ACTL9 Activators
ACTL9, also known by its aliases HSD21 and SPGF53, is a gene located within the human genome that encodes for a protein presumed to share structural similarities with the actin family. Actin proteins are highly conserved and play critical roles in various cellular functions, including cell motility, structure, and integrity. The ACTL9 protein is postulated to be a component of the dynactin complex, which is integral to cellular processes such as intracellular transport and cell division. While the specific functions of ACTL9 remain to be fully elucidated, its association with the dynactin complex suggests a role in the mechanical aspects of cellular operation. Interestingly, ACTL9 has been implicated in spermatogenic failure 53, pointing to a probable significance in human fertility, particularly in spermatogenesis, the process by which spermatozoa are produced.
The expression of ACTL9, like many genes, is subject to regulation by a variety of intracellular and extracellular factors. Certain chemicals have the potential to stimulate the expression of ACTL9 through diverse mechanisms, which are predominantly centered on the modification of chromatin structure, the alteration of transcription factor activity, or the modulation of signaling pathways that converge on gene expression. For instance, chemical agents such as retinoic acid might enhance ACTL9 transcription by engaging with nuclear receptors that directly bind to DNA sequences upstream of the ACTL9 gene, thereby promoting transcriptional initiation. Compounds like 5-Azacytidine could upregulate ACTL9 expression by inducing epigenetic changes, specifically the demethylation of DNA, which could unveil the ACTL9 gene to transcriptional enzymes. Additionally, molecules such as forskolin may activate cellular signaling cascades involving cAMP, which can lead to the activation of protein kinase A and subsequent phosphorylation of transcription factors that are known to increase gene expression. Substances like trichostatin A and sodium butyrate, both histone deacetylase inhibitors, could promote the expression of ACTL9 by inducing a more relaxed and transcriptionally active chromatin state. These examples illustrate the array of chemicals that, through their action at the molecular level, could serve as activators of ACTL9 gene expression. However, it is crucial to note that these interactions are speculative and would necessitate rigorous scientific validation to confirm their effects on ACTL9 expression.
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| Product Name | CAS # | Catalog # | QUANTITY | Price | Citations | RATING |
|---|---|---|---|---|---|---|
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 could upregulate ACTL9 by binding retinoic acid receptors that interact directly with the promoter regions of genes involved in spermatogenesis, potentially including ACTL9. | ||||||
5-Azacytidine | 320-67-2 | sc-221003 | 500 mg | $280.00 | 4 | |
By inhibiting DNA methyltransferase, 5-Azacytidine could lead to the demethylation of the ACTL9 promoter, potentially resulting in the upregulation of ACTL9 transcription in germ cells. | ||||||
Trichostatin A | 58880-19-6 | sc-3511 sc-3511A sc-3511B sc-3511C sc-3511D | 1 mg 5 mg 10 mg 25 mg 50 mg | $149.00 $470.00 $620.00 $1199.00 $2090.00 | 33 | |
Trichostatin A could stimulate ACTL9 expression by preventing histone deacetylase from removing acetyl groups on histones, thus maintaining an open chromatin conformation around the ACTL9 gene. | ||||||
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 may stimulate the synthesis of cAMP, which in turn activates protein kinase A. This activation may lead to the phosphorylation of transcription factors that enhance ACTL9 gene transcription. | ||||||
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 | |
Sodium butyrate may increase ACTL9 transcription by maintaining an open chromatin state through its histone deacetylase inhibition activity, which could lead to enhanced accessibility of the ACTL9 gene to transcriptional machinery. | ||||||
Dibutyryl-cAMP | 16980-89-5 | sc-201567 sc-201567A sc-201567B sc-201567C | 20 mg 100 mg 500 mg 10 g | $45.00 $130.00 $480.00 $4450.00 | 74 | |
This cAMP analog could stimulate ACTL9 expression by mimicking cAMP and activating protein kinase A, which may then phosphorylate transcription factors that bind to the ACTL9 gene promoter. | ||||||
(−)-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 | |
This green tea polyphenol may stimulate the expression of ACTL9 by altering the methylation status of its gene promoter or modifying the histones associated with it, thereby enhancing transcription. | ||||||
Resveratrol | 501-36-0 | sc-200808 sc-200808A sc-200808B | 100 mg 500 mg 5 g | $60.00 $185.00 $365.00 | 64 | |
Resveratrol may stimulate ACTL9 expression by activating sirtuin pathways, which can lead to deacetylation of histones and potentially lower the threshold for transcriptional activation of the ACTL9 gene. | ||||||
Lithium | 7439-93-2 | sc-252954 | 50 g | $214.00 | ||
Lithium chloride can stimulate the Wnt signaling pathway, which might lead to an increase in ACTL9 expression if the gene is downstream of this pathway, due to increased transcriptional activity. | ||||||
Rapamycin | 53123-88-9 | sc-3504 sc-3504A sc-3504B | 1 mg 5 mg 25 mg | $62.00 $155.00 $320.00 | 233 | |
Rapamycin may upregulate ACTL9 by inhibiting the mTOR pathway, which is implicated in cell growth and proliferation; this inhibition could trigger a compensatory increase in ACTL9 expression as part of a stress response. | ||||||