Dynamic Modelling of DNA Repair Pathway at the Molecular Level: A New Perspective

Lecca, Paola; Ihekwaba, Adaoha E. C.

doi:10.3389/fmolb.2022.878148

Cited by 4 publications

(2 citation statements)

References 108 publications

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“…The overall goal of designing this genetic circuit is to take advantage of the natural process of RBP activity inside the host cell for vRNA degradation. The operation of the proposed genetic circuit for targeted viral RNA degradation will be tested via a combination of mathematical modeling and experimental validation [89,90].…”

Section: Perspectives and Conclusionmentioning

confidence: 99%

A Genetic Circuit Design for Targeted Viral RNA Degradation

Bello,

Popoola,

Okpuzor

et al. 2023

Bioengineering

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Advances in synthetic biology have led to the design of biological parts that can be assembled in different ways to perform specific functions. For example, genetic circuits can be designed to execute specific therapeutic functions, including gene therapy or targeted detection and the destruction of invading viruses. Viral infections are difficult to manage through drug treatment. Due to their high mutation rates and their ability to hijack the host’s ribosomes to make viral proteins, very few therapeutic options are available. One approach to addressing this problem is to disrupt the process of converting viral RNA into proteins, thereby disrupting the mechanism for assembling new viral particles that could infect other cells. This can be done by ensuring precise control over the abundance of viral RNA (vRNA) inside host cells by designing biological circuits to target vRNA for degradation. RNA-binding proteins (RBPs) have become important biological devices in regulating RNA processing. Incorporating naturally upregulated RBPs into a gene circuit could be advantageous because such a circuit could mimic the natural pathway for RNA degradation. This review highlights the process of viral RNA degradation and different approaches to designing genetic circuits. We also provide a customizable template for designing genetic circuits that utilize RBPs as transcription activators for viral RNA degradation, with the overall goal of taking advantage of the natural functions of RBPs in host cells to activate targeted viral RNA degradation.

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Section: Perspectives and Conclusionmentioning

confidence: 99%

A Genetic Circuit Design for Targeted Viral RNA Degradation

Bello,

Popoola,

Okpuzor

et al. 2023

Bioengineering

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“…DNA nanotechnology takes advantage of DNA structures and functions that have not yet been used in the natural world [ 1 , 2 ], which makes DNA not only function as a genetic information carrier [ 3 , 4 , 5 ], but also act as a role of programmable material [ 6 , 7 ]. Owing to the distinct advantages of programmability and predictability, DNA molecules have been used for fabricating two- or three-dimensional nanostructures by a precise sequence design [ 8 , 9 ].…”

Section: Introductionmentioning

confidence: 99%

Active Self-Assembly of Ladder-Shaped DNA Carrier for Drug Delivery

et al. 2023

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With the advent of nanotechnology, DNA molecules have been transformed from solely genetic information carriers to multifunctional materials, showing a tremendous potential for drug delivery and disease diagnosis. In drug delivery systems, DNA is used as a building material to construct drug carriers through a variety of DNA self-assembly methods, which can integrate multiple functions to complete in vivo and in situ tasks. In this study, ladder-shaped drug carriers are developed for drug delivery on the basis of a DNA nanoladder. We first demonstrate the overall structure of the nanoladder, in which a nick is added into each rung of the nanoladder to endow the nanoladder with the ability to incorporate a drug loading site. The structure is designed to counteract the decrement of stability caused by the nick and investigated in different conditions to gain insight into the properties of the nicked DNA nanoladders. As a proof of concept, we fix the biotin in every other nick as a loading site and assemble the protein (streptavidin) on the loading site to demonstrate the feasibility of the drug-carrying function. The protein can be fixed stably and can be extended to different biological and chemical drugs by altering the drug loading site. We believe this design approach will be a novel addition to the toolbox of DNA nanotechnology, and it will be useful for versatile applications such as in bioimaging, biosensing, and targeted therapy.

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