Effect of dietary protein source on the activity of polysomal ornithine decarboxylase messenger RNA in rat liver

To pursue the mechanism underlying dietary induction of ornithine decarboxylase (ODC) activity in rat liver, changes in free-polysome-associated messenger RNA (mRNA) activity for the enzyme were studied in rats fed diets containing either casein or zein. The enzyme activity increased 50- to 100-fold in 4 h after feeding a 50% casein diet. Changes in the amount of immunoreactive ODC protein roughly paralleled changes in the enzyme activity. Dietary casein was found to cause a several fold increase in polysomal mRNA activity coding for this enzyme, which preceded the increase in catalytic activity. Therefore, the induction of hepatic ODC by casein feeding is due partly to an increase in the activity of its mRNA associated with free polysomes and partly to some translational and/or posttranslational control. On the other hand, feeding the zein diet hardly increased ODC activity, immunoreactive ODC protein or free-polysomal ODC-mRNA activity. This indicates that adequate supply and balance of amino acids are required both for the increase in polysome-associated ODC-mRNA activity and for the translational and/or posttranslational mechanism(s) during the induction of hepatic ODC activity.     

Effect of energy restriction on riboflavin retention in normal and deficient tissues of the rat

We investigated the effects of energy restriction on tissue riboflavin depletion and subsequent repletion of deficient tissues. Groups of male Sprague Dawley rats with average body weights between 268 and 275g were placed on energy-restricted diets consisting of 8g (31kcal or 130kJ) per day of a basal diet adequate in all other nutrients and either 12mg of riboflavin/kg or no added riboflavin. The ad libitum controls received additional energy as a mixture of sucrose, starch, and corn oil (10:3:1 by wt). No significant difference in the degree of riboflavin deficiency was detected between energy-restricted and ad libitum-fed rats as assessed by riboflavin concentrations in the liver and gastrocnemius and soleus muscles and by the erythrocyte glutathione reductase activity coefficient (EGRAC). Additional energy-restricted riboflavin-deficient rats were subsequently repleted by feeding either the supplemented basal diet with no additional energy or with ad libitum energy. Repletion of liver riboflavin concentration and reduction of the EGRAC values to control levels occurred regardless of energy intake. Muscle riboflavin concentrations were normal in the ad libitum-fed group but decreased in the energy-restricted rats despite 4 weeks of supplementation. The latter group had muscle riboflavin levels similar to those in the rats fed the riboflavin-deficient diet for 8 weeks. The results suggest that energy restriction impairs flavo-protein synthesis in muscle but not in the liver.     

Specific decrease in liver insulin-like growth factor-I and brain insulin-like growth factor-II gene expression in energy-restricted rats.

Four-week-old male rats were maintained for 10 d on a series of diets containing a constant high level of dietary protein and total energy at 100, 70, 60 or 50% of the ad libitum intake rate. Under these conditions, growth rate varied as a function of dietary energy. Serum insulin-like growth factor (IGF)-I was decreased in the energy-restricted animals. Total hepatic IGF-I mRNA was decreased by approximately the same factor as circulating IGF-I protein. In contrast to previous results obtained with protein-restricted animals, serum albumin mRNA was not decreased in the energy-restricted animals. Brain IGF-II mRNA was slightly decreased in animals fed the 70 and 60% energy diets and was decreased by 50% in animals fed the 50% energy diet. Insulin-like growth factor binding protein-2 (IGFBP-2) gene expression was increased in the liver but not in the brain of the energy-restricted animals, indicating that dietary energy regulates IGFBP-2 gene expression differently in liver and brain. The results demonstrate specific changes in liver IGF-I and IGFBP-2 gene expression and brain IGF-II gene expression in animals that are growth-retarded because of a restriction of dietary energy.     

The effect of a low protein diet on the response of rat colonic and hepatic ornithine decarboxylase activity to sodium deoxycholate and thioacetamide treatment

Adult male Sprague-Dawley rats fed ad libitum AIN-76A diet with 5% casein for 10 days had the same basal level of colonic ornithine decarboxylase (ODC) as rats fed 20% casein, but showed a higher level following induction of the colonic enzyme by sodium deoxycholate. Total colonic ODC activity was more responsive than holo-ODC activity to the regimen of induction, which suggested to us that functional (i.e., holoenzyme) levels of the decarboxylase may not be as sensitive to dietary modulation as total enzyme levels. Contrary to the results observed for the colon, the basal level of hepatic ODC was decreased in rats fed 5% casein, and the level following induction of the hepatic enzyme by thioacetamide was also diminished compared with induced enzyme levels in animals fed 20% casein. Additionally, there was no difference in the degree of response between holoenzyme and total hepatic enzyme to dietary treatment and a regimen of enzyme induction.     

Effects of energy restriction on mouse mammary tumor virus mRNA levels in mammary glands and uterus and on uterine endometrial hyperplasia and pituitary histology in C3H/SHN F1 mice

We investigated the effects of energy restriction on the pituitary-ovarian axis and on a hormone responsive gene, the mouse mammary tumor virus (MMTV). Female C3H/SHN F1-hybrid mice, known to display a high incidence of mammary tumors, ate an energy-restricted diet (48 kcal/wk) or a control diet (95 kcal/wk) beginning at the time of weaning. By 67 wk of age, 12 of 32 mice in the control group, but none of the 33 mice in the energy-restricted group, had developed mammary tumors. Six tumor-free mice from each group were studied in detail at 67 wk of age. All six tumor-free control mice, but none of the six energy-restricted mice, showed uterine endometrial hyperplasia at autopsy. Mice subjected to energy restriction did not display an estrous cycle. The average levels of MMTV mRNA in mammary glands and uteri were strongly reduced by energy restriction. MMTV mRNA levels in mammary glands from control mice were two orders of magnitude lower than those in mammary tumors. Energy restriction lowered the percentage of pituitary mammatropes and suppressed proliferation of mammatropes with advancing age. Energy restriction thus appeared to inhibit endometrial hyperplasia and to decrease MMTV production at the mRNA level in the mammary glands and in the uterus. These effects may be a consequence of hormonal changes originating at the pituitary-ovarian axis.     

Dietary protein enhanced mammary ornithine decarboxylase activity and tumorigenesis in rats

Sprague-Dawley rats (F-1) were fed a normal protein (19% casein, NP) or high protein (33% casein, HP) isoenergetic diet containing 15% corn oil prior to conception. Female pups (F-2) were also fed the maternal diet after weaning. At 7 wk of age, before saline or N-nitrosomethylurea (NMU) treatment, ornithine decarboxylase (ODC, EC 4.1.1.17) activity in mammary epithelium and liver tissue was significantly higher in the HP group than in the NP group. Eight weeks after saline treatment ODC activity in mammary tissue decreased in both groups, but remained significantly higher in the HP group. NMU treatment caused a sixfold increase in ODC activity in the mammary tissue in the HP group and a significantly lower response in the NP group. Liver ODC activity had a minimal response to NMU treatment. Changing from the HP to the NP diet 4 wk after NMU treatment reduced mammary ODC induction response but not tumor burden; changing from the NP diet to HP diet produced no change in ODC activity or tumor burden. Mammary tumor burden was positively related to dietary protein and mammary epithelium ODC activity prior to and following NMU treatment.     

Effects of dietary protein and calcium levels on renal glucose-6-phosphatase activity of intact and thyroparathyroidectomized rats.

In order to determine the relationship of parathyroid hormone and levels of dietary protein and calcium with the activity of renal glucose-6-phosphatase (G6Pase), effects of two levels of dietary protein, namely, 25 and 75%, on the enzyme activity were compared at three levels of dietary calcium, namely, 0.06, 0.63, and 1.83%, with the use of intact and thyroparathyroidectomized (TPTX) rats. In intact rats, 0.06% dietary calcium caused an increase in renal G6Pase activity in rats fed the high carbohydrate diet, and dietary calcium in excess (1.83%) caused the enzyme activity to decrease. Similar responses in the activity of renal G6Pase to the variation of dietary calcium levels were seen in rats fed the high protein diet, but significant differences were not obtained. In TPTX rats fed the high carbohydrate diet, the activity of renal G6Pase was significantly decreased compared with that of intact rats. When TPTX rats were fed the high protein diet, however, no significant decrease in the enzyme activity was observed. Free access to aqueous 0.1% CaC1(2) solution by TPTX rats tended to restore the activity of renal G6Pase and serum calcium concentrations depressed by thyroparathyroidectomy. In addition, a significant correlation was observed between the total activity of renal G6Pase and serum calcium concentrations. Hypothyroidism produced by oral administration of propylthiouracil (0.05% of diets) did not affect the enzyme activity in the kidneys of rats fed the high carbohydrate and the high protein diets. The results suggest that the activity of renal G6Pase of rats fed the high protein diet might be less susceptible both to dietary calcium levels and to parathyroid function than that of rats fed the high carbohydrate diet.     

Energy restriction reduces fractional calcium absorption in mature obese and lean rats

Weight loss is associated with bone loss and the risk may be greater in lean than heavier individuals, but the mechanisms involved remain unclear. We hypothesized that energy restriction (EnR) would decrease true fractional Ca absorption (TFCA) and be mediated by Ca-regulating hormones, but differently in obese and lean rats. Rats were fed a high fat (47% energy) or low fat (16% energy) diet for 4 mo. At 6 mo of age, the resulting lean [284 +/- 28g (mean +/- SD, n = 18)] and obese (319 +/- 34g, n = 20) groups (P < 0.005) were divided into controls (CTL, ad libitum) and energy-restricted (40% restriction) groups. At baseline, bone resorption (urinary crosslinks) was higher and bone formation (serum osteocalcin) was lower in obese than in lean rats, whereas Ca balance components and Ca-regulating hormones did not differ. EnR for 10 wk reduced body weight by 25 +/- 7% compared with a 6 +/- 6% gain in CTL rats (P < 0.001). For both lean and obese rats, TFCA (5-d measurement, (45)Ca radioisotope) decreased from 30 +/- 9% to 24 +/- 9% with EnR, compared with 25 +/- 10% to 29 +/- 11% in controls (P < 0.05). Weight loss was directly correlated with the decrease in TFCA (r = 0.34, P < 0.05). Uterine weights indicated a reduced estrogenic activity in energy-restricted rats (P < 0.0001). In lean, but not obese rats, serum estradiol (E(2)) correlated with weight loss (r = 0.52, P < 0.05), and tended to correlate with the decrease in TFCA (r = 0.48, P = 0.06). At the end of the study, serum 25-hydroxyvitamin-D was lower and urinary Ca was higher in lean than obese energy-restricted rats. Distinct endocrine profiles during weight loss in obese and lean rats suggest that the susceptibility of bone and Ca metabolism to EnR could differ depending on initial body weight.     

Influence of total parenteral nutrition on tumor growth and polyamine biosynthesis of fibrosarcoma-bearing rats after induced cachexia

The effect of a protein-free diet (PF) or a restricted intake of chow (RI) and subsequent host repletion with total parenteral nutrition (PF-TPN, RI-TPN) on tumor growth and polyamine metabolism of fibrosarcoma-bearing rats was examined. Host weight was significantly reduced by PF and RI. Tumor growth was reduced in malnourished rats with the PF regimen resulting in the greatest decrease. Rats receiving TPN after 14 days of the RI or PF regimens had higher host weight and plasma albumin levels than malnourished rats. Tumor growth during TPN was evaluated as the percent increase and compared with that of the respective malnourished rats. The percent increase for RI-TPN rats was significantly greater although a trend toward an increase was also evident for PF-TPN rats. Tumor ornithine decarboxylase (ODC) activity and putrescine levels were increased for PF rats and decreased for RI rats while tumor ODC activity was consistently increased by TPN. Tumor growth, ODC activity, and putrescine levels were simultaneously increased only for those rats fed the RI regimen prior to TPN. These results show a disparity in tumor ODC activity, putrescine levels, and tumor growth in malnourished rats. The results of this study suggest that the nutritional origin of cachexia influences the response of the tumor to TPN and emphasizes the importance of considering the methods to induce malnutrition in designing therapuetic regimens.     

Effect of diet restriction on some key enzymes tryptophan-NAD pathway in rats.

Dietary intake of rats was restricted by feeding varying amounts of a 20% protein diet. After 6 weeks of feeding, some key enzymes of the tryptophan and nicotinic acid-NAD pathway, liver nicotinamide nucleotide concentration, and urinary metabolites of tryptophan and nicotinic acid were studied. With an increase in diet restriction, liver tryptophan oxygenase (EC 1.13.1.12) activity increased. Quinolinate phosphoribosyltransferase (EC 2.4.2.a) activity, on the other hand, was found to decrease with moderate diet restriction up to 50% restriction, but increased again with more severe diet restriction in rats fed 25% of ad libitum intake. Liver nicotinate phosphoribosyltransferase (EC 2.4.2.11) activity was also observed to decrease with moderate diet restriction and did not further change when the restriction was severe while picolinate carboxylase (EC 4.1.1.45) activity increased significantly only in severe diet restriction. In rats fed 25% of ad libitum intake, urinary quinolinic acid excretion was low whereas N'-methylnicotinamide excretion was elevated. Alterations in the enzyme activities accompanied by changes in the levels of urinary metabolites, observed in the present study, suggest that the potential efficiency of conversion of tryptophan to nicotinamide nucleotides is not constant and is influenced by dietary intake.     

Food restriction beneficially affects renal transport and cortical membrane lipid content in rats.

Food restriction (FR) exerts a variety of beneficial effects and may prolong life in both humans and animals. However, studies of its effects on the cortical brush border membrane (BBM) and basolateral membrane (BLM) lipid concentration, which may be pertinent to renal function, have not been reported in detail. We hypothesized that FR would decrease renal work and lower renal membrane lipid concentration. The changes in lipid concentration would be most dramatic in BBM because this membrane is the entry site for the recovery of filtered ions and nutrients. Young male Fischer 344 x Brown-Norway F1 rats consumed food ad libitum (AL) or were food-restricted (FR, 60% of AL consumption) for 6 wk. AL rats had higher fractional excretions of Na(+), K(+), and Cl(-) than did the FR group (P < 0.001). Renal Na,K-ATPase activity in AL rats was 100% higher than in FR rats (P < 0.001), reflecting greater renal work. The work required for renal proton secretion was lower in FR than in the AL rats. In FR rats, all BBM phospholipid concentrations (phosphatidylserine, phosphatidylcholine, phosphatidylethanolamine, and sphingomyelin) were approximately 50% lower than in the AL rats (P < 0.001). In the BLM, food restriction resulted only in lower phosphatidylcholine concentration, while the other phospholipids were unaffected. Plasma and renal membrane (BBM and BLM) cholesterol concentrations were significantly lower in FR than in AL rats. These results show that a nutritionally complete, but energy restricted, diet improves renal function. It also prevents renal membrane lipid deposition and decreases plasma cholesterol. Prolonged food restriction might attenuate the renal injury that occurs in obese humans as a consequence of insulin resistance and atherosclerosis.     

Role of putrescine in cell proliferation in a colon carcinoma cell line

OBJECTIVES: Putrescine, the precursor for higher polyamine biosynthesis, is necessary for cell growth in mammals. Ornithine decarboxylase (ODC) activity and polyamine production are increased in neoplastic cells. Using colon cancer cell line derived from a tumor with high metastatic potential (CT-26), our objective was to study the effect of exogenous putrescine on ODC regulation, polyamine metabolism, and cell proliferation. METHODS: Cells cultured with fetal calf serum were exposed to 100, 550, and 1000 microM putrescine for 24 h. RESULTS: Intracellular free putrescine, determined by high-performance liquid chromatography, showed a statistically significant increase in exposed cells compared with controls and a significant correlation with levels of the metabolite present in the medium (r = 0.93; P < 0.001). Bromodeoxyuridine incorporation into newly synthesized DNA, a marker of cell proliferation, showed a statistically significant increase in the three putrescine groups as opposed to the control group. In samples with added aminoguanidine, significant increases in DNA synthesis were observed in the 550- and 1000-microM putrescine groups as opposed to the control group. Spermidine and spermine intracellular contents in all three putrescine-treated groups remained below control levels. No statistical differences in ODC enzymatic activity or ODC mRNA content were observed. Newly incorporated putrescine stimulated colon tumor cell growth. CONCLUSIONS: Because neither enhanced conversion into the higher polyamines nor aminoguanidine inhibition of proliferation was observed, we suggest that this effect can be attributed to the putrescine molecule itself.     

Age-related alteration of vitamin D metabolism in response to low-phosphate diet in rats

The responses of renal vitamin D metabolism to its major stimuli alter with age. Previous studies showed that the increase in circulating 1,25-dihydroxyvitamin D (1,25(OH)2D3) as well as renal 25-hydroxyvitamin D3 1-alpha hydroxylase (1-OHase) activity in response to dietary Ca or P restriction reduced with age in rats. We hypothesized that the mechanism involved in increasing circulating 1,25(OH)2D3 in response to mineral deficiency alters with age. In the present study, we tested the hypothesis by studying the expression of genes involved in renal vitamin D metabolism (renal 1-OHase, 25-hydroxyvitamin D 24-hydroxylase (24-OHase) and vitamin D receptor (VDR)) in young (1-month-old) and adult (6-month-old) rats in response to low-phosphate diet (LPD). As expected, serum 1,25(OH)2D3 increased in both young and adult rats upon LPD treatment and the increase was much higher in younger rats. In young rats, LPD treatment decreased renal 24-OHase (days 1-7, P<0.01) and increased renal 1-OHase mRNA expression (days 1-5, P<0.01). LPD treatment failed to increase renal 1-OHase but did suppress 24-OHase mRNA expression (P<0.01) within 7 d of LPD treatment in adult rats. Renal expression of VDR mRNA decreased with age (P<0.001) and was suppressed by LPD treatment in both age groups (P<0.05). Feeding of adult rats with 10 d of LPD increased 1-OHase (P<0.05) and suppressed 24-OHase (P<0.001) as well as VDR (P<0.05) mRNA expression. These results indicate that the increase in serum 1,25(OH)2D3 level in adult rats during short-term LPD treatment is likely to be mediated by a decrease in metabolic clearance via the down-regulation of both renal 24-OHase and VDR expression. The induction of renal 1-OHase mRNA expression in adult rats requires longer duration of LPD treatment than in younger rats.     

Mitotic activity in mice is suppressed by energy restriction-induced torpor.

We monitored core body temperature by telemetry in energy-restricted (201 kJ/wk) and control (397 kJ/wk) C57BL/6 and SHN/C3H F1 mice to determine whether torpor may be involved in the suppression of mitotic activities resulting from energy restriction. The energy restriction regimen employed inhibited the development of cancer and greatly extended longevity in both these mouse strains. Male and female C57BL/6 mice subjected to energy restriction from 4 wk of age and tested at 3 mo of age became torporific (body temperature less than 31 degrees C) at ambient air temperatures of 20-22 degrees C, whereas control animals stayed euthermic (greater than 35 degrees C). Energy restriction also induced torpor in 3- and 13-mo-old SHN/C3H F1 female mice, whereas 3-, 13- and 24-mo-old control mice were euthermic. Energy restriction decreased mitotic activities to approximately 30% of control values in both jejunum and epidermis in 3-mo-old female C57BL/6 mice maintained at 20-22 degrees C. However, this suppression of mitotic activities was antagonized by housing the energy-restricted mice at 30 degrees C for 2 wk, indicating that torpor plays a substantial role in suppressing mitotic activities in energy-restricted mice.     

Dietary restriction of single essential amino acids reduces plasma insulin-like growth factor-I (IGF-I) but does not affect plasma IGF-binding protein-1 in rats

The effects of dietary restriction of a single essential amino acid (EAA) on insulin-like growth factor-I (IGF-I) and IGF-binding protein (IGFBP)-1 were investigated in rats. Rats were fed experimental diets containing amino acid (AA) mixtures in which the concentrations of all EAA were at levels recommended by the National Research Council (control), in which a single EAA was restricted to 20% of that of the control diets (Leu(-), Lys(-), Met(-) or Thr(-)), or in which the diet was devoid of amino acids (AA(-)). To eliminate the effect of differences in energy intake, rats were fed the mean amount of food as consumed by the AA(-) group on the previous day. Growth was significantly retarded in rats fed diets restricted in just one EAA compared with that of rats fed the control diet, and further growth retardation was observed in rats fed the AA(-) diet. On the other hand, the plasma IGF-I concentrations in the groups with a single EAA restriction or in the AA(-) group were 66% (P: < 0. 05) and 50% (P: < 0.05) of that of the control group, respectively. The effect of any single EAA restriction was not significantly different from that of total AA deprivation. The plasma IGFBP-1 concentration in the control group did not differ from that of rats fed diets with the single EAA restrictions except for methionine restriction, but it was approximately 6-fold greater in the AA(-) group. Differences in plasma IGFBP-1 concentration under these conditions could be explained by differences in hepatic IGFBP-1 mRNA contents. Based on these results, we conclude that restriction of single EAA does not affect IGFBP-1 synthesis in vivo, although the deprivation of a single EAA has been reported to increase IGFBP-1 production in hepatocyte cultures. Our results also indicated that a single EAA restriction decreased IGF-I production but did not affect IGFBP-1 production. The present study suggests that not only plasma IGF-I, but also IGFBP-1, affects the magnitude of growth retardation in vivo.     

Dietary carbamazepine administration decreases liver pyruvate carboxylase activity and biotinylation by decreasing protein and mRNA expression in rats

Clinical data demonstrate that certain antiepileptic drugs including carbamazepine (CBZ) decrease serum biotin concentration 45-50% and increase urine and serum organic acids, which is suggestive of reduced function of biotin-dependent enzymes. However, little is known about biotin-dependent enzyme function at the tissue level in patients undergoing long-term CBZ treatment. We recently established that dietary CBZ administration to rats increases brain lactate and also decreases specific enzymatic activity and the relative abundance of hepatic biotinylated pyruvate carboxylase (PC). To examine the mechanism of altered activity and abundance of biotinylated PC, the effect of orally administered CBZ on hepatic PC protein and mRNA expression was examined in rats consuming a physiologically relevant level of dietary biotin (0.06 mg/kg). Rats were fed 0 or 3.4 g CBZ/kg diet for 28 d, a dose designed to achieve clinically relevant serum CBZ concentrations. Hepatic biotinylated PC and PC activity were significantly reduced by approximately 43 and 30%, respectively, in the drug-treated group. Liver PC protein expression and mRNA were approximately 43 and 35% lower, respectively, in the drug-treated group than in controls. Brain biotinylated PC was significantly lower (29%), whereas specific enzymatic activity was 175% higher in rats consuming the 3.4 g CBZ/kg diet. Brain, but not serum, lactate was significantly higher in rats consuming CBZ. Taken together, the lower PC protein and mRNA expression provide a plausible biochemical mechanism to explain the decreased abundance of biotinylated hepatic PC observed in previous studies.     

Impact of energy and casein or whey protein intake on bone status in a rat model of age-related bone loss

In the elderly, nutritional deficiencies, such as low energy and protein intake, are suggested to increase the risk of osteoporotic fractures. Modulation of the amount and quality of protein intake under energy deficient conditions represents an interesting strategy to prevent aged-related bone loss. We investigated the effect of a 5-month dietary restriction on bone status in 16-month-old male rats. Rats were randomised into six groups (n 10 per group). Control animals were fed a normal diet containing either casein (N-C) or whey protein (N-WP). The other groups received a 40 % protein and energy-restricted diet with casein or whey protein (PER-C and PER-WP) or a normal protein and energy-restricted diet (ER-C and ER-WP). Both restrictions (PER and ER) induced a decrease in femoral bone mineral density (BMD), consistent with impaired biomechanical properties and a reduced cortical area at the diaphysis. Plasma osteocalcin and urinary deoxypyridinoline levels suggested a decrease in bone turnover in the PER and ER groups. Interestingly, circulating insulin-like growth factor 1 (IGF-1) levels were also lowered. Overall, normal protein intake did not elicit any bone sparing effect in energy-deficient rats. Regarding protein quality, neither casein nor WP appeared to significantly prevent the BMD decrease. This study confirms that nutritional deficiencies may contribute to osteopenia through decreased IGF-1 levels. Moreover, it seems that impaired bone status could not be significantly prevented by modulating the amount and quality of dietary proteins.     

Effects of trans-10,cis-12 CLA on liver size and fatty acid oxidation under energy restriction conditions in hamsters

Objective

Little evidence exists concerning the effects of trans-10,cis-12 conjugated linoleic acid (CLA) under energy restriction. Thus, the effects of this CLA isomer on adipose tissue size, liver composition, as well as on expression and activity of carnitine-palmitoyl transferase I (CPT-I) and acyl CoA oxidase (ACO), in hamsters fed an energy-restricted diet were analyzed.

Methods

Hamsters were fed a high-fat diet for 7 wk and then subjected to 25% energy-restricted diets supplemented with 0.5% linoleic acid or 0.5% trans-10,cis-12 CLA for 3 wk. Serum insulin, free-triiodothyronine and non-esterified fatty acid levels, liver triacylglycerol, protein and water contents, and CPT-I, ACO, and Peroxisome proliferator-activated receptor alpha (PPARα) expressions and enzyme activities were assessed.

Results

Energy restriction reduced liver size, serum levels of insulin, free-triiodothyronine, and non-esterified fatty acid and increased CPT-I activity. Liver composition was not modified. No differences were found between both restricted groups, with the exception of CPT-I and ACO oxidative enzyme activities, which were greater in hamsters fed the CLA diet.

Conclusions

Energy restriction does not cause trans-10,cis-12 CLA to induce liver hyperplasia. Although this CLA isomer increases liver CPT-I and ACO activities, this effect does not result in reduced hepatic triacylglyerol content or decreased adipose tissue size. Consequently, this CLA isomer seems not to be a useful tool for inclusion in body weight loss strategies followed during obesity treatment.