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Fatty acid, activation oxidation

See also Acetyl-CoA, Fats, Albumin, Fatty Acid Activation, Oxidation of Saturated Fatty Acids, Oxidation of Unsaturated Fatty Acids, Fatty Acid Biosynthesis Strategy, Palmitate Synthesis from Acetyl-CoA, Fatty Acid Desaturation, Essential Fatty Acids, Control of Fatty Acid Synthesis, Molecular Structures and Properties of Lipids (from Chapter 10)... [Pg.128]

A study of the effect of stearic acid and 2iac oxide on a sulfonamide-accelerated, sulfiir-cured natural mbber compound dramatically showed the need for both 2iac and fatty acid activators (Fig. 7) (21). [Pg.238]

A forth molecule, the receptor G2A (GPR132), is also related to this group. However, recent data suggest that G2A is a receptor for oxidized free fatty acids. Activation by acidic pH could not be confirmed. [Pg.1035]

Synthesis of PHAMCL from fatty acids such as octanoic acid or from the corresponding alkanes such as octane was first detected in P. oleovorans [119]. The alkanes are oxidized to the fatty acids the latter are activated by thiokinases and then degraded via the fatty acid /1-oxidation pathway. Obviously intermediates of this pathway accumulate under conditions favorable for the synthesis of PHA and are subsequently converted into substrates for the PHA synthase. Many reactions for the conversion of an intermediate of the -oxidation cycle into R-(-)-3-hydroxyacyl-CoA were considered. These were ... [Pg.106]

Belkner et al. [32] demonstrated that 15-LOX oxidized preferably LDL cholesterol esters. Even in the presence of free linoleic acid, cholesteryl linoleate continued to be a major LOX substrate. It was also found that the depletion of LDL from a-tocopherol has not prevented the LDL oxidation. This is of a special interest in connection with the role of a-tocopherol in LDL oxidation. As the majority of cholesteryl esters is normally buried in the core of a lipoprotein particle and cannot be directly oxidized by LOX, it has been suggested that LDL oxidation might be initiated by a-tocopheryl radical formed during the oxidation of a-tocopherol [33,34]. Correspondingly, it was concluded that the oxidation of LDL by soybean and recombinant human 15-LOXs may occur by two pathways (a) LDL-free fatty acids are oxidized enzymatically with the formation of a-tocopheryl radical, and (b) the a-tocopheryl-mediated oxidation of cholesteryl esters occurs via a nonenzymatic way. Pro and con proofs related to the prooxidant role of a-tocopherol were considered in Chapter 25 in connection with the study of nonenzymatic lipid oxidation and in Chapter 29 dedicated to antioxidants. It should be stressed that comparison of the possible effects of a-tocopherol and nitric oxide on LDL oxidation does not support importance of a-tocopherol prooxidant activity. It should be mentioned that the above data describing the activity of cholesteryl esters in LDL oxidation are in contradiction with some earlier results. Thus in 1988, Sparrow et al. [35] suggested that the 15-LOX-catalyzed oxidation of LDL is accelerated in the presence of phospholipase A2, i.e., the hydrolysis of cholesterol esters is an important step in LDL oxidation. [Pg.810]

Between meals when fatty acids are oxidized in the liver for energy, accumulating acetyl CoA activates pyruvate carboxylase and gluconeogenesis and inhibits PDH, thus preventing conversion of lactate and alanine to acetyl CoA. [Pg.198]

Figure 1-16-2. Fatty Acid Activation, Transport, and Oxidation... Figure 1-16-2. Fatty Acid Activation, Transport, and Oxidation...
The oxidation of aciy lic acid can be rationalized in terms of the endogenous catabolism of propionic acid, in which acrylyl coenzyme A is an intermediate. This pathway is analogous with fatty acid 3-oxidation, common to all species and, unlike the corresponding pathway in plants, does not involve vitamin 8,2. 3-Hydroxypropionic acid has been found as an intennediate in the metabolism of acrylic acid in vitro in rat liver and mitochondria (Finch Frederick, 1992). The CO2 excreted derives from the carboxyl carbon, while carbon atoms 2 and 3 are converted to acetyl coenzyme A, which participates in a variety of reactions. The oxidation of acrylic acid is catalysed by enzymes in a variety of tissues (Black Finch, 1995). In mice, the greatest activity was found in kidney, which was five times more active than liver and 50 times more active than skin (Black et al., 1993). [Pg.1225]

Figure 10-4 Reactions of fatty acid activation and of breakdown by (S oxidation. Figure 10-4 Reactions of fatty acid activation and of breakdown by (S oxidation.
Induction of peroxisome proliferation following treatment with DEHP is not due to the parent compound, but to DEHP metabolites. Studies with MEHP in vitro have demonstrated that the proximate peroxisome proliferators are mono(2-ethyl-5-oxohexyl) phthalate (metabolite VI) and mono(2-ethyl-5-hydroxyhexyl) phthalate, (metabolite IX) and that for 2-ethylhexanol, the proximate proliferator is 2-ethylhexanoic acid (Elcombe and Mitchell 1986 Mitchell et al. 1985a). Similar findings were observed by Maloney and Waxman (1999), who showed that MEHP (but not DEHP) activated mouse and human PPARa and PPARy, while 2-ethylhexanoic acid activated mouse and human PPARa only, and at much higher concentrations. Based on its potency to induce enzyme activities, such as the peroxisomal fatty acid (3-oxidation cycle and carnitine acetyltransferase, DEHP might be considered a relatively weak proliferator. [Pg.138]

Now transported to the liver, fatty acids activate Giving CoA thioesters, oxidation is their fate Ketone bodies, Ketone bodies, because low glycerol-P Glucagon up, insulin down, stops reversal to TG. [Pg.75]

Sohlenius, A. K., Eriksson, A. M., Hogstrom, C., Kimland, M., Depierre, J. W. Perfluorooctane sulfonic acid is a potent inducer of peroxisomal fatty-acid beta-oxidation and other activities known to be affected by peroxisome proliferators in mouse liver. Pharmacol Toxicol, 72 90-93... [Pg.59]

Fatty acid degradation and synthesis are relatively simple processes that are essentially the reverse of each other. The process of degradation converts an aliphatic compound into a set of activated acetyl units (acetyl CoA) that can be processed by the citric acid cycle (Figure 22.2). An activated fatty acid is oxidized to introduce a double bond the double bond is hydrated to introduce an oxygen the alcohol is oxidized to a ketone and, finally, the four carbon fragment is cleaved by coenzyme A to yield acetyl CoA and a fatty acid chain two carbons shorter. If the fatty acid has an even number of carbon atoms and is saturated, the process is simply repeated until the fatty acid is completely converted into acetyl CoA units. [Pg.897]

Eugene Kennedy and Albert Lehninger showed in 1949 that fatty acids are oxidized in mitochondria. Subsequent work demonstrated that they are activated before they enter the mitochondrial matrix. Adenosine triphosphate (ATP) drives the formation of a thioester linkage between the carboxyl group of a fatty acid and the sulfhydryl group of CoA. This activation reaction takes place on the outer mitochondrial membrane, where it is catalyzed by acyl CoA synthetase (also called fatty acid thiokinase). [Pg.904]

The metabolic functions of pantothenic acid in human biochemistry are mediated through the synthesis of CoA. Pantothenic acid is a structural component of CoA. which is necessary for many important metabolic processes. Pantothenic acid is incorporated into CoA by a. series of five enzyme-catalyzed reactions. CoA is involved in the activation of fatty acids before oxidation, which requires ATP to form the respective fatty ocyl-CoA derivatives. Pantothenic acid aI.so participates in fatty acid oxidation in the final step, forming acetyl-CoA. Acetyl-CoA is also formed from pyruvate decarboxylation, in which CoA participates with thiamine pyrophosphate and lipoic acid, two other important coenzymes. Thiamine pyrophosphate is the actual decarboxylating coenzyme that functions with lipoic acid to form acetyidihydrolipoic acid from pyruvate decarboxylation. CoA then accepts the acetyl group from acetyidihydrolipoic acid to form acetyl-CoA. Acetyl-CoA is an acetyl donor in many processes and is the precursor in important biosyntheses (e.g.. those of fatty acids, steroids, porphyrins, and acetylcholine). [Pg.887]

C. Fatty acids cross the inner mitochondrial membrane on a carnitine carrier. This process is inhibited during fatty acid synthesis by malonyl CoA. Fatty acids are very insoluble in water and are transported in the blood by serum albumin. They cross the plasma membrane and are converted to fatty acyl CoA by CoASH and ATP. In the process, ATP is converted to AMP, so fatty acid activation utilizes the equivalent of 2 ATP. In mitochondria, fatty acids are oxidized to C02 and H20. They cannot be oxidized in red blood cells, which lack mitochondria. [Pg.225]

D. Ketone bodies are synthesized in the liver from fatty acids derived from the blood. During the cytosolic activation of the fatty acid, ATP is converted to AMP. Carnitine is required to carry the fatty acyl group across the mitochondrial membrane. In the mitochondrion, the fatty acid is oxidized. Acetyl CoA and acetoacetyl CoA are produced and react to... [Pg.226]

In summary, substantial progress has been made over the past few years in understanding the cytoplasmic organelle peroxisome and factors that alter its normal functions. Peroxisome proliferator-in-duced increase in the liver peroxisomes is associated with an approximately two-fold increase in catalase activity and several-fold increases in the activity of the peroxisomal fatty acid jS-oxidation system. It is also evident from the available literature that hepatic peroxisomal proliferation appears to be a carcinogenic event in rodents, and this may depend on the potency of the inducer. However, there is no single mechanism that is attributed to the peroxisome proliferation or carcinogenesis induced by... [Pg.1954]


See other pages where Fatty acid, activation oxidation is mentioned: [Pg.675]    [Pg.199]    [Pg.273]    [Pg.139]    [Pg.76]    [Pg.53]    [Pg.36]    [Pg.82]    [Pg.634]    [Pg.196]    [Pg.371]    [Pg.137]    [Pg.176]    [Pg.185]    [Pg.189]    [Pg.259]    [Pg.140]    [Pg.92]    [Pg.306]    [Pg.1202]    [Pg.158]    [Pg.1948]    [Pg.1948]    [Pg.2231]    [Pg.2231]    [Pg.2232]    [Pg.18]    [Pg.278]    [Pg.366]   
See also in sourсe #XX -- [ Pg.137 , Pg.138 , Pg.139 , Pg.140 , Pg.141 , Pg.142 , Pg.143 , Pg.144 , Pg.384 , Pg.389 ]




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Activated oxidation

Activation oxidation

Active oxides

Activity oxidation

Fatty acid oxidation uptake activity

Fatty acid, activation oxidation spiral

Fatty acids activation

Fatty acids oxidation

Oxidative activation

Oxides activated

Oxidized fatty acids

Oxidizing activators

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