Inhibition of protein synthesis by ricin: experiments with rat liver mitochondria and nuclei and with ribosomes from Escherichia coli (Short Communication)

1. Ricin, a toxic protein from the seeds of Ricinus communis which inhibits poly(U)-directed polyphenylalanine synthesis by rat liver ribosomes (Montanaro et al., 1973), does not affect protein synthesis by isolated rat liver mitochondria. 2. The toxin is ineffective also on poly(U)-directed polyphenylalanine synthesis in reconstituted systems with ribosomes isolated from rat liver mitochondria or from Escherichia coli. 3. Ricin inhibits protein synthesis by isolated rat liver nuclei, but at concentrations much higher than those affecting rat liver ribosomes.     

Effect of Inhibition of Macromolecule Synthesis on the Association of Bacteriophage T4 DNA with Membrane

The "Mg(2+)-Sarkosyl crystals" (M band) technique distinguishes between membrane-bound and free intracellular DNA. This procedure was employed to investigate the nature of the reactions necessary to convert input T4 DNA to a rapidly sedimenting form. Energy poisoning inhibits this attachment reaction. Neither protein nor DNA synthesis appears to be required, but experiments with rifampin and extensively irradiated T4 suggest that RNA synthesis is involved. These results were confirmed by a second procedure for the determination of rapidly sedimenting DNA.     

Ribonucleic acid and protein synthesis in Rhizophlyctis rosea zoospores

LéJohn, Herbert B. (Purdue University, Lafayette, Ind.), and James S. Lovett. Ribonucleic acid and protein synthesis in Rhizophlyctis rosea zoospores. J. Bacteriol. 91:709-717. 1966.-The uniflagellate zoospores of Rhizophlyctis rosea display active motility and a high endogenous respiratory metabolism, but neither growth nor net ribonucleic acid (RNA) or protein synthesis can be measured by ordinary procedures. Nevertheless, synthesis can be detected with isotopic precursors. Uracil-C(14) is incorporated slowly into both the soluble and ribosomal RNA. Analysis of zoospore extracts (on diethylaminoethyl cellulose columns or sucrose gradients) after various periods of labeling suggested that most of the uracil incorporation represents slow synthesis of ribosomal precursor RNA and, ultimately, ribosomes. Actinomycin D caused an 80% inhibition of uracil incorporation. The most rapidly labeled RNA was susceptible to extensive degradation in cells treated with actinomycin, but the percentage of stable RNA increased with the time of incorporation before addition of the antibiotic. Neither the effects of actinomycin nor the results of chase experiments have established unequivocally the existence of turnover or the presence of a short-lived "messenger" fraction in motile spores. Both leucine and methionine were slowly incorporated into a spectrum of cellular proteins. The methyl group of C(14)-methylmethionine also served as a methyl donor for the methylation of soluble RNA but not of ribosomal RNA. The observations that some of the newly synthesized RNA and protein occur in the intact 82S ribosomes and that actinomycin inhibits the low level of protein synthesis provide some indirect evidence for a very low rate of "messenger" synthesis and turnover in zoospores.     

The mode of action of zaluzanin C, an inhibitor of translation in eukaryotes

Zaluzanin C, a substance extracted from several species of the genus Zaluzania (Compositae), has been shown to inhibit protein synthesis in intact HeLa cells preferentially to DNA and RNA synthesis. "In vitro" protein synthesis was also blocked by zaluzanin C and the study of the effects of the drug on resolved model systems indicates that it inhibits enzymic translocation of peptidyl-tRNA specifically.     

THE EFFECT OF PROTEIN SYNTHESIS INHIBITION ON THE ENTRY OF MESSENGER RNA INTO THE CYTOPLASM OF SEA URCHIN EMBRYOS

Emetine is a potent inhibitor of protein synthesis in sea urchin embryos. At a concentration of the drug that rapidly inhibits protein synthesis in blastulae by 95%, uridine incorporation into RNA continues for more than 1 hr and presumptive histone messenger RNA is synthesized and transported into the cytoplasm where it is apparently associated with polyribosomes. Possible explanations of this result and its implications for the "informasome" theory of messenger transport in embryonic cells are discussed.     

Lack of correlation between overall protein synthesis and the onset of cell elongation in germinating embryos of Haplopappus gracilis

10⁻⁵M abscisic acid (ABA) completely inhibits germination or (if seeds deprived of integuments are used) embryo elongation in Haplopappus gracilis (Nutt.) Gray. Nevertheless, considerable rates of protein and RNA synthesis were found in embryos grown in abscisic acid, at least during the early hours after sowing. On the contrary, seeds grown in cycloheximide + fusicoccin (a powerful promoter of cell expansion), where protein synthesis is almost completely inhibited, show full protrusion of radicle, thus simulating a "germination" process. These results suggest that some of the most important events involved in seed germination, i.e. protein and RNA synthesis, and cell elongation which leads to radicle protrusion, may not necessarily be linked together and are possibly regulated by different control mechanisms. Moreover, when seeds or embryos are grown in abscisic acid + fusicoccin, protein synthesis is considerable, cell elongation is greater than in water controls at least for 12 h, and germination in its early stages appears to be normal; but DNA synthesis and cell division are not resumed, possibly since some other factor is required. All these findings propose a reevaluation of criteria for defining successful germination.     

Heat-shock inhibits protein synthesis and eIF-2 activity in cultured cortical neurons

Stress, such as heat-shock, hypoxia and hypoglycemia, inhibits the initiation of protein synthesis. The effects of heat-shock on protein synthesis, eucaryotic initiation factor 2 (eIF-2) activity, protein kinase C (PKC), and casein kinase II (CKII) activities were studied in primary cortical neuronal cultures. In neurons exposed to heat-shock at 44°C for 20 min, protein synthesis is inhibited by more than 80%, and is accompanied by a 60% decrease in eIF-2 activity. Steady state PKC and CK II activities were not affected by heat-shock. Vanadate (200 M), a protein phosphotyrosine phosphatase inhibitor, partially prevented the depression of eIF-2 activity during heat-shock, and increased CKII activity by 90%. In contrast, staurosporine (62nM), a protein kinase C inhibitor, did not affect eIF-2 activity. We conclude that heat-shock causes a change in the phosphorylation/ dephosphorylation of regulatory proteins leading to a depressed eIF-2 activity and protein synthesis in neurons.     

Protein synthesis and wall extensibility in the Avena coleoptile

Summary The inhibitors cycloheximide and puromycin have been used to examine the relationship between protein synthesis and wall extensibility, as measured with an Instron, in Avena coleoptile segments. Cycloheximide at 4 g/ml almost totally inhibits both auxin-induced cell elongation and protein synthesis with only a slight lag. Wall extensibility is unaffected by the inhibitor if auxin is absent. If added prior to auxin, cycloheximide prevents auxin-induced wall loosening while if added after auxin it causes a substantial decline in the wall extensibility. With puromycin there is a 2–4 hr lag before growth and wall loosening are inhibited. These results support the conclusions that the proteins needed for wall loosening are unstable, and that continued protein synthesis is necessary to maintain the wall loosening process.     

Inhibition by Chloramphenicol of Glucose Transfer in Teichoic Acid Biosynthesis

CHLORAMPHENICOL is widely accepted as a highly effective inhibitor of protein synthesis in bacteria, both in whole cells and at the subcellular level. Although some of the details of its mechanism of action are still unsettled, it has been shown to bind selectively to the 50S ribosomal subunit¹ and to inhibit peptide formation possibly by preventing binding between the ribosome and raRNA². It is well established that the bacteriostatic action of the antibiotic results from inhibition of protein synthesis and its use as a tool in the study of cellular biochemistry is frequently based on the view that its action is highly specific. In fact, there are reports of its inhibitory action on other cell processes³, but these are either relatively unimportant or the effects are only shown at concentrations of antibiotic much higher than those required for inhibition of protein synthesis. Anraku and Landman⁴ have reported that chloramphenicol inhibits a late stage in the reversion of protoplasts of Bacillus subtilis to the osmotically stable bacillary form and this is accompanied by inhibition of synthesis of a phosphorylated wall polymer believed to be a teichoic acid. It was suggested that inhibition of synthesis of wall polymers, including the teichoic acid, was an indirect effect arising from inhibition of synthesis of the appropriate enzyme proteins. We now report that chloramphenicol powerfully inhibits the biosynthesis of a wall teichoic acid in a cell-free system of fragmented cytoplasmic membrane from B. licheniformis ATCC 9945 (B. subtilis NCIB 8062); this occurs through direct action on the teichoic acid synthesizing system and is unrelated to protein synthesis. Although this may provide an alternative explanation of the effect observed by Anraku and Landman, a more detailed study of their system would be required.     

The effect of calcium on synthesis and degradation of mammary cytosolic proteins and casein

In mammary explants prepared from mid-pregnant rabbits, rates of intracellular and secretory protein synthesis and degradation can be manipulated by the addition or removal of hormones (insulin, prolactin, cortisol). Under both culture conditions, depletion of extracellular calcium with EGTA markedly decreases cytosolic protein synthesis and degradation, and also decreases the rate of synthesis of casein. Culture of explants in calcium-free medium also inhibits cytosolic protein synthesis, but has no significant effect on protein degradation, either in the presence or the absence of hormones. The results suggest that mammary protein synthesis and degradation may be affected by changes in the intracellular concentration or distribution of calcium.     

Radiation-induced recovery processes in cultured marsupial cells

The ultraviolet sensitivity of Potorous tridactylus male kidney (PtK-2) cells is markedly increased by post irradiation treatment for 24 h with 5 microM emetine (which inhibits protein synthesis by acting on the 40S ribosomal subunit), or with 5 microM cycloheximide (which inhibits by interaction with the 60S subunit), or with the RNA polymerase II inhibitor 5,6-dichloro-1-beta-ribofuranosylbenzimidazole at 50 microM. All 3 treatments give the same sensitivity, while unirradiated cells are little affected. Shortening the time of treatment, or delaying application of the drugs decreases their effect on the same time schedule. Preiirradiation of cells, with no drug treatment in the following 8 h, diminishes the sensitivity to a subsequent irradiation with protein synthesis blocked afterwards. Photoreactivation immediately following such preirradiation eliminates its desensitizing effect. Inhibiting protein synthesis after irradiation also markedly reduces the frequency of UV-induced mutants in the surviving population. These facts suggest that gene expression in the period following irradiation facilitates recovery from radiation damage, with an increased probability of mutation, reminiscent of the "SOS response" in Escherichia coli.     

Chemotaxis and the synthesis of specific proteins are inhibited by 3-deazaadenosine and other adenosine analogs in a mouse macrophage cell line

It has been shown earlier that 3-deazaadenosine but not 3-deazaaristeromycin inhibits chemotaxis of RAW264 cells (Aksamit, R.R., Falk, W., and Cantoni, G.L. (1982) J. Biol. Chem. 257, 621-625). We show here in RAW264 cells that (a) the incorporation of the methyl group of methionine into phosphatidylcholine is inhibited approximately 90% by both 3-deazaadenosine and 3-deazaaristeromycin, (b) 3-deazaadenosine but not 3-deazaaristeromycin inhibits the synthesis of specific proteins, and (c) 3'-deoxyadenosine and erythro-9-(2-hydroxy-3-nonyl)-adenine in the presence of adenosine and homocysteine inhibit chemotaxis and the synthesis of specific proteins. Inhibition of the synthesis of specific proteins can be observed only after the solubilized cellular proteins are separated by two-dimensional polyacrylamide gel electrophoresis, since the adenosine analogs do not significantly affect total protein synthesis. When total protein synthesis is inhibited by incubation of the cells with cycloheximide, puromycin, or actinomycin D, chemotaxis is correspondingly inhibited. The results suggest that the continuous synthesis of one or more cellular proteins is required for chemotaxis by RAW264 cells.     

Comparison of metabolic effects of EGF,TGF-α, and TGF-β1 in primary culture of fetal bovine myoblasts and rat L6 myoblasts

• 1.1. Comparative studies of EGF, TGF-α, and TGF-βl action on the synthesis of DNA and cellular proteins in rat L6 myogenic cells and fetal bovine myoblasts demonstrated considerable differences between particular growth factors, dependent on dose and target cells.
• 2.2. Among examined growth factors only EGF exerted mitostimulatory action, more pronounced at lower concentrations. EGF, progressively with dose, stimulated protein synthesis much more effectively in fetal bovine myoblasts than in L6 cells.
• 3.3. The dynamics of stimulation of protein synthesis by TGF-α was greater than by EGF in both examined types of cell cultures.
• 4.4. The maximal response of fetal bovine myoblasts to TGF-α in a concentration of 100 ng/ml reached 370%, whereas EGF in a 10 times higher concentration stimulated protein synthesis only to 123% of control.
• 5.5. In contrast to EGF, TGF-α significantly inhibits DNA synthesis. Inhibition of the mitogenic response with simultaneous stimulation of protein synthesis by TGF-α may indicate changes toward cell differentiation.
• 6.6. TGF-β 1 in smallest concentration inhibits both DNA and protein synthesis. The suppressive action of TGF-β 1 was more distinct in fetal bovine myoblasts than in the L6 cell line.
• 7.7. Increasing concentrations of TGF-β l diminished its inhibitory effect, even leading to stimulation of protein synthesis at higher doses in L6 myoblasts.

     

Studies with a human plasma-derived immunosuppressive,anti-lymphoma factor

Summary A low-molecular-weight (1,400) factor isolated from a human plasma -globulin concentrate by acid-salt dissociation and ultrafiltration inhibits proliferation of mitogen-stimulated T cells and L1210 leukemia cells. The factor (UM05R) inhibits DNA, RNA, and protein synthesis in sensitive cells, acts in G1 of the cell cycle, and appears to suppress mitogen-responsive T cells without an accessory cell requirement. UM05R activity is enhanced by known cAMP-elevating agents and by sulfhydryl compounds. The results of the present study are consistent with the hypothesis that the plasma-derived agent inhibits lympho-proliferation as a result of elevation of intracellular cAMP.     

The respective roles of the protein kinase and pppA2'' p5'' A2'' p5 A-activated endonuclease in the inhibition of protein synthesis by double stranded RNA in rabbit reticulocyte lysates.

Double-stranded RNA (dsRNA) inhibits protein synthesis in rabbit reticulocyte lysates by activating the synthesis of the endonuclease effector pppA2' p5' A2' p5' A(2-5A) and a protein kinase which phosphorylates the protein synthesis initiation factor eIF-2. Under certain assay conditions, high concentrations of dsRNA are without inhibitory effect in many lysates (high dsRNA "reversible" lysates). In these lysates natural dsRNA at low concentrations stimulated protein kinase activity to a greater extent than did the synthetic dsRNA poly rI.rC. Synthesis of 2--5A was greater when poly rI.rC was used. However, a number of factors, including the salt concentration and messenger RNA used, combine to determine the overall effect of dsRNA on protein synthesis under any given set of experimental conditions.     

Nitric oxide and nitric oxide-generating compounds inhibit hepatocyte protein synthesis.

Hepatocytes are stimulated to produce nitric oxide (NO.) from L-arginine in response to conditioned Kupffer cell medium or a combination of cytokines. Associated with the production of NO.in hepatocytes, there is a profound decrease in total protein synthesis ([3H]leucine incorporation). This report demonstrates that authentic NO.and the NO.-generating compound S-nitroso-N-acetylpenicillamine inhibit hepatocyte total protein synthesis in a reversible and concentration-dependent fashion. In parallel with the suppression of hepatocyte total protein synthesis, authentic NO.inhibits the production of two specific hepatocyte proteins, albumin and fibrinogen, without influencing the quantity of albumin mRNA. Although authentic NO.induces a rapid increase in cGMP levels in hepatocytes, the addition of the cGMP analog 8-bromoguanosine 3':5' cyclic monophosphate to unstimulated HC cultures does not reproduce the inhibition of total protein synthesis. These data show that NO.is the hepatocyte L-arginine metabolite that inhibits protein synthesis. Furthermore, these findings indicate that NO.does not inhibit hepatocyte protein synthesis solely through the activation of soluble guanylate cyclase but appears to affect a translational or posttranslational process.