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Fatty acid metabolism

February 15, 2024

Fatty acid metabolism consists of various metabolic processes involving or closely related to fatty acids, a family of molecules classified within the lipid macronutrient category. These processes can mainly be divided into (1) catabolic processes that generate energy and (2) anabolic processes where they serve as building blocks for other compounds.[1]

In catabolism, fatty acids are metabolized to produce energy, mainly in the form of adenosine triphosphate (ATP). When compared to other macronutrient classes (carbohydrates and protein), fatty acids yield the most ATP on an energy per gram basis, when they are completely oxidized to CO2 and water by beta oxidation and the citric acid cycle.[2] Fatty acids (mainly in the form of triglycerides) are therefore the foremost storage form of fuel in most animals, and to a lesser extent in plants.

In anabolism, intact fatty acids are important precursors to triglycerides, phospholipids, second messengers, hormones and ketone bodies. For example, phospholipids form the phospholipid bilayers out of which all the membranes of the cell are constructed from fatty acids. Phospholipids comprise the plasma membrane and other membranes that enclose all the organelles within the cells, such as the nucleus, the mitochondria, endoplasmic reticulum, and the Golgi apparatus. In another type of anabolism, fatty acids are modified to form other compounds such as second messengers and local hormones. The prostaglandins made from arachidonic acid stored in the cell membrane are probably the best-known of these local hormones.

Fatty acid catabolism edit

 
A diagrammatic illustration of the process of lipolysis (in a fat cell) induced by high epinephrine and low insulin levels in the blood. Epinephrine binds to a beta-adrenergic receptor in the cell membrane of the adipocyte, which causes cAMP to be generated inside the cell. The cAMP activates a protein kinase, which phosphorylates and thus, in turn, activates a hormone-sensitive lipase in the fat cell. This lipase cleaves free fatty acids from their attachment to glycerol in the fat stored in the fat droplet of the adipocyte. The free fatty acids and glycerol are then released into the blood. However more recent studies have shown that adipose triglyceride lipase has to first convert triacylglycerides to diacylglycerides, and that hormone-sensitive lipase converts the diacylglycerides to monoglycerides and free fatty acids. Monoglycerides are hydrolyzed by monoglyceride lipase.[3] The activity of hormone sensitive lipase is regulated by the circulation hormones insulin, glucagon, norepinephrine, and epinephrine, as shown in the diagram.
 
A diagrammatic illustration of the transport of free fatty acids in the blood attached to plasma albumin, its diffusion across the cell membrane using a protein transporter, and its activation, using ATP, to form acyl-CoA in the cytosol. The illustration is, for diagrammatic purposes, of a 12 carbon fatty acid. Most fatty acids in human plasma are 16 or 18 carbon atoms long.
 
A diagrammatic illustration of the transfer of an acyl-CoA molecule across the inner membrane of the mitochondrion by carnitine-acyl-CoA transferase (CAT). The illustrated acyl chain is, for diagrammatic purposes, only 12 carbon atoms long. Most fatty acids in human plasma are 16 or 18 carbon atoms long. CAT is inhibited by high concentrations of malonyl-CoA (the first committed step in fatty acid synthesis) in the cytoplasm. This means that fatty acid synthesis and fatty acid catabolism cannot occur simultaneously in any given cell.
 
A diagrammatic illustration of the process of the beta-oxidation of an acyl-CoA molecule in the mitochondrial matrix. During this process an acyl-CoA molecule which is 2 carbons shorter than it was at the beginning of the process is formed. Acetyl-CoA, water and 5 ATP molecules are the other products of each beta-oxidative event, until the entire acyl-CoA molecule has been reduced to a set of acetyl-CoA molecules.

Fatty acids are stored as triglycerides in the fat depots of adipose tissue. Between meals they are released as follows:

  • Lipolysis, the removal of the fatty acid chains from the glycerol to which they are bound in their storage form as triglycerides (or fats), is carried out by lipases. These lipases are activated by high epinephrine and glucagon levels in the blood (or norepinephrine secreted by sympathetic nerves in adipose tissue), caused by declining blood glucose levels after meals, which simultaneously lowers the insulin level in the blood.[1]
  • Once freed from glycerol, the free fatty acids enter the blood, which transports them, attached to plasma albumin, throughout the body.[4]
  • Long-chain free fatty acids enter metabolizing cells (i.e. most living cells in the body except red blood cells and neurons in the central nervous system) through specific transport proteins, such as the SLC27 family fatty acid transport protein.[5][6] Red blood cells do not contain mitochondria and are therefore incapable of metabolizing fatty acids; the tissues of the central nervous system cannot use fatty acids, despite containing mitochondria, because long-chain fatty acids (as opposed to medium-chain fatty acids[7][8]) cannot cross the blood-brain barrier[9] into the interstitial fluids that bathe these cells.
  • Once inside the cell, long-chain-fatty-acid—CoA ligase catalyzes the reaction between a fatty acid molecule with ATP (which is broken down to AMP and inorganic pyrophosphate) to give a fatty acyl-adenylate, which then reacts with free coenzyme A to give a fatty acyl-CoA molecule.
  • In order for the acyl-CoA to enter the mitochondrion the carnitine shuttle is used:[10][11][12]
  1. Acyl-CoA is transferred to the hydroxyl group of carnitine by carnitine palmitoyltransferase I, located on the cytosolic faces of the outer and inner mitochondrial membranes.
  2. Acyl-carnitine is shuttled inside by a carnitine-acylcarnitine translocase, as a carnitine is shuttled outside.
  3. Acyl-carnitine is converted back to acyl-CoA by carnitine palmitoyltransferase II, located on the interior face of the inner mitochondrial membrane. The liberated carnitine is shuttled back to the cytosol, as an acyl-CoA is shuttled into the mitochondrial matrix.
  • Beta oxidation, in the mitochondrial matrix, then cuts the long carbon chains of the fatty acids (in the form of acyl-CoA molecules) into a series of two-carbon (acetate) units, which, combined with co-enzyme A, form molecules of acetyl CoA, which condense with oxaloacetate to form citrate at the "beginning" of the citric acid cycle.[2] It is convenient to think of this reaction as marking the "starting point" of the cycle, as this is when fuel - acetyl-CoA - is added to the cycle, which will be dissipated as CO2 and H2O with the release of a substantial quantity of energy captured in the form of ATP, during the course of each turn of the cycle and subsequent oxidative phosphorylation.
Briefly, the steps in beta oxidation are as follows:[2]
  1. Dehydrogenation by acyl-CoA dehydrogenase, yielding 1 FADH2
  2. Hydration by enoyl-CoA hydratase
  3. Dehydrogenation by 3-hydroxyacyl-CoA dehydrogenase, yielding 1 NADH + H+
  4. Cleavage by thiolase, yielding 1 acetyl-CoA and a fatty acid that has now been shortened by 2 carbons (forming a new, shortened acyl-CoA)
This beta oxidation reaction is repeated until the fatty acid has been completely reduced to acetyl-CoA or, in, the case of fatty acids with odd numbers of carbon atoms, acetyl-CoA and 1 molecule of propionyl-CoA per molecule of fatty acid. Each beta oxidative cut of the acyl-CoA molecule eventually yields 5 ATP molecules in oxidative phosphorylation.[13][14]
  • The acetyl-CoA produced by beta oxidation enters the citric acid cycle in the mitochondrion by combining with oxaloacetate to form citrate. Coupled to oxidative phosphorylation this results in the complete combustion of the acetyl-CoA to CO2 and water. The energy released in this process is captured in the form of 1 GTP and 11 ATP molecules per acetyl-CoA molecule oxidized.[2][10] This is the fate of acetyl-CoA wherever beta oxidation of fatty acids occurs, except under certain circumstances in the liver.
The propionyl-CoA is later converted into succinyl-CoA through biotin-dependant propionyl-CoA carboxylase (PCC) and Vitamin B12-dependant methylmalonyl-CoA mutase (MCM), sequentially.[15][16] Succinyl-CoA is first converted to malate, and then to pyruvate where it is then transported to the matrix to enter the citric acid cycle.

In the liver oxaloacetate can be wholly or partially diverted into the gluconeogenic pathway during fasting, starvation, a low carbohydrate diet, prolonged strenuous exercise, and in uncontrolled type 1 diabetes mellitus. Under these circumstances, oxaloacetate is hydrogenated to malate, which is then removed from the mitochondria of the liver cells to be converted into glucose in the cytoplasm of the liver cells, from where it is released into the blood.[10] In the liver, therefore, oxaloacetate is unavailable for condensation with acetyl-CoA when significant gluconeogenesis has been stimulated by low (or absent) insulin and high glucagon concentrations in the blood. Under these conditions, acetyl-CoA is diverted to the formation of acetoacetate and beta-hydroxybutyrate.[10] Acetoacetate, beta-hydroxybutyrate, and their spontaneous breakdown product, acetone, are frequently, but confusingly, known as ketone bodies (as they are not "bodies" at all, but water-soluble chemical substances). The ketones are released by the liver into the blood. All cells with mitochondria can take up ketones from the blood and reconvert them into acetyl-CoA, which can then be used as fuel in their citric acid cycles, as no other tissue can divert its oxaloacetate into the gluconeogenic pathway in the way that this can occur in the liver. Unlike free fatty acids, ketones can cross the blood–brain barrier and are therefore available as fuel for the cells of the central nervous system, acting as a substitute for glucose, on which these cells normally survive.[10] The occurrence of high levels of ketones in the blood during starvation, a low carbohydrate diet, prolonged heavy exercise, or uncontrolled type 1 diabetes mellitus is known as ketosis, and, in its extreme form, in out-of-control type 1 diabetes mellitus, as ketoacidosis.

The glycerol released by lipase action is phosphorylated by glycerol kinase in the liver (the only tissue in which this reaction can occur), and the resulting glycerol 3-phosphate is oxidized to dihydroxyacetone phosphate. The glycolytic enzyme triose phosphate isomerase converts this compound to glyceraldehyde 3-phosphate, which is oxidized via glycolysis, or converted to glucose via gluconeogenesis.

Fatty acids as an energy source edit

 
Example of an unsaturated fat triglyceride. Left part: glycerol, right part from top to bottom: palmitic acid, oleic acid, alpha-linolenic acid. Chemical formula: C55H98O6

Fatty acids, stored as triglycerides in an organism, are a concentrated source of energy because they contain little oxygen and are anhydrous. The energy yield from a gram of fatty acids is approximately 9 kcal (37 kJ), much higher than the 4 kcal (17 kJ) for carbohydrates. Since the hydrocarbon portion of fatty acids is hydrophobic, these molecules can be stored in a relatively anhydrous (water-free) environment. Carbohydrates, on the other hand, are more highly hydrated. For example, 1 g of glycogen binds approximately 2 g of water, which translates to 1.33 kcal/g (4 kcal/3 g). This means that fatty acids can hold more than six times the amount of energy per unit of stored mass. Put another way, if the human body relied on carbohydrates to store energy, then a person would need to carry 31 kg (67.5 lb) of hydrated glycogen to have the energy equivalent to 4.6 kg (10 lb) of fat.[10]

Hibernating animals provide a good example for utilization of fat reserves as fuel. For example, bears hibernate for about 7 months, and during this entire period, the energy is derived from degradation of fat stores. Migrating birds similarly build up large fat reserves before embarking on their intercontinental journeys.[17]

The fat stores of young adult humans average between about 10–20 kg, but vary greatly depending on gender and individual disposition.[18] By contrast, the human body stores only about 400 g of glycogen, of which 300 g is locked inside the skeletal muscles and is unavailable to the body as a whole. The 100 g or so of glycogen stored in the liver is depleted within one day of starvation.[10] Thereafter the glucose that is released into the blood by the liver for general use by the body tissues has to be synthesized from the glucogenic amino acids and a few other gluconeogenic substrates, which do not include fatty acids.[1] Nonetheless, lipolysis releases glycerol which can enter the pathway of gluconeogenesis.

Carbohydrate synthesis from glycerol and fatty acids edit

Fatty acids are broken down to acetyl-CoA by means of beta oxidation inside the mitochondria, whereas fatty acids are synthesized from acetyl-CoA outside the mitochondria, in the cytosol. The two pathways are distinct, not only in where they occur, but also in the reactions that occur, and the substrates that are used. The two pathways are mutually inhibitory, preventing the acetyl-CoA produced by beta-oxidation from entering the synthetic pathway via the acetyl-CoA carboxylase reaction.[1] It can also not be converted to pyruvate as the pyruvate dehydrogenase complex reaction is irreversible.[10] Instead the acetyl-CoA produced by the beta-oxidation of fatty acids condenses with oxaloacetate, to enter the citric acid cycle. During each turn of the cycle, two carbon atoms leave the cycle as CO2 in the decarboxylation reactions catalyzed by isocitrate dehydrogenase and alpha-ketoglutarate dehydrogenase. Thus each turn of the citric acid cycle oxidizes an acetyl-CoA unit while regenerating the oxaloacetate molecule with which the acetyl-CoA had originally combined to form citric acid. The decarboxylation reactions occur before malate is formed in the cycle.[1] Only plants possess the enzymes to convert acetyl-CoA into oxaloacetate from which malate can be formed to ultimately be converted to glucose.[1]

However, acetyl-CoA can be converted to acetoacetate, which can decarboxylate to acetone (either spontaneously, or catalyzed by acetoacetate decarboxylase). It can then be further metabolized to isopropanol which is excreted in breath/urine, or by CYP2E1 into hydroxyacetone (acetol). Acetol can be converted to propylene glycol. This converts to pyruvate (by two alternative enzymes), or propionaldehyde, or to L-lactaldehyde then L-lactate (the common lactate isomer).[19][20][21] Another pathway turns acetol to methylglyoxal, then to pyruvate, or to D-lactaldehyde (via S-D-lactoyl-glutathione or otherwise) then D-lactate.[20][22][23] D-lactate metabolism (to glucose) is slow or impaired in humans, so most of the D-lactate is excreted in the urine; thus D-lactate derived from acetone can contribute significantly to the metabolic acidosis associated with ketosis or isopropanol intoxication.[20] L-Lactate can complete the net conversion of fatty acids into glucose. The first experiment to show conversion of acetone to glucose was carried out in 1951. This, and further experiments used carbon isotopic labelling.[21] Up to 11% of the glucose can be derived from acetone during starvation in humans.[21]

The glycerol released into the blood during the lipolysis of triglycerides in adipose tissue can only be taken up by the liver. Here it is converted into glycerol 3-phosphate by the action of glycerol kinase which hydrolyzes one molecule of ATP per glycerol molecule which is phosphorylated. Glycerol 3-phosphate is then oxidized to dihydroxyacetone phosphate, which is, in turn, converted into glyceraldehyde 3-phosphate by the enzyme triose phosphate isomerase. From here the three carbon atoms of the original glycerol can be oxidized via glycolysis, or converted to glucose via gluconeogenesis.[10]

Other functions and uses of fatty acids edit

Intracellular signaling edit

 
Chemical structure of the diglyceride 1-palmitoyl-2-oleoyl-glycerol

Fatty acids are an integral part of the phospholipids that make up the bulk of the plasma membranes, or cell membranes, of cells. These phospholipids can be cleaved into diacylglycerol (DAG) and inositol trisphosphate (IP3) through hydrolysis of the phospholipid, phosphatidylinositol 4,5-bisphosphate (PIP2), by the cell membrane bound enzyme phospholipase C (PLC).[24]

Eicosanoid paracrine hormones edit

 
Arachidonic acid
 
Prostaglandin E1 - Alprostadil

One product of fatty acid metabolism are the prostaglandins, compounds having diverse hormone-like effects in animals. Prostaglandins have been found in almost every tissue in humans and other animals. They are enzymatically derived from arachidonic acid, a 20-carbon polyunsaturated fatty acid. Every prostaglandin therefore contains 20 carbon atoms, including a 5-carbon ring. They are a subclass of eicosanoids and form the prostanoid class of fatty acid derivatives.[25]

The prostaglandins are synthesized in the cell membrane by the cleavage of arachidonate from the phospholipids that make up the membrane. This is catalyzed either by phospholipase A2 acting directly on a membrane phospholipid, or by a lipase acting on DAG (diacyl-glycerol). The arachidonate is then acted upon by the cyclooxygenase component of prostaglandin synthase. This forms a cyclopentane ring roughly in the middle of the fatty acid chain. The reaction also adds 4 oxygen atoms derived from two molecules of O2. The resulting molecule is prostaglandin G2, which is converted by the hydroperoxidase component of the enzyme complex into prostaglandin H2. This highly unstable compound is rapidly transformed into other prostaglandins, prostacyclin and thromboxanes.[25] These are then released into the interstitial fluids surrounding the cells that have manufactured the eicosanoid hormone.

If arachidonate is acted upon by a lipoxygenase instead of cyclooxygenase, Hydroxyeicosatetraenoic acids and leukotrienes are formed. They also act as local hormones.

Prostaglandins have two derivatives: prostacyclins and thromboxanes. Prostacyclins are powerful locally acting vasodilators and inhibit the aggregation of blood platelets. Through their role in vasodilation, prostacyclins are also involved in inflammation. They are synthesized in the walls of blood vessels and serve the physiological function of preventing needless clot formation, as well as regulating the contraction of smooth muscle tissue.[26] Conversely, thromboxanes (produced by platelet cells) are vasoconstrictors and facilitate platelet aggregation. Their name comes from their role in clot formation (thrombosis).

Dietary sources of fatty acids, their digestion, absorption, transport in the blood and storage edit

 
Dietary fats are emulsified in the duodenum by soaps in the form of bile salts and phospholipids, such as phosphatidylcholine. The fat droplets thus formed can be attacked by pancreatic lipase.
 
Structure of a bile acid (cholic acid), represented in the standard form, a semi-realistic 3D form, and a diagrammatic 3D form
 
Diagrammatic illustration of mixed micelles formed in the duodenum in the presence of bile acids (e.g. cholic acid) and the digestion products of fats, the fat soluble vitamins and cholesterol.

A significant proportion of the fatty acids in the body are obtained from the diet, in the form of triglycerides of either animal or plant origin. The fatty acids in the fats obtained from land animals tend to be saturated, whereas the fatty acids in the triglycerides of fish and plants are often polyunsaturated and therefore present as oils.

These triglycerides cannot be absorbed by the intestine.[27] They are broken down into mono- and di-glycerides plus free fatty acids (but no free glycerol) by pancreatic lipase, which forms a 1:1 complex with a protein called colipase (also a constituent of pancreatic juice), which is necessary for its activity. The activated complex can work only at a water-fat interface. Therefore, it is essential that fats are first emulsified by bile salts for optimal activity of these enzymes.[28] The digestion products consisting of a mixture of tri-, di- and monoglycerides and free fatty acids, which, together with the other fat soluble contents of the diet (e.g. the fat soluble vitamins and cholesterol) and bile salts form mixed micelles, in the watery duodenal contents (see diagrams on the right).[27][29]

The contents of these micelles (but not the bile salts) enter the enterocytes (epithelial cells lining the small intestine) where they are resynthesized into triglycerides, and packaged into chylomicrons which are released into the lacteals (the capillaries of the lymph system of the intestines).[30] These lacteals drain into the thoracic duct which empties into the venous blood at the junction of the left jugular and left subclavian veins on the lower left hand side of the neck. This means that the fat-soluble products of digestion are discharged directly into the general circulation, without first passing through the liver, unlike all other digestion products. The reason for this peculiarity is unknown.[31]

 
A schematic diagram of a chylomicron.

The chylomicrons circulate throughout the body, giving the blood plasma a milky or creamy appearance after a fatty meal.[citation needed] Lipoprotein lipase on the endothelial surfaces of the capillaries, especially in adipose tissue, but to a lesser extent also in other tissues, partially digests the chylomicrons into free fatty acids, glycerol and chylomicron remnants. The fatty acids are absorbed by the adipocytes[citation needed], but the glycerol and chylomicron remnants remain in the blood plasma, ultimately to be removed from the circulation by the liver. The free fatty acids released by the digestion of the chylomicrons are absorbed by the adipocytes[citation needed], where they are resynthesized into triglycerides using glycerol derived from glucose in the glycolytic pathway[citation needed]. These triglycerides are stored, until needed for the fuel requirements of other tissues, in the fat droplet of the adipocyte.

The liver absorbs a proportion of the glucose from the blood in the portal vein coming from the intestines. After the liver has replenished its glycogen stores (which amount to only about 100 g of glycogen when full) much of the rest of the glucose is converted into fatty acids as described below. These fatty acids are combined with glycerol to form triglycerides which are packaged into droplets very similar to chylomicrons, but known as very low-density lipoproteins (VLDL). These VLDL droplets are processed in exactly the same manner as chylomicrons, except that the VLDL remnant is known as an intermediate-density lipoprotein (IDL), which is capable of scavenging cholesterol from the blood. This converts IDL into low-density lipoprotein (LDL), which is taken up by cells that require cholesterol for incorporation into their cell membranes or for synthetic purposes (e.g. the formation of the steroid hormones). The remainder of the LDLs is removed by the liver.[32]

Adipose tissue and lactating mammary glands also take up glucose from the blood for conversion into triglycerides. This occurs in the same way as in the liver, except that these tissues do not release the triglycerides thus produced as VLDL into the blood. Adipose tissue cells store the triglycerides in their fat droplets, ultimately to release them again as free fatty acids and glycerol into the blood (as described above), when the plasma concentration of insulin is low, and that of glucagon and/or epinephrine is high.[33] Mammary glands discharge the fat (as cream fat droplets) into the milk that they produce under the influence of the anterior pituitary hormone prolactin.

All cells in the body need to manufacture and maintain their membranes and the membranes of their organelles. Whether they rely entirely on free fatty acids absorbed from the blood, or are able to synthesize their own fatty acids from blood glucose, is not known. The cells of the central nervous system will almost certainly have the capability of manufacturing their own fatty acids, as these molecules cannot reach them through the blood brain barrier.[34] However, it is unknown how they are reached by the essential fatty acids, which mammals cannot synthesize themselves but are nevertheless important components of cell membranes (and other functions described above).

Fatty acid synthesis edit

Main article: Fatty acid synthesis
 
Synthesis of saturated fatty acids via Fatty Acid Synthase II in E. coli

Much like beta-oxidation, straight-chain fatty acid synthesis occurs via the six recurring reactions shown below, until the 16-carbon palmitic acid is produced.[35][36]

The diagrams presented show how fatty acids are synthesized in microorganisms and list the enzymes found in Escherichia coli.[35] These reactions are performed by fatty acid synthase II (FASII), which in general contains multiple enzymes that act as one complex. FASII is present in prokaryotes, plants, fungi, and parasites, as well as in mitochondria.[37]

In animals as well as some fungi such as yeast, these same reactions occur on fatty acid synthase I (FASI), a large dimeric protein that has all of the enzymatic activities required to create a fatty acid. FASI is less efficient than FASII; however, it allows for the formation of more molecules, including "medium-chain" fatty acids via early chain termination.[37] Enzymes, acyltransferases and transacylases, incorporate fatty acids in phospholipids, triacylglycerols, etc. by transferring fatty acids between an acyl acceptor and donor. They also have the task of synthesizing bioactive lipids as well as their precursor molecules.[38]

Once a 16:0 carbon fatty acid has been formed, it can undergo a number of modifications, resulting in desaturation and/or elongation. Elongation, starting with stearate (18:0), is performed mainly in the endoplasmic reticulum by several membrane-bound enzymes. The enzymatic steps involved in the elongation process are principally the same as those carried out by fatty acid synthesis, but the four principal successive steps of the elongation are performed by individual proteins, which may be physically associated.[39][40]

Step Enzyme Reaction Description
(a) Acetyl CoA:ACP transacylase
 
 Activates acetyl CoA for reaction with malonyl-ACP
(b) Malonyl CoA:ACP transacylase   Activates malonyl CoA for reaction with acetyl-ACP
(c) 3-ketoacyl-ACP synthase
 
 Reacts ACP-bound acyl chain with chain-extending malonyl-ACP
(d) 3-ketoacyl-ACP reductase
 
 Reduces the carbon 3 ketone to a hydroxyl group
(e) 3-Hydroxyacyl ACP dehydrase
 
 Eliminates water
(f) Enoyl-ACP reductase
 
 Reduces the C2-C3 double bond.

Abbreviations: ACP – Acyl carrier protein, CoA – Coenzyme A, NADP – Nicotinamide adenine dinucleotide phosphate.

Note that during fatty synthesis the reducing agent is NADPH, whereas NAD is the oxidizing agent in beta-oxidation (the breakdown of fatty acids to acetyl-CoA). This difference exemplifies a general principle that NADPH is consumed during biosynthetic reactions, whereas NADH is generated in energy-yielding reactions.[34] (Thus NADPH is also required for the synthesis of cholesterol from acetyl-CoA; while NADH is generated during glycolysis.) The source of the NADPH is two-fold. When malate is oxidatively decarboxylated by “NADP+-linked malic enzyme" pyruvate, CO2 and NADPH are formed. NADPH is also formed by the pentose phosphate pathway which converts glucose into ribose, which can be used in synthesis of nucleotides and nucleic acids, or it can be catabolized to pyruvate.[34]

Glycolytic end products are used in the conversion of carbohydrates into fatty acids edit

Main article: Citric acid cycle § Glycolytic end products are used in the conversion of carbohydrates into fatty acids

In humans, fatty acids are formed from carbohydrates predominantly in the liver and adipose tissue, as well as in the mammary glands during lactation. The pyruvate produced by glycolysis is an important intermediary in the conversion of carbohydrates into fatty acids and cholesterol.[34] This occurs via the conversion of pyruvate into acetyl-CoA in the mitochondrion. However, this acetyl CoA needs to be transported into cytosol where the synthesis of fatty acids and cholesterol occurs. This cannot occur directly. To obtain cytosolic acetyl-CoA, citrate (produced by the condensation of acetyl CoA with oxaloacetate) is removed from the citric acid cycle and carried across the inner mitochondrial membrane into the cytosol.[34] There it is cleaved by ATP citrate lyase into acetyl-CoA and oxaloacetate. The oxaloacetate is returned to mitochondrion as malate (and then converted back into oxaloacetate to transfer more acetyl-CoA out of the mitochondrion).[41] The cytosolic acetyl-CoA is carboxylated by acetyl CoA carboxylase into malonyl CoA, the first committed step in the synthesis of fatty acids.[41][42]

Regulation of fatty acid synthesis edit

Acetyl-CoA is formed into malonyl-CoA by acetyl-CoA carboxylase, at which point malonyl-CoA is destined to feed into the fatty acid synthesis pathway. Acetyl-CoA carboxylase is the point of regulation in saturated straight-chain fatty acid synthesis, and is subject to both phosphorylation and allosteric regulation. Regulation by phosphorylation occurs mostly in mammals, while allosteric regulation occurs in most organisms. Allosteric control occurs as feedback inhibition by palmitoyl-CoA and activation by citrate. When there are high levels of palmitoyl-CoA, the final product of saturated fatty acid synthesis, it allosterically inactivates acetyl-CoA carboxylase to prevent a build-up of fatty acids in cells. Citrate acts to activate acetyl-CoA carboxylase under high levels, because high levels indicate that there is enough acetyl-CoA to feed into the Krebs cycle and produce energy.[43]

High plasma levels of insulin in the blood plasma (e.g. after meals) cause the dephosphorylation and activation of acetyl-CoA carboxylase, thus promoting the formation of malonyl-CoA from acetyl-CoA, and consequently the conversion of carbohydrates into fatty acids, while epinephrine and glucagon (released into the blood during starvation and exercise) cause the phosphorylation of this enzyme, inhibiting lipogenesis in favor of fatty acid oxidation via beta-oxidation.[34][42]

Disorders edit

Disorders of fatty acid metabolism can be described in terms of, for example, hypertriglyceridemia (too high level of triglycerides), or other types of hyperlipidemia. These may be familial or acquired.

Familial types of disorders of fatty acid metabolism are generally classified as inborn errors of lipid metabolism. These disorders may be described as fatty acid oxidation disorders or as a lipid storage disorders, and are any one of several inborn errors of metabolism that result from enzyme or transport protein defects affecting the ability of the body to oxidize fatty acids in order to produce energy within muscles, liver, and other cell types. When a fatty acid oxidation disorder affects the muscles, it is a metabolic myopathy.

Moreover, cancer cells can display irregular fatty acid metabolism with regard to both fatty acid synthesis[44] and mitochondrial fatty acid oxidation (FAO)[45] that are involved in diverse aspects of tumorigenesis and cell growth.

References edit

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  14. ^ Oxidation of unsaturated fatty acids
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February 15, 2024
fatty, acid, metabolism, consists, various, metabolic, processes, involving, closely, related, fatty, acids, family, molecules, classified, within, lipid, macronutrient, category, these, processes, mainly, divided, into, catabolic, processes, that, generate, e. Fatty acid metabolism consists of various metabolic processes involving or closely related to fatty acids a family of molecules classified within the lipid macronutrient category These processes can mainly be divided into 1 catabolic processes that generate energy and 2 anabolic processes where they serve as building blocks for other compounds 1 In catabolism fatty acids are metabolized to produce energy mainly in the form of adenosine triphosphate ATP When compared to other macronutrient classes carbohydrates and protein fatty acids yield the most ATP on an energy per gram basis when they are completely oxidized to CO2 and water by beta oxidation and the citric acid cycle 2 Fatty acids mainly in the form of triglycerides are therefore the foremost storage form of fuel in most animals and to a lesser extent in plants In anabolism intact fatty acids are important precursors to triglycerides phospholipids second messengers hormones and ketone bodies For example phospholipids form the phospholipid bilayers out of which all the membranes of the cell are constructed from fatty acids Phospholipids comprise the plasma membrane and other membranes that enclose all the organelles within the cells such as the nucleus the mitochondria endoplasmic reticulum and the Golgi apparatus In another type of anabolism fatty acids are modified to form other compounds such as second messengers and local hormones The prostaglandins made from arachidonic acid stored in the cell membrane are probably the best known of these local hormones Contents 1 Fatty acid catabolism 1 1 Fatty acids as an energy source 1 2 Carbohydrate synthesis from glycerol and fatty acids 2 Other functions and uses of fatty acids 2 1 Intracellular signaling 2 2 Eicosanoid paracrine hormones 3 Dietary sources of fatty acids their digestion absorption transport in the blood and storage 4 Fatty acid synthesis 4 1 Glycolytic end products are used in the conversion of carbohydrates into fatty acids 4 2 Regulation of fatty acid synthesis 5 Disorders 6 ReferencesFatty acid catabolism edit nbsp A diagrammatic illustration of the process of lipolysis in a fat cell induced by high epinephrine and low insulin levels in the blood Epinephrine binds to a beta adrenergic receptor in the cell membrane of the adipocyte which causes cAMP to be generated inside the cell The cAMP activates a protein kinase which phosphorylates and thus in turn activates a hormone sensitive lipase in the fat cell This lipase cleaves free fatty acids from their attachment to glycerol in the fat stored in the fat droplet of the adipocyte The free fatty acids and glycerol are then released into the blood However more recent studies have shown that adipose triglyceride lipase has to first convert triacylglycerides to diacylglycerides and that hormone sensitive lipase converts the diacylglycerides to monoglycerides and free fatty acids Monoglycerides are hydrolyzed by monoglyceride lipase 3 The activity of hormone sensitive lipase is regulated by the circulation hormones insulin glucagon norepinephrine and epinephrine as shown in the diagram nbsp A diagrammatic illustration of the transport of free fatty acids in the blood attached to plasma albumin its diffusion across the cell membrane using a protein transporter and its activation using ATP to form acyl CoA in the cytosol The illustration is for diagrammatic purposes of a 12 carbon fatty acid Most fatty acids in human plasma are 16 or 18 carbon atoms long nbsp A diagrammatic illustration of the transfer of an acyl CoA molecule across the inner membrane of the mitochondrion by carnitine acyl CoA transferase CAT The illustrated acyl chain is for diagrammatic purposes only 12 carbon atoms long Most fatty acids in human plasma are 16 or 18 carbon atoms long CAT is inhibited by high concentrations of malonyl CoA the first committed step in fatty acid synthesis in the cytoplasm This means that fatty acid synthesis and fatty acid catabolism cannot occur simultaneously in any given cell nbsp A diagrammatic illustration of the process of the beta oxidation of an acyl CoA molecule in the mitochondrial matrix During this process an acyl CoA molecule which is 2 carbons shorter than it was at the beginning of the process is formed Acetyl CoA water and 5 ATP molecules are the other products of each beta oxidative event until the entire acyl CoA molecule has been reduced to a set of acetyl CoA molecules Fatty acids are stored as triglycerides in the fat depots of adipose tissue Between meals they are released as follows Lipolysis the removal of the fatty acid chains from the glycerol to which they are bound in their storage form as triglycerides or fats is carried out by lipases These lipases are activated by high epinephrine and glucagon levels in the blood or norepinephrine secreted by sympathetic nerves in adipose tissue caused by declining blood glucose levels after meals which simultaneously lowers the insulin level in the blood 1 Once freed from glycerol the free fatty acids enter the blood which transports them attached to plasma albumin throughout the body 4 Long chain free fatty acids enter metabolizing cells i e most living cells in the body except red blood cells and neurons in the central nervous system through specific transport proteins such as the SLC27 family fatty acid transport protein 5 6 Red blood cells do not contain mitochondria and are therefore incapable of metabolizing fatty acids the tissues of the central nervous system cannot use fatty acids despite containing mitochondria because long chain fatty acids as opposed to medium chain fatty acids 7 8 cannot cross the blood brain barrier 9 into the interstitial fluids that bathe these cells Once inside the cell long chain fatty acid CoA ligase catalyzes the reaction between a fatty acid molecule with ATP which is broken down to AMP and inorganic pyrophosphate to give a fatty acyl adenylate which then reacts with free coenzyme A to give a fatty acyl CoA molecule In order for the acyl CoA to enter the mitochondrion the carnitine shuttle is used 10 11 12 Acyl CoA is transferred to the hydroxyl group of carnitine by carnitine palmitoyltransferase I located on the cytosolic faces of the outer and inner mitochondrial membranes Acyl carnitine is shuttled inside by a carnitine acylcarnitine translocase as a carnitine is shuttled outside Acyl carnitine is converted back to acyl CoA by carnitine palmitoyltransferase II located on the interior face of the inner mitochondrial membrane The liberated carnitine is shuttled back to the cytosol as an acyl CoA is shuttled into the mitochondrial matrix Beta oxidation in the mitochondrial matrix then cuts the long carbon chains of the fatty acids in the form of acyl CoA molecules into a series of two carbon acetate units which combined with co enzyme A form molecules of acetyl CoA which condense with oxaloacetate to form citrate at the beginning of the citric acid cycle 2 It is convenient to think of this reaction as marking the starting point of the cycle as this is when fuel acetyl CoA is added to the cycle which will be dissipated as CO2 and H2O with the release of a substantial quantity of energy captured in the form of ATP during the course of each turn of the cycle and subsequent oxidative phosphorylation Briefly the steps in beta oxidation are as follows 2 Dehydrogenation by acyl CoA dehydrogenase yielding 1 FADH2 Hydration by enoyl CoA hydratase Dehydrogenation by 3 hydroxyacyl CoA dehydrogenase yielding 1 NADH H Cleavage by thiolase yielding 1 acetyl CoA and a fatty acid that has now been shortened by 2 carbons forming a new shortened acyl CoA This beta oxidation reaction is repeated until the fatty acid has been completely reduced to acetyl CoA or in the case of fatty acids with odd numbers of carbon atoms acetyl CoA and 1 molecule of propionyl CoA per molecule of fatty acid Each beta oxidative cut of the acyl CoA molecule eventually yields 5 ATP molecules in oxidative phosphorylation 13 14 The acetyl CoA produced by beta oxidation enters the citric acid cycle in the mitochondrion by combining with oxaloacetate to form citrate Coupled to oxidative phosphorylation this results in the complete combustion of the acetyl CoA to CO2 and water The energy released in this process is captured in the form of 1 GTP and 11 ATP molecules per acetyl CoA molecule oxidized 2 10 This is the fate of acetyl CoA wherever beta oxidation of fatty acids occurs except under certain circumstances in the liver The propionyl CoA is later converted into succinyl CoA through biotin dependant propionyl CoA carboxylase PCC and Vitamin B12 dependant methylmalonyl CoA mutase MCM sequentially 15 16 Succinyl CoA is first converted to malate and then to pyruvate where it is then transported to the matrix to enter the citric acid cycle In the liver oxaloacetate can be wholly or partially diverted into the gluconeogenic pathway during fasting starvation a low carbohydrate diet prolonged strenuous exercise and in uncontrolled type 1 diabetes mellitus Under these circumstances oxaloacetate is hydrogenated to malate which is then removed from the mitochondria of the liver cells to be converted into glucose in the cytoplasm of the liver cells from where it is released into the blood 10 In the liver therefore oxaloacetate is unavailable for condensation with acetyl CoA when significant gluconeogenesis has been stimulated by low or absent insulin and high glucagon concentrations in the blood Under these conditions acetyl CoA is diverted to the formation of acetoacetate and beta hydroxybutyrate 10 Acetoacetate beta hydroxybutyrate and their spontaneous breakdown product acetone are frequently but confusingly known as ketone bodies as they are not bodies at all but water soluble chemical substances The ketones are released by the liver into the blood All cells with mitochondria can take up ketones from the blood and reconvert them into acetyl CoA which can then be used as fuel in their citric acid cycles as no other tissue can divert its oxaloacetate into the gluconeogenic pathway in the way that this can occur in the liver Unlike free fatty acids ketones can cross the blood brain barrier and are therefore available as fuel for the cells of the central nervous system acting as a substitute for glucose on which these cells normally survive 10 The occurrence of high levels of ketones in the blood during starvation a low carbohydrate diet prolonged heavy exercise or uncontrolled type 1 diabetes mellitus is known as ketosis and in its extreme form in out of control type 1 diabetes mellitus as ketoacidosis The glycerol released by lipase action is phosphorylated by glycerol kinase in the liver the only tissue in which this reaction can occur and the resulting glycerol 3 phosphate is oxidized to dihydroxyacetone phosphate The glycolytic enzyme triose phosphate isomerase converts this compound to glyceraldehyde 3 phosphate which is oxidized via glycolysis or converted to glucose via gluconeogenesis Fatty acids as an energy source edit nbsp Example of an unsaturated fat triglyceride Left part glycerol right part from top to bottom palmitic acid oleic acid alpha linolenic acid Chemical formula C55H98O6Fatty acids stored as triglycerides in an organism are a concentrated source of energy because they contain little oxygen and are anhydrous The energy yield from a gram of fatty acids is approximately 9 kcal 37 kJ much higher than the 4 kcal 17 kJ for carbohydrates Since the hydrocarbon portion of fatty acids is hydrophobic these molecules can be stored in a relatively anhydrous water free environment Carbohydrates on the other hand are more highly hydrated For example 1 g of glycogen binds approximately 2 g of water which translates to 1 33 kcal g 4 kcal 3 g This means that fatty acids can hold more than six times the amount of energy per unit of stored mass Put another way if the human body relied on carbohydrates to store energy then a person would need to carry 31 kg 67 5 lb of hydrated glycogen to have the energy equivalent to 4 6 kg 10 lb of fat 10 Hibernating animals provide a good example for utilization of fat reserves as fuel For example bears hibernate for about 7 months and during this entire period the energy is derived from degradation of fat stores Migrating birds similarly build up large fat reserves before embarking on their intercontinental journeys 17 The fat stores of young adult humans average between about 10 20 kg but vary greatly depending on gender and individual disposition 18 By contrast the human body stores only about 400 g of glycogen of which 300 g is locked inside the skeletal muscles and is unavailable to the body as a whole The 100 g or so of glycogen stored in the liver is depleted within one day of starvation 10 Thereafter the glucose that is released into the blood by the liver for general use by the body tissues has to be synthesized from the glucogenic amino acids and a few other gluconeogenic substrates which do not include fatty acids 1 Nonetheless lipolysis releases glycerol which can enter the pathway of gluconeogenesis Carbohydrate synthesis from glycerol and fatty acids edit Fatty acids are broken down to acetyl CoA by means of beta oxidation inside the mitochondria whereas fatty acids are synthesized from acetyl CoA outside the mitochondria in the cytosol The two pathways are distinct not only in where they occur but also in the reactions that occur and the substrates that are used The two pathways are mutually inhibitory preventing the acetyl CoA produced by beta oxidation from entering the synthetic pathway via the acetyl CoA carboxylase reaction 1 It can also not be converted to pyruvate as the pyruvate dehydrogenase complex reaction is irreversible 10 Instead the acetyl CoA produced by the beta oxidation of fatty acids condenses with oxaloacetate to enter the citric acid cycle During each turn of the cycle two carbon atoms leave the cycle as CO2 in the decarboxylation reactions catalyzed by isocitrate dehydrogenase and alpha ketoglutarate dehydrogenase Thus each turn of the citric acid cycle oxidizes an acetyl CoA unit while regenerating the oxaloacetate molecule with which the acetyl CoA had originally combined to form citric acid The decarboxylation reactions occur before malate is formed in the cycle 1 Only plants possess the enzymes to convert acetyl CoA into oxaloacetate from which malate can be formed to ultimately be converted to glucose 1 However acetyl CoA can be converted to acetoacetate which can decarboxylate to acetone either spontaneously or catalyzed by acetoacetate decarboxylase It can then be further metabolized to isopropanol which is excreted in breath urine or by CYP2E1 into hydroxyacetone acetol Acetol can be converted to propylene glycol This converts to pyruvate by two alternative enzymes or propionaldehyde or to L lactaldehyde then L lactate the common lactate isomer 19 20 21 Another pathway turns acetol to methylglyoxal then to pyruvate or to D lactaldehyde via S D lactoyl glutathione or otherwise then D lactate 20 22 23 D lactate metabolism to glucose is slow or impaired in humans so most of the D lactate is excreted in the urine thus D lactate derived from acetone can contribute significantly to the metabolic acidosis associated with ketosis or isopropanol intoxication 20 L Lactate can complete the net conversion of fatty acids into glucose The first experiment to show conversion of acetone to glucose was carried out in 1951 This and further experiments used carbon isotopic labelling 21 Up to 11 of the glucose can be derived from acetone during starvation in humans 21 The glycerol released into the blood during the lipolysis of triglycerides in adipose tissue can only be taken up by the liver Here it is converted into glycerol 3 phosphate by the action of glycerol kinase which hydrolyzes one molecule of ATP per glycerol molecule which is phosphorylated Glycerol 3 phosphate is then oxidized to dihydroxyacetone phosphate which is in turn converted into glyceraldehyde 3 phosphate by the enzyme triose phosphate isomerase From here the three carbon atoms of the original glycerol can be oxidized via glycolysis or converted to glucose via gluconeogenesis 10 Other functions and uses of fatty acids editIntracellular signaling edit nbsp Chemical structure of the diglyceride 1 palmitoyl 2 oleoyl glycerolFatty acids are an integral part of the phospholipids that make up the bulk of the plasma membranes or cell membranes of cells These phospholipids can be cleaved into diacylglycerol DAG and inositol trisphosphate IP3 through hydrolysis of the phospholipid phosphatidylinositol 4 5 bisphosphate PIP2 by the cell membrane bound enzyme phospholipase C PLC 24 Eicosanoid paracrine hormones edit nbsp Arachidonic acid nbsp Prostaglandin E1 AlprostadilOne product of fatty acid metabolism are the prostaglandins compounds having diverse hormone like effects in animals Prostaglandins have been found in almost every tissue in humans and other animals They are enzymatically derived from arachidonic acid a 20 carbon polyunsaturated fatty acid Every prostaglandin therefore contains 20 carbon atoms including a 5 carbon ring They are a subclass of eicosanoids and form the prostanoid class of fatty acid derivatives 25 The prostaglandins are synthesized in the cell membrane by the cleavage of arachidonate from the phospholipids that make up the membrane This is catalyzed either by phospholipase A2 acting directly on a membrane phospholipid or by a lipase acting on DAG diacyl glycerol The arachidonate is then acted upon by the cyclooxygenase component of prostaglandin synthase This forms a cyclopentane ring roughly in the middle of the fatty acid chain The reaction also adds 4 oxygen atoms derived from two molecules of O2 The resulting molecule is prostaglandin G2 which is converted by the hydroperoxidase component of the enzyme complex into prostaglandin H2 This highly unstable compound is rapidly transformed into other prostaglandins prostacyclin and thromboxanes 25 These are then released into the interstitial fluids surrounding the cells that have manufactured the eicosanoid hormone If arachidonate is acted upon by a lipoxygenase instead of cyclooxygenase Hydroxyeicosatetraenoic acids and leukotrienes are formed They also act as local hormones Prostaglandins have two derivatives prostacyclins and thromboxanes Prostacyclins are powerful locally acting vasodilators and inhibit the aggregation of blood platelets Through their role in vasodilation prostacyclins are also involved in inflammation They are synthesized in the walls of blood vessels and serve the physiological function of preventing needless clot formation as well as regulating the contraction of smooth muscle tissue 26 Conversely thromboxanes produced by platelet cells are vasoconstrictors and facilitate platelet aggregation Their name comes from their role in clot formation thrombosis Dietary sources of fatty acids their digestion absorption transport in the blood and storage edit nbsp Dietary fats are emulsified in the duodenum by soaps in the form of bile salts and phospholipids such as phosphatidylcholine The fat droplets thus formed can be attacked by pancreatic lipase nbsp Structure of a bile acid cholic acid represented in the standard form a semi realistic 3D form and a diagrammatic 3D form nbsp Diagrammatic illustration of mixed micelles formed in the duodenum in the presence of bile acids e g cholic acid and the digestion products of fats the fat soluble vitamins and cholesterol A significant proportion of the fatty acids in the body are obtained from the diet in the form of triglycerides of either animal or plant origin The fatty acids in the fats obtained from land animals tend to be saturated whereas the fatty acids in the triglycerides of fish and plants are often polyunsaturated and therefore present as oils These triglycerides cannot be absorbed by the intestine 27 They are broken down into mono and di glycerides plus free fatty acids but no free glycerol by pancreatic lipase which forms a 1 1 complex with a protein called colipase also a constituent of pancreatic juice which is necessary for its activity The activated complex can work only at a water fat interface Therefore it is essential that fats are first emulsified by bile salts for optimal activity of these enzymes 28 The digestion products consisting of a mixture of tri di and monoglycerides and free fatty acids which together with the other fat soluble contents of the diet e g the fat soluble vitamins and cholesterol and bile salts form mixed micelles in the watery duodenal contents see diagrams on the right 27 29 The contents of these micelles but not the bile salts enter the enterocytes epithelial cells lining the small intestine where they are resynthesized into triglycerides and packaged into chylomicrons which are released into the lacteals the capillaries of the lymph system of the intestines 30 These lacteals drain into the thoracic duct which empties into the venous blood at the junction of the left jugular and left subclavian veins on the lower left hand side of the neck This means that the fat soluble products of digestion are discharged directly into the general circulation without first passing through the liver unlike all other digestion products The reason for this peculiarity is unknown 31 nbsp A schematic diagram of a chylomicron The chylomicrons circulate throughout the body giving the blood plasma a milky or creamy appearance after a fatty meal citation needed Lipoprotein lipase on the endothelial surfaces of the capillaries especially in adipose tissue but to a lesser extent also in other tissues partially digests the chylomicrons into free fatty acids glycerol and chylomicron remnants The fatty acids are absorbed by the adipocytes citation needed but the glycerol and chylomicron remnants remain in the blood plasma ultimately to be removed from the circulation by the liver The free fatty acids released by the digestion of the chylomicrons are absorbed by the adipocytes citation needed where they are resynthesized into triglycerides using glycerol derived from glucose in the glycolytic pathway citation needed These triglycerides are stored until needed for the fuel requirements of other tissues in the fat droplet of the adipocyte The liver absorbs a proportion of the glucose from the blood in the portal vein coming from the intestines After the liver has replenished its glycogen stores which amount to only about 100 g of glycogen when full much of the rest of the glucose is converted into fatty acids as described below These fatty acids are combined with glycerol to form triglycerides which are packaged into droplets very similar to chylomicrons but known as very low density lipoproteins VLDL These VLDL droplets are processed in exactly the same manner as chylomicrons except that the VLDL remnant is known as an intermediate density lipoprotein IDL which is capable of scavenging cholesterol from the blood This converts IDL into low density lipoprotein LDL which is taken up by cells that require cholesterol for incorporation into their cell membranes or for synthetic purposes e g the formation of the steroid hormones The remainder of the LDLs is removed by the liver 32 Adipose tissue and lactating mammary glands also take up glucose from the blood for conversion into triglycerides This occurs in the same way as in the liver except that these tissues do not release the triglycerides thus produced as VLDL into the blood Adipose tissue cells store the triglycerides in their fat droplets ultimately to release them again as free fatty acids and glycerol into the blood as described above when the plasma concentration of insulin is low and that of glucagon and or epinephrine is high 33 Mammary glands discharge the fat as cream fat droplets into the milk that they produce under the influence of the anterior pituitary hormone prolactin All cells in the body need to manufacture and maintain their membranes and the membranes of their organelles Whether they rely entirely on free fatty acids absorbed from the blood or are able to synthesize their own fatty acids from blood glucose is not known The cells of the central nervous system will almost certainly have the capability of manufacturing their own fatty acids as these molecules cannot reach them through the blood brain barrier 34 However it is unknown how they are reached by the essential fatty acids which mammals cannot synthesize themselves but are nevertheless important components of cell membranes and other functions described above Fatty acid synthesis editMain article Fatty acid synthesis nbsp Synthesis of saturated fatty acids via Fatty Acid Synthase II in E coliMuch like beta oxidation straight chain fatty acid synthesis occurs via the six recurring reactions shown below until the 16 carbon palmitic acid is produced 35 36 The diagrams presented show how fatty acids are synthesized in microorganisms and list the enzymes found in Escherichia coli 35 These reactions are performed by fatty acid synthase II FASII which in general contains multiple enzymes that act as one complex FASII is present in prokaryotes plants fungi and parasites as well as in mitochondria 37 In animals as well as some fungi such as yeast these same reactions occur on fatty acid synthase I FASI a large dimeric protein that has all of the enzymatic activities required to create a fatty acid FASI is less efficient than FASII however it allows for the formation of more molecules including medium chain fatty acids via early chain termination 37 Enzymes acyltransferases and transacylases incorporate fatty acids in phospholipids triacylglycerols etc by transferring fatty acids between an acyl acceptor and donor They also have the task of synthesizing bioactive lipids as well as their precursor molecules 38 Once a 16 0 carbon fatty acid has been formed it can undergo a number of modifications resulting in desaturation and or elongation Elongation starting with stearate 18 0 is performed mainly in the endoplasmic reticulum by several membrane bound enzymes The enzymatic steps involved in the elongation process are principally the same as those carried out by fatty acid synthesis but the four principal successive steps of the elongation are performed by individual proteins which may be physically associated 39 40 Step Enzyme Reaction Description a Acetyl CoA ACP transacylase nbsp Activates acetyl CoA for reaction with malonyl ACP b Malonyl CoA ACP transacylase nbsp Activates malonyl CoA for reaction with acetyl ACP c 3 ketoacyl ACP synthase nbsp Reacts ACP bound acyl chain with chain extending malonyl ACP d 3 ketoacyl ACP reductase nbsp Reduces the carbon 3 ketone to a hydroxyl group e 3 Hydroxyacyl ACP dehydrase nbsp Eliminates water f Enoyl ACP reductase nbsp Reduces the C2 C3 double bond Abbreviations ACP Acyl carrier protein CoA Coenzyme A NADP Nicotinamide adenine dinucleotide phosphate Note that during fatty synthesis the reducing agent is NADPH whereas NAD is the oxidizing agent in beta oxidation the breakdown of fatty acids to acetyl CoA This difference exemplifies a general principle that NADPH is consumed during biosynthetic reactions whereas NADH is generated in energy yielding reactions 34 Thus NADPH is also required for the synthesis of cholesterol from acetyl CoA while NADH is generated during glycolysis The source of the NADPH is two fold When malate is oxidatively decarboxylated by NADP linked malic enzyme pyruvate CO2 and NADPH are formed NADPH is also formed by the pentose phosphate pathway which converts glucose into ribose which can be used in synthesis of nucleotides and nucleic acids or it can be catabolized to pyruvate 34 Glycolytic end products are used in the conversion of carbohydrates into fatty acids edit Main article Citric acid cycle Glycolytic end products are used in the conversion of carbohydrates into fatty acids In humans fatty acids are formed from carbohydrates predominantly in the liver and adipose tissue as well as in the mammary glands during lactation The pyruvate produced by glycolysis is an important intermediary in the conversion of carbohydrates into fatty acids and cholesterol 34 This occurs via the conversion of pyruvate into acetyl CoA in the mitochondrion However this acetyl CoA needs to be transported into cytosol where the synthesis of fatty acids and cholesterol occurs This cannot occur directly To obtain cytosolic acetyl CoA citrate produced by the condensation of acetyl CoA with oxaloacetate is removed from the citric acid cycle and carried across the inner mitochondrial membrane into the cytosol 34 There it is cleaved by ATP citrate lyase into acetyl CoA and oxaloacetate The oxaloacetate is returned to mitochondrion as malate and then converted back into oxaloacetate to transfer more acetyl CoA out of the mitochondrion 41 The cytosolic acetyl CoA is carboxylated by acetyl CoA carboxylase into malonyl CoA the first committed step in the synthesis of fatty acids 41 42 Regulation of fatty acid synthesis edit Acetyl CoA is formed into malonyl CoA by acetyl CoA carboxylase at which point malonyl CoA is destined to feed into the fatty acid synthesis pathway Acetyl CoA carboxylase is the point of regulation in saturated straight chain fatty acid synthesis and is subject to both phosphorylation and allosteric regulation Regulation by phosphorylation occurs mostly in mammals while allosteric regulation occurs in most organisms Allosteric control occurs as feedback inhibition by palmitoyl CoA and activation by citrate When there are high levels of palmitoyl CoA the final product of saturated fatty acid synthesis it allosterically inactivates acetyl CoA carboxylase to prevent a build up of fatty acids in cells Citrate acts to activate acetyl CoA carboxylase under high levels because high levels indicate that there is enough acetyl CoA to feed into the Krebs cycle and produce energy 43 High plasma levels of insulin in the blood plasma e g after meals cause the dephosphorylation and activation of acetyl CoA carboxylase thus promoting the formation of malonyl CoA from acetyl CoA and consequently the conversion of carbohydrates into fatty acids while epinephrine and glucagon released into the blood during starvation and exercise cause the phosphorylation of this enzyme inhibiting lipogenesis in favor of fatty acid oxidation via beta oxidation 34 42 Disorders editDisorders of fatty acid metabolism can be described in terms of for example hypertriglyceridemia too high level of triglycerides or other types of hyperlipidemia These may be familial or acquired Familial types of disorders of fatty acid metabolism are generally classified as inborn errors of lipid metabolism These disorders may be described as fatty acid oxidation disorders or as a lipid storage disorders and are any one of several inborn errors of metabolism that result from enzyme or transport protein defects affecting the ability of the body to oxidize fatty acids in order to produce energy within muscles liver and other cell types When a fatty acid oxidation disorder affects the muscles it is a metabolic myopathy Moreover cancer cells can display irregular fatty acid metabolism with regard to both fatty acid synthesis 44 and mitochondrial fatty acid oxidation FAO 45 that are involved in diverse aspects of tumorigenesis and cell growth References edit a b c d e f Stryer Lubert 1995 Fatty acid metabolism In Biochemistry Fourth ed New York W H Freeman and Company pp 603 628 ISBN 0 7167 2009 4 a b c d Oxidation of fatty acids Zechner R Strauss JG Haemmerle G Lass A Zimmermann R 2005 Lipolysis pathway under construction Curr Opin Lipidol 16 3 333 40 doi 10 1097 01 mol 0000169354 20395 1c PMID 15891395 S2CID 35349649 Mobilization and cellular uptake of stored fats triacylglycerols with animation Stahl Andreas 1 February 2004 A current review of fatty acid transport proteins SLC27 Pflugers Archiv European Journal of Physiology 447 5 722 727 doi 10 1007 s00424 003 1106 z PMID 12856180 S2CID 2769738 Anderson Courtney M Stahl Andreas April 2013 SLC27 fatty acid transport proteins Molecular Aspects of Medicine 34 2 3 516 528 doi 10 1016 j mam 2012 07 010 PMC 3602789 PMID 23506886 Ebert D Haller RG Walton ME Jul 2003 Energy contribution of octanoate to intact rat brain metabolism measured by 13C nuclear magnetic resonance spectroscopy J Neurosci 23 13 5928 35 doi 10 1523 JNEUROSCI 23 13 05928 2003 PMC 6741266 PMID 12843297 Marin Valencia I Good LB Ma Q Malloy CR Pascual JM Feb 2013 Heptanoate as a neural fuel energetic and neurotransmitter precursors in normal and glucose transporter I deficient G1D brain J Cereb Blood Flow Metab 33 2 175 82 doi 10 1038 jcbfm 2012 151 PMC 3564188 PMID 23072752 Stryer Lubert 1995 Fatty acid metabolism In Biochemistry Fourth ed New York W H Freeman and Company pp 770 771 ISBN 0 7167 2009 4 a b c d e f g h i Stryer Lubert 1995 Biochemistry Fourth ed New York W H Freeman and Company pp 510 515 581 613 775 778 ISBN 0 7167 2009 4 Activation and transportation of fatty acids to the mitochondria via the carnitine shuttle with animation Vivo Darryl C Bohan Timothy P Coulter David L Dreifuss Fritz E Greenwood Robert S Nordli Douglas R Shields W Donald Stafstrom Carl E Tein Ingrid 1998 l Carnitine Supplementation in Childhood Epilepsy Current Perspectives Epilepsia 39 11 1216 1225 doi 10 1111 j 1528 1157 1998 tb01315 x ISSN 0013 9580 PMID 9821988 S2CID 28692799 Oxidation of odd carbon chain length fatty acids Oxidation of unsaturated fatty acids Wongkittichote P Ah Mew N Chapman KA December 2017 Propionyl CoA carboxylase A review Molecular Genetics and Metabolism 122 4 145 152 doi 10 1016 j ymgme 2017 10 002 PMC 5725275 PMID 29033250 Halarnkar PP Blomquist GJ 1989 Comparative aspects of propionate metabolism Comp Biochem Physiol B 92 2 227 31 doi 10 1016 0305 0491 89 90270 8 PMID 2647392 Stryer Lubert 1995 Biochemistry Fourth ed New York W H Freeman and Company p 777 ISBN 0 7167 2009 4 Sloan A W Koeslag J H Bredell G A G 1973 Body composition work capacity and work efficiency of active and inactive young men European Journal of Applied Physiology 32 17 24 doi 10 1007 bf00422426 S2CID 39812342 Ruddick JA 1972 Toxicology metabolism and biochemistry of 1 2 propanediol Toxicol Appl Pharmacol 21 1 102 111 doi 10 1016 0041 008X 72 90032 4 PMID 4553872 a b c Glew Robert H Invited review You Can Get There From Here Acetone Anionic Ketones and Even Carbon Fatty Acids can Provide Substrates for Gluconeogenesis Nigerian Journal of Physiological Science 25 1 2 4 Archived from the original on 26 September 2013 Retrieved 7 August 2016 a b c Park Sung M Klapa Maria I Sinskey Anthony J Stephanopoulos Gregory 1999 Metabolite and isotopomer balancing in the analysis of metabolic cycles II Applications PDF Biotechnology and Bioengineering 62 4 398 doi 10 1002 sici 1097 0290 19990220 62 4 lt 392 aid bit2 gt 3 0 co 2 s ISSN 0006 3592 PMID 9921151 Miller DN Bazzano G Bazzano 1965 Propanediol metabolism and its relation to lactic acid metabolism Ann NY Acad Sci 119 3 957 973 Bibcode 1965NYASA 119 957M doi 10 1111 j 1749 6632 1965 tb47455 x PMID 4285478 S2CID 37769342 D L Vander Jagt B Robinson K K Taylor L A Hunsaker 1992 Reduction of trioses by NADPH dependent aldo keto reductases Aldose reductase methylglyoxal and diabetic complications The Journal of Biological Chemistry 267 7 4364 4369 doi 10 1016 S0021 9258 18 42844 X PMID 1537826 Stryer Lubert 1995 Signal transduction cascades In Biochemistry Fourth ed New York W H Freeman and Company pp 343 350 ISBN 0 7167 2009 4 a b Stryer Lubert 1995 Eicosanoid hormones are derived from fatty acids In Biochemistry Fourth ed New York W H Freeman and Company pp 624 627 ISBN 0 7167 2009 4 Nelson Randy F 2005 An introduction to behavioral endocrinology 3rd ed Sunderland Mass Sinauer Associates p 100 ISBN 978 0 87893 617 5 a b Digestion of fats triacylglycerols Hofmann AF 1963 The function of bile salts in fat absorption The solvent properties of dilute micellar solutions of conjugated bile salts Biochem J 89 1 57 68 doi 10 1042 bj0890057 PMC 1202272 PMID 14097367 Stryer Lubert 1995 Membrane structures and dynamics In Biochemistry Fourth ed New York W H Freeman and Company pp 268 270 ISBN 0 7167 2009 4 Smith Sareen S Gropper Jack L Smith Jack S 2013 Advanced nutrition and human metabolism 6th ed Belmont CA Wadsworth Cengage Learning ISBN 978 1133104056 a href Template Cite book html title Template Cite book cite book a CS1 maint multiple names authors list link Williams Peter L Warwick Roger Dyson Mary Bannister Lawrence H 1989 Angiology In Gray s Anatomy Thirty seventh ed Edinburgh Churchill Livingstone pp 841 843 ISBN 0443 041776 Stryer Lubert 1995 Biosynthesis of membrane lipids and steroids In Biochemistry Fourth ed New York W H Freeman and Company pp 697 700 ISBN 0 7167 2009 4 Stralfors Peter Honnor Rupert C 1989 Insulin induced dephosphorylation of hormone sensitive lipase European Journal of Biochemistry 182 2 379 385 doi 10 1111 j 1432 1033 1989 tb14842 x PMID 2661229 a b c d e f Stryer Lubert 1995 Biochemistry Fourth ed New York W H Freeman and Company pp 559 565 614 623 ISBN 0 7167 2009 4 a b Dijkstra Albert J R J Hamilton and Wolf Hamm Fatty Acid Biosynthesis Trans Fatty Acids Oxford Blackwell Pub 2008 12 Print MetaCyc pathway superpathway of fatty acids biosynthesis MetaCyc Metabolic Pathway Database BioCyc E coli a b Christie William W 20 April 2011 Fatty Acids Straight chain Saturated Structure Occurrence and Biosynthesis In American Oil Chemists Society ed AOCS Lipid Library Archived from the original on 2011 07 21 Retrieved 2011 05 02 Yamashita Atsushi Hayashi Yasuhiro Nemoto Sasaki Yoko Ito Makoto Oka Saori Tanikawa Takashi Waku Keizo Sugiura Takayuki 2014 01 01 Acyltransferases and transacylases that determine the fatty acid composition of glycerolipids and the metabolism of bioactive lipid mediators in mammalian cells and model organisms Progress in Lipid Research 53 18 81 doi 10 1016 j plipres 2013 10 001 ISSN 0163 7827 PMID 24125941 MetaCyc pathway stearate biosynthesis I animals MetaCyc Metabolic Pathway Database BioCyc MetaCyc pathway very long chain fatty acid biosynthesis II MetaCyc Metabolic Pathway Database BioCyc a b Ferre P F Foufelle 2007 SREBP 1c Transcription Factor and Lipid Homeostasis Clinical Perspective Hormone Research 68 2 72 82 doi 10 1159 000100426 PMID 17344645 Retrieved 2010 08 30 this process is outlined graphically in page 73 a b Voet Donald Judith G Voet Charlotte W Pratt 2006 Fundamentals of Biochemistry 2nd Edition John Wiley and Sons Inc pp 547 556 ISBN 978 0 471 21495 3 Diwan Joyce J Fatty Acid Synthesis Rensselaer Polytechnic Institute RPI Architecture Business Engineering IT Humanities Science Web 30 Apr 2011 lt Fatty Acid Synthesis Archived from the original on 2011 06 07 Retrieved 2011 05 02 gt Ezzeddini R Taghikhani M Somi MH Samadi N Rasaee MJ May 2019 Clinical importance of FASN in relation to HIF 1a and SREBP 1c in gastric adenocarcinoma Life Sciences 224 169 176 doi 10 1016 j lfs 2019 03 056 PMID 30914315 S2CID 85532042 Ezzeddini R Taghikhani M Salek Farrokhi A Somi MH Samadi N Esfahani A Rasaee MJ May 2021 Downregulation of fatty acid oxidation by involvement of HIF 1a and PPARg in human gastric adenocarcinoma and its related clinical significance Journal of Physiology and Biochemistry 77 2 249 260 doi 10 1007 s13105 021 00791 3 ISSN 1138 7548 PMID 33730333 S2CID 232300877 Retrieved from https en wikipedia org w index php title Fatty acid metabolism amp oldid 1175469608, wikipedia, wiki, book, books, library,

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