Direct bioelectrocatalysis at the interfaces by genetically engineered dehydrogenase

Yucesoy, Deniz Tanil; Karaca, Banu Taktak; Çetinel, Sibel; Caliskan, Huseyin Burak; Adalı, Eşref; Gul-Karaguler, Nevin; Tamerler, Candan

doi:10.1680/bbn.14.00022

Cited by 8 publications

(15 citation statements)

References 56 publications

(89 reference statements)

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“…The paper by Yucesoy et al 10 relates to the emerging interest in developing bio-functionalisation routes. The work introduces a new platform that could serve as a bioengineering platform for assembling diverse enzymes onto material surfaces for laboratoryon-a-chip-based sensing and energy-harvesting systems.…”

Section: Ice | Sciencementioning

confidence: 99%

Editorial

Zollfrank¹

2015

Bioinspired, Biomimetic and Nanobiomaterials

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1Dr Mallick was an internationally renowned material scientist with a strong focus on biological and medicinal sciences. As a material scientist, he was always open to other scientific disciplines and innovative technology routes as such the bioinspired approach. He strongly developed the new field of bioinspired materials, especially for biomedical applications. Most recently, he headed the Tissue Engineering and Ceramic Processing research group (TiECeP), which includes a large number of undergraduate and graduate students, as well as doctoral candidates from the natural and engineering sciences. His research and teaching was focused on the synthesis, structure, processing and characterisation of materials including ceramics, glass and glass-ceramics, polymers, metals and biomedical materials. His other areas of significant research impact included functional, engineering and electroceramics for mobile and telecommunication applications as well as superconductors. He published nearly 100 refereed papers in leading peer-reviewed high-impact international journals, as well as a number of contributed/invited conference papers.The Dr Kajal Mallick memorial issue honours his life's work in his various fields of research. It includes part of his own work and contributions from his friends and partners in sciences. Major contributions come from the area of biomedical science, and novel scaffold fabrication and bone regenerative medicine. This issue further encompasses innovative ceramic manufacturing techniques and bioinspired materials such as optical structures and theoretical consideration on the toucan beak.The first paper by Winnet and Mallick 2 and accompanied work derives from the renowned Warwick Manufacturing Group and reflects the research of Dr Kajal Mallick. The topic of this paper is the fabrication of porous 3D bioscaffolds by adaptive foam reticulation. Highly interconnected and porous hydroxyapatite (HA) scaffolds with controllable macroporosity and microporosity were produced using the adaptive foam reticulation technique, combining foam reticulation and freeze-casting methodologies. The developed process yielded an optimised macropore structure from the polymeric template. Designed micropores are introduced into the struts using the porogen approach. The cell culture and assay test distinctly showed that the scaffolds are not cytotoxic and can be used as bone grafts.The next paper by Gu et al.3 deals with the evaluation of the dynamic nanomechanical behaviour of healthy compared with disordered (osteogenesis imperfecta (OI)) human cortical bone. The assessment of the viscoelastic properties of bone is of profound interest, because the time-dependent mechanical properties relate to the fracture risk of bone under dynamic loading. The authors studied the nanomechanical behaviour of the intact, demineralised and OI human cortical bone specimens by dynamic nanoindentation. Their results suggest that the viscoelasticity of bone is primarily attributable to the mineral component. This study is a valuable ...

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Section: Ice | Sciencementioning

confidence: 99%

Editorial

Zollfrank¹

2015

Bioinspired, Biomimetic and Nanobiomaterials

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“…Another approach that has been developed recently by our groups and others is the use of genetically engineered affinity peptides for the selective, specific immobilization of biomolecules at particular material interfaces. − These peptides have been developed using cell surface display and phage display to have a high affinity for a specific material (e.g., Au, Ag, silica, graphite). − While a number of peptides with high affinity for different materials have been developed and demonstrated, detailed investigation of the immobilization of active enzymes using these peptides is relatively unexplored. ,,,− We and others studied solid binding peptides to control orientation of the proteins and demonstrated self-immobilization of several enzymes, including alkaline phosphatase, glutathione S-transferase, and lactate dehydrogenase on specific materials, − but details including information regarding the correlation of orientation and coverage with activity are still lacking …”

Section: Introductionmentioning

confidence: 99%

Probing Selective Self-Assembly of Putrescine Oxidase with Controlled Orientation Using a Genetically Engineered Peptide Tag

et al. 2021

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Controlling enzyme orientation and location on surfaces is a critical step for their successful deployment in diverse applications from biosensors to lab-on-a-chip devices. Functional activity of the enzymes on the surface will largely depend on the spatial arrangement and orientation. Solid binding peptides have been proven to offer versatility for immobilization of biomolecules on inorganic materials including metals, oxides, and minerals. Previously, we demonstrated the utility of a gold binding peptide genetically incorporated into the enzyme putrescine oxidase (PutOx−AuBP), enabling self-enzyme assembly on gold substrates. PutOx is an attractive biocatalyst among flavin oxidases, using molecular oxygen as an electron acceptor without requiring a dissociable coenzyme. Here, we explore the selective self-assembly of this enzyme on a range of surfaces using atomic force microscopy (AFM) along with the assessment of functional activity. This work probes the differences in surface coverage, distribution, size, shape, and activity of PutOx−AuBP in comparison to those of native putrescine oxidase (PutOx) on multiple surfaces to provide insight for material-selective enzymatic assembly. Surfaces investigated include metal (templated-stripped gold (TSG)), oxide (native SiO 2 on Si(111)), minerals (mica and graphite), and self-assembled monolayers (SAMs) with a range of hydrophobicity and charge. Supported by both the coverage and the dimensions of immobilized enzymes, our results indicate that of the surfaces investigated, material-selective binding takes place with orientation control only for PutOx−AuBP onto the TSG substrate. These differences are consistent with the measurements of surface-bound enzymatic activities. Substrate-dependent differences observed indicate significant variations in enzyme−surface interactions ranging from peptide-directed self-assembly to enzyme aggregation. The implications of this study provide insight for the fabrication of enzymatic patterns directed by self-assembling peptide tags onto localized surface regions. Enabling functional enzyme-based nanoscale materials offers a fascinating path for utilization of sustainable biocatalysts integrated into multiscale devices.

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“…Despite well-established phage display selection procedures and subsequent improvements towards increasing the winner peptides' potential, the methods are still far from leveraging the huge combinatorial potential since the diversity of the libraries is in the order of 10 9 variants. 2,7,15,18,19 The drawback is primarily due to the limited scalability of clone selection techniques and characterization. Moreover, in low-throughput Sanger sequencing workflows traditionally used, the number of peptides isolated in a reasonable time frame after several rounds of the biopanning process is limited to 10-100 clones.…”

Section: Introductionmentioning

confidence: 99%

Deep Directed Evolution of Solid Binding Peptides for Quantitative Big-data Generation

Yucesoy

Rath

Rodriguez

et al. 2021

Preprint

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Proteins have evolved over millions of years to mediate and carry-out biological processes efficiently. Directed evolution approaches have been used to genetically engineer proteins with desirable functions such as catalysis, mineralization, and target-specific binding. Next-generation sequencing technology offers the capability to discover a massive combinatorial sequence space that is costly to sample experimentally through traditional approaches. Since the permutation space of protein sequence is virtually infinite, and evolution dynamics are poorly understood, experimental verifications have been limited. Recently, machine-learning approaches have been introduced to guide the evolution process that facilitates a deeper and denser search of the sequence-space. Despite these developments, however, frequently used high-fidelity models depend on massive amounts of properly labeled quality data, which so far has been largely lacking in the literature. Here, we provide a preliminary high-throughput peptide-selection protocol with functional scoring to enhance the quality of the data. Solid binding dodecapeptides have been selected against molybdenum disulfide substrate, a two-dimensional atomically thick semiconductor solid. The survival rate of the phage-clones, upon successively stringent washes, quantifies the binding affinity of the peptides onto the solid material. The method suggested here provides a fast generation of preliminary data-pool with ∼2 million unique peptides with 12 amino-acids per sequence by avoiding amplification. Our results demonstrate the importance of data-cleaning and proper conditioning of massive datasets in guiding experiments iteratively. The established extensive groundwork here provides unique opportunities to further iterate and modify the technique to suit a wide variety of needs and generate various peptide and protein datasets. Prospective statistical models developed on the datasets to efficiently explore the sequence-function space will guide towards the intelligent design of proteins and peptides through deep directed evolution. Technological applications of the future based on the peptide-single layer solid based bio/nano soft interfaces, such as biosensors, bioelectronics, and logic devices, is expected to benefit from the solid binding peptide dataset alone. Furthermore, protocols described herein will also benefit efforts in medical applications, such as vaccine development, that could significantly accelerate a global response to future pandemics.

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Direct bioelectrocatalysis at the interfaces by genetically engineered dehydrogenase

Cited by 8 publications

References 56 publications

Editorial

Editorial

Probing Selective Self-Assembly of Putrescine Oxidase with Controlled Orientation Using a Genetically Engineered Peptide Tag

Deep Directed Evolution of Solid Binding Peptides for Quantitative Big-data Generation

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