Studies on the flavins in rat liver mitochondrial outer membranes

The incorporation of radioactivity derived from [2-¹⁴C] riboflavin into the flavins of rat liver mitochondrial outer membranes was studied. These membranes were found to contain about 0.6 nmol of non-covalently bound flavins per mg protein; the majority is in the form of FAD (73%) and FMN (24%). The membranes also contain about 1.5 nmol per mg of covalently bound flavins.After labeling, radioactive flavins appeared in the non-covalently bound flavins for about 4 h. Most of this radioactivity was in FAD (77%). Neither the rate nor extent of this labelling was affected by cycloheximide (1 mg/kg) administered 30 min prior to the radioactive riboflavin. With the covalently bound flavins, radioactivity was incorporated into the coenzymes for at least 18 h, but the rate of incorporation was much slower. After cycloheximide, radioactive flavins continued to appear in covalently bound flavins for about 2 h, but then stopped. Labeling of both types of flavins after [¹⁴C] riboflavin was considerably slower than the incorporation of [³H] leucine into outer membrane proteins. These results suggest that with flavoproteins from the mitochondrial outer membranes, the incorporation of flavins occurs after synthesis of the various apoenyzmes is complete.     

The relationship of protein and lipid synthesis during the biogenesis of mitochondrial membranes

Summary Rat liver mitochondria were fractionated into inner and outer membrane components at various times after the intravenous injection of¹⁴C-leucine or¹⁴C-glycerol. The time curves of protein and lecithin labeling were similar in the intact mitochondria, the outer membrane fraction, and the inner membrane fraction. In rat liver slices also, the kinetics of³H-phenylalanine incorporation into mitochondrial KCl-insoluble proteins was identical to that of¹⁴C-glycerol incorporation into mitochondrial lecithin. These results suggest a simultaneous assembly of protein and lecithin during membrane biogenesisThe proteins and lecithin of the outer membrane were maximally labeledin vivo within 5 min after injection of the radioactive precursors, whereas the insoluble proteins and lecithin of the inner membrane reached a maximum specific acitivity 10 min after injection.Phospholipid incorporation into mitochondria of rat liver slices was not affected when protein synthesis was blocked by cycloheximide, puromycin, or actinomycin D. The injection of cycloheximide 3 to 30 min prior to¹⁴C-choline did not affect thein vivo incorporation of lecithin into the mitochondrial inner or outer membranes; however treatment with the drug for 60 min prior to¹⁴C-choline resulted in a decrease in lecithin labeling. These results suggest that phospholipid incorporation into membranes may be regulated by the amount of newly synthesized protein available.When mitochondria and microsomes containing labeled phospholipids were incubated with the opposite unlabeled fractionin vitro, a rapid exchange of phospholipid between the microsomes and the outer membrane occurred. A slight exchange with the inner membrane was observed.     

Biogenesis of mitochondrial membranes in Neurospora crassa. Mitochondrial protein synthesis during conidial germination.

The conidia of Neurospora crassa entered logarithmic growth after a 1-h lag period at 30 degrees C. Although [14C]leucine is incorporated quickly early in growth, cellular protein data indicated that no net protein synthesis occurred until after 2 h of growth. Neurospora is known to produce ethanol during germination even though respiratory enzymes are present. Also, Neurospora mitochondria isolated from cells less than 3-h old are uncoupled. Since oxygen uptake increased during germination, was largely cyanide-sensitive, and reached a maximum at 3 h, it is hypothesized that during early germination the uncoupled electron transport chain merely functions to dispose of reducing equivalents generated by substrate level ATP production. The rate of protein synthesis in vitro by mitochondria isolated from 0-8-h-old cells increased as did cell age. Mitochondrial protein synthesis in vivo, assayed in the presence of 100 mug cycloheximide/ml, increased from low levels in the cinidia to peak levels at 3-4 h of age and then slowly decreased. The rate of mitochondrial protein synthesis in vivo was linear for at least 90 min in 0-4-h-old cells, but declined after 15 min of incorporation in 6 and 8-h-old cells. The products of mitochondrial protein synthesis in vivo were analyzed with dodecylsulfate gel electrophoresis and autoradiography. Early in germination 80% of the synthesis was of two small proteins (molecular weights 7200 and 9000). At 8 h 85% of the radioactivity was in 10 larger proteins (12 200 to 80 000). Within the high-molecular-weight class, proteins of between 12 000 and 21 500 molecular weight were preferentially lavelled early in germination, whereas after 8 h of growth proteins of 27 500 to 80 000 molecular weight were preferentially labelled. It is hypothesized that the 7200 and 9000-molecular-weight products of mitochondrial protein synthesis combine with other proteins to form the larger proteins found later in growth. The availability of these other proteins in cells of different ages could affect the rate of mitochondrial protein synthesis in vivo.     

Synthesis of the mitochondrial inner membrane in cultured Xenopus laevis oocytes.

The purpose of this study was to investigate the contribution of mitochondrial and cytoplasmic protein synthesis to the biogenesis of cytochrome oxidase (ferrocytochrome c:oxygen oxidoreductase EC 1.9.3.1) and rutamycin-sensitive adenosine triphosphatase (ATP phosphohydrolase EC 3.6.1.3) in cultured oocytes of the toad, Xenopus laevis. X. laevis cytochrome oxidase was purified over 23-fold with respect to specific activity and over 29-fold with respect to specific heme a content from oocyte submitochondrial particles. Polyacrylamide gel electrophoresis in the presence of sodium dodecyl sulfate separated the enzyme into six subunits with molecular weights of 44,000, 33,000, 23,000, 17,000, 12,000 and 9,500. the synthesis of the three larger subunits is sensitive to chloramphenicol (an inhibitor of mitochondrial protein synthesis), indicating that these subunits are made on mitochondrial ribosomes; the synthesis of the three smaller subunits is sensitive to cycloheximide (an inhibitor of cytoplasmic protein synthesis) and therefore occurs on cytoplasmic ribosomes. X. laevis rutamycin-sensitive ATPase, purified over 19-fold from oocyte submitochondrial pparticles, consists of 10 subunits with molecular weights of 56,000, 53,000, 41,000, 32,000, 29,000, 24,000, 21,000, 17,500 (2), and 11,500 on sodium dodecyl sulfate-polyacrylamide gels. The 29,000, 21,000, and one of the 17,500-dalton polypeptides are synthesized in the presence of cycloheximide and are, therefore, products of mitochondrial protein synthesis; the synthesis of the remaining seven subunits occurs in the presence of chloramphenicol, indicating that these subunits are made on cytoplasmic ribosomes. The synthesis of protein by mitochondria in cultured oocytes appears to be dependent upon cytoplasmic protein synthesis. In the presence of cycloheximide, the mitoribosomal synthesis of the subunits of cytochrome oxidase and rutamycin-sensitive ATPase is detectable only after a prior inhibition of mitochondrial protein synthesis by chloramphenicol. Oocyte mitochondrial ribosomes synthesize at least nine polypeptides after chloramphenicol treatment, three of which are components of neither cytochrome oxidase nor rutamycin-sensitive ATPase.     

Early events in yeast mitochondrial protein targeting

Protein import into mitochondria involves a number of complex steps occurring in the cytosol, on the mitochondrial surface, and inside the organelle. Once an initial interaction between mitochondrial proteins and their specific receptors occurs, the proteins are transported into the organelle in a series of reactions involving (in the case of a protein to be translocated into the mitochondrial matrix) the mitochondrial membrane potential, ATP hydrolysis and an undetermined number of membrane components. Inside the organelle, mitochondrial proteins are processed and sorted to their final intramitochondrial destinations. The earliest steps in the import process take place in the cytosol and include the synthesis of the mitochondrial proteins themselves, their interaction with cytosolic factors, and perhaps the establishment of cotranslational import complexes on the mitochondrial surface. These early events are important because it is during this phase that the system as a whole is most sensitive to cytosolic conditions that may exert control over the entire import process.     

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.     

Products of mitochondrial protein synthesis in Tetrahymena.

The products of mitochondrial protein synthesis have been investigated in Tetrahymena after labelling with [35S]methionine in the presence of cycloheximide. The labelled proteins were analyzed by sodium dodecyl sulfate slab polyacrylamide gel electrophoresis. We have identified 13 electrophoretically discrete bands as well as 4 other bands with a more variable occurrence. These proteins ranged in apparent molecular weight from 8100 to 57,500. The cycloheximide-resistant incorporation could be blocked with chloramphenicol. The mitochondrial proteins appeared to be in a disaggregated state and were stable to agents such as trichloroacetic acid (hot or cold) and chloroform-methanol. The pattern of proteins was similar following labelling times ranging from 30 min to 3 h.     

The effect of chloramphenicol and cycloheximide on the activity of enzyme "markers" of mitochondrial substructures of the rat liver.

Chloramphenicol and cycloheximide exert in vivo inhibitory effects on the synthesis of mitochondrial enzymes. Choloramphenicol action results in a significant decrease of the activity of enzymes being the "markers" of all submitochondrial structures including that of the outer membrane. This suggests that chloramphenicol affects biosynthesis of of "assembly protein" on mitochondrial ribosomes and thus affects incorporation of proteins, wherever they are synthesized, into the structure of the mitochondrion as a functional entity. The effect of cycloheximide depends markedly on the concentration of the inhibitor and on the time of its administration. The differences in sensitivity of examined enzymes to the drug are probably related to their differential turnover.     

The synthesis of cytochrome b on mitochondrial ribosomes in baker's yeast.

Antiserum against a major cytochrome b peptide isolated from yeast mitochondria as described previously (Lin, L.-F.H., and Beattie, D.S., J. Biol. Chem. 1978, 253, 2412--2418) was raised in rabbits and shown to be monospecific against the pure antigen. Mitochondria were isolated from yeast cells grown in [3H]leucine, extracted with Lubrol and treated with antiserum to cytochrome b. Analysis of the immunoprecipitates by sodium dodecyl sulfate/polyacrylamide gel electrophoresis revealed the presence of a single major band of molecular weight 31 000 corresponding to cytochrome b. In order to determine the intracellular site of translation of cytochrome b, yeast cells were labeled in vivo under non-growing conditions with [3H]leucine in the absence or presence of inhibitors of cytoplasmic and mitochondrial protein synthesis. The incorporation of radioactive leucine into the apoprotein of cytochrome b isolated by immunoprecipitation followed by gel electrophoresis was insensitive to cycloheximide (an inhibitor of cytoplasmic protein synthesis) and sensitive to acriflavin, erythromycin, and chloramphenicol (inhibitors of mitochondrial protein synthesis). Furthermore, no cytochrome b apoprotein was present in a cytoplasmic petite mutant which lacked mitochondrial protein synthesis. Cytochrome b is thus a product of protein synthesis on mitochondrial ribosomes.     

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.     

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.     

Brugia pahangi: inhibition of protein synthesis

The effects of inhibitors of protein synthesis and electron transport on the incorporation of [14C]leucine and [35S]methionine into protein by the filarial worm Brugia pahangi have been investigated. Cycloheximide inhibits the accumulation of both [14C]leucine and [35S]methionine by the worms and their incorporation into protein. In addition, inhibitors of electron transport and some anti-parasitic compounds also significantly inhibit filarial protein synthesis. Antimycin A and cyanide inhibit [14C]leucine incorporation into protein 63 and 72%, respectively, without affecting either motility or lactate production. Interestingly, the anti-malarial compounds chloroquine and quinacrine also significantly inhibit both accumulation and incorporation of [14C]leucine by B. pahangi. In addition, fluorographs of sodium dodecyl sulfate-polyacrylamide gels of homogenates from filariids incubated in [35S]methionine and cycloheximide with and without chloramphenicol indicate that there is a discrete population of proteins, possibly mitochondrial in origin, that are synthesized in the presence of cycloheximide and are not inhibited by chloramphenicol.     

Effect of cycloheximide on protein and ribonucleic acid synthesis in cultured human lymphocytes

1. Phytohaemagglutinin stimulates the transformation into blast cells of human lymphocytes incubated in vitro. This transformation is accompanied by an increase in the incorporation of [(14)C]leucine into protein and [(3)H]uridine into RNA. 2. The incorporation of [(14)C]leucine by cultures grown in the presence or absence of phytohaemagglutinin is inhibited to the same extent by cycloheximide, a known inhibitor of protein synthesis. 3. Lymphocytes grown without phytohaemagglutin synthesize mainly non-ribosomal RNA. [(3)H]Uridine incorporation by these cells was increased by cycloheximide. 4. Lymphocytes incubated with phytohaemagglutinin begin to synthesize substantial quantities of ribosomal RNA. Under these conditions [(3)H]uridine incorporation was partially inhibited by cycloheximide. This inhibition is shown to be largely a result of inhibition of the synthesis of ribosomal RNA.     

Induction of deoxyribonucleic Acid synthesis in potato tuber slices: role of protein synthesis

Timing of protein synthesis which is a prerequisite to DNA synthesis induced in potato tuber tissue (Solanum tuberosum L.) by cut injury has been studied using cycloheximide. The induction of DNA synthesis which was measured by incorporation of ³H-thymidine was completely inhibited when the inhibitor was applied to the tuber discs immediately after slicing. When the application of cycloheximide was delayed for 6 hours or more after slicing, DNA synthesis was observed but its rate was reduced to 20% of control. The inhibitory effect of cycloheximide, however, rapidly decreased when the inhibitor was applied at 6 or less hours immediately prior to determination of DNA synthesis. The effect of cycloheximide on the incorporation of ¹⁴C-leucine suggests that the change in the effect of cycloheximide on the induction of DNA synthesis is not due to incomplete inhibition of protein synthesis. Cycloheximide did not have significant effects on either uptake or phosphorylation of ³H-thymidine in the discs. Inhibition of both protein and DNA synthesis by cycloheximide was reversed by washing and further incubation of the discs. Almost no qualitative difference was detected by buoyant density analysis between DNA formed under inhibition of protein synthesis of the later stage and DNA synthesized under normal conditions. These results suggest that DNA synthesis induced in potato tuber tissue by cut injury requires continuous synthesis of new protein molecules in a characteristically programmed sequence.     

The use of protein synthesis inhibitors in the estimation of the contribution of halophilic archaebacteria to bacterial activity in hypersaline environments

Abstract Antibiotics affecting protein synthesis were used to differentiate between the activity of different groups of organisms (halophilic archaebacteria, eubacteria and eukaryotes) in water samples from hypersaline ecosystems. Anisomycin (inhibiting both archaebacterial halophiles and eukaryotes) can be used to quantitate the contribution of the archaebacterial halophiles to amino acid incorporation by the microbial community, when cycloheximide (inhibiting eukaryotic protein synthesis, but not affecting halobacteria) is used as a control. Both in saltern ponds at salinities above 300 g/1 and in Dead Sea surface water more than 95% of the amino acid incorporation activity was abolished by anisomycin, but not by cycloheximide. Inhibition by anisomycin was well correlated with inhibition by low concentrations of bile salts, which specifically affect bacteria of the Halobacterium group. Chloramphenicol (an inhibitor of eubacterial protein synthesis) quantitatively inhibited amino acid incorporation in saltern brines of relatively low salinity, but also caused significant (28–42%) inhibition at high salinities. Erythromycin was also found valuable in the estimation of activities of the different bacterial groups.     

Effect of ethionine on the in vitro synthesis and degradation of mitochondrial translation products in yeast

The effect of ethionine, an amino acid analog of methionine, has been studied in Saccharomyces cerevisiae in relation to cell growth, oxygen consumption, in vitro protein synthesis of mitochondrial translation products (MTPs) and the degradation of those mitoribosomally made proteins by an ATP-dependent process present within the organelle. Ethionine was found to increase the generation time of those cells already committed to cell division and to abolish the initiation of new cell cycles. Oxygen consumption of cultures grown in the presence of the analog was drastically reduced. Ethionine was also found to impair the incorporation of methionine and leucine into mitochondrial translation products, however the synthesis of proteins was not totally blocked and, apparently, mitochondria utilized ethionine as a precursor amino acid. MTPs synthesized by isolated mitochondria in the presence of ethionine were rapidly degraded inside the organelle at a faster rate compared with the normal proteins synthesized under identical conditions in the mitochondria. It is also shown that these in vitro synthesized proteins are degraded by an ATP-stimulated proteolytic system, as has been previously established.     

Formation of the yeast mitochondrial membrane. 3. Accumulation of mitochondrial proteins synthesized in both the cytoplasm and mitochondria in yeast undergoing glucose depression

The inhibitors of protein synthesis, chloramphenicol and cycloheximide, were added to cultures of yeast undergoing glucose derepression at different times during the growth cycle. Both inhibitors blocked the increase in activity of coenzyme QH₂-cytochrome c reductase, suggesting that the formation of complex III of the respiratory chain requires products of both mitochondrial and cytoplasmic protein synthesis.The possibility that precursor proteins synthesized by either cytoplasmic or mitochondrial ribosomes may accumulate was investigated by the sequential addition of cycloheximide and chloramphenicol (or the reverse order) to cultures of yeast undergoing glucose derepression. When yeast cells were grown for 3 hr in medium containing cycloheximide and then transferred to medium containing chloramphenicol, the activity of cytochrome oxidase increased at the same rate as the control during the first hour in chloramphenicol. These results suggest that some accumulation of precursor proteins synthesized in the mitochondria had occurred when cytoplasmic protein synthesis was blocked during the growth phase in cycloheximide. In contrast, essentially no products of mitochondrial protein synthesis accumulated as precursors for either oligomycin-sensitive ATPase or complex III of the respiratory chain during growth of the cells in cycloheximide.When yeast were grown for 3 hr in medium containing chloramphenicol followed by 1 hr in cycloheximide, the activities of cytochrome oxidase and succinate-cytochrome c reductase increased at the same rate as the control, while the activities of oligomycin-sensitive ATPase and NADH or coenzyme QH₂-cytochrome c reductase were nearly double that of the control. These data suggest that a significant accumulation of mitochondrial proteins synthesized in the cytoplasm had occurred when the yeast cells were grown in medium containing sufficient chloramphenicol to block mitochondrial protein synthesis. The possibility that proteins synthesized in the cytoplasm may act to control the synthesis of mitochondrial proteins for both oligomycin-sensitive ATPase and complex III of the respiratory chain is discussed.     

In vitro synthesis of myelin proteolipid protein from rat brain using a total homogenate system

In vitro synthesis of myelin proteolipid protein (PLP) was explored at different ages using rat brain total homogenates, incubated for 30 min with [³H]glycine. Total proteolipids, extracted from the incubated samples, were separated by SDSPAGE and the radioactivity was measured in the band corresponding to myelin PLP. The incorporation into PLP in relation to the incorporation into brain total proteins increased from 0.04% at 10 days of age to 0.63% at 20 days, and declined slowly thereafter. Time course experiments were carried out using brain homogenates obtained from rats of 20 days of age (i.e. at the period of maximal synthesis of PLP). Labeled PLP molecules were already found at 2.5 min of incubation and the incorporation of the label into this protein, relative to the incorporation into total proteins, did not vary throughout the entire incubation time (30 min). Pulsechase experiments using a similar system and adding cycloheximide at different incubation times showed that the appearance of label into mature PLP was immediately blocked by the inhibitor of protein synthesis. These data suggest that PLP is synthesized as such and not as a pre-protein which is subsequently processed to render mature PLP.     

Evolution and diversification of mitochondrial protein import systems

More than 95% of mitochondrial proteins are encoded in the nucleus, synthesised in the cytosol and imported into the organelle. The evolution of mitochondrial protein import systems was therefore a prerequisite for the conversion of the α-proteobacterial mitochondrial ancestor into an organelle. Here, I review that the origin of the mitochondrial outer membrane import receptors can best be understood by convergent evolution. Subsequently, I discuss an evolutionary scenario that was proposed to explain the diversification of the inner membrane carrier protein translocases between yeast and mammals. Finally, I illustrate a scenario that can explain how the two specialised inner membrane protein translocase complexes found in most eukaryotes were reduced to a single multifunctional one in trypanosomes.     

Differential effects of analogs of cycloheximide on protein and RNA synthesis in Achlya

Analogs of the glutarimide antibiotic cycloheximide were tested for their effect on growth and incorporation of proline and uridine into acid-insoluble material in Achlya bisexualis. Each of the compounds tested had reduced antibiotic activity as compared to cycloheximide. The effects of the antibiotics on protein and RNA synthesis were varied. While cycloheximide inhibited both protein and RNA synthesis immediately, two of the analogs inhibited proline incorporation without effect on uridine incorporation, while three, each representing a modification of the hydroxyl of cycloheximide, stimulated uridine incorporation and either had no effect on or inhibited protein synthesis. These results indicate that the control of RNA synthesis by protein synthesis in Achlya can be released by glutarimide antibiotics.