Abstract
Silver nanoparticles (AgNPs) are known mainly because of their bactericidal properties. Among the different types of synthesis, there is the biogenic synthesis, which allows the synergy between the nanocomposites and substances from the organism employed for the synthesis. This study describes the synthesis of AgNPs using infusion of roots (AgNpR) and extract (AgNpE) of the plant Althaea officinalis. After the synthesis through reduction of silver nitrate with compounds of A. officinalis, physico-chemical analyzes were performed by UV-Vis spectroscopy, nanoparticles tracking analysis (NTA), dynamic light scattering (DLS) and scanning electron microscopy (SEM). Toxicity was evaluated through Allium cepa assay, comet test with cell lines, cell viability by mitochondrial activity and image cytometry and minimal inhibitory concentration on pathogenic microorganisms. Biochemical analyzes (CAT - catalase, GPx - glutathione peroxidase e GST - glutationa S-transferase) and genotoxicity evaluation in vivo on Zebrafish were also performed. AgNpE and AgNpR showed size of 157 ± 11 nm and 293 ± 12 nm, polydispersity of 0.47 ± 0.08 and 0.25 ± 0.01, and zeta potential of 20.4 ± 1.4 and 26.5 ± 1.2 mV, respectively. With regard to toxicity, the AgNpE were the most toxic when compared with AgNpR. Biochemical analyzes on fish showed increase of CAT activity in most of the organs, whereas GPx showed few changes and the activity of GST decreased. Also regarding to bactericidal activity, both nanoparticles were effective, however AgNpR showed greater activity. Althaea officinalis can be employed as reducing agent for the synthesis of silver nanoparticles, although it is necessary to consider its potential toxicity and ecotoxicity.
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Introduction
Nanotechnology has shown considerable potential for use in diverse areas including the textile, medical, pharmaceutical, cosmetics, agricultural, and chemical sectors1,2,3,4. Among the nanomaterials, metallic nanoparticles have attracted attention, especially in the medical and engineering fields, due to the unique properties that metals acquire at the nanometric scale5, as well as the possibility of conjugated synthesis and surface functionalization6, which opens up possibilities for a wide range of applications, in which silver nanoparticles are among those most extensively used, due to their proven bactericidal properties7,8,9,10,11,12,13.
There are different methods employed to synthesize nanoparticles and biogenic techniques are of particular interest since they are considered sustainable and allow synergy between the metal precursor and enzymes, proteins, polysaccharides, and other active substances derived from the reducing organism (Althaea officinalis, in the case of the present study)14,15,16.
Biogenic nanoparticles produced using plant extracts as reducers are among those that have received most attention10,17,18,19,20,21,22,23,24,25,26,27,28,29,30,31. Although the reduction of metal ions by plant extracts has been known since the 20th century, the mechanisms of bioreduction have not been fully elucidated32, however some studies have indicated that it involves enzymatic action of compounds in the extract33,34, specially enzymes such as nitrate reductase. The biogenic synthesis of AgNPs and their application in the control of bacteria has been shown to be feasible, as demonstrated by Makarov et al.20, who obtained promising results using the technique with different plants. Benelli et al.35 highlighted the effectiveness, low cost, and simplicity of synthesizing nanoparticles using botanical extracts, and described applications of these materials for the control of insects that are pests and disease vectors in agriculture. The authors noted the importance of studying the mechanisms of action of these nanomaterials and understanding their potential toxicity towards non-target organisms. As example, Guilger et al.15 described the potential of this kind of nanoparticles for the control of an important pathogenic fungus in agriculture.
The extract of the plant Althaea officinalis (marshmallow) has been used for many years to treat inflammations and wounds36. The root is widely used due to its ability to retain water and its high content of polysaccharides that can stimulate the immune system37. This plant could therefore be an attractive option for use as a reducer in biogenic synthesis.
In this study two types of biogenic AgNPs were synthesized using leaf extract and infusion of roots of Althaea officinalis as a reducing agent and their physico-chemical characteristics were evaluated. In order to verify the possible toxicity and antimicrobial potential the assays reduction of tetrazolium through mitochondrial activity (MTT), image cytometry, comet and minimal inhibitory concentration were performed. Ecotoxicity was also evaluated through Allium cepa assay and comet and biochemical assays with zebrafish.
Methods
Biological materials
Cell lines
Cyto and genotoxicity assays employed the standard ATCC cell lines 3T3, HaCat, A549, V79 and HeLa, obtained from the Rio de Janeiro cell bank. The cells were first grown, then trypsinized and transferred to 6, 12, 24 or 96-well plates, depending on the assay to be performed.
Microbial strains
The minimum inhibitory concentration (MIC) tests employed standard strains of Staphylococcus aureus, Escherichia coli, Pseudomonas aeruginosa, and Candida albicans (ATCC numbers 25923, 25922, 10145, and 10231, respectively), as recommended for use in antimicrobial susceptibility tests38. The strains were supplied by Cefar (São Paulo, Brazil).
Fish
Juvenile Danio rerio (Zebrafish) (body mass = 0.5–0.9 g; total length = 2–3 cm) from the World Fish, Brazil, were acclimated to the laboratory for 10 days in holding tanks (3L) at 25 ± 1 °C, with a continuous flow of aerated, dechlorinated tap water (pH 7.0 ± 0.2; conductivity = 8.3 ± 0.3 µS; alkalinity = 23.7 ± 1.9 mg.L−1 as CaCO3; hardness = 24.5 ± 0.2 mg.L−1 as CaCO3) and in a 12D:12L (12Dark:12Light) photoperiod. The fish were fed with balanced fish food appropriate for this species (TetraMin Tropical Flakes) every 48 h. Feeding was suspended 24 h before assays. All experiments were performed in accordance with relevant guidelines and regulations. All experimental protocols were approved by the Animal Research Ethical Commission of the University of Sorocaba (Protocol 004/2012).
Synthesis and physicochemical characterization of the nanoparticles
The nanoparticles were synthesized using Althaea officinalis leaf extract and dehydrated root infusion. The procedure was performed as described by Logeswari, Silambarasan and Abraham39, with minor modifications, mixing 20% of silver nitrate solution (0.1 mol.L−1) with 80% of extract or infusion solution (0.2 g.mL−1). The mixture was stirred in the dark for 24 h.
Firstly, physicochemical characterization of the synthesized nanoparticles was performed by UV-Vis spectroscopy, determination of the hydrodynamic diameter (nm), polydispersity index (PDI), and zeta potential by dynamic light scattering (DLS) and microelectrophoresis techniques. The analyses were performed at a fixed angle of 90° and temperature of 25 °C, using a Zetasizer Nano ZS90 system (Malvern Instruments). The nanoparticles concentration (NP mL−1) and size distribution were determined by nanoparticle tracking analysis (NTA), using a NanoSight LM14 instrument and NanoSight v.2.3 software. The water used to perform the ecotoxicity assays was also evaluated through the same analyses after exposing the fish to the nanoparticles, in order to identify any changes resulting from the exposure. Also, scanning electron microscopy (SEM) was performed in order to investigate the morphology and size distribution of the nanoparticles. Nanoparticles suspensions were diluted (1:50 v:v), dried in a silicon grids and analyzed by scanning electron microscopy (EVO-LS-15, Carls Zeiss). SEM was operated at 20 kV of high voltage with a spot size between 3.0–4.0 and working distance (WD) of 8.5 mm. Size distribution histogram of the AgNPs was calculated using ImageJ and GraphPad Prism 7.0 software, and approximately 300 nanoparticles were counted in each study.
Evaluation of cell viability through mitochondrial activity (MTT)
For the evaluation of cell viability, the mitochondrial activity was determined by the reduction of MTT (4-5-dimethylthiazolyl-2)-2,5-diphenyltetrazolium bromide) salt. The cells (3T3, HaCat, A549, V79 and HeLa) were transferred to 96-well plates, at a concentration of 2 × 104 cells per well, and were kept at 37 °C for 24 h, with 5% CO2. After adherence, the cells were exposed for 24 h to the AgNPs at decreasing concentrations (3 × 109, 108, 107, 106, 105, 104, 103, and 102 NPs.mL−1). The cultures were then washed with PBS, followed by addition of 100 μL of MTT solution (0,5 mg mL−1) to each well and incubation for 3 h at 37 °C, with 5% CO2. After the incubation period, the culture medium was removed and 100 μL of Dimethyl Sulfoxide (DMSO) was added to each well. The readings were performed at 570 nm using a microplate reader (Evolution 201, Thermo Scientific).
Cell viability, apoptosis and necrosis by imaging cytometry analyses
Imaging cytometry was used to evaluate cell viability, apoptosis, and necrosis. The cells (A549 and V79) were exposed to the nanoparticles at a concentration of 3 × 108 NPs.mL−1 for 1 h, trypsinized and centrifugated. The supernatant was discarded and the samples were prepared using a Tali™ Apoptosis Kit (Annexin V AlexaFluor® 488 and Propidium Iodide, Invitrogen), according to the manufacturer’s instructions. The readings were performed using Tali™ imaging cytometry.
Evaluation of DNA damage by comet assay
The comet assay was adapted from Azqueta et al.40, exposing 3T3, A549, V79 and HeLa cell lines to nanoparticles at a concentration of 3 × 108 NPs.mL−1. The cells were classified by visual scoring, using 0 to 4 categories, where 0 represents damage absence and 4 indicates the most intense damage41. The analyses were performed in duplicate, with observation of at least 200 randomly selected cells. The final scores were obtained by multiplying the number of cells allocated to each category by the category number. The damage index (DI) was calculated by dividing the sum of the values for each category by the total number of cells analyzed.
Evaluation of antimicrobial potential using minimum inhibitory concentration (MIC) assays
MIC assays were performed with the E. coli, S. aureus, C. albicans, and P. aeruginosa strains grown in Mueller-Hinton broth for 24 h. After growth, 10 µL of microorganism suspensions at a concentration of 5 × 105 CFU.mL−1 were added to 96-well plates with culture broth and decreasing concentrations of AgNpE and AgNpE (3 × 109 to 102 NPs.mL−1). The plate was incubated at 37 °C for 24 h, followed by addition of 10 μL of Resazurin (6.75 mg.mL−1) to each well and incubation for a further 24 h. The results were obtained by colorimetric analysis.
Ecotoxicity evaluation by Allium cepa assays
Previously germinated roots of Allium cepa were exposed to AgNpR and AgNpE at a concentration of 3 × 108 NPs.mL−1 during 24 h. After exposure, the roots were fixed with Carnoy’s solution (3:1 ethyl alcohol and acetic acid, v-v), washed, and submitted to acid hydrolysis with 1 mol.L−1 hydrochloric acid at 60 °C for 9 min. Coloration was performed by reaction with Schiff reagent for 2 h in the dark at room temperature, and the slides were prepared by separating the meristematic region, adding a drop of 2% Acetic Carmine dye and smashing to separate the cells. Analyses were performed in triplicate with observation of at least 1,500 cells. Mitotic index (MI) and alteration index (AI) were calculated employing Eqs 1 and 2, respectively.
Evaluation of ecotoxicity in zebrafish
Fish exposure and removal of biological material
The fish were separated into different aquaria (n = 15 per aquarium) and exposed to the nanoparticles at concentrations of 3 × 105, 3 × 106, 3 × 107, and 3 × 108 NPs.mL−1 for 72 h, after which they were anesthetized using benzocaine (250 mg.L−1). Animals were then sacrificed by painless medulla section (Resolution no. 1000, March 11th, 2012: Procedures and Methods of Euthanasia in Animals), from which 10 µL of blood were collected into tubes containing fetal bovine serum and Ethylenediaminetetraacetic acid (EDTA). The organs (gills, brain, heart, liver, skin, and muscle) were then collected and stored according to the analyses to be performed.
Quantification of proteins and determination of enzymatic activity
For the biochemical analysis, the organs (brain, heart, liver, skin, and muscle) collected from zebrafish were homogenized in 0.5 mL of Phosphate-Buffered Saline (PBS) buffer (pH 7.2), the mixture was centrifuged at 12,000 g for 20 min at 4 °C, and the supernatant was collected in tubes. This material was used immediately or stored at −80 °C for subsequent use.
Proteins were quantified using the method of Bradford42. The sample and the solution were applied to the plate and kept for 5 min in the absence of light, followed by reading of the absorbance at 595 nm using a Tecan Infinite M200 Pro plate reader.
In order to investigate the possible use of zebrafish in biomonitoring, it was evaluated the enzymatic activity of catalase (CAT), glutathione peroxidase (GPx), and glutathione S-transferase (GST), which have been linked to the redox cycle and detoxification processes.
The CAT activity was determined as described by Aebi43, with the sample dispersed in reaction buffer (1 M Tris-HCl and 5 mmol.L−1 EDTA) in a quartz cuvette. The absorbance was measured at 240 nm, at 15 s intervals during 2 min, using a PerkinElmer Lambda 35 spectrophotometer.
The GPx activity was evaluated as described by Beutler44. A 20 μL aliquot of the supernatant of the protein sample was pipetted into a 96-well plate, followed by addition of 140 μL of reaction medium (2 mmol.L−1 sodium azide, 0.2 mmol.L−1 NADPH, 2 mmol.L−1 GSH, 1 U.mL−1 glutathione reductase, and 14.45 mL of 0.1 mol.L−1 PBS, at pH 7). After 2 min, 40 μL of hydrogen peroxide solution was added and the absorbance was measured at 340 nm using the Tecan Infinite M200 Pro microplate reader.
The GST activity was evaluated according to Keen et al.45, with modifications. A 20 μL aliquot of the protein sample was added to a well of the microplate, followed by addition of 180 μL of reaction medium (1.5 mmol.L−1 GSH, 2 mmol.L−1 CDNB (1-chloro-2,4-dinitrobenzene), and 0.1 mol.L−1 PBS, at pH 6.5). The absorbance was measured at 340 nm. The activity was calculated using the molar extinction coefficient for CDNB (9.6 mmol−1.cm−1).
These biomarkers were selected because they act in the main enzymatic defenses of the organisms and are the most sensitive46.
Evaluation of DNA damage using comet assay in vivo
For the performance of the in vivo comet assay, blood and gills from zebrafish were collected into tubes containing fetal bovine serum and EDTA, homogenized and used according to the method previously described for in vitro comet assay.
Statistical analyses
Statistical analysis was performed using one-way analysis of variance (ANOVA) and the Tukey-Kramer test, with a significance level of p < 0.05, by GraphPad Prism 7.0 software.
Availability of data and materials
The datasets used and/or analyzed during the current study are available from the corresponding author on reasonable request.
Results and Discussion
Physicochemical characterization of the nanoparticles
The nanoparticles were characterized immediately after the synthesis and after fish exposure assays. The first technique performed was UV-Vis spectroscopy in order to confirm the synthesis. Bands of 384 and 380 nm were obtained for AgNpE and AgNpR, respectively (data not shown). These bands indicate the surface plasmon resonance of silver nanoparticle (Ago), confirming that a successful synthesis was performed47.
The initial analyses showed that the AgNpR were larger and more stable than the AgNpE, while the concentration of AgNpE was slightly larger than the AgNpR, as shown by NTA (Table 1) and SEM images (Fig. 1). Therefore, it did not influence in our studies since the concentrations of the nanoparticles in all subsequent assays were adjusted to 3 × 1010 NPs.mL−1 in aqueous medium (corresponding to 3.4 mg.L−1). Durán et al.48 and Chandran et al.49 also obtained biogenic nanoparticles with similar sizes ranging between 130 and 300 nm (measured by DLS) and zeta potentials close to 30 mV, corroborating with our studies.
The morphology of NPs was evaluated by SEM and it was observed that AgNpE are more spherical than AgNpR (Fig. 1), probably due to the differences in chemical composition of each reducing agent and/or due to the distinct interactions between the biomolecules existing in the different parts extracted from the plant. In addition, AgNPs did not present aggregates, and the size distribution given by the histogram showed that AgNpR presents a larger population in relation to AgNpE.
Toxicity evaluation using in vitro assays with different cell lines
Viability assays through mitochondrial metabolism performed using the MTT salt showed that AgNpR was less cytotoxic than AgNpE towards all the cell lines (Fig. 2a). The IC50 values obtained for A549, HeLa and V79 cell lines exposed to AgNpE were 3.75 × 102, 2.78 × 106, and 1.38 × 108 NPs.mL−1, respectively. None of the nanoparticles presented cytotoxicity towards HaCat. Imaging cytometry evaluation of the effects of the nanoparticles at a concentration of 3 × 108 NPs.mL−1 on V79 and A549 showed death by necrosis of 98% of the cells, with V79 being slightly more resistant than A549 (Fig. 2b).
In addition to the effects of nanoparticles on the functions and survival of cells, it is important to consider possible damage to the genetic material, so evaluation of genotoxicity and DNA damage was performed using the same concentrations employed in the apoptosis and necrosis assays (3 × 108 NPs.mL−1) (Fig. 2c).
The greater potential cytotoxicity of AgNpE, compared to AgNpR, could have been due to the smaller size of the particles, as suggested previously50,51,52. Another possible contributing factor was that the biogenic AgNPs were synthesized using different solutions (leaf extract and root infusion). As discussed previously53, different types of biogenic nanoparticles have their own unique characteristics, and the potential toxicity and activity can be affected by the presence of coatings on the nanoparticles.
The types of cells employed could also have contributed to the observed differences, since it has been found that tumor cells present greater sensitivity to AgNPs54. Therefore, the results obtained using the HeLa and A549 tumor cell lines suggested that the AgNpE nanoparticles could possibly be used to combat tumor cells, supporting other studies which indicated that biogenic AgNPs might be one option for the treatment of diseases such as cancer55,56,57.
Although the comet results revealed DNA damage, which could be indicative of future death by apoptosis, this did not occur, and necrosis appeared to be the main cause of cell death (Fig. 2b). The results concerning necrosis are important, because many tumor cells possess mechanisms of resistance to apoptosis, so these nanoparticles could offer an alternative in the fight against tumor cells58,59,60,61.
As found for the other cell lines, the A549 and HeLa cells exhibited greater numbers of DNA breaks when exposed to AgNpR, compared to exposure to AgNpE. The viability results showed that these same cells (A549 and HeLa) presented cell death with low IC50 values when treated with AgNpE, so it is possible that the cells died and for this reason it was not possible to detect DNA damage.
Evaluation of antimicrobial potential using minimum inhibitory concentration (MIC) assays
The MIC analyses showed that at concentrations of 106 NPs.mL−1, both AgNpE and AgNpR were inhibitory towards E. coli, S. aureus, and C. albicans, while E. coli was inhibited by the AgNpR nanoparticles at 105 NPs.mL−1. These results were in agreement with other studies demonstrating the bactericidal potential of these nanomaterials23,62,63. Evaluation of the pure extract of Althaea officinalis revealed no bactericidal or fungicidal activity, as found previously by Shah64.
The activity of AgNPs is similar to that of silver ions, acting at different sites, rather than according to a specific pathway, with the main mechanisms being the generation of reactive oxygen species, enzymatic inhibition, damage to the genetic material, and disruption of the mechanisms of protein synthesis65,66,67,68.
Ecotoxicity evaluation using Allium cepa
The exposure of Allium cepa to both AgNpE and AgNpR at a concentration of 3 × 108 NPs.mL−1 resulted in mitotic indexes increase (Fig. 3), however there was no difference between the two exposures. Similar findings were reported by Lima et al.69, for biogenic nanoparticles based on the fungus Fusarium oxysporum.
Both AgNpE and AgNpR showed higher aberration indexes, with AgNpE being slightly more toxic than AgNpR.
Ecotoxicity evaluation using zebrafish
Determination of the physicochemical characteristics of the nanoparticles after the fish exposure showed diameter increase, indicating agglomeration (Fig. 4a), which can be due to interaction of the nanoparticles with the environment. According to Yin et al.70, water chemistry has a major impact on the aggregation of AgNPs, due to the combined effects of organic materials and electrolytes.
Another factor that influences nanoparticle characteristics is the presence of light, which can alter the particle morphology and increase sedimentation rates. Metabolic factors involving the fish should also be considered, since these could have modified the nanoparticles. The diameter increase may result from oxidation of the nanoparticles in the aquatic environment71, however it may also be a positive factor, since large aggregates tend not to affect the cells of organisms.
Exposure of zebrafish to AgNpE and AgNpR at 3 × 108 and 3 × 107 NPs.mL−1 resulted in death of the fish after 24 h, indicating high toxicity. At 3 × 106 NPs.mL−1, the exposure of the fish to AgNpE led to death, while animals exposed to AgNpR presented greater damage in the gill cells through comet assay (Fig. 4d).
In contrast to the effects observed at the 10-fold higher concentration, exposure of the fish to AgNpE and AgNpR at 3 × 105 NPs.mL−1 resulted in a greater number of DNA damage in the blood cells, compared to the gill cells, suggesting that a lower availability of nanoparticles reduced their accumulation in the gills facilitating the entry of nanoparticles into the organism, reaching blood cells.
It has been shown that nanoparticles can generate oxidative stress in fish, which typically leads to apoptosis, and that the Ag+ ions released can cause rupture damage in the system, resulting in interaction with membrane proteins and disturbance of cellular homeostasis72,73,74. Osborne et al.52 found nanoparticles accumulated in the gills and intestines, which resulted in increased production of mucus in the attempt to cleanse the organs, consequently hindering respiration and leading to death.
The biochemical analyses showed that CAT activity increased in the heart, liver, muscle, and skin (Fig. 5a). As expected, the highest activity occurred in the liver, indicating that CAT redox system was activated following the exposure. The brain showed no significant alteration, although catalase levels in this organ are normally extremely low (Fig. 5a).
The GPx analyses showed that in most of the organs, the activity of this enzyme remained stable for both AgNpE and AgNpR, except in the skin of fish exposed to AgNpR, where there was an increase of its activity, and in the heart where a decrease was observed for both the nanoparticles (Fig. 5b).
The GST activity showed changes in all the organs, with decrease in the brain, muscle, skin, and liver (Fig. 5c). GST consists of a group of enzymes that are widely distributed in the tissues, which catalyze the conjugation of GSH and compounds with reactive electrophilic groups (including xenobiotics such as metals and pesticides). The decreased GST activities in these tissues could therefore have been related to lower levels of GSH.
Catalase (CAT) is responsible for reduction of hydrogen peroxide, so an increase of its activity in tissues can be indicative of oxidative stress. In the liver, it may reflect the presence of high levels of H2O2, associated with the accumulation and detoxification of various environmental pollutants. Oxidative stress is mostly controlled by means of CAT and superoxide dismutase (SOD) pathways. SOD and CAT respond rapidly during oxidative stress, as found in the marine gastropod Onchidium struma exposed to copper75.
Several studies have reported the exposure of aquatic organisms to nanoparticles. Choi et al.76 observed a significant decrease in CAT activity in the tissues of zebrafish exposed to commercial AgNPs, however, McCarthy et al.77 and Buffet et al.78 obtained results similar to those found in the present study by using other species of aquatic animals (Crassostrea virginica, Hediste diversicolor and Scrobicularia plana).
The enzyme GPx removes H2O2, which is a precursor of reactive oxygen species (ROS), hence protecting the cell membrane against lipid peroxidation. Decreased GPx activity in the heart could be a sign of toxicity associated with the production of ROS induced by the presence of nanoparticles. An explanation for this decrease/inhibition could be related to a shortage of GSH in the organ. CAT and GSH act in the reduction of H2O2, suggesting that this mechanism was activated due to the formation of large amounts of this compound, since the amount of GPx is dependent on the GSH substrate, whose function is to protect cells from the free radicals produced by oxidation.
The levels of reduced glutathione (GSH) are mainly determined by equilibrium among GSH synthesis, conjugation by glutathione S-transferase (GST), oxidation by non-enzymatic mechanisms or by GPx, and reduction of oxidized glutathione (GSSG) to GSH by glutathione reductase (GR)79. Similar results were obtained by Masoud et al.80 for continuous exposure of organisms to AgNPs, while other studies have found the opposite effect, with decreases of GPx activity in tilapia exposed to AgNPs at concentrations of 2 and 4 mg.L−1 for 15 days81.
Increases in GST levels are directly linked to the processes of detoxification in organisms82, and in the present work, this behavior was only observed in the heart. The increased GST activity in the heart could indicate that GSH was used by this organ in conjugation catalyzed by GST, leading to a decrease in GSH due to GPx activity. However, decreases in GST have been reported in organisms exposed to pesticides, as in the work of Sillapawattana et al.83, where arthropods were exposed to nanoparticles and the level of GST decreased at higher contaminant concentrations. Arle et al.84 reported the same behavior in zebrafish embryos exposed to AgNPs.
Increased activity of GST in the liver has been reported previously in studies of fish85 and could indicate an attempt by the organism to adapt, since it probably reduces the possibility of compounds binding to other macromolecules such as DNA. GST is a scavenger of hydroxyl radicals, and its lack can lead to disastrous consequences in organisms, such as lysis of erythrocytes, as described in Adamussium colbecki by Cogo et al.86.
Although there were no major changes in GST levels, the comet assays showed increased DNA damage in zebrafish blood cells exposed to 3 × 105 NPs.mL−1 (Fig. 5c), highlighting the importance of this enzyme in the biotransformation of compounds. Its activity could potentially be employed as a good biological marker of contamination by metallic nanoparticles.
Bacchetta et al.87 found no oxidative stress in zebrafish exposed to AgNPs. Poynton et al.88 suggested three mechanisms of toxicity of AgNPs: (i) toxicity following the release of Ag+ ions in aquatic environments; (ii) toxicity caused by metal ions according to independent mechanisms; and (iii) the transport into the cell of Ag+ ions released from nanoparticles that remain outside the cell.
In order to investigate the toxicity of silver nanoparticles in aquatic systems, some studies using algae as target organism were performed. Zhang et al.89,90 have shown that silver nanomaterials could induce toxicity being this cellular toxicity caused by the modulation of reactive oxygen species (ROS) in cells as a result of the faster release of Ag species, however these nanoparticles were not biogenic.
Conclusions
Althaea officinalis acts as an effective reducing and stabilizing agent for the biogenic synthesis of silver nanoparticles, which present adequate physicochemical characteristics. Even though this new nanomaterial presents potential for the control of microrganisms and tumoral cells, it is therefore necessary to consider the possible toxicity of these formulations when in direct contact with organisms or released in environment. AgNpE was slightly more toxic than AgNpR, and both materials exhibited physicochemical changes during exposure assays. The results demonstrated the importance of performing toxicological and ecotoxicological evaluations of new nanoparticles, since although they may provide the desired bactericidal effect, their toxicity could threaten the survival of organisms.
The current study highlighted the possible differences in the response of tissues to silver nanoparticles exposures, depending the biogenic AgNPs species and their concentrations. Silver nanoparticles caused oxidative stress followed by the increase in CAT and decrease in GPx and GST even in the lower concentration and in almost all tissues. In this circumstance, it seems to reflect an aggravation status due to reduced cell protection ability to protect fish against ROS under stress conditions caused by these nanoparticles. The findings show that the enzymes associated with biotransformation and detoxification can be used as biomarkers in zebrafish exposed to contamination by nanoparticles.
References
Rai, M., Gade, A. & Yadav, A. Biogenic nanoparticles: an introduction to what they are, how they are synthetized and their applications. In: Rai, M. & Durán, N. editors Metal Nanoparticles and Microbiology Berlin: Springer; p. 1–14 (2011).
Handy, R. D., Owen, R. & Valsami-Jones, E. The ecotoxicology of nanoparticles and nanomaterials: current status, knowledge gaps, challenges, and futures needs. Ecotoxicology. 17, 315–325 (2008).
Maruyama, C. R. et al. Nanoparticles based on chitosan for the combined herbicides Imazapic and Imazapyr. Sci. Rep. 6, 1–15 (2016).
Pasquoto-Stigliani, T. et al. Nanocapsules containing Neem (Azadirachtaindica) oil: Development, characterization, and toxicity evaluation. Sci. Rep. 7, 1–12 (2017).
Edmundson, M., Capeness, M. & Horsfall, L. Exploring the potential of metallic nanoparticles within synthetic biology. N. Biotechnol. 31, 572–578 (2014).
Moody, V. V., Siwale, R., Singh, A. & Mody, H. R. Introduction to metallic nanoparticles. J. Pharm. Bioallied Sci. 2, 282–289 (2010).
Haberl, N. et al. Cytotoxic and proinflammatory effects of PVP-coated silver nanoparticles after intratracheal instillation in rats. Beilstein J. Nanotechnol. 4, 933–940 (2013).
Durán, N. et al. Potential use of silver nanoparticles on pathogenic bactéria, their toxicity and possible mechanisms of action. J. Braz. Chem. Soc. 21, 949–59 (2010).
Salvioni, L. et al. Negatively charged silver nanoparticles with potent antibacterial activity and reduced toxicity for pharmaceutical preparations. Int. J. Nanomed. 12, 2517–2530 (2017).
Appapalam, S. T. & Panchamoorthy, R. Aerva Ianata mediated phytofabrication of silver nanoparticles and evaluation of their antibacterial activity against wound associated bacteria. J. Taiwan Inst. Chem. Eng. 78, 539–551 (2017).
Huang, X. et al. Green synthesis of silver nanoparticles with high antimicrobial activity and low cytotoxicity using catechol-conjugated chitosan. RSC Advances 6, 64357–64363 (2016).
Huang, X., Bao, X., Wang, Z. & Hu, Q. A novel silver-loaded chitosan composite sponge with sustained silver release as a long-lasting antimicrobial dressing. RSC Advances 7, 34655–34663 (2017a).
Huang, X., Bao, X., Liu, Y., Wang, Z. & Hu, Q. Catechol-functional chitosan/silver nanoparticle composite as a highly effective antibacterial agent with species-specific mechanisms. Scientific Reports 7, 1–10 (2017b).
Saha, N. & Gupta, S. D. Low-dose toxicity of biogenic silver nanoparticles fabricated by Swertiachirataon roots tips and flower buds of Allium cepa. J. Hazard. Mat. 330, 18–28 (2017).
Guilger, M. et al. Biogenic silver nanoparticles based on trichoderma harzianum: synthesis, characterization, toxicity evaluation and biological activity. Sci. Rep. 7, 1–13 (2017).
Ahmed, S., Ahmad, M., Swami, B. L. & Ikram, S. A review on plants extract mediated synthesis of silver nanoparticles for antimicrobial applications: A green expertise. J. Adv. Res. 7, 17–28 (2016).
Rico, C. M., Majumdar, S., Duarte-Gardea, M., Peralta-Videa, J. R. & Gardea-Torresdey, J. L. Interaction of nanoparticles with edible plants and their possible implications in the food chain. J. Agric. Food Chem. 59, 3485–3498 (2011).
Durán, N. et al. Mechanistic aspects in the biogenic synthesis of extracellular metal nanoparticles by peptides, bactéria, fungi, and plants. Appl. Microbiol. Biotechnol. 5, 3249–3258 (2011).
Chung, I. M., Park, I., Seung-Hyun, K., Thiruvengadam, M. & Rajakumar, G. Plant-mediated synthesis of silver nanoparticles: Their characteristic properties and therapeutic applications. Nanoscale Res. Lett. 11(11), 40 (2016).
Makarov, V. V. et al. “Green” Nanotechnologies: synthesis of metal nanoparticles using plants. Acta Naturae. 1, 35–44 (2014).
Hola, K., Markova, Z., Zoppelaro, G., Tucek, J. & Zboril, R. Tailored functionalization of iron oxide nanoparticles dor MRI, drug delivery, magneetic separation and immobilization of biosubstances. Biotechnol. Adv. 33, 1162–1176 (2015).
Zahir, A. A. et al. Green synthesis of silver and titanium dioxide nanoparticles using Euphorbia prostrataI extract show shift from apoptosis to G0/G1 arrest followed by necrotic cell death in. Leishmaniadonovani. Antimicrob. Agents Chemother. 8, 4782–4799 (2015).
Singh, R. et al. Chemical and biological metal nanoparticles as animycobacterialagentes: A comparative study. Int. J. Antimicrob. Agents. 46, 183–88 (2015).
Duan, H., Wang, D. & Li, Y. Green chemistry for nanoparticle synthesis. Chem. Soc. Rev. 16, 5778–5792 (2015).
Shende, S., Ingle, A. P., Gade, A. & Rai, M. Green synthesis of Cooper nanoparticles by citrus medica Linn, (Idilimbu) juice and its microbial activity. World J. Microbiol. Biotechnol. 31, 865–73 (2015).
El-Kassas, H. Y. & Ghobrial, M. G. Biosynthesis of metal nanoparticles using three marine plant species: anti-algal efficiencies against “Oscillatoria simplicíssima”. Environ. Sci. Pollut. Res. 24, 7837–7849 (2016).
Logaranjan, K., Raiza, A. J., Gopinath, S. C. B., Chen, Y. & Pandian, K. Shape- and size-controlled synthesis of silver nanoparticles using Aloe vera plant extract and their antimicrobial activity. Nanoscale Res. Lett. 11, 1–9 (2016).
Miri, A., Dorani, N., Darroudi, M. & Sarani, M. Green synthesis of silver nanoparticles using Salvadora pérsica L. and its antibacterial activity. Cell Mol. Biol. 62, 46–50 (2016).
Martinez-Cabanas, M., López-Garcia, M., Barriada, J. L., Herrero, R. & Sastre de Vicente, M. E. Green synthesis of iron oxide nanoparticles. Development of magnetic hybrid materials for efficient As (V) removal. Chem. Eng. J. 301, 83–91 (2016).
Vu, T. T. et al. In vitro antibacterial activity of selecter medicinal plants traditionally used in Vietnam against human pathogenic bacteria. BMC Complementary Altern. Med. 16, 1–6 (2016).
Balaz, M. et al. Plant-Mediated synthesis of silver nanoparticles and their stabilization by wet stirred media milling. Nanoscale Res. Lett. 12, 1–9 (2017).
Mittal, A. K., Kaler, A., Mulay, A. V. & Banerjee, U. C. Synthesis of gold nanoparticles using whole cells of Geotrichumcandidum. J. Nanopart. 2013, 1–6 (2013).
Karthik, L., Kumar, G., Kirthi, A. V., Rahuman, A. A. & Bhaskara Rao, A. V. Streptomyces sp. LK3 mediated synthesis of silver nanoparticles and it’s biomedical application. Bioprocess Biosyst. Eng. 37, 261–267 (2016).
Golinska, P. et al. Biogenic synthesis of metal nanoparticles from actinomyceles: Biomedical applications and cytotoxicity. Appl. Microbiol. Biotechnol. 98, 8083–8097 (2014).
Benelli, G. Green synthesized nanoparticles in the fight against mosquito-borne diseases and câncer- a brief review. Enzyme Microb. Technol. 95, 58–68 (2016).
Deters, A. et al. Aqueous extracts and polysaccharides from Marshmallow roots (Althaea officinalis L.): Cellular internalisation and stimulation of cell physiology of human epitelial cells in vitro. J. Ethnopharmacol. 127, 62–69 (2010).
Medicatriz, cosméticos. Althéia. Available Accessed 28 Aug, http://medicatriz.com.br/altheia (2016).
CLSI (Clinical and Laboratory Standards Institute). Performance Standards for Antimicrobial Disk Susceptibility Tests. Approved Standard. 8th. ed. Franklin Lakes, NJ: CLSI; (CLSI document M2-A8CLSI) (2003).
Logeswari, P., Silambarasan, S. & Abraham, J. Synthesis of silver nanoparticles using plant extract and analysis of their antimicrobial property. Journal Saudi Chem. Soc. 19, 311–317 (2012).
Azqueta, A., Gutzkow, K., Brunborg, G. & Collins, A. R. Towards a more reliable comet assay: optimising agarose concentration, unwinding time and eletrophoresis conditions. Mutat. Res. 724, 41–45 (2011).
Collins, A. R., Fleming, I. M. & Gedik, C. M. In vitro repair of oxidative and ultraviolet-induced DNA damage in supercoiled nucleoid DNA by human cell extract. Biochim. Biophys. Acta. 22, 724–727 (1994).
Bradford, M. A rapid and sensitive method for the quantitation of microgram quantities of protein utilizing the principle of protein-dye binding. Anal. Biochem. 72, 248–254 (1976).
Aebi, H., Wyss, S., Scherz, B. & Skvaril, F. Heterogeneidy of Erythrocyte Catalase II. Eur. J. Biochem. 7, 248–254 (1974).
Beutler, E. Superoxide dismutase. In: Beutler, E, editor. Red cell metabolism. A manual of biochemical methods. New York:Grune & Stratton; p. 83–5 (1984).
Keen, J. H., Habig, W. H. & Jakobi, W. B. Mechanism of the several activities of the glutathione S-transferase. J. Biol. Chem. 251, 6183–6188 (1976).
Di Giulio, R. & Meyer, J. N. Reactive oxygen species and Oxidative stress. In: Di Giulio, R. T. & Hinton, D. E. editors The toxicology of fishes, CRC Pressp. p. 273–324 (2008).
Durán, N., Cuevas, R., Cordi, L., Rubilar, O. & Diez, M. C. Biogenic Silver nanoparticles associated with silver cloride nanoparticles produced by laccase from Trametes versicolor. Springler Plus. 3, 1–7 (2014).
Chandran, S. P., Chaudhary, M., Pasricha, R., Ahmad, A. & Sastry, M. Synthesis of gold nanotriangles and silver nanoparticles using Aloe veraplant extract. Biotecnol. Prog. 22, 577–583 (2006).
Haes, A. J. et al. Plasmonic materials for surface-enhanced sensing and spectroscopy. MRS Bulletin 30, 368–375 (2005).
Park, M. V. D. Z. et al. The effect of particle size on the cytotoxicity, inflammation, developmental toxicity and genotocixity of silver nanoparticles. Biomaterials. 32, 9810–9817 (2011).
Gliga, A. R., Skoglund, S., Wallinder, I. Q., Fadeel, B. & Karlsson, H. L. Size-dependent cytotoxicity of silver nanoparticles in human lung cells: the hole of cellular uptake, aglomeration and Ag release. Part. Fibre Toxicol. 11, 1–17 (2014).
Osborne, O. J. et al. Organ-specific and size-dependant Ag nanoparticles toxicity in gills and intestines of adult zebrafish. ACS Nano. 9, 9573–9584 (2015).
Lima, R., Seabra, A. B. & Durán, N. Silver nanoparticles: a brief review of cytotoxicity and genotoxicity of chemically and biogenically synthetized nanoparticles. J. Appl. Toxicol. 32, 867–879 (2012).
Ortega, F. G. et al. Study of antitumor activity in breast cell lines using silver nanoparticles produced by yeast. Int. J. Nanomedicine. 10, 2021–2031 (2015).
Jeyaraj, M. et al. Biogenic silver nanoparticles for cancer treatment: an experimental report. Colloids Surf., B. 106, 86–92 (2013).
Ong, C. et al. Silver nanoparticles in cancer: therapeutic efficacy and toxicity. Curr. Med. Chem. 20, 772–781 (2013).
Duraipandy, N., Lakra, L., Kunnavakkam, V. S., Samanta, D. K. P. S. & Kiran, M. S. Caging of plumbagin on silver nanoparticles imparts selectivity and sensitivity to plumbagin for targeted cancer call apoptosis. Metallomics. 11, 2025–2033 (2014).
Cheng, M. et al. Synthesis of glycyrrhetinic acid-modified chitosan 5-fluorouracil nanoparticles and its inhibiton of liver cancer characteristics in vitro and in vivo. Mar Drugs 11, 3517–3536 (2013).
Khan, M. et al. Apoptosis inducing ability of silver decorated highly reduce graphene oxide nanocomposites in a549 lung cancer. Int. J. Nanomedicine. 11, 873–883 (2014).
Morioka, S. et al. TAK1 kinase switches cell fate from apoptosis to necrosis following TNF stimulation. J. Cell. Biol. 204, 607–623 (2014).
Moriwaki, K. & Chan, F. K. RIP3: a molecular switch for necrosis and inflammation. Genes Dev. 15, 1640–1649 (2013).
Li, G. et al. Fungus-Mediated Green Synthesis of Silver Nanoparticles Using Aspergillus terreus. Int. J. Mol. Sci. 13, 466–476 (2012).
Kora, A. J. & Sashidar, R. B. Biogenic silver nanoparticles synthetized with rhamnogalacturonan gum: Antibacterial activity, cytotoxicity and its mode of action. Arabian J. Chem. 11, 313–323 (2014).
Shah, S. M. A. et al. Pharmacological activity of Althaea officinalis L. J. Med. Plants Res. 5, 5662–5666 (2011).
Kumar, S., Aaron, J. & Sokolov, K. Directional conjugation of antibodies to nanoparticles for synthesis of multiplexed optical contrast agents with both delivery and targeting moieties. Nat. Protoc. 3, 314–320 (2008).
Li, W. R. et al. Antibacterial effect of silver nanoparticles on Staphyloccocus aureus. BioMetals 24, 135–141 (2011).
Rai, M. K., Deshmukh, S. D., Ingle, A. P. & Gade, A. K. Silver nanoparticles: the powerful nanoweapon against the multidrug-resistant bacteria. J. Appl. Microbiol. 112, 841–852 (2012).
Pandey, S. & Mishra, S. B. Catalytic reduction of p-nitrophenol by using platinum nanoparticles stabilized by guar gum. Carbohydr. Polym. 113, 525–531 (2014).
Lima, R. et al. Cytotoxicity and genotoxicity of biogenic silver nanoparticles. J. Phys. Conf. Ser. 429, 1–9 (2013).
Yin, Y. et al. Water chemistry controlled aggregation and photo-transformation of silver nanoparticles in environmental waters. J. Environ. Sci. (China). 31, 116–125 (2015).
Reeves, J. F., Davies, S. J., Dodd, N. J. & Jha, A. N. Hydroxil radicals (*OH) are associated with titanium dioxide (TiO(2)) nanoparticle-induced cytotoxicity and oxidative DNA damage in fish cells. Mutat. Res. 640, 113–122 (2008).
Su, Z. et al. Heat stress preconditioning improves cognitive outcome after diffuse axonal injury in rats. J. Neurotrama. 26, 1695–1706 (2009).
Yun, J. M., Afaq, F., Khan, N. & Mukhtar, H. Delphinidin, and anthocyanidin in pigmented fruits and vegetables, induces apoptosis and cell cycle arrest in human colon cancer HCT116 cells. Mol. Carcinog. 48, 260–270 (2009).
Girilal, M., Krishnakumar, V., Poornima, P., Fayaz, A. M. & Kalaichelvan, P. T. A comparative study on biologically and chemically synthesized silver nanoparticles induced Heat Shock Proteins on fresh water fish Oreochromis niloticus. Chemosphere. 139, 461–468 (2015).
Li, X. B. et al. Toxic effect of copper on antioxidative and metabolic enzymes of the marine gastropod. Onchidium struma. Arch. Environ. Contam. Toxicol. 54, 776–784 (2009).
Choi, J. E. et al. Induction of oxidative stress and apoptosis by silver nanoparticles in the liver of adult zebrafish. Aquat. Toxicol. 100, 151–159 (2010).
McCarthy, M. P., Carroll, D. L. & Ringwood, A. H. Tissue specific responses of oysters, Crossostrea virginica, to silver nanoparticles. Aquat. Toxicol. 138–139, 123–128 (2013).
Buffet, P. E. et al. A marine mesocosm study on the environmental fate of silver nanoparticles and toxicity effects on two endobenthic species: the ragworm Hediste diversicolor and the bivalve mollusk Scrobicularia plana. Sci. Total Environ. 470–471, 1151–1159 (2014).
Peña-Llopis, S., Ferrando, M. D. & Peña, J. B. Increased recovery of brain acetylcholinesterase activity in dichlorvos-intoxicated European eels Anguilla anguilla by bath treatment with N-acetylcysteine. Dis. Aquat. Organ. 55, 237–245 (2003).
Negahdary, M., Chelongar, R., Zadeh, S. K. & Ajdary, M. The antioxidant effects of silver, gold, and zinc oxide nanoparticles on male mice in in vivo condition. Adv. Biomed. Res. 4, 69 (2015).
Afifi, M., Saddick, S. & Abu-Zinada, O. A. Toxicity of silver nanoparticles on the brain of Oreochromis niloticus and Tilapia zilli. Saudi. J. Biol. Sci. 23, 754–60 (2016).
Wang, C., Lu, G., Cui, J. & Wang, P. Sublethal effects of pesticide mixtures on selected biomakers of Carassius auratus. Environ. Toxicol. Pharmacol. 28, 414–9 (2009).
Sillapawattana, P., Gruhlke, M. & Schaffer, A. Effect of silver nanoparticles on the standard soil arthropod Folsomia cândida (Collembola) and the eukaryote model organism Saccharomyces cerevisiae. Environ. Sci. Eur. 28(27), 1–12 (2016).
Arle, R. V. et al. Molecular mechanisms of toxicity of silver nanoparticles in Zebrafish embryos. Environ. Sci. Technol. 47, 8005–8014 (2013).
Goksoyr, A. & Husoy, A. Immunochemical approaches to studies of CYP1A localization and induction xenobiotios in fish. In: Braunbeck, S., Hinton, D. E. & Streit, B. editors Fish ecotoxicology, Birkhüser Basel:Springer, p. 165–202 (1998).
Cogo, A. J. D., Siqueira, A. F., Ramos, A. C., Cruz, Z. M. A. & Silva, A. G. Utilização de enzimas do estresse oxidativo como biomarcadores de impactos ambientais. Natureza online. 7, 37–2 (2009).
Baccheta, C. et al. Toxicological effects induced by silver nanoparticles in zebra fish (danio rerio) and in the bacteria communities living at their surface. Bull. Environ. Contam. Toxicol. 4, 1883–7 (2016).
Poynton, H. C. et al. Toxicogenimic responses of nanotoxicity in Daphnia magna exposed to silver nitrate and coated silver nanoparticles. Environ. Sci. Technol. 11, 6288–6296 (2012).
Zhang, L. et al. Uptake and effect of highly fluorescent silver nanoclusters on Scenedesmus obliquus. Chemosphere 153, 322–331 (2016).
Zhang, L., Goswani, N., Xie, J., Zhang, B. & He, Y. Unraveling the molecular mechanism of photosynthetic toxicity of highly fluorescent silver nanoclusters to Scenedesmus obliquus. Sci Rep. 7, 1–12 (2017).
Acknowledgements
The authors would like to thank the following Brazilian funding agencies: São Paulo State Science Foundation (FAPESP- 2014/21618-5; 2016/13692-6; 2017/13328-5), National Council for Scientific and Technological Development (CNPq 470529/2013-0; 303967/2015-3) and Coordination of Improvement of Higher Education Personnel (CAPES).
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R.L., L.F.F. and C.S.C. proposed and designed the experiments. R.G. Performed Scanning Electron Microscopy analysis. D.T.R. performed nanoparticles synthesis and all characterization experiments M.G., N.B.J., T.G.C., T.P.S. and R.L. performed cellular viability experiments and genotoxicity evaluation. D.T.R., M.G., N.B.J., T.G.C., T.P.S., T.B.B.G. performed fish biochemical analyses. R.L., R.G., C.S.C., T.P.S., M.G. and L.F.F. wrote the manuscript. All the authors participated in discussion of the research.
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Rheder, D.T., Guilger, M., Bilesky-José, N. et al. Synthesis of biogenic silver nanoparticles using Althaea officinalis as reducing agent: evaluation of toxicity and ecotoxicity. Sci Rep 8, 12397 (2018). https://doi.org/10.1038/s41598-018-30317-9
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DOI: https://doi.org/10.1038/s41598-018-30317-9
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