Submit or Track your Manuscript LOG-IN

Characterization of Catalase form Carnivorous Fish Channa Striata Exposed to Binary Insecticides Mixture (Deltamethrin + Endosulfan)

PJAR_31_4_368-374

 

 

 

Research Article

Characterization of Catalase form Carnivorous Fish Channa Striata Exposed to Binary Insecticides Mixture (Deltamethrin + Endosulfan)

Sana Rana1, Sajid Abdullah1, Huma Naz2* and Khalid Abbas1

1Department of Zoology, Wildlife and Fisheries, University of Agriculture Faisalabad, Pakistan; 2Department of Zoology, Govt. College Women University Sialkot, Pakistan.

Abstract | In this experiment toxic effect of deltamethrin(DM)+endoslfan(END) mixture on catalase (CAT) activity in gills of carnivorous fish Channa striata was observed. Fish were exposed to sub-lethal concentration (1/3rd of LC50) of DM+END mixture for 14-day. CAT was partially purified by using ammonium sulphate precipitation technique and kinetic characterization was also performed against different pH and temperature. CAT activity was measured spectrophotometrically at A240 nm. Results showed that highest CAT activity was noted from the crude extract of control fish gills (140.66±0.71UmL-1) as compared to DM+END exposed fish (99.23±0.71UmL-1). After desalted the CAT activity in gills of both control and insecticides exposed fish was calculated as 73.45±0.71 and 42.77±1.36UmL-1, respectively. The highest specific activity was observed in crude CAT extract from gills of control fish (112.53±0.28 Umg-1) as compared to exposed fish (82.69±1.12Umg-1). After desalted specific activity of gills CAT was lower in exposed fish (112.20±1.41Umg-1) in relation to control (170.80±1.41 Umg-1). Highest fold purification of CAT was noted in the gills of control C. striata (1.52±0.01) as compared to exposed fish (1.48±0.01). The percentage recovery of CAT for control and DM+END exposed fish was calculated as 52.21±1.41 and 43.10±1.41, respectively. Results further indicated that after each step of partial purification total protein contents and percentage recovery decreased from crude extract to desalted sample while fold purification was increased. The maximum activity of purified CAT was recorded at 6.0 pH and 30°C temperature for gills of C. striata. As the temperature was raised further the catalase activity decreased.


Received | July 01, 2018; Accepted | November 01, 2018; Published | November 13, 2018

*Correspondence | Huma Naz, Department of Zoology, Govt. College Women University Sialkot, Pakistan; Email: [email protected]

Citation | Rana, A., S. Abdullah, H. Naz and K. Abbas. 2018. Characterization of catalase form carnivorous fish channa striata exposed to binary insecticides mixture (Deltamethrin + Endosulfan). Pakistan Journal of Agricultural Research, 31(4): 368-374.

DOI | http://dx.doi.org/10.17582/journal.pjar/2018/31.4.368.374

Keywords | Antioxidant Enzyme, Insecticides mixture, Chronic exposure, Fish, Organ



Introduction

The environment is plagued with different kinds of pollutants. Pesticides are one of such pollutants which play an important role in controlling different types of pests that cause damage to the crop plants and to improve agricultural production. Insecticides, fungicides and herbicides constitute the major source of potential environmental hazards not only to birds, fish, and other animals but also to humans when they become a part of food chains (Abd-Alla et al., 2002). Long term exposure to these pollutants causes countless abnormalities and reduces the life span of organisms (Hussain et al., 2011; Naz et al., 2011; Khan et al., 2012).

Endosulfan (EDS) is one such organochlorine (OC) compound that has been classified as highly toxic by the majority of environmental protection agencies (Sutherland et al., 2004). However, endosulfan (EDS) has been registered and released for use as a pesticide in the cultivation of soya, cotton, coffee, tobacco, and tea among others in several developed and developing countries (Bedor et al., 2010). EDS is considered to be toxic to all kinds of organisms (Xu et al., 2007; Weber et al., 2010). One pyrethroid which is used more commonly than other synthetic pyrethroids and has found wide acceptability for agricultural purposes is deltamethrin. They are extensively used in agriculture, for controlling pests, insects and vectors of endemic diseases, protecting seeds during storage and fighting household insects because of their low environmental persistence (DeSai et al., 2003). Deltamethrin toxicity in fishes showed that it causes varied effect including histopathological, oxidative stress, haematological, neurotoxin, biochemical changes as well as immunological effects. Also, deltamethrin has found to be highly toxic in fishes even in very low concentration (Pawar et al., 2009). The neurotoxic effect of the synthetic pyrethroids, deltamethrin is attributed to the blocking of sodium channels and inhibiting the GABA receptors in the nervous filaments which results in an excessive stimulation of the central nervous system that sometimes can lead to brain hypoxia (El-Sayed et al., 2007).

Fish have to face the toxicity of different pesticides entered in natural aquatic habitats due to industrial development of man. These enter in food chain by accumulation in body tissues of fish which is consumed by a large population of human. Several studies indicated that pesticides had toxic effect on enzymes in certain fishes. Variations in activity of enzyme are used as markers to identify the tissue injury, a diseased condition, or environmental stress. The rate of increase of enzyme activity and the rate of leakage caused by injury depends on the concentration of an enzyme (Roy et al., 2011). Pesticides induce oxidative stress by generating free oxygen radicals. In this situation organisms boost up defense system by producing antioxidant enzymes viz. glutathione peroxidase, superoxide dismutase and catalase (Guven et al., 2008). If the antioxidant system not able to eliminate oxidants or neutralize the excess of ROS, the fish will be at high risk of oxidative damage and oxidative stress. It is examined that waterborne pollutants induces oxidative stress and cellular damage in fish and other aquatic organisms (Box et al., 2007). The use of biochemical biomarkers of environmental contamination allows a sensitive assessment of the xenobiotic effects in aquatic organisms in order to detect early alterations in the environment prior to any irreversible harm being caused to the ecosystem (Huggett et al., 1992; De-Caprio, 1997). The objectives of present work were to check the activity of catalase in gills in C. stiata exposed to insecticides mixture

Materials and Methods

Experimental animal

Fish Channa striata commonly known as Snakehead murrel was collected from natural breeding grounds and shifted to the wet laboratory at Fisheries Research Farm, University of Agriculture Faisalabad. C. striata were acclimatized to laboratory condition for 14 days. After the acclimation period, fish were moved to 100-liter glass aquarium each containing a group of fish (n=10). The 96-hr LC50 of insecticides, deltamethrin (DM) +endosulfan (END) mixture (1:1) for C. striata was calculated as 1.374μgL-1 by Anum (2017). Fish were exposed to the sub-lethal concentration (1/3rd of LC50) of DM+END mixture for 14 days. During chronic trail, water temperature, pH and total hardness were kept constant as 30C, 7.25 and 250 mgL-1, respectively.

Isolation of catalase extract

After sampling, the fish was dissected and gills were separated. Phosphate buffer (pH 6.5) was added in the extracted gills by the ratio of 1:4 (w/v) and homogenized it for 15 minutes with the help of pestle and mortar. Homogenized material was passed through Whatman filter paper no. 1. Filtrate obtained from above step was centrifuged in refrigerator centrifugal machine at 10,000 rpm for 15 minutes. Both sediments and supernatants were separated and stored at 4 C for further analysis.

Partial purification of cat

Crude enzyme was partially purified with the help of ammonium sulfate precipitation by following the methods of Zia et al. (2007). The purification of CAT enzyme from gills consists of Salting In and Salting Out method. Salting In procedure crude extract of CAT was saturated with 60% solid ammonium sulfate by dissolving 42g in 100 ml of sample and refrigerated it for 4 hours at 4oC. After 4 hours, centrifuged at 10000 rpm and 4oC 15 minutes. The supernatant obtained from salting In procedure was saturation up to 80% solid ammonium sulfate by adding 56g/100 ml of CAT extract by shaking it and kept at 4oC overnight. After that, centrifuged it at 10000 rpm for 15 minutes and obtained both supernatant and residues. The residues were dissolved in minimum of phosphate buffer (pH 6.5).

Desalting of residues

Residues obtained from salting Out procedure were subjected to dialysis with the help of dialysis bag. Dialysis bag had semi permeable membranes that allow movement of salts, lower weight molecules and ions. Precipitated proteins samples obtained through salting out process in residue from dialyzed against low ionic strength phosphate buffer (pH 7.4). All of the samples obtained, supernatant, sediments and desalting sample were subjected to enzyme essay and protein contents estimation.

CAT assay

Catalase activity was determined by its ability to decrease the H2O2 concentration at 240 nm (Chance and Mehaly, 1977).

Estimation of total protein contents

To estimate protein contents of a sample, Biuret method (Gornall et al., 1949) was used.

Kinetic Characterization of catalase

Optimum pH and temperature: Optimum pH was determined by assaying the purified catalase enzyme from gills of wild C. striata at different pH ranging from 4-12(4.0,4.5,5.0,5.5,6.0,6.5,7.0,7.5,8.0,8.5 and 9.0). To obtained optimum temperature for purified CAT enzyme from gills of wild C. striata was assayed at different temperature ranging from 5-50°C (5,10,15,20,25,30,35,40,45 and 50) keeping the pH optimum at which catalase showed highest activity.

Statistical Analyses: Obtained data were presented as Mean Standard Deviation (Mean±SD). Analysis of variance was employed to calculated statistical difference between exposed and control fish (Steel et al., 1997). The value of P<0.05 considered as significant.

Results and Discussion

Activity and specific activity of CAT

The results showed that highest catalase activity was noted from the crude extract of controlled C. striata gills (140.66±0.71UmL-1) as compared to stressed C. striata gills (99.23±0.71UmL-1). After desalted the gills of controlled C. striata and DM+END stressed gills about 42.77±0.71 and 99.23±1.36 UmL-1, respectively Figure 1.

Figure 2 showed that highest specific activity was observed in crude CAT extract from gills of control fish (112.53±0.28 Umg-1) as compared to DM+END exposed fish (82.69±1.12Umg-1). After desalted specific activity of gills CAT was lower in insecticides mixture exposed C. striata (112.20±1.41Umg-1) in relation to control (170.80±1.41 Umg-1).



Total protein contents, fold purification and percentage recovery

Total Protein contents in gills of exposed fish were lowest in relation to control. In results of partial purification highest fold purification of CAT was noted from control C. striata (1.52±0.01) as compared to exposed fish (1.48±0.01) gills. The percentage recovery of CAT for control and DM+END exposed fish was calculated as 52.21±1.41 and 43.10±1.41, respectively. Results further indicated that after each step of partial purification total protein contents and percentage recovery decreased from crude extract to desalted sample while fold purification was increased (Table 1).

Kinetic characterization of CAT

Effect of pH and temperature on CAT activity: The maximum activity that purified CAT showed was recorded at pH and temperature at 6.0 and 30°C for gills of C. striata. As the temperature was raised further the

Table 1: Partial purification of CAT from gills Channa striata exposed to pesticides mixture.

Fractions Control DM+END
Protein(mgL-1)

Fold Purification %recovery Protein(mgL-1)

Fold Purification %Recovery
Crude Extract 1.25±0.01a 1.00±0.02d 100±0.41a 1.20±0.01a 1.00±0.01d 100±2.12a
SaltingIn Supernatent 0.95±0.07b 1.10±0.01c 85.85±2.83b 0.92±0.01b 1.06±0.03c 80.77±1.41b
SaltingOut Supernatent 0.65±0.01c 1.34±0.01b 71.12±1.41c 0.53±0.01c 1.14±0.01b 61.92±0.71c
Desalted 0.43±0.01d 1.52±0.01a 52.21±1.41d 0.35±0.01d 1.48±0.01a 43.10±1.41d

Means sharing similar letter in a row or in a column are statistically non-significant (p>0.05).

CAT activity decreased (Figure 3, 4). Enzymes are proteins in nature and can be isolated and purified from all kinds of living organisms. Majority of enzymes are sub mingled with other proteins and bio-molecules when isolated and therefore needed to purify by using very precise technique so that properties of purified enzyme can be described clearly. Present research work was designed to compare purified catalase enzyme characterization extracted from gills of normal and DM+END mixture exposed C. striata.


Oxidative stress in aquatic organisms, particularly fish, has a great importance for environmental and aquatic toxicology. Because oxidative stress is induced by many chemicals, including some pesticides, these pollutants may stimulate ROS and alteration in antioxidant systems (Kadry et al., 2012). It is well documented that DM may prompt oxidative stress (Sayeed et al., 2003; Tu et al., 2012). As itis known that the antioxidant enzymes CAT, SOD and GSH-Px are the first line of defense against oxidative stress which convert superoxide anions (O−2) into H2O2 and then into H2O and O2 (Kadry et al., 2012; Stara et al., 2012). This view was in agreement with Abdelkhalek et al. (2015) who recorded significant decrease in SOD, CAT and GSH-Px levels in liver, kidney and gill tissues of tilapia fish upon exposure to DM and Hamed (2015) who documented marked depletion in the hepatic SOD and CAT levels of catfish upon exposure to malathion. This decrease in the SOD activity may be the result of excessive free radical production, such as the superoxide anion and hydrogen peroxide, direct damage of its protein structure by pesticide or a direct action of pesticide on the synthesis of the enzyme (Yonar et al., 2015). Tripathi and Shasmal (2011) Chlorpyriphos significantly decreased the specific activity of CAT in the gill of the fish Heteropneustes fossilis. Vineela and Reddy, 2014 CAT activity is gradually decreased in Catla catla exposed to Lihocin. Enzymes are important biological compounds as they minimize the activation energy of all metabolic reactions occurring in living organisms. Enzymes are protein in nature composed of amino acids and highly specific in nature so their activity affected by any change in pH, temperature, substrate concentration and pressure (Boeuf et al., 2000).


Ahmed et al. (2000) also reported a decreased CAT activity in gills of Channa striata exposed to paper mill effluent. Atli et al. (2010) also reported the change in gills CAT activity of fish exposed to sub-lethal concentrations (25 μgL-1) of carbosulfan. Bainy et al. (1996) analyzed the decreased gills CAT level in fish. Diana et al. (2007) observed the decreased gills CAT level in Carassius auratus gibelio exposed to deltamethrin. Faheem et al. (2012) CAT activity decreased in gill of Oreochromis niloticus exposed to aquatic pollutants (CdCl-2). Catalase activities decreased in the gills of African cat fish (Clarias gariepinus) exposed to sub-lethal concentrations of butachlor (Farombi et al., 2008). Prusty et al. (2011) CAT activity decreased in gills of fishes Labeo rohita exposed to sub-lethal concentration (1/3rd of LC50) of fenvalerate was exposed for 15 days. CAT activity was decreased in gills of gilthead seabream Sparus aurata exposed to sub-lethal concentration of malathion (Rosety et al., 2005). CAT reduced in gills of African catfish; Clarias gariepinus exposed to deltamethrin (Hamed, 2016).

Decreased CAT level gills of common carp exposed to zeta-cypermethrin (Stara et al., 2013). Yonar and Sakin (2011) studied the effect deltamethrin at concentrations of 0.018 and 0.036 μgL-1 on common carp for 14 days. They observed decrease SOD, CAT, and GSH activity and significantly increased levels of malondialdehyde in liver and gill. The activity of CAT was found to be reduced in the fish Labeo rohita exposed to endosulfan and fenvalerate when compared to control (Suneetha, 2014). Significant decrease in gills CAT level of C. punctatus exposed to alphamethrin was observed by Tripathi and Singh (2013). Insecticidal stress caused a reduction in CAT activity and reduced glutathione levels in zebrafish gills exposed to dimethoate (Ansari and Ansari, 2014).

Conclusions and Recommendations

These results suggest that an immediate adaptive response to the oxidative stress appeared, demonstrating alterations in the antioxidant defense mechanism in the gills of deltamethrin intoxicated fish. Therefore, present study was conducted in order to conserve freshwater fisheries in the natural waters. Both cultured and wild fish have become the victim of pesticides pollution caused by organic and inorganic chemicals.

Author’s Contribution

Sana Rana executed this research work.Sajid Abdullah planned this research work. Huma Naz performed statistical analyses. Khalid Abbas help in writing article.

References

APHA. 1998. (American Public Health Association). Standard method for examination of water and waste water. (20th Edition). New York, p. 1193.

Abd-alla, E.A.M., Nasser, A.M., Neamat-allah, A.A. and Aly, S.E. 2002. Prevalence of pesticide residues in fish, cheese and human milk. Assiut Vet. Med. J. 47: 110-124.

Abdelkhalek, N.K.M., Ghazy, E.W. and Abdel-Daim, M.M. 2015. Pharmacodynamic Interaction of Spirulina platensis and deltamethrin in freshwater fish Nile tilapia, Oreochromis niloticus: Impact on lipid peroxidation and oxidative stress. Environ. Sci. Pollut. Res. 22(4): 3023-3031. https://doi.org/10.1007/s11356-014-3578-0

Ahmad, I., Hamid, T., Fatima, M., Chand, H.S., Jain, S.K., Athar, M. and Raisuddin, S. 2000. Induction of hepatic antioxidants in freshwater catfish (Channa punctatus Bloch) is a biomarker of paper mill effluent exposure. Biochim. Biophy. Acta Rev. 1523(1): 37-48.

Ansari, S. and Ansari, B.A. 2014. Temporal variations of CAT, GSH, and LPO in gills and livers of zebrafish, Danio rerio, exposed to dimethoate. Arch. Pol. Fish. 22 (2): 101-109. https://doi.org/10.2478/aopf-2014-0009

Anum, S., Abdullah, S., Abbas, K., Naz, H. and Hassan, W. 2017. Changes in antioxidant enzyme (glutathione S-transferase) activity in fish Channa Striata exposed to the different aquatic pollutants (heavy metals and pesticides mixture). 6th Int. Fish. Symp.

Atli, G. and Canli, M. 2010. Response of antioxidant system of freshwater fish Oreochromisniloticus to acute and chronic pestisides exposures. Ecotoxicol. Environ. Saf. 73(8): 1884- 188. https://doi.org/10.1016/j.ecoenv.2010.09.005

Bainy, C.D., Saito, E., Carvalho, S.M.P. and Virginia, B.C. 1996. Oxidative stress in gills, erythrocytes, liver and kidney of Nile tilapia, Oreochromis niloticus from polluted site. Aquat. Toxicol. 34(2), 151-162. https://doi.org/10.1016/0166-445X(95)00036-4

Bedor, C.N.G., Morais, R.J.L., Cavalcanti, L.S., Ferreira, J.V. and Pavao, A.C. 2010. Carcinogenic potential of endosulfan and its metabolites based on a quantum chemical model. Sci. Total Environ. 408 (24), 6281–6284. https://doi.org/10.1016/j.scitotenv.2010.09.014

Boeuf, G.B., Legrand, B. and Rambour, S. 2000. Purification and characterization of a basic peroxidase from the medium of cell suspension culture of chicory. Plant physiol. Biochem. 38(3): 217-224. https://doi.org/10.1016/S0981-9428(00)00731-2

Box, A., Sureda, A., Galgani, F.,Pons, A., H Deudero, S. 2007. Assessment of environmental pollution at Balearic Islands applying oxidative stress biomarkers in the mussel Mytilus galloprovincialis. Comp. Biochem. Physiol. Part C: Toxicol. Pharm. 146(4): 531-539.

Chance, M. and Mehaly, A.C. 1997. Assay of catalase and peroxidase. Methods Enzymol. 2:764-817. https://doi.org/10.1016/S0076-6879(55)02300-8

DeSai, H.S., Balaramnd, N. and Jayananda, P. 2003. Toxicological effects of some biochemical parameters of fresh water Channa punctatus under the stress of nickel. J. Environ. Biol. 23(3): 275-277.

DeCaprio, A.P. 1997. Biomarkers: Coming age for environmental health and risk assessment. Sci. Total Environ. 31 (7): 1837–1848. https://doi.org/10.1021/es960920a

Diana, C., Cristina, S.A., Diana, D., Huculeci R., Marieta, C. and Anca, D. 2007. Biochemical and histological effects of deltamethrin exposure on the gills of Carassius auratus gibelio (Pisces Cyprinidae) Lucrari stiintifice Zootehnie si Biotehnol. 40(1): 65-72.

El-Sayed, Y.S., Saad, T.T. and El-Bahr, S.M. 2007. Acute intoxication of deltamethrin in monosex Nile tilapia, Oreochromis niloticus with special reference to the clinical, biochemical and haematological effects. Environ. Toxicol. Pharmacol. 24(3): 212- 217. https://doi.org/10.1016/j.etap.2007.05.006

Faheem, M., Sulehria, A.Q.K., Tariq, M., Khadija, I., Fiaz, A. and Saeed, M. 2012. Effect of sub-lethal dose of cadmium chloride on biochemical profile and catalase activity in fresh water fish Oreochromis niloticus. Biologia (Pak.) 58 (1 and 2): 73-78.

Farombi, E.O., Ajimoko, Y.R. and Adelowo, O.A. 2008. Effect of butachlor on antioxidant enzyme status and lipid peroxidation in fresh water African catfish, (Clarias gariepinus). In. J. Environ. Res. Public Health. 5(5): 423-427. https://doi.org/10.3390/ijerph5050423

Gornall, A.G., Bardawill, C.J., David, M.M. 1949. Determination of serum proteins by means of the biuret reaction. “The Journal of biological chemistry.J. Biol. Chem. 177(2):751-66.

Guven, A., Gul, S., Kaya, I., Nur, G., Deveci, A. and Kaya, O. 2008. Antioxidant enzymes and lipid peroxidation in Alburnus fllippii and Canthulburnus microlepis: A comparative study. Kafkas Üniv. Vet. Fakültesi Dergisi. 14(1): 13-18.

Hamed, H.S. 2015. Impact of a short-term malathion exposure of Nile tilapia, (Oreochromis niloticus): The protectiven role of selenium. Int. J. Environ. Monit. Anal. 3(5-1), 30-37.

Hamed, H.S. 2016. Ameliorative effects of Spirulina platensis on deltamethrin-induced biochemical alterations and oxidative stress in the African catfish; Clarias gariepinus. Open J. Marine Sci. 6(1):1-10. https://doi.org/10.4236/ojms.2016.61001

Huggett, R.J., Kimerie, R.A., Mehrie, J.P.M. and Bergman, H.L. 1992. Biomarkers: Biochemical, physiological and histological markers of anthropogenic stress. Lewis Publishers, Boca Raton, FL. 155–209.

Hussain, R., Mahmood, F., Khan, M.Z., Khan, A. and Muhammad, F. 2011. Pathological and genotoxic effects of atrazine in male Japanese quail (Coturnix japonica). Ecotoxicol. 20(1): 1–8. https://doi.org/10.1007/s10646-010-0515-y

Kadry, S.M., Marzouk, M.S., Amer, A.M., Hanna, M.I., Azmy, A.H. and Hamed, H.S. 2012. Vitamin E as antioxidant in female African catfish (Clarias gariepinus) exposed to chronic toxicity of atrazine. Egypt. J. Aquat. Biol. Fish. 16(2): 83-98. https://doi.org/10.21608/ejabf.2012.2127

Khan, A., Ahmad, L. and Khan, M.Z. 2012. Hemato-biochemical changes induced by pyrethroid insecticides in avian, fish and mammalian species. Int. J. Agric. Biol. 14(5): 834–842.

Kumari, B., Madan, V.K. and Kathpal, T.S. 2006. Monitoring of pesticide residues in fruits. Environ. Monit. Assess. 123(1-3): 407–412. https://doi.org/10.1007/s10661-006-1493-7

Naz, S., Rana, S.A., Javed, M. and Rehman, K.U. 2011. Toxicological effects of brodifacoum and food energy inhibitor on some physiological parameters in house rats (Rattus rattus). Pak. Vet. J. 31(3): 219– 222.

Pawar, S., Chaves, I., Dugro, S.P., Bin-Hafeez, B., Haque, R. and Raisuddin, S. 2000. Effect of endoslufan on antioxidants of freshwater fish (Channa punctatus). Arch. Environ. Contam. Toxicol. 41(3): 345-352.

Pawar, B.A., Jaralli, J.M.A. and Shendge, N. 2009. toxicity and impact of deltamethrin on glycogen level of freshwater fish Puntius chrysopterus (McClelland). J. Exp. Zool. 12:319-323.

Prusty, A.K., Kohli, M.P.S., Sahu, N.P., Pal, A.K., Saharan, N., Mohapatra, S. and Gupta, S.K. 2011. Effect of short term exposure of fenvalerate on biochemical and haematological responses in Labeo rohita (Hamilton) fingerlings. Pestic. Biochem. Physiol. 100(2): 124–129. https://doi.org/10.1016/j.pestbp.2011.02.010

Rosety, M., Rosety-Rodrigue, M., Ordonez, F.J. and Rosety, I. 2005. Time course variations of antioxidant enzyme activities and histopathology of gilthead seabream gills exposed to malathion. Histol. Histopathol. 20(4):1017-20.

Roy, J.M., Hyndman, K.A., Kriska, T., Girooti, A.W. and Crockett, E.L. 2011. Relationship between oxidizable fatty acid content and level of antioxidant glutathione peroxidase in marine fish. J. Exp. Biol. 214(22): 3751-3759. https://doi.org/10.1242/jeb.058214

Sayeed, I., Parvez, S., Pandey, S., Bin-Hafeez, B., Haque, R. and Raisuddin, S. 2003. Oxidative stress biomarkers of exposure to deltamethrin in freshwater fish, Channa punctatus Bloch. Ecotoxicol. Environ. Saf. 56(2): 295-302. https://doi.org/10.1016/S0147-6513(03)00009-5

Stara, A., Steinbach, C., Wlasow, T., Gomulka, P., Ziemok, E., Machova, J. and Velisek, J. 2013. Effect of zeta-cypermethrin on common carp (Cyprinus carpio L.). Neuroendocrinol. Lett. 34(2):37-42.

Stara, A., Machova, J. and Velisek, J. 2012. Effect of chronic exposure to simazine on oxidative stress and antioxidant response in common carp (Cyprinus carpio L.). Environ. Toxicol. Pharmacol. 33(2): 334-343.

Steel, R.G.D., Torrie, J.H., Dickey, D.A. 1997. Principles and procedures of statistics: A biometrical approach. 3rd Ed. McGraw Hill Book Co. Inc. New York: 400-428.

Suneetha, K. 2014. Toxic effect of endosulfan and fenvalerate on oxidative stress biomarkers and lipid peroxidation in freshwater fish Labeo rohita (Hamilton). Int. J. Biol. Pharm. Res. 5(2): 156-160.

Sutherland, T.D., Home, I., Weir, K.M., Russell, R.J. and Oakeshott, J.G. 2004. Toxicity and residues of endosulfan isomers. Rev. Environ. Contam. Toxicol. 183: 99–113. https://doi.org/10.1007/978-1-4419-9100-3_4

Tripathi, G. and Singh, H. 2013. Impact of alphamethrin on biochemical parameters of Channa punctatus. J. Environ. Biol. 34(2): 227-230.

Tripathi, G. and Shasmal, J. 2011. Concentration related responses of chlorpyriphos in antioxidant, anaerobic and protein synthesizing machinery of the freshwater fish, Heteropneustes fossilis. Pestic. Biochem. Physiol. 99(3): 215–220. https://doi.org/10.1016/j.pestbp.2010.12.006

Tu, H.T., Silvestre, F., Meulder, B., Thome, J.P., Phuong, N.T. and Kestemont, P. 2012. Combined effects of deltamethrin, temperature and salinity on oxidative stress biomarkers and acetylcholinesterase activity in the black tiger shrimp (Penaeus monodon). Chemosphere. 86(1): 83-91. https://doi.org/10.1016/j.chemosphere.2011.09.022

Vineela, D. and Reddy, S.J. 2014. Impact of lihocin on immuno haematological and antioxidant enzyme indices of carp fish. Int. J. Pharm. Life Sci. 5(5): 3517-3525.

Webber, N.R., Boone, M.D., Distel, C.A. 2010.HYPERLINK “https://www.ncbi.nlm.nih.gov/pubmed/20872697” \t “_blank” Effects of aquatic and terrestrial carbaryl exposure on feeding ability, growth, and survival of American toads. Environ. Toxicol. Chem. 29(10): 2323-2327.

Xu, X., Yang, H., Li, Q., Yang, B., Wang, X., Lee, F.S.C. 2007. Residues of organochlorine pesticides in near shore waters of LaiZhou Bay and JiaoZhou Bay, Shangdong Peninsula, China. Chemosphere, 68 (1): 126–139.

Yonar, M.E. and Sakin, F. 2011. Ameliorative effect of lycopene on antioxidant status in Cyprinus carpio during pyrethroid deltamethrin exposure. Pestic. Biochem. Physiol. 99 (3): 226–231. https://doi.org/10.1016/j.pestbp.2010.12.008

Yonar, M.E., Yonar, S.M., Pala, A., Silici, S. and Saglam, N. 2015. Trichlorfon induced haematological and biochemical changes in Cyprinus carpio: Ameliorative Effect of Propolis. Dis. Aquat. Organ. 114(3): 209-216. https://doi.org/10.3354/dao02866

Zia, M.A., Rahman, K., Saeed, M.K., Andaleeb, F., Rajoka, M.I., Sheikh, M.A., Khan, I.A. and Khan, A.I. 2007. Thermal characterization of purified glucose oxidase from a newly isolated Aspergillus niger JAF-l. J. Clin. Biochem. Nutr. 41: 132-138. https://doi.org/10.3164/jcbn.2007018

To share on other social networks, click on any share button. What are these?

Pakistan Journal of Zoology

December

Pakistan J. Zool., Vol. 56, Iss. 6, pp. 2501-3000

Featuring

Click here for more

Subscribe Today

Receive free updates on new articles, opportunities and benefits


Subscribe Unsubscribe