Polyadenylic acid-containing RNA from rat brain

Modulation of messenger RNA metabolism in experimental methyl mercury neurotoxicity

We have investigated the effects of methyl mercury of mRNA metabolism in mouse brain cells in vivo. It was demonstrated that methyl mercury substantially reduces the rate of synthesis of ATP and poly(A)-segments of mRNAs. The molecular sizes of poly(A)-segments isolated from hnRNA and polysomal mRNA of the experimental animal brain are smaller than the dimensions of the same segments from the cellular RNA of intact mice. A fall in the mRNA polyadenylation rate seen under methyl mercury directly correlates with reduced metabolic stability (t 1/2) of the respective poly(A)+mRNA. The mean time of nuclear-cytoplasmic transport of these mRNAs (t0 is substantially increased under methyl mercury. At the same time, methyl mercury has no effect on the metabolism of brain polysomal poly(A)-mRNA. Direct addition of methyl mercury to an in vitro system containing excess ATP failed to affect the activity of poly(A) polymerase isolated from the brain of intact mice. The poison-induced alterations in the poly(A)+mRNA metabolism bring about a considerable reduction of the poly(A)+-fraction's share in the total polysomal mRNA and dramatic fall in the intracellular polysomes concentration. All the alterations in the examined metabolic parameters well correlate both with a reduced ATP content in the brain tissue and decreased rate of total protein synthesis in brain cells. Proceeding from these results as well as data from the literature, we developed a hypothetical model of a general molecular mechanism whereby methyl mercury inhibits protein synthesis in the brain.

Effect of convulsions of the synthesis of heterogeneous nuclear RNA associated with polyadenylate and oligoadenylate sequences from El mouse brain as a convulsive strain

Animals from the El (susceptible to seizures) and ddy (nonsusceptible) mouse strains were subjected to vestibular stimulation by tossing. After convulsions in the El mice, both the stimulated El mice and ddY mice were intracranially injected with [14C]- and [3H]adenosine, respectively. In the control experiment, nonstimulated El and ddY mice received radioactive adenosines in the same manner. The rate of incorporation of adenosine into brain nuclear RNA, expressed as a percentage of the 3H; 14C ratio, was reduced to an average of 68% at 15 min after convulsions, then increased and reached a control value at 5 h. This reduction in nuclear RNA synthesis was not due to alteration of the adenosine triphosphate pool. Gel electrophoresis of RNA revealed no obvious differences in the labeling distribution between El and ddY mice, but the synthesis of RNA species larger than 35S in heterogeneous nuclear RNA (HnRNA) was impaired in convulsed El mice. Nuclear resistant segments of HnRNA with both T1 RNase and RNase A, were chromatographed with poly(U)-Sepharose followed by urea-polyacrylamide gel electrophoresis. The ologo(A) and poly(A) segments consisted of 29, 19, and 11, and 203, 135, and 69 nucleotides, respectively. The convulsions of El mice reduced the incorporation of radioactive adenosines into oligo(A) and poly(A) segments, suggesting that they inhibited transcription as well as polyadenylation within HnRNA.

Analysis of messenger RNA coding for S100 protein in the mammalian brain

S100 protein is a brain-specific protein which is absent at birth and first appears in rabbit brain 2-3 days after birth. To determine how the synthesis of this brain-specific protein is regulated, mRNA was isolated from brain polysomes and assayed for S100 protein mRNA activity by in vitro translation in a heterologous cell-free system and immunoprecipitation of released polypeptides with rabbit anti-S100 protein antiserum. S100 protein mRNA was detected primarily in small polysomes containing five to eight ribosomes, and virtually no S100 protein mRNA was present in polysomes containing more than eight ribosomes. S100 protein mRNA was not detected in brain polysomes at stages prior to the induction of synthesis of S100 protein, i.e., in fetal brain or in 1-day neonates. The amount of S100 protein mRNA in polysomes of the cerebral cortex and cerebellum was measured to see if it correlated with the level of S100 protein in the two regions of adult brain. The cerebellum, which contained three to four times the level of S100 protein in the cerebral cortex, contained four times more S100 protein mRNA.

Developmental changes in the protein and ribonucleic acid components of rat brain messenger ribonucleic acid-protein particles isolated from free polyribosomes by oligo(dT)-cellulose chromatography

A study has been made of the developmental changes that occur in the RNA and protein moieties of mRNA-protein particles isolated from newborn and adult rat forebrain free polyribosomes. mRNA-protein particles were isolated by oligo(dT)-cellulose chromatography from salt-washed polyribosomes dissociated by puromycin/0.5 M-KCl treatment as two fractions (E1 and E2) by using Tris/HCl/NaCl eluting buffers containing respectively 25 and 50% (v/v) formamide. Isopycnic centrifugation on CsCl gradients showed that the newborn-derived fractions E1 and E2 has buoyant densities of 1.48--1.50 and 1.41--1.43 g/cm3. Adult-derived E1 and E2 fractions had corresponding values of 1.47 and 1.42 g/cm3. The pooled mRNA-protein particles from the E1 and E2 fractions after deproteinization with proteinase K sedimented with a mean size of approx. 18 S on a sucrose gradient containing 85% formamide with little differences between mRNA molecules from newborn and adult. The mean lengths of the poly(A) segments were similar, being about 130 nucleotides long. Distinct changes were found in the protein composition of the mRNA-protein particles. Fractions E1 and E2 from the newborn contained two major proteins of mol.wts. 74 000 and 52 000 with differences in the relative proportions in each fraction. In contrast, adult fractions E1 and E2 contained predominantly the larger protein. However, the adult fraction E2 contained a more heterogeneous population of minor bands of proteins, including that of mol.wt. 52 000. The findings are discussed briefly in relation to other changes in the developing brain.

Poly(A)- and nonpoly(A)-RNA associated with rat brain microsomal fractions: in vivo labelling studies

The time course of incorporation of radiolabelled precursor into RNA associated with rat brain free polyribosomes, rough membranes, and smooth membranes was measured following a single intracranial injection of [3H] orotic acid. Polyadenylated RNAs were separated from nonpolyadenylated RNAs by affinity chromatography on oligo (dT)-cellulose columns. Poly(A)-RNA associated with each of the microsomal fractions became more rapidly labelled than did the nonpoly(A)-RNA of the same fractions. While the labelling profiles of the nonpoly(A)-RNA isolated from the polyribosomes and rough membranes are similar from one fraction to another, the specific radioactivity of the poly(A)-RNA isolated from free polyribosomes increased much more drastically than that of the poly(A)-RNA associated with rough membranes. The labelling profiles of RNA species isolated from smooth membranes were very different in this respect from the two ribosomal fractions. There was a lag of more than four hours before significant label appeared in the RNA associated with the smooth membrane fraction. These studies demonstrate that the different populations of brain microsomal RNA are labelled at different rates, perhaps reflecting differences in the turnover of these RNAs and differences in their function.

The influence of brain cytosol on RNA synthesis and RNA products of isolated mouse brain nuclei

The incubation of isolated nuclei obtained from 10-day-old mouse brain in the presence of brain cell cytosol resulted in an increase in the synthesis of RNA. Under conditions of saturating concentrations of nucleoside triphosphates, the influence of cytosol could not be duplicated by the addition of cyclic nucleotides. The stimulatory activity of cytosol on brain nuclear RNA synthesis could not be attributed to either alterations in the permeability of the nuclear envelope or an increased uptake of radioactively-labeled precursors. Sucrose gradient analysis demonstrated that the RNA products synthesized by nuclei isolated from 10-day-old and adult mouse brain were of a relatively low molecular weight. However, the addition of cytosol resulted in a significant increase in the size of the RNA transcripts. In contrast to the observations with 10-day-old and adult brain nuclei, the RNA from 2-day-old mouse brain nuclei was larger in size and relatively unaffected by the presence of cytosol. Although cytosol caused an increase in the amounts of poly[A]-RNA in nuclei of 2-day-old and adult animals, no comparable effect could be measured in nuclei from 10-day-old brain tissue.

Decrease in levels and rates of synthesis of tubulin and actin in developing rat brain

The cytoplasmic and particulate tubulin content of postnatal rat brains was determined at various stages of development. The amount of tubulin in the soluble fraction was found to increase after birth and levels off at the age of 10-15 days, while the total protein content is still increasing. Indeed, the percentage of tubulin in the soluble fraction is about 33% at birth, stays at this value until day 10, and then decreases to 20% between days 10 and 15. On the other hand, the rate of increase in the level of the particulate tubulin parallels that of the total particulate proteins, and hence there is no change in the percentage of particulate tubulin during brain development. There was close agreement between the tubulin values obtained by the [3H]-colchicine binding assay and those obtained by electrophoretic resolution in sodium dodecylsulfate-polyacrylamide gels. Polyacrylamide gel electrophoresis was also utilized to determine actin levels in developing brains. The percentage of cytoplasmic brain actin also decreased with the age of the rats, from a value of 20% at birth to 10% at day 30, while the percentage of the particulate actin remained constant. The decline in the percentage of cytoplasmic tubulin and actin during brain development can be accounted for by reduction in the proportions of the respective mRNA species. Translation of poly (A)-rich brain mRNA in a wheat-germ cell-free system showed that the percentages of tubulin and actin synthesized decreased gradually with age. Similar results were obtained by analyzing the proteins produced by isolated brain polysomes in a brain cell-free system.

Analysis of rabbit brain polysomal poly (A+) mRNA by DNA excess hybridization

DNA sequence representation in rabbit brain mRNA was examined by DNA excess hybridization. purified polysomal poly (A+) mRNA was labeled in vitro with [3H] dimethyl sulfate and reacted at DNA: RNA ratios of 5000 : 1 and 30 000 : 1. Poly(A+) mRNA hybridizied mainly to nonrepeated DNA with a smaller kinetic component which was complementary to repeated DNA sequences. The latter component was not due to nuclear or ribosomal RNA contamination. Poly(A-) RNA purified from brain polysomes hybridized to excess DNA as a single repeated component. Thermal denaturation profiles of the RNA - DNA hybrids indicated a high degree of fidelity in base pairing.

Alterations of macromolecule biosynthesis after chronic administration of opiates and ethanol

The literature concerning the effects of opiates, alcohol and barbiturates on RNA and protein metabolism is reviewed. Recent findings from this laboratory suggest that chronic morphine treatment increases the template activity of chromatin from oligodendroglial nuclei while chronic ethanol treatment decreases this activity. In addition, chronic morphine treatment stimulates protein synthesis in cell free systems and may increase the synthesis of discrete synaptic membrane proteins. Results from other laboratories suggest a general decrease in macromolecule biosynthesis with long term ethanol consumption. These results are discussed in terms of the possible roles of protein synthesis in the effects of chronic opiate and ethanol administration.

Alteration of the pattern of hippocampal nerve cell RNA labelling during training in rats

RNA synthesis in the CA3 region of brain hippocampus was studied in rats trained to a handedness reversal task. The newly synthesized RNA, labelled by intraventricular injection of radioactive orotic acid, was extracted and analyzed by micromethods. The result was following. In the trained animals the incorporation of the labelled precursor into RNA, corrected by the pool radioactivity, was almost double in comparison with the controls. In the trained animals there was a stimulation of the incorporation in the high molecular weight (greater than 18S) RNA region and in two specific low molecular weight regions: 8-9 and 16-17S. Taking in account previous results of other authors, these data appear to imply a stimulation of brain mRNA synthesis as a result of training.

Poly(A) associated RNA from mitochondria and microsomes of rat brain

Rat brain mitochondria contain a significant proportion of poly(A) associated RNA which is higher than that found in microsomes from the same source. When steady state poly(A) RNA of brain mitochondria was analyzed by microelectrophoresis, it displayed a characteristic separation pattern with a large amount of "free" poly(A).

Nucleo-cytoplasmic relationships of high-molecular-weight ribonucleic acid, including polyadenylated species, in the developing rat brain

The metabolism of high-molecular-weight RNA in the nuclear and cytoplasmic fractions of newborn and adult rat brain was investigated after the intracranial administration of [32P]Pi. In young brain, a considerable proportion of the newly synthesized radioactive RNA is transferred to the cytoplasm, in contrast with the adult brain, where there appears to be a high intranuclear turnover. Electrophoretic analysis of the newly synthesized RNA showed that processing of the rRNA precursor to yield the 28S and 18S rRNA may be more rapid in the adult than in the young, although most of the adult rRNA in the nucleus is not transferred to the cytoplasm. In young brain, processing is probably tightly coupled to transport of rRNA into the cytoplasm, so that 28S and 18S rRNA are not subjected to possible degradation within the nucleus. Polyadenylated RNA turns over in concert with high-molecular-weight RNA in the nuclei of the adult rat brain. In the cytoplasm the polyadenylated RNA has a higher turnover rate relative to rRNA. In the young brain the polyadenylated RNA is transferred to the cytoplasm along with rRNA, although polyadenylated RNA is transported into the cytoplasm at a faster rate. The nuclear and cytoplasmic polyadenylated RNA species of young brain are larger than their corresponding adult counterparts. These results suggest that there are considerable changes in the regulation of the nucleo-cytoplasmic relationship of rRNA and polyadenylated RNA during the transition of the brain from a developing replicative phase to an adult differentiated and non-dividing state.

Pattern of labelling of poly (A)-associated RNA in the CA3 region of rat hippocampus during training

Newly synthesized poly (A)-associated mRNA was analysed in the hippocampal CA3 pyramidal nerve cells in rats subjected to training to reverse handedness. The nerve cells of trained animals showed a smaller percentage of poly(A)-associated mRNA than did the active controls. However, a specific fraction of this poly (A) hippocampal RNA with a SE value of around 25 was reproducibly stimulated. This qualitative nerve cell mRNA change is discussed in relation to similar changes in the protein pattern as a function of training.