Abstract
Effect of realimentation was studied on the structure and function of liver tissue of carp,Cyprinus carpio. Yearling carp, after a 3-month starvation period, were renourished at a feeding rate of 1% body weight per day. Samples were taken at refeeding days 0, 1, 2, 5, 22 and 78. Analyses were made of blood metabolites, liver RNA, DNA, lipids, glycogen and protein and of liver enzyme activities. Additionally, liver cytology was examined by means of qualitative and quantitative electron microscopy. The early refeeding period (up to day 5) was characterized by a fast recovery of plasma metabolite concentrations (protein, total lipids, free fatty acids, glucose), a drastic augmentation of hepatic glycogen reserves, and a pronounced increase of total liver weight and liver-somatic index. Constant values of total hepatic DNA showed that liver weight augmentation was not due to cell proliferation, but to a pronounced enlargement of the existing hepatocytes. Major hunger-related structural modifications of carp hepatocytes such as enlarged mitochondria or prominence of the lysosomal compartment were reversed. A significant volume increase of cell nuclei, together with a particularly strong elevation of hepatic RNA concentrations during initial realimentation suggest an immediate stimulation of protein synthesis. Since the cisternae of the endoplasmic reticulum were not reconstituted during that early phase, protein synthesis may have been executed mainly by free ribosomes. With prolonged realimentation, the volume of the endoplasmic reticulum as well as total and relative contents of liver soluble protein continuously increased, whereas RNA concentrations decreased again. An enforcement of liver oxidative capacity was indicated by the augmentation of cellular number and volume of mitochondria. The activities of the enzymes glucose-6-phosphate dehydrogenase and malic enzyme, which convert excess energy into NADPH, increased steadily. Concomitantly, hepatic lipid accumulation was enhanced. In conclusion, liver metabolism during the early recovery phase seems to be dominated both by repair processes and by intensive protein and glycogen synthesis. The liver slows down these processes during prolonged refeeding and directs an increasing percentage of energy and metabolites toward the generation of reducing equivalents and lipid reserves.
This is a preview of subscription content, log in via an institution to check access.
Similar content being viewed by others
Abbreviations
- BW:
-
body weight
- ER:
-
endoplasmic reticulum
- FFA:
-
free fatty acids
- G6PDH:
-
glucose-6-phosphate dehydrogenase
- LSI:
-
liver somtic index
- LW:
-
liver weight
- ME:
-
malic enzyme
References
Aebi H, Berger EG (1980) Nutrition and enzyme regulation. Verlag Hans Huber, Bern
Agius L, Peak M, Al-Habori M (1991) What determines the increase in liver cell volume in the fasted-to-fed transition: glycogen or insulin? Biochem J 277:843–845
Bastrop R, Spangenberg R, Jürss K (1991) Biochemical adaptation of juvenile carp (Cyprinus carpio) to food deprivation. Comp Biochem Physiol 98A:143–149
Bastrop R, Jürss K, Wacke R (1992) Biochemical parameters as a measure of food availability and growth in immature rainbow trout (Oncorhynchus mykiss). Comp Biochem Physiol 102A:151–161
Bayne BL (1985) The effects of stress and pollution on marine animals. Praeger, New York
Black D, Love RM (1986) The sequential mobilisation and restoration of energy reserves in tissues of atlantic cod during starvation and refeeding. J Comp Physiol 156B:469–479
Blasco J, Fernandez F, Gutiérrez J (1992) Fasting and refeeding in carp,Cyprinus carpio L.: the mobilization of reserves and plasma metabolites and hormone variations. J Comp Physiol 162B:539–546
Böhm R, Hanke W, Segner H (1993) Regulation der Glykolyse und Glukoneogenese in der Leber des Karpfens,Cyprinus carpio. Verh Dtsch Zool Ges 86.1:82
Bouche G, Murat JC, Parent JP (1971) Etude de l'influence des régimes synthetiques sur la protéosynthese et les reserves glucidiques et lipidiques dans le foie de la carpe dénutrie. C R Seanc Soc Biol Paris 165:2202–2205
Braunbeck T, Segner H (1992) Pre-exposure temperature acclimation and diet as modifying factors for the tolerance of golden ide (Leuciscus idus melanotus) to short-term exposure to 4-chloroaniline. Ecotox Environ Safety 24:72–94
Brunk Sd, Swanson JR (1981) Colorimetric method for FFA in serum, valididated by comparison with gas chromatography. Clin Chem 27:924–926
Chavin W (1973) Teleostean endocrine and paraendocrine alterations of utility in environmental studies. In: Chavin W (ed): Responses of fish to environmental changes. Thomas, Springfield/Illinois, pp 199–239
Creach Y, Murat JC (1974) La jeune et la réalimentation chez la carpe (Cyprinus carpio L.): VII. Métabolisme du glucose-1-14C et du glucose-6-14C. Arch Sci Physiol 28:157–172
Creach Y, Serfaty A (1974) Le jeune et la réalimentation chez la carpe (Cyprinus carpio L). J Physiol (Paris) 68:245–260
Deutsch J (1983) Glucose-6-phosphate dehydrogenase. In: Bergmeyer HU (ed): Methods of enzymatic analysis, vol 3. Verlag Chemie, Weinheim, pp 190–197
Freedland R, Szepesi B (1971) Control of enzyme activity: nutritional factors. In: Enzyme synthesis and degradation in mammalian systems. Karger, Basel, pp 103–140
Gas N (1973) Cytophysiologie du foie de carpeCyprinus carpio L.). Modifications ultrastructurales consécutives au maintien dans des conditions de jeune hivernal. J Physiol (Paris) 64:57–67
Gas N, Bouche G, Serfaty A (1971) Etude cytophotometrique de l'évolution des acides nucléiques du foie de carpe (Cyprinus carpio L.) pendant la jeune et la réalimentation. J Physiol (Paris) 63:625–633
Hinton De, Hampton JA, Lantz RC (1985) Morphometric analysis of liver in rainbow trout: quantitatively defining an organ of xenobiotic metabolism. Mar Environ Res 17:238–239
Iniesta MG, Cano MJ, Garrido-Pertierra A (1985) Properties and function of malate enzyme fromDicentrachus labrax L. liver. Comp Biochem Physiol 80B:35–39
Karnovsky MJ (1971) Use of ferrocyanide-reduced osmium tetroxide in electron microscopy. J Cell Biol 51:284
Keppler D, Decker K (1984) Glycogen. In: Bergmeyer HU (ed): Methods in enzymatic analysis, vol 6. Verlag Chemie, Weinheim, pp 11–18
Kuwajima M, Newgard CB, Foster DW, McGarry JD (1986) The glucose-phosphorylating capacity of liver as measured by three independent assays. J Biol Chem 261:8849–8853
Likimani TA, Wilson RP (1982) Effects of diet on lipogenic enzyme activities in channel catfish hepatic and adipose tissue. J Nutr 112:112–117
Love RM (1980) The chemical biology of fishes, vol 2. Academic Press, London
Lowry OH, Rosebrough NJ, Farr AL, Randall RJ (1951) Protein measurement with the folin phenol reagent. J Biol Chem 193:265–275
McMillan DN, Houlihan DF (1989) Short-term responses of protein synthesis to re-feeding in rainbow trout. Aquaculture 79:37–46
Mendez G, Wieser W (1993) Metabolic responses to food deprivation and refeeding in juveniles ofRutilus rutilus (Teleostei: Cyprinidae). Env Biol Fish 36:73–81
Miglavs I, Jobling M (1989a) The effects of feeding regime on proximate body composition and patterns of energy deposition in juvenile arctic charr,Salvelinus alpinus. J Fish Biol 35:1–11
Miglavs I, Jobling M (1989b) Effects of feeding regime on food consumption, growth rates and tissue nucleic acids in juvenile arctic charr,Salvelinus alpinus, with particular respect to compensatory growth. J Fish Biol 34:947–957
Nagai M, Ikeda S (1971) Carbohydrate metabolism in fish. — I. Effects of starvation and dietary composition on the blood glucose level and the hepatopancreatic glycogen and lipid contents in carp. Bull Jpn Soc Sci Fish 37:404–409
Newgard CB, Moore SV, Foster DW, McGarry JD (1984) Efficient hepatic glycogen synthesis in refeeding rats requires continued carbon flow through the gluconeogenic pathway. J Biol Chem 259:6958–6963
Pain VM, Clemens MJ (1980) Mechanisms and regulation of protein synthesis in eukaryotic cells. In: Buttery PJ, Lindsay DB (eds) Protein deposition in animals. Butterworth, London, pp 1–20
Rafael J, Vsianski P (1981) Quantitative determination of nucleic acids in brown and white adipose tissue. Anal Biochhem 115:158–162
Sachs L (1984) Angewandte Statistik. Springer, Berlin Heidelberg New York
Segner H, Braunbeck T (1988) Hepatocellular adaptation to extreme nutritional conditions in ide,Leuciscus idus melanotus L. (Cyprinidae). A morphofunctional analysis. Fish Physiol Biochem 5:9–97
Segner H, Braunbeck T (1990) Adaptive changes of liver composition and structure in golden ide during winter acclimatization. J Exp Zool 255:171–185
Shimeno S, Kheyyali D, Takeda M (1990) Metabolic adaptation to prolonged starvation in carp. Nippon Suisan Gakkaishi 56:35–41
Spurr AR (1969) A low viscosity embedding medium for electron microscopy. J Ultrastruct Res 26:31–47
Steffens W (1964) Die Überwinterung des Karpfens (Cyprinus carpio) als physiologisches Problem. Z Fischerei N F 12:97–153
Stoll B, Gerok W, Lang E, Häussinger D (1992) Liver cell volume and protein synthesis. Biochem J 287:217–22
Walzem RM, Storebakken T, Hung SSO, Hansen RJ (1991) Relationship between growth and selected liver enzyme activities of individual rainbow trout. J Nutr 121:1090–1098
Weibel ER (1979) Stereological methods, vol 1. Academic Press, London New York
Yamauchi T, Stegeman J, Goldberg E (1975) The effects of starvation and temperature acclimation on pentose phosphate pathway dehydrogenases in brook trout liver. Archs Biochim Biophys 167:13–20
Zöllner N, Kirsch K (1962) Über die quantitative Bestimmung von Lipiden (Mikromethode) mittels der vielen natürlichen Lipiden (allen bekannten Plasmalipiden) gemeinsamen Sulphophosphovanillinreaktion. Z Ges Exp Med 135:545–561
Author information
Authors and Affiliations
Rights and permissions
About this article
Cite this article
Böhm, R., Hanke, W. & Segner, H. The sequential restoration of plasma metabolite levels, liver composition and liver structure in refed carp,Cyprinus carpio . J Comp Physiol B 164, 32–41 (1994). https://doi.org/10.1007/BF00714568
Issue Date:
DOI: https://doi.org/10.1007/BF00714568