The role of isoacceptor transfer RNAs in regulation of age-related changes in the rate of protein synthesis

In cell-free protein-synthesizing systems containing an S30 extract from liver and brain cortex tissues of 22-day-old fetuses and of male WAG rats (1-900 days old), the minimal rate of protein synthesis was observed in the fetuses, while the maximal one - in 7-day-old animals. The difference in the rates of protein synthesis correlated with the minimal concentration of total tRNA in the former group and with its maximal concentration in the latter. In fetal tissues, an addition to cell-free systems of total tRNA isolated from homologous tissues of 7-day-old animals augmented protein synthesis up to a level observed in 7-day-old animals, whereas in the tissues of animals belonging to other age groups total tRNA had a far less pronounced stimulating effect which decreased with age. Fractionation of total tRNA and analysis of effects of individual tRNAs on protein synthesis demonstrated that the stimulating influence was induced by tRNA(2Arg), tRNA(4Arg) and tRNA(2Val) from brain cortex and by tRNA(2Leu), tRNA(5Leu), tRNA(2Val), tRNA(1Met) and tRNA(2Met) from liver.     

The effect of protein depletion and repletion on muscle-protein turnover in the chick.

Rates of growth and protein turnover in the breast muscle of young chicks were measured in order to assess the roles of protein synthesis and degradation in the regulation of muscle mass. Rates of protein synthesis were measured in vivo by injecting a massive dose of L-[1-14C]valine, and rates of protein degradation were estimated as the difference between the synthesis rate and the growth rate of muscle protein. In chicks fed on a control diet for up to 7 weeks of age, the fractional rate of synthesis decreased from 1 to 2 weeks of age and then changed insignificantly from 2 to 7 weeks of age, whereas DNA activity was constant for 1 to 7 weeks. When 4-week-old chicks were fed on a protein-free diet for 17 days, the total amount of breast-muscle protein synthesized and degraded per day and the amount of protein synthesized per unit of DNA decreased. Protein was lost owing to a greater decrease in the rate of protein synthesis, as a result of the loss of RNA and a lowered RNA activity. When depleted chicks were re-fed the control diet, rapid growth was achieved by a doubling of the fractional synthesis rate by 2 days. Initially, this was a result of increased RNA activity; by 5 days, the RNA/DNA ratio also increased. There was no evidence of a decrease in the fractional degradation rate during re-feeding. These results indicate that dietary-protein depletion and repletion cause changes in breast-muscle protein mass primarily through changes in the rate of protein synthesis.     

Brain Slice Protein Degradation and Development

Protein degradation rates were measured in brain slices prepared from rats of various ages. This was done by adding the protein synthesis rate, determined by incorporation of a labeled precursor, and the net protein degradation rate, determined by measuring the changes with time of total free amino acids. These rates are about 30% higher than those previously calculated from data on protein synthesis rates and protein accumulation rates in vico. The protein degradation rates in brain slices diminish with age; i.e., 2-day cerebellum > 2-day cerebral hemisphere > 12-day cerebral hemisphere > young adult cerebral hemisphere. Protein degradation rates in slices from young brain are initially slightly higher than protein synthesis rates, resulting in a small net degradation with time. Unlike slices from adult brain, the protein degradation rates in slices from young brain decline only modestly with time for as much as 100 min of incubation. The characteristics of protein degradation in brain slices from young animals are roughly similar to some of the data calculated for protein degradation in vivi. suggesting that this system may prove useful for studying factors which control or affect brain protein degradation.     

Analysis of effect of age on synthesis of specific proteins by hepatocytes

The effect of age on the synthesis of specific proteins by hepatocytes was studied in Fischer F344 rats using two-dimensional polyacrylamide gel electrophoresis. Almost all proteins synthesized by hepatocytes from young rats were synthesized by hepatocytes isolated from old rats. Of over 500 proteins visually compared by two-dimensional polyacrylamide gel electrophoresis, only 11 proteins were observed to disappear and/or appear consistently with increasing age. The rates of synthesis of 36 randomly chosen proteins were quantified. Interestingly, the synthesis of 35 of the 36 proteins decreased between 5 and 30 months of age. The decrease in protein synthesis varied (15% to 70%) from one protein to another; i.e., a heterogeneity was observed in the age-related decrease in the synthesis of proteins. The age-related decrease in protein synthesis was statistically significant for 53% of the proteins studied. The total decrease in the rate of synthesis of all 36 proteins studied was 40% between 5 and 30 months of age, which is essentially the same as the decrease in total protein synthesis by suspension of hepatocytes isolated from 5- and 30-month-old rats. The results of this study demonstrate that the mechanism underlaying aging is different from development, which is characterized by a major change in the species of proteins synthesized by a cell.     

The relation of protein synthesis to the concentrations of free and membrane-bound ribosomes in brain at different ages

Free and membrane-bound ribosomes were prepared from the brains of young (3- and 8-day-old) and adult (30 day) rats by the method of Ramsey and Steele (1977). Though the concentration of RNA in young brain is higher than that in adult brain, the fraction of the RNA which is ribosomal is virtually the same (64%) as is the ratio of free ribosomes total ribosomes (61%) at all ages studied. The rate of protein synthesis measured in vivo, expressed in the usual terms of “% per h”, is much higher in young compared to adult brain, but when expressed as the ribosomal specific activity, i.e. “mg protein synthesized per hour per mg ribosomal RNA”, is the same in the three age groups (0.61, 0.58 and 0.60, respectively). Thus, even during early development, when protein is increasing rapidly, ribosomes are no more active than in adult brain, suggesting that synthesis rates in brain are limited by ribosomal content.     

Age-related changes of protein- and RNA-synthetic processes in experimental hyper- and hypothyroidism

The rate of liver and plasma protein synthesis and the activity of liver RNA polymerases 1 and 2 were investigated in rats of various age under experimental hyper- and hypothyroidism. The rate of plasma protein synthesis decreased with age more dramatically than that of liver proteins. Hyper- and hypothyroidism exerted opposite effects on protein synthesis in rats: stimulation and inhibition, respectively. The manifestation of these effects was age related. The thyroid status of animals also influenced the balance of protein synthesis. Thyroxin administration caused preferential incorporation of a label into blood plasma proteins. Changes of thyroid status of old animals insignificantly affected the absolute values of the label incorporation into proteins and the ratio of the label incorporation into local and secreted liver proteins. Age-related decrease of total hepatic nuclear RNA-polymerase activity was due to reduction of the template-bound functionally active forms of RNA-polymerases 1 and 2. Administration of thyroxin caused initial redistribution of the enzyme activity between template-bound and free fractions accompanied by the increase of template bound RNA-polymerases. Prolonged hormonal stimulus also caused an increase of free RNA-polymerases, which reflects the increased synthesis of these enzymes. Mecrazolyl administration reduced the activity of RNA-polymerase 1 and 2. All age groups were characterized by preferential reduction of the bound form. RNA-polymerase 2 activity decreased to a greater extent than that of RNA-polymerase 1. The data suggest age-determined reactions of the body to altered thyroid status.     

Polyribosome disaggregation and cell-free protein synthesis in preparations from cerebral cortex of hyperphenylalaninemic rats

Abstract— Seven-day-old rats were injected intraperitoneally with l -phenylalanine (1 g/kg) and the time course of brain polyribosome disaggregation and changes in brain levels of phenylalanine, tryptophan and tyrosine were determined. Disaggregation of brain polyribosomes preceded the increase in levels of phenylalanine in brain, and followed the same time course as depletion of tryptophan from brain. The effects of several metabolites of phenylalanine (which are formed in phenylketonuria) on protein synthesis in vitro was determined for brain and liver systems. None of the compounds tested was inhibitory at concentrations below 10 mM and in all cases hepatic protein synthesis was more sensitive to inhibition than was the corresponding system from brain. Ribosomal dimers, formed in brain after injection of phenylalanine, were incapable of supporting high levels of protein synthesis in vitro, a finding that suggested that the inhibition of protein synthesis in vitro in cell-free systems of brain tissue after injection of phenylalanine into young rats was mediated by disaggregation of brain polyribosomes associated with tryptophan deficiency in brain.     

RIBOSOMAL ACTIVITY IN PRENATAL MOUSE BRAIN

Abstract— Regulation of protein synthesis is important for the proper growth and development of the brain. Our previous work on the regulation of protein synthetic activity in fetal mouse brain cell suspensions showed that the rate of protein synthesis decreased during the prenatal period. In the present study, ribosomal activity of cell-free homogenates and purified ribosomes obtained from fetal neural tissue was measured. The post-mitochondrial supernatant (PMS) fraction actively incorporated amino acids into polypeptides using either endogenous mRNA or polyuridylic acid as template. The protein synthetic activity was dependent upon the age of the fetus. Ribosomes purified from this fraction were also active in protein synthesis. Incorporation of phenylalanine was linear for 20 min, and dependent upon the concentration of ribosomes and the pH 5 enzyme fraction. The age dependent decrease in protein synthetic activity observed with the post-mitochondrial supernatant fractions was not found when these purified ribosomes were employed. Ribosomes obtained from fetal, newborn or adult neural tissue were compared and found equally active in their protein synthetic capacity.     

Purification of a new acidic glutathione S-transferase, GST-Yn1Yn1, with a high leukotriene-C4 synthase activity from rat brain

A new acidic form of glutathione S-transferase (GST, pI 6.2) was purified from rat brain by S-hexylglutathione affinity chromatography followed by chromatofocusing. This form occupied 20-25% of the total activity bound to the affinity column. It had a molecular mass (subunit 26 kDa) similar to that of a major GST form of rat testis (MT or 6-6) on sodium dodecyl sulfate/polyacrylamide gel electrophoresis. However, it differed from the MT in isoelectric point, activity towards 1,2-dichloro-4-nitrobenzene and immunological properties. On two-dimensional gel electrophoresis the brain form gave a spot which was identical in molecular mass, isoelectric point and immunological properties to a less acidic one (Yn1) of two spots (Yn1 and Yn2) of the testis GST-MT. Therefore, the brain acidic form is a homodimer, and named GST-Yn1Yn1. The activity was inhibited by sulfasalazine, an inhibitor of leukotriene-C4 synthase. This form (GST-Yn1Yn1) showed the highest leukotriene-C4 synthase activity, 496 nmol/mg protein in 5 min, among nine cytosolic GST isoenzymes from the rat. The Km values for leukotriene A4 and glutathione were 26 microM and 3.5 mM respectively. A major GST form of rat brain, occupying about 40% of the total activity, was identical with GST-P (7-7) purified from rat liver bearing preneoplastic hyperplastic nodules and localized at astroglias. GST-P also showed the significant leukotriene-C4 synthase activity, 67.2 nmol/mg protein in 5 min, but the Km for leukotriene A4 was 100 microM, fourfold higher than that of GST-Yn1 Yn1. These results suggest that mainly GST-Yn1 Yn1 may be involved in leukotriene-C4 synthesis in rat brain.     

DEVELOPMENTAL AND REGIONAL VARIATIONS IN NEUROTRANSMITTER-SENSITIVE ADENYLATE CYCLASE SYSTEMS IN CELL-FREE PREPARATIONS FROM RAT BRAIN

Investigations have been carried out on regional and developmental variations in the properties of adenylate cyclase systems in participate preparations from rat brain. EGTA was routinely included in the assay medium to minimize differences in the state of activation of these systems resulting from variations in their exposure to endogenous Ca²⁺. At birth, adenylate cyclase activity was much higher in the hindbrain-medullary preparations than in comparable fractions from cerebellum, cerebral cortex or subcortex (including midbrain, corpus striatum, hypothalamus and hippocampus). Adenylate cyclase activity increased during early development in preparations from all areas of the brain. Maximal levels were reached at 14 days of age or later. These levels were not greatly altered in the young adult animal, except in the hindbrain-medullary area, where a decrease in activity was observed. Adenylate cyclase systems in cerebral cortical and subcortical preparations were activated by norepinephrine and dopamine throughout development. Serotonin also stimulated adenylate cyclase activity in these preparations from young animals but was much less effective in comparable fractions from adult rats. The response to dopamine was diminished with age in cerebral cortical preparations, but not in subcortical fractions. The responses to norepinephrine increased in both brain regions during early development. Adenylate cyclase systems in particulate preparations from the cerebellum and hindbrain-medullary areas exhibited relatively poor responses to the biogenic amines. Detailed studies of the properties of the cerebral cortical adenylate cyclase systems revealed enhancement of activity by Ca²⁺ and F^? at all stages of development with the maximal activation at 2–3 weeks of age. The results suggest that developmental differences in hormonal sensitivity of adenylate cyclase systems from diverse areas of the brain are related to changes in the proportions of the receptor-enzyme complexes responsive to the different biogenic amines.     

MYELIN SYNTHESIS IN VITRO: A COMPARATIVE STUDY OF CENTRAL AND PERIPHERAL NERVOUS TISSUE

Abstract— Brain, spinal cord and sciatic nerve from rats at different ages were incubated for 2 h in a medium containing [¹⁴C]acetate and [¹⁴C]leucine as the precursors for synthesis of lipids and proteins. Myelin was purified from the incubated tissues and the specific and total radioactivites of myelin lipids and protein were determined. The uptake of radioactive precursors decreased with increasing age up to 6 months of postnatal age, the decrease following the same pattern for the three types of myelin. After age 6 months the uptake of the protein and lipid precursors reached a plateau that persisted up to 18 months, the oldest postnatal age studied. The amount of myelin isolated and the total myelin lipids extracted from both the central and peripheral nervous systems increased continuously from age 25 days to 18 months after birth. Consequently we suggest that myelination is a process that continues during the whole life of the rat.
The metabolic activity of peripheral nerve myelin was higher than myelin from the CNS at all ages studied. Although myelination in the sciatic nerve begins before that in brain and spinal cord, the three types of myelin apparently reach maturity at the same age. Lecithin exhibited the highest metabolic activity of the individual myelin lipids at all ages in both the central and peripheral nervous system. The metabolic activity of cholesterol in myelin from the 25-day-old rats was similar to that of lecithin but decreased to very low levels in myelin from the 18-month-old rats.     

IN VITRO BIOSYNTHESIS OF TUBULIN ON TOTAL, FREE AND MEMBRANE-BOUND POLYSOMES FROM THE DEVELOPING RAT BRAIN

Abstract— Incorporation of [³H]leucine into tubulin and total protein was examined using a polysomal system from newborn (1-day-old). young (10-day-old) and adult (3-month-old) rat brains and cerebral cortices. The rate of tubulin biosynthesis (specific radioactivity) was always lower than that of total protein biosynthesis. No significant differences in the specific radioactivities of the synthesized total proteins were found between the newborn and young brain polysomal system, although young cerebral cortical polysomes were less active than newborn cerebral cortical polysomes. The adult brain (or cerebral cortical) polysomes were less active, about 20-30% lower than the young brain (or cerebral cortical) polysomes. The incorporation of [³H]leucine into tubulin showed a progressive decrease in the polysomal systems isolated from the newborn, young and adult rat brains and cerebral cortices. These tendencies were similar in every cell sap taken from newborn, young and adult rat brain homogenates.
In order to examine the relative activities of free and bound polysomes of the developing rat brain in tubulin biosynthesis. double-labelling experiments were carried out. Labelled tubulin was purified by the assembly and disassembly method, followed by SDS gel electrophoresis, or by vinblastine precipitation method, followed by SDS gel electrophoresis; then identification by co-electrophoresis with native brain tubulin, molecular weight determination and demonstration of specific aggregation in the presence of GTP followed. Free and bound polysomes showed approximately similar activities during tubulin biosynthesis. Furthermore, relative activities of tubulin biosynthesis by free and bound polysomes did not significantly change during development.     

Cerebrospinal fluid gradients of acetylcholinesterase and butyrylcholinesterase activity in healthy aging

Acetylcholinesterase (AChE) and butyrylcholinesterase (BChE) activities were measured in 13 sequential 2 ml aliquots of cerebrospinal fluid (CSF) obtained by lumbar puncture from 7 young and 7 elderly healthy normal subjects. The slopes of the rostrocaudal gradients of AChE and BChE were calculated and compared to those of total protein concentration and the major dopaminergic metabolite homovanillic acid (HVA), for which a pronounced rostrocaudal gradient (with highest concentrations of HVA in more rostral CSF) is consistent with HVA originating primarily from the brain. AChE activity was higher in more caudal fractions of young, but not elderly subjects and there was a significant difference between the mean AChE gradient slopes in the young and old groups. These results suggest that the spinal cord makes an important contribution to AChE activity in lumbar CSF. Furthermore, the absence of a negative AChE gradient in elderly subjects may be the result of a greater rate of entry of cerebral AChE into CSF, possibly as a consequence of an increased ventricular surface area and shorter diffusion distances in atrophic elderly brains. In contrast to AChE, BChE activity and total protein concentrations were higher in more caudal CSF fractions of not only young but also old subjects. In addition, there was a significant correlation between the gradient slopes of BChE activity and total protein concentrations, suggesting that the majority of BChE activity in lumbar CSF derives from the same source as the majority of total protein, namely plasma. The diffuse (i.e. brain and spinal cord) origin of AChE in lumbar CSF would explain the relatively modest changes in lumbar CSF AChE activity in diseases involving certain central cholinergic systems, most notably Alzheimer's disease.     

Changes in kynurenine pathway metabolism in the brain, liver and kidney of aged female Wistar rats

The kynurenine pathway of tryptophan catabolism plays an important role in several biological systems affected by aging. We quantified tryptophan and its metabolites kynurenine (KYN), kynurenine acid (KYNA), picolinic acid (PIC) and quinolinic acid (QUIN), and activity of the kynurenine pathway enzymes indoleamine 2,3-dioxygenase (IDO), tryptophan 2,3-dioxygenase (TDO) and quinolinic acid phosphoribosyltransferase (QPRTase), in the brain, liver and kidney of young, middle-aged and old female Wistar rats. Tryptophan levels and TDO activity decreased in all tissues with age. In contrast, brain IDO activity increased with age, while liver and kidney IDO activity decreased with age. The levels of KYN, KYNA, QUIN and PIC in brain all increased with age, while the levels of KYN in the liver and kidney showed a tendency to decrease. The levels of KYNA in the liver did not change, but the levels of KYNA in the kidney increased. The levels of PIC and QUIN increased significantly in the liver but showed a tendency to decrease in the kidney. QPRTase activity in both brain and liver decreased with age but was elevated in the kidney in middle-aged (12-month-old) rats. These age-associated changes in tryptophan metabolism have the potential to impact upon major biological processes, including lymphocyte function, pyridine (NAD(P)(H)) synthesis and N-methyl-d-aspartate (NMDA)-mediated synaptic transmission, and may therefore contribute to several degenerative changes of the elderly.     

Metallothionein-3 and neuronal nitric oxide synthase levels in brains from the Tg2576 mouse model of Alzheimer's disease

Using antiserum against the recombinant isoform 3 of mouse brain metallothionein (MT3), the amount of MT3 protein was determined in whole brain homogenates from the Tg2576 transgenic mouse model of Alzheimer's Disease. Twenty-two month old transgenic positive mice showed a 27% decrease of MT3 normalized to the total protein in the extracts compared to same age, control transgenic negative mice. Metallothioneins bind seven molar equivalents of divalent metal ions per mole of protein so metal levels also were measured in these whole brain extracts using inductively coupled plasma atomic absorption (ICP-AA) spectrometry. No significant difference was observed for any metal assayed. Because neuronal nitric oxide synthase (nNOS) is involved in neurodegenerative disease and nitric oxide specifically interacts with MT3, the concentration and total nNOS activity also were evaluated. The transgenic positive mice showed a decrease of 28% in nNOS protein compared to the same age transgenic negative mice. Normalized to the amount of nNOS protein, total NOS activity was higher in the transgenic positive mice. These data showed that protein levels of both MT3 and nNOS were reduced in transgenic positive mice that show many characteristics of Alzheimer's Disease. In vitro studies suggested that MT3 was not a likely candidate for directly affecting nNOS activity in the brain.     

Mechanism of inhibition of peptide chain initiation by amino acid deprivation in perfused rat liver. Regulation involving inhibition of eukaryotic initiation factor 2 alpha phosphatase activity.

In previous studies, initiation of protein synthesis was shown to be inhibited in perfused rat livers deprived of single essential amino acids. In the present study, histidinol, a competitive inhibitor of histidinyl-tRNA synthetase, was used to amplify the effects of histidine deprivation on protein synthesis in perfused liver to facilitate investigation of mechanisms involved in the inhibition of peptide chain initiation. Protein synthesis was reduced to 77% of the control rate in livers deprived of histidine and to 13% of the control rate in livers deprived of histidine and exposed to 2.0 mM histidinol. The inhibition of protein synthesis caused by histidine deprivation alone was accompanied by a 2-fold increase in the number of free ribosomal particles, a 29% decrease in Met-tRNA(i) binding to 43 S preinitiation complexes, and a 31% reduction in activity of eukaryotic initiation factor 2B (eIF-2B). By comparison, histidine deprivation combined with histidinol addition resulted in a 3-fold increase in free ribosomal particles, a 66% decrease in Met-tRNAi binding, and a 78% reduction in eIF-2B activity. The proportion of the alpha-subunit of eukaryotic initiation factor two (eIF-2) in the phosphorylated form increased from 8.9 +/- 0.8% in control livers to 52.4 +/- 5.5% in response to histidinol. The increase in the amount of eIF-2 alpha in the phosphorylated form apparently was not due to an increase in kinase activity, because there was no change in eIF-2 alpha kinase activity in extracts of liver perfused with medium containing histidinol compared to controls. Instead, the increased phosphorylation of eIF-2 alpha was associated with an inhibition of eIF-2 alpha phosphatase activity. Thus, in contrast to other systems that have been examined, the mechanism involved in the increase in the phosphorylation state of eIF-2 alpha appears to involve an inhibition of eIF-2 alpha phosphatase activity rather than activation of an eIF-2 alpha kinase.