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GSK-3

September 01, 2023

Glycogen synthase kinase 3 (GSK-3) is a serine/threonine protein kinase that mediates the addition of phosphate molecules onto serine and threonine amino acid residues. First discovered in 1980 as a regulatory kinase for its namesake, glycogen synthase (GS),[2] GSK-3 has since been identified as a protein kinase for over 100 different proteins in a variety of different pathways.[3][4] In mammals, including humans, GSK-3 exists in two isozymes encoded by two homologous genes GSK-3α (GSK3A) and GSK-3β (GSK3B). GSK-3 has been the subject of much research since it has been implicated in a number of diseases, including type 2 diabetes, Alzheimer's disease, inflammation, cancer, addiction[5] and bipolar disorder.

Glycogen synthase kinase 3, catalytic domain
Identifiers
SymbolSTKc_GSK3
InterProIPR039192
CDDcd14137
glycogen synthase kinase 3 alpha
Identifiers
SymbolGSK3A
NCBI gene2931
HGNC4616
OMIM606784
RefSeqNM_019884
UniProtP49840
Other data
EC number2.7.11.26
LocusChr. 19 q13.2
Search for
StructuresSwiss-model
DomainsInterPro
glycogen synthase kinase 3 beta
Crystallographic structure of human GSK-3β (rainbow colored, N-terminus = blue, C-terminus = red) bound to phosphoaminophosphonic acid-adenylate ester (spheres).[1]
Identifiers
SymbolGSK3B
NCBI gene2932
HGNC4617
OMIM605004
PDB1Q3W More structures
RefSeqNM_002093
UniProtP49841
Other data
EC number2.7.11.26
LocusChr. 3 q13.33
Search for
StructuresSwiss-model
DomainsInterPro

GSK-3 is a serine/threonine protein kinase that phosphorylate either threonine or serine, and this phosphorylation controls a variety of biological activities, such as glycogen metabolism, cell signaling, cellular transport, and others.[6] GS inhibition by GSK-3β leads to a decrease in glycogen synthesis in the liver and muscles, along with increased blood glucose or hyperglycemia.[7] This is why GSK-3β is associated with the pathogenesis and progression of many diseases, such as diabetes, obesity, cancer,[8] and Alzheimer's disease.[9] It is active in resting cells and is inhibited by several hormones such as insulin, endothelial growth factor, and platelet-derived growth factor. Insulin inactivates it by phosphorylation of the specific serine residues Ser21 and Ser9 in GSK-3 isoforms α and β, respectively. In a phosphatidylinositol 3-kinase-dependent way.[citation needed]

As of 2019, GSK-3 is the only type of glycogen synthase kinase named and recognized. The gene symbols for GSK1 and GSK2 have been withdrawn by the HUGO Gene Nomenclature Committee (HGNC), and no new names for these "genes" nor their locations have been specified.[10][11]

Mechanism Edit

 
The active site of GSK-3. The three residues in blue bind the priming phosphate on the substrate, as demonstrated by the ligand. Residues D181, D200, K85, and E97.

GSK-3 functions by phosphorylating a serine or threonine residue on its target substrate. A positively charged pocket adjacent to the active site binds a "priming" phosphate group attached to a serine or threonine four residues C-terminal of the target phosphorylation site. The active site, at residues 181, 200, 97, and 85, binds the terminal phosphate of ATP and transfers it to the target location on the substrate (see figure 1).[12]

Glycogen synthase Edit

Glycogen synthase is an enzyme that is responsible in glycogen synthesis. It is activated by glucose 6-phosphate (G6P), and inhibited by glycogen synthase kinases (GSK3). Those two mechanisms play an important role in glycogen metabolism.[13]

Function Edit

Phosphorylation of a protein by GSK-3 usually inhibits the activity of its downstream target.[14][15][16] GSK-3 is active in a number of central intracellular signaling pathways, including cellular proliferation, migration, glucose regulation, and apoptosis.

GSK-3 was originally discovered in the context of its involvement in regulating glycogen synthase.[2] After being primed by casein kinase 2 (CK2), glycogen synthase gets phosphorylated at a cluster of three C-terminal serine residues, reducing its activity.[17] In addition to its role in regulating glycogen synthase, GSK-3 has been implicated in other aspects of glucose homeostasis, including the phosphorylation of insulin receptor IRS1[18] and of the gluconeogenic enzymes phosphoenolpyruvate carboxykinase and glucose 6 phosphatase.[19] However, these interactions have not been confirmed, as these pathways can be inhibited without the up-regulation of GSK-3.[17]

GSK-3 has also been shown to regulate immune and migratory processes. GSK-3 participates in a number of signaling pathways in the innate immune response, including pro-inflammatory cytokine and interleukin production.[20][21] The inactivation of GSK3B by various protein kinases also affects the adaptive immune response by inducing cytokine production and proliferation in naïve and memory CD4+ T cells.[21] In cellular migration, an integral aspect of inflammatory responses, the inhibition of GSK-3 has been reported to play conflicting roles, as local inhibition at growth cones has been shown to promote motility while global inhibition of cellular GSK-3 has been shown to inhibit cell spreading and migration.[20]

GSK-3 is also integrally tied to pathways of cell proliferation and apoptosis. GSK-3 has been shown to phosphorylate Beta-catenin, thus targeting it for degradation.[22] GSK-3 is therefore a part of the canonical Beta-catenin/Wnt pathway, which signals the cell to divide and proliferate. GSK-3 phosphorylates cyclins D and E, which are important for the transition from G1 to S phase, and causes their degradation. The transcription factors c-myc and c-fos (also S phase promoters ), which are primarily phosphorylated by the dual-specificity tyrosine phosphorylation-regulated kinase, are also phosphorylated by GSK3, causing them to be degraded.[23] GSK-3 also participates in a number of apoptotic signaling pathways by phosphorylating transcription factors that regulate apoptosis.[4] GSK-3 can promote apoptosis by both activating pro-apoptotic factors such as p53[24] and inactivating survival-promoting factors through phosphorylation.[25] The role of GSK-3 in regulating apoptosis is controversial, however, as some studies have shown that GSK-3β knockout mice are overly sensitized to apoptosis and die in the embryonic stage, while others have shown that overexpression of GSK-3 can induce apoptosis.[26] Overall, GSK-3 appears to both promote and inhibit apoptosis, and this regulation varies depending on the specific molecular and cellular context.[27]

GSK-3 is also involved in nuclear transcriptional activator kappa B (NFκB) signaling pathway, Hedgehog signaling pathway, Notch signaling pathway, and epithelial-mesenchymal transition.[23]

Regulation Edit

Due to its importance across numerous cellular functions, GSK-3 activity is subject to tight regulation.

The speed and efficacy of GSK-3 phosphorylation is regulated by a number of factors. Phosphorylation of certain GSK-3 residues can increase or decrease its ability to bind substrate. Phosphorylation at tyrosine-216 in GSK-3β or tyrosine-279 in GSK-3α enhances the enzymatic activity of GSK-3, while phosphorylation of serine-9 in GSK-3β or serine-21 in GSK-3α significantly decreases active site availability (see Figure 1).[20] Further, GSK-3 is unusual among kinases in that it usually requires a "priming kinase" to first phosphorylate a substrate. A phosphorylated serine or threonine residue located four amino acids C-terminal to the target site of phosphorylation allows the substrate to bind a pocket of positive charge formed by arginine and lysine residues.[17][28]

Depending on the pathway in which it is being utilized, GSK-3 may be further regulated by cellular localization or the formation of protein complexes. The activity of GSK-3 is far greater in the nucleus and mitochondria than in the cytosol in cortical neurons,[29] while the phosphorylation of Beta-catenin by GSK-3 is mediated by the binding of both proteins to Axin, a scaffold protein, allowing Beta-catenin to access the active site of GSK-3.[20]

Disease relevance Edit

Due to its involvement in a great number of signaling pathways, GSK-3 has been associated with a host of high-profile diseases. GSK-3 inhibitors are currently being tested for therapeutic effects in Alzheimer's disease, type 2 diabetes mellitus (T2DM), some forms of cancer, and bipolar disorder.[30]

It has now been shown that lithium, which is used as a treatment for bipolar disorder, acts as a mood stabilizer by selectively inhibiting GSK-3. The mechanism through which GSK-3 inhibition stabilizes mood is not known, though it is suspected that the inhibition of GSK-3's ability to promote inflammation contributes to the therapeutic effect.[20] Inhibition of GSK-3 also destabilises Rev-ErbA alpha transcriptional repressor, which has a significant role in the circadian clock.[31] Elements of the circadian clock may be connected with predisposition to bipolar mood disorder.[32]

GSK-3 activity has been associated with both pathological features of Alzheimer's disease, namely the buildup of amyloid-β (Aβ) deposits and the formation of neurofibrillary tangles. GSK-3 is thought to directly promote Aβ production and to be tied to the process of the hyperphosphorylation of tau proteins, which leads to the tangles.[4][20] Due to these roles of GSK-3 in promoting Alzheimer's disease, GSK-3 inhibitors may have positive therapeutic effects on Alzheimer's patients and are currently in the early stages of testing.[33]

In a similar fashion, targeted inhibition of GSK-3 may have therapeutic effects on certain kinds of cancer. Though GSK-3 has been shown to promote apoptosis in some cases, it has also been reported to be a key factor in tumorigenesis in some cancers.[34] Supporting this claim, GSK-3 inhibitors have been shown to induce apoptosis in glioma and pancreatic cancer cells.[26][35] GSK-3 also seems to be responsible for NFκB aberrant activity in pediatric acute lymphoblastic leukemia and pancreatic cancer cells. In renal cancer cells, GSK-3 inhibitors induce cell cycle arrest, differentiation of the malignant cells, and autophagy. In contrast to the above neoplasms, high expression of inactive pGSK3β-S9 is found in skin, oral, and lung cancers, suggesting tumor suppressive effects of the enzyme in these cancers. In melanoma, the microRNA miR-769 inhibits GSK-3 activity during the tumor development process, also indicating tumor suppressive effects of GSK3.[23]

GSK-3 inhibitors have also shown promise in the treatment of T2DM.[17] Though GSK-3 activity under diabetic conditions can differ radically across different tissue types, studies have shown that introducing competitive inhibitors of GSK-3 can increase glucose tolerance in diabetic mice.[20] GSK-3 inhibitors may also have therapeutic effects on hemorrhagic transformation after acute ischemic stroke.[36] GSK-3 can negatively regulate the insulin signaling pathway by inhibiting IRS1 via phosphorylation of serine-332,[18] rendering the insulin receptor incapable of activating IRS1 and further initiating the canonical PI3K/Akt pathway. The role that inhibition of GSK-3 might play across its other signaling roles is not yet entirely understood.

GSK-3 inhibition also mediates an increase in the transcription of the transcription factor Tbet (Tbx21) and an inhibition of the transcription of the inhibitory co-receptor programmed cell death-1 (PD-1) on T-cells.[37] GSK-3 inhibitors increased in vivo CD8(+) OT-I CTL function and the clearance of viral infections by murine gamma-herpesvirus 68 and lymphocytic choriomeningitis clone 13 as well as anti-PD-1 in immunotherapy.

Inhibitors Edit

Glycogen synthase kinase inhibitors are different chemotypes and have variable mechanisms of action; they may be cations, from natural sources, synthetic ATP and non-ATP competitive inhibitors and substrate-competitive inhibitors. GSK3 is a bi-lobar architecture with N-terminal and C-terminal, the N-terminal is responsible for ATP binding and C-terminal which is called as activation loop mediates the kinase activity, Tyrosine located at the C-terminal it essential for full GSK3 activity.[38]

Benefits of GSK-3β inhibitors Edit

In diabetes, GSK-3β inhibitors increase insulin sensitivity, glycogen synthesis, and glucose metabolism in skeletal muscles, and reduce obesity by affecting the adipogenesis process.[39] GSK-3β is also over expressed in several types of cancers, like colorectal, ovarian, and prostate cancer.[38] GSK-3β inhibitors also aid in the treatment of Alzheimer's disease,[citation needed] stroke,[36] and mood disorders, including bipolar disorder.[40]

Specific agents Edit

Inhibitors of GSK-3 include:[41][42][43][44]

Metal cations Edit

ATP-competitive Edit

Marine organism-derived Edit

  • 6-BIO (IC50=1.5μM)
  • Dibromocantharelline (IC50=3μM)
  • Hymenialdesine (IC50=10nM)
  • Indirubin (IC50=5-50nM)
  • Meridianin

Aminopyrimidines Edit

  • CHIR99021 (IC50=6.9nM-10nM)
  • CHIR98014 (IC50=0.58-0.65nM)
  • CT98014
  • CT98023
  • CT99021
  • TWS119 (IC50=30nM)

Arylindolemaleimide Edit

  • SB-216763 (IC50=34nM)
  • SB-41528 (IC50=31-78nM)

Thiazoles Edit

  • AR-A014418 (IC50=104nM)
  • AZD-1080 (IC50=6.9nM-31nM)

Paullones Edit

IC50=4-80nM:

  • Alsterpaullone
  • Cazpaullone
  • Kenpaullone

Aloisines Edit

IC50=0.5-1.5μM:

Non-ATP competitive Edit

Marine organism-derived Edit

  • Manzamine A (IC50=1.5μM)
  • Palinurine (IC50=4.5μM)
  • Tricantine (IC50=7.5μM)

Thiazolidinediones Edit

  • TDZD-8 (IC50=2μM)
  • NP00111 (IC50=2μM)
  • NP031115 (IC50=4μM)
  • Tideglusib (IC50=60nM)

Halomethylketones Edit

  • HMK-32 (IC50=1.5μM)

Peptides Edit

  • L803-mts (IC50=20μM)
  • L807-mts (IC50=1μM)

Unknown Mechanism (small-molecule inhibitors) Edit

  • COB-187 (IC50=11nM-22nM)
  • COB-152 (IC50=77nM-132nM)

Lithium Edit

Lithium which is used in the treatment of bipolar disorder was the first natural GSK-3 inhibitor discovered. It inhibits GSK-3 directly by competition with magnesium ions and indirectly by phosphorylation and auto-regulation of serine. Lithium has been found to have insulin-like effects on glucose metabolism, including stimulation of glycogen synthesis in fat cells, skin, and muscles, increasing glucose uptake, and activation of GS activity. In addition to inhibition of GSK-3, it also inhibits other enzymes involved in the regulation of glucose metabolisms, such as myo-inositol-1-monophosphatase and 1,6 bisphosphatase. Also, it has shown therapeutic benefit in Alzheimer's and other neurodegenerative diseases such as epileptic neurodegeneration.[43]

Naproxen and Cromolyn Edit

Naproxen is a non-steroidal anti-inflammatory drug while cromolyn is an anti-allergic agent which acts as a mast cell stabilizer. Both drugs have demonstrated the anticancer effect in addition to hypoglycemic effect due to inhibition of glycogen synthase kinase-3β (GSK-3β).

To validate the anti-GSK-3β hypothesis of naproxen and cromolyn, docking of the two structures against GSK-3β binding pocket and comparing their fitting with known GSK-3β inhibitor ARA014418 was performed, in addition to measuring the serum glucose, serum insulin, serum C-peptide, weight variation and hepatic glycogen levels for normal and diabetic fasting animal's models to assess their in vitro hypoglycemic effects.[citation needed]

Naproxen and cromolyn were successfully docked into the binding site of GSK-3β (both were fitted into its binding pocket). They exhibited electrostatic, hydrophobic, and hydrogen-bonding interactions with key amino acids within the binding pocket with binding interaction profiles similar to AR-A014418 (the known inhibitor). The negative charges of the carboxylic acid groups in both drugs interact electrostatically with the positively charged guanidine group of Arg141. Moreover, the hydrogen bonding interactions between carboxylic acid moieties of cromolyn and the ammonium groups of Lys183 and Lys60, in addition to π-stacking of the naphthalene ring system of naproxen with the phenolic ring of Tyr134.

Antidiabetic effects of naproxen and cromolyn: In normal animal models, both drugs have showed dose-dependent reduction in blood glucose levels and rise in glycogen levels. In chronic type II diabetic model, glucose levels were also reduced, and glycogen level and insulin levels were elevated in a dose-dependent manner with a reduction in plasma glucose.[citation needed]

Anti-obesity effects of naproxen and cromolyn: Both drugs showed significant anti-obesity effects as they reduce body weight, resistin, and glucose levels in a dose-dependent manner. They were also found to elevate adiponectin, insulin, and C-peptide levels in a dose-dependent manner.[39]

Famotidine Edit

Famotidine is a specific, long-acting H2 antagonist that decreases gastric acid secretion. It is used in the treatment of peptic ulcer disease, GERD, and pathological hypersecretory conditions, like Zollinger–Ellison syndrome. (14,15) H2-receptor antagonists affect hormone metabolism, but their effect on glucose metabolism is not well established. (16) A study has revealed a glucose-lowering effect for famotidine.[citation needed]

The study of famotidine binding to the enzyme has showed that famotidine can be docked within the binding pocket of GSK-3β making significant interactions with key points within the GSK-3β binding pocket. Strong hydrogen bond interactions with the key amino acids PRO-136 and VAL -135 and potential hydrophobic interaction with LEU-188 were similar to those found in the ligand binding to the enzyme (AR-A014418).[citation needed]

Furthermore, famotidine showed high GSK-3β binding affinity and inhibitory activity due to interactions that stabilize the complex, namely hydrogen bonding of guanidine group in famotidine with the sulfahydryl moiety in CYS-199; and electrostatic interactions between the same guanidine group with the carboxyl group in ASP-200, the hydrogen bond between the terminal NH2 group, the OH of the TYR-143, and the hydrophobic interaction of the sulfur atom in the thioether with ILE-62. In vitro studies showed that famotidine inhibits GSK-3β activity and increases liver glycogen reserves in a dose dependent manner. A fourfold increase in the liver glycogen level with the use of the highest dose of famotidine (4.4 mg/kg) was observed. Also, famotidine has been shown to decrease serum glucose levels 30, and 60 minutes after oral glucose load in healthy individuals.[45]

Curcumin Edit

Curcumin, which Is a constituent of turmeric spice, has flavoring and coloring properties.[46] It has two symmetrical forms: enol (the most abundant forms) and ketone.[47][48]

Curcumin has wide pharmacological activities: anti-inflammatory,[49] anti-microbial,[50] hypoglycemic, anti-oxidant, and wound healing effects.[51] In animal models with Alzheimer disease, it has anti-destructive effect of beta amyloid in the brain,[52] and recently it shows anti-malarial activity.[53]

Curcumin also has chemo preventative and anti-cancer effects.[citation not found], and it has been shown to attenuate oxidative stress and renal dysfunction in diabetic animals with chronic use.[54]

Curcumin's mechanism of action is anti-inflammatory; it inhibits the nuclear transcriptional activator kappa B (NF-KB) that is activated whenever there is inflammatory response.[citation needed]

NF-kB has two regulatory factors, IkB and GSK-3,[55] which suggests curcumin directly binds and inhibits GSK-3B. An in vitro study confirmed GSK-3B inhibition by simulating molecular docking using a silico docking technique.[56] The concentration at which 50% of GK-3B would be inhibited by curcumin is 66.3 nM.[56]

Among its two forms, experimental and theoretical studies show that the enol form is the favored form due to its intra-molecular hydrogen bonding, and an NMR experiment show that enol form exist in a variety of solvents.[citation needed]

Olanzapine Edit

Antipsychotic medications are increasingly used for schizophrenia, bipolar disorder, anxiety, and other psychiatric conditions[57] Atypical antipsychotics are more commonly used than first generation antipsychotics because they decrease the risk of extrapyramidal symptoms, such as tardive dyskinesia, and have better efficacy.[58]

Olanzapine and atypical antipsychotics induce weight gain through increasing body fat.[59] It also affects glucose metabolism, and several studies shows that it may worsen diabetes.[60]

A recent study shows that olanzapine inhibits GSK3 activity, suggesting olanzapine permits glycogen synthesis. A study of the effect of olanzapine on mouse blood glucose and glycogen levels showed a significant decrease in blood glucose level and elevation of glycogen level in mice, and the IC50% of olanzapine were 91.0 nm, which is considered a potent inhibitor. The study also illustrates that sub-chronic use of olanzapine results in potent inhibition of GSK3.[40]

Pyrimidine derivatives Edit

Pyrimidine analogues are antimetabolites that interfere with nucleic acid synthesis.[61] Some of them have been shown to fit the ATP-binding pocket of GSK-3β to lower blood glucose levels and improve some neuronal diseases.[62]

See also Edit

References Edit

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External links Edit

September 01, 2023
glycogen, synthase, kinase, serine, threonine, protein, kinase, that, mediates, addition, phosphate, molecules, onto, serine, threonine, amino, acid, residues, first, discovered, 1980, regulatory, kinase, namesake, glycogen, synthase, since, been, identified, . Glycogen synthase kinase 3 GSK 3 is a serine threonine protein kinase that mediates the addition of phosphate molecules onto serine and threonine amino acid residues First discovered in 1980 as a regulatory kinase for its namesake glycogen synthase GS 2 GSK 3 has since been identified as a protein kinase for over 100 different proteins in a variety of different pathways 3 4 In mammals including humans GSK 3 exists in two isozymes encoded by two homologous genes GSK 3a GSK3A and GSK 3b GSK3B GSK 3 has been the subject of much research since it has been implicated in a number of diseases including type 2 diabetes Alzheimer s disease inflammation cancer addiction 5 and bipolar disorder Glycogen synthase kinase 3 catalytic domainIdentifiersSymbolSTKc GSK3InterProIPR039192CDDcd14137glycogen synthase kinase 3 alphaIdentifiersSymbolGSK3ANCBI gene2931HGNC4616OMIM606784RefSeqNM 019884UniProtP49840Other dataEC number2 7 11 26LocusChr 19 q13 2Search forStructuresSwiss modelDomainsInterProglycogen synthase kinase 3 betaCrystallographic structure of human GSK 3b rainbow colored N terminus blue C terminus red bound to phosphoaminophosphonic acid adenylate ester spheres 1 IdentifiersSymbolGSK3BNCBI gene2932HGNC4617OMIM605004PDB1Q3W More structuresRefSeqNM 002093UniProtP49841Other dataEC number2 7 11 26LocusChr 3 q13 33Search forStructuresSwiss modelDomainsInterProGSK 3 is a serine threonine protein kinase that phosphorylate either threonine or serine and this phosphorylation controls a variety of biological activities such as glycogen metabolism cell signaling cellular transport and others 6 GS inhibition by GSK 3b leads to a decrease in glycogen synthesis in the liver and muscles along with increased blood glucose or hyperglycemia 7 This is why GSK 3b is associated with the pathogenesis and progression of many diseases such as diabetes obesity cancer 8 and Alzheimer s disease 9 It is active in resting cells and is inhibited by several hormones such as insulin endothelial growth factor and platelet derived growth factor Insulin inactivates it by phosphorylation of the specific serine residues Ser21 and Ser9 in GSK 3 isoforms a and b respectively In a phosphatidylinositol 3 kinase dependent way citation needed As of 2019 update GSK 3 is the only type of glycogen synthase kinase named and recognized The gene symbols for GSK1 and GSK2 have been withdrawn by the HUGO Gene Nomenclature Committee HGNC and no new names for these genes nor their locations have been specified 10 11 Contents 1 Mechanism 2 Glycogen synthase 3 Function 4 Regulation 5 Disease relevance 6 Inhibitors 6 1 Benefits of GSK 3b inhibitors 6 2 Specific agents 6 3 Metal cations 6 4 ATP competitive 6 4 1 Marine organism derived 6 4 2 Aminopyrimidines 6 4 3 Arylindolemaleimide 6 4 4 Thiazoles 6 4 5 Paullones 6 4 6 Aloisines 6 5 Non ATP competitive 6 5 1 Marine organism derived 6 5 2 Thiazolidinediones 6 5 3 Halomethylketones 6 5 4 Peptides 6 5 5 Unknown Mechanism small molecule inhibitors 6 6 Lithium 6 7 Naproxen and Cromolyn 6 8 Famotidine 6 9 Curcumin 6 10 Olanzapine 6 11 Pyrimidine derivatives 7 See also 8 References 9 External linksMechanism Edit The active site of GSK 3 The three residues in blue bind the priming phosphate on the substrate as demonstrated by the ligand Residues D181 D200 K85 and E97 GSK 3 functions by phosphorylating a serine or threonine residue on its target substrate A positively charged pocket adjacent to the active site binds a priming phosphate group attached to a serine or threonine four residues C terminal of the target phosphorylation site The active site at residues 181 200 97 and 85 binds the terminal phosphate of ATP and transfers it to the target location on the substrate see figure 1 12 Glycogen synthase EditGlycogen synthase is an enzyme that is responsible in glycogen synthesis It is activated by glucose 6 phosphate G6P and inhibited by glycogen synthase kinases GSK3 Those two mechanisms play an important role in glycogen metabolism 13 Function EditPhosphorylation of a protein by GSK 3 usually inhibits the activity of its downstream target 14 15 16 GSK 3 is active in a number of central intracellular signaling pathways including cellular proliferation migration glucose regulation and apoptosis GSK 3 was originally discovered in the context of its involvement in regulating glycogen synthase 2 After being primed by casein kinase 2 CK2 glycogen synthase gets phosphorylated at a cluster of three C terminal serine residues reducing its activity 17 In addition to its role in regulating glycogen synthase GSK 3 has been implicated in other aspects of glucose homeostasis including the phosphorylation of insulin receptor IRS1 18 and of the gluconeogenic enzymes phosphoenolpyruvate carboxykinase and glucose 6 phosphatase 19 However these interactions have not been confirmed as these pathways can be inhibited without the up regulation of GSK 3 17 GSK 3 has also been shown to regulate immune and migratory processes GSK 3 participates in a number of signaling pathways in the innate immune response including pro inflammatory cytokine and interleukin production 20 21 The inactivation of GSK3B by various protein kinases also affects the adaptive immune response by inducing cytokine production and proliferation in naive and memory CD4 T cells 21 In cellular migration an integral aspect of inflammatory responses the inhibition of GSK 3 has been reported to play conflicting roles as local inhibition at growth cones has been shown to promote motility while global inhibition of cellular GSK 3 has been shown to inhibit cell spreading and migration 20 GSK 3 is also integrally tied to pathways of cell proliferation and apoptosis GSK 3 has been shown to phosphorylate Beta catenin thus targeting it for degradation 22 GSK 3 is therefore a part of the canonical Beta catenin Wnt pathway which signals the cell to divide and proliferate GSK 3 phosphorylates cyclins D and E which are important for the transition from G1 to S phase and causes their degradation The transcription factors c myc and c fos also S phase promoters which are primarily phosphorylated by the dual specificity tyrosine phosphorylation regulated kinase are also phosphorylated by GSK3 causing them to be degraded 23 GSK 3 also participates in a number of apoptotic signaling pathways by phosphorylating transcription factors that regulate apoptosis 4 GSK 3 can promote apoptosis by both activating pro apoptotic factors such as p53 24 and inactivating survival promoting factors through phosphorylation 25 The role of GSK 3 in regulating apoptosis is controversial however as some studies have shown that GSK 3b knockout mice are overly sensitized to apoptosis and die in the embryonic stage while others have shown that overexpression of GSK 3 can induce apoptosis 26 Overall GSK 3 appears to both promote and inhibit apoptosis and this regulation varies depending on the specific molecular and cellular context 27 GSK 3 is also involved in nuclear transcriptional activator kappa B NFkB signaling pathway Hedgehog signaling pathway Notch signaling pathway and epithelial mesenchymal transition 23 Regulation EditDue to its importance across numerous cellular functions GSK 3 activity is subject to tight regulation The speed and efficacy of GSK 3 phosphorylation is regulated by a number of factors Phosphorylation of certain GSK 3 residues can increase or decrease its ability to bind substrate Phosphorylation at tyrosine 216 in GSK 3b or tyrosine 279 in GSK 3a enhances the enzymatic activity of GSK 3 while phosphorylation of serine 9 in GSK 3b or serine 21 in GSK 3a significantly decreases active site availability see Figure 1 20 Further GSK 3 is unusual among kinases in that it usually requires a priming kinase to first phosphorylate a substrate A phosphorylated serine or threonine residue located four amino acids C terminal to the target site of phosphorylation allows the substrate to bind a pocket of positive charge formed by arginine and lysine residues 17 28 Depending on the pathway in which it is being utilized GSK 3 may be further regulated by cellular localization or the formation of protein complexes The activity of GSK 3 is far greater in the nucleus and mitochondria than in the cytosol in cortical neurons 29 while the phosphorylation of Beta catenin by GSK 3 is mediated by the binding of both proteins to Axin a scaffold protein allowing Beta catenin to access the active site of GSK 3 20 Disease relevance EditDue to its involvement in a great number of signaling pathways GSK 3 has been associated with a host of high profile diseases GSK 3 inhibitors are currently being tested for therapeutic effects in Alzheimer s disease type 2 diabetes mellitus T2DM some forms of cancer and bipolar disorder 30 It has now been shown that lithium which is used as a treatment for bipolar disorder acts as a mood stabilizer by selectively inhibiting GSK 3 The mechanism through which GSK 3 inhibition stabilizes mood is not known though it is suspected that the inhibition of GSK 3 s ability to promote inflammation contributes to the therapeutic effect 20 Inhibition of GSK 3 also destabilises Rev ErbA alpha transcriptional repressor which has a significant role in the circadian clock 31 Elements of the circadian clock may be connected with predisposition to bipolar mood disorder 32 GSK 3 activity has been associated with both pathological features of Alzheimer s disease namely the buildup of amyloid b Ab deposits and the formation of neurofibrillary tangles GSK 3 is thought to directly promote Ab production and to be tied to the process of the hyperphosphorylation of tau proteins which leads to the tangles 4 20 Due to these roles of GSK 3 in promoting Alzheimer s disease GSK 3 inhibitors may have positive therapeutic effects on Alzheimer s patients and are currently in the early stages of testing 33 In a similar fashion targeted inhibition of GSK 3 may have therapeutic effects on certain kinds of cancer Though GSK 3 has been shown to promote apoptosis in some cases it has also been reported to be a key factor in tumorigenesis in some cancers 34 Supporting this claim GSK 3 inhibitors have been shown to induce apoptosis in glioma and pancreatic cancer cells 26 35 GSK 3 also seems to be responsible for NFkB aberrant activity in pediatric acute lymphoblastic leukemia and pancreatic cancer cells In renal cancer cells GSK 3 inhibitors induce cell cycle arrest differentiation of the malignant cells and autophagy In contrast to the above neoplasms high expression of inactive pGSK3b S9 is found in skin oral and lung cancers suggesting tumor suppressive effects of the enzyme in these cancers In melanoma the microRNA miR 769 inhibits GSK 3 activity during the tumor development process also indicating tumor suppressive effects of GSK3 23 GSK 3 inhibitors have also shown promise in the treatment of T2DM 17 Though GSK 3 activity under diabetic conditions can differ radically across different tissue types studies have shown that introducing competitive inhibitors of GSK 3 can increase glucose tolerance in diabetic mice 20 GSK 3 inhibitors may also have therapeutic effects on hemorrhagic transformation after acute ischemic stroke 36 GSK 3 can negatively regulate the insulin signaling pathway by inhibiting IRS1 via phosphorylation of serine 332 18 rendering the insulin receptor incapable of activating IRS1 and further initiating the canonical PI3K Akt pathway The role that inhibition of GSK 3 might play across its other signaling roles is not yet entirely understood GSK 3 inhibition also mediates an increase in the transcription of the transcription factor Tbet Tbx21 and an inhibition of the transcription of the inhibitory co receptor programmed cell death 1 PD 1 on T cells 37 GSK 3 inhibitors increased in vivo CD8 OT I CTL function and the clearance of viral infections by murine gamma herpesvirus 68 and lymphocytic choriomeningitis clone 13 as well as anti PD 1 in immunotherapy Inhibitors EditGlycogen synthase kinase inhibitors are different chemotypes and have variable mechanisms of action they may be cations from natural sources synthetic ATP and non ATP competitive inhibitors and substrate competitive inhibitors GSK3 is a bi lobar architecture with N terminal and C terminal the N terminal is responsible for ATP binding and C terminal which is called as activation loop mediates the kinase activity Tyrosine located at the C terminal it essential for full GSK3 activity 38 Benefits of GSK 3b inhibitors Edit In diabetes GSK 3b inhibitors increase insulin sensitivity glycogen synthesis and glucose metabolism in skeletal muscles and reduce obesity by affecting the adipogenesis process 39 GSK 3b is also over expressed in several types of cancers like colorectal ovarian and prostate cancer 38 GSK 3b inhibitors also aid in the treatment of Alzheimer s disease citation needed stroke 36 and mood disorders including bipolar disorder 40 Specific agents Edit Inhibitors of GSK 3 include 41 42 43 44 Metal cations Edit Beryllium Copper Lithium IC50 2mM Mercury Tungsten Indirect Zinc IC50 15mM ATP competitive Edit Marine organism derived Edit 6 BIO IC50 1 5mM Dibromocantharelline IC50 3mM Hymenialdesine IC50 10nM Indirubin IC50 5 50nM MeridianinAminopyrimidines Edit CHIR99021 IC50 6 9nM 10nM CHIR98014 IC50 0 58 0 65nM CT98014 CT98023 CT99021 TWS119 IC50 30nM Arylindolemaleimide Edit SB 216763 IC50 34nM SB 41528 IC50 31 78nM Thiazoles Edit AR A014418 IC50 104nM AZD 1080 IC50 6 9nM 31nM Paullones Edit IC50 4 80nM Alsterpaullone Cazpaullone KenpaulloneAloisines Edit IC50 0 5 1 5mM Non ATP competitive Edit Marine organism derived Edit Manzamine A IC50 1 5mM Palinurine IC50 4 5mM Tricantine IC50 7 5mM Thiazolidinediones Edit TDZD 8 IC50 2mM NP00111 IC50 2mM NP031115 IC50 4mM Tideglusib IC50 60nM Halomethylketones Edit HMK 32 IC50 1 5mM Peptides Edit L803 mts IC50 20mM L807 mts IC50 1mM Unknown Mechanism small molecule inhibitors Edit COB 187 IC50 11nM 22nM COB 152 IC50 77nM 132nM Lithium Edit Lithium which is used in the treatment of bipolar disorder was the first natural GSK 3 inhibitor discovered It inhibits GSK 3 directly by competition with magnesium ions and indirectly by phosphorylation and auto regulation of serine Lithium has been found to have insulin like effects on glucose metabolism including stimulation of glycogen synthesis in fat cells skin and muscles increasing glucose uptake and activation of GS activity In addition to inhibition of GSK 3 it also inhibits other enzymes involved in the regulation of glucose metabolisms such as myo inositol 1 monophosphatase and 1 6 bisphosphatase Also it has shown therapeutic benefit in Alzheimer s and other neurodegenerative diseases such as epileptic neurodegeneration 43 Naproxen and Cromolyn Edit Naproxen is a non steroidal anti inflammatory drug while cromolyn is an anti allergic agent which acts as a mast cell stabilizer Both drugs have demonstrated the anticancer effect in addition to hypoglycemic effect due to inhibition of glycogen synthase kinase 3b GSK 3b To validate the anti GSK 3b hypothesis of naproxen and cromolyn docking of the two structures against GSK 3b binding pocket and comparing their fitting with known GSK 3b inhibitor ARA014418 was performed in addition to measuring the serum glucose serum insulin serum C peptide weight variation and hepatic glycogen levels for normal and diabetic fasting animal s models to assess their in vitro hypoglycemic effects citation needed Naproxen and cromolyn were successfully docked into the binding site of GSK 3b both were fitted into its binding pocket They exhibited electrostatic hydrophobic and hydrogen bonding interactions with key amino acids within the binding pocket with binding interaction profiles similar to AR A014418 the known inhibitor The negative charges of the carboxylic acid groups in both drugs interact electrostatically with the positively charged guanidine group of Arg141 Moreover the hydrogen bonding interactions between carboxylic acid moieties of cromolyn and the ammonium groups of Lys183 and Lys60 in addition to p stacking of the naphthalene ring system of naproxen with the phenolic ring of Tyr134 Antidiabetic effects of naproxen and cromolyn In normal animal models both drugs have showed dose dependent reduction in blood glucose levels and rise in glycogen levels In chronic type II diabetic model glucose levels were also reduced and glycogen level and insulin levels were elevated in a dose dependent manner with a reduction in plasma glucose citation needed Anti obesity effects of naproxen and cromolyn Both drugs showed significant anti obesity effects as they reduce body weight resistin and glucose levels in a dose dependent manner They were also found to elevate adiponectin insulin and C peptide levels in a dose dependent manner 39 Famotidine Edit Famotidine is a specific long acting H2 antagonist that decreases gastric acid secretion It is used in the treatment of peptic ulcer disease GERD and pathological hypersecretory conditions like Zollinger Ellison syndrome 14 15 H2 receptor antagonists affect hormone metabolism but their effect on glucose metabolism is not well established 16 A study has revealed a glucose lowering effect for famotidine citation needed The study of famotidine binding to the enzyme has showed that famotidine can be docked within the binding pocket of GSK 3b making significant interactions with key points within the GSK 3b binding pocket Strong hydrogen bond interactions with the key amino acids PRO 136 and VAL 135 and potential hydrophobic interaction with LEU 188 were similar to those found in the ligand binding to the enzyme AR A014418 citation needed Furthermore famotidine showed high GSK 3b binding affinity and inhibitory activity due to interactions that stabilize the complex namely hydrogen bonding of guanidine group in famotidine with the sulfahydryl moiety in CYS 199 and electrostatic interactions between the same guanidine group with the carboxyl group in ASP 200 the hydrogen bond between the terminal NH2 group the OH of the TYR 143 and the hydrophobic interaction of the sulfur atom in the thioether with ILE 62 In vitro studies showed that famotidine inhibits GSK 3b activity and increases liver glycogen reserves in a dose dependent manner A fourfold increase in the liver glycogen level with the use of the highest dose of famotidine 4 4 mg kg was observed Also famotidine has been shown to decrease serum glucose levels 30 and 60 minutes after oral glucose load in healthy individuals 45 Curcumin Edit Curcumin which Is a constituent of turmeric spice has flavoring and coloring properties 46 It has two symmetrical forms enol the most abundant forms and ketone 47 48 Curcumin has wide pharmacological activities anti inflammatory 49 anti microbial 50 hypoglycemic anti oxidant and wound healing effects 51 In animal models with Alzheimer disease it has anti destructive effect of beta amyloid in the brain 52 and recently it shows anti malarial activity 53 Curcumin also has chemo preventative and anti cancer effects citation not found and it has been shown to attenuate oxidative stress and renal dysfunction in diabetic animals with chronic use 54 Curcumin s mechanism of action is anti inflammatory it inhibits the nuclear transcriptional activator kappa B NF KB that is activated whenever there is inflammatory response citation needed NF kB has two regulatory factors IkB and GSK 3 55 which suggests curcumin directly binds and inhibits GSK 3B An in vitro study confirmed GSK 3B inhibition by simulating molecular docking using a silico docking technique 56 The concentration at which 50 of GK 3B would be inhibited by curcumin is 66 3 nM 56 Among its two forms experimental and theoretical studies show that the enol form is the favored form due to its intra molecular hydrogen bonding and an NMR experiment show that enol form exist in a variety of solvents citation needed Olanzapine Edit Antipsychotic medications are increasingly used for schizophrenia bipolar disorder anxiety and other psychiatric conditions 57 Atypical antipsychotics are more commonly used than first generation antipsychotics because they decrease the risk of extrapyramidal symptoms such as tardive dyskinesia and have better efficacy 58 Olanzapine and atypical antipsychotics induce weight gain through increasing body fat 59 It also affects glucose metabolism and several studies shows that it may worsen diabetes 60 A recent study shows that olanzapine inhibits GSK3 activity suggesting olanzapine permits glycogen synthesis A study of the effect of olanzapine on mouse blood glucose and glycogen levels showed a significant decrease in blood glucose level and elevation of glycogen level in mice and the IC50 of olanzapine were 91 0 nm which is considered a potent inhibitor The study also illustrates that sub chronic use of olanzapine results in potent inhibition of GSK3 40 Pyrimidine derivatives Edit Pyrimidine analogues are antimetabolites that interfere with nucleic acid synthesis 61 Some of them have been shown to fit the ATP binding pocket of GSK 3b to lower blood glucose levels and improve some neuronal diseases 62 See also EditKetamine Tau protein kinaseReferences Edit PDB 1J1B Aoki M Yokota T Sugiura I Sasaki C Hasegawa T Okumura C et al March 2004 Structural insight into nucleotide recognition in tau protein kinase I glycogen synthase kinase 3 beta Acta Crystallographica Section D Biological Crystallography 60 Pt 3 439 446 doi 10 1107 S090744490302938X PMID 14993667 a b Embi N Rylatt DB Cohen P June 1980 Glycogen synthase kinase 3 from rabbit skeletal muscle Separation from cyclic AMP dependent protein kinase and phosphorylase kinase European Journal of Biochemistry 107 2 519 527 doi 10 1111 j 1432 1033 1980 tb06059 x PMID 6249596 Beurel E Grieco SF Jope RS April 2015 Glycogen synthase kinase 3 GSK3 regulation actions and diseases Pharmacology amp Therapeutics 148 114 131 doi 10 1016 j pharmthera 2014 11 016 PMC 4340754 PMID 25435019 a b c Jope RS Johnson GV February 2004 The glamour and gloom of glycogen synthase kinase 3 Trends in Biochemical Sciences 29 2 95 102 doi 10 1016 j tibs 2003 12 004 PMID 15102436 Turlik J Wasikiewicz E Domaradzka A Chrostek G Gniadzik W Domagalski M Duda P December 2021 GSK3b Activity in Reward Circuit Functioning and Addiction NeuroSci 2 4 443 466 doi 10 3390 neurosci2040033 ISSN 2673 4087 Pandey MK DeGrado TR 2016 Glycogen Synthase Kinase 3 GSK 3 Targeted Therapy and Imaging Theranostics 6 4 571 593 doi 10 7150 thno 14334 PMC 4775866 PMID 26941849 Ali A Hoeflich KP Woodgett JR August 2001 Glycogen synthase kinase 3 properties functions and regulation Chemical Reviews 101 8 2527 2540 doi 10 1021 cr000110o PMID 11749387 Eldar Finkelman H March 2002 Glycogen synthase kinase 3 an emerging therapeutic target Trends in Molecular Medicine 8 3 126 132 doi 10 1016 S1471 4914 01 02266 3 PMID 11879773 Hooper C Killick R Lovestone S March 2008 The GSK3 hypothesis of Alzheimer s disease Journal of Neurochemistry 104 6 1433 1439 doi 10 1111 j 1471 4159 2007 05194 x PMC 3073119 PMID 18088381 Glycogen synthase kinase at the U S National Library of Medicine Medical Subject Headings MeSH GSK1 GSK2 NCBI Gene Dajani R Fraser E Roe SM Young N Good V Dale TC Pearl LH June 2001 Crystal structure of glycogen synthase kinase 3 beta structural basis for phosphate primed substrate specificity and autoinhibition Cell 105 6 721 732 doi 10 1016 S0092 8674 01 00374 9 PMID 11440715 S2CID 17401752 Bouskila M Hunter RW Ibrahim AF Delattre L Peggie M van Diepen JA et al November 2010 Allosteric regulation of glycogen synthase controls glycogen synthesis in muscle Cell Metabolism 12 5 456 466 doi 10 1016 j cmet 2010 10 006 PMID 21035757 Woodgett JR August 1994 Regulation and functions of the glycogen synthase kinase 3 subfamily Seminars in Cancer Biology 5 4 269 275 PMID 7803763 Woodgett JR September 2001 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schizophrenia Neuropsychiatric Disease and Treatment 6 573 581 doi 10 2147 NDT S5463 PMC 2938306 PMID 20856920 Murphy F Middleton M 2012 Cytostatic and cytotoxic drugs A worldwide yearly survey of new data in adverse drug reactions and interactions Side Effects of Drugs Annual Vol 34 pp 731 747 doi 10 1016 B978 0 444 59499 0 00045 3 ISBN 978 0 444 59499 0 Kramer T Schmidt B Lo Monte F 2012 Small Molecule Inhibitors of GSK 3 Structural Insights and Their Application to Alzheimer s Disease Models International Journal of Alzheimer s Disease 2012 381029 doi 10 1155 2012 381029 PMC 3408674 PMID 22888461 External links EditGlycogen Synthase Kinase 3 at the U S National Library of Medicine Medical Subject Headings MeSH Portal Biology Retrieved from https en wikipedia org w index php title GSK 3 amp oldid 1170321372 Inhibitors, wikipedia, wiki, book, books, library,

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