Fetal development: the effects of maturation on in vitro protein synthesis by mouse brain tissue

Developmental studies of the first step of the initiation of brain protein synthesis, role for initiation factor 2

Developmental changes at the level of initiation step of translation in the rat brain were studied. The level of deacylated tRNAimet in rat brain was measured at two stages of postnatal development. Although the amount of tRNA was slightly lower in adult than in young (4 day old) rats, the charging capacity of initiator tRNAimet in vitro was similar at both ages. No differences during development were found in methionyl-tRNA synthetase activity, which throws doubt on its possible participation in regulation of the initiation step. When assayed in the ribosomal salt wash protein fractions, initiation factor 2 activity decreased during brain development, and increased activities were detected in the supernatant of the microsomal fractions. The decrease in eIF-2 activity paralleled the observed decrease in the rat of overall protein synthesis or initiation activity in vitro, suggesting that the regulation of the initiation step of translation during brain development may be tightly linked to changes in initiation factor 2 activity in brain tissue.

Isolation of eukaryotic initiation factor 2 from rat brain

Eukaryotic initiation factor 2 (eIF-2) was isolated from salt-washed microsomes of 4-day-old rat brain which show a high rate of protein synthesis. A three-step purification scheme was employed, including heparin-Sepharose, phosphocellulose, and DEAE-cellulose column chromatography. Sodium dodecyl sulfate-polyacrylamide gel electrophoresis of the isolated factor revealed three polypeptides with molecular weights of 43,000, 54,000, and 59,000 and 90% purity. The rat brain eIF-2 forms ternary complexes with [3H]methionyl-tRNAi and GTP. In terms of specific activity, the purification does not correspond to that revealed by electrophoretic analysis. During purification there is an apparent loss of additional factors that modulates the activity of eIF-2 and explains the high rate of activity of the crude fraction.

Protein turnover in brain of the rat fetus

Protein synthesis in vivo was studied in whole brain of rat fetuses using continuous intravenous infusion of L-[U-14C]tyrosine into unrestrained pregnant rats at 19 and 21 days gestation. Protein degradation (KD) was calculated by subtracting fractional growth rate of brain protein (KG) from the fractional synthesis rate (KS). KS was high at both gestational ages (0.42 +/- 0.03 days-1 at day 19, 0.47 +/- 0.029 days-1 at 21 days), comparable to values previously reported for newborn rat cerebral hemispheres, and threefold higher than is seen in adult animals. KD was similar at both 19 and 21 days gestation (0.19-0.24) and lower than that reported in neonatal rat brain using similar techniques. Protein accretion during the most rapid phase of brain growth (fetus) is accomplished by similar rates of protein synthesis, but decreased rates of degradation when compared with a slower growth phase (newborn). KD in the brain of the rapidly growing fetus is slightly higher than in adult cerebral hemispheres.

Heterogeneity of protein-synthesis initiation factors in developing and aging rat brain

Protein synthesis initiation factors from rat brain were assayed in vitro through the formation of the initiator Met-tRNA X initiation factor 2 X GTP ternary complex. The initiation factor showed different intrinsic activity with increase in age. This difference was elicited by additions of high-salt ribosomal-wash protein to incubation mixtures that were already saturated with protein preparations from brains of older animals. This qualitative difference was further documented by examining the sensitivity of the activities of the initiation factor to spermidine and to temperature. The sensitivity to these effectors varied with age. By fitting an exponential decay model to data from the temperature experiments, it was possible to demonstrate that the preparations of the initiation factor from older brains behaved as a multicomponent system. The brain preparations from older animals contained at least two subpopulations of initiation factor. The fractions of these two gross subclasses varied, inversely one to the other, with age.

Protein metabolism in an astroglial primary culture

Protein metabolism was studied in astroglial primary cultures, grown for different time periods. Removal of fetal calf-serum for two days led to a morphological differentiation consisting of retraction of cell soma and extention of processes. There was a prominent decrease in total soluble protein and a decrease in [3H]valine incorporation into soluble protein. Dibutyrylcyclic-3'-5'-adenosine monophosphate (dB-cAMP)-treatment for two days also changed morphology in a similar way, but had no effect on [3H]valine incorporation into protein. After addition of soluble brain extract to the cultures an increased [3H]valine incorporation into soluble protein was seen together with a morphological differentiation, more pronounced in the presence than in the absence of fetal calf-serum. Proteins were secreted from the cells into the incubation medium and studied by electrophoresis. The more prominent protein bands had m.w. in the region of 10,000-100,000 daltons. The amount of newly synthesized proteins released into the medium was unchanged (or decreased slightly in 14 and 16 day old cultures) after addition of dB-cAMP" or soluble brain extract, and was much reduced after removal of fetal calf-serum.

Tryptophan overload in the pregnant rat: effect on brain amino acid levels in in vitro protein synthesis

The concentration of most amino acids was higher in the brains of 19- and 21-day rat fetuses than in their respective mothers. After an intraperitoneal load of tryptophan to the mother, the intracerebral concentration of several amino acids (including leucine) decreased not only in the mothers, but also in their fetuses. The in vitro incorporation of [3H]leucine into proteins in brain postmitochondrial supernatant fractions was enhanced in both the mothers and fetuses after tryptophan administration, but this effect disappeared when protein synthesis was calculated by using specific activities corrected for the amount of unlabeled leucine in the preparation. By this criterion, protein synthesis activity appeared similar in the brains of 19- and 21-day pregnant rats but was higher in their fetuses, especially in the 21-day subjects. Thus, protein synthesis in the brain was not altered by marked changes in the amino acid pool and more profound and prolonged metabolic disturbances must occur to cause permanent damage in the developing brain.

Role of elongation factor 1 in the translational control of rodent brain protein synthesis

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 other 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.

Regulation of prenatal and postnatal protein synthesis in mouse brain

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 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 congruent to 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.

Fate of mRNA following disaggregation of brain polysomes after administration of (+)-lysergic acid diethylamide in vivo

Intravenous injection of (+)-lysergic acid diethylamide into young rabbits induced a transient brain-specific disaggregation of polysomes to monosomes. Investigation of the fate of mRNA revealed that brain poly(A+)mRNA was conserved. In particular, mRNA coding for brain-specific S100 protein was not degraded, nor was it released into free ribonucleoprotein particles. Following the (+)-lysergic acid diethylamide-induced disaggregation of polysomes, mRNA shifted from polysomes and accumulated on monosomes. Formation of a blocked monosome complex, which contained intact mRNA and 40-S plus 60-S ribosomal subunits but lacked nascent peptide chains, suggested that (+)-lysergic acid diethylamide inhibited brain protein synthesis at a specific stage of late initiation or early elongation.

Maintenance of neurons isolated in bulk from rat brain: incorporation of radiolabeled substrates

Neurons isolated in bulk from 10- to 15-day-old rat brain can be maintained for 18--24 h. Phase microscopy shows that the cells remain morphologically intact during this time. As a criterion of viability, the incorporation of radiolabeled amino acids and uridine into trichloroacetic acid-insoluble material was selected. The cells are capable of the incorporation both after isolation and after maintenance. The uptake is constant with time, is proportional to substrate concentration, and is inhibited by puromycin and cycloheximide, but not by chloramphenicol. Thus the cells remain viable during this maintenance period. This system may provide a model for the study of the synthesis of specific neuronal components.

Biochemical studies of chick brain development and maturation: II. Alterations in the mechanisms of cell-free protein synthesis

The molecular mechanisms responsible for the decreased cell-free protein synthetic activity of chicken brain (cerebrum, cerebellum, and optic lobes) from the late embryonic stage to the adult stage were investigated. The changes in polyribosome content closely paralleled changes in cell-free protein synthetic activity; both increased during late embryonic development, reached a maximum around hatching,and thereafter decreased to the level found in the adult. Both cell sap and microsomal or ribosomal fractions from the adult brain tissue were less active in protein synthesis; however, the microsomal or ribosomal fractions contributed more to the decreased protein synthesis than did the cell sap. The lower activity of adult cell sap in protein synthesis was primarily due to a decreased activity in the aminoacylation of tRNA with no apparent change in the ability of the cell sap to catalyze the elongation of polyphenylalanine synthesis. Ribosomal particles (80 S) from adult and embryonic brain tissue had similar biological activities and fidelity in the translation of polyuridylic acid; however, the cell-free protein synthetic activity of the embryonic post-mitochondrial supernatant preparation was more sensitive to inhibitors of the initiation of protein synthesis (aurintricarboxylic acid and polyinosinic acid) than adult post-mitochondrial supernatant, indicating a decreased initiation capacity in adult brain post-mitochondrial supernatant compared to embryonic brain post-mitochondrial supernatant.

Biochemical studies of chick brain development and maturation: I. Alterations in the macromolecule content and cell-free protein synthesis

Changes in macromolecule content (DNA, RNA, and protein) and cell-free protein synthetic activity in chick brain developing from 9-day-old embryos to 1 1/2-year-old adults were studied in three brain regions: cerebrum, cerebellum, and optic lobes. The accumulation of DNA, RNA, and protein in three brain regions occurred each in its own characteristic pattern although three distinct phases could be observed. The most rapid accumulation always occurred during embryonic development followed by a slower accumulation from hatching to 3-mo. with very little or no change in the brain macromolecule content thereafter. In all three brain regions, the cell-free protein synthetic activity increased during embryonic development, reaching maximum around hatching then decreased substantially (50-70%) after hatching. Comparison of 18-day-old embryonic and 1 1/2-year-old adult brain tissue showed that there was no significant alteration in the relative proportion of membrane-bound and free ribosomes. When the products of cell-free protein synthesis by embryonic and adult brain preparations were compared by SDS polyacrylamide gel electrophoresis, it was found that the percentage of various proteins synthesized by embryonic brain tissue was very similar to that of the adult. It is concluded that the decrease in cell-free protein synthesis is due to a general decrease in the synthesis of all types of proteins rather than a decrease in a specific group or groups of proteins.

The mechanism of polyribosome disaggregation in brain tissue by phenylalanine

The injection of neonatal mice with phenylalanine resulted in a rapid decrease in brain polyribosomes and a concomitant increase in monomeric ribosomes. Animals of 1-16 days of age were equally affected by phenylalanine, although the brain polyribosomes of 60-day-old mice were relatively resistant to the effects of phenylalanine. The population of free polyribosomes appeared to be more sensitive to phenylalanine treatment than bound polyribosomes, which were somewhat more resistant to disruption by high concentrations of the amino acid. The effects of phenylalanine were more pronounced with polyribosomes in the cerebral cortex than with those in the cerebellar tissue. The mechanism of polyribosome disruption was shown to be independent of hydrolysis mediated by ribonuclease. Virtually all of the monomeric ribosomes that resulted from phenylalanine treatment were shown to be inactive with regard to endogenous protein synthesis and were present in the cell cytoplasm as vacant couples. These ribosomes were readily dissociated by treatment with 0.5 M-KCl and subsequent ultracentrifugation. These results are discussed in the light of the possibility that high concentrations of phenylalanine disrupt brain protein synthesis by a molecular mechanism that is associated with initiation events.