Epigenetics
Epigenetics research delves into the molecular mechanisms that control gene expression and cellular traits without altering the underlying DNA sequence. One crucial aspect of this field is the role of small molecules, which act as powerful regulators of epigenetic modifications. These small compounds, typically comprising a few dozen to a few hundred atoms, have emerged as essential tools in understanding and manipulating the epigenome.
- DNA Methylation Inhibitors: Small molecules like 5-azacytidine and 5-aza-2'-deoxycytidine are DNA methyltransferase inhibitors. They block the addition of methyl groups to DNA, leading to DNA demethylation. This can reactivate silenced genes, potentially offering therapeutic avenues for conditions like cancer.
- HDAC inhibitors: HDACs remove acetyl groups from histone proteins, contributing to gene repression. Small molecule HDAC inhibitors, such as Vorinostat and Romidepsin, can reverse this process by increasing histone acetylation, allowing genes to be more accessible for transcription. These inhibitors are being explored for cancer therapy and other conditions.
- Histone Methyltransferase Inhibitors: Small molecules like GSK126 inhibit specific histone methyltransferases, affecting histone methylation patterns. This can alter gene expression, making them promising candidates for cancer and other diseases with epigenetic dysregulation.
- RNA Modulators: Small molecules can also target non-coding RNAs involved in epigenetic regulation. For instance, small molecules called small interfering RNAs (siRNAs) can be designed to target and degrade specific long non-coding RNAs, influencing gene expression.
- Epigenetic Reader Domain Inhibitors: These small molecules target proteins that recognize and bind to specific epigenetic marks. Examples include inhibitors of bromodomain-containing proteins (BET inhibitors), which can disrupt gene regulation by interfering with protein-DNA interactions.
Small molecules in epigenetics research not only provide insights into the fundamental biology of gene regulation but also hold immense promise for developing novel therapeutics. Their ability to selectively modulate specific epigenetic marks and pathways has led to ongoing clinical trials and drug development efforts for various diseases, including cancer, neurological disorders, and inflammatory conditions. Understanding and harnessing the power of these small molecules is at the forefront of modern epigenetics research, offering new hope for precision medicine and targeted therapies.
3 key components involved in the regulation of epigenetic modifications
Epigenetics Writer
Epigenetics writers are enzymes responsible for adding chemical marks or modifications to DNA or histone proteins. These marks include DNA methylation (addition of methyl groups to DNA) and histone modifications (such as acetylation, methylation, phosphorylation, etc.).
Epigenetics Reader
Function: Epigenetics readers are proteins that can recognize and bind to specific epigenetic marks on DNA or histones. These reader proteins interpret the epigenetic code and facilitate downstream cellular processes, such as gene activation or repression.
Epigenetics Eraser
Function: Epigenetics erasers are enzymes responsible for removing or reversing epigenetic marks on DNA or histones. This process allows for the dynamic regulation of gene expression and the resetting of epigenetic states during various stages of development and in response to environmental changes.
-
EGFR, PKA,PKC inhibitor
Daphnetin is a coumarin analog that acts as an inhibitor of several protein kinases. It inhibits EGFR kinase (IC50 = 7.67 μM), PKA (IC50 = 9.33 μM), and PKC (IC50 = 25 μM), in vitro. The inhibition of EGFR kinase by daphnetin was competitive to ATP and non-competitive to the peptide substrate. Also acts as a potent antioxidant and anti-malarial agent. -
Akt inhibitor
A-674563 is a B/Akt inhibitor with an IC50 of 14 nM and also shows inhibitory activity against PKA and CDK2 with IC50 of 16 and 46 nM, respectively.- Kobayashi T, .et al. , Biochem Biophys Res Commun, 2018, Jan 1;495(1):1468-1475 PMID: 29196261
- Lin Xu, .et al. , Biochem Biophys Res Commun, 2016, Apr 15;472(4):662-8 PMID: 26920060
- Zou Y, .et al. , Biochem Biophys Res Commun, 2016, Aug 12;477(1):1-8 PMID: 26970307
-
PKA inhibitor
H 89 dihydrochloride is a cell-permeable, selective, reversible, ATP-competitive and potent inhibitor of protein kinase.- Guo Q, .et al. , Biomed Pharmacother, 2020, Mar;123:109812 PMID: 31945696
- Y Kaibori, .et al. , the FASEB Journal, 2019, Jan 22:fj201801519RR PMID: 30668924
-
PKA, PKG, Casein Kinase I and II inhibitor
A-3 Hydrochloride is an inhibitor of PKA (cAMP-dependent protein kinase, Ki=4.3μM) and cGMP-dependent protein kinase, Ki=3.8μM, PKC (protein kinase C, Ki=47μM), casein kinase I and II, and MLCK (myosin light chain kinase) ( Ki=7.4μM). -
PKA inhibitor
PKA inhibitor fragment (6-22) amide is a synthetic peptide that acts as a protein kinase inhibitor. -
Akt inhibitor
AT7867 dihydrochloride is a potent ATP-competitive inhibitor of Akt1/2/3 and p70S6K/PKA with IC50 of 32 nM/17 nM/47 nM and 85 nM/20 nM, respectively, little activity outside the AGC kinase family. -
protein kinase A activator
8-Bromo-cAMP is a cell perbeable cyclic AMP (cAMP) analog and a PKA activator. -
PKA activator
Dibutyryl-cAMP is a cell-permeable PKA activator by mimicing the action of endogenous cAMP. -
PKA-selective activator
6-Bnz-cAMP is a PKA-selective activator. It regulates the PKA dependent signaling pathways. -
reversible PKA inhibitor
Rp-cAMPS is a cell-permeable and reversible inhibitor of PKA (protein kinase A) (Ki = 11 uM). Rp-cAMPS is resistant to hydrolysis by phosphodiesterases and is noncompetitive with respect to ATP. -
PKA inhibitor
PKI 14-22 amide, myristoylated is a useful heat stable cAMP-dependent protein kinase inhibitor. This is often used to study PKA in cellular systems in-vitro.- Dao-Lai Zhang, .et al. , eLife, 2018, 7: e33432 PMID: 29393851
-
PKG/PKA inhibitor
cGMP Dependent Kinase Inhibitor Peptid is a specific cGKI (cyclic GMP-dependent protein kinase) inhibitor. Data indicates that it does not block cyclic GMP-dependent protein kinase phosphorylation of intact histones and has been used to study Plasmodium falciparum. - Synaptamide is a potent mediator for neurogenic differentiation of NSCs acting through PKA/CREB activation.
-
protein kinase A inhibitor
Warangalone is a prenylated isoflavone from the insecticidal plant Derris scandens that acts as a powerful inhibitor of protein kinase A. -
PKs inhibitor
HA-100 is an isoquinoline compound with an added piperazinylsulfonyl group that acts as an inhibitor of protein kinases (PKs), including PKA, PKC, and PKG (IC50 = 8, 12, and 4 μM, respectively). -
PKA activator
Jaspamycin (7-CN-7-C-Ino) is a potent activator of PKA, binding to the R site (PKAR), with an EC50 of 6.5 nM and Kd of 8 nM in Trypanosoma brucei. Jaspamycin (7-CN-7-C-Ino) does not bind with purified human PKARIα. Anti-parasite activity. -
PKs inhibitor
HA-100 is an isoquinoline compound with an added piperazinylsulfonyl group that acts as an inhibitor of protein kinases (PKs), including PKA, PKC, and PKG (IC50s = 8, 12, and 4 ?M, respectively). - Malantide is a synthetic dodecapeptide derived from the site phosphorylated by cAMP-dependent protein kinase (PKA) on the β-subunit of phosphorylase kinase. Malantide is a highly specific substrate for PKA with a Km of 15 μM and shows protein inhibitor (PKI) inhibition >90% substrate phosphorylation in various rat tissue extracts. Malantide is also an efficient substrate for PKC with a Km of 16 μM.
