Mitigative effect of green tea extract against mercury(II) chloride toxicity in Allium cepa L. model.

Mercury (Hg) is a highly toxic heavy metal for all organisms. In the present study, the mitigative role of 190 mg/L and 380 mg/L doses of green tea extract (GTex) against mercury(II) chloride (HgCI2)-induced toxicity was evaluated in Allium cepa L. For this aim, selected physiological, genotoxicity, and biochemical parameters as well as meristematic cell injuries in the roots were investigated. Ratios of catechin and caffeine in GTex were determined by HPLC analysis. Also, free radical scavenging activity of GTex was tested against superoxide and hydrogen peroxide radicals. As a result of HgCI2 application, germination percentage, root elongation, weight gain, and mitotic index (MI) declined, while the frequency of micronucleus (MN), chromosomal abnormalities (CAs), and meristematic cell damages increased. HgCI2 administration also led to a significant increase in malondialdehyde content, superoxide dismutase, and catalase activities which are signs of oxidative stress. On contrary, applications of GTex together with HgCI2 reduced HgCI2-induced adverse effects in all parameters in a dose-dependent manner. Antioxidant components in GTex were listed as caffeine, epigallocatechin gallate, epigallocatechin, epicatechin gallate, and catechin according to their abundance. GTex exhibited a strong scavenging ability in the presence of superoxide and hydrogen peroxide radicals. The present study revealed the strong protective capacity of GTex against HgCI2-induced toxicity in A. cepa owing to its high antioxidant content with a multifaceted perspective. With this study, a reliable starting point was established for future studies investigating the more common and diverse use of GTex against toxic substances.

Introduction

Mercury (Hg) and Hg compounds are used in many fields ranging from agriculture to medicine. Most of the Hg deposits of the world are in certain countries, including China, Kyrgyzstan, Mexico, Peru, Russia, Slovenia, Spain, and Ukraine, and are used in various industries (UNEP 2013). Hg is utilized in the electrical, cement, mining, paint, and paper industries. It is also a catalyst in plastic production, a component in various measurement and control devices such as barometers and thermometers, a filling material in dental treatments, and a fungicide in agriculture (Özbolat and Tuli 2016). Natural sources of Hg in the environment are soil and rocks. As a result of mining and various human activities, Hg compounds in rocks can be released and accumulate in high concentrations in soil or surface waters (Öztürk 2006). The increase in Hg contamination in nature with industrialization has tripled the Hg pollution in the environment. As a heavy metal, even small amounts of Hg can cause adverse effects on organisms including humans (Kamynsky et al. 2016). Hg toxicity varies depending on its chemical form. Hg exists in three forms: metallic, inorganic, and organic. Metallic Hg has a property that does not form a compound with other elements, is insoluble in water, and can evaporate in highly toxic amounts at room temperature. Inorganic Hg compounds, called mercury salts, are formed as a result of the combination of Hg with chlorine, sulfur, and oxygen. They are soluble in water and can introduce human body through direct contact and diet (Liu et al. 2021). Mercury(II) chloride (HgCl2), one of the inorganic compounds of Hg, has been classified as a “violent poison” (Kumari and Chand 2021). Organic Hg, which is formed by the combination of Hg with the carbon atom, is the most toxic form and has a lipophilic character. Organic Hg, which is formed by microorganisms such as Desulfovibrio desulfuricans and by various natural processes, is called methyl mercury and can also be obtained chemically by methylation of inorganic mercury (Akcan and Dursun 2008; Özbolat and Tuli 2016). Humans, aquatic organisms, and plants are open targets for Hg poisoning. The toxic effects of Hg in organisms are related to its high affinity for sulfhydryl groups. Hg is bound to macromolecules through sulfur with an oxidation state of − 1 and − 2. In most cases, the binding sites are the thiol groups of the Cys residue in the macromolecule (Ajsuvakova et al. 2020). As a result of interaction between Hg and a macromolecule containing the -SH group, irreversible damage to the cell membrane, enzyme inhibition, impairment in transport mechanisms, and dysfunction in structural/functional proteins occur (Mutter et al. 2005; Zhu et al. 2021). Generally, Hg toxicity may increase neurological and neurodegenerative, metabolic, cardiovascular, and renal diseases while Hg in elemental form is especially harmful to the brain and kidneys (Ajsuvakova et al. 2020). Inorganic Hg forms are more accessible for plants than organic ones. Plants are contaminated with Hg as a result of irrigation with wastewater or Hg-containing pesticide applications. In plants, Hg exhibits some toxic effects such as damage to the cell membrane and aquaporin, inhibition of light and dark reactions of photosynthesis, and root damage. Foods contaminated with Hg, including edible parts of the plants, are the main routes of Hg exposure for humans (Natasha et al. 2020).

The toxic effects of heavy metals and many xenobiotics can be reduced by various antioxidant compounds. Green tea is a powerful antioxidant with a high content of catechins (Larsen et al. 2010; Bettuzzi et al. 2021). In green tea production, unlike black tea, Camellia sinensis L. leaves are dried and steamed to prevent fermentation (Cabrera et al. 2003). Research on the health benefits of tea has focused on green tea, as it contains more catechins than other types of tea (black and oolong). Green tea is particularly rich in flavonoids (30% by dry weight) including catechins and catechin derivatives. The most abundant catechins in green tea are ( −)-epigallocatechin-3-gallate (EGCG) (70%), epicatechin-3-gallate (ECG), and ( −)-epigallocatechin (EGC) (Shirakami and Shimizu 2018). The main flavonols found in green tea are quercetin, kaempferol, and myricetin (Maiti et al. 2019). In addition, gallic acid, chlorogenic acid, neochlorogenic acid, and p-coumaryl quinic acid are frequent phenolic acids found in green tea (Şahin and Özdemir 2006). These complex components contribute to many biological activities of green tea. Anticancer, antiatherosclerotic, antiobesity, antidiabetic, antibacterial, immunostimulatory, and anti-viral properties of green tea are mostly associated with these compounds (Suzuki et al. 2012; Hemmati et al. 2021). It was recently reported that EGCG extracted from green tea inhibits coronavirus replication (Jang et al. 2021).

As studies of toxic substances in humans raise ethical concerns, various plant, animal, and microbial analyses have been developed to assess toxicity and contamination (Xia et al. 2013). Allium assay, the most common plant experiment, reveals chromosomal damages in the meristem cells of the root of A. cepa that resulted from genotoxicity of dangerous chemicals (Kaur et al. 2019). The Allium assay is well-accepted for being cheap and simple as well as having highly correlated results with other assays (Özkara et al. 2015).

Determination of potential protectors against Hg poisoning is one of the important research topics. In this context, this work investigated whether the green tea extract (GTex) could mitigate damages caused by HgCl2 in growth (germination rate, root elongation, weight gain), genotoxicity (Mitotic index, chromosomal aberrations), biochemical parameters (malondialdehyde level, superoxide dismutase, and catalase activity), and meristematic cell damages of A. cepa. Mercury-induced toxicity was examined with multiple parameters and the mitigative effect of GTex in each parameter was investigated. As the catechins in green tea are associated with antioxidant potential, the catechin content of GTex was analyzed by HPLC. The radical scavenging effect of GTEx was tested against strong oxidant superoxide and hydrogen peroxide (H2O2). With these analyses, the toxicity of HgCl2 and the mitigative effects of GTEx were demonstrated with a versatile model.

Materials and methods

Chemicals

Among the forms of mercury, HgCl2 was used because of its water-soluble properties and also inorganic forms of mercury are more accessible to plants than organic ones. HgCI2 was obtained from Merck (≥ 99.5%, CAS Number 7487–94-7). All standards and mobile phase solutions (purity: 99%) of HPLC were obtained from Sigma-Aldrich. Pure green tea extract (60 capsules × 380 mg) was obtained commercially from Sepe Natural (İzmir/Turkey). Uniform and healthy small bulbs (A. cepa L., 2n = 16) used for the assay were obtained from Giresun, Turkey.

Experimental design

In this study, the protective feature of GTex against HgCl2 toxicity was investigated. Mercury toxicity and green tea protection were investigated using physiological, cytogenetic, and biochemical parameters. The protective property of green tea is related to its phytochemical composition and radical scavenging activity. For this purpose, HPLC analysis and radical scavenging activity were also investigated. All parameters used in the study were given in Diagram 1.

Diagram 1.

Experimental design of study

HPLC analysis

GTex samples were extracted before HPLC analysis. For extraction, 1 g of sample was incubated with 150 mL of acetonitrile:water (1:1) for 40 min at 25 °C. The extract was filtered and then used for HPLC analysis (Agilent, 1260 Infinity series, RID) with an XDB-C8 analytical column (Zorbax Eclipse, 150 mm * 4.6 mm, 5 µm). The mobile phase consisting of water-acetonitrile-formic acid was used for HPLC analysis of GTex. Gradient elution program was applied for 20 min at a flow rate of 1 mL/min. Injection volume was 5.0 μL. Solutions of standard compounds such as epigallocatechin, epigallocatechin gallate, epicatechin gallate, catechin, and caffeine (100 μg/mL) were prepared in acetonitrile and stored at 4 °C. All samples were microfiltered before injection (Fernandez et al. 2000).

Radical scavenging activity of GTex

Free radical scavenging is one of the important mechanisms of antioxidants. In this study, free radical scavenging activity of GTex was tested against superoxide and hydrogen peroxide.

The superoxide radical scavenging activity of GTex was studied according to the modified method proposed by Gülçin et al. (2010). Light induction of the reaction mixture was carried out using a fluorescent lamp (20 W). A mixture (3 mL) of riboflavin (1.33 × 10−5 M), methionine (4.46 × 10−5 M), and nitroblue tetrazolium (8.15 × 10−8 M) was prepared and illuminated at 25 °C for 40 min. The un-illuminated mixture was used as a blank. Different concentrations of GTex (0.125–1.0 mg/mL) were added to the reaction medium and the absorbance of all mixtures was measured at 560 nm. The reduced absorption of the reaction mixture indicated the increased scavenging activity. The percentage of superoxide scavenging activity was calculated using Eq. 1.

A1 is the absorbance of resveratrol or standard solution, and A2 is the absorbance of the control. The experiment was repeated three times at each concentration.

H2O2 scavenging experiments were carried out according to the procedure of Ruch et al. (1989). A solution containing different concentrations of GTex (3.4 mL, 0.125–1.0 mg/mL) and 0.6 mL H2O2 (40 mM) was prepared. The absorbance of the reaction mixture was measured spectrophotometrically at 230 nm. H2O2-free sodium phosphate buffer was accepted as blank. The scavenging activity was determined by monitoring the decrease in H2O2 absorbance. The absorbance of H2O2 and the scavenging activity of resveratrol were calculated using Eqs. 2 and 3, respectively.

A1 is the absorbance of solution in the presence of GTex, and A2 is the absorbance of the control.

Butylated hydroxytoluene (BHT) was used as a standard antioxidant agent.

Germination and physiological parameters

Equal-sized (4.7 ± 0.1 g) and healthy A. cepa bulbs were sterilized using NaClO (2.5%) solution for 10 min and then rinsed with distilled water. The bulbs of A. cepa were divided into six treatment groups and immersed in the prepared solutions in glass beakers: Control–Tap water, 190 mg/L GTex, 380 mg/L GTex, 100 mg/L HgCI2, 190 mg/L GTex + 100 mg/L HgCI2, and 380 mg/L GTex + 100 mg/L HgCI2. All solutions were prepared in dH2O. Bulbs were germinated at 23 °C in dark for 72 h. At the end of the 72nd hour, germination periods were ended, and then germination rates were calculated using 50 bulbs (n = 50). HgCI2 dosage was determined by considering our previous studies (Çavuşoğlu et al. 2018). The applied GTex concentration was chosen as a value above the dose at which the protective effect was observed in Allium cells (Çavuşoğlu 2020). A millimetric ruler was used to measure the root lengths of 10 bulbs (n = 10). The mean difference in weights before and after germination was measured with precision scales over 10 bulbs (n = 10).

Cytogenetic parameters

Root tips of (1–1.5 cm) A. cepa bulbs were used for cytogenetic analysis. Root tips were pretreated with saturated para-dichlorobenzene solution for 4 h and then fixed for a day in solution of ethanol–acetic acid (75–25%). Fixated tips were hydrolyzed using 1 N HCl at 60 °C for 17 min before stained with Feulgen for 1.5–2 h. To prepare squash slides, stained root tips were crushed with a drop of 45% acetic acid (Sharma and Gupta 1982). Mitotic index (MI), frequencies of micronucleus (MN), and chromosomal abnormalities (CAs) were observed at 500 × magnification with a microscope (Olympus CX41) and photographed with a digital camera (Olympus C-5060). MI was calculated by analyzing 1,000 of cells from ten slides prepared from each treatment (10,000 for each treatment). CAs and MN frequencies of each treatment were observed on ten slides (1,000 cells for each treatment) (Çavuşoğlu et al. 2021).

Antioxidant/oxidant dynamics

Lipid peroxidation

MDA levels of A. cepa roots were determined as an indicator of lipid peroxidation in cells. Lipid peroxidation experiment was conducted according to the method suggested by Unyayar et al. (2006). Root tissue (0.5 g) was homogenized in the presence of 1 ml of 5% trichloroacetic acid (TCA) solution. The homogenates of samples were centrifuged at 12,000 rpm for 15 min at room temperature. Equal volumes of 0.5% thiobarbituric acid (TBA), TCA (20%), and supernatant were mixed in a glass tube and incubated at boiling hot bath (98 °C) for 30 min. At the end of 30 min, the mixture tubes were transferred to an ice-cold bath to stop the reaction. Cooled mixtures were centrifuged at 10,000 rpm for 5 min. The absorbance of the mixtures was read at 532 nm on a spectrophotometer.

Antioxidant enzymes

SOD and CAT activities were measured to understand the oxidative stress levels of root samples. SOD and CAT activity assays were performed using the same extraction methods. 0.5 g of fresh root material from sample was homogenized in the presence of 5 mL sodium phosphate buffer (pH 7.8). The collected homogenates were centrifuged at 10,500 rpm for 20 min at 4 °C and their supernatants were used for SOD and CAT enzyme analysis (Çavuşoğlu et al. 2021).

Activity of SOD was determined using the method proposed by Beauchamp and Fridovich (1971). To obtain a reaction solution, 0.01 mL extract was added to a mixture containing 1.5 mL sodium phosphate buffer (0.05 M, pH 7.8), 0.28 mL deionized water, 0.3 mL nitroblue tetrazolium chloride, 0.3 mL methionine, 0.3 mL EDTA-Na2, 0.3 mL riboflavin, and 0.01 mL 4% insoluble polyvinylpyrrolidone. A 215 W fluorescent lamp was used to start the reaction in glass tubes. At the end of the 10th minute, absorbance of the reaction mixture reaction was measured at 560 nm.

Activity of CAT was measured using the modified method of Beers and Sizer (1952). To prepare a reaction mixture, 1.5 mL of 200 mM sodium phosphate buffer (pH 7.8), 0.3 mL of 0.1 M H2O2, and 1.0 mL of distilled water were mixed in a glass tube. Addition of 0.2 mL sample extract to the mixture initiated the reaction. CAT activity was measured by monitoring the reduction in absorbance at 240 nm as a result of H2O2 consumption. Activity was expressed as OD240 nm min g−1 FW. MDA, SOD, and CAT assays were repeated three times and performed in triplicate.

Anatomical alterations

Root tips were investigated for HgCI2-induced anatomical alterations in meristematic cells. Before cross-sections were taken manually, root tips were thoroughly rinsed with distilled water to remove residues. Cross-sections were stained with a drop of 1% methylene blue. Meristematic damages were observed at 500 × magnification with a light microscope (Olympus CX41 with Olympus C-5060 digital camera). Meristematic cell damages were classified as no damage, little damage, moderate damage, and severe damage (Yalçın et al. 2021).

Statistical analyses

The statistical analyses of results were performed using SPSS (version 23) software (SPSS Inc., Chicago, IL, USA). Data were shown as mean ± standard deviation (SD). The statistical significance between the means was assessed using One-way ANOVA (one-way analysis of variance) and Duncan tests, and it was considered statistically significant when the determined value (p) was less than 0.05.

Results and discussion

HPLC analysis of GTex

The presence of different ratios of catechin and caffeine in GTex was determined by HPLC analysis and the chromatogram was given in Fig. 1. In GTex, catechin species were found in the range of 0.559–0.991% (w/w), while caffeine was detected at a rate of 2.12% (w/w). Among the catechins, epigallocatechin gallate and epigallaocatechin were found in higher proportion compared to others. Catechins showed an order according to their presence in GTex as epigallocatechin gallate > epigallocatechin > epicatechin gallate > catechin. It has also been found that there is a higher rate of caffeine in GTex compared to catechins. Fernandez et al. (2000) reported that the proportions of epigallocatechin gallate, epigallocatechin, and catechin in a commercially available green tea extract were 4.6%, 2.25%, and 0.55% (w/w), respectively. Catechins are antioxidant molecules capable of scavenging reactive oxygen species and reactive nitrogen species. Tea catechins are known to protect GSH, a powerful endogenous antioxidant, against oxidation. The relative efficiency of catechins in terms of GSH protection is ranked as epigallocatechin gallate > epigallocatechin > epicatechin gallate > epicatechin (Maurya and Rizvi 2009). Shirakami and Shimizu (2018) reported that the most biologically active member of tea catechines is epigallocatechin gallate due to its suppressive effects against carcinogenesis. The high epigallocatechin gallate and epigallocatechin contents of GTex, as proved by HPLC analysis, show that GTex has an important role in the protection of endogenous antioxidants in cells.

Fig. 1

HPLC chromatogram and the contents (% w/w, dry base) of GTex. a Epigallocatechin, b catechin, c caffeine, d epigallocatechin gallate, e epicatechin gallate

There is a close relationship between the protective role of GTex and its antioxidant activity. Radical scavenging activity plays an important role in antioxidant activity mechanism. The radical scavenging property of GTex was tested against superoxide and H2O2 and the results were given in Fig. 2. Superoxide and H2O2 scavenging effects of GTex and BHT increased with the increasing concentrations of the solutions. Superoxide scavenging activities of 1 mg/mL GTex and BHT were found as 79% and 63.1%, respectively. There were statistically significant differences in superoxide removal activities of GTex and BHT at all tested concentrations except for the 0.25 mg/mL concentration (p < 0.05). The maximum hydrogen peroxide removal activities of GTex and BHT were 71% and 89%, respectively. There were statistically significant differences in H2O2 radical scavenging activities of GTex and BHT at all tested concentrations (p < 0.05).

Fig. 2

Superoxide and H2O2 scavenging property of GTex and BHT. Each histogram is a decimal average. The vertical lines on the bars indicate the standard deviation. Different letters (a–h) indicated averages p < 0.05 are significant

These results indicated that GTex is a powerful antioxidant and would have protective properties against induced oxidative stress. The HPLC analysis performed in this study showed that GTex contains high levels of catechins and that the high radical scavenging effect of GTex is directly related to these catechins. Catechins have the ability to inhibit free radical formation, scavenge free radicals, and chelate transition metal ions, which are catalysts of free radical reactions. In addition, catechins scavenge free radicals such as hydroxyl, superoxide, and lipid radicals (Costa et al. 2007). It is stated in the literature that GTex is a good radical scavenging agent (Masek et al. 2017). Gramza et al. (2005) reported that green tea and green tea polyphenols have a much stronger scavenging effect on active oxygen radicals than vitamin C and vitamin E.

Effects of HgCI2 and GTex on physiological parameters of A. cepa during germination are shown in Table 1. Administration of 190 mg/L and 380 mg/L GTex did not cause a statistically significant change in germination rate, root elongation, and weight gain in A. cepa bulbs (p > 0.05). Absence of difference in physiological parameters in physiological parameters can be interpreted as GTex has no toxic effect on A. cepa bulbs during germination. Application of on 100 mg/L HgCI2 resulted in significant reduction in root elongation (75%) and weight gain (82%) (p < 0.05) as well apparent drop in germination rate (52%) compared to control. Adverse effect of mercurials on plant germination period documented on several plants (Patra and Sharma 2000; Muhammad et al. 2015). Similar to our results, Çavuşoğlu et al. (2018) reported depressive effects of HgCI2 on germination percentage, weight gain, and root length of A. cepa bulbs. Patra and Sharma (2000) stated that Hg effects the embryo by causing -S-Hg-S- bridge formation and effecting -SH system in cells. -SH system disruption causes more destructive consequences in the embryo than other tissues due to its high -SH content (Patra and Sharma 2000). Mercury is bound to macromolecules through sulfur with an oxidation state of − 1 and − 2. In most cases, the binding sites are the thiol groups of the Cys residue in the macromolecule (Ajsuvakova et al. 2020). Modification of thiol groups in proteins can cause serious functional damage in biological systems, including loss of enzyme activity. Reduced root elongation and weight gain showed severe damage on germinated A. cepa bulbs due to -SH degradation caused by HgCl2 administration. It should be considered that Hg-induced oxidative stress is associated with the interaction between Hg and -SH groups and is equally important in the terms of toxicity (Hansen et al. 2006). Administration of increasing GTex doses (190 mg/L and 380 mg/L GTex) with 100 mg/L HgCl2 significantly reduced the adverse effect of HgCl2 on the selected physiological parameters of A. cepa depending on the dose, but their physiological parameter results were still below control levels. The best reducing effect against Hg toxicity was observed in 380 mg/L GTex + 100 mg/L HgCl2 application with 22% reduction in germination rate, 34% reduction in root elongation, and 44% reduction in weight gain compared to control. GTex doses mitigated HgCl2 induced toxicity in germination process. Many experimental studies in the literature indicate that plant extracts, including tea, can alleviate experimentally induced Hg toxicity in animals (Bhattacharya 2018). In contrast, there is no previous study on the role of GTex in protecting against Hg toxicity in plants. Studies on plant extracts and heavy metals in A. cepa indicated that the protective roles of plant extracts were related to their antioxidant capacity (Glińska et al. 2007; Macar et al. 2020a; Kalefetoğlu Macar et al. 2020a). Similarly, the protective property of GTex against mercury is also associated with its antioxidant activity. Mercury acts by inhibiting antioxidants containing -SH such as glutathione, while green tea improves the deteriorated antioxidant balance of the cell. Furthermore, GTEx also has a protective role on -SH groups in molecules. Miyagawa et al. (1997) reported that GTex and tea polyphenols play an important role in the inhibition of the loss of thiol groups in molecules. Especially catechin and its derivatives in green tea not only exhibit strong antioxidant properties in vitro, but also modulate the activity of antioxidant defense enzymes such as superoxide dismutase (SOD), glutathione peroxidase (GPx), and catalase (CAT). In this way, they mediate the recovery of the antioxidant balance disrupted by mercury (Simos et al. 2012).

Table 1

Effects of HgCI2 and GTex on physiological parameters

Treatments	Germination rate (%)	Root elongation (cm)	Weight gain (g)
Control	96	9.50 ± 1.70a	+ 6.30a
190 mg/L GTex	98	9.60 ± 1.74a	+ 6.41a
380 mg/L GTex	98	9.70 ± 1.75a	+ 6.48a
100 mg/L HgCI2	44	2.40 ± 0.96d	+ 0.50d
190 mg/L GTex + 100 mg/L HgCI2	60	4.10 ± 1.38c	+ 1.85c
380 mg/L GTex + 100 mg/L HgCI2	75	6.30 ± 1.55b	+ 3.50b

*Means with the same letter within the same column are not statistically different (p > 0.05)

Normal appearance of mitotic phases in root tips of control group is presented in Fig. 3. Effects of GTex and HgCI2 on MI, MN, and CAs are shown in Table 2 and Fig. 4. Similar to physiological parameters, application of 190 mg/L and 380 mg/L GTex did not induce statistical changes on the frequencies of MI, MN, and CAs. MI measures the proportion of cells in the mitosis phase and is a common indicator of cell proliferation (Jaiswal et al. 2021). MI results of GTex exposed bulbs revealed that GTex did not hinder cell mitosis as a toxic substance. GTex also did not increase incidences of MN (Fig. 4a) and CAs which are reliable biomarkers of genotoxicity (Grant 1982). In contrast to the effects of GTex, administration of 100 mg/L HgCl2 resulted in a statistically significant decrease in MI (43%) and a sudden increase in the frequencies of MN (54.4 ± 5.83) and CAs compared to control (p < 0.05). In the presence of HgCl2, fragment (Fig. 4b, c) formation (40.2 ± 4.85) was the most observed CAs followed by sticky chromosomes (Fig. 4d) (35.7 ± 3.24) and vagrant chromosomes (Fig. 4e, f) (28.5 ± 3.12) (p < 0.05). Bridge formation (Fig. 4f), unequal distribution of chromatin (Fig. 4g), irregular mitosis (Fig. 3h), and nucleus damage (Fig. 4i) were also observed as a result of HgCl2 exposure. These results provided strong evidence for Hg toxicity. In line with our results, the reduction of mitotic index and induction of CAs in A. cepa caused by Hg treatment were previously reported (Patra et al. 2004; Sharma et al. 2012; Çavuşoğlu et al. 2018). In addition, Çavuşoğlu et al. (2018) also mentioned that the most common Hg-induced CAs in A. cepa were MN, fragment formation, and sticky chromosomes. Crespo-López et al. (2009) explained the genotoxic effect of Hg with oxidative stress caused by free radical and reactive oxygen species (ROS) formation caused by Hg. Although the main reason of Hg genotoxicity is oxidative stress, adverse effects of Hg on microtubules, DNA repair mechanism, and DNA (directly) are also important in genotoxicity (Crespo-López et al. 2009). Briefly, the genotoxic effect of mercury is attributed to its ability to bind to the sulfhydryl groups of tubulin, impairing spindle function, causing chromosomal aberrations and polyploidy. Another important mechanism of mercury genotoxicity is its ability to produce free radicals that can cause DNA damage (Telahigue et al. 2020).

Fig. 3

Normal mitosis phases in meristems of A. cepa root tip cells (a interphase, b prophase, c metaphase 2n = 16, d anaphase, e telophase. Scale bar = 10 μm)

Table 2

Effects of GTex and HgCI2 on genotoxicity parameters

CAs	Control	190 mg/L GTex	380 mg/L GTex	100 mg/L HgCI2	190 mg/L Gtex + 100 mg/L HgCI2	380 mg/L Gtex + 100 mg/L HgCI2
MI	851 ± 30.5a	864 ± 32.6a	871 ± 34.5a	485 ± 20.4d	551 ± 24.8c	691 ± 27.6b
MN	0.26 ± 0.32d	0.16 ± 0.24d	0.10 ± 0.15d	54.4 ± 5.83a	40.1 ± 4.36b	31.5 ± 3.98c
FRG	0.00 ± 0.00d	0.00 ± 0.00d	0.00 ± 0.00d	40.2 ± 4.85a	32.3 ± 3.95b	25.6 ± 3.14c
SC	0.24 ± 0.34d	0.13 ± 0.22d	0.00 ± 0.00d	35.7 ± 3.24a	25.8 ± 2.96b	18.7 ± 2.38c
VC	0.00 ± 0.00d	0.00 ± 0.00d	0.00 ± 0.00d	28.5 ± 3.12a	21.9 ± 2.85b	14.6 ± 2.23c
B	0.00 ± 0.00d	0.00 ± 0.00d	0.00 ± 0.00d	24.3 ± 2.52a	15.2 ± 1.80b	9.60 ± 1.45c
UDC	0.00 ± 0.00d	0.00 ± 0.00d	0.00 ± 0.00d	18.8 ± 1.53a	10.4 ± 1.12b	6.60 ± 0.92c
IM	0.18 ± 0.24d	0.00 ± 0.00d	0.00 ± 0.00d	15.1 ± 1.24a	8.70 ± 0.91b	4.30 ± 0.66c
ND	0.00 ± 0.00d	0.00 ± 0.00d	0.00 ± 0.00d	5.00 ± 0.84a	3.10 ± 0.69b	1.50 ± 0.52c

*Means with the same letter within the same line are not statistically different (p > 0.05). MI, mitotic index; MN, micronucleus; FRG, fragment; SC, sticky chromosome; VC, vagrant chromosome; B, bridge; UDC, unequal distribution of chromatin; IM, irregular mitosis; ND, nucleus damage

Fig. 4

Chromosomal aberrations promoted by HgCI2 (a MN in interphase MN, b fragment in interphase, c fragment in metaphase, d sticky chromosome, e vagrant in early telophase, f vagrant in anaphase (Straight arrows), bridge (dotted arrow), g unequal distribution of chromatin, h irregular mitosis, i nucleus damage)

Parallel to physiological parameters, administration of 190 mg/L and 380 mg/L GTex doses with 100 mg/L HgCl2 restored the genotoxic effects of Hg in a dose depending manner. The MI level was restored to 81% of the control in the 380 mg/L GTex application with Hg, and 65% in the 190 mg/L GTex application with Hg (p < 0.05). Hg-induced MN frequencies also decreased with the 190 mg/L (40.1 ± 4.36) and 380 mg/L (31.5 ± 3.98) GTex application given with Hg (p < 0.05). All CAs resulting from Hg treatment declined with increased GTex administration (p < 0.05). Although the levels in control had not been reached, the application of GTex had a significant mitigating power on the adverse effects of the Hg on the genotoxicity parameters. Our findings regarding the antigenotoxic properties of GTex were consistent with previous studies based on different test systems such as Chinese hamster V-79 (Roy et al. 2003), mice (García-Rodríguez et al. 2013), and human leucocytes (Glei and Pool-Zobel 2006; Jo et al. 2008). The main focus of these studies was on catechins and polyphenols, powerful antioxidants found in abundance in green tea. Hasegawa et al. (1995) noted that the rich antioxidant content of tea prevented induction of DNA damage and DNA scission from genotoxic agents. Hg-induced genotoxicity might be alleviated by GTex preventing the formation of free radicals or facilitating their scavenging. GTex reduces the genotoxic effects by reducing free radicals and protecting thiol groups and also has a positive effect on the DNA repair mechanism. Chong et al. (2019) reported that GTex enhances expression of DNA repair genes in yeast cells.

Oxidative stress related to HgCI2 and GTex applications in A. cepa was investigated using MDA level, SOD, and CAT activity analyses (Table 3). Applications of 190 mg/L and 390 mg/L GTex did not induce a significant change in MDA levels as well as SOD and CAT activities compared to control in A. cepa root tissue. In contrast, HgCl2 treatment significantly increased MDA level (2.7 times), SOD activity (2 times), and CAT activity (2.9 times) compared to control (p < 0.05). On the other hand, co-administration of increasing GTex doses with HgCl2 significantly reduced SOD and CAT activities and MDA levels compared to HgCl2 administration alone. Decreases in MDA, SOD, and CAT values in 380 mg/L GTex + 100 mg/L HgCl2 application were higher than the 190 mg/L GTex + 100 mg/L HgCl2 group, although they were still above the control levels. While MDA content is an indicator of lipid peroxidation in cells caused by oxidative stress, CAT and SOD are protectors against oxidative stress (Macar 2020). In parallel with the physiological and genotoxic results of this study, application of GTex did not trigger any oxidative stress in A. cepa bulbs. Unlike GTex, application of HgCI2 caused severe oxidative stress in A. cepa. HgCI2 administration caused a significant increase in MDA level and abnormality in antioxidant enzyme levels, resulting in deterioration of antioxidant/oxidant balance. Hg can damage the cells by increasing the ROS level (Ercal et al. 2001). Free radicals generated by Hg have different effects, but genotoxic effect is the most important one. Lipids are very sensitive to ROS and mercury-induced free radicals cause lipid peroxidation (Rabeh et al. 2019). In the cell membrane, which has a high lipid content, changes occur in membrane structure and permeability due to lipid peroxidation. MDA is a mutagenic product formed as a result of lipid peroxidation. At the end of the normal biochemical process, low levels of MDA can occur in cells and can be removed with the antioxidant system. Increasing MDA level indicates oxidative stress and lipid peroxidation in the cell (Rana et al. 1995; Crespo-López et al. 2009). Oxidative stress caused by mercurial was observed on a variety of organisms such as tomato (Cho and Park 2000), mallard ducks (Hoffman and Heinz 1998), cucumber (Cargnelutti et al. 2006), and human (Marcusson and Jarstrand 1998; Granitzer et al. 2020). In addition, modifying effect of Hg on SOD and CAT activities in A. cepa was mentioned by other researchers (Subhadra et al. 1991; Fatima and Ahmad 2005). Medicinal plants and their products have protective effects against Hg-induced oxidative stress by raising of endogenous enzymatic and non-enzymatic defense systems (Bhattacharya 2018). With GTex application, a decrease in MDA levels and an improvement in antioxidant/oxidant balance were observed. The decrease in MDA levels is closely related to the radical scavenging activity of GTex. The ability of GTex to scavenge free radicals was determined by previous analyzes in this study. GTex exhibited a significant scavenging effect against superoxide and H2O2 that cause oxidation in the cell and especially in cell membrane lipids. Especially catechins in GTex content have an important role in scavenging free radicals. Catechins perform their activities with H-donating antioxidant processes, reducing oxidative stress and maintaining the antioxidant balance in the cell. Catechins also have mechanisms that directly or indirectly regulate the expression of enzymatic antioxidants including SOD (Simos et al. 2012). Caffeine, another active ingredient in GTex, also scavenges various radicals such as peroxyl and hydroxyl, thereby reducing oxidative stress in the cell (Demirtaş et al. 2012). In short, the catechin derivatives and caffeine found in GTex allow the protection and continuation of the antioxidant balance that has been disturbed by the mercury.

Table 3

Effect of HgCI2 and GTex on biochemical parameters

Treatments	MDA (µM g−1 FW)	SOD (U mg−1 FW)	KAT (OD240 nm min.g−1 FW)
Control	2.70 ± 1.48d	66.8 ± 5.32d	0.92 ± 1.15d
190 mg/L GTex	2.60 ± 1.45d	64.1 ± 5.19d	0.88 ± 1.12d
380 mg/L GTex	2.50 ± 1.42d	65.3 ± 5.24d	0.87 ± 1.10d
100 mg/L HgCI2	8.80 ± 1.86a	135 ± 9.16a	2.68 ± 1.60a
190 mg/L GTex + 100 mg/L HgCI2	7.30 ± 1.62b	110 ± 8.25b	2.20 ± 1.48b
380 mg/L GTex + 100 mg/L HgCI2	5.00 ± 1.48c	92.4 ± 6.58c	1.83 ± 1.30c

*Means with the same letter within the same column are not statistically different (p > 0.05)

Anatomical alterations

Since the roots are the first contact areas with heavy metals, cell damage can be seen easily in the meristematic tissue in the roots. Table 4 shows the severity of meristematic cell damages in GTex and HgCI2 treatments. Meristematic cell damages induced by HgCI2 are presented in Fig. 5. No meristematic cell injury was observed in control, 190 mg/L, and 380 mg/L GTex treatments. Application of HgCI2 resulted in severe epidermis cell damage (Fig. 5e), moderate thickening of the cortex cell wall (Fig. 5f), moderate cortex cell damage (Fig. 5f), severely flattened cell nucleus (Fig. 5g), and moderate indistinct transmission tissue (Fig. 5h). Severity of all meristematic cell damage types was decreased with increasing GTex doses. Scarce Hg in the soil tends to accumulate in the root tissue, indicating that the roots act as a barrier to Hg (Patra and Sharma 2000). Roots are more vulnerable than other parts of the plant due to Hg accumulation. Similar to our findings, Çavuşoğlu et al. (2018) reported meristematic cell damages in A. cepa induced by Hg exposure. In addition, copper-induced injuries in the A. cepa root meristem have been reported previously (Macar et al. 2020b; Kalefetoğlu Macar et al. 2020b). The most likely causes of meristematic cell damages are direct attack of ROS arising from Hg-related oxidative imbalance to the macromolecules in the cells as well as cell membrane injuries caused by lipid peroxidation. Results of meristematic cell damages were in line with growth retardation, genotoxicity, and oxidative stress finding of this study. Thanks to its high antioxidant power, GTex prevented root damage by reducing the toxic effects of Hg.

Table 4

Protective role of GTex against HgCI2-induced meristematic cell damage

Damages	ECD	TCCW	CCD	FCN	ITT
Control	-	-	-	-	-
190 mg/L GTex	-	-	-	-	-
380 mg/L GTex	-	-	-	-	-
100 mg/L HgCI2	+  +  +	+  +	+  +	+  +  +	+  +
190 mg/L m GTex + 100 mg/L HgCI2	+  +	+	+	+  +	+
380 mg/L GTex + 100 mg/L HgCI2	+	+	-	+	-

*ECD, epidermis cell damage; TCCW, thickening of the cortex cell wall; CCD, cortex cell damage; FCN, flattened cell nucleus; ITT, indistinct transmission tissue. ( −), no damage; ( +), little damage; (+ +), moderate damage; (+ + +), severe damage

Fig. 5

Meristematic cell damage caused by HgCI2 application (a normal appearance of epidermis cells, b normal appearance of cortex cells, c normal appearance of nucleus, d normal appearance of transmission tissue, e epidermis cell damage, f cortex cell damage (black arrows), thickening of the cortex cell wall (white arrows), g flattened cell nucleus, h indistinct transmission tissue)

Conclusion

In conclusion, mitigative and healing capabilities of GTex against HgCI2-induced toxicity revealed with detailed A. cepa assay. Although toxicity of Hg has already been investigated, this is the first work that demonstrated the preventive and restorative role of GTex extract against a dangerous heavy metal in A. cepa. Results of the study clearly exhibit HgCI2 exposure has serious adverse effects on all investigated parameters. On the contrary, GTex application mitigated and restored the harmful effects of Hg-induced toxicity on all parameters depending on the dose. Results of biochemical parameters pointed that well-known antioxidant power of GTex closely related to alleviation of toxicity caused by Hg. The absence of a negative effect of GTex in this study answered some concerns regarding the use of this product. The overall results of this study provide a reliable starting point for studies investigating the more widespread and diverse use of GTex against toxic substances, especially heavy metals.

As a result, it was determined that HgCI2, which is widely used in industrial sectors and polluting the environment in various ways from these sectors, has a toxic effect on A. cepa. For this reason, the use of HgCI2 in industrial areas should be avoided as much as possible or its contamination should be reduced. Within the scope of the study, it was determined that GTex plays a role in reducing HgCI2 toxicity and the A. cepa test material is a useful biological indicator to observe these effects. A. cepa, a model eukaryotic organism, is very useful in determining the toxic effects of chemical agents in eukaryotes and in detecting agents that will reduce these toxic effects.