Abstract
Quinone reductase 2 (NQO2) is an FAD-linked enzyme and the only known human target of two antimalarial drugs, primaquine (PQ) and chloroquine (CQ). The structural differences between oxidized and reduced NQO2 and the structural basis for inhibition by PQ and CQ were investigated by x-ray crystallography. Structures of oxidized NQO2 in complex with PQ and CQ were solved at 1.4 Å resolution. CQ binds preferentially to reduced NQO2, and upon reduction of NQO2-CQ crystals, the space group changed from P2(1)2(1)2(1) to P2(1), with 1-Å decreases in all three unit cell dimensions. The change in crystal packing originated in the negative charge and 4-5º bend in the reduced isoalloxazine ring of FAD, which resulted in a new mode of CQ binding and closure of a flexible loop (Phe(126)-Leu(136)) over the active site. This first structure of a reduced quinone reductase shows that reduction of the FAD cofactor and binding of a specific inhibitor lead to global changes in NQO2 structure and is consistent with a functional role for NQO2 as a flavin redox switch.
Highlights
The flavoenzyme quinone reductase 2 (NQO2) has an unknown cellular function and binds many drugs and bioactive molecules
NQO2 was identified as a human target of both CQ and PQ; kinetic studies showed that PQ binds preferentially to NQO2 can exist as either the oxidized (NQO2ox), whereas chloroquine binds to NQO2red [6, 25]
The NQO2red-CQ complex is the first structure of reduced NQO2, and it shows that the mode of CQ binding to NQO2red is completely different from what is observed for CQ binding to NQO2ox
Summary
The flavoenzyme quinone reductase 2 (NQO2) has an unknown cellular function and binds many drugs and bioactive molecules. The change in crystal packing originated in the negative charge and 4 –5o bend in the reduced isoalloxazine ring of FAD, which resulted in a new mode of CQ binding and closure of a flexible loop (Phe126–Leu136) over the active site. This first structure of a reduced quinone reductase shows that reduction of the FAD cofactor and binding of a specific inhibitor lead to global changes in NQO2 structure and is consistent with a functional role for NQO2 as a flavin redox switch
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