β3Gn-T8 Activators
Chemical activators of β3Gn-T8 play a pivotal role in modulating the enzyme's activity through a variety of mechanisms. Manganese chloride, magnesium chloride, calcium chloride, and nickel chloride serve as vital cofactors that enhance the glycosyltransferase activity of β3Gn-T8. Manganese chloride contributes to the stabilization of the enzyme's structure, ensuring it maintains an optimal configuration for activity. In a similar fashion, magnesium chloride helps preserve the correct conformation of β3Gn-T8, promoting its functional state. Calcium chloride acts by potentially altering the tertiary or quaternary structure of the enzyme, thus facilitating an increase in enzymatic activity. Meanwhile, nickel chloride may provide essential ionic support required for the enzyme's catalytic actions, influencing its conformation and function.
Further contributing to the activation of β3Gn-T8, cobalt chloride, zinc sulfate, iron(II) sulfate, and copper(II) sulfate each bring unique interactions to the enzyme's structural and catalytic landscape. Cobalt chloride might induce necessary conformational shifts that are integral to the enzyme's activity. Zinc sulfate can bind to β3Gn-T8, aiding in the proper folding of the protein or stabilization of its active site. Iron(II) sulfate, through its role as a metal cofactor, enhances the transferase activity of β3Gn-T8, which is central to its function. Copper(II) sulfate also has the capacity to stabilize the enzyme's structure or engage directly in its catalytic mechanism. Beyond these, sodium fluoride, aluminum chloride, zinc dibenzyldithiocarbamate, and sodium lauryl sulfate can each activate β3Gn-T8 through distinct interactions that affect the enzyme's phosphorylation state, conformation, or the enzyme-substrate relationship, thereby facilitating the glycosylation process that β3Gn-T8 catalyzes. These chemical activators collectively ensure that β3Gn-T8 achieves and maintains a state that is conducive to its glycosyltransferase activity.
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| Product Name | CAS # | Catalog # | QUANTITY | Price | Citations | RATING |
|---|---|---|---|---|---|---|
Manganese(II) chloride beads | 7773-01-5 | sc-252989 sc-252989A | 100 g 500 g | $19.00 $30.00 | ||
Manganese chloride can activate β3Gn-T8 by enhancing its glycosyltransferase activity through the stabilization of the enzyme structure, as manganese ions are often crucial cofactors for the function of glycosyltransferases. | ||||||
Magnesium chloride | 7786-30-3 | sc-255260C sc-255260B sc-255260 sc-255260A | 10 g 25 g 100 g 500 g | $27.00 $34.00 $47.00 $123.00 | 2 | |
Magnesium chloride can serve as a cofactor to functionally activate β3Gn-T8 by maintaining the enzyme's conformation for optimal activity, as magnesium is a known cofactor for many enzymes including glycosyltransferases. | ||||||
Calcium chloride anhydrous | 10043-52-4 | sc-207392 sc-207392A | 100 g 500 g | $65.00 $262.00 | 1 | |
Calcium chloride can activate β3Gn-T8 by altering the enzyme's tertiary or quaternary structure, thus enhancing its enzymatic activity, as calcium ions can influence the function and stability of glycosyltransferases. | ||||||
Nickel(II) chloride | 7718-54-9 | sc-236169 sc-236169A | 100 g 500 g | $67.00 $184.00 | ||
Nickel chloride can activate β3Gn-T8 by potentially serving as an essential ionic cofactor that is required for the optimal catalytic activity of the enzyme, as nickel ions can influence enzyme conformation and function. | ||||||
Cobalt(II) chloride | 7646-79-9 | sc-252623 sc-252623A | 5 g 100 g | $63.00 $173.00 | 7 | |
Cobalt chloride can activate β3Gn-T8 by acting as a cofactor that induces conformational changes necessary for enzymatic activity, as cobalt can be involved in the catalytic mechanisms of certain enzymes. | ||||||
Zinc | 7440-66-6 | sc-213177 | 100 g | $47.00 | ||
Zinc sulfate can activate β3Gn-T8 by binding to the enzyme and facilitating proper folding or stabilizing its active site conformation, as zinc often plays a catalytic or structural role in enzyme function. | ||||||
Iron(II) sulfate solution | 10028-21-4 | sc-224024 | 1 each | $45.00 | ||
Iron(II) sulfate can activate β3Gn-T8 through its role as a metal cofactor that may be involved in the enzymatic mechanism of glycosyltransferases, thereby enhancing the transferase activity. | ||||||
Copper(II) sulfate | 7758-98-7 | sc-211133 sc-211133A sc-211133B | 100 g 500 g 1 kg | $45.00 $120.00 $185.00 | 3 | |
Copper(II) sulfate can activate β3Gn-T8 by potentially interacting with the enzyme to stabilize its structure or participate in its catalytic activity, as copper ions can be important for enzyme function. | ||||||
Sodium Fluoride | 7681-49-4 | sc-24988A sc-24988 sc-24988B | 5 g 100 g 500 g | $39.00 $45.00 $98.00 | 26 | |
Sodium fluoride can activate β3Gn-T8 by influencing the phosphorylation state of the enzyme or its substrates, thereby enhancing the glycosylation process catalyzed by the enzyme. | ||||||
Aluminum chloride anhydrous | 7446-70-0 | sc-214528 sc-214528B sc-214528A | 250 g 500 g 1 kg | $92.00 $97.00 $133.00 | ||
Aluminum chloride can activate β3Gn-T8 by altering the enzyme's conformation or by acting as a cofactor in the catalytic process of glycosylation. | ||||||