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1 Aldose Reductase (2IKH)
2 Introduction
3 Polyol Pathway and Diabetes
4 Structure
5 Mechanism
6 References

Aldose Reductase (2IKH)

Wikipedia

Introduction

Aldose reductase is an oxidoreductase/dehydrogenase enzyme.^[1] It reduces aldehydes and carbonyl, including monosaccharides to their corresponding alcohol products using NADPH as a cofactor.^[1]^[2] Aldose reductase is most well known in the first step of the polyol pathway of glucose metabolism.^[1]^[2]

Polyol Pathway and Diabetes

The polyol pathway involves the synthesis of fructose from glucose, but does not require energy from ATP like glycolysis does.^[1] ^[2] The first step of the pathway is the production of sorbitol from glucose, catalyzed by aldose reductase and using NADPH as a reducing cofactor.^[1]^[2] The second step in the pathway is the production of fructose from sorbitol, catalyzed by sorbitol dehydrogenase, which is NAD+ dependent.^[1]^[2] Under normal blood glucose levels most glucose is metabolized through glycolysis or the pentose phosphate pathway while only a small amount of glucose is metabolized through the polyol pathway.^[1] Under the hyperglycemic conditions of diabetes the flux of glucose through the polyol pathway is increased.^[1]^[2] This causes osmotic and oxidative stress, which can cause pathological interferences with cytokine signalling, regulation of apoptosis, and activation of kinase cascades.^[2] For example, under increased glucose flux through the polyol pathway protein kinase C activivty increases, which causes smooth muscle cell proliferation of blood vessels in agreement with atherosclerosis.^[2] This explains estimates that 75-80% of adults with diabetes die from complications of atherosclerosis.^[2] Aldose reductase is located in the cornea, retina, lens, kidneys, and myelin sheath.^[1] This correlates with long-term complications such as retinopathy, nephropathy, neuropathy, cataracts, and angiopathy.^[2] Aldose reductase inhibitors are possible beneficial treatment options for diabetes.^[2]

Structure

Aldose reductase is a 36kDa aldo-keto reductase^[2] made of 315 amino acid residues in one polypeptide chain.^[1] It has a (β/α)8-TIM-barrel structural motif made of 8 parallel β strands connected to 8 peripheral α helices running anti-parallel to the β strands.^[1] Including the β-strands and α-helices of the TIM barrel, aldose reductase has a total of 10 helices and 13 β-strands. The catalytic active site is located at the C-terminal loop of the enzyme^[2] in the barrel core.^[1] The NADPH cofactor is situated at the top of the barrel with the nicotinamide ring projecting down the center of the barrel and the pyrophosphate straddling the lip of the barrel.^[1] The substrate binding pocket is deeply buried and made of residues that are most likely involved in the catalytic reaction (involving residues Tyr48, Lys77, His110).^[2] The nicotinamide moiety of NADP+ and Trp111 interact with the head group of most ligands.^[2] Hydrophobic contacts can be formed by the side-chains of Trp20, Val47, Trp79, and Trp219.^[2]

Mechanism

The exact mechanism of the operation of the enzyme is under discussion.^[2] NADPH donates a hydride ion to the carbonyl carbon of the aldehyde.^[1]^[2] The hydride transferred from NADPH to glucose comes from C-4 of the nicotinamide ring at the base of the hydrophobic cavity.^[1] Most likely then the transfer of a proton from one of the neighbouring acidic residues to the intermediately formed substrate ion occurs.^[2] Tyr48, His110, and Cys298 are all within a proper distance of C-4 to be potential proton donors.^[1] Evolutionary, thermodynamic, and molecular modeling evidence predicted that Tyr48 was the proton donor.^[1] Mutagenesis studies confirmed it was Tyr48.^[1] The NADPH binds to the polypeptide first, followed by the substrate.^[1] The binding of NADPH induces a conformational change that involves a hinge-like movement of the surface loop (residues 213-217) so it covers part of the NADPH like a safety belt.^[1] After the reaction occurs and the alcohol product has been released another conformational change occurs to release the NADP+.^[1] Kinetic studies have shown that the reorientation of the loop to permit the release of the NADP+ may be the rate-limiting step.^[1] Thus, disturbing interactions that stabilize the coenzyme binding can have dramatic effects on the maximum rate of the reaction.^[1] Hydrogen-bonding interaction between the phenolic hydroxyl group of Tyr48 and the ammonium side chain of Lys77 are thought to help facilitate hydride transfer.^[1]

References

↑ ^1.00 ^1.01 ^1.02 ^1.03 ^1.04 ^1.05 ^1.06 ^1.07 ^1.08 ^1.09 ^1.10 ^1.11 ^1.12 ^1.13 ^1.14 ^1.15 ^1.16 ^1.17 ^1.18 ^1.19 ^1.20 ^1.21 ^1.22 ^1.23 Wikipedia. Aldose Reductase. http://en.wikipedia.org/wiki/Aldose_reductase
↑ ^2.00 ^2.01 ^2.02 ^2.03 ^2.04 ^2.05 ^2.06 ^2.07 ^2.08 ^2.09 ^2.10 ^2.11 ^2.12 ^2.13 ^2.14 ^2.15 ^2.16 ^2.17 ^2.18 Steuber H, Heine A, Klebe G. Structural and thermodynamic study on aldose reductase: nitro-substituted inhibitors with strong enthalpic binding contribution. J Mol Biol. 2007 May 4;368(3):618-38. Epub 2006 Dec 15. PMID:17368668 doi:10.1016/j.jmb.2006.12.004

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@@ Line 13: / Line 13: @@
 <ref name="Steuber"/> The first step of the pathway is the production of sorbitol from glucose, catalyzed by aldose reductase and using NADPH as a reducing cofactor.<ref name="wikipedia"/><ref name="Steuber"/> The second step in the pathway is the production of fructose from sorbitol, catalyzed by sorbitol dehydrogenase, which is NAD+ dependent.<ref name="wikipedia"/><ref name="Steuber"/> Under normal blood glucose levels most glucose is metabolized through glycolysis or the pentose phosphate pathway while only a small amount of glucose is metabolized through the polyol pathway.<ref name="wikipedia"/> Under the hyperglycemic conditions of diabetes the flux of glucose through the polyol pathway is increased.<ref name="wikipedia"/><ref name="Steuber"/> This causes osmotic and oxidative stress, which can cause pathological interferences with cytokine signalling, regulation of apoptosis, and activation of kinase cascades.<ref name="Steuber"/> For example, under increased glucose flux through the polyol pathway protein kinase C activivty increases, which causes smooth muscle cell proliferation of blood vessels in agreement with atherosclerosis.<ref name="Steuber"/> This explains estimates that 75-80% of adults with diabetes die from complications of atherosclerosis.<ref name="Steuber"/> Aldose reductase is located in the cornea, retina, lens, kidneys, and myelin sheath.<ref name="wikipedia"/> This correlates with long-term complications such as retinopathy, nephropathy, neuropathy, cataracts, and angiopathy.<ref name="Steuber"/> Aldose reductase inhibitors are possible beneficial treatment options for diabetes.<ref name="Steuber"/>
 ==Structure==
-Aldose reductase is a 36kDa aldo-keto reductase<ref name="Steuber"/> made of 315 amino acid residues.<ref name="wikipedia"/> It has a (β/α)8-TIM-barrel structural motif made of 8 parallel β strands connected to 8 peripheral α helices running anti-parallel to the β strands.<ref name="wikipedia"/> The catalytic active site is located at the C-terminal loop of the enzyme<ref name="Steuber"/> in the barrel core.<ref name="wikipedia"/> The NADPH cofactor is situated at the top of the barrel with the nicotinamide ring projecting down the center of the barrel and the pyrophosphate straddling the lip of the barrel.<ref name="wikipedia"/> The substrate binding pocket is deeply buried and made of residues that are most likely involved in the catalytic reaction (involving residues Tyr48, Lys77, His110).<ref name="Steuber"/> The nicotinamide moiety of NADP+ and Trp111 interact with the head group of most ligands.<ref name="Steuber"/> Hydrophobic contacts can be formed by the side-chains of Trp20, Val47, Trp79, and Trp219.<ref name="Steuber"/>
+Aldose reductase is a 36kDa aldo-keto reductase<ref name="Steuber"/> made of 315 amino acid residues in one polypeptide chain.<ref name="wikipedia"/> It has a (β/α)8-TIM-barrel structural motif made of 8 parallel β strands connected to 8 peripheral α helices running anti-parallel to the β strands.<ref name="wikipedia"/> Including the β-strands and α-helices of the TIM barrel, aldose reductase has a total of 10 helices and 13 β-strands. The catalytic active site is located at the C-terminal loop of the enzyme<ref name="Steuber"/> in the barrel core.<ref name="wikipedia"/> The NADPH cofactor is situated at the top of the barrel with the nicotinamide ring projecting down the center of the barrel and the pyrophosphate straddling the lip of the barrel.<ref name="wikipedia"/> The substrate binding pocket is deeply buried and made of residues that are most likely involved in the catalytic reaction (involving residues Tyr48, Lys77, His110).<ref name="Steuber"/> The nicotinamide moiety of NADP+ and Trp111 interact with the head group of most ligands.<ref name="Steuber"/> Hydrophobic contacts can be formed by the side-chains of Trp20, Val47, Trp79, and Trp219.<ref name="Steuber"/>
 ==Mechanism==
 The exact mechanism of the operation of the enzyme is under discussion.<ref name="Steuber"/> NADPH donates a hydride ion to the carbonyl carbon of the aldehyde.<ref name="wikipedia"/><ref name="Steuber"/> The hydride transferred from NADPH to glucose comes from C-4 of the nicotinamide ring at the base of the hydrophobic cavity.<ref name="wikipedia"/> Most likely then the transfer of a proton from one of the neighbouring acidic residues to the intermediately formed substrate ion occurs.<ref name="Steuber"/> Tyr48, His110, and Cys298 are all within a proper distance of C-4 to be potential proton donors.<ref name="wikipedia"/> Evolutionary, thermodynamic, and molecular modeling evidence predicted that Tyr48 was the proton donor.<ref name="wikipedia"/> Mutagenesis studies confirmed it was Tyr48.<ref name="wikipedia"/> The NADPH binds to the polypeptide first, followed by the substrate.<ref name="wikipedia"/> The binding of NADPH induces a conformational change that involves a hinge-like movement of the surface loop (residues 213-217) so it covers part of the NADPH like a safety belt.<ref name="wikipedia"/> After the reaction occurs and the alcohol product has been released another conformational change occurs to release the NADP+.<ref name="wikipedia"/> Kinetic studies have shown that the reorientation of the loop to permit the release of the NADP+ may be the rate-limiting step.<ref name="wikipedia"/> Thus, disturbing interactions that stabilize the coenzyme binding can have dramatic effects on the maximum rate of the reaction.<ref name="wikipedia"/> Hydrogen-bonding interaction between the phenolic hydroxyl group of Tyr48 and the ammonium side chain of Lys77 are thought to help facilitate hydride transfer.<ref name="wikipedia"/>

Sandbox Reserved 339

From Proteopedia

Revision as of 07:58, 13 March 2011

Contents

Aldose Reductase (2IKH)

Introduction

Polyol Pathway and Diabetes

Structure

Mechanism

References

Views

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