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.     

RNA METABOLISM IN ISOLATED MOUSE BRAIN NUCLEI DURING EARLY POSTNATAL DEVELOPMENT

—RNA metabolism in isolated brain nuclei has been shown to be dramatically altered during early postnatal brain development. The present study involved an examination of the RNA products synthesized by nuclei at various stages of postnatal neural maturation. In all cases, the majority of the RNA appeared to be heterodisperse, non-ribosomal and non-tRNA in nature. In comparison to the RNA isolated from nuclei of neonatal tissue, the RNA from nuclei of 12-day and 30-day-old mouse brain was found to be of smaller molecular weight. Despite the heterodisperse nature of these RNA molecules, the addition of α-amanitin did not completely inhibit nuclear synthesis. An investigation of RNA synthesis in isolated neuronal and glial cell nuclei revealed that nucleic acid metabolism in these respective cell populations had different and distinct developmental patterns. Preparations enriched with glial cell nuclei were found to be most active at birth and then decreased in activity (3–4-fold) during neural maturation. On the other hand, the rate of RNA synthesis in fractions enriched in neuronal cell nuclei was observed to increase dramatically in activity (4–5-fold) until 14 days of age. From 14 days of age until adulthood, RNA synthetic activity remained essentially the same.     

Regulation of Prenatal and Postnatal Protein Synthesis in Mouse Brain

Abstract: Regulation of protein synthesis during prenatal and postnatal brain development was examined using postmitochondrial supernatant (PMS) fractions and isolated ribosome-pH 5 enzyme systems from fetal, neonatal, and adult neural tissue. The rate of polyuridylic acid (poly-U)-dependent protein synthetic activity was inversely proportional to the endogenous rate of protein synthesis in either the PMS fractions or ribosomal preparations. A careful analysis of the kinetics of the poly-U-dependent polypeptide synthesis revealed that there was a lag in the time at which certain of the PMS preparations could begin to utilize the poly-U template as sole source of mRNA. The lag period was dependent upon the developmental age of the neural tissue used and the Mg²⁺ concentration of the protein synthesis reaction. Since previous work reported that the observed developmental decrease in the rate of polypeptide synthesis utilizing a poly-U template could not be measured in a purified ribosomal-pH 5 enzyme system, ribosomes were obtained by several isolation techniques to determine if the purification procedure might have affected the ribosomes in some manner by removing a specific protein(s) involved in ribosome-cytosol interactions. At 6 mM-Mg²⁺ the rate of poly-U-dependent protein synthesis was inversely proportional to the rate of endogenous synthesis and depended upon the method used to isolate the ribosomes: microsomes ∼Triton X-100-treated < DOC-treated < KCl-treated. However, there was no age-dependent effect with any of the ribosomal preparations. The data suggest that there is a developmental modulating effect of ribosomal activity in PMS preparations which is not found in association with the isolated ribosome-pH 5 enzyme protein synthesizing system.     

Mechanisms of stimulation of collagen synthesis during chick embryonic skin development.

To study how collagen synthesis is regulated in developing chick embryonic skin, hydroxyproline synthesis, incorporation of proline, and translational activity and content of collagen mRNA in 12-, 15-, and 18-day skins were determined and compared with each other. Hydroxyproline synthesis in the 18-day skins was markedly increased over that in the 12-day skins, whereas proline incorporation was moderately increased. The increase in collagen synthesis from day 15 to 18 was accompanied by increases in both the translational activity and the content of type I procollagen mRNA, with a selective increase in the lower-molecular-weight species of pro alpha 1 (I) collagen mRNA. In contrast, the stimulation of collagen synthesis from day 12 to day 15 did not parallel the levels of type I procollagen mRNA. These results suggest that the stimulation of collagen synthesis is regulated by collagen mRNA levels only in the later stage of development (from day 15 to day 18). Both the collagen synthesis and type I procollagen mRNA levels in the fibroblasts isolated on each corresponding day were constant. The difference in collagen synthesis under two different culture conditions suggests that cell-matrix interaction and/or some serum factors, including several growth factors, are essential for the marked stimulation of collagen synthesis observed in 12- to 18-day skin.     

CELL-FREE PROTEIN SYNTHESIS BY MOUSE BRAIN DURING EARLY DEVELOPMENT

—Cell-free homogenates were employed to study the nature of the mechanism that is responsible for the rapid decrement in protein synthesis during early neural development. There was a progressive loss of polypeptide synthesis in post-mitochondrial fractions that were isolated from increasingly older tissue. By the time the animals were approximately 17 days old, the rate of amino acid incorporation had decreased to the rate that was measured in adult brain preparations. This decrement in synthetic activity was similar to that previously measured in developing intact brain cells. The loss in protein synthesis was demonstrated to be independent of cellular membrane permeability and under the influence of intracellular control mechanisms. Although the nature of the control mechanism is still not clear, a lack of template RNA to direct protein synthesis was not the limiting factor in the decreased synthesis of the older brain preparations.     

Cell cultures of fetal rat brain : Growth and marker enzyme development

Growth and enzyme development in cell cultures of fetal rat brain were influenced by type of growth medium, cell density, and age of fetal tissue source. Cells grew better in one medium (DMEM), but the other (F12G) enhanced development of choline acetyltransferase activity. One type of growth medium (DMEM) lost efficacy 2 weeks after preparation of complete medium. Cell division rate was density dependent, and choline acetyltransferase development was related to time in culture and cell concentration. Some results suggested division of choline acetyltransferase producing cells. Differences in age of tissue source resulted primarily in differences in growth: cultures of 21 day fetal cells developed more protein per 10⁶ cells inoculated than cultures of cells from younger animals; there was little difference in enzyme activity per culture. Conditions may be controlled such that fetal rat brain cells will grow and express differentiated functions in culture in a predictable manner.     

CHARACTERISTICS AND PRODUCTS OF A CELL-FREE POLYPEPTIDE SYNTHESIZING SYSTEM FROM NEONATAL AND ADULT MOUSE BRAIN

—The regulation of protein synthesis by ribosomes isolated from mouse brain tissue was studied using a cell-free polyphenylalanine synthesizing system. Polypeptide synthesis was followed by assaying translocation and analysing the reaction products by BD-cellulose chromatography. The brain ribosomal activity could be divided by these methods into two distinct steps : binding of aminoacyl-tRNA to the ribosome and active translocation leading to subsequent polyphenylalanine synthesis. In comparison to initial binding of aminoacyl-tRNA, translocation in the cell-free system increased the incorporation of labelled phenylalanine by 10-fold. An analysis of the reaction products clearly showed active ribosomal synthesis of oligophenylalanine from [³H]phe-tRNA. Ribosomes isolated from neonatal brain tissue were 2–4 times as active as those obtained from adult brain tissue in polypeptide synthesis. In addition, polypeptides synthesized on the more active ribosomes from neonates tended to be of greater chain length than those from adult. Therefore, the maturation-dependent decrease in ribosomal protein synthetic activity during neural development was shown to be directly associated with the ribosome particles.     

Developmental patterns in rat brain of phosphatidylinositol synthetic enzymes and phosphatidylinositol transfer protein

Phosphatidylinositol synthetic and intermembrane transfer activities were studied in rat in the developing whole brain and isolated cerebellum. Specific activities of CTP: phosphatidate cytidylyltransferase and CDPdiacylglycerol: inositol phosphatidyltransferase were found to have similar developmental patterns. Levels of phosphatidyltransferase seen in fetal animals (whole brain only) and neonatal (whole brain and cerebellum) were maintained through approximately postnatal day 15, peaked at day 28, and then declined to somewhat higher than fetal levels at day 60. Cytidylyltransferase activity varied from the phosphatidylinositol synthesizing enzyme in that specific activity continued to increase up to day 60. Whole brain phosphatidylinositol transfer specific activity showed a sharp peak at postnatal day 9 after which activity was maintained at or above the fetal levels to day 60. Cerebellum phosphatidylinositol transfer specific activity had a similar peak which was delayed 7–10 days compared to the whole brain. Phosphatidylinositol transfer protein was also determined immunologically: whole brain levels increased dramatically from fetal day 16 to 18 and then remained relatively constant, while cerebellum levels (measured from postnatal day 7) displayed a variable profile between days 7 and 28. The developmental pattern of CTP: phosphatidate cytidylyltransferase in rat brain is reported here for the first time.     

BRAIN PROTEINS: QUALITATIVE AND QUANTITATIVE CHANGES, SYNTHESIS AND DEGRADATION DURING FETAL DEVELOPMENT OF THE RABBIT

The composition and metabolism of the proteins of the cerebral pallium of the rabbit during the final one-third of the gestational period were measured. During this period, the brain increased in size almost 10-fold and the migration of neuroblasts to form the cerebral cortex became complete. Concurrent with the marked structural changes, the solubility characteristics and electrophoretic distribution of various brain proteins showed little change. However, at the time of birth and in the adult, significant differences in gel electrophoresis patterns were apparent. The rate of synthesis of protein in brain slices from the fetus of 20 days gestation was 3-fold higher per mg of tissue than in the neonate and about 30-fold higher than in the adult. Activities of acidic and neutral proteases per unit weight were virtually the same and nearly constant throughout the late fetal period. However, during this stage, while rapid growth persists, the total protein synthetic activity of the pallium predominated over the total proteolytic activity, whereas sometime after birth the ratios of these activities reversed consequent to a shutdown of the synthetic process.     

Developmental patterns in rat brain of phosphatidylinositol synthetic enzymes and phosphatidylinositol transfer protein

Phosphatidylinositol synthetic and intermembrane transfer activities were studied in rat in the developing whole brain and isolated cerebellum. Specific activities of CTP:phosphatidate cytidylyltransferase and CDPdiacylglycerol:inositol phosphatidyltransferase were found to have similar developmental patterns. Levels of phosphatidyltransferase seen in fetal animals (whole brain only) and neonatal (whole brain and cerebellum) were maintained through approximately postnatal day 15, peaked at day 28, and then declined to somewhat higher than fetal levels at day 60. Cytidylyltransferase activity varied from the phosphatidylinositol synthesizing enzyme in that specific activity continued to increase up to day 60. Whole brain phosphatidylinositol transfer specific activity showed a sharp peak at postnatal day 9 after which activity was maintained at or above the fetal levels to day 60. Cerebellum phosphatidylinositol transfer specific activity had a similar peak which was delayed 7-10 days compared to the whole brain. Phosphatidylinositol transfer protein was also determined immunologically: whole brain levels increased dramatically from fetal day 16 to 18 and then remained relatively constant, while cerebellum levels (measured from postnatal day 7) displayed a variable profile between days 7 and 28. The developmental pattern of CTP:phosphatidate cytidylyltransferase in rat brain is reported here for the first time.     

Early biochemical detection of adverse effects of a neurobehavioral teratogen: influence of prenatal methylmercury exposure on ornithine decarboxylase in brain and other tissues of fetal and neonatal rat

Ornithine decarboxylase (ODC), an enzymatic regulator of macromolecule synthesis, has proven useful as a biochemical marker for teratologic events. Daily administration of methylmercury (0.5 or 1 mg/kg s.c.) to pregnant rats during the second and third trimesters had a profound effect on ODC in whole fetus that was detectable as early as 13 days of gestation. Levels of enzyme activity in fetal brain also showed a marked increase centered about gestational day 17 as well as a significant elevation during early postnatal life; in the latter case, the cerebellum appeared to be a major target for methylmercury-induced aberrations. These effects were accompanied by little or no alteration in general growth rate, brain weights, or weights of other tissues (liver, heart, lung). Furthermore, no other tissue displayed such dramatic effects on ODC activity. Lowering the dose of methylmercury by an order of magnitude (0.05 to 0.1 mg/kg), levels which are associated with almost purely neurobehavioral effects of the teratogen, still resulted in clear-cut elevations of both whole fetus ODC and fetal and neonatal brain ODC. These results indicate that a sensitive biochemical detection procedure used in the fetus/neonate can successfully predict the subsequent tissue-specific damage to neurotransmitter systems and behavior resulting from methylmercury.     

Neuronal maturation in an experimental model of brain tissue heterotopia in the lung

Neural maturation involves diverse interaction and signaling mechanisms that are essential to the development of the nervous system. However, little is known about the development of neurons in heterotopic brain tissue in the lung, a rare abnormality observed in malformed babies and fetuses. The aim of this study was to identify the neurons and to investigate their maturation in experimental brain tissue heterotopia during fetal and neonatal periods. The fetuses from 24 pregnant female Swiss mice were used to induce brain tissue heterotopia on the 15th gestational day. Briefly, the brain of one fetus of each dam was extracted, disaggregated, and injected into the right hemithorax of siblings. Six of these fetuses with pulmonary brain tissue implantation were collected on the 18th gestational day (group E18), and six others were collected on the 8th postnatal day (group P8). The brain of each fetus from dams not submitted to any experimental procedure was collected on the 18th gestational day (group CE18) and on the 8th postnatal day (group CP8) to serve as a control for neuronal quantitation and maturation. Immunohistochemical staining of NeuN was used to assess neuron quantity and maturation. The NeuN labeling index was greater in the postnatal period than in the fetal period for the experimental and control groups (P8 > E18 and CP8 > CE18), although there were fewer neurons in experimental than in control groups (P8 < CP8 and E18 < CE18) (P < 0.005). These results indicate that fetal neuroblasts/neurons not only survive a dramatic event such as mechanical disaggregation, in the same way as it happens in human cases, but also they retain their development in heterotopia, irrespective of local tissue influences.     

Effect of cortisol on the synthesis of lamellar body glycerophospholipids in fetal rabbit lung tissue in vitro

The effect of cortisol on the rate of choline incorporation into tissue phosphatidylcholine was investigated in lung explants from fetal rabbits of 19-28 days gestational age. The explants were incubated in medium with or without fetal calf serum for up to 7 days. When lung tissues were incubated in serum-free medium, a stimulatory effect of cortisol on tissue phosphatidylcholine synthesis was found in explants from 21-, 24-, 26- and 28-day fetal rabbits; a stimulatory effect of cortisol was observed in 19-day fetal lung explants only if fetal calf serum was present in the culture medium. To assess directly the effect of cortisol on the synthesis of lamellar body phosphatidylcholine, choline incorporation into phosphatidylcholine associated with a purified lamellar body fraction isolated from lung explants of 21- and 28-day fetal rabbits was also investigated. Cortisol caused a marked stimulation of synthesis and accumulation of lamellar body phosphatidylcholine in lung explants from both 21- and 28-day fetal rabbits. The magnitude of the stimulatory effect of cortisol on the rate of synthesis of lamellar body phosphatidylcholine was always greater than the effect of cortisol on the rate of choline incorporation into lipids of tissue homogenates. The relative rates of synthesis of lamellar body phosphatidylinositol and phosphatidylglycerol were also significantly altered in lung explants from 21- and 28-day fetal rabbits by cortisol treatment. Lamellar bodies that were formed initially in the fetal lung explants were enriched in phosphatidylcholine and phosphatidylinositol and had a relatively low phosphatidylglycerol content. With cortisol treatment there was a decrease in the relative rate of synthesis of lamellar body phosphatidylinositol and an increase in the relative rate of synthesis of phosphatidylglycerol. The stimulatory effect of cortisol on the synthesis of lamellar body phosphatidylcholine was observed at an earlier time-point of incubation than was the effect of cortisol on the relative rates of synthesis of lamellar body phosphatidylinositol and phosphatidylglycerol. The temporal sequence of the cortisol-induced changes in the synthesis of lamellar body glycerophospholipids, therefore, reflects that which occurs with maturation in vivo.     

Immunochemical measurement of myelin basic protein in developing rat brain: an index of myelin synthesis.

The initial time and rate of myelin basic protein synthesis in neural tissues of the rat have been measured from birth to 120 days. The protein was quantitated by a radioimmunoassay directly applied to unfractionated cerebrum, cerebellum, olfactory bulb, midbrain, brain stem, optic and trigeminal nerve, and areas of the spinal cord. Because the protein is a specific myelin constituent and its appearance correlates precisely with the synthesis of myelin lipids, the data in this report can be interpreted in terms of myelin synthesis and oligodendrocyte activity. The results show striking heterogeneity in the initial time and rate of myelin synthesis in neural tissue.     

Hydroxyproline contents and prolyl hydroxylase activities in lungs of rats exposed to low levels of ozone.

Exposure of adult rats to 0.8 ppm ozone enhanced collagen synthesis in the lungs. Collagen synthesis was studied by estimating hydroxyproline (Hyp) content and by following the activity of prolyl hydroxylase (PH), a crucial enzyme in the pathway of collagen biosynthesis. In the early phases (1–2 day) of ozone-induced injury, PH activity was increased twofold over control values and the amount of collagen synthesized (as estimated by Hyp formation) was double the amount of non-collagenous protein synthesized. This resulted, by the third day, in a significant increase (29%) in total lung collagen. In the later stages of the injury (3–7 day), however, increases in PH activity were more gradual, approaching 2.7 times control levels at the end of the 7-day exposure period. The synthesis of non-collagenous protein during this period increased steadily and by the 7th day the ratio of the amounts of collagen to non-collagenous protein synthesized was comparable to that of controls. When the exposed (0.8 ppm O₃/7 days) animals were placed in filtered ambient air, PH activity returned to normal in 13 days whereas Hyp content remained elevated for up to 28 days. These results suggest that environmental ozone exposure could be a contributing factor in pulmonary disorders involving lung collagen synthesis.     

Carnosine Synthesis in Olfactory Tissue During Ontogeny: Effect of Exogenous β-Alanine

Carnosine has now been demonstrated by chemical analysis to be present in rat olfactory mucosa on day 16 of gestation. The tissue content of this dipeptide then increases progressively during fetal and postnatal life. Radioactive carnosine can be isolated from cultured embryonic rat olfactory mucosa incubated with [14C]beta-alanine as early as 13-14 days of gestation. The amount of incorporation also increases progressively with the initial age of the explant and with time in culture indicating in vitro maturation of the carnosine synthesis capability of olfactory tissue. To test whether the level of beta-alanine was limiting the synthesis of carnosine, we evaluated the effect of elevated beta-alanine levels on tissue carnosine content. Exogenous beta-alanine caused an increase in the tissue content of carnosine at several ages in vivo and in vitro. In adult animals this increase was observed in olfactory bulb, olfactory mucosa, and skeletal muscle. However, there was no associated alteration in carnosine synthetase activity. In addition, the different half-lives of carnosine in olfactory tissue and muscle seemed unaltered, arguing against any effect on degradative enzymes. Thus, tissue carnosine levels are regulated, at least in part, by substrate availability. The early appearance of carnosine synthetic capacity during prenatal development indicates that this enzyme activity should be a valuable aid in studying early events in olfactory neuron maturation.     

Role of Elongation Factor 1 in the Translational Control of Rodent Brain Protein Synthesis

Abstract: The translational control of protein synthesis during early postnatal neural development and aging was examined in the mouse and the rat. The activity of brain elongation factor 1 (bEF-1) was found to decrease exponentially with age and to decline parallel to the age-dependent decrease in total protein synthesis in both rodents. This decrement in bEF-1 activity fell within the range of reported age-related decreases in protein synthesis in in vitro systems. The factor was present in multiple forms; the lighter species predominated in older animals, whereas the young light form apparently disappeared with increasing age, and was replaced by others arising from the heavy form. Elongation factor 1 derived from young brains functioned as a rate-limiting component in polypeptide synthesis in previously saturated adult systems. The data suggest that bEF-1 has an important modulatory effect on total brain protein synthesis.     

Ontogenesis of the insulin receptor in the rabbit brain

We delineated the ontogeny of the brain insulin binding, insulin receptor number and affinity using plasma membranes isolated from the rabbit. Specific 125I-insulin binding and receptor number expressed per milligram of protein increased from the 20 day gestation fetus to the 1-day-old newborn, declining thereafter to attain adult values by day 6 of postnatal life. Specific 125I-insulin binding and the receptor number in the adult brain was less than the fetal and neonatal (1 day) brain receptors. Although a similar trend was observed specifically during fetal development, the changes in receptor number expressed per microgram DNA were not significant in the neonatal period. The adult brain insulin receptor number was higher than the 20- to 27-day fetus and similar to that of the 30-day fetus and the 1- to 5-day newborns. The total receptor number correlated linearly with the brain plasma membrane protein increment velocity. The affinity of the receptors increased during early fetal development (20-27 days) and remained constant thereafter in the postnatal period. We conclude that the ontogenic changes of the brain insulin receptors are similar to the ontogenic changes of brain plasma membrane protein. The developmental changes are more pronounced when the receptor number is expressed per milligram protein versus microgram DNA.     

Metabolic features of the liver and spleen and antibody formation in animals following hyperimmunization with viral antigens]

Hyperimmunization with the tick encephalitis and Western horse encephalomyelitis viruses reproduced in the brain of albino mice, intensified the protein synthesis in the splenic tissue during the productive phase of the immunogenesis (the 7th day). An accumalation of protein, activation of aniuno-acyl-t-RNA-ligases, a reduction of the concehtration of some amino acids was noted, An analogous reaction was distinct in the tissue of the liver only when an intact brain suspension was used as an antigen. Formation of specific antibodies coursed more intensively after the administration of a more pathogenic virusof Western equine encephalomyelitis.     

Translational regulation in the brain by TDP-43 phase separation

The in vivo physiological function of liquid–liquid phase separation (LLPS) that governs non–membrane-bound structures remains elusive. Among LLPS-prone proteins, TAR DNA-binding protein of 43 kD (TDP-43) is under intense investigation because of its close association with neurological disorders. Here, we generated mice expressing endogenous LLPS-deficient murine TDP-43. LLPS-deficient TDP-43 mice demonstrate impaired neuronal function and behavioral abnormalities specifically related to brain function. Brain neurons of these mice, however, did not show TDP-43 proteinopathy or neurodegeneration. Instead, the global rate of protein synthesis was found to be greatly enhanced by TDP-43 LLPS loss. Mechanistically, TDP-43 LLPS ablation increased its association with PABPC4, RPS6, RPL7, and other translational factors. The physical interactions between TDP-43 and translational factors relies on a motif, the deletion of which abolished the impact of LLPS-deficient TDP-43 on translation. Our findings show a specific physiological role for TDP-43 LLPS in the regulation of brain function and uncover an intriguing novel molecular mechanism of translational control by LLPS.