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Autores principales: Terrosu, Salvatore, Nurullina, Liliia, Supantanapong, Nantamon, Pak, Bonnie S, Nguyen, Sierra, Holm, Mikael, Wu, Cheng, Lin, Min, Horne, David, Sachs, Matthew S, Blanchard, Scott C, Yusupov, Marat, Vanderwal, Christopher D
Formato: Artículo científico
Lenguaje:en
Publicado: ACS chemical biology 2025
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Acceso en línea:https://pubmed.ncbi.nlm.nih.gov/40119759/
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author Terrosu, Salvatore
Nurullina, Liliia
Supantanapong, Nantamon
Pak, Bonnie S
Nguyen, Sierra
Holm, Mikael
Wu, Cheng
Lin, Min
Horne, David
Sachs, Matthew S
Blanchard, Scott C
Yusupov, Marat
Vanderwal, Christopher D
author_facet Terrosu, Salvatore
Nurullina, Liliia
Supantanapong, Nantamon
Pak, Bonnie S
Nguyen, Sierra
Holm, Mikael
Wu, Cheng
Lin, Min
Horne, David
Sachs, Matthew S
Blanchard, Scott C
Yusupov, Marat
Vanderwal, Christopher D
Terrosu, Salvatore
Nurullina, Liliia
Supantanapong, Nantamon
Pak, Bonnie S
Nguyen, Sierra
Holm, Mikael
Wu, Cheng
Lin, Min
Horne, David
Sachs, Matthew S
Blanchard, Scott C
Yusupov, Marat
Vanderwal, Christopher D
collection PubMed - marine biology
contents Synthesis of Differentially Halogenated Lissoclimide Analogues To Probe Ribosome E-Site Binding. Terrosu, Salvatore Nurullina, Liliia Supantanapong, Nantamon Pak, Bonnie S Nguyen, Sierra Holm, Mikael Wu, Cheng Lin, Min Horne, David Sachs, Matthew S Blanchard, Scott C Yusupov, Marat Vanderwal, Christopher D Ribosomes Halogenation Humans Diterpenes Binding Sites RNA, Transfer Halogenated natural products from marine sources often demonstrate potent activity against microorganisms and cancer cell lines. During the last three decades, the lissoclimide class of chlorinated labdane diterpenoids has been characterized with respect to structure and cytotoxic activity. Recently, our laboratories have developed different strategies to produce a broad range of naturally occurring lissoclimides and designed synthetic analogues. This work led to the discovery of a novel halogen-π dispersion interaction between the C2 chloride of chlorolissoclimide and guanine residues in the tRNA exit (E) site of the ribosome. In this study, we aimed to synthesize lissoclimide analogues bearing different substituents in place of the chloride to investigate the importance of the halogen identity for binding, translation inhibition, and cytotoxicity. With previous access to the protio and chloro compounds (haterumaimide Q and chlorolissoclimide), we synthesized two more halogenated variants, fluorolissoclimide and bromolissoclimide, as well as a methylated analogue, methyllissoclimide, to complete a panel of chemical probes for functional and structural studies. Using an integrative approach, we explored the effects of these analogues on the eukaryotic translational machinery in vivo and in vitro. X-ray cocrystal structures with the eukaryotic ribosome were solved for each probe molecule, and the effects on ribosomal thermal stability and FRET-derived ribosome binding constants were determined. Together, these data provide a detailed understanding of the different modes of binding of lissoclimides and insight into their relative activities, which vary according to the substitutions that interact with the eukaryote-specific ribosomal protein eL42. Ultimately, we learned that the presence of a lissoclimide C2-halogen atom─offering a potentially stabilizing halogen-π interaction─appears to facilitate or to synergize with a hydrogen-bonding interaction between the C7-hydroxyl group and the backbone of the ribosomal protein eL42, leading to stronger translation inhibition. We therefore conclude that the C2-halogen and C7-hydroxyl groups are critical contributors to potency, and this idea is borne out in the observations of reduced biological activities in the absence of either group.
format Artículo científico
id pubmed_40119759
institution PubMed
language en
publishDate 2025
publisher ACS chemical biology
record_format pubmed
spellingShingle Synthesis of Differentially Halogenated Lissoclimide Analogues To Probe Ribosome E-Site Binding.
Terrosu, Salvatore
Nurullina, Liliia
Supantanapong, Nantamon
Pak, Bonnie S
Nguyen, Sierra
Holm, Mikael
Wu, Cheng
Lin, Min
Horne, David
Sachs, Matthew S
Blanchard, Scott C
Yusupov, Marat
Vanderwal, Christopher D
Ribosomes
Halogenation
Humans
Diterpenes
Binding Sites
RNA, Transfer
Synthesis of Differentially Halogenated Lissoclimide Analogues To Probe Ribosome E-Site Binding. Terrosu, Salvatore Nurullina, Liliia Supantanapong, Nantamon Pak, Bonnie S Nguyen, Sierra Holm, Mikael Wu, Cheng Lin, Min Horne, David Sachs, Matthew S Blanchard, Scott C Yusupov, Marat Vanderwal, Christopher D Ribosomes Halogenation Humans Diterpenes Binding Sites RNA, Transfer Halogenated natural products from marine sources often demonstrate potent activity against microorganisms and cancer cell lines. During the last three decades, the lissoclimide class of chlorinated labdane diterpenoids has been characterized with respect to structure and cytotoxic activity. Recently, our laboratories have developed different strategies to produce a broad range of naturally occurring lissoclimides and designed synthetic analogues. This work led to the discovery of a novel halogen-π dispersion interaction between the C2 chloride of chlorolissoclimide and guanine residues in the tRNA exit (E) site of the ribosome. In this study, we aimed to synthesize lissoclimide analogues bearing different substituents in place of the chloride to investigate the importance of the halogen identity for binding, translation inhibition, and cytotoxicity. With previous access to the protio and chloro compounds (haterumaimide Q and chlorolissoclimide), we synthesized two more halogenated variants, fluorolissoclimide and bromolissoclimide, as well as a methylated analogue, methyllissoclimide, to complete a panel of chemical probes for functional and structural studies. Using an integrative approach, we explored the effects of these analogues on the eukaryotic translational machinery in vivo and in vitro. X-ray cocrystal structures with the eukaryotic ribosome were solved for each probe molecule, and the effects on ribosomal thermal stability and FRET-derived ribosome binding constants were determined. Together, these data provide a detailed understanding of the different modes of binding of lissoclimides and insight into their relative activities, which vary according to the substitutions that interact with the eukaryote-specific ribosomal protein eL42. Ultimately, we learned that the presence of a lissoclimide C2-halogen atom─offering a potentially stabilizing halogen-π interaction─appears to facilitate or to synergize with a hydrogen-bonding interaction between the C7-hydroxyl group and the backbone of the ribosomal protein eL42, leading to stronger translation inhibition. We therefore conclude that the C2-halogen and C7-hydroxyl groups are critical contributors to potency, and this idea is borne out in the observations of reduced biological activities in the absence of either group.
title Synthesis of Differentially Halogenated Lissoclimide Analogues To Probe Ribosome E-Site Binding.
topic Ribosomes
Halogenation
Humans
Diterpenes
Binding Sites
RNA, Transfer
url https://pubmed.ncbi.nlm.nih.gov/40119759/