AMPKs

The AMP-activated protein kinase (AMPK) acts as a sensor of cellular energy status. AMPK exists as heterotrimeric complexes comprising a catalytic α subunit and regulatory β and γ subunits. In mammals, each of these subunits is encoded by multiple genes and at least 12 possible combinations of subunit isoforms are possible. The α subunits (α1, α2) contain the kinase domain at the N-terminus followed by a C-terminal region that is required for formation of the αβγ complex. The β subunits (β1, β2) contain short, variable N-terminal regions followed by two more highly conserved regions. The first is now recognized to be a glycogen-binding domain (related to N-isoamylase domains that are found in enzymes that metabolize the α1->6 branches in α1->4 linked glucans such as glycogen) that causes AMPK to associate with glycogen particles inside the cell. The C-terminal conserved region is required for the formation of the αβγ complex. The γ subunit isoforms (γ1, γ2, γ3) contain variable N-terminal regions of unknown function, followed by four tandem repeats of a sequence termed a CBS motif. These motifs, which also occur in a small number of other proteins, act in pairs to form two domains that bind the regulatory nucleotides, AMP and ATP, in a mutually exclusive manner. Binding of AMP to the two sites is highly co-operative. Mutations within the AMP binding sites of the γ2 and γ3 isoforms cause glycogen storage disorders in cardiac muscle in humans and skeletal muscle in pigs, respectively.

The AMPK system is activated by cellular stresses that cause a drop in the cellular ATP:ADP ratio either by interfering with ATP synthesis (e.g. metabolic poisons, hypoxia, glucose starvation) or by increasing ATP consumption (e.g. contraction in muscle). An increase in the cellular ADP:ATP ratio is amplified into a much larger increase in AMP:ATP by adenylate kinase. AMP binds to the two sites on the γ subunit (an effect antagonized by high ATP). This promotes phosphorylation within the α subunit by the upstream kinase, which is essential for AMPK activity. The major form of the upstream kinase is a complex between the tumor suppressor LKB1, and two accessory subunits, STRAD and MO25. AMP binding also allosterically activates the phosphorylated AMPK complex. Dissociation of AMP both reverses the allosteric activation and also promotes dephosphorylation to switch the kinase off again.

Once activated, AMPK switches on catabolic processes that generate ATP, such as the uptake and oxidation of glucose and fatty acids. It also switches off processes that consume ATP that are not essential for the short-term survival of the cell. This includes the biosynthesis of fatty acids, cholesterol, glycogen and protein. AMPK switches off protein biosynthesis and cell growth in part by down-regulating the TOR (target-of-rapamycin) pathway. AMPK causes both short-term effects via direct phosphorylation of metabolic enzymes, and longer-term effects by modulating gene expression.

AMPK is a prime target for drugs aimed at treatment of obesity and Type 2 diabetes. It can be activated in intact cells and in vivo using the nucleoside 5-aminoimidazole-4-carboxamide riboside (AICAR), which is taken up by cells and converted to the equivalent monophosphorylated nucleotide, ZMP, which mimics all of the effects of AMP. AMPK is also activated in intact cells and/or in vivo by two major classes of anti-diabetic drugs, i.e. the biguanides (metformin and phenformin) and the thiazolidinediones (rosiglitazone and pioglitazone). These drugs appear to act indirectly on AMPK, possibly via inhibition of the respiratory chain, and it remains uncertain to what extent their therapeutic benefits are mediated by AMPK.

The Table below contains accepted modulators and additional information. For a list of additional products, see the "Related Products" section below.

Isoforms	α1	α2	β1	β2
Molecular Weight (kDa)	62.8 kDa	62.3 kDa	30.1 kDa	30.3 kDa
Structural Data	550 aa	552 aa	269 aa Myristoylation	272 aa Myristoylation
Species	Human	Human	Human	Human
Domain Organization	Kinase domain Complex formation	Kinase domain Complex formation	Glycogen binding Complex formation	Glycogen binding Complex formation
Phosphorylation Sites	Thr172 (by LKB1, CaMKKs) Thr258 Ser485	Thr172 (by LKB1, CaMKKs) Thr258 Ser491	Ser24/S25 Ser96 Ser101 Ser108 Ser182	Not Known
Tissue Distribution	Ubiquitous	Muscle Liver	Ubiquitous	Skeletal/cardiac Muscle Others
Subcellular Localization	Cytoplasmic	Nuclear Cytoplasmic	Extranuclear Nuclear	Cytoplasm
Binding Partners/ Associated Proteins	β and γ subunits	β and γ subunits	α and γ subunits glycogen	α and γ subunits glycogen
Upstream Activators	LKB1/STRAD/MO25 Calmodulin-dependent protein kinases (CaMKKs)	LKB1/STRAD/MO25 Calmodulin-dependent protein kinases (CaMKKs)	Not Known	Not Known
Downstream Activation	Not Known	Not Known	Not Known	Not Known
Activatorsa	AICAR (A9978) Metformin (D150959) Rosiglitazone (R2408) Pioglitazone (E6910)	AICAR (A9978) Metformin (D150959) Rosiglitazone (R2408) Pioglitazone (E6910)	Not Known	Not Known
Inhibitorsb	Compound C2	Compound C2	Not Known	Not Known
Selective Activators	Not Known	Not Known	Not Known	Not Known
Physiological Function	Catalytic	Catalytic	Glycogen-binding	Glycogen-binding
Disease Relevance	Not Known	Mouse KO: Insulin resistant Glucose intolerant	Not Known	Not Known

Isoforms	γ1	γ2	γ3
Molecular Weight (kDa)	37.6 kDa	63.1 kDa	51.5 kDa
Structural Data	331 aa	569 aa Myristoylation	464 aa
Species	Human	Human	Human
Domain Organization	AMP/ATP-binding (two sites)	AMP/ATP-binding (two sites)	AMP/ATP-binding (two sites)
Phosphorylation Sites	Not Known	Not Known	Not Known
Tissue Distribution	Ubiquitous	Skeletal/cardiac Muscle Others	Skeletal muscle
Subcellular Localization	Cytoplasm	Cytoplasm	Cytoplasm
Binding Partners/ Associated Proteins	α and β subunits	α and β subunits	α and β subunits
Upstream Activators	Not Known	Not Known	Not Known
Downstream Activation	Not Known	Not Known	Not Known
Activatorsa	Not Known	Not Known	Not Known
Inhibitorsb	Not Known	Not Known	Not Known
Selective Activators	Not Known	Not Known	Not Known
Physiological Function	AMP/ATP-binding	AMP/ATP-binding	AMP/ATP-binding
Disease Relevance	Not Known	Mutations: Cardiac glycogen increased, Cardiac arrhythmias	Mutations (pig): Skeletal muscle glycogen increased

Footnotes

a) These activators only work in intact cells and require an intact αβγ complex

b) Compound C may inhibit the isolated kinase domain of the α subunit but has only been tested on the intact αβγ complex; see Zhou, et al., J. Clin. Invest., 108, 1167-1174 (2001).

References

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15. Thornton C, Snowden MA, Carling D. 1998. Identification of a Novel AMP-activated Protein Kinase ? Subunit Isoform That Is Highly Expressed in Skeletal Muscle. J. Biol. Chem.. 273(20):12443-12450. https://doi.org/10.1074/jbc.273.20.12443

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