A GFET Nitrile Sensor Using a Graphene‐Binding Fusion Protein

Mohamed, Abubaker A.; Noguchi, Hironaga; Tsukiiwa, Mirano; Chen, Chen; Heath, Rachel S.; Mubarak, M. Qadri E.; Komikawa, Takumi; Tanaka, Masayoshi; Okochi, Mina; Visser, Sam P. de; Hayamizu, Yuhei; Blanford, Christopher F.

doi:10.1002/adfm.202207669

Cited by 3 publications

(1 citation statement)

References 53 publications

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“…Electrical detection of the target molecules with transistor-based biosensors is currently a ubiquitous mechanism for biosensing. To enhance the transistor-based biosensors’ sensitivity, nanomaterials such as Si nanowires and carbon nanotubes are often used for the detection-channel part of the transistor because of their high specific surface area. − More recently, biosensors with two-dimensional (2D) nanomaterials represented by graphene and MoS 2 have demonstrated a high sensitivity to a variety of target molecules. − While graphene is semi-metallic, MoS 2 is a new member of the 2D materials with a semiconducting property, allowing for higher electrical sensitivity for biosensing, in principle, than graphene biosensors …”

Section: Introductionmentioning

confidence: 99%

Self-assembled GA-Repeated Peptides as a Biomolecular Scaffold for Biosensing with MoS₂ Electrochemical Transistors

Noguchi

Nakamura

Tezuka

et al. 2023

ACS Appl. Mater. Interfaces

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Biosensors with two-dimensional materials have gained wide interest due to their high sensitivity. Among them, single-layer MoS2 has become a new class of biosensing platform owing to its semiconducting property. Immobilization of bioprobes directly onto the MoS2 surface with chemical bonding or random physisorption has been widely studied. However, these approaches potentially cause a reduction of conductivity and sensitivity of the biosensor. In this work, we designed peptides that spontaneously align into monomolecular-thick nanostructures on electrochemical MoS2 transistors in a non-covalent fashion and act as a biomolecular scaffold for efficient biosensing. These peptides consist of repeated domains of glycine and alanine in the sequence and form self-assembled structures with sixfold symmetry templated by the lattice of MoS2. We investigated electronic interactions of self-assembled peptides with MoS2 by designing their amino acid sequence with charged amino acids at both ends. Charged amino acids in the sequence showed a correlation with the electrical properties of single-layer MoS2, where negatively charged peptides caused a shift of threshold voltage in MoS2 transistors and neutral and positively charged peptides had no significant effect on the threshold voltage. The transconductance of transistors had no decrease due to the self-assembled peptides, indicating that aligned peptides can act as a biomolecular scaffold without degrading the intrinsic electronic properties for biosensing. We also investigated the impact of peptides on the photoluminescence (PL) of single-layer MoS2 and found that the PL intensity changed sensitively depending on the amino acid sequence of peptides. Finally, we demonstrated a femtomolar-level sensitivity of biosensing using biotinylated peptides to detect streptavidin.

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Section: Introductionmentioning

confidence: 99%

Self-assembled GA-Repeated Peptides as a Biomolecular Scaffold for Biosensing with MoS₂ Electrochemical Transistors

Noguchi

Nakamura

Tezuka

et al. 2023

ACS Appl. Mater. Interfaces

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A GFET Nitrile Sensor Using a Graphene‐Binding Fusion Protein

Mohamed

Noguchi

Tsukiiwa

et al. 2022

Adv Funct Materials

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A new route to single-step and non-covalent immobilization of proteins on graphene is exemplified with the first biosensor for nitriles based on a graphene field-effect transistor (GFET). The biological recognition element is a fusion protein consisting of nitrile reductase QueF from Escherichia coli with an N-terminal self-assembling and graphene-binding dodecapeptide. Atomic force microscopy and analysis using a quartz crystal microbalance show that both the oligopeptide and the fusion protein incorporating it form a single adlayer of monomeric enzyme on graphene. The fusion protein has a 6.3-fold increase in binding affinity for benzyl cyanide (BnCN) versus wild-type QueF and a 1.4-fold increase for affinity for the enzyme's natural substrate preQ 0 . Density functional theory analysis of QueF's catalytic cycle with BnCN shows similar transition-state barriers to preQ 0 , but differences in the formation of the initial thioimidate covalent bonding (∆G ‡ = 19.0 kcal mol −1 for preQ 0 vs 27.7 kcal mol −1 for BnCN) and final disassociation step (∆G = −24.3 kcal mol −1 for preQ 0 vs ∆G = +4.6 kcal mol −1 for BnCN). Not only do these results offer a single-step route to GFET modification, but they also present new opportunities in the biocatalytic synthesis of primary amines from nitriles.

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A Graphene Field-Effect Transistor Sensor Utilizing Au-S Bond Self-Assembly for Specific Detection of L-Cysteine in Chicken Broth

Wu,

Cao,

Dong

et al. 2024

Preprint

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A GFET Nitrile Sensor Using a Graphene‐Binding Fusion Protein

Cited by 3 publications

References 53 publications

Self-assembled GA-Repeated Peptides as a Biomolecular Scaffold for Biosensing with MoS₂ Electrochemical Transistors

Self-assembled GA-Repeated Peptides as a Biomolecular Scaffold for Biosensing with MoS₂ Electrochemical Transistors

A GFET Nitrile Sensor Using a Graphene‐Binding Fusion Protein

A Graphene Field-Effect Transistor Sensor Utilizing Au-S Bond Self-Assembly for Specific Detection of L-Cysteine in Chicken Broth

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A GFET Nitrile Sensor Using a Graphene‐Binding Fusion Protein

Cited by 3 publications

References 53 publications

Self-assembled GA-Repeated Peptides as a Biomolecular Scaffold for Biosensing with MoS2 Electrochemical Transistors

Self-assembled GA-Repeated Peptides as a Biomolecular Scaffold for Biosensing with MoS2 Electrochemical Transistors

A GFET Nitrile Sensor Using a Graphene‐Binding Fusion Protein

A Graphene Field-Effect Transistor Sensor Utilizing Au-S Bond Self-Assembly for Specific Detection of L-Cysteine in Chicken Broth

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Product

Resources

About

Self-assembled GA-Repeated Peptides as a Biomolecular Scaffold for Biosensing with MoS₂ Electrochemical Transistors

Self-assembled GA-Repeated Peptides as a Biomolecular Scaffold for Biosensing with MoS₂ Electrochemical Transistors