Vitamin A status affects obesity development and hepatic expression of key genes for fuel metabolism in Zucker fatty rats

We hypothesized that vitamin A (VA) status may affect obesity development. Male Zucker lean (ZL) and fatty (ZF) rats after weaning were fed a synthetic VA deficient (VAD) or VA sufficient (VAS) diet for 8 weeks before their plasma parameters and hepatic genes' expression were analyzed. The body mass (BM) of ZL or ZF rats fed the VAD diet was lower than that of their corresponding controls fed the VAS diet at 5 or 2 weeks, respectively. The VAD ZL and ZF rats had less food intake than the VAS rats after 5 weeks. The VAD ZL and ZF rats had lower plasma glucose, triglyceride, insulin, and leptin levels, as well as lower liver glycogen content, net mass of epididymal fat, and liver/BM and epididymal fat/BM ratios (ZL only) than their respective VAS controls. VAD rats had lower hepatic Cyp26a1, Srebp-1c, Fas, Scd1, Me1, Gck, and Pklr (ZL and ZF); and higher Igfbp1 (ZL and ZF), Pck1(ZF only), and G6pc (ZF only) mRNA levels than their respective VAS controls. We conclude that ZL and ZF rats responded differently to dietary VA deficiency. VA status affected obesity development and altered the expression of hepatic genes for fuel metabolism in ZF rats. The mechanisms will help us to combat metabolic diseases.     

The effects of fasting and refeeding on serum parathormone and calcitonin concentrations in young and old male rats.

Although fasting and refeeding reveal the existence of age-related changes in carbohydrate and lipid metabolism, the effects of aging on mineral metabolism in refed animals are unknown. We therefore investigated hormonal regulation of calcium metabolism in young (4 months) and old (26 months) male rats fasted for 48 hours and then refed for 4 or 24 hours. Serum concentrations of total and ionized calcium and parathormone were similar in control young and old rats. Serum calcitonin level was higher, and the concentrations of albumin and inorganic phosphate and alkaline phosphatase activity were lower in fed old rats. In young fasted rats, the serum ionized and total calcium was decreased, and phosphate concentration was increased. In old rats, fasting resulted in the increase of serum parathormone level. Fasting reduced serum alkaline phosphatase activity to a similar extent in both age groups. In young rats, refeeding for 24h normalized serum calcium and phosphate levels and alkaline phosphatase activity, and decreased serum concentrations of PTH and calcitonin. In old refed rats, serum calcitonin concentration was raised by 77% compared to fed or fasted animals, whereas parathormone levels were normalized. Our results indicate that old fasted or refed rats maintain normal serum calcium concentration in a different way than young animals, possibly through the increase in serum levels of parathormone and/or calcitonin. Thus, dietary manipulations such as fasting and refeeding constitute an interesting model for the investigation of the effects of aging on the hormonal regulation of serum calcium level.     

Are Kupffer cells involved in the metabolic adaptation of the liver to dietary carbohydrates given after fasting?

In rats, a high carbohydrate fat-free (HCFF) diet, given after fasting, induces both hepatic lipogenic and glycogenic enzymes. In the present study, we evaluated the involvement of Kupffer cells in the metabolic events occurring in the liver during the fasting-refeeding transition. Male Wistar rats were fasted for 48 h and received an intravenous injection of either NaCl 0.9% (Gd-) or 10 mg/kg GdCl(3) (Gd+), an inhibitor of Kupffer cells, then fed for 12 h with a HCFF diet. The comparison of colloidal carbon uptake was similar in rats fasted and in rats fasted and then refed a HCFF diet, thus indicating that refeeding does not affect per se Kupffer cell phagocytic activity. The inhibition of Kupffer cells by GdCl(3) did not affect fatty acid synthase (FAS) induction, as shown by the analysis of both FAS mRNA and activity; refeeding a HCFF diet increased the hepatic triglyceride and glycogen content to the same extent in Gd+ and Gd- rats. Our results do not support the involvement of Kupffer cells in the metabolic events occurring in the liver tissue by feeding a HCFF diet after fasting. However, the discussion supports the involvement of Kupffer cells in the modulation of the hepatic lipid metabolism by other nutrients than carbohydrates.     

Metabolic control of phosphorylase conversion in muscle. Effect of fasting and refeeding on the response of rat diaphragm glycogen phosphorylase, cyclic AMP Dependent protein kinase, and phosphorylase b kinase to adrenergic stimulation.

The influence of fasting and refeeding on the response to adrenergic stimulation of several enzymes involved in glycogen metabolism has been investigated in the isolated, intact rat diaphragm. The in vitro response of the phosphorylase system to terbutaline was found to decrease markedly following fasting. A pronounced increase in this response was seen upon refeeding. This increased responsiveness was normalized by incubation of isolated tissues with palmitate (1.5 mM). Plasma free fatty acid concentration was increased in fasted rats compared to the value found in refed animals. The effect of terbutaline on cyclic AMP concentration and protein kinase activity was not significantly influenced by fasting and refeeding while fasting decreased the effect of terbutaline upon phosphorylase b kinase. Diaphragm glycogen levels were reduced by more than 50% in rats fasted for 24 hours and were significantly increased upon refeeding compared to fed rats. The results indicate that the nutritional state can modulate the sensitivity of the interconverting system for phosphorylase. It is suggested that this modulation might depend upon fatty acid metabolism.     

Vitamin A and Feeding Statuses Modulate the Insulin-Regulated Gene Expression in Zucker Lean and Fatty Primary Rat Hepatocytes

Unattended hepatic insulin resistance predisposes individuals to dyslipidemia, type 2 diabetes and many other metabolic complications. The mechanism of hepatic insulin resistance at the gene expression level remains unrevealed. To examine the effects of vitamin A (VA), total energy intake and feeding conditions on the insulin-regulated gene expression in primary hepatocytes of Zucker lean (ZL) and fatty (ZF) rats, we analyze the expression levels of hepatic model genes in response to the treatments of insulin and retinoic acid (RA). We report that the insulin- and RA-regulated glucokinase, sterol regulatory element-binding protein-1c and cytosolic form of phosphoenolpyruvate carboxykinase expressions are impaired in hepatocytes of ZF rats fed chow or a VA sufficient (VAS) diet ad libitum. The impairments are partially corrected when ZF rats are fed a VA deficient (VAD) diet ad libitum or pair-fed a VAS diet to the intake of their VAD counterparts in non-fasting conditions. Interestingly in the pair-fed ZL and ZF rats, transient overeating on the last day of pair-feeding regimen changes the expression levels of some VA catabolic genes, and impairs the insulin- and RA-regulated gene expression in hepatocytes. These results demonstrate that VA and feeding statuses modulate the hepatic insulin sensitivity at the gene expression level.     

Effect of fasting and refeeding on gluconeogenesis and glyconeogenesis in the muscle of the crab Chasmagnathus granulatus previously fed a protein- or carbohydrate-rich diet

The present study investigated the participation of the muscle gluconeogenic and glyconeogenic pathways in lactate metabolism after 15 fasting and during different periods of refeeding in Chasmagnathus granulatus previously maintained on a carbohydrate-rich (HC) or high-protein (HP) diet. In C. granulatus the metabolic adjustments during the fasting use different pathways according to the composition of the diet previously offered to the crab. During fasting, the gluconeogenic capacity is reduced in crabs maintained on the HC diet. In animals maintained on the HP diet, an increase in activity of the glyconeogenic pathway occurs after 15 days of fasting. In the animals fed HC diet, the glyconeogenesis is one of the pathways responsible for maintenance of the lactate levels in the fed and refeeding states. In crabs fed on the HP diet, the gluconeogenesis and glyconeogenesis pathways are involved in the reduction of lactate levels during the refeeding period. This study shows that protein or carbohydrates levels in the diet previously administrated to the crabs modulate the gluconeogenesis, glyconeogenesis in muscle and lactate concentration in the hemolymph in fed, fasting and refeeding states.     

Food restriction followed by refeeding with a casein- or whey-based diet differentially affects the gut microbiota of pre-pubertal male rats

Researchers are gaining an increasing understanding of host–gut microbiota interactions, but studies of the role of gut microbiota in linear growth are scarce. The aim of this study was to investigate the effect of food restriction and refeeding with different diets on gut microbiota composition in fast-growing rats. Young male Sprague–Dawley rats were fed regular rat chow ad libitum (control group) or subjected to 40% food restriction for 36 days followed by continued restriction or ad libitum refeeding for 24 days. Three different diets were used for refeeding: regular vegetarian protein chow or chow in which the sole source of protein was casein or whey. In the control group, the composition of the microbiota remained stable. Food restriction for 60 days led to a significant change in the gut microbiota at the phylum level, with a reduction in the abundance of Firmicutes and an increase in Bacteroidetes and Proteobacteria. Rats refed with the vegetarian protein diet had a different microbiota composition than rats refed the casein- or whey-based diet. Similarities in the bacterial population were found between rats refed vegetarian protein or a whey-based diet and control rats, and between rats refed a casein-based diet and rats on continued restriction. There was a significant strong correlation between the gut microbiota and growth parameters: humerus length, epiphyseal growth plate height, and levels of insulin-like growth factor 1 and leptin. In conclusion, the type of protein in the diet significantly affects the gut microbiota and, thereby, may affect animal's health.     

Secretion of lipoprotein lipid and synthesis of fatty acids, cholesterol and triacylglycerol by hepatocytes of fasted-refed rats

Synthetic rates of fatty acid, cholesterol and triacylglycerols, and contents and secretion of lipoprotein lipids, were determined in hepatocytes of rats fed ad libitum a fat-containing stock diet or of rats fasted for 48 h and then refed for 24 or 48 h with stock diet or with a glucose-rich fat-free diet. When compared with the values for the ad libitum-fed rats, fatty acid synthesis was lower in fasted rats, slightly increased in rats refed with the stock diet, but several-fold elevated after refeeding the glucose-rich fat-free diet. Cholesterol synthesis was decreased in the fasted cells, and restored to the control level upon refeeding either diet. Triacylglycerol synthesis from exogenous oleate was greatly stimulated in the cells of fasted-refed rats above the rate in cells of the ad libitum-fed rats, the increase being considerably higher after refeeding the glucose-rich fat-free diet than the stock diet. The amount of triacylglycerol secreted by the cells was also elevated by the fasting-refeeding treatment, but the difference between the two diets was much less pronounced than seen for the lipids' synthetic rates. This imbalance may underlie the huge accumulation of this lipid observed in the heptatocytes after refeeding the rats for 48 h with the glucose-rich fat-free diet.     

On lysosomal fragility and induction of liver hexose-monophosphate dehydrogenases in the fasted-refed rat.

Young adult male rats were fasted for 3 days, then fed a glucose-rich diet, ad libitum. At the end of the fasting period, the specific activity of liver glucose-6-phosphate dehydrogenase and 6-phosphogluconate dehydrogenase was decreased to 60% of control (nonfasted) levels. After 24 to 72 h of refeeding, the specific activity of glucose-6-phosphate dehydrogenase and 6-phosphogluconate dehydrogenase increased seven- and twofold, respectively. During the fasting period, the liver lysosome fragility increased, as judged by increased release of bound acid phosphatase and β-N-acetylglucosammidase activity during standard homogenization. Three hours after feeding a carbohydrate-rich diet, a further increase in liver lysosomal fragility was observed that returned to control values prior to the induction of the dehydrogenases. Similarly, the susceptibility of liver lysosomes from fasted rats to increased fragility by the intraperitoneal injection of glucose or galactose was also observed. Prior starvation was not a requisite for labilization of lysosomal membranes by injected glucose, but induction of the pentose phosphate shunt dehydrogenase was not observed.In a group of 6-week old male rats fed a commercial pellet diet throughout, the injection of insulin caused no change in liver lysosomal fragility, though hypoglycemia resulted. Similar animals made diabetic by treatment with Streptozotocin and diabetic rats given insulin, showed no change in liver lysosmal fragility based on the percentage of free to total activities of β-N-acetylglucosaminidase, β-glucuronidase, β-galactosidase, and Cathespin D. However, when adult female rats were fasted for 24 h, then injected with sufficient insulin to produce hypoglycemia, liver lysosomal fragility, based on the release of β-N-acetylglucosaminidase during homogenization, increased nearly threefold. These studies demonstrate that stimulated lysosomal fragility can be initiated by refeeding fasted animals a carbohydrate-rich diet, by intraperitoneal injections of fasted rats with glucose or galactose, or by administering insulin alone to fasted rats. However, hyperglycemia induced by diabetogenic doses of Streptozotocin, or hypoglycemia induced in well-fed animals by insulin injection failed to elicit an enhanced liver lysosomal fragility. Whether induction of the enzymes of lipogenesis by rat liver is dependent upon a prior lysosomal membrane labilization remains to be determined.     

Regulation of apolipoprotein E synthesis and mRNA by diet and hormones

Rats were fasted or fasted and refed simple purified diets so the effects of individual carbohydrates or fats could be studied. Freshly isolated hepatocytes from these animals were used to measure both apoE synthesis and mRNA levels so any changes in apoE synthesis that might occur without changes in its mRNA could be detected. Some of these experiments were done with both sexes. Both fasting and fasting and refeeding a 60% glucose fat-free diet significantly increased spoE synthesis. However, cyclic AMP is not likely to rapidly mediate the effect of fasting since dibutyryl cAMP slightly lowered (rather than increased) apoE synthesis and mRNA when injected into rats for 4.5 h. Dietary fat had no effect either in the absence of carbohydrate or when consumption of carbohydrate was constant in pair-fed rats. ApoE mRNA levels remained normal for 4 days in primary hepatocytes cultured in medium that had only amino acids as an energy source. Added hormones or fructose had no significant effect. Thus, only fasting and fasting and refeeding glucose were able to significantly change apoE synthesis or mRNA levels. Synthesis of apoE may be regulated to increase when apoE is secreted with very low density lipoprotein or when apoE in secreted high density lipoprotein is needed to acquire cholesteryl esters for the synthesis of bile salts and acids by liver.     

Thyroid C cell function during fasting and refeeding of young and old rats

Age-related alterations in the structure and function of many organs often become apparent under stimulation of their function. Although the ageing process affects the regulation of mineral homeostasis, the function of thyroid C-cells that secrete calcitonin (CT) under the conditions of fasting and refeeding, a way of dietary manipulation that reveal the existence of age-related changes of follicular thyroid cells, has not been characterized. Therefore, we investigated the number of C-cells and serum CT concentration in young (4 mo) and old (26 mo) male rats fasted for 48 hours, and then refed for 4 or 24 hours. We found significantly higher number of C-cells in thyroids of old vs young rats both under basal conditions, and after fasting/refeeding. Correspondingly, serum calcitonin level was higher in fed or fasted old rats vs young ones. However, in young rats refeeding decreased, whereas in old animals increased serum concentrations of calcitonin. Thus, the control of serum calcium concentration, that was well preserved in old rats, occurs at the expense of increased serum CT level both under basal conditions, and after refeeding. These observations suggest that C-cell function is altered in ageing.     

Hepatospecific effects of fructose on c-jun NH2-terminal kinase: implications for hepatic insulin resistance

Sucrose- and fructose-enriched diets produce hepatic insulin resistance in rats independently of obesity. In humans, fructose infusion results in impaired insulin regulation of glucose production. The aim of the present study was to identify intrahepatic mediators of sucrose- and fructose-induced hepatic insulin resistance. In study 1, male rats were fed a control diet (STD, 68% of energy from corn starch, 12% from corn oil) or a sucrose-enriched diet (HSD, 68% sucrose, 12% corn oil) for 1, 2, or 5 wk. HSD produced hepatic insulin resistance at all time points. Hepatic protein tyrosine phosphatase 1B protein levels and activity were increased at 5 wk only, whereas c-jun NH(2)-terminal kinase (JNK) activity was increased at all time points. Normalization of JNK activity in hepatocytes isolated from HSD rats improved insulin-stimulated tyrosine phosphorylation of insulin receptor substrate (IRS) proteins and insulin suppression of glucose release. In study 2, male rats were provided STD for 1 wk and then were either fasted or fasted and refed either STD or HSD for 3 or 6 h. Rats refed HSD were characterized by increased hepatic JNK activity and phosphorylation of IRS1 on Ser(307) after 6 h only. In study 3, hyperglycemic, hyperinsulinemic pancreatic clamps were performed for 3 or 6 h in the presence or absence of low or high intraportal fructose infusions. High intraportal fructose infusions, which increased portal vein fructose concentration to approximately 1 mM, increased hepatic JNK activity and phosphorylation of IRS1 on Ser(307) at 6 h only. These data suggest that sucrose- and fructose-induced hepatic insulin resistance are mediated, in part, via activation of JNK activity. Thus high rates of fructose metabolism in the liver appear to acutely activate stress pathways.     

Expression of hepatic calcium-binding protein regucalcin mRNA is elevated by refeeding of fasted rats: Involvement of glucose,insulin and calcium as stimulating factors

The effect of refeeding on the expression of Ca²⁺-binding protein regucalcin mRNA in the liver of fasted rats was investigated. When rats were fasted overnight, the hepatic regucalcin mRNA level was reduced about 70% of that in feeding rats. Refeeding produced a remarkable elevation of hepatic regucalcin mRNA level (about 150–170% of fasted rats). Liver regucalcin concentration was appreciably increased by refeeding, although it was not altered by fasting. The oral administration of glucose (2 g/kg body weight) to fasted rats caused a significant increase in hepatic regucalcin mRNA level. Moreover, hepatic regucalcin mRNA level was clearly elevated by a single subcutaneous administration of insulin (10 and 100 U/kg) to fasted rats. The hormonal effect was not further enhanced by the simultaneous administration of calcium chloride (250 mg Ca/kg) to fasted rats, although calcium administration stimulated regucalcin mRNA expression in the liver. The present study suggests that the expression of hepatic regucalcin mRNA stimulated by refeeding is significantly involved in the action of insulin and/or calcium as stimulating factors.     

Refeeding with a standard diet after a 48-h fast elicits an inflammatory response in the mouse liver

Unhealthy eating behaviors increase the risk of metabolic diseases, but the underlying mechanisms are not fully elucidated. Because inflammation contributes to the pathogenesis of metabolic diseases, it is important to understand the effects of unhealthy eating on the inflammatory state. The objective of our present study was to address the effects of a fasting–refeeding regime, a model of irregular eating, on the hepatic inflammatory responses in mouse. The animals were fasted for 48 h and then refed either a standard or low-carbohydrate/high-fat diet. Inflammatory gene expression in the liver was then sequentially measured for the first 17 h after initiation of refeeding. To assess the roles of dietary carbohydrates and toll-like receptor 2 (TLR2) in the refeeding-induced inflammatory changes, gene expression levels in mice refed only carbohydrates (α-corn starch and sucrose) at different doses and in TLR2-deficient mice refed a standard diet were also analyzed. Refeeding with a standard diet increased the liver expression of Tlr2, proinflammatory mediators (Cxcl10, Cxcl1, Cxcl2, Icam-1) and negative regulators of TLR-signaling (A20 and Atf3). These increases were attenuated in mice refed a low-carbohydrate/high-fat diet. Refeeding only α-corn starch and sucrose also increased the expression of these inflammatory pathway genes depending on the doses. TLR2 deficiency significantly attenuated the refeeding-induced increase in the liver expression of Cxcl10, Cxcl1, Icam-1 and A20. These findings suggest that an irregular eating behavior can elicit a liver inflammatory response, which is at least partly mediated by TLR2, and that dietary carbohydrates play critical roles in this process.     

Brown fat activity in fasted and refed rats

Four days of fasting in the rat reduced brown-adipose-tissue (BAT) mass, mitochondrial protein, and tissue protein content. Specific binding of guanosine diposphate (GDP) to BAT mitochondria was depressed by 55% in 4d-fasted rats. Rats fasted for 3 d, and then refed a single carbohydrate meal (40 kJ), showed a significant increase in specific GDP-binding (27% above fasted) 24 h later, and a large increase in total binding. Specific activities of cytochrome oxidase and -glycerophosphate dehydrogenase in BAT mitochondria were not significantly affected by fasting or refeeding. These results suggest that BAT may be partly responsible for the fall in metabolic rate associated with fasting and the delayed increase after carbo-hydrate refeeding. These effects may be due to changes in the mitochondrial proton-conductance pathway in brown fat.     

The association of lysosomal enzymes with nuclei during enzyme induction in rat liver.

Male rats of the Holtzman strain were fasted for 3 days and refed a diet high in carbohydrate (68.9%). The induction of liver glucose 6-phosphate dehydrogenase and 6-phosphogluconate dehydrogenase was monitored for up to 48 h after refeeding. Induction occurred by 24 h, and by 48 h, 4.2- and 1.5-fold increases were observed for glucose 6-phosphate dehydrogenase and 6-phosphogluconate dehydrogenase, respectively, compared with that of livers of pellet-fed rats. After refeeding, lysosomes increased in fragility as judged by an increased release of acid phosphatase activity during standard homogenization. Fragility was greatest 3 h after refeeding, but normal fragility was observed 24 h after refeeding. Nuclei were isolated from the liver samples before and after refeeding. Those isolated just before refeeding revealed small latent acid phosphatase activity (4–6%). However, after refeeding the carbohydrate-rich diet, a transient and significant (P < 0.01) increase in the latent activity occurred that was maximal (20%) at 1 h, returning to normal by 24 h. Cross-mixing the 800g nuclear pellet from livers of animals starved for 3 days with the 800g supernatant fraction from livers of animals refed the carbohydrate-containing diet did not alter the nuclear lysosomal-free (overt) or latent (detergent-released) enzyme activity. Similarly, mixing the 800g nuclear pellet from livers of animals refed for 1 h with the 800g supernatant fraction from livers of animals starved for 3 days, but not refed, did not change the nuclear lysosomalfree or latent enzyme activity. Purified nuclei, further washed in hypotonic buffer, lost acid phosphatase activity, but those isolated from livers of rats refed for 1 h retained 10% of the enzyme latency, whereas all latency was lost from those isolated from uninduced rats. A second lysosomal enzyme, β-galactosidase, became associated with the nuclei with the same temporal pattern as for acid phosphatase. However, no variation in nuclear content of cytosolic lactate dehydrogenase occurred as a result of feeding the high-carbohydrate diet to starved rats. When similarly starved rats were refed a diet high in lipid and carbohydrate-free, no induction of glucose 6-phosphate dehydrogenase and 6-phosphogluconate dehydrogenase was observed. Lysosomes were not temporarily fragile and purified nuclei did not exhibit increased latency of acid phosphatase activity. Though the evidence presented does not establish a direct correlation between lysosome migration to nuclei as a required function in enzyme induction, the temporal and specific nature of the phenomenon support the hypothesis that liver lysosomal enzymes participate in early signals in the induction of enzymes of lipogenesis.     

Effect of fasting on body composition and responses to stress in sunshine bass

The integrated responses of the hormonal regulation of growth and stress in sunshine bass (Morone chrysops X Morone saxatilis) as regulated by feed deprivation were investigated. Groups of fish were fed 1.5% of the body weight per day or offered no feed for 4 weeks. Another group of fish was not fed for 3 weeks and feed was offered during the fourth week. Fish in each group were sampled immediately before or after a 15-min low water confinement stressor after each week of the experiment. Liver mass and liver glycogen content were decreased after one week of fasting and remained low until the end of the study. However, both recovered after a week of refeeding. Intraperitoneal fat was significantly lower after two weeks of fasting and did not recover after a week of refeeding. None of these components were affected by confinement stress. Plasma glucose in unstressed fish was generally unaffected by fasting or refeeding; however, plasma glucose increased after confinement stress in fed but not in fasted fish. The cortisol stress response was unaltered by fasting and remained robust. Plasma IGF-I generally decreased in fasted fish but was not significantly lower than fed fish until the fourth week. A week of refeeding did not restore plasma IGF-I concentrations. Plasma IGF-I concentrations were higher in confinement stressed fed fish after two and four weeks but were unchanged in the fourth week. There was no change in the plasma IGF-I concentrations in fasted or refed fish due to the stress. Liver weight and liver glycogen were essentially depleted after 2 weeks of fasting. The reduction of liver glycogen greatly reduced the glucose response to stress; however, the cortisol stress response was maintained for at least four weeks of fasting. Intraperitoneal fat was decreased very little after 4 weeks of fasting. Plasma IGF-I concentrations were reduced only after 3 weeks of fasting.     

Effect on Lipids in Liver and Serum,and Some Urinary Components of Dietary Supplement of Excess Lysine Given to Previously Starved or Non-starved Rats

In order to obtain further information on the changes in liver lipids, either a basal or a lysine-sexcess diet was refed to previously starved rats or fed to previously non-starved rats. Liver lipid accumulation was observed in previously starved rats refed the lysine-excess diet for 7 days, but not in rats without previous starvation. The liver lipid did not accumulate with another 8 days’ feeding (15 days⁹ refeeding). The addition of methionine alone or in combination with threonine to the lysine-excess diet had no effect on the liver lipid level. The decrease in serum triacylglycerol in rats refed the lysine-excess diet was preceded by lipid accumulation in the liver. Urinary potassium during the initial two days increased with refeeding and feeding. Marked excretion of orotate was observed for 2 days from the initiation of refeeding of the lysine-excess diet and it then decreased. Thus, such a marked increase in the urinary excretion of orotate might be associated with the stimulation of orotate biosynthesis and with lipid accumulation in the liver.