Synthesis and degradation of fatty acids

Synthesis and degradation of fatty acids Zdeňka Klusáčková

Fatty acids (FA) • mostly an even number of carbon atoms and linear chain • in esterified form as component of lipids • in unesterified form in plasma binding to albumin Groups of FA: • according to the chain length <C6 short-chain FA (SCFA) C6 – C12 medium-chain FA (MCFA) C12 – C20 long-chain FA (LCFA) >C20 very-long-chain FA (VLCFA) • according to the number of double bonds no double bond saturated FA (SAFA) one double bond monounsaturated FA (MUFA) more double bonds polyunsaturated FA (PUFA)

Overview of FA

Triacylglycerols • main storage form of FA • acylglycerols with three acyl groups • stored mainly in adipose tissue

FA biosynthesis function: energy storage in the form of TAG • FA biosynthesis in the excess of energy (increased caloric intake) • acyl-CoA and glycerol-3-phosphate synthesis of TAG in liver • TAG incorporation into very low density lipoproteins (VLDL) • entry of VLDL into the blood circulation • TAG transport from the liver to other tissues via VLDL (especially skeletal muscle, adipose tissue)

FA biosynthesis • mainly in the liver, adipose tissue, mammary gland during lactation (always in excess calories) localization: • cell cytoplasm (up to C16) • endoplasmic reticulum, mitochondrion (elongation = chain extension) enzymes: • acetyl-CoA-carboxylase (HCO3- - source of CO2, biotin, ATP) • fatty acid synthase (NADPH + H+, pantothenic acid) primary substrate: • acetyl-CoA final product: • palmitate

FA biosynthesis • on the multienzyme complex – FA synthase • repeated extension of FA by two carbons in each cycle • to the chain length C16 (palmitate) • palmitate, a precursor of saturated and unsaturated FA: saturated FA (> C16) elongation systems desaturation systems unsaturated FA

Precursors for FA biosynthesis 1. Acetyl-CoA source: • oxidative decarboxylation of pyruvate (the main source of glucose) • degradation of FA, ketones, ketogenic amino acids • transport across the inner mitochondrial membrane as citrate 2. NADPH source: • pentose phosphate pathway (the main source) • theconversionofmalate to pyruvate • (NADP+-dependentmalatedehydrogenase - „malic enzyme”) • theconversionofisocitrate to α-ketoglutarate • (isocitratedehydrogenase)

FA biosynthesis Formation of malonyl-CoA HCO3- + ATP ADP + Pi enzyme-biotin enzyme-biotin-COO- biotinyl-enzyme carboxybiotinyl-enzyme 1 carboxylation of biotin 2 transfer of carboxyl group to acetyl-CoA acetyl-CoA formation of malonyl-CoA enzyme-biotin + enzyme – acetyl-CoA-carboxylase malonyl-CoA

FA biosynthesis Regulation at the level of ACC glucagon adrenaline cAMP insulin AMP protein kinase A AMP-dependent protein kinase A acetyl-CoA malonyl-CoA glucose citrate palmitate palmitoyl-CoA acetyl-CoA carboxylase

FA biosynthesis FA synthase

FA biosynthesis The course of FA biosynthesis acetyl-CoA malonyl-CoA CoASH CoASH acetyltransacylase malonyltransacylase transacylation acyl(acetyl)-malonyl- -enzyme complex

FA biosynthesis The course of FA biosynthesis 3-ketoacyl-synthase CO2 condensation acyl(acetyl)-malonyl-enzyme complex 3-ketoacyl-enzyme complex (acetacetyl-enzyme complex)

FA biosynthesis The course of FA biosynthesis NADP+ NADPH + H+ NADP+ NADPH + H+ H2O 3-ketoacyl-reductase 3-hydroxyacyl- dehydrase enoylreductase first reduction dehydration second reduction 3-ketoacyl-enzyme complex (acetoacetyl-enzyme complex) 3-hydroxyacyl-enzyme complex 2,3-unsaturated acyl-enzyme complex acyl-enzyme complex

FA biosynthesis Repetition of the cycle malonyl-CoA CoASH acyl-enzyme complex (palmitoyl-enzyme complex)

FA biosynthesis The release of palmitate thioesterase + H2O palmitate palmitoyl-enzyme complex

FA biosynthesis The fate of palmitate after FA biosynthesis acylglycerols cholesterol esters ATP + CoA AMP + PPi esterification palmitate palmitoyl-CoA acyl-CoA-synthetase elongation desaturation acyl-CoA

FA biosynthesis FA elongation 1. microsomal elongation system • in the endoplasmic reticulum • malonyl-CoA – the donor of the C2 units NADPH + H+ – the donor of the reducing equivalents • extension of saturated and unsaturated FA FA > C16 elongases (chain elongation) palmitic acid (C16) fatty acid synthase 2. mitochondrial elongation system • in mitochondria • acetyl-CoA – the donor of the C2 unit • not reverse β-oxidation

FA biosynthesis Microsomal extension of FA CoASH + CO2 + synthase acetyl-CoA malonyl-CoA 3-ketoacyl-CoA NADPH + H+ NADP+ H2O NADPH + H+ NADP+ hydratase reductase reductase 3-hydroxyacyl-CoA 2,3-unsaturated acyl-CoA acyl-CoA Example: CoASH + CO2 + palmitoyl-CoA malonyl-CoA NADPH + H+ NADP+ NADPH + H+ NADP+ H2O stearoyl-CoA

FA biosynthesis FA desaturation • in the endoplasmic reticulum • process requiring O2, NADH, cytochrome b5

FA degradation function: major energy source (especially between meals, at night, in increased demand for energy intake – exercise) • release of FA from triacylglycerols in adipose tissue into the bloodstream • binding of FA to albumin in the bloodstream • transport to tissues • entry of FA into target cells activation to acyl-CoA • transfer of acyl-CoA via carnitine system into mitochondria β-oxidation Most important FA released from adipose tissue: • palmitic acid • oleic acid • stearic acid

FA degradation Mechanisms of FA degradation long-chain FA (LCFA, C12 – C20) mitochondrial β-oxidation unsaturated FA modified odd-chain-length FA mitochondrial β-oxidation peroxisomal β-oxidation very-long-chain FA (VLCFA, > C20) peroxisomal α-oxidation long-chain branched-chain FA FA with C10 or C12 ω-oxidation

FA degradation Mechanisms of FA degradation β-oxidation ω-oxidation α-oxidation

FA degradation β-oxidation • mainly in muscles localization: • mitochondrial matrix • peroxisome enzymes: • acyl CoA synthetase • carnitine palmitoyl transferase I, II; carnitine acylcarnitine translocase • dehydrogenase (FAD, NAD+), hydratase, thiolase substrate: • acyl-CoA final products: • acetyl-CoA • propionyl-CoA

FA degradation β-oxidation • repeated shortening of FA by two carbons in each cycle • cleavage of two carbon atoms in the form of acetyl-CoA • oxidation of acetyl-CoA to CO2 and H2O in the citric acid cycle complete oxidation of FA • generation of 8 molecules of acetyl-CoA from 1 molecule of palmitoyl-CoA • production of NADH, FADH2 reoxidation in the respiratory chain to form ATP PRODUCTION OF LARGE QUANTITY OF ATP

FA degradation Activation of FA fatty acid ATP acyl-CoA-synthetase acyl adenylate pyrophosphate (PPi) acyl-CoA-synthetase pyrophosphatase 2Pi acyl-CoA AMP fatty acid+ ATP + CoASH acyl-CoA + AMP + PPi PPi + H2O 2Pi

FA degradation The role of carnitine in the transport of FA into mitochondrion FA transfer across the inner mitochondrial membrane by carnitine and three enzymes: • carnitinepalmitoyltransferase I (CPT I) • acyl transfer to carnitine • carnitineacylcarnitinetranslocase • acylcarnitine transfer across • theinnermitochondrialmembrane • carnitinepalmitoyltransferase II (CPT II) • acyl transfer fromacylcarnitineback to CoA in themitochondrial matrix

FA degradation β-oxidation Steps of cycle: acyl-CoA • dehydrogenation • oxidation by FAD • creationofunsaturated acid acyl-CoA-dehydrogenase trans-Δ2-enoyl-CoA • hydration • additionofwater on theβ-carbon atom • creationofβ-hydroxyacid enoyl-CoA-hydratase L-β-hydroxyacyl-CoA L-β-hydroxyacyl-CoA- • dehydrogenation • oxidation by NAD+ • creationofβ-oxoacid -dehydrogenase β-ketoacyl-CoA • cleavageatthe presence ofCoA • formationof acetyl-CoA • formationof acyl-CoA (twocarbonsshorter) β-ketoacyl-CoA-thiolase acyl-CoA acetyl-CoA

FA degradation Oxidation of unsaturated FA • the most common unsaturated FA in the diet: linoleoyl-CoA cis Δ9, cis-Δ12 oleic acid,linoleic acid 3 rounds of β-oxidation 3 acetyl-CoA • degradation of unsaturated FA • by β-oxidation to a double bond cis-Δ3, cis-Δ6 enoyl-CoA-isomerase • conversion of cis-isomer of FA • by specific isomerase to trans-isomer trans-Δ2, cis-Δ6 β-oxidation 1 acetyl-CoA • continuation of β-oxidation • to the next double bond cis-Δ4 acyl-CoA-dehydrogenase • formation of double bond between C2 and C3 by dehydrogenation trans-Δ2, cis-Δ4 NADPH + H+ • elimination of double bond between C4 and C5 by reduction dienoyl-CoA-reductase NADP+ trans-Δ3 enoyl-CoA-isomerase • intramolecular transfer of double bond trans-Δ2 4 rounds of β-oxidation • continuation of β-oxidation 5 acetyl-CoA

FA degradation Oxidation of odd-chain FA propionyl-CoA • shortening of FA to C5 stopping of β-oxidation HCO3- + ATP propionyl-CoA carboxylase (biotin) ADP + Pi • formation of acetyl-CoA and propionyl-CoA D-methylmalonyl-CoA • carboxylation of propionyl-CoA methylmalonyl-CoA racemase • epimerization of D-form into L-form L-methylmalonyl-CoA • intramolecular rearrangement to form succinyl-CoA methylmalonyl-CoA mutase (B12) • entry of succinyl-CoA into the citric acid cycle succinyl-CoA

FA degradation Peroxisomal oxidation of FA A)very-long-chain FA (VLCFA, > C20) • transport of acyl-CoA into the peroxisome without carnitine Differences between β-oxidation in the mitochondrion and peroxisome: 1. step – dehydrogenation by FAD mitochondrion: electronsfrom FADH2 are delivered to therespiratorychain wherethey are transferred to O2 to form H2O and ATP peroxisome: electrons from FADH2 aredelivered to O2 to form H2O2,which is degraded by catalase to H2O and O2 3. step – dehydrogenation by NAD+ mitochondrion: reoxidation of NADH in the respiratory chain peroxisome: reoxidation of NADH is not possible, export to the cytosol or the mitochondrion

FA degradation Peroxisomal oxidation of FA Differences between β-oxidation in the mitochondrion and peroxisome: 4. step – cleavage at the presence of CoA acetyl-CoA mitochondrion: metabolization in the citric acid cycle peroxisome: export to the cytosol, to the mitochondrion (oxidation) a precursor for the synthesis of cholesterol and bile acids a precursor for the synthesis of fatty acids of phospholipids

FA degradation Peroxisomal oxidation of FA B)long-chain branched-chain FA • blocking of β-oxidation by the alcyl group at Cβ • α-oxidation • hydroxylation at Cα • cleavage of the original carboxyl group as CO2 • methyl group is in the position α • shortening of FA to 8 carbons • transfer of FA in the form of acylcarnitine into the mitochondrion • complete of β-oxidation in the mitochondrion

Refsum's disease • rare autosomal recessive hereditary disease • phytanic acid a product of metabolism of phytol (part of chlorophyll) in milk and animal fats • decreased activity of peroxisomal α-hydroxylase accumulation of phytanic acid (in tissues of nervous system and serum) • ataxia, night blindness, hearing loss, skin changes etc.

FA degradation ω-oxidation of FA • minor pathway of FA oxidation • in the endoplasmatic reticulum • repeated oxidation of ω-carbon -CH3 -CH2OH -COOH • formation of dicarboxylic acid • entry of dicarboxylic acid into β-oxidation • reduction of FA to adipic acid (C6) or suberic acid (C8) excreted in the urine

FA degradation Regulation of β-oxidation A) by energy demands of cell by the level of ATP and NADH: FA can not be oxidized faster than NADH andFADH2 arereoxidized in the respiratory chain B) via carnitine palmitoyl transferase I (CPT I) CPT I is inhibited by malonyl-CoA, which is generated in the synthesis of FA by acetyl-CoA carboxylase (ACC) active FA synthesis inhibition of β-oxidation acetyl-CoA malonyl-CoA CPT I β-oxidation ACC

Comparison of FA biosynthesis and FA degradation

Ketone bodies Ketogenesis • in the liver localization: • mitochondrial matrix substrate: • acetyl-CoA products: • acetone • acetoacetate • D-β-hydroxybutyrate conditions: • in excess of acetyl-CoA function: • energy substrates for extrahepatic tissues

Ketone bodies Ketogenesis

Ketone bodies Ketogenesis acetoacetate • spontaneous decarboxylation to acetone • conversion to D-β-hydroxybutyrate • by D-β-hydroxybutyrate dehydrogenase waste product (lung, urine) energy substrates for extrahepatic tissues

Ketone bodies Utilization of ketone bodies • water-soluble FA equivalents • energy source for extrahepatic tissues (especially heart and skeletal muscle) • in starvation - the main source of energy for the brain energy citric acid cycle production

Ketone bodies Production, utilization and excretion of ketone bodies acetyl-CoA • oxidation in the citric acid cycle (liver) • conversion to ketone bodies (liver - mitochondrion) • release of ketone bodies into blood • transport to tissues

Ketone bodies Ketogenesis increased ketogenesis: lipolysis • starvation • prolonged exercise • diabetes mellitus FA in plasma • high-fat diet • low-carbohydrate diet β-oxidation utilization of ketone bodies as an energy source (skeletal muscle, intestinal mucose, adipocytes, brain, heart etc.) excess of acetyl-CoA to spare of glucose and muscle proteins ketogenesis

Bibliography and sources Devlin, T. M. Textbook of biochemistry: with clinical correlations. 6th edition. Wiley-Liss, 2006. Marks, A.; Lieberman, M. Marks' basic medical biochemistry: a clinical approach. 3rd edition. Lippincott Williams & Wilkins, 2009. Matouš a kol. Základy lékařské chemie a biochemie. Galén, 2010. Meisenberg, G.; Simmons, W. H. Principles of medical biochemistry. 2nd edition. Elsevier, 2006. Murray et al. Harper's Biochemistry. 25th edition. Appleton & Lange, 2000. http://www.hindawi.com/journals/jobes/2011/482021/fig2/

Synthesis and degradation of fatty acids