Energy-linked synthesis and decay of membrane proteins in isolated rat liver mitochondria

The adaptation to salinity: protein synthesis and some aspects of energy transduction in fish gill mitochondria

Exposure of freshwater fish to saline conditions brings about somewhat drastic changes in the mitochondrial energy metabolism. These include abolition of oxidative phosphorylation, ATP-induced contraction of swollen mitochondria and transhydrogenase activity. On the other hand the endogenous calcium levels and protein synthetic capacity are elevated. In vitro protein synthesis by mitochondria from freshwater and stressed fish shows qualitative and quantitative variations. Effluxing the excess calcium by treatment with NaCl or inhibiting the protein synthesis by chloramphenicol in stressed mitochondria restores almost all the functions. It is proposed that the energy potential formed by the mitochondrial membrane is channelized to perform different functions and that the ratio of channelization can be altered to suit the needs of the cell.

The effects of cryopreservation on protein synthesis and membrane transport in isolated rat liver mitochondria

Protein synthesizing activity and membrane transport were examined in fresh and cryopreserved isolated rat liver mitochondria. In the presence of 0.6, 1.2, and 1.8 M final concentrations of dimethyl sulfoxide (Me2SO), both metabolic parameters were considerably inhibited in the fresh samples and even more inhibited in the cryopreserved specimens. However, simple exposure to this penetrating cryoprotectant, followed by its subsequent removal by washing, did not seem to affect significantly the examined functions. When different freeze-thaw regimes were investigated, it was observed that optimal recovery of protein synthesis and membrane transport functions were obtained when fast freezing took place in the absence of Me2SO.

Aplastic anaemia--aetiology and clinical features

Acquired aplastic anaemia remains a devastating and frustrating disease from which a proportion of patients still die as a result of failure of support measures. Its pathogenesis remains a mystery.

T-2 mycotoxin inhibits mitochondrial protein synthesis

We investigated the effect of T-2 toxin on rat liver mitochondrial protein synthesis. Isolated rat liver mitochondria were supplemented with an S-100 supernatant from rat liver and an external ATP-generating system. We used an in vitro assay employing cycloheximide, an inhibitor of cytoplasmic protein synthesis, and chloramphenicol, an inhibitor of mitochondrial protein synthesis, to distinguish mitochondrial protein synthesis from the cytoplasmic process. Amino acid incorporation into mitochondria was dependent on the concentration of mitochondria and was inhibited by chloramphenicol. The rate of uptake of [3H]leucine into mitochondrial protein was unaffected by the addition of T-2 toxin and was not a rate-limiting step in incorporation. However, 0.02 micrograms/ml of T-2 toxin decreased the rate of protein synthesis by isolated mitochondria by 50%. The degree of protein synthesis inhibition correlated with the amount of T-2 toxin taken up by the mitochondria. While T-2 toxin is known to inhibit eukaryotic protein synthesis, this is the first time T-2 was shown to inhibit mitochondrial protein synthesis.

Protein synthesis by hepatic mitochondria isolated from carbon tetrachloride-exposed rats

Hepatic mitochondria isolated from rats 40 h after dosage with 1.1 ml/kg CCl4 are uncoupled and display structural damage. Mitochondrial function returns during hepatic recovery. Because the products of mitochondrial protein synthesis are essential to mitochondrial structure and function, the effects of CCl4 on the rate of mitochondrial protein synthesis, and on the products, was studied using mitochondria from CCl4-exposed rats during the early, maximum development and resolution stages of CCl4-induced mitochondrial damage. Rates of mitochondrial protein synthesis (incorporation of [35S]methionine) were elevated 300% over that of mitochondria from non-exposed rats 17 h after exposure; depressed by 50% at 40 h and above control at 113 h. When the radiolabeled products of incorporation were separated and examined by autoradiography, a novel, low-molecular-weight band, of approx. 9700, was apparent 40 h after CCl4 exposure. A band of similar molecular weight appeared when control mitochondria were incubated without an exogenous supply of ATP. Mitochondria from exposed rats which displayed rates of protein synthesis greater than control consistently had a relative increase in a band that corresponded in size to that of cytochrome oxidase subunit I. It was concluded that the loss of mitochondrial function induced by CCl4 could not be attributed to inhibition of mitochondrial protein synthesis, and that the mitochondria may not always synthesize protein in constant proportions.

Endogenous free radical generation may influence proteolysis in mitochondria

Isolated Mitochondria were allowed to incorporate radioactive amino acids into protein and proteolysis was then measured. In State 4 free radical generation was manipulated by means of respiratory chain blockers and uncouplers. Conditions of enhanced radical flux resulted in accelerated protein breakdown. We suggest that radicals influence proteolysis in cells both directly (by fragmenting proteins) and indirectly (by rendering proteins more susceptible to proteinases).

Liver mitochondria contain an ATP-dependent, vanadate-sensitive pathway for the degradation of proteins

A large fraction (30-50%) of the various proteins synthesized within isolated rat liver mitochondria were degraded to amino acids within 60 min after synthesis. Incomplete mitochondrial polypeptides resulting from the incorporation of puromycin were degraded even more extensively (80% per hr). Protein breakdown was measured by the appearance of acid-soluble radioactivity and by the disappearance of labeled polypeptides detected on NaDodSO4/polyacrylamide gel electrophoresis. The amino acids generated by proteolysis were transported rapidly out of the mitochondria and no peptide intermediates accumulated in the organelle. This degradative process did not involve lysosomes or lysosomal enzymes and was markedly stimulated by ATP either generated within the mitochondria or supplied exogenously. An inhibitor of respiration (cyanide) or uncouplers of oxidative phosphorylation (oligomycin, dinitrophenol) reduced proteolysis when mitochondria were provided substrates for ATP generation. When exogenous ATP was provided, these agents did not affect proteolysis, but degradation was then sensitive to atractyloside, an inhibitor of adenine nucleotide transport. Vanadate, an inhibitor of various ATPases, blocked proteolysis even in the presence of ATP and caused a marked stabilization of nearly all polypeptide bands. Thus, mitochondria--like bacteria or the cytosol of animal cells--contain a pathway for complete degradation of proteins which seems to selectively remove polypeptides with abnormal structures. Within this organelle, ATP hydrolysis appears necessary for an initial step in this degradative process.

Inhibition of mitochondrial protein synthesis and energy coupling by fragment A of diphtheria toxin

The effect of intact diphtheria toxin and its fragment A on energy-dependent functions in mouse liver mitochondria/mitoplasts has been studied. Fragment A was found to inhibit protein synthesis in mitoplasts to the same extent (approximately 80%) as the uncoupler carbonylcyanide p-trifluoromethoxyphenylhydrazone, but had no similar effect in lysed mitoplasts. Intact diphtheria toxin had no effect in either case. Fragment A was found to function as a potent uncoupler in isolated mitochondria and mitoplasts, inhibiting oxidative phosphorylation by approximately 80% at a concentration (2 micrograms fragment A/mg of protein) that did not inhibit protein synthesis. In contrast, intact toxin slightly increased the tightness of energy coupling in isolated mitoplasts. 125I-labelled intact diphtheria toxin was bound to mitoplasts to about the same extent as labelled fragment A. At concentrations which efficiently inhibited mitochondrial protein synthesis, fragment A had no effect on the intramitochondrial concentration of nicotinamide adenine dinucleotides, nor was it capable of ADP-ribosylating mitochondrial proteins, indicating that the well known enzymatic activity of fragment A is not involved in the observed effect in mitochondria. The results indicate that fragment A of diphtheria toxin inhibits protein synthesis in mitochondria and mitoplasts by inhibiting mitochondrial energy transduction. The detailed mechanism of the uncoupling effect and its possible significance in intact cells remain to be elucidated.

In vivo effect of chloramphenicol and thiamphenicol on some enzymes of normal mouse liver

Chloramphenicol a potent inhibitor of bacterial and some mammalian cell protein synthesis, was administered i.p. to a group of mice for 6 consecutive days. Another group of animals was treated similarly with thiamphenicol and a third group served as control. The effects of the two antibiotics on the activity of some liver enzymes; the two pyridoxal 5-phosphate dependent enzymes, kynurenine hydrolase and kynurenine amino-transferase; pyridoxal phosphokinase; beta-glucuronidase and acid ribonuclease were determined. Chloramphenicol and thiamphenicol decreased significantly the activities of kynurenine hydrolase, beta-glucuronidase and acid ribonuclease and both drugs increased the activity of pyridoxal phosphokinase significantly. Their effect on kynurenine amino-transferase was different, chloramphenicol decreased while thiamphenicol increased the enzyme activity. Results are discussed and possible explanations suggested.

Maintenance of neurons isolated in bulk from rat brain: incorporation of radiolabeled substrates

Neurons isolated in bulk from 10- to 15-day-old rat brain can be maintained for 18--24 h. Phase microscopy shows that the cells remain morphologically intact during this time. As a criterion of viability, the incorporation of radiolabeled amino acids and uridine into trichloroacetic acid-insoluble material was selected. The cells are capable of the incorporation both after isolation and after maintenance. The uptake is constant with time, is proportional to substrate concentration, and is inhibited by puromycin and cycloheximide, but not by chloramphenicol. Thus the cells remain viable during this maintenance period. This system may provide a model for the study of the synthesis of specific neuronal components.

Tolerance to morphine-induced calcium depletion in regional brain areas: characterization with reserpine and protein synthesis inhibitors

1 Administration of a single dose of morphine sulphate (25 mg/kg) induces tolerance to calcium depletion lasting seven days. 2 There are no apparent changes in calcium content in any of eight discrete brain regions throughout this seven day period. 3 Pretreatment with reserpine (5 mg/kg) did not alter the ability of morphine to induce tolerance. Reserpine alone produced no tolerance to its own calcium depleting action. 4 Cycloheximide (500 mug/kg) but not chloramphenicol (200 mg/kg) effectively prevented development of tolerance. 5 It is concluded that the induction of tolerance to calcium depletion seen after morphine may involve changes in various proteins in membranes of synaptic origin.

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.

Mitochondrial protein synthesis and the stimulation of steroidogenesis by cyclic adenosine 3',5'-monophosphate in isolated rat adrenal cells

The stimulation by cyclic AMP of steroidogenesis in rat adrenal cells isolated by trypsin treatment was inhibited by D-threo-chloramphenicol and by its L-threo-isomer. The former is an inhibitor of mitochondrial protein synthesis while the latter is not. Both substances, at concentrations which inhibit steroidogenesis, inhibit amino acid incorporation into the proteins of microsomes. Inhibition in other subcellular fractions also occurs depending on the isomer and its concentration. In no case was there a preferential inhibition of amino acid incorporation into mitochondrial proteins. Carbomycin, another inhibitor of mitochondrial protein synthesis, gave similar results. In addition, subfractionation of mitochondria in these experiments revealed no preferential inhibition of amino acid incorporation into the proteins of either the soluble of membrane fractions of this organelle. The above results were obtained at several concentrations of the inhibitors when only partial inhibition of steroidogenesis was present. Both isomers of chloramphenicol inhibited steroidogenesis in a cell-free system to an extent equal to that found with cyclic AMP-stimulated steroidogenesis in intact cells. It is concluded that these inhibitors of mitochondrial protein synthesis have multiple metabolic effects in adrenal cells.

The significance of promitochondrial structures in rat liver for mitochondrial biogenesis

1. The heavy, light and fluffy mitochondrial fractions obtained by differential centrifugation were further characterized with respect to their protein synthesizing ability in vitro, their nucleic acid content, buoyant density of their DNA and ultrastructure. 2. The light mitochondrial fraction synthesized proteins in vitro at a rate 4-5 times as high as heavy and fluffy mitochondria. The incorporation ability of this fraction was also maximally affected by the thyroid status of the animal. The radioactivity in leucyl-tRNA of the light mitochondrial fraction was about 3-4 times as high as that of the other two fractions. 3. The heavy, light and fluffy mitochondrial fractions contained small but consistent amounts of RNA and DNA. Although the DNA content was the same in all mitochondria fractions, the light mitochondria contained relatively more RNA. The buoyant density of DNA from all the fractions was 1.701g/cm(3). 4. Electron microscopy revealed that the heavy mitochondria have a typical mitochondrial architecture, with densely packed cristae and a well developed double membrane. Light mitochondria were also surrounded by double membranes, but were smaller in size and contained less cristae. The fluffy fraction consisted of a mixture of well formed mitochondria and those in the process of degradation. 5. The significance of these findings in relation to mammalian mitochondrial genesis is discussed.

Effects of cycloheximide, D-threo-chloramphenicol, erythromycin and actinomycin D on De-novo synthesis of cytoplasmic and mitochondrial proteins in the cotyledons of germinating pea seeds

Inhibitors of, and radioactive substrates for, protein synthesis were introduced into germinating pea (Pisum sativum L.) seeds, and protein synthesis was allowed to proceed in vivo. Subsequent analyses of subcellular fractions showed the following: Cycloheximide strongly inhibited the incorporation of [(14)C]leucine into both mitochondrial and cytoplasmic proteins. D-Threo-chloramphenicol and erythromycin did not affect cytoplasmic protein synthesis, but partially inhibited mitochondrial protein synthesis. These results suggest that most of the new mitochondrial proteins were originally synthesized in the cytoplasm. Actinomycin D did not appreciably affect the initial incorporation of [(14)C]leucine into either mitochondrial or cytoplasmic proteins, suggesting that information (mRNA) concerning the initially synthesized proteins may be present in the quiescent seeds. The lack of appreciable incorporation of [(3)H]thymidine into mitochondrial DNA supported our previons report that mitochondria may not be synthesized de novo in pea cotyledons.

Atypical pattern of utilization of amino acids for mitochondrial protein synthesis in HeLa cells

The capacity of HeLa cell mitochondria, either isolated or in intact cells, to incorporate different labeled amino acids into proteins was investigated. Eight amino acids (alanine, arginine, aspartic acid, cysteine, glutamic acid, glutamine, glycine, and lysine), which include most of the charged polar ones, showed a very low amount, if any at all, of chloramphenicol-sensitive incorporation, relative to that expected for an "average" HeLa-cell protein. By contrast, the most hydrophobic amino acids (leucine, isoleucine, valine, phenylalanine, and methionine) were the most actively incorporated by HeLa mitochondria. The available evidence suggests that pool effects cannot account for this general pattern of utilization of amino acids; furthermore, this pattern is in good agreement with the known hydrophobic properties of proteins synthesized in mitochondria.