QUANTITATIVE ISOLATION AND PROPERTIES OF NEARLY HOMOGENEOUS POPULATIONS OF UNDEGRADED FREE AND BOUND POLYSOMES FROM RAT BRAIN1

Abstract— A procedure is described for the preparation of free and bound polysomes from whole homogenate of rat brain tissue. Brain is homogenized in a sucrose-polysome buffer medium high in KCl (250 mm). After a 12-min centrifugation at 135,000 g, the free polysomes in the supernatant are decanted and saved, while the membrane bound polysomes in the pellet are resuspended in homogenizing medium, homogenized in the presence of detergent (Triton X-100), centrifuged for 5min at 1470 g to remove nuclei, decanted, treated with deoxycholate and centrifuged for 10 min at 24,000 g to remove deoxycholate-insoluble material. Polysomes in the two supernatants are harvested by centrifugation through sucrose gradients prepared in high KCl polysome buffer, and with or without cell sap. Free and bound polysomes prepared in this manner are undegraded, equally active in cell-free protein synthesis, and largely free of the usual contaminants. Cross-contamination is minimal (>10%). The recovery of polysomes is at least 95%. The distribution of ribosomes and polysomes in rat brain is 58% free and 42% membrane-bound. The distribution of rat brain RNA is 65% ribosomal and 35% non-ribosomal. Conditions are described for the visualization and analysis of the entire complement of free and bound ribosomes. The size fractionation procedure is rapid and reproducible, requires much less ultracentrifugation than the density-gradient technique, and provides a nearly quantitative means of isolating undegraded free and bound polysomes of rat brain tissue.     

Phycobilisomes of Porphyridium cruentum. I. Isolation

A procedure was developed for the isolation of phycobilisomes from Porphyridium cruentum. The cell homogenate, suspended in phosphate buffer (pH 6.8), was treated with 1% Triton X-100, and its supernatant fraction was centrifuged on a sucrose step gradient. Phycobilisomes were recovered in the 1 M sucrose band. The phycobilisome fraction was identified by the characteristic appearance of the phycobilisomes, and the absorbance of the component pigments: phycoerythrin, R-phycocyanin, and allophycocyanin Isolated phycobilisomes had a prolate shape, with one particle axis longer than the other. Their size varied somewhat with their integrity, but was about 400–500 A (long axis) by 300–320 A (short axis). Phycobilisome recovery was determined at six phosphate buffer concentrations from 0.067 M to 1.0 M. In 0.5 M phosphate, phycobilisome yield (60%) and preservation were optimal. Such a preparation had a phycoerythrin 545 nm/phycocyanin 620 nm ratio of 8.4. Of the detergents tested (Triton X-100, Tween 80, and sodium deoxycholate), Triton X-100 gave the best results Freezing of the cells caused destruction of phycobilisomes.     

Some properties of bound and soluble dynein from sea urchin sperm flagella

Axonemes were isolated from sperm of Colobocentrotus by a procedure involving two extractions with 1% Triton X-100 and washing The isolated axonemes contained 7 x 10¹⁵ g protein per µm of their length. Treatment of the axonemes with 0 5 M KCl for 30 min extracted 50–70% of the flagellar ATPase protein, dynein, and removed preferentially the outer arms from the doublet tubules. Almost all of the dynein (85–95%) could be extracted from the axonemes by dialysis at low ionic strength. In both cases the extracted dynein sedimented through sucrose gradients at 12–14S, and no 30S form was observed The enzymic properties of dynein changed when it was extracted from the axonemes into solution. Solubilization had a particularly marked effect on the KCl- and pH-dependence of the ATPase activity. The pH-dependence of soluble dynein was fairly simple with a single peak extending from about pH 6 to pH 10. The pH-dependence of bound dynein was more complex. In 0.1 M KCl, the bound activity appeared to peak at about pH 9, and dropped off rapidly with decreasing pH, reaching almost zero at pH 7; an additional peak at pH 10 0 resulted from the breakdown of the axonemal structure and solubilization of dynein that occurred at about this pH. A similar curve was obtained in the absence of KCl, except for the presence of a further large peak at pH 8 Measurement of the kinetic parameters of soluble dynein showed that both K_m and V_max increased with increasing concentrations of KCl up to 0.5 M When bound dynein was assayed under conditions that would induce motility in reactivated sperm (0 15 M KCl with Mg⁺⁺ activation), it did not obey Michaelis-Menten kinetics, although it did when assayed under other conditions. The complex enzyme-kinetic behavior of bound dynein, and the differences between its enzymic properties and those of soluble dynein, may result from its interactions with tubulin and other axonemal proteins     

A method for visualizing and quantifying the total complement of free and membrane-bound ribosomes in rat liver.

A method is described for both visualization and quantification of the total complement of rat liver free and membrane-bound ribosomes, undegraded by nucleolysis and unaggregated by pelleting. The method involves: (a) differential centrifugation of liver homogenate which separates free and membrane-bound ribosomes; (b) treatment of the fractions with detergents to solubilize membranes and remove nuclei; (c) centrifugation of a portion of each fraction to remove all the ribosomes; (d) sedimentation of the samples and blanks on sucrose gradients; and (e) difference photometric scanning of the gradients, sample minus ribosome-free blank, to detect the ribosomes free of interference from nonribosomal materials. The use of the SW 56 rotor in the initial centrifugation and of a high Mg²⁺ concentration (20 mm) in the medium used to suspend the bound fraction prior to detergent treatment were found to be essential in obtaining bound polysomes of large size (～19-somes). The difference scanning technique is shown to be a sensitive, accurate, and reproducible means of eliminating interference from nonribosomal materials, principally detergents and protein, and of quantifying ribosomes in both fractions. The method is rapid (3.5 h), simple to perform, and well suited for the analysis of multiple liver samples. It can be used to assess the concentration, distribution, organization, and average size of the total complement of rat liver free and membrane-bound ribosomes in a single experiment.     

In vitro exchange of ribosomal subunits between free and membrane-bound ribosomes

Studies on the distribution of isotopieally labeled ribosomal subunits between free and membrane-bound ribosomes from rat liver showed that, upon release of nascent polypeptides in vitro, the small subunits of membrane-bound ribosomes could exchange with small subunits derived from free polysomes. However, under the same conditions, the large subunits of membrane-bound ribosomes did not exchange efficiently with large subunits derived either from free or bound polysomes; instead, the addition of large subunits caused a transfer of microsomal small subunits into a newly formed pool of free monomers.The small subunit exchange required a macromolecular fraction of the cell sap, was stimulated by ATP or GTP, and occurred at low concentrations of magnesium ions.Sodium dodecyl sulfate, polyacrylamide gel electrophoresis revealed close similarities between the protein complement of subunits from free and membrane-bound ribosomes, with the exception of one protein band which was more intense in free large subunits.     

In vitro amino acid incorporation into myosin by free polysomes of rat skeletal muscle

Rat skeletal muscle polysomes were separated into free and membrane-bound fractions by centrifugation through 2M sucrose. About 80% of total ribosomes extracted were recovered as free polysomes. Sucrose gradient experiments showed similar size distribution patterns for both free and bound polysomes. Chromatographic and electrophoretic analyses of proteins in the cell free amino acid incorporation system indicated that free polysomes are capable of synthesizing myosin.     

The rough endoplasmic reticulum is the site of reserve-protein synthesis in developing Phaseolus vulgaris cotyledons

Cytyledons of the common bean, Phaseolus vulgaris L., were incubated with radioactive amino acids at different stages of seed development. The proteins were fractionated by ion-exchange chromatography, sucrose gradients, and sodium dodecylsulfate (SDS) polyacrylamide gel electrophoresis. From 16 to 28 d after flowering about 40% of the incorporated radioactivity was associated with the polypeptides of vicilin and 10% with those of phytohemagglutinin.Polysomes were isolated from developing cotyledons 20–25 d after flowering and free polysomes were separated from membrane-bound polysomes. Aurintricarboxylic acid, an inhibitor of initiation in cell-free translation systems, did not inhibit the incorporation of amino acids into in-vitro synthesized proteins, indicating that synthesis was limited to the completion of already initiated polypeptides. Autofluorography of SDS-polyacrylamide gels showed that the two classes of polysomes made two different sets of polypeptides and that there was little overlap between these two sets.Four polypeptides similar in size to the 4 polypeptides of vicilin were made by membrane-bound polysomes and not by free polysomes. Antibodies specific for vicilin bound to those 4 polypeptides. Free polysomes made only polypeptides which did not bind to antibodies specific for vicilin. Antibodies against phytohemagglutinin did not bind to any of the invitro synthesized polypeptides.The membranes to which the polysomes were bound were characterized on sucrose gradients and by electron microscopy. Polysomes recovered from membranes which banded on top of 35 and 50% sucrose synthesized the vicilin polypeptides most rapidly. These membrane fractions were rich in vesicles of rough endoplasmic reticulum (ER). The ER marker-enzyme NADH-cytochrome-c reductase banded with an average density of 1.18 g/cm³ (40% w/w sucrose) on continuous gradients. These experiments demonstrate that the ER is the site of vicilin synthesis in developing bean cotyledons. Quantitative determinations of several ER parameters (RNA and lipid-phosphate content, NADH-cytochrome-c-reductase activity) show that expansion of the cotyledons is accompanied by a 4-6-fold increase in ER.     

Cation regulation in the smooth muscle of frog stomach

Cation composition of frog smooth muscle cells was investigated. Fresh stomach muscle rings resembled skeletal muscle, but marked Na gain and K loss followed immersion. Mean Na (49.8–79.7 mM/kg tissue) and K (61.8–80.1 mM/kg tissue) varied between batches, but were stable for long periods in vitro. Exchange of 6–30 mM Na/kg tissue with ²²Na was extremely slow and distinct. Extracellular water was estimated from sucrose-¹⁴C uptake. Calculated exchangeable intracellular Na was 9 mM/kg cell water, and varied little. Thus steady-state transmembrane cation gradients appeared to be steep. K-free solution had only slight effects. Ouabain (10^-4 M) caused marked Na gain and reciprocal K loss; at 30°C, Na and K varied linearly with time over a wide range of contents, indicating constant net fluxes. Net fluxes decreased with temperature decrease. ²²Na exchange in ouabain-treated tissue at 20–30°C was rapid and difficult to analyze. The best minimum estimates of unidirectional Na fluxes at 30°C were 10–12 times the constant net flux; constant pump efflux may explain these findings. The rapidity of Na exchange may not reflect very high permeability, but it does require a high rate of transport work.     

Requirement for extraction of polyribosomes from barley tissue

The isolation of barley (Hordeum vulgare L.) polyribosomes, showing minimal degradation effects of endogenous RNase, required a buffer adjusted to pH 8.0 and containing 0.40 m KCl in addition to common extraction components. The extracted polyribosomes were characterized in sucrose gradients by their conversion to monosomes when incubated with pancreatic RNase and by their dependence on adequate amounts of Mg²⁺ during extraction and analysis. Factors which contributed to polyribosome stability were evaluated by the relative sedimentation rates of aggregates in sucrose gradients. Tissue extraction at KCl concentrations less than 0.40 m and below pH 8.0 resulted in an appearance of larger amounts of ribosomes in the less dense region of the sucrose gradient after centrifugation. The addition of 10 mm dithiothreitol was partially effective in preventing the loss of higher polymerized states of polyribosomes at KCl concentrations below 0.40 m. Extractions conducted at KCl concentrations greater than 0.40 m and at pH 8.0 reduced the amount of ribosomes obtained from the tissue. The monosome portion of the polyribosomal profile was partially dissociated into subunits when the tissue was extracted in 0.60 m KCl. A similar effect on monosomes was obtained when polyribosomes were incubated with cycloheximide and 0.40 m KCl, a result not observed by use of a combination of 0.10 m KCl and the drug or 0.40 m KCl alone.     

A procedure for the quantitative recovery of homogeneous populations of undegraded free and bound polysomes from rat liver.

A procedure is described for the preparation of free and bound polysomes from whole homogenates of rat liver tissue. Liver is homogenized in a conventional medium containing glutathione; then after a 12-min centrifugation at 131000g, the free polysomes in the supernatant are saved, while the membrane-bound polysomes in the pellet are suspended in a mixture of ribonuclease inhibitors (cell sap, 250 mM KCl, and glutathione), homogenized in the presence of detergent (Triton X-100), centirfuged for 5 min at 1470g, decanted, and treated with deoxycholate; the polysomes in the two supernatants are harvested by centrifugation through sucrose gradients containing 250 mM KCl and cell sap. Free and bound polysomes prepared in this manner are undegraded, equally active in cell-free protein synthesis, and virtually free of ribonuclease, membranous material, glycogen, deoxycholate, completed protein, and cross-contamination. The recovery of polysomes is approximately 95% and the distribution between the free and membrane-bound state is 25 and 75%, respectively. The molecular weight profiles after sodium dodecyl sulfate-acrylamide gel electrophoresis of the polypeptides completed and released by free and bound polysomes in vitro are different, indicating that there are quantitative differences in the synthesis of various size polypeptides between the two polysome classes. The differential centrifugation procedure is rapid and reproducible, requires much less ultracentrifugation than the isopycnic technique, and provides a nearly quantitative means of separating free and bound polysomes.     

ISOLATION OF AN INSULIN SECRETION GRANULE FRACTION

Goosefish islets were homogenized in 0.25 M sucrose and separated into nuclear, mitochondrial + secretion granule, microsomal, and supernatant fractions. Eighty per cent of the cytochrome oxidase activity and 75 per cent of the bioassayed insulin activity were found in the mitochondrial + secretion granule fraction (6000 g for 10 minutes). The mitochondrial + secretion granule fraction was further subfractionated by centrifugation (2 hours at 100,000 g and 0°C) using a continuous linear density gradient 1.0–2.0 M sucrose). Eighteen to 20 subfractions were collected by piercing the bottom of the tube and collecting drops. The total protein was distributed into a bimodal curve consisting of a high density component, which contained 90 per cent of the insulin (secretion granules), and a lower density component, which contained the cytochrome oxidase activity (mitochondria).     

Studies on lysosomes. XI. Characterization of a hydrolase-rich fraction from human lymphocytes

Pure suspensions of human lymphocytes were separated from peripheral blood by means of nylon wool, homogenized in 0.34 M sucrose-0.01 M EDTA solution, and fractionated by differential centrifugation. The bulk of acid hydrolase activity was found to be concentrated in a 20,000 g x 20 min granular fraction, whereas nuclear, debris, and supernatant fractions contained lesser concentrations of hydrolases. Acid hydrolase activity present in the granular fraction showed appropriate "latency" as judged by its dose-dependent release into the 20,000 g x 20 min supernatant after exposure to membrane-disruptive agents such as streptolysin S, filipin, and lysolecithin. Heparin proved to be necessary in the suspending medium so that reproducible homogenization and cell fractionation could be obtained. Even excessive contamination of lymphocyte suspensions with platelets did not appreciably alter the acid hydrolase activity of lymphocyte homogenates or the distribution of enzymes in subcellular fractions. Discontinuous density-gradient centrifugation of a 500 g x 10 min supernatant, containing both acid hydrolase-rich organelles and mitochondria, resulted in partial resolution of hydrolase-rich organelles from mitochondria. Fine structural studies of the intact lymphocytes showed the presence of acid phosphatase-positive, membrane-bounded organelles. Electron microscopy of the "large granule" (20,000 g x 20 min) fraction of such lymphocytes demonstrated 80–90% mitochondria, 5–10% platelets, and 5–10% membrane-bounded acid phosphatase-positive structures. The data indicate the presence in human peripheral blood lymphocytes of acid hydrolase-rich granules which possess many of the biochemical and structural characteristics of lysosomes in other tissues.     

Choline permeability in cardiac muscle cells of the cat

Permeability of the cardiac cell membrane to choline ions was estimated by measuring radioactive choline influx and efflux in cat ventricular muscle. Maximum values for choline influx in 3.5 and 137 mM choline were respectively 0.56 and 9 pmoles/cm²·sec. In 3.5 mM choline the intracellular choline concentration was raised more than five times above the extracellular concentration after 2 hr of incubation. In 137 mM choline, choline influx corresponded to the combined loss of intracellular Na and K ions. Paper chromatography of muscle extracts indicated that choline was not metabolized to any important degree. The accumulation of intracellular choline rules out the existence of an efficient active pumping mechanism. By measuring simultaneously choline and sucrose exchange, choline efflux was analyzed in an extracellular phase, followed by two intracellular phases: a rapid and a slow one. Efflux corresponding to the rapid phase was estimated at 16–45 pmoles/cm²·sec in 137 mM choline and at 1.3–3.5 pmoles/cm²·sec in 3.5 mM choline; efflux in 3.5 mM choline was proportional to the intracellular choline concentration. The absolute figures for unidirectional efflux were much larger than the net influx values. The data are compared to Na and Li exchange in heart cells. Possible mechanisms for explaining the choline behavior in heart muscle are discussed.     

The sedimentation behaviour of ribonuclease-active and -inactive ribosomes from bacteria

1. The `30s' and `50s' ribosomes from ribonuclease-active (Escherichia coli B) and -inactive (Pseudomonas fluorescens and Escherichia coli MRE600) bacteria have been studied in the ultracentrifuge. Charge anomalies were largely overcome by using sodium chloride–magnesium chloride solution, I 0·16, made 0–50mm with respect to Mg²⁺. 2. Differentiation of enzymic and physical breakdown at Mg²⁺ concentrations less than 5mm was made by comparing the properties of E. coli B and P. fluorescens ribosomes. 3. Ribonuclease-active ribosomes alone showed a transformation of `50s' into 40–43s components. This was combined with the release of a small amount of `5s' material which may be covalently bound soluble RNA. Other transformations of the `50s' into 34–37s components were observed in both ribonuclease-active and -inactive ribosomes at 1·0–2·5mm-Mg²⁺, and also with E. coli MRE600 when EDTA (0·2mm) was added to a solution in 0·16m-sodium chloride. 4. Degradation of ribonuclease-active E. coli B ribosomes at Mg²⁺ concentration 0·25mm or less was coincident with the formation of 16s and 21s ribonucleoprotein in P. fluorescens, and this suggested that complete dissociation of RNA from protein was not an essential prelude to breakdown of the RNA by the enzyme. 5. As high Cs⁺/Mg²⁺ ratios cause ribosomal degradation great care is necessary in the interpretation of equilibrium-density-gradient experiments in which high concentrations of caesium chloride or similar salts are used. 6. The importance of the RNA moiety in understanding the response of ribosomes to their ionic environment is discussed.     

Polyribosomes from Peas: III. Stimulation of Polysome Degradation by Exogenous and Endogenous Calcium

Attempts were made to isolate microsomes from Pisum sativum L. var. Alaska by low speed centrifugation of a postmitochondrial supernatant made 8 mm in Ca²⁺. However, the addition of Ca²⁺ in concentrations as low as 1 mm to the postmitochondrial supernatant resulted in extensive polysome degradation. Degradation was dependent on both Ca²⁺ concentration and the duration of incubation. Resuspension of isolated polysomes in Ca²⁺-containing buffer did not result in degradation, whereas resuspension in Ca²⁺-containing postpolysomal supernatant did. Both Ca²⁺ and a heat-labile factor in the supernatant were required for polysome degradation. The degradation in the homogenate with or without added Ca²⁺ could be reduced by (a) dilution with larger volumes of grinding buffer, (b) increasing the concentration of tris-HCl in the grinding buffer, (c) adding diethylpyrocarbonate or ethyleneglycol-bis (2-aminoethylether) tetraacetic acid (a specific calcium chelator) prior to homogenization or immediately after the addition of Ca²⁺. Endogenous Ca²⁺ can increase the destruction of polysomes during their isolation in this tissue, presumably by activating a ribonuclease. Addition of Ca²⁺ is not a useful technique for separating undegraded free and membrane-bound polyribosomes.     

Mitoribosomes from Candida utilis. Morphological, physical, and chemical characterization of the monomer form and of its subunits

Highly purified mitochondrial ribosomes (mitoribosomes) have been obtained from the yeast Candida utilis. Sedimentation analysis in sucrose gradients made in 5 mM MgCl₂, 1 mM Tris, pH 7.4 and 50 mM KCl clearly distinguishes mitoribosomes (72S) from cytoplasmic ribosomes (cytoribosomes) (78S). Mitoribosomes are completely dissociated into 50S and 36S subunits at 10^-4 M MgCl₂ whereas complete dissociation of cytoribosomes into 61S and 37S subunits occurs only at 10^-6 M MgCl₂ Electron microscopy of negatively stained mitoribosomes (72S peak) shows bipartite profiles, about 265 x 210 x 200 A Characteristic views are interpreted as frontal, dorsal, and lateral projections of the particles, the latter is observed in two enantiomorphic forms Mitoribosome 50S subunits display rounded profiles bearing a conspicuous knoblike projection, reminiscent of the large bacterial subunit. The 36S subunits show a variety of angular profiles. Mitoribosomal subunits are subject to artifactual dimerization at high Mg²⁺ concentration Under these conditions, a supplementary 80S peak arises. Electron microscopic observation of the 80S peak reveals closely paired particles of the 50S type Buoyant density determinations after glutaraldehyde fixation show a single peak at ρ = 1.48 for mitoribosomes and 1.53 for cytoribosomes In the presence of ethylenediaminetetraacetate (EDTA), two species of RNA, 21S and 16S, are obtained from mitoribosomes, while 25S and 17S RNA are obtained from cytoribosomes It is established that the small and large RNA species are derived from the 36S and 50S subunits, respectively, by extraction of the RNA from each subunit The G + C content of the RNA is lower for mitoribosomes (33%) than for cytoribosomes (50%). Incubation of C utilis mitochondria with leucine-¹⁴C results in the labeling of 72S mitoribosomes. The leucine-¹⁴C incorporation is inhibited by chloramphenicol and resistant to cycloheximide Puromycin strips the incorporated radioactivity from the 72S mitoribosomes, which is consistent with the view that leucine-¹⁴C is incorporated into nascent polypeptide chains at the level of mitoribosomes     

Potassium fluxes in dialyzed squid axons

Measurements have been made of K influx in squid giant axons under internal solute control by dialysis. With [ATP]_i = 1 µM, [Na]_i = 0, K influx was 6 ± 0.6 pmole/cm² sec; an increase to [ATP]_i = 4 mM gave an influx of 8 ± 0.5 pmole/cm² sec, while [ATP]_i 4, [Na]_i 80 gave a K influx of 19 ± 0.7 pmole/cm² sec (all measurements at ∼16°C). Strophanthidin (10 µM) in seawater quantitatively abolished the ATP-dependent increase in K influx. The concentration dependence of ATP-dependent K influx on [ATP]_i, [Na]_i, and [K]_o was measured; an [ATP]_i of 30 µM gave a K influx about half that at physiological concentrations (2–3 mM). About 7 mM [Na]_i yielded half the K influx found at 80 mM [Na]_i. The ATP-dependent K influx responded linearly to [K]_o from 1–20 mM and was independent of whether Na, Li, or choline was the principal cation of seawater. Substances tested as possible energy sources for the K pump were acetyl phosphate, phosphoarginine, PEP, and d-ATP. None was effective except d-ATP and this substance gave 70% of the maximal flux only when phosphoarginine or PEP was also present.     

Polyribosomes from peas: an improved method for their isolation in the absence of ribonuclease inhibitors

Profiles of polyribosomes were obtained from etiolated stem segments of Pisum sativum L. var. Alaska isolated in various buffers. Tissue homogenized in a medium containing 0.2 m tris-HCl, pH 8.5, 0.2 m sucrose, 30 mm MgCl₂, and 60 mm KCl yielded polyribosomes exhibiting far less degradation than tissue homogenized in conventional media containing tris-HCl at lower ionic strength and pH. A further decrease in degradation was found when polyribosomes were sedimented through a sucrose pad buffered at pH 8.5 prior to centrifugation. Increased separation was obtained using heavy (125-500 mg/ml), linear sucrose gradients. Using these techniques, messenger RNA species bearing up to 12 ribosomes (dodecamers) were resolved, with messenger RNA chains bearing 9 ribosomes (nonamers) being the most abundant (having the highest absorption peak). The data presented suggest that buffer of high ionic strength and high pH was more effective in preventing degradation of polyribosomes than was diethyl pyrocarbonate and, furthermore, that ratios involving large polyribosomes (hexamers and larger) were more accurate indices of degradation than were ratios involving total polyribosomes.     

Evidence that free polysomes are not the precursors of membrane-bound polysomes in rat liver

We tested, in rat liver, the postulate that free polysomes were precursors of membrane-bound polysomes. Three methods were used to isolate free and membrane-bound ribosomes from either post-nuclear or post-mitochondrial supernatants of rat liver. Isolation and quantitation of 28 S and 18 S rRNA allowed determination of the 40 S and 60 S subunit composition of free and membrane-bound ribosomal populations, while pulse labeling of 28 S and 18 S rRNA with [6-¹⁴C]orotic acid and inorganic [³²P]phosphate allowed assessment of relative rates of subunit renewal. Throughout the extra-nuclear compartment, 40 S and 60 S subunits were present in essentially equal numbers, but, free ribosomes contained a stoichiometric excess of 40 S subunits, while membrane-bound ribosomes contained a complementary excess of 60 S subunits. Experiments with labeled precursors showed that throughout the extra-nuclear compartment, 40 S and 60 S subunits accumulated isotopes at essentially equal rates, however, free ribosomes accumulated isotopes faster than membrane-bound ribosomes. Among free ribosomes or polysomes, 40 S subunits accumulated isotopes faster than 60 S subunits, but, this relationship was not seen among membrane-bound ribosomes. Here, 40 S subunits accumulated isotope more slowly than 60 S subunits. This distribution of labeled precursors does not support the postulate that free polysomes are precursors of membrane-bound polysomes, but, these data suggest that membrane-bound polysomes could be precursors of free polysomes.     

Ribosome crystallization in chicken embryos. I. Isolation, characterization, and in vitro activity of ribosome tetramers

Isolated tetrameric particles (166S) derived from the crystalline lattices known to appear in hypothermic chicken embryos consist of mature 80S ribosomes which contain all species of ribosomal RNA and a complete set of ribosomal proteins. Ribosome tetramers are not a special type of polysomes since in solutions of high ionic strengths (500 mM KCl and 50 nM triethanolamine-HCl buffer) containing 5 mM MgCl₂ they dissociate into 40S and 60S ribosomal subunits, without the need of puromycin, and at a concentration of Mg⁺⁺ higher than 3 mM they are not disassembled by mild RNase treatment. Tetramers spontaneously disassemble into 80S monomers when the Mg⁺⁺ concentration is lowered to 1 mM at relatively low ionic strength. Tetramers failed to couple in vitro puromycin-³H into an acid-insoluble product, indicating the lack of nascent polypeptide chains. Although tetramers have no endogenous messenger RNA activity, they can be programmed in vitro with polyuridylic acid (poly U) to synthesize polyphenylalanine. All ribosomes within a tetramer can accept poly U, without the need of disassembly of the tetramers into monomers or subunits.