Cdc25 Activators
Cdc25 activators encompass a group of chemical compounds that specifically interact with and increase the activity of the Cdc25 family of phosphatases, which are critical regulatory enzymes in the cell cycle. The Cdc25 phosphatases, including Cdc25A, Cdc25B, and Cdc25C in humans, are responsible for the dephosphorylation of cyclin-dependent kinases (CDKs), thereby activating them and promoting progression through various phases of the cell cycle. Activators of Cdc25 would enhance this dephosphorylation activity, potentially by stabilizing the active form of the enzyme, increasing its affinity for CDK substrates, or by protecting it from regulatory proteins that would otherwise inhibit its phosphatase activity. The chemical structures of Cdc25 activators are likely to be varied, potentially including small molecules or peptides, and these would be specifically designed or identified based on their ability to bind to and modulate the function of Cdc25 phosphatases.
In the realm of fundamental cell biology research, the study of Cdc25 activators would involve detailed biochemical and molecular investigations to ascertain how these compounds affect the enzymatic activity of Cdc25 phosphatases. Assays to measure the phosphatase activity toward synthetic substrates or actual CDKs would be necessary to screen potential activator compounds. These assays could be based on colorimetric detection of free phosphate groups released by the action of Cdc25 or by employing more sophisticated methods such as mass spectrometry to directly measure the extent of dephosphorylation on CDKs. Once identified, the interaction between Cdc25 activators and the phosphatases would be characterized through a variety of techniques. Kinetic studies would reveal the effect of activators on the rates of enzymatic reactions, while biophysical methods such as isothermal titration calorimetry (ITC) or surface plasmon resonance (SPR) would provide details on the binding affinity and thermodynamics of the interaction. Furthermore, structural studies using X-ray crystallography or nuclear magnetic resonance (NMR) spectroscopy would be crucial to elucidate the molecular basis of activation, including any conformational changes in the Cdc25 phosphatases upon binding of the activators. These studies would enhance the understanding of cell cycle regulation and the role of Cdc25 enzymes within it.
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| Product Name | CAS # | Catalog # | QUANTITY | Price | Citations | RATING |
|---|---|---|---|---|---|---|
(−)-Epigallocatechin Gallate | 989-51-5 | sc-200802 sc-200802A sc-200802B sc-200802C sc-200802D sc-200802E | 10 mg 50 mg 100 mg 500 mg 1 g 10 g | $42.00 $72.00 $124.00 $238.00 $520.00 $1234.00 | 11 | |
EGCG, a component of green tea, has been shown to affect numerous signaling pathways potentially and might modulate the expression of genes involved in cell cycle regulation, including Cdc25. | ||||||
Forskolin | 66575-29-9 | sc-3562 sc-3562A sc-3562B sc-3562C sc-3562D | 5 mg 50 mg 1 g 2 g 5 g | $76.00 $150.00 $725.00 $1385.00 $2050.00 | 73 | |
Forskolin activates adenylate cyclase, leading to increased cAMP levels and PKA activation, which can regulate transcription factors that affect Cdc25 expression. | ||||||
Curcumin | 458-37-7 | sc-200509 sc-200509A sc-200509B sc-200509C sc-200509D sc-200509F sc-200509E | 1 g 5 g 25 g 100 g 250 g 1 kg 2.5 kg | $36.00 $68.00 $107.00 $214.00 $234.00 $862.00 $1968.00 | 47 | |
Curcumin has been demonstrated to affect various signaling pathways including those related to cell cycle regulation, which might result in changes to Cdc25 expression levels. | ||||||
5-Azacytidine | 320-67-2 | sc-221003 | 500 mg | $280.00 | 4 | |
As a DNA methyltransferase inhibitor, 5-Azacytidine can alter the methylation status of DNA, potentially leading to re-expression of genes that were epigenetically silenced, including possibly Cdc25 genes. | ||||||
Retinoic Acid, all trans | 302-79-4 | sc-200898 sc-200898A sc-200898B sc-200898C | 500 mg 5 g 10 g 100 g | $65.00 $319.00 $575.00 $998.00 | 28 | |
Retinoic acid can modulate gene expression via retinoic acid receptors, potentially affecting the transcription of cell cycle regulatory genes like Cdc25. | ||||||
D,L-Sulforaphane | 4478-93-7 | sc-207495A sc-207495B sc-207495C sc-207495 sc-207495E sc-207495D | 5 mg 10 mg 25 mg 1 g 10 g 250 mg | $150.00 $286.00 $479.00 $1299.00 $8299.00 $915.00 | 22 | |
Sulforaphane, found in cruciferous vegetables, can influence gene expression and has been shown to affect cell cycle regulation, which may involve modulation of Cdc25 levels. | ||||||
Resveratrol | 501-36-0 | sc-200808 sc-200808A sc-200808B | 100 mg 500 mg 5 g | $60.00 $185.00 $365.00 | 64 | |
Resveratrol has been implicated in affecting signaling pathways related to cell growth and could potentially modulate the expression of genes like Cdc25 indirectly. | ||||||
Lithium | 7439-93-2 | sc-252954 | 50 g | $214.00 | ||
Lithium is known to affect glycogen synthase kinase-3 (GSK-3) activity, which is involved in cell cycle regulation, and might influence Cdc25 expression. | ||||||
Sodium Butyrate | 156-54-7 | sc-202341 sc-202341B sc-202341A sc-202341C | 250 mg 5 g 25 g 500 g | $30.00 $46.00 $82.00 $218.00 | 19 | |
As a histone deacetylase inhibitor, sodium butyrate can cause changes in chromatin structure, potentially leading to the upregulation of genes including cell cycle regulators like Cdc25. | ||||||
Cholecalciferol | 67-97-0 | sc-205630 sc-205630A sc-205630B | 1 g 5 g 10 g | $70.00 $160.00 $290.00 | 2 | |
Vitamin D, through its receptor, can regulate gene expression. It might influence the transcription of various genes, possibly including those involved in cell cycle control like Cdc25. | ||||||