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1. Enhanced cellular death in liver and breast cancer cells by dual BET/BRPF1 inhibitors.

Author

Cazzanelli, Giulia, Dalle Vedove, Andrea, Sbardellati, Nicolò, Valer, Luca, Caflisch, Amedeo, and Lolli, Graziano

Abstract

The acetylpyrrole scaffold is an acetylated lysine mimic that has been previously explored to develop bromodomain inhibitors. When tested on the hepatoma cell line Huh7 and the breast cancer cell line MDA‐MB‐231, a few compounds in our acetylpyrrole‐thiazole library induced peculiar morphological changes, progressively causing cell death at increasing concentrations. Their evaluation on a panel of human bromodomains revealed concurrent inhibition of BRPF1 and BET bromodomains. To dissect the observed cellular effects, the acetylpyrrole derivatives were compared to JQ1 and GSK6853, chemical probes for the bromodomains of BET and BRPF1, respectively. The appearance of neurite‐like extrusions, accompanied by βIII‐tubulin overexpression, is caused by BET inhibition, with limited effect on cellular viability. Conversely, interference with BRPF1 induces cellular death but not phenotypic alterations. Combined treatment with JQ1 and GSK6853 showed additivity in reducing cellular viability, comparably to the acetylpyrrole‐thiazole‐based BET/BRPF1 inhibitors. In addition, we determined the crystallographic structures of the BRD4 and BRPF1 bromodomains in complex with the acetylpyrrole‐thiazole compounds. The binding modes in the two bromodomains show similar interactions for the acetylpyrrole and different orientations of the moiety that point to the rim of the acetyl‐lysine pocket. [ABSTRACT FROM AUTHOR]

Published
2024
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3. Pliability in the m6A-Binding Region Extends Druggability of YTH Domains

Author

Cazzanelli, Giulia, primary, Dalle Vedove, Andrea, additional, Spagnolli, Giovanni, additional, Terruzzi, Luca, additional, Colasurdo, Enrica, additional, Boldrini, Alberto, additional, Patsilinakos, Alexandros, additional, Sturlese, Mattia, additional, Grottesi, Alessandro, additional, Biasini, Emiliano, additional, Provenzani, Alessandro, additional, Quattrone, Alessandro, additional, and Lolli, Graziano, additional

Published
2024
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5. Reevaluation of bromodomain ligands targeting BAZ2A

Author

Cazzanelli, Giulia, Dalle Vedove, Andrea, Parolin, Eleonora, D'Agostino, Vito Giuseppe, Unzue, Andrea, Nevado, Cristina; https://orcid.org/0000-0002-3297-581X, Caflisch, Amedeo; https://orcid.org/0000-0002-2317-6792, Lolli, Graziano; https://orcid.org/0000-0002-8536-5599, Cazzanelli, Giulia, Dalle Vedove, Andrea, Parolin, Eleonora, D'Agostino, Vito Giuseppe, Unzue, Andrea, Nevado, Cristina; https://orcid.org/0000-0002-3297-581X, Caflisch, Amedeo; https://orcid.org/0000-0002-2317-6792, and Lolli, Graziano; https://orcid.org/0000-0002-8536-5599

Abstract

BAZ2A promotes migration and invasion in prostate cancer. Two chemical probes, the specific BAZ2-ICR, and the BAZ2/BRD9 cross-reactive GSK2801, interfere with the recognition of acetylated lysines in histones by the bromodomains of BAZ2A and of its BAZ2B paralog. The two chemical probes were tested in prostate cancer cell lines with opposite androgen susceptibility. BAZ2-ICR and GSK2801 showed different cellular efficacies in accordance with their unequal selectivity profiles. Concurrent inhibition of BAZ2 and BRD9 did not reproduce the effects observed with GSK2801, indicating possible off-targets for this chemical probe. On the other hand, the single BAZ2 inhibition by BAZ2-ICR did not phenocopy genetic ablation, demonstrating that bromodomain interference is not sufficient to strongly affect BAZ2A functionality and suggesting a PROTAC-based chemical ablation as an alternative optimization strategy and a possible therapeutic approach. In this context, we also present the crystallographic structures of BAZ2A in complex with the above chemical probes. Binding poses of TP-238 and GSK4027, chemical probes for the bromodomain subfamily I, and two ligands of the CBP/EP300 bromodomains identify additional headgroups for the development of BAZ2A ligands.

Published
2023

6. Small-Molecule Ebselen Binds to YTHDF Proteins Interfering with the Recognition of N6-Methyladenosine-Modified RNAs

Author

Micaelli, Mariachiara, primary, Dalle Vedove, Andrea, additional, Cerofolini, Linda, additional, Vigna, Jacopo, additional, Sighel, Denise, additional, Zaccara, Sara, additional, Bonomo, Isabelle, additional, Poulentzas, Georgios, additional, Rosatti, Emanuele Filiberto, additional, Cazzanelli, Giulia, additional, Alunno, Laura, additional, Belli, Romina, additional, Peroni, Daniele, additional, Dassi, Erik, additional, Murakami, Shino, additional, Jaffrey, Samie R., additional, Fragai, Marco, additional, Mancini, Ines, additional, Lolli, Graziano, additional, Quattrone, Alessandro, additional, and Provenzani, Alessandro, additional

Published
2022
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8. Small-Molecule Ebselen Binds to YTHDF Proteins Interfering with the Recognition of N6‑Methyladenosine-Modified RNAs.

Author

Micaelli, Mariachiara, Dalle Vedove, Andrea, Cerofolini, Linda, Vigna, Jacopo, Sighel, Denise, Zaccara, Sara, Bonomo, Isabelle, Poulentzas, Georgios, Rosatti, Emanuele Filiberto, Cazzanelli, Giulia, Alunno, Laura, Belli, Romina, Peroni, Daniele, Dassi, Erik, Murakami, Shino, Jaffrey, Samie R., Fragai, Marco, Mancini, Ines, Lolli, Graziano, and Quattrone, Alessandro

Published
2022
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10. Identification of a BAZ2A Bromodomain Hit Compound by Fragment Joining

Author

Dalle Vedove, Andrea, Cazzanelli, Giulia, Corsi, Jessica, Sedykh, Maria, D’Agostino, Vito Giuseppe, Caflisch, Amedeo; https://orcid.org/0000-0002-2317-6792, Lolli, Graziano; https://orcid.org/0000-0002-8536-5599, Dalle Vedove, Andrea, Cazzanelli, Giulia, Corsi, Jessica, Sedykh, Maria, D’Agostino, Vito Giuseppe, Caflisch, Amedeo; https://orcid.org/0000-0002-2317-6792, and Lolli, Graziano; https://orcid.org/0000-0002-8536-5599

Abstract

The bromodomains of BAZ2A and BAZ2B (bromodomain adjacent to zinc finger domain proteins 2) are among the most hard to drug of the 61 human bromodomains. While little is known about the role of BAZ2B, there is strong evidence for the opportunity of targeting BAZ2A in various cancers. Here, a benzimidazole–triazole fragment that binds to the BAZ2A acetyl lysine pocket was identified by a molecular docking campaign and validated by competitive binding assays and X-ray crystallography. Another ligand was observed in close proximity by soaking experiments using the BAZ2A bromodomain preincubated with the benzimidazole–triazole fragment. The crystal structure of BAZ2A with the two ligands was employed to design a few benzimidazole–triazole derivatives with increased affinity. We also present the engineering of a BAZ2A bromodomain mutant for consistent, high-resolution crystallographic studies.

Published
2021

12. Identification of compounds inhibiting prion replication and toxicity by removing PrPC from the cell surface

Author

Biggi, Silvia, primary, Pancher, Michael, additional, Stincardini, Claudia, additional, Luotti, Silvia, additional, Massignan, Tania, additional, Dalle Vedove, Andrea, additional, Astolfi, Andrea, additional, Gatto, Pamela, additional, Lolli, Graziano, additional, Barreca, Maria Letizia, additional, Bonetto, Valentina, additional, Adami, Valentina, additional, and Biasini, Emiliano, additional

Published
2019
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13. Structure-Based Virtual Screening Allows the Identification of Efficient Modulators of E-Cadherin-Mediated Cell–Cell Adhesion

Author

Dalle Vedove, Andrea, primary, Falchi, Federico, additional, Donini, Stefano, additional, Dobric, Aurelie, additional, Germain, Sebastien, additional, Di Martino, Giovanni Paolo, additional, Prosdocimi, Tommaso, additional, Vettraino, Chiara, additional, Torretta, Archimede, additional, Cavalli, Andrea, additional, Rigot, Veronique, additional, André, Frederic, additional, and Parisini, Emilio, additional

Published
2019
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14. Моделирование методом молекулярной динамики для анализа структуры и функций ферментов Amadoriase

Author

Rigoldi, Federica, Spero, Ludovica, Dalle Vedove, Andrea, Redaelli, Alberto, Parisini, Emilio, Gautieri, Alfonso, and This work has been supported by and the H2020 EU Project AMMODIT – Approximation Methods for Molecular Modelling and Diagnosis Tools, Project ID 645672. This work has been partially supported by Fondazione Cariplo, grant no. 2016-0481

Subjects
Information technology, system analysis and guidance, Fructosyl amino acid oxidase, Amadoriases, Deglycating enzymes, Molecular dynamics simulation, Enzyme specificity, Binding interactions, HbA1c monitoring, Diabetes monitoring, Glycated haemoglobin, Оксидаза фруктозиламінокислоти, Амадоріази, Дегліковані ферменти, Моделювання методом молекулярної динаміки, Специфічність ферменту, Зв’язувальні взаємодії, Моніторинг HbA1c, Моніторинг діабету, Глікований гемоглобін, Оксидаза фруктозиламинокислоты, Амадориазы, Дегликированные ферменты, Моделирование методом молекулярной динамики, Специфичность фермента, Связывающие взаимодействия, Мониторинг HbA1c, Мониторинг диабета, Гликированный гемоглобин
Abstract

Background. Enzymatic assays based on Fructosyl Amino Acid Oxidases (FAOX) represent a potential, rapid and economical strategy to measure glycated hemoglobin (HbA1c), which is in turn a reliable method to monitor the insurgence and the development of diabetes mellitus. However, the engineering of naturally occurring FAOX to specifically recognize fructosyl-valine (the glycated N-terminal residue of HbA1c) has been hindered by the paucity of information on the tridimensional structures and catalytic residues of the different FAOX that exist in nature, and in general on the molecular mechanisms that regulate specificity in this class of enzymes.Objective. In this study, we use molecular dynamics simulations and advanced modeling techniques to investigate five different relevant wild-type FAOX (Amadoriase I, Amadoriase II, PnFPOX, FPOX-E and N1-1-FAOD) in order to elucidate the molecular mechanisms that drive their specificity towards polar and nonpolar substrates. Specifically, we compare these five different FAOX in terms of overall folding, ligand entry tunnel, ligand binding residues and ligand binding energies.Methods. We used a combination of homology modeling and molecular dynamics simulations to provide insights into the structural difference between the five enzymes of the FAOX family.Results. We first predicted the structure of the N1-1-FAOD and PnFPOX enzymes using homology modelling. Then, we used these models and the experimental crystal structures of Amadoriase I, Amadoriase II and FPOX-E to run extensive molecular dynamics simulations in order to compare the structures of these FAOX enzymes and assess their relevant interactions with two relevant ligands, f-val and f-lys.Conclusions. Our work will contribute to future enzyme structure modifications aimed at the rational design of novel biosensors for the monitoring of blood glucose levels., Проблематика. Анализ ферментативной активности, основанный на использовании оксидаз фруктозиламинокислот (FAOX), представляет собой быструю, экономичную и с большим потенциалом стратегию для измерения гликированного гемоглобина (HbA1c), который в свою очередь является надежным маркером для мониторинга возникновения и развития сахарного диабета. Однако разработка естественного FAOX конкретно для распознавания фруктозил-валина (гликированного N-концевого остатка HbA1c) усложнялась недостатком информации о трехмерных структурах и каталитических остатках различных FAOX, которые существуют в природе, и о молекулярных механизмах, которые регулируют специфичность в этом классе ферментов, в общем.Цель исследования. Мы используем моделирование методом молекулярной динамики, а также современные методы моделирования для исследования пяти различных соответствующих FAOX немутантного типа (Amadoriase I, Amadoriase II, PnFPOX, FPOX-E и N1-1-FAOD), чтобы выяснить молекулярные механизмы, которые обуславливают их специфичность к полярным и неполярным субстратам. В частности, мы сравниваем пять FAOX с точки зрения общей складчатости, входного туннеля лиганда, лигандсвязывающих остатков и энергий связи лигандов.Методика реализации. Мы использовали гомологичное моделирование в сочетании с моделированием методом молекулярной динамики, чтобы дать представление о структурной разнице между пятью ферментами семейства FAOX.Результаты исследований. Сначала мы спрогнозировали структуру ферментов N1-1-FAOD и PnFPOX с использованием гомологичного моделирования. Затем мы использовали модели и экспериментальные кристаллические структуры Amadoriase I, Amadoriase II и FPOX-E для обширного молекулярно-динамического моделирования, чтобы сравнить структуры этих ферментов FAOX и оценить их соответствующие взаимосвязи с лигандами f-val и f-lys.Выводы. Наша работа будет использоваться для будущих модификаций структуры ферментов с целью рационального проектирования новых биосенсоров для контроля уровня глюкозы в крови., Проблематика. Аналіз ферментативної активності, що базується на використанні оксидаз фруктозиламінокислот (FAOX), являє собою швидку, економічну і з великим потенціалом стратегію для вимірювання глікованого гемоглобіну (HbA1c), який своєю чергою є надійним маркером для моніторингу виникнення і розвитку цукрового діабету. Однак розробка природного FAOX конкретно для розпізнавання фруктозил-валіну (глікованого N-кінцевого залишку HbA1c) ускладнювалася нестачею інформації про тривимірні структури і каталітичні залишки різних FAOX, які існують у природі, і про молекулярні механізми, які регулюють специфічність у цьому класі ферментів, загалом.Мета дослідження. Ми використовуємо моделювання методом молекулярної динаміки, а також сучасні методи моделювання для дослідження п’яти різних відповідних FAOX немутантного типу (Amadoriase I, Amadoriase II, PnFPOX, FPOX-E і N1-1-FAOD), щоб з’ясувати молекулярні механізми, які обумовлюють їх специфічність до полярних і неполярних субстратів. Зокрема, ми порівнюємо п’ять FAOX з точки зору загальної складчастості, вхідного тунелю ліганду, лігандзв’язувальних залишків і енергій зв’язку лігандів.Методика реалізації. Ми використовували гомологічне моделювання в поєднанні з моделюванням методом молекулярної динаміки, щоб дати уявлення про структурну різниці між п’ятьма ферментами родини FAOX.Результати дослідження. Спочатку ми спрогнозували структуру ферментів N1-1-FAOD і PnFPOX з використанням гомологічного моделювання. Потім ми використовували моделі та експериментальні кристалічні структури Amadoriase I, Amadoriase II і FPOX-E для обширного молекулярно-динамічного моделювання, щоб порівняти структури цих ферментів FAOX і оцінити їх відповідні взаємозв’язки з лігандами f-val і f-lys.Висновки. Наша робота буде використовуватись для майбутніх модифікацій структури ферментів з метою раціонального проектування нових біосенсорів для контролю рівня глюкози в крові.

Published
2017

15. Biochemical and cellular mechanism of protein kinase CK2 inhibition by deceptive curcumin.

Author

Cozza, Giorgio, Zonta, Francesca, Dalle Vedove, Andrea, Venerando, Andrea, Dall'Acqua, Stefano, Battistutta, Roberto, Ruzzene, Maria, and Lolli, Graziano

Subjects
PROTEIN kinase CK2, FERULIC acid, CURCUMIN, PROTEIN crystallography, CELL death inhibition
Abstract

Protein kinase CK2 is an antiapoptotic cancer‐sustaining protein. Curcumin, reported previously as a CK2 inhibitor, is too bulky to be accommodated in the CK2 active site and rapidly degrades in solution generating various ATP‐mimetic inhibitors; with a detailed comparative analysis, by means of both protein crystallography and enzymatic inhibition, ferulic acid was identified as the principal curcumin degradation product responsible for CK2 inhibition. The other curcumin derivatives vanillin, feruloylmethane and coniferyl aldehyde are weaker CK2 inhibitors. The high instability of curcumin in standard buffered solutions flags this compound, which is included in many commercial libraries, as a possible source of misleading interpretations, as was the case for CK2. Ferulic acid does not show any cytotoxicity and any inhibition of cellular CK2, due to its poor cellular permeability. However, curcumin acts as a prodrug in the cellular context, by generating its degradation products inside the treated cells, thus rescuing CK2 inhibition and consequently inducing cell death. Through the intracellular release of its degradation products, curcumin is expected to affect various target families; here, we identify the first bromodomain of BRD4 as a new target for those compounds. Database: Structural data are available in the PDB database under the accession numbers 6HOP (CK2α/curcumin), 6HOQ (CK2α/ferulic acid), 6HOR (CK2α/feruloylmethane), 6HOT (CK2α/ferulic aldehyde), 6HOU (CK2α/vanillin) and 6HOV (BRD4/ferulic acid). [ABSTRACT FROM AUTHOR]

Published
2020
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16. Identification of compounds inhibiting prion replication and toxicity by removing PrPC from the cell surface.

Author

Biggi, Silvia, Pancher, Michael, Stincardini, Claudia, Luotti, Silvia, Massignan, Tania, Dalle Vedove, Andrea, Astolfi, Andrea, Gatto, Pamela, Lolli, Graziano, Barreca, Maria Letizia, Bonetto, Valentina, Adami, Valentina, and Biasini, Emiliano

Subjects
CELL membranes, PRIONS, BOVINE spongiform encephalopathy, PRION diseases, SCRAPIE, CHEMICAL libraries, CELL culture
Abstract

The vast majority of therapeutic approaches tested so far for prion diseases, transmissible neurodegenerative disorders of human and animals, tackled PrPSc, the aggregated and infectious isoform of the cellular prion protein (PrPC), with largely unsuccessful results. Conversely, targeting PrPC expression, stability or cell surface localization are poorly explored strategies. We recently characterized the mode of action of chlorpromazine, an anti‐psychotic drug known to inhibit prion replication and toxicity by inducing the re‐localization of PrPC from the plasma membrane. Unfortunately, chlorpromazine possesses pharmacokinetic properties unsuitable for chronic use in vivo, namely low specificity and high toxicity. Here, we employed HEK293 cells stably expressing EGFP‐PrP to carry out a semi‐automated high content screening (HCS) of a chemical library directed at identifying non‐cytotoxic molecules capable of specifically relocalizing PrPC from the plasma membrane as well as inhibiting prion replication in N2a cell cultures. We identified four candidate hits inducing a significant reduction in cell surface PrPC, one of which also inhibited prion propagation and toxicity in cell cultures in a strain‐independent fashion. This study defines a new screening method and novel anti‐prion compounds supporting the notion that removing PrPC from the cell surface could represent a viable therapeutic strategy for prion diseases. [ABSTRACT FROM AUTHOR]

Published
2020
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17. Tracking Fluorescent Polyoxometalates within Cells

Author

Modugno, Gloria, primary, Fabbretti, Elsa, additional, Dalle Vedove, Andrea, additional, Da Ros, Tatiana, additional, Maccato, Chiara, additional, Hosseini, Hadigheh Sadat, additional, Bonchio, Marcella, additional, and Carraro, Mauro, additional

Published
2018
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19. Amadoriase engineered enzyme for protein deglycation

Author

Rigoldi, Federica, Dalle Vedove, Andrea, Vesentini, Simone, Parisini, Emilio, and Gautieri, Alfonso

Abstract

Introduction: The progressive accumulation of Advanced Glycation End-product (AGEs) in the human body leads to several deleterious consequences, which involve tissues stiffening and pathologies such as aterosclerosis, nephropathy, retinopathy and Alzheimer’s disease. Nowadays there are no effective therapies against AGEs build-up, although a promising strategy is represented by deglycating enzymes (FAOXs), which are however inactive towards entire proteins due to their buried active site. Aim: We developed a rational in silico design strategy in order to engineer a novel FAOX mutant with a wider active pocket tunnel Material and methods: We performed a preliminary extensive computational investigation of the most studied FAOXs to individuate the best candidate for mutagenesis1. The selected wild-type enzyme (Amadoriase I) was then further characterized with crystallography, molecular dynamics simulations and enzymatic assays2. Finally, a computational library of enzyme mutants was created and then screened using several in silico techniques to select the best candidate. The experimental validation concerning folding and activity of the candidate enzyme are currently on-going. Conclusions: We provided the design of a novel FAOX that can represent a step forward towards a protein deglycation strategy. Furthermore, this work provides novel computational tools for enzyme design., Journal of International Society of Antioxidants in Nutrition & Health, Vol 3, No 2 (2016): Journal of ISANH Volume 3: Special Issue for Maillard Reaction & Glycation

Published
2016
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22. Crystal structure of the deglycating enzyme Amadoriase I in its free form and substrate-bound complex

Author

Rigoldi, Federica, Gautieri, Alfonso, DALLE VEDOVE, Andrea, Lucarelli, Anna Paola, Vesentini, Simone, and Parisini, Emilio

Subjects
Models, Molecular, Glycation, Enzyme structure, Protein Conformation, Aspergillus fumigatus, Lysine, Molecular modeling, Deglycating enzyme, Protein crystallization, Biochemistry, Structural Biology, Molecular Biology, Crystallography, X-Ray, Substrate Specificity, Thermodynamics, Amino Acid Oxidoreductases, Amino Acid Sequence, Sequence Alignment, Protein Binding
Abstract

Amadoriases, also known as fructosyl amine oxidases (FAOX), are enzymes that catalyze the de-glycosylation of fructosyl amino acids. As such, they are excellent candidates for the development of enzyme-based diagnostic and therapeutic tools against age- and diabetes-induced protein glycation. However, mostly because of the lack of a complete structural characterization of the different members of the family, the molecular bases of their substrate specificity have yet to be fully understood. The high resolution crystal structures of the free and the substrate-bound form of Amadoriase I shown herein allow for the identification of key structural features that account for the diverse substrate specificity shown by this class of enzymes. This is of particular importance in the context of the rather limited and partially incomplete structural information that has so far been available in the literature on the members of the FAOX family. Moreover, using molecular dynamics simulations, we describe the tunnel conformation and the free energy profile experienced by the ligand in going from bulk water to the catalytic cavity, showing the presence of four gating helices/loops, followed by an "L-shaped" narrow cavity. In summary, the tridimensional architecture of Amadoriase I presented herein provides a reference structural framework for the design of novel enzymes for diabetes monitoring and protein deglycation. Proteins 2016; 84:744-758. © 2016 Wiley Periodicals, Inc.

Published
2015

24. Discovery of Inhibitors of Four Bromodomains by Fragment-Anchored Ligand Docking

Author

Marchand, Jean-Rémy, Dalle Vedove, Andrea, Lolli, Graziano, and Caflisch, Amedeo

Abstract

The high-throughput docking protocol called ALTA-VS (anchor-based library tailoring approach for virtual screening) was developed in 2005 for the efficient in silico screening of large libraries of compounds by preselection of only those molecules that have optimal fragments (anchors) for the protein target. Here we present an updated version of ALTA-VS with a broader range of potential applications. The evaluation of binding energy makes use of a classical force field with implicit solvent in the continuum dielectric approximation. In about 2 days per protein target on a 96-core compute cluster (equipped with Xeon E3-1280 quad core processors at 2.5 GHz), the screening of a library of nearly 77 000 diverse molecules with the updated ALTA-VS protocol has resulted in the identification of 19, 3, 3, and 2 μM inhibitors of the human bromodomains ATAD2, BAZ2B, BRD4(1), and CREBBP, respectively. The success ratio (i.e., number of actives in a competition binding assay in vitro divided by the number of compounds tested) ranges from 8% to 13% in dose–response measurements. The poses predicted by fragment-based docking for the three ligands of the BAZ2B bromodomain were confirmed by protein X-ray crystallography.

Published
2024
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25. Cover Image, Volume 84, Issue 6

Author

Rigoldi, Federica, primary, Gautieri, Alfonso, additional, Dalle Vedove, Andrea, additional, Lucarelli, Anna Paola, additional, Vesentini, Simone, additional, and Parisini, Emilio, additional

Published
2016
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31. Tracking Fluorescent Polyoxometalates within Cells

Author

Marcella Bonchio, Chiara Maccato, Andrea Dalle Vedove, Elsa Fabbretti, Hadigheh Sadat Hosseini, Tatiana Da Ros, Mauro Carraro, Gloria Modugno, Modugno, Gloria, Fabbretti, Elsa, Dalle Vedove, Andrea, Da Ros, Tatiana, Maccato, Chiara, Hosseini, Hadigheh Sadat, Bonchio, Marcella, and Carraro, Mauro

Subjects
010405 organic chemistry, Chemistry, Hybrid polyoxometalates, Chirality, Fluorescence, Drug delivery, Inorganic Chemistry, Nanotechnology, 010402 general chemistry, Tracking (particle physics), 01 natural sciences, 0104 chemical sciences, Hybrid polyoxometalate
Abstract

Novel organic‐inorganic polyoxometalates (POMs) decorated with covalent fluorescent tags have been designed for cell internalization. Their localization within model HEK cells is readily accomplished by confocal fluorescence microscopy. While cell internalization is dictated by the formation of the amphiphilic POM‐based nanostructures, their cytoplasmic‐nuclear trafficking appears to be regulated by a subtle interplay of the organic‐inorganic domains of the nanoassemblies which, in turn, impacts their dynamic behavior and capability to interact with cell membranes.

Published
2018

32. Enhanced cellular death in liver and breast cancer cells by dual BET/BRPF1 inhibitors.

Author

Cazzanelli G, Dalle Vedove A, Sbardellati N, Valer L, Caflisch A, and Lolli G

Subjects
Humans, Cell Line, Tumor, Azepines pharmacology, Azepines chemistry, Transcription Factors antagonists & inhibitors, Transcription Factors metabolism, Transcription Factors chemistry, Liver Neoplasms drug therapy, Liver Neoplasms pathology, Liver Neoplasms metabolism, Cell Cycle Proteins antagonists & inhibitors, Cell Cycle Proteins metabolism, Cell Cycle Proteins chemistry, Female, Cell Death drug effects, Thiazoles pharmacology, Thiazoles chemistry, Pyrroles pharmacology, Pyrroles chemistry, Bromodomain Containing Proteins, Breast Neoplasms drug therapy, Breast Neoplasms pathology, Breast Neoplasms metabolism, Triazoles pharmacology, Triazoles chemistry
Abstract

The acetylpyrrole scaffold is an acetylated lysine mimic that has been previously explored to develop bromodomain inhibitors. When tested on the hepatoma cell line Huh7 and the breast cancer cell line MDA-MB-231, a few compounds in our acetylpyrrole-thiazole library induced peculiar morphological changes, progressively causing cell death at increasing concentrations. Their evaluation on a panel of human bromodomains revealed concurrent inhibition of BRPF1 and BET bromodomains. To dissect the observed cellular effects, the acetylpyrrole derivatives were compared to JQ1 and GSK6853, chemical probes for the bromodomains of BET and BRPF1, respectively. The appearance of neurite-like extrusions, accompanied by βIII-tubulin overexpression, is caused by BET inhibition, with limited effect on cellular viability. Conversely, interference with BRPF1 induces cellular death but not phenotypic alterations. Combined treatment with JQ1 and GSK6853 showed additivity in reducing cellular viability, comparably to the acetylpyrrole-thiazole-based BET/BRPF1 inhibitors. In addition, we determined the crystallographic structures of the BRD4 and BRPF1 bromodomains in complex with the acetylpyrrole-thiazole compounds. The binding modes in the two bromodomains show similar interactions for the acetylpyrrole and different orientations of the moiety that point to the rim of the acetyl-lysine pocket., (© 2024 The Author(s). Protein Science published by Wiley Periodicals LLC on behalf of TheProtein Society.)

Published
2024
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33. Pliability in the m 6 A-Binding Region Extends Druggability of YTH Domains.

Author

Cazzanelli G, Dalle Vedove A, Spagnolli G, Terruzzi L, Colasurdo E, Boldrini A, Patsilinakos A, Sturlese M, Grottesi A, Biasini E, Provenzani A, Quattrone A, and Lolli G

Subjects
Pliability, RNA, Messenger chemistry, RNA, Messenger metabolism, Molecular Conformation, RNA-Binding Proteins chemistry, RNA-Binding Proteins genetics, RNA-Binding Proteins metabolism
Abstract

Epitranscriptomic mRNA modifications affect gene expression, with their altered balance detected in various cancers. YTHDF proteins contain the YTH reader domain recognizing the m 6 A mark on mRNA and represent valuable drug targets. Crystallographic structures have been determined for all three family members; however, discrepancies are present in the organization of the m 6 A-binding pocket. Here, we present new crystallographic structures of the YTH domain of YTHDF1, accompanied by computational studies, showing that this domain can exist in different stable conformations separated by a significant energetic barrier. During the transition, additional conformations are explored, with peculiar druggable pockets appearing and offering new opportunities for the design of YTH-interfering small molecules.

Published
2024
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34. Small-Molecule Ebselen Binds to YTHDF Proteins Interfering with the Recognition of N 6 -Methyladenosine-Modified RNAs.

Author

Micaelli M, Dalle Vedove A, Cerofolini L, Vigna J, Sighel D, Zaccara S, Bonomo I, Poulentzas G, Rosatti EF, Cazzanelli G, Alunno L, Belli R, Peroni D, Dassi E, Murakami S, Jaffrey SR, Fragai M, Mancini I, Lolli G, Quattrone A, and Provenzani A

Abstract

YTHDF proteins bind the N 6 -methyladenosine (m6A)-modified mRNAs, influencing their processing, stability, and translation. Therefore, the members of this protein family play crucial roles in gene regulation and several physiological and pathophysiological conditions. YTHDF proteins contain a hydrophobic pocket that accommodates the m6A embedded in the RRACH consensus sequence on mRNAs. We exploited the presence of this cage to set up an m6A-competitive assay and performed a high-throughput screen aimed at identifying ligands binding in the m6A pocket. We report the organoselenium compound ebselen as the first-in-class inhibitor of the YTHDF m6A-binding domain. Ebselen, whose interaction with YTHDF proteins was validated via orthogonal assays, cannot discriminate between the binding domains of the three YTHDF paralogs but can disrupt the interaction of the YTHDF m6A domain with the m6A-decorated mRNA targets. X-ray, mass spectrometry, and NMR studies indicate that in YTHDF1 ebselen binds close to the m6A cage, covalently to the Cys412 cysteine, or interacts reversibly depending on the reducing environment. We also showed that ebselen engages YTHDF proteins within cells, interfering with their mRNA binding. Finally, we produced a series of ebselen structural analogs that can interact with the YTHDF m6A domain, proving that ebselen expansion is amenable for developing new inhibitors. Our work demonstrates the feasibility of drugging the YTH domain in YTHDF proteins and opens new avenues for the development of disruptors of m6A recognition., Competing Interests: The authors declare the following competing financial interest(s): The authors declare are filed a patent about ebselen analogues. S.R.J. is a scientific advisor and owns stock in 858 Therapeutics., (© 2022 The Authors. Published by American Chemical Society.)

Published
2022
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35. Identification of compounds inhibiting prion replication and toxicity by removing PrP C from the cell surface.

Author

Biggi S, Pancher M, Stincardini C, Luotti S, Massignan T, Dalle Vedove A, Astolfi A, Gatto P, Lolli G, Barreca ML, Bonetto V, Adami V, and Biasini E

Subjects
Animals, Casein Kinase II antagonists & inhibitors, Cell Line, Tumor, Cell Survival drug effects, Drug Evaluation, Preclinical methods, Fluorescent Dyes, Gene Expression, Green Fluorescent Proteins analysis, Green Fluorescent Proteins genetics, HEK293 Cells, Harmaline analogs & derivatives, Harmaline pharmacology, Hematoxylin analogs & derivatives, Hematoxylin pharmacology, Humans, Mice, Neuroblastoma, PrPC Proteins genetics, Prions biosynthesis, Prions toxicity, Quinacrine pharmacology, Tacrolimus pharmacology, Cell Membrane chemistry, PrPC Proteins analysis, Prions antagonists & inhibitors
Abstract

The vast majority of therapeutic approaches tested so far for prion diseases, transmissible neurodegenerative disorders of human and animals, tackled PrP Sc , the aggregated and infectious isoform of the cellular prion protein (PrP C ), with largely unsuccessful results. Conversely, targeting PrP C expression, stability or cell surface localization are poorly explored strategies. We recently characterized the mode of action of chlorpromazine, an anti-psychotic drug known to inhibit prion replication and toxicity by inducing the re-localization of PrP C from the plasma membrane. Unfortunately, chlorpromazine possesses pharmacokinetic properties unsuitable for chronic use in vivo, namely low specificity and high toxicity. Here, we employed HEK293 cells stably expressing EGFP-PrP to carry out a semi-automated high content screening (HCS) of a chemical library directed at identifying non-cytotoxic molecules capable of specifically relocalizing PrP C from the plasma membrane as well as inhibiting prion replication in N2a cell cultures. We identified four candidate hits inducing a significant reduction in cell surface PrP C , one of which also inhibited prion propagation and toxicity in cell cultures in a strain-independent fashion. This study defines a new screening method and novel anti-prion compounds supporting the notion that removing PrP C from the cell surface could represent a viable therapeutic strategy for prion diseases., (© 2019 International Society for Neurochemistry.)

Published
2020
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