Age-dependent changes in brain protein synthesis in the rat

Brain protein synthesis was studied in vivo, in brain slices, and in cell-free systems in rats aged 1, 16, and 24 months. We observed a highly significant reduction in amino acid incorporation with advancing age. This reduction was observed in vivo, in slices, in postmitochondrial supernatant, microsomes, and membrane-bound polysomes. Free heavy polysomes showed no age-dependent decline but formed a smaller proportion of total ribosomes in older animals. These studies suggest that in the rat brain protein synthesis declines before senescence, possibly due to an impairment in the initiation process.     

Effect of phenylalanine on protein synthesis in the developing rat brain

1. Inhibition of the rate of incorporation of [(35)S]methionine into protein by phenylalanine was more effective in 18-day-old than in 8-day-old or adult rat brain. 2. Among the subcellular fractions incorporation of [(35)S]methionine into myelin proteins was most inhibited in 18-day-old rat brain. 3. Transport of [(35)S]methionine and [(14)C]leucine into the brain acid-soluble pool was significantly decreased in 18-day-old rats by phenylalanine (2mg/g body wt.). The decrease of the two amino acids in the acid-soluble pool equalled the inhibition of their rate of incorporation into the protein. 4. Under identical conditions, entry of [(14)C]glycine into the brain acid-soluble pool and incorporation into protein and uptake of [(14)C]acetate into lipid was not affected by phenylalanine. 5. It is proposed that decreased myelin synthesis seen in hyperphenylalaninaemia or phenylketonuria may be due to alteration of the free amino acid pool in the brain during the vulnerable period of brain development. Amyelination may be one of many causes of mental retardation seen in phenylketonuria.     

Age-dependent degradation of amyloid precursor protein in the post-mortem mouse brain cortex

We have examined the degradation of amyloid precursor protein (APP) in the brain cortex of adult (24±2) and old (58±2) mice at different post-mortem time intervals (0, 1.5, 3, 6, 12 and 24 h). The brain cortex extract was prepared and processed for immunoblotting using antibodies against N-terminal 47–62 amino acids (Asp29) and central 301–316 amino acids containing Kunitz protease inhibitor (KPI) domain (Asp45) of APP. Asp29 (N-terminal) recognizes two bands of 140 and 112 kDa. The amount of 140 kDa is relatively higher in adult than old. The level of 112 kDa is 1.6 times lower in adult than old. It shows no remarkable change with varying post-mortem time. On the other hand, Asp45 (KPI) detects two bands of 110 and 116 kDa. While 116 kDa disappears rapidly after death of the animal, 110 kDa shows no remarkable change with different post-mortem periods. Further incubation of the disrupted tissue at 4 °C for 24 h and immunoblot analysis with Asp29 (N-terminal) shows 112 kDa in both ages but 58.5 kDa in adult and 70 kDa in old only. Analysis with Asp45 (KPI) shows only 54 kDa which increases after 3 h in adult but decreases significantly after 1.5 h and becomes undetectable at 24 h in old. Thus the present findings indicate that APP is degraded in a precise pattern and it depends on cellular intactness, post-mortem period and age of the animal.     

Utilization of tyrosine and tryptophan for protein synthesis by undernourished developing rat brain

Incorporation of tracer doses of radiolabeled tryptophan and tyrosine into brain proteins was investigated in rats malnourished during gestation and lactation. Age and time dependent increases in the radioactivity was observed in the whole homogenate and in the TCA insoluble fraction. Protein malnourished rats showed increased incorporation of tryptophan and tyrosine. However the diet restricted (Pair-fed) animals showed increased incorporation of tyrosine only. The increased incorporation may probably be due to changes in the pool size of the amino acids and effective recycling of the amino acids. The enhanced utilization in protein synthesis may also probably offer a mechanism for conservation of these amino acids.     

Effects of hypothyroidism on RNA synthesis in the adult rat brain

In this study we investigated the effects of hypothyroidism on adult brain RNA synthesis. Our data show that in the cerebral hemispheres of hypothyroid rats there is a decrease in microsomal RNA content and microsomal [³H]uridine incorporation. Sucrose gradient analysis revealed that these changes are mainly associated with free ribosomes and subunits and reflect changes in rRNA. The above changes are accompanied by a decrease in RNA polymerase I activity. All of the above mentioned changes returned to normal after thyroxine (T₄) treatment. In contrast to RNA polymerase I, RNA polymerase II activity was not affected. However, electrophoretic analysis of the in vitro poly(A)⁺RNA translation products revealed that hypothyroidism affects a few mRNAs. These results indicate that thyroid hormones have a role in adult brain tissue metabolism.     

Stimulation of tubulin synthesis by thyroid hormone in the developing rat brain

The effect of triiodothyronine on the biogenesis of tubulin has been studied in the developing rat brain. In organ cultures of brains from newborn rats, the hormone stimulates the incorporation of [14C]leucine into tubulin by 60-80% within 2 h in the absence of any significant change in total protein synthesis. This stimulation is strictly age-dependent (only brains from late fetal or newborn rats are sensitive), dose-dependent (stimulation increases progressively and reaches a maximum level with physiological dose of the hormone) and displays tissue specificity. The temporal correspondence of the sensitivity of the rat brain to triiodothyronine with the period of normal rise in the level of tubulin and that of the maximal level of nuclear triiodothyronine receptors in the brain strongly suggests the involvement of the hormone in regulating the biogenesis of tubulin during the differentiation and maturation of neonatal rat brain.     

Age-dependent modifications of mitochondrial proteins in cerebral cortex and striatum of rat brain

The protein composition of free mitochondria purified from cerebral cortex and striatum during aging was analyzed by gel electrophoresis. Mitochondria were isolated from cerebral cortex and striatum of 4-, 12-, and 24-month-old rat brain. The percent amount of mitochondrial proteins after gel-electrophoretic separation was determined densitometrically. A significant decrease in the amount of two polypeptides (with molecular weights of 20 and 16 kDa, respectively) in both brain regions during aging was found. The decrease was higher in the striatum indicating a greater vulnerability of this brain area to the aging process. The age-dependent modifications of mitochondrial proteins observed may play an important role in several mitochondrial functions, such as energy transduction and transport processes as well as in structural changes occurring with age, causing altered membrane permeability and fluidity.     

Protein synthesis by membrane-bound and free ribosomes of the developing rat cerebral cortex

1. Rates of RNA and protein synthesis were measured in rat cerebral-cortex slices, and compared with amino acid incorporation into protein by membrane-bound and free ribosomes from the same tissue, in the first 3 weeks of life. 2. A rapid age-dependent decline in the incorporation of labelled precursors into both RNA and protein was observed, which was more marked for amino acid incorporation into protein. 3. Although membrane-bound ribosomes comprise only a small fraction of total ribosomes, they were more active in incorporating amino acids into protein than were free ribosomes, especially immediately after birth. The decline in activity with age was more marked in the membrane-bound fraction than in free ribosomes. This loss of activity was largely independent of alterations in soluble factors or endogenous mRNA content and appeared to involve some alteration of the function of the ribosome itself, with relatively small alterations in the ratio of membrane-bound to free ribosomes. 4. Thyroidectomy, performed soon after birth, had no effect on the incorporation of radioactive precursors into RNA or protein by either slices or the cell-free preparations during the first 3-4 weeks of life.     

Coding of tactile stimulus amplitude by neuronal ensembles in the somatosensory cortex of the rat brain

Dependence of the neuronal excitatory responses in a barrel column of the primary somatosensory cortex on the amplitude of bending of a central vibrissa within the receptive field was studied in rats. The neurons localized at a layer IV level were shown to represent a region of the hierarchically organized thalamic input to a barrel column, which possesses the highest sensitivity to the variation of the stimulus amplitude. Concept is substantiated here whereby coding of the stimulus amplitude is based on the afferent impulsation-induced modulation of a structurally preformed gradient of synaptical efficiency in the specific input to a column.Neirofiziologiya/Neurophysiology, No. 2, Vol. 27, pp. 83–92, March–April, 1995.     

The inhibition of protein synthesis in a rat brain system by ethionine in vitro and in vivo

Abstract— An amino acid incorporating system from rat brain has been used to study in vitro four aspects of protein synthesis: amino acid-AMP-enzyme complex formation; amino acid-tRNA synthesis; amino acid incorporation into protein and protein synthesis from presynthesized amino acid-tRNA. Ethionine (0.5 mm ) inhibited the system and the inhibition appeared to be in the formation of amino acid-tRNA. The inhibition in vitro was independent of the sex of the animal from which the system was derived. Pretreatment of animals in vivo with ethionine yielded in females only preparations deficient in incorporating capacity when tested in vitro. Exchange experiments demonstrated that the defect was in the pH 5 enzymes and not in the ribosomes. The inhibition in vitro was not reversed by addition of ATP and appeared to be competitive with the amino acid substrate.     

Mechanism of the inhibition of protein synthesis by vasopressin in rat liver

A recent study reported that protein synthesis was inhibited in rat livers perfused with medium containing vasopressin (Chin, K. -V., Cade, C., Brostrom, M. A., and Brostrom, C. O. (1988) Int. J. Biochem. 20, 1313-1319). The inhibition of protein synthesis caused by vasopressin was associated with a disaggregation of polysomes, suggesting that peptide chain initiation was slowed relative to elongation. In contrast, Redpath and Proud (Redpath, N. T., and Proud, C. G. (1989) Biochem. J. 262, 69-75) recently reported an inhibition of peptide chain elongation by a calcium/calmodulin-dependent mechanism. Therefore, the question remained whether only peptide chain initiation was inhibited or both initiation and elongation were affected by vasopressin. In the present study, vasopressin was found to inhibit protein synthesis in both perfused rat livers and isolated rat hepatocytes. Ribosomal half-transit times in isolated hepatocytes averaged 1.9 +/- 0.1 min with or without vasopressin present in the media, demonstrating that the rate of peptide chain elongation was unaffected by vasopressin. Instead, the inhibition of protein synthesis induced by vasopressin was manifested at the level of peptide chain initiation. Vasopressin treatment resulted in both a 2-fold increase in the number of free ribosomal particles and a greater than 50% decrease in the amount of [35S]methionine bound to 43 S preinitiation complexes. In addition, the activity of eukaryotic initiation factor (eIF) 2B in crude extracts from perfused livers was reduced to 53% of the control value in response to vasopressin. The inhibition of eIF-2B activity was associated with an increase in the proportion of the alpha-subunit of eIF-2 in the phosphorylated form from 9.6% in control livers to 30.7% in livers perfused with medium containing vasopressin. The results demonstrate the novel finding that the inhibition of protein synthesis in vasopressin-treated livers is caused by a reduction in eIF-2B activity due to an increase in phosphorylation of eIF-2 alpha.     

Effect of hypothyroidism on the labeling of the various RNA species in developing rat brain

The effect of hypothyroidism on the in vitro incorporation of [³H]uridine into different RNA species in tissue slices of rat cerebral hemispheres at 5, 10, 15, and 21 days of age has been investigated. Gel electrophoresis analysis of total, nuclear and microsomal RNA was also accomplished. The results obtained indicate that RNA labeling is differently influenced by hypothyroidism at the various ages examined. RNA labeling is not significantly affected at 5 days of age while at later ages and especially at 21 days it is higher in hypothyroid rats compared to the controls. Moreover distinct differences at the various ages in the transport of newly synthesized RNA from the nucleus to the cytoplasm in the two groups of animals were found. These results are in agreement with the hypothesis that thyroid hormone deficiency causes a delay of the processes of cell proliferation and differentiation in developing rat brain.     

HMG-2 protein in developing rat brain cells

• 1.1. The distribution of HMG-2 protein was followed in unfractionated rat brain cells at different stages of development. Its amount gradually decreased and reached the lowest level in the terminally differentiated and non-proliferating cells.
• 2.2. In isolated oligodendrocyte nuclei the changes in the content of HMG-2 followed the same pattern of distribution which corresponded to their stage of development and proliferative activity, while in the terminally differentiated and non-proliferating cortical neurons a substantial amount of HMG-2 protein was present up to the twenty-eighth postnatal day.
• 3.3. In the presence of anti-HMG-2 antibodies the DNA synthetic activity of oligodendrocyte nuclei in vitro was significantly decreased. The treatment with antibodies affected mainly the DNA replicative activity of the nuclei, while their DNA repair activity remained unchanged.

     

Modes of neuronal migration in the developing cerebral cortex

The conventional scheme of cortical formation shows that postmitotic neurons migrate away from the germinal ventricular zone to their positions in the developing cortex, guided by the processes of radial glial cells. However, recent studies indicate that different neuronal types adopt distinct modes of migration in the developing cortex. Here, we review evidence for two modes of radial movement: somal translocation, which is adopted by the early-generated neurons; and glia-guided locomotion, which is used predominantly by pyramidal cells. Cortical interneurons, which originate in the ventral telencephalon, use a third mode of migration. They migrate tangentially into the cortex, then seek the ventricular zone before moving radially to take up their positions in the cortical anlage.     

Protein synthesis in neuronal perikarya isolated from cerebral cortex of the immature rat

Abstract— Homogenates of neuronal perikarya isolated from the cerebral cortex of the 8-day-old rat were incubated with [³H]leucine, and the characteristics of the protein synthetic process were studied. Incorporation of leucine into protein was linear up to 90 min, proceeded optimally at pH 7.6 and was stimulated by K⁺ and NH₄⁺, unaffected by Li⁺ and inhibited by Na⁺. Puromycin, cycloheximide, RNAse, sulphhydryl blocking agents and phospholipase A exerted a pronounced inhibition, whereas chloramphenicol and phospholipase C had no effect. About 42 per cent of the total radioactive protein formed in the optimally fortified in uitro system was recovered in non-sedimentable form. Incorporation into the subcellular fractions of the neuronal perikarya increased steadily with increasing time of incubation. The microsomal fraction acquired the highest specific radioactivity (d.p.m./mg of protein), followed by the mitochondrial and the nuclear + cell debris fractions. The high-speed soluble fraction exhibited the lowest specific radioactivity. Although the addition of L-methionine to a suitably fortified incubation medium inhibited neuronal protein synthesis by about 80 per cent, the addition of D-methionhe, α-methyl-DL-methionine or L-tryptophan was relatively ineffective by comparison.     

Neonatal undernutrition and RNA synthesis in developing rat brain

—Underfeeding of newborn rats results in a decreased body and brain weight at 10, 20 and 30 days of age. The DNA and RNA content of the brain in these animals are similar to those of normal controls. The in vivo and in vitro synthesis of RNA in brain is significantly decreased in undernourished rats at 10 days of age when compared with controls. The metabolic transformation of ³H-orotic acid to nucleotides is also diminished. A short period of food rehabilitation produces -an improvement in the above mentioned alterations. However, a reduced incorporation of label into microsomal RNA persists even in the last condition. The results suggest that malnutrition, during the first days of life, alters the metabolism of cerebral RNA.     

Prostaglandin synthesis inhibition and monoamine metabolites in the rat brain

The effect of indomethacin 3 mg/kg on levels of homovanillic acid (HVA), 4-hydroxy-3-methoxy phenyl ethylene glycol (HMPG) and 5-hydroxy indol acetic acid (5HIAA) was studied in rat striatum and olfactory tubercle with and without pretreatment with morphine 10 mg/kg. Indomethacin caused a small decrease in resting levels of HVA in striatum but not in olfactory tubercle. No effects were seen on resting or morphine induced changes in the levels of these monoamine metabolites. Likewise indomethacin 20 mg/kg failed to alter the elevation of HVA induced by chlorpromazine 15 mg/kg or the decrease of HVA induced by apomorphine (1–10 mg/kg) in the rat striatum. Our results do not support a major role for endogenous prostaglandins in the modulation of monoamine neurotransmission in the rat brain.