Viviana De Luca scite author profile

SspCA, a novel `extremo-α-carbonic anhydrase' isolated from the thermophilic bacterium Sulfurihydrogenibium yellowstonense YO3AOP1, is an efficient catalyst for the hydration of CO2 and presents exceptional thermostability. Indeed, SspCA retains a high catalytic activity even after being heated to 343-373 K for several hours. Here, the crystallographic structure of this α-carbonic anhydrase (α-CA) is reported and the factors responsible for its function at high temperature are elucidated. In particular, the study suggests that increased structural compactness, together with an increased number of charged residues on the protein surface and a greater number of ionic networks, seem to be the key factors involved in the higher thermostability of this enzyme with respect to its mesophilic homologues. These findings are of extreme importance, since they provide a structural basis for the understanding of the mechanisms responsible for thermal stability in the α-CA family for the first time. The data obtained offer a tool that can be exploited to engineer α-CAs in order to obtain enzymes with enhanced thermostability for use in the harsh conditions of the CO2 capture and sequestration processes.

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Biochemical properties of a novel and highly thermostable bacterial α-carbonic anhydrase fromSulfurihydrogenibium yellowstonense YO3AOP1

Capasso

Luca

Carginale

et al. 2012

Journal of Enzyme Inhibition and Medicinal Chemistry

121

109

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Protonography, a new technique for the analysis of carbonic anhydrase activity

Luca

Prete

Supuran

et al. 2014

Journal of Enzyme Inhibition and Medicinal Chemistry

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All proteolytic enzymes, which are able to renature and reacquire the proteolytic activity on a copolymerized substrate, can be analyzed by zymography upon removal of sodium dodecyl sulfate (SDS). Protonography, the new technique described in this study, unlike zymography, allows the detection of a different protein, not a protease, i.e. of the carbonic anhydrase (CA, EC 4.2.1.1) activity on a SDS polyacrylamide gel electrophoresis gel. CAs are zinc-containing enzymes that catalyze the reversible conversion of carbon dioxide to bicarbonate and protons. Hydrogen ions produced during the catalyzed reaction are responsible for the change of color that appears on the gel around the CA band. For this reason, we named the new technique ''protonography''. The following four salient features characterize this new technique: (a) on the basis of molecular weight markers, recombinant or native CAs with different molecular weights can be detected and quantified rapidly on a single gel; (b) the hydratase activity can be reversibly inhibited by SDS during electrophoresis and recovered by incubating the gel in aqueous Triton X-100; (c) it is possible to separate active oligomeric forms of CAs on the gel enabling their activities to be determined independently of one another. This feature is not possible when using solution assays; and (d) it can be a useful tool to establish if a putative or a newly identified CA in a genome is expressed and enzymatically active. This article outlines the general principles employed in protonography, providing an easy procedure to implement it in laboratories working with CAs. It also presents an overview of its development and current research applications through specific examples.

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An α-carbonic anhydrase from the thermophilic bacterium Sulphurihydrogenibium azorense is the fastest enzyme known for the CO2 hydration reaction

Luca

Vullo

Scozzafava

et al. 2013

Bioorganic & Medicinal Chemistry

132

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We report the biochemical characterization of a new carbonic anhydrase (CA, EC 4.2.1.1), named SazCA, identified by translated genome inspection in Sulfurihydrogenibium azorense, a thermophilic bacterium from terrestrial hot springs of the Azores. SazCA is an α-CA showing kinetic parameters that make it the fastest enzyme of the CA family described so far. The biochemical properties, thermostability and inhibition of SazCA were compared with those of the thermophilic and mesophilic counterparts, demonstrating the special features of this unique enzyme.

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Biomimetic CO₂ capture using a highly thermostable bacterial α-carbonic anhydrase immobilized on a polyurethane foam

Migliardini

Luca

Carginale

et al. 2013

Journal of Enzyme Inhibition and Medicinal Chemistry

142

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The biomimetic approach represents an interesting strategy for carbon dioxide (CO 2 ) capture, offering advantages over other methods, due to its specificity for CO 2 and its eco-compatibility, as it allows concentration of CO 2 from other gases, and its conversion to water soluble ions. This approach uses microorganisms capable of fixing CO 2 through metabolic pathways or via the use of an enzyme, such as carbonic anhydrase (CA, EC 4.2.1.1). Recently, our group cloned and purified a novel bacterial a-CA, named SspCA, from the thermophilic bacteria, Sulfurihydrogenibium yellowstonense YO3AOP1 living in hot springs at temperatures of up to 110 C. This enzyme showed an exceptional thermal stability, retaining its high catalytic activity for the CO 2 hydration reaction even after being heated at 70 C for several hours. In the present paper, the SspCA was immobilized within a polyurethane (PU) foam. The immobilized enzyme was found to be catalytically active and showed a long-term stability. A bioreactor containing the ''PU-immobilized enzyme'' (PU-SspCA) as shredded foam was used for experimental tests aimed to verify the CO 2 capture capability in conditions close to those of a power plant application. In this bioreactor, a gas phase, containing CO 2 , was put into contact with a liquid phase under conditions, where CO 2 contained in the gas phase was absorbed and efficiently converted into bicarbonate by the extremo-a-CA.

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Viviana De Luca

X-ray structure of the first `extremo-α-carbonic anhydrase', a dimeric enzyme from the thermophilic bacteriumSulfurihydrogenibium yellowstonenseYO3AOP1

Biochemical properties of a novel and highly thermostable bacterial α-carbonic anhydrase fromSulfurihydrogenibium yellowstonense YO3AOP1

Protonography, a new technique for the analysis of carbonic anhydrase activity

An α-carbonic anhydrase from the thermophilic bacterium Sulphurihydrogenibium azorense is the fastest enzyme known for the CO2 hydration reaction

Biomimetic CO₂ capture using a highly thermostable bacterial α-carbonic anhydrase immobilized on a polyurethane foam

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Viviana De Luca

X-ray structure of the first `extremo-α-carbonic anhydrase', a dimeric enzyme from the thermophilic bacteriumSulfurihydrogenibium yellowstonenseYO3AOP1

Biochemical properties of a novel and highly thermostable bacterial α-carbonic anhydrase fromSulfurihydrogenibium yellowstonense YO3AOP1

Protonography, a new technique for the analysis of carbonic anhydrase activity

An α-carbonic anhydrase from the thermophilic bacterium Sulphurihydrogenibium azorense is the fastest enzyme known for the CO2 hydration reaction

Biomimetic CO2 capture using a highly thermostable bacterial α-carbonic anhydrase immobilized on a polyurethane foam

Contact Info

Product

Resources

About

Biomimetic CO₂ capture using a highly thermostable bacterial α-carbonic anhydrase immobilized on a polyurethane foam