Effects of Cerulenin upon the Syntheses of Lipid and Protein and upon the Formation of Respiratory Enzymes in Adapting, Lipid-Limited Saccharomyces cerevisiae

When bakers' yeast cells were grown anaerobically in a medium supplemented with Tween 80 and ergosterol, exposure during aeration to the fatty acid synthesis inhibitor, cerulenin, had little effect upon respiratory adaptation, the induction of enzymes of electron transport, or the in vivo incorporation of [(14)C]leucine into mitochondrial membranes. These lipid-supplemented cells were apparently able to undergo normal respiratory adaptation utilizing endogenous lipids alone. The level of cerulenin used (2 mug/ml) inhibited the in vivo incorporation of [(14)C]acetate into mitochondrial membrane lipids by 96%. If, however, the cells were deprived of exogenous lipid during anaerobic growth, subsequent exposure to cerulenin severely reduced their capacity to undergo respiratory adaptation, to form enzymes of electron transport, and to incorporate amino acid into both total cell and mitochondrial membrane proteins. This cerulenin-mediated inhibition of enzyme formation and of protein synthesis was nearly completely reversed by the addition of exogenous lipid during the aeration of the cells. In lipid-limited cells, chloramphenicol also had dramatic inhibitory effects, both alone (75%) and together with cerulenin (85%), upon total cell and mitochondrial membrane [(14)C]leucine incorporation. This marked chloramphenicol-mediated inhibition was also largely reversed by exogenous lipid. It is concluded that, in lipid-limited cells, either cerulenin or chloramphenicol may prevent the emergence of a pattern of lipids required for normal levels of protein synthetic activity. The effect of cerulenin upon the formation of mitochondrial inner membrane enzymes thus appears to reflect a nonspecific effect of this antilipogenic antibiotic upon total cell protein synthesis.     

Defective assembly of the mitochondrial ribosomes in yeast cells grown in the presence of mitochondrial protein synthesis inhibitors

The involvement of mitochondrial protein synthesis in the assembly of the mitochondrial ribosomes was investigated by studying the extent to which the assembly process can proceed in the presence of mitochondrial protein synthesis inhibitors erythromycin and chloramphenicol. Yeast cells grown in the presence of erythromycin (2 mg/ml) do not appear to contain any detectable amounts of the mitochondrial small (37 S) ribosomal subunit. Instead, a ribonucleoparticle with a sedimentation coefficient of 30 S was observed; this particle could be shown to be related to the mitochondrial small ribosomal subunit by two-dimensional gel electrophoretic analysis of its protein components. Since the var1 protein is the only mitochondrial translation product known to be associated with the mitochondrial ribosome, our results suggest that this protein is essential for the assembly of the mature small subunit, and that the var1 protein enters the pathway for the assembly of the small subunit at a late step. In at least one strain of yeast the accumulation of the 30-S particle appears to be very sensitive to catabolite repression. When yeast cells are grown in the presence of chloramphenicol instead of erythromycin, assembly of the small subunit appears to be only partially inhibited, and the presence of the 30-S particle could not be clearly demonstrated. This observation is consistent with the fact that in yeast, chloramphenicol inhibits mitochondrial protein synthesis by about 95% only and that the synthesis of the var1 protein appears to be the least sensitive to this inhibition.     

Effects of Chloramphenicol on the Circadian Rhythm of Neurospora crassa

Chloramphenicol, an inhibitor of mitochondrial protein synthesis, shortened the period length of the circadian rhythm in the Timex strain of Neurospora crassa by 2 hours. Both the l(+) threo and d(-) threo optical isomers had the same effect on the period of the rhythm, whereas only the d(-) threo isomer significantly inhibited mitochondrial protein synthesis. Tetracycline, another inhibitor of mitochondrial protein synthesis, did not change the period of the circadian rhythm. The effect of chloramphenicol on the circadian rhythm is, therefore, presumably not directly related to inhibition of mitochondrial protein synthesis, suggesting that chloramphenicol has other effects.     

Isolation and detailed characterization of human cell lines resistant to -threo-chloramphenicol

The isolation and characterization of chloramphenicol resistant derivatives of the human cell line HeLa B is described. Growth of resistant lines was unaffected in the presence of 100 μg/ml -threo-chloramphenicol, whereas growth of the parental cells was inhibited at 12.5 μg/ml. The incorporation of [³⁵S]methionine into mitochondrial protein of intact resistant cells continued normally in the presence of 100 μg/ml chloramphenicol (cytoplasmic protein synthesis was blocked by addition of 50 μg/ml emetine). Under these conditions the electrophoretic profile of labelled, presumptive mitochondrially-made proteins was similar to that of the parental cell line labelled in the absence of chloramphenicol. The cell lines selected in the presence of chloramphenicol also showed increased resistance to some other inhibitors of mitochondrial protein synthesis, e.g. carbomycin and mikamycin. [¹⁴C]Chloramphenicol was found to have normal access to the interior of resistant cells and it is therefore unlikely that resistance results from altered cell permeability. No modification of the drug by acetylation or glucuronide conjugation mechanisms was observed. The possibilities remain that resistance is mediated by altered permeability of the mitochondrial membrane, or from modification to a component of the mitochondrial protein synthetic system.     

Effect of Unsaturated Fatty Acids on the Development of Respiration and on Protein Synthesis in an Unsaturated Fatty Acid Mutant of Saccharomyces cerevisiae

The extent of development of respiratory function induced by aeration of an anaerobically grown unsaturated fatty acid auxotroph of Saccharomyces cerevisiae is determined by the availability, endogenous or externally supplied, of unsaturated fatty acid. The synthesis of mitochondrial and cytoplasmic enzymes during aeration appears to have a similar basis of regulation by available unsaturated fatty acid. Levels of unsaturated fatty acid that permit the synthesis of mitochondrial enzymes also result in a substantial stimulation of cellular protein synthesis.     

Protein synthesis inhibitors and ethanol selectively enhance heterologous expression of P450s and related proteins in Escherichia coli.

The antibiotics chloramphenicol (Cm), tetracycline, and erythromycin, which inhibit bacterial protein synthesis and are known to induce the cold shock response, unexpectedly enhance the heterologous expression of P450s and related proteins in Escherichia coli. In contrast, antibiotics that mimic heat shock in E. coli such as puromycin, streptomycin, and kanamycin decrease the expression of the same proteins. A sublethal dose of Cm (1 microgram/ml) effectively enhances the expression of both membrane-bound proteins (microsomal and mitochondrial P450s) and a soluble mitochondrial protein (adrenodoxin) over the range of two- to eightfold. The expression level of N-terminal truncated P450c17 (1600 nmol/liter culture without Cm), for instance, reached 3500 nmol/liter culture by the addition of Cm, approximately 8.4% of the total cellular protein. Cm also enabled expression at useful levels of active P450s previously difficult to express in E. coli. In contrast, the expression of P450scc, a mitochondrial protein, is decreased by Cm but enhanced by ethanol, a powerful elicitor of heat shock response in E. coli. These results show that both the cold shock response induced by some antibiotics and the heat shock response induced by ethanol may lead to enhanced expression of certain heterologous proteins in E. coli. This study also indicates that protein synthesis inhibitors associated with the cold shock response may act as protein synthesis enhancers under certain conditions.     

Erythromycin inhibition of cell proliferation and in vitro mitochondrial protein synthesis in human HeLa cells is pH dependent

The growth of HeLa cells in Hepes-buffered medium was significantly more sensitive to the inhibitory effects of erythromycin than in medium buffered by the more conventional bicarbonate-CO₂ system. Since growth inhibition by erythromycin became more pronounced as the pH of the medium was increased the difference in erythromycin sensitivity between the Hepes-buffered medium vs. the bicarbonate-CO₂-buffered medium is most likely due to pH effects. The relative growth sensitivity to erythromycin of ERY2301, an erythromycin-resistant mutant of HeLa, was also affected by elevated pH of the growth medium. However, ERY2301 cells were able to proliferate to a greater extent in the presence of erythromycin than HeLa cells grown under the same conditions. The selective growth advantage of ERY2301 (in the presence of erythromycin) is best seen in medium of pH 7.4, or in the Hepes-buffered medium. In vitro protein synthesis by intact mitochondria isolated from HeLa cells was relatively insensitive to erythromycin inhibition at pH 7.4 and 7.6, but at high pH values was inhibited approx. 50%. Although the erythromycin sensitivity of ERY2301 mitochondrial protein synthesis was also affected by increasing the pH, the incorporation of [³H]leucine was more resistant to erythromycin than that observed for HeLa mitochondria over the pH range tested. Increasing the concentration of erythromycin at a given pH did not result in a further increase in the inhibition of either HeLa or ERY2301 mitochondrial protein synthesis. When the mitochondrial membranes were disrupted by Triton X-100, erythromycin inhibition of HeLa mitochondrial protein synthesis was pH dependent and, at the lower pH values tested, greater inhibition was observed as the erythromycin concentration was increased. ERY2301 mitochondrial protein synthesis under the same conditions displayed a high level of erythromycin-resistant activity independent of both pH and erythromycin concentration. It is suggested that, as has been proposed for bacterial systems, only the non-protonated molecule of erythromycin is effective in inhibiting mitochondrial protein synthesis. The ability of erythromycin to permeate the mitochondrial membranes and the plasma membres may also be facilitated by a higher pH.     

Effects of mitochondrial protein synthesis inhibitors on the incorporation of isoleucine into Plasmodium falciparum in vitro

Plasmodium falciparum was grown in human erythrocytes in vitro and the effect of chloramphenicol, erythromycin, and tetracycline on growth and maturation of the parasites and on their ability to incorporate [3H]isoleucine into protein was observed. Exposure of rings to high concentrations of chloramphenicol had little effect on subsequent maturation of the rings whereas brief (4 h) exposure of trophozoites caused a dose-dependent inhibition of subsequent ring formation. Incorporation of [3H]isoleucine into protein was not affected during at least 6 h of exposure to high concentration of the three drugs examined, but appreciable inhibition was observed after 21 h, with chloramphenicol being the least effective inhibitor. These results suggest that there is a stage-specific effect of inhibition of mitochondrial protein synthesis on subsequent development and that the mitochondria are essential for growth and development even though they lack a functional Krebs cycle.     

Effect of chloramphenicol on mitochondrial and extramitochondrial systems in the isolated perfused rat heart

The isolated, perfused working rat heart was used as a model for investigating the effects of chloramphenicol on mitochondrial amino acid incorporation in an intact organ. The most obvious inhibitory effects of chloramphenicol were extramitochondrial: decreased mechanical performance of the heart and marked reduction in glucose uptake and lactate production. The ATP levels of the perfused heart were significantly increased at high levels of chloramphenicol. Chloramphenicol (50 to 500 μg/ml perfusate) did not inhibit the incorporation into the mitochondria or other subcellular fractions. A specific inhibitory effect on mitochondrial protein synthesis could only be observed when the cytoplasmic protein synthetizing system had been inhibited by cycloheximide. Under these conditions it could be demonstrated that the chloramphenicol sensitivity was greater for the synthesis of the insoluble proteins than for that of the soluble proteins of the mitochondria The chloramphenicol inhibition of mitochondrial protein synthesis which could be obtained in the isolated heart was approx. 70% which was twice as high as could be achieved when isolated mitochondria were incorporating amino acids.     

Effect of chloramphenicol,antimycin A and hydroxamate on the morphogenetic development of the dimorphic ascomyceteEndomycopsis capsularis

Mitochondrial protein synthesis, primary (antimycin-sensitive) respiration and secondary (antimycin-insensitive, salicyl-hydroxamate-sensitive) respiration, have been characterized in the dimorphic yeastEndomycopsis capsularis. The inhibition by chloramphenicol (CAP) of the morphogenetic development from the yeast-like form to the mycelial structure in this yeast could represent the intervention in the morphogenetic process of mitochondrial protein synthesis, since chloramphenicol blocks in vivo and in vitro mitochondrial protein synthesis. In fact, other functions such as primary and secondary respiration, do not seem to play a role in the morphogenetic development since their inhibition by antimycin A (AA) or by salicyl-hydroxamic acid (SHAM) does not affect the process. In addition, mitochondrial protein synthesis has been shown to be uninhibited by the two respiratory inhibitors.     

Effects of Mitochondrial Protein Synthesis Inhibitors on the Incorporation of Isoleucine into Plasmodium falciparum In Vitro1

Plasmodium falciparum was grown in human erythrocytes in vitro and the effect of chloramphenicol, erythromycin, and tetracycline on growth and maturation of the parasites and on their ability to incorporate [³H]isoleucine into protein was observed. Exposure of rings to high concentrations of chloramphenicol had little effect on subsequent maturation of the rings whereas brief (4 h) exposure of trophozoites caused a dose-dependent inhibition of subsequent ring formation. Incorporation of [³H]isoleucine into protein was not affected during at least 6 h of exposure to high concentration of the three drugs examined, but appreciable inhibition was observed after 21 h, with chloramphenicol being the least effective inhibitor. These results suggest that there is a stage-specific effect of inhibition of mitochondrial protein synthesis on subsequent development and that the mitochondria are essential for growth and development even though they lack a functional Krebs cycle.     

Erythromycin-inducible resistance in Staphylococcus aureus: requirements for induction

At least two functionally different types of ribosomes are found in strains of Staphylococcus aureus which display "dissociated" resistance to erythromycin. One type of ribosome is found under conditions of growth in ordinary nutrient broth, and the second is formed during growth in the presence of erythromycin. In these strains, erythromycin acts as an inducer of resistance to three different classes of inhibitors of the 50S ribosomal subunit-the macrolides, lincosamides, and streptogramin B-type antibiotics. The optimal inducing concentration of erythromycin is between 10(-8) and 10(-7)m. Concentrations as low as 10(-9)m can produce a 10-fold increase in resistant cells over the uninduced, background level, whereas concentrations greater than 10(-7)m block induction owing to inhibition of protein synthesis. Resistant cells begin to appear within 5 to 10 min after addition of erythromycin (to 10(-7)m), and within 40 min (i.e., about one generation) more than 90% of the entire culture is resistant to erythromycin as well as to lincomycin and vernamycin B(alpha). A resistant culture becomes sensitive if grown for 90 min in the absence of erythromycin. The process of induction is inhibited by chloramphenicol and streptovaricin, which inhibit protein and ribonucleic acid synthesis, respectively, but not by novobiocin, which inhibits deoxyribonucleic acid synthesis. Resistant cells produced in this manner fail to concentrate (14)C-erythromycin and (14)C-lincomycin, but not (14)C-chloramphenicol. Constitutively erythromycin-resistant strains which do not require the presence of erythromycin for expression of resistance can be selected on media containing antibiotics which belong to any one of the three classes. Two patterns of constitutive resistance have been found. These are (i) generalized constitutive resistance-which involves resistance in the absence of erythromycin to all members of each of the three cited classes of 50S subunit inhibitors which were tested, and (ii) partial constitutive resistance-which involves different degrees of resistance, in the absence of erythromycin, to various members of the three classes. Several different patterns of variable constitutivity are possible. 50S ribosomal subunits isolated from induced or constitutively resistant cells show decreased ability to bind erythromycin and lincomycin, and possible enzymatic inactivation of these antibiotics has been rigorously excluded. The induced change, therefore involves modification of ribosome structure rather than modification of the antibiotic.     

The synthesis of yeast matrix mitochondrial enzymes is regulated by different levels of mitochondrial function

The role of mitochondria in the oxygen induction of a number of catabolic and mitochondrial enzymes (citrate synthase, NAD- and NADP-isocitrate dehydrogenases, oxoglutarate dehydrogenase, NAD-glutamate dehydrogenase) has been investigated in anaerobic yeast grown under different conditions. The patterns of variation of enzyme activity with oxygen and lipid content of the mitochondria and with antibiotics suggest that more than one control is operating. The inhibition produced by cycloheximide, which blocks protein translation, suggests that induction involves de novo protein synthesis, except for an initial 2-h induction of citrate synthase, which is insensitive to all antibiotics tested. Ethidium bromide prevents enzyme induction in lipid-depleted anaerobic yeast. Induction follows normal kinetics in lipid-supplemented cultures despite the ethidium bromide block in the development of respiratory ability. Enzyme induction is inhibited by chloramphenicol in both lipid-depleted and lipid-supplemented anaerobic yeast. On the basis of four results it can be postulated that the mitochondrial genome is involved in controlling the induction of enzymes synthesized on cytoplasmic ribosomes. This control might be exerted by a specific, mitochondrial product or might be the result of modulation by a secondary product of mitochondrial function.     

Mitochondrial protein synthesis in a mammalian cell-line with a temperature-sensitive leucyl-tRNA synthetase.

The temperature-sensitive Chinese hamster ovary cell mutant tsH1, has been shown previously to contain a temperature-sensitive leucyl-tRNA synthetase. At the non-permissive temperature of 40 degrees C cytosolic protein synthesis is rapidly inhibited. The protein synthesis which continues at 40 degrees C appears to be mitochondrial, since: (a) whole-cell protein synthesis at the permissive temperature of 34 degrees C is not inhibied by tevenel, the sulfamoyl analogue of chloramphenicol and a specific inhibitor of mitochondrial protein synthesis; however, whole-cell protein synthesis at 40 degrees C is inhibited by tevenel, (b) Protein synthesis by isolated mitochondria from tsH1 cells is not significantly inhibited at 40 degrees C. (c) At 40 degrees C [14C]leucine is incorporated predominantly into the mitochondrial fraction of tsH1 cells. (d) The incorporation of [14C]leucine at 40 degrees C into mitochondrial proteins of tsH1 cells is inh-bited by tevenel but not by cycloheximide. These results suggest that the mitochondria of tsH1 cells contain a leucyl-tRNA synthetase which is different from the cytosolic enzyme. The inhibition of cytosolic, but not of mitochondrial protein synthesis in tsH1 cells at 40 degrees C allows the selective labelling of mitochondrial translation products in the absence of inhibitors. The mitochondrial translation products labelled in tsH1 cells at 40 degrees C and at 34 degrees C in the presence of cycloheximide have been compared by sodium dodecylsulphate-polyacrylamide gel electrophoresis. Both conditions of labelling give similar profiles. The mitochondrial translation products are resolved into two components, one with an apparent molecular weight range from 40,000 to 20,000 and a second with an apparent molecular weight range from 20,000 to 10,000.     

Protein synthesis and the recovery of both survival and cytoplasmic “petite” mutation in ultraviolet-treated yeast cells. II. Mitochondrial protein synthesis

The contribution of mitochondrial proteins in the repair of UV-induced lethal and cytoplasmic genetic damages was studied in dark liquid held exponential and stationary phase yeast cells. This was performed by using the specific inhibitors, erythromycin (ER) and chloramphenicol (CAP). It was shown that mitochondrial proteins are involved in the recovery of survival of UV-treated exponential phase cells, but not in the recovery of stationary phase cells. Mitochondrial proteins are partly implicated in the mechanisms leading to the restoration of the ϱ⁺ genotype in UV-irradiated dark liquid held exponential phase cells. Here again, in statonary phase cells, mitochondrial enzymes do not seem to participate in the negative liquid holding (NLH) processes for the ϱ⁻ induction, as shown by inhibiting mitochondrial protein synthesis or both mitochondrial and nuclear protein synthesis.When cells are grown in glycerol, the response after dark liquid holding of UV-treated cells in the different growth stages are similar to that found for glucose-grown cells. In other words, the fate of cytoplasmic genetic damage, in particular, is not correlated with the repressedor depressed state of the mitochondria.     

Effect of mitochondrial protein synthesis inhibitors on erythroid differentiation of mouse erythroleukemia (Friend) cells.

When mouse erythroleukemia (MEL) cells were incubated in the presence of chloramphenicol (a specific inhibitor for mitochondrial protein synthesis) during the early stage of in vitro erythroid differentiation, the number of induced erythroid cells was greatly reduced. By use of cell fusion between two genetically marked MEL cells, this finding was further investigated. We found that the drug, along with other agents which inhibit mitochondrial protein synthesis, blocked the induction and turnover of the DMSO-inducible intracellular-erythroid-inducing activity (differentiation-inducing factor II) in a manner similar to that of cycloheximide, an inhibitor for nuclear protein synthesis. The inhibitory effect was confirmed by directly assaying differentiation-inducing factor II in the cell extracts. These results strongly suggest that mitochondrial protein synthesis is closely associated with in vitro erythroid differentiation of MEL cells.     

On the Origin of Mitochondrial Mutants: Evidence for Intracellular Selection of Mitochondria in the Origin of Antibiotic-Resistant Cells in Yeast

In wild-type Saccharomyces cerevisiae, erythromycin and certain other antibacterial antibiotics inhibit the formation of respiratory enzymes in mitochondria by inhibiting translation on mitochondrial ribosomes. This paper is concerned with the origin of mutant cells, resistant to erythromycin by virtue of having a homogeneous population of mutant mitochondrial DNA molecules. Such mutant cells are obtained by plating wild-type (sensitive) cells on a nonfermentable substrate plus the antibiotic. Colonies of mutant cells appear first about four days after the time of appearance of established mutant cells; new colonies continue to appear, often at a constant rate, for many days. Application of the Newcombe respreading experiment demonstrates that most or all of the mutant cells which form the resistant colonies on selective medium arise only after exposure of the population to erythromycin. It is suggested that this result is most probably due to intracellular selection for mitochondrial genomes. Resistant mitochondria arising from spontaneous mutation are postulated to be at a selective disadvantage in the absence of erythromycin; reproducing more slowly than wild-type sensitive mitochondria, they cannot easily accumulate in sufficient numbers in a cell to render it resistant as a whole. In the presence of erythromycin, resistant mitochondria can continue to reproduce while sensitive mitochondria cannot, until there is a sufficient number to make the cell resistant, i.e. to permit normal cell growth. The same phenomenon is seen with respect to chloramphenicol resistance. Intracellular selection is considered more likely than direct induction of mutation by the antibiotic, since mutant cells do not accumulate in the presence of erythromycin if the mitochondrial genome is rendered non-essential by growth on glucose or nontranslatable by chloramphenicol. Intra-cellular selection provides a mechanism for direct adaptation at the cell level, compatible with currently acceptable ideas of spontaneous mutation and selection at the organelle level.