User:Jeremiah C Hagler/Sandbox 1
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==Alkaline phosphatase== | ==Alkaline phosphatase== | ||
| - | <StructureSection load='1alk' size='340' side='right' caption=' | + | <StructureSection load='1alk' size='340' side='right' caption='Alkaline phosphatase' scene=''> |
==Alkaline Phosphatase Overview and Questions== | ==Alkaline Phosphatase Overview and Questions== | ||
Alkaline phosphatase is an enzyme commonly used in molecular biology research to hydrolyse phosphates from the ends of macromolecules (proteins, DNA, RNA) and nucleotides. This protein is a metalloenzyme (metal containing) that utilizes two zinc atoms and a magnesium atom as cofactors in the active site to carry out catalysis. We will be utilizing a mammalian version of this enzyme to study enzyme function and kinetics in a future lab. | Alkaline phosphatase is an enzyme commonly used in molecular biology research to hydrolyse phosphates from the ends of macromolecules (proteins, DNA, RNA) and nucleotides. This protein is a metalloenzyme (metal containing) that utilizes two zinc atoms and a magnesium atom as cofactors in the active site to carry out catalysis. We will be utilizing a mammalian version of this enzyme to study enzyme function and kinetics in a future lab. | ||
| - | Look at the jmol representation of alkaline phosphatase (window on the right, click on "popup" to see a larger version of this representation). The default image is the entire dimeric enzyme complex (containing two identical subunits). | + | Look at the jmol representation of alkaline phosphatase (window on the right, click on "popup" to see a larger version of this representation). The default image is the entire dimeric enzyme complex (containing two identical subunits). |
| + | <br> | ||
| + | <scene name='71/711667/Ap_single_subunit/2'>Click here to see a single alkaline phosphatase subunit</scene> This is a cartoon representation of the secondary structures found in this protein. Alpha helices are in red, beta pleated sheets in yellow. Notice that this protein is rich in alpha-helices, but also has a large beta-pleated sheet buried within the interior. The active site is located towards the surface of the protein in a broad groove. The metal cofactors are represented as balls (green for Mg2+ and grey for Zn2+), the phosphate ligand (PO42-) in orange (phosphorous) and red (oxygen). | ||
*1. Knowing that this enzyme functions to remove phosphate from a wide array of biological molecules, including protein, DNA, RNA and nucleotides, why do you think the active site is located near the surface of the protein? | *1. Knowing that this enzyme functions to remove phosphate from a wide array of biological molecules, including protein, DNA, RNA and nucleotides, why do you think the active site is located near the surface of the protein? | ||
| + | <br> | ||
| + | <scene name='71/711667/Ap_active_site/8'>Click to see a close up of alkaline phosphatase active site</scene> | ||
| + | This image shows the active site residues, metal cofactors, phosphate and water (red balls labeled as HOH) only. The magnesium ion is green, zinc grey, phosphate orange (phosphorous) and red (oxygen)and the active site residues colored according to their make up (carbon light grey, nitrogen blue, oxygens light green or red). You can identify the various components of this image by hovering the mouse cursor over the appropriate component--a name will pop up, along with a number indicating it's position, etc. Note also that thick lines indicate covalent bonds, the thinner lines are ionic bonds between amino acids, metal ions and/or phosphate. Note that hydrogen bonds are not shown in this image. | ||
| - | *2. What role do you think zinc and magnesium ions are playing in active site function of this enzyme? (hint; zinc and magnesium are doing slightly different things here…take a look at the active site structure: | ||
| - | <scene name='71/711667/Ap_active_site/7'>Close up of alkaline phosphatase active site</scene> | ||
| - | This image shows the active site residues, metal cofactors and phosphate only. The magnesium ion is green, zinc grey, phosphate orange (phosphorous) and red (oxygen)and the active site residues colored according to their make up (carbon light grey, nitrogen blue, oxygens light green or red). You can identify the various components of this image by hovering the mouse cursor over the appropriate component--a name will pop up, along with a number indicating it's position, etc. Note also that thick lines indicate covalent bonds, the thinner lines hydrogen bonds or ionic bonds between amino acids, metal ions and/or phosphate. | ||
| - | + | <scene name='47/471754/Cv/3'>Click here for another view of the alkaline phosphatase active site</scene><br>. In this view, bonds hydrogen and ionic bonds are shown as white dashed lines. The complexity of the interactions between amino acid aide chains of the enzyme is evident in this view. | |
| + | *2. What role do you think zinc and magnesium ions are playing in active site function of this enzyme? (hint; zinc and magnesium are doing slightly different things here) | ||
| + | <br> | ||
| + | In the active site image, move your cursor around to find the amino acid residue Arg 166 (R166). | ||
| + | <br> | ||
*3. What function is this residue playing in this enzyme? What do you think would would happen if this amino acid was mutated to glycine, or some other nonpolar small amino acid? Why? | *3. What function is this residue playing in this enzyme? What do you think would would happen if this amino acid was mutated to glycine, or some other nonpolar small amino acid? Why? | ||
Current revision
Alkaline phosphatase
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