula (ER)-resident transmembrane (TM) proteins that act as synthases and activate the synthesis of ceramide-like moieties and/or sphingolipids (Si et al., 2019Si W, Hang T, Guo M, Chen Z , Liang Q, Gu L and Ding T (2019) Whole-Genome and transposed duplication contribute to the expansion and diversification of TLC genes in maize. Int J Mol Sci 20:5484. ). According to Si et al. (2019Si W, Hang T, Guo M, Chen Z , Liang Q, Gu L and Ding T (2019) Whole-Genome and transposed duplication contribute to the expansion and diversification of TLC genes in maize. Int J Mol Sci 20:5484. ), sphingolipid synthesis, including ceramide synthesis, plays an important role in biotic and abiotic stress responses, triggering programmed cell death in plants. According to these authors, Zmtlc9 and -17 presented low expression levels in roots and were up-regulated when the plantlets were treated with the mycotoxin Fumonisin B1 or the pathogenic fungus Curvularia lunata. In our observations, Zmtlc9 was strongly down-regulated in the presence of yucasin (Yuc vs. Ctr.) and strongly up-regulated when the bacterium was in the treatment (AzoYuc vs. Yuc). On the other hand, Zmtlc17 was up-regulated in the first comparison and down-regulated in the second one (^{Figure S2} Figure S2 - Genes that switched the expression pattern when analyzing two experimental comparisons (Yuc x Ctr and AzoYuc x Yuc). , Tables 2 and ^S4 Table S4 - Maize DEGs that changed their pattern of expression when comparing two experimental conditions (Yuc x Ctr and AzoYuc x Yuc). ).

According to Kazan and Manners (2009Kazan KM and Manners JM (2009) Linking development to defense: Auxin in plant-pathogen interactions. Trends Plant Sci 14:373-382. ), auxin participates in the plant defense response. It happens in a direct way or by interaction with other hormone signaling pathways (Bari and Jones, 2009Bari R and Jones JDG (2009) Role of plant hormones in plant defense responses. Plant Mol Biol 69:473-488. ; Kazan and Manners, 2009Kazan KM and Manners JM (2009) Linking development to defense: Auxin in plant-pathogen interactions. Trends Plant Sci 14:373-382. ). Auxin production or effects are stimulated or repressed during pathogen infection (Bari and Jones, 2009Bari R and Jones JDG (2009) Role of plant hormones in plant defense responses. Plant Mol Biol 69:473-488. ; Kazan and Manners, 2009Kazan KM and Manners JM (2009) Linking development to defense: Auxin in plant-pathogen interactions. Trends Plant Sci 14:373-382. ), and low levels of this hormone are needed to trigger biotrophic resistance, which may occur due to the production of compounds involved in the plant defense from tryptophan using part of the auxin synthesis pathway (Kazan and Manners, 2009Kazan KM and Manners JM (2009) Linking development to defense: Auxin in plant-pathogen interactions. Trends Plant Sci 14:373-382. ). Taking all these together alongside our observations, we can suggest that the presence of yucasin was responsible for the up-regulation observed for the genes Zmmkk5, Zmmpk5, Zmaba2, and Zmtlc17, and the down-regulation of Zmtlc19. Since IAA concentration in the AzoYuc group was no different from the Yuc group, we can also suggest that A. brasilense, through an IAA-independent pathway, was responsible for the change in the expression pattern of these genes (^{Figure S2} Figure S2 - Genes that switched the expression pattern when analyzing two experimental comparisons (Yuc x Ctr and AzoYuc x Yuc). , Tables 2 and ^S4 Table S4 - Maize DEGs that changed their pattern of expression when comparing two experimental conditions (Yuc x Ctr and AzoYuc x Yuc). ).

According to Li et al. (2016Li L, Hey S, Liu S, Liu Q, McNinch C, Hu HC, Wen TJ, Marcon C, Paschold A, Bruce W et al. (2016) Characterization of maize roothairless6 which encodes a D-type cellulose synthase and controls the switch from bulge formation to tip growth. Sci Rep - UK 6:34395. ), the gene rth6 is involved in root hair formation. This gene encodes the plasma membrane protein CSLD5 (Cellulose Synthase-like D), a D-type cellulose synthase (Li et al., 2016Li L, Hey S, Liu S, Liu Q, McNinch C, Hu HC, Wen TJ, Marcon C, Paschold A, Bruce W et al. (2016) Characterization of maize roothairless6 which encodes a D-type cellulose synthase and controls the switch from bulge formation to tip growth. Sci Rep - UK 6:34395. ). According to Li et al. (2016Li L, Hey S, Liu S, Liu Q, McNinch C, Hu HC, Wen TJ, Marcon C, Paschold A, Bruce W et al. (2016) Characterization of maize roothairless6 which encodes a D-type cellulose synthase and controls the switch from bulge formation to tip growth. Sci Rep - UK 6:34395. ), this transmembrane protein is responsible for the synthesis of cellulose in the plasma membrane which is extruded in the inner side of the cell wall in the maize root hair tips. These authors observed that maize mutants for this gene showed a reduced number of root hairs and did not express it in their roots. Based on this and this gene expression profile alongside the IAA concentrations observed in our experiment (Figure 2), we can hypothesize that yucasin caused this gene repression (Yuc vs. Ctr), and the bacterium (AzoYuc vs. Yuc), through an IAA-independent pathway, recovered its expression (^{Figure S2} Figure S2 - Genes that switched the expression pattern when analyzing two experimental comparisons (Yuc x Ctr and AzoYuc x Yuc). , Table 2, ^S2 Table S2 - Maize differentially expressed genes (DEGs) in all experimental conditions. and ^S4 Table S4 - Maize DEGs that changed their pattern of expression when comparing two experimental conditions (Yuc x Ctr and AzoYuc x Yuc). ).

In this scenario, a total of 129 genes were differentially expressed: 48 genes changed their expression from being down- to up-regulated, and the other 81 changed from being up- to down-regulated (Figure S2 and Table S4 bottom). When comparing the data from AzoYuc with the data from the Yuc group we observed that the former presented a higher number of lateral roots, and longer lengths (root and aerial parts) than the second one (Figure 3). All these together with the fact that there was no difference in IAA concentration in both comparisons allow us to assume that the bacterium caused these changes in gene expression through an IAA-independent pathway. We also conclude that these gene expressions are somehow involved in the physiological effect observed when comparing the AzoYuc group with Yuc one.

Conclusion

Gene expression analyses showed genes involved in the IAA response pathway, IAA efflux transport, and cell division control, responding to the bacterium, yucasin, the decrease in IAA concentration, or altogether. Several genes changed their expression pattern in response to bacterial inoculation. Some of them were identified as genes that code for proteins involved in the ABA biosynthesis pathway, response to biotic/abiotic stress, plant disease resistance (R) system, and D-type cellulose synthase. Our results suggest that yucasin itself was enough to trigger the expression of some genes involved in the biotic/abiotic responses, and A. brasilense reverted it probably through an IAA-independent pathway. The opposite change was observed for genes involved in plant disease resistance and the D-type cellulose synthase, indicating that A. brasilense stimulated their expression.

All these results lead us to suggest that A. brasilense interferes with the expression of many maize’s genes through an IAA-independent pathway. The results also showed that the bacterial plant growth effect somehow involves the repression of some genes involved in biotic/abiotic stress and stimulating/repressing genes involved in cell division regulation. Since this is an exploratory study to bring some light on the plant-bacteria relationship, more specific studies are required to better understand how Azospirillum interferes with these genes’ expression and which phytohormones and substances other than IAA are involved in plant growth promotion.

Acknowledgments

This work was supported by the Brazilian funding agencies Conselho Nacional de Desenvolvimento Científico e Tecnológico (CNPq), Coordenação de Aperfeiçoamento de Pessoal de Nível Superior (Capes), and by Newton Fund (Brazil-UK collaboration).

References

Supplementary material

The following online material is available for this article:

Figure S1 - Scanning electron microscopy of maize roots inoculated with A. brasilense strain FP2.

Figure S2 - Genes that switched the expression pattern when analyzing two experimental comparisons (Yuc x Ctr and AzoYuc x Yuc).

Table S1 - Library features and number of total reads attributed to Zea mays or the combined reference.

Table S2 - Maize differentially expressed genes (DEGs) in all experimental conditions.

Table S3 - Maize uncharacterized DEGs in all experimental conditions.

Table S4 - Maize DEGs that changed their pattern of expression when comparing two experimental conditions (Yuc x Ctr and AzoYuc x Yuc).

Table S5 - Azospirillum brasilense DEGs in the experimental condition evaluated.

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