Fatty acids anabolism

A rather limited collection of simple precursor molecules is sufficient to provide for the biosynthesis of virtually any cellular constituent, be it protein, nucleic acid, lipid, or polysaccharide. All of these substances are constructed from appropriate building blocks via the pathways of anabolism. In turn, the building blocks (amino acids, nucleotides, sugars, and fatty acids) can be generated from metabolites in the cell. For example, amino acids can be formed by amination of the corresponding a-keto acid carbon skeletons, and pyruvate can be converted to hexoses for polysaccharide biosynthesis. 

Whereas catabolism is fundamentally an oxidative process, anabolism is, by its contrasting nature, reductive. The biosynthesis of the complex constituents of the cell begins at the level of intermediates derived from the degradative pathways of catabolism or, less commonly, biosynthesis begins with oxidized substances available in the inanimate environment, such as carbon dioxide. When the hydrocarbon chains of fatty acids are assembled from acetyl-CoA units, activated hydrogens are needed to reduce the carbonyl (C=0) carbon of acetyl-CoA into a —CHg— at every other position along the chain. When glucose is... 

As a rule, the anabolic pathway by which a substance is made is not the reverse of the catabolic pathway by which the same substance is degraded. The two paths must differ in some respects for both to be energetically favorable. Thus, the y3-oxidation pathway for converting fatty acids into acetyl CoA and the biosynthesis of fatty acids from acetyl CoA are related but are not exact opposites. Differences include the identity of the acvl-group carrier, the stereochemistry of the / -hydroxyacyl reaction intermediate, and the identity of the redox coenzyme. FAD is used to introduce a double bond in jS-oxidalion, while NADPH is used to reduce the double bond in fatty-acid biosynthesis. 

Biomolecules are synthesized as well as degraded, but the pathways for anabolism and catabolism are not the exact reverse of one another. Fatty acids are biosynthesized from acetate by an 8-step pathway, and carbohydrates are made from pyruvate by the 11-step gluconeogenesis pathway. 

In eukaryotes, anabolic and catabolic pathways that interconvert common products may take place in specific subcellular compartments. For example, many of the enzymes that degrade proteins and polysaccharides reside inside organelles called lysosomes. Similarly, fatty acid biosynthesis occurs in the cytosol, whereas fatty... 

During catabolic and anabolic processes, a renovation of the molecular cellular components takes place. It should be emphasized that the catabolic and anabolic pathways are independent of each other. Be these pathways coincident and differing in the cycle direction only, the metabolism would have been side-tracked to the so-called useless, or futile, cycles. Such cycles arise in pathology, where a useless turnover of metabolites may occur. To avoid this undesirable contingency, the synthetic and degradative routes in the cell are most commonly separated in space. For example, the oxidation of fatty acids occurs in the mitochondria, while the synthesis thereof proceeds extramitochondrially, in the microsomes. 

Examples of such intra cellular membrane transport mechanisms include the transfer of pyruvate, the symport (exchange) mechanism of ADP and ATP and the malate-oxaloacetate shuttle, all of which operate across the mitochondrial membranes. Compartmentalization also allows the physical separation of metabolically opposed pathways. For example, in eukaryotes, the synthesis of fatty acids (anabolic) occurs in the cytosol whilst [3 oxidation (catabolic) occurs within the mitochondria. 

Thioesters play a paramount biochemical role in the metabolism of fatty acids and lipids. Indeed, fatty acyl-coenzyme A thioesters are pivotal in fatty acid anabolism and catabolism, in protein acylation, and in the synthesis of triacylglycerols, phospholipids and cholesterol esters [145], It is in these reactions that the peculiar reactivity of thioesters is of such significance. Many hydrolases, and mainly mitochondrial thiolester hydrolases (EC 3.1.2), are able to cleave thioesters. In addition, cholinesterases and carboxylesterases show some activity, but this is not a constant property of these enzymes since, for example, carboxylesterases from human monocytes were found to be inactive toward some endogenous thioesters [35] [146], In contrast, allococaine benzoyl thioester was found to be a good substrate of pig liver esterase, human and mouse butyrylcholinesterase, and mouse acetylcholinesterase [147],... 

The pentose phosphate pathway (PPP, also known as the hexose monophosphate pathway) is an oxidative metabolic pathway located in the cytoplasm, which, like glycolysis, starts from glucose 6-phosphate. It supplies two important precursors for anabolic pathways NADPH+H+, which is required for the biosynthesis of fatty acids and isopren-oids, for example (see p. 168), and ribose 5-phosphate, a precursor in nucleotide biosynthesis (see p. 188). 

Volatile compounds formed by anabolic or catabolic pathways include fatty acid derivatives, terpenes and phenolics. In contrast, volatile compounds formed during tissue damage are typically formed through enzymatic degradation and/ or autoxidation reactions of primary and/or secondary metabolites and includes lipids, amino acids, glucosinolates, terpenoids and phenolics. 

Again, the resulting high [NADPH]/[NADP+] ratio provides the reducing environment that favors reductive anabolic processes such as fatty acid synthesis. 

Very little data are available regarding effects of anabolic steroid implants on the lipid metabolism in growing ruminants. Lipogenic enzyme activity and fatty acid synthesis in vitro were elevated in subcutaneous adipose tissue from bulls implanted with estradiol (44), which may account for the increase in fat content of carcasses reported in some studies. TBA implants have no effect on lipogenesis in intact heifers, and only tend to reduce lipogenic enzyme activities in ovariectomized heifers (45). 

The anabolic hormone insulin has the opposite effect to glucagon and epinephrine. It stimulates the formation of triacylglycerols through decreasing the level of cAMP, which promotes the dephosphorylation and inactivation of hormone-sensitive lipase (Fig. 5). Insulin also stimulates the dephosphorylation of acetyl CoA carboxylase, thereby activating fatty acid synthesis (see Topic K3). Thus fatty acid synthesis and degradation are coordinately controlled so as to prevent a futile cycle. 

The TCA cycle takes place inside the mitochondria. It is not only the metabolic pathway that accounts for the complete combustion of the product of glycolysis, but also the pathway that accounts for the complete combustion of carbohydrates, fatty acids, and amino acids. The main functions of the cycle are to provide different compounds that are precursors for the cell anabolism and to generate most of the metabolic energy. 

The / -keto esters are reduced to the respective chiral ft -hydroxy esters by at least two alternative enzymes one of which is D-directing the other one is L-directing (Fig. 3.4). A product mixture results that contains both enantiomeric forms, d and i.,b of the carbinol (/1-hydroxy ester) in varying degrees. In the case of ethyl acetoacetate (1) preferably the L-form of ethyl 3-hydroxybutyrate (l-4) is produced which is then secreted from the cell [55-58]. The L-directing enzyme is methyl butyralde-hyde reductase (MBAR EC 1.1.1.265), and the D-enantiomer is formed by the action of /J-ketoacyl reductase (KAR EC 1.1.1.100) which is a constituent of fatty acid anabolism (Fig. 3.4) [49, 59]. Alcohol dehydrogenase (ADH EC 1.1.1.1) L-directing activity is classically attributed to was shown to be inactive - moreover the enzyme is even inhibited by the substrate [2, 34, 37]. 

Figure 7-1. Pathways of fuel metabolism and oxidative phosphorylation. Pyruvate may be reduced to lactate in the cytoplasm or may be transported into the mitochondria for anabolic reactions, such as gluconeogenesis, or for oxidation to acetyl-CoA by the pyruvate dehydrogenase complex (PDC). Long-chain fatty acids are transported into mitochondria, where they undergo [ -oxidation to ketone bodies (liver) or to acetyl-CoA (liver and other tissues). Reducing equivalents (NADH, FADII2) are generated by reactions catalyzed by the PDC and the tricarboxylic acid (TCA) cycle and donate electrons (e ) that enter the respiratory chain at NADH ubiquinone oxidoreductase (Complex 0 or at succinate ubiquinone oxidoreductase (Complex ID- Cytochrome c oxidase (Complex IV) catalyzes the reduction of molecular oxygen to water, and ATP synthase (Complex V) generates ATP fromADP Reprinted with permission from Stacpoole et al. (1997).

Additionally, the study demonstrated that there are fatty acid metabolism genes that were positively associated with lovastatin production and tended to encode catabolic enzymes that are predicted to promote formation of the polyketide precursors acetyl-CoA and malonyl-CoA, whereas fatty acid metabolism genes that are negatively associated with secondary metabolite production encode anabolic enzymes, i.e., acyl-CoA oxidase, fatty acid desaturase, and fatty acid synthases. 

Excess acetate (C2) can be converted to the mobile ketone body energy source aceto-acetate (C4) and thence its reduced form hydroxybutyrate (C,) for transport throughout the body. Excess acetate can be carboxylated (via acetylCoA carboxylase) to form malonylCoA (C3), the donor for further C2 additions (with C02 elimination) in the anabolic synthesis of long chain fatty acids. Fatty acids are components of the phospholipids of cellular membranes and are also stored as triacylglycerols (triglycerides) for subsequent hydrolysis and catabolic fatty acid oxidation to yield reduced coenzymes and thence ATP (see Chapter 2). 

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