Journal:JBSD:20
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<StructureSection load='' size='450' side='right' scene='Journal:JBSD:20/Cv/1' caption=''> | <StructureSection load='' size='450' side='right' scene='Journal:JBSD:20/Cv/1' caption=''> | ||
=== Insight into TPMT*23 Mutation Mis-folding Using Molecular Dynamics Simulation and Protein Structure Analysis === | === Insight into TPMT*23 Mutation Mis-folding Using Molecular Dynamics Simulation and Protein Structure Analysis === | ||
| - | <big>Sofiene Larif, Chaker Ben Salem, Zohra Soua, Houssem Hmouda, Kamel Bouraoui </big> <ref> | + | <big>Sofiene Larif, Chaker Ben Salem, Zohra Soua, Houssem Hmouda, Kamel Bouraoui </big> <ref>doi 10.1080/07391102.2012.721495</ref> |
<hr/> | <hr/> | ||
<b>Molecular Tour</b><br> | <b>Molecular Tour</b><br> | ||
Thiopurine antimetabolite pharmacologic class is one of the therapeutic arsenals available today for treatment of acute lymphoblastic, myeloblastic leukemia, as well as palliative chemotherapy, and some autoimmune diseases such as inflammatory bowel disease, rheumatoid arthritis, and organ transplantation. | Thiopurine antimetabolite pharmacologic class is one of the therapeutic arsenals available today for treatment of acute lymphoblastic, myeloblastic leukemia, as well as palliative chemotherapy, and some autoimmune diseases such as inflammatory bowel disease, rheumatoid arthritis, and organ transplantation. | ||
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/ | + | <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. | ||
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Our suggested hypothesis is that enzyme reaction is activated by thiopurine drug binding to it's site, which probably induces structural modifications that opens the SAM tunnel, but further investigations should be addressed. | Our suggested hypothesis is that enzyme reaction is activated by thiopurine drug binding to it's site, which probably induces structural modifications that opens the SAM tunnel, but further investigations should be addressed. | ||
| + | Click on following morphs: | ||
| + | *<scene name='Journal:JBSD:20/Samwt/1'>SAM water channel entrance (WT), 0 and 20 ns MD simulation</scene> <font color='darkmagenta'><b>(Leu24, Thr25, Leu26, Ser134, Phe136, Asn159 and Asp162)</b></font> | ||
| + | *<scene name='Journal:JBSD:20/Sammut/2'>SAM water channel entrance (A167G mutation), 0 and 20 ns MD simulation</scene> <font color='darkmagenta'><b>(Leu24, Thr25, Leu26, Ser134, Phe136, Asn159 and Asp162)</b></font> | ||
| + | *<scene name='Journal:JBSD:20/Thwt/1'>Thiopurine water channel entrance (WT), 0 and 20 ns MD simulation</scene> <span style="color:violet;background-color:black;font-weight:bold;">(Trp29, Lys32, Lys37, Ala39, Phe40, Pro195, Pro196, Arg226 and Trp230)</span> | ||
| + | *<scene name='Journal:JBSD:20/Thmut/1'>Thiopurine water channel entrance (A167G mutation), 0 and 20 ns MD simulation</scene> <span style="color:violet;background-color:black;font-weight:bold;">(Trp29, Lys32, Lys37, Ala39, Phe40, Pro195, Pro196, Arg226 and Trp230)</span> | ||
</StructureSection> | </StructureSection> | ||
<references/> | <references/> | ||
__NOEDITSECTION__ | __NOEDITSECTION__ | ||
Current revision
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- ↑ Larif S, Ben Salem C, Soua Z, Hmouda H, Bouraoui K. Insight into TPMT( *)23 mutation mis-folding using molecular dynamics simulation and protein structure analysis. J Biomol Struct Dyn. 2012 Oct 2. PMID:23025308 doi:10.1080/07391102.2012.721495
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