Marginal protein deficiency in pregnant rats. Changes in offspring body composition

The influence of protein on some biochemical parameters in the liver, brain and plasma of rats at weaning was studied. The tissue parameters studied were the amounts of DNA, RNA and protein in the liver and brain. For the plasma, the parameters studied were the total amount of protein and the ratio of non-essential to essential amino acids (ratio NE/E). During the gestation and lactation period, the rats were divided into three groups according to the diet received: group 1, 20% casein; group 2, 8% casein; and group 3, 8% corn. As a result we can assert that groups 2 and 3, fed on hypoprotein diets, were seriously compromised in body weight and in the biochemical parameters and these alteration were enhanced by the corn diet. These results suggest that the alterations depend on the duration and intensity of the malnourishment and that the quality of the protein is an important factor to be considered.     

Altered methionine metabolism in streptozotocin-diabetic rats

Summary We examined the origin of hypermethioninaemia in streptozotocin-diabetic rats. In rats administered streptozotocin over a range from 55 to 75 mg/kg, the dose of drug injected correlated directly with the plasma methionine concentration and inversely with the plasma insulin level. Although insulin administration prevented hypermethioninaemia in streptozotocin-diabetic rats, discontinuing insulin treatment resulted in a time-dependent increase in the plasma methionine level. Plasma methionine concentration was, however, normal in insulin-deprived BB Wistar rats despite severe hyperglycaemia. Thus, although insulin deficiency may be a contributing factor, it does not cause hypermethioninaemia independent of other drug-related effects. Administering a loading dose of methionine (100 mg/kg) indicated that streptozotocin-diabetic rats have a reduced metabolic capacity. Since dietary intake is the primary source of methionine, it is likely that hyperphagia combined with limited disposal produces hypermethioninaemia. Methionine is the most toxic amino-acid; therefore, metabolic studies using the streptozotocin model of insulin deficiency must be interpreted with caution.     

Voluntary and forced exercise influence the survival and body composition of ageing male rats differently

The importance of maintaining physical fitness by engaging in exercise in a life-long perspective as well as the avoidance of obesity has been emphasised in recent years by epidemiological studies on human populations as well as studies on laboratory rodents. In laboratory studies, voluntary running in wheels and forced training in a treadmill have been used with beneficial results. Restriction of the food intake of sedentary laboratory rodents can be regarded either as life prolongation or prevention of life shortening by obesity. We compared the effects of these interventions on male Sprague–Dawley rats from the age of 5 to 23 months in the following groups: (1) RW=voluntary running in wheels; (2) PW=fed to pair weight with RW animals; (3) TM=forced training in a treadmill; and (4) S1=sedentary with ad libitum access to food. Each group consisted of 32 animals, all housed individually in cages. Two RW animals died, five died in each of the PW and S1 groups and 10 in the TM group (p<0.05). The S1 and TM groups gained most weight, the TM less after the age of 21 months (p<0.05). The body weights of the RW group was lower than those of the S1 and TM groups all the time (p<0.001) and the difference increased all the time. Body composition was analysed by bioelectrical impedance analysis. There were no differences in fat free mass (FFM) neither between RW and PW at any time, nor between S1 and TM. FFM was lower for RW and PW compared to S1 and TM. TM gained FFM until the age of 17 months, while S1 gained FFM all the time. S1 gained fat all the time, but the gain for TM levelled off. It stayed constant for RW until 13 months and decreased afterwards. We conclude that voluntary running in wheels enhances survival and keeps body fat lower than in PW animals up to the age of 17 months. Body composition and survival data suggest that voluntary running is more optimal than forced. Care must, however, be taken in analyses, since RW is a heterogenous group because there is a large variation between the animals with respect to how much they run.     

Altered ketone body metabolism during gram-negative sepsis in the rat

To investigate why blood ketone bodies are depressed during sepsis, the production and utilization of ketone bodies was studied in fasted control, fasted, Escherichia coli-treated, fed control, and fed E coli-treated rats. Gram-negative sepsis was induced by intravenous (IV) injection of 8 x 10(7) live colonies of E coli per 100 g body weight. Food was removed from the fasted rats after E coli injection. Fed rats were infused intragastrically with a nutritionally adequate diet for 5 days before inducing sepsis. Twenty-four hours after E coli injection, blood ketone bodies were reduced in fasted septic rats and fed septic rats compared with their respective control rats. Ketogenesis and oxidation of labeled palmitate was not altered in hepatocytes from fasted E coli-treated rats. Yet, ketogenesis declined significantly in hepatocytes from fed E coli-treated rats. Oxidation of labeled palmitate was also significantly reduced in hepatocytes from fed E coli-treated rats. Utilization of ketone bodies as measured by the incorporation of [3-14C]beta-hydroxybutyrate into CO2, increased over threefold in the diaphragm, 12% in the heart, and 19% in the kidneys from the fasted E coli-treated rats. In the fed state, incorporation of [3-14C]beta-hydroxybutyrate into CO2 was elevated fivefold in the heart, fourfold in the diaphragm, and over threefold in the kidneys from the septic rats. These results suggest that in the fasted state, plasma ketone bodies remain low during gram-negative sepsis because peripheral tissues use more ketone bodies and because liver ketogenesis is not increased to compensate for the increased utilization. In the fed state, the reduction in blood ketone bodies appears to be attributed to both impaired ketogenic capacity and increased peripheral utilization.     

Altered triiodothyronine metabolism in Zucker fatty rats

Genetically obese Zucker fatty rats require two autosomal recessive genes (fa/fa) to express the obese phenotype. The obese Zucker rat (fa/fa) has decreased total and free serum T3 concentrations, but normal serum T4 concentrations, compared to those in their lean littermates. To elucidate the mechanism of these differences, we measured the MCR and production rate (PR) of T4 and T3 in the three genotypes of 4-month-old male Zucker rats (Fa/Fa, Fa/fa, and fa/fa). In addition, 5'-deiodinase activity in liver, kidney, and brown adipose tissue homogenates was determined. T4 MCRs were equivalent in all three genotypes, but a decreased T3 MCR was seen in Fa/fa and fa/fa rats. An additive effect of the fa gene was noted with respect to the decrease in T3 MCR (Fa/Fa, 42.0 +/- 1.5; Fa/fa, 38.7 +/- 2.4; fa/fa, 34.7 +/- 3.4 ml/h; P less than 0.05). Whole body T4 PRs were equal in all three genotypes, but the T3 PR was decreased in the fa/fa rat by 25% compared to that in the homozygous lean rats (15.7 +/- 2.1 vs. 21.2 +/- 2.4 ng/h; P less than 0.005). Liver and kidney 5'-deiodinase activities were decreased in the fa/fa rat by 34% (P less than 0.005) and 20% (P less than 0.01), respectively. Brown adipose tissue and pituitary 5'-deiodinase activity were similar in all three genotypes. These results show a reduction in T3, but not T4, MCR in obese Zucker rats. Whole body T3 production and type I 5'-deiodinase activity were decreased in the obese (fa/fa) rats. These results suggest that decreased T4 to T3 conversion is responsible for the decreased T3 production rate in the fatty rat and may contribute to its obesity.     

Altered systemic ketone body metabolism in advanced heart failure

Heart failure is a systemic disease in which both myocardium and skeletal muscle exhibit alterations of energy metabolism. Failing myocardium exhibits impaired utilization of free fatty acids and glucose, which are major substrates for myocardial energy production. Ketone bodies normally provide a modest contribution to energy balance, but serum concentrations of ketone bodies are elevated in heart failure. To profile ketone body metabolism in advanced heart failure, we directly measured ketone body utilization by heart and skeletal muscle.Metabolite concentrations in arterial, coronary sinus, and central venous beds were measured to derive myocardial and skeletal-muscle ketone body utilization in 11 patients with advanced heart failure and 10 healthy control subjects who were undergoing electrophysiologic procedures. As expected, the mean myocardial arteriovenous oxygen difference was significantly increased in the heart-failure patients (8.3 ± 0.4 mL/dL, vs 7 ± 0.5 mL/dL in the control subjects; P = 0.05). Although the mean myocardial ketone body extraction ratio was relatively unchanged (0.49 ± 0.05 in heart-failure patients vs 0.54 ± 0.06 in control subjects, P = 0.53), skeletal-muscle ketone body utilization was markedly lower in the heart-failure patients (0.18 ± 0.06, vs 0.4 ± 0.04 in control subjects; P = 0.01).In this preliminary study, heart failure was associated with tissue-specific alteration of ketone body metabolism. In advanced heart failure, skeletal-muscle ketone body utilization was impaired, whereas myocardial ketone body utilization was preserved. Future studies are needed to determine whether ketone body metabolism serves as a dynamic quantitative biomarker of skeletal myopathy and fatigue in heart failure.     

Altered IGF-I and IGFBPs in senescent male and female rats

The effects of senescence on muscle characteristics and the insulin-like growth factor I (IGF-I) pathway were assessed in male and female BN/F344 rats. The mass and total ATPase activity of gastrocnemius and plantaris muscles were reduced with age and to a greater extent in males than in females. The mass and total ATPase activity of soleus muscle were not significantly altered with age. Circulating IGF-I was also significantly reduced with age, 60% in females and 21% in males. Circulating IGF-binding protein 3 (IGFBP-3) was reduced with age. In liver and gastrocnemius muscle, mRNAs for IGF-1, IGFBP-2, and IGFBP-3 were analyzed in young and aged males of two strains, BN/F344 and Sprague-Dawley. In BN/F344 rats, liver mRNAs were unchanged with age. Also in BN/F344 rats, muscle mRNAs for IGFBP-2, and IGFBP-3 displayed nonsignificant trends toward increase with age. In aged Sprague-Dawley males, liver mRNA for IGF-I was increased 15% and muscle mRNA for IGFBP-2 was increased 110%. Thus, different age-related changes in the growth hormone (GH)/IGF pathway occur in males and females between the sexes and strains. These changes may play a role in the muscle atrophy associated with senescence.     

Altered muscle metabolism in rats after thermal injury

Burn injury is associated with an elevation in total body oxygen consumption, increased hepatic alanine uptake and conversion to glucose, and a negative nitrogen balance. The primary source of the alanine used for gluconeogenesis by the liver and of the nitrogen lost as urea is believed to be from skeletal muscle. Selected muscle regulatory enzymes and pyruvate and oleate oxidation rates were assayed for maximal activity during the postburn period. Male Sprague-Dawley rats that received 50% total body surface scald burns on the dorsum and abdomen were examined for citrate synthase (CS), phosphofructokinase (PFK), and glutamate-pyruvate transaminase (GPT) activity in uninjured muscle at 3, 7, 13, and 20 days postburn, and the ability of muscle to oxidize pyruvate and oleate was measured at 3 and 13 days after injury. CS, PFK, and GPT activities increased significantly (p < 0.05) by 13–20 days after injury in the soleus and diaphragm. The epitrochlearis showed no change in CS, but PFK and GPT were elevated within this time frame. The gastrocnemius muscle showed an elevated oleate oxidation rate at 13 days after injury, but no change at 3 days postburn. Pyruvate oxidation rates were unaltered.The results of this study indicate that during the postburn period several metabolic alterations occur in muscle. These adaptations include: (1) elevated CS activity which may be associated with increased oxidative capactiy, (2) increased PFK activity which implies that more substrate is being shuttled through the glycolytic pathway, (3) increased GPT activity which may reflect increased pyruvate conversion to alanine, and (4) increased oleate oxidation rates which demonstrate that muscle is utilizing more fatty acid substrates during the postburn period.     

高脂饲养大鼠脂代谢调控基因的表达与胰岛素抵抗的关系及机制

目的探讨高脂饲养SD大鼠脂代谢基因表达的改变与胰岛素抵抗（IR）的关系。方法8周龄雄性SD大鼠随机分为3组：正常饲养组（NC,10只）、高脂饲养组（HF,10只）、高脂饲养＋吡格列酮15mg·kg^-1·d^-1进行灌胃组（HP,12只）。饲养20周时测定血清、肝脏及肌肉组织中TG含量,3组均行正常血糖高胰岛素钳夹试验,并用实时定量PCR方法分析脂肪、肝脏和肌肉中脂代谢调控基因mRNA表达的变化。结果饲养20周时,与NC组比较,HF组血清TG增加45．0％（P〈0．01）,肝脏和肌肉TG含量增加2．28倍和9．31倍（P〈0．01）;HF组葡萄糖的输注率（GIR）下降61％（P〈0．01）,存在明显的IR;脂肪组织脂肪酸合成酶、激素敏感酯酶表达分别增高21．3％、28．2％（P〈0．05）;肝脏乙酰辅酶A羧化酶表达增高48．3％（P〈0．05）、肉毒碱脂酰转移酶1（CPT-1）表达呈增高趋势（P〉0．05）;肌肉乙酰辅酶A羧化酶表达增加101．1％、CPT-1表达减少71．0％（P〈0．01）。HP组与HF组比较,血TG、肝脏TG、肌肉TG分别下降66．0％、64．5％及59．6％,GIR增加1．54倍,脂代谢基因的表达也发生了明显的改变。结论高脂饲养可引起sD大鼠肝脏和肌肉组织脂肪异位沉积及IR,吡格列酮干预可以改善,可能与脂代谢调控基因的改变有关。     

Short-term leptin treatment increases fatty acids uptake and oxidation in muscle of high fat-fed rats

The purpose of this study was to measure the effects of short-term (10 days) leptin treatment on insulin sensitivity as it pertains to fatty acid (FA) uptake, oxidation, and muscle triglyceride (mTG) synthesis in animals that have been administered a high-fat (HF) diet for 3 months. Male Wistar rats were randomly assigned to 1 of 4 groups. One group was fed a control diet (CON) and 3 groups were fed a HF diet. The HF and HF-leptin (HF-LEP) groups were fed the HF diet ad libitum and the amount of food eaten by the HF-pair fed (HF-P) group was equal to that of the HF-LEP group. At the end of the dietary period, rats were injected daily either with saline (CON, HF, HF-P) or with leptin (HF-LEP; 10 mg.kg-1.d-1) for 10 days before hindlimb perfusion. The perfusate contained 600 micromol/L palmitate traced with [14C]palmitate, 9 mmol/L glucose, and 100 microU/mL insulin. As dictated by the protocol, energy expenditure was not significantly different (P>.05) between HF-LEP and HF-P. Palmitate uptake and oxidation as well as mTG synthesis were greater (P<.05) in HF (9.8+/-0.3, 2.0+/-0.1, and 1.9+/-0.2 nmol.min-1.g-1) than in CON (8.0+/-0.4, 1.4+/-0.1, and 1.1+/-0.1 nmol.min-1.g-1) and this was associated with higher levels of mTG in HF. Palmitate uptake and oxidation were higher (P<.05) in HF-LEP (10.3+/-0.6 and 2.0+/-0.1 nmol.min-1.g-1) than in HF-P (8.3+/-0.5 and 1.5+/-0.2 nmol.min-1.g-1, P<.05), but mTG synthesis and mTG levels were not changed significantly by leptin treatment (P>.05). High-fat feeding decreased glucose uptake by 41% when compared with CON (2.4+/-0.4 vs 4.1+/-0.4 micromol.h-1.g-1; P<.05) but pair feeding alone (4.7+/-0.4 micromol.h-1.g-1) or leptin treatment (3.8+/-0.3 micromol.h-1.g-1) similarly prevented the HF diet-induced decrease in glucose uptake. These data indicate that short-term leptin treatment in HF-fed rats alters muscle FA metabolism by increasing FA uptake and oxidation relative to pair feeding alone. This results in a decrease in the FA esterification-oxidation ratio.     

Altered carbohydrate metabolism in endotoxin-tolerant rats after lead sensitization

The lethality of endotoxin is greatly enhanced in lead-sensitized rats. Previous work showed that hepatic carbohydrate metabolism in lead-treated rats is perturbed by minute endotoxin doses [Fed Proc 41:1607, 1982]. These studies were extended to rats made tolerant to endotoxin by IV injection of lipopolysaccharide (50 micrograms/100 g body weight [BW]) 18 h before simultaneous treatment with lead acetate trihydrate (1.5 mg/100 g BW) and endotoxin (1.0 micrograms/100 g BW). Liver samples removed by freeze-clamping at 5 h from fasted young adult male rats were assayed for glycolytic intermediates. The tolerant rats generally showed smaller alterations in concentrations of metabolites than nontolerant comparison rats challenged with lead and endotoxin. However, phosphoenolpyruvate (PEP) levels were similarly elevated (80-90%) in both groups. The failure of the tolerance procedure to minimize or protect against hepatic PEP changes suggests that the enzymes forming or consuming this metabolite were particularly vulnerable to the action of an endotoxin-released mediator. The fact that some liver glycolytic intermediates remain markedly altered despite amelioration of the lethal effects of endotoxin by the tolerance procedure indicates the existence of independent mediators acting on carbohydrate metabolism in the endotoxic rats.     

Cholesteryl ester metabolism in fat- and cholesterol/fat-fed guinea pigs

Guinea pigs were fed a semisynthetic diet containing 10% (by weight) cottonseed oil with or without 1% cholesterol. In response to cholesterol/fat feeding there was a significant accumulation of cholesteryl ester (CE), particularly in the liver, but also in the kidney, spleen and suprarenal glands. The hepatic acyl-CoA:cholesterol acyltransferase (ACAT) increased 5-10 times when the animals were fed cholesterol fat during 11 weeks while the acid cholesterol esterase (CE-ase) was similar in the two dietary groups. Intestinal lymph showed the highest content of cholesterol (both free and esterified) in guinea pigs fed cholesterol/fat. A low activity of lecithin:cholesterol acyltransferase (LCAT) was present in the intestinal lymph, irrespective of dietary composition. Triglyceride-rich lipoproteins seem to inhibit LCAT activity in the intestinal lymph. Plasma cholesterol levels in animals fed cholesterol/fat increased markedly while LCAT remained unaffected by the diets. Activity of ACAT and CE-ase in kidney and spleen was low compared to liver tissue and the enzyme activities were not affected by the cholesterol/fat feeding.     

Combined effects of oral oleoyl-estrone and limited food intake on body composition of young overweight male rats

OBJECTIVE: The combined effects of limited food intake and OE treatment have been analysed in order to determine whether hypocaloric diets enhance the slimming effects of OE on mature overweight male rats. Two levels of dietary limitation at 50 and 25% of a standard intake were established, roughly corresponding to the human LCDs and VLCDs. DESIGN: Wistar male rats (6 weeks old) were made overweight by a cafeteria diet. After transition to standard diet, they were subjected to food restriction: down to 50 or 25% with respect to the transition period. Half the animals were given daily oral gavages of 10 nmol/g oleoyl-estrone (OE), and the rest received only the vehicle during 10 days. MEASUREMENTS: Changes in weight and body composition: water, lipid, protein or gross energy were determined by comparing the final pool size with that of day 0, calculated from the initial body weight and the composition of untreated rats. Energy and nitrogen balances were estimated. Plasma levels of metabolites and hormones were also measured. RESULTS: OE induced changes in body composition similar to those elicited by a 50% reduction in food, with massive loss of lipid and energy. OE-treated rats ate less than the controls, but additional effects on body composition on reduced diet were minimal. OE improved metabolic homoeostasis: better maintained glycaemia, lower cholesterol and shallower hormonal changes, but at the expense of slightly increased protein mobilisation. CONCLUSIONS: The data presented suggest that no advantages are accomplished by combining OE treatment and hypocaloric diets compared with OE alone, at least under the experimental conditions tested, since the effects were not additive. Despite OE affecting food intake, mechanisms other than that are deemed responsible for the mobilisation of body fat, since intake alone cannot explain the effects on body weight, nor the metabolic and hormonal changes in OE-treated rats. It is concluded that the combination of food restriction and OE may result in unwanted increased protein mobilisation with no synergy between both slimming treatments.     

Gender difference in the effect of body composition on energy metabolism

OBJECTIVE: The aim of this study was to investigate the relationship between energy expenditure (EE) and fat mass (FM) by using a cross-sectional approach to study the linear relationship between body composition variables and EE phenotypes as well as an intervention design to investigate the effect of body weight loss on energy metabolism in both genders. METHODS: The correlations and linear relationships between body weight, FM, fat-free mass (FFM) and abdominal fat vs 24 h EE (EE 24) and sleeping metabolic rate (SMR) were compared between 65 men and 35 women, and before and after weight loss in 10 men and 10 women. RESULTS: Our results showed that for a given FM, men displayed a higher EE than women, independently of FFM. Furthermore, regression analysis revealed that after body weight loss, men displayed a lower SMR for a given FM or FM adjusted for FFM compared to before the treatment, but this was not so in women. However, when FM was adjusted for abdominal fat deposition, the difference between the conditions was no longer observed. CONCLUSIONS: FM has a significant impact on EE only in men. We suggest that abdominal adipose tissue may exert a potent regulatory effect on energy metabolism which would be more detectable in men who generally store more fat in this compartment than women.     

Maternal protein intake in the pregnant rat programs the insulin axis and body composition in the offspring

Evidence to support an association between early nutrition and the development of obesity in the rat is equivocal. In this study we have investigated the postnatal growth, glucose tolerance, and adipocyte function of the offspring from pregnant rats fed with diets containing either 20% or 8% protein during gestation. By 25 weeks of age, the female offspring of dams fed with the diet containing 8% protein had a significantly lower adult body weight due in part to a decrease in body fat. The peak concentration of insulin after oral administration of a glucose dose was significantly lower in both the male and female offspring of the dams fed with the diet containing 8% protein. However, the ability of insulin to stimulate lipogenesis or suppress lipolysis in fat cells isolated from the offspring was not influenced by the prenatal diet. Hepatic phosphoenolpyruvate carboxykinase activity was reduced in female offspring of dams fed with the diet containing 8% protein. These results show that adult body composition is determined during the prenatal period as a result of programming of the insulin axis. This metabolic programming influences hepatic metabolism; however, there is no evidence for a programmed change in adipocyte function.