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Gluconeogenesis

December 02, 2023

Not to be confused with Glycogenesis, Glyceroneogenesis, Glycogenolysis, or Glycolysis.

Gluconeogenesis (GNG) is a metabolic pathway that results in the biosynthesis of glucose from certain non-carbohydrate carbon substrates. It is a ubiquitous process, present in plants, animals, fungi, bacteria, and other microorganisms.[1] In vertebrates, gluconeogenesis occurs mainly in the liver and, to a lesser extent, in the cortex of the kidneys. It is one of two primary mechanisms – the other being degradation of glycogen (glycogenolysis) – used by humans and many other animals to maintain blood sugar levels, avoiding low levels (hypoglycemia).[2] In ruminants, because dietary carbohydrates tend to be metabolized by rumen organisms, gluconeogenesis occurs regardless of fasting, low-carbohydrate diets, exercise, etc.[3] In many other animals, the process occurs during periods of fasting, starvation, low-carbohydrate diets, or intense exercise.

In humans, substrates for gluconeogenesis may come from any non-carbohydrate sources that can be converted to pyruvate or intermediates of glycolysis (see figure). For the breakdown of proteins, these substrates include glucogenic amino acids (although not ketogenic amino acids); from breakdown of lipids (such as triglycerides), they include glycerol, odd-chain fatty acids (although not even-chain fatty acids, see below); and from other parts of metabolism that includes lactate from the Cori cycle. Under conditions of prolonged fasting, acetone derived from ketone bodies can also serve as a substrate, providing a pathway from fatty acids to glucose.[4] Although most gluconeogenesis occurs in the liver, the relative contribution of gluconeogenesis by the kidney is increased in diabetes and prolonged fasting.[5]

The gluconeogenesis pathway is highly endergonic until it is coupled to the hydrolysis of ATP or GTP, effectively making the process exergonic. For example, the pathway leading from pyruvate to glucose-6-phosphate requires 4 molecules of ATP and 2 molecules of GTP to proceed spontaneously. These ATPs are supplied from fatty acid catabolism via beta oxidation.[6]

Precursors edit

 
Catabolism of proteinogenic amino acids. Amino acids are classified according to the abilities of their products to enter gluconeogenesis:[7]

In humans the main gluconeogenic precursors are lactate, glycerol (which is a part of the triglyceride molecule), alanine and glutamine. Altogether, they account for over 90% of the overall gluconeogenesis.[8] Other glucogenic amino acids and all citric acid cycle intermediates (through conversion to oxaloacetate) can also function as substrates for gluconeogenesis.[9] Generally, human consumption of gluconeogenic substrates in food does not result in increased gluconeogenesis.[10]

In ruminants, propionate is the principal gluconeogenic substrate.[3][11] In nonruminants, including human beings, propionate arises from the β-oxidation of odd-chain and branched-chain fatty acids, and is a (relatively minor) substrate for gluconeogenesis.[12][13]

Lactate is transported back to the liver where it is converted into pyruvate by the Cori cycle using the enzyme lactate dehydrogenase. Pyruvate, the first designated substrate of the gluconeogenic pathway, can then be used to generate glucose.[9] Transamination or deamination of amino acids facilitates entering of their carbon skeleton into the cycle directly (as pyruvate or oxaloacetate), or indirectly via the citric acid cycle. The contribution of Cori cycle lactate to overall glucose production increases with fasting duration.[14] Specifically, after 12, 20, and 40 hours of fasting by human volunteers, the contribution of Cori cycle lactate to gluconeogenesis was 41%, 71%, and 92%, respectively.[14]

Whether even-chain fatty acids can be converted into glucose in animals has been a longstanding question in biochemistry.[15] Odd-chain fatty acids can be oxidized to yield acetyl-CoA and propionyl-CoA, the latter serving as a precursor to succinyl-CoA, which can be converted to oxaloacetate and enter into gluconeogenesis. In contrast, even-chain fatty acids are oxidized to yield only acetyl-CoA, whose entry into gluconeogenesis requires the presence of a glyoxylate cycle (also known as glyoxylate shunt) to produce four-carbon dicarboxylic acid precursors.[9] The glyoxylate shunt comprises two enzymes, malate synthase and isocitrate lyase, and is present in fungi, plants, and bacteria. Despite some reports of glyoxylate shunt enzymatic activities detected in animal tissues, genes encoding both enzymatic functions have only been found in nematodes, in which they exist as a single bi-functional enzyme.[16][17] Genes coding for malate synthase alone (but not isocitrate lyase) have been identified in other animals including arthropods, echinoderms, and even some vertebrates. Mammals found to possess the malate synthase gene include monotremes (platypus) and marsupials (opossum), but not placental mammals.[17]

The existence of the glyoxylate cycle in humans has not been established, and it is widely held that fatty acids cannot be converted to glucose in humans directly. Carbon-14 has been shown to end up in glucose when it is supplied in fatty acids,[18] but this can be expected from the incorporation of labelled atoms derived from acetyl-CoA into citric acid cycle intermediates which are interchangeable with those derived from other physiological sources, such as glucogenic amino acids.[15] In the absence of other glucogenic sources, the 2-carbon acetyl-CoA derived from the oxidation of fatty acids cannot produce a net yield of glucose via the citric acid cycle, since an equivalent two carbon atoms are released as carbon dioxide during the cycle. During ketosis, however, acetyl-CoA from fatty acids yields ketone bodies, including acetone, and up to ~60% of acetone may be oxidized in the liver to the pyruvate precursors acetol and methylglyoxal.[19][4] Thus ketone bodies derived from fatty acids could account for up to 11% of gluconeogenesis during starvation. Catabolism of fatty acids also produces energy in the form of ATP that is necessary for the gluconeogenesis pathway.

Location edit

In mammals, gluconeogenesis has been believed to be restricted to the liver,[20] the kidney,[20] the intestine,[21] and muscle,[22] but recent evidence indicates gluconeogenesis occurring in astrocytes of the brain.[23] These organs use somewhat different gluconeogenic precursors. The liver preferentially uses lactate, glycerol, and glucogenic amino acids (especially alanine) while the kidney preferentially uses lactate, glutamine and glycerol.[24][8] Lactate from the Cori cycle is quantitatively the largest source of substrate for gluconeogenesis, especially for the kidney.[8] The liver uses both glycogenolysis and gluconeogenesis to produce glucose, whereas the kidney only uses gluconeogenesis.[8] After a meal, the liver shifts to glycogen synthesis, whereas the kidney increases gluconeogenesis.[10] The intestine uses mostly glutamine and glycerol.[21]

Propionate is the principal substrate for gluconeogenesis in the ruminant liver, and the ruminant liver may make increased use of gluconeogenic amino acids (e.g., alanine) when glucose demand is increased.[25] The capacity of liver cells to use lactate for gluconeogenesis declines from the preruminant stage to the ruminant stage in calves and lambs.[26] In sheep kidney tissue, very high rates of gluconeogenesis from propionate have been observed.[26]

In all species, the formation of oxaloacetate from pyruvate and TCA cycle intermediates is restricted to the mitochondrion, and the enzymes that convert Phosphoenolpyruvic acid (PEP) to glucose-6-phosphate are found in the cytosol.[27] The location of the enzyme that links these two parts of gluconeogenesis by converting oxaloacetate to PEP – PEP carboxykinase (PEPCK) – is variable by species: it can be found entirely within the mitochondria, entirely within the cytosol, or dispersed evenly between the two, as it is in humans.[27] Transport of PEP across the mitochondrial membrane is accomplished by dedicated transport proteins; however no such proteins exist for oxaloacetate.[27] Therefore, in species that lack intra-mitochondrial PEPCK, oxaloacetate must be converted into malate or aspartate, exported from the mitochondrion, and converted back into oxaloacetate in order to allow gluconeogenesis to continue.[27]

 
Gluconeogenesis pathway with key molecules and enzymes. Many steps are the opposite of those found in the glycolysis.

Pathway edit

Gluconeogenesis is a pathway consisting of a series of eleven enzyme-catalyzed reactions. The pathway will begin in either the liver or kidney, in the mitochondria or cytoplasm of those cells, this being dependent on the substrate being used. Many of the reactions are the reverse of steps found in glycolysis.[citation needed]

  • Gluconeogenesis begins in the mitochondria with the formation of oxaloacetate by the carboxylation of pyruvate. This reaction also requires one molecule of ATP, and is catalyzed by pyruvate carboxylase. This enzyme is stimulated by high levels of acetyl-CoA (produced in β-oxidation in the liver) and inhibited by high levels of ADP and glucose.
  • Oxaloacetate is reduced to malate using NADH, a step required for its transportation out of the mitochondria.
  • Malate is oxidized to oxaloacetate using NAD+ in the cytosol, where the remaining steps of gluconeogenesis take place.
  • Oxaloacetate is decarboxylated and then phosphorylated to form phosphoenolpyruvate using the enzyme PEPCK. A molecule of GTP is hydrolyzed to GDP during this reaction.
  • The next steps in the reaction are the same as reversed glycolysis. However, fructose 1,6-bisphosphatase converts fructose 1,6-bisphosphate to fructose 6-phosphate, using one water molecule and releasing one phosphate (in glycolysis, phosphofructokinase 1 converts F6P and ATP to F1,6BP and ADP). This is also the rate-limiting step of gluconeogenesis.
  • Glucose-6-phosphate is formed from fructose 6-phosphate by phosphoglucoisomerase (the reverse of step 2 in glycolysis). Glucose-6-phosphate can be used in other metabolic pathways or dephosphorylated to free glucose. Whereas free glucose can easily diffuse in and out of the cell, the phosphorylated form (glucose-6-phosphate) is locked in the cell, a mechanism by which intracellular glucose levels are controlled by cells.
  • The final gluconeogenesis, the formation of glucose, occurs in the lumen of the endoplasmic reticulum, where glucose-6-phosphate is hydrolyzed by glucose-6-phosphatase to produce glucose and release an inorganic phosphate. Like two steps prior, this step is not a simple reversal of glycolysis, in which hexokinase catalyzes the conversion of glucose and ATP into G6P and ADP. Glucose is shuttled into the cytoplasm by glucose transporters located in the endoplasmic reticulum's membrane.

Regulation edit

While most steps in gluconeogenesis are the reverse of those found in glycolysis, three regulated and strongly endergonic reactions are replaced with more kinetically favorable reactions. Hexokinase/glucokinase, phosphofructokinase, and pyruvate kinase enzymes of glycolysis are replaced with glucose-6-phosphatase, fructose-1,6-bisphosphatase, and PEP carboxykinase/pyruvate carboxylase. These enzymes are typically regulated by similar molecules, but with opposite results. For example, acetyl CoA and citrate activate gluconeogenesis enzymes (pyruvate carboxylase and fructose-1,6-bisphosphatase, respectively), while at the same time inhibiting the glycolytic enzyme pyruvate kinase. This system of reciprocal control allow glycolysis and gluconeogenesis to inhibit each other and prevents a futile cycle of synthesizing glucose to only break it down. Pyruvate kinase can be also bypassed by 86 pathways[28] not related to gluconeogenesis, for the purpose of forming pyruvate and subsequently lactate; some of these pathways use carbon atoms originated from glucose.

The majority of the enzymes responsible for gluconeogenesis are found in the cytosol; the exceptions are mitochondrial pyruvate carboxylase and, in animals, phosphoenolpyruvate carboxykinase. The latter exists as an isozyme located in both the mitochondrion and the cytosol.[29] The rate of gluconeogenesis is ultimately controlled by the action of a key enzyme, fructose-1,6-bisphosphatase, which is also regulated through signal transduction by cAMP and its phosphorylation.

Global control of gluconeogenesis is mediated by glucagon (released when blood glucose is low); it triggers phosphorylation of enzymes and regulatory proteins by Protein Kinase A (a cyclic AMP regulated kinase) resulting in inhibition of glycolysis and stimulation of gluconeogenesis. Insulin counteracts glucagon by inhibiting gluconeogenesis. Type 2 diabetes is marked by excess glucagon and insulin resistance from the body.[30] Insulin can no longer inhibit the gene expression of enzymes such as PEPCK which leads to increased levels of hyperglycemia in the body.[31] The anti-diabetic drug metformin reduces blood glucose primarily through inhibition of gluconeogenesis, overcoming the failure of insulin to inhibit gluconeogenesis due to insulin resistance.[32]

Studies have shown that the absence of hepatic glucose production has no major effect on the control of fasting plasma glucose concentration. Compensatory induction of gluconeogenesis occurs in the kidneys and intestine, driven by glucagon, glucocorticoids, and acidosis.[33]

Insulin resistance edit

In the liver, the FOX protein FOXO6 normally promotes gluconeogenesis in the fasted state, but insulin blocks FOXO6 upon feeding.[34] In a condition of insulin resistance, insulin fails to block FOXO6 resulting in continued gluconeogenesis even upon feeding, resulting in high blood glucose (hyperglycemia).[34]

Insulin resistance is a common feature of metabolic syndrome and type 2 diabetes. For this reason gluconeogenesis is a target of therapy for type 2 diabetes, such as the antidiabetic drug metformin, which inhibits gluconeogenic glucose formation, and stimulates glucose uptake by cells.[35]

Origins edit

Gluconeogenesis is considered one of the most ancient anabolic pathways and is likely to have been exhibited in the last universal common ancestor.[36] Rafael F. Say and Georg Fuchs stated in 2010 that "all archaeal groups as well as the deeply branching bacterial lineages contain a bifunctional fructose 1,6-bisphosphate (FBP) aldolase/phosphatase with both FBP aldolase and FBP phosphatase activity. This enzyme is missing in most other Bacteria and in Eukaryota, and is heat-stabile even in mesophilic marine Crenarchaeota". It is proposed that fructose 1,6-bisphosphate aldolase/phosphatase was an ancestral gluconeogenic enzyme and had preceded glycolysis.[37] But the chemical mechanisms between gluconeogenesis and glycolysis, whether it is anabolic or catabolic, are similar, suggesting they both originated at the same time. Fructose 1,6-bisphosphate is shown to be nonenzymatically synthesized continuously within a freezing solution. The synthesis is accelerated in the presence of amino acids such as glycine and lysine implying that the first anabolic enzymes were amino acids. The prebiotic reactions in gluconeogenesis can also proceed nonenzymatically at dehydration-desiccation cycles. Such chemistry could have occurred in hydrothermal environments, including temperature gradients and cycling of freezing and thawing. Mineral surfaces might have played a role in the phosphorylation of metabolic intermediates from gluconeogenesis and have to been shown to produce tetrose, hexose phosphates, and pentose from formaldehyde, glyceraldehyde, and glycolaldehyde.[38][39][40]

See also edit

References edit

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External links edit

  • Overview at indstate.edu
  • The chemical logic behind gluconeogenesis
  • metpath: Interactive representation of gluconeogenesis

December 02, 2023
gluconeogenesis, confused, with, glycogenesis, glyceroneogenesis, glycogenolysis, glycolysis, metabolic, pathway, that, results, biosynthesis, glucose, from, certain, carbohydrate, carbon, substrates, ubiquitous, process, present, plants, animals, fungi, bacte. Not to be confused with Glycogenesis Glyceroneogenesis Glycogenolysis or Glycolysis Gluconeogenesis GNG is a metabolic pathway that results in the biosynthesis of glucose from certain non carbohydrate carbon substrates It is a ubiquitous process present in plants animals fungi bacteria and other microorganisms 1 In vertebrates gluconeogenesis occurs mainly in the liver and to a lesser extent in the cortex of the kidneys It is one of two primary mechanisms the other being degradation of glycogen glycogenolysis used by humans and many other animals to maintain blood sugar levels avoiding low levels hypoglycemia 2 In ruminants because dietary carbohydrates tend to be metabolized by rumen organisms gluconeogenesis occurs regardless of fasting low carbohydrate diets exercise etc 3 In many other animals the process occurs during periods of fasting starvation low carbohydrate diets or intense exercise In humans substrates for gluconeogenesis may come from any non carbohydrate sources that can be converted to pyruvate or intermediates of glycolysis see figure For the breakdown of proteins these substrates include glucogenic amino acids although not ketogenic amino acids from breakdown of lipids such as triglycerides they include glycerol odd chain fatty acids although not even chain fatty acids see below and from other parts of metabolism that includes lactate from the Cori cycle Under conditions of prolonged fasting acetone derived from ketone bodies can also serve as a substrate providing a pathway from fatty acids to glucose 4 Although most gluconeogenesis occurs in the liver the relative contribution of gluconeogenesis by the kidney is increased in diabetes and prolonged fasting 5 The gluconeogenesis pathway is highly endergonic until it is coupled to the hydrolysis of ATP or GTP effectively making the process exergonic For example the pathway leading from pyruvate to glucose 6 phosphate requires 4 molecules of ATP and 2 molecules of GTP to proceed spontaneously These ATPs are supplied from fatty acid catabolism via beta oxidation 6 Contents 1 Precursors 2 Location 3 Pathway 4 Regulation 5 Insulin resistance 6 Origins 7 See also 8 References 9 External linksPrecursors edit nbsp Catabolism of proteinogenic amino acids Amino acids are classified according to the abilities of their products to enter gluconeogenesis 7 Glucogenic amino acids have this abilityKetogenic amino acids do not These products may still be used for ketogenesis or lipid synthesis Some amino acids are catabolized into both glucogenic and ketogenic products In humans the main gluconeogenic precursors are lactate glycerol which is a part of the triglyceride molecule alanine and glutamine Altogether they account for over 90 of the overall gluconeogenesis 8 Other glucogenic amino acids and all citric acid cycle intermediates through conversion to oxaloacetate can also function as substrates for gluconeogenesis 9 Generally human consumption of gluconeogenic substrates in food does not result in increased gluconeogenesis 10 In ruminants propionate is the principal gluconeogenic substrate 3 11 In nonruminants including human beings propionate arises from the b oxidation of odd chain and branched chain fatty acids and is a relatively minor substrate for gluconeogenesis 12 13 Lactate is transported back to the liver where it is converted into pyruvate by the Cori cycle using the enzyme lactate dehydrogenase Pyruvate the first designated substrate of the gluconeogenic pathway can then be used to generate glucose 9 Transamination or deamination of amino acids facilitates entering of their carbon skeleton into the cycle directly as pyruvate or oxaloacetate or indirectly via the citric acid cycle The contribution of Cori cycle lactate to overall glucose production increases with fasting duration 14 Specifically after 12 20 and 40 hours of fasting by human volunteers the contribution of Cori cycle lactate to gluconeogenesis was 41 71 and 92 respectively 14 Whether even chain fatty acids can be converted into glucose in animals has been a longstanding question in biochemistry 15 Odd chain fatty acids can be oxidized to yield acetyl CoA and propionyl CoA the latter serving as a precursor to succinyl CoA which can be converted to oxaloacetate and enter into gluconeogenesis In contrast even chain fatty acids are oxidized to yield only acetyl CoA whose entry into gluconeogenesis requires the presence of a glyoxylate cycle also known as glyoxylate shunt to produce four carbon dicarboxylic acid precursors 9 The glyoxylate shunt comprises two enzymes malate synthase and isocitrate lyase and is present in fungi plants and bacteria Despite some reports of glyoxylate shunt enzymatic activities detected in animal tissues genes encoding both enzymatic functions have only been found in nematodes in which they exist as a single bi functional enzyme 16 17 Genes coding for malate synthase alone but not isocitrate lyase have been identified in other animals including arthropods echinoderms and even some vertebrates Mammals found to possess the malate synthase gene include monotremes platypus and marsupials opossum but not placental mammals 17 The existence of the glyoxylate cycle in humans has not been established and it is widely held that fatty acids cannot be converted to glucose in humans directly Carbon 14 has been shown to end up in glucose when it is supplied in fatty acids 18 but this can be expected from the incorporation of labelled atoms derived from acetyl CoA into citric acid cycle intermediates which are interchangeable with those derived from other physiological sources such as glucogenic amino acids 15 In the absence of other glucogenic sources the 2 carbon acetyl CoA derived from the oxidation of fatty acids cannot produce a net yield of glucose via the citric acid cycle since an equivalent two carbon atoms are released as carbon dioxide during the cycle During ketosis however acetyl CoA from fatty acids yields ketone bodies including acetone and up to 60 of acetone may be oxidized in the liver to the pyruvate precursors acetol and methylglyoxal 19 4 Thus ketone bodies derived from fatty acids could account for up to 11 of gluconeogenesis during starvation Catabolism of fatty acids also produces energy in the form of ATP that is necessary for the gluconeogenesis pathway Location editIn mammals gluconeogenesis has been believed to be restricted to the liver 20 the kidney 20 the intestine 21 and muscle 22 but recent evidence indicates gluconeogenesis occurring in astrocytes of the brain 23 These organs use somewhat different gluconeogenic precursors The liver preferentially uses lactate glycerol and glucogenic amino acids especially alanine while the kidney preferentially uses lactate glutamine and glycerol 24 8 Lactate from the Cori cycle is quantitatively the largest source of substrate for gluconeogenesis especially for the kidney 8 The liver uses both glycogenolysis and gluconeogenesis to produce glucose whereas the kidney only uses gluconeogenesis 8 After a meal the liver shifts to glycogen synthesis whereas the kidney increases gluconeogenesis 10 The intestine uses mostly glutamine and glycerol 21 Propionate is the principal substrate for gluconeogenesis in the ruminant liver and the ruminant liver may make increased use of gluconeogenic amino acids e g alanine when glucose demand is increased 25 The capacity of liver cells to use lactate for gluconeogenesis declines from the preruminant stage to the ruminant stage in calves and lambs 26 In sheep kidney tissue very high rates of gluconeogenesis from propionate have been observed 26 In all species the formation of oxaloacetate from pyruvate and TCA cycle intermediates is restricted to the mitochondrion and the enzymes that convert Phosphoenolpyruvic acid PEP to glucose 6 phosphate are found in the cytosol 27 The location of the enzyme that links these two parts of gluconeogenesis by converting oxaloacetate to PEP PEP carboxykinase PEPCK is variable by species it can be found entirely within the mitochondria entirely within the cytosol or dispersed evenly between the two as it is in humans 27 Transport of PEP across the mitochondrial membrane is accomplished by dedicated transport proteins however no such proteins exist for oxaloacetate 27 Therefore in species that lack intra mitochondrial PEPCK oxaloacetate must be converted into malate or aspartate exported from the mitochondrion and converted back into oxaloacetate in order to allow gluconeogenesis to continue 27 nbsp Gluconeogenesis pathway with key molecules and enzymes Many steps are the opposite of those found in the glycolysis Pathway editGluconeogenesis is a pathway consisting of a series of eleven enzyme catalyzed reactions The pathway will begin in either the liver or kidney in the mitochondria or cytoplasm of those cells this being dependent on the substrate being used Many of the reactions are the reverse of steps found in glycolysis citation needed Gluconeogenesis begins in the mitochondria with the formation of oxaloacetate by the carboxylation of pyruvate This reaction also requires one molecule of ATP and is catalyzed by pyruvate carboxylase This enzyme is stimulated by high levels of acetyl CoA produced in b oxidation in the liver and inhibited by high levels of ADP and glucose Oxaloacetate is reduced to malate using NADH a step required for its transportation out of the mitochondria Malate is oxidized to oxaloacetate using NAD in the cytosol where the remaining steps of gluconeogenesis take place Oxaloacetate is decarboxylated and then phosphorylated to form phosphoenolpyruvate using the enzyme PEPCK A molecule of GTP is hydrolyzed to GDP during this reaction The next steps in the reaction are the same as reversed glycolysis However fructose 1 6 bisphosphatase converts fructose 1 6 bisphosphate to fructose 6 phosphate using one water molecule and releasing one phosphate in glycolysis phosphofructokinase 1 converts F6P and ATP to F1 6BP and ADP This is also the rate limiting step of gluconeogenesis Glucose 6 phosphate is formed from fructose 6 phosphate by phosphoglucoisomerase the reverse of step 2 in glycolysis Glucose 6 phosphate can be used in other metabolic pathways or dephosphorylated to free glucose Whereas free glucose can easily diffuse in and out of the cell the phosphorylated form glucose 6 phosphate is locked in the cell a mechanism by which intracellular glucose levels are controlled by cells The final gluconeogenesis the formation of glucose occurs in the lumen of the endoplasmic reticulum where glucose 6 phosphate is hydrolyzed by glucose 6 phosphatase to produce glucose and release an inorganic phosphate Like two steps prior this step is not a simple reversal of glycolysis in which hexokinase catalyzes the conversion of glucose and ATP into G6P and ADP Glucose is shuttled into the cytoplasm by glucose transporters located in the endoplasmic reticulum s membrane Metabolism of common monosaccharides including glycolysis gluconeogenesis glycogenesis and glycogenolysis nbsp Regulation editWhile most steps in gluconeogenesis are the reverse of those found in glycolysis three regulated and strongly endergonic reactions are replaced with more kinetically favorable reactions Hexokinase glucokinase phosphofructokinase and pyruvate kinase enzymes of glycolysis are replaced with glucose 6 phosphatase fructose 1 6 bisphosphatase and PEP carboxykinase pyruvate carboxylase These enzymes are typically regulated by similar molecules but with opposite results For example acetyl CoA and citrate activate gluconeogenesis enzymes pyruvate carboxylase and fructose 1 6 bisphosphatase respectively while at the same time inhibiting the glycolytic enzyme pyruvate kinase This system of reciprocal control allow glycolysis and gluconeogenesis to inhibit each other and prevents a futile cycle of synthesizing glucose to only break it down Pyruvate kinase can be also bypassed by 86 pathways 28 not related to gluconeogenesis for the purpose of forming pyruvate and subsequently lactate some of these pathways use carbon atoms originated from glucose The majority of the enzymes responsible for gluconeogenesis are found in the cytosol the exceptions are mitochondrial pyruvate carboxylase and in animals phosphoenolpyruvate carboxykinase The latter exists as an isozyme located in both the mitochondrion and the cytosol 29 The rate of gluconeogenesis is ultimately controlled by the action of a key enzyme fructose 1 6 bisphosphatase which is also regulated through signal transduction by cAMP and its phosphorylation Global control of gluconeogenesis is mediated by glucagon released when blood glucose is low it triggers phosphorylation of enzymes and regulatory proteins by Protein Kinase A a cyclic AMP regulated kinase resulting in inhibition of glycolysis and stimulation of gluconeogenesis Insulin counteracts glucagon by inhibiting gluconeogenesis Type 2 diabetes is marked by excess glucagon and insulin resistance from the body 30 Insulin can no longer inhibit the gene expression of enzymes such as PEPCK which leads to increased levels of hyperglycemia in the body 31 The anti diabetic drug metformin reduces blood glucose primarily through inhibition of gluconeogenesis overcoming the failure of insulin to inhibit gluconeogenesis due to insulin resistance 32 Studies have shown that the absence of hepatic glucose production has no major effect on the control of fasting plasma glucose concentration Compensatory induction of gluconeogenesis occurs in the kidneys and intestine driven by glucagon glucocorticoids and acidosis 33 Insulin resistance editIn the liver the FOX protein FOXO6 normally promotes gluconeogenesis in the fasted state but insulin blocks FOXO6 upon feeding 34 In a condition of insulin resistance insulin fails to block FOXO6 resulting in continued gluconeogenesis even upon feeding resulting in high blood glucose hyperglycemia 34 Insulin resistance is a common feature of metabolic syndrome and type 2 diabetes For this reason gluconeogenesis is a target of therapy for type 2 diabetes such as the antidiabetic drug metformin which inhibits gluconeogenic glucose formation and stimulates glucose uptake by cells 35 Origins editGluconeogenesis is considered one of the most ancient anabolic pathways and is likely to have been exhibited in the last universal common ancestor 36 Rafael F Say and Georg Fuchs stated in 2010 that all archaeal groups as well as the deeply branching bacterial lineages contain a bifunctional fructose 1 6 bisphosphate FBP aldolase phosphatase with both FBP aldolase and FBP phosphatase activity This enzyme is missing in most other Bacteria and in Eukaryota and is heat stabile even in mesophilic marine Crenarchaeota It is proposed that fructose 1 6 bisphosphate aldolase phosphatase was an ancestral gluconeogenic enzyme and had preceded glycolysis 37 But the chemical mechanisms between gluconeogenesis and glycolysis whether it is anabolic or catabolic are similar suggesting they both originated at the same time Fructose 1 6 bisphosphate is shown to be nonenzymatically synthesized continuously within a freezing solution The synthesis is accelerated in the presence of amino acids such as glycine and lysine implying that the first anabolic enzymes were amino acids The prebiotic reactions in gluconeogenesis can also proceed nonenzymatically at dehydration desiccation cycles Such chemistry could have occurred in hydrothermal environments including temperature gradients and cycling of freezing and thawing Mineral surfaces might have played a role in the phosphorylation of metabolic intermediates from gluconeogenesis and have to been shown to produce tetrose hexose phosphates and pentose from formaldehyde glyceraldehyde and glycolaldehyde 38 39 40 See also editBioenergeticsReferences edit Nelson DL Cox MM 2000 Lehninger Principles of Biochemistry USA Worth Publishers p 724 ISBN 978 1 57259 153 0 Silva P The Chemical Logic Behind Gluconeogenesis Archived from the original on August 26 2009 Retrieved September 8 2009 a b Beitz DC 2004 Carbohydrate metabolism In Reese WO ed Dukes Physiology of Domestic Animals 12th ed Cornell Univ Press pp 501 15 ISBN 978 0801442384 a b Kaleta C de Figueiredo LF Werner S Guthke R Ristow M Schuster S July 2011 In silico evidence for gluconeogenesis from fatty acids in humans PLOS Computational Biology 7 7 e1002116 Bibcode 2011PLSCB 7E2116K doi 10 1371 journal pcbi 1002116 PMC 3140964 PMID 21814506 a href Template Cite journal html title Template Cite journal cite journal a CS1 maint unflagged free DOI link Swe MT Pongchaidecha A Chatsudthipong V Chattipakorn N Lungkaphin A June 2019 Molecular signaling mechanisms of renal gluconeogenesis in nondiabetic and diabetic conditions Journal of Cellular Physiology 234 6 8134 8151 doi 10 1002 jcp 27598 PMID 30370538 S2CID 53097552 Rodwell V 2015 Harper s illustrated Biochemistry 30th edition USA McGraw Hill p 193 ISBN 978 0 07 182537 5 Ferrier DR Champe PC Harvey RA 1 August 2004 20 Amino Acid Degradation and Synthesis Biochemistry Lippincott s Illustrated Reviews Hagerstwon MD Lippincott Williams amp Wilkins ISBN 978 0 7817 2265 0 a b c d Gerich JE Meyer C Woerle HJ Stumvoll M February 2001 Renal gluconeogenesis its importance in human glucose homeostasis Diabetes Care 24 2 382 91 doi 10 2337 diacare 24 2 382 PMID 11213896 a b c Garrett RH Grisham CM 2002 Principles of Biochemistry with a Human Focus USA Brooks Cole Thomson Learning pp 578 585 ISBN 978 0 03 097369 7 a b Nuttall FQ Ngo A Gannon MC September 2008 Regulation of hepatic glucose production and the role of gluconeogenesis in humans is the rate of gluconeogenesis constant Diabetes Metabolism Research and Reviews 24 6 438 458 doi 10 1002 dmrr 863 PMID 18561209 S2CID 24330397 Van Soest PJ 1994 Nutritional Ecology of the Ruminant 2nd ed Cornell Univ Press ISBN 978 1501732355 Rodwell VW Bender DA Botham KM Kennelly PJ Weil PA 2018 Harper s Illustrated Biochemistry 31st ed McGraw Hill Publishing Company Baynes J Dominiczak M 2014 Medical Biochemistry 4th ed Elsevier a b Katz J Tayek JA September 1998 Gluconeogenesis and the Cori cycle in 12 20 and 40 h fasted humans The American Journal of Physiology 275 3 E537 42 doi 10 1152 ajpendo 1998 275 3 E537 PMID 9725823 a b de Figueiredo LF Schuster S Kaleta C Fell DA January 2009 Can sugars be produced from fatty acids A test case for pathway analysis tools Bioinformatics 25 1 152 8 doi 10 1093 bioinformatics btn621 PMID 19117076 Liu F Thatcher JD Barral JM Epstein HF June 1995 Bifunctional glyoxylate cycle protein of Caenorhabditis elegans a developmentally regulated protein of intestine and muscle Developmental Biology 169 2 399 414 doi 10 1006 dbio 1995 1156 PMID 7781887 a b Kondrashov FA Koonin EV Morgunov IG Finogenova TV Kondrashova MN October 2006 Evolution of glyoxylate cycle enzymes in Metazoa evidence of multiple horizontal transfer events and pseudogene formation 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and ruminating bovine Journal of Animal Science 73 2 546 51 doi 10 2527 1995 732546x PMID 7601789 a b c d Voet D Voet J Pratt C 2008 Fundamentals of Biochemistry John Wiley amp Sons Inc p 556 ISBN 978 0 470 12930 2 Christos Chinopoulos 2020 From Glucose to Lactate and Transiting Intermediates Through Mitochondria Bypassing Pyruvate Kinase Considerations for Cells Exhibiting Dimeric PKM2 or Otherwise Inhibited Kinase Activity https www frontiersin org articles 10 3389 fphys 2020 543564 full Chakravarty K Cassuto H Reshef L Hanson RW 2005 Factors that control the tissue specific transcription of the gene for phosphoenolpyruvate carboxykinase C Critical Reviews in Biochemistry and Molecular Biology 40 3 129 54 doi 10 1080 10409230590935479 PMID 15917397 S2CID 633399 He L Sabet A Djedjos S Miller R Sun X Hussain MA et al May 2009 Metformin and insulin suppress hepatic gluconeogenesis through phosphorylation of CREB binding protein Cell 137 4 635 46 doi 10 1016 j cell 2009 03 016 PMC 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Origins Chemical Reviews 120 15 7708 7744 doi 10 1021 acs chemrev 0c00191 PMID 32687326 Messner CB Driscoll PC Piedrafita G De Volder MF Ralser M July 2017 Nonenzymatic gluconeogenesis like formation of fructose 1 6 bisphosphate in ice Proceedings of the National Academy of Sciences of the United States of America 114 28 7403 7407 doi 10 1073 pnas 1702274114 PMC 5514728 PMID 28652321 Ralser Markus 2018 08 30 An appeal to magic The discovery of a non enzymatic metabolism and its role in the origins of life The Biochemical Journal 475 16 2577 2592 doi 10 1042 BCJ20160866 ISSN 1470 8728 PMC 6117946 PMID 30166494 External links editOverview at indstate edu Interactive diagram at uakron edu The chemical logic behind gluconeogenesis metpath Interactive representation of gluconeogenesis Retrieved from https en wikipedia org w index php title Gluconeogenesis amp oldid 1186292295, wikipedia, wiki, book, books, library,

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