5430405G05Rik Activators
Chemical activators of transmembrane protein 74B (TMEM74B) include a variety of compounds that induce cellular stress, leading to the activation of this stress response protein. Cycloheximide, for example, acts by inhibiting protein biosynthesis, which in turn can lead to an increased expression of TMEM74B as part of the cell's compensatory mechanisms to cope with reduced protein production. Similarly, thapsigargin, by disrupting calcium homeostasis through its inhibition of the sarco/endoplasmic reticulum Ca2+-ATPase (SERCA), can trigger the unfolded protein response, a cellular stress response that often involves the activation of proteins such as TMEM74B. Tunicamycin contributes to this response by blocking N-linked glycosylation, causing endoplasmic reticulum stress that can also result in the activation of TMEM74B. Furthermore, proteostasis disruptors like MG132, which inhibits the proteasome, lead to an accumulation of misfolded proteins, a condition that typically activates TMEM74B as part of the cellular attempt to restore protein homeostasis.
In addition to these, chemical activators that interfere with various cellular functions can also lead to the activation of TMEM74B. Brefeldin A, by inhibiting ER to Golgi transport, induces ER stress that may activate TMEM74B. Chloroquine, through its accumulation in lysosomes and consequent impairment of lysosomal function, can activate TMEM74B as part of the lysosomal stress response. Cellular energy stress induced by 2-Deoxy-D-glucose, which inhibits glycolysis, can similarly activate TMEM74B as the cell responds to energy deficits. Toxic stress, such as that caused by cadmium chloride, results in oxidative stress and the cellular activation of TMEM74B in response to metal-induced toxicity. Additionally, TMEM74B can be activated by redox imbalances caused by dithiothreitol, a reducing agent, or by the oxidative stress induced by hydrogen peroxide. These various chemical activators, by disrupting different cellular pathways and processes, each contribute to the activation of TMEM74B, a protein that plays a role in the cell's response to stress.
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| Product Name | CAS # | Catalog # | QUANTITY | Price | Citations | RATING |
|---|---|---|---|---|---|---|
Cycloheximide | 66-81-9 | sc-3508B sc-3508 sc-3508A | 100 mg 1 g 5 g | $40.00 $82.00 $256.00 | 127 | |
Cycloheximide inhibits protein biosynthesis, which can lead to upregulation of stress response proteins including transmembrane protein 74B (TMEM74B), as the cell attempts to counteract the inhibited protein synthesis. | ||||||
Sodium phenylbutyrate | 1716-12-7 | sc-200652 sc-200652A sc-200652B sc-200652C sc-200652D | 1 g 10 g 100 g 1 kg 10 kg | $75.00 $163.00 $622.00 $4906.00 $32140.00 | 43 | |
4-Phenylbutyrate serves as a chemical chaperone that can enhance the proper folding and stability of proteins, including TMEM74B, thus potentially increasing its functional activity. | ||||||
Thapsigargin | 67526-95-8 | sc-24017 sc-24017A | 1 mg 5 mg | $94.00 $349.00 | 114 | |
Thapsigargin disrupts calcium homeostasis by inhibiting the sarco/endoplasmic reticulum Ca2+-ATPase (SERCA), which can lead to the activation of the unfolded protein response and subsequently increase the activity of proteins like TMEM74B involved in stress responses. | ||||||
Tunicamycin | 11089-65-9 | sc-3506A sc-3506 | 5 mg 10 mg | $169.00 $299.00 | 66 | |
Tunicamycin causes endoplasmic reticulum stress by inhibiting N-linked glycosylation, which may activate proteins involved in the unfolded protein response, including TMEM74B, as part of the cellular response to glycosylation defects. | ||||||
MG-132 [Z-Leu- Leu-Leu-CHO] | 133407-82-6 | sc-201270 sc-201270A sc-201270B | 5 mg 25 mg 100 mg | $56.00 $260.00 $980.00 | 163 | |
MG132 inhibits proteasomes, leading to the accumulation of misfolded or damaged proteins, which can activate cellular stress responses that include the functional activation of TMEM74B as a component of these responses. | ||||||
Brefeldin A | 20350-15-6 | sc-200861C sc-200861 sc-200861A sc-200861B | 1 mg 5 mg 25 mg 100 mg | $30.00 $52.00 $122.00 $367.00 | 25 | |
Brefeldin A disrupts ER to Golgi transport, which can trigger ER stress and potentially enhance the activation of proteins like TMEM74B that are part of the ER stress response machinery. | ||||||
Triton X-100 | 9002-93-1 | sc-29112 sc-29112A | 100 ml 500 ml | $20.00 $41.00 | 55 | |
Triton X-100, a non-ionic surfactant, can disrupt lipid bilayers, potentially leading to membrane stress and activation of membrane-associated stress response proteins, including TMEM74B. | ||||||
Chloroquine | 54-05-7 | sc-507304 | 250 mg | $68.00 | 2 | |
Chloroquine accumulates in lysosomes and impairs their function, which can lead to the activation of lysosomal stress responses and possibly increase the activity of TMEM74B, as it is associated with lysosomal function and stress. | ||||||
2-Deoxy-D-glucose | 154-17-6 | sc-202010 sc-202010A | 1 g 5 g | $65.00 $210.00 | 26 | |
2-Deoxy-D-glucose inhibits glycolysis, which can lead to energy stress and may activate stress response pathways that include TMEM74B activation as the cell attempts to restore energy balance. | ||||||
Cadmium chloride, anhydrous | 10108-64-2 | sc-252533 sc-252533A sc-252533B | 10 g 50 g 500 g | $55.00 $179.00 $345.00 | 1 | |
Cadmium chloride induces cellular toxicity and oxidative stress, which can activate stress response proteins including TMEM74B as part of the cellular defense mechanisms against metal-induced toxicity. | ||||||