Citric acid cycle pyruvate carboxylase

See also Coenzyme A, Citric Acid Cycle, Pyruvate Kinase, Pyruvate Carboxylase... 

The enzyme that catalyzes this reaction is pyruvate carboxylase, an allosteric enzyme found in the mitochondria. Acetyl-CoA is an allosteric effector that activates pyruvate carboxylase. If high levels of acetyl-GoA are present (in other words, if there is more acetyl-GoA than is needed to supply the citric acid cycle), pyruvate (a precursor of acetyl-GoA) can be diverted to gluconeogenesis. (Oxaloacetate from the citric acid cycle can frequendy be a starting point for gluconeogenesis as well.) Magnesium ion (Mg +) and biotin are also required for effective catalysis. We have seen Mg + as a cofactor before, but we have not seen biotin, which requires some discussion. 

Theoretically, a fall in concentration of oxaloacetate, particularly within the mitochondria, could impair the ability of the citric acid cycle to metabolize acetyl-CoA and divert fatty acid oxidation toward ketogenesis. Such a fall may occur because of an increase in the [NADH]/[NAD+] ratio caused by increased P-oxida-tion affecting the equilibrium between oxaloacetate and malate and decreasing the concentration of oxaloacetate. However, pyruvate carboxylase, which catalyzes the conversion of pyruvate to oxaloacetate, is activated by acetyl-CoA. Consequently, when there are significant amounts of acetyl-CoA, there should be sufficient oxaloacetate to initiate the condensing reaction of the citric acid cycle. 

Pyruvate carboxylase (also called PC) is an enzyme that converts pyruvate to oxaloacetate (shown as oxaloacetic acid in the citric acid cycle diagram). Pyruvate carboxylase deficiency is a genetic disorder that is characterized by insufficient quantities of pyruvate carboxylate in the body. How do you think this disorder affects the citric acid cycle Use print and electronic resources to research pyruvate carboxylase deficiency. Find out what its symptoms are, and how it affects the body at the molecular level. Also find out what percent of the population is affected, and how the deficiency can be relieved. Present your findings as an informative pamphlet. If possible, conduct an e-mail interview with an expert on the disorder. 

The reaction involves biotin as a carrier of activated HCO3 (Fig. 14-18). The reaction mechanism is shown in Figure 16-16. Pyruvate carboxylase is the first regulatory enzyme in the gluconeogenic pathway, requiring acetyl-CoA as a positive effector. (Acetyl-CoA is produced by fatty acid oxidation (Chapter 17), and its accumulation signals the availability of fatty acids as fuel.) As we shall see in Chapter 16 (see Fig. 16-15), the pyruvate carboxylase reaction can replenish intermediates in another central metabolic pathway, the citric acid cycle. 

Table 16-2 shows the most common anaplerotic reactions, all of which, in various tissues and organisms, convert either pyruvate or phosphoenolpyruvate to ox-aloacetate or malate. The most important anaplerotic reaction in mammalian liver and kidney is the reversible carboxylation of pyruvate by C02 to form oxaloacetate, catalyzed by pyruvate carboxylase. When the citric acid cycle is deficient in oxaloacetate or any other intermediates, pyruvate is carboxylated to produce more oxaloacetate. The enzymatic addition of a carboxyl group to pyruvate requires energy, which is supplied by ATP—the free energy required to attach a carboxyl group to pyruvate is about equal to the free energy available from ATP. 

Pyruvate carboxylase is a regulatory enzyme and is virtually inactive in the absence of acetyl-CoA, its positive allosteric modulator. Whenever acetyl-CoA, the fuel for the citric acid cycle, is present in excess, it stimulates the pyruvate carboxylase reaction to produce more oxaloacetate, enabling the cycle to use more acetyl-CoA in the citrate synthase reaction. 

The other anaplerotic reactions shown in Table 16-2 are also regulated to keep the level of intermediates high enough to support the activity of the citric acid cycle. Phosphoenolpyruvate (PEP) carboxylase, for example, is activated by the glycolytic intermediate fructose 1,6-bisphosphate, which accumulates when the citric acid cycle operates too slowly to process the pyruvate generated by glycolysis. 

When intermediates are shunted from the citric acid cycle to other pathways, they are replenished by several anaplerotic reactions, which produce four-carbon intermediates by carboxylation of three-carbon compounds these reactions are catalyzed by pyruvate carboxylase, PEP carboxykinase, PEP carboxylase, and malic enzyme. Enzymes that catalyze carboxylations commonly employ biotin to activate C02 and... 

Propionyl-CoA is first carboxylated to form the d stereoisomer of methylmalonyl-CoA (Pig. 17—11) by propionyl-CoA carboxylase, which contains the cofactor biotin. In this enzymatic reaction, as in the pyruvate carboxylase reaction (see Pig. 16-16), C02 (or its hydrated ion, HCO ) is activated by attachment to biotin before its transfer to the substrate, in this case the propionate moiety. Formation of the carboxybiotin intermediate requires energy, which is provided by the cleavage of ATP to ADP and Pi- The D-methylmalonyl-CoA thus formed is enzymatically epimerized to its l stereoisomer by methylmalonyl-CoA epimerase (Pig. 17-11). The L-methylmal onyl -CoA then undergoes an intramolecular rearrangement to form succinyl-CoA, which can enter the citric acid cycle. This rearrangement is catalyzed by methylmalonyl-CoA mutase, which requires as its coenzyme 5 -deoxyadenosyl-cobalamin, or coenzyme Bi2, which is derived from vitamin B12 (cobalamin). Box 17—2 describes the role of coenzyme B12 in this remarkable exchange reaction. 

Carboxylation of pyruvate to oxaloacetate (OAA) by pyruvate carboxylase is a biotin-dependent reaction (see Figure 8.24). This reaction is important because it replenishes the citric acid cycle intermediates, and provides substrate for gluconeogenesis (see p. 116). 

Reductive citric acid cycle 5 3 NAD(P)H, 1 unknown donor", 2 ferredoxin 2-Oxoglutarate synthase Isocitrate dehydrogenase6 Pyruvate synthase PEP carboxylase C02 C02 C02 HCOJ Acetyl-CoA, pyruvate, PEP, oxaloacetate, succinyl-CoA, 2-oxoglutarate 2-Oxoglutarate synthase, ATP-citrate lyase... 

Oxaloacetate, the product of the pyruvate carboxylase reaction, functions both as an important citric acid cycle intermediate in the oxidation of acetyl CoA and as a precursor for gluconeogenesis. The activity of pyruvate carboxylase depends on the presence of acetyl CoA so that more oxaloacetate is made when acetyl CoA levels rise. 

Thus pyruvate carboxylase generates oxaloacetate for gluconeogenesis but also must maintain oxaloacetate levels for citric acid cycle function. For the latter reason, the activity of pyruvate carboxylase depends absolutely on the presence of acetyl CoA the biotin prosthetic group of the enzyme cannot be carboxy-lated unless acetyl CoA is bound to the enzyme. This allosteric activation by acetyl CoA ensures that more oxaloacetate is made when excess acetyl CoA is present. In this role of maintaining the level of citric acid cycle intermediates, the pyruvate carboxylase reaction is said to be anaplerotic, that is filling up. ... 

Answer Because pyruvate carboxylase is a mitochondrial enzyme, the [14C]oxaloacetate (OAA) formed by this reaction mixes with the OAA pool of the citric acid cycle. A mixture of [1-14C] and [4-14C] OAA eventually forms by randomization of the C-l and C-4 positions in the reversible conversions OAA —> malate —> succinate. [1-14C] OAA leads to formation of [3,4-14C]glucose. 

Answer Anaplerotic reactions replenish intermediates in the citric acid cycle. Net synthesis of a-ketoglutarate from pyruvate occurs by the sequential actions of (1) pyruvate carboxylase (which makes extra molecules of oxaloacetate), (2) pyruvate dehydrogenase, and the citric acid cycle enzymes (3) citrate synthase, (4) aconitase, and (5) isocitrate dehydrogenase ... 

Answer Fatty acid catabolism increases the level of acetyl-CoA, which stimulates pyruvate carboxylase. The resulting increase in oxaloacetate concentration stimulates acetyl-CoA consumption through the citric acid cycle, causing the citrate and ATP concentrations to rise. These metabolites inhibit glycolysis at PFK-1 and inhibit pyruvate dehydrogenase, effectively slowing the utilization of sugars and pyruvate. 

Pyruvate carboxylase is another enzyme which is not a part of the citric acid cycle per se but which functions in close association with it. The function of this enzyme is described in Chap. 11. but it is useful to consider its action, and that of pyruvate dehydrogenase, in relation to the citric acid cycle. 

The product of this reaction, oxaloacetate, can either enter the gluconeogenic pathway (Chap. 11) by way of malate or condense with acetyl-CoA to yield citrate. Pyruvate carboxylase is an allosteric enzyme, and it is activated by the heterotropic effector, acetyl-CoA. Thus, pyruvate in the mitochondria is the substrate for either pyruvate dehydrogenase or pyruvate carboxylase, the activities of which, in turn, are controlled by reactants associated with the citric acid cycle. The interplay among pyruvate dehydrogenase, pyruvate carboxylase, pyruvate, and the citric acid cycle is shown in Fig. 12-9. 

The cycle oxidizes acetyl-CoA, and to perform this task, it must convert acetyl-CoA to citrate. For this to be achieved, oxaloacetate must be available. If the removal of intermediates results in a decrease in the amount of oxaloacetate for this purpose, acetyl-CoA cannot be removed and will accumulate. This will inhibit the pyruvate dehydrogenase complex and activate pyruvate carboxylase, leading to the conversion of pyruvate to oxaloacetate. This product is now available to condense with the acetyl-CoA to produce citrate, which will restore the status quo. Reactions like that of pyruvate carboxylase that provide molecules for the replacement of intermediates of the citric acid cycle are known as anaplerotic reactions (Greek, meaning to fill up ana = up + plerotikos from pleroun = to make full ). 

Pyruvate can be converted to acetyl-CoA via the pyruvate dehydrogenase complex. Pyruvate can also be carboxylated via pyruvate carboxylase to produce oxaloacetate. So, two molecules of pyruvate can form the precursors of citrate, which can be converted to succinate within the citric acid cycle. 

The formation of acetyl-CoA from pyruvate in animals is via the pyruvate dehydrogenase complex, which catalyzes the irreversible decarboxylation reaction. Carbohydrate is synthesized from oxaloacetate, which in turn is synthesized from pyruvate via pyruvate carboxylase. Since the pyruvate dehydrogenase reaction is irreversible, acetyl-CoA cannot be converted to pyruvate, and hence animals cannot realize a net gain of carbohydrate from acetyl-CoA. Because plants have a glyoxylate cycle and animals do not, plants synthesize one molecule of succinate and one molecule of malate from two molecules of acetyl-CoA and one of oxaloacetate. The malate is converted to oxaloacetate, which reacts with another molecule of acetyl-CoA and thereby continues the reactions of the glyoxylate cycle. The succinate is also converted to oxaloacetate via the enzymes of the citric acid cycle. Thus, one molecule of oxaloacetate is diverted to carbohydrate synthesis and, therefore, plants are able to achieve net synthesis of carbohydrate from acetyl-CoA. 

Pyruvate Carboxylase Pyruvate carboxylase catalyzes the car-boxylation of pyruvate to oxaloacetate - both the first committed step of gluconeogenesis from pyruvate and also an important anaplerotic reaction, permitting repletion of tricarboxylic acid cycle intermediates and hence fatty acid synthesis. The mammalian enzyme is activated aUosterically by acetyl CoA, which accumulates when there is a need for increased activity of pyruvate carboxylase to synthesize oxaloacetate to permit increased citric acid cycle activity or for gluconeogenesis (Attwood, 1995 Jitrapakdee and Wallace, 1999). 

Genetic deficiency of pyruvate carboxylase does not cause the expected hypoglycemia. Rather, it seems that depletion of tissue pools of oxaloacetate results in impaired activity of citrate synthase, and a slowing of citric acid cycle activity, leading to accumulation of lactate, pyruvate, and alanine, and also increased accumulation of acetyl CoA, resulting in ketosis. Affected infants have serious neurological problems and rarely survive. A less severe variant of the disease is associated with low residual activity of pyruvate carboxylase. 

How is oxaloacetate replenished Mammals lack the enzymes for the net conversion of acetyl CoA into oxaloacetate or any other citric acid cycle intermediate. Rather, oxaloacetate is formed by the carboxylation of pyruvate, in a reaction catalyzed by the biotin-dependent enzyme pyruvate carboxylase. 

The acetyl CoA formed in fatty acid oxidation enters the citric acid cycle only if fat and carbohydrate degradation are appropriately balanced. The reason is that the entry of acetyl CoA into the citric acid cycle depends on the availability of oxaloacetate for the formation of citrate, but the concentration of oxaloacetate is lowered if carbohydrate is unavailable or improperly utilized. Recall that oxaloacetate is normally formed from pyruvate, the product of glycolysis, by pyruvate carboxylase (Section 16.3.1). This is the molecular basis of the adage that fats burn in the flame of carbohydrates. 

A third fate of pyruvate is its carboxylation to oxaloacetate inside mitochondria, the first step in gluconeogenesis. This reaction and the subsequent conversion of oxaloacetate into phosphoenolpyruvate bypass an irreversible step of glycolysis and hence enable glucose to be synthesized from pyruvate. The carboxylation of pyruvate is also important for replenishing intermediates of the citric acid cycle. Acetyl CoA activates pyruvate carboxylase, enhancing the synthesis of oxaloacetate, when the citric acid cycle is slowed by a paucity of this intermediate. 

In order for pyruvate carboxylase to be ready to function, it requires biotin. Mg", and Mn" ". It is allosterically activated by acetyl CoA. The biotin is not carboxylated until acetyl CoA binds the enzyme. By this means, high levels of acetyl CoA signal the need for more oxaloacetate. When ATP levels are high, the oxaloacetate is consumed in gluconeogenesis. When ATP levels are low, the oxaloacetate enters the citric acid cycle. Gluconeogenesis only occurs in the liver and kidneys. 

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