key: cord-0026259-1sjjhg6f authors: Anjum, Tehmina; Iram, Wajiha; Iqbal, Mazhar; Abbas, Mateen; Akram, Waheed; Li, Guihua title: Structure Elucidation and Toxicity Analysis of the Byproducts Formed after Biodegradation of Aflatoxins B1 and B2 Using Extracts of Mentha arvensis date: 2022-01-01 journal: Toxins (Basel) DOI: 10.3390/toxins14010024 sha: 9958446fa485b19bb3540ddb4ab79a3165d87af0 doc_id: 26259 cord_uid: 1sjjhg6f The aqueous extracts of leaves and shoots of Mentha arvensis were checked for their potential to biodegrade aflatoxin B1 and B2 (AFB1; 100 µg/L and AFB2; 50 µg/L) through in vitro assays. Overall, the results showed that leaf extract degrades aflatoxins more efficiently than the shoot extract. First, the pH, temperature and incubation time were optimized for maximum degradation by observing this activity at different temperatures between 25 and 60 °C, pH between 2 and 10 and incubation time from 3 to 72 h. In general, an increase in all these parameters significantly increased the percentage of biodegradation. In vitro trials on mature maize stock were performed under optimized conditions, i.e., pH 8, temperature 30 °C and an incubation period of 72 h. The leaf extract resulted in 75% and 80% biodegradation of AFB1 and AFB2, respectively. Whereas the shoot extract degraded both toxins up to 40–48%. The structural elucidation of degraded toxin products by LCMS/MS analysis showed seven degraded products of AFB1 and three of AFB2. MS/MS spectra showed that most of the products were formed by the loss of the methoxy group from the side chain of the benzene ring, the removal of the double bond in the terminal furan ring and the modification of the lactone group, indicating less toxicity compared to the parent compounds. The degraded products showed low toxicity against brine shrimps, confirming that M. arvensis leaf extract has significant potential to biodegrade aflatoxins. Aflatoxins comprise a family of extremely toxic mycotoxins produced by Aspergillus flavus, A. parasiticus and A. nominus. These are hepatotoxic mycotoxins usually produced in various agricultural commodities. Maize, however, has shown a higher contamination rate as it provides an excellent substrate for mold infection. Among the eighteen different types of aflatoxins identified so far, aflatoxins B1, B2, G1 and G2 have been reported in maize. The order of toxicity is AFB1 > AFG1 > AFB2 > AFG2, probably because of the slight difference in structures of these aflatoxins [1] . AFB1 and AFG1 contain a double bond that undergoes reduction, forming vinyl ether at the terminal furan ring; this is not the case in AFB2 and AFG2. The problem of mycotoxin contamination in maize is more common in tropical and subtropical regions of the world because of hot and humid conditions in these areas. Tabuc, et al. [2] found 30% of the maize samples contaminated with aflatoxins B1 in a survey between 2002 and 2004 in Southeastern Romania. Similarly, Ghiasian, et al. [3] , in 2011, analyzed maize samples from the Kermanshah and Mazandaran provinces of Iran and found aflatoxin contamination between 58% and 80%. Various surveys have been performed in Pakistan covering the provinces of Punjab and Khaybar Pakhtun Khuah. Scientists have reported aflatoxin levels ranging between 30 and 200 µg/kg [4] [5] [6] [7] . In our recent survey encompassing maize storehouses of fifteen districts belonging to three agro-ecological zones of Punjab, Pakistan, 78% of collected samples were found to be contaminated with aflatoxins B1 and B2. However, aflatoxins G1, G2 and ochratoxin A were not found in any sample [8] . Various physical and chemical methods have been investigated for reducing these carcinogenic toxins to safe levels [9] . Physical methods use binding agents, such as clay, zeolites, sepiolite, kaolin, bentonites, monomorillonite and activated charcoal. The process is expensive and laborious and reduces the toxin to only 50-60%. A higher inclusion of clay can increase the binding of these compounds with minerals and antibiotics. Most of these binders are not biodegradable; thus, they can cause environmental problems. Chemical methods use caustic soda, ammonia, oxidants (such as ozone, hydrogen peroxide and sodium hypochlorite), reducing agents (such as chlorinated agents, bisulphites and formaldehyde). These chemicals are not safe, hence are not accepted by consumers [10] . Many researchers have tested the potential of microorganisms, including bacteria, yeast and fungi, to degrade these mycotoxins [11] . Microbial degradation of AFB1 using Flavobacterium aurantiacum (now called Nocardia corynebacterioides) was first reported in 1966 [12] . Though detoxification products were not identified, the residual toxicity was found to be absent when checked against ducklings [12] . After this first report, several investigations have concentrated on the biodegradation of AFB1. However, very few reports describe details regarding the degraded products and their toxicity. Many of these studies have shown the transformation of aflatoxins B1 to aflatoxicol, which is eighteen times less toxic than AFB1 but is still hazardous for other organisms [13] . Phytochemicals are of interest as a rich source of natural, ecofriendly antimicrobial components. Recently, many plant sources have been exploited for the detoxification and biodegradation of mycotoxins [14] [15] [16] [17] [18] . In this study, we investigated the potential of a common herb, i.e., Mentha arvensis (family: Lamiaceae), to degrade AFB1 and AFB2. Mentha arvensis is a well-known appetizer in Ayurveda and is traditionally used to treat digestive problems and cough [19] . A large number of different chemicals identified in this herb, including α-menthol, neomenthol, d-menthone, menthofuran, isomnethone, isomenthol, p-cymene, menthylacetate, cineol, limonine, phellandrene, aromadendrene, αpinene, α-phellandrene, pinene, piperitone, carvomenthone, carvacrol, thujone, dipentene, cadinene, menthofuran, linalyl acetate, carvone, linalool and piperitenone oxide, are being used in pharmaceuticals, food, flavoring, cosmetics, beverages and allied industries [20] [21] [22] . Earlier studies have also confirmed the antifungal potential of M. arvensis [23, 24] . Keeping this in view, the present study was planned to explore the biodegrading potential of M. arvensis against aflatoxins B1 and B2. The study was extended to the identification of the byproducts and evaluating their biological toxicity. Time course investigation on aflatoxin degradation revealed the start of detoxification within three hours of incubation and a significant increase with an increase in incubation time. Qualitative analysis of degraded toxins by thin-layer chromatography showed a distinct decline in florescence with an increase in biodegradation percentage ( Figure 1 ). of incubation. The percentage of degradation increased with an increase in incubation time, as after 72 h, 70.9% of AFB1 and 71.85% of AFB2 were degraded at 25 °C. Similarly, an increase in temperature significantly increased the efficacy of M. arvensis to biodegrade aflatoxins (Table 1) . At 60 °C, the percentage of degradation in both AFB1 and AFB2 was up to 83-88%. Shoot extract was found to be less effective than the leaf extract, as after 72 h at 60 °C, it degraded AFB1 up to 50.03% and AFB2 up to 57.46%. However, further in vitro studies were carried out at 30 °C to avoid any harmful effect of high temperature on maize. In this trial, the leaf extract of M. arvensis at 30 °C resulted in significant degradation of AFB1 (72.12%) and AFB2 (74.01%) after an incubation of 72 h. At the lowest tested temperature of 25 • C, the leaf extract of M. arvensis resulted in 44.31% and 62.16% degradation of AFB1 and AFB2, respectively, when checked after 3 h of incubation. The percentage of degradation increased with an increase in incubation time, as after 72 h, 70.9% of AFB1 and 71.85% of AFB2 were degraded at 25 • C. Similarly, an increase in temperature significantly increased the efficacy of M. arvensis to biodegrade aflatoxins (Table 1) . At 60 • C, the percentage of degradation in both AFB1 and AFB2 was up to 83-88%. Shoot extract was found to be less effective than the leaf extract, as after 72 h at 60 • C, it degraded AFB1 up to 50.03% and AFB2 up to 57.46%. However, further in vitro studies were carried out at 30 • C to avoid any harmful effect of high temperature on maize. In this trial, the leaf extract of M. arvensis at 30 • C resulted in significant degradation of AFB1 (72.12%) and AFB2 (74.01%) after an incubation of 72 h. The results present a significant (p < 0.05) biodegradation in both aflatoxin B1 and B2 when incubated at a pH of 2. However, an increase in pH increased this percentage. Similarly, an increase in incubation period also enhanced the biodegradation potential of Mentha arvensis. The leaf extract of M. arvensis resulted in more degradation when compared to that of its shoot extract. After three hours of incubation, the leaf extract of M. arvensis caused 43.8% and 56.9% degradation of AFB1 and AFB2, respectively, at a pH of 2. With an increase in pH, this percentage increased, and at the highest tested pH of 10 a degradation of 69% was recorded in both AFB1 and AFB2 (Tables 2 and 3 ). The overall results showed a maximum degradation at pH 10. However, aflatoxins are known to become sensitive and unstable at very high basic pH. Hence to avoid this in further trials, pH 8 was selected, which is much less alkaline than pH 10. The degradation percentages of both AFB1 and AFB2 at pH 8 were also found to be comparable with the results recorded at pH 10. A similar trend of degradation was recorded in in vitro trials using mature maize stock. This study was conducted in optimized conditions, i.e., a pH of 8, temperature of 30 • C and an incubation time of 72 h. In the control, maize samples were spiked with 100 µg/L AFB1 and 50 µg/L AFB2; the toxin recovery was 97.3 and 47.6 µg/L. When the spiked maize was treated with leaf extract of M. arvensis, the toxin recovery reduced to 24.9 µg/L for AFB1 and 9.6 µg/L for AFB2, respectively. The potential of the shoot extract was found to be lower than the leaf extract. Its percentage biodegradation was 40% in the case of AFB1 and 46.5% for AFB2 (Table 4 ). The degradation products of AFB1 and AFB2 in response to the treatment with M. arvensis leaf extract showed structural alteration in the parent compound. The structural formulas of the identified degraded products of AFB1 and AFB2 are shown in Figure 2A ,B. Leaf extract degraded aflatoxin B1 into seven new compounds and aflatoxin B2 into three products. The degraded products at m/z 279.17 and m/z 283.08 corresponded to molecular formulas C 16 H 6 O 5 and C 16 H 10 O 5 . Both products were obtained by the loss of the methoxy group from the side chain of the benzene ring, with a difference of four hydrogen atoms. The double bond equivalence (DBE) of C 16 H 10 O 5 was the same as that of AFB1, while C 16 H 6 O 5 showed a DBE content greater than AFB1, i.e., 14. The loss of carbon monoxide and oxygen was the main fragmentation pathway of both products. More detail on the fragmentation of precursor ions is shown in Figures 3 and 4 . Similarly, the degraded products obtained at 295.08 (C 16 The degraded products at m/z 279.17 and m/z 283.08 corresponded to molecular formulas C16H6O5 and C16H10O5. Both products were obtained by the loss of the methoxy group from the side chain of the benzene ring, with a difference of four hydrogen atoms. The double bond equivalence (DBE) of C16H10O5 was the same as that of AFB1, while C16H6O5 showed a DBE content greater than AFB1, i.e., 14. The loss of carbon monoxide and oxygen was the main fragmentation pathway of both products. More detail on the fragmentation of precursor ions is shown in Figures 3 and 4 . Similarly, the degraded products obtained at 295.08 (C16H22O5) and 293.17 m/ (C16H20O5) were produced by the loss of CO from the lactone ring of the parent compound The difference between the two products is of two hydrogen atoms with the same DBE content less than AFB1, i.e., 6 The degradation product C 16 H 12 O 4 (with 269.00 m/z) was formed by the loss of carbon dioxide from the lactone ring. The DBE of C 16 H 12 O 4 was one less than AFB1. Loss of CO was the main fragmentation pathway. More details on the fragmentation pathway are shown in Figure 7 . While the product obtained at 311.17 m/z (C 17 H 10 O 6 ) had two more hydrogen atoms than AFB1, the DBE content of C 17 H 10 O 6 was one more than AFB1, i.e., 13. Fragments of the precursor ion showed losses of CO, CH 2 The degradation product C16H12O4 (with 269.00 m/z) was formed by the loss of carbon dioxide from the lactone ring. The DBE of C16H12O4 was one less than AFB1. Loss of CO was the main fragmentation pathway. More details on the fragmentation pathway are shown in Figure 7 . While the product obtained at 311.17 m/z (C17H10O6) had two more hydrogen atoms than AFB1, the DBE content of C17H10O6 was one more than AFB1, i.e., 13. Fragments of the precursor ion showed losses of CO, CH2 and O (Figure 8 ). The degradation product C17H10O7 (with m/z 327.0) was formed by the addition of an oxygen atom onto the double bond of the furan ring; the DBE content was greater than AFB1, i.e., 13. The degraded products of AFB2 obtained at 317. 25 Figure 10) . Similarly, by the replacement of the methoxy group with the hydroxyl group on the side chain of the benzene ring, degradation product C 16 Similarly, by the replacement of the methoxy group with the hydroxyl group on th side chain of the benzene ring, degradation product C16H12O6 was formed. The DBE o Figure 11 ). The degradation product C15H14O4 was originated by the removal of CO from the lactone ring of AFB2, with a DBE content less than AFB2, i.e., 9. The loss of CO and H2O was the main fragmentation pathway of C15H14O4 ( Figure 12 ). At the lowest tested concentration of AFB1 (50 µg/L) and AFB2 (20 µg/L), a significant increase in larval mortality was observed compared to the control, i.e., 75%. This percentage of mortality was increased to 87.5% with an increase in incubation time. The mortality response of larvae varied according to the dosage concentration in an experimented period of 24 to 96 h. Larvae treated with dosage concentrations of 100 (AFB1), 50 (AFB2), 200 (AFB1) and 90 µg/L (AFB2) showed 83-91.7% and 86.7-96.7% mortality after 24 to 96 h of incubation, respectively. Similarly, at the highest tested concentration of 300 µg/L AFB1 and 130 µg/L AFB2, the percentage of larval mortality was found to be 95-100% after 24 to 96 h, respectively (Table 5) . A significant reduction in larval mortality was recorded after incubation with treated toxins in comparison to the ones incubated with untreated toxins (Figure 13 ). Larvae incubated with treated 100 µg/L of AFB1 and 50 µg/L of AFB2 showed a percentage mortality of 19.2% after 24 h that increased to 28.3% after 96 h of incubation. This percentage mortality was 63% lower than when shrimps were incubated in a similar concentration of untreated toxins. A significant reduction in larval mortality was recorded after incubation with treated toxins in comparison to the ones incubated with untreated toxins (Figure 13 ). Larvae incubated with treated 100 µg/L of AFB1 and 50 µg/L of AFB2 showed a percentage mortality of 19.2% after 24 h that increased to 28.3% after 96 h of incubation. This percentage mortality was 63% lower than when shrimps were incubated in a similar concentration of untreated toxins. Biodegradation of mycotoxins using fungi, bacteria and enzymes is now a known strategy to manage this issue [25] [26] [27] [28] [29] . However, not much data is available on the use of plant extracts for the same purpose. In our previous study, aqueous extracts of Acacia nilotica were used to detoxify aflatoxins in maize [30] . Whereas, this study was planned to explore the potential of a common medicinal herb, i.e., Mentha arvensis, to detoxify or inactivate aflatoxins in maize. In various trials, M. arvensis significantly degraded both AFB1 and AFB2 even when checked after three hours of incubation at the lowest tested temperature and pH. However, the percentage of degradation increased with increases in incubation time, temperature and pH. The high temperature always supports chemical reactions. In in vitro assays, an increase in temperature significantly increased the percentage of degradation of aflatoxins. However, the overall results could be due to the synergistic effect of moisture and high temperature [31] . Many earlier workers have reported similar effects of high temperature on the rate of degradation of mycotoxins [18, 32, 33] . However, for further in vitro trials, 30 • C was selected to eliminate any bad effect of high temperature on food chemistry. Moreover, 30 • C is quite close to the room temperature and prevailing temperature of storehouses in Pakistan during summer. This selection can make degradation a cost-effective approach at the industrial level. After temperature, pH also plays an important role in governing a reaction speed. In this study, basic pH supported degradation reactions. Méndez-Albores, et al. [34] showed that a decrease in aflatoxins fluorescence due to a change in coumarin moiety in alkaline conditions. In the present investigation, the highest degradation was achieved at pH 10. However, pH 8 was selected for further trials to avoid the possibility of aflatoxins being unstable and sensitive at the basic pH. As pH 8 is 100 times less alkaline than pH 10 and the percentage of biodegradation was also found comparable to pH 10, pH 8 was preferred for in vitro trials using detached maize stock. Aflatoxin B1 was converted into seven different compounds. A total of 28% of these compounds were formed due to the modification of the lactone ring. The lactone ring is responsible for the toxicity, carcinogenicity and fluorescence of aflatoxin B1 [35] . Modification in the lactone ring of AFB1 results in the loss of these properties, as observed in this study. Another 28% were formed due to the removal of the methoxy group from the side chain of benzene. A total of 14% of compounds were produced after the removal of the double bond in the furan ring. The presence of the double bond in the furan ring is another feature of AFB1 responsible for its toxicity and carcinogenic properties [36] . The rest of the compounds were formed by the loss of H 2 and CO 2 . Aflatoxin B2 was degraded to three different compounds by the replacement of the methoxy group with a hydroxyl group, the addition of H 2 and removal of CO from the lactone ring and the side chain of the benzene ring. All these changes synergistically reduced the toxicity of the toxin significantly. These biodegraded products were tested for biological toxicity against brine shrimps. Earlier studies have shown that the eggs and larvae of brine shrimps are susceptible to mycotoxins and hence have been used by several workers as a biological indicator of toxicity of mycotoxins in food and feed [37, 38] . The percentage mortality of brine shrimps significantly decreased when they were incubated in water containing treated toxins. Hence it was confirmed that the treatment of selected toxins with aqueous extracts of M. arvensis can biodegrade targeted toxins into significantly less toxic compounds. Due to its efficacy, leaves of M. arvensis or its aqueous extract can be used as additives in food and feed for making bioactive packaging and mycotoxins binding commercial products to minimize the production and toxicity of aflatoxins. The identification of bioactive components from tested extracts and their use can increase the percentages of biodegradation. Plants of Mentha arvensis were collected from Islamabad, Pakistan, in the month of May. Leaves and shoots of M. arvensis were first surface sterilized with 1% sodium hypochlorite for 10 min, followed by several washings with sterile distilled water. A total of 10 g of plant material was homogenized with 10 mL sterilized distilled water to obtain the aqueous extract. This mixture was then filtered using a muslin cloth and centrifuged at 14,000 rpm for 20 min. The supernatant obtained was sterilized by passing through a 0.2 µm syringe filter assembly before using in further trials. Firstly, the working solution was prepared consisting of methanol and water (60:40, v/v). A total of 50 µL of the working solution containing 50 µg/L AFB2 and 100 µg/L AFB1 mixed with 250 µL of M. arvensis aqueous extract was incubated for various time intervals. After the incubation period, 500 µL of chloroform was added to terminate the reaction. The mixture was thoroughly vortexed to extract the residual toxin. This was followed by the separation of the chloroform fraction at low-speed (5000 rpm) centrifugation. The organic phase was then evaporated to dryness under a gentle stream of nitrogen and dissolved in 100 µL of methanol. A total of 50 µL of toxin in 250 µL of water acted as the control that was also incubated under parallel conditions. The pH of the aqueous extracts was adjusted between 2.0 and 10.0 using 1N HCl or 1N NaOH and then checked for their biodegradation potential. Distilled water and untreated extract acted as a control. Plant extracts were incubated with toxins at 25, 30, 35, 40, 45, 50, 55 and 60 • C for 3, 6, 12, 24, 48 and 72 h. The toxin content in various reaction mixtures was estimated using high-performance liquid chromatography. Maize stock samples containing mature grains were spiked with aflatoxins (B1 100 µg/L and B2 50 µg/L). First, samples were decontaminated as described by Das and Mishra [39] with minor modifications. Briefly, 10 g of maize samples were kept in each 250 mL Erlenmeyer flask and spiked with 3 mL of aflatoxins (with concentration B1 100 µg L −1 and B2 50 µg L −1 ). These samples were then incubated with 10 mL of aforementioned plant extracts at 30 • C for 72 h. Afterward, aflatoxin was extracted according to the modified method of Stroka, et al. [40] . Maize samples were incubated with water:acetonitrile (15:85%) in a shaking water bath for 2 h. Afterward, the extracts were filtered through filter paper (Whatman, Inc., Clifton, NJ, USA). Afterward, the filtrate was passed through an afla immunoaffinity column in a solid-phase extraction assembly. The toxins were slowly eluted from the column with 1 mL of methanol in a glass vial, which was further analyzed by TLC and HPLC. The control comprised an untreated maize sample, a sample with plant extract without toxin and a sample with toxin without plant extract. Each experiment was performed in triplicate. TLC was used to detect the products of treated toxins. Chloroform and methanol fraction (20 µL), of both treated and control toxins, were run on 0.25 mm silica gel (60F254 20 × 20 cm, Merck, Darmstadt, Germany) TLC plates. These plates were then developed in 92:8 v/v chloroform:acetone and viewed under UV light (365 nm). Quantification of treated and untreated toxins after derivatization was performed through Agilent 1100 series HPLC (Agilent Technologies, Santa Clara, CA, USA) fitted with a reversed-phase C18 column (Merck, Darmstadt, Germany) and a fluorescence detector. Water:methanol:acetonitrile (60:20:20) was used as the mobile phase with a flow rate of 1 mL/min. Aflatoxins were detected at excitation and emission wavelengths of 360 and 440 nm, respectively. Using a series of calibration solutions in methanol, calibration curves were drawn for HPLC method validation. Each standard solution was chromatographed in duplicate. The identification of degraded toxin metabolites was performed by mass spectral studies. Analyses of the degraded toxins and their products were carried out by a surveyor LC system equipped with a mass spectrophotometer and PDA plus detectors (Thermo Fisher Scientific Waltham, MA, USA). All analyses were performed in triplicate using a luna phenomenex C18 column (150 × 4.6 mm, 3 µm), in isocratic mode. The column temperature was maintained at 30 • C. The injection volume was 10 µL, whereas the mobile phase consisted of methanol:acetonitrile:water in 22.5:22.5:55.0 v/v ratio. The flow rate was 0.5 mL/min. The capillary temperature was 335 • C, sheath gas flow and auxiliary gas flow were 20 and 4 L/min, respectively. Source voltage, capillary voltage and tube lens voltage were 5 KV, 49 V and 120 V, respectively. Mass spectrometry/mass spectrometry was carried out using a Thermo Scientific LTQ XL System equipped with electrospray ionization (ESI) source operating in the positive ionization mode with a capillary voltage of 49.0 V, a source voltage of 5.0 KV, a tube lens voltage of 110 V and a capillary temperature of 275 • C. The sheath and auxiliary gas flow were adjusted to 3 and 0.4 L/min, respectively, to get a stable spray. Data were collected in positive mode within the range of 100 to 500 m/z. The identification of unknown compounds was based on the accurate measurement of the mass of parent ions and fragments, as well as other useful MS/MS spectrum information. The bio-toxicity of degraded toxin products was checked using a brine shrimp (Artemia salina) bioassay following the method developed by Solis 36, with some modifications. Brine shrimp eggs, 100-200 mg, were hatched in artificial seawater (34g sea salt/L of deionized water) by incubation at 26 • C under a 60 W lamp. After separating from shells, the nauplii were transferred to fresh seawater. A total of 300 µL of treated and untreated AFB1 (50, 100, 200, 300 µg/L) and AFB2 (20, 50, 90 , 130 µg/L) was added to 96-well plates and dried overnight. After solvent evaporation, the toxins were redissolved in seawater (200 µL). Another 200 µL of seawater containing 40-45 organisms was pipetted into each well, making a final volume of 400 µL and were incubated at 26 • C for 24-96 h. Methanol was used as positive control, while for the negative control, seawater was used. Mortality was calculated by counting the immobile (dead) larvae under a stereomicroscope. The test was performed in triplicate. Five replicates were performed of each treatment, and the values are presented as mean ± standard error. Data acquired in the above experiments were subjected to statistical analyses using DSSTAT software. Analysis of variance (ANOVA) and differences among the means was calculated for significance at p ≤ 0.05 using Tukey's multiple range test. 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Data Availability Statement: Data is contained within the article. The authors declare no conflict of interest.