Chlamydomonas carries out fatty acid β‐oxidation in ancestral peroxisomes using a bona fide acyl‐CoA oxidase

Peroxisomes are thought to have played a key role in the evolution of metabolic networks of photosynthetic organisms by connecting oxidative and biosynthetic routes operating in different compartments. While the various oxidative pathways operating in the peroxisomes of higher plants are fairly well characterized, the reactions present in the primitive peroxisomes (microbodies) of algae are poorly understood. Screening of a Chlamydomonas insertional mutant library identified a strain strongly impaired in oil remobilization and defective in Cre05.g232002 (CrACX2), a gene encoding a member of the acyl‐CoA oxidase/dehydrogenase superfamily. The purified recombinant CrACX2 expressed in Escherichia coli catalyzed the oxidation of fatty acyl‐CoAs into trans‐2‐enoyl‐CoA and produced H₂O₂. This result demonstrated that CrACX2 is a genuine acyl‐CoA oxidase, which is responsible for the first step of the peroxisomal fatty acid (FA) β‐oxidation spiral. A fluorescent protein‐tagging study pointed to a peroxisomal location of CrACX2. The importance of peroxisomal FA β‐oxidation in algal physiology was shown by the impact of the mutation on FA turnover during day/night cycles. Moreover, under nitrogen depletion the mutant accumulated 20% more oil than the wild type, illustrating the potential of β‐oxidation mutants for algal biotechnology. This study provides experimental evidence that a plant‐type FA β‐oxidation involving H₂O₂‐producing acyl‐CoA oxidation activity has already evolved in the microbodies of the unicellular green alga Chlamydomonas reinhardtii.     

Acyl Coenzyme A Synthetase Regulation: Putative Role in Long‐Chain Acyl Coenzyme A Partitioning

Objective: Long‐chain acyl coenzyme A synthetase (ACSL) converts free fatty acids (FFAs) into their metabolizable long‐chain acyl coenzyme A (LC‐CoA) derivatives that are essential for FFA conversion to CO₂, triglycerides, or complex lipids. ACSL‐1 is highly expressed in adipose tissue with broad substrate specificity. We tested the hypothesis that ACSL localization, and resulting local generation of LC‐CoA, regulates FFA partitioning. Research Methods and Procedures: These studies used cell fractionation of rat adipocytes to measure ACSL activity and mass and compared cells from young, mature, fed, fasted, and diabetic rats. Functional studies included measurement of FFA oxidation, complex lipid synthesis, and LC‐CoA levels. Results: High ACSL specific activity was expressed in the mitochondria/nuclei (M/N), high‐density microsomes (HDM), low‐density microsomes (LDM), and plasma membrane (PM) fractions. We show here that, during fasting, total FFA oxidation increased, and, although total ACSL activity decreased, a greater percentage of activity (43 ± 1.5%) was associated with the M/N fraction than in the fed state (23 ± 0.3%). In the fed state, more ACSL activity (34 ± 0.5%) was associated with the HDM than in the fasted state (25 ± 0.9%), concurrent with increased triglyceride formation from FFA. Insulin increased LC‐CoA and ACSL activity associated with the PM. The changes in ACSL activity in response to insulin were associated with only minor changes in mass as determined by Western blotting. Discussion: It is hypothesized that ACSL plays an important role in targeting FFA to specific metabolic pathways or acylation sites in the cell, thus acting as an important control mechanism in fuel partitioning. Localization of ACSL at the PM may serve to decrease FFA efflux and trap FFA within the cell as LC‐CoA.     

Evidence for the involvement of polyunsaturated fatty acids in the regulation of long-chain acyl CoA thioesterases and peroxisome proliferation in rat carcinosarcoma

The feeding of high-fat diets rich in polyunsaturated fatty acids (PUFAs) caused a marked increase in the acyl CoA thioesterase activity of the Walker 256 tumour. Diets containing lower levels of PUFAs did not alter the activity of acyl CoA thioesterase and the exposure of LLC-WRC256 tumour cells, in culture, to PUFAs (150 microM) also was ineffective in altering activity. The tumours from n-3 PUFA-rich and control diets were analysed by transmission electron microscopy in order to compare peroxisomal content. The presence of PUFAs led to an almost 10-fold increase in the number of peroxisomes present in the tumour tissue. A common feature of the PUFA-treated tumour was the presence of many cells containing highly condensed heterochromatin at the periphery of the nucleus, indicative of apoptosis. The sparsity of endoplasmic reticulum and the lack of detection of mitochondrial acyl CoA thioesterase, MTE-I, led to the conclusion that the increase in tumour acyl CoA thioesterase activity may be due to an increase in the activity of the peroxisomal enzyme.     

Lack of correlation between ACAT mRNA expression and cholesterol esterification in primary liver cells

A partial rabbit cDNA clone (14b) for ACAT has been characterized and used to demonstrate that hepatic and aortic ACAT mRNA_14b abundance increased 2–3-fold in rabbits receiving a high fat/high cholesterol-diet compared to chow fed animals (Pape et al. (1995) J. Lipid Res. 36, 823–838). Because of those data we hypothesized that increased hepatic cholesteryl ester mass and synthesis rates in rabbit liver cells are associated with an increase in ACAT mRNA_14b levels. To test this hypothesis we altered cellular cholesteryl ester mass and synthesis rates in primary parenchymal and nonparenchymal cells using various extracellular agents and measured the accumulated mass of ACAT mRNA_14b. Parenchymal cells incubated with rabbit β VLDL or mevalonolactone displayed a 6–10-fold increase in cellular cholesteryl ester mass over a three day treatment with no significant changes in cellular free cholesterol, triacylglycerols, or ACAT mRNA_14b levels; HMG CoA reductase and LDL receptor mRNA mass decreased initially as a result of cholesteryl ester loading. Treatment of parenchymal cells with CI-976, an ACAT inhibitor, showed a marked reduction in cholesteryl ester synthetic rate compared to β VLDL controls but displayed no change in ACAT mRNA_14b levels. A mixed population of rabbit hepatic nonparenchymal cells was incubated with β VLDL for 24 h in culture which resulted in a 6-fold increase in cellular cholesteryl ester mass; there was no change in ACAT mRNA_14b levels. In an in vivo study, rabbits consuming a high fat/high cholesterol-diet for three weeks showed a 10-fold increase in hepatic cholesteryl ester with no significant changes in ACAT mRNA_14b levels. Together these data indicate that rabbit liver cellular cholesteryl ester mass increases of up to 10-fold are not correlated with ACAT mRNA_14b changes. Thus, hepatic ACAT mRNA_14b expression and cellular cholesterol esterification do not appear to be coordinately regulated at this level of cholesteryl ester loading.     

Biochemical and genetic investigation of initial reactions in aerobic degradation of the bile acid cholate in Pseudomonas sp. strain Chol1

Bile acids are surface-active steroid compounds with toxic effects for bacteria. Recently, the isolation and characterization of a bacterium, Pseudomonas sp. strain Chol1, growing with bile acids as the carbon and energy source was reported. In this study, initial reactions of the aerobic degradation pathway for the bile acid cholate were investigated on the biochemical and genetic level in strain Chol1. These reactions comprised A-ring oxidation, activation with coenzyme A (CoA), and beta-oxidation of the acyl side chain with the C(19)-steroid dihydroxyandrostadienedione as the end product. A-ring oxidizing enzyme activities leading to Delta(1,4)-3-ketocholyl-CoA were detected in cell extracts and confirmed by liquid chromatography-tandem mass spectrometry (LC-MS/MS). Cholate activation with CoA was demonstrated in cell extracts and confirmed with a chemically synthesized standard by LC-MS/MS. A transposon mutant with a block in oxidation of the acyl side chain accumulated a steroid compound in culture supernatants which was identified as 7alpha,12alpha-dihydroxy-3-oxopregna-1,4-diene-20-carboxylate (DHOPDC) by nuclear magnetic resonance spectroscopy. The interrupted gene was identified as encoding a putative acyl-CoA-dehydrogenase (ACAD). DHOPDC activation with CoA in cell extracts of strain Chol1 was detected by LC-MS/MS. The growth defect of the transposon mutant could be complemented by the wild-type ACAD gene located on the plasmid pBBR1MCS-5. Based on these results, the initiating reactions of the cholate degradation pathway leading from cholate to dihydroxyandrostadienedione could be reconstructed. In addition, the first bacterial gene encoding an enzyme for a specific reaction step in side chain degradation of steroid compounds was identified, and it showed a high degree of similarity to genes in other steroid-degrading bacteria.     

Activation of aromatic acids and aerobic 2-aminobenzoate metabolism in a denitrifying Pseudomonas strain

The initial reactions possibly involved in the acrobic and anaerobic metabolism of aromatic acids by a denitrifying Pseudomonas strain were studied. Several acyl CoA synthetases were found supporting the view that activation of several aromatic acids preceeds degradation. A benzoyl CoA synthetase activity (AMP forming) (apparent K _m values of the enzyme from nitrate grown cells: 0.01 mM benzoate, 0.2 mM ATP, 0.2 mM coenzyme A) was present in aerobically grown and anaerobically, nitrate grown cells when benzoate or other aromatic acids were present. In addition to benzoate and fluorobenzoates, also 2-amino-benzoate was activated, albeit with unfavorable K _m (0.5 mM 2-aminobenzoate). A 2-aminobenzoyl CoA synthetase (AMP forming) was induced both aerobically and anaerobically with 2-aminobenzoate as growth substrate which had a similar substrate spectrum but a low K _m for 2-aminobenzoate (<0.02 mM). Anaerobic growth on 4-hydroxybenzoate induced a 4-hydroxybenzoyl CoA synthetase, and cyclohexanecarboxylate induced another synthetase. In contrast, 3-hydroxybenzoate and phenyl-acetate grown anaerobic cells appeared not to activate the respective substrates at sufficient rates. Contrary to an earlier report extracts from aerobic and anaerobic 2-aminobenzoate grown cells catalysed a 2-aminobenzoyl CoA-dependent NADH oxidation. This activity was 10–20 times higher in aerobic cells and appeared to be induced by 2-aminobenzoate and oxygen. In vitro, 2-aminobenzoyl CoA reduction was dependent on 2-aminobenzoyl CoA NAD(P)H, and oxygen. A novel mechanism of aerobic 2-aminobenzoate degradation is suggested, which proceeds via 2-aminobenzoyl CoA.     

Regulation of eicosanoid synthesis in microvessel endothelium: glucocorticoids do not affect arachidonyl CoA synthetase activity

The properties of acyl coenzyme A (CoA) synthetase activity were characterized in cultured rabbit coronary microvessel endothelial cells. We report here that microvessel endothelial cells contain two long-chain acyl CoA synthetases. One shows activity with a variety of fatty acids, similar to long-chain non-selective fatty acyl CoA synthetases described previously. The other activity was selective for arachidonic acid and other structurally related substrates. Both activities required ATP, Mg2+ and CoA for optimal activity. The arachidonyl CoA and the non-selective acyl CoA synthetases showed different thermolabilities. Arachidonyl CoA formation was inhibited by greater than 50% after 1 min at 45 degrees C, whereas a 15 min heating treatment was necessary to produce the same relative inhibition of oleoyl CoA synthesis. Glucocorticoid pretreatment (10(-7) M dexamethasone) of the RCME cells did not affect the apparent Km or Vmax, nor the fatty acid selectivity for either acyl CoA synthetase. Therefore, although fatty acyl CoA synthetases may be involved in limiting eicosanoid formation, these activities do not appear to be glucocorticoid-responsive.     

Export of acyl chains from plastids isolated from embryos of Brassica napus (L.)

We report the first measurements of the kinetics of transmembrane transport of acyl chains in plants. This was achieved by separating the period of in vitro synthesis of fatty acids from their export and by making use of acyl-CoA-binding protein (ACBP), which specifically binds long-chain acyl-CoAs. In the absence of added CoA but in the presence of ACBP, newly synthesised acyl chains accumulated as free fatty acids (FFAs) in plastids isolated from embryos of oilseed rape (Brassica napus L.). When CoA was added to plastids that had accumulated FFAs, the acyl chains were converted to acyl-CoAs that, in the presence of ACBP, were exported to the incubation medium. The rate of export was dependent on the CoA concentration and, at a saturating CoA concentration, was similar to the rate at which the fatty acids had been synthesised prior to CoA addition.     

Studies on the uptake of fatty acids by Escherichia coli

Oleate uptake by Escherichia coli showed saturation kinetics with a K_m of 34 μm and an activation energy of 6.25 kcal/mole indicating that the rate limiting step in oleate uptake involves an enzyme-catalyzed step. The rate of oleate uptake was decreased by the respiratory poisons, arsenate and 4-pentenoate, which apparently is activated to pentenoyl CoA, thus reducing the intracellular concentration of free intracellular CoA. These data indicated that oleate uptake is dependent on cellular ATP and CoA. During short pulses with [1-¹⁴C]oleate, most of the radioactivity which was taken up was released as ¹⁴C0₂; cells accumulated radioactivity in phospholipids and compounds with the chromatographic mobility of Krebs cycle intermediates. Neither free fatty acid nor oleyl CoA were detectable in the cells. The results support the hypothesis that long-chain fatty acids are translocated by the long-chain fatty acyl CoA synthetase and that uptake is the rate limiting step in the utilization of exogenous fatty acid.     

Identification of a 51-kilodalton polypeptide fatty acyl chain acceptor in soluble extracts from mouse cardiac tissue

We have identified a protein in the soluble fraction from mouse cardiac tissue extracts which is rapidly and selectively acylated by myristyl CoA. This protein was partially purified by anion-exchange chromatography and gel filtration, and the acylation reaction was measured using [3H]myristyl CoA as substrate, followed by sodium dodecyl sulfate - polyacrylamide gel electrophoresis to resolve [3H]fatty acyl polypeptides. The [3H]acyl protein migrated as heterogeneous bands corresponding to relative masses (MrS) of 42,000-51,000 under nonreducing conditions or as a single polypeptide of Mr 51,000 in the presence of reducing agents. Fatty acyl chain incorporation into protein was very rapid and already maximum after 30 s of incubation, whereas no acylation was detected using heat-denatured samples or when the reaction was stopped immediately after initiation. Only the acyl CoA served as fatty acyl chain donor. No incorporation into protein occurred when myristyl CoA was substituted by myristic acid, ATP, and CoA. A time-dependent reduction in the level of [3H]fatty acyl polypeptide was observed upon addition of excess unlabeled myristyl CoA, indicating the ability of the labeled acyl moiety of the protein to turn over during incubation. The saturated C10:0, C14:0, and C16:0 acyl CoAs were more effective to chase the label from the [3H]acyl polypeptide than the C18:0 and C18:1 acyl CoAs. These results provide evidence for a 51-kilodalton polypeptide which serves as an acceptor for fatty acyl chains and could represent an important intermediate in fatty acyl chain transfer reactions in cardiac tissue.     

Transient induction of poly(A)-short myosin heavy chain messenger RNA during terminal differentiation of L6E9 myoblasts

The rat myoblast L₆E₉ cell line under appropriate culture conditions is a uniform population of cycling cells which can be induced to differentiate into a pure population of myotubes. The pattern and kinetics of myogenic differentiation of this cell line are similar to those of primary skeletal muscle myoblasts. We have used this cell line to investigate the controls regulating the synthesis and accumulation of myosin heavy chain during myogenic development. From pulse labeling studies of total cellular protein synthesis, we observed that activation of MHC⁴ synthesis is temporally correlated with cell fusion and myotube formation. MHC synthesis is transiently induced from <1% up to 25% of the total protein synthesized. After MHC has accumulated to the steady-state level characteristic of fully differentiated myotubes, MHC synthesis decreases very rapidly to almost basal levels. To determine whether this transient induction of MHC synthesis was due to parallel changes in MHC messenger RNA levels, the accumulation and compartmentalization of MHC mRNA during L₆E₉ cell differentiation was followed by complementary DNA/RNA hybridization using cDNA prepared against MHC mRNA purified from L₆E₉ cells. We demonstrate that the level of MHC synthesis closely parallels the level of cytoplasmic MHC mRNA. The induction of MHC mRNA accumulation is initiated at least 36 hours prior to cell fusion and at a time when all cells in the population are still uncommitted to terminal differentiation as tested by cell cloning. The level of cytoplasmic MHC mRNA is increased from ~200 molecules per cell in the growing state to ~50,000 molecules at the peak of induction (day 6 after plating). Subsequently the levels of MHC mRNA decrease very rapidly and at day 10 after plating there are only ~3000 molecules per myotube nucleus. A striking feature of this regulation is the behavior of MHC mRNA on oligo(dT) columns. Most (~90%) of the MHC mRNA transiently induced during differentiation has a very short poly(A) tail (<20 nucleotides). We conclude that the striking induction followed by deinduction of MHC synthesis is controlled primarily by the induction and deinduction of cytoplasmic MHC mRNA accumulation. The relationship of our observations to muscle physiology is discussed.     

Exometabolome profiling reveals activation of the carnitine buffering pathway in fed-batch cultures of CHO cells co-fed with glucose and lactic acid

Adjustments to CHO cell physiology were recently observed during implementation of a Raman spectroscopy-based glucose and lactate control strategy. To further understand how these cells, under monoclonal antibody (mAb) production conditions, utilized the extra lactic acid fed, we performed a comprehensive semi-quantitative and time-dependent analysis of the exometabolome. This study focused on the CHO cell's metabolic shift from the fifth day of culture. We compared relative levels of extracellular metabolites in the absence or presence of a 2 g/L lactic acid setpoint while glucose was kept at 4 g/L. Our hypothesis is that extra lactic acid would supply more pyruvate, favoring oxidative phosphorylation. We subsequentially uncovered several carnitine derivatives as biomarkers of the simultaneous activation of TCA anaplerotic pathways as well as a carbon-buffering pathway. CHO cells exhibited a balance between intermediates from (i) amino acid catabolism, (ii) fatty acid β-oxidation, and (iii) pyruvate from glycolysis and lactic acid; and the secretion of their intermediate carnitine derivatives. In addition, 3-hydroxy-methyl-glutaric acid (HMG) and mevalonate syntheses were found as biomarkers of alternative acyl group removal. Together, under a limited capacity to assimilate the surplus of acyl-CoA groups as well as an ability to maintain the acyl-CoA: free CoA ratio for proper and continuous functioning of the TCA cycle, CHO cells activate the carnitine-buffering system, HMG, and mevalonate pathways.     

Interaction of fatty acids,acyl-CoA derivatives and retinoids with microsomal membranes: effect of cytosolic proteins

This paper reviews characteristics of microsomal membrane structure; long chain fatty acids, acyl CoA derivatives, retinoids and the microsomal formation of acyl CoA derivatives and retinyl esters. It is analyzed how the movement of these molecules at the intracellular level is affected by their respective binding proteins (Fatty acid binding protein, acyl CoA binding protein and cellular retinol binding protein). Studies with model systems using these hydrophobic ligands and the lipid-binding or transfer proteins are also described. This topic is of interest especially because in the esterification of retinol the three substrates and the three binding proteins may interact. (Mol Cell Biochem20: 89–94, 1993)Abbreviations FABP(s) Fatty Acid Binding Protein(s) - CRBP Cellular Retinol Binding Protein - ACBP Acyl-CoA-Binding Protein     

Analysis of acyl CoA ester intermediates of the mevalonate pathway in Saccharomyces cerevisiae

The mevalonate pathway plays an important role in providing the cell with a number of essential precursors for the synthesis of biomass constituents. With respect to their chemical structure, the metabolites of this pathway can be divided into two groups: acyl esters [acetoacetyl CoA, acetyl CoA, hydroxymethylglutaryl (HMG) CoA] and phosphorylated metabolites (isopentenyl pyrophosphate, dimethylallyl pyrophosphate, geranyl pyrophosphate, farnesyl pyrophosphate). In this study, we developed a method for the precise analysis of the intracellular concentration of acetoacetyl CoA, acetyl CoA and HMG CoA; and we used this method for quantification of these metabolites in Saccharomyces cerevisiae, both during batch growth on glucose and on galactose and in glucose-limited chemostat cultures operated at three different dilution rates. The level of the metabolites changed depending on the growth phase/specific growth rate and the carbon source, in a way which indicated that the synthesis of acetoacetyl CoA and HMG CoA is subject to glucose repression. In the glucose batch, acetyl CoA accumulated during the growth on glucose and, just after glucose depletion, HMG CoA and acetoacetyl CoA started to accumulate during the growth on ethanol. In the galactose batch, HMG CoA accumulated during the growth on galactose and a high level was maintained into the ethanol growth phase; and the levels of acetyl CoA and HMG CoA were more than two-fold higher in the galactose batch than in the glucose batch.     

Development of resting membrane potentials in differentiating murine neuroblastoma cells (N1E-115) evaluated by flow cytometry

With the aid of a voltage-sensitive oxonol dye, flow cytometry was used to measure relative changes in resting membrane potential (V_m) and forward angle light scatter (FALS) profiles of a differentiating/differentiated murine neuroblastoma cell line (N1E-115). Electrophysiological differentiation was characterized by V_m establishment. The (V_m)-time profile was found to be seed cell concentration-dependent for cell densities of less than 2 × 10⁴ cells/cm². At higher initial cell densities, under differentiating culture conditions, V_m development commenced on day 2 and reached a steady-state on day 12. The relative distribution of differentiated cells between low and high FALS has been proposed as a potential culture electrophysiological differentiation state index. These experiments offer a general methodology to characterize cultured excitable cells of nervous system origin, with respect to electrophysiological differentiation. This information is valuable in studies employing neuroblastoma cells as in vitro screening models for safety/hazard evaluation and/or risk assessment of therapeutical and industrial chemicals under development. This revised version was published online in July 2006 with corrections to the Cover Date.     

Resistin induces lipolysis and re-esterification of triacylglycerol stores, and increases cholesteryl ester deposition, in human macrophages

Human resistin, found within atheroma, exerts inflammatory, angiogenic and proliferative effects in vascular cells and may predict coronary events. Here, we investigate mechanisms by which resistin contributes to macrophage 'foam cell' formation. Increases in macrophage (THP-1) cholesteryl ester mass, in the presence or absence of oxidized LDL, were not explained by altered cholesterol efflux. Instead, resistin enhanced fractional turnover of the endogenous triacylglycerol pool, increased uptake and decreased oxidation of exogenous fatty acids, and decreased phosphorylation of acetyl CoA carboxylase, all factors increasing the availability of fatty acyl CoA substrate for acyl CoA: cholesterol acyltransferase-1, thereby enhancing macrophage cholesteryl ester deposition.     

Propionate mitochondrial toxicity in liver and skeletal muscle: acyl CoA levels

Propionic acidemia occasionally produces a toxic encephalopathy resembling Reye syndrome, indicating disruption of mitochondrial metabolism. Understanding the mitochondrial effect of propionate might clarify the pathophysiology. Liver mitochondria are inhibited by propionate (5 mM) while muscle mitochondria are not. Preincubation is required to inhibit liver mitochondria, suggesting that propionate is metabolized to propionyl CoA. Liver and skeletal muscle mitochondria incubated with [1-14C]propionate contain similar quantities of matrix isotope and release comparable [14C]CO2. However, only liver mitochondria accumulated significant propionyl CoA, which was largely (68%) synthesized from propionate. Carnitine reduced the level of liver matrix propionyl CoA. Inhibition of respiratory control ratios by propionate correlated with propionyl CoA levels. These results support the hypothesis that acyl CoA esters are toxic and that carnitine exerts its protective effect by converting acyl CoA esters to acylcarnitine esters.     

Crystallographic and mass spectrometric analyses of a tandem GNAT protein from the clavulanic acid biosynthesis pathway

(3R,5R)‐Clavulanic acid (CA) is a clinically important inhibitor of Class A β‐lactamases. Sequence comparisons suggest that orf14 of the clavulanic acid biosynthesis gene cluster encodes for an acetyl transferase (CBG). Crystallographic studies reveal CBG to be a member of the emerging structural subfamily of tandem Gcn5‐related acetyl transferase (GNAT) proteins. Two crystal forms (C2 and P2₁ space groups) of CBG were obtained; in both forms one molecule of acetyl‐CoA (AcCoA) was bound to the N‐terminal GNAT domain, with the C‐terminal domain being unoccupied by a ligand. Mass spectrometric analyzes on CBG demonstrate that, in addition to one strongly bound AcCoA molecule, a second acyl‐CoA molecule can bind to CBG. Succinyl‐CoA and myristoyl‐CoA displayed the strongest binding to the “second” CoA binding site, which is likely in the C‐terminal GNAT domain. Analysis of the CBG structures, together with those of other tandem GNAT proteins, suggest that the AcCoA in the N‐terminal GNAT domain plays a structural role whereas the C‐terminal domain is more likely to be directly involved in acetyl transfer. The available crystallographic and mass spectrometric evidence suggests that binding of the second acyl‐CoA occurs preferentially to monomeric rather than dimeric CBG. The N‐terminal AcCoA binding site and the proposed C‐terminal acyl‐CoA binding site of CBG are compared with acyl‐CoA binding sites of other tandem and single domain GNAT proteins. Proteins 2010. © 2009 Wiley‐Liss, Inc.     

Fat metabolism in higher plants. Properties of the palmityl acyl carrier protein: stearyl acyl carrier protein elongation system in maturing safflower seed extracts

Palmityl acyl carrier protein is elongated specifically to stearyl acyl carrier protein by a system which required palmityl acyl carrier protein, malonyl CoA, and NADPH. Extracts from maturing safflower seeds, avocado mesocarp, and stroma from spinach chloroplasts contain the elongation system. The system differs from the de novo fatty acid synthetase system in that (1) it is inactivated at 37 °C whereas the de novo system remains fully active, (2) the pH optimum of the elongation system is 7.8–8.6 whereas the de novo system has a narrow pH optimum at 7.0, (3) NADPH is specifically required whereas the de novo system requires both NADPH and NADH, and (4) the elongation system is relatively insensitive to cerulenin whereas the de novo system is highly sensitive. Acetyl CoA does not serve as a C₂ donor. Stearyl acyl carrier protein, lauryl CoA, myristyl CoA, and palmityl CoA are inactive.     

Cell metabolism and medium perfusion in VERO cell cultures on microcarriers in a bioreactor

Parameters of VERO cell growth and metabolism were studied in cultures performed on microcarriers (MCs) using a bioreactor with a working capacity of 3.7?l. Kinetic studies of VERO cell growth in batch, semi-batch and perfusion cultures using concentrations of 2 and 10?mg/ml of MCs showed that a high concentration of MCs (10?mg/ml) and the use of medium perfusion allowed the attainment of higher final yields of VERO cells (6?×?10⁶ cells/ml after 10 days of culture). Perfusion also allowed better use of MCs as indicated by the observation of about 100% of MCs totally covered by cells and the appearance of multilayered cells on 64% of MCs after 13 days of VERO cell culture with 2?mg/ml of MCs. Concerning the concentration of nutrients in the cultures, the medium perfusion was able to sustain suitable levels of galactose and glutamine, which quickly decreased after 4 days in batch cultures. The air inlet in the batch cultures was capable of eliminating the NH₄ ⁺ which accumulated in the medium culture. Lactate accumulated during the first days of culture but then was utilized by the cells and decreased along the culture time. The optimization of VERO cell cultures on microcarriers as indicated by the concentration of MCs, medium perfusion and air inlet is discussed.