Ferritin mRNA is found on bound as well as on free polyribosomes in rat heart

Free and endoplasmic reticulum-bound polyribosomes from rat heart were examined for their ferritin mRNA content. A procedure for separation and purification of the two ribosome populations that produced good yields of homogeneous mono- and polyribosomes with no contaminating ultrastructures and gave distinctive sedimentation profiles in 15-50% sucrose gradients was developed. 14C-labeled free and bound polyribosomes added to heart preparations indicated that only 3% of free and 5.5% of bound polyribosomes cross-contaminated the bound and free fractions, respectively. RNA from both polyribosome populations hybridized with [32P]cDNA for rat ferritin. The extent of hybridization with mRNA from endoplasmic reticulum (ER)-derived polyribosomes was much greater than what could be accounted for by cross-contamination with free polyribosomes. This indicates that heart ferritin is synthesized not only on free polyribosomes for internal use in iron storage but also on ER-bound polyribosomes, where it may be destined for secretion into the plasma.     

Differential effects of iron and inflammation on ferritin synthesis on free and membrane-bound polyribosomes of rat liver.

We have examined the distribution of ferritin mRNA to free and endoplasmic reticulum (ER)-bound liver polyribosomes during inflammation and iron treatment of rats. Postnuclear tissue supernatants were fractionated on a discontinuous sucrose gradient developed to separate free and bound polyribosomes. Total RNA recovered averaged 3.2 mg/g tissue, 40% of which was with ER and 30% with the free polyribosomes, about 25% being with the postribosomal/RNP fraction. Slot-blot hybridization of equal portions of RNA revealed that 12 h after injection of turpentine to induce inflammation, ferritin mRNA was concentrated on the ER-bound polyribosomes, while it was concentrated on the free polyribosomes 2 h after injection of ferric ammonium citrate. Differences were highly significant, based on multiple determinations and densitometry. Profiles of ferritin mRNA distribution on linear sucrose gradients corroborated the differential findings. Concentrations of total ferritin mRNA per gram liver doubled with iron treatment but were not significantly different 12 h after turpentine treatment. At the same time point after turpentine, ferritin protein synthesis was increased twofold, as measured by the 1 h incorporation of [14C]leucine. We conclude that a significant portion of ferritin mRNA always associates with the ER-bound polyribosomes, and that inflammation and iron differentially alter the polysomal distribution of ferritin mRNA, suggesting that two different kinds of mRNA may be involved.     

Translational control during the acute phase response. Ferritin synthesis in response to interleukin-1.

Interleukin-1 (IL-1 beta) increases the synthesis of both heavy and light (L)-ferritin subunits when added to human hepatoma cells (HepG2) grown in culture. RNase protection and Northern blot analysis with L-ferritin probes revealed that no changes in L-ferritin mRNA levels occur after cytokine stimulation. However, the induction coincides with an increased association of the L-subunit mRNA with polyribosomes. Since the recruitment of stored ferritin mRNA onto polyribosomes is seen when iron enters the cell, the effect of IL-1 beta on iron uptake was tested and was found to be unaffected by the lymphokine. Neither transferrin receptor mRNA levels nor the number of receptors displayed on the cell surface was affected by IL-1 beta. However, the action of the cytokine on ferritin translation is inhibited by the action of the intracellular iron chelator deferoxamine. These data indicate that IL-1 beta induces ferritin gene expression by translational control of its mRNA. The pathway of induction is different from iron-dependent ferritin gene expression whereas regulation requires the background presence of cellular iron.     

Translational regulation of ferritin synthesis in rat spleen: effects of iron and inflammation

Translational control of ferritin synthesis was studied in rat spleen, and compared with that for liver, heart and brain, in response to iron and inflammation. Spleen concentrations of total RNA in the ribonucleoprotein (mRNP) fraction was comparable to that for liver, while polyribosomal RNA was less. Both fractions were ten-fold lower in heart and brain. In untreated animals, the mRNP fraction of all tissues had the largest portion of the ferritin mRNA, as determined by slot blot hybridization with 32P-labeled cDNA for the L subunit. Acute treatment with ferric ammonium citrate shifted the spleen ferritin mRNA to the polyribosome fraction. This was also so in liver but not in the heart and brain which took up much less iron. The findings were confirmed by hybridization studies of mRNPs and polyribosomes separated in sucrose gradients. Turpentine-induced inflammation also caused a shift in ferritin mRNA from the mRNP to the polyribosome fraction of spleen and liver, over 12 h. We conclude that as in liver, spleen ferritin synthesis is under translational control by iron, and that both tissues also respond to inflammation by shifting of ferritin mRNA to the polyribosomes.     

Biosynthesis of ferritin in rat hepatoma cells and rat livers. I. Synthesis and assembly of protein subunits of ferritin.

Cell fractions were prepared from ACI rat livers and from rat hepatoma cell clone M-5123-C1. Radioimmunoassays of ferritin and of its protein subunits in various cell fractions after biosynthetic labeling with [14C]leucine were done by means of ferritin-specific and subunit-specific rabbit antibody. In both ACI rat livers and M-5123-C1 hepatoma cells free polyribosomes synthesized approximately 81% of the protein subunits of ferritin, and membrane-bound polyribosomes synthesized the rest. In both polyribosomal fractions, [14C]leucine-labeled subunits were detected earlier than [14C]leucine-labeled ferritin and apoferritin (5 min as against 30 min after initiation of a pulse). Time sequence studies of the shifts of biosynthetically labeled subunits and ferritin through different cell compartments provided evidence for vectorial transport of subunits and of ferritin, the direction of transport being from the two polyribosomal systems to the smooth membrane compartment and to the cytosol.     

Diversity and nature of ribosomal pools in hepatoma 7800 and host liver

1. The ribosomal components in the postmitochondrial supernatant of a rat hepatoma (hepatoma 7800) and the corresponding host liver were examined for diversity and functional competence. 2. The ;free' and ;membrane-bound' polyribosomes of both tissues were equally active in vivo and had equilibrated with newly synthesized ribosomes 4hr. after administration of [6-(14)C]orotic acid. 3. The inactive monomer-dimer pool in hepatoma 7800 was unattached to membranes and a larger fraction of the polyribosomes was free in hepatoma than in liver. 4. By using sensitivity to puromycin as a criterion, evidence was obtained that most of the polyribosomes in hepatoma 7800 were active in vivo. 5. Actinomycin, azaguanine and carbon tetrachloride caused marked conversion of polyribosomes into inactive monomers and dimers in the host liver and moderate conversion in the hepatoma. 6. Significant accumulation of ferritin and shifts in the mean polyribosome size to the lighter species occurred in the host liver of rats bearing large hepatomas.     

Both subunits of rat liver ferritin are regulated at a translational level by iron induction.

A few hours after administering iron to rats, liver ferritin synthesis increases several fold. However, Northern blot analysis with cDNA probes for ferritin light (L) and heavy (H) subunit mRNAs failed to show an increase in total population of either messenger. Cytoplasmic distribution of ferritin messages was therefore investigated in control and iron administered rats killed at 3.5 hours. The liver post-mitochondrial supernatant was fractionated on a sucrose gradient to separate polyribosomes, monosomes, ribosomal subunits and cell sap. RNA extracted from each fraction and analyzed using Northern blotting showed that 65% of the total mRNA population for each subunit was present in the cell sap of control rats, presumably as mRNP particles since ribosomal RNA was absent from this fraction. After iron administration, these reserves of free mRNA were recruited onto the polysomes, reducing the free mRNA pool to 15% of the total. We interpret this to be due to activation of blocked ferritin messages on entry of iron into the cell.     

Stereo-electron microscopy and energy-dispersive x-ray analysis of avian reticulocytes.

Utilizing the techniques of stereo-electron microscopy (stereo-EM) and energy-dispersive x-ray analysis (EDX), we have studied aspects of the ultrastructure of avian reticulocytes. Stereo-EM of thin sections (0.10 to 0.25 mum thick) stained with uranyl and lead revealed the three-dimensional arrangement of 25 nm chromatin fibers on the tangential surfaces of nuclei. Use of the Bernhard staining procedure in combination with stereo-EM permitted a three-dimensional view of the interchromatin spaces and channels leading to the nuclear pores, and of cytoplasmic polyribosomes. With either staining technique we frequently encountered in the cytoplasm clusters and paracrystalline arrays of electron-dense granules with granule diameters approximately 1/2 that of monomer ribosomes. These granules were highly electron-dense in unstained specimens and have been identified as intracellular ferritin on the basis of the similarity of their ultrastructural morphology to that of horse spleen ferritin and their high content of iron as determined by EDX. The possibility that these granules represent toxic products of phenylhydrazine treatment (Heinz bodies) is considered unlikely, since we have demonstrated in this study that Heinz bodies cannot be visualized in unstained preparations, do not reveal the same granular structure, and do not contain significant amounts of iron above background. The occurrence of intracellular ferritin is discussed in light of current concepts of iron transport and storage during erythropoiesis.     

Translational control of gene expression in a normal fibroblast. Characterization of a subclass of mRNAs with unusual kinetic properties

The translation of a small number of mRNAs in mouse SC-1 fibroblasts can be stimulated by cycloheximide, under conditions where the synthesis of most proteins is inhibited. These mRNAs are ordinarily present in small polyribosomes or messenger ribonucleoprotein particles, although the addition of cycloheximide drives them into large (greater than or equal to 5) polysomes. These mRNAs cannot be translated in vitro unless they are extracted with phenol. With such treatment, however, they are translated with normal competitive efficiencies. In iron-poor media, the mRNA for ferritin exhibits several of the distinctive kinetic properties of this class of mRNAs. With iron supplementation, however, ferritin translation appears normal. These observations are consistent with the existence of translational induction/repression systems in eukaryotes. Several types of evidence suggest that repressors may act by interfering with the interaction between mRNAs and limiting translational initiation components.     

Biosynthesis of collagen and other proteins on tightly and loosely bound polyribosomes from chick embryos]

Free polyribosomes and polyribosomes bound to endoplasmic membranes were isolated from 10-day-old chick embryos by differential centrifugation. The tightly and loosely bound polyribosomal fractions were isolated from the membrane-bound polyribosomes using 0,5 M KCl. The synthesis of collagen and non-collagen proteins on the polyribosomes were studied in a homologous cell-free system. It was shown that the polyribosomes tightly bound to the membranes possess a lower protein-synthesizing activity as compared to free and loosely bound polyribosomes. The amount of bacterial collagenase-cleaved polypeptides in the protein product synthesized on the polyribosomes tightly and loosely bound to the memranes and on free polyribosomes is 31, 23 and 9%, respectively. The data obtained suggest that the loosely bound polyribosomes are actively involved in collagen synthesis and that this fraction is not a contamination of free polyribosomes in the preparations of totally bound polyribosomes. The role of tightly and loosely bound polyribosomes in the formation of the membrane polyribosomal complex is discussed.     

Resonance Raman spectra of heme a derivatives. Evidence for the reaction of peripheral formyl group with HCN and NaHSO3.

A separate and distinct population of polyribosomes exists in the detergent-washed nuclei of adenovirus-infected HeLa cells. These polyribosomes, released by exposure to polynucleotides such as high molecular weight nuclear RNA or poly(U), do not appear to be cytoplasmic contaminants. Nuclear polyribosomes have a considerably lower buoyant density compared to cytoplasmic ones. Nuclear polyribosomes, in a cell-free system of protein synthesis, are six- to eight-fold less active compared to cytoplasmic ones and are insensitive to aurin tricarboxylic acid. They do not complement cytoplasmic polyribosomes in protein synthesis in the cell-free system. Finally, the number of proteins synthesized by nuclear polyribosomes is higher compared with that synthesized by the cytoplasmic ones. Only the virus-specific proteins, including P-VII, are synthesized by cytoplasmic polyribosomes. Nuclear polyribosomes, on the other hand, synthesize virusspecific proteins, including P-VII and VII, and a number of additional proteins not synthesized by the cytoplasmic ones.     

Distribution of histone messenger RNA among free and membrane-associated polyribosomes of a mouse myeloma cell line

The distribution of histone messenger RNA among free polyribosomes and two classes of membrane-associated polyribosomes was studied in an immunoglobulin-secreting mouse myeloma cell line. The two classes of membrane polyribosomes were distinguished on the basis of their sensitivity to dissociation from membranes upon exposure to high concentrations of salt or during repeated centrifugation through sucrose. Histone messenger RNA is specifically excluded from that class of polyribosomes most tightly associated with cellular membranes.     

BIOSYNTHESIS OF COLLAGEN : Biochemical and Physicochemical Characterization of Collagen-Synthesizing Polyribosomes

Synthesis of collagen on polyribosomes has been demonstrated in vitro in chick embryo corium by radioisotope incorporation, zone centrifugation through sucrose gradients, and analytical ultracentrifugation. Collagen synthesis was associated with polyribosomes ranging in size, as reflected by their sedimentation constants, from about 180S to approximately 1600S. Most of the newly formed collagen, hydroxyproline, was present on the largest polyribosome aggregates (~ 350–1600S), but small polyribosomes (~180–200S) also contained collagen. On the basis of the proline-¹⁴C/hydroxyproline-¹⁴C ratios and the disrupting effect of collagenase, the proposal is made that the 350–1600S polyribosomes from this tissue are involved predominantly in collagen synthesis. The large polyribosomes are disrupted extensively by collagenase but only partially by ribonuclease and trypsin. Therefore, it appears that they are stabilized by the interaction of newly forming collagen chains. Evidence is presented consistent with the hypothesis that these large polyribosomes are formed by the aggregation of small polyribosomes (180–200S) through the interaction of collagen polypeptides. It is suggested that these small polyribosomes might be involved in the synthesis of subunits of the collagen alpha chain.     

Free and membrane-bound chloroplast polyribosomes Chlamydomonas reinhardtii.

Over half of the chloroplast ribosomes isolated from growing cultures of Chlamydomonas reinhardtii are bound to chloroplast thylakoid membranes if completion of nascent polypeptide chains is prevented by chloramphenicol. The free chloroplast ribosomes are recovered in homogenate supernatants, and presumably originate from the chloroplast stroma. Only about 10% of these free chloroplast ribosomes are polyribosomes, even under conditions when 70% of free cytoplasm ribosomes are recovered as polyribosomes. The nonionic detergent Nonidet P-40 liberates atypical polyribosomes (Type I), from membranes, which require both ribonuclease and proteases for complete conversion to monomeric ribosomes. Thus Type I particles are held together by mRNA but are also held together by peptide bonds. These Type I polyribosomes probably are not bound to intact membrane, but might be bound to some protein-containing sub-membrane particle. The Type I polyribosomes are dissociated to ribosomal subunits by puromycin and high salt, and contained 0.2 to 1 nascent chain per ribosome. If membranes are treated with Nonidet and proteases at the same time, polyribosomes which are digested to monomeric ribosomes by ribonuclease alone (Type II) are obtained. Type II polyribosomes are smaller than Type I, and probably represent the true size distribution of polyribosomes on the membranes. At least 50% of the membrane-bound ribosomes are polyribosomes, since that much membrane bound chloroplast RNA is recovered as Type I or Type II polyribosomes.     

Inhibitory action of erythromycin on protein biosynthesis by isolated polyribosomes

Consistent with the previous work by Pestka (Antimicrob. Agents Chemother.5, 255, 1974) on the binding of erythromycin to polyribosomes, we found that erythromycin does not inhibit protein synthesis catalyzed by polyribosomes. This is due to the presence of nascent peptidyl tRNA on the naturally occurring polyribosomes. In a soluble extract from E. coli pretreated to remove the ribosome releasing factor, polyribosomes without nascent polypeptides remain intact and can catalyze protein synthesis in the absence of initiation. In this system erythromycin effectively inhibited protein synthesis. The inhibition by erythromycin was caused by premature release of oligopeptidyl tRNA from polyribosomes.     

The effect of cycloheximide on incorporation of newly formed mRNA into membrane-bound polyribosomes in rat liver cells]

Incorporation kinetics of new synthesized mRNA into free and endoplasmic membrane-bound polyribosomes in the absence of normal translation (when protein synthesis in inhibited by 98% with cycloheximide) is studied. mRNA is found to incorporate into both free and bound polyribosomes. Relative content of new synthesized membrane-bound polyribosomes in the presence of cycloheximide within 2.5-4.5 hours is by 30-40% lower as compared with the control. This fact can be explained either by the absence of a growing peptide of a sufficient length, which is necessary for the formation of a part of membrane-bound polyribosomes, or by a restricted number of attachment sites on membranes as a result of delayed translation of mRNA in pre-existed polyribosomes. It is suggested that 1) the growing peptide in liver cells is responsible for the recognition of a membrane only under the formation of only one type of membrane-bound polyribosomes, or 2) the formation of all bound polyribosomes has a single mechanism and the growing peptide does not participates in the membrane recognition.     

Polyribosome size analysis. Measurement of number-average polyribosome sizes

The analysis of translational efficiencies of specific mRNAs requires a determination of the polyribosome size. The appropriate value to use in such calculations is the number-average size. A method is described for accurately measuring the number-average size of total and of specific protein synthesizing polyribosomes using isokinetic sucrose density gradients and 125I-labeled antibodies. By this method, we demonstrated that albumin synthesizing polyribosomes from a serum albumin secreting mouse hepatoma cell line exist over a broad range from trimers to 20-mers (mean 6-10). The specificity of antibody interaction with polyribosomes was demonstrated using cells not synthesizing mouse serum albumin, and by demonstrating that 125I-anti ovalbumin does not bind to mouse hepatoma polyribosomes. Treatment of the mouse hepatoma cells with 1 MUM cycloheximide shifted practically all of the monomers into polyribosomes resulting in an increase in the number-average size of the albumin synthesizing polyribosomes. Cycloheximide treatment, however, did not eliminate the size heterogeneity in the albumin synthesizing polyribosomes.