Polyribosome metabolism, growth and water status in the growing tissues of osmotically stressed plant seedlings

Relationships between growth of osmotically stressed intact seedlings and polyribosome levels and water status of growing tissues were examined. Sudden exposure of barley (Hordeum vulgare L. cv. Arivat) roots to a solution of ?0.8 MPa polyethylene glycol caused leaf growth to stop almost immedately, but growth resumed at a much lower rate after 0.5–1 h. In the growing region of leaves, the polyribosome: total ribosome ratio of free (non-membrane-bound) ribosomes was significantly reduced after 15 min stress, but a decrease in the large polyribosome:total polyribosome ratio occurred only after 1–2 h. Membrane-bound and free polyribosome levels both decreased to 70% of unstressed control values after 4 h stress. Recovery of total polyribosomes occurred within 1 h after relief of 4 h stress, but required 3 h after relief of 24 h stress. Stress detectably reduced the water potential and osmotic potential of growing tissue within 0.5–1.0 h, and osmotic adjustment continued for up to 10 h. Recovery of water status was incomplete after 1 h relief of a 4 h stress. In contrast, expanded blade tissues of stressed plants underwent minor changes in water status and slow decreases in polyribosomes levels. These results confirm that growing tissues of barley leaves are selectively responsive to stress, and suggest that changes in growth, water status and polyribosome levels may be initiated by the same signal. Measurements of seedling growth, polyribosome levels and water status of growing tissues of barley and wheat (Triticum aestivum L. cv. Zaragoza) leaves, etiolated pea (Pisum sativum L. cv. Alaska) epicotyl and etiolated squash (Cucurbita pepo L. cv. Elite) hypocotyl stressed with polyethylene glycol solutions of ?0.3 to ?0.8 MPa for 12 h or more showed that polyribosome levels were highly correlated with seedling growth rate as well as with tissue water and osmotic potentials, while turgor remained unchanged. These results suggest that long-term growth of osmotically stressed plants may be limited by a reduced capacity for protein synthesis in growing tissues and is not dictated by turgor loss.     

The selectivity and stoicheiometry of membrane binding sites for polyribosomes, ribosomes and ribosomal subunits in vitro.

Differences in the binding sites for polyribosomes, template-depleted ribosomes and large ribosomal subunits were found in microsomal derivatives of the rough endoplasmic reticulum. 1. The stoicheiometry of polyribosome and ribosome interaction in vitro with membranes was shown to be influenced by the relative concentration of interactants and the duration of their mixing. Large ribosomal subunits required a more prolonged mixing schedule to achieve saturation of membranes than did polyribosomes. 2. By using a procedure which minimized the effects on binidng by the stoicheiometric variables, competition between populations of polyribosomes, ribosomes and subunits for membrane sites showed that subunits, and to a lesser extent ribosomes, failed to block polyribosome attachment. 3. Polyribosomes isolated from liver, kidney and hepatoma 5123C entirely bound to a common membrane site, but some polyribosomes from myeloma MOPC-21 bound to other sites, perhaps influenced by their unique nascent proteins. 4. Subunit-binding sites appear on rough membranes only after endogenous polyribosomes have been removed, but no evidence that resulting changes in surface constituents are responsible was found. Large-subunit binding was largely abolished by lowering MgC12 concentration of 0.1 mM, whereas under the same conditions polyribosome binding was undiminished. 5. The large-subunit site appears to be distinct from the polyribosome site not only in the restriction of its affinity for particles but also spatially, to the extent that bound subunits do not hinder access of polyribosomes to their sites.     

THE IN VIVO PROTEIN SYNTHETIC ACTIVITIES OF FREE VERSUS MEMBRANE-BOUND RIBONUCLEOPROTEIN IN A PLASMA-CELL TUMOR OF THE MOUSE

Cytoplasmic extracts of the transplantable RPC-20 plasma-cell tumor were fractionated by sucrose density gradient centrifugation. Four major fractions were distinguished: (a) microsomes and mitochondria; (b) membrane-free polyribosomes; (c) free monomeric ribosomes; and (d) soluble fraction. The fractions were analyzed for RNA and lipid phosphorus, and their particulate components were characterized by electron microscopy. Particular attention was paid to the problem of membrane contamination of the free polyribosome fraction. It was shown that this contamination was small in relation with the total content of ribosomes in the fraction, and that it consisted primarily of smooth-surfaced membranes which were not physically associated with the polyribosomes themselves. In vivo incorporation studies were carried out by injecting tumor-bearing animals intravenously with leucine-C¹⁴, removing the tumors at various times thereafter, and determining the distribution of protein radioactivity among the gradient-separated cytoplasmic fractions. The free polyribosome and the microsome-mitochondria fractions constituted active centers for protein synthesis. It was shown that nascent protein of the free polyribosome fractions was not associated significantly with the contaminating membranes. The kinetics of labeling during incorporation times up to 11 min suggested that protein synthesized on the free polyribosomes was rapidly transferred in vivo to the soluble fraction of the cell, while protein synthesized by the microsomes and mitochondria remained localized within these elements. It was estimated that the free polyribosome fraction and the microsome-mitochondria fraction accounted for approximately equal proportions of the total cytoplasmic protein synthesis in vivo.     

ROLE OF RIBONUCLEASE ACTION IN PHENYLALANINE-INDUCED DISAGGREGATION OF RAT CEREBRAL POLYRIBOSOMES

—l -phenylalanine (1 mg/g body wt) or physiological saline (0.9% NaCl) was given intraperitoneally to infant (7-day old), immature (14-day old), and adult (42-day old) rats. The state of ribosomal aggregation was determined in the cerebral postmitochondrial supernatant and purified polyribosome fractions prepared in the presence of rat liver ribonuclease inhibitor. Polyribosomes isolated from cerebral cortices of infant and immature rats 30 or 60 min after administration of phenylalanine were partially disaggregated, whereas the state of aggregation of polyribosomes from mature cerebrum was unchanged. In contrast, little or no evidence of phenylalanine-induced polyribosome disruption was noted in the postmitochondrial supernatant fractions, from which the cerebral polyribosomes were prepared, in any of the animals. Omission of the ribonuclease inhibitor resulted in polyribosome disaggregation in the postmitochondrial supernatant fractions prepared from saline-treated as well as phenylalanine-treated infant rats, but the disruption was more profound in the latter group. Ribonuclease activities in cerebral postmitochondrial supernatant preparations from infant and immature rats were higher than the corresponding values in preparations from adult animals. In addition, the administration of phenylalanine resulted in increases in ribonuclease activities in cerebral postmitochondrial supernatant preparations from the younger animals, but had no effect on these activities in adult animals. These results suggest that alterations in structure and function of polyribosomes from the infant rat cerebrum following a loading dose of phenylalanine were related to exposure of the polyribosomes during isolation to elevated activities of cerebral ribonucleases resulting from this treatment. This hypothesis was supported by the finding that phenylalanine treatment had no effect on the incorporation in vivo of intracisternally-administered radioactive lysine into total, soluble or ribosomal protein of infant cerebrum. However, when cerebral ribosomal RNA was differentially labelled in phenylalanine-treated and saline-treated infant rats by the intracisternal administration of [³H] or [¹⁴C]uridine, and polyribosome fractions were then prepared from the pooled cerebral cortices of both groups, radioactive ribosomes derived from saline-treated rats were more highly aggregated than those derived from phenylalanine-treated animals. It is concluded that gross alterations in cerebral polyribosome structure and function do not occur in vivo in young rats given a large amount of phenylalanine intraperitoneally. However, this treatment, in addition to increasing ribonuclease activity in cerebral cell-free preparations, also sensitizes cerebral polyribosomes to subsequent breakdown upon exposure to ribonucleases during isolation.     

The 5' end of the pea ferredoxin-1 mRNA mediates rapid and reversible light-directed changes in translation in tobacco

Ferredoxin-1 (Fed-1) mRNA contains an internal light response element (iLRE) that destabilizes mRNA when light-grown plants are placed in darkness. mRNAs containing this element dissociate from polyribosomes in the leaves of transgenic tobacco (Nicotiana tabacum) plants transferred to the dark for 2 d. Here, we report in vivo labeling experiments with a chloramphenicol acetyl transferase mRNA fused to the Fed-1 iLRE. Our data indicate that the Fed-1 iLRE mediates a rapid decline in translational efficiency and that iLRE-containing mRNAs dissociate from polyribosomes within 20 min after plants are transferred to darkness. Both events occur before the decline in mRNA abundance, and polyribosome association is rapidly reversible if plants are re-illuminated. These observations support a model in which Fed-1 mRNA in illuminated leaves is stabilized by its association with polyribosomes, and/or by translation. In darkness a large portion of the mRNA dissociates from polyribosomes and is subsequently degraded. We also show that a significant portion of total tobacco leaf mRNA is shifted from polyribosomal to non-polyribosomal fractions after 20 min in the dark, indicating that translation of other mRNAs is also rapidly down-regulated in response to darkness. This class includes some, but not all, cytoplasmic mRNAs encoding proteins involved in photosynthesis.     

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.     

Alterations in the biosynthesis of proteins and nucleic acids in finger millet (Eleucine coracana) seedlings during water stress and the effect of proline on protein biosynthesis

The biosynthesis of DNA appeared to be unaffected in the water-stressed seedlings of finger millet (Eleucine coracana), but an increase in the synthesis de novo of RNA and proteins was observed during mild water stress. The polyribosome content was also increased in stressed finger millet seedlings. Proline, a solute which accumulates during water stress, enhanced the incorporation of radioactive precursors into proteins; caused an increase in translatability of finger millet messengers in vitro; and stabilized the polyribosomes isolated from normal seedlings. The results emphasize the role of proline in the adaptation of finger millet to the intermittent drought it experiences during cultivation.     

The effect of insulin on proteins associated with free,cytoskeletal-bound and membrane-bound polysome populations.

It is known that insulin treatment increases the rate of protein synthesis in many cells and tissues and that it causes changes in the distribution of ribosomes between free (FP), cytoskeletal-bound (CBP) and membrane-bound polysome (MBP) populations. This paper concerns an analysis of the pattern of proteins in high-salt extracts of FP, CBP and MBP isolated from Krebs II ascites and MPC-11 cells. A combined detergent/salt extraction procedure was used to isolate the three fractions of polysomes from control cells and from cells following short-term stimulation with insulin. There were differences in the protein patterns in the individual fractions and changes occurred after insulin stimulation.     

Transport of messenger RNA into different classes of membrane-associated polyribosomes in Ehrlich-ascites-tumor cells.

The membrane-bound polyribosomes in Ehrlich ascites tumor cells can be separated into a loosely bound and a tightly bound fraction by means of a high salt treatment. Both membrane fractions as well as the free polyribosomes in the supernatant synthesize about the same set of proteins, suggesting a close relationship between these polyribosome fractions in the Ehrlich cell. Relatively high concentrations of cycloheximide do not prevent newly synthesized poly(A)-containing mRNA from entering the tightly bound polyribosome fraction. Nor had treatment of the cells with puromycin in the presence of cycloheximide, which released about 70% of the nascent chains, any significant effect on the entrance of newly synthesized mRNA into tightly bound polyribosomes. These results suggest that in ehrlich ascites tumor cells nascent polypeptide chains are not involved in the binding of polyribosomes to membranes.     

OSMOTIC REGULATION OF α-AMYLASE SYNTHESIS AND POLYRIBOSOME FORMATION IN ALEURONE CELLS OF BARLEY

Water stress inhibits the gibberellic acid (GA₃)-induced synthesis of α-amylase in aleurone layers of barley (Hordeum vulgare L.). Electron microscope evidence indicates that the effect of water stress induced by 0.6 M solutions of polyethylene glycol (PEG) is to reduce the binding of ribosomes to the endoplasmic reticulum. This was confirmed by sucrose density gradient centrifugation of polyribosome preparations from stressed cells. The reduction in polyribosome formation does not result from reduced ribosome activity as measured by [³H]peptidylpuromycin formation. Thus, calculation of percent active ribosomes shows that osmoticum has little effect on the ability of ribosomes to incorporate puromycin into nascent protein. Water stress does not cause a marked decrease in the total RNA level of aleurone cells. Estimates of total RNA in postmitochondrial supernatant fractions from stressed cells show only a reduction of 8–9% relative to the control. Membrane synthesis measured by [¹⁴C]choline incorporation is depressed by 15% in cells stressed with 0.6 M PEG for 2.5 hours.     

Changes in ribosomal patterns and a related membrane fraction during induction of cold hardiness in mimosa epicotyl tissues

Sucrose gradient profiles of polyribosomes from epicotyl tissuesof mimosa seedlings (Albizzia julibrissin Durazzini) were followedthroughout induction of cold hardiness. An unusual fractionappeared in the polyribosome region of sucrose gradients withadvancing stages of cold hardiness. Treatment of this unusualfraction and polyribosome fractions with RNase, Triton X-100and deoxycholate suggests that the unusual fraction consistedof chloroplast or mitochondrial membrane fragments. Free polyribosome patterns were retained throughout inductionof cold hardiness. However, the presence of polyribosomes duringadvancing stages of cold hardiness does not necessarily insureactive protein synthesis. ¹ This investigation was supported in part by National ScienceFoundation Grant GB 8692. ² Contribution from the Missouri Agricultural Experiment Station.Journal Series Number 6253. (Received November 30, 1971; )     

Effect of osmotic stress on the formation of a population of polysomes and their stability in pea (<Emphasis Type="Italic">Pisum sativum</Emphasis> L.) seeds

Plants growing under natural conditions are constantly exposed to various stress factors, which can restrain their productivity and limit yields. This paper deals with the effect of long- and short-term osmotic stress followed by recovery on the formation of polysomes and their stability during germination of pea (Pisum sativum L.) seeds. By isolating polysomes, it is possible to obtain an index which evidences the ability of tissues to synthesize proteins. Changes in the distribution of polysomes often precede measurable changes in amounts of proteins. Under osmotic stress, the dominant population of polysomes was the population of free polysomes (FP). The share of membrane-bound polysomes (MBP) and cytoskeleton-bound polysomes (CBP) and cytoskeleton-membrane-bound polysomes (CMBP) in the total fraction of ribosomes increased under intensive (−1.0 and −1.5 MPa) osmotic stress. These results can suggest that the bound forms of polysomes play an important role in the synthesis of stress proteins. In addition, the stability of polysomes isolated from pea early seedlings growing under unstressed control and osmotic stress conditions was tested. It turned out that polysomes formed under osmotic stress conditions (especially the CMBP) were more resistant to the activity of exogenous ribonucleases than the polysomes in the control samples. Under stress conditions it is highly likely that ribosomes become more densely packed on mRNA thus making it more resistant to ribonuclease. This is just one of the many mechanisms regulating stability of mRNA.     

Localization of Polyribosomes Containing Alkaline Phosphatase Nascent Polypeptides on Membranes of Escherichia coli

A procedure has been developed for extracting membranes from bacterial cells under conditions that keep a large fraction of bacterial polyribosomes intact. Freeze-thawing spheroplasts in the presence of deoxyribonuclease, followed by differential centrifugation, permits a separation of free and membrane-associated polyribosomes. The latter fraction contains as much as 40% of cell ribosomal ribonucleic acid (RNA) and 55% of cell messenger RNA (mRNA). Nascent polypeptides were divided almost equally between the two fractions, but 70 to 80% of alkaline phosphatase nascent chains, detected both chemically and immunologically, were derived from polyribosomes associated with the bacterial membrane. Analysis of the fractions for mRNA specific for the lac and trp operons by RNA-deoxyribonucleic acid hydridization showed somewhat larger amounts on membrane than on free polyribosomes, but enrichment for nascent alkaline phosphatase (a secreted protein) on membranes was consistently greater, suggesting that polyribosomes making secreted proteins are more tightly bound to membranes. Electron micrographs of the membrane preparations show relatively intact membranes with clusters of polyribosomes on their inner surfaces.     

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.     

Electron microscopy of polyribosomes synthesizing immunoglobin chains. Comparison with sizes determined by density-gradient-sedimentation data

Polyribosomes from the immunoglobulin-producing plasma-cell tumour X5563 were fractionated on a linear sucrose gradient and fractions containing polyribosomes carrying heavy (H) and light (L) immunoglobulin chains were examined with the electron microscope. The size distribution of the polyribosomes in the various fractions was determined. The results are consistent with previous estimates by Williamson & Askonas (1967) of the size of the polyribosomes synthesizing immunoglobulin chains, despite some discrepancies in their calculations based on sedimentation data. In particular, polyribosomes of up to 18 ribosomes were present in the part of the gradient containing H-chain polyribosomes. The polyribosomal clusters appeared to be true linear aggregates of uniformly spaced ribosomes, arranged mostly in open or zig-zag configuration. The appearance of most of them does not seem to support a general helical model of the polyribosome.     

Polyribosome Content in Young and Aged Wheat Leaves Subjected to Drought

The effect of a droughting treatment on the polyribosome contentof wheat leaves was markedly different on leaves of differentages. Growing leaves showed a large decrease in their polyribosomepopulation, while fully expanded leaves showed no loss of polyribosomescompared with controls. These results suggest that the largereductions in polyribosome population observed in growing tissuesare due to reductions in growth, rather than a direct effectof water stress.     

Isolation of preparative amounts of polyribosomes from normal rabbit and guinea pig spleen]

Preparative amounts of polyribosomes were isolated from normal rabbit and guinea pig spleen; up to 40 optical units of the polyribosome preparation could be obtained by centrifugation in a Spinco L-2B centrifuge with SW-27 rotor. The amount of polyribosomes isolated from spleens of immune animals was 2-3 higher than that isolated from normal animal spleens. Concentration of polyribosomal preparations by lyophylization and the storage of dried preparations do not alter the sedimentation properties of the polyribosomes. The distribution pattern of normal rabbit spleen polyribosomes in a linear sucrose gradient and the sedimentation constants of the polyribosome peaks are in good agreement with data reported by some other authors for plasmocytome polyribosomes. Using electrophoresis in agarose-polyacrylamide gel the radioactive proteins synthesized in the cell culture of normal rabbit spleen it was shown that in normal spleen the average amount of globulins makes up to 35% of total protein synthesis, as reported by some authors.     

Phytochrome-mediated assembly of polyribosomes in etiolated bean leaves. Evidence for post-transciptional regulation of development.

Light operating through phytochrome controls the proportion of total ribosomes present as polyribosomes in etiolated leaves of Phaseolus vulgaris. Similar responses but with slightly different time courses are elicited by brief red light treatment and by continuous far-red or white light. The increase in polyribosome proportions after red light treatment reaches a maximum within 2 h, after which the proportion steadily declines. Light treatment appears to lead to increased proportions of polyribosomes in higher size classes. This is most evident with continuous white light, but probably also occurs with red and far-red light. The increase in polyribosomes is due principally to cytoplasmic ribosomes although proportionately greater effects are observed in chloroplast ribosomes. Although cordycepin inhibits RNA synthesis by 85-90% within 3 h there is no depression of the light-mediated increase in polyribosome proportions when leaves are preincubated in the inhibitor for 3 h. The data therefore indicate that phytochrome is capable of controlling protein synthesis, and thus development, at a post-transciptional level.