HDAC

Histone deacetylases

HDAC

HDAC Isoform Specific Products:

HDAC Isoform Comparison

HDAC Related Products (637)
Antibodies (16)
HDAC Signaling Pathway
HDAC Isoform Comparison

By Effects:	Controls (2) Ligands (2) Inhibitors (569) Degraders (14) Antagonists (2) Activators (9) Modulators (3)

Cat. No.	Product Name	Effect	Purity	Chemical Structure

HY-RS06071

Hdac3 Mouse Pre-designed siRNA Set A	Inhibitor
Hdac3 Mouse Pre-designed siRNA Set A contains three designed siRNAs for Hdac3 gene (Mouse), as well as a negative control, a positive control, and a FAM-labeled negative control.

Hdac3 Mouse Pre-designed siRNA Set A Hdac3 Mouse Pre-designed siRNA Set A

HY-162378

LT-630	Inhibitor
LT-630 is a HDAC6 inhibitor. LT-630 ameliorates liver injury by reducing oxidative damage.

HY-N13121

Daphnegiravone D	Inhibitor
Daphnegiravone D (compound 70) is an HDAC6 inhibitor with anti-hepatocellular carcinoma activity. Daphnegiravone D can induce apoptosis and selectively inhibit the proliferation of liver cancer cells through the p38 and JNK MAPK pathways.

HY-145815

JPS014
JPS014 is a benzamide-based Von Hippel-Lindau (VHL) E3-ligase proteolysis targeting chimeras (PROTAC). JPS014 degrades class I histone deacetylase (HDAC). JPS014 is potent HDAC1/2 degrader correlated with greater total differentially expressed genes and enhanced apoptosis in HCT116 cells.

HY-163803

CM-444	Inhibitor
CM-444 is inhibitor for HDAC (IC₅₀ is 6 nM-0.6 μM) and DNA methyltransferases (DNMT, IC₅₀ is 1.8-2.3 μM). CM-444 is an inducer for the differentiation of acute myeloid leukemia cells. CM-444 exhibits anti-leukemic activity and improves the survival rate in mouse models.

HY-146212

HDAC/HSP90-IN-4
These compounds have strong hdac and hsp90 inhibitory activities. Compound 20 (HDAC ic₅₀   =   194   nm; Hsp90 α < b> Ic₅₀ =   153   nm) and compound 26 ((HDAC ic₅₀=   360   nm; Hsp90 α < b> Ic₅₀   =   77   nm) shows the strongest HDAC and HSP90 α Inhibitory activity. Both compounds can induce hsp90 expression and down regulate hsp90 client proteins, which play an important role in regulating the survival and invasion of cancer cells.

HY-144725

HDAC1/6-IN-1	Inhibitor
HDAC1/6-IN-1 (compound D7) is a potent multitarget inhibitor of GLP, HDAC6 and HDAC1, with IC₅₀ values of 1.3, 13, and 89 nM, respectively. HDAC1/6-IN-1 can inhibit the methylation and deacetylation of H3K9 on protein level. HDAC1/6-IN-1 induces cancer cell apoptosis, G0/G1 cell cycle arrest, and blocks migration and invasion.

HY-169156

HDAC6-IN-49	Inhibitor
HDAC6-IN-49 (Compound 3) is an inhibitor for HDAC with IC₅₀ of 0.012 and 0.735 μM for HDAC6 and HDAC1. HDAC6-IN-49 also exhibits inhibitory activities against MAO-B, cholinesterase (ChE), histamine receptor (H3R) and serotonin 6 receptor (5-HT6R). HDAC6-IN-49 exhibits neuroprotective efficacy on SH-SY5Y cell. HDAC6-IN-49 improves cognitive function and locomotor ability in Drosophila Parkinson's disease models and in C. elegans Alzheimer's disease models.

HY-173330

HDAC-IN-89	Inhibitor
HDAC-IN-89 is an inhibitor of HDAC1 (IC₅₀: 0.95 nM), HDAC2 (IC₅₀: 0.86 nM), HDAC3 (IC₅₀: 1.06 nM) and HDAC8 (IC₅₀: 4.24 nM). HDAC-IN-89 blocks the cell cycle and induces apoptosis. HDAC-IN-89 has anti-tumor activity.

HY-125645

M122	Inhibitor
M122 is a potent inhibitor of HDAC1 and HDAC2, with the IC₅₀ values of 0.48 μM and 0.47 μM, respectively, respectively. M122 has antitumor activity.

HY-139815

ZYJ-34c	Inhibitor
ZYJ-34c is an orally active and potent histone deacetylase inhibitor (HDACi) with IC₅₀s of 0.056 μM and 0.146 μM for HDAC6 and HDAC8, respectively. ZYJ-34c causes G1 phase arrest in low concentration. ZYJ-34c has antiproliferative activities. ZYJ-34c exhibits antitumor potency in MDA-MB-231 and HCT116 xenograft models and possesses antimetastatic potential in a mouse hepatoma-22 (H22) pulmonary metastasis model.

HY-100585R

Splitomicin (Standard)	Inhibitor
Splitomicin (Standard) is the analytical standard of Splitomicin. This product is intended for research and analytical applications. Splitomicin (Splitomycin) is a selective Sir2p inhibitor. Splitomicin inhibits NAD+-dependent HDAC activity of Sir2 protein. Splitomicin induces dose-dependent inhibition of HDAC in the yeast extract with an IC50 of 60 μM[1].

HY-148624

CHDI-00484077	Inhibitor
CHDI-00484077 (Compound 12) is a CNS-penetrant class IIa HDAC inhibitor, with IC₅₀s of 0.01 μM (HDAC4), 0.02 μM(HDAC5), 0.02 μM (HDAC7), 0.03 μM (HDAC9) respectively. CHDI-00484077 can be used for research of huntington’s disease.

HY-160846

HDAC6-IN-40	Inhibitor
HDAC6-IN-40 (Compound I-6) is an inhibitor for HDAC6 with IC₅₀ of 0.029 μM.

HY-128436

KT-531	Inhibitor
KT-531 is a potent and selective inhibitor of HDAC6 with an IC₅₀ of 8.5 nM. KT-531 exhibits strong inhibition against SUP-T11 cells with an IC₅₀ of 0.42 μM. KT-531 can be used in study hematological cancers.

HY-W400496

Valproic acid β-D-glucuronide	Control
Valproic acid β-D-glucuronide is the major urinary metabolite of Valproic acid (HY-10585).

HY-136959

M133	Inhibitor
M133 is a HDAC1 and HDAC2 selective inhibitor which shows potent antiproliferative activity against diverse human tumor cell lines with IC₅₀s of 0.75-1.94 μM. M133 can be used for cancer research.

HY-N7036R

Rhamnetin (Standard)	Inhibitor
Rhamnetin (Standard) is the analytical standard of Rhamnetin. This product is intended for research and analytical applications. Rhamnetin is a quercetin derivative found in Coriandrum sativum, inhibits secretory phospholipase A2 and histone deacetylase 2 (HDAC2). Rhamnetin exhibits antitumor, antioxidant and anti-inflammatory activity.

HY-10528R

Tasquinimod (Standard)	Modulator
Tasquinimod (Standard) is the analytical standard of Tasquinimod. This product is intended for research and analytical applications. Tasquinimod is an oral antiangiogenic agent, which has the potential for castration-resistant prostate cancer treatment. Tasquinimod binds to the regulatory Zn2+ binding domain of HDAC4 with Kd of 10-30 nM. Tasquinimod also is a S100A9 inhibitor[1][2][3].

HY-164539

TMU 35435	Inhibitor
TMU 35435 is a histone deacetylase (HDAC) inhibitor. TMU-35435 inhibits the NHEJ pathway through ubiquitination of DNA-dependent protein kinase catalytic subunit (DNA-PKcs). In addition, TMU 35435 enhances radiosensitivity by inducing misfolded protein aggregation and autophagy in TNBC.

TCR CD3 GPCR Adrenergic Agonists, Endothelin, Angiotensin, 5-HT, and Others PKC PKD Rho PLCβ CaMK 14-3-3 14-3-3 HDACII LMB CRM1 HDACII HDACII 14-3-3 HDACII MEF2 p300 Cytokines
Cytokine receptors
Adhesion molecules
(e.e., LFA1) HSP90 p23 HDAC6 HDACi p23 HSP90
HDAC6 Proteasome HDAC1 p53 HDAC1 p53 HATs HDAC Antigen presentation:
Co-stimulatory molecules
(e.g., CD40, CD86)
MHCII expression Anti-viral response: IFN-stimulated
genes (e.g., Rsad2, Ifit2, ISG54) Cyclin E/A, TLR TRIF TRAM HDAC6 MyD88 Mal HDAC
1/2/3 NF-κB HDAC2 HDAC6 MTA-1 HDAC
1/2/3 HATs MKP-1 p38 HDAC
1/8 IRF AP-1 HDAC11 IL-10 HATs HDAC CBP p53 HAT
activity CBP p53 CBP p53 IFNGR IFNγ HDAC
1/2 CIITA IFNα/β IFNAR HDAC1 JAK STAT PLZF HDAC
1/2/3 HATs HDAC HDAC BAX HATs BAX Apoptosis E2F p53 p21 CDK Cyclin HDAC RB HDAC RB E2F DP TF E2F DP TK, DHFR, ... Inflammatory mediators:
Cytokines
(e.g., IL-6, TNFα, Ifnβ) Chemokines (e.g., CXCL10, Ccl2/7)
Other mediators
(e.g., MMP9, Edn-1)

Download HDAC Signaling Pathway Map.

TCR, GPCR and HDAC II interaction: Diverse agonists act through G-protein-coupled receptors (GPCRs) to activate the PKC-PKD axis, CaMK, Rho, or MHC binding to antigens stimulates TCR to activate PKD, leading to phosphorylation of class II HDACs. Phospho-HDACs dissociate from MEF2, bind 14-3-3, and are exported to the cytoplasm through a CRM1-dependent mechanism. CRM1 is inhibited by leptomycin B (LMB). Release of MEF2 from class II HDACs allows p300 to dock on MEF2 and stimulate gene expression. Dephosphorylation of class II HDACs in the cytoplasm enables reentry into the nucleus^[1].

TLR: TLR signaling is initiated by ligand binding to receptors. The recruitment of TLR domain-containing adaptor protein MyD88 is repressed by HDAC6, whereas NF-κB and MTA-1 can be negatively regulated by HDAC1/2/3 and HDAC2, respectively. Acetylation by HATs enhance MKP-1 which inhibits p38-mediated inflammatory responses, while HDAC1/2/3 inhibits MKP-1 activity. HDAC1 and HDAC8 repress, whereas HDAC6 promotes, IRF function in response to viral challenge. HDAC11 inhibits IL-10 expression and HDAC1 and HDAC2 represses IFNγ-dependent activation of the CIITA transcription factor, thus affecting antigen presentation^[2][3].

IRNAR: IFN-α/β induce activation of the type I IFN receptor and then bring the receptor-associated JAKs into proximity. JAK adds phosphates to the receptor. STATs bind to the phosphates and then phosphorylated by JAKs to form a dimer, leading to nuclear translocation and gene expression. HDACs positively regulate STATs and PZLF to promote antiviral responses and IFN-induced gene expression^[2][3].

Cell cycle: In G1 phase, HDAC, Retinoblastoma protein (RB), E2F and polypeptide (DP) form a repressor complex. HDAC acts on surrounding chromatin, causing it to adopt a closed chromatin conformation, and transcription is repressed. Prior to the G1-S transition, phosphorylation of RB by CDKs dissociates the repressor complex. Transcription factors (TFs) gain access to their binding sites and, together with the now unmasked E2F activation domain. E2F is then free to activate transcription by contacting basal factors or by contacting histone acetyltransferases, such as CBP, that can alter chromatin structure^[4].

The function of non-histone proteins is also regulated by HATs/HDACs. p53: HDAC1 impairs the function of p53. p53 is acetylated under conditions of stress or HDAC inhibition by its cofactor CREB binding protein (CBP) and the transcription of genes involved in differentiation is activated. HSP90: HSP90 is a chaperone that complexes with other chaperones, such as p23, to maintain correct conformational folding of its client proteins. HDAC6 deacetylates HSP90. Inhibition of HDAC6 would result in hyperacetylated HSP90, which would be unable to interact with its co-chaperones and properly lead to misfolded client proteins being targeted for degradation via the ubiquitin-proteasome system^[5][6].

Reference:

[1]. Vega RB, et al. Protein kinases C and D mediate agonist-dependent cardiac hypertrophy through nuclear export of histone deacetylase 5.Mol Cell Biol. 2004 Oct;24(19):8374-85.
[2]. Shakespear MR, et al. Histone deacetylases as regulators of inflammation and immunity. Trends Immunol. 2011 Jul;32(7):335-43.
[3]. Suliman BA, et al. HDACi: molecular mechanisms and therapeutic implications in the innate immune system.Immunol Cell Biol. 2012 Jan;90(1):23-32.
[4]. Brehm A, et al. Retinoblastoma protein meets chromatin.Trends Biochem Sci. 1999 Apr;24(4):142-5.
[5]. Butler R, et al. Histone deacetylase inhibitors as therapeutics for polyglutamine disorders.Nat Rev Neurosci. 2006 Oct;7(10):784-96
[6]. Minucci S, et al. Histone deacetylase inhibitors and the promise of epigenetic (and more) treatments for cancer.Nat Rev Cancer. 2006 Jan;6(1):38-51.

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HDAC

HDAC

HDAC Isoform Specific Products:

HDAC Isoform Specific Products:

HDAC Related Products (637)

Antibodies (16)

HDAC Signaling Pathway

HDAC Isoform Comparison

HDAC Related Products (637):