Abstract
The impact of fullerene C60 water soluble daughter molecules - fullerols C60(OH)24 nanoparticles (FNP) on emerging (non-aflatoxin biosynthetic pathway) toxins production in mycelia and yeast extract sucrose (YES) media of A. flavus was investigated under growth conditions of 29 °C in the dark for a 168 h period. The FNP solution (10, 100 and 1000 ng mL−1) contained predominantly nanoparticles of 8 nm diameter and with zeta potential mean value of −33 mV. Ten emerging metabolites were produced at concentrations reaching 1,745,035 ng 50 mL−1 YES medium. Seven of the metabolites were found in mycelia and media, while three were only in mycelia. Majority of the metabolites were detected in higher quantity in mycelia than in media, at a ratio of 99:1 (m/m). However, higher metabolite quantities were found in media following FNP application, while FNP caused a decrease of total metabolite quantities in mycelia. The concentrations of the metabolites in media increased in the presence of 1000 ng mL−1 FNP while mycelial quantities of the metabolites decreased with increased applied FNP dose. The impacts of global climate changes on FNP availability in the environment and on mycotoxin occurrence in crops increase the relevance of this study for risk assessment of nanoparticles. Cordycepin is reported for the first time as metabolite of A. flavus.
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Discover the latest articles, news and stories from top researchers in related subjects.Introduction
Global climate changes contribute to increased mycotoxin contamination of foods by shaping the mycotoxigenic fungal community structure in the environment. The most obvious example is the prediction of Battiliani et al.1 about aflatoxins becoming a food safety issue in Eastern Europe, the Balkan Peninsula and Mediterranean regions in the next 100 years as a result of +2 °C environmental temperature change. Several review papers on the impacts of interacting climate change factors on growth and mycotoxin production by major foodborne fungi have been published2,3,4,5,6,7,8. The most important mycotoxigenic fungi is Aspergillus flavus, producer of the strongest known natural hepatocarcinogen – aflatoxin B1 (AFT B1). This fungus has been widely studied due to the severe health and economic challenges it causes through aflatoxin contamination of foods. The dynamics of A. flavus, influenced by factors of global climate changes (e.g. temperature, drought stress and CO2 concentration) have also been recently studied2,9,10. Besides the regulated mycotoxins, the impact of climate change on the emerging toxins are receiving increasing attention in recent years2,11. According to Kovalsky et al.11 emerging toxins are a group of chemically diverse mycotoxins for which to date no regulations exist. For example, the AFT precursors are one of the emerging toxins group11,12 and there is only limited literature available on the emerging toxins from Aspergillus species11,13. For the purpose of the present study, emerging toxins produced by A. flavus are the non-aflatoxin biosynthetic pathway metabolites.
Similar to the attention global climate changes received in the past two decades1,14, nanotechnology research, development and application have also skyrocketed. Increasing the application of nanoparticles to various commodities raises chances for environmental release during production processes, use or disposal of products. Consequently, the utilization of nanoparticles should be based on thorough knowledge of their effects on biological systems as well as on the aforementioned abiotic stressors15,16. The most intensely investigated carbon-based nanoparticles are fullerenes and their hydroxylated derivatives due to their numerous applications17,18,19. The major side effect of their usage is the determined realistic environmental occurrence of fullerene C60 in almost every part of the environment (wastewaters, surface waters, river sediments and soils)20,21,22. In addition, the increase of fullerenes in sewage sludge-treated soil on annual basis was predicted by Sun et al.23. Fullerene C60 can, however, be spontaneously mineralized into water soluble daughter molecules (fullerols C60(OH)24 (FNP)) over 16 weeks in the environment24.
Despite the over 20-year long research period, the environmental reactivity of fullerene C60 and FNP is still poorly defined, mainly due to distinctive material properties and biological activities such as induction of side effects on cells, organelles and biomolecules19,25,26,27,28,29,30,31,32. The interaction between FNP and mycotoxigenic fungi (e.g. A. flavus) has been under research but literature are still limited13,33,34. However, it is known that FNP modulates oxidative status of A. flavus, consequently affecting the production of aflatoxins and their precursors13,34. Medina et al.9,10,35 reported stimulation of AFT B1 production by fluctuations in environmental abiotic stressors and secondary metabolites regulatory gene shifts. According to that report, the mechanism of FNP biological activity related to antioxidative properties could play a role in oxidative status perturbations in the sensitive saprophytic soil fungus, A. flavus, during FNP mineralization process.
Therefore, the aim of this study was to determine secondary metabolite production besides aflatoxins and their precursors in the mycelia and growth media of A. flavus, and to confirm whether there are secondary metabolite shifts in the A. flavus cells under FNP influence. This is one of the follow up studies focused on interaction of FNP with mycotoxigenic fungi and is one step closer to determination of mechanism of FNP action.
Results and Discussion
The geographical distribution of mycotoxigenic fungi determines mycotoxin contamination worldwide, and this is a reflection of environmental temperature, humidity and CO2 concentration35. With the predicted changes in climate expected to occur in many parts of the world including eastern Europe, it is of necessity to understand the role of neglected environmental compounds (e.g. the abiotic stressor – FNP) in the production of emerging toxins by A. flavus. The FNP solution (10 µg mL−1) used in this study was obtained from the same batch of FNP solution prepared, characterised and used in the study performed by Kovač et al.13 and the final concentrations present in YES media were 10, 100 and 1000 ng mL−1. The concentrations of 10 and 100 ng mL−1 of FNP are present in environment at this moment20,21,22, while occurrence of 1000 ng mL−1 is expected in the future. Consequently and for the reasons stated by Kovač et al.34, we wanted to examine what the effect of possible future environmental concentration spike reaching about 1000 ng/mL could result in. However, we also included the lower (10 ng/mL) and present high (100 ng/mL) concentrations in this study.
As previously reported, the FNP solution contained only particles smaller than 100 nm (range: 5–25 nm). The particles had a hydrodynamic radius of 8 nm and the zeta potential of the FNP aqueous solution was –33 mV. The particle diameter is in accordance with EC Recommendation for the definition of the term “nanomaterial”36.
Figure 1. depicts the effect of FNP on A. flavus biomass production. Overall, the results agree with previously reported data on FNP influence on A. flavus biomass production13. At least 48 h incubation period was required to obtain measurable quantity of mycelia in the first instance and in this study, there was no statistically significant (p > 0.05) effect of the applied concentrations of FNP on biomass production at all the time intervals13. The fact that growth of fungi under abiotic stressor remains practically unaffected is in accordance with results of Medina et al.9,10 and Kovač et al.13.
Regarding the effect of FNP on metabolite/toxin production by A. flavus, we did not investigate in this study the effect on production of AFT B1 and its precursors, which are regarded as the main metabolites from A. flavus. Detailed explanation on FNP effect on AFT B1 and precursor metabolites are given in our previous report Kovač et al.13. From that report, FNP exerted a concentration-dependent effect on the AFT biosynthesis pathway metabolites and altered sterigmatocystin (ST) export from the cell. Prior to 120 h of growth of A. flavus, FNP exerted antioxidative potential, which vanished afterwards to cause strong and concentration-dependent rise in biosynthesis of aflatoxins. However, it is pertinent that we investigated, in this present study, the possibility of FNP modulation of emerging toxins production in A. flavus mycelia and growth media. Mostly due to conclusions of Medina et al.35 who suggested that abiotic stressors could stimulate AFT B1 production owing to regulatory shifts in AFT B1 and cyclopiazonic acid gene clusters, and our understanding that FNPs are behaving as the classical abiotic stressors, but belong to the group of the new abiotic stressors.
In this study, the emerging A. flavus toxins fellatunine A, gliocladic acid, heptelidic acid, meleagrin, kojic acid, cordycepin, 3-nitropropionic acid, cyclopiazonic acid, emodin and dichlorodiaportin were detected. Cordycepin is reported here for the first time as metabolite of Aspergillus, specifically A. flavus; chromatograms and EPI fragmentation scans are given in Fig. 2. All aforementioned emerging toxins were detected in both mycelia and growth media, with the exception of cyclopiazonic acid, emodin and dichlorodiaportin, which were found only in mycelia (Fig. 3). The 10 metabolites detected in this study were categorized as minor (fellatunine A, heptelidic acid, meleagrin, cordycepin, emodin and dichlorodiaportin) and major (gliocladic acid, kojic acid, 3-nitropropionic acid and cyclopiazonic acid) based on their production at <1000 ng 50 mL−1 and >1000 ng 50 mL−1 levels, respectively.
Fellutanine A is a naturally occurring 2,5-diketopiperazines, bio-active diketopiperazine alkaloid obtained from species of several fungal genera37,38. This metabolite was found in higher quantity in growth media than in A. flavus mycelia (Fig. 3). There were no statistically significant changes in fellutanine A concentration under FNP presence, neither in growth media nor in mycelia (Fig. 4). In addition, gliocladic acid and heptelidic acid were detected both in mycelia and growth media, with most of the metabolites remaining in YES media (67.7% gliocladic acid) and mycelia (83.8% heptelidic acid) (Fig. 3). These metabolites are known to be produced by species of several fungal genera including Aspergillus, Chaetomium, Gliocladium and Trichoderma39. Similar to fellutanine A, FNP did not significantly affect gliocladic acid biosynthesis at any of the tested concentrations. However, there was statistically significant difference (p = 0.02) in heptelidic acid concentrations between control samples and samples treated with 100 ng mL−1 FNP (Fig. 4).
The fungal secondary metabolite meleagrin, which possesses neurohumoural and antibiotic activity40, was quantified in mycelia and growth media, with higher concentrations in the mycelia than in the growth media (Fig. 4). Statistically significant (p = 0.04) increase in the meleagrin concentration (up to 10%) was recorded in growth media containing 1000 ng mL−1 FNP at 168 h of fungal growth in comparison to the control samples.
Cordycepin is considered an immunological regulator, anticancer, antifungal, antiviral, antileukemia and antihyperlipidemia agent41. This metabolite, also regarded as a Phase I/II clinical stage drug candidate for the treatment of refractory acute lymphoblastic leukemia patients who express the enzyme terminal deoxynucleotidyl transferase41 was one of the emerging metabolites produced in higher amount in YES media (74.7%) than in mycelia, although the difference between mycelia and media concentrations were statistically insignificant (Fig. 5). Specifically, the cordycepin concentration quantified in YES media supplemented with 1000 ng mL−1 FNP and incubated for 168 h was the highest (34.5%) compared to other FNP concentrations (Fig. 3b). Kojic acid was also detected in both mycelia and media, albeit at higher concentrations in mycelia (96.4%) than in the YES media. The concentration of kojic acid in YES media was, however, elevated with an increase in the FNP concentration (72.6% at 10 ng mL−1 FNP, 78.6% at 100 ng mL−1 FNP and 84.2% at 1000 ng mL−1 FNP) at 168 h of growth (Figs. 3a and 4). Kojic acid is known to be produced by Aspergillus spp., Penicillium spp. as well as some other fungi, and is a tyrosinase activity inhibitor, food additive, skin-whitening agent, antioxidant, anti-tumour and radioprotective agent42. 3-nitropropionic acid, a major secondary metabolite specific to Aspergilli, was detected both in mycelia and media, although the mycelial concentration was higher (88.7%) than the concentration in the growth media (Figs. 3a and 5). Statistically significant difference (p = 0.03) was recorded for the sum of 3-nitropropionic acid concentrations produced in mycelia and media when A. flavus was grown in YES media containing 10 and 1000 ng mL−1 FNP at 120 h (Fig. 5).
In addition to the metabolites found in both mycelia and media, three metabolites (cyclopiazonic acid, emodin and dichlorodiaportin) were detected only in the mycelia. Cyclopiazonic acid is known to react with ambient oxygen, causing its degradation43. During the incubation of the media under shaking conditions, contact between oxygen and the media is increased, causing the degradation of cyclopiazonic acid which has been released into the media43. Consequently, only cyclopiazonic acid retained in the mycelia without direct contact with oxygen remains stable and easily detected; this is the most logical reason why these three metabolites were not found in the media. Many ascomycetous fungi belonging to Aspergillus spp. and Penicillium spp. produce cyclopiazonic acid, which causes degenerative changes and necrosis in the liver, spleen, pancreas, kidney, salivary glands, myocardium and skeletal muscles, based on toxic effects observed in male and female rats44. Aflatoxins often co-occur with cyclopiazonic acid in high quantities in maize and peanuts suggesting that synergism from their co-exposures may occur44. In addition, cyclopiazonic acid may be co-produced with other metabolites as found in the present study (Figs. 3–5). The FNP concentrations tested in this study caused a decrease in cyclopiazonic acid concentrations in the amended media compared to the control, with statistically significant differences recorded only at 96 h (p = 0.01) and 144 h (p = 0.01) of growth (Fig. 5). Similar FNP dose-dependent decrease that was reported for AFT B1 in YES media13 was recorded in our present study. This could be additional data to confirm previous reports of co-occurrence of cyclopiazonic acid with aflatoxins44.
Emodin is a fungal secondary metabolite that exhibits diverse biological activities including anticancer and anti-inflammatory functions45,46. In A. flavus mycelia, emodin was present in low concentrations (0.64–2.53 ng 50 mL−1) (Fig. 3b; Fig. 4). However, 1000 ng mL−1 FNP caused a significant (p = 0.03) decrease in emodin concentration at 72 h of growth. Dichlorodiaportin belongs to the isocoumarins, a group of natural products with diverse chemical structures and pharmacological activities including antibacterial activity47. It is reported to be produced a variety of species of fungal genera including Aspergillus47,48,49. The highest dichlorodiaportin concentrations were detected at 120 h of growth (Fig. 4), afterwards the concentrations decreased in both control and FNP treated samples.
In general, majority of the A. flavus emerging metabolites were determined in higher quantity in mycelia than in YES media at a ratio of 99:1. In YES media higher metabolite quantities were obtained after FNP was applied (11.6% at 10 ng mL−1 FNP, 20% at 100 ng mL−1 FNP and 22.9% at 1000 ng mL−1 FNP), while in mycelia the opposite effect was observed. The presence of FNP during the incubation period caused decrease of total metabolites (24.9% at 10 ng mL−1 FNP, 52.9% at 100 ng mL−1 FNP and 24.4% at 1000 ng mL−1 FNP) (Fig. 3a). When the minor secondary metabolites were compared, a decrease of 4.5 and 2.4% in the concentrations in YES media was recorded under the presence of 10 and 100 ng mL−1 FNP, respectively, while an increase of 11.5% was observed at 1000 ng mL−1 FNP. When the quantities of minor metabolites in mycelia were compared, a decrease with increased dose of FNP was recorded (10.0% at 10 ng mL−1 FNP, 33.3% at 100 ng mL−1 FNP and 49.8% at 1000 ng mL−1 FNP); this similar trend was recorded also for the major ones (Fig. 3b).
The increased FNP levels can be expected in the future as a consequence of increased production, usage, release, and time-lag in the mineralisation processes in the environment17,18,19,20,21,22,23. Consequently, according to trends of increasing environmental occurrence of FNP, shaping of the Aspergillus spp. community by climate changes and here presented results, it seems that FNPs are capable of posing higher threat levels to the toxigenic potentials of A. flavus; this may further be even more aggravated by future climate changes. This study confirmed the ability of FNP to modulate production of 10 emerging A. flavus toxins. As previously established, the relevant parameters for environmental risk estimation were data for the sum of the secondary metabolites detected in mycelia and in growth media. FNP in this study exerted a concentration-dependent effect on the production of A. flavus emerging toxins. Although some of the metabolites (e.g. cyclopiazonic acid) decreased in concentration with increased dose of FNP, the sum of all concentrations increased. It can be concluded that the antioxidative potential of FNP, which vanishes over time, causes concentration-dependent rise in the sum of secondary metabolites produced by A. flavus. Such prospects of FNP occurring in the environment opens up further investigations into its modulation of regulated and emerging toxins in food samples, as well as a study into the photosensitized FNP action on available mycotoxigenic fungal species in other to control mycotoxins occurrence and avoid food safety and human health risks. In this paper, we further report the production of cordycepin in YES media; which was not previously reported in A. flavus in available literature.
To sum up above mentioned, the FNP environmental concentration are increasing since production and release are faster than degradation into environment. At the same time, dynamics of A. flavus is influenced by temperature, drought stress and CO2 concentration due to global climate changes. Accordingly, probability of FNP for interaction with fungi is only increasing and which can certainly be reflected in the amount of secondary metabolites produced, which is confirmed by the results of this study (Figs. 3–5). Moreover, FNP present in environment only can be added value to already known negative effects of mentioned abiotic stressors that cause increase of mycotoxins occurrence. However, this study is one of the follow up studies and for establishing of general opinion of mechanisms of FNP action and their impact on environment, or consequently on food and feed safety, as well as human health, more research is needed.
Future Perspectives
This report increases our understanding of the different metabolites that A. flavus can produce during competition in its environment to exclude other species. Further research may attempt to silence the expression of genes responsible for AFT biosynthesis in favour of genes for codycepin production since cordycepin offers to be of health benefits due to its anticancer, antiviral, antileukemia and antihyperlipidemia activities. Furthermore, this paper has provided data to establish the foundation for further studies on determining the mechanism of FNP action during interaction with mycotoxigenic fungi.
Materials and Methods
Chemicals
Yeast extract, potato dextrose agar, malt extract agar and sucrose were purchased from Biolife (Italy). AFT standard mix (B1, G1, B2, G2) was purchased from Biopure (Austria). Acetonitrile and methanol (HPLC grade both) were obtained from Merck (Germany). Ammonium acetate and glacial acetic acid (p.a.) were purchased from Sigma Aldrich (Vienna, Austria). For ultrapure water preparation, a Purelab Ultra system (ELGA LabWater, Celle, Germany) was used. Standards of A. flavus metabolites were collected from various research groups or purchased from the following commercial sources: Romer Labs®Inc.(Tulln, Austria), Sigma–Aldrich (Vienna, Austria), Iris Biotech GmbH (Marktredwitz, Germany), Axxora Europe (Lausanne, Switzerland) And LGC Promochem GmbH (Wesel, Germany). Purchased standards were prepared according to Malachova et al.50.
Fullerol C60(OH)24 synthesis, preparation and characterisation of nanoparticles solution
The synthesis of fullerol C60(OH)2449,preparation of nanoparticle solution in ultrapure water and characterisation of the particles by Dynamic Light Scattering (DLS) and Electrophoretic Light Scattering (ELS) techniques were performed as previously described by Kovač et al.13. The hydrodynamic size and the surface charge (zeta potential (ζ)) of the nanoparticle solution samples were determined by Zetasizer Nano ZS instrument (Malvern Instruments Inc., UK). All DLS analysis (633 nm wavelength and a measurement angle of 173° (backscatter detection)) were performed in triplicates in aqueous solution at ambient temperature (25 °C) while zeta potential (ζ) measurements were performed in duplicates.
Cultivation of Aspergillus flavus on mycological media
Aspergillus flavus NRRL 3251 culture maintained on malt extract agar (Biolife, Italy) at 4 °C was used in this study. The A. flavus NRRL 3251 strain was grown on potato dextrose agar (Biolife, Italy) in the dark at 29 °C for 7 days to stimulate conidia production. Yeast extract sucrose (YES) broths amended with 0, 10, 100 and 1000 ng mL−1 of C60(OH)24 were prepared. The preparation of fungal conidia suspension, its inoculation into nanoparticle-amended aflatoxin-inducing YES broth in 250 mL flasks and incubation were conducted in the dark at 29 °C, which favours AFT production, as previously described34. The rotary shaker (KS 260 basic, IKA, Germany) set at 200 rpm was used for the incubation of the inoculated flasks for 168 h. Every 24 h from the 48th to 168th h of incubation, samples of medium and mycelia were collected from the flasks. Mycelia were separated from the media by filtration and stored in 2 mL vials at −80 °C for at least 24 h until lyophilisation (Christ, Alpha 1-4 LD, Germany). Drying conditions were as follows: freezing temperature −55 °C; temperature of sublimation −35 to 0 °C; vacuum level 0.220 mbar. The temperature of isothermal desorption varied from 0 to 22 °C under the vacuum of 0.060 mbar. Freeze-drying lasted until the constant mass of mycelia was obtained, which was approximately 5 h. Additionally, a portion of the mycelia was taken prior to −80 °C storage and lyophilisation, and dried until constant mass (24 h at 105 °C) in order to determine the dry mycelial weight.
Determination of emerging toxins in mycelia and culture media of A. flavus
The metabolites produced by A. flavus in mycelia and culture medium were determined by the multi-analyte “dilute and shoot” LC-MS/MS method of Malachova et al.50. For the analysis of mycelia, 125 mg of the lyophilised mycelia were mixed with 1 mL of extraction solvent (acetonitrile/water/acetic acid 79:20:1, v/v/v) and extracted for 90 min at ambient temperature using GLF 3017 rotary shaker (GLF, Germany). After extraction, 500 µL of the extracts were transferred into glass vials and diluted with 500 µL of dilution solvent (acetonitrile/water/acetic acid 20:79:1, v/v/v). Vial contents were vigorously mixed and 5 µL was injected directly into the LC-MS/MS system. For the determination of metabolites in YES medium, a ten-fold dilution of 100 µL of the medium with mixture of extraction solvent and dilution solvent (1:1, v/v) in glass vials without any pre-treatment was performed.
The screening and detection of metabolites was performed as described by Malachová et al.50, and in brief the QTrap 5500 MS/MS detector (Applied Biosystems, Foster City, CA) equipped with TurboV electrospray ionization (ESI) source, and Agilent 1290 binary UHPLC system (Agilent Technologies, Waldbronn, Germany) were used. For the separation of the metabolites, the C18 security guard pre-column (4 × 3 mm i.d.) (Phenomenex, Torrance, CA, US) with the Gemini® C18 column (150 × 4.6 mm i.d., 5 µm particle size) was used. Freshly prepared eluents and the gradient were exactly as described by Malachová et al.50. The Scheduled selected reaction monitoring (sSRM) mode was applied, and two runs per sample were used (each for one mode). The detection window was set to ± 27 s in positive and ± 42 s in negative mode due to high number of monitored metabolites. The ESI source parameters were exactly as described by Malachová et al.50. At least two sSRM transitions were monitored per metabolite (quantifier and qualifier), and according to the validation guidelines the ratio between two transitions were used as additional identity confirmation point.
Statistical analysis
Data are expressed as the mean value ± SEM from three separate experiments. The pooled datasets were checked for normality distribution by Shapiro-Wilk test and compared by nonparametric statistics methods (Friedman ANOVA and Kendall coefficient of concordance; Kruskal-Wallis ANOVA). The programme package Statistica 13.1 (Dell Inc., Texas, USA) was used and differences were considered significant when the p value was < 0.05. For the drawing of the Sankey diagrams Flourish studio was used (Flourish Studio, Kiln Enterprises Ltd, London, UK).
References
Battilani, P. et al. Aflatoxin B 1 contamination in maize in Europe increases due to climate change. Sci Rep 6, 24328 (2016).
Medina, A., Akbar, A., Baazeem, A., Rodriguez, A. & Magan, N. Climate change, food security and mycotoxins: do we know enough? Fungal Biol. Rev. 31, 143–154 (2017).
Magan, N. & Aldred, D. Post-harvest control strategies: minimizing mycotoxins in the food chain. Int. J. Food Microbiol. 119, 131–139 (2007).
Bebber, D. P., Ramotowski, M. A. T. & Gurr, S. J. Crop pests and pathogens move polewards in a warming world. Nat. Clim. Chang. 3, 985–988 (2013).
Helfer, S. Rust fungi and global change. New Phytol. 201, 770–780 (2014).
Miraglia, M. et al. Climate change and food safety: an emerging issue with special focus on Europe. Food Chem. Toxicol. 47, 1009–1021 (2009).
Trnka, M. et al. Adverse weather conditions for European wheat production will become more frequent with climate change. Nat. Clim. Chang. 4, 637–643 (2014).
Schaafsma, A. W. & Hooker, D. C. Climatic models to predict occurrence of Fusarium toxins in wheat and maize. Int. J. Food Microbiol. 119, 116–125 (2007).
Medina, A., Rodriguez, A. & Magan, N. Effect of climate change on Aspergillus flavus and aflatoxin B1 production. Front. Microbiol. 5, 1–7 (2014).
Medina, A., Rodríguez, A. & Magan, N. Climate change and mycotoxigenic fungi: Impacts on mycotoxin production. Curr. Opin. Food Sci. 5, 99–104 (2015).
Kovalsky, P. et al. Co-Occurrence of Regulated, Masked and Emerging Mycotoxins and Secondary Metabolites in Finished Feed and Maize—An Extensive Survey. Toxins (Basel) 8, 1–29 (2016).
Gruber-Dorninger, C., Novak, B., Nagl, V. & Berthiller, F. Emerging Mycotoxins: Beyond Traditionally Determined Food Contaminants. J. Agric. Food Chem. 65, 7052–7070 (2017).
Kovač, T. et al. Fullerol C60(OH)24 nanoparticles modulate aflatoxin B1 biosynthesis in Aspergillus flavus. Sci. Rep. 8, 12855 (2018).
Battilani, P. et al. Scientific report submitted to EFSA. Modelling, predicting and mapping the emergence of aflatoxins in cereals in the EU due to climate change (2012).
Parisi, C., Vigani, M. & Rodríguez-Cerezo, E. Agricultural nanotechnologies: What are the current possibilities? Nano Today 10, 124–127 (2015).
Krishna, V. D. et al. Nanotechnology: Review of concepts and potential application of sensing platforms in food safety. Food Microbiol., https://doi.org/10.1016/j.fm.2018.01.025 (2018).
Michalitsch, R., Kallinger, C., Verbandt, Y., Veefkind, V. & Huebner, S. R. The fullerene patent landscape in Europe. Nanotechnol. Law Bus. 5, 85–94 (2008).
Duncan, T. V. Applications of nanotechnology in food packaging and food safety: Barrier materials, antimicrobials and sensors. J. Colloid Interface Sci. 363, 1–24 (2011).
Pycke, B. F. G., Chao, T.-C., Herckes, P., Westerhoff, P. & Halden, R. U. Beyond nC60: strategies for identification of transformation products of fullerene oxidation in aquatic and biological samples. Anal. Bioanal. Chem. 404, 2583–95 (2012).
Sanchís, J., Bosch-Orea, C., Farré, M. & Barceló, D. Nanoparticle tracking analysis characterisation and parts-per-quadrillion determination of fullerenes in river samples from Barcelona catchment area. Anal Bioanal Chem 407, 4261–4275 (2015).
Sanchís, J. et al. Occurrence of C60and related fullerenes in the Sava River under different hydrologic conditions. Sci. Total Environ. 643, 1108–1116 (2018).
Farré, M., Sanchís, J. & Barceló, D. Analysis and assessment of the occurrence, the fate and the behavior of nanomaterials in the environment. TrAC Trends Anal. Chem. 30, 517–527 (2011).
Sun, T. Y., Gottschalk, F., Hungerbühler, K. & Nowack, B. Comprehensive probabilistic modelling of environmental emissions of engineered nanomaterials. Environ. Pollut. 185, 69–76 (2014).
Avanasi, R., Jackson, W. A., Sherwin, B., Mudge, J. F. & Anderson, T. A. C60 fullerene soil sorption, biodegradation, and plant uptake. Environ. Sci. Technol. 48, 2792–2797 (2014).
Brar, S. K., Verma, M., Tyagi, R. D. & Surampalli, R. Y. Engineered nanoparticles in wastewater and wastewater sludge – evidence and impacts. Waste Manag. 30, 504–520 (2010).
Benn, T. M., Westerhoff, P. & Herckes, P. Detection of fullerenes (C60 and C70) in commercial cosmetics. Environ. Pollut. 159, 1334–42 (2011).
Chen, Z., Westerhoff, P. & Herckes, P. Quantification of C60 fullerene concentrations in water. Environ. Toxicol. Chem. 27, 1852–1859 (2008).
Farré, M. et al. First determination of C60 and C70 fullerenes and N-methylfulleropyrrolidine C60 on the suspended material of wastewater effluents by liquid chromatography hybrid quadrupole linear ion trap tandem mass spectrometry. J. Hydrol. 383, 44–51 (2010).
Huang, F. et al. A fullerene colloidal suspension stimulates the growth and denitrification ability of wastewater treatment sludge-derived bacteria. Chemosphere 108, 411–417 (2014).
Kubatova, H., Zemanova, E., Klouda, K., Bilek, K. & Kadukova, J. Effects of C 60 Fullerene and its Derivatives on Selected. Microorganisms. 3, 152–162 (2013).
Trpkovic, A., Todorovic-Markovic, B. & Trajkovic, V. Toxicity of pristine versus functionalized fullerenes: mechanisms of cell damage and the role of oxidative stress. Arch. Toxicol. 86, 1809–1827 (2012).
Yang, L. Y. et al. Characterization of fullerenol-protein interactions and an extended investigation on cytotoxicity. Colloids Surfaces B Biointerfaces 157, 261–267 (2017).
Unković, N. et al. Aspergilli Response to Benzalkonium Chloride and Novel-Synthesized Fullerenol / Benzalkonium Chloride Nanocomposite. Sci. World J. 2015, (2015).
Kovač, T. et al. Fullerol C60(OH)24 nanoparticles and mycotoxigenic fungi: a preliminary investigation into modulation of mycotoxin production. Env. Sci Pollut Res 60, 1–9 (2017).
Medina, A. et al. Interactions between water activity and temperature on the Aspergillus flavus transcriptome and aflatoxin B 1 production. Int. J. Food Microbiol. 256, 36–44 (2017).
Rauscher, H. et al. Towards a review of the EC Recommendation for a definition of the term ‘nanomaterial’, Part 3: Scientific-technical evaluation of options to clarify the definition and to facilitate its implementation., https://doi.org/10.2788/678452 (2015).
Zin, W. W. M. et al. New cyclotetrapeptides and a new diketopiperzine derivative from the marine sponge-associated fungus Neosartorya glabra KUFA 0702. Mar. Drugs 14, (2016).
Sulyok, M. et al. Quantitation of multiple mycotoxins and cyanogenic glucosides in cassava samples from Tanzania and Rwanda by an LC-MS/MS-based multi-toxin method. Food Addit. Contam. - Part A Chem. Anal. Control. Expo. Risk Assess. 32, 488–502 (2015).
Skóra, J., Sulyok, M., Nowak, A., Otlewska, A. & Gutarowska, B. Toxinogenicity and cytotoxicity of Alternaria, Aspergillus and Penicillium moulds isolated from working environments. Int. J. Environ. Sci. Technol. 14, 595–608 (2017).
Kozlovsky, A. G., Zhelifonova, V. P. & Antipova, T. V. Biologically active metabolites of Penicillium fungi. Signpost Open Access J. Org. Biomol. Chem. 01, 11–21 (2013).
Kang, C. et al. Optimization of large-scale culture conditions for the production of cordycepin with cordyceps militaris by liquid static culture. Sci. World J. 2014, 20–24 (2014).
Rodrigues, A. P. D. et al. Kojic acid, a secondary metabolite from Aspergillus sp., acts as an inducer of macrophage activation. Cell Biol. Int. 35, 335–343 (2011).
Diaz, G., Thompson, W. & Martos, P. Stability of cyclopiazonic acid in solution. World Mycotoxin J. 3, 25–33 (2010).
Ostry, V., Toman, J., Grosse, Y. & Malir, F. Cyclopiazonic acid: 50 th anniversary of its discovery. World Mycotoxin J. 11, 1–14 (2018).
Lu, P., Zhao, X. & Cui, T. Production of emodin from Aspergillus ochraceus at preparative scale. African J. Biotechnol. 9, 512–517 (2010).
Mikušova, P., Sulyok, M., Santini, A. & Škrobarova, A. Aspergillus spp. and their secondary metabolite production in grape berries from Slovakia. Phytopathol. Mediterr. 53, 311–317 (2014).
Wu, Y. & Chen, S. Cytotoxic isocoumarin derivatives from the mangrove endophytic fungus Aspergillus sp. HN15-5D. Arch. Pharm. Res. 1–6, https://doi.org/10.1007/s12272-018-1019-1 (2018).
Larsen, T. O. & Breinholt, J. Dichlorodiaportin, diaportinol, and diaportinic acid: Three novel isocoumarins from Penicillium nalgiovense. J. Nat. Prod. 62, 1182–1184 (1999).
Mirkov, S. M. et al. Nitric oxide-scavenging activity of polyhydroxylated fullerenol, C 60(OH) 24. Nitric Oxide - Biol. Chem. 11, 201–207 (2004).
Malachová, A., Sulyok, M., Beltrán, E., Berthiller, F. & Krska, R. Optimization and validation of a quantitative liquid chromatography-tandem mass spectrometric method covering 295 bacterial and fungal metabolites including all regulated mycotoxins in four model food matrices. J. Chromatogr. A 1362, 145–156 (2014).
Acknowledgements
The nanoparticles characterization experiment was supported by the Ministry of Education, Science and Technological Development of the Republic of Serbia, Project number III 45005.
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T. Kovač and B. Šarkanj conceived and designed experiments. T. Kovač, I. Borišev and A. Djordjevic carried out FNP suspension preparation and characterization. T. Kovač carried out fungal growth and prepared mycelial samples for lyophilisation, which was carried out by A. Lončarić. M. Kovač and T. Kovač prepared growth media samples for LC-MS/MS analysis. M. Sulyok, B. Šarkanj, T. Kovač and R. Krska performed LC-MS/MS analysis and carried out qualification and quantification of metabolites. T. Kovač and B. Šarkanj prepared data for statistical analysis; T. Kovač, B. Šarkanj and F. Čačić Kenjerić carried out statistical analysis. T. Kovač, B. Šarkanj, M. Sulyok and C. N. Ezekiel checked analysed data and interpreted results of statistical analysis. T. Kovač, B. Šarkanj and C. N. Ezekiel prepared the figures. T. Kovač wrote the manuscript. B. Šarkanj, A. Lončarić, M. Kovač, I. Borišev, A. Djordjevic, C. N. Ezekiel, I. Strelec, M. Sulyok and R. Krska reviewed and revised manuscript.
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Kovač, T., Borišev, I., Kovač, M. et al. Impact of fullerol C60(OH)24 nanoparticles on the production of emerging toxins by Aspergillus flavus. Sci Rep 10, 725 (2020). https://doi.org/10.1038/s41598-020-57706-3
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DOI: https://doi.org/10.1038/s41598-020-57706-3
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