α-Ketoglutaric acid exerts its biological action in multiple ways. It is an
agonist of the
OXGR1 receptor. It is also a cellular antioxidant and a cofactor for certain enzymes.
OXGR1 receptor-dependent bioactions 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. or when their actions are inhibited by an OXGR1
receptor antagonists. OXGR1 is inhibited by
montelukast, a well-known inhibitor of the
cysteinyl leukotriene receptor 1, i.e., the receptor for LTD4, LTC4, and LTE4. Montelukast also blocks the binding of these leukotrienes to, and thereby inhibits their activation of, OXGR1. One study presented evidence suggesting that α-ketoglutarate binds to OXGR1. It is assumed that montelukast similarly blocks α-ketoglutarate's binding to, and thereby inhibits its activation of OXGR1. A study in mice found that OXGR1 colocalizes with
pendrin in the
β-intercalated cells and non-α non-β intercalated cells lining the
tubules of their kidney's CDS. The intercalated cells in the CDS tubules isolated from mice used pendrin in cooperation with the
electroneutral sodium bicarbonate exchanger 1 protein to mediate the Cl− for HCO3− exchange. α-Ketoglutarate stimulated the rate of this exchange in CDS tubules isolated from control mice (i.e., mice that had the
Oxgr1 gene and protein) but not in CDS tubules isolated from
Oxgr1 gene knockout mice (i.e., mice that lacked the
Oxgr1 gene and protein). This study also showed that the α-ketoglutarate in the blood of mice filtered through their kidney's
glomeruli into the
proximal tubules and
loops of Henle where it was reabsorbed. Mice drinking water with a
basic pH (i.e., >7) due to the addition of
sodium bicarbonate and mice lacking the
Oxgr1 gene and protein who drink water without sodium bicarbonate had urines that were more basic (i.e., pH about 7.8) and contained higher levels of urinary α-ketoglutarate than control mice drinking water without this additive. Furthermore,
Oxgr1 gene knockout mice drinking sodium bicarbonate-rich water developed
metabolic alkalosis (body tissue pH levels higher than normal) that was associated with blood bicarbonate levels significantly higher and blood chloride levels significantly lower than those in control mice drinking the sodium bicarbonate-rich water. Several other studies confirmed these findings and reported that cells in the proximal tubules of mice synthesize α-ketoglutarate and either broke it down thereby reducing its urine levels or secreted it into the tubules' lumens thereby increasing its urine levels. Another study showed that
a) In silico computer simulations strongly suggested that α-ketoglutarate bound to mouse OXGPR1;
b) suspensions of canal duct cells isolated from the collecting ducts, loops of Henle,
vasa recta, and
interstitium of mouse kidneys raised their cytosolic ionic calcium, i.e., Ca2+ levels in response to α-ketoglutarate but this response (which is an indicator of cell activation) was blocked by pretreating the cells with montelukast; and
c) compared to mice not treated with
streptozotocin, streptozotocin-induced diabetic mice (an
animal disease model of
diabetes) urinated only a small amount of the ionic sodium () that they drank or received by intravenous injections; montelukast reversed this defect in the streptozotocin-pretreated mice. Additional mechanisms include inhibition of hepatic
gluconeogenesis via serpina1e signaling (reducing hyperglycemia) and activation of the PHD3/ADRB2 pathway in muscle cells. Supplementation studies have shown that oral α-ketoglutarate increases serum levels of α-ketoglutarate, suppresses obesity and improves glucose tolerance in mice. See below.
OXGR1 receptor-independent bioactions The following actions of α-ketoglutarate have not been evaluated for their dependency on activating OXGR1 and are here assumed to be OXGR1-independent. Futures studies are needed to determine if OXGR1 contributes in whole or part to these actions of α-ketoglutarate.
Reactive oxygen species α-Ketoglutarate is one of the non-enzymatic antioxidant agents. It reacts with hydrogen peroxide (H2O2) to form
succinate, carbon dioxide (i.e., ), and water (i.e., () thereby lowering the levels of H2O2. Additionally, α-ketoglutarate increases the activity of
superoxide dismutase, which converts the highly toxic ()
radical to molecular
oxygen (i.e., O2) and .
Fe2+/α-ketoglutarate-dependent dioxygenase enzymes and TET enzymes α-Ketoglutarate is a cofactor that activates
histone-lysine demethylase protein superfamily. This superfamily consists of two groups, the FAD-dependent amine oxidases which do not require α-ketoglutarate for activation and the Fe2+/α-ketoglutarate-dependent dioxygenases (Fe2+ is the
ferrous form of iron, i.e., Fe2+). The latter group of more than 30 enzymes is classified into 7 subfamilies termed histone lysine demethylases, i.e., HDM2 to HDM7, with each subfamily having multiple members. These HDMs are characterized by containing a Jumonji C (JmjC)
protein domain. They function as
dioxygenases or
hydroxylases to remove
methyl groups from the
lysine residues on the
histones enveloping DNA and thereby alter the expression of diverse genes. These altered gene expressions lead to a wide range of changes in the functions of various cell types and thereby caused the development and/or progression of various cancers, pathological inflammations, and other disorders (see
α-Ketoglutarate-dependent demethylase biological functions). The
TET enzymes (i.e., ten-eleven translocation (TET) methylcytosine dioxygenase family of enzymes) consists of three members, TET-1, TET-2, and TET-3. Like the Fe2+/α-ketoglutarate-dependent dioxygenases, all three TET enzymes require Fe2+ and α-ketoglutarate as cofactors to become activated. Unlike the dioxygenases, however, they remove methyl groups from the 5-methylcytosines of
DNA sites that regulate the expression of nearby genes. These demethylations have a variety of effects including, similar to the Fe2+/α-ketoglutarate-dependent dioxygenases, alteration of the development and/or progression of various cancers, immune responses, and other disorders (see
functions of TET enzymes).
β-Ketoglutaric acid and TET-2 β-Ketoglutaric acid has been detected in the saliva of individuals chewing
betel quid, a complex mixture derived from
betel nuts mixed with various other materials. Chronic chewing betel quid is associated with the development of certain cancers, particularly those in the
oral cavity. The study showed that β-ketoglutaric acid bound to the cancer-promoting protein
TET-2 thereby inhibiting α-ketoglutarate's binding to this protein. Since α-ketoglutarate's binding of TET-2 is thought to be required for it to activate TET-2, the study suggested that β-ketoglutaric acid may not fulfill the requirements for TET-2 to be activatable and therefore may prove able to block α-ketoglutarate's cancer-promoting as well as inflammation-promoting and other actions that involve its activation of TET-2.
Immune regulation Under glutamine-deprived conditions, α-ketoglutarate promotes
naïve CD4+ T cells differentiation into inflammation-promoting Th1 cells while inhibiting their differentiation into inflammation-inhibiting
Treg cells thereby promoting certain inflammation responses. == Interactive pathway map ==