Retarding effect of inhibitors of protein and RNA synthesis on chlorophyll and protein breakdown

Cycloheximide, ethionine,p-fluorophenylalanine, 6-azauracil, 5-diazouracil and vanillin, applied at relatively high concentrations, retarded the yellowing of kale (Brassica oleracea L. var.acephala) leaf discs in darkness, and stimulated it in light. All the compounds inhibited protein synthesis and retarded protein breakdown. Cycloheximide,p-fluorophenylalanine, diazouracil and vanillin also inhibited the incorporation of uracil-¹⁴C into RNA of senescing discs. Abscisic acid and 2-chloroethylphosphonic acid accelerated yellowing both in darkness and in light and stimulated the protein breakdown in senescing discs. Abscisic acid inhibited the chlorophyll, protein and RNA synthesis in detached, greening cucumber cotyledons. There was no direct correlation between the activity of a given compound as an inhibitor of yellowing in darkness, and the degree of inhibition of RNA synthesis. The arrest of yellowing in darkness is possibly a consequence of the retarded rate of protein breakdown. Yellowing in light, on the contrary, is dependent on the actual rate of protein synthesis.     

Trans-translation and protein synthesis inhibitors

Trans-translation is a process found in all bacteria, which contributes to the release of ribosomes that are stalled through a variety of causes, for example when the 3' end of a truncated mRNA lacking a stop codon is reached or at internal clusters of rare codons. Trans-translation requires tmRNA. Trans-translation is not essential for cell viability under laboratory conditions, but recently it has been shown that it can contribute to cell viability in the presence of protein synthesis inhibitors. In this minireview, we consider the connection between trans-translation and antibiotics and the potential of using trans-translation as a therapeutic target.     

Effect of dietary protein intake on plasma leucine flux, protein synthesis, and degradation in sheep

Combined experiments of an isotope dilution method of [1-(13)C]leucine with open circuit calorimetry and a nitrogen (N) balance test were applied to determine the effect of dietary crude protein (CP) intake on plasma leucine flux and protein synthesis and degradation in four sheep. The experiment was conducted in a 3 x 4 Latin rectangle design of three 3-week periods. Dietary CP intake was 5.6, 7.7, and 10.8 g/(kg(0.75) x d). Metabolizable energy intake was 120% of requirement for all dietary treatments. [1-(13)C]Leucine was intravenously infused for 8 h and blood and breath samples were collected during the latter 2-h period of infusion. Isotopic enrichments of plasma [1-(13)C]leucine, alpha-[1-(13)C]ketoisocaproic acid, and exhaled (13)CO(2) were determined. For the N balance test, N digestibility, N excretion in urine, and protein balance (N x 6.25) increased with increasing dietary CP intake. Rates of plasma leucine turnover, protein synthesis, and degradation changed toward reduction with increased dietary CP intake. It is likely that in sheep, high CP intake enhances protein deposition with reduced protein degradation rather than increased protein synthesis.     

Chlorolissoclimides: new inhibitors of eukaryotic protein synthesis

Lissoclimides are cytotoxic compounds produced by shell-less molluscs through chemical secretions to deter predators. Chlorinated lissoclimides were identified as the active component of a marine extract from Pleurobranchus forskalii found during a high-throughput screening campaign to characterize new protein synthesis inhibitors. It was demonstrated that these compounds inhibit protein synthesis in vitro, in extracts prepared from mammalian and plant cells, as well as in vivo against mammalian cells. Our results suggest that they block translation elongation by inhibiting translocation, leading to an accumulation of ribosomes on mRNA. These data provide a rationale for the cytotoxic nature of this class of small molecule natural products.     

Trypanosoma cruzi: effect of olivacine on macromolecular synthesis, ultrastructure, and respiration of epimastigotes.

Olivacine (a pyridocarbazole derivative) causes ultrastructural and metabolic alterations in Trypanosoma cruzi epimastigotes. The cytoplasm of cells grown in the presence of olivacine appears vacuolated, and swelling of the mitochondria is observed. Concomitant with the ultrastructural alterations, there was a reduction of the respiratory rate as well as inhibition of pyruvate oxidation. A marked inhibition of protein synthesis and a slower although significant inhibition of DNA, RNA, and lipid synthesis were also observed. The in vivo activity of olivacine does not parallel its in vitro effects suggesting inactivation of the drug by the host.     

Rhythmic changes in protein synthesis in mouse pancreatocytes after food stimulation, in alloxan diabetes and in isoproterenol exposure

Radioautography revealed data on protein synthesis dynamics in pancreacytes of intact mice, subjected to alloxan diabetes and isoproterenol (ISP) injection after synchronized secretion. Rhythmic fluctuation of protein synthesis with maximum uptake of 3H-leucine 40 and 80 min after treatment was observed in intact animals. The above maximums correlated with the increase in the cell size. In alloxan diabetes, injections of ISP and their combination the rhythm of protein synthesis is retained, the total intensity of isotope uptake increases significantly, but at the same time secretion periods, particularly in the latter case decrease. The results obtained revealed the existence of endogenic rhythms in protein synthesis with certain secretion plasticity within pancreacytes.     

Metalloendoprotease inhibitors block protein synthesis, intracellular transport, and endocytosis in hepatoma cells

Fusion of membrane vesicles has been implicated in many intracellular processes including the transport of proteins destined for secretion or storage. Vesicular transport coupled with membrane fusion has been demonstrated for rough endoplasmic reticulum to Golgi and Golgi to plasma membrane transport as well as receptor mediated endocytosis and receptor recycling. Recent studies with inhibitors suggest that metalloendoproteases may mediate a wide variety of intracellular fusion events. Thus, in order to examine the potential role of metalloendoproteases in both transport/secretion and endocytosis/recycling we have used selected dipeptide substrates to probe these processes in human HepG2 cells. Using pulse-chase labeling, immunoprecipitation, and polyacrylamide gel electrophoresis we show that transport and secretion of newly synthesized proteins along the exocytotic route were completely inhibited by substrate dipeptides (e.g. Cbz-Gly-Phe-amide, where Cbz is benzyloxycarbonyl) but not by irrelevant dipeptides (e.g. Cbz-Gly-Gly-amide). The effect was rapid, reversible, and specific. The secretory pathway was blocked between the rough endoplasmic reticulum and Golgi as well as Golgi and plasma membrane as judged by the status of N-glycosylation intermediates. In addition, these inhibitors specifically inhibited protein synthesis without alterations in cellular ATP concentrations. However, cell-free amino acid incorporation was not inhibited. Receptor-mediated uptake of asialoglycoproteins was specifically and reversibly inhibited by dipeptide substrates. This effect appears to be secondary to inhibition of recycling as neither ligand binding nor internalization were affected. Thus the present observations suggest that metalloendoprotease activity may be involved in the regulation of multiple intracellular pathways perhaps at the level of vesicular fusion events.     

The relation of sodium and potassium ion transport to the respiration and adenine nucleotide content of liver slices treated with inhibitors of respiration

1. The dependence of the net transport of Na(+) and K(+) by rat liver on the respiration has been determined by incubating slices in the presence of varying concentrations of respiratory inhibitors. 2. Neither the rate of net transport nor the total amount of each ion transported was inhibited unless the rate of endogenous respiration was decreased below a critical value of about 330mmol of O(2)/h per kg of protein (i.e. 50% of the total endogenous respiration). 3. The uninhibited rate of respiration could be varied over a twofold range (380-770mmol of O(2)/h per kg of protein) by the use of different substrates, but the critical value for the onset of transport inhibition was quite constant (290-360mmol/h per kg of protein) under these different conditions. 4. Slices incubated at 38 degrees C without inhibitors showed an increase of their ATP content and the concentration ratio ATP/ADP. The final ATP content and concentration ratio, ATP/ADP, of slices treated with different concentrations of inhibitors were closely related to the rate of respiration. 5. The increased ATP content of the control slices during incubation was equal to the increase of total adenine nucleotides. At increasing degrees of respiratory inhibition the relative contributions of ADP and AMP to the total adenine nucleotide content increased. 6. The critical rate of respiration for the onset of inhibition of ion transport and the corresponding contents of adenine nucleotides provide estimates of the maximal values of certain parameters of energy metabolism required for the support of alkali-cation transport in the liver slices.     

Protein toxin inhibitors of protein synthesis.

Two classes of extremely toxic proteins kill eukaryotic cells by covalently modifying unique structural features of components that are essential for protein synthesis. Intoxication by these proteins results from the entry of a catalytic fragment into the cytoplasm. One class is typified by diphtheria toxin and Pseudomonas exotoxin A. The catalytic component of these toxins ADP-ribosylates and inactivates elongation factor 2 which is an essential participant in protein synthesis. This modification occurs at a unique post-translational histidine derivative, diphthamide, that is present in the ribosomal binding site of the elongation factor. The two toxins differ in their molecular organization but appear to possess identical reaction mechanisms and very similar active sites. The other class contains two types of toxins typified, respectively, by alpha-sarcin, a member of a family of fungal toxins, and ricin, a member of a group of closely related plant proteins collectively termed ribosome-inactivating proteins. The catalytic components of the two types of toxins in this second class inactivate the large ribosomal subunit through two different hydrolytic alterations of 23-28S RNA. alpha-Sarcin and its congeners act as a specific endonuclease whereas ricin and its congeners act as a specific N-glycosidase. These hydrolytic cleavages occur at a pair of adjacent nucleotides within a highly conserved sequence near the 3' terminus of 23-28S RNA. The covalent integrity of this region of RNA is essential to elongation factor-dependent ribosomal functions and is located within the ribosomal binding domain of these factors. Both of these classes of toxins are being employed as 'magic bullets' to eliminate pathological cells. By combining the catalytic component of these toxins with various cell targeting components, useful and specific anticancer and immunomodulatory agents have been created.     

Protective effect of cerulein on memory impairment induced by protein synthesis inhibitors in rats.

Previous studies have demonstrated that NMDA receptor antagonists and protein kinase C inhibitors induced marked memory impairment in rats, but that peripherally administered cerulein (CER) prevented these effects. In the present study, the effect of subcutaneously administered CER on amnesia induced by protein synthesis inhibitors was examined in passive and active avoidance responses and in the Morris water maze test. Intraperitoneal injection of the inhibitors produced marked memory impairment, but the effect was abolished by combined administration with CER. The effective dose of subcutaneously injected CER was, on a molar basis, three thousand- and six thousandfold less than the dose of anisomycin, and two hundred eighty- and three thousandfold less than the dose of puromycin in the passive and active avoidance response experiments, respectively. Similarly, in the Morris water maze test, behavioral disturbances produced by the protein synthesis inhibitors were abolished by CER. These results indicate the effectiveness of CER in preventing memory impairment induced by protein synthesis inhibitors.