Your search keyword '"Banta S"' showing total 7 results

1. Engineered Biomolecular Recognition of RDX by Using a Thermostable Alcohol Dehydrogenase as a Protein Scaffold.

Author

Bulutoglu B, Haghpanah J, Campbell E, and Banta S

Subjects

Alcohol Dehydrogenase metabolism, Enzyme Stability, Molecular Docking Simulation, Solubility, Water chemistry, Alcohol Dehydrogenase chemistry, Protein Engineering, Pyrococcus furiosus enzymology, Temperature, Triazines chemistry

Abstract

There are many biotechnology applications that would benefit from simple, stable proteins with engineered biomolecular recognition. Here, we explored the hypothesis that a thermostable alcohol dehydrogenase (AdhD from Pyrococcus furiosus) could be engineered to bind a small molecule instead of a cofactor or molecules involved in the catalytic transition state. We chose the explosive molecule 1,3,5-trinitro-1,3,5-triazine (royal demolition explosive, RDX) as a proof-of-concept. Its low solubility in water was exploited for immobilization for biopanning by using ribosome display. Docking simulations were used to identify two potential binding sites in AdhD, and a randomized library focused on tyrosine or serine mutations was used to determine that RDX was binding in the substrate binding pocket of the enzyme. A fully randomized binding pocket library was selected, and affinity maturation by error-prone PCR led to the identification of a mutant (EP-16) that gained the ability to bind RDX with an affinity of (73±11) μm. These results underscore the way in which thermostable enzymes can be useful scaffolds for expanding the biomolecular recognition toolbox., (© 2018 Wiley-VCH Verlag GmbH & Co. KGaA, Weinheim.)

Published

2018

2. Engineering the cofactor specificity of an alcohol dehydrogenase via single mutations or insertions distal to the 2'-phosphate group of NADP(H).

Author

Solanki K, Abdallah W, and Banta S

Subjects

Binding Sites, Humans, Pyrococcus furiosus enzymology, Alcohol Dehydrogenase chemistry, Alcohol Dehydrogenase genetics, Archaeal Proteins chemistry, Archaeal Proteins genetics, Coenzymes chemistry, Mutation, NADP chemistry, Pyrococcus furiosus genetics

Abstract

There have been many reports exploring the engineering of the cofactor specificity of aldo-keto reductases (AKRs), as this class of proteins is ubiquitous and exhibits many useful activities. A common approach is the mutagenesis of amino acids involved in interactions with the 2'-phosphate group of NADP(H) in the cofactor binding pocket. We recently performed a 'loop-grafting' approach to engineer the substrate specificity of the thermostable alcohol dehydrogenase D (AdhD) from Pyrococcus furiosus and we found that a loop insertion after residue 211, which is on the back side of the cofactor binding pocket, could also alter cofactor specificity. Here, we further explore this approach by introducing single point mutations and single amino acid insertions at the loop insertion site. Six different mutants of AdhD were created by either converting glycine 211 to cysteine or serine or by inserting alanine, serine, glycine or cysteine between the 211 and 212 residues. Several mutants gained activity with NADP+ above the wild-type enzyme. And remarkably, it was found that all of the mutants investigated resulted in some degree of reversal of cofactor specificity in the oxidative direction. These changes were generally a result of changes in conformations of the ternary enzyme/cofactor/substrate complexes as opposed to changes in affinities or binding energies of the cofactors. This study highlights the role that amino acids which are distal to the cofactor binding pocket but are involved in substrate interactions can influence cofactor specificity in AdhD, and this strategy should translate to other AKR family members., (© The Author 2017. Published by Oxford University Press. All rights reserved. For Permissions, please e-mail: journals.permissions@oup.com.)

Published

2017

3. Extreme makeover: Engineering the activity of a thermostable alcohol dehydrogenase (AdhD) from Pyrococcus furiosus.

Author

Solanki K, Abdallah W, and Banta S

Subjects

Alcohol Dehydrogenase genetics, Binding Sites, Enzyme Stability, Hydrogels, Mutation, Protein Conformation, Substrate Specificity, Alcohol Dehydrogenase chemistry, Alcohol Dehydrogenase metabolism, Protein Engineering methods, Pyrococcus furiosus enzymology

Abstract

Alcohol dehydrogenase D (AdhD) is a monomeric thermostable alcohol dehydrogenase from the aldo-keto reductase (AKR) superfamily of proteins. We have been exploring various strategies of engineering the activity of AdhD so that it could be employed in future biotechnology applications. Driven by insights made in other AKRs, we have made mutations in the cofactor-binding pocket of the enzyme and broadened its cofactor specificity. A pre-steady state kinetic analysis yielded new insights into the conformational behavior of this enzyme. The most active mutant enzyme concomitantly gained activity with a non-native cofactor, nicotinamide mononucleotide, NMN(H), and an enzymatic biofuel cell was demonstrated with this enzyme/cofactor pair. Substrate specificity was altered by grafting loop regions near the active site pocket from a mesostable human aldose reductase (hAR) onto the thermostable AdhD. These moves not only transferred the substrate specificity of hAR but also the cofactor specificity of hAR. We have added alpha-helical appendages to AdhD to enable it to self-assemble into a thermostable catalytic proteinaceous hydrogel. As our understanding of the structure/function relationship in AdhD and other AKRs advances, this ubiquitous protein scaffold could be engineered for a variety of catalytic activities that will be useful for many future applications., (Copyright © 2016 WILEY-VCH Verlag GmbH & Co. KGaA, Weinheim.)

Published

2016

4. Modular exchange of substrate-binding loops alters both substrate and cofactor specificity in a member of the aldo-keto reductase superfamily.

Author

Campbell E, Chuang S, and Banta S

Subjects

Alcohol Dehydrogenase genetics, Aldehyde Reductase genetics, Amino Acid Sequence, Glyceraldehyde metabolism, Humans, Models, Molecular, Molecular Sequence Data, Mutation, Protein Conformation, Protein Engineering, Protein Stability, Pyrococcus furiosus chemistry, Pyrococcus furiosus genetics, Substrate Specificity, Temperature, Alcohol Dehydrogenase chemistry, Alcohol Dehydrogenase metabolism, Aldehyde Reductase chemistry, Aldehyde Reductase metabolism, Pyrococcus furiosus enzymology

Abstract

Substrate specificity in the aldo-keto reductase (AKR) superfamily is determined by three mobile loops positioned at the top of the canonical (α/β)(8)-barrel structure. These loops have previously been demonstrated to be modular in a well-studied class of AKRs, in that exchanging loops between two similar hydroxysteroid dehydrogenases resulted in a complete alteration of substrate specificity (Ma,H. and Penning,T.M. (1999) Proc. Natl Acad. Sci. USA, 96, 11161-11166). Here, we further examine the modularity of these loops by grafting those from human aldose reductase (hAR) into the hyperthermostable AKR, alcohol dehydrogenase D (AdhD), from Pyrococcus furiosus. Replacement of Loops A and B was sufficient to impart hAR activity into AdhD, and the resulting chimera retained the thermostability of the parent enzyme. However, no active chimeras were observed when the hAR loops were grafted into a previously engineered cofactor specificity mutant of AdhD, which displayed similar kinetics to hAR with the model substrate dl-glyceraldehyde. The non-additivity of these mutations suggests that efficient turnover is more dependent on the relative positioning of the cofactor and substrate in the active site than on binding of the individual species. The ability to impart the substrate specificities of mesostable AKRs into a thermostable scaffold will be useful in a variety of applications including immobilized enzyme systems for bioelectrocatalysis and fine chemical synthesis.

Published

2013

5. Effect of thermal stability on protein adsorption to silica using homologous aldo-keto reductases.

Author

Felsovalyi F, Patel T, Mangiagalli P, Kumar SK, and Banta S

Subjects

Adsorption, Amino Acid Sequence, Circular Dichroism, Humans, Molecular Sequence Data, Protein Conformation, Protein Denaturation, Protein Stability, Pyrococcus furiosus chemistry, Sequence Alignment, Surface Properties, Temperature, Alcohol Dehydrogenase chemistry, Aldehyde Reductase chemistry, Pyrococcus furiosus enzymology, Silicon Dioxide chemistry

Abstract

Gaining more insight into the mechanisms governing the behavior of proteins at solid/liquid interfaces is particularly relevant in the interaction of high-value biologics with storage and delivery device surfaces, where adsorption-induced conformational changes may dramatically affect biocompatibility. The impact of structural stability on interfacial behavior has been previously investigated by engineering nonwild-type stability mutants. Potential shortcomings of such approaches include only modest changes in thermostability, and the introduction of changes in the topology of the proteins when disulfide bonds are incorporated. Here we employ two members of the aldo-keto reductase superfamily (alcohol dehydrogenase, AdhD and human aldose reductase, hAR) to gain a new perspective on the role of naturally occurring thermostability on adsorbed protein arrangement and its subsequent impact on desorption. Unexpectedly, we find that during initial adsorption events, both proteins have similar affinity to the substrate and undergo nearly identical levels of structural perturbation. Interesting differences between AdhD and hAR occur during desorption and both proteins exhibit some level of activity loss and irreversible conformational change upon desorption. Although such surface-induced denaturation is expected for the less stable hAR, it is remarkable that the extremely thermostable AdhD is similarly affected by adsorption-induced events. These results question the role of thermal stability as a predictor of protein adsorption/desorption behavior., (Copyright © 2012 The Protein Society.)

Published

2012

6. Broadening the cofactor specificity of a thermostable alcohol dehydrogenase using rational protein design introduces novel kinetic transient behavior.

Author

Campbell E, Wheeldon IR, and Banta S

Subjects

Amino Acid Substitution genetics, Binding Sites genetics, Kinetics, Models, Molecular, Mutagenesis, Site-Directed, Protein Conformation, Alcohol Dehydrogenase genetics, Alcohol Dehydrogenase metabolism, Coenzymes metabolism, NADP metabolism, Protein Engineering methods, Pyrococcus furiosus enzymology

Abstract

Cofactor specificity in the aldo-keto reductase (AKR) superfamily has been well studied, and several groups have reported the rational alteration of cofactor specificity in these enzymes. Although most efforts have focused on mesostable AKRs, several putative AKRs have recently been identified from hyperthermophiles. The few that have been characterized exhibit a strong preference for NAD(H) as a cofactor, in contrast to the NADP(H) preference of the mesophilic AKRs. Using the design rules elucidated from mesostable AKRs, we introduced two site-directed mutations in the cofactor binding pocket to investigate cofactor specificity in a thermostable AKR, AdhD, which is an alcohol dehydrogenase from Pyrococcus furiosus. The resulting double mutant exhibited significantly improved activity and broadened cofactor specificity as compared to the wild-type. Results of previous pre-steady-state kinetic experiments suggest that the high affinity of the mesostable AKRs for NADP(H) stems from a conformational change upon cofactor binding which is mediated by interactions between a canonical arginine and the 2'-phosphate of the cofactor. Pre-steady-state kinetics with AdhD and the new mutants show a rich conformational behavior that is independent of the canonical arginine or the 2'-phosphate. Additionally, experiments with the highly active double mutant using NADPH as a cofactor demonstrate an unprecedented transient behavior where the binding mechanism appears to be dependent on cofactor concentration. These results suggest that the structural features involved in cofactor specificity in the AKRs are conserved within the superfamily, but the dynamic interactions of the enzyme with cofactors are unexpectedly complex., (© 2010 Wiley Periodicals, Inc.)

Published

2010

7. A chimeric fusion protein engineered with disparate functionalities-enzymatic activity and self-assembly.

Author

Wheeldon IR, Campbell E, and Banta S

Subjects

Alcohol Oxidoreductases chemistry, Aldehyde Reductase, Aldo-Keto Reductases, Archaeal Proteins chemistry, Archaeal Proteins genetics, Archaeal Proteins metabolism, Hot Temperature, Hydrogel, Polyethylene Glycol Dimethacrylate metabolism, Kinetics, Models, Molecular, Protein Multimerization, Protein Structure, Tertiary, Recombinant Fusion Proteins chemistry, Alcohol Oxidoreductases genetics, Alcohol Oxidoreductases metabolism, Pyrococcus furiosus enzymology, Recombinant Fusion Proteins genetics, Recombinant Fusion Proteins metabolism

Abstract

The fusion of protein domains is an important mechanism in molecular evolution and a valuable strategy for protein engineering. We are interested in creating fusion proteins containing both globular and structural domains so that the final chimeric protein can be utilized to create novel bioactive biomaterials. Interactions between fused domains can be desirable in some fusion protein applications, but in this case the optimal configuration will enable the bioactivity to be unaffected by the structural cross-linking. To explore this concept, we have created a fusion consisting of a thermostable aldo-keto reductase, two alpha-helical leucine zipper domains, and a randomly coiled domain. The resulting protein is bifunctional in that (1) it can self-assemble into a hydrogel material as the terminal leucine zipper domains form interprotein coiled-coil cross-links, and (2) it expresses alcohol dehydrogenase and aldo-keto reductase activity native to AdhD from Pyrococcus furiosus. The kinetic parameters of the enzyme are minimally affected by the addition of the helical appendages, and rheological studies demonstrate that a supramolecular assembly of the bifunctional protein building blocks forms a hydrogel. An active hydrogel is produced at temperatures up to 60 degrees C, and we demonstrate the functionality of the biomaterial by monitoring the oxidation and reduction of the native substrates by the gel. The design of chimeric fusion proteins with both globular and structural domains is an important advancement for the creation of bioactive biomaterials for biotechnology applications such as tissue engineering, bioelectrocatalysis, and biosensing and for the study of native assembled enzyme structures and clustered enzyme systems such as metabolons.

Published

2009