Proximity-Induced Nucleic Acid Degrader (PINAD) approach to targeted RNA degradation using small molecules

Sigitas Mikutis; Maria Rebelo; Eliza Yankova; Muxin Gu; Cong Tang; Ana R. Coelho; Mo Yang; Madoka E. Hazemi; Marta Pires de Miranda; Maria Eleftheriou; Max Robertson; George S. Vassiliou; David J. Adams; J. Pedro Simas; Francisco Corzana; John S. Schneekloth; Konstantinos Tzelepis; Gonçalo J.L. Bernardes

doi:10.1021/acscentsci.3c00015

Proximity-Induced Nucleic Acid Degrader (PINAD) approach to targeted RNA degradation using small molecules

Sigitas Mikutis^*, Maria Rebelo, Eliza Yankova, Muxin Gu, Cong Tang, Ana R. Coelho, Mo Yang, Madoka E. Hazemi, Marta Pires de Miranda, Maria Eleftheriou, Max Robertson, George S. Vassiliou, David J. Adams, J. Pedro Simas, Francisco Corzana, John S. Schneekloth, Konstantinos Tzelepis^*, Gonçalo J.L. Bernardes^*

^*Corresponding author for this work

Research output: Contribution to journal › Article › peer-review

37 Citations (Scopus)

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Abstract

Nature has evolved intricate machinery to target and degrade RNA, and some of these molecular mechanisms can be adapted for therapeutic use. Small interfering RNAs and RNase H-inducing oligonucleotides have yielded therapeutic agents against diseases that cannot be tackled using protein-centered approaches. Because these therapeutic agents are nucleic acid-based, they have several inherent drawbacks which include poor cellular uptake and stability. Here we report a new approach to target and degrade RNA using small molecules, proximity-induced nucleic acid degrader (PINAD). We have utilized this strategy to design two families of RNA degraders which target two different RNA structures within the genome of SARS-CoV-2: G-quadruplexes and the betacoronaviral pseudoknot. We demonstrate that these novel molecules degrade their targets using in vitro, in cellulo, and in vivo SARS-CoV-2 infection models. Our strategy allows any RNA binding small molecule to be converted into a degrader, empowering RNA binders that are not potent enough to exert a phenotypic effect on their own. PINAD raises the possibility of targeting and destroying any disease-related RNA species, which can greatly expand the space of druggable targets and diseases.

Original language	English
Pages (from-to)	892-904
Number of pages	13
Journal	ACS Central Science
Volume	9
Issue number	5
DOIs	https://doi.org/10.1021/acscentsci.3c00015
Publication status	Published - 24 May 2023

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Mikutis, S., Rebelo, M., Yankova, E., Gu, M., Tang, C., Coelho, A. R., Yang, M., Hazemi, M. E., Miranda, M. P. D., Eleftheriou, M., Robertson, M., Vassiliou, G. S., Adams, D. J., Simas, J. P., Corzana, F., Schneekloth, J. S., Tzelepis, K., & Bernardes, G. J. L. (2023). Proximity-Induced Nucleic Acid Degrader (PINAD) approach to targeted RNA degradation using small molecules. ACS Central Science, 9(5), 892-904. https://doi.org/10.1021/acscentsci.3c00015

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title = "Proximity-Induced Nucleic Acid Degrader (PINAD) approach to targeted RNA degradation using small molecules",

abstract = "Nature has evolved intricate machinery to target and degrade RNA, and some of these molecular mechanisms can be adapted for therapeutic use. Small interfering RNAs and RNase H-inducing oligonucleotides have yielded therapeutic agents against diseases that cannot be tackled using protein-centered approaches. Because these therapeutic agents are nucleic acid-based, they have several inherent drawbacks which include poor cellular uptake and stability. Here we report a new approach to target and degrade RNA using small molecules, proximity-induced nucleic acid degrader (PINAD). We have utilized this strategy to design two families of RNA degraders which target two different RNA structures within the genome of SARS-CoV-2: G-quadruplexes and the betacoronaviral pseudoknot. We demonstrate that these novel molecules degrade their targets using in vitro, in cellulo, and in vivo SARS-CoV-2 infection models. Our strategy allows any RNA binding small molecule to be converted into a degrader, empowering RNA binders that are not potent enough to exert a phenotypic effect on their own. PINAD raises the possibility of targeting and destroying any disease-related RNA species, which can greatly expand the space of druggable targets and diseases.",

author = "Sigitas Mikutis and Maria Rebelo and Eliza Yankova and Muxin Gu and Cong Tang and Coelho, \{Ana R.\} and Mo Yang and Hazemi, \{Madoka E.\} and Miranda, \{Marta Pires de\} and Maria Eleftheriou and Max Robertson and Vassiliou, \{George S.\} and Adams, \{David J.\} and Simas, \{J. Pedro\} and Francisco Corzana and Schneekloth, \{John S.\} and Konstantinos Tzelepis and Bernardes, \{Gon{\c c}alo J.L.\}",

year = "2023",

month = may,

day = "24",

doi = "10.1021/acscentsci.3c00015",

language = "English",

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Mikutis, S, Rebelo, M, Yankova, E, Gu, M, Tang, C, Coelho, AR, Yang, M, Hazemi, ME, Miranda, MPD, Eleftheriou, M, Robertson, M, Vassiliou, GS, Adams, DJ, Simas, JP, Corzana, F, Schneekloth, JS, Tzelepis, K & Bernardes, GJL 2023, 'Proximity-Induced Nucleic Acid Degrader (PINAD) approach to targeted RNA degradation using small molecules', ACS Central Science, vol. 9, no. 5, pp. 892-904. https://doi.org/10.1021/acscentsci.3c00015

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T1 - Proximity-Induced Nucleic Acid Degrader (PINAD) approach to targeted RNA degradation using small molecules

AU - Mikutis, Sigitas

AU - Rebelo, Maria

AU - Yankova, Eliza

AU - Gu, Muxin

AU - Tang, Cong

AU - Coelho, Ana R.

AU - Yang, Mo

AU - Hazemi, Madoka E.

AU - Miranda, Marta Pires de

AU - Eleftheriou, Maria

AU - Robertson, Max

AU - Vassiliou, George S.

AU - Adams, David J.

AU - Simas, J. Pedro

AU - Corzana, Francisco

AU - Schneekloth, John S.

AU - Tzelepis, Konstantinos

AU - Bernardes, Gonçalo J.L.

PY - 2023/5/24

Y1 - 2023/5/24

N2 - Nature has evolved intricate machinery to target and degrade RNA, and some of these molecular mechanisms can be adapted for therapeutic use. Small interfering RNAs and RNase H-inducing oligonucleotides have yielded therapeutic agents against diseases that cannot be tackled using protein-centered approaches. Because these therapeutic agents are nucleic acid-based, they have several inherent drawbacks which include poor cellular uptake and stability. Here we report a new approach to target and degrade RNA using small molecules, proximity-induced nucleic acid degrader (PINAD). We have utilized this strategy to design two families of RNA degraders which target two different RNA structures within the genome of SARS-CoV-2: G-quadruplexes and the betacoronaviral pseudoknot. We demonstrate that these novel molecules degrade their targets using in vitro, in cellulo, and in vivo SARS-CoV-2 infection models. Our strategy allows any RNA binding small molecule to be converted into a degrader, empowering RNA binders that are not potent enough to exert a phenotypic effect on their own. PINAD raises the possibility of targeting and destroying any disease-related RNA species, which can greatly expand the space of druggable targets and diseases.

AB - Nature has evolved intricate machinery to target and degrade RNA, and some of these molecular mechanisms can be adapted for therapeutic use. Small interfering RNAs and RNase H-inducing oligonucleotides have yielded therapeutic agents against diseases that cannot be tackled using protein-centered approaches. Because these therapeutic agents are nucleic acid-based, they have several inherent drawbacks which include poor cellular uptake and stability. Here we report a new approach to target and degrade RNA using small molecules, proximity-induced nucleic acid degrader (PINAD). We have utilized this strategy to design two families of RNA degraders which target two different RNA structures within the genome of SARS-CoV-2: G-quadruplexes and the betacoronaviral pseudoknot. We demonstrate that these novel molecules degrade their targets using in vitro, in cellulo, and in vivo SARS-CoV-2 infection models. Our strategy allows any RNA binding small molecule to be converted into a degrader, empowering RNA binders that are not potent enough to exert a phenotypic effect on their own. PINAD raises the possibility of targeting and destroying any disease-related RNA species, which can greatly expand the space of druggable targets and diseases.

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DO - 10.1021/acscentsci.3c00015

M3 - Article

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SN - 2374-7943

VL - 9

SP - 892

EP - 904

JO - ACS Central Science

JF - ACS Central Science

IS - 5

ER -

Proximity-Induced Nucleic Acid Degrader (PINAD) approach to targeted RNA degradation using small molecules

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