Effect of undernutrition on DNA and RNA synthesis in subcellular fractions from different regions of the developing rat brain

The effect of undernutrition on the incorporation of [methyl-³H]thymidine into DNA and of 5-[³H]uridine into RNA of cerebral hemispheres, cerebellum, and brain stem was studied in vivo and in vitro in rats. The labeling of DNA from nuclei and mitochondria and of RNA from nuclei, mitochondria, microsomes, and soluble fractions, was also measured in vitro. The results demonstrate that nucleic acid synthesis is impaired and delayed during undernutrition. Specific effects were observed for the different brain regions and subcellular fractions: at 10 days nuclear and mitochondrial DNA and RNA synthesis was impaired, whereas at 30 days only the mitochondrial nucleic acid synthesis was affected.The delay of DNA and RNA labeling, caused by undernutrition, was most evident in the cerebellum, probably due to its intense cell proliferation during postnatal development. The specific sensitivity of mitochondria as compared to other subcellular fractions, may be due to the intense biogenesis and/or turnover of nucleic acids in brain mitochondria not only during postnatal development, but also in the adult animal.     

Effect of hypoxia on nucleic acid and protein synthesis in different brain regions

The incorporation of [methyl-³H]thymidine into DNA, of [5-³H]uridine into RNA, and of [1-¹⁴C]leucine into proteins of cerebral hemispheres, cerebellum, and brainstem of guinea pigs after 80 hr of hypoxic treatment was measured. Both in vivo (intraventricular administration of labeled precursors) and in vitro (tissue slices incubation) experiments were performed. The labeling of macromolecules extracted from the various subcellular fractions of the above-mentioned brain regions was also determined. After hypoxic treatment the incorporation of the labeled precursors into DNA, RNA, and proteins was impaired to a different extent in the three brain regions and in the various subcellular fractions examined; DNA and RNA labeling in cerebellar mitochondria and protein labeling in microsomes of the three brain regions examined were particularly affected.     

The relationship between DNA synthesis and the synthesis of nuclear proteins in rat brain during development

—The incorporation of [³H]thymidine into nuclear DNA of rat brain progressively increased from birth until the 8th postnatal day and it was lowest in the adult brain. When isolated nuclei from brain cells were separated into a neuronal- and a glial-rich fraction (composed of glial and neuroblast nuclei in young animals), the specific radioactivity of the DNA was higher in the glial-rich fraction at all ages investigated. The incorporation of [³H]leucine into proteins of rat brain was considerably higher in the 8-than in the 1-day-old rat. The greatest difference in the rate of protein synthesis between 8- and 1-day-old brain occurred in the nuclear proteins, especially those associated with DNA. There was an accumulation of protein and RNA in nuclei from brain cells from birth to the 8th postnatal day. The increased content of proteins occurred primarily in the fraction soluble in buffered saline (nuclear sap).     

Effect of CDP-choline on the biosynthesis of nucleic acids and proteins in brain regions during hypoxia

The effect of CDP-choline on the in vivo incorporation of labeled precursors into DNA, RNA, and proteins in cerebral hemispheres, cerebellum, and brainstem of guinea pigs after hypoxic treatment was studied. The labeling of macromolecules extracted from the various subcellular fractions of these brain regions was also determined. Hypoxic treatment affected macromolecular labeling to a different extent in the three brain regions examined. CDP-choline treatment was not able to reverse the effect of hypoxia on DNA labeling, but it was able to remove the effect of hypoxia on RNA and protein labeling. The action of CDP-choline was particularly evident on the labeling of RNA in nuclei and mitochondria of the cerebellum and on the labeling of proteins in microsomes of the three brain regions examined.     

Macromolecular synthesis in the livers of aging mice as revealed by electron microscopic radioautography

For the purpose of studying the aging changes of macromolecular synthesis in animal cells, we studied many groups of aging mice during development and aging from fetal day 19 to postnatal newborn, juvenile, young adults, aged and senescent adults up to 12 and month 24 (2 years). They were injected with ³H-thymidine, ³H-uridine or ³H-leucine, precursors for DNA, RNA and proteins, as well as ³H-glucose, ³H-glucosamine, ³⁵S-sulfuric acid, or ³H-glycerol for glucide and lipid precursors, respectively, then sacrificed and the liver tissues were taken out, fixed and processed for light and electron microscopic radioautography. On many radioautograms the localization of silver grains demonstrating DNA, RNA and proteins in hepatocytes in respective aging groups were analyzed qualitatively. The number of silver grains and the number of cell organelles in each cell of each animal in respective aging groups were analyzed quantitatively in relation to the aging of individual animals. The results revealed that the localization of respective precursors as well as the number of silver grains in cell nuclei, cell organelles, changed with the aging of animals. The numbers of labeled nuclei and cell organelles, as well as the numbers of silver grains in nuclei and cell organelles changed due to aging of individual animals. The number of mitochondria, the number of labeled mitochondria and the mitochondrial labeling index labeled with silver grains were counted in each hepatocyte. It was demonstrated that the numbers of mitochondria, the numbers of labeled mitochondria and the labeling indices showing DNA, RNA and protein synthesis at various ages from embryonic day 19 to postnatal newborn day 1, 3, 9, 14, adult month 1, 2 and 6, reaching the maxima, then decreased to senile year 1 to 2, indicating the aging changes. The results indicated that mitochondria in hepatocytes synthesized nucleic acids and proteins independently from the nuclei, but their synthetic activities were affected from the aging of the individual animals.     

Quantitation of mitochondrial DNA,RNA, and protein in starved and starved-refed rat liver

The purpose of this study was to investigate the problem of mitochondrial biogenesis in rat liver. The approach consisted of isolating mitochondria from control, 6 day starved and 6 day starved-5 day refed rats and comparing their DNA, RNA and protein content. This was performed by isolating the mitochondria by reorienting rate zonal centrifugation in sucrose gradients. It was found that six days of starvation resulted in a loss of 30% of the body weight, 55% of the liver weight, 40% of the mitochondrial protein, 60% of the mitochondrial RNA, but only 20% of the mitrochondrial DNA. It was also shown that refeeding of the rats for five days resulted in a restoration to normal or near normal levels in all the parameters measured. Further experiments employing the incorporation of ³H-TTP into isolated mitochondria indicated that the maintenance of mitochondrial DNA was not the result of continuous DNA synthesis.     

Effects of cycloheximide,d-threo-chloramphenicol,erythromycin and actinomycin D on De-novo synthesis of cytoplasmic and mitochondrial proteins in the cotyledons of germinating pea seeds

Summary Inhibitors of, and radioactive substrates for, protein synthesis were introduced into germinating pea (Pisum sativum L.) seeds, and protein synthesis was allowed to proceed in vivo. Subsequent analyses of subcellular fractions showed the following: Cycloheximide strongly inhibited the incorporation of [¹⁴C]leucine into both mitochondrial and cytoplasmic proteins. d-Threo-chloramphenicol and erythromycin did not affect cytoplasmic protein synthesis, but partially inhibited mitochondrial protein synthesis. These results suggest that most of the new mitochondrial proteins were originally synthesized in the cytoplasm. Actinomycin D did not appreciably affect the initial incorporation of [¹⁴C]leucine into either mitochondrial or cytoplasmic proteins, suggesting that information (mRNA) concerning the initially synthesized proteins may be present in the quiescent seeds. The lack of appreciable incorporation of [³H]thymidine into mitochondrial DNA supported our previons report that mitochondria may not be synthesized de novo in pea cotyledons.     

The study of ubiquitin-dependent increase in monoamine oxidase sensitivity to proteolysis and specific inhibitor, pargyline

Insertion of exogenous ubiquitin into rat brain mitochondria in the presence of ATP and the ATPregenerating system (creatine phosphate/creatine phosphokinase) results in the increase in: sensitivity of mitochondrial monoamine oxidases (MAO) A and B to inhibition by mechanism based inhibitor and incorporation of [³H]-pargyline, which was especially notable in the fraction obtained by immunoprecipitation of mitochondrial proteins with anti-ubiquitin antiserum and protein A Sepharose. This suggests that MAO is a potential substrate for ubiquitination in vitro. However, the content of the tritium label in this fraction was less than 0.1 % and not more than 0.25% of total radioactivity of [³H]-pargyline bound to control and ATP-ubiquitin treated mitochondria, respectively. Insertion of ubiquitin into mitochondria did not influence molecular masses of [³H]-pargyline labeled proteins. These results suggest that direct ubiquitination of MAO insignificantly contributes to marked changes in the sensitivity of MAO A and MAO B to proteolysis and specific inhibition found under these experimental conditions. It is possible that more complex processes are involved into realization of these effects during ATP-dependent ubiquitin incorporation into mitochondria.     

Incorporation of [6-3H] glucose into lipid, protein, RNA and DNA of slices of differentiating rat cerebral cortex

Abstract— An assay in vitro utilizing [6^?3H)glucose as precursor for synthesis of lipids, proteins, RNA and DNA was developed for incubated slices of rat cerebral cortex. The developmental changes in synthesis of macromolecules were followed during differentiation of rat cerebral cortex. The incorporation of glucose into lipids and proteins decreased 10-fold in incubated slices of cerebral cortex during progression from foetal to adult ages. In contrast, the specific radioactivities of RNA and DNA in incubated slices increased from the values at 3 days prepartum to peaks at 2–4 weeks postpartum.     

EFFECT OF EHRLICH ASCITES CELL CHALONE ON NASCENT DNA SYNTHESIS IN ISOLATED NUCLEI

Ehrlich Ascites Tumor (EAT) chalone has been shown to inhibit nascent DNA synthesis by inhibiting DNA polymerase α and β (Nakai, 1976), but one of the problems in studying eurkaryotic DNA replication has been the relative impermeability of the cell membrane to precursors and macromolecules; hence, to circumvent this restriction without sacrificing the integrity of the replication process, a broken cell system utilizing nuclei in aqueous media was investigated. Isolated nuclei appear to continue the process of DNA replication that was proceeding in vivo before their isolation and under optimal conditions are able to initiate new synthesis (Fraser & Huberman, 1977). The effects of partially purified EAT chalone on nascent DNA could be studied directly in this nuclear system, which excluded effects of the cell membrane, nucleotide pools and other cytosol elements. A concentration-related inhibition of [³H]thymidine triphosphate ([³H]-dTTP) incorporation was noted over a chalone range of 50–200 μg/ml. It appears that chalone can inhibit DNA polymerase α directly within the nucleus without an intermediate step such as a cell membrane receptor.     

Spatial and Temporal Variations in Bacterial Macromolecule Labeling with [methyl-3H]Thymidine in a Hypertrophic Lake

The incorporation of [methyl-³H]thymidine into three macromolecular fractions, designated as DNA, RNA, and protein, by bacteria from Hartbeespoort Dam, South Africa, was measured over 1 year by acid-base hydrolysis procedures. Samples were collected at 10 m, which was at least 5 m beneath the euphotic zone. On four occasions, samples were concurrently collected at the surface. Approximately 80% of the label was incorporated into bacterial DNA in surface samples. At 10 m, total incorporation of label into bacterial macromolecules was correlated to bacterial utilization of glucose (r = 0.913, n = 13, P < 0.001). The labeling of DNA, which ranged between 0 and 78% of total macromolecule incorporation, was inversely related to glucose uptake (r = -0.823), total thymidine incorporation (r = -0.737), and euphotic zone algal production (r = -0.732, n = 13, P < 0.005). With decreased DNA labeling, increasing proportions of label were found in the RNA fraction and proteins. Enzymatic digestion followed by chromatographic separation of macromolecule fragments indicated that DNA and proteins were labeled while RNA was not. The RNA fraction may represent labeled lipids or other macromolecules or both. The data demonstrated a close coupling between phytoplankton production and heterotrophic bacterial activity in this hypertrophic lake but also confirmed the need for the routine extraction and purification of DNA during [methyl-³H]thymidine studies of aquatic bacterial production.     

The effects of phenylpyruvate and hyperphenylalaninemia on incorporation of (6- 3 H)glucose into macromolecules of slices of rat cerebral cortex

The effects of phenylpyruvate and hyperphenylalaninemia on the incorporation of [6-³H]glucose into lipids, proteins and nucleic acids were examined in differentiating and adult rat brain. Foetal brain was most sensitive to inhibition by phenylpyruvate in vitro, with significant effects occurring at 2·5 mM for labelling of lipids and proteins and at 5 mM for labelling RNA and DNA. Older age groups were less affected, and cortical slices from adult brain were slightly or not at all affected by phenylpyruvate. The inhibition by phenylpyruvate of incorporation of [6-³H]glucose into nucleic acids, proteins, and lipids could be further distinguished by the reversibility of the effect on nucleic acid and protein synthesis at high levels of glucose and the irreversibility of the effect on lipid synthesis. Lipid synthesis was most sensitive to inhibition by phenylpyruvate at the stage of fatty acid synthesis, with lesser effect on the formation of glyceride glycerol. Exposure in utero of the foetal brain to maternal hyperphenylalaninemia resulted in reduction of 26–38 per cent in the subsequent incorporation in vitro of [6-³H]glucose into lipids, proteins, RNA and DNA of brain slices from foetal animals. Feeding hyperphenylalaninemic pregnant rats a high-glucose diet significantly protected the foetal brain from the neurotoxicity accompanying the hyperphenylalanemia.     

Exit of proteins and fragments thereof from mitochondria is accelerated by the import of cytosolic synthesized proteins

Most mitochondrial proteins are synthesized on cytosolic ribosomes and imported into mitochondria. Incubation of ³⁵S-methionine labeled mitochondria from rat hepatocytes with proteins synthesized in a cell-free system, using messenger RNA from rat liver, dramatically increased the release of mitochondrial proteins and fragments thereof into the medium. Since the synthesized proteins include cytosolic precursors of mitochondrial proteins, our results strongly suggest that import of proteins from the cytosol into mitochondria influences the half-life of proteins in these organelles. The use of this simple approach — i.e. combining the study of protein import and exit with mitochondria — to further clarify intracellular protein turnover and its regulation is suggested.     

Mitochondrial poly(A) RNA synthesis during early sea urchin development

The synthesis of mitochondrial messenger RNA during early sea urchin development was examined. Oligo(dT) chromatography and electrophoresis on aqueous or formamide gels of mitochondrial RNA from pulse-labeled embryos showed the presence of eight distinct poly(A)-containing RNA species, ranging in size from 9 to 22 S. Nuclease digestion of these RNAs revealed poly(A) sequences of 4 S size. Using sea urchin anucleate fragments, we were able to demonstrate that all eight messenger RNAs are transcribed from mitochondrial DNA, rather than being transcribed from nuclear DNA and imported into the mitochondria.There was no change in the electrophoretic profile of the eight poly(A) RNAs when embryos were pulsed with [³H]uridine at various times after fertilization. Neither was there any change in the incorporation of [³H]uridine into these species or in the percentage of total newly synthesized mitochondrial RNA that contains poly(A) sequences as development progresses. Even though these RNAs appear to be transcribed at a constant rate throughout early development, they were not detected in mitochondrial polysomes until 18 hr after fertilization.     

The relationship of protein and lipid synthesis during the biogenesis of mitochondrial membranes

Summary Rat liver mitochondria were fractionated into inner and outer membrane components at various times after the intravenous injection of¹⁴C-leucine or¹⁴C-glycerol. The time curves of protein and lecithin labeling were similar in the intact mitochondria, the outer membrane fraction, and the inner membrane fraction. In rat liver slices also, the kinetics of³H-phenylalanine incorporation into mitochondrial KCl-insoluble proteins was identical to that of¹⁴C-glycerol incorporation into mitochondrial lecithin. These results suggest a simultaneous assembly of protein and lecithin during membrane biogenesisThe proteins and lecithin of the outer membrane were maximally labeledin vivo within 5 min after injection of the radioactive precursors, whereas the insoluble proteins and lecithin of the inner membrane reached a maximum specific acitivity 10 min after injection.Phospholipid incorporation into mitochondria of rat liver slices was not affected when protein synthesis was blocked by cycloheximide, puromycin, or actinomycin D. The injection of cycloheximide 3 to 30 min prior to¹⁴C-choline did not affect thein vivo incorporation of lecithin into the mitochondrial inner or outer membranes; however treatment with the drug for 60 min prior to¹⁴C-choline resulted in a decrease in lecithin labeling. These results suggest that phospholipid incorporation into membranes may be regulated by the amount of newly synthesized protein available.When mitochondria and microsomes containing labeled phospholipids were incubated with the opposite unlabeled fractionin vitro, a rapid exchange of phospholipid between the microsomes and the outer membrane occurred. A slight exchange with the inner membrane was observed.     

DNA import into mitochondria

In recent decades, it has become evident that the condition for normal functioning of mitochondria in higher eukaryotes is the presence of membrane transport systems of macromolecules (proteins and nucleic acids). Natural competence of the mitochondria in plants, animals, and yeasts to actively uptake DNA may be directly related to horizontal gene transfer into these organelles occurring at much higher rate compared to the nuclear and chloroplast genomes. However, in contrast with import of proteins and tRNAs, little is known about the biological role and molecular mechanism underlying import of DNA into eukaryotic mitochondria. In this review, we discuss current state of investigations in this area, particularly specificity of DNA import into mitochondria and its features in plants, animals, and yeasts; a tentative mechanism of DNA import across the mitochondrial outer and inner membranes; experimental data evidencing several existing, but not yet fully understood mechanisms of DNA transfer into mitochondria. Currently available data regarding transport of informational macromolecules (DNA, RNA, and proteins) into the mitochondria do not rule out that the mechanism of protein and tRNA import as well as tRNA and DNA import into the mitochondria may partially overlap.     

Protein and nucleic acid synthesis during imbibition of dormant and after-ripened Vaccaria pyramidata seeds.

The regulation of nucleic acid and protein synthesis in dormant, thermodormant, and after-ripened embryos of Vaccaria pyramidata (Caryophyllaceae) has been studied. Germination of after-ripened V. pyramidata seeds is prevented by inhibitors of protein, RNA, and DNA synthesis. The synthesis of both protein and RNA is activated at the beginning of imbibition, whereas [³H]thymidine incorporation does not start until the second period of the imbibition phase. [³H]Thymidine incorporation is greatly reduced in embryos treated with cycloheximide or 6-methylpurine. There is no correlation between the level of [³H]uracil and l-[¹⁴C]leucine incorporation into macromolecules and the physiological state of the seeds: tRNA, ribosomal RNA, and poly(A)-containing RNA (probably mRNA) as well as proteins are synthesized at the same rate in both dormant and thermodormant embryos as in after-ripened embryos. The protein patterns of dormant and after-ripened embryos are similar, as shown by electrophoresis and electrofocusing of double-labeled proteins. The level of DNA synthesis, measured as [³H]thymidine incorporation, may, on the other hand, indicate the physiological activity of the seeds: [³H]Thymidine is incorporated at a high rate in after-ripened embryos only and remains at a low level in dormant or thermodormant embryos. This correlation is, however, observed only in the axes. DNA synthesis in the cotyledons does not show any relation to the developmental stage of the seeds. These results are discussed in relation to the regulation of dormancy and after-ripening of seeds.     

Variance of ploidy in mitochondrial nucleus during spherulation in Physarum polycephalum

In Physarum polycephalum, microplasmodia differentiated into spherules when cultures were aged for 8–10 days. Respiration rates of the microplasmodia decreased rapidly with ageing to a 90% decrease in oxygen consumption over 9 days. We studied this phenomena by isolating and characterizing mitochondria from microplasmodia and spherules at different stages of spherulation. Oxygen uptake by the isolated mitochondria decreased with spherulation. Morphological and biochemical analyses showed that mitochondrial differentiation to inactive state was characterized by a decrease not only in dimension but also of content (DNA, RNA and protein). Diminutive mitochondria contained small particle-shaped mitochondrial nuclei. The DNA content, measured by microscopic fluorometry, was about 1.15 and 0.58 × 10⁻¹⁰ g, which corresponded to about 16 and 8 genome copies, respectively (e.g., 32 genome copies per mitochondrion at mitochondrial G1). Restriction endonuclease analysis showed that the physical structure and methylation pattern of the mtDNA had not changed although the DNA content per mitochondrion had decreased remarkably with spherulation. This showed that changes in the ploidy level of the mitochondrial nucleus during spherulation were due to reduction in the number of whole mitochondrial genomes.     

Pyrimidine biosynthesis and its regulation in the developing rat brain.

—Measurements of the incorporation of [¹⁴C]NaHCO₃ into orotic acid, uridine nucleotides and RNA in tissue minces establish the occurrence of the complete orotate pathway for the de novo biosynthesis of pyrimidines in rat brain. Selective inhibition of the incorporation of various radiolabelled precursors into orotic acid by uridine demonstrates the operation of a feedback control mechanism in brain minces and indicates carbamoylphosphate synthetase to be the site of inhibition; purine nucleosides were similarly found to inhibit the de novo biosynthesis of pyrimidines. The activity of the orotate pathway, as assessed by the rate of incorporation of [¹⁴C]NaHCO₃ into orotic acid, was found to be very high in fetal brain and to decline rapidly with neurological development; the mature rat brain exhibits less than 1% of the activity of the fetal brain at 18 days of gestation. Comparative studies on the ability of minces of the brain and several extraneural tissues to utilize [¹⁴C]NaHCO₃ and [¹⁴C]aspartate as precursors of orotic acid lead us to speculate that variations in the ability of tissues to synthesize orotic acid de novo are determined by similar variations in their ability to synthesize carbamoylphosphate.