Effect of emotional-pain stress on RNA and protein synthesis in rats of different age]

The intensity of RNA and protein biosynthesis is studied in different tissues as well as in active and low-active fractions of liver chromatin, when adult and old rats are subjected to emotional-painful stress during 3 days. Significant stimulation of RNA and protein biosynthesis in chromatin fractions in liver and total RNA and protein in adrenals and hypothalamus is observed.     

Synthesis of lipoprotein lipase in the liver of newborn rats and localization of the enzyme by immunofluorescence.

In newborn rats, lipoprotein lipase (LPL) activity was higher in the liver than in several other tissues, such as heart, diaphragm or lungs, and accounted for about 3% of total LPL activity in the body. There was no significant correlation between LPL activity in liver and in plasma. Thus transport of the enzyme from extrahepatic tissues was probably not the major source of LPL in liver. To study LPL biosynthesis directly, newborn rats were injected intraperitoneally with [35S]methionine, and LPL was isolated by immunoprecipitation and separation by SDS/polyacrylamide-gel electrophoresis. Radioactivity in LPL increased with a similar time course in all tissues studied, including the liver. Substantial synthesis of LPL was also demonstrated in isolated perfused livers from newborn rats, whereas synthesis was low in livers from adult rats. There was strong LPL immunofluorescence in livers from newborn rats, mainly within sinusoids and along the walls of larger vessels. This labelling disappeared after perfusion with heparin, which indicates that much of the enzyme is in contact with blood and can take part in lipoprotein metabolism.     

Biotin-mediated protein biosynthesis

The effect of administration of biotin to biotin-deficient rats on protein biosynthesis was studied. Biotin treatment resulted in stimulation by more than twofold of amino acid incorporation into protein, both in vivo and in vitro in rat liver, pancreas, intestinal mucosa and skin. Analysis of the products of amino acid incorporation into liver proteins in vivo and in vitro indicated that the synthesis of some proteins was stimulated more than twofold, but others were not stimulated at all. This indicates a specificity in the stimulation of protein synthesis mediated by biotin.     

Increased level of apolipoprotein B mRNA in the liver of ventromedial hypothalamus lesioned obese rats

The mRNA level of apolipoprotein B (apoB), which is a principal protein component of nascent very low density lipoprotein (VLDL), was determined in parallel with the measurement of acetyl-coenzyme A (Ac-CoA) carboxylase activity in the liver of ventromedial hypothalamus (VMH) lesioned obese rats. Eight weeks after the electrolysis of the bilateral VMH, the level of apoB mRNA in the VMH-lesioned rats was about 1.5-fold higher than that in the sham-operated rats, indicating increased apoB synthesis in the liver of the VMH-lesioned obese rats. The activity of Ac-CoA carboxylase, which is a rate-limiting enzyme for the fatty acid biosynthesis, was about 1.8-fold higher in the VMH-lesioned rats. These observations indicated that VLDL synthesis is increased in the liver of VMH-lesioned obese rats.     

Effect of chromium supplementation on the diabetes induced-oxidative stress in liver and brain of adult rats

This study was designed to investigate the susceptibility of liver and brain tissues, as insulin-independent tissues, of normal adult male rats to the oxidative challenge of subchronic supplementation with chromium picolinate (CrPic) at low (human equivalent) and high doses (2.90 and 13.20 μg Cr kg⁻¹ day⁻¹, respectively). Also, the modulative effect of CrPic administration on the enhanced oxidative stress in the liver and brain tissues of alloxan-diabetic rats was studied. Fasting serum glucose level was not modified in normal rats but significantly reduced in diabetic rats that had received CrPic supplement. A mild oxidative stress was observed in the liver and brain of CrPic-supplemented normal rats confirmed by the dose-dependent reductions in the levels of hepatic and cerebral free fatty acids, superoxide dismutase and glutathione peroxidase activities, and in contrast increased tissue malondialdehyde concentration. On the other hand, hepatic and cerebral catalase activity was reduced in the high dose group only. CrPic supplementation did not act as a peroxisome proliferator confirmed by the significant reductions in liver and brain peroxisomal palmitoyl CoA oxidase activity. The non significant alterations in liver protein/DNA and RNA/DNA ratios indicate that CrPic did not affect protein synthesis per cell, and that mild elevations in hepatic total protein and RNA concentrations might be due to block or decrease in the export rate of synthesized proteins from the liver to the plasma. In diabetic rats, elevated levels of hepatic and cerebral free fatty acids and malondialdehyde, and in contrast the overwhelmed antioxidant enzymes, were significantly modulated in the low dose group and near-normalized in the high dose group. The significant increases observed in liver total protein and RNA concentrations, as well as protein/DNA and RNA/DNA ratios in diabetic rats supplemented with the high dose of Cr, compared to untreated diabetics, may be related to the improvement in the glycemic status of the diabetic animals rather than the direct effect of CrPic on protein anabolism.     

Orotic acid biosynthesis in arginine-deficient rats.

Arginine deficiency is associated with a mild orotic aciduria. Liver slices from rats fed a purified l-amino acid diet with (control) and without arginine supplementation were used for studies of [¹⁴C]bicarbonate incorporation into orotic acid. The nanomoles of orotic acid synthesized in isolated liver slices from both control and arginine-deficient animals increased linearly with time. Orotic acid biosynthesis was significantly greater in liver slices than slices of heart, muscle, kidney, and minced spleen. The order of orotate biosynthesis from [¹⁴C]bicarbonate was liver > spleen = kidney > muscle > heart. Arginine deficiency resulted in a significant stimulation of liver orotic acid biosynthesis. This stimulation in pyrimidine biosynthesis can account for a major portion of the orotic aciduria. Orotic acid synthesis from spleens isolated from arginine-deficient rats was also enhanced compared with controls. Although the rate of orotic acid biosynthesis is small relative to liver production, the spleen may contribute slightly to increased orotic aciduria in the arginine-deficient rat. Arginine supplementation in vitro to livers from rats fed either the control of arginine-deficient diet resulted in a significant reduction in synthesis of orotic acid. Dietary arginine may play a key role in regulating mitochondrial carbamoyl phosphate utilization into both pyrimidine and urea biosynthesis.     

Effect of hypothalamic extracts and synthetic LH-RH on proteic synthesis by rat hypothalamus in vitro (author's transl)]

The incorporation of 14C-Leucine in pituitary proteins in rats, in vitro, has been studied. In absence of stimulation, the pituitaries of adult female rats have shown approximately twice the capacity of protein biosynthesis in vitro than the pituitaries of prepuberal female rats (21 days old). For the stimulation in vitro of the pituitaries, synthetic LH-RH or hypothalamic extracts from adult or prepuberal female rats were used. The pituitaries of adult female rats did not respond to any of the stimulation tests employed. The pituitaries of prepuberal female rats increased their biosynthetic activity significantly, when synthetic LH-RH or adult female rat hypothalamic extract was added to the culture medium. The addition of prepuberal female rat hypothalamic extract did not alter the basic response. The female prepuberal rats injected during 5 consecutive days with FSH and LH, have shown a greater sensibility to LH-RH in vitro than the ones injected with estradiol and progesterone, or with synthetic LH-RH.     

应激引起血压升高大鼠血管升压素V1受体mRNA水平改变

实验在雄性ＳｐｒａｇｕｅＤａｗｌｅｙ 大鼠上进行。实验动物被随机分为对照组和应激组, 应激组大鼠每天给予电击足底结合噪声的应激刺激, 每日２ 次, 每次２ ｈ 。应激组大鼠在接受连续１５ ｄ 的慢性应激刺激后, 其尾动脉收缩压与对照动物相比有显著升高。对照组为１６－２５ ±０－６３ｋＰａ （ｎ ＝ ７） ; 应激组为１９－５５ ±１－４５ ｋＰａ （ｎ ＝ ８, Ｐ＜ ０－０５） 。用ＲＴＰＣＲ 结合Ｓｏｕｔｈｅｒｎ 印迹核酸分子杂交技术观察到, 血管升压素（ｖａｓｏｐｒｅｓｓｉｎ, ＡＶＰ）Ｖ１ 受体ｍＲＮＡ 广泛存在于大鼠下丘脑、皮质、延髓等部位以及心脏、肝脏、肾脏等组织中。用定量ＰＣＲ 方法观察到, 大鼠在接受慢性应激刺激之后, 其大脑顶叶皮质、下丘脑及延髓组织中ＡＶＰＶ１ 受体ｍＲＮＡ 水平均显著低于正常大鼠（ 顶叶皮质： Ｐ＜ ０－０５ ; 下丘脑： Ｐ＜ ０－０１ ; 延髓： Ｐ＜ ０－００１） , 而心脏、肝脏及肾脏组织中的ＡＶＰＶ１ 受体ｍＲＮＡ水平与正常大鼠相比均无明显差别（ 心脏： Ｐ＞ ０－０５ ; 肝脏： Ｐ＞ ０－０５ ; 肾脏：Ｐ＞ ０－０５） 。上述结果提示, 慢性应激刺激可引起大鼠不同部位脑组织ＡＶＰＶ１ 受体合成水平下调, 可能导致     

Specificity and mechanism of serotonin stimulation of adenylate deaminase activity]

Adenylate deaminating activity was stimulated in the liver mitochondria of rats in vivo not only by serotonin or synthetic indolylalkylamines, but also by phenyl- and imidazolalkyamines. Actinomycin D and cycloheximide protein biosynthesis inhibitors prevented stimulation of adenylate deaminating activity. Theophylline, phosphodiesterase inhibitor, produced a similar effect only when the extent of stimulation of adenylate deaminating activity was comparatively high.     

Maternal stress induces adult reduced REM sleep and melatonin level

We have previously reported that neonatal maternal deprivation (MD) resulted in a decrease of total sleep and an increase of orexin A in adult rats. Now, we characterized features of sleep, activity, and melatonin levels in rats neonatally treated with MD and control (MC) procedures. Adult male Sprague-Dawley rats were treated with either MD or MC procedures for 10 days starting at postnatal day 4. At 3 months of age, sleep was recorded for 48 h in one set of MD and MC rats, while another set of MD and MC rats was measured for locomotor activity (under LD = 12:12). Melatonin levels in the blood, pineal gland, and hypothalamus were measured as well as clock protein level in the hypothalamus. Compared to the MC rats, REM sleep in the MD rats was significantly reduced in the light periods but not in the dark periods. Both quiet wake and total wake in the MD rats were significantly increased during the light period compared to the MC rats. The weight of the pineal gland of the MD rats was significantly smaller than in MC rats. Melatonin levels of the MD group were significantly reduced in the pineal gland and hypothalamus compared to the MC group. No significant difference was identified between groups in the expression of the clock protein in the hypothalamus. Neonatal MD resulted in reduced REM sleep and melatonin levels, without changes of circadian cycle of locomotor activity and levels of clock protein.     

Differential Changes in Superoxide Dismutase Activity in Brain and Liver of Old Rats and Mice

Superoxide dismutase (SOD) activity was measured in the brain and liver of 24–26- and 3-month-old rats. No significant age-related differences in Cu/Zn-SOD activity were found in any of the tissues studied. A small but significant increase in total SOD activity was observed in the whole brain (10-20%), cerebral cortex (11%), and hypothalamus (18%) of old rats, whereas a much more important increase in Mn-SOD activity was found in the whole brain (48%), cerebral cortex (70%), striatum (60%), and hypothalamus (30%). The increase of Mn-SOD activity in the brain of old rats suggests the enzyme may play an important role in the process of aging. Mn-SOD is found only in the mitochondrion, which could be an important site of oxygen free radical production, and a significant increase in the enzyme activity was also found in the lung of hypoxic rats. A significant decrease in total SOD and Mn-SOD activity was observed in the liver of old rats. Preliminary experiments in 23–24-month-old mice similarly showed an increase and a decrease in total SOD and Mn-SOD activity, respectively, in the whole brain and liver. These results suggest that the regulatory mechanisms of Mn-SOD in the brain and liver vary differentially with age.     

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.     

Influence of neomycin pretreatment on stimulated and maturative renal transport of p-aminohippurate (PAH)

Renal tubular transport of organic anions is immature at birth and can be stimulated in adult rats by repeated administration of xenobiotics. There is some evidence of an increased synthesis of carrier proteins in renal tubular cells following stimulation as well as during postnatal development of renal tubular transport processes. The effect of pretreatment with an inhibitor of protein biosynthesis (neomycin) on stimulated and maturative transport of p-aminohippurate (PAH) was measured. Neomycin has a dose dependent long acting and reversible effect on stimulated PAH transport and on postnatal maturation of PAH excretion, and increased protein biosynthesis is the likely common basic phenomenon of both processes.     

Dynamics of the biosynthesis of components of the protein synthesizing apparatus of the rat liver at the stage of restoration of translation, inhibited by cycloheximide

The biosynthesis of proteins, ribosomal RNA and other components of the rat liver protein-synthesizing system during the reparation and subsequent activation of translation inhibited by a sublethal dose cycloheximide (CHI, 3 mg/kg) was studied. It was found that the incorporation of labeled precursors into proteins and ribosomal rRNA isolated from free and membrane-bound polysomes is repaired already 3 hours after CHI injection. 6-9 hours thereafter, the level of component labeling reaches control values, whereas the total protein biosynthesis is retarded. After 12-24 hours, marked stimulation of ribosome biosynthesis and the integration of ribosomes into polysomes are observed together with an asymmetric accumulation of excessive amounts of newly synthesized 40S subunits into polysomes 12 hours after CHI infection. The putative mechanisms of the activation of expression of the part of the genome responsible for protein and ribosomal rRNA synthesis as well as for the synthesis of other components of the protein-synthesizing system are discussed.     

Diurnal changes in actin mRNA levels and incorporation of35S-methionine into actin in the rat hypothalamus

1. The in vitro incorporation of 35S-methionine into actin and total soluble proteins, as well as the levels of actin mRNA, were studied in the hypothalamus and frontal cerebral cortex of adult male rats killed at six different time intervals during a 24-hr cycle. 2. The specific activity of total soluble proteins after labeled methionine incubations did not vary as a function of time of day in any of the examined brain regions. 3. The incorporation of 35S-methionine into a 43-kDa protein, corresponding to the electrophoretic mobility of actin, varied diurnally in the hypothalamus, exhibiting a maximum at 1200 hr. Such a diurnal variation was not found in frontal cerebral cortex. 4. Similar results were obtained when labeled methionine incorporation into actin was assessed in hypothalamus and cerebral cortex by an immunoprecipitation procedure. 5. An increase in actin hypothalamic mRNA levels, quantitated by dot-blot analysis, was found at 0800, 4 hr in advance to the maximum in 35S-methionine incorporation to actin. 6. The levels of actin mRNA did not vary significantly as a function of time of day in the frontal cerebral cortex.     

Metabolism of glycosaminoglycans in tissues of adjuvant arthritic rat

The metabolic changes in the connective tissue glycosaminoglycans were studied in tissues of adjuvant induced arthritic rats. Arthritic process was induced in rats with the inoculation of Freund's adjuvant containing heat killed Mycobacterium tuberculosis in paraffin oil. The connective tissue glycosaminoglycans were fractionated into sulfated and non-sulfated glycosaminoglycans by chemical and enzymatic methods. The biosynthesis of sulfated glycosaminoglycans was examined using radioactive labeled (³⁵S)-sulfate incorporation measurements into the sulfated glycosaminoglycans in tissues such as liver, kidney, spleen and skin of arthritic rats. The catabolism of glycosaminoglycans was studied by measuring the activity of various connective tissue degrading lysosomal glycohydrolases in tissues of experimental animals. In addition, the changes in the contents of total glycosaminoglycans, mono-sulfated, highly-sulfated and non-sulfated glycosaminoglycans were quantitatively assessed in diseased tissues. Alterations in the metabolism of connective tissue glycosaminoglycans were demonstrated in tissues of arthritic rats. The uptake of (³⁵S)-sulfate into the tissue was found to be increased in liver, kidney and spleen, while that of skin decreased during the process of arthritis. The total glycosaminoglycan content was significantly elevated in diseased tissues compared to normal. Similarly, mono-sulfated, highly-sulfated and non-sulfated glycosaminoglycans were found to be increased in arthritic tissues. In addition, the activity of various connective tissue degrading lysosomal glycohydrolases such as -glucuronidase, -N-acetylglucosaminidase, cathepsin B, cathepsin L and collagenolytic cathepsin was increased in tissues of arthritic rat. The results presented in this communication indicate that the characteristic alterations were induced in the metabolism of glycosaminoglycans by the dynamic process of adjuvant arthritis.     

Effect of repeated stress and administration of phenobarbital on the lymphoid tissue and on protein metabolism in the lymphocytes of infant and adult rats

Further study of the response to chronic stress stimulation in the early postnatal phase showed that the i.p. injection of physiological saline (stress stimulation) induced lymphopenia, a 50% decrease in the incorporation of 3H-leucine into isolated lymphocytes and a decrease in the weight of the thymus in 7-day-old male rats. No such changes were observed in adult animals. If repeated doses of phenobarbital were administered to stressed young rats, however, lymphopenia did not occur and the rate of the incorporation of 3H-leucine into isolated lymphocytes was not different from the control value; the protein content of the lymphocytes was significantly raised, however. In adult animals, phenobarbital increased the rate of incorporation of 3H-leucine into the lymphocytes. The repeated administration of phenobarbital reduced the weight of the thymus in both young and adult animals, but a decrease in spleen weight was recorded only in the young animals. A single i.p. injection of ACTH or dexamethasone caused lymphopenia and slowed down the incorporation of 3H-leucine into the lymphocytes of both young and adult animals. The results show that the striking decrease observed in the rate of the liver metabolism of corticosterone in suckling young rats not injured by repeated stress stimulation is accompanied by significant changes in the lymphoid tissue.     

Galanin influences vasopressin and oxytocin release from the hypothalamo-neurohypophysial system of salt loaded rats.

Galanin is a peptide present in the nervous system and peripheral tissues which exerts a broad range of physiological functions. The influence of centrally administered galanin (Gal; 100 pM i.c.v.) on arginine vasopressin (AVP) and oxytocin (OT) content in the hypothalamus and neurohypophysis as well as on their blood plasma concentration was estimated in male Wistar rats drinking ad libitum 2% solution of natrium chloride per 48 hours. In euhydrated rats and subsequently applied i.c.v. with Gal a significant fall in the hypothalamic and neurohypophysial content of OT but not AVP was observed, however, without simultaneous changes in these neurohormones blood plasma concentration. On the contrary, i.c.v. injection of Gal to salt-loaded rats caused a marked raise in AVP and OT level in the hypothalamus and neurohypophysis with subsequent diminution of both neurohormones concentration in blood plasma. These results suggest that in euhydrated rats Gal has an inhibitory influence on the biosynthesis as well as axonal transport of OT, but not AVP. On the contrary, in salt-loaded rats galanin restricts secretion of both neurohormones into the systemic circulation.     

Sites and regulation of carnitine biosynthesis in mammals

Although the pathway of carnitine biosynthesis in mammals is known, the location of active synthesis of carnitine and regulation of the pathway have not been clearly defined. Studies in several laboratories have shown that the enzymes that collectively convert epsilon-N-trimethyllysine (epsilon-N-TML) to gamma-butyrobetaine are found in all tissues studied in rats and humans, but distribution of the final enzyme of the pathway, gamma-butyrobetaine, 2-oxoglutarate dioxygenase (gamma-butyrobetaine hydroxylase) is variable from one species to another. Evidence from studies in rats and humans indicates that uptake and metabolism of epsilon-N-TML by the kidney is necessary for carnitine biosynthesis from circulating epsilon-N-TML. Limited data now available suggest that some of the intracellularly derived epsilon-N-TML is metabolized to gamma-butyrobetaine and carnitine in the tissue of origin, and some is released into the circulation. epsilon-N-TML in mammals is apparently derived from lysine residues in proteins, which are methylated and later released by protein hydrolysis. This source probably provides sufficient substrate for carnitine biosynthesis. Carnitine biosynthesis from epsilon-N-TML is not regulated by end-product feedback mechanisms. Hepatic gamma-butyrobetaine hydroxylase activity in rats and humans is developmentally regulated, and is increased by dietary L-thyroxine in adult rats. No other mechanisms for regulation of carnitine biosynthesis have been identified.