How Modification of Accessible Lysines to Phenylalanine Modulates the Structural and Functional Properties of Horseradish Peroxidase: A Simulation Study

Navapour, Leila; Mogharrab, Navid; Amininasab, Mehriar

doi:10.1371/journal.pone.0109062

Cited by 4 publications

(4 citation statements)

References 63 publications

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“…Computational chemistry on hemeproteins has been widely used ,− and proved to be a good strategy to describe molecular details concerning hemic systems and as a prediction tool of relevant biological processes.…”

Section: Introductionmentioning

confidence: 99%

Access and Binding of H₂S to Hemeproteins: The Case of HbI of Lucina pectinata

et al. 2016

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Hydrogen sulfide (H2S) was recently discovered as a gasotransmitter, capable of coordinating to the heme iron of hemeproteins. H2S is unique for its ability to render varying concentrations of the nucleophilic conjugate bases (HS(-) or S(2-)), either as free or bound species with expected outcomes on its further reactivity. There is no direct evidence about which species (H2S, HS(-), or S(2-)) coordinates to the iron. We performed computer simulations to address the migration and binding processes of H2S species to the hemoglobin I of Lucina pectinata, which exhibits the highest affinity for the substrate measured to date. We found that H2S is the most favorable species in the migration from the bulk to the active site, through an internal pathway of the protein. After the coordination of H2S, an array of clustered water molecules modifies the active site environment, and assists in the subsequent deprotonation of the ligand, forming Fe(III)-SH(-). The feasibility of the second deprotonation of the coordinated ligand is also discussed.

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Section: Introductionmentioning

confidence: 99%

Access and Binding of H₂S to Hemeproteins: The Case of HbI of Lucina pectinata

et al. 2016

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“…57, 58 In addition, its relatively small physical size is ideal for probing the efficiency of a covalent attachment to a bioink scaffold, enabling easy distinction between sole physical entrapment and covalent anchoring. Since HRP only presents 6 free amino residues on its surface, 59 we aimed to introduce as many methacrylate groups as possible.…”

Section: Resultsmentioning

confidence: 99%

Enzyme Bioink for the 3D Printing of Biocatalytic Materials

Altevogt,

Sheikh,

Molley

et al. 2024

Preprint

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The field of 3D biofabrication faces major challenges on the road to printing fully functional tissues and organs. One of them is adding functionality to the newly formed tissue for replicating an active biochemical environment. Native extracellular matrices sequester numerous bioactive species, making the microenvironment biochemically active. On the other hand, most 3D-printed constructs have limited activity, serving merely as mechanical scaffolding. Here we demonstrate active scaffolding through the integration of biocatalytic enzymes within the bioink. Enzymes are an attractive class of biocompatible and substrate-specific bioactive agents that can improve tissue regeneration outcomes. However, the difficulty in the application remains in providing enzymes at the targeted site in adequate amounts over an extended time.In this work, a durable biocatalytic active enzyme bioink for 3D extrusion-based bioprinting is developed by covalently attaching the globular enzyme horseradish peroxidase (HRP) to a gelatin methacrylate (Gel-MA) biopolymer scaffold. Upon introducing methacrylate groups on the surface of the enzyme, it undergoes photo-crosslinking in a post-printing step with the methacrylate groups of Gel-MA without compromising its activity. As a result, HRP becomes a fixed part of the hydrogel network and achieves higher stability inside the gel which results in a higher concentration and catalytic activity for a longer time than solely entrapping the protein inside the hydrogel. We also demonstrate the cytocompatibility of this enzyme bioink and show its printing capabilities for precise applications in the field of tissue engineering. Our approach offers a promising solution to enhance the bioactive properties of 3D-printed constructs, representing a critical step towards achieving functional biofabricated tissues.

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“…Several reports have demonstrated that the modification of the surface of functional proteins can modulate their native activity [5–7] . The modification of the primary sequence of the protein can give rise to several scenarios: from the complete inactivation of the protein to a significant enhancement of its performance.…”

Section: Introductionmentioning

confidence: 99%

“…[3,4] Several reports have demonstrated that the modification of the surface of functional proteins can modulate their native activity. [5][6][7] The modification of the primary sequence of the protein can give rise to several scenarios: from the complete inactivation of the protein to a significant enhancement of its performance. Among all the combinations of functional proteins and artificial materials, the particular case of enzymes modified with polymers requires detailed investigation.…”

Section: Introductionmentioning

confidence: 99%

Enzyme‐Polymer Conjugates for Tuning, Enhancing, and Expanding Biocatalytic Activity

Heredero

Beloqui

2023

ChemBioChem

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Combining polymers with functional proteins is an approach that has brought several successful stories in the field of biomedicine with PEGylated therapeutic proteins. The latest advances in polymer chemistry have facilitated the expansion of protein-polymer hybrids to other research areas such as biocatalysis. Polymers can impart stability and novel functionalities to the enzyme of interest, thereby improving the catalytic performance of a given reaction. In this review, we have revisited the main methodologies currently used for the synthesis of enzyme-polymer hybrids, unveiling the interplay between the configuration and the composition of the assembled structure and the eventual traits of the hybrid. Finally, the latest advances, such as the assembly of polymerbased chemoenzymatic nanoreactors and the use of deep learning methodologies to achieve the most suitable polymer compositions for catalysis, are discussed.

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How Modification of Accessible Lysines to Phenylalanine Modulates the Structural and Functional Properties of Horseradish Peroxidase: A Simulation Study

Cited by 4 publications

References 63 publications

Access and Binding of H₂S to Hemeproteins: The Case of HbI of Lucina pectinata

Access and Binding of H₂S to Hemeproteins: The Case of HbI of Lucina pectinata

Enzyme Bioink for the 3D Printing of Biocatalytic Materials

Enzyme‐Polymer Conjugates for Tuning, Enhancing, and Expanding Biocatalytic Activity

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How Modification of Accessible Lysines to Phenylalanine Modulates the Structural and Functional Properties of Horseradish Peroxidase: A Simulation Study

Cited by 4 publications

References 63 publications

Access and Binding of H2S to Hemeproteins: The Case of HbI of Lucina pectinata

Access and Binding of H2S to Hemeproteins: The Case of HbI of Lucina pectinata

Enzyme Bioink for the 3D Printing of Biocatalytic Materials

Enzyme‐Polymer Conjugates for Tuning, Enhancing, and Expanding Biocatalytic Activity

Contact Info

Product

Resources

About

Access and Binding of H₂S to Hemeproteins: The Case of HbI of Lucina pectinata

Access and Binding of H₂S to Hemeproteins: The Case of HbI of Lucina pectinata