Controllable and high‐performance immobilized enzyme reactor: DNA‐directed immobilization of multienzyme in polyamidoamine dendrimer‐functionalized capillaries

Li, Mengqi; Shen, Hao; Zhou, Zixin; He, Wenting; Su, Ping; Song, Jiayi; Yang, Yi

doi:10.1002/elps.201900428

Cited by 11 publications

(4 citation statements)

References 52 publications

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“…In line with previous work performed in 2013 [86], this time frame also witnessed the simultaneous analysis of two enzymes in one run either offline [61,87] or inline [53,77,80].…”

Section: Discussionsupporting

confidence: 81%

Overview of in‐capillary enzymatic reactions using capillary electrophoresis

2021

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This review summarizes the research that has recently been performed on in‐capillary enzymatic reactions integrated with capillary electrophoresis. The manuscript is subdivided in homogeneous and heterogeneous approaches. The main homogeneous techniques are Electrophoretically Mediated Microanalysis, At‐inlet and Transverse Diffusion of Laminar Flow Profiles. The main heterogeneous ones are Immobilized MicroEnzyme Reactors with enzymes grafted on either non‐magnetic or magnetic particles. The overview covers the period from 2018 to early 2021. The applications range from drug discovery over natural products to food, beverage and pesticide analysis.

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“…In line with previous work performed in 2013 [86], this time frame also witnessed the simultaneous analysis of two enzymes in one run either offline [61,87] or inline [53,77,80].…”

Section: Discussionsupporting

confidence: 81%

Overview of in‐capillary enzymatic reactions using capillary electrophoresis

2021

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“…Other than spherical nanoparticles, surfaces of other shapes may also be used for immobilizing DNA-guided multienzyme systems to adapt different application scenarios. For example, Li et al built a capillary electrophoresis-integrated immobilized enzyme reactor (CE-IMER), in which the ssDNA strands for directing the immobilization of complementary ssDNA-coupled GOx and HRP were fixed on the inner surface of a capillary (Figure 4B,E) (Li et al, 2020).…”

Section: Multi-enzyme Systems Constructed Based On Simple Dna Scaffoldsmentioning

confidence: 99%

Application of Nucleic Acid Frameworks in the Construction of Nanostructures and Cascade Biocatalysts: Recent Progress and Perspective

Zhu

Song

et al. 2022

Front. Bioeng. Biotechnol.

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Nucleic acids underlie the storage and retrieval of genetic information literally in all living organisms, and also provide us excellent materials for making artificial nanostructures and scaffolds for constructing multi-enzyme systems with outstanding performance in catalyzing various cascade reactions, due to their highly diverse and yet controllable structures, which are well determined by their sequences. The introduction of unnatural moieties into nucleic acids dramatically increased the diversity of sequences, structures, and properties of the nucleic acids, which undoubtedly expanded the toolbox for making nanomaterials and scaffolds of multi-enzyme systems. In this article, we first introduce the molecular structures and properties of nucleic acids and their unnatural derivatives. Then we summarized representative artificial nanomaterials made of nucleic acids, as well as their properties, functions, and application. We next review recent progress on constructing multi-enzyme systems with nucleic acid structures as scaffolds for cascade biocatalyst. Finally, we discuss the future direction of applying nucleic acid frameworks in the construction of nanomaterials and multi-enzyme molecular machines, with the potential contribution that unnatural nucleic acids may make to this field highlighted.

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“…Using them as carriers to directionally coimmobilize multiple enzymes has shown great potential for the precise positioning of enzyme molecules. [10,22,23] Many kinds of literature have reported that various DNA assemblies constructed by DNA origami can accurately position multiple enzymes. [24,25,26] Recently, a DNA tetrahedral scaffold [27] as well as a switchable trident-shaped DNA nanoactuator [28] has been prepared to co-immobilize GOD and HRP.…”

Section: Introductionmentioning

confidence: 99%

Co‐Immobilization of GOD & HRP on Y‐Shaped DNA Scaffold and the Regulation of Inter‐Enzyme Distance

Chu

Han

et al. 2023

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In multienzymes cascade reaction, the inter‐enzyme spacing is supposed to be a factor affecting the cascade activity. Here, a simple and efficient Y‐shaped DNA scaffold is assembled using two partially complementary DNA single strands on magnetic microspheres, which is used to coimmobilize glucose oxidase (GOD) and horseradish peroxidase (HRP). As a result, on poly(vinyl acetate) magnetic microspheres (PVAC), GOD/HRP‐DNA@PVAC multienzyme system is obtained, which can locate GOD and HRP accurately and control the inter‐enzyme distance precisely. The distance between GOD and HRP is regulated by changing the length of DNA strand. It showed that the cascade activity is significantly distance‐dependent. Moreover, the inter‐enzyme spacing is not the closer the better, and too short distance would generate steric hindrance between enzymes. The cascade activity reached the maximum value of 967 U mg−1 at 13.6 nm, which is 3.5 times higher than that of free enzymes. This is ascribed to the formation of substrate channeling.

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Controllable and high‐performance immobilized enzyme reactor: DNA‐directed immobilization of multienzyme in polyamidoamine dendrimer‐functionalized capillaries

Cited by 11 publications

References 52 publications

Overview of in‐capillary enzymatic reactions using capillary electrophoresis

Overview of in‐capillary enzymatic reactions using capillary electrophoresis

Application of Nucleic Acid Frameworks in the Construction of Nanostructures and Cascade Biocatalysts: Recent Progress and Perspective

Co‐Immobilization of GOD & HRP on Y‐Shaped DNA Scaffold and the Regulation of Inter‐Enzyme Distance

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