Protein synthesis in liver,skeletal muscle,and brown adipose tissue of rats fed a protein-deficient diet

Feeding protein-deficient diets to rats is known to stimulate diet-induced thermogenesis and activate brown adipose tissue (BAT). The fact that BAT protein content, unlike that of other tissues, is unnaffected by protein deficiency prompted us to measure tissue protein synthesis in vivo in animals maintained on normal- (18.8%) and low- (7.6%) protein (LP) diets. Protein synthesis was depressed in the liver of the LP rats due to a fall in RNA activity, with no change in RNA content, and synthesis was also reduced in skeletal muscle from the LP group, but this was due to decreased RNA content with no change in RNA activity. Conversely, protein synthesis, RNA, DNA, and protein content of interscapular BAT were all unaltered in protein-restricted animals. These data indicate that, unlike liver, skeletal muscle, and whole carcass, BAT protein synthesis is not reduced in protein-restricted rats, and this may be related to activation of thermogenesis in the tissue.     

Anabolic effectiveness of nitrogenous preparations for parenteral nutrition in the presence of toxic liver damage]

The authors studied the assimilation of nitrogen preparations--moriamin S-2 and "improved" caseine hydrolysate in parenternal administration to 100 albino rats. Healthy animals and those with toxic affection of the liver induced with CCl4 were experimented upon. In healthy animals administration of nitrogen preparations led to the change of negative nitrogen balance into a positive one, normalized the content of blood and tissue amine nitrogen deranged in protein deficiency. Assimilation of nitrogen preparations fell considerably in toxic hepatitis. An 8-day parenteral nutrition failed to change the negative nitrogen balance into positive, and did not eliminate hypoproteinemia; however, it normalized the amine nitrogen concentration in the blood and tissues.     

Dynamics of the nuclear DNA content in the liver, skeletal muscles and myocardium of the rat in the postmortem period (a microspectrophotometric study)]

A comparative microspectrophotometric analysis of changes in nuclear DNA in the liver, skeletal muscle and myocardium of noninbred male albino rats which had died of cerebrocranial injury was conducted during three days following death. A decrease in the content of nuclear DNA within an interval of 30-72 h can be depicted mathematically by regression curves of the type M(t) = e-at+b. The data obtained allowed one to mathematically show the postmortem changes in DNA of the test material.     

In vivo tissue specific modulation of rat insulin receptor gene expression in an experimental model of mineralocorticoid excess

Insulin receptor (IR) gene expression at the mRNA level was investigated in hindlimb skeletal muscle, epididymal adipose tissue and in the liver of rats exposed to prolonged in vivo administration of deoxycorticosterone acetate (DOCA). Following treatment, plasma insulin levels were reduced while glucose levels increased compared to values in control rats. DOCA-treated animals showed an increase in blood pressure and a reduction in body weight. This treatment also induced hypokalemia and decreased plasma protein levels. Sodium levels were unaffected. Moreover, no differences in DNA and protein content or in the indicator of cell size (protein/DNA) were observed in the skeletal muscle or adipose tissue of animals. In contrast, there was a clear increase in the protein and DNA contents of the liver with no change in the indicator of cell size. Northern blot assays revealed 2 major IR mRNA species of approximately 9.5 and 7.5 Kb in the 3 tissues from control animals. DOCA treatment induced no change in the levels of either RNA species in skeletal muscle. However, a decrease of approximately 22% was detected in the levels of both species in adipose tissue whereas the liver showed an increase of 64%. These results provide the first evidence for an in vivo tissue-specific modulation of IR mRNA levels under experimental conditions of mineralocorticoid excess.     

Changes in the concentrations of total RNA and DNA in the cerebral cortex and internal organs (liver and heart) after prolonged hypovolemic hypotension and in the post-resuscitation period

It was shown in experiments on dogs that after 4-hour hypovolemic hypotension the content of total RNA in brain cortex and myocardium homogenates decreased. In the liver, there was a significant decrease both in RNA and DNA content. In the postresuscitation period, the content of nucleic acids in the myocardium returned to normal after 14--21 days, and that in the liver after 3--4 months. The gray matter of the brain manifested a delayed lowering of DNA content (after 14--21 days), and the level of nucleic acid did not return ot normal over 3--4 months after resuscitation.     

A comparison of tRNA populations of rat liver and skeletal muscle during aging

Total tRNA extracted from liver as well as from skeletal muscle of young, adult and old female albino rats showed quantitative variation with age. The amount of liver total tRNA was maximum in adult rats when compared to that in young and old ones, whose levels were almost the same. Transfer RNA from skeletal muscle showed a different pattern with age. It was maximum in young rats and showed a gradual decline with age. Transfer RNAs were aminoacylated using homologous synthetase preparations to study their qualitative variation during aging, which followed the trend of quantitative variation in both the tissues. Arginyl and glutamyl-tRNAs were fractionated from both the tissues at the three ages. Isoacceptor profile of glutamyl-tRNAs showed neither tissue specificity nor age-related change, whereas a definite change was found in the case of arginyl-tRNA isoacceptors in the two tissues during aging.     

Effect of excess and deficiency of vitamin A on the utilization of FFA by liver and skeletal muscle.

Fatty acid metabolism in liver and skeletal muscle has been studied in rats treated with high doses of vitamin A and in those made vitamin A-deficient. Ingestion of 30,000 IU of vitamin A for two days resulted in increased incorporation of palmitate-1-14C into triglycerides but not into phospholipids. Accumulation of hepatic triglycerides was observed in vitamin A-fed rats. Deficiency of vitamin A did not cause any change in the triglyceride or phospholipid content of the liver. The rate of hepatic fatty acid oxidation and ketogenesis was markedly increased in vitamin A-fed rats. The experimental evidence indicated that vitamin A may have a stimulatory effect on these processes apart from that exerted by the high plasma FFA level in vitamin A-fed rats. Oxidation of palmitate-1-14C into C32 by skeletal muscle (latissimus dorsi) was also increased as a result of vitamin A administration. Vitamin A deficiency did not cause any change in fatty acid oxidation by liver and skeletal muscle. Hepatic palmitoyl-CoA synthetase activity was decreased in vitamin A-deficient rats. The results presented suggest that vitamin A may be required for the uptake and utilization of fatty acids by liver and akeletal muscle.     

Tissue-specific modulation of insulin receptor mRNA levels in adrenaline-treated rats

Insulin receptor (IR) gene expression at the mRNA level was investigated in liver, hindlimb skeletal muscle, and epididymal adipose tissue of rats exposed to prolonged in vivo administration of adrenaline in relation to control rats. In the liver of adrenaline-treated rats, there were no differences in relation to controls when DNA and protein content were measured. In skeletal muscle, only a slight decrease in protein concentration was detected. By contrast, a clear increase in both protein and DNA content was observed in the adipose tissue of treated animals. Northern blot assays revealed two IR mRNA species of approximately 9.5 and 7.5 Kb in the three tissues from controls. Adrenaline treatment induced an increase of approximately 60% in the levels of both RNAs in adipose tissue but not in liver or skeletal muscle. These results provide evidence for an in vivo tissue-specific regulation of IR gene expression at the mRNA level in rats under an experimental condition of excess of catecholamines.     

The effects of chlorphentermine and phentermine on certain metabolic parameters associated with development of rat kidney and liver.

Daily oral administration of the anorexigenic agents chlorphentermine or phentermine (60 mg/kg) to rats for either 1, 3, 5 or 7 days resulted in a significant fall in the incorporation of [¹⁴C]thymidine into renal and hepatic DNA throughout the course of the experiment. Although 24 h after treatment with either drug there was no dramatic change in the incorporation of [¹⁴C]orotic acid into liver RNA, a statistically significant reduction was noted after 3, 5 and 7 days. In rat kidney, the incorporation of [¹⁴C]orotic acid into RNA was only significantly depressed by chlorphentermine at 5 days and by phentermine at 3 days. In general, treatment with either anorexigenic agent tended to significantly lower or not affect the endogenous concentrations of renal and hepatic putrescine, spermidine and spermine. The chlorphentermine-induced decrease in liver and kidney nucleic acid synthesis was accompanied by depression in the levels of cyclic AMP in both tissues as well as a reduction in the activity of adenylate cyclase in renal tissue. In contrast, chlorphentermine produced a rise in hepatic adenylate cyclase at 5 days followed by a return to control values after 7 days. The phentermine-induced alterations in nucleic acid metabolism appeared generally to occur independent of any changes in the adenylate cyclase-cyclic AMP system of renal and hepatic tissues. In view of the fact that nucleic acids, polyamines and cyclic AMP constitute integral components of the growth process, our data suggest that chlorphentermine and phentermine interfere with certain biochemical parameters associated with the development of kidney and liver.     

A streamlined protocol for extracting RNA and genomic DNA from archived human blood and muscle

We combined the TRIzol method of nucleic acid extraction with QIAamp columns to achieve coextraction of RNA and genomic DNA from peripheral blood mononuclear cells (PBMCs) and biopsied skeletal muscle, both stored at −80 °C for many months. Total RNA was recovered from the upper aqueous phase of TRIzol. The interphase and organic phases were precipitated with ethanol, digested with proteinase K, and filtered through QIAamp MinElute columns to recover DNA. The combined protocol yielded excellent quality and quantity of nucleic acids from archived human PBMCs and muscle and may be easily adapted for other tissues.     

Trafficking of dietary oleic, linolenic, and stearic acids in fasted or fed lean rats

Increasing evidence supports the notion that there are significant differences in the health effects of diets enriched in saturated, as opposed to monounsaturated or polyunsaturated fat. However, the current understanding of how these types of fat differ in their handling by relevant tissues is incomplete. To examine the effects of fat type and nutritional status on the metabolic fate of dietary fat, we administered (14)C-labeled oleic, linolenic, or stearic acid with a small liquid meal to male Sprague-Dawley rats previously fasted for 15 h (fasted) or previously fed ad libitum (fed). (14)CO(2) production was measured for 8 h after tracer administration. The (14)C content of gastrointestinal tract, serum, liver, skeletal muscle (soleus, lateral, and medial gastrocnemius), and adipose tissue (omental, retroperitoneal, and epididymal) was measured at six time points (2, 4, 8, 24, and 48 h and 10 days) after tracer administration. Plasma levels of glucose, insulin, and triglyceride were also measured. Oxidation of stearic acid was significantly less than that of either linolenic or oleic acid in both the fed and fasted states. This reduction was in part explained by a greater retention of stearic acid within skeletal muscle and liver. Oxidation of oleate and stearate were significantly lower in the fed state than in the fasted state. In the fasted state, liver and skeletal muscle were quantitatively more important than adipose tissue in the uptake of dietary fat tracers during the immediate postprandial period. In contrast, adipose tissue was quantitatively more important than skeletal muscle or liver in the fed state. The movement of carbons derived from dietary fat between tissues is a complex time-dependent process, which varies in response to the type of fat ingested and the metabolic state of the organism.     

Effect of acetylcholine on incorporation of 14C-precursors into uridylic and cytidylic nucleotides of the RNA of digestive glands

The incorporation rate of [2-14C]orotic acid and [2-14C]uridine into the cytidylic RNA nucleotides is significantly lower than into the uridylic ones. In the liver it was twice as low as in the stomach mucosa or in pancreas of albino rats. The administration of acetylcholine in combination with proserine has no influence on the RNA content and its nucleotide composition in the tissues. The administered drugs however caused changes in the relation of the incorporation rates of both labels into uridylic and cytidylic RNA nucleotides, which evidences for the uridylic nucleotide synthesis. In the liver such changes are not detected, but utilization of the labeled uridine is shown to be more intensive for the cytidylic RNA nucleotides synthesis.     

Analysis of bases of rat-liver nucleic acids after administration of the carcinogen dimethylnitrosamine

Dimethylnitrosamine is metabolized to form an alkylating intermediate, which may have significance for its carcinogenic action. However, certain other compounds that are known to be highly mutagenic, including nitrous acid and hydroxylamine, might also be formed. Owing to the general reactivity of these compounds, it would be difficult to detect their formation in the intact animal. Instead, the nucleic acids of carcinogen-treated animals were examined for products of reaction with nitrous acid and hydroxylamine, i.e. for deamination of adenine and guanine, and formation of N(6)-hydroxycytosine, respectively. A double-labelling technique was used to detect very small amounts of the abnormal bases. The purine moieties of DNA in adult rat liver were labelled either with (14)C or with (3)H, by treating the neonatal animals with [(14)C]formate or with [(3)H]formate, and then allowing a period for normal growth. During this time, in liver, the labels were largely lost by metabolic turnover from cell components other than DNA. The pyrimidine moieties in DNA were labelled by treating the neonatal animals with [(14)C]orotate. The purine constituents of RNA of adult rat liver were labelled by repeated administration of [(14)C]- or [(3)H]-formate to the adult rats. The [(14)C]nucleic acid-labelled rat could then be treated with the carcinogen, and the [(3)H]nucleic acid-labelled animal could be used as a control. By this means the experimental and control tissues could be homogenized together in a single preparation, and the nucleic acids from the two tissues could be isolated, hydrolysed and analysed in a single sample. It was therefore possible to have an internal control for artifacts due to changes taking place in the nucleic acid bases during the experimental procedures. With this technique, the formation in vivo of 7-methylguanine in rat-liver DNA and RNA after administration of dimethylnitrosamine was confirmed, and no evidence was found for the formation of xanthine, hypoxanthine, N(6)-hydroxycytosine, or any other abnormal base.     

Impact of monocrotophos on protein and carbohydrate metabolism in different tissues of albino rats.

The impact of monocrotophos on protein and carbohydrate metabolism in different tissues of albino rats was investigated. The monocrotophos (0.25 mg/ml) was orally intubated into an experimental group of rats. In another group, the same amount of water was orally intubated (control group) for 29 days. The protein content was increased in liver, serum and spleen of albino rats after treatment with monocrotophos. The protein content decreased in muscle and kidney, and overall the free sugar level decreased in all tissues. The glycogen content increased in muscle, serum and kidney after treatment with monocrotophos, and the glycogen content and reducing sugar level decreased in liver and spleen. The significance of these results is discussed.     

Effects of potassium deficiency on potassium,polyamines and amino acids in mouse tissues

Sexual dimorphism in potassium content was found in plasma, kidney, heart and skeletal muscle of CD1 mice. We observed that feeding mice with a K(+)-deficient diet had an uneven and gender-dependent effect on organ weight and tissue potassium concentrations. Treatment produced a marked decrease in plasma, pancreas and skeletal muscle K(+) levels in both sexes, and a reduction in kidney, liver and heart potassium concentrations in females. Moreover, K(+) deficiency produced a 2-3-fold increase in the concentrations of cationic amino acids, such as arginine and lysine in both heart and skeletal muscle of the two sexes, a slight increase ( approximately 37%) in renal arginine in the male mice. The concentrations of these amino acids in plasma and other tissues in both sexes remained unaltered. Polyamine levels in heart, liver, skeletal muscle and pancreas from male and female mice were not affected by K(+) deficiency. However, in the male kidney potassium deficiency was accompanied by an increase of putrescine and spermidine concentration, and a reduction of putrescine excretion into the urine, even though renal K(+) concentration was not significantly affected and ornithine decarboxylase activity was dramatically decreased. The general lack of correlation between tissue potassium decrease and the increase in organic cations suggests that it is unlikely that the changes observed could be related with an attempt of the tissues to compensate for the reduction in cellular positive charge produced by the fall in K(+) content. The mechanisms by which these changes are produced are discussed, but their physiological implications remain to be determined.     

Optimum Conditions for the Assay of Cardiac RNA: Comparative Content and Effect of Hypertension

An investigation was made into techniques for the routine measurement of cardiac ribonucleic acid (RNA). Conditions were defined for the determination of rat ventricular RNA, based on uv absorption spectrophotometry. Optimum RNA hydrolysis occurred at 0.3 mol/liter alkali at 37°C for 1 h. Suitable correction factors for non-RNA material were also described and these gave similar results to RNA assayed by colonmetric methods. It was concluded that many of the methods previously reported may cause artifactual observations (in some cases apparent negative amounts of RNA). The technique was applied to the assay of RNA in various regions of the heart (i.e., left and light atrial and the left and right ventricular regions) and compared with noncardiac tissues (i.e., skeletal muscle, liver, bone, intestine, and kidney). The left ventricular RNA concentrations were comparable to the right ventricle and the interventricular septum, but approximately half that of atria. There were very little differences between left and right atrial regions. Differences between atrial and ventricular legions were reduced when data were expressed relative to DNA. The cardiac RNA content was shown to be comparable to skeletal muscle and bone. However, cardiac RNA concentrations were lower than those of kidney, liver, lung, and small intestine. Data were also expressed relative to DNA and showed that cardiac RNA/DNA ratios were higher than those of skeletal muscle and lower than those of bone, kidney, liver, lung, and small intestine. The assay procedure for cardiac RNA was applied to investigations in the hypertrophied left ventricle induced by aortic constriction. After 10 days the RNA concentration (mg/g wet wt) and RNA content (mg/region) increased by 7 and 43%, respectively.     

Similarities between the biochemical actions of cycasin and dimethylnitrosamine

1. Rats were given the hepatotoxin and carcinogen cycasin by stomach tube. In one experiment, rats whose RNA had previously been labelled with [(14)C]-formate were given the acetate ester of the aglycone form of cycasin, methylazoxymethanol, by intraperitoneal injection. 2. Incorporation of (14)C from l-[U-(14)C]leucine into the proteins of some organs was measured in cycasin-treated rats. Cycasin inhibited leucine incorporation into liver proteins but not into kidney, spleen or ileum proteins. This inhibition was not evident until about 5hr. after cycasin administration, but once established it persisted for the next 20hr. 3. Methylation of nucleic acids was detected in some organs of rats treated with cycasin or methylazoxymethanol. The purine bases of RNA and DNA were isolated by acid hydrolysis followed by ion-exchange column chromatography. The resulting chromatograms showed an additional purine base that was identified as 7-methylguanine. It was shown that, in animals treated with the toxin, liver RNA was methylated to a greater extent than was either kidney or small-intestine RNA. Also, as a result of cycasin administration, liver DNA guanine was methylated to a greater extent than was RNA guanine. 4. These results are discussed in relation to comparable experiments with dimethylnitrosamine. It is suggested that cycasin and dimethylnitrosamine are metabolized to the same biochemically active compound, perhaps diazomethane, but that various tissues differ in their capacity to metabolize the two carcinogens.     

Effect of short-term treatment of eugenol on the seminal vesicles of adult albino rats

The structure and biochemical content of adult albino rat seminal vesicles, were studied, after administration of two different doses of eugenol for 10 days (0.2 and 0.3 mg/kg/day, i.m.). Marked decreases in the concentrations of nucleic acids, fructose and total protein as well as RNA/DNA ratio (61%) and protein/DNA ratio (27%) were observed. A remarkable increase in phospholipid concentration was noted with a corresponding decrease in neutral lipids. Histologically, eugenol treated animals showed degeneration of the secretory columnar cells and well developed myofibrillar connective tissues when compared to control animals.     

A method to determine RNA and DNA oxidation simultaneously by HPLC-ECD: greater RNA than DNA oxidation in rat liver after doxorubicin administration

We developed a novel method for the simultaneous extraction and analysis of total tissue RNA and DNA to quantify the RNA and DNA oxidation products 8-oxo-7,8-dihydroguanosine and 8-oxo-7,8-dihydro-2'-deoxyguanosine using HPLC coupled to electrochemical detection (HPLC-ECD). The protein denaturing agents guanidine thiocyanate and phenol/chloroform at neutral pH were found to be very efficient for the isolation of RNA and DNA from rat brain, liver and muscle. The method is very fast, allows extraction at 0 degrees C, gives high yields of pure RNA and DNA with low background oxidation levels, and also determines the RNA/DNA ratio. Experiments with isolated RNA and DNA exposed to the Fenton reagents H2O2/ascorbate/Fe3+ (or Cu2+) resulted in significantly greater RNA oxidation. The RNase inhibitor 2-mercaptoethanol, commonly used for RNA extraction, acted as a pro-oxidant during nucleic acid extraction, an effect attenuated by the inclusion of the metal chelator deferoxamine mesylate. In vivo, administration of doxorubicin (an oxidant generator) to Fisher-344 rats resulted in a significant increase in liver RNA oxidation, but no significantly increased DNA oxidation. This new method could be useful to assess oxidatively damaged RNA and DNA simultaneously, and our data show that RNA is more susceptible to oxidative stress than DNA in vivo and in vitro.     

Brain and Muscle Redox Imbalance Elicited by Acute Ethylmalonic Acid Administration

Ethylmalonic acid (EMA) accumulates in tissues and biological fluids of patients affected by short-chain acyl-CoA dehydrogenase deficiency (SCADD) and ethylmalonic encephalopathy, illnesses characterized by neurological and muscular symptoms. Considering that the mechanisms responsible for the brain and skeletal muscle damage in these diseases are poorly known, in the present work we investigated the effects of acute EMA administration on redox status parameters in cerebral cortex and skeletal muscle from 30-day-old rats. Animals received three subcutaneous injections of EMA (6 μmol/g; 90 min interval between injections) and were killed 1 h after the last administration. Control animals received saline in the same volumes. EMA administration significantly increased thiobarbituric acid-reactive substances levels in cerebral cortex and skeletal muscle, indicating increased lipid peroxidation. In addition, carbonyl content was increased in EMA-treated animal skeletal muscle when compared to the saline group. EMA administration also significantly increased 2’,7’-dihydrodichlorofluorescein oxidation and superoxide production (reactive species markers), and decreased glutathione peroxidase activity in cerebral cortex, while glutathione levels were decreased only in skeletal muscle. On the other hand, respiratory chain complex I-III activity was altered by acute EMA administration neither in cerebral cortex nor in skeletal muscle. The present results show that acute EMA administration elicits oxidative stress in rat brain and skeletal muscle, suggesting that oxidative damage may be involved in the pathophysiology of the brain and muscle symptoms found in patients affected by SCADD and ethylmalonic encephalopathy.