Failure to demonstrate an effect of dietary fatty acid composition on body weight, body composition and parameters of lipid metabolism in mature rats

The objectives of the present study were to examine the effects of dietary fatty acid composition on body composition and on several parameters of lipid metabolism in adipose tissue and to assess the ease of weight loss with restricted dietary intake. Rats were fed diets containing 14% fish oil, safflower oil or beef fat plus 2% corn oil. These diets were fed ad libitum for 4 wk (first phase). A number of the animals from each group were killed, and the others were fed 50% of their first-phase food intake for an additional 4 wk (second phase). The diets used in the second phase contained 3% of the above fats plus 2% corn oil. Food consumption, food efficiency and body weights were monitored. After the rats were killed, fatty acid composition of epididymal fat pads was examined. In addition, in vivo lipolysis and in vitro lipogenesis in epididymal fat pads were examined. The results indicate that dietary fatty acid composition had no effect on body weight, food consumption, in vivo lipolysis and in vitro lipogenesis in epididymal fat pads. In addition, although dietary fatty acid manipulation resulted in alteration in adipose tissue fatty acid composition, it had no effect on the rate of weight loss, body composition, in vivo lipolysis and in vitro lipogenesis in epididymal fat pads. It is concluded that dietary fatty acid composition does not play a role in body composition and in lipid metabolism in adipose tissue of mature rats.     

Potency of polyunsaturated and saturated fats as short-term inhibitors of hepatic lipogenesis in rats

Three dietary studies using male Sprague-Dawley rats conditioned to meal-eat a high glucose, fat-free diet and one in vitro study with isolated rat hepatocytes were designed to examine the hypothesis that polyunsaturated fats (i.e., safflower oil or linoleate) are more potent acute inhibitors of liver fatty acid synthesis than are saturated fats (i.e., beef tallow or palmitate). Fat in the first in vivo study was administered via intubation (1500 mg/rat) whereas in the second and third in vivo studies fat was added to the meal in amounts of 50, 100, 250 or 500 mg/g fat-free diet. When the rats were in a postprandial condition, significant suppression of hepatic lipogenesis required the meal to contain 38% of its energy as fat (i.e., 250 mg/g fat-free diet). At this level of fat, safflower oil was more inhibitory than beef tallow (p less than 0.05). The inhibition constant (Ki) for palmitate inhibition of fatty acid synthesis by isolated hepatocytes was fourfold greater than linoleate's Ki (fatty acid/albumin ratio of 1.4/1). When fat constituted 50% of the ingested energy, beef tallow was equivalent to safflower oil as an inhibitor of lipogenesis. Although a single meal containing 50 mg safflower oil/g fat-free diet did not decrease fatty acid synthesis, it effectively delayed the induction of lipogenesis during the first 30 min of the adaptive decrease in lipogenic enzymes attributed to polyunsaturated fats extends to short-term regulatory mechanisms.     

Hepatic cholesterol and fatty acid synthesis in pregnant and fetal rats: effect of maternal dietary fat and cholestyramine.

Previous studies from this laboratory have demonstrated that 20% rather than 5% (wt/wt) safflower oil or addition of 5% (wt/wt) cholestyramine to the diet of pregnant rats leads to an increase in the activity of 3-hydroxy-3-methylglutaryl CoA reductase, the rate-limiting enzyme of cholesterol synthesis, in the fetal liver. Total cholesterol, however, was not altered in fetal plasma or liver. The effect of these diets on cholesterol and fatty acid synthesis in vivo was therefore studied in fetal and maternal liver. In fetuses of rats fed a reference nonpurified diet, rates of hepatic cholesterol and fatty acid synthesis decreased from gestation d 20 to 21. In contrast, total and active 3-hydroxy-3-methyl-glutaryl CoA reductase activity increased. Adding cholestyramine to the diet or modifying the quantity of safflower oil fed had no effect on fetal hepatic lipogenesis. Maternal hepatic cholesterol synthesis was greater in rats fed cholestyramine, whereas fatty acid synthesis was lower in the dams fed the diet containing 20% compared with 5% safflower oil. The results suggest near-term fetal liver 3-hydroxy-3-methylglutaryl CoA reductase activities do not reflect fetal cholesterol synthesis in vivo.     

Effect of dietary levels of corn oil on maternal arachidonic acid synthesis and fatty acid composition in lactating rats

OBJECTIVE: We examined the effect of different amounts of dietary corn oil rich in linoleic acid (LA) on the endogenous synthesis of arachidonic acid (AA), uptake of its precursor LA, and fatty acid composition of tissues involved in the supply of long-chain polyunsaturated fatty acids for milk synthesis. METHODS: Female Sprague Dawley rats received one of the following diets during pregnancy and lactation: a low-lipid diet (LLD; 2%), an adequate-lipid diet (ALD; 5%), or a high-lipid diet (HLD; 10%). Lipids were provided by corn oil. On day 12 of lactation we measured the endogenous synthesis of AA and quantified the conversion of (13)C-LA to (13)C-AA and the metabolic fate of (13)C-LA from all dietary groups. RESULTS: The LLD rats demonstrated larger amounts of endogenous synthesis of (13)C-AA and more dietary (13)C-LA transferred to the mammary gland (MG) than HLD rats during lactation. The proportion of medium-chain fatty acids was higher in the MG, milk clot, and liver of LLD than of HLD rats. Daily volume and 24-h yield of lipids and energy were lower in LLD rats than in HLD rats. Measurements of milk composition demonstrated that fat concentration significantly increased as lipid concentration increased in the diet. CONCLUSION: These results suggest that maternal adaptations used to compensate for diets deficient in long-chain polyunsaturated fatty acids include increased endogenous synthesis of AA and elevated uptake of LA in the MG and increased synthesis of medium-chain polyunsaturated fatty acids. It appears that the MG and liver participate together for AA synthesis for milk when this fatty acid is not provided in the diet.     

Dietary n-3 fatty acids affect mRNA level of brown adipose tissue uncoupling protein 1, and white adipose tissue leptin and glucose transporter 4 in the rat

We examined the effect of dietary fats rich in n-3 polyunsaturated fatty acids (PUFA) on mRNA levels in white and brown adipose tissues in rats. Four groups of rats were fed on a low-fat diet (20 g safflower oil/kg) or a high-fat diet (200 g/kg) containing safflower oil, which is rich in n-6 PUFA (linoleic acid), or perilla (alpha-linolenic acid) or fish oil (eicosapentaenoic and docosahexaenoic acids), both of which are rich in n-3 PUFA, for 21 d. Energy intake was higher in rats fed on a high-safflower-oil diet than in those fed on low-fat or high-fish-oil diet, but no other significant differences were detected among the groups. Perirenal white adipose tissue weight was higher and epididymal white adipose tissue weight tended to be higher in rats fed on a high-safflower-oil diet than in those fed on a low-fat diet. However, high-fat diets rich in n-3 PUFA, compared to a low-fat diet, did not increase the white adipose tissue mass. High-fat diets relative to a low-fat diet increased brown adipose tissue uncoupling protein 1 mRNA level. The increases were greater with fats rich in n-3 PUFA than with n-6 PUFA. A high-safflower-oil diet, compared to a low-fat diet, doubled the leptin mRNA level in white adipose tissue. However, high-fat diets rich in n-3 PUFA failed to increase it. Compared to a low-fat diet, high-fat diets down-regulated the glucose transporter 4 mRNA level in white adipose tissue. However, the decreases were attenuated with high-fat diets rich in n-3 PUFA. It is suggested that the alterations in gene expression in adipose tissue contribute to the physiological activities of n-3 PUFA in preventing body fat accumulation and in regulating glucose metabolism in rats.     

Fatty acids and retinyl esters of rat milk: effects of diet and duration of lactation

This study was initiated to explore the quantitative and qualitative differences in milk total fatty acids and milk retinyl esters when either hydrogenated or nonhydrogenated fat is fed during pregnancy and lactation. Rats were fed diets containing 10% by weight of corn oil or partially hydrogenated corn oil. Milk was collected on d 1, 8 and 14 of lactation and analyzed for protein, total fatty acids, fatty acid pattern, and retinyl ester pattern. Whereas diet produced no quantitative differences in milk protein or total fatty acids, the pattern of milk fatty acids varied significantly. Rats fed corn oil produced milk having more medium-chain saturated fatty acids, less long-chain monoenoic fatty acids, and more polyunsaturated fatty acids compared to those fed hydrogenated corn oil. Rats fed hydrogenated corn oil produced milk fat having 21-26% of the trans fatty acid, elaidic acid. Significant differences were also observed with duration of lactation: medium-chain fatty acids increased three to fourfold between d 1 and 8, where cis-monoenes and polyunsaturated fatty acids declined. The pattern of milk retinyl esters strongly reflected, but was not identical to, that of total milk fat. Comparing d 14 milk from rats fed corn oil with that from rats fed hydrogenated corn oil, medium-chain esters of retinol constituted 24 and 11% of total retinyl esters, whereas saturated long-chain fatty acid esters constituted 52 and 44%, respectively. trans Fatty acid esters of retinol comprised 24% of vitamin A esters in milk of rats fed hydrogenated fat. These data provide evidence that the composition of milk retinyl esters, as well as that of total milk fat, is determined both by the type of fatty acids from diet and from diet-related differences in de novo synthesis of fatty acids within the mammary gland and other tissues.     

Effects of repeated gestation and lactation on milk n-6 fatty acid composition in rats fed on a diet rich in 18:2n-6 or 18:3n-6.

The present study examined the effect of repeated gestation and lactation on the levels of long-chain n-6 polyunsaturated fatty acids in rat milk fat, and examined whether such levels might be modulated by supplementing the diet of the lactating dams with either (g/kg) 50 safflower oil (SFO; containing 800 g 18:2n-6/kg), or 50 evening primrose oil (EPO; containing 720 g 18:2n-6 and 90 g 18:3n-6/kg). The milk was collected at three different times (days 1, 8 and 15) in each given lactation period from female Sprague-Dawley rats which were successively bred for four pregnancies and lactations. Results showed that dietary fat and breeding frequency had no significant effects on milk triacylglycerol content, but they modified the pattern of milk fatty acids in both triacylglycerol and phospholipid fractions. After three or four successive breedings rats fed on EPO produced milk containing less saturated but more monounsaturated and polyunsaturated fatty acids compared with those fed on SFO. During the course of lactation the levels of n-6 metabolites, e.g. 18:3n-6, 20:3n-6 and 20:4n-6, in milk fat declined progressively. However, they were consistently higher in the EPO group than in the SFO group. These findings suggest that the levels of long-chain n-6 metabolites in the milk fat may be increased through supplementing the maternal diet with 18:3n-6.     

Body fat accumulation is greater in rats fed a beef tallow diet than in rats fed a safflower or soybean oil diet

The effects of dietary fats , consisting of different fatty acids, on body fat accumulation and uncoupling protein (UCP) in interscapular brown adipose tissue were studied in rats. Metabolisable energy in experimental diets based on safflower oil, soybean oil or beef tallow was measured strictly (experiment 1). Male Wistar rats were then meal-fed an isoenergetic diet for 8 weeks (experiment 2). Each group of rats showed the same weight gain during the 8-week experimental period. Carcass fat content was greater in rats fed the beef tallow diet than in those fed the with the safflower or soybean oil diets, whereas the weight of abdominal adipose tissue was the same for all three dietary groups. Gene expression of UCP1 and the UCP content of the interscapular brown adipose tissue was lower in the beef tallow diet group than in the other dietary groups. A negative correlation was observed between carcass fat content and n-6 unsaturated fatty acid content in dietary fats. These results suggest that the greater body fat accumulation in rats fed the beef tallow diet results from lower expression of UCP1 mRNA and lower UCP content in brown adipose tissue. n-6 Polyunsaturated fatty acids may be the most effective fatty acids in limiting body fat.     

Effect of dietary protein and food restriction on milk production and composition, maternal tissues and enzymes in lactating rats

Lactating rats have been fed either a protein-restricted diet (10 vs. 20% casein in the control diet) or the control diet at 80, 60 and 40% of the voluntary intake for 7 d from d 7 of lactation. Food consumption, changes in maternal live weight, litter live weight gain and the mass of several maternal tissues were determined together with the activity of several mammary and liver enzymes, including 10 that are essential for fatty acid and complex lipid synthesis. Milk production was estimated from the litter weight gain and litter weight. Lactating rats fed the 20% protein diet ad libitum consumed three times that of nonlactating rats; their liver and kidney masses were significantly higher and their adipose mass was lower. The livers of the lactating rats were fatty, containing 118 mg lipid/g compared with 42 mg/g for the nonlactating rats. Lactating rats fed either the protein-restricted diet or the control diet at 40 and 60% of the ad libitum intake of the control diet had lower mammary, liver and kidney masses than rats consuming the control diet ad libitum. Both protein and food restriction led to lower rates of milk production than those of ad libitum-fed control rats as evidenced by the decrease in litter live weight gains. The concentrations of total lipid, total protein and lactose in milk were not affected by these dietary treatments. The concentration of alpha-lactalbumin in milk of rats fed the low protein diet was, however, lower than that in the milk of all rats receiving the control diet, irrespective of intake. Consumption of the restricted diets resulted in only small changes in specific activities (mu/mg protein) of 15 mammary enzymes. In the livers, lactation led to higher specific activities of all four soluble lipogenic enzymes examined but did not affect the particulate enzymes involved in complex lipid synthesis. The dietary restrictions resulted in lower specific activities of the soluble enzymes compared with those of the lactating rats consuming the control diet ad libitum without affecting the particulate enzymes. Total activities of these enzymes were, however, lower than those for the control rats as a result of the smaller liver mass in the rats receiving the restricted diets.     

Dietary conjugated linoleic acids lower the triacylglycerol concentration in the milk of lactating rats and impair the growth and increase the mortality of their suckling pups

Recent studies showed that conjugated linoleic acids (CLA) lower triacylglycerol concentrations in the milk of lactating animals. This study was performed to determine the reasons for this phenomenon; we also investigated whether there is a relation between altered lipid metabolism in the liver and the reduction in milk triacylglycerols in rats fed CLA. Two groups of female rats were fed diets containing 0 [sunflower oil (SFO) group] or 14.7 g/kg diet of a CLA mixture (CLA group) at the expense of sunflower oil during growth, pregnancy, and lactation. CLA-fed rats had 49 and 80% lower mRNA concentration and activity of fatty acid synthase, respectively, a 51% lower mRNA concentration of lipoprotein lipase (LPL) in their mammary glands at d 17 of lactation, and a 46% lower milk fat content than SFO rats (P < 0.05). Although CLA rats had lower concentrations of triacylglycerols in the liver than SFO rats (20.8 +/- 2.6 vs. 62.6 +/- 27.7 micromol/g, P < 0.05), concentrations of triglycerides in plasma, which are the substrates of LPL, did not differ between the groups. Moreover, the number of pups per litter, litter weights, and pup weights at d 17 of lactation were 41, 35, and 22% lower, respectively, in the CLA group than in the SFO group. In conclusion, the present study suggests that dietary CLA reduces triacylglycerol concentrations in the milk via reduced de novo fatty acid synthesis in the mammary gland and an impaired uptake of fatty acids from lipoproteins into the mammary gland. This might be the reason for reduced growth rates and an increased mortality of suckling pups.     

A thermally oxidized dietary oil does not lower the activities of lipogenic enzymes in mammary glands of lactating rats but reduces the milk triglyceride concentration

It was shown that dietary thermoxidized oils suppress gene expression of lipogenic enzymes in the liver. This study was performed to investigate whether oxidized oils also influence the activities of lipogenic enzymes in the mammary gland of lactating rats. Female rats (n = 24) were divided into two groups at 4 wk of age. They were fed for 14 wk diets with either fresh oil (a mixture of sunflower oil, linseed oil, and palm oil, 73:15:12) or oxidized oil (a mixture of sunflower oil and linseed oil, 80:20) prepared by heating at a temperature of 50 degrees C for 16 d. At the age of 12 wk, the rats were mated. At birth, litters were adjusted to 7 pups/dam. Milk was sampled at d 14 of lactation; mammary glands were taken at d 19 of lactation. Rats fed the oxidized oil had a lower activity of glucose-6-phosphate dehydrogenase (G6PDH) in their mammary glands than those fed the fresh oil (P < 0.05); the activities of fatty acid synthase (FAS) and acetyl-CoA-carboxylase in mammary glands did not differ. Relative mRNA concentrations of G6PDH, FAS, and sterol-regulatory element binding protein-1, a regulator of lipogenesis, in the mammary gland did not differ between groups. The concentrations in the milk of medium-chain fatty acids (C8-C14), the major products of fatty acid synthesis in mammary glands, also did not differ. The concentrations of triglycerides and long-chain fatty acids (C18-C22), however, were lower in the milk of rats fed the oxidized oil than in the milk of rats fed the fresh oil (P < 0.05). In conclusion, this study shows that feeding oxidized oils to lactating rats does not affect lipogenic enzymes in mammary glands but reduces the triglyceride concentrations in their milk.     

Resistance of lung fatty acid synthesis to inhibition by dietary fat in the meal-fed rat

One-half of the palmitate utilized by the lung for production of the surfactant phospholipid, dipalmitoyl phosphatidylcholine, originates from de novo palmitate synthesis in the lung. In this report the lung was examined for the influence of dietary fat on the lung de novo fatty acid synthesis pathway. Lung lipogenesis was reduced by fasting and accelerated by carbohydrate refeeding or insulin injection. However, in general lung fatty acid synthesis was unaffected by dietary fat. Supplementing one meal (high glucose diet) with as much as 36% additional fat kilocalories did not suppress lung fatty acid synthesis. An inhibition of fatty acid synthesis resulted from a fat supplement of +60 and +120% of meal kilocalories, but this inhibition was likely due to an attenuated rate of glucose absorption. Ingestion of a high carbohydrate diet supplemented with 10, 17, or 30% added kilocalories as safflower oil or palmitate had no effect on lipogenesis after 10 days. On the other hand, liver fatty acid synthesis and acetyl-CoA carboxylase were selectively suppressed by safflower oil, whereas dietary palmitate was ineffective as an inhibitor of lipogenesis. These data clearly demonstrate that the well-characterized preferential suppression of liver lipogenesis by dietary polyunsaturated fats does not extend to lung tissue, and, more importantly, the inhibition of liver lipogenesis is not secondary to an essential fatty acid deficiency. The marked resistance of lung fatty acid synthesis to inhibition by dietary fat might be a biological protective mechanism to ensure adequate palmitate for dipalmitoyl phosphatidylcholine synthesis.     

Comparison among the lipogenic potential of various substrates in rat hepatocytes: the differential effects of fructose-containing diets on hepatic lipogenesis

Fructose feeding has been reported to cause hypertriglyceridemia in rats. Apparently this is due to increased hepatic fatty acid synthesis. In hepatocytes from female rats fed a 60% sucrose or fructose diet, the rate of lipogenesis was two times higher than in cells from rats fed a 60% glucose diet and three times higher than in cells from rats fed a commercial nonpurified diet. In hepatocytes from rats fed the fructose-containing diets, lactate was a better substrate than either butyrate or acetate, whereas in cells from rats fed either the glucose diet or the non-purified diet, butyrate was the best lipogenic substrate, and the lipogenic potential of lactate and acetate was similar. In all cases, 1 mM fructose caused a 30-40% stimulation of lipogenesis, while 10 mM glucose did not enhance fat synthesis above the endogenous rates. These results suggest that the differential effect of fructose-containing diets on hepatic lipogenesis results from activation of pyruvate dehydrogenase, thereby increasing the efficiency by which lactate is used as a carbon source for fatty acid synthesis. The differences in lipogenic potential of the various substrates tested is discussed.     

Enrichment of (n-3) fatty acids of suckling rats by maternal dietary menhaden oil

The study was undertaken to determine whether the content of eicosapentaenoic acid (EPA) and docosahexaenoic acid (DHA) in neonatal rats can be increased through milk provided by lactating mothers fed a diet containing 20% menhaden oil (experimental group), in comparison with a group fed a 20% corn oil diet (control group). The test diets were isocaloric and provided 41% of total energy as fat. Coinciding with 3-9% higher maternal body weight gain throughout the lactation period with the menhaden oil diet, the suckling rats in the experimental group at the ages of 3-9 d gained 5-10% more weight than did their control counterparts. When compared with corn oil, maternal dietary menhaden oil induced not only a higher weight percentage but also higher concentrations (microgram/mL) of EPA, DHA and total (n-3) fatty acids in milk, plasma, platelets and erythrocytes of neonates. These changes were accompanied by lower arachidonic and linoleic acid levels. EPA and DHA were detected in all three blood components of the control group, whose corn oil diet contained linolenic acid but not longer chain (n-3) fatty acids. This finding, together with the higher DHA to EPA ratios found in the three blood components than in the milk of the experimental group, suggests that neonatal rats possess the enzymes necessary for producing DHA from EPA and linolenate by desaturation and elongation mechanisms.     

Dietary fat and cecal microbial activity in the rat

Weanling rats were fed low-fat (1% w/w safflower oil) or high-fat (1% w/w safflower oil plus 35% w/w beef fat or cocoa butter) diets for 30 days, and the activities of five cecal microbial enzymes were determined. When compared with the low-fat diet, beef fat significantly increased total cecal beta-glucuronidase activity, but cocoa butter, with a similar fatty acid composition, did not. Both high-fat diets significantly decreased total cecal azoreductase, beta-glucosidase, and nitrate reductase activities, but neither significantly affected urease activity. When expressed as specific activities (per 10(11) bacteria), cocoa butter decreased azoreductase, and beef fat caused increases of beta-glucuronidase and urease. Beef fat, but not cocoa butter, significantly reduced cecal bacterial numbers when compared to the low-fat diet. Both high-fat diets led to equivalent reductions in the proportion of aerobic bacteria.     

Serum leptin and insulin levels in lactating protein-restricted rats: implications for energy balance

The present study analysed the effect of protein restriction on serum insulin and leptin levels and their relationship with energy balance during lactation. Four groups of rats received isocaloric diets containing 170 g protein/kg or 60 g protein/kg from pregnancy until the 14th day of lactation: control non-lactating, control lactating (both fed a control diet), low-protein non-lactating and low-protein lactating. Energy intake, body composition, energy balance, serum insulin and leptin concentrations and the relationship between these hormones and several factors related to obesity were analysed. Low-protein-intake lactating rats exhibited hypoinsulinaemia, hyperleptinaemia, hypophagia and decreased energy expenditure compared with control lactating rats. The protein level in the carcasses was lower in the low-protein lactating group than in the control lactating group, resulting in a higher fat content in the first group compared with the latter. Body fat correlated inversely with serum insulin and positively with serum leptin level. There was a significant negative correlation between serum leptin and energy intake, and a positive relationship between energy intake and serum insulin level in lactating rats and in the combined data from both groups. Energy expenditure was correlated positively with serum insulin and negatively with serum leptin in lactating rats and when data from control non-lactating and lactating rats were pooled. Lactating rats submitted to protein restriction, compared with lactating control rats, showed that maternal reserves were preserved owing to less severe negative energy balance. This metabolic adaptation was obtained, at least in part, by hypoinsulinaemia that resulted in increased insulin sensitivity favouring enhanced fat deposition, hyperleptinaemia and hypophagia.     

Metabolic fate of chylomicrons obtained from rats maintained on diets varying in fatty acid composition

The importance of the fatty acid component in the metabolism of chylomicrons was demonstrated by feeding diets varying in fatty acid composition which resulted in chylomicrons of different sizes. On a diet rich in polyunsaturated fatty acids (PUFA) from safflower oil, chylomicrons of diameter 1853 +/- 192 A were harvested from the mesenteric lymph, whereas on coconut oil and medium-chain triglyceride diets the chylomicron size was 1403 +/- 83 and 604 +/- 40 A, respectively. When the isolated chylomicrons were injected into recipient rats maintained on a regular diet, their half-life (t1/2) decreased from 5.4 +/- 0.4 to 1.8 +/- 0.3 min with the increase in particle size. No significant difference in the apolipoprotein profile of chylomicrons of various sizes was noted, indicating that alterations of chylomicron removal are not related to apolipoprotein composition. Rats maintained on PUFA diets showed a marked increase in their adipose tissue lipoprotein lipase activity. The fast removal of large chylomicrons and increased tissue lipoprotein lipase activity, together with suppression of hepatic lipogenesis on this diet, apparently explains the low plasma triglyceride level in rats maintained on diets rich in PUFAs.     

Influence of dietary conjugated linoleic Acid and fat source on body fat and apoptosis in mice

OBJECTIVE: To determine whether altered dietary essential fatty acid (linoleic and arachidonic acid) concentrations alter sensitivity to conjugated linoleic acid (CLA)-induced body fat loss or DNA fragmentation. RESEARCH METHODS AND PROCEDURES: Mice were fed diets containing soy oil (control), coconut oil [essential fatty acid deficient (EFAD)], or fish oil (FO) for 42 days, and then diets were supplemented with a mixture of CLA isomers (0.5% of the diet) for 14 days. Body fat index, fat pad and liver weights, DNA fragmentation in adipose tissue, and fatty acid profiles of adipose tissue were determined. RESULTS: The EFAD diet decreased (p < 0.05) linoleic and arachidonic acid in mouse adipose tissue but did not affect body fat. Dietary CLA caused a reduction (p < 0.05) in body fat. Mice fed the EFAD diet and then supplemented with CLA exhibited a greater reduction (p < 0.001) in body fat (20.21% vs. 6.94% in EFAD and EFAD + CLA-fed mice, respectively) compared with mice fed soy oil. Dietary FO decreased linoleic acid and increased arachidonic acid in mouse adipose tissue. Mice fed FO or CLA were leaner (p < 0.05) than control mice. FO + CLA-fed mice did not differ in body fat compared with FO-fed mice. Adipose tissue apoptosis was increased (p < 0.001) in CLA-supplemented mice and was not affected by fat source. DISCUSSION: Reductions in linoleic acid concentration made mice more sensitive to CLA-induced body fat loss only when arachidonic acid concentrations were also reduced. Dietary essential fatty acids did not affect CLA-induced DNA fragmentation.     

Effects of dietary protein, fat and restriction on body composition and energy balance in lactating rats

Isoenergetic diets formulated at three levels of dietary protein using 12,24 and 40% casein and at two levels of fat using 2.26 and 13.82% corn oil were fed at five levels of intake, ad libitum, 75, 62.5, 50 and 37.5% of average ad libitum intake, to 90 lactating rats from d 7 to 14 of lactation. Regression equations developed from lactating rats killed on d 7 of lactation were used to calculate initial body composition and energy of rats killed on d 14 of lactation. Changes in body weight and body water were significantly (P less than 0.05) affected by dietary fat and protein, but change in dry lean body mass was affected only by level of dietary fat, whereas body nitrogen and fat and lean body energy were not affected by level of dietary fat or protein. However, restricted intake significantly increased loss of all these. Likewise, restricted intake decreased milk production. Changes in weights of heart and liver were not affected by diet or intake, whereas intestinal weight decreased with intake restriction. Liver enzyme activities were markedly affected by intake restriction, whereas responses to dietary protein and fat were marginal.     

Dietary calcium phosphate promotes Listeria monocytogenes colonization and translocation in rats fed diets containing corn oil but not milk fat

Most Gram-positive bacteria are susceptible to the bactericidal action of fatty acids and bile acids. Because dietary calcium phosphate (CaP(i)) lowers the intestinal concentration of these antimicrobial agents, high CaP(i) intake may enhance intestinal colonization of Gram-positive pathogens and the subsequent pathogenesis. In this study, we tested this hypothesis in a rat model using Listeria monocytogenes. Rats were fed diets containing low (20 micromol/g diet) or high (160 micromol/g diet) amounts of CaP(i). Dietary fat was provided as corn oil or milk fat. Rats were orally inoculated with L. monocytogenes. When rats consumed diets containing corn oil, high CaP(i) intake indeed stimulated colonization of L. monocytogenes and increased L. monocytogenes translocation and diarrhea. In addition, supplemental CaP(i) enhanced ex vivo growth of L. monocytogenes in fecal extracts of rats fed corn oil diets, suggesting that high CaP(i) intake decreased a luminal inhibitory factor. The concentrations of bile salts and fatty acids, which were highly listericidal in vitro, were indeed considerably decreased in fecal water of rats in the high calcium corn oil group. Surprisingly, dietary CaP(i) did not affect colonization and translocation of L. monocytogenes in rats fed the milk fat diet, nor did CaP(i) enhance ex vivo growth in fecal extracts. This absence of Listeria stimulation was associated with a lack of effect of dietary CaP(i) on fecal soluble fatty acids. In addition, residual soluble bile salts were higher in rats fed the high CaP(i) milk fat diet compared with the high CaP(i) corn oil diet. These results suggest that the stimulating effect of CaP(i) on L. monocytogenes infection depends on the type of dietary fat consumed.