Locking the Ultrasound-Induced Active Conformation of Metalloenzymes in Metal–Organic Frameworks

Liang, Jieying; Zulkifli, Muhammad Yazid Bin; Yong, Joel; Du, Zheyuan; Ao, Zhimin; Rawal, Aditya; Scott, Jason; Harmer, Jeffrey; Wang, Joseph; Liang, Kang

doi:10.1021/jacs.2c06471

Cited by 34 publications

(30 citation statements)

References 66 publications

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“…However, the content of β‐sheet from HRP‐COF‐LZU1 is increased, whereas the content of β‐sheet from HRP‐RT‐COF‐1 and HRP‐ACOF‐1 is decreased, suggesting the HRP conformation in COF‐LZU1 is more favorable. the enzyme experienced significant structural alteration upon immobilization within reticular framework, although this structural change is generally not stable in its free form, as evidenced by our previous research that the reticular frameworks could lock this fragile conformation and improve the enzyme stability [4a] …”

Section: Resultsmentioning

confidence: 98%

“…Next, 2D 13 C− 1 H heteronuclear correlation (HETCOR) NMR measurement was conducted to probe the interaction between HRP and COFs. Incorporating a 10 ms 1 H− 1 H spin diffusion time prior to the transfer of signal from the 1 H to the 13 C nuclei enables the local ≈1–2 nm scale region around the detected 13 C species to be probed [4a, 24] . The contour plots in Figure 3d–f display cross‐correlation peaks between the 1 H NMR signals of the HRP (CH 3 /Hβ ≈1.8 ppm and Hα 3.5 ppm) and the 13 C species of the COFs (180 ppm‐100 ppm).…”

Section: Resultsmentioning

confidence: 99%

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Insight into Bioactivity of In‐situ Trapped Enzyme‐Covalent‐Organic Frameworks

et al. 2023

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Selecting a suitable support material for enzyme immobilization with excellent biocatalytic activity and stability is a critical aspect in the development of functional biosystems. The highly stable and metal‐free properties of covalent‐organic frameworks (COFs) make them ideal supports for enzyme immobilization. Herein, we constructed three kinds of COFs via a biofriendly and one‐pot synthetic strategy at room temperature in aqueous solution. Among the three developed COFs (COF‐LZU1, RT‐COF‐1 and ACOF‐1), the horseradish peroxidase (HRP)‐incorporated COF‐LZU1 is found to retain the highest activity. Structural analysis reveals that a weakest interaction between the hydrated enzyme and COF‐LZU1, an easiest accessibility by the COF‐LZU1 to the substrate, as well as an optimal conformation of enzyme together promote the bioactivity of HRP‐COF‐LZU1. Furthermore, the COF‐LZU1 is revealed to be a versatile nanoplatform for encapsulating multiple enzymes. The COF‐LZU1 also offers superior protection for the immobilized enzymes under harsh conditions and during recycling. The comprehensive understanding of interfacial interactions of COF host and enzyme guest, the substrate diffusion, as well as the enzyme conformation alteration within COF matrices represents an opportunity to design the ideal biocatalysts and opens a broad range of applications of these nanosystems.

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Section: Resultsmentioning

confidence: 98%

Section: Resultsmentioning

confidence: 99%

Insight into Bioactivity of In‐situ Trapped Enzyme‐Covalent‐Organic Frameworks

et al. 2023

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“…The design, synthesis, characterization, and biocatalytic application of enzyme/MOF composites have been experiencing considerable growth recently. [5][6][7][8][9][10][11][12] Following their development, biocomposites have been synthesized via the orthogonal combination of various enzymes and MOFs. Enzyme immobilization can be realized via one-pot encapsulation in MOFs, infiltration in MOFs, or surface-bonding on a MOF crystallite.…”

Section: Introductionmentioning

confidence: 99%

Heterogeneity in enzyme/metal–organic framework composites for CO₂transformation reactions

2023

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“…Enzyme immobilization, defined as the spatial restriction of an enzyme on solid carriers based on adsorption, covalent binding, and cross-linking, is an effective way to overcome these intrinsic demerits of enzymes and considerably facilitate the industrialization of biotechnology. , However, not all carriers and immobilization strategies can provide optimal advantages in the case of enzymes. Substantial challenges remain in this area, such as enzyme leakage, irreversible disruption of enzyme structure, and poor accessibility of the enzyme active sites. , The natural biomineralization-inspired in situ enzyme encapsulation strategy enables simultaneous enzyme immobilization and carrier synthes is under mild conditions, effectively overcoming the aforementioned shortcomings of traditional post-immobilization strategies. , In addition, the in situ encapsulation adapts to retain enzyme properties, overcomes enzyme size limitations, and addresses the issue of compromised enzyme sensitivity when subjected to harsh environments …”

Section: Introductionmentioning

confidence: 99%

Enhancing Enzyme Activity Using Hydrophilic Hollow Layered Double Hydroxides as Encapsulation Carriers

Gan

et al. 2023

ACS Appl. Mater. Interfaces

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Enzyme immobilization enables the fabrication of flexible and powerful biocatalytic systems that can meet the needs of green and efficient development in various fields. However, restricted electron and mass transfer during enzymatic reactions and disruption of the enzyme structure during encapsulation limit the wide application of the immobilized enzyme systems. Herein, we report an encapsulation strategy based on hollow-shell-layered double hydroxides (LDHs; ZnCo-LDH) for green and nondestructive enzyme immobilization. Benefiting from the protective and enzyme-friendly microenvironment provided by the hydrophilic hollow structure of ZnCo-LDH, the encapsulated enzyme maintains a nearly natural enzyme biostructure and enhanced stability. Notably, mesoporous ZnCo-LDH with excellent electrical properties considerably facilitates electron and mass transport during enzymatic reactions, exhibiting 5.56 times the catalytic efficiency of free enzymes or traditional enzyme encapsulation systems. The current study broadens the family of encapsulated carriers and alleviates the trade-off between enzyme stability and catalytic activity in the encapsulated state, presenting a promising avenue for the industrial application of the enzyme.

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Locking the Ultrasound-Induced Active Conformation of Metalloenzymes in Metal–Organic Frameworks

Cited by 34 publications

References 66 publications

Insight into Bioactivity of In‐situ Trapped Enzyme‐Covalent‐Organic Frameworks

Insight into Bioactivity of In‐situ Trapped Enzyme‐Covalent‐Organic Frameworks

Heterogeneity in enzyme/metal–organic framework composites for CO₂transformation reactions

Enhancing Enzyme Activity Using Hydrophilic Hollow Layered Double Hydroxides as Encapsulation Carriers

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Locking the Ultrasound-Induced Active Conformation of Metalloenzymes in Metal–Organic Frameworks

Cited by 34 publications

References 66 publications

Insight into Bioactivity of In‐situ Trapped Enzyme‐Covalent‐Organic Frameworks

Insight into Bioactivity of In‐situ Trapped Enzyme‐Covalent‐Organic Frameworks

Heterogeneity in enzyme/metal–organic framework composites for CO2transformation reactions

Enhancing Enzyme Activity Using Hydrophilic Hollow Layered Double Hydroxides as Encapsulation Carriers

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Heterogeneity in enzyme/metal–organic framework composites for CO₂transformation reactions