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Journal:BMC:3

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Revision as of 07:39, 21 March 2012

Identification of novel isocytosine derivatives as xanthine oxidase inhibitors from a set of virtual screening hits

Chandrika B-Rao, Asha Kulkarni-Almeida, Kamlesh V. Katkar, Smriti Khanna, Usha Ghosh, Ashish Keche, Pranay Shah, Ankita Srivastava, Vaidehi Korde, Kumar V. S. Nemmani, Nitin J. Deshmukh, Amol Dixit, Manoja K. Brahma, Umakant Bahirat, Lalit Doshi, Rajiv Sharma, H. Sivaramakrishnan ^[1]

Molecular Tour

The paper reports a novel scaffold containing isocytosine moiety that was discovered for xanthine oxidase inhibition by virtual screening and enzymatic assay. Several co-crystal structures of Xanthine oxidase and xanthine dehydrogenase (which do not differ in conformation of active site) were studied to understand key interactions for enzyme inhibition. Docking of novel hits and inactive compounds was performed (to in PDB with ID 1vdv) to understand the ligand-protein interactions and hence, for structure-based design of more potent molecules. The paper reports the directions for modification of the hit compound derived from these considerations, which are reported below. The mechanism of action of the novel hits are like and (“pure inhibitors”) and not like & FYX-051 (“substrate inhibitors”).

Introduction to functional aspect of xanthine oxidase:

Xanthine oxidoreductase (XOR), is an oxidoreductive enzyme that is synthesized as xanthine dehydrogenase (XDH) and can be converted reversibly or irreversibly to xanthine oxidase (XO) form. It catalyzes the such as and which is excreted by kidneys.^[2] The reaction occurs at the center from where the electrons are transferred via two Fe₂S₂ clusters to FAD, which then passes them on to the second substrate NAD+ in case of XDH or to molecular oxygen in XO leading to the formation superoxide anion and H₂O₂. Excessive production and/or inadequate excretion of uric acid results in hyperuricemia is associated with conditions like gout, cardiovascular mortality and metabolic syndrome including hyperinsulinemia and hypertriglyceridemia. Alleviating hyperuricemia, therefore, has therapeutic significance, and XO is a key target towards this end.

Important interactions of XO inhibitors with protein active site :

Piraxostat (PDB code 1vdv) ^[3] and Febuxostat (PDB code 1n5x)^[4], show several interactions with the active site residues of the protein. The carboxyl group of Piraxostat is involved in and as well. The ring nitrogen is involved in . The cyano group of the ligand forms another crucial H-bond with Asn768. Besides these polar interactions, a number of hydrophobic interactions are observed as well. The heteroaromatic ring is pi-stacked between Phe914 and Phe1009. The phenyl ring has hydrophobic interactions with Leu873, Val1011 and Leu1014. The alkoxy side chain extends towards the solvent accessible region and is engaged in hydrophobic interactions with various residues at the entrance of the pocket such as Leu648, Phe649 and Phe1013.

Similar interactions have been observed by docking our isocytosine series of compounds. The pyrimidine ring pi-stacks between Phe914 and Phe1009. Highly polar groups such as –OH on pyrimidine ring correspond to carboxylate of piraxostat and retain H-bonds with Arg880 and Thr1010. The –NH₂ group in the same ring H-bonds to Glu802, which seems to play the role of anchoring the molecule in appropriate pose in the active site. The methoxy group shows a few of the several hydrophobic interactions observed for piraxostat and febuxostat.

Mechanism of action of xanthine oxidase:

Currently approved drugs for xanthine oxidase inhibition are allopurinol and febuxostat. Although both bind to the xanthine-binding site of XO, they work by different molecular mechanisms of action. Allopurinol acts as a substrate that is metabolized via hydroxylation to oxypurinol by Mo-Pt in the active site. Oxypurinol further inhibits the binding of xanthine by co-ordinating with Mo-Pt.^[5] Febuxostat binds tightly in the active site and blocks the binding of xanthine, without interacting with Mo-Pt.^[4] FYX-051 or topiroxostat currently in Phase II clinical trials also interacts with Mo-Pt just like allopurinol whereas piraxostat is akin to febuxostat.^[6]

The mechanism of metabolism of substrate by XO requires that an electrophilic carbon next to a ring nitrogen of the substrate be positioned adjacent to Mo-Pt, with nitrogen towards Glu1261. Glu1261 acts as a general base and abstracts a proton from Mo-Pt hydroxyl group. The ionized Mo-Pt facilitates nucleophilic attack on the electrophilic carbon center. This type of motif is seen in the substrate inhibitors, allopurinol and FYX-051.^[6] Febuxostat and piraxostat do not possess this motif and do not get metabolized by Mo-Pt. Our hit has a novel isocytosine scaffold that has a nitrogen in the desired position, but the carbon is substituted with –NH2, and is not available for attack by Mo-Pt. Hence our compounds are "pure inhibitors" and not "substrate inhibitors".

↑ none yet
↑ Pauff JM, Cao H, Hille R. Substrate Orientation and Catalysis at the Molybdenum Site in Xanthine Oxidase: CRYSTAL STRUCTURES IN COMPLEX WITH XANTHINE AND LUMAZINE. J Biol Chem. 2009 Mar 27;284(13):8760-7. Epub 2008 Dec 24. PMID:19109252 doi:10.1074/jbc.M804517200
↑ Fukunari A, Okamoto K, Nishino T, Eger BT, Pai EF, Kamezawa M, Yamada I, Kato N. Y-700 [1-[3-Cyano-4-(2,2-dimethylpropoxy)phenyl]-1H-pyrazole-4-carboxylic acid]: a potent xanthine oxidoreductase inhibitor with hepatic excretion. J Pharmacol Exp Ther. 2004 Nov;311(2):519-28. Epub 2004 Jun 9. PMID:15190124 doi:10.1124/jpet.104.070433
↑ ^4.0 ^4.1 Okamoto K, Eger BT, Nishino T, Kondo S, Pai EF, Nishino T. An extremely potent inhibitor of xanthine oxidoreductase. Crystal structure of the enzyme-inhibitor complex and mechanism of inhibition. J Biol Chem. 2003 Jan 17;278(3):1848-55. Epub 2002 Nov 5. PMID:12421831 doi:10.1074/jbc.M208307200
↑ Truglio JJ, Theis K, Leimkuhler S, Rappa R, Rajagopalan KV, Kisker C. Crystal structures of the active and alloxanthine-inhibited forms of xanthine dehydrogenase from Rhodobacter capsulatus. Structure. 2002 Jan;10(1):115-25. PMID:11796116
↑ ^6.0 ^6.1 Okamoto K, Matsumoto K, Hille R, Eger BT, Pai EF, Nishino T. The crystal structure of xanthine oxidoreductase during catalysis: implications for reaction mechanism and enzyme inhibition. Proc Natl Acad Sci U S A. 2004 May 25;101(21):7931-6. Epub 2004 May 17. PMID:15148401 doi:10.1073/pnas.0400973101

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Alexander Berchansky, Jaime Prilusky

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Retrieved from "http://52.214.119.220/wiki/index.php/Journal:BMC:3"

@@ Line 9: / Line 9: @@
 Introduction to functional aspect of xanthine oxidase:
-Xanthine oxidoreductase (XOR), is an oxidoreductive enzyme that is synthesized as xanthine dehydrogenase (XDH) and can be converted reversibly or irreversibly to xanthine oxidase (XO) form. It catalyzes the <scene name='Journal:BMC:3/Cv/12'>transformation of physiological substrates</scene> such as <scene name='Journal:BMC:3/Cv/9'>hypoxanthine to xanthine</scene> and <scene name='Journal:BMC:3/Cv/11'>xanthine to uric acid</scene> which is excreted by kidneys.<ref name="Pauff">PMID:19109252</ref> The reaction occurs at the <scene name='Journal:BMC:3/Cv1/2'>cofactor molybdopterin (Mo-Pt)</scene> center from where the electrons are transferred via two Fe<sub>2</sub>S<sub>2</sub> clusters to FAD, which then passes them on to the second substrate NAD+ in case of XDH or to molecular oxygen in XO leading to the formation superoxide anion and H<sub>2</sub>O<sub>2</sub>. Excessive production and/or inadequate excretion of uric acid results in hyperuricemia is associated with conditions like gout, cardiovascular mortality and metabolic syndrome including hyperinsulinemia and hypertriglyceridemia. Alleviating hyperuricemia, therefore, has therapeutic significance, and XO is a key target towards this end.
+Xanthine oxidoreductase (XOR), is an oxidoreductive enzyme that is synthesized as xanthine dehydrogenase (XDH) and can be converted reversibly or irreversibly to xanthine oxidase (XO) form. It catalyzes the <scene name='Journal:BMC:3/Cv/12'>transformation of physiological substrates</scene> such as <scene name='Journal:BMC:3/Cv/9'>hypoxanthine to xanthine</scene> and <scene name='Journal:BMC:3/Cv/11'>xanthine to uric acid</scene> which is excreted by kidneys.<ref name="Pauff">PMID:19109252</ref> The reaction occurs at the <scene name='Journal:BMC:3/Cv1/6'>cofactor molybdopterin (Mo-Pt)</scene> center from where the electrons are transferred via two Fe<sub>2</sub>S<sub>2</sub> clusters to FAD, which then passes them on to the second substrate NAD+ in case of XDH or to molecular oxygen in XO leading to the formation superoxide anion and H<sub>2</sub>O<sub>2</sub>. Excessive production and/or inadequate excretion of uric acid results in hyperuricemia is associated with conditions like gout, cardiovascular mortality and metabolic syndrome including hyperinsulinemia and hypertriglyceridemia. Alleviating hyperuricemia, therefore, has therapeutic significance, and XO is a key target towards this end.
 Important interactions of XO inhibitors with protein active site :
-Piraxostat (PDB code [[1vdv]]) <ref name="Fukunari">PMID: 15190124</ref> and Febuxostat (PDB code [[1n5x]])<ref name="Okamoto"/>, show several interactions with the active site residues of the protein. The carboxyl group of Piraxostat is involved in <scene name='Journal:BMC:3/Cv1/3'>electrostatic interactions with guanidinium group of Arg880</scene> and <scene name='Journal:BMC:3/Cv1/4'>H-bonds to Thr1010</scene> as well. The ring nitrogen is involved in <scene name='Journal:BMC:3/Cv1/5'>H-bond interaction with Glu802</scene>. Asn768 forms another crucial H-bond with the cyano group of the ligand. Besides these polar interactions, a number of hydrophobic interactions are observed as well. The heteroaromatic ring is pi-stacked between Phe914 and Phe1009. The phenyl ring has hydrophobic interactions with Leu873, Val1011 and Leu1014. The alkoxy side chain extends towards the solvent accessible region and is engaged in hydrophobic interactions with various residues at the entrance of the pocket such as Leu648, Phe649 and Phe1013.
+Piraxostat (PDB code [[1vdv]]) <ref name="Fukunari">PMID: 15190124</ref> and Febuxostat (PDB code [[1n5x]])<ref name="Okamoto"/>, show several interactions with the active site residues of the protein. The carboxyl group of Piraxostat is involved in <scene name='Journal:BMC:3/Cv1/3'>electrostatic interactions with guanidinium group of Arg880</scene> and <scene name='Journal:BMC:3/Cv1/4'>H-bonds to Thr1010</scene> as well. The ring nitrogen is involved in <scene name='Journal:BMC:3/Cv1/5'>H-bond interaction with Glu802</scene>. The cyano group of the ligand forms another crucial H-bond with Asn768. Besides these polar interactions, a number of hydrophobic interactions are observed as well. The heteroaromatic ring is pi-stacked between Phe914 and Phe1009. The phenyl ring has hydrophobic interactions with Leu873, Val1011 and Leu1014. The alkoxy side chain extends towards the solvent accessible region and is engaged in hydrophobic interactions with various residues at the entrance of the pocket such as Leu648, Phe649 and Phe1013.
 Similar interactions have been observed by docking our isocytosine series of compounds. The pyrimidine ring pi-stacks between Phe914 and Phe1009. Highly polar groups such as –OH on pyrimidine ring correspond to carboxylate of piraxostat and retain H-bonds with Arg880 and Thr1010. The –NH<sub>2</sub> group in the same ring H-bonds to Glu802, which seems to play the role of anchoring the molecule in appropriate pose in the active site. The methoxy group shows a few of the several hydrophobic interactions observed for piraxostat and febuxostat.

Journal:BMC:3

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Revision as of 07:39, 21 March 2012

Identification of novel isocytosine derivatives as xanthine oxidase inhibitors from a set of virtual screening hits

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