Effects of starvation and re-feeding on recovery of digestive enzyme capacity in Sobeity (Sparidentex hasta) marine fish

Yazdi, Nima; Zakeri, Mohammad; Kochanian, Preeta; Mousavi, Seyed Mohammad; Taghavi Moghadam, Ahmad

doi:10.22059/jfisheries.2022.344371.1334

Effects of starvation and re-feeding on recovery of digestive enzyme capacity in Sobeity (Sparidentex hasta) marine fish

Document Type : Research Paper

Authors

¹ M.Sc. Graduate, Department of Fisheries, Faculty of Marine Natural Resources, Khorramshahr University of Marine Science and Technology, Khorramshahr, Iran.

² Professor, Department of Fisheries, Faculty of Marine Natural Resources, Khorramshahr University of Marine Science and Technology, Iran.

³ Razi Vaccine and Serum Research Institute, Ahvaz, Iran

10.22059/jfisheries.2022.344371.1334

Abstract

In this study, the ability of the Sobeity fish to regulate and restore the capacity of digestive enzymes (trypsin, chymotrypsin, and lipase) during different periods of starvation and re-feeding was studied for 80- day period. 300 fish with an average initial weight of 28.47±0.24 g was stocked in twelve 300-liter polyethylene tanks. In four experimental treatments, including treatment 1 (T1), the fish were starved for two days and fed for eight days; in treatment 2 (T2), the fish were starved for four days and fed for sixteen days; in treatment 3 (T3), the fish were starved for eight days and fed for thirty-three days. The cycles were repeated eight times for the T1, four times for the T2, and two times for the T3 until the end of the experiment (80 days). The control treatment was also fed to satiety throughout the experiment. At the end of the period of starvation, the activity level of trypsin and chymotrypsin in the control treatment was significantly higher than other treatments (P<0.05). The lipase activity level in the first cycle of T1 and T2 did not significantly different from the control treatment. However, the lipase enzyme activity in the midpoint cycle of T2 was significantly lower than control (P<0.05). At the end of days 40 and 80, no significant difference was observed in the activities of three digestive enzymes between the control and the experimental treatments. The present study showed that Sparidentex hasta can cover their digestive capacity after overcoming various periods of starvation.
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Keywords

20.1001.1.20085729.1401.75.4.5.0

References

Abolfathi, M., Hajimoradloo, A., Ghorbani, R., Zamani, A., 2012. Effect of starvation and refeeding on digestive enzyme activities in juvenile roach, Rutilus rutilus caspicus. Comparative Biochemistry and Physiology-Part A: Molecular & Integrative Physiology 161(-), 166-173.

Applebaum, S., Holt, G. 2003. The digestive protease, chymotrypsin, as an indicator of nutritional condition in larval red drum (Sciaenops ocellatus). Marine Biology 142(-), 1159-1167.

Bavi, Z., Zakeri, M., Mousavi, S.M., Yavari, V., 2022. "Effects of Dietary Taurine on Growth, Body Composition, Blood Parameters, and Enzyme Activities of Juvenile Sterlet (Acipenser ruthenus)", Aquaculture Nutrition 28(2), 1-13.

Belanger, F., Blier, P., Dutil, J.D., 2002. Digestive capacity and compensatory growth in Atlantic cod (Gadus morhua). Fish Physiology and Biochemistry 26, 121-128.

Belinger, C., Fried, M., Whitehouse, L., Jansen, J.B., Lamers, C.B., Gyr, K., 1985. Pancreatic enzyme response to a liquid meal and to hormonal stimulation. Journal of Clinical Investigation 75, 1471-1476.

Blier, P., Pelletier, D., Dutil, J.D., 1997. Does aerobic capacity set a limit on fish growth rate? Reviews in Fisheries Science 5, 323-340.

Bolasina, S., Pérez, A., Yamashita, Y., 2006. Digestive enzymes activity during ontogenetic development and effect of starvation in Japanese flounder, Paralichthys olivaceus. Aquaculture 252, 503-515.

Bradford, M.M., 1976. A rapid and sensitive method for the quantitation of microgram quantities of protein utilizing the principle of protein-dye binding. Analytical biochemistry 72, 248-254.

Buddington, R.K., Doroshev, S.I., 1986. Development of digestive secretion in white sturgeon juveniles. Comparative Biochemistry and Physiology A 83, 233–238.

Chakrabarti, I., Gani, A., Chaki, K., Sur, R., Misra, K., 1995. Digestive enzymes in 11 freshwater teleost fish species in relation to food habit and niche segregation. Comparative Biochemistry and Physiology A 11, 167–177.

Chan, C.R., Lee, D.N., Cheng, Y.H., Hsieh, D.J.Y., Weng, C.F., 2008. Feed deprivation and refeeding on alterations of proteases in tilapia Oreochromis mossambicus. Zoological Studies 47(2), 207-214.

Einarsson, S., Davies, P.S., Talbot, C., 1996. The effect of feeding on the secretion of pepsin, trypsin and chymotrypsin in the Atlantic salmon, Salmo salar L. Fish Physiology and Biochemistry 15, 439-446.

Erlanger, B.F., Kokowsky, N., Cohen, W., 1961. The preparation and properties of two new chromogenic substrates of trypsin. Archives of biochemistry and biophysics 95, 271-278.

Eroldoğan, O.T., Taşbozan, O., Tabakoğlu, S., 2008. Effects of restricted feeding regimes on growth and feed utilization of juvenile gilthead sea bream, Sparus aurata. Journal of the World Aquaculture Society 39, 267-274.

Furne, M., García-Gallego, M., Hidalgo, M.C., Morales, A.E., Domezain, A., Domezain, J., Sanz, A., 2008. Effect of starvation and refeeding on digestive enzyme activities in sturgeon (Acipenser naccarii) and trout (Oncorhynchus mykiss). Comparative Biochemistry and Physiology A 149, 420-425.

Hasanpour, S., Oujifard, A., Torfi Mozanzadeh, M., Safari, O., 2021. Compensatory growth, antioxidant capacity and digestive enzyme activities of Sobaity (Sparidentex hasta) and yellowfin seabreams (Acanthopagrus latus) subjected to ration restriction. Aquaculture Nutrition 27(6), 2448-2458

Hidalgo, M., Urea, E., Sanz, A., 1999. Comparative study of digestive enzymes in fish with different nutritional habits. Proteolytic and amylase activities. Aquaculture 170, 267- 283.

Hoehne-Reitan, K., Kjørsvik, E., Reitan, K.I., 2003. Lipolytic activities in developing turbot larvae as influenced by diet. Aquaculture International 1, 477– 489.

Hornick, J.L., Van Eenaeme, C., Gérard, O., Dufrasne, I., Istasse, L., 2000. Mechanisms of reduced and compensatory growth. Domestic Animal Endocrinology 19, 121-132.

Hummel, B.C.W., 1959. A modified spectrophotometric determination of chymotrypsin, trypsin, and thrombin. Canadian Journal of Biochemistry and Physiology 37, 1393-1399.

Imani A., Yazdanparast R., Farhangi M., Bakhtiari M., Majazi Amiri B., Shokouh Saljoghi Z., 2010. Study of digestive enzyme activities in rainbow trout (Oncorhynchus mykiss) over feed deprivation and refeeding periods. Journal of the Marine Science and Technology 8 (3-4), 24-33 (In Persian).

Jahantigh, M., 2015. Characteristics of some digestive enzymes in sobaity, Sparidentex hasta, Iranian Journal of Veterinary Medicine 9(3), 213-218. (In Persian).

Kaushik, S.J., de Oliva Teles, A., 1985. Effect of digestible energy on nitrogen and energy balance in rainbow trout. Aquaculture 50, 89-101.

Kuronuma, K., Abe, Y., 1986. Fishes of the (Persian) Gulf. Kuwait Institute for Scientific Research 356 p.

Kuzmina, V.V., 1990. Temperature influence on the total level of proteolytic activity in the digestive tract of some species of freshwater fishes. Journal of Ichthyology 30, 97–109.

Lemieux, H., Blier, P., Dutil, J.D., 1999. Do digestive enzymes set a physiological limit on growth rate and food conversion efficiency in the Atlantic cod (Gadus morhua)?. Fish Physiology and Biochemistry 20, 293-303.

Love, R.M., 1970. The Chemical Biology of Fishes, Academic Press, London, 547 pp.

Lundstedt, L.M., Bibiano, J.M., Moraes, G., 2004. Digestive enzymes and metabolic profile of Pseudoplatystoma corruscans (Teleostei: Siluriformes) in response to diet composition. Comparative Biochemistry and Physiology B 137, 331–339.

Martinez, I., Moyano, F.J., Fernández-Diaz, C., Yufera, M., 1999. Digestive enzyme activity during larval development of the Senegal sole (Solea senegalensis). Fish Physiology and Biochemistry 21, 317–323.

Martínez-Palacios, C., Racotta, I., Ríos-Durán, M., Palacios, E., Toledo-Cuevas, M., Ross, L., 2006. Advances in applied research for the culture of Mexican silversides (Chirostoma, Atherinopsidae). Biocell 30, 137-148.

Metcalfe, N.B., Monaghan, P., 2001. Compensation for a bad start: grow now, pay later?. Trends in Ecology & Evolution 16, 254-260.

Molayemraftar, T., Kochanian, P., Zakeri, M., Yavari, V., Mousavi, S.M., 2014. Effects of short-term starvation on biochemical carcass composition, liver glycogen and fat in silver seabream fingerlings, Sparidentex hasta. Journal of the Marine Science and Technology 12 (4), 60-70 (In Persian).

Molayemraftar, T., Kochanian, P., Zakeri, M., Yavari, V., Mousavi, S.M., 2019. Effects ofshort term food deprivation and re-feeding on growth, feeding and biochemical body composition in Sobaity fish, Sparidentex hasta. Veterinary Research 12 (4), 10-18.

Morales, A.E., Pérez-Jiménez, A., Hidalgo, M.C., Abellan, E., Cardenete, G., 2004. Oxidative stress and antioxidant defenses after prolonged starvation in Dentex dentex liver. Comparative Biochemistry and Physiology C 139,153–161.

Murray, H.M., Gallant, J.W., Perez-Casanova, J.C., 2003. Ontogeny of lipase expression in winter flounder. Journal of Fish Biology 62 (4), 816–833.

Nikki, J., Pirhonen, J., Jobling, M., Karjalainen, J., 2004. Compensatory growth in juvenile rainbow trout, Oncorhynchus mykiss (Walbaum), held individually. Aquaculture 235, 285-296.

Oh, S.Y., Noh, C.H., Kang, R.S., Kim, C.K., Cho, S.H., JO, J.Y., 2008. Compensatory growth and body composition of juvenile black rockfish Sebastes schlegeli following feed deprivation. Fisheries Science 74, 846-852.

Peres, A., Zambonino Infante, J., Cahu, C., 1998. Dietary regulation of activities and mRNA levels of trypsin and amylase in sea bass (Dicentrarchus labrax) larvae. Fish Physiology and Biochemistry 19,145-152.

Pérez-Jiménez, A., Guedes, M.J., Morales, A.E., Oliva-Teles, A., 2007. Metabolic responses to short starvation and refeeding in Dicentrarchus labrax. Effect of dietary composition. Aquaculture 265, 325-335.

Rungruangsak-Torrissen, K., Moss, R., Andresen, L., Berg, A., Waagbø, R., 2006. Different expressions of trypsin and chymotrypsin in relation to growth in Atlantic salmon (Salmo salar L.). Fish Physiology and Biochemistry 32, 7-23.

Torfi Mozanzadeh, M., Zabayeh Najafabadi, M., Torfi, M., Safari, O., Oosooli, R., Mehrjooyan, Sh., Pagheh, E., Hoseini, S.J., Saghavi, H., Monem, J., Gisbert, E., 2021. Compensatory growth of Sobaity (Sparidentex hasta) and yellowfin seabreams (Acanthopagrus latus) relative to feeding rate during nursery phase, Aquaculture Nutrition 27(2), 468-476.

Weatherley, A., Gill, H., 1981. Recovery growth following periods of restricted rations and starvation in rainbow trout Salmo gairdneri Richardson. Journal of Fish Biology 18, 195-208.

Worthington, C.C., 1991. Worthington enzyme manual related Biochemical.3th Edition. Freehold, New jersey, pp.212-215.

Yoshinaka, R., Sato, M., Ikeda, S., 1984. Distribution of trypsin and chymotrypsin and their zymogens in digestive system of the eel (Anguilla japonica). Comparative Biochemistry and Physiology C 83(3), 569-573.

Volume 75, Issue 4 - Serial Number 4
December 2022
Pages 535-548

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Effects of starvation and re-feeding on recovery of digestive enzyme capacity in Sobeity (Sparidentex hasta) marine fish

References

Volume 75, Issue 4 - Serial Number 4
December 2022
Pages 535-548

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Effects of starvation and re-feeding on recovery of digestive enzyme capacity in Sobeity (Sparidentex hasta) marine fish

References

Volume 75, Issue 4 - Serial Number 4December 2022Pages 535-548

Files

Share

How to cite

Statistics

Volume 75, Issue 4 - Serial Number 4
December 2022
Pages 535-548