Half-life and rate of synthesis of globin messenger ribonucleic acid. Determination of half-life of messenger ribonucleic acid and its relative synthetic rate in erythroid cells

The specific radioactivity of mouse globin mRNA in blood reticulocytes was measured after injection of [(3)H]uridine into anaemic mice up to 60h before collection of reticulocytes. From these data, the decay of the acid-soluble nucleotide pool in the marrow and the relative marrow-cell composition it is possible to build models that allow the cell life-times and half-life of mRNA in the erythroid cells of the marrow to be calculated. Best fit of models to these data favour a model with either one or two cell divisions from the onset of mRNA synthesis. The single-cell-division model has cell times of 20, 13 and 7h respectively for the basophilic erythroblast, polychromatophilic erythroblast and reticulocyte. The two-cell-division model has cell times of 12, 12, 12 and 7h for the basophilic erythroblast 1 and 2, polychromatophilic erythroblast and reticulocyte respectively. Both models have an mRNA half-life of 17h and a constant rate of mRNA synthesis until enucleation at the reticulocyte stage, when synthesis stops. A declining rate of mRNA synthesis can be accommodated in a two-cell-division model, when synthesis halves at each cell division and cell times are essentially the same as above, but mRNA half-life is either 9h in the basophilic and polychromatophilic erythroblasts and 17h in the later cells, or 10h in the basophilic erythroblasts and polychromatophilic erythroblasts and 14.5h in later cells. In all cases it is clear that mRNA synthesis occurs over a time-period of only 30-36h and that mRNA cannot be pre-synthesized in precursor erythroid cells.     

Analysis of the ratio of alpha- to beta-globin and globin messenger ribonucleic acid content of fractionated rabbit erythroid bone-marrow cells.

The ratio of alpha- to beta-globin mRNA was measured by hybridization of a constant amount of highly purified alpha- or beta-globin cDNA (complementary DNA) with increasing amounts of RNA in the range up to 20% cDNA hybridization, where an essentially linear reaction is obtained. Statistical analysis indicates that the ratio of alpha- to beta-globin can be measured within a maximal error of +/- 0.3 and in most cases is better than +/- 0.15. Under these conditions there is no significant deviation from the ratio of 1.3 in the alpha- to beta-globin mRNA ratio of RNA isolated from erythroid cells rich in pronormoblasts through to reticulocytes. If the ratio of alpha- to beta-globin mRNA exceeded 1.7 or was less than 0.9 in pronormoblasts, it would be detected in these experiments. The overall globin mRNA content increases to a maximal value in the fractions rich in basophilic normoblasts of 30,000--50,000 molecules/cell. However, the accuracy of these determinations is not as great as for the ratio determinations, and no significant deviations were seen except in the cells rich in pronormoblasts, which contained less globin mRNA than the later stages.     

Interaction between polyuridylic acid and rabbit globin messenger ribonucleic acid

Poly(U) binds to globin mRNA in 0.1m-NaCl. Studies with ribonuclease digestion of this complex suggest that there are polyadenylate-rich sequences in the mRNA containing about 30-40 adenylate residues. The sequences appear to be homogenous and of approximately the same length for both alpha- and beta-globin mRNA. They are most likely located at the 3' terminus of the molecule.     

The identification of globin messenger ribonucleic acid in newt erythropoietic cells.

Polyadenylated [poly(A)+]-RNA isolated from newt (Triturus cristatus) erythropoietic cells contained two main species sedimenting at 9S and 25S, and minor amounts of a 15-20S component. The 9S poly(A)+-RNA fraction induced synthesis of newt haemoglobin and globins in frog oocytes and in an mRNA-dependent rabbit reticulocyte lysate, confirming its identity as newt globin mRNA. Translation of 9S globin mRNA in reticulocyte lysate was concentration-dependent, the patterns of globin synthesis suggesting both preferential utilization and unequal amounts of the different globin mRNA subspecies. Globin mRNA activity was also evident in the 25S poly(A)+-RNA fraction whose localization in polyribosomes excluded its function as a nuclear globin mRNA precursor. Denaturation in formamide and estimation of its relative methyl content indicated that the 25S poly(A)+-RNA fraction contained equimolar amounts of 9S globin mRNA and 26S rRNA. Translation of the 25S fraction in reticulocyte lysate was less efficient than that of comparable amounts of 9S globin mRNA and induced a pattern of globin synthesis similar to that obtained with subsaturating amounts of 9S mRNA. The 25S mRNA-rRNA complex was considered to be a non-physiological aggregate generated by extraction of RNA in the presence of buffers of moderate to high ionic strength.     

A precursor of globin messenger RNA

The size of pulse-labeled globin messenger RNA nucleotide sequences was investigated, to determine whether newly transcribed globin mRNA molecules are larger than steady-state globin mRNA. Molecular hybridization techniques were used to compare directly the sedimentation of steady-state (unlabeled) and pulse-labeled (radioactive) globin mRNA sequences in the same analytical sucrose gradient. In gradients containing 98% formamide, radioactive globin mRNA sequences from mouse fetal liver cells labeled for 15 to 20 minutes with [³H]uridine sediment in a broad band with a peak at approximately 14 S, while steady-state globin mRNA sediments at 10 S. The large radioactive RNA can be recovered from one gradient and recentrifuged in a second gradient, in which it again sediments in a broad band with a peak at 14 S. The large radioactive RNA is cleaved to 10 S during a 75-minute “chase” with either actinomycin D or unlabeled uridine plus cytidine. The estimated half-life of the precursor is 45 minutes or less under these conditions. A covalent RNA precursor larger than 18 S with a similar turnover rate is not observed.     

Cordycepin. An inhibitor of newly synthesized globin messenger RNA.

The effect of cordycepin (3'-deoxyadenosine) on newly synthesized globin mRNA in cultured mouse fetal liver erythroid cells is investigated. At cordycepin concentrations that do not inhibit amino acid incorporation into acid-precipitable material, the quantity of pulse-labeled (radioactive) globin mRNA nucleotide sequences is reduced by 90%, as compared to adenosine-treated controls. The reduction of radioactivity in globin-specific RNA sequences is greater than the inhibition of total RNA synthesis in experiments in which the labeling times range from 6 to 60 min. Control experiments demonstrate that cordycepin does not reduce the recovery of total cell RNA or steady state (unlabeled) globin mRNA. The hybridization assay used to detect radioactive globin mRNA sequences is independent of the cellular location or the number of 3'-terminal adenylate residues in the mRNA-containing molecules. These data thus indicate that cordycepin inhibits newly synthesized mRNA as effectively as it inhibits ribosomal and transfer RNA synthesis.     

Changes in globin messenger RNA content during erythroid cell differentiation.

Previous studies have shown that mouse fetal erythroid precursor cells isolated by an immunological technique synthesize little or no globin and contain little, if any, globin mRNA, as assayed in a cell-free system (translatable mRNA). After culture for 10 hours in the presence of erythropoietin, there is a marked increase in globin synthesis and in translatable globin mRNA. The present studies were designed to measure directly the content of globin mRNA sequences during erythroid cell differentiation, by molecular hybridization with 3H-labeled DNA complementary to globin mRNA. The results indicate that few, if any, globin mRNA sequences are present in the total RNA of erythroid precursor cells. There is little or no pool of untranslated globin mRNA in these cells. After 10 hours of culture with erythropoietin, there is an increase in globin mRNA content, as ;easured by a change in the Cot1/2 values obtained by cDNA: mRNA hybridization with (Co) representing the concentration of RNA. Between 0 and 22 hours of culture, there is a 250-fold rise, and between 22 and 44 hours, a further 2-fold increase in globin mRNA content. During the 44 hours in culture, the number of cells in culture increases 2- to 3-fold. The number of globin mRNA molecules rises in erythroid precursor cells to an average value of 1800 molecules/cell during 22 hours of culture. In cultures without added erythropoietin, the absolute number of cells decreases, however, cells presumably induced to differentiate by exposure to erythropoietin in vivo continue to differentiate in vitro, accumulating globin mRNA and initiating globin synthesis.     

Molecular modifications associated with Aging of globin messenger RNA in vitro.

Using polyacrylamide gel elution-electrophoresis in aqueous medium, highly purified rabbit globin mRNA can be fractionated into several populations of molecules differing by their mean poly(A) content. Both alpha and beta globin mRNA are heterogenous with respect to their electrophoretic mobilities. With the conditions used no separation of alpha and beta globin mRNA occurs during electrophoresis. From the specific radioactivity distribution in the different mRNA fractions one can conclude that the polyadenylate sequence at the 3' end of globin mRNA molecules becomes shorter with aging. This shortening occurs on alpha as well as beta, globin mRNAs and the extent of heterogeneity in poly(A) content is similar for both globin mRNAs. Furthermore, using two different methods of mRNA fractionation (polyacrylamide gel elution-electrophoresis and elution of poly (U)-Sepharose-bound mRNA at increasing temperatures) it is shown that old mRNA molecules differ from relatively young messages in their ability to direct cell-free globin synthesis. Modifications reducing template activity in vitro thus seem to take place during globin mRNA aging.     

A specific dimerization of rabbit beta-globin messenger ribonucleic acid.

Rabbit globin mRNA, when layered in low salt on 0.1 M-NaCl/sucrose gradients, separates into two peaks of material. Translation of these two RNA fractions in the wheat-germ cell-free system, hybridization against globin complementary DNA (cDNA) and cross-hybridization against cDNA species prepared from each fraction show that the first peak sedimenting at 10S is a alpha-globin mRNA and the second peak, sedimenting at approx. 15S, is beta-globin mRNA. The sedimentation rate of the beta-globin mRNA is concentration-dependent. By changing concentration and pH, it is indicated that in low-salt beta-globin mRNA adopts a conformation that leads to specific, but weak, self-dimerization during centrifugation in 0.1M-NaCl. This property permits rapid preparation of intact and relatively pure alpha- and beta-globin mRNA species.     

The effect of trimethoprim on macromolecular synthesis in Escherichia coli. General effects on ribonucleic acid and protein synthesis

In trimethoprim-inhibited RC(str) strains of Escherichia coli, the expression of the RC control of stable RNA synthesis arose primarily from a decrease in the intracellular concentrations of glycine and methionine, and not from inhibition of the initiation of new protein chains. In non-supplemented cultures, experiments with rifampicin showed that the immediate response to the addition of trimethoprim was a rapid decrease in the rate of initiation of RNA chains. This was followed after a few minutes by a sufficiently large fall in the rate of endogenous synthesis of nucleotide bases to cause a decrease in the rate of RNA chain polymerization. Inhibition of RNA chain initiation was thus overridden by an accumulation of DNA-dependent RNA polymerases upon the cistrons. RC(rel) strains also accumulated polymerases upon the DNA in similar circumstances, but did not suffer the initial effects on chain initiation. If purines were supplied before adding trimethoprim, RC(str) strains polymerized RNA chains at normal rates, but initiation rates were permanently decreased. In either situation, an increased% of the RNA formed was mRNA. However, in RC(rel) strains supplemented with bases, trimethoprim did not affect either the rate of initiation of new chains or their rates of polymerization or the relative rates of synthesis of stable RNA and mRNA. Protein synthesis was also severely inhibited by trimethoprim. Though the addition of glycine and methionine to base-supplemented, trimethoprim-inhibited RC(str) strains did not apparently affect the decreased rate of protein synthesis, RNA accumulation resumed at its normal rate. Thus, the inhibition of protein chain initiation had no effect on the rate of RNA accumulation in either RC(str) or RC(rel) bacteria. The RC control does not express itself through inhibitions of protein synthesis at this level.     

Mouse kidney nonpolysomal messenger ribonucleic acid: metabolism, coding function, and translational activity

To elucidate the distribution and function of mRNA in mouse kidney cytoplasm, we compared mRNA isolated from polysomal (greater than 80S) and native postpolysomal (20--80S) ribonucleoproteins with respect to synthesis and lifetime, sequence content, and translational activity. The 20--25% of cytoplasmic mRNA recovered from postpolysomal ribonucleoprotein is similar to polysomal mRNA in size (20--22S), in apparent half-life (11--13 h), in major products of cell-free translation, and in nucleotide complexity (approximately 4 x 10(7) nucleotides). The labeling kinetics of polysomal and postpolysomal mRNA suggest these mRNA populations are in equilibrium. [3H]cDNAs transcribed from polysomal and from postpolysomal poly(A)-containing mRNAs react with template mRNA and with the heterologous mRNA at the same rate (Cot1/2 approximately 6.3 mol.s/L) and to the same extent (95%). Therefore, these mRNAs are equally diverse and homologous and occur at similar relative frequencies. Postpolysomal mRNA directs cell-free protein synthesis at only approximately 30% of the rate of polysomal mRNA and to only 30% of the extent of mRNA from polysomes. Postpolysomal mRNA is approximately 3-fold less sensitive than polysomal mRNA to inhibition of translation by m7GMP, suggesting postpolysomal mRNA contains a greater fraction of molecules deficient in 5'-terminal caps. Postpolysomal mRNA may derive from renal mRNAs that initiate translation inefficiently and thus accumulate as postpolysomal ribonucleoproteins.     

A simple method for the purification of reticulocyte globin messenger ribonucleic acid

A relatively simple and inexpensive method has been developed for the preparation of highly purified rabbit reticulocyte globin mRNA. After phenol extraction, polysomal RNA was chromatographed on Sigmacell type 38 cellulose and Sepharose 4B. The resulting mRNA preparation has a purity in excess of 90%. No selective loss of either alpha or beta globin mRNA is observed.     

Contribution of polyadenylate sequences to the translational efficiency of globin messenger RNAs.

mRNAs from reticulocyte polysomes were fractionated by chromatography on poly(U)-Sepharose and thermal elution. The molar ratio of alpha- to beta-globin mRNA was found to be 2:1 and 1:1 respectively in short- and long-poly(A) size classes. Translational analyses indicated that the globin mRNAs containing long poly(A) tracts (with a mean length of about 70 nucleotides) directed protein synthesis with higher rates than did mRNA containing short poly(A) tracts (15-35 nucleotides). Experiments performed with sub-saturating mRNA concentrations showed that the digestion with RNAase H induced a decrease in the translational capacity of both globin mRNAs and an increase in the alpha- to beta-globin synthesis ratio. No correlation was observed between the size of the poly(A) tail in mRNA and the optimal K+ requirement for translation.     

Ribonucleic acid synthesis in rabbit erythroid cells.

Kinetic studies on the synthesis of RNA in mature bone-marrow erythroid cells from rabbits were made by measuring the incorporation of [2-3H]adenosine into the ATP pool and RNA over periods up to 8h. By use of equations to fit the pool specific radioactivity and an equation using the same type of pool to generate the rate of linear DNA synthesis, good agreement between the pool parameters is found, provided that the ATP pool is measured in whole cell extracts, and assuming that the dATP and ATP pools equilibrate rapidly. RNA-synthesis rates were measured by using curve fits to equations developed by using the pool specific-radioactivity curves. The rate of synthesis of poly(A)-containing RNA varied in three experiments from 90 to 220mol/min per cell, with half-life of nuclear processing of 12-22 min with a mean of 16 min. Ribosomal RNA is synthesized at a rate of 70-200 mol/min per cell with an average half-life of nuclear processing of 37 min for the 18S RNA and 214 min for the 28S RNA. When the stable rRNA components are subtracted from the nRNA synthesis, the rate of nRNA synthesis is between 2 and 6fg/min per cell with an average half-life of degradation of 27 min. The rate of synthesis of poly(A)-containing RNA is 1.5-3.5% of the RNA-synthesis rates. These rates are compared with the RNA-synthesis rates found in L cells and concentrations of globin mRNA found in various erythroid-cell preparations.