Journal:JBSD:20
From Proteopedia
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TPMT enzyme is responsible for purine analogs deactivation by a methylation mechanism. Using the S-adenosylmethionine (SAM) as co-substrate, the transfers of methyl group from SAM to the thiopurine molecule transform this latter to thiopurine S-methylether, and transform SAM to S-adenosylhomocysteine (SAH). <scene name='Journal:JBSD:20/Cv/3'>Human TPMT structure</scene> ([[2bzg]]) shows a monomeric protein composed by nine β sheets core surrounded by nine α helices (β sheets depicted as b1, b2... ''etc''. and α helices as a1, a2... ''etc''.; <span style="color:salmon;background-color:black;font-weight:bold;">SAH in the active site is colored in salmon</span>). This protein has two site receptors; one of them is for the co-substrate SAM, surrounded by residues in helices α1, α5, α6, β strands 1 and 2. The second site is thiopurine receptor surrounded by residues in helices α1, α6, α9 and the β7-α8 loop. In TPMT structure, it has been described that substrate can diffuse through an internal channel linked to the SAM binding pocket. | TPMT enzyme is responsible for purine analogs deactivation by a methylation mechanism. Using the S-adenosylmethionine (SAM) as co-substrate, the transfers of methyl group from SAM to the thiopurine molecule transform this latter to thiopurine S-methylether, and transform SAM to S-adenosylhomocysteine (SAH). <scene name='Journal:JBSD:20/Cv/3'>Human TPMT structure</scene> ([[2bzg]]) shows a monomeric protein composed by nine β sheets core surrounded by nine α helices (β sheets depicted as b1, b2... ''etc''. and α helices as a1, a2... ''etc''.; <span style="color:salmon;background-color:black;font-weight:bold;">SAH in the active site is colored in salmon</span>). This protein has two site receptors; one of them is for the co-substrate SAM, surrounded by residues in helices α1, α5, α6, β strands 1 and 2. The second site is thiopurine receptor surrounded by residues in helices α1, α6, α9 and the β7-α8 loop. In TPMT structure, it has been described that substrate can diffuse through an internal channel linked to the SAM binding pocket. | ||
<scene name='Journal:JBSD:20/Cv/5'>SAM water channel entrance</scene> were identified as residues (<font color='darkmagenta'><b>Leu24, Thr25, Leu26, Ser134, Phe136, Asn159 and Asp162 (colored in darkmagenta)</b></font>. The <scene name='Journal:JBSD:20/Cv/6'>thiopurine water channel entrance</scene> is bordered by residues <span style="color:violet;background-color:black;font-weight:bold;">Trp29, Lys32, Lys37, Ala39, Phe40, Pro195, Pro196, Arg226 and Trp230 (colored in violet)</span>. | <scene name='Journal:JBSD:20/Cv/5'>SAM water channel entrance</scene> were identified as residues (<font color='darkmagenta'><b>Leu24, Thr25, Leu26, Ser134, Phe136, Asn159 and Asp162 (colored in darkmagenta)</b></font>. The <scene name='Journal:JBSD:20/Cv/6'>thiopurine water channel entrance</scene> is bordered by residues <span style="color:violet;background-color:black;font-weight:bold;">Trp29, Lys32, Lys37, Ala39, Phe40, Pro195, Pro196, Arg226 and Trp230 (colored in violet)</span>. | ||
| - | This enzyme activity is affected among other factors by Genetic polymorphisms. The single nucleotide polymorphism (SNP) C500G is located on allele TPMT*23. The produced protein is affected by mutation of | + | This enzyme activity is affected among other factors by Genetic polymorphisms. The single nucleotide polymorphism (SNP) C500G is located on allele TPMT*23. The produced protein is affected by <scene name='Journal:JBSD:20/Cv/7'>mutation of alanine to glycine amino-acid at position 167</scene>. |
Changes inflicted by mutation on solvent (SASA) can disturb TPMT substrate binding. The suggested mechanisms involve an increase in solvent exposure prohibiting the binding of the co-substrate SAM, and or, a decrease in accessibility to thiopurine site. | Changes inflicted by mutation on solvent (SASA) can disturb TPMT substrate binding. The suggested mechanisms involve an increase in solvent exposure prohibiting the binding of the co-substrate SAM, and or, a decrease in accessibility to thiopurine site. | ||
Both thiopurine and SAM tunnels entrances continue to exist during simulations. Furthermore, the shape of the SAM entrance was unchanged in the WT, but deformed in the mutant TPMT. | Both thiopurine and SAM tunnels entrances continue to exist during simulations. Furthermore, the shape of the SAM entrance was unchanged in the WT, but deformed in the mutant TPMT. | ||
Revision as of 10:11, 28 August 2012
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- ↑ REF
This page complements a publication in scientific journals and is one of the Proteopedia's Interactive 3D Complement pages. For aditional details please see I3DC.
