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Α-Ketoglutaric acid
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Α-Ketoglutaric acid
α-Ketoglutaric acid is an organic compound with the formula HO2CCO(CH2)2CO2H. A white, nontoxic solid, it is a common dicarboxylic acid. Relevant to its biological roles, it exists in water as its conjugate base α-ketoglutarate. It is also classified as a 2-ketocarboxylic acid. β-Ketoglutaric acid is an isomer. "Ketoglutaric acid" and "ketoglutarate", when not qualified as α or β, almost always refers respectively to α-ketoglutaric acid or α-ketoglutarate.
α-Ketoglutarate is an intermediate in the citric acid cycle, a cycle that supplies the energy to cells. It is also an intermediate in or product of several other metabolic pathways. These include its being a component of metabolic pathways that: make amino acids and in the process regulate the cellular levels of carbon, nitrogen, and ammonia; reduce the cellular levels of potentially toxic reactive oxygen species; and synthesize the neurotransmitter gamma-aminobutyric acid. It also acts as a direct stimulator of, or cofactor (i.e., required for but does not itself stimulate) for various cellular functions as defined in studies that are primarily preclinical (i.e., conducted in animal models of disease or on animal or human tissues). These studies have provided evidence that α-ketoglutarate contributes to regulating: kidney function; the benefits that resistance exercise has in reducing obesity, strengthening muscles, and preventing muscle atrophy; glucose tolerance as defined in glucose tolerance tests; aging and the development of changes that are associated with aging including old age-related disorders and diseases; the development and/or progression of certain types of cancer and inflammations; and the differentiation of immature T cells into mature T cells.
α-Ketoglutarate is a component of the citric acid cycle, a cyclical metabolic pathway located in the mitochondria. This cycle supplies the energy that cells need by sequentially metabolizing (indicated by →) citrate through seven intermediate metabolites and then converting the eighth intermediate metabolite, oxaloacetate, back to citrate:
In this cycle, the enzyme isocitrate dehydrogenase 3 converts isocitrate (isocitrate has 4 isomers of which only the (−)-d-threo-isomer is the naturally occurring isomer in the citric acid cycle.) to α-ketoglutarate which in the next step is converted to succinyl-CoA by the oxoglutarate dehydrogenase complex of enzymes.
Aside from the citric acid cycle, α-ketoglutarate is made by a) glutaminolysis in which the enzyme glutaminase removes the amino group from glutamine to form glutamate which is converted to α-ketoglutarate by any one of three enzymes, glutamate dehydrogenase, alanine transaminase, or aspartate transaminase (see The glutaminolytic pathways); and various pyridoxal phosphate-dependent transamination reactions mediated by, e.g., the alanine transaminase enzyme, in which glutamate is converted to α-Ketoglutarate by "donating" its −NH2 to other compounds (see transamination). Acting in these pathways, α-ketoglutarate contributes to the production of amino acids such as glutamine, proline, arginine, and lysine as well as the lowering of cellular carbon and nitrogen (i.e., N) levels; this prevents excessive levels of these two potentially toxic elements from accumulating in cells and tissues. The neurotoxin, ammonia (i.e., NH3), is also prevented form accumulating in tissues. In this metabolic pathway the −NH2 group on an amino acid is transferred to α-ketoglutarate; this forms the α-keto acid of the original amino acid and the amine-containing product of α-ketoglutarate, glutamate. The celllular glutamate passes into the circulation and is taken up by the liver where it delivers its acquired −NH2 group to the urea cycle. In effect, the latter pathway removes excess ammonia from the body in the form of urinary urea.
α-Ketoglutarate is one of the non-enzymatic antioxidant agents. It reacts with hydrogen peroxide (H2O2) to form succinate, carbon dioxide (i.e., CO2), and water (i.e., (H2O) thereby lowering the levels of H2O2. Additionally, α-ketoglutarate increases the activity of superoxide dismutase, which converts the highly toxic (O−
2) radical to molecular oxygen (i.e., O2) and H
2O
2.
A study conducted on the GABAergic neurons (i.e., nerve cells) in the neocortex of rat brains reported that the cytosolic form of the aspartate transaminase enzyme metabolizes α-ketoglutarate to glutamate which in turn is metabolized by glutamic acid decarboxylase to the inhibitory neurotransmitter gamma-aminobutyric acid. These metabolic reactions occur at the ends of the inhibitory axons of the GABAergic neurons and result in the release of gamma-aminobutyric acid which then inhibits the activation of nearby neurons.
OXGR1 (also known as GPR99) is a G protein-coupled receptor, i.e., a receptor located on the surface membrane of cells that binds certain ligands and is thereby stimulated to activate G proteins that elicit pre-programmed responses in their parent cells. OXGR1 was identified as a receptor for: a) α-ketoglutarate in 2004; b) three leukotrienes viz., leukotrienes E4, C4, and D4 in 2013. and c) itaconate in 2023. These ligands have the following relative potencies in stimulating responses in OXGR1-bearing cells (Note that LTE4 can stimulate OXGR1 at concentrations far lower than those of the other four ligands):
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Α-Ketoglutaric acid
α-Ketoglutaric acid is an organic compound with the formula HO2CCO(CH2)2CO2H. A white, nontoxic solid, it is a common dicarboxylic acid. Relevant to its biological roles, it exists in water as its conjugate base α-ketoglutarate. It is also classified as a 2-ketocarboxylic acid. β-Ketoglutaric acid is an isomer. "Ketoglutaric acid" and "ketoglutarate", when not qualified as α or β, almost always refers respectively to α-ketoglutaric acid or α-ketoglutarate.
α-Ketoglutarate is an intermediate in the citric acid cycle, a cycle that supplies the energy to cells. It is also an intermediate in or product of several other metabolic pathways. These include its being a component of metabolic pathways that: make amino acids and in the process regulate the cellular levels of carbon, nitrogen, and ammonia; reduce the cellular levels of potentially toxic reactive oxygen species; and synthesize the neurotransmitter gamma-aminobutyric acid. It also acts as a direct stimulator of, or cofactor (i.e., required for but does not itself stimulate) for various cellular functions as defined in studies that are primarily preclinical (i.e., conducted in animal models of disease or on animal or human tissues). These studies have provided evidence that α-ketoglutarate contributes to regulating: kidney function; the benefits that resistance exercise has in reducing obesity, strengthening muscles, and preventing muscle atrophy; glucose tolerance as defined in glucose tolerance tests; aging and the development of changes that are associated with aging including old age-related disorders and diseases; the development and/or progression of certain types of cancer and inflammations; and the differentiation of immature T cells into mature T cells.
α-Ketoglutarate is a component of the citric acid cycle, a cyclical metabolic pathway located in the mitochondria. This cycle supplies the energy that cells need by sequentially metabolizing (indicated by →) citrate through seven intermediate metabolites and then converting the eighth intermediate metabolite, oxaloacetate, back to citrate:
In this cycle, the enzyme isocitrate dehydrogenase 3 converts isocitrate (isocitrate has 4 isomers of which only the (−)-d-threo-isomer is the naturally occurring isomer in the citric acid cycle.) to α-ketoglutarate which in the next step is converted to succinyl-CoA by the oxoglutarate dehydrogenase complex of enzymes.
Aside from the citric acid cycle, α-ketoglutarate is made by a) glutaminolysis in which the enzyme glutaminase removes the amino group from glutamine to form glutamate which is converted to α-ketoglutarate by any one of three enzymes, glutamate dehydrogenase, alanine transaminase, or aspartate transaminase (see The glutaminolytic pathways); and various pyridoxal phosphate-dependent transamination reactions mediated by, e.g., the alanine transaminase enzyme, in which glutamate is converted to α-Ketoglutarate by "donating" its −NH2 to other compounds (see transamination). Acting in these pathways, α-ketoglutarate contributes to the production of amino acids such as glutamine, proline, arginine, and lysine as well as the lowering of cellular carbon and nitrogen (i.e., N) levels; this prevents excessive levels of these two potentially toxic elements from accumulating in cells and tissues. The neurotoxin, ammonia (i.e., NH3), is also prevented form accumulating in tissues. In this metabolic pathway the −NH2 group on an amino acid is transferred to α-ketoglutarate; this forms the α-keto acid of the original amino acid and the amine-containing product of α-ketoglutarate, glutamate. The celllular glutamate passes into the circulation and is taken up by the liver where it delivers its acquired −NH2 group to the urea cycle. In effect, the latter pathway removes excess ammonia from the body in the form of urinary urea.
α-Ketoglutarate is one of the non-enzymatic antioxidant agents. It reacts with hydrogen peroxide (H2O2) to form succinate, carbon dioxide (i.e., CO2), and water (i.e., (H2O) thereby lowering the levels of H2O2. Additionally, α-ketoglutarate increases the activity of superoxide dismutase, which converts the highly toxic (O−
2) radical to molecular oxygen (i.e., O2) and H
2O
2.
A study conducted on the GABAergic neurons (i.e., nerve cells) in the neocortex of rat brains reported that the cytosolic form of the aspartate transaminase enzyme metabolizes α-ketoglutarate to glutamate which in turn is metabolized by glutamic acid decarboxylase to the inhibitory neurotransmitter gamma-aminobutyric acid. These metabolic reactions occur at the ends of the inhibitory axons of the GABAergic neurons and result in the release of gamma-aminobutyric acid which then inhibits the activation of nearby neurons.
OXGR1 (also known as GPR99) is a G protein-coupled receptor, i.e., a receptor located on the surface membrane of cells that binds certain ligands and is thereby stimulated to activate G proteins that elicit pre-programmed responses in their parent cells. OXGR1 was identified as a receptor for: a) α-ketoglutarate in 2004; b) three leukotrienes viz., leukotrienes E4, C4, and D4 in 2013. and c) itaconate in 2023. These ligands have the following relative potencies in stimulating responses in OXGR1-bearing cells (Note that LTE4 can stimulate OXGR1 at concentrations far lower than those of the other four ligands):
