BVR-B (biliverdin-IXbeta reductase) also known as FR (flavin reductase) is a promiscuous enzyme catalysing the pyridine-nucleotide-dependent reduction of a variety of flavins, biliverdins, PQQ (pyrroloquinoline quinone) and ferric ion. Mechanistically it is a good model for BVR-A (biliverdin-IXalpha reductase), a potential pharmacological target for neonatal jaundice and also a potential target for adjunct therapy to maintain protective levels of biliverdin-IXalpha during organ transplantation. In a commentary on the structure of BVR-B it was noted that one outstanding issue remained: whether the mechanism was a concerted hydride transfer followed by protonation of a pyrrolic anion or protonation of the pyrrole followed by hydride transfer. In the present study we have attempted to address this question using QM/MM (quantum mechanics/molecular mechanics) calculations. QM/MM potential energy surfaces show that the lowest energy pathway proceeds with a positively charged pyrrole intermediate via two transition states. These initial calculations were performed with His(153) as the source of the proton. However site-directed mutagenesis studies with both the H153A and the H153N mutant reveal that His(153) is not required for catalytic activity. We have repeated the calculation with a solvent hydroxonium donor and obtain a similar energy landscape indicating that protonation of the pyrrole is the most likely first step followed by hydride transfer and that the required proton may come from bulk solvent. The implications of the present study for the design of inhibitors of BVR-A are discussed.
Many vertebrate species express two enzymes that are capable of catalysing the reduction of various isomers of biliverdin. Biliverdin‐IXα reductase (BVR‐A) is most active with its physiological substrate biliverdin‐IXα, but can also reduce the three other biliverdin isomers IXβ, IXδ and IXγ. Biliverdin‐IXβ reductase (BVR‐B) catalyses the reduction of only the IXβ, IXδ and IXγ isomers of biliverdin. Therefore, the activity of BVR‐A can be measured using biliverdin‐IXα as a specific substrate. We now show that the dimethyl esters of biliverdin‐IXβ and biliverdin‐IXδ are substrates for BVR‐B, but not for BVR‐A. This provides a useful method for specifically assaying the activity of both BVR‐A and BVR‐B in crude mixtures, using biliverdin‐IXα for BVR‐A and the dimethyl ester of either biliverdin‐IXβ or biliverdin‐IXδ for BVR‐B. Human BVR‐A has been suggested as a pharmacological target for neonatal jaundice. Because of the absence of a crystal structure with biliverdin bound to BVR‐A, we have investigated indirect ways of examining tetrapyrrole binding. In the present study, we report that a number of sterically locked conformers of 18‐ethylbiliverdin‐IXα are substrates for human BVR‐A, and discuss the implications for the biliverdin binding site. The oxidation of bilirubin‐IXα ditaurate to biliverdin‐IXα ditaurate is also described. We show that biliverdin‐IXα ditaurate is a substrate for human BVR‐A and discuss the possibility of using a competing substrate, which is reduced to a water soluble and excretable rubin, as a prototypic inhibitor of BVR‐A.
Biliverdin reductase IXβ (BLVRB) is a crucial enzyme in heme metabolism. Recent studies in humans have identified a loss-of-function mutation (Ser111Leu) that unmasks a fundamentally important role in hematopoiesis. We have applied experimental and thermodynamic modeling studies to provide further insight into role of the cofactor in substrate accessibility and protein folding properties regulating BLVRB catalytic mechanisms. Site-directed mutagenesis with molecular dynamic (MD) simulations establish the critical role of NAD(P)H-dependent conformational changes on substrate accessibility by forming the “hydrophobic pocket”, along with identification of a single key residue (Arg35) modulating NADPH/NADH selectivity. Loop80 and Loop120 block the hydrophobic substrate binding pocket in apo BLVRB (open), while movement of these structures after cofactor binding results in the “closed” (catalytically active) conformation. Both enzymatic activity and thermodynamic stability are affected by mutation(s) involving Ser111 which is located in the core of the BLVRB active site. This work (1) elucidates the crucial role of Ser111 in enzymatic catalysis and thermodynamic stability by active site hydrogen bond network, (2) defines a dynamic model for apo BLVRB extending beyond the crystal structure of the binary BLVRB/NADP+ complex, (3) provides the structural basis for the “encounter” and “equilibrium” states of the binary complex which are regulated by NAD(P)H.
The effect of pH on the initial-rate kinetic behaviour of BVR-A (biliverdin-IXalpha reductase) exhibits an alkaline optimum with NADPH as cofactor, but a neutral optimum with NADH as cofactor. This has been described as dual cofactor and dual pH dependent behaviour; however, no mechanism has been described to explain this phenomenon. We present evidence that the apparent peak of activity observed at neutral pH with phosphate buffer and NADH as cofactor is an anion-dependent activation, where inorganic phosphate apparently mimics the role played by the 2'-phosphate of NADPH in stabilizing the interaction between NADH and the enzyme. The enzymes from mouse, rat and human all exhibit this behaviour. This behaviour is not seen with BVR-A from Xenopus tropicalis or the ancient cyanobacterial enzyme from Synechocystis PCC 6803, which, in addition to being refractory to activation by inorganic phosphate, are also differentiated by an acid pH optimum with both nicotinamide nucleotides.
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