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Insights into the Mechanism of Paraoxonase-1: Comparing the Reactivity of the Six-Bladed β-Propeller Hydrolases.

Timothy J Grunkemeyer, David G Mata, Kiran Doddapaneni, Srividya Murali, Thomas J Magliery

Biochemistry 2024 Dec 17


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    The mammalian protein paraoxonase-1 (PON1) has been explored as a promising bioscavenger treatment for organophosphorus (OP) agent poisoning, but it is not active enough to protect against many agents. Engineering is limited because PON1's catalytic mechanism is poorly understood; moreover, its native activity and substrate are unknown. PON1 is a calcium-bound six-bladed β-propeller hydrolase that shares high structural homology, a conserved metal-coordinating active site, and substrate specificity overlap with other members of a superfamily that includes squid diisopropylfluorophosphatase, bacterial drug responsive protein 35, and mammalian senescence marker protein 30. We hypothesized that, by examining the reactivity of all four hydrolases using a common set of conservative mutations, we could gain further insight into the catalytic mechanism of PON1. We chose a set of mutations to examine conserved Asp and Glu residues in the hydrolase active sites and the ligation sphere around the catalytic calcium and a His-His dyad seen in PON1. The wild-type (WT) and mutant hydrolases were assayed against a set of lactones, aryl esters, and OPs that PON1 is known to hydrolyze. Surprisingly, some mutations of Ca2+-coordinating residues, previously thought to be essential for turnover, resulted in significant activity toward all substrate classes examined. Additionally, merely maintaining WT-like charge in the active site of PON1 was insufficient for high activity. Finally, the H115-H134 dyad does not appear to be essential for catalysis against any substrate. Therefore, previously proposed mechanisms must be re-evaluated.

    Citation

    Timothy J Grunkemeyer, David G Mata, Kiran Doddapaneni, Srividya Murali, Thomas J Magliery. Insights into the Mechanism of Paraoxonase-1: Comparing the Reactivity of the Six-Bladed β-Propeller Hydrolases. Biochemistry. 2024 Dec 17;63(24):3287-3299

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    PMID: 30547569

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