Fernanda Ely scite author profile

Abstract:The glycerophosphodiesterase from Enterobacter aerogenes (GpdQ) belongs to the family of binuclear metallohydrolases and has attracted recent attention due to its potential in bioremediation. Formation of a catalytically competent binuclear center is promoted by the substrate (Hadler et al. J. Am. Chem. Soc. 2008, 130, 14129). Using the paramagnetic properties of Mn(II), we estimated the K d values for the metal ions in the R and sites to be 29 and 344 µM, respectively, in the absence of a substrate analogue. In its presence, the affinity of the site increases substantially (K d ) 56 µM), while that of the R site is not greatly affected (K d ) 17 µM). Stopped-flow fluorescence measurements identified three distinct phases in the catalytic turnover, associated with the initial binding of substrate to the active site (k obs1 ), the assembly of a catalytically active binuclear center (k obs2 ), and subsequent slower structural rearrangements to optimize catalysis (k obs3 ). These three phases depend on the concentration of substrate ([S]), with k obs1 and k obs2 reaching maximum values at high [S] (354 and 38 s -1 , respectively), whereas k obs3 is reduced as [S] is increased. The k cat for the hydrolysis of the substrate bis(para-nitrophenyl) phosphate (∼1 s -1 ) gradually increases from the moment of initiating the reaction, reaching a maximum when the structural change associated with k obs3 is complete. This structural change is mediated via an extensive hydrogen-bond network that connects the coordination sphere with the substrate binding pocket, as demonstrated by mutation of two residues in this network (His81 and His217). The identities of both the substrate and the metal ion also affect interactions within this H-bond network, thus leading to some mechanistic variations. Overall, the mechanism employed by GpdQ is a paradigm of a substrate-and metal-ion-induced fit to optimize catalysis.

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Generalizable Protein Biosensors Based on Synthetic Switch Modules

Guo

et al. 2019

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Allosteric protein switches are key controllers of information and energy processing in living organisms and are desirable engineered control tools in synthetic systems. Here we present a generally applicable strategy for construction of allosteric signaling systems with inputs and outputs of choice. We demonstrate conversion of constitutively active enzymes into peptide-operated synthetic allosteric ON switches by insertion of a calmodulin domain into rationally selected sites. Switches based on EGFP, glucose dehydrogenase, NanoLuciferase, and dehydrofolate reductase required minimal optimization and demonstrated a dynamic response ranging from 1.8-fold in the former case to over 200-fold in the latter case. The peptidic nature of the calmodulin ligand enables incorporation of such synthetic switch modules into higher order sensory architectures. Here, a ligand-mediated increase in proximity of the allosteric switch and the engineered activator peptide modulates biosensor’s activity. Created biosensors were used to measure concentrations of clinically relevant drugs and biomarkers in plasma, saliva, and urine with accuracy comparable to that of the currently used clinical diagnostic assays. The approach presented is generalizable as it allows rapid construction of efficient protein switches that convert binding of a broad range of analytes into a biochemical activity of choice enabling construction of artificial signaling and metabolic circuits of potentially unlimited complexity.

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The organophosphate-degrading enzyme from Agrobacterium radiobacter displays mechanistic flexibility for catalysis

Ely

Hadler

Gahan

et al. 2010

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The OP (organophosphate)-degrading enzyme from Agrobacterium radiobacter (OpdA) is a binuclear metallohydrolase able to degrade highly toxic OP pesticides and nerve agents into less or non-toxic compounds. In the present study, the effect of metal ion substitutions and site-directed mutations on the catalytic properties of OpdA are investigated. The study shows the importance of both the metal ion composition and a hydrogen-bond network that connects the metal ion centre with the substrate-binding pocket using residues Arg254 and Tyr257 in the mechanism and substrate specificity of this enzyme. For the Co(II) derivative of OpdA two protonation equilibria (pKa1 ~5; pKa2 ~10) have been identified as relevant for catalysis, and a terminal hydroxide acts as the likely hydrolysis-initiating nucleophile. In contrast, the Zn(II) and Cd(II) derivatives only have one relevant protonation equilibrium (pKa ~4-5), and the μOH is the proposed nucleophile. The observed mechanistic flexibility may reconcile contrasting reaction models that have been published previously and may be beneficial for the rapid adaptation of OP-degrading enzymes to changing environmental pressures.

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Fernanda Ely

Structural Flexibility Enhances the Reactivity of the Bioremediator Glycerophosphodiesterase by Fine-Tuning Its Mechanism of Hydrolysis

Generalizable Protein Biosensors Based on Synthetic Switch Modules

The organophosphate-degrading enzyme from Agrobacterium radiobacter displays mechanistic flexibility for catalysis

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