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Hub AI
Purine nucleotide cycle AI simulator
(@Purine nucleotide cycle_simulator)
Hub AI
Purine nucleotide cycle AI simulator
(@Purine nucleotide cycle_simulator)
Purine nucleotide cycle
The Purine Nucleotide Cycle is a metabolic pathway in protein metabolism requiring the amino acids aspartate and glutamate. The cycle is used to regulate the levels of adenine nucleotides, in which ammonia and fumarate are generated. AMP converts into IMP and the byproduct ammonia. IMP converts to S-AMP (adenylosuccinate), which then converts to AMP and the byproduct fumarate. The fumarate goes on to produce ATP (energy) via oxidative phosphorylation as it enters the Krebs cycle and then the electron transport chain. Lowenstein first described this pathway and outlined its importance in processes including amino acid catabolism and regulation of flux through glycolysis and the Krebs cycle.
AMP is produced after strenuous muscle contraction when the ATP reservoir is low (ADP > ATP) by the adenylate kinase (myokinase) reaction. AMP is also produced from adenine and adenosine directly; however, AMP can be produced through less direct metabolic pathways, such as de novo synthesis of IMP or through salvage pathways of guanine (a purine) and any of the purine nucleotides and nucleosides. IMP is synthesized de novo from glucose through the pentose phosphate pathway which produces ribose 5-P, which then converts to PRPP that with the amino acids glycine, glutamine, and aspartate (see Purine metabolism) can be further converted into IMP.
The cycle comprises three enzyme-catalysed reactions. The first stage is the deamination of the purine nucleotide adenosine monophosphate (AMP) to form inosine monophosphate (IMP), catalysed by the enzyme AMP deaminase:
The second stage is the formation of adenylosuccinate from IMP and the amino acid aspartate, which is coupled to the energetically favourable hydrolysis of GTP, and catalysed by the enzyme adenylosuccinate synthetase:
Finally, adenylosuccinate is cleaved by the enzyme adenylosuccinate lyase to release fumarate and regenerate the starting material of AMP:
A recent study showed that activation of HIF-1α allows cardiomyocytes to sustain mitochondrial membrane potential during anoxic stress by utilizing fumarate produced by adenylosuccinate lyase as an alternate terminal electron acceptor in place of oxygen. This mechanism should help provide protection in the ischemic heart.
The purine nucleotide cycle occurs in the cytosol (intracellular fluid) of the sarcoplasm of skeletal muscle, and in the myocyte's cytosolic compartment of the cytoplasm of cardiac and smooth muscle. The cycle occurs when ATP reservoirs run low (ADP > ATP), such as strenuous exercise, fasting or starvation.
Proteins catabolize into amino acids, and amino acids are precursors for purines, nucleotides and nucleosides which are used in the purine nucleotide cycle. The amino acid glutamate is used to neutralize the ammonia produced when AMP is converted into IMP. Another amino acid, aspartate, is used along with IMP to produce S-AMP in the cycle. Skeletal muscle contains amino acids for use in catabolism, known as the free amino acid pool; however, inadequate carbohydrate supply and/or strenuous exercise requires protein catabolism to sustain the free amino acids.
Purine nucleotide cycle
The Purine Nucleotide Cycle is a metabolic pathway in protein metabolism requiring the amino acids aspartate and glutamate. The cycle is used to regulate the levels of adenine nucleotides, in which ammonia and fumarate are generated. AMP converts into IMP and the byproduct ammonia. IMP converts to S-AMP (adenylosuccinate), which then converts to AMP and the byproduct fumarate. The fumarate goes on to produce ATP (energy) via oxidative phosphorylation as it enters the Krebs cycle and then the electron transport chain. Lowenstein first described this pathway and outlined its importance in processes including amino acid catabolism and regulation of flux through glycolysis and the Krebs cycle.
AMP is produced after strenuous muscle contraction when the ATP reservoir is low (ADP > ATP) by the adenylate kinase (myokinase) reaction. AMP is also produced from adenine and adenosine directly; however, AMP can be produced through less direct metabolic pathways, such as de novo synthesis of IMP or through salvage pathways of guanine (a purine) and any of the purine nucleotides and nucleosides. IMP is synthesized de novo from glucose through the pentose phosphate pathway which produces ribose 5-P, which then converts to PRPP that with the amino acids glycine, glutamine, and aspartate (see Purine metabolism) can be further converted into IMP.
The cycle comprises three enzyme-catalysed reactions. The first stage is the deamination of the purine nucleotide adenosine monophosphate (AMP) to form inosine monophosphate (IMP), catalysed by the enzyme AMP deaminase:
The second stage is the formation of adenylosuccinate from IMP and the amino acid aspartate, which is coupled to the energetically favourable hydrolysis of GTP, and catalysed by the enzyme adenylosuccinate synthetase:
Finally, adenylosuccinate is cleaved by the enzyme adenylosuccinate lyase to release fumarate and regenerate the starting material of AMP:
A recent study showed that activation of HIF-1α allows cardiomyocytes to sustain mitochondrial membrane potential during anoxic stress by utilizing fumarate produced by adenylosuccinate lyase as an alternate terminal electron acceptor in place of oxygen. This mechanism should help provide protection in the ischemic heart.
The purine nucleotide cycle occurs in the cytosol (intracellular fluid) of the sarcoplasm of skeletal muscle, and in the myocyte's cytosolic compartment of the cytoplasm of cardiac and smooth muscle. The cycle occurs when ATP reservoirs run low (ADP > ATP), such as strenuous exercise, fasting or starvation.
Proteins catabolize into amino acids, and amino acids are precursors for purines, nucleotides and nucleosides which are used in the purine nucleotide cycle. The amino acid glutamate is used to neutralize the ammonia produced when AMP is converted into IMP. Another amino acid, aspartate, is used along with IMP to produce S-AMP in the cycle. Skeletal muscle contains amino acids for use in catabolism, known as the free amino acid pool; however, inadequate carbohydrate supply and/or strenuous exercise requires protein catabolism to sustain the free amino acids.
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