Phosphorylation of pig brain microtubule proteins. General properties and partial characterization of endogenous substrate and cyclic AMP-dependent protein kinase.

Collagen synthesis and the activities of prolyl hydroxylase, lysyl hydroxylase, collagen galactosyltransferase and collagen glucosyltransferase were studied in isolated chick-embryo tendon cells after the administration of cortisol acetate to the chick embryos. When the steroid was injected 1 day before isolation of the tendon cells, collagen synthesis was decreased, even though the enzyme activities were not changed. When cortisol acetate was given as repeated injections over a period of 4 days, both collagen synthesis and the enzyme activities decreased. The hydroxylase activities decreased even more than the two collagen glycosyltransferase activities, both in isolated cells and in whole chick embryos. The amount of prolyl hydroxylase protein diminished to the same extent as the enzyme activity, indicating that cortisol acetate inhibits enzyme synthesis. The inhibitory effect of cortisol acetate on collagen synthesis and on the enzyme activities was partially reversible in 3 days. Total protein synthesis was completely restored within this time. Only massive doses of cortisol acetate inhibited collagen synthesis in vitro. Additional experiments indicated that cortisol acetate did not decrease the rate of the enzyme reactions when added directly to the enzyme incubation mixtures. The results suggest that cortisol acetate decreases collagen synthesis both by its direct effect on collagen polypeptide-chain synthesis and by decreasing the activities of enzymes involved in post-translational modifications.     

Inhibition of protein synthesis by (aminooxy)acetate in rat liver

(Aminooxy)acetate and D-cycloserine, two inhibitors of hepatic transamination reactions, inhibited also protein synthesis in isolated cells and postmitochondrial supernatants from rat liver. Both inhibitors acted in extracts only in concentrations higher than 1 mM. However, while D-cycloserine acted in isolated cells, as in extracts, (aminooxy)acetate inhibits protein synthesis in isolated cells by 50% of the control in the range 0.03-3 mM. NH+4 and H2O2, two by-products of (aminooxy)acetate degradation, inhibited protein synthesis in isolated liver cells, but at such a high concentration that the inhibition of protein synthesis carried out by (aminooxy)acetate cannot be explained by generation of these species. The results point out that the inhibitory action of (aminooxy)acetate on protein synthesis appears to require the integrity of the molecule.     

Mechanism of acetate synthesis from CO2 by Clostridium acidiurici.

Total synthesis of acetate from CO2 by Clostridium acidiurici during fermentations of hypoxanthine has been shown to involve synthesis of glycine from methylenetetrahydrofolate, CO2, and NH3. The glycine is converted to serine by the addition of methylenetetrahydrofolate, and the resulting serine is converted to pyruvate, which is decarboxylated to form acetate. Since CO2 is converted to methylenetetrahydrofolate, both carbons of the acetate are derived from CO2. The evidence supporting this pathway is based on (i) the demonstration that glycine decarboxylase is present in C. acidiurici, (ii) the fact that glycine is synthesized by crude extracts at a rate which is rapid enough to account for the in vivo synthesis of acetate from CO2, (iii) the fact that methylenetetrahydrofolate is an intermediate in the formation of both carbons of acetate from CO2, and (iv) the fact that the alpha carbon of glycine is the source of the carboxyl group of acetate. Evidence is presented that this synthesis of acetate does not involve carboxylation of a methyl corrinoid enzyme such as occurs in Clostridium thermoaceticum and Clostridium formicoaceticum. Thus, there are two different mechanisms for the total synthesis of acetate from CO2 by clostridia.     

Uptake of Acetate and Propionate by Isolated Nerve Endings from the Electric Organ of Torpedo marmorata and Their Incorporation into Choline Esters

Abstract: The uptake and incorporation into choline esters of acetate and propionate by electric organ synaptosomes were compared, with the aim of better understanding the basis for the selectivity of choline ester synthesis shown by this tissue for acetate. It was found that propionate uptake, like acetate uptake, was a temperature-dependent, saturable process. Both uptake mechanisms had similar affinities for their substrates, but the maximal velocity of propionate uptake was considerably lower than that of acetate uptake; and less of the accumulated propionate was used for choline ester synthesis than of the accumulated acetate. While acetate was a good inhibitor of propionate uptake, propionate was a very poor inhibitor of acetate uptake. This finding, in addition to the observation that the two uptakes were not affected in the same way by changes in pH, led to the suggestion that acetate uptake and propionate uptake reflect different processes. In both cases, however, the pH dependence of uptake indicated that these substrates cross the membrane as the charged species. Acetate uptake and acetylcholine synthesis remained closely associated under various experimental conditions, while propionate uptake could be dissociated from the synthesis of propionylcholine. Hence, it appears that acetate is taken up by a specific, high-velocity mechanism linked to acetylcholine synthesis, whereas propionate uptake may represent a less specific mechanism.     

Identification of the rhaA, rhaB and rhaD gene products from Escherichia coli K-12

Washed cells of Peptostreptococcus products (strain Marburg), which were incubated in the presence of CO/CO2/N2 (50%/17%/33%; 200 kPa) catalyzed the synthesis of acetate from carbon monoxide. The rate of acetate formation from CO was stimulated more than threefold by the addition of sodium (10 mM); potassium did not effect acetate synthesis. The degree of stimulation was dependent on the sodium concentration; the dependence followed simple Michaelis-Menten kinetics. The apparent Km for sodium was determined to be about 2 mmol/l. Sodium also stimulated acetate synthesis from H2 plus CO2. In the absence of added sodium the formation of formate as an intermediate in methyl group synthesis was stimulated. It is suggested that the sodium dependent reaction(s) is one (or more) of the reactions involved in methyl group synthesis from CO2.     

Lipid biosynthesis in liver slices of the foetal guinea pig.

Lipid synthesis as measured by the incorporation of acetate or 3H2O into slices of foetal liver, is much higher than in slices of adult liver and shows a peak at about two-thirds of gestation. At this time the synthesis from glucose was low and reached a peak 10 days later. The changes in the activity of ATP citrate lyase, which mirrored acetate incorporation, and the effect of glucose and pyruvate on acetate corporation into lipid suggests that some of the lipid synthesis occurs via intramitochondrial acetyl-CoA production from acetate. Despite this, lipid synthesis was not inhibited by (-)-hydroxycitrate. The low rate of synthesis from glucose at two-thirds of gestation is ascribed to the low activity of pyruvate carboxylase at this time and a role for a phosphoenolpyruvate carboxykinase in providing oxaloacetate for lipogenesis is proposed. The activity of fatty acid synthetase broadly agreed with the changes in lipid synthesis, whereas the activity of acetyl-CoA carboxylase was barely sufficient to account for the rates of lipid synthesis in vivo. Acetate and short-chain fatty acids are likely to be the major precursors for lipid synthesis in vivo.     

In vitro enzymatic synthesis of baccatin III with novel and cheap acetyl donors by the recombinant taxoid 10β-O-acetyl transferase

Despite the importance of baccatin III as a precursor to paclitaxel, a widely used chemotherapeutic agent, efficient enzymatic synthesis methods are lacking. Therefore, in this study, the recombinant taxoid 10β-O-acetyl transferase was prepared to produce baccatin III in vitro. The recombinant enzyme could use vinyl acetate, butyl acetate, sec-butyl acetate, isobutyl acetate, amyl acetate, and isoamyl acetate as novel and cheap alternative acetyl group donors to replace the expensive acetyl CoA for the enzymatic synthesis of baccatin III. A molecular docking study further confirmed that these acetyl donors could reasonably bind to the enzyme molecule. Using the aqueous two-phase bio-catalytic reaction system, hexane and ethyl acetate could increase the yield of product baccatin III by 2.8% and 1.1% respectively. This approach using novel and cheap acetyl donors is promising for the enzymatic synthesis of baccatin III for the future industrial production of paclitaxel.     

Evaluation of acetate uptake and its relative conversion to acetylcholine in Torpedo electric organ synaptosomes under different ionic and metabolic conditions

The uptake of acetate and its incorporation into acetylcholine were measured under various conditions in nerve terminals isolated from the electric organ in order to characterize acetate uptake and to study the relationship between acetate uptake and acetylcholine synthesis in a pure cholinergic preparation. It was found that increasing extracellular choline up to 10^?4 M had no effect on either acetate uptake or the conversion of acetate to ACh, while the addition of hemicholinium-3 to the incubation medium led to decreases in both parameters. Hence, it appears that endogenous levels of choline are sufficient to support ongoing acetylcholine synthesis in this preparation and that this synthesis depends to some extent on the uptake of extracellular choline. Nonetheless, in the absence of choline uptake, both the uptake of acetate and the conversion of acetate to acetylcholine remained substantial, indicating that internal sources of choline as well can be used for acetylcholine synthesis.Acetate uptake displayed a marked requirement for external Na⁺ and was decreased following depolarization of the synaptosomes by an elevated K⁺ concentration. The conversion of acetate to acetylcholine followed a similar pattern, except that a small reduction in acetylcholine synthesis was observed in the absence of external Ca²⁺, while acetate uptake was unaffected. The addition of ATP, AMP-PNP or phosphate to the incubation medium caused an increase in both the uptake and incorporation of acetate, but adenosine had no effect on either of these functions. Choline uptake, meanwhile, was unchanged in the presence of ATP, phosphate or adenosine. Acetate uptake appears to be more closely linked to its intracellular metabolism than to the transmembrane movement of choline itself.The mechanism by which acetate crosses the nerve terminal membrane has not been established, but the possibility that acetate is a substrate for a monocarboxylate transport system such as has been described in other systems can be ruled out as inhibitors of anion permeability do not block acetate uptake in this preparation.     

Continous ethyl acetate production by Kluyveromyces fragilis on whey permeate

The synthesis of ethyl acetate by Kluyveromyces fragilis on diluted whey permeate was studied. Ethanol, lactose and O₂ are the direct precursors for ethyl acetate synthesis by this yeast. Ethyl acetate production is affected by many parameters, particularly the carbon/nitrogen (C/N) ratio, Tween 80 and iron. Ethyl acetate synthesis is optimum for C/N = 45. Tween 80 lowered slightly the level of ethyl acetate whereas iron completely stopped ethyl acetate production. The level of ethanol in the feed, the dissolved O₂ (DO) and dilution rate (D) were also optimised. Thus at D = 0.24 h ^–1, for 4 g/l of ethanol in the feed and 40% DO, the productivity of ethyl acetate was optimal (0.7 g/l per hour). Correspondence to: A. Miclo     

Long-term regulation by theophylline of fatty acid synthetase, acetyl-CoA carboxylase and lipid synthesis in cultured glial cells.

The long-term regulation of fatty acid synthetase and acetyl-CoA carboxylase and of fatty acid and sterol synthesis was studied in C-6 glial cells in culture. When theophylline (10(-3) M) was added to the culture medium of these cells, rates of lipid synthesis from acetate and activities of synthetase and carboxylase became distinctly lower than in cells that were untreated. This effect appeared after approximately 12 h, and after 48 h enzymatic activities were reduced approx. 2-fold and rates of lipid synthesis from acetate 3- to 4-fold. The likelihood that the decrease in fatty acid synthesis from acetate was caused by the decrease in activities of fatty acid synthetase and acetyl-CoA carboxylase was established by several observations. These indicated that the locus of the effect probably did not reside at the level of acetate uptake into the cell, alterations in acetate pool sizes or conversion of acetate to acetyl-CoA. Moreover, de novo fatty acid synthesis was found to be the predominant pathway in these glial cells, whether treated with theophylline or not. The mechanism of the effect of theophylline on fatty acid synthetase was shown by immunochemical techniques to involve an alteration in content of enzyme rather than in catalytic efficiency. The change in content of fatty acid synthetase was shown by isotopic-immunochemical experiments to involve a decrease in synthesis of the enzyme. The mechanism whereby theophylline leads to a decrease in lipogenesis and in the synthesis of fatty acid synthetase may not be mediated entirely by inhibition of phosphodiesterase and an increase in cyclic AMP levels, because dibutyryl cyclic AMP (10(-3) M) only partially reproduced the effect.     

The effects of lactate, acetate, glucose, insulin, starvation and alloxan-diabetes on protein synthesis in perfused rat hearts.

Compared with glucose, lactate + acetate stimulated ventricular protein synthesis in anterogradely perfused hearts from fed or 72 h-starved rats. Stimulation was greater on a percentage basis in starved rats. Atrial protein synthesis was not detectably stimulated by lactate + acetate. Insulin stimulated protein synthesis in atria and ventricles. The stimulation of protein synthesis by lactate + acetate and insulin was not additive, the percentage stimulation by insulin being less in the ventricles of lactate + acetate-perfused hearts than in glucose-perfused hearts. Perfusion of hearts from 72 h-starved or alloxan-diabetic rats with glucose + lactate + acetate + insulin did not increase protein-synthesis rates or efficiencies (protein synthesis expressed relative to total RNA) to values for fed rats, implying there is a decrease in translational activity in these hearts. In the perfused heart, inhibition of protein synthesis by starvation and its reversal by re-feeding followed a relatively prolonged time course. Synthesis was still decreasing after 3 days of starvation and did not return to normal until after 2 days of re-feeding.     

C nuclear magnetic resonance study of acetate incorporation into malate during ca-uptake by isolated leaf tissues

¹³C Nuclear magnetic resonance spectroscopy of leaflets of Gleditsia triacanthos and Albizia julibrisin was used to determine the fate of acetate taken up during the absorption of calcium from ¹³C-labeled Ca-acetate solution. Small amounts of acetate accumulated temporarily in the leaf tissues, but the bulk of acetate was incorporated into malate. The initial rate of malate synthesis was very low, but increased rapidly during acetate treatment and reached its maximum after 8 hours; the enzymes involved in malate synthesis thus appear to be substrate induced. Use of acetate-2-¹³C yielded malate labeled in C-3, indicating that vacuolar malate accumulating during Ca-uptake might be synthesized via malate synthase from acetate and glyoxalate. However, a source of glyoxalate condensing with acetate during malate synthesis could not be identified. Glycolate produced in photorespiration is an unlikely source, because glycolate-2-¹³C was absorbed and metabolized by the leaf tissues into products of the glycolate pathway, but was not a major precursor in malate synthesis. Malate synthesis via the glyoxalate cycle is also unlikely, because no evidence for the recycling of a ¹³C-labeled 4-carbon organic acid was found. Malate synthesis in the leaflets of Gleditsia and Albizia thus appears to involve the inducible condensation of acetate with a 2-carbon compound of unidentified nature and origin.     

Lipid Synthesis in the Presence of Nitrogenous Compounds in Chlorella pyrenoidosa

Acetate was incorporated by Chlorella pyrenoidosa into nonvolatile water-soluble compounds (amino acids, organic acids and carbohydrates) with pH optimum between 4 and 5. Incorporation into lipid was maximal at pH 7.5. The proportion of incorporated acetate in lipid was not significantly affected by acetate concentration and chlorophyll concentration in the ranges tested. Illumination of Chlorella during acetate metabolism increased the synthesis of lipid with concomitant decrease in the synthesis of water-soluble compounds. Nitrate and ammonium ions had essentially no effect on acetate metabolism. Inhibition by nitrite was greater on the synthesis of lipid. Illumination reversed the gross inhibition by nitrite, but altered the distribution of incorporated label in favor of the water-soluble compounds.     

Effects of peroxisome proliferators gemfibrozil and clofibrate on syntheses of dolichol and cholesterol in rat liver

The effects of two peroxisome proliferators, gemfibrozil and clofibrate, on syntheses of dolichol and cholesterol in rat liver were investigated. Gemfibrozil did not affect the overall content of dolichyl phosphate, but it changed the chain-length distribution of dolichyl phosphate, increasing the levels of species with shorter isoprene units. Gemfibrozil suppressed synthesis of dolichyl phosphate from [(3)H]mevalonate and [(3)H]farnesyl pyrophosphate in rat liver. In contrast, clofibrate increased the content of dolichol (free and acyl ester forms). It remarkably enhanced dolichol synthesis from mevalonate, but did not affect dolichol synthesis from farnesyl pyrophosphate. Gemfibrozil elevated cholesterol synthesis from [(14)C]acetate, but did not affect the synthesis from mevalonate. Clofibrate suppressed cholesterol synthesis from acetate, but did not affect cholesterol synthesis from mevalonate. These results suggest that gemfibrozil suppresses synthesis of dolichyl phosphate by inhibiting, at the least, the pathway from farnesyl pyrophosphate to dolichyl phosphate. As a result, the chain-length pattern of dolichyl phosphate may show an increase in shorter isoprene units. Clofibrate may increase the content of dolichol by enhancing dolichol synthesis from mevalonate. Gemfibrozil may increase cholesterol synthesis by activating the pathway from acetate to mevalonate. Unlike gemfibrozil, clofibrate may decrease cholesterol synthesis by inhibiting the pathway from acetate to mevalonate.     

Fatty acids synthesis in rat adipose tissue. Tracer concentration effects in vitro

1. The use of labelled acetate for studying the synthesis of long-chain fatty acids in rat adipose tissue in vitro has been examined, with special reference to the effect of acetate concentration. 2. The incorporation of acetate into fatty acids is proportional to the concentration of acetate in the medium when the latter does not exceed about 10mum. Above this concentration, the relative incorporation becomes progressively less, and reasons for this are discussed. 3. In particular it is shown that this is not necessarily due to disturbance of the endogenous rate of fatty acid synthesis by a relatively large amount of acetyl-CoA derived from added acetate. 4. However, to ensure that the added acetate does not cause such a disturbance its concentration must be kept sufficiently low. For labelled acetate used under present conditions, this concentration should not be more than about 10mum.     

Sodium dependent acetate formation from CO2 in Peptostreptococcus productus (strain Marburg)

Abstract Washed cells of Peptostreptococcus productus (strain Marburg), which were incubated in the presence of CO/CO₂/N₂ (50%/ 17%/ 33%; 200 kPa) catalyzed the synthesis of acetate from carbon monoxide. The rate of acetate formation from CO was stimulated more than threefold by the addition of sodium (10 mM); potassium did not effect acetate synthesis. The degree of stimulation was dependent on the sodium concentration; the dependence followed simple Michaelis-Menten kinetics. The apparent K _m for sodium was determined to be about 2 mmol/1. Sodium also stimulated acetate synthesis from H₂ plus CO₂. In the absence of added sodium the formation of formate as an intermediate in methyl group synthesis was stimulated. It is suggested that the sodium dependent reaction(s) is one (or more) of the reactions involved in methyl group synthesis from CO₂.     

Evidence That Isolated Chloroplasts Contain an Integrated Lipid-Synthesizing Assembly That Channels Acetate into Long-Chain Fatty Acids

High rates of light-dependent fatty acid synthesis from acetate were measured in isolated chloroplasts that were permeabilized to varying extents by resuspension in hypotonic reaction medium. The reactions in hypotonic medium unsupplemented with cofactors were linear with time and were directly proportional to chlorophyll concentration, suggesting that the enzymes and cofactors of fatty acid synthesis remained tightly integrated and thylakoid associated within disrupted chloroplasts. Permeabilized chloroplasts expanded to at least twice the volume of intact chloroplasts, lost about 50% of their stromal proteins in the medium, and metabolized exogenous nucleotides. However, neither acetyl-coenzyme A (CoA) nor malonyl-CoA inhibited fatty acid synthesis from acetate; nor were [1-14C]acetyl-CoA and [14C]malonyl-CoA significantly incorporated into fatty acids. Fatty acid synthesis from acetate was independent of added cofactors but was totally light dependent. Changes in the products of fatty acid synthesis were consistent with the loss of endogenous glycerol-3-phosphate from permeabilized chloroplasts. However, in appropriately supplemented medium, the products of acetate incorporation by spinach (Spinacia oleracea) chloroplasts were similar when reactions were carried out in either isotonic or hypotonic medium. Taken together, the results of this study suggest that the enzymes of fatty acid synthesis with chloroplasts are organized into a multienzyme assembly that channels acetate into long-chain fatty acids, glycerides, and CoA esters.     

Effect of a single ethanol injection on lipid and lipoprotein synthesis in rat liver]

A single ethanol injection results in the increase of mono-, di- and tri-glicerides synthesis in rat liver, and also of the synthesis of apoprotein of very low density lipoproteins, their formation and secretion. Different uptake of pools of 14C-acetyl CoA, synthesized from injected 14C-acetate, and 3H-acetyl CoA, synthesized through metabolic pathways of 3H-leucine, indicates the compartmentalization of acetyl CoA in the synthesis of saturated and unsaturated fatty acids. 3H-acetyl CoA is more intensively used in the synthesis of unsaturated fatty acids than 14C-acetyl CoA synthesized from acetate. Ethanol increases the uptake of acetyl CoA, synthesized from acetate, for the synthesis of all the lipids, probably, for the expense of the increased synthesis of endogenous acetate in metabolic transformation of ethanol.