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Protective potential of Lactobacillus species in lead toxicity model in broiler chickens

Published online by Cambridge University Press:  02 November 2016

M. F. Jahromi
Affiliation:
Institute of Tropical Agriculture, Universiti Putra Malaysia, 43400 Serdang, Selangor, Malaysia Agricultural Biotechnology Research Institute or Iran (ABRII), East and North-East Branch, P.O.B. 91735844, Mashhad, Iran
J. B. Liang*
Affiliation:
Institute of Tropical Agriculture, Universiti Putra Malaysia, 43400 Serdang, Selangor, Malaysia
R. Ebrahimi
Affiliation:
Institute of Tropical Agriculture, Universiti Putra Malaysia, 43400 Serdang, Selangor, Malaysia
A. F. Soleimani
Affiliation:
Institute of Tropical Agriculture, Universiti Putra Malaysia, 43400 Serdang, Selangor, Malaysia
A. Rezaeizadeh
Affiliation:
Department of Endocrinology, Sydney Medical School, University of Sydney, Sydney, NSW, Australia
N. Abdullah
Affiliation:
Institute of Tropical Agriculture, Universiti Putra Malaysia, 43400 Serdang, Selangor, Malaysia
P. Shokryazdan
Affiliation:
Institute of Tropical Agriculture, Universiti Putra Malaysia, 43400 Serdang, Selangor, Malaysia
*
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Abstract

To alleviate adverse effects of heavy metal toxicity, diverse range of removing methods have been suggested, that is usage of algae, agricultural by-products and microorganisms. Here, we investigated lead (Pb) biosorption efficacy by two lactic acid bacteria species (LABs) in broiler chickens. In an in vitro study, Pb was added to culture medium of LABs (Lactobacillus pentosus ITA23 and Lactobacillus acidipiscis ITA44) in the form of lead acetate. Results showed that these LABs were able to absorb more than 90% of Pb from the culture medium. In follow-up in vivo study, LABs mixture was added to diet of broiler chickens contained lead acetate (200 mg/kg). Pb exposure significantly increased lipid peroxidation and decreased antioxidant activity in liver. The changes were recovered back to normal level upon LABs supplementation. Moreover, addition of LABs eliminated the liver tissue lesion and the suppressed performance in Pb-exposed chicks. Analysis of liver and serum samples indicated 48% and 28% reduction in Pb accumulation, respectively. In conclusion, results of this study showed that L. pentosus ITA23 and L. acidipiscis ITA44 effectively biosorb and expel dietary Pb from gastrointestinal tract of chickens.

Type
Research Article
Copyright
© The Animal Consortium 2016 

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References

Ahmed, AY, Abdullah, MP, Wood, AK, Hamza, MS and Othman, MR 2013. Determination of some trace elements in marine sediment using ICP-MS and XRF (a comparative study). Oriental Journal of Chemistry 29, 645653.Google Scholar
Altaher, YW, Jahromi, MF, Ebrahim, R, Zulkifli, I and Liang, JB 2015. Lactobacillus pentosus ITA23 and Lactobacillus acidipiscis ITA44 enhance feed conversion efficiency and beneficial gut microbiota in broiler chickens. Revista Brasileira de Ciência Avícola 17, 159164.Google Scholar
Bakalli, RI, Pesti, GM and Ragland, WL 1995. The magnitude of lead toxicity in broiler chickens. Veterinary and Human Toxicology 37, 1519.Google Scholar
Bourogaa, E, Nciri, R, Mezghani-Jarraya, R, Racaud-Sultan, C, Damak, M and El-Feki, A 2013. Antioxidant activity and hepatoprotective potential of Hammada scoparia against ethanol-induced liver injury in rats. Journal of Physiology and Biochemistry 69, 227237.Google Scholar
Cory-Slechta, DA, Virgolini, MB, Thiruchelvam, M, Weston, DD and Bauter, MR 2004. Maternal stress modulates effects of developmental lead exposure. Environmental Health Perspectives 112, 717730.Google Scholar
Damron, BL, Simpson, CF and Harms, RH 1969. The effect of feeding various levels of lead on the performance of broilers. Poultry Science 48, 15071509.Google Scholar
Davis, TA, Volesky, B and Mucci, A 2003. A review of the biochemistry of heavy metal biosorption by brown algae. Water Research 37, 43114330.Google Scholar
Demirbas, A 2008. Heavy metal adsorption onto agro-based waste materials: a review. Journal of Hazardous Materials 157, 220229.Google Scholar
Ebrahimi, R, Jahromi, MF, Liang, JB, Soleimani, AF, Shokryazdan, P and Zulkifli, I 2015. Effect of dietary lead on intestinal nutrient transporters mRNA expression in broiler chickens. Biomed Research International 28, 149745.Google Scholar
Ercal, N, Guerer-orhan, H and Aykin-burns, N 2001. Toxic metals and oxidative stress part I: mechanisms involved in metal induced oxidative damage. Current Topics in Medicinal Chemistry 1, 529539.CrossRefGoogle ScholarPubMed
Erdogan, Z, Erdogan, S, Aksu, T and Baytok, E 2004. The effects of dietary lead exposure and ascorbic acid on performance, lipid peroxidation status and biochemical parameters of broilers. Turkish Journal of Veterinary Animal Sciences 29, 10531059.Google Scholar
Fox, MR 1987. Assessment of cadmium, lead and vanadium status of large animals as related to the human food chain. Journal of Animal Science 65, 17441752.Google Scholar
Fuller, R 2001. The chicken gut microflora and probiotic supplements. The Journal of Poultry Science 38, 189196.Google Scholar
Grenier, B, Bracarense, AP, Schwartz, HE, Trumel, C, Cossalter, AM, Schatzmayr, G, Kolf-Clauw, M, Moll, WD and Oswald, IP 2012. The low intestinal and hepatic toxicity of hydrolyzed fumonisin B1 correlates with its inability to alter the metabolism of sphingolipids. Biochemical Pharmacology 83, 14651473.Google Scholar
Haider, S, Saleem, S, Tabassum, S, Khaliq, S, Shamim, S, Batool, Z, Parveen, T, Inam, QU and Haleem, DJ 2013. Alteration in plasma corticosterone levels following long term oral administration of lead produces depression like symptoms in rats. Metabolic Brain Disease 28, 8592.Google Scholar
Hu, XF, Guo, YM, Huang, BY, Bun, S, Zhang, LB, Li, JH, Liu, D, Long, FY, Yang, X and Jiao, P 2010. The effect of glucagon-like peptide 2 injection on performance, small intestinal morphology, and nutrient transporter expression of stressed broiler chickens. Poultry Science 89, 19671974.Google Scholar
Jahromi, MF, Altaher, YW, Shokryazdan, P, Ebrahimi, R, Ebrahimi, M, Zulkifli, I, Goh, YM, Tufarelli, V and Liang, JB 2016. Dietary supplementation of a mixture of Lactobacillus strains enhances performance of broiler chickens raised under heat stress conditions. International Journal of Biometeorology 60, 1099–1110.Google Scholar
Kapoor, A and Viraraghavan, T 1997. Heavy metal biosorption sites in Aspergillus niger . Bioresource Technology 61, 221227.Google Scholar
Kapoor, A, Viraraghavan, T and Cullimore, DR 1999. Removal of heavy metals using the fungus Aspergillus niger . Bioresource Technology 70, 95104.Google Scholar
Mahesar, SA, Sherazi, STH, Niaz, A, Bhanger, MI and Abdul Rauf, S 2010. Simultaneous assessment of zinc, cadmium, lead and copper in poultry feeds by differential pulse anodic stripping voltammetry. Food Chemical and Toxicology 48, 23572360.Google Scholar
Meimandipour, A, Shuhaimi, M, Soleimani, AF, Azhar, K, Hair-Bejo, M, Kabeir, BM, Javanmard, A, Muhammad Anas, O and Yazid, AM 2010. Selected microbial groups and short-chain fatty acids profile in a simulated chicken cecum supplemented with two strains of Lactobacillus. Poultry Science 89, 470476.Google Scholar
Mountzouris, KC, Tsirtsikos, P, Kalamara, E, Nitsch, S, Schatzmayr, G and Fegeros, K 2007. Evaluation of the efficacy of a probiotic containing Lactobacillus, Bifidobacterium, Enterococcus, and Pediococcus strains in promoting broiler performance and modulating cecal microflora composition and metabolic activities. Poultry Science 86, 309317.Google Scholar
National Research Council 1994. Nutrient requirements of poultry, 9th revised edition. The National Academy Press, Washington, DC, USA.Google Scholar
Navidshad, B, Liang, JB and Jahromi, MF 2012. Correlation coefficients between different methods of expressing bacterial quantification using real time PCR. International Journal of Molecular Sciences 13, 21192132.Google Scholar
Nicholson, FA, Chambers, BJ, Williams, JR and Unwin, RJ 1999. Heavy metal contents of livestock feeds and animal manures in England and Wales. Bioresource Technology 70, 2331.Google Scholar
Prvulovic, D, Kojic, D, Popovic, M and Grubor-Lajsic, G 2015. Inhibitory effects of aluminosilicates on lead acetate toxicity in selected organs of broilers. The Thai Veterinary Medicine 45, 255261.Google Scholar
Scheuhammer, AM 1987. The chronic toxicity of aluminium, cadmium, mercury, and lead in birds: a review. Environmental Pollution 46, 263295.Google Scholar
Senapati, SK, Dey, S, Dwivedi, SK and Swarup, D 2001. Effect of garlic (Allium sativum L.) extract on tissue lead level in rats. Journal of Ethnopharmacology 76, 229232.Google Scholar
Seven, I, Aksu, T and Tatli-Seven, P 2012. The effects of propolis and vitamin C supplemented feed on performance, nutrient utilization and carcass characteristics in broilers exposed to lead. Livestock Science 148, 1015.Google Scholar
Sharma, R and Barber, I 2012. Histopathological alterations in developing duodenum of Swiss mice, exposed to lead acetate. Journal of Chemical Biological and Physical Sciences 2, 13121318.Google Scholar
Shokryazdan, P, Liang, JB, Jahromi, MF and Abdullah, N 2015. Probiotic potential of lactic acid bacteria isolated from Mulberry silage. Journal of Pure and Applied Microbiology 9 (Spl. Edn. 2), 443452.Google Scholar
Soares, EV and Soares, HM 2012. Bioremediation of industrial effluents containing heavy metals using brewing cells of Saccharomyces cerevisiae as a green technology: a review. Environmental Science and Pollution Research 19, 10661083.Google Scholar
Teemu, H, Seppo, S, Jussi, M, Raija, T and Kalle, L 2008. Reversible surface binding of cadmium and lead by lactic acid and bifidobacteria. International Journal of Food Microbiology 125, 170175.Google Scholar
Tobin, J, Cooper, D and Neufeld, RJ 1990. Investigation of the mechanism of metal uptake by denatured Rhizopus arrhizus biomass. Enzyme and Microbial Technology 12, 591595.Google Scholar
Yalcin, S, Settar, P, Ozkan, S and Cahaner, A 1997. Comparative evaluation of three commercial broiler stocks in hot versus temperate climates. Poultry Science 76, 921929.Google Scholar
Yodseranee, R and Bunchasak, C 2012. Effects of dietary methionine source on productive performance, blood chemical, and hematological profiles in broiler chickens under tropical conditions. Tropical Animal Health and Production 44, 19571963.Google Scholar
Yuan, C, Song, HH, Jiang, YJ, Azzam, MMM, Zhu, S and Zou, XT 2013. Effects of lead contamination in feed on laying performance, lead retention of organs and eggs, protein metabolism, and hormone levels of laying hens. Journal of Applied Poultry Research 22, 878884.Google Scholar
Zhang, F, Li, Y, Yang, M and Li, W 2012. Content of heavy metals in animal feeds and manures from farms of different scales in northeast China. International Journal of Environmental Research and Public Health 9, 26582668.Google Scholar