Bioaccumulation and oxidative stress induction of heavy metals in ecosystem of an urban region: A case study to assess ecotoxicological risk on freshwater mollusk, Lanistis carinatus in Kafr El-Zayat region, Egypt

doi:10.21608/ejah.2021.134824

Bioaccumulation and oxidative stress induction of heavy metals in ecosystem of an urban region: A case study to assess ecotoxicological risk on freshwater mollusk, Lanistis carinatus in Kafr El-Zayat region, Egypt

10.21608/ejah.2021.134824

Abstract

Bioaccumulation pattern of heavy metals (HMs) emitted from urban region of Kafr El-Zayat city was studied in attributing to oxidative stress induction in freshwater mollusk, Lanistis carinatus. Regional distribution of HMs in water, sediments, mollusk's tissues in collected samples from sites near industrial units showed significantly differences, respect to reference site (rural). Measured metals: cadmium (Cd), lead (Pb), manganese (Mn), copper (Cu), zinc (Zn), and iron (Fe) in the tissues were greater than those found in water and sediments, representing bioconcentration factors (BCFs) in range (0.83-49.13) during summer and (0.00-24.85) during winter for ratio of tissue/water. However, its ranged (0.09-29.25) during summer and (0.00-8.05) during winter for ratio of tissue/sediments. On the other hand, levels of malondialdehyde (MDA) in digestive glands of mollusk from contaminated sites were greater than those of reference site. Moreover, significantly alterations were recorded for catalase (CAT), glutathione peroxidase (GPx), and carbonyl protein (CP) in a positively correlation with measured HMs. From all findings, it was obtained that use of cumulative biomarkers with BCF may provide diagnostic tool to assess ecotoxicological risk in ecosystem of industrial and urban regions.

Keywords

Full Text

Bioaccumulation and oxidative stress induction of heavy metals in ecosystem of an urban region: A case study to assess ecotoxicological risk on freshwater mollusk, Lanistis carinatus in Kafr El-Zayat region, Egypt

Khaled Y. Abdel-Halim¹, Fayz A. Shoukr², Safaa R. Osman¹, Mohamed H. Mona²

¹Mammalian & Aquatic Toxicology Department, Central Agricultural Pesticides Laboratory (CAPL), Agricultural Research Center (ARC), 12618-Dokki, Giza, Egypt

² Department of Zoology, Faculty of Science, Tanta University, Tanta, Egypt

Introduction

Environmental pollution with heavy metals (HMs) is known to be one of the most important problems in urban regions. HMs, dependent on their oxidation state, can be highly reactive and as a consequence toxic to most organisms (Pinto et al., 2003). Aquatic ecosystems can be considered as final sinks for environmental contaminants. Practically, watercourses of urban regions are affected by high inputs of mixtures of organic and inorganic compounds from various sources, such as domestic and industrial sewage waters, abrasion from streets and vehicles (Papiri et al., 2003; Maher et al., 2005; van Metre and Mahler, 2005).

Biomarkers studies are applied in the field (biomonitoring), because they provide an integrated view on how organisms are affected by the bioavailable fraction of the pollution present in the around media. So, HMs can bioconcentrate and bioaccumulate in food chain and contribute the chronic toxicity to aquatic organisms (Ahmad et al., 2010). Potential toxic metals such as cadmium (Cd), nickel (Ni), lead (Pb) and chromium (Cr) mainly have oxidative potential effects than other metals such as iron (Fe), zinc (Zn), copper (Cu), selenium (Se) and manganese (Mn) which are essential for metabolism. However, they become toxic when their concentrations are excessive (Chang et al., 1996).

The cytotoxicity of metals has been extensively linked to oxidative damage Numerous metals are already capable to induce oxidative stress as well as in the presence of transition metals, like Fe and Cu, O₂^·- and H₂O₂ can generate ^·OH through Fenton reaction (Valko et al., 2005). Other non-transition metal ions can also be implicated in reactive oxygen and nitrogen species (ROS/RNS) generation in mitochondria. Thus, potential role of ROS to damage tissues and cellular components is called oxidative stress. Oxidative stress occurs in living organisms when the rate of generation of oxygen radicals exceeds the rate of their decomposition (Sies, 1986). The enzymatic defenses degrade ROS directly such as superoxide dismutase (SOD) which catalyzes the dismutation of two superoxide radicals to hydrogen peroxide. Catalase (CAT) and selenium-dependent glutathione peroxidase (GPx) degrade H₂O₂ (Halliwell and Gutteridge, 1999). On the other hand, production of ROS can initiate lipid peroxidation (LPO) causing an intracellular excess of malondialdehyde (MDA). Also, exposure to ROS is known to cause a range of reversible and irreversible covalent modification of amino acid side-chains of proteins (Chezzi and Bonetto, 2003). They alter proteins structure or function. It has been suggested that induction of protein carbonylation may be a powerful addition to the battery of biochemical endpoints in study of oxidative stress in the environment (McDonagh et al., 2005).

Mollusks are used as a good biomonitoring of water pollution with HMs by being sedentary, hardly tolerant to high concentration of pollutants, easy to identify and having enough tissues for analysis. They reflect the high degree of environmental contamination and are the most useful biomarker tools. The use of oxidative stress biomarkers is considered a potential interest for pollutants impact assessment or seasonal variation in animals under field conditions (Regoli and Principato, 1995). Moreover, the interaction between xenobiotic and the components of the antioxidants defense system plays an important role in the ecotoxicological response of an organism to its environment (Regoli et al., 2006). Therefore, this study was conducted to use freshwater mollusk, Lanistis carinatus to assess bio-accumulation and oxidative stress effect of water pollution with HMs in Kafr El-Zayat region as an urban model.

2. Material and Methods

2.1. Studied area

This study was conducted in the Kafr El-Zayat district of Egypt, which lies on the Nile River (Rosetta branch). This area is one of the main industrial regions and a number of large factories, especially chemical industries: C1 (pesticides), C2 (fertilizers), C3 (oils & detergents), C4 (brick making factories), C5 (salts & acids) and C6 (textile) are located there. Surface waters in this area are thought to be adversely affected by discharges emitted from industrial and urban sources. Five locations were chosen near factories and urbanized areas from which invertebrate were collected: S1 (Belshay village), S2 (El-Demer area) and S3 (Afify area) are near urbanized discharges, salts and pesticide factories, respectively. S4 (Benufer village) and S5 (Rosetta branch) are near factories making pesticides, fertilizers, textile and bricks, respectively (Figure 1). Another site, situated in a rural region was selected as a likely less contaminated reference area (S6), to compare risk factors.

2.2. Heavy metals analysis

2.2.1. Water

Water samples from different sites as marked in the geographic map were collected periodically every season from 2018 to 2019. Heavy metals (HMs) in water samples were determined according to the method (APHA, 1998). About 250 ml of collected water were filtered through Whattman filter paper (No.1) and 5 ml of concentrated nitric acid were added. The samples were boiled to constant volume (5 ml). After cooling, the remained mixture was dissolved in 3 ml of the acid, filtered and completed to 25 ml with deionized water.

2.2.2. Sediments

The samples were taken by using simplified equipment (auger) at a depth of 5 cm of sediment. The water was removed from the sediments before packed in a labeled polyethylene bag and transferred to the laboratory in an icebox. The samples were air dried in the laboratory for 72 hr, before analysis. Five g of sieved sediment were taken into 150 ml conical flasks. So, 50 ml of 0.1M HCl was added and the flask was agitated on an orbital shaker for 30 min. The content was filtered into 50 ml standard flask and made up to mark with 0.1M HCl for the determination of desirable metals (Olowu et al., 2010).

2.2.3. Tissues

Gastropod, L. carinatus were collected and transferred to laboratory in glass jars. Digestive gland was dissected and frozen at -20 ^°C until used. The samples were dried in an oven at 100 ^ºC until constant weight and then mineralised (Salvo et al., 1998). Ten millilitres of a nitric acid/ sulphuric acid (4:1 v/v) mixture were added to 1 g of sample and heated about 1 hr on a hot plate provided with a magnetic agitator and reflux condenser. After cooling, 10 ml of concentrated HCl were added and the volume of the samples was reduced by heating mantles. Finally, the samples were reduced to a quantity of around 5 ml and diluted to 30 ml with deionized water for analysis by Inductive Coupled Plasma Optical Emission Spectroscopy (ICP-OES).

2.2.4. ICP-OES

All measurements were performed on Agilent microwave plasma model 4200 MP-AES. An auto-sampler was used to deliver samples to instrumental cyclonic spray chamber with mass flow-controlled nebulizer gas flow as 0.65 L/min. The instrument was operated in a fast sequential mode at rinse time 30 sec with stabilization time 15 sec and featured to cooled CCD detection. Background and spectral interferences could be easily corrected and accurately using Agilent's MP Expert Software.

The limits of detection (LODs) of measured metals were calculated as double the standard deviation of a series of measurements of a solution against the blank absorbance (ISO/IEC, 1990). Working standards were used and quality assurance procedures and precautions were carried out to ensure reliability of the results. The samples were carefully handled and deionized water was used to avoid contamination. A recovery experiment was carried out by spiked the blank with 50 and 100 ppm of multi-standards of desired metals and the procedures were done as described above. Table 1 highlights the validation and accuracy among studied conditions.

Bioconcentration factor (BCF) is defined as the ratio between the chemical concentration in organism (C_org.) to the respective concentration in the surrounding media (C_media) (EC, 2011).

2.3. Biochemical quantifications

Half g was homogenized in 10 volumes (w/v) of ice-cold saline solution using a polytron homogenizer for 15 sec. The homogenate was centrifuged at 5000 rpm for 20 min at 4 ^°C. The homogenate was used as a source for LPO, while supernatant was used for CAT and GPx and total protein content.

2.3.1. LPO

The barbituric acid reactive substances (TBARS) were used as an index of lipid peroxidation according to Rice-Evans et al. (1991). TBARS was determined by spectrophotometric quantification of MDA content in tissues. Briefly, 250 µl of tissue homogenate was mixed with 1ml of 15% (w/v) trichloroacetic acid (TCA) in 25 mM HCl and 2 ml of thiobarbituric acid (TBA) (0.37%). The samples were boiled for 10 min, quickly cooled, and immediately centrifuged at 5000 rpm for 5 min. Spectrophotometric determination was carried out at 535 nm. MDA was quantified using an extinction coefficient of 156 Mm^-1 and its concentration was expressed as mM/g tissue.

2.3.2. CAT

The enzyme activity was measured following the decrease of absorbance at 240 nm due to hydrogen peroxide (H₂O₂) consumption (Beers et al., 1952). The reaction mixture consisted of 1 ml of 12.5 mM H₂O₂ (substrate), 2 ml of 66.7 mM phosphate buffer, pH 7.0 and an aliquot of enzyme source. The activity was expressed as U/g wet mass. The unit of CAT is the amount of enzyme which liberates half the peroxide oxygen from hydrogen peroxide solution of any concentration in 100 at 25 ^ºC.

2.3.3. Glutathione peroxidase (GPx)

The enzyme activity was measured according to Flohe and Gunzler (1984) by mixing phosphate buffer solution (100 mM), EDTA (50 mM), sodium azide (250 mM), H₂O₂ (10 mM) and enzyme in a cuvette. The change in absorbance at 340 nm was recorded every 3 sec for 40 sec. The activity was expressed as mU GPx/mg protein. One unit of GPx is defined as the amount of enzyme necessary to oxidize 1µM of NADPH per min.

2.3.4. Carbonyl protein (CP)

Oxidative damage to protein was quantified as a carbonyl protein (CP) (Stedman and Levine, 2000). Frozen samples of tissues were weighed, homogenized (1:20 w/v) in ice-cold 5% (w/v) sulfosalicylic acid and then centrifuged at 13000 rpm for 15 min at 4 ^°C. The supernatant was removed and 0.5 ml of 2, 4-dinitrophenylhydrazine (10 mM/L in 2 mM of HCl) solution was added to the pellet. The samples were kept at room temperature for 1 hr with vigorous vortex every 15 min, then 0.5 ml of 20% w/v TCA was added and the tubes were centrifuged as described above. The supernatant was again discarded and the excess of 2, 4-dinitrophenylhydrazine was removed by washing the pellet three times with 1 ml of ethanol: ethyl acetate (1:1 v/v), followed by vigorous vortex and re-centrifuging as described before. Finally, the pellet was dissolved in 6 M of guanidine chloride and incubated for 15 min at 37 ^ºC. The maximum absorbance in the range of 360-370 nm was recorded and the find carbonyl protein values were expressed by using the extinction coefficient of 22 mM^-1. The blank was prepared by replacing 2,4-dinitrophenyl hydrazine with 2 mM HCl.

2.3.5. Protein content

Total protein was determined according to the method of Lowry et al. (1951). Bovine serum albumin (BSA) was used as a standard.

2.4. Statistical analysis

Analysis of variance (ANOVA) was used to compare means among treatments. The least square means were compared for significant differences between treatments using Student-Newman-Keels test (Sokel and Rohlf, 1969). The regression coefficient (RC) between biochemical parameters and HMs concentrations was estimated, where the analysis was performed on Costat program (Cohort software Inc., 1985).

Results

3.1. Determination of heavy metals in ecosystem.

Water, sediment and mollusk's samples from the study area were screened for the levels of Zn, Cu, Mn, Cd, Pb and Fe, respectively.

Levels of HMs in water samples are presented in Table (1). Distribution of metals in summer was higher than those of winter of a regional mean value 120.23 µg/L. During summer, levels of Mn and Fe were higher than other metals in all studied zones ranged from 668.04 to 64.31 µg/L for Mn and from 583.08 to 276.84 µg/L for Fe. However, mean levels of metals were distributed in the following order: Fe> Mn> Zn > Cu> Pb with mean values: 453.82, 241.57, 20.91, 4.90 and 0.20 µg/L, respectively. During winter, Mn values were higher than other metals which distributed moderately, and mean values of metals were in the order as follows: Mn> Cu> Zn> Pb> Fe> Cd accounting for 168.26, 27.36, 25.83, 14.36, 9.02 and 4.16 µg/L, respectively.

Table (2) represents HMs content in sediment samples from the studied zones. The data showed that, Fe exhibited the greatest value (325.72 µg/g) in S3, while Mn exhibited the greatest one (320.52 µg/g) in S4 during summer. The metals were distributed in the following order: Mn> Fe> Pb> Zn > Cu with mean values: 108.63, 85.95, 40.03, 13.30 and 8.23 µg/g, respectively. During winter, Fe and Mn exhibited the greatest values: 629.8 and 411.15 µg/g in S5, while other metals displayed no significant differences in all selected sites. The distribution pattern of HMs was as follows: Fe> Mn> Cu> Zn > Pb> Cd with mean values: 105.68, 73.54, 3.26, 3.09, 0.81 and 0.26 µg/g, respectively.

In case of mollusk's tissues, levels of HMs during summer were greater than those during winter. In fact, Fe exhibited the high contaminated status during both seasons with mean values: 1891.42 and 224.15 µg/g during summer and winter, respectively. During summer, HMs levels were as follows: Fe> Cu> Mn> Zn> Pb> Cd with mean values: 1891.42, 240.75, 199.38, 19.28, 3.85 and 1.07 µg/g, respectively. However, the distribution pattern during winter was as follows: Fe> Cu> Mn> Zn with mean values: 224.15, 114.25, 26.25 and 14.43 µg/g, respectively. Moreover, Cd and Pb were below detection limits (Table 3).

The measured HMs exhibited BCFs in animal's tissue respect to their levels in the surrounding media (Table 4). The measured HMs displayed BCF pattern from tissue/sediment greater than those from tissue/water. Between water and mollusk's tissues, positively HM levels showed BCF ranged from to 0.83 to 49.13 during summer and from 0.00 to 24.85 during winter, arising mean values: 0.75, 25.05, 0.76, 0.54, 9.63 and 14.52 for Zn, Cu, Mn, Cd, Pb, and Fe, respectively. In case of BCF obtained from ratio of tissue/sediment, examined HMs exhibited the range (0.09-29.25) during summer and the range (0.00-8.05) during winter with mean values: 3.06, 18.65, 1.71, 0.54, 0.05 and 12.07 for metals as described above.

3.2. Biochemical responses.

3.2.1. MDA

Levels of MDA in digestive gland of freshwater mollusk, L. carinatus seasonally collected from different sites of studied area are illustrated in Figure (2). The obtained data showed that, MDA levels during summer were greater than those during other seasons as follows: summer> winter> spring> autumn. During summer, MDA levels exhibited the order: S3> S2> S6> S4> S1>S5 with mean values: 5.27, 3.21, 2.67, 2.65, 1.81 and 1.59 mM/g tissue, respectively. The lowest levels of MDA were found during autumn with mean values: 0.17, 0.69, 2.37, 0.79, 1.28 and 0.84 mM/g tissue for sites as described above. However, level in mollusk's samples from S3 was greater than other sites during all seasons.

3.2.2. Catalase (CAT).

Activity of CAT in haemolymph and tissue homogenate of collected mollusk seasonally are illustrated in Figures (3). The presented data displayed that, mean values during autumn were greater than others. During this season, the activity exhibited the following order: S1> S3> S2> S4> S5> S6 with mean values: 6.59, 5.49, 4.79, 3.48, 3.07 and 2.35 nM/mg tissue, respectively. In case of heamolymph, CAT activity during autumn was greater than others. In this season, the activity was in the following order: S5> S2> S3> S4> S1> S6 with mean values: 70.37, 58.87, 45.11, 40.52, 31.28 and 19.88 nM/g tissue, respectively. In fact, S6 (rural site) displayed the lowest values during all seasons.

3.2.3. Glutathione peroxidase (GPx).

The activities of GPx in tissue's homogenate of seasonally collected mollusk are illustrated in Figure (). The highest mean values of GPx activity were recorded during winter season as follows: S4> S5> S3> S6> S1> S2 with mean values: 2.06, 1.56, 0.09, 0.08, 0.04 and 0.03 nM/mg tissue, respectively. However, the lowest values were recorded during autumn, 0.02, 0.03, 0.05 and 0.08 nM/mg for sites: S3, S6, S2, S4, S1 and S5, respectively.Among seasonally impactof pollutants on enzyme activity, winter exhibited the highest activity, followed by spring and summer, respectively.

3.2.4. Carbonyl protein (CP).

Levels of CP in tissue's homogenate of seasonally collected mollusk are illustrated in Figure (3). Levels of CP during winter was greater than those during other seasons as follows: winter> autumn> spring> summer. Site (S1) exhibited the greatest value of CP levels during autumn and winter (0.237and 0.289 mM/L), respectively, while S5 exhibited the lowest values of CP levels: 0.027, 0.017, 0.006 and 0.026 mM/L during spring, summer, autumn and winter, respectively.

3.3. Relationship between HMs and biomarker responses.

Among antioxidant enzymes or carbonyl protein (CP), it revealed negative correlation with most metals, while Mn and Pb were the only observed positive correlation with LPO and carbonyl protein. In case of CAT, Zn, Cu and Fe revealed positive correlation, while Mn, Cd and Pb observed the negative one (Table 5).

4. DISCUSSION

The present study focused on the distribution of HMs into aquatic environment surrounding industrial plants of Kafr El-Zayat district. Additionally, it may state the impact of these metals on some of freshwater mollusks which is commonly distributed in this region (L. carinatus). Overall data indicated the major ecotoxicological effects of HMs in the ecosystem.

As mentioned above in POP_sresidue levels, HMs elevated the same concept, where their concentrations during summer were greater than those during winter. Moreover, Fe and Mn recovered the greatest levels in most sampling sites, followed by other essential metals: Cu and Zn. This concept may due to emission of fertilizers companies into water course or air, followed by that emitted from oil extraction and brick making factories in Kafr El-Zayat. In previous studies, Abdel-Halim et al. (2013) investigated that land snail, Helix aspersa showed hyperaccumulation capacity for HMs emitted in atmosphere of Kafr El-Zayat, where tissues of gastropod showed regional means of Cd, Mn, Ni, Pb, Zn and Cu at values: 0.71, 7.09, 0.71, 2.68, 41.44 and 18.01 mg/kg b.w, respectively. On the other hand, several studies demonstrated that, freshwater mollusks are considered good bioindicators for water pollution with HMs (Lau et al., 1998; Zhou et al., 2008; Kanakaraju et al., 2008; Moloukhia and Saleem, 2011; Bhalchandra and Ram, 2013; Kesavan et al., 2013; Yap and Cheng, 2013). In the present data Pb and Cd exhibited low concentrations in water, sediments and mollusk's tissues compared with other metals, except in some sites. These findings explain the limitation of Pb and Cd source in Kafr El-Zayat region, except those emitted from brick making factories near these sites. These data are in agreement with that obtained by Abdel-Halim (2014), where Pb and Ni were the mostly detected in freshwater alga collected from sites near brick making factories of Kafr El-Zayat region considering the use of fuel in these factories is the major source of potential toxic metals. Moreover, sewage water is considered another source of metals in aquatic media of this region as stated previously by Chen et al. (2005) and Wannaz et al. (2006).

4.2. Biochemical responses.

The obtained results demonstrate the assessment of the biological impact and risk of HMs from industrial and urban discharge in the aquatic media of Kafr El-Zayat.

the use of freshwater mollusk, L. carinatus may represent a relative easy process to improve the actual monitoring techniques even in the absence of native organisms. Additionally, the biological significant of the results presented here is important both in terms of the accumulated chemicals and appear once of toxicological responses. The digestive gland was chosen as a target organ for biochemical and toxicants assessment according to its ability to uptake and concentrate the contaminants by 5-10 folds higher than other organs (Gomot de-Vaufleury and Pihan, 2002; Beeby and Richmond, 2003). On the other hand, heamolymph of collected animals was used a source to assess the activities of both CAT and MDA in correlation to induction in genotoxic effects of contaminants were proven to be related to the production of ROS in chosen organism which affect various cellular processes, mostly the function of membrane system (Pinto et al., 2003; Valko et al., 2005). The potential of ROS to damage tissues and cellular components is called oxidative stress. In this study, CAT, LPO, GPx and CP were used as good parameters in oxidative stress, where ROS cause intracellular excess of MDA and LDH. Moreover, they are capable to interact with DNA to form DNA adduct in different forms.

The obtained data revealed the ability of measured chemical which emitted from this region into aquatic media to induce oxidative stress in contaminated sites compared with reference site (S6). Most studies in aquatic animals centered on oxyradicals such as O^•–, H₂O₂ and OH^•, respectively, are main form of ROS. Rates of amount of ROS production can be increased by the presence of a wide range of natural and man–made xenobiotic. Possible anthropogenic–related sources of enhanced ROS and other pro–oxidant free radical production includes organic contaminants such as nitro aromatics, PAHs, PCB_s, pesticides and heavy metals (Lemaire and Livingstone, 1993; Di Giulio et al., 1995; Halliwell and Gutteridge, 1999). In the present study, ROS cause intracellular excess of MDA in all sites more than reference site. The formation of lipid peroxidation in membranes disrupts the normal cellular metabolism, triggering adaptive response causing cell death (Girotti, 1998). Previous studies demonstrated the levels of lipid peroxidation (as malondialdehyde, MDA) in mussel species submitted to different stresses (Almeida et al., 2003, 2004, 2005).

On the other hand, catalase and glutathione peroxidase have complementary roles in hydrogen peroxide detoxication. In the present study, CAT activity in animals collected from all sites observed increases in either tissues or heamolymph compared with reference site. These increases are due to regulation by ROS as stated previously by Hermes-Lima (2004). GPx activity in the collected animals from the polluted sites of this region decreased during most seasons in comparison with other animals in the reference site. Among effect of pollutants discharge into water, S4 (near fertilizers factories) demonstrated the highest responsibility for oxidative stress than other sites, followed by S5 and S3, respectively. Previous studies demonstrated the oxidative stress in different species of mollusks impacted different pollutant in coastal areas, marine and freshwater. As example, in mussels, Mytilus galloprovincialis (Vlahogianni et al., 2007), Perna perna (Almeida et al., 2007), and freshwater mussel (Falfushynska et al., 2014).

The levels of LPO and CP in selected gastropod were significantly higher in polluted sites than other animals of reference site. This fact indicated that, some oxidative injury may be related to POP_s toxicity and accumulation. Previous studies in other polluted regions marked an increase of LPO and CAT levels in the digestive gland than those of the reference organs of mussels M. yuyanensis (Torres et al., 2002) and snails; Theba pisma (El-Gendy et al., 2009; Radwan et al., 2010), Helix aspersa (Abdel-Halim et al., 2013a).

Formation of CP was checked in this study as an index of protein oxidation of exposed mollusk to industrial effluents in this region. The obtained data revealed the induction of CP in most collected animals from desired sites. Sites 1, 2 and 4 displayed the most response among CP levels in their exposed mollusk. This induction in digestive gland samples disclosed the relationship between the distance of the sampling sites and contamination source, where the level of detected CP increased in a direct proportional manner with the distance to emission source (S1> S2> S4). Since digestive gland is the principal feeding organ of mollusk and the first organ to come into contact with xenobiotic, it is plausible that metals and/or other xenobiotic entering the animal via this organ may cause transient oxidative stress resulting in protein glutathionylation. Overall, our data suggest that long term chronic exposure to pollutants can result in higher levels irreversible modification such as carbonylation of protein (McDonagh et al., 2005). Moreover, winter season was the mostly polluted period with chemicals resulting in CP induction more than other season compared with reference zone (S6). Other literatures stated that, tissue- specific formation of protein carbonylation by environmental by pollutants such as POP_sand heavy metals had been demonstrated by proteomic approach in few mollusk's species (McDonagh et al., 2005, 2006; Dowling et al., 2006; Chora et al., 2008). Other findings previously established inducting levels of CP in response to oil exposure (Prevodnik et al., 2007) or PAHs (Almorth et al., 2005; Kaloyanni et al., 2009). On the other hand, exposed gastropods to OP_s and PAH_s observed significantly CP content in their digestive gland tissue (Itziou et al., 2011). In Kafr El-Zayat region, Abdel-Halim et al. (2013b) stated that, land snail Helix aspersa affected with breathing contaminated air of industrial emission resulting in significantly CP induction in digestive glands, especially in groups near brick making and pesticides factories. In agreement with the previous data, Gupta et al. (2007) also supported the correlation between CP content formation and ROS generation with the up-regulation of the latter in environmental toxicants exposed organism, indicating the involvement of ROS in induction protein modification.

From these findings, we would to focus on the use of cumulative biomarkers as approaches of oxidative stress, immune functions, DNA adducts, and protein profile of selected mollusks may state imposed risk from industrial effluents and urbanized activity. These outcomes investigate good information among ecosystem status of Kafr El-Zayat region and arise predicted risk of chemicals emitted from industrial units on aquatic organisms. Moreover, governmental and management decisions and control options must be done for environmental remediation resulting in good quality of ecosystem arising human health protection outcome.

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