GSK-3 inibitori (GSK-3 Inhibitors)

Altro PI3K/Akt/mTOR Inibitori

Prodotti selettivi di isoforme

• Inibitori in evidenza
• Inibitori (37)
• Sostanza chimica (1)
• Attivatore (1)

N. Cat.	Nome del prodotto	Informazioni	Citazioni di utilizzo del prodotto	Validazioni del prodotto
S1263	CHIR-99021 (Laduviglusib)	Laduviglusib (CHIR-99021, CT99021) è un inibitore di GSK-3α e GSK-3β con valori di IC50 di 10 nM e 6,7 nM, rispettivamente. Non mostra reattività crociata contro le chinasi ciclina-dipendenti (CDK) e mostra una selettività 350 volte superiore verso GSK-3β rispetto alle CDK. Questo composto funziona come attivatore di Wnt/β-catenin e induce l'autophagy.	Cancer Cell, 2025, 43(4):776-796.e14 Circulation, 2025, 151(20):1436-1448 Nat Biomed Eng, 2025, 9(1):93-108
S2924	Laduviglusib (CHIR-99021) Hydrochloride	Laduviglusib (CHIR-99021; CT99021) HCl è il cloridrato di CHIR-99021, che è un inibitore di GSK-3α/β con IC50 di 10 nM/6,7 nM; CHIR-99021 mostra una selettività maggiore di 500 volte per GSK-3 rispetto ai suoi omologhi più stretti Cdc2 ed ERK2. CHIR-99021 è un potente attivatore farmacologico della via di segnalazione Wnt/beta-catenin. CHIR-99021 recupera significativamente l'autophagy indotta dalla luce e aumenta GR, RORα e le proteine correlate all'autofagia.	Cell, 2025, 188(11):2974-2991.e20 Cell, 2025, S0092-8674(25)00807-4 Protein Cell, 2025, pwaf098
S1075	SB216763	SB216763 è un inibitore potente e selettivo della GSK-3 con una IC50 di 34,3 nM per GSK-3α ed è ugualmente efficace nell'inibire la GSK-3β umana. Questo composto attiva l'autophagy.	iScience, 2025, 28(11):113642 iScience, 2025, 28(8):113117 Oncol Rep, 2025, 54(4)125
S2745	CHIR-98014	CHIR-98014 (CT98014) è un potente inibitore di GSK-3α/β con IC50 di 0,65 nM/0,58 nM in saggi senza cellule, con la capacità di distinguere GSK-3 dai suoi omologhi più stretti Cdc2 ed ERK2.	Med Oncol, 2025, 42(8):333 Stem Cell Res, 2025, 87:103797 Commun Med (Lond), 2025, 5(1):323
S1590	TWS119	TWS119 è un inibitore di GSK-3β con IC50 di 30 nM in un saggio senza cellule; questo composto è in grado di indurre la differenziazione neuronale e può essere utile per la biologia delle cellule staminali. L'inibizione di GSK-3β da parte di questa sostanza chimica innesca l'autophagy.	Discov Oncol, 2025, 16(1):364 Nat Commun, 2024, 15(1):2089 Sci Rep, 2024, 14(1):5038
S7198	GSK-3 Inhibitor IX (BIO)	BIO (GSK-3 Inhibitor IX, 6-bromoindirubin-3-oxime, 6-Bromoindirubin-3'-oxime, MLS 2052) è un inibitore specifico di GSK-3 con un IC50 di 5 nM per GSK-3α/β in un saggio privo di cellule, mostra una selettività >16 volte superiore a CDK5, ed è anche un inibitore pan-JAK con un IC50 di 30 nM per Tyk2. BIO induce l'apoptosi nelle cellule di melanoma umano.	Cell Rep, 2025, 44(3):115361 Development, 2025, 152(3)DEV204214 bioRxiv, 2025, 2025.04.11.648340
S7063	LY2090314	LY2090314 è un potente inibitore di GSK-3 per GSK-3α/β con IC50 di 1,5 nM/0,9 nM; può migliorare l'efficacia dei regimi chemioterapici a base di platino. Questo composto è altamente selettivo nei confronti di GSK3, come dimostrato dalla sua selettività relativa a un ampio pannello di chinasi.	Cell Mol Gastroenterol Hepatol, 2026, 20(1):101633 Cancer Cell, 2025, 43(4):776-796.e14 Cell Rep, 2025, 44(5):115617
S2823	Tideglusib	Tideglusib è un inibitore irreversibile, non ATP-competitivo di GSK-3β con IC50 di 60 nM in un saggio senza cellule; questo composto non riesce a inibire le chinasi con una Cys omologa a Cys-199 situata nel sito attivo. Fase 2.	Addict Biol, 2025, 30(5):e70044 Cell Rep, 2024, 43(9):114667 SLAS Discov, 2024, S2472-5552(24)00007-8
S2729	SB415286	SB415286 è un potente inibitore di GSK3α con IC50/Ki di 78 nM/31 nM con un'inibizione altrettanto efficace di GSK-3β. Questo composto provoca l'arresto della crescita e l'apoptosis delle cellule di mieloma multiplo.	bioRxiv, 2025, 2025.03.08.642085 Front Immunol, 2022, 13:880988 Sci Rep, 2022, 12(1):7
S7435	AR-A014418	AR-A014418 (GSK-3β Inhibitor VIII) è un inibitore di GSK3β selettivo e competitivo per l'ATP con IC50 e Ki di 104 nM e 38 nM in saggi acellulari, senza inibizione significativa su 26 altre chinasi testate.	Cancer Med, 2025, 14(5):e70047 NPJ Precis Oncol, 2024, 8(1):264 Commun Biol, 2024, 7(1):1380
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Glycogen Synthase Kinase-3: Structure and Isoform-Specific Functions

Glycogen synthase kinase-3 (GSK-3) is a constitutively active kinase that was initially identified for its role in regulating glycogen synthesis by phosphorylating and inactivating glycogen synthase. Subsequent research has revealed that GSK-3 exists as two isoforms, GSK-3α (51 kDa) and GSK-3β (47 kDa), which are encoded by separate genes (GSK3A and GSK3B, respectively) and share approximately 97% homology in their catalytic domains but differ in their N- and C-terminal regions. These structural differences contribute to isoform-specific interactions with regulatory proteins and substrates, leading to distinct functional outcomes. GSK-3β, in particular, has been implicated in a wide range of disease-related pathways, making it a primary target for inhibitor development in research investigations.

Structural Basis of GSK-3 Kinase Activity

The catalytic domain of GSK-3 contains the conserved kinase fold, consisting of an N-terminal lobe rich in β-sheets and a C-terminal lobe dominated by α-helices, with the active site located at the interface between the two lobes. A unique feature of GSK-3 is its requirement for a "priming phosphate" on substrates, which binds to an arginine-rich pocket (the "priming site") adjacent to the active site, enabling efficient phosphorylation of the substrate at a serine or threonine residue four positions C-terminal to the priming phosphate. This priming-dependent mechanism distinguishes GSK-3 from many other kinases and dictates its substrate specificity. The constitutive activity of GSK-3 is attributed to the absence of an autoinhibitory domain, with regulation primarily occurring through post-translational modifications (e.g., phosphorylation, ubiquitination) and interactions with regulatory proteins.

Isoform-Specific Roles of GSK-3α and GSK-3β

While GSK-3α and GSK-3β share overlapping substrates and functions, accumulating evidence indicates isoform-specific roles in cellular processes and disease pathogenesis. GSK-3α is predominantly expressed in adipose tissue, liver, and brain, and has been linked to glycogen metabolism and insulin resistance. In contrast, GSK-3β is ubiquitously expressed and plays critical roles in inflammation, cell survival, and neurodegeneration. For example, in Alzheimer’s disease (AD), GSK-3β phosphorylates the microtubule-associated protein tau, leading to the formation of neurofibrillary tangles, a hallmark of AD pathology. In cancer, GSK-3β exhibits both tumor-promoting and tumor-suppressive roles depending on the cellular context, regulating the activity of oncogenes such as β-catenin and p53. These isoform-specific functions highlight the importance of developing selective GSK-3 inhibitors in research to dissect the distinct roles of GSK-3α and GSK-3β.

Pathway Modulation by GSK-3 Inhibitors: Key Signaling Networks

GSK-3 is a central node in numerous signaling pathways, integrating inputs from upstream regulators such as the PI3K/Akt, Wnt, and MAPK pathways. GSK-3 inhibitors exert their effects by disrupting these pathways, leading to downstream changes in gene expression and cellular function. Understanding the pathway-specific effects of GSK-3 inhibitors is critical for their application in research and therapeutic development, as it enables the identification of context-dependent outcomes and potential off-target effects.

Wnt/β-Catenin Pathway Regulation by GSK-3β Inhibitors

The Wnt/β-catenin pathway is one of the most well-characterized pathways regulated by GSK-3β. In the absence of Wnt signaling, GSK-3β forms a destruction complex with adenomatous polyposis coli (APC), axin, and casein kinase 1 (CK1), which phosphorylates β-catenin, targeting it for ubiquitination and proteasomal degradation. GSK-3β inhibitors disrupt this destruction complex, preventing β-catenin phosphorylation and leading to its accumulation in the cytoplasm and nucleus. Nuclear β-catenin then binds to T-cell factor/lymphoid enhancer factor (TCF/LEF) transcription factors, activating the expression of target genes involved in cell proliferation and differentiation. This pathway modulation is particularly relevant in stem cell research, where GSK-3 inhibitors are used to maintain pluripotency, and in cancer research, where aberrant Wnt/β-catenin signaling drives tumorigenesis.

PI3K/Akt Pathway and GSK-3 Kinase Inhibition

The PI3K/Akt pathway is a major upstream regulator of GSK-3, with Akt phosphorylating GSK-3α at Ser21 and GSK-3β at Ser9, leading to their inactivation. GSK-3 inhibitors mimic this inhibitory effect, bypassing upstream signaling events to directly block GSK-3 activity. This pathway modulation has significant implications in neurodegenerative disease research, as the PI3K/Akt/GSK-3 axis is dysregulated in AD, Parkinson’s disease, and Huntington’s disease. In preclinical studies, GSK-3 inhibitors have been shown to reduce tau phosphorylation, protect against neuronal apoptosis, and improve cognitive function in animal models of AD. Additionally, in metabolic research, GSK-3 inhibitors enhance insulin sensitivity by regulating glycogen synthesis and glucose uptake, making them potential candidates for the treatment of type 2 diabetes.

Substrates of GSK-3: Specificity and Regulatory Mechanisms in Inhibition

GSK-3 phosphorylates over 100 substrates, including transcription factors, cytoskeletal proteins, metabolic enzymes, and signaling molecules, highlighting its pleiotropic roles in cellular physiology. The specificity of GSK-3 inhibitors for substrate phosphorylation is a critical consideration in research, as off-target effects on non-GSK-3 substrates or isoform-specific substrates can complicate data interpretation. Understanding the regulatory mechanisms that govern GSK-3-substrate interactions is essential for the development of selective inhibitors and the accurate interpretation of their biological effects.

Substrate Specificity of GSK-3β: Priming-Dependent and Priming-Independent Mechanisms

As mentioned earlier, most GSK-3 substrates require a priming phosphate for efficient phosphorylation, a mechanism that contributes to substrate specificity. For example, glycogen synthase is primed by casein kinase 2, while β-catenin is primed by CK1. However, some substrates, such as p53 and heat shock protein 90 (Hsp90), are phosphorylated by GSK-3β in a priming-independent manner, expanding the range of cellular processes regulated by this kinase. GSK-3 inhibitors can block both priming-dependent and priming-independent phosphorylation, but the extent of inhibition varies depending on the inhibitor’s binding mode and specificity for GSK-3 isoforms. In research, this substrate specificity is exploited to dissect the role of individual GSK-3 substrates in disease pathways, for example, by using inhibitors to selectively block the phosphorylation of tau in neurodegeneration research.

Regulation of GSK-3 Substrate Phosphorylation by Inhibitors

The regulation of GSK-3 substrate phosphorylation by inhibitors is a complex process that involves not only direct inhibition of kinase activity but also indirect effects on upstream signaling pathways and regulatory proteins. For instance, some GSK-3 inhibitors bind to the active site of the kinase, competing with ATP and preventing substrate phosphorylation. Others bind to allosteric sites, inducing conformational changes that reduce kinase activity. Additionally, GSK-3 inhibitors can modulate the expression of regulatory proteins that interact with GSK-3, such as axin and APC, further influencing substrate phosphorylation. In research, techniques such as mass spectrometry and phospho-specific antibodies are used to characterize the substrate-specific effects of GSK-3 inhibitors, enabling the identification of novel downstream targets and the validation of inhibitor specificity.

GSK-3 Inhibitors in Scientific Research: Tools and Translational Potential

GSK-3 inhibitors have become indispensable tools in scientific research, facilitating the dissection of GSK-3-mediated pathways and the validation of GSK-3 as a therapeutic target. A wide range of GSK-3 inhibitors have been developed, including synthetic small molecules (e.g., SB216763, CHIR99021), natural products (e.g., lithium, curcumin), and peptide inhibitors. These inhibitors vary in their potency, selectivity for GSK-3 isoforms, and binding modes, making them suitable for different research applications. For example, CHIR99021, a selective GSK-3β inhibitor, is commonly used in stem cell research to maintain pluripotency, while SB216763 is used to study the role of GSK-3 in neurodegeneration.
Despite their utility in research, the translational potential of GSK-3 inhibitors has been hindered by challenges such as off-target effects, toxicity, and limited efficacy in clinical trials. However, recent advances in structure-based drug design have led to the development of more selective and potent GSK-3 inhibitors, addressing some of these limitations. For example, inhibitors that target the unique N-terminal region of GSK-3β have been shown to exhibit higher isoform specificity, reducing off-target effects on GSK-3α. Additionally, combination therapies involving GSK-3 inhibitors and other pathway modulators are being explored in cancer and neurodegenerative disease research, aiming to enhance efficacy and reduce toxicity.
In conclusion, GSK-3 inhibitors have significantly advanced our understanding of glycogen synthase kinase-3-mediated pathways, substrate regulation, and isoform-specific functions. As research continues to unravel the complex mechanisms underlying GSK-3 activity and the effects of inhibition, the development of more selective and effective GSK-3 inhibitors holds great promise for the treatment of a wide range of diseases. The ongoing integration of structural biology, proteomics, and preclinical models in GSK-3 inhibitor research will continue to drive scientific progress and translational success in this field.