ALDH3A2 Activators
ALDH3A2 Activators encompass a diverse range of chemical compounds that indirectly boost the functional activity of ALDH3A2 through various biochemical pathways. Compounds like Retinoic Acid and Acetaldehyde act by increasing substrate availability for ALDH3A2, enhancing its enzymatic activity in aldehyde metabolism and retinoid processing. NAD+, as a crucial cofactor, directly impacts ALDH3A2's activity; higher levels of NAD+ improve ALDH3A2's efficiency in aldehyde detoxification. Disulfiram and Sulforaphane, by influencing the redox state of cells, indirectly promote ALDH3A2 activity, with Disulfiram affecting copper metabolism and Sulforaphane activating the Nrf2 pathway. This enhancement is vital for coping with increased oxidative stress, thereby necessitating the detoxification role of ALDH3A2. Similarly, Resveratrol and its glucoside, Polydatin, modify cellular metabolism and oxidative stress responses through SIRT1 modulation, indirectly leading to an augmented need for ALDH3A2's function in aldehyde processing.
The influence of metabolites like Alpha-Ketoglutarate and Fumarate, integral to the Krebs cycle, exemplifies the connection between cellular metabolism and ALDH3A2 activity. Their roles in modulating metabolic flux indirectly result in an increased demand for ALDH3A2's enzymatic action in dealing with by-products like aldehydes. Glutathione, as a primary cellular antioxidant, also plays a crucial role. By altering oxidative stress levels, it indirectly necessitates enhanced ALDH3A2 activity for maintaining cellular redox balance. Oleanolic Acid and Zinc further contribute to this regulatory network. Oleanolic Acid, through its effects on liver function and oxidative stress, and Zinc, by influencing the metalloprotein environment, both facilitate an increase in ALDH3A2 activity. Collectively, these activators, through their targeted effects on cellular metabolism, oxidative stress, and cofactor availability, foster the enhancement of ALDH3A2 mediated detoxification processes without direct activation of the protein itself.
SEE ALSO...
| 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 | $66.00 $325.00 $587.00 $1018.00 | 28 | |
Retinoic Acid influences the retinoic acid signaling pathway. ALDH3A2, being involved in aldehyde metabolism, is essential in the metabolism of retinoids. Retinoic Acid can enhance ALDH3A2 activity by increasing the substrate availability, thereby indirectly enhancing its functional activity. | ||||||
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+ serves as an essential cofactor for ALDH3A2's enzymatic activity. By increasing NAD+ levels, ALDH3A2's aldehyde dehydrogenase activity is enhanced due to the improved availability of this necessary cofactor. | ||||||
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 | $153.00 $292.00 $489.00 $1325.00 $8465.00 $933.00 | 22 | |
Sulforaphane activates Nrf2, a key regulator of antioxidant response. ALDH3A2, being part of the cellular antioxidant defense, can be indirectly activated due to the increased demand for aldehyde detoxification under enhanced oxidative stress conditions. | ||||||
Resveratrol | 501-36-0 | sc-200808 sc-200808A sc-200808B | 100 mg 500 mg 5 g | $80.00 $220.00 $460.00 | 64 | |
Resveratrol, by modulating SIRT1 activity, can indirectly affect ALDH3A2. SIRT1 influences oxidative stress responses and metabolic pathways, potentially leading to an increased requirement for ALDH3A2's aldehyde detoxification activity. | ||||||
α-Ketoglutaric Acid | 328-50-7 | sc-208504 sc-208504A sc-208504B sc-208504C sc-208504D sc-208504E sc-208504F | 25 g 100 g 250 g 500 g 1 kg 5 kg 16 kg | $33.00 $43.00 $63.00 $110.00 $188.00 $738.00 $2091.00 | 2 | |
Alpha-Ketoglutarate, as part of the Krebs cycle, can influence cellular metabolism and redox states. An increased availability of Alpha-Ketoglutarate could enhance the metabolic flux, indirectly necessitating increased ALDH3A2 activity for aldehyde processing. | ||||||
Glutathione, reduced | 70-18-8 | sc-29094 sc-29094A | 10 g 1 kg | $82.00 $2091.00 | 8 | |
Glutathione, a major antioxidant, can indirectly influence ALDH3A2 by modulating the oxidative stress levels in cells. Higher levels of glutathione may increase the need for aldehyde detoxification, thereby enhancing ALDH3A2 activity. | ||||||
Oleanolic Acid | 508-02-1 | sc-205775 sc-205775A | 100 mg 500 mg | $86.00 $302.00 | 8 | |
Oleanolic Acid has been shown to modulate liver function and oxidative stress. Through these pathways, it can indirectly increase the demand for ALDH3A2 activity in aldehyde detoxification. | ||||||
Polydatin | 65914-17-2 | sc-203203 | 10 mg | $94.00 | 5 | |
Polydatin, a resveratrol glucoside, influences SIRT1 and other metabolic pathways similar to resveratrol. This can indirectly lead to increased ALDH3A2 activity by altering cellular redox states and metabolic demands. | ||||||
Zinc | 7440-66-6 | sc-213177 | 100 g | $48.00 | ||
Zinc, an essential trace element, plays a role in many enzymatic functions and can indirectly influence ALDH3A2 activity. By modulating the metalloprotein environment in cells, Zinc can enhance the functional activity of ALDH3A2. | ||||||
Fumaric acid | 110-17-8 | sc-250031 sc-250031A sc-250031B sc-250031C | 25 g 100 g 500 g 2.5 kg | $43.00 $57.00 $114.00 $228.00 | ||
Fumarate, part of the Krebs cycle, can influence cellular metabolism. An increase in Fumarate levels could indirectly lead to enhanced ALDH3A2 activity due to altered metabolic requirements and increased production of aldehydes needing detoxification. | ||||||