Adrenomyeloneuropathy: increased accumulation of very long chain fatty acid in cultured skeletal muscle

Skeletal muscle cultures from a patient with the rare disease adrenomyeloneuropathy (AMN), challenged by the addition of an extra amount of docosanoic or hexacosanoic acid to the usual growth medium, accumulated much more of these fatty acids into several lipid classes than did control patient cultures. Triglycerides were particularly affected. These experiments are the first demonstrating an enhanced capacity of AMN cultured tissue to accumulate medium-derived fatty acids into cellular lipid. Cultured human skeletal muscle represents a new model system for evaluating the metabolic defect which results in the pathological accumulation of very-long-chain fatty-acids in AMN patients.     

Isolation of a branched chain alpha-keto acid dehydrogenase from rabbit liver

An enzyme catalysing a series of reactions resulting in the oxidative decarboxylation of branched chain alpha-keto acids and production of NADH, was extracted from rabbit liver mitochondria with the aid of NaClO4. Purification yielded a product which appeared homogeneous on electrophoresis. The enzyme is active on three substrates alpha-ketoisocaproate, alpha-keto-beta-methyl valerate, and alpha-ketoisovalerate.     

Isolation of a branched chain α-keto acid dehydrogenase from rabbit liver

An enzyme catalysing a series of reactions resulting in the oxidative decarboxylation of branched chain α-keto acids and production of NADH, was extracted from rabbit liver mitochondria with the aid of NaClO₄. Purification yielded a product which appeared homogeneous on electrophoresis. The enzyme is active on three substrates α-ketoisocaproate, α-keto-β-methyl valerate, and α-ketoisovalerate.     

Localization of the human gene for the El alpha subunit of branched chain keto acid dehydrogenase (BCKDHA) to chromosome 19q13.1----q13.2

The gene encoding the El alpha subunit of branched chain keto acid dehydrogenase (BCKDHA) was mapped to human chromosome region 19q13.1----q13.2 using 3H-labeled cDNA hybridized in situ to human chromosomes.     

Purification of a branched-chain keto acid dehydrogenase from Pseudomonas putida.

We purified branched-chain keto acid dehydrogenase to a specific activity of 10 mumol/min per mg of protein from Pseudomonas putida grown on valine. The purified enzyme was active with 2-ketoisovalerate, 2-ketoisocaproate, and 2-keto-3-methylvalerate in a ratio of 1.0:0.8:0.7 but showed no activity with either pyruvate or 2-ketoglutarate. There were four polypeptides in the purified enzyme (molecular weights, 49,000, 46,000, 39,000, and 37,000). The purified enzyme was deficient in the specific lipoamide dehydrogenase produced during growth on valine (molecular weight, 49,000). Branched-chain keto acid dehydrogenase required L-valine, oxidized nicotinamide adenine dinucleotide, coenzyme A, thiamine pyrophosphate, and magnesium chloride. A partially purified preparation catalyzed the oxidation of 2-keto-[1-14C]isovalerate to [14C]carbon dioxide, isobutyryl-coenzyme A, and reduced nicotinamide adenine dinucleotide in equimolar amounts. Both the Km and the Vmax for 2-ketoisovalerate were affected by the addition of L-valine to the assay mixture. However, only the Vmax values for oxidized nicotinamide adenine dinucleotide and coenzyme A were affected when L-valine was present. This suggested that valine acted by affecting the binding of branched-chain keto acids to subunit E1 of the complex.     

Interconversion of Tetrahymena pyriformis ornithine decarboxylase from inactive to active form by phosphorylation

A protein kinase and an acidic phosphoprotein phosphatase were purified from Tetrahymena pyriformis which phosphorylate and dephosphorylate the purified ornithine decarboxylase (ODC) of this microorganism. The protein kinase and the phosphoprotein phosphatase are copurified with ODC and can be separated in three distinct peaks only by a hydrophobic column of phenyl-Sepharose. The purified kinase is not dependent on cAMP, requires Mg2+ for its catalytic activity and has a molecule mass of 45 kDa. Incubation of [32P]ODC with the purified phosphoprotein phosphatase results in a complete loss of 32P and its catalytic activity. Phosphorylation of the inactive phosphatase-treated ODC by endogenous kinase or rat liver casein kinase-2 results in 100 or 40% reactivation of the initial untreated ODC activity, respectively.     

Pathways of straight and branched chain fatty acid catabolism in higher plants.

Significant advances in our knowledge of fatty acid breakdown in plants have been made since the subject was last comprehensively reviewed in the early 1990s. Many of the genes encoding the enzymes of peroxisomal beta-oxidation of straight chain fatty acids have now been identified. Biochemical genetic approaches in the model plant, Arabidopsis thaliana, have been particularly useful not only in the identification and functional characterisation of genes involved in fatty acid beta-oxidation but also in establishing the role of beta-oxidation at different stages in plant development. Advances in our understanding of branched chain amino acid catabolism have provided convincing evidence that mitochondria play an important role in this process. This work is discussed in the context of the long running debate on the sub-cellular localisation of fatty acid beta-oxidation in plants. A significant aspect of this review is that it provides the opportunity to present a comprehensive analysis of the complete Arabidopsis genome sequence for each of the different gene families that are known to be involved in beta-, alpha-, and omega-oxidation of fatty acids in plants. Inevitably, this increase in information, as well as providing many answers also raises many new intriguing questions, particularly as regards the regulation and physiological role of fatty acid catabolism throughout the higher plant life cycle.     

Generation mechanism and purification of an inactive form convertible in vivo to the active form of quinoprotein alcohol dehydrogenase in Gluconobacter suboxydans.

Alcohol dehydrogenase (ADH) of acetic acid bacteria is a membrane-bound quinohemoprotein-cytochrome c complex involved in vinegar production. In Gluconobacter suboxydans grown under acidic growth conditions, it was found that ADH content in the membranes was largely increased but the activity was not much changed, suggesting that such a condition produces an inactive form of ADH (inactive ADH). A similar phenomenon could be also observed in Acetobacter aceti, another genus of acetic acid bacteria. Furthermore, aeration conditions were also shown to affect ADH production; the ADH level was increased and was present as an active form under low-aeration conditions, while the ADH level was decreased and was present mainly as an inactive form under high-aeration conditions. Inactive ADH was solubilized from the membranes of G. suboxydans grown in acidic and high-aeration conditions and was purified separately from the normal, active form of ADH (active ADH). In spite of having 10 times less enzyme activity than active ADH, inactive ADH could not be distinguished from active ADH with respect to their subunit compositions, molecular sizes, and prosthetic groups. Inactive ADH, however, had a relatively loose conformation with a partially oxidized state, while active ADH had a tight conformation with a completely reduced state, suggesting that inactive ADH may lack a right subunit's interaction and that one of the heme c components may be inactivated. Reactivation from such an inactive ADH occurred either by shifting of the pH of the culture medium up during the cultivation or by incubation of the resting cells at the neutral pH region in the presence of an energy source such as D-sorbitol. Such an activation of ADH was repressed by the addition of a proton uncoupler and could not occur in the spheroplasts. Thus, the results suggest that inactive ADH could be generated abundantly under acidic growth conditions and converted to the active form at a neutral culture pH. The data also suggest that some periplasmic component may be involved in the conversion of inactive ADH into the active form by consuming some forms of energy.     

Localization of short/branched chain Acyl-CoA dehydrogenase (ACADSB) to human chromosome 10

Short/branched chain acyl-CoA dehydrogenase, SBCAD (gene symbol ACADSB), is a member of the acyl-CoA dehydrogenase family of genes with activity toward the short/branched chain acyl-CoA derivatives as well as short/straight chain acyl-CoAs. Southern blot analysis of DNA from a panel of human/rodent somatic cell hybrids localized ACADSB to human chromosome 10, and fluorescence in situ hybridization experiments confirmed the chromosomal assignment and refined the subchromosomal localization to 10q25–q26.     

A comparative study of straight chain and branched chain fatty acid oxidation in skin fibroblasts from patients with peroxisomal disorders.

The beta-oxidation of stearic acid and of alpha- and gamma-methyl isoprenoid-derived fatty acids (pristanic and tetramethylheptadecanoic acids, respectively) was investigated in normal skin fibroblasts and in fibroblasts from patients with inherited defects in peroxisomal biogenesis. Stearic acid beta-oxidation by normal fibroblast homogenates was several-fold greater compared to the oxidation of the two branched chain fatty acids. The effect of phosphatidylcholine, alpha-cyclodextrin, and bovine serum albumin on the three activities suggests that different enzymes are involved in the beta-oxidation of straight chain and branched chain fatty acids. Homogenates of fibroblasts from patients with a deficiency in peroxisomes (Zellweger syndrome and infantile Refsum's disease) showed a normal ability to beta-oxidize stearic acid, but the oxidation of pristanic and tetramethylheptadecanoic acid was decreased. Concomitantly, 14CO2 production from the branched chain fatty acids by Zellweger fibroblasts in culture (but not from stearic acid) was greatly diminished. The Zellweger fibroblasts also showed a marked reduction in the amount of water-soluble metabolites from the radiolabeled branched chain fatty acids that are released into the culture medium. The data presented indicate that the oxidation of alpha- and gamma-methyl isoprenoid-derived fatty acids takes place largely in peroxisomes in human skin fibroblasts.     

Lung injury-induced skeletal muscle wasting in aged mice is linked to alterations in long chain fatty acid metabolism

Introduction

Older patients are more likely to acquire and die from acute respiratory distress syndrome (ARDS) and muscle weakness may be more clinically significant in older persons. Recent data implicate muscle ring finger protein 1 (MuRF1) in lung injury-induced skeletal muscle atrophy in young mice and identify an alternative role for MuRF1 in cardiac metabolism regulation through inhibition of fatty acid oxidation.

Objectives

To develop a model of lung injury-induced muscle wasting in old mice and to evaluate the skeletal muscle metabolomic profile of adult and old acute lung injury (ALI) mice.

Methods

Young (2 month), adult (6 month) and old (20 month) male C57Bl6 J mice underwent Sham (intratracheal H₂O) or ALI [intratracheal E. coli lipopolysaccharide (i.t. LPS)] conditions and muscle functional testing. Metabolomic analysis on gastrocnemius muscle was performed using gas chromatography-mass spectrometry (GC–MS).

Results

Old ALI mice had increased mortality and failed to recover skeletal muscle function compared to adult ALI mice. Muscle MuRF1 expression was increased in old ALI mice at day 3. Non-targeted muscle metabolomics revealed alterations in amino acid biosynthesis and fatty acid metabolism in old ALI mice. Targeted metabolomics of fatty acid intermediates (acyl-carnitines) and amino acids revealed a reduction in long chain acyl-carnitines in old ALI mice.

Conclusion

This study demonstrates age-associated susceptibility to ALI-induced muscle wasting which parallels a metabolomic profile suggestive of altered muscle fatty acid metabolism. MuRF1 activation may contribute to both atrophy and impaired fatty acid oxidation, which may synergistically impair muscle function in old ALI mice.

     

Regulation of long chain fatty acid activation in heart muscle.

Regulation of fatty acid activation was studied in whole tissue homogenates of rat heart. The palmityl-CoA synthestase activity was proportional to the fatty acid to albumin ratio in the incubation medium with maximal activity occurring at a molar ratio of about 5. Fatty acyl-CoA synthetase activity was inhibited by products of the reaction (AMP, pyrophosphate, and palmityl-CoA). The apparent Ki for palmityl-CoA inhibition was 5 muM and this inhibition could be relieved by CoA-SH or albumin. The Km for CoA-SH in the absence of palmityl-CoA was 7 muM and was increased to 24 muM by addition of 8 muM palmityl-CoA. Cytosolic and mitochondrial levels of CoA-SH and carnitine were estimated in whole tissue homogenates of heart and liver. From 90 to 100% of whole tissue CoA was recovered in the mitochondrial fraction of heart muscle and it was estimated that the cytosolic concentration of free CoA-SH probably never exceeds its Km value for fatty acid activation in this tissue. Therefore, the rate of fatty acid activation would be expected to depend on the availability of CoA-SH in the cytosolic space. By adjusting the concentration of CoA-SH in the cytosol to the rate of acetyl-CoA oxidation, carnitineacetyl-CoA transferase may function in cardiac muscle to couple the rate of fatty acid activation in the cytosolic compartment to acetyl-CoA oxidation in the mitochondria. Approximately 30% of whole tissue CoA-SH was located in the cytosolic space in liver. Heart muscle has about twice as much carnitine as liver but in both tissues 100% of whole tissue carintine was located in the cytosolic space. The ratio of carnitine to CoA-SH in the cytosolic space was estimated to be about 100 in heart and 17 in liver. This high ratio in cardiac muscle may function to channel fatty acids toward oxidation rather than toward synthesis of complex lipids.     

Effects of reduced free fatty acid availability on skeletal muscle PDH activation during aerobic exercise. Pyruvate dehydrogenase

This study investigated the effect of reduced free fatty acid (FFA) availability on pyruvate dehydrogenase activation (PDHa) and carbohydrate metabolism during moderate aerobic exercise. Eight active male subjects cycled for 40 min at 55% Vo(2 peak) on two occasions. During one trial, subjects ingested 20 mg/kg body mass of the antilipolytic drug nicotinic acid (NA) during the hour before exercise to reduce FFA. Nothing was ingested in the control trial (CON). Blood and expired gas measurements were obtained throughout the trials, and muscle biopsy samples were obtained immediately before exercise and at 5, 20, and 40 min of exercise. Plasma FFA were lower in the NA trial (0.13 +/- 0.01 vs. 0.48 +/- 0.03 mM, P < 0.05), and the respiratory exchange ratio (RER) was increased with NA (0.93 +/- 0.01 vs. 0.89 +/- 0.01, P < 0.05), resulting in a 14.5 +/- 1.8% increase in carbohydrate oxidation compared with CON. PDHa increased rapidly in both trials at exercise onset but was approximately 15% higher (P < 0.05) throughout exercise in the NA trial (2.44 +/- 0.19 and 2.07 +/- 0.12 mmol x kg wet muscle(-1) x min(-1) for NA and CON at 40 min). Muscle glycogenolysis was 15.3 +/- 9.6% greater in the NA trial vs. the CON trial but did not reach statistical significance. Glucose 6-phosphate contents were elevated (P < 0.05) in the NA trial at 30 and 40 min of exercise, but pyruvate and lactate contents were unaffected. These data demonstrate that the reduction of exogenous FFA availability increased the activation of PDH and carbohydrate oxidation during moderate aerobic exercise in men. The increased activation of PDH was not explained by changes in muscle pyruvate or the ATP/ADP ratio but may be related to a decrease in the NADH/NAD(+) ratio or an epinephrine-induced increase in calcium concentration.     

Activation of hepatocyte growth factor by proteolytic conversion of a single chain form to a heterodimer.

Hepatocyte growth factor (HGF) is a heterodimeric protein consisting of a heavy chain and a light chain held by a disulfide bond. These chains are produced by endoproteolytic processing from a single chain precursor. In this study, we examined whether the processing is a prerequisite for the mitogenic activity of HGF on hepatocytes in primary culture. Single chain HGF was proteolytically converted to the heterodimeric form during incubation with hepatocytes and was as mitogenic as the heterodimeric form. When the conversion was inhibited by serine-protease inhibitors, the mitogenic activity of single chain HGF was markedly reduced. Furthermore, a mutant resistant to the proteolytic processing, which was prepared by in vitro mutagenesis, completely lost the mitogenic activity. From these results, we concluded that the single chain form of HGF is endoproteolytically processed by a serine-protease and that this processing is a prerequisite for the mitogenic activity of HGF.     

Mechanism of lactic acid oxidation catalyzed by lactate dehydrogenase from the tail muscle of Homarus americanus.

The mechanism of lactic acid oxidation in the tail muscles of Homarus americanus was studied. In solutions of intermediate ionic strength (0.55) time-course progress curves for lactic acid oxidation as catalyzed by lactate dehydrogenase exhibited a lag period. Evidence is presented which indicates that the lactate dehydrogenase found in the tail muscles of the lobster exists in two distinct physical and kinetic forms. The equilibrium of these forms is dependent upon the ionic strength of the reaction mixture. In low ionic strength solutions, the enzyme exists as a tetrameric species with an apparent K_m for lactic acid of 1.1 m; in high ionic strength solutions, the enzyme exists as a dimer and the corresponding K_m is 0.028 m. At intermediate ionic strengths, an equilibrium between the two physical and kinetic species exists which is modulated by the NADH mole-fraction ($\text{[}\text{NADH}\text{]}\text{[}\text{NADH}\text{+}\text{NAD}{}^{\mathrm{+}}\text{]}$) and, in turn, this modulation results in sigmoidal time-course progress curves. The role of this enzyme is discussed as affected by in vivo ionic strength, temperature and levels of oxidized and reduced nicotine adenine dinucleotides.