Innovative Biocatalysts as Tools to Detect and Inactivate Nerve Agents.

Pesticides and warfare nerve agents are frequently organophosphates (OPs) or related compounds. Their acute toxicity highlighted more than ever the need to explore applicable strategies for the sensing, decontamination and/or detoxification of these compounds. Herein, we report the use of two different thermostable enzyme families capable to detect and inactivate OPs. In particular, mutants of carboxylesterase-2 from Alicyclobacillus acidocaldarius and of phosphotriesterase-like lactonases from Sulfolobus solfataricus and Sulfolobus acidocaldarius, have been selected and assembled in an optimized format for the development of an electrochemical biosensor and a decontamination formulation, respectively. The features of the developed tools have been tested in an ad-hoc fabricated chamber, to mimic an alarming situation of exposure to a nerve agent. Choosing ethyl-paraoxon as nerve agent simulant, a limit of detection (LOD) of 0.4 nM, after 5 s of exposure time was obtained. Furthermore, an optimized enzymatic formulation was used for a fast and efficient environmental detoxification (>99%) of the nebulized nerve agent simulants in the air and on surfaces. Crucial, large-scale experiments have been possible thanks to production of grams amounts of pure (>90%) enzymes.

An efficient thermostable organophosphate hydrolase and its application in pesticide decontamination.

In vitro evolution of enzymes represents a powerful device to evolve new or to improve weak enzymatic functions. In the present work a semi-rational engineering approach has been used to design an efficient and thermostable organophosphate hydrolase, starting from a lactonase scaffold (SsoPox from Sulfolobus solfataricus). In particular, by in vitro evolution of the SsoPox ancillary promiscuous activity, the triple mutant C258L/I261F/W263A has been obtained which, retaining its inherent stability, showed an enhancement of its hydrolytic activity on paraoxon up to 300-fold, achieving absolute values of catalytic efficiency up to 10(5) M(-1) s(-1). The kinetics and structural determinants of this enhanced activity were thoroughly investigated and, in order to evaluate its potential biotechnological applications, the mutant was tested in formulations of different solvents (methanol or ethanol) or detergents (SDS or a commercial soap) for the cleaning of pesticide-contaminated surfaces.

Conformational stability and ligand binding properties of BldR, a member of the MarR family, from Sulfolobus solfataricus.

The multiple antibiotic resistance regulators (MarR) constitute a family of ligand-responsive transcriptional regulators ubiquitous among the bacterial and archaeal domains. BldR, an archaeal MarR member characterized from the hyperthermophilic crenarchaeon Sulfolobus solfataricus regulates its own expression and that of an alcohol dehydrogenase gene by binding to sequences in their promoters and responding to benzaldehyde as the effector molecule. In this study we assessed the thermodynamic stability of the protein BldR and its binding with benzaldehyde through biophysical measurements. The temperature- and denaturant-induced unfolding experiments, performed by means of circular dichroism (CD) and differential scanning calorimetry (DSC), showed that BldR has an extremely high thermal stability (Td=108.9°C) and a remarkable resistance against GuHCl (Cm=5.3M at 25°C). The unfolding Gibbs energy, ΔdG (H2O), calculated by the linear extrapolation model from GuHCl-induced unfolding equilibrium curve, is 72.2kJmol(-1). ITC binding experiments showed that four benzaldehyde molecules bind to one BldR dimer with a binding constant Kb of 7.5·10(5)M(-1), being the binding entropically driven. ITC, CD and fluorescence results are consistent with a conformational change induced by benzaldehyde binding, further proving that this molecule is a specific effector for BldR modulating its DNA binding activity.

A novel arsenate reductase from the bacterium Thermus thermophilus HB27: its role in arsenic detoxification.

Microorganisms living in arsenic-rich geothermal environments act on arsenic with different biochemical strategies, but the molecular mechanisms responsible for the resistance to the harmful effects of the metalloid have only partially been examined. In this study, we investigated the mechanisms of arsenic resistance in the thermophilic bacterium Thermus thermophilus HB27. This strain, originally isolated from a Japanese hot spring, exhibited tolerance to concentrations of arsenate and arsenite up to 20mM and 15mM, respectively; it owns in its genome a putative chromosomal arsenate reductase (TtarsC) gene encoding a protein homologous to the one well characterized from the plasmid pI258 of the Gram+bacterium Staphylococcus aureus. Differently from the majority of microorganisms, TtarsC is part of an operon including genes not related to arsenic resistance; qRT-PCR showed that its expression was four-fold increased when arsenate was added to the growth medium. The gene cloning and expression in Escherichia coli, followed by purification of the recombinant protein, proved that TtArsC was indeed a thioredoxin-coupled arsenate reductase with a kcat/KM value of 1.2×10(4)M(-1)s(-1). It also exhibited weak phosphatase activity with a kcat/KM value of 2.7×10(-4)M(-1)s(-1). The catalytic role of the first cysteine (Cys7) was ascertained by site-directed mutagenesis. These results identify TtArsC as an important component in the arsenic resistance in T. thermophilus giving the first structural-functional characterization of a thermophilic arsenate reductase.

Identification and physicochemical characterization of BldR2 from Sulfolobus solfataricus, a novel archaeal member of the MarR transcription factor family.

The multiple antibiotic resistance regulators (MarR) constitute a family of ligand-responsive transcriptional regulators abundantly distributed throughout the bacterial and archaeal domains. Here we describe the identification and characterization of BldR2, as a new member of this family, in the archaeon Sulfolobus solfataricus and report physiological, biochemical, and biophysical investigation of its stability and DNA binding ability. Transcriptional analysis revealed the upregulation of BldR2 expression by aromatic compounds in the late-logarithmic growth phase and allowed the identification of cis-acting sequences. Our results suggest that BldR2 possesses in solution a dimeric structure and a high stability against both temperature and chemical denaturing agents; the protein binds site specifically to its own promoter, Sso1082, with a micromolar binding affinity at two palindromic sites overlapping TATA-BRE and the transcription start site. Benzaldehyde and salicylate, ligands of MarR members, are antagonists of binding of DNA by BldR2. Moreover, two single-point mutants of BldR2, R19A and A65S, properly designed for obtaining information about the dimerization and the DNA binding sites of the protein, have been produced and characterized. The results point out an involvement of BldR2 in the regulation of the stress response to aromatic compounds and point to arginine 19 as a key amino acid involved in protein dimerization, while the introduction of serine 65 increases the DNA affinity of the protein, making it comparable with those of other members of the MarR family.