TMEM17 Activators
Chemical activators of TMEM17 encompass a variety of compounds that engage different cellular mechanisms to initiate the protein's activity. Calcium chloride is a notable activator, enhancing intracellular calcium levels which may lead to the phosphorylation of TMEM17, thus priming it for participation in cellular processes such as membrane fusion or signaling. Similarly, magnesium sulfate contributes to TMEM17 activation by increasing cellular magnesium ion concentrations, essential for numerous enzymes that could be integral to TMEM17's role in membrane dynamics. Zinc acetate provides zinc ions, which are crucial cofactors for a plethora of proteins; by increasing the availability of these ions, TMEM17's structural or catalytic roles are facilitated. Additionally, potassium chloride alters the potassium ion gradient across the cell membrane, which can directly interact with TMEM17 if its function is tied to ion transport or the regulation of membrane potential.
Furthermore, sodium bicarbonate influences TMEM17 activation by altering intracellular pH levels, which can lead to conformational changes in the protein, enabling its involvement in pH-dependent processes. D-Glucose, through its role in energy metabolism, can trigger TMEM17 activation by affecting cellular energy levels, whereas adenosine triphosphate directly provides the energy necessary for TMEM17 activation through phosphorylation or conformational changes. NAD+ serves as a cofactor in redox reactions, potentially modifying the redox state of TMEM17, which is necessary for its function in oxidative stress responses. Sodium pyruvate, a key player in the Krebs cycle and ATP production, fosters an energy-rich environment that supports TMEM17 activation. Iron(II) sulfate and copper(II) sulfate contribute essential iron and copper ions, respectively, which might be necessary for TMEM17's function in enzymatic processes or signaling pathways. Lastly, coenzyme A, by participating in lipid metabolism and acetylation reactions, can lead to post-translational modifications of TMEM17, promoting its activation and role in metabolic regulation. Each of these chemicals plays a distinct role in modulating the intracellular environment to favor TMEM17 activation, reflecting the multifaceted nature of cellular protein regulation.
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| Product Name | CAS # | Catalog # | QUANTITY | Price | Citations | RATING |
|---|---|---|---|---|---|---|
Calcium chloride anhydrous | 10043-52-4 | sc-207392 sc-207392A | 100 g 500 g | $66.00 $262.00 | 1 | |
Calcium chloride can activate TMEM17 by increasing intracellular calcium levels, which may lead to the phosphorylation of TMEM17, thereby activating its function in cellular processes such as membrane fusion or signaling. | ||||||
Magnesium sulfate anhydrous | 7487-88-9 | sc-211764 sc-211764A sc-211764B sc-211764C sc-211764D | 500 g 1 kg 2.5 kg 5 kg 10 kg | $46.00 $69.00 $163.00 $245.00 $418.00 | 3 | |
Magnesium sulfate can activate TMEM17 by enhancing the magnesium ion concentration in the cell, which is necessary for the function of many enzymes and could be critical for the activation of TMEM17 and its role in membrane dynamics. | ||||||
Zinc | 7440-66-6 | sc-213177 | 100 g | $48.00 | ||
Zinc acetate can activate TMEM17 by delivering zinc ions that are crucial cofactors for many proteins, potentially including TMEM17, thus activating its structural or catalytic roles. | ||||||
Potassium Chloride | 7447-40-7 | sc-203207 sc-203207A sc-203207B sc-203207C | 500 g 2 kg 5 kg 10 kg | $55.00 $155.00 $285.00 $455.00 | 5 | |
Potassium chloride can activate TMEM17 by altering the potassium ion gradient across the cell membrane, which could directly influence TMEM17 function if it is involved in ion transport or membrane potential regulation. | ||||||
Sodium bicarbonate | 144-55-8 | sc-203271 sc-203271A sc-203271B sc-203271C sc-203271D | 25 g 500 g 1 kg 5 kg 25 kg | $21.00 $29.00 $43.00 $84.00 $697.00 | 1 | |
Sodium bicarbonate can activate TMEM17 by changing the pH balance within the cell, which may lead to conformational changes in TMEM17, resulting in its activation and participation in pH-dependent cellular processes. | ||||||
D(+)Glucose, Anhydrous | 50-99-7 | sc-211203 sc-211203B sc-211203A | 250 g 5 kg 1 kg | $38.00 $198.00 $65.00 | 5 | |
D-Glucose can activate TMEM17 by participating in energy metabolism, potentially leading to alterations in energy levels within the cell that can trigger TMEM17 activation if it is linked to cellular energy status. | ||||||
Adenosine 5′-Triphosphate, disodium salt | 987-65-5 | sc-202040 sc-202040A | 1 g 5 g | $39.00 $75.00 | 9 | |
Adenosine triphosphate can activate TMEM17 by providing the necessary energy for its activation through phosphorylation or conformational changes that enable TMEM17 to participate actively in cellular processes. | ||||||
NAD+, Free Acid | 53-84-9 | sc-208084B sc-208084 sc-208084A sc-208084C sc-208084D sc-208084E sc-208084F | 1 g 5 g 10 g 25 g 100 g 1 kg 5 kg | $57.00 $191.00 $302.00 $450.00 $1800.00 $3570.00 $10710.00 | 4 | |
NAD+ can activate TMEM17 by serving as a cofactor in redox reactions, potentially altering the redox state of TMEM17, which may be necessary for its activation and function in oxidative stress responses or other redox-sensitive pathways. | ||||||
Iron(II) sulfate solution | 10028-21-4 | sc-224024 | 1 each | $46.00 | ||
Iron(II) sulfate can activate TMEM17 by providing iron ions, which may be essential for the catalytic activity of TMEM17 if it is involved in iron-dependent enzymatic processes or signaling pathways. | ||||||
Copper(II) sulfate | 7758-98-7 | sc-211133 sc-211133A sc-211133B | 100 g 500 g 1 kg | $46.00 $122.00 $189.00 | 3 | |
Copper(II) sulfate can activate TMEM17 by supplying copper ions necessary for the function of enzymes that might interact with TMEM17, thereby facilitating its activation in copper-dependent pathways. | ||||||