Petroleum contamination and bioaugmentation in bacterial rhizosphere communities from Avicennia schaueriana

Simone Dealtry Angela Michelato Ghizelini Leda C.S. Mendonça-Hagler Ricardo Moreira Chaloub Fernanda Reinert Tácio M.P. de Campos Newton C.M. Gomes Kornelia Smalla About the authors

ABSTRACT

Anthropogenic activity, such as accidental oil spills, are typical sources of urban mangrove pollution that may affect mangrove bacterial communities as well as their mobile genetic elements. To evaluate remediation strategies, we followed over the time the effects of a petroleum hydrocarbon degrading consortium inoculated on mangrove tree Avicennia schaueriana against artificial petroleum contamination in a phytoremediation greenhouse experiment. Interestingly, despite plant protection due to the inoculation, denaturing gradient gel electrophoresis of the bacterial 16S rRNA gene fragments amplified from the total community DNA indicated that the different treatments did not significantly affect the bacterial community composition. However, while the bacterial community was rather stable, pronounced shifts were observed in the abundance of bacteria carrying plasmids. A PCR-Southern blot hybridization analysis indicated an increase in the abundance of IncP-9 catabolic plasmids. Denaturing gradient gel electrophoresis of naphthalene dioxygenase (ndo) genes amplified from cDNA (RNA) indicated the dominance of a specific ndo gene in the inoculated petroleum amendment treatment. The petroleum hydrocarbon degrading consortium characterization indicated the prevalence of bacteria assigned to Pseudomonas spp., Comamonas spp. and Ochrobactrum spp. IncP-9 plasmids were detected for the first time in Comamonas sp. and Ochrobactrum spp., which is a novelty of this study.

Keywords:
Phytoremediation; Mangrove; IncP-9 plasmids; ndo genes

Introduction

Mangroves are tropical and subtropical region coastal ecosystems located in transitional zones between terrestrial environments and sea and rivers.11 Schaeffer-Novelli Y, Cintrón-Molero G, Soares MLG, De-Rosa T. Brazilian mangroves. Aquat Ecosyst Health Manag. 2000;3(4):561-570. Several studies have demonstrated the role of the mangrove archaeal,22 Pires ACC, Cleary DFR, Almeida A, et al. Denaturing gradient gel electrophoresis and barcoded pyrosequencing reveal unprecedented Archaeal diversity in mangrove sediment and rhizosphere samples. Appl Environ Microbiol. 2012;78(16):5520-5528. bacterial33 Andreote FD, Jiménez DJ, Chaves D, et al. The microbiome of Brazilian mangrove sediments as revealed by metagenomics. PLoS ONE. 2012;7(6):e38600. and fungi44 Arfi Y, Buée M, Marchand C, Levasseur A, Record E. Multiple markers pyrosequencing reveals highly diverse and host-specific fungal communities on the mangrove trees Avicennia marina and Rhizophora stylosa. FEMS Microbiol Ecol. 2012;79:433-444. communities in important biogeochemical cycles. Moreover, mangroves ecosystems have a particular and great microbial diversity. Different microorganisms inhabiting mangroves provide support for mangrove trees to survive under extreme conditions, likely by producing enzymes which are also of considerable industrial interest.55 Soares L, Marcon J, C M De, et al. A novel multifunctional β-N-acetylhexosaminidase revealed through metagenomics of an oil-spilled mangrove. Bioengineering. 2017;4(62), http://dx.doi.org/10.3390/bioengineering4030062.
http://dx.doi.org/10.3390/bioengineering...
1010 Soares Júnior FL, Dias Franco AC, Fasanella CC, et al. Endo- and exoglucanase activities in bacteria from mangrove sediment. Braz J Microbiol. 2013;44(3):969-976.

In view of the current severe mangrove degradation, mainly due to the anthropogenic activity impacts, the present study is focusing on a pilot scale study for recovering these ecosystems through the adoption of bioaugmentation by using natural polycyclic aromatic hydrocarbon (PAH) degrading bacteria from the rhizosphere of mangrove plants, which might be a promising strategy to be applied in oil-polluted mangroves.1111 Valiela I, Bowen JL, York JK. Mangrove forests: one of the world's threatened major tropical environments. Bioscience. 2001;51(10):807.1515 Angelim AL, Costa SP, Farias BCS, Aquino LF, Melo VMM. An innovative bioremediation strategy using a bacterial consortium entrapped in chitosan beads. J Environ Manage. 2013;127:10-17.

The mangrove studied herein is located at Guanabara Bay, Rio de Janeiro, Brazil, near the Duque de Caxias Oil Refinery (REDUC), which has a long history of oil spill accidents and an intense raw sewage discharge into the bay.1616 Meniconi MFG, Barbanti SM. Case study: evaluation of hydrocarbon sources in Guanabara Bay, Brazil. In: Wang Z, Stout S, eds. Oil Spill Environmental Forensics, Fingerprinting and Source Identification. Amsterdam: Academic Press; 2007:505–537.,1717 Júnior JTA, Campos TMP, Pires PJM. Sediment characteristics of an impacted coastal bay: Baía de Guanabara, Rio de Janeiro, Brazil. J Coast Res. 2014;71:41-47. Therefore, such pollution makes the surrounding mangrove a hotspot for microbe-assisted degradation of petroleum components, such as polycyclic aromatic hydrocarbons (PAHs).1818 Gomes NCM, Borges LR, Paranhos R, et al. Diversity of ndo genes in mangrove sediments exposed to different sources of polycyclic aromatic hydrocarbon pollution. Appl Environ Microbiol. 2007;73(22):7392-7399. Herein we target PAHs because they are well known to form a group of priority organic pollutants, due to the risk to the human health, high toxicity and persistence in the environment.1919. Polynuclear aromatic compounds, Part 1, Chemical, environmental and experimental data. IARC Monogr Eval Carcinog Risk Chem Hum. 1983;32:1-453.

Many studies have demonstrated that mobile genetic elements (MGEs), such as plasmids, play an important role in bacterial adaptation to oil biodegradation within a bacterial population, by promoting the assembly and spread of PAH catabolic gene clusters within the community.2020 Dealtry S, Ding GC, Weichelt V, et al. Cultivation-independent screening revealed hot spots of IncP-1, IncP-7 and IncP-9 plasmid occurrence in different environmental habitats. PLOS ONE. 2014;9(2):e89922. Among the known catabolic plasmids involved in PAH compound degradation, the narrow host range IncP-9 plasmids, which belongs to the incompatibility (Inc) plasmids group2121 Couturier M, Bex F, Bergquist PL, Maas WK. Identification and classification of bacterial plasmids. Microbiol Rev. 1988;52(3):375-395. are of particular importance, as they often carry PAH degrading genes, such as the naphthalene dioxygenase (ndo) genes clusters.2222 Sota M, Yano H, Ono A, et al. Genomic and functional analysis of the IncP-9 naphthalene-catabolic plasmid NAH7 and its transposon Tn4655 suggests catabolic gene spread by a tyrosine recombinase. J Bacteriol. 2006;188(11):4057-4067.2424 Dealtry S, Holmsgaard PN, Dunon V, et al. Shifts in abundance and diversity of mobile genetic elements after the introduction of diverse pesticides into an on-farm biopurification system over the course of a year. Appl Environ Microbiol. 2014;80(13):4012-4020. The ndo genes were target in the present study instead of others PAH degrading genes, due to their important role to initiate PAH degradation.2525 Kauppi B, Lee K, Carredano E, et al. Structure of an aromatic-ring-hydroxylating dioxygenase – naphthalene 1,2-dioxygenase. Structure. 1998;6(5):571-586.,2626 Ghosal D, Ghosh S, Dutta TK, Ahn Y. Current state of knowledge in microbial degradation of polycyclic aromatic hydrocarbons (PAHs): a review. Front Microbiol. 2016;7. Article 1369.

We studied and tested a previously isolated petroleum hydrocarbon degradative consortium (PHDC) derived from the rhizosphere of the mangrove tree Avicennia schaueriana which showed a high ability for PAH removal and high abundances of IncP-9 plasmids and ndo genes.2727 Gomes NCM, Flocco CG, Costa R, et al. Mangrove microniches determine the structural and functional diversity of enriched petroleum hydrocarbon-degrading consortia. FEMS Microbiol Ecol. 2010;74(2):276-290. Herein the PHDC was characterized in order to test potential for bioremediation and application as inoculum in A. schaueriana artificially contaminated with oil in a phytoremediation greenhouse microcosm experiment. Due to the high ability for PAH removal, and high abundances of IncP-9 plasmids and ndo genes previously shown by the PHDC isolated by Gomes et al.2727 Gomes NCM, Flocco CG, Costa R, et al. Mangrove microniches determine the structural and functional diversity of enriched petroleum hydrocarbon-degrading consortia. FEMS Microbiol Ecol. 2010;74(2):276-290.A. schaueriana was the mangrove tree of choice for the current microcosm experiment. This mangrove tree is typically growing in the intertidal regions of sheltered tropical and subtropical coasts,2828 Saenger P. Mangrove Ecology, Silviculture and Conservation. Springer Science & Business Media; 2002. 15–20 m in size and very tolerant to high salinity.2929 Tomlinson PB. The Botany of Mangroves. Cambridge: Cambridge University Press; 1995. Microcosm experiments are often performed in the laboratory or under greenhouse conditions in order to mimic natural environment conditions as much as possible to study biodegradation pathways of different pollutants and the interactions between microorganisms and organic compounds under well controlled conditions.3030 Hill KE, Top EM. Gene transfer in soil systems using microcosms. FEMS Microb Ecol. 1998;25:319-329.

We hypothesized that the isolation of bacterial communities which have been regularly exposed to high oil concentrations might show accelerated hydrocarbon degradation, which can be explained by the proliferation of adapted bacteria involved in biodegradation pathways.3131 Heuer H, Smalla K. Plasmids foster diversification and adaptation of bacterial populations in soil. FEMS Microbiol Rev. 2012;36(6):1083-1104. Therefore, we expected that the PHDC inoculation to A. schaueriana grown in sediment artificially contaminated with oil, in comparison to treatments without PHDC would: (i) protect plants against deleterious oil effects, (ii) cause changes in the composition of bacterial populations, and (iii) increase the abundance of plasmids potentially carrying catabolic genes, such as ndo genes, due to the proliferation of indigenous or introduced bacteria carrying catabolic plasmids such as IncP-9 plasmids, or their spread through horizontal gene transfer.

In order to prove our hypothesis, the assessment of changes in the bacterial communities over time and the detection of functional genes and plasmids involved in PAH degradation, denaturing gradient gel electrophoresis (DGGE) analysis of bacterial 16S rRNA gene and ndo fragments, detection of ndo gene and IncP-1, IncP-7 and IncP-9 by polymerase chain reaction (PCR) and Southern blot hybridization (SBH) were performed.

Materials and methods

Petroleum hydrocarbon degrading consortium (PHDC) bioaugmentation inoculum source

Tree sampling, rhizosphere processing and PHDC enrichment were performed according to Gomes et al.2727 Gomes NCM, Flocco CG, Costa R, et al. Mangrove microniches determine the structural and functional diversity of enriched petroleum hydrocarbon-degrading consortia. FEMS Microbiol Ecol. 2010;74(2):276-290.A. schaueriana was selected for the phytoremediation microcosm experiment based on previous gas chromatography (GC)-based data, which indicated a significant decrease in the total polycyclic hydrocarbon (PH) concentrations (129.6 ± 62 mg L-1) in comparison with the control flasks (301 ± 109.3 mg L-1) (p < 0.05). This PHDC also showed a high abundance of naphthalene dioxygenase (ndo) genes genotypes and plasmids belonging to the incompatibility (Inc) group.2727 Gomes NCM, Flocco CG, Costa R, et al. Mangrove microniches determine the structural and functional diversity of enriched petroleum hydrocarbon-degrading consortia. FEMS Microbiol Ecol. 2010;74(2):276-290. In this study, the A. schaueriana rhizosphere PHDC were further characterized, as described below, and were used as the bioaugmentation inoculum in the phytoremediation microcosm experiment.

Petroleum hydrocarbon degrading consortium (PHDC) bacteria characterization

A cultivation-based approach combined with molecular characterization was performed, in order to characterize the bacterial community present in the inoculum, previously used in Gomes et al.,2727 Gomes NCM, Flocco CG, Costa R, et al. Mangrove microniches determine the structural and functional diversity of enriched petroleum hydrocarbon-degrading consortia. FEMS Microbiol Ecol. 2010;74(2):276-290. applied in the microcosm experiment.

Bacterial strains were isolated from the enriched inoculum applied in the microcosm experiment described below. First, 4 replicates of the inoculum were incubated in a liquid Minimum Salt Medium (MSM)3232 Margesin R, Schinner F. Efficiency of indigenous and inoculated cold-adapted soil microorganisms for biodegradation of diesel oil in alpine soils. Appl Environ Microbiol. 1997;63(7):2660-2664. with the addition of 1% of Arabian Light crude oil (cordially provided by Petrobras S.A.) as the only carbon source and maintained at room temperature under constant shaking at 150 rpm for a total period of 20 days. After that, in order to obtain the isolates, the culture was plated in a solid MSM with crude oil vapor as the sole carbon source by dropping oil on filter paper placed on the lid of Petri dishes. The incubation time varied between 5, 15 and 20 days at 30 ºC. The genomic DNA was extracted3333 Valence P, Gouveia C, de Lemos GA, et al. PCR amplification of the rDNA internal transcribed spacer region for differentiation of Saccharomyces cultures. FEMS Microbiol Lett. 1996;137:253-256. from 80 isolates (20 from each replicate). The bacterial 16S rRNA gene was amplified in a PCR reaction by using the F-27 e R-1492 primers, generating a product of 1450 bp in size.3434 Weisburg WG, Barns SM, Pelletier DA, Lane DJ. 6S ribosomal DNA amplification for phylogenetic study. J Bacteriol. 1991;173(2):697-703.

The PCR products were purified by using the MinElute PCR Purification Kit from QIAGEN (QIAGEN GmbH, Germany) and 100 µM of the primer U8-27' (AGA GTT TGA TCA TGG CTC AG) (Kornelia Smalla, personal communication) were added to perform the sequencing reaction. The sequencing was performed by the German Company IIT Biotech in Bielefeld, Germany.

Primers were trimmed away and chimeric sequences were removed de novo with uChime in uSearch 5.2.32.3535 Edgar RC, Haas BJ, Clemente JC, Quince C, Knight R. UCHIME improves sensitivity and speed of chimera detection. Bioinformatics. 2011;27(16):2194-2200. The sequences were compared using BLASTN (http://www.ncbi.nlm.nih.gov/BLAST) and RDP (http://rdp.cme.msu.edu/).

Plasmid DNA extraction from bacterial strains and detection of incompatibility (Inc) plasmid groups and naphthalene dioxygenase (ndo) genes

Bacterial strains were cultivated overnight on a MSM with oil distributed on Petri dishes covers as the only carbon source, at 28 ºC. Subsequently, each isolate was harvested and the plasmid DNA was obtained by phenol-chloroform extraction of the potassium acetate fraction.3636 Smalla K, Heuer H, Götz A, Niemeyer D, Krögerrecklenfort E, Tietze E. Exogenous isolation of antibiotic resistance plasmids from piggery manure slurries reveals a high prevalence and diversity of IncQ-Like plasmids. Appl Environ Microbiol. 2000;66(11):4854-4862. The quality of the plasmid DNA was verified under a UV light after agarose gel electrophoresis (1%, w/v) stained with ethidium bromide. Plasmid DNA from isolates was screened for the presence of ndo genes1818 Gomes NCM, Borges LR, Paranhos R, et al. Diversity of ndo genes in mangrove sediments exposed to different sources of polycyclic aromatic hydrocarbon pollution. Appl Environ Microbiol. 2007;73(22):7392-7399. and of Inc plasmids belonging to the following groups: IncP-1,3737 Bahl MI, Burmølle M, Meisner A, Hansen LH, Sørensen SJ. All IncP-1 plasmid subgroups, including the novel ɛ subgroup, are prevalent in the influent of a Danish wastewater treatment plant. Plasmid. 2009;62(2):134-139. IncP-7,3838 Izmalkova TY, Sazonova OI, Sokolov SL, Kosheleva IA, Boronin AM. The P-7 incompatibility group plasmids responsible for biodegradation of naphthalene and salicylate in fluorescent pseudomonads. Microbiology. 2005;74(3):290-295. and IncP-9.2020 Dealtry S, Ding GC, Weichelt V, et al. Cultivation-independent screening revealed hot spots of IncP-1, IncP-7 and IncP-9 plasmid occurrence in different environmental habitats. PLOS ONE. 2014;9(2):e89922. Plasmid DNA was used for dot blot hybridization as previously described by Gomes et al.1818 Gomes NCM, Borges LR, Paranhos R, et al. Diversity of ndo genes in mangrove sediments exposed to different sources of polycyclic aromatic hydrocarbon pollution. Appl Environ Microbiol. 2007;73(22):7392-7399.

Experimental phytoremediation microcosm design

Young, six months old, A. schaueriana trees previously planted at the Jequiá mangrove forest located in Guanabara Bay, near the Duque de Caxias Oil Refinery (REDUC) (Rio de Janeiro, Brazil) were carefully removed along with sediment surrounding the roots and replanted into plant pots filled with 500 g of sediment each. The sampling site characteristics have been previously described by Gomes et al.1818 Gomes NCM, Borges LR, Paranhos R, et al. Diversity of ndo genes in mangrove sediments exposed to different sources of polycyclic aromatic hydrocarbon pollution. Appl Environ Microbiol. 2007;73(22):7392-7399. The artificial oil contamination was performed by covering the plant-mangrove sediment microcosms with 1 mL of crude oil emulsified in 9 mL of seawater. The following four treatments, each with four replicates, were carried out: treatment 1: plant-mangrove microcosms without addition of oil or inoculum; treatment 2: plant-mangrove microcosms inoculated with 109 CFU mL-1 of the total isolated strain from the inoculum (PHDC) (pellets were obtained after centrifugation in 0.85% NaCl for 10 min at 5000 × g); treatment 3: plant-mangrove microcosms artificially contaminated with 1 mL of emulsified crude oil in 10 mL of sea water inoculated with 109 CFU mL-1 inoculum (PHDC); treatment 4: plant-mangrove microcosms artificially contaminated with 1 mL of emulsified crude oil in 10 mL of sea water. To expose the microcosms to the high and low tide conditions, as in natural mangroves, all microcosms were partially flooded with seawater for 6 h every day. Fresh seawater was directly collected from the Jequiá mangrove. At the end of the flooding period, seawater was leached out by gravitation.

Inoculum preparation and inoculation

The oil-degrading consortium was activated by cultivation in liquid MSM3232 Margesin R, Schinner F. Efficiency of indigenous and inoculated cold-adapted soil microorganisms for biodegradation of diesel oil in alpine soils. Appl Environ Microbiol. 1997;63(7):2660-2664. supplemented with crude oil (1%, v/v) for 5 days. The biomass production for the plant-mangrove microcosm inoculation was performed by spreading 0.1 mL of the pre-activated degrading consortium onto MSM agar plates. Crude oil vapor was used as the sole carbon source by dropping oil on filter paper placed on the lid of Petri dishes. The microbial cells were harvested from the plates by washing with 0.85% saline after 3 days of incubation. The microbial suspension was centrifuged and re-suspended in sterile saline up to 3 times for removal of residual oil compounds. The cell suspension was standardized by optical density at 600 nm to achieve a cell density of 109 cells mL-1. Due to the fact that mangrove roots are very sensitive to desiccation and physical damage, the plant-mangrove microcosm inoculation was performed by adding 2 mL of cell suspension per each 100 g of sediment above the sediment near the base of each plant. The same volume of sterile saline was added to non-inoculated soils to standardize the final moisture content of each microcosm.

Sampling and sample processing

The microcosm experiment lasted 52 days. Samples were taken just after the inoculation (day 0), and at 7, 21 and 52 days post-inoculation, corresponding to T0, T1, T2 and T3, respectively. Four entire microcosms were analyzed per treatment. The rhizosphere sample consisted of the total root system with tightly adhering sediment of four individual plants. Each rhizosphere sample was cut and thoroughly mixed prior to microbial cell detachment. Extraction of microbial cells from the roots was performed by gently shaking (100 rpm) 5 g of homogenized root samples in Erlenmeyer flasks containing 5 g of glass beads (diameter of ∼4 mm) and 45 mL of extraction solution containing Tween 80 (0.1%) and sodium pyrophosphate (0.1%) for 30 min. After the microbial cells were dislodged from the sediment matrices, 10 mL from the supernatant of each sample were centrifuged and the pellets were re-suspended in ethanol (PA) up to a final volume of 2 mL and frozen at -60 ºC until processed for DNA/RNA extraction.3939 Gomes NCM, Kosheleva IA, Abraham W-R. Effects of the inoculant strain Pseudomonas putida KT2442 (pNF142) and of naphthalene contamination on the soil bacterial community. FEMS Microbiol Ecol. 2005;54:21-33. Only 1 mL from this suspension was used for nucleic acid extraction (amount of microbial cell corresponding to 0.5 g of fresh sediment).

Chlorophyll and total carotenoid pigments determinations

To determine the stress caused in the plants due to the hydrocarbon contamination, we measured chlorophyll a and b and total carotenoid concentrations. Circular discs were cut with a 6.36 mm diameter cork bore (approx. 127 mm2) from both leaves of the second and third nodes counting from the top down. Each leaf disc, weighing approximately 50 mg (wet weight), was placed in a vial containing 6 mL of dimethyl sulfoxide (DMSO) and photosynthetic pigments were extracted without grinding at 60 ºC for 14 h in the dark.4040 Hiscox JD, Israelstam GF. A method for the extraction of chlorophyll from leaf tissue without maceration. Can J Bot. 1979;57(12):1332-1334. Thereafter, the organic extracts were stored at 10 ºC and 3 mL of DMSO were added to each leaf disc, maintained at 60 ºC for 4 h for further extracting any remained pigments. These nearly colorless extracts were poured into the first ones. Chlorophylls (a + b) and total carotenoids (carotenes plus xanthophylls) were quantified spectrophotometrically according to Wellburn4141 Wellburn AR. The spectral determination of chlorophylls a and b, as well as total carotenoids, using various solvents with spectrophotometers of different resolution. J Plant Physiol. 1994;144(3):307-313. after subtracting the turbidity at 750 nm.

Total community (TC)-DNA and cDNA (RNA) extraction from microcosm soil samples

TC-DNA was extracted from 0.5 g of microcosm soil samples using the FastDNA® Spin Kit for Soil (Bio101, Qbiogene, Carlsbad, CA, USA) after a harsh lysis step with the FastPrep FP120 bead beating system for cell lysis. DNA was purified by GENECLEAN Spin Kit (Qbiogene), and the yield and quality were verified by electrophoresis on 1% (w/v) agarose gels under UV light after staining with ethidium bromide. The extracted TC-DNA was used for PCR-Southern blot hybridization (SBH) analysis, quantitative real-time PCR (qPCR) and DGGE fingerprints. The absence of PCR-inhibiting substances was verified by PCR amplification of bacterial 16S rRNA gene ragments from TC-DNA using the F27 and R1494 primers as previously described by Heuer et al.4242 Heuer H, Kopmann C, Binh CTT, Top EM, Smalla K. Spreading antibiotic resistance through spread manure: characteristics of a novel plasmid type with low %G + C content. Environ Microbiol. 2009;11(4):937-949. The cDNA was extracted according to Costa et al.4343 Costa R, Gomes NCM, Milling A, Smalla K. An optimized protocol for simultaneous extraction of DNA and RNA from soils. Braz J Microbiol. 2004;35(3):230-234.

Bacterial 16S rRNA gene PCR amplification and quantification

Bacterial 16S rRNA gene PCR amplification was performed as previously described by Heuer et al.4242 Heuer H, Kopmann C, Binh CTT, Top EM, Smalla K. Spreading antibiotic resistance through spread manure: characteristics of a novel plasmid type with low %G + C content. Environ Microbiol. 2009;11(4):937-949. (product size of 1506 bp) from the TC-DNA of microcosm soil samples and the genomic DNA from isolated bacterial strains. PCR products were checked after electrophoresis in 1% agarose gel stained with ethidium bromide under UV light in comparison with the 1-kb gene-ruler TM DNA ladder (Fermentas, St. Leon-Rot, Germany). Quantitative PCR (qPCR) targeting the bacterial 16S rRNA gene from the TC-DNA was performed with the TaqMan system as described by Suzuki et al.4444 Suzuki MT, Taylor LT, DeLong EF. Quantitative analysis of small-subunit rRNA genes in mixed microbial populations via 5'-nuclease assays. Appl Environ Microbiol. 2000;66(11):4605-4614. The bacterial 16S rRNA gene qPCR standard was obtained through a dilution series (10-3–10-7) of the cloned bacterial 16S rRNA gene amplicons (1467 bp) from Escherichia coli.

DGGE analysis of bacterial 16S rRNA gene fragments from the TC-DNA of microcosm soil samples

Bacterial 16S rRNA gene fragments amplified from TC-DNA were analyzed by DGGE as described by Ding et al.4545 Ding GC, Heuer H, Smalla K. Dynamics of bacterial communities in two unpolluted soils after spiking with phenanthrene: soil type specific and common responders. Front Microbiol. 2012;3:. Comparison of silver-stained DGGE profiles and band intensities was performed by means of the GelCompar II 5.6 software (Applied Maths, Sint-Martens-Latem, Belgium). A cluster analysis based on the Pearson similarity matrix was constructed by the Unweighted Pair Group Method with Arithmetic Mean (UPGMA).4646 Smalla K, Oros-Sichler M, Milling A, et al. Bacterial diversity of soils assessed by DGGE, T-RFLP and SSCP fingerprints of PCR-amplified 16S rRNA gene fragments: do the different methods provide similar results?. J Microbiol Methods. 2007;69(3):470-479. In order to evaluate slight differences in the bacterial community fingerprints visualized by DGGE, a statistical test analysis was applied by using a permutation test based on the pairwise similarity measures.4747 Kropf S, Heuer H, Grüning M, Smalla K. Significance test for comparing complex microbial community fingerprints using pairwise similarity measures. J Microbiol Methods. 2004;57(2):187-195.

Naphthalene dioxygenase (ndo) gene-based DGGE analysis

PCR amplification of ndo gene fragments from the TC-DNA and cDNA of the four microcosm treatments at two different sampling times were performed for DGGE analyses.1818 Gomes NCM, Borges LR, Paranhos R, et al. Diversity of ndo genes in mangrove sediments exposed to different sources of polycyclic aromatic hydrocarbon pollution. Appl Environ Microbiol. 2007;73(22):7392-7399. PCR products were checked on 1% agarose gels in order to verify the correct band size. The ndo genes were subsequently analyzed by DGGE as described by Gomes et al.1818 Gomes NCM, Borges LR, Paranhos R, et al. Diversity of ndo genes in mangrove sediments exposed to different sources of polycyclic aromatic hydrocarbon pollution. Appl Environ Microbiol. 2007;73(22):7392-7399.

Southern blot-PCR based detection of incompatibility (Inc) plasmids: IncP-1, IncP-7 and IncP-9 plasmids from the TC-DNA of microcosm soil samples

The Southern blot-PCR based detection of IncP-1,3737 Bahl MI, Burmølle M, Meisner A, Hansen LH, Sørensen SJ. All IncP-1 plasmid subgroups, including the novel ɛ subgroup, are prevalent in the influent of a Danish wastewater treatment plant. Plasmid. 2009;62(2):134-139. IncP-7,3838 Izmalkova TY, Sazonova OI, Sokolov SL, Kosheleva IA, Boronin AM. The P-7 incompatibility group plasmids responsible for biodegradation of naphthalene and salicylate in fluorescent pseudomonads. Microbiology. 2005;74(3):290-295. and IncP-92020 Dealtry S, Ding GC, Weichelt V, et al. Cultivation-independent screening revealed hot spots of IncP-1, IncP-7 and IncP-9 plasmid occurrence in different environmental habitats. PLOS ONE. 2014;9(2):e89922. from the TC-DNA of the four microcosm treatments at two different sampling times was performed according to Dealtry et al.4848 Dealtry S, Nour EH, Holmsgaard PN, et al. Exploring the complex response to linuron of bacterial communities from biopurification systems by means of cultivation-independent methods. FEMS Microbiol Ecol. 2016;92(2):1-12.

Results

Identification of bacterial isolates from the PHDC inoculum based on the partial sequence of the bacterial 16S rRNA gene

From the initial 80 isolates, a screening based on phenotypes and biochemical tests: colony morphology, catalase and oxidase reaction,4949 Holt GH, Krieg NR, Sneath PHA, Staley JT, Williams ST. Bergey's Manual of Determinative Bacteriology. 9th ed. Baltimore, MD, USA: Williams & Wilkins Co; 1994. and Gram staining test,5050 Madigan MT, Martinko JM, Parker J. Estrutura/Função celular. In: Microbiologia de Brock. 10th ed. USA: Prentice Hall; 2004:52–94. led to the selection of 35 isolates for bacterial 16S rRNA partial gene sequencing. Based on the partial sequences of the 16S rRNA gene, the bacterial strains were identified as Pseudomonas spp. (20), Ochrobactrum spp. (6), Comamonas spp. (5), Achromobacter spp. (2), Bacillus sp. (1), and Pseudoacidovorax sp. (1). The bacterial 16S rRNA amplicon sequences have GenBank accession numbers KX061935–KX061969.

Detection of incompatibility (Inc) plasmids and naphthalene dioxygenase (ndo) genes from the plasmid DNA of PHDC bacterial isolates

The presence of plasmids and ndo genes were confirmed by dot blot hybridization analysis performed with the PCR products with predicted band sizes of each of the amplicon targets. PCR amplicons and Southern blot hybridization (SBH) signals of the predicted sizes corresponding to IncP-1 plasmids were obtained for five isolates. Most of the isolates (11), showed PCR amplicons and SBH signals corresponding to IncP-9 plasmids (Supplementary S1), while six showed signals indicating the presence of ndo genes (Supplementary S2). Only one isolate showed the presence of IncP-9 plasmid and ndo gene at same time (Table 1).

Table 1
Identification of bacteria isolated from the petroleum hydrocarbon degradative consortium (PHDC), based on bacterial 16S rRNA gene partial sequence and screening for the detection of incompatibility (Inc) plasmids and naphthalene dioxygenase (ndo) genes trough dot blot hybridization.

Plant protection of bacterial communities inoculated on A. schaueriana against artificial petroleum contamination

In order to evaluate the potential of the inoculated PHDC to protect A. schaueriana mangrove plants against the phytotoxicity induced by artificial contamination with petroleum, symptoms such as the numbers of leaves with blight lesions and plant length at the initial time point (T0) and at the end of the experiment (T3) were measured and compared. The results indicated that none of the analyzed leaves displayed blight lesions, and only weak symptoms in five leaves were observed in one replicate (3.1) of the inoculated plants artificially contaminated with oil at the end of the experiment (T3) in the control (1) and in inoculated plants without oil (2). On the other hand, all plants artificially contaminated with oil (4) displayed several leaves with blight lesions: six, three, nine and four leaves respectively, from 4.1, 4.2, 4.3 and 4.4 at the end of the experiment (T3) (Fig. 1).

Fig. 1
Effects of PAH contamination on A. schaueriana mangrove tree stems and blight lesions after 21 days of contamination with crude oil. (A) controls, plants without inoculum and oil; (B) inoculated plants; (C) inoculated plants artificially contaminated with 1 mL of emulsified crude oil in 10 mL of sea water; (D) plant artificially contaminated with 1 mL of emulsified crude oil in 10 mL of sea water.

Determination of total chlorophyll and total carotenoids of A. schaueriana used in the phytoremediation greenhouse microcosm experiment

In order to evaluate A. schaueriana stress caused by the artificial addition of petroleum, pigment extractions from the initial time point (T0) and the end of the experiment (T3) were performed. The results of these pigments, total chlorophyll (a + b) and total carotenoids, indicate that, except for the control plants (1), all other treatments, 2, 3 and 4, respectively – inoculated plants, inoculated plants artificially contaminated with oil, and plants artificially contaminated with oil – resulted in a decrease of chlorophyll (a + b) levels and, to a lower degree, in a decrease of total carotenoids. The occurrence of plant stress is indicated by the ratio of chlorophyll divided by the total carotenoid concentrations, which, in the present study, decreased significantly from the ratio of 6.2 mg/m2 (control) to 5.2 mg/m2 in the other treatments (2; 3; 4) at the last sampling timepoint.

Determination of bacterial 16S rRNA gene copies by qPCR from the TC-DNA of microcosm soil samples

In order to estimate the bacterial abundance of the mangrove microcosm samples, the 16S rRNA gene copies were determined by qPCR from soil TC-DNA extracts. All samples (Table 2) showed a high abundance of bacterial populations ranging from 108 to 109 bacterial 16S rRNA gene copy numbers per gram of microcosm soil samples with no significant differences between the treatments (Tukey's test, p < 0.05).

Table 2
Bacterial densities and PCR-Southern blot hybridization detection of plasmid replicon-specific sequences belonging to the IncP-1, IncP-7 and IncP-9 groups.

Response of bacterial mangrove communities to oil revealed by bacterial 16S rRNA gene-based DGGE analysis

To evaluate the effect of oil and PHDC on the bacterial community composition over time, a DGGE analysis was performed of bacterial 16S rRNA genes amplified from TC-DNA extracted from the four microcosm treatments from samples taken after 7 and 21 days of growth in the greenhouse. The bacterial DGGE fingerprints (Fig. 2A and b) showed a high stability of the bacterial community over time, without detectable variation among replicates and treatments. The UPGMA cluster analysis of the DGGE patterns did not detect any significant difference between the two sampling times for the bacterial diversity between the different treatments over time (Fig. 2A and b). The permutation test analysis of total bacterial DGGE fingerprints revealed no significant differences in the composition of these communities between the different treatments and incubation times. The DGGE analysis data is only shown for the time point after seven (T1) and 21 (T2) days of inoculation in congruence with the time points analyzed by the others molecular analysis (ndo-DGGE fingerprints of DNA and cDNA genes and Southern blot hybridization of catabolic plasmids).

Fig. 2
Comparison of the bacterial community structures by DGGE based on bacterial 16S rRNA. S: (S) Standard bacterial 16S rRNA; (1) controls, plants without inoculum and oil; (2) inoculated plants; (3) inoculated plants artificially contaminated with 1 mL of emulsified crude oil in 10 mL of sea water; (4) plant artificially contaminated with 1 mL of emulsified crude oil in 10 mL of sea water.

Molecular analysis of naphthalene dioxygenase (ndo) genes

In this study, an ndo gene fingerprint approach1818 Gomes NCM, Borges LR, Paranhos R, et al. Diversity of ndo genes in mangrove sediments exposed to different sources of polycyclic aromatic hydrocarbon pollution. Appl Environ Microbiol. 2007;73(22):7392-7399. was used to evaluate the effect of oil contamination and bioaugmentation on the diversity and expression of polycyclic aromatic hydrocarbon (PAH) degrading genes. Based on the band profiles, the comparison of ndo-DGGE fingerprints of DNA and cDNA revealed that both indigenous and introduced bacteria were able to express the genes coding for PAH degrading enzymes in the sediment rhizosphere (Fig. 3A and b). However, the appearance of dominant bands in the cDNA of inoculated treatments was observed, with the most intense signal on day 7, indicated the dominance of a specific ndo gene in the inoculated treatments, with high abundance and expression on day 7.

Fig. 3
Comparison of DNA and RNA (cDNA) DGGE ndo fingerprints of the mangrove microcosms artificially contaminated with petroleum at 7 (A) and 21 (B) days after contamination. Microcosms with and without inoculation are shown. Arrow indicates the ndo gene type introduced by inoculation.

Southern Blot-PCR based detection of incompatibility (Inc) plasmids from soil TC-DNA

From the TC-DNA, Southern blot hybridization (SBH) with labeled probes generated from specific PCR-amplicons from the TC-DNA were applied in order to avoid the detection of false-positive results which might occur in a conventional PCR amplification.5151 Smalla K, Jechalke S, Top E. Plasmid detection, characterization, and ecology. In: Tolmasky M, Alonso J, eds. Plasmids: Biology and Impact in Biotechnology and Discovery. Washington, DC: ASM Press; 2015:445–458. In order to detect the occurrence and temporal and treatment-dependent changes in the abundance of IncP-1, IncP-7 and IncP-9 plasmids, SBH analysis were performed.

PCR amplicons and SBH signals of the predicted sizes were not obtained for IncP-7 plasmids (Table 2). However, weak, strong and very strong signals were detected for IncP-1 and IncP-9 plasmids. While SBH of IncP-1 signals were detected without variation over time and between the different treatments, SBH of IncP-9 signals increased in response to the addition of the PHDC consortium in oil polluted treatments over the time. The SBH analysis results indicated higher IncP-9 plasmid abundance in the oil treatment, displaying the strongest signals (S3) in treatment 3 with the respective replicates on day 7 (T1), decreasing IncP-9 plasmid abundance after 21 days (T2) (Table 2). Southern Blot-PCR-based detection of Inc plasmid analysis data is only shown for the time point after seven and 21 days of inoculation, due to the absence of variation from the day 21 (T2) and at the end of the experiment, after 52 days of inoculation (T3).

Discussion

The microbial community was exposed to Arabian Light crude oil in the greenhouse microcosm experiment with or without the addition of selected indigenous petroleum hydrocarbon degrading consortium (PHDC). The microcosm experiment simulated an oil spill, and the effects of the microbial inoculation were evaluated over the time. The PHDC tested as inoculum in this phytoremediation microcosm experiment was previously shown to efficiently degrade polyaromatic hydrocarbons.2727 Gomes NCM, Flocco CG, Costa R, et al. Mangrove microniches determine the structural and functional diversity of enriched petroleum hydrocarbon-degrading consortia. FEMS Microbiol Ecol. 2010;74(2):276-290. Previous studies reported high abundances of IncP-9 plasmids and naphthalene dioxygenase (ndo) genes by Southern blot hybridization (SBH) analysis, and considerable polycyclic aromatic hydrocarbon (PAH) removal rates detected in PHDC originated from the A. schaueriana rhizosphere.2727 Gomes NCM, Flocco CG, Costa R, et al. Mangrove microniches determine the structural and functional diversity of enriched petroleum hydrocarbon-degrading consortia. FEMS Microbiol Ecol. 2010;74(2):276-290. In addition, a microarray analysis of the PHDC indicated that the majority of taxa with positive microarray signals, and most of the populations detected by the sequence analysis of dominant DGGE bands were associated to Pseudomonadales. Moreover, the bacterial 16S rRNA gene sequence analysis of bands excised from Pseudomonas DGGE profiles indicated the dominance of populations related to P. aeruginosa and P. putida, which are commonly involved in polycyclic hydrocarbons (PHs) degradation.2727 Gomes NCM, Flocco CG, Costa R, et al. Mangrove microniches determine the structural and functional diversity of enriched petroleum hydrocarbon-degrading consortia. FEMS Microbiol Ecol. 2010;74(2):276-290. However, the bacterial population present in the PHDC must be alive to be used as inoculum, and cultivation-independent TC-DNA based methods do not reflect survival. Therefore, bacterial isolates were obtained by using crude oil as selection source in the present study, in order to characterize the PHDC used as inoculum in the A. schaueriana phytoremediation microcosm experiment. As expected because the IncP-9 plasmid detected, most of the isolates were assigned to Pseudomonas spp. However, the majority of the isolates carried IncP-9 and IncP-1 plasmids and ndo genes, indicating their potential to perform the first step in PAH degradation. The isolation of PAH degrading bacteria is important for the formulation of efficient PHDC based inocula to be used in future phytoremediation applications, where the processes are dependent on microbial viability. Interestingly, some of the bacterial isolates assigned to Pseudomonas spp. (Table 1), which are well-known PAH degraders,5252 Dunn NW, Gunsalus IC. Transmissible plasmid coding early enzymes of naphthalene oxidation in Pseudomonas putida. J Bacteriol. 1973;114(3):974-979.5656 Dennis JJ, Zylstra GJ. Complete sequence and genetic organization of pDTG1, the 83 kilobase naphthalene degradation plasmid from Pseudomonas putida strain NCIB 9816-4. J Mol Biol. 2004;341(3):753-768. presented ndo genes in the absence of IncP-9 plasmids, which often carry genes involved in petroleum degradation and other natural contaminants.2020 Dealtry S, Ding GC, Weichelt V, et al. Cultivation-independent screening revealed hot spots of IncP-1, IncP-7 and IncP-9 plasmid occurrence in different environmental habitats. PLOS ONE. 2014;9(2):e89922. We also observed the presence of ndo genes in one of Pseudomonas sp. isolate which carried only IncP-1 plasmid, generally described as vehicle of genes involved in the degradation of man-made pollutants, such as pesticides and not natural contaminants such as petroleum.2424 Dealtry S, Holmsgaard PN, Dunon V, et al. Shifts in abundance and diversity of mobile genetic elements after the introduction of diverse pesticides into an on-farm biopurification system over the course of a year. Appl Environ Microbiol. 2014;80(13):4012-4020.

IncP-1 plasmids are a broad host range and have been observed in a wide range of hosts, such as Achromobacter xylosoxidans, Burkholderia cepacia, Cupriavidus necator, Pseudomonas sp., Sphingomonas sp. A1, Variovorax sp.,5757 Norberg P, Bergström M, Jethava V, Dubhashi D, Hermansson M. The IncP-1 plasmid backbone adapts to different host bacterial species and evolves through homologous recombination. Nat Commun. 2011;2:268. while IncP-9 is well known to be a narrow host range plasmid, mainly occurring in Pseudomonas.5858 Sevastsyanovich YR, Krasowiak R, Bingle LEH, et al. Diversity of IncP-9 plasmids of Pseudomonas. Microbiology. 2008;154(10):2929-2941. However, IncP-9 was detected in bacteria from other taxonomic groups for the first time here: in Comamonas aquatica and in two different Ochrobactrum spp. species. These are very interesting findings, which may also indicate that environmental pressure over time might have fostered the adaptation of other hosts by the uptake of IncP-9 plasmids, in order to increase bacterial survival under stressful conditions.

The use of bioremediation to accelerate the rates of petroleum components degradation has many successful examples, such as the case of the Exxon Valdez oil spill in Prince William Sound5959 Sugai SF, Lindstrom JE, Braddock JF. Environmental influences on the microbial degradation of Exxon Valdez oil on the shorelines of Prince William Sound, Alaska. Environ Sci Technol. 1997;31(5):1564-1572. and the oil spill in the northern Gulf of Mexico.6060 Liu Z, Liu J. Evaluating bacterial community structures in oil collected from the sea surface and sediment in the northern Gulf of Mexico after the Deepwater Horizon oil spill. Microbiologyopen. 2013;2(3):492-504. The results obtained in these cases have demonstrated that the stimulation of the indigenous bacteria able to degrade hydrocarbons by adding fertilizer significantly enhanced petroleum degradation rates and shaped the function and structure of bacterial communities.6161 Lu Z, Deng Y, Van Nostrand JD, et al. Microbial gene functions enriched in the Deepwater Horizon deep-sea oil plume. ISME J. 2012;6(2):451-460. The use of plants to enhance the bioremediation of petroleum hydrocarbons at contaminated soil sites, at a pilot-scale, demonstrated the relevant role of rhizosphere-associated microbes in the petroleum components degradation.6262 Olson PE, Reardon KF, Pilon-Smits EAH. Ecology of rhizosphere bioremediation. In: McCutcheon S, ed. Phytoremediation, Transformation and Control of Contaminants. Hoboken, NJ: SC John Wiley, Sons Inc; 2003:317–353.,6363 Hutchinson SL, Schwab AP, Banks MK. Biodegradation of petroleum hydrocarbons in the rhizosphere. In: McCutcheon SC, Schnoor JL, eds. Phytoremediation, Transformation and Control of Contaminants. Hoboken, NJ: John Wiley & Sons Inc; 2003:355–386. The bioaugmentation strategy used in the present greenhouse microcosm indicated promising results and can be further explored in future field phytoremediation experiments of polluted mangrove ecosystems.

The short-term effects of oil addition in association with the PHDC inoculation were evaluated under both aspects: structure and functional level. Firstly, in order to unravel and assess the changes in the structure of bacterial communities, a culture-independent method, the PCR-DGGE fingerprint technique, which is a suitable technique to access the structure of bacterial and archaeal communities of mangrove trees,6464 Colares GB, Melo VMM. Relating microbial community structure and environmental variables in mangrove sediments inside Rhizophora mangle L. habitats. Appl Soil Ecol. 2013;64:171-177. was applied. Pyrosequencing analysis of bacterial 16S rRNA gene amplicons already showed that most of the microbial community of mangrove trees involved in oil degradation were assigned to Bacteria, with highest abundance related to Proteobacteria,6565 Nogueira VLR, Rocha LL, Colares GB, et al. Microbiomes and potential metabolic pathways of pristine and anthropized Brazilian mangroves. Reg Stud Mar Sci. 2015, http://dx.doi.org/10.1016/j.rsma.2015.08.008.
http://dx.doi.org/10.1016/j.rsma.2015.08...
,6666 Alzubaidy H, Essack M, Malas TB, et al. Rhizosphere microbiome metagenomics of gray mangroves (Avicennia marina) in the Red Sea. Gene. 2016;576:626-636. which guided our focus to the comparative analysis of bacterial communities inhabiting the rhizosphere of mangrove trees. Based on the appearance of several DGGE bands in both analyzed sampling times, bacterial PHDC fingerprints indicated a high complexity of different bacterial populations. These results are indications of the adaptation of a high number of populations able to survive in the presence of PHs. These findings are in accordance with the results reported by Gomes et al.,2727 Gomes NCM, Flocco CG, Costa R, et al. Mangrove microniches determine the structural and functional diversity of enriched petroleum hydrocarbon-degrading consortia. FEMS Microbiol Ecol. 2010;74(2):276-290. which revealed a higher number of bacterial populations adapted to growth on PH, inhabiting the rhizosphere, in comparison with the complexity found in the bulk sediment.

Analysis of photosynthetic pigments (chlorophyll a, chlorophyll b and carotenoids) are often performed to indicate plant stress.6767 Molnárová M, Fargasová A. Se (IV) phytotoxicity for monocotyledonae cereals (Hordeum vulgare L., Triticum aestivum L.) and dicotyledonae crops (Sinapis alba L., Brassica napus L.). J Hazard Mater. 2009;172:854-861. In comparison with the control plants at the end of the experiment (T3), the chlorophyll/carotenoid ratio (total chlorophyll over total carotenoid) showed increased plant stress for all other evaluated treatments indicating plant metabolism alterations induced by the inoculated microorganisms. On the one hand, pigment analysis did not indicate a decrease of plant stress induced by oil due to the PHDC inoculation. On the other hand, plant symptoms observed in leaves indicate protection against oil-induced phytotoxicity.6868 Chaîneau CH, Morel J, Oudot J. Phytotoxicity and plant uptake of fuel oil hydrocarbons. J Environ Qual. 1997;26:1478-1483. Our results thus demonstrate that bacterial communities able to partially or totally degrade PHs inoculated in the greenhouse microcosm plants could improve A. schaueriana health, protecting this species against the phytotoxicity induced by the artificial contamination with petroleum. Inoculated plants showed only weak symptoms in five leaves in one replicate, while the non-inoculated plants showed several leaves with blight lesions (Fig. 1), indicating the protective effect of the inoculation with PAH-degrading bacteria in the presence of oil. The absence of significant differences in plant length measured at the end of the experiment (T3) (data not shown) between the non-inoculated and inoculated plants can be explained by the use of trees originated from a polluted urban mangrove, which likely carried oil-adapted bacterial communities, enriched catabolic plasmids and PAH degrading genes.2727 Gomes NCM, Flocco CG, Costa R, et al. Mangrove microniches determine the structural and functional diversity of enriched petroleum hydrocarbon-degrading consortia. FEMS Microbiol Ecol. 2010;74(2):276-290.,3131 Heuer H, Smalla K. Plasmids foster diversification and adaptation of bacterial populations in soil. FEMS Microbiol Rev. 2012;36(6):1083-1104. The frequent addition of petroleum to a microcosm tends to affect the microbial communities present in this environment, which also occurs in situ, in different polluted mangroves.2323 Gomes NCM, Borges LR, Paranhos R, Pinto FN, Mendonça-Hagler LCS, Smalla K. Exploring the diversity of bacterial communities in sediments of urban mangrove forests. FEMS Microbiol Ecol. 2008;66(1):96-109. The selection of PAH-degrading bacteria occurs in order to maintain the health and balance of this ecosystem. The shifts in the structure of pre-adapted bacterial communities to long-term oil pollution tending toward lesser diversity, but more specialized and adapted microbial communities, have been previously reported,4545 Ding GC, Heuer H, Smalla K. Dynamics of bacterial communities in two unpolluted soils after spiking with phenanthrene: soil type specific and common responders. Front Microbiol. 2012;3:.,6969 Ding GC, Pronk GJ, Babin D, et al. Mineral composition and charcoal determine the bacterial community structure in artificial soils. FEMS Microbiol Ecol. 2013;86(1):15-25. in accordance with the bacterial community stability shown in both treatments, as revealed by the DGGE analysis herein.

Secondly, in order to unravel and assess functional changes in bacterial communities caused by the short-term effects of oil addition in association with the PHDC inoculation, analysis of mobile genetic elements (MGEs) of interest were performed. Interestingly, while the structure of bacterial community was rather stable, pronounced shifts occurred in the MGEs over the time, indicating that the adaptation process in the mangrove is probably mainly driven by the proliferation of bacteria carrying plasmids with degradative genes and horizontal transfer of catabolic plasmids, e.g. encoding PAH degrading genetic determinants, rather than by changes in bacterial community composition due to the selection for PAH-degrading bacteria already present in the environment.2424 Dealtry S, Holmsgaard PN, Dunon V, et al. Shifts in abundance and diversity of mobile genetic elements after the introduction of diverse pesticides into an on-farm biopurification system over the course of a year. Appl Environ Microbiol. 2014;80(13):4012-4020.

Although SBH does not provide quantitative information on specific gene copy numbers per gram of material as does qPCR, changes in the abundances of the different plasmid groups can be indicated and are often confirmed by amplicon pyrosequencing, as demonstrated in other studies involving the biodegradation of organic pollutants.2424 Dealtry S, Holmsgaard PN, Dunon V, et al. Shifts in abundance and diversity of mobile genetic elements after the introduction of diverse pesticides into an on-farm biopurification system over the course of a year. Appl Environ Microbiol. 2014;80(13):4012-4020. On the basis of the exposure time of the identical blots hybridized with digoxigenin-labeled probes generated from reference plasmids (S1), it was shown that the bacteria carrying IncP-9 plasmids were highly abundant in treatment 3, which received both oil and the PHDC inoculum. The comparison between the bacterial 16S rRNA gene copy numbers by qPCR indicated that these differences were not due to differences in bacterial abundance among the samples. Several other studies have demonstrated the role of IncP-9 plasmids in the adaptation of the bacterial communities to PAH contamination in situ.5858 Sevastsyanovich YR, Krasowiak R, Bingle LEH, et al. Diversity of IncP-9 plasmids of Pseudomonas. Microbiology. 2008;154(10):2929-2941.,7070 Flocco CG, Gomes NCM, Mac Cormack W, Smalla K. Occurrence and diversity of naphthalene dioxygenase genes in soil microbial communities from the Maritime Antarctic. Environ Microbiol. 2009;11(3):700-714. The high abundance of the IncP-9 plasmids observed in the present study confirmed previously reported findings2020 Dealtry S, Ding GC, Weichelt V, et al. Cultivation-independent screening revealed hot spots of IncP-1, IncP-7 and IncP-9 plasmid occurrence in different environmental habitats. PLOS ONE. 2014;9(2):e89922. which indicate that IncP-9 plasmids often carry genes involved in the degradation of natural contaminants, e.g. ndo gene products responsible for different PAH degradation steps.1818 Gomes NCM, Borges LR, Paranhos R, et al. Diversity of ndo genes in mangrove sediments exposed to different sources of polycyclic aromatic hydrocarbon pollution. Appl Environ Microbiol. 2007;73(22):7392-7399. The exposure of mangrove bacteria to PAH for a longer period of time might have fostered adaptations to rapidly changing environmental conditions via horizontally acquired MGEs.3131 Heuer H, Smalla K. Plasmids foster diversification and adaptation of bacterial populations in soil. FEMS Microbiol Rev. 2012;36(6):1083-1104. No treatment-dependent changes in the abundance of IncP-1 plasmid carrying populations were observed, which is not surprising, since it is well known that this plasmid group often encodes genes involved in man-made pollutants, e.g. pesticides2020 Dealtry S, Ding GC, Weichelt V, et al. Cultivation-independent screening revealed hot spots of IncP-1, IncP-7 and IncP-9 plasmid occurrence in different environmental habitats. PLOS ONE. 2014;9(2):e89922. and not natural organic pollutants like petroleum.

It is well known that the important multicomponent enzyme system involved in PAH degradation, ndo genes, present a huge genetic variability which complicates their detection in environmental samples. However, in order to overcome this limitation, primers which target the ndo alpha subunits belonging to the main clade of group III, comprising several ndo genes, including the nahAc and phnAc genes, were applied.1818 Gomes NCM, Borges LR, Paranhos R, et al. Diversity of ndo genes in mangrove sediments exposed to different sources of polycyclic aromatic hydrocarbon pollution. Appl Environ Microbiol. 2007;73(22):7392-7399. PCR-based primer systems targeting a broad range of ndo genes were applied, and it was shown that the enrichment with microbial PAH genes indeed offered plant protection through the insertion of specific ndo genes as visualized by DGGE. The comparison of ndo-DGGE fingerprints of DNA and cDNA revealed that both indigenous and introduced bacteria were able to express the genes coding for PAH-degrading enzymes in the rhizosphere. However, due to the presence of dominant bands in the DNA and cDNA in the inoculated treatments, it can be suggested that specific ndo genes are present which are only expressed under high levels of oil pollution and have an earlier activity, as the band intensity was higher on day 7.

In conclusion, the data reported herein indicate that, due to the previous selection of bacterial consortia able to survive by using petroleum as carbon and nitrogen sources, the addition of petroleum did not change the composition of a bacterial community pre-adapted to PAH, in a greenhouse microcosm experiment over time. However, while the overall bacterial community composition did not significantly shift based on the methods used, changes in the abundance of conjugative plasmids and PAH-degrading genes were observed, indicating that horizontal gene transfer is a crucial parameter in the development of effective PAH-degrading microbial communities occurring in urban mangrove soils. It was shown that mangrove roots provide a suitable environment for the expression of PAH-catabolic genes expression. The results of this study aid in elucidating the response in bacterial community composition to oil contamination in mangrove ecosystems, indicating that a bioaugmentation strategy mediated by highly efficient PDHC can be a useful tool to clean-up the environment, with certain advantages, such as low implementation and maintenance costs. The main novelty of this work regarding the PDHC results is that Comamonas sp. (Betaproteobacteria) and Ochrobactrum sp. (Alphaproteobacteria) carrying IncP-9 plasmids are reported here for the first time. Thus it seems that under condition with strong selective pressure the host range of IncP-9 plasmids is far broader as previously reported.

Concluding remarks

DGGE7171 Muyzer G, Waal ECW, Uitierlinden AG. Profiling of complex microbial populations by denaturing gradient gel electrophoresis analysis of polymerase chain reaction-amplified genes coding for 16S rRNA. Appl Environ Microbiol. 1993;59(3):695-700. is a fingerprinting technique which allows to analyze rapidly and in a cost-effective way the structure and dynamics of microbial communities. Herein DGGE provided important information, which indicated that the abundant bacterial communities analyzed were stable over the time likely due to their pre-adaptation to oil. Commonly to every independent of cultivation technique, DGGE has its limitations such as the limit to detect only the most abundant microbial communities (>1% of the total community), not including some of rare species or those below to the detection limit, which can play an important role in PAH degradation. However, previous work22 Pires ACC, Cleary DFR, Almeida A, et al. Denaturing gradient gel electrophoresis and barcoded pyrosequencing reveal unprecedented Archaeal diversity in mangrove sediment and rhizosphere samples. Appl Environ Microbiol. 2012;78(16):5520-5528. based on the study of microbial communities from mangrove contaminated with oil indicated the absence of difference in the results revealed by DGGE and barcoded pyrosequencing. Nevertheless, would be interesting future amplicon analysis by next generation sequencing technologies for comparison with the data shown here and to provide information on the taxonomic affiliation of the dominant bacterial community members.

Based on the knowledge that sometimes a certain gene can be present but not expressed, DGGE analysis of ndo amplified from cDNA, instead only DNA analysis of ndo genes, brought a more complete and useful information, indicating not only the presence of ndo genes but also their expression of SBH has many advantages, as it provides insights into the prevalence and diversity of plasmids and genes in a larger numbers samples. When compared to the conventional PCR, which can also amplify non-specific products, SBH significantly increases the specificity and sensitivity of detection.7272 Götz A, Pukall R, Smit E, et al. Detection and characterization of broad-host-range plasmids in environmental Bacteria by PCR. Appl Environ Microbiol. 1996;62(7):2621-2628. Therefore, herein the PCR-based detection combined with SBH revealed intense shifts in the MGEs of bacterial communities, indicating the increased abundance of MGEs which might be due to the proliferation of bacterial populations carrying MGEs or due to horizontal transfer processes. In summary, this study provided novel data about the host range of IncP-9 catabolic plasmids, which were found for the first time in Comamonas sp. and Ochrobactrum spp. Furthermore, this study demonstrated that the PHDC inoculated in the greenhouse microcosm plants protected the A. schaueriana plants against the phytotoxicity induced by the artificial contamination with petroleum. Our results indicated that studies focusing on PHDC development and its application in bioaugmentation can be an interesting approach to promote mangrove environment detoxification and recovery after an oil spill accident.

Acknowledgments

Acknowledgments are due to PNPD-CAPES (Brazilian Ministry of Education) and CAPES for scholarship support given to S. Dealtry and A.M. Ghizelini. This study was funded by the Deutsche Forschungsgemeinschaft SM59/4-1 and 4-2 and by FAPERJ-Brazil.

Appendix A   Supplementary data

Supplementary data associated with this article can be found, in the online version, at doi:10.1016/j.bjm.2018.02.012.

REFERENCES

  • 1
    Schaeffer-Novelli Y, Cintrón-Molero G, Soares MLG, De-Rosa T. Brazilian mangroves. Aquat Ecosyst Health Manag 2000;3(4):561-570.
  • 2
    Pires ACC, Cleary DFR, Almeida A, et al. Denaturing gradient gel electrophoresis and barcoded pyrosequencing reveal unprecedented Archaeal diversity in mangrove sediment and rhizosphere samples. Appl Environ Microbiol 2012;78(16):5520-5528.
  • 3
    Andreote FD, Jiménez DJ, Chaves D, et al. The microbiome of Brazilian mangrove sediments as revealed by metagenomics. PLoS ONE 2012;7(6):e38600.
  • 4
    Arfi Y, Buée M, Marchand C, Levasseur A, Record E. Multiple markers pyrosequencing reveals highly diverse and host-specific fungal communities on the mangrove trees Avicennia marina and Rhizophora stylosa FEMS Microbiol Ecol 2012;79:433-444.
  • 5
    Soares L, Marcon J, C M De, et al. A novel multifunctional β-N-acetylhexosaminidase revealed through metagenomics of an oil-spilled mangrove. Bioengineering 2017;4(62), http://dx.doi.org/10.3390/bioengineering4030062
    » http://dx.doi.org/10.3390/bioengineering4030062
  • 6
    Rocha LL, Colares GB, Nogueira VLR, Paes FA, Melo VMM. Distinct habitats select particular bacterial communities in mangrove sediments. Int J Microbiol 2016. Article ID 3435809.
  • 7
    Ghizelini AM, Mendonça-Hagler LCS, Macrae A. Microbial diversity in Brazilian mangrove sediments – a mini review. Braz J Microbiol 2012;43(4):1242-1254.
  • 8
    Dias ACF, Andreote FD, Dini-Andreote F, et al. Diversity and biotechnological potential of culturable bacteria from Brazilian mangrove sediment. World J Microbiol Biotechnol 2009;25:1305-1311.
  • 9
    Basha SKC, Rao KRSS. An intrinsic assessment of bioactive potentiality of mangroves actinomycetes. J Entomol Zool Stud 2017;5(1):20-26.
  • 10
    Soares Júnior FL, Dias Franco AC, Fasanella CC, et al. Endo- and exoglucanase activities in bacteria from mangrove sediment. Braz J Microbiol 2013;44(3):969-976.
  • 11
    Valiela I, Bowen JL, York JK. Mangrove forests: one of the world's threatened major tropical environments. Bioscience 2001;51(10):807.
  • 12
    Polidoro BA, Carpenter KE, Collins L, et al. The loss of species: mangrove extinction risk and geographic areas of global concern. PLoS ONE 2010;5(4):e10095.
  • 13
    Korda A, Santas P, Tenente A, Santas R. Petroleum hydrobcarbon bioremediation: sampling and analytical techniques, in situ treatments and commercial microorganisms currently used. Appl Microbiol Biotechnol 1997;48(6):677-686.
  • 14
    Rocha LL, Colares GB, Angelim AL, Grangeiro TB, Melo VMM. Culturable populations of Acinetobacter can promptly respond to contamination by alkanes in mangrove sediments. Mar Pollut Bull 2013;76(1–2):214-219.
  • 15
    Angelim AL, Costa SP, Farias BCS, Aquino LF, Melo VMM. An innovative bioremediation strategy using a bacterial consortium entrapped in chitosan beads. J Environ Manage 2013;127:10-17.
  • 16
    Meniconi MFG, Barbanti SM. Case study: evaluation of hydrocarbon sources in Guanabara Bay, Brazil. In: Wang Z, Stout S, eds. Oil Spill Environmental Forensics, Fingerprinting and Source Identification Amsterdam: Academic Press; 2007:505–537.
  • 17
    Júnior JTA, Campos TMP, Pires PJM. Sediment characteristics of an impacted coastal bay: Baía de Guanabara, Rio de Janeiro, Brazil. J Coast Res 2014;71:41-47.
  • 18
    Gomes NCM, Borges LR, Paranhos R, et al. Diversity of ndo genes in mangrove sediments exposed to different sources of polycyclic aromatic hydrocarbon pollution. Appl Environ Microbiol 2007;73(22):7392-7399.
  • 19
    Polynuclear aromatic compounds, Part 1, Chemical, environmental and experimental data. IARC Monogr Eval Carcinog Risk Chem Hum 1983;32:1-453.
  • 20
    Dealtry S, Ding GC, Weichelt V, et al. Cultivation-independent screening revealed hot spots of IncP-1, IncP-7 and IncP-9 plasmid occurrence in different environmental habitats. PLOS ONE 2014;9(2):e89922.
  • 21
    Couturier M, Bex F, Bergquist PL, Maas WK. Identification and classification of bacterial plasmids. Microbiol Rev 1988;52(3):375-395.
  • 22
    Sota M, Yano H, Ono A, et al. Genomic and functional analysis of the IncP-9 naphthalene-catabolic plasmid NAH7 and its transposon Tn4655 suggests catabolic gene spread by a tyrosine recombinase. J Bacteriol 2006;188(11):4057-4067.
  • 23
    Gomes NCM, Borges LR, Paranhos R, Pinto FN, Mendonça-Hagler LCS, Smalla K. Exploring the diversity of bacterial communities in sediments of urban mangrove forests. FEMS Microbiol Ecol 2008;66(1):96-109.
  • 24
    Dealtry S, Holmsgaard PN, Dunon V, et al. Shifts in abundance and diversity of mobile genetic elements after the introduction of diverse pesticides into an on-farm biopurification system over the course of a year. Appl Environ Microbiol 2014;80(13):4012-4020.
  • 25
    Kauppi B, Lee K, Carredano E, et al. Structure of an aromatic-ring-hydroxylating dioxygenase – naphthalene 1,2-dioxygenase. Structure 1998;6(5):571-586.
  • 26
    Ghosal D, Ghosh S, Dutta TK, Ahn Y. Current state of knowledge in microbial degradation of polycyclic aromatic hydrocarbons (PAHs): a review. Front Microbiol 2016;7. Article 1369.
  • 27
    Gomes NCM, Flocco CG, Costa R, et al. Mangrove microniches determine the structural and functional diversity of enriched petroleum hydrocarbon-degrading consortia. FEMS Microbiol Ecol 2010;74(2):276-290.
  • 28
    Saenger P. Mangrove Ecology, Silviculture and Conservation Springer Science & Business Media; 2002.
  • 29
    Tomlinson PB. The Botany of Mangroves Cambridge: Cambridge University Press; 1995.
  • 30
    Hill KE, Top EM. Gene transfer in soil systems using microcosms. FEMS Microb Ecol 1998;25:319-329.
  • 31
    Heuer H, Smalla K. Plasmids foster diversification and adaptation of bacterial populations in soil. FEMS Microbiol Rev 2012;36(6):1083-1104.
  • 32
    Margesin R, Schinner F. Efficiency of indigenous and inoculated cold-adapted soil microorganisms for biodegradation of diesel oil in alpine soils. Appl Environ Microbiol 1997;63(7):2660-2664.
  • 33
    Valence P, Gouveia C, de Lemos GA, et al. PCR amplification of the rDNA internal transcribed spacer region for differentiation of Saccharomyces cultures. FEMS Microbiol Lett 1996;137:253-256.
  • 34
    Weisburg WG, Barns SM, Pelletier DA, Lane DJ. 6S ribosomal DNA amplification for phylogenetic study. J Bacteriol 1991;173(2):697-703.
  • 35
    Edgar RC, Haas BJ, Clemente JC, Quince C, Knight R. UCHIME improves sensitivity and speed of chimera detection. Bioinformatics 2011;27(16):2194-2200.
  • 36
    Smalla K, Heuer H, Götz A, Niemeyer D, Krögerrecklenfort E, Tietze E. Exogenous isolation of antibiotic resistance plasmids from piggery manure slurries reveals a high prevalence and diversity of IncQ-Like plasmids. Appl Environ Microbiol 2000;66(11):4854-4862.
  • 37
    Bahl MI, Burmølle M, Meisner A, Hansen LH, Sørensen SJ. All IncP-1 plasmid subgroups, including the novel ɛ subgroup, are prevalent in the influent of a Danish wastewater treatment plant. Plasmid 2009;62(2):134-139.
  • 38
    Izmalkova TY, Sazonova OI, Sokolov SL, Kosheleva IA, Boronin AM. The P-7 incompatibility group plasmids responsible for biodegradation of naphthalene and salicylate in fluorescent pseudomonads. Microbiology 2005;74(3):290-295.
  • 39
    Gomes NCM, Kosheleva IA, Abraham W-R. Effects of the inoculant strain Pseudomonas putida KT2442 (pNF142) and of naphthalene contamination on the soil bacterial community. FEMS Microbiol Ecol 2005;54:21-33.
  • 40
    Hiscox JD, Israelstam GF. A method for the extraction of chlorophyll from leaf tissue without maceration. Can J Bot 1979;57(12):1332-1334.
  • 41
    Wellburn AR. The spectral determination of chlorophylls a and b, as well as total carotenoids, using various solvents with spectrophotometers of different resolution. J Plant Physiol 1994;144(3):307-313.
  • 42
    Heuer H, Kopmann C, Binh CTT, Top EM, Smalla K. Spreading antibiotic resistance through spread manure: characteristics of a novel plasmid type with low %G + C content. Environ Microbiol 2009;11(4):937-949.
  • 43
    Costa R, Gomes NCM, Milling A, Smalla K. An optimized protocol for simultaneous extraction of DNA and RNA from soils. Braz J Microbiol 2004;35(3):230-234.
  • 44
    Suzuki MT, Taylor LT, DeLong EF. Quantitative analysis of small-subunit rRNA genes in mixed microbial populations via 5'-nuclease assays. Appl Environ Microbiol 2000;66(11):4605-4614.
  • 45
    Ding GC, Heuer H, Smalla K. Dynamics of bacterial communities in two unpolluted soils after spiking with phenanthrene: soil type specific and common responders. Front Microbiol 2012;3:.
  • 46
    Smalla K, Oros-Sichler M, Milling A, et al. Bacterial diversity of soils assessed by DGGE, T-RFLP and SSCP fingerprints of PCR-amplified 16S rRNA gene fragments: do the different methods provide similar results?. J Microbiol Methods 2007;69(3):470-479.
  • 47
    Kropf S, Heuer H, Grüning M, Smalla K. Significance test for comparing complex microbial community fingerprints using pairwise similarity measures. J Microbiol Methods 2004;57(2):187-195.
  • 48
    Dealtry S, Nour EH, Holmsgaard PN, et al. Exploring the complex response to linuron of bacterial communities from biopurification systems by means of cultivation-independent methods. FEMS Microbiol Ecol 2016;92(2):1-12.
  • 49
    Holt GH, Krieg NR, Sneath PHA, Staley JT, Williams ST. Bergey's Manual of Determinative Bacteriology. 9th ed. Baltimore, MD, USA: Williams & Wilkins Co; 1994.
  • 50
    Madigan MT, Martinko JM, Parker J. Estrutura/Função celular. In: Microbiologia de Brock 10th ed. USA: Prentice Hall; 2004:52–94.
  • 51
    Smalla K, Jechalke S, Top E. Plasmid detection, characterization, and ecology. In: Tolmasky M, Alonso J, eds. Plasmids: Biology and Impact in Biotechnology and Discovery Washington, DC: ASM Press; 2015:445–458.
  • 52
    Dunn NW, Gunsalus IC. Transmissible plasmid coding early enzymes of naphthalene oxidation in Pseudomonas putida J Bacteriol 1973;114(3):974-979.
  • 53
    Denome SA, Stanley DC, Olson ES, Young KD. Metabolism of dibenzothiophene and naphthalene in Pseudomonas strains: complete DNA sequence of an upper naphthalene catabolic pathway. J Bacteriol 1993;175(21):6890-6901.
  • 54
    Greated A, Lambertsen L, Williams PA, Thomas CM. Complete sequence of the IncP-9 TOL plasmid pWW0 from Pseudomonas putida Environ Microbiol 2002;4(12):856-871.
  • 55
    Ferrero M, Llobet-Brossa E, Lalucat J, García-Valdés E, Rosselló-Mora R, Bosch R. Coexistence of two distinct copies of naphthalene degradation genes in Pseudomonas strains isolated from the western Mediterranean region. Appl Environ Microbiol 2002;68(2):957-962.
  • 56
    Dennis JJ, Zylstra GJ. Complete sequence and genetic organization of pDTG1, the 83 kilobase naphthalene degradation plasmid from Pseudomonas putida strain NCIB 9816-4. J Mol Biol 2004;341(3):753-768.
  • 57
    Norberg P, Bergström M, Jethava V, Dubhashi D, Hermansson M. The IncP-1 plasmid backbone adapts to different host bacterial species and evolves through homologous recombination. Nat Commun 2011;2:268.
  • 58
    Sevastsyanovich YR, Krasowiak R, Bingle LEH, et al. Diversity of IncP-9 plasmids of Pseudomonas Microbiology 2008;154(10):2929-2941.
  • 59
    Sugai SF, Lindstrom JE, Braddock JF. Environmental influences on the microbial degradation of Exxon Valdez oil on the shorelines of Prince William Sound, Alaska. Environ Sci Technol 1997;31(5):1564-1572.
  • 60
    Liu Z, Liu J. Evaluating bacterial community structures in oil collected from the sea surface and sediment in the northern Gulf of Mexico after the Deepwater Horizon oil spill. Microbiologyopen 2013;2(3):492-504.
  • 61
    Lu Z, Deng Y, Van Nostrand JD, et al. Microbial gene functions enriched in the Deepwater Horizon deep-sea oil plume. ISME J 2012;6(2):451-460.
  • 62
    Olson PE, Reardon KF, Pilon-Smits EAH. Ecology of rhizosphere bioremediation. In: McCutcheon S, ed. Phytoremediation, Transformation and Control of Contaminants Hoboken, NJ: SC John Wiley, Sons Inc; 2003:317–353.
  • 63
    Hutchinson SL, Schwab AP, Banks MK. Biodegradation of petroleum hydrocarbons in the rhizosphere. In: McCutcheon SC, Schnoor JL, eds. Phytoremediation, Transformation and Control of Contaminants Hoboken, NJ: John Wiley & Sons Inc; 2003:355–386.
  • 64
    Colares GB, Melo VMM. Relating microbial community structure and environmental variables in mangrove sediments inside Rhizophora mangle L. habitats. Appl Soil Ecol 2013;64:171-177.
  • 65
    Nogueira VLR, Rocha LL, Colares GB, et al. Microbiomes and potential metabolic pathways of pristine and anthropized Brazilian mangroves. Reg Stud Mar Sci 2015, http://dx.doi.org/10.1016/j.rsma.2015.08.008
    » http://dx.doi.org/10.1016/j.rsma.2015.08.008
  • 66
    Alzubaidy H, Essack M, Malas TB, et al. Rhizosphere microbiome metagenomics of gray mangroves (Avicennia marina) in the Red Sea. Gene 2016;576:626-636.
  • 67
    Molnárová M, Fargasová A. Se (IV) phytotoxicity for monocotyledonae cereals (Hordeum vulgare L., Triticum aestivum L.) and dicotyledonae crops (Sinapis alba L., Brassica napus L.). J Hazard Mater 2009;172:854-861.
  • 68
    Chaîneau CH, Morel J, Oudot J. Phytotoxicity and plant uptake of fuel oil hydrocarbons. J Environ Qual 1997;26:1478-1483.
  • 69
    Ding GC, Pronk GJ, Babin D, et al. Mineral composition and charcoal determine the bacterial community structure in artificial soils. FEMS Microbiol Ecol 2013;86(1):15-25.
  • 70
    Flocco CG, Gomes NCM, Mac Cormack W, Smalla K. Occurrence and diversity of naphthalene dioxygenase genes in soil microbial communities from the Maritime Antarctic. Environ Microbiol 2009;11(3):700-714.
  • 71
    Muyzer G, Waal ECW, Uitierlinden AG. Profiling of complex microbial populations by denaturing gradient gel electrophoresis analysis of polymerase chain reaction-amplified genes coding for 16S rRNA. Appl Environ Microbiol 1993;59(3):695-700.
  • 72
    Götz A, Pukall R, Smit E, et al. Detection and characterization of broad-host-range plasmids in environmental Bacteria by PCR. Appl Environ Microbiol 1996;62(7):2621-2628.

Publication Dates

  • Publication in this collection
    Oct-Dec 2018

History

  • Received
    12 May 2017
  • Accepted
    14 Feb 2018
  • Published
    14 June 2018
Sociedade Brasileira de Microbiologia USP - ICB III - Dep. de Microbiologia, Sociedade Brasileira de Microbiologia, Av. Prof. Lineu Prestes, 2415, Cidade Universitária, 05508-900 São Paulo, SP - Brasil, Ramal USP 7979, Tel. / Fax: (55 11) 3813-9647 ou 3037-7095 - São Paulo - SP - Brazil
E-mail: bjm@sbmicrobiologia.org.br