Your search keyword '"Cutruzzolà, Francesca"' showing total 11 results

1. Targeting the Grb2 cSH3 domain: Design, synthesis and biological evaluation of the first series of modulators

Author

Bufano, Marianna, Puxeddu, Michela, Nalli, Marianna, La Regina, Giuseppe, Toto, Angelo, Liberati, Francesca Romana, Paone, Alessio, Cutruzzolà, Francesca, Masci, Domiziana, Bigogno, Chiara, Dondio, Giulio, Silvestri, Romano, Gianni, Stefano, Coluccia, Antonio, Masci, Domiziana (ORCID:0000-0002-5615-5111), Bufano, Marianna, Puxeddu, Michela, Nalli, Marianna, La Regina, Giuseppe, Toto, Angelo, Liberati, Francesca Romana, Paone, Alessio, Cutruzzolà, Francesca, Masci, Domiziana, Bigogno, Chiara, Dondio, Giulio, Silvestri, Romano, Gianni, Stefano, Coluccia, Antonio, and Masci, Domiziana (ORCID:0000-0002-5615-5111)

Abstract

Growth factor receptor bound protein 2 (Grb2) is an adaptor protein featured by a nSH3-SH2-cSH3 domains. Grb2 finely regulates important cellular pathways such as growth, proliferation and metabolism and a minor lapse of this tight control may totally change the entire pathway to the oncogenic. Indeed, Grb2 is found overexpressed in many tumours type. Consequently, Grb2 is an attractive therapeutic target for the development of new anticancer drug. Herein, we reported the synthesis and the biological evaluation of a series of Grb2 inhibitors, developed starting from a hit-compound already reported by this research unit. The newly synthesized compounds were evaluated by kinetic binding experiments, and the most promising derivatives were assayed in a short panel of cancer cells. Five of the newly synthesized derivatives proved to be able to bind the targeted protein with valuable inhibitory concentration in one-digit micromolar concentration. The most active compound of this series, derivative 12, showed an inhibitory concentration of about 6 mu M for glioblastoma and ovarian cancer cells, and an IC50 of 1.67 for lung cancer cell. For derivative 12, the metabolic stability and the ROS production was also evaluated. The biological data together with the docking studies led to rationalize an early structure activity relationship.

Published

2023

2. Anticancer Activity of (S)-5-Chloro-3-((3,5-dimethylphenyl)sulfonyl)-N-(1-oxo-1-((pyridin-4-ylmethyl)amino)propan-2-yl)-1H-indole-2-carboxamide (RS4690), a New Dishevelled 1 Inhibitor

Author

Coluccia, Antonio, Bufano, Marianna, La Regina, Giuseppe, Puxeddu, Michela, Toto, Angelo, Paone, Alessio, Bouzidi, Amani, Musto, Giorgia, Badolati, Nadia, Orlando, Viviana, Biagioni, Stefano, Masci, Domiziana, Cantatore, Chiara, Cirilli, Roberto, Cutruzzolà, Francesca, Gianni, Stefano, Stornaiuolo, Mariano, Silvestri, Romano, Masci, Domiziana (ORCID:0000-0002-5615-5111), Coluccia, Antonio, Bufano, Marianna, La Regina, Giuseppe, Puxeddu, Michela, Toto, Angelo, Paone, Alessio, Bouzidi, Amani, Musto, Giorgia, Badolati, Nadia, Orlando, Viviana, Biagioni, Stefano, Masci, Domiziana, Cantatore, Chiara, Cirilli, Roberto, Cutruzzolà, Francesca, Gianni, Stefano, Stornaiuolo, Mariano, Silvestri, Romano, and Masci, Domiziana (ORCID:0000-0002-5615-5111)

Abstract

Simple Summary The WNT/beta-catenin pathway regulates a huge number of cellular functions, and its dysregulation is correlated to the development of cancer. In this work, we focused on the interaction between Dishevelled 1 (DVL1) protein, an important player in this pathway, and its cognate receptor Frizzled via a shared PDZ domain. Computational studies led to the discovery of racemate RS4690 (1) showing selective inhibition of DVL1 binding. After separation of the racemic mixture, enantiomer (S)-1 inhibited DVL1 with an EC50 of 0.49 +/- 0.11 mu M and the growth of HCT116 cells that did not present the APC mutation with an EC50 value 7.1 +/- 0.6 mu M, and caused a high level of ROS production. Compound (S)-1 shows potential as a new therapeutic agent against WNT-dependent colon cancer. Wingless/integrase-11 (WNT)/beta-catenin pathway is a crucial upstream regulator of a huge array of cellular functions. Its dysregulation is correlated to neoplastic cellular transition and cancer proliferation. Members of the Dishevelled (DVL) family of proteins play an important role in the transduction of WNT signaling by contacting its cognate receptor, Frizzled, via a shared PDZ domain. Thus, negative modulators of DVL1 are able to impair the binding to Frizzled receptors, turning off the aberrant activation of the WNT pathway and leading to anti-cancer activity. Through structure-based virtual screening studies, we identified racemic compound RS4690 (1), which showed a promising selective DVL1 binding inhibition with an EC50 of 0.74 +/- 0.08 mu M. Molecular dynamic simulations suggested a different binding mode for the enantiomers. In the in vitro assays, enantiomer (S)-1 showed better inhibition of DVL1 with an EC50 of 0.49 +/- 0.11 mu M compared to the (R)-enantiomer. Compound (S)-1 inhibited the growth of HCT116 cells expressing wild-type APC with an EC50 of 7.1 +/- 0.6 mu M and caused a high level of ROS production. These results highlight (S)-1 as a lead compound for the d

Published

2022

3. Insights into the GTP-dependent allosteric control of c-di-GMP hydrolysis from the crystal structure of PA0575 protein from Pseudomonas aeruginosa

Author

Mantoni, Federico, Paiardini, Alessandro, Brunotti, Paolo, D'Angelo, Cecilia, Cervoni, Laura, Paone, Alessio, Cappellacci, Loredana, Petrelli, Riccardo, Ricciutelli, Massimo, Leoni, Livia, Rampioni, Giordano, Arcovito, Alessandro, Rinaldo, Serena, Cutruzzolà, Francesca, Giardina, Giorgio, Arcovito, Alessandro (ORCID:0000-0002-8384-4844), Mantoni, Federico, Paiardini, Alessandro, Brunotti, Paolo, D'Angelo, Cecilia, Cervoni, Laura, Paone, Alessio, Cappellacci, Loredana, Petrelli, Riccardo, Ricciutelli, Massimo, Leoni, Livia, Rampioni, Giordano, Arcovito, Alessandro, Rinaldo, Serena, Cutruzzolà, Francesca, Giardina, Giorgio, and Arcovito, Alessandro (ORCID:0000-0002-8384-4844)

Abstract

Bis-(3'-5')-cyclic diguanylic acid (c-di-GMP) belongs to the class of cyclic dinucleotides, key carriers of cellular information in prokaryotic and eukaryotic signal transduction pathways. In bacteria, the intracellular levels of c-di-GMP and their complex physiological outputs are dynamically regulated by environmental and internal stimuli, which control the antagonistic activities of diguanylate cyclases (DGCs) and c-di-GMP specific phosphodiesterases (PDEs). Allostery is one of the major modulators of the c-di-GMP-dependent response. Both the c-di-GMP molecule and the proteins interacting with this second messenger are characterized by an extraordinary structural plasticity, which has to be taken into account when defining and possibly predicting c-di-GMP-related processes. Here, we report a structure-function relationship study on the catalytic portion of the PA0575 protein from Pseudomonas aeruginosa, bearing both putative DGC and PDE domains. The kinetic and structural studies indicate that the GGDEF-EAL portion is a GTP-dependent PDE. Moreover, the crystal structure confirms the high degree of conformational flexibility of this module. We combined structural analysis and protein engineering studies to propose the possible molecular mechanism guiding the nucleotide-dependent allosteric control of catalysis; we propose that the role exerted by GTP via the GGDEF domain is to allow the two EAL domains to form a dimer, the species competent to enter PDE catalysis. This article is protected by copyright. All rights reserved.

Published

2018

4. Interactions outside the Boundaries of the Canonical Binding Groove of a PDZ Domain Influence Ligand Binding

Author

Chi, Celestine N., Haq, S. Raza, Rinaldo, Serena, Dogan, Jakob, Cutruzzolà, Francesca, Engström, Åke, Gianni, Stefano, Lundström, Patrik, Jemth, Per, Chi, Celestine N., Haq, S. Raza, Rinaldo, Serena, Dogan, Jakob, Cutruzzolà, Francesca, Engström, Åke, Gianni, Stefano, Lundström, Patrik, and Jemth, Per

Abstract

The postsynaptic density protein-95/discs large/zonula occludens-1 (PDZ) domain is a protein-protein interaction module with a shallow binding groove where protein ligands bind. However, interactions that are not part of this canonical binding groove are likely to modulate peptide binding. We have investigated such interactions beyond the binding groove for PDZ3 from PSD-95 and a peptide derived from the C-terminus of the natural ligand CRIPT. We found via nuclear magnetic resonance experiments that up to eight residues of the peptide ligand interact with the PDZ domain, showing that the interaction surface extends far outside of the binding groove as defined by the crystal structure. PDZ3 contains an extra structural element, a C-terminal helix (α3), which is known to affect affinity. Deletion of this helix resulted in the loss of several intermolecular nuclear Overhauser enhancements from peptide residues outside of the binding pocket, suggesting that α3 forms part of the extra binding surface in wild-type PDZ3. Site-directed mutagenesis, isothermal titration calorimetry, and fluorescence intensity experiments confirmed the importance of both α3 and the N-terminal part of the peptide for the affinity. Our data suggest a general mechanism in which different binding surfaces outside of the PDZ binding groove could provide sites for specific interactions., funding agencies|Swedish Research Council||Lars Hiertas Minne and the Royal Swedish society||Italian Ministero dellIstruzione dellUniversita e della Ricerca, Progetto di Interesse Invecchiamento||Ministero dellIstruzione, Universita e Ricerca of Italy|RBRN07BMCT_007RBFR10LHD1_001|Sapienza University of Rome (Italy)

Published

2012

5. Observation of fast release of NO from ferrous d1 haem allows formulation of a unified reaction mechanism for cytochrome cd1 nitrite reductases

Author

Rinaldo, Serena, Sam, Katerine Ann, Castiglione, Nicoletta, Stelitano, Valentina, Arcovito, Alessandro, Brunori, Maurizio, Allen, James Wa, Ferguson, Stuart J, Cutruzzolà, Francesca, Arcovito, Alessandro (ORCID:0000-0002-8384-4844), Rinaldo, Serena, Sam, Katerine Ann, Castiglione, Nicoletta, Stelitano, Valentina, Arcovito, Alessandro, Brunori, Maurizio, Allen, James Wa, Ferguson, Stuart J, Cutruzzolà, Francesca, and Arcovito, Alessandro (ORCID:0000-0002-8384-4844)

Abstract

Cytochrome cd1 nitrite reductase is a haem-containing enzyme responsible for the reduction of nitrite into nitric oxide (NO), a key step in the anaerobic respiratory process of denitrification. The active site of cytochrome cd1 contains the unique d1 haem cofactor, from which NO must be released. In general, reduced hemes bind NO tightly relative to oxidised hemes. Here we present experimental evidence that the reduced d1 heme of cytochrome cd1 from Paracoccus pantotrophus releases NO rapidly (k=65-200 s-1); this result suggests that NO release is the rate-limiting step of the catalytic cycle (turnover number = 72 s-1). We also demonstrate using a complex of the d1 haem and apomyoglobin, that the rapid dissociation of NO is largely controlled by the d1 haem cofactor itself. We present a reaction mechanism proposed to be applicable to all cytochromes cd1 and conclude that the d1 haem has evolved to have low affinity for NO, as compared to other ferrous haems

Published

2011

6. Intramolecular electron transfer in Pseudomonas aeruginosa cd(1) nitrite reductase:thermodynamics and kinetics

Author

Farver, Ole, Brunori, Maurizio, Cutruzzolà, Francesca, Rinaldo, Serena, Wherland, Scot, Pecht, Israel, Farver, Ole, Brunori, Maurizio, Cutruzzolà, Francesca, Rinaldo, Serena, Wherland, Scot, and Pecht, Israel

Abstract

The cd(1) nitrite reductases, which catalyze the reduction of nitrite to nitric oxide, are homodimers of 60 kDa subunits, each containing one heme-c and one heme-d(1). Heme-c is the electron entry site, whereas heme-d(1) constitutes the catalytic center. The 3D structure of Pseudomonas aeruginosa nitrite reductase has been determined in both fully oxidized and reduced states. Intramolecular electron transfer (ET), between c and d(1) hemes is an essential step in the catalytic cycle. In earlier studies of the Pseudomonas stutzeri enzyme, we observed that a marked negative cooperativity is controlling this internal ET step. In this study we have investigated the internal ET in the wild-type and His369Ala mutant of P. aeruginosa nitrite reductases and have observed similar cooperativity to that of the Pseudomonas stutzeri enzyme. Heme-c was initially reduced, in an essentially diffusion-controlled bimolecular process, followed by unimolecular electron equilibration between the c and d(1) hemes (k(ET) = 4.3 s(-1) and K = 1.4 at 298 K, pH 7.0). In the case of the mutant, the latter ET rate was faster by almost one order of magnitude. Moreover, the internal ET rate dropped (by approximately 30-fold) as the level of reduction increased in both the WT and the His mutant. Equilibrium standard enthalpy and entropy changes and activation parameters of this ET process were determined. We concluded that negative cooperativity is a common feature among the cd(1) nitrite reductases, and we discuss this control based on the available 3D structure of the wild-type and the H369A mutant, in the reduced and oxidized states.

Published

2009

7. Intramolecular electron transfer in Pseudomonas aeruginosa cd(1) nitrite reductase:thermodynamics and kinetics

Author

Farver, Ole, Brunori, Maurizio, Cutruzzolà, Francesca, Rinaldo, Serena, Wherland, Scot, Pecht, Israel, Farver, Ole, Brunori, Maurizio, Cutruzzolà, Francesca, Rinaldo, Serena, Wherland, Scot, and Pecht, Israel

Abstract

The cd(1) nitrite reductases, which catalyze the reduction of nitrite to nitric oxide, are homodimers of 60 kDa subunits, each containing one heme-c and one heme-d(1). Heme-c is the electron entry site, whereas heme-d(1) constitutes the catalytic center. The 3D structure of Pseudomonas aeruginosa nitrite reductase has been determined in both fully oxidized and reduced states. Intramolecular electron transfer (ET), between c and d(1) hemes is an essential step in the catalytic cycle. In earlier studies of the Pseudomonas stutzeri enzyme, we observed that a marked negative cooperativity is controlling this internal ET step. In this study we have investigated the internal ET in the wild-type and His369Ala mutant of P. aeruginosa nitrite reductases and have observed similar cooperativity to that of the Pseudomonas stutzeri enzyme. Heme-c was initially reduced, in an essentially diffusion-controlled bimolecular process, followed by unimolecular electron equilibration between the c and d(1) hemes (k(ET) = 4.3 s(-1) and K = 1.4 at 298 K, pH 7.0). In the case of the mutant, the latter ET rate was faster by almost one order of magnitude. Moreover, the internal ET rate dropped (by approximately 30-fold) as the level of reduction increased in both the WT and the His mutant. Equilibrium standard enthalpy and entropy changes and activation parameters of this ET process were determined. We concluded that negative cooperativity is a common feature among the cd(1) nitrite reductases, and we discuss this control based on the available 3D structure of the wild-type and the H369A mutant, in the reduced and oxidized states.

Published

2009

8. Intramolecular electron transfer in pseudomonas aeruginosa cd1 Nitrite reductase:Thermodynamics and kinetics

Author

Farver, Ole, Brunori, Maurizio, Cutruzzolà, Francesca, Rinaldo, Serena, Wherland, Scot, Pecht, Israel, Farver, Ole, Brunori, Maurizio, Cutruzzolà, Francesca, Rinaldo, Serena, Wherland, Scot, and Pecht, Israel

Abstract

The cd(1) nitrite reductases, which catalyze the reduction of nitrite to nitric oxide, are homodimers of 60 kDa subunits, each containing one heme-c and one heme-d(1). Heme-c is the electron entry site, whereas heme-d(1) constitutes the catalytic center. The 3D structure of Pseudomonas aeruginosa nitrite reductase has been determined in both fully oxidized and reduced states. Intramolecular electron transfer (ET), between c and d(1) hemes is an essential step in the catalytic cycle. In earlier studies of the Pseudomonas stutzeri enzyme, we observed that a marked negative cooperativity is controlling this internal ET step. In this study we have investigated the internal ET in the wild-type and His369Ala mutant of P. aeruginosa nitrite reductases and have observed similar cooperativity to that of the Pseudomonas stutzeri enzyme. Heme-c was initially reduced, in an essentially diffusion-controlled bimolecular process, followed by unimolecular electron equilibration between the c and d(1) hemes (k(ET) = 4.3 s(-1) and K = 1.4 at 298 K, pH 7.0). In the case of the mutant, the latter ET rate was faster by almost one order of magnitude. Moreover, the internal ET rate dropped (by approximately 30-fold) as the level of reduction increased in both the WT and the His mutant. Equilibrium standard enthalpy and entropy changes and activation parameters of this ET process were determined. We concluded that negative cooperativity is a common feature among the cd(1) nitrite reductases, and we discuss this control based on the available 3D structure of the wild-type and the H369A mutant, in the reduced and oxidized states.

Published

2009

9. Intramolecular electron transfer in pseudomonas aeruginosa cd1 Nitrite reductase:Thermodynamics and kinetics

Author

Farver, Ole, Brunori, Maurizio, Cutruzzolà, Francesca, Rinaldo, Serena, Wherland, Scot, Pecht, Israel, Farver, Ole, Brunori, Maurizio, Cutruzzolà, Francesca, Rinaldo, Serena, Wherland, Scot, and Pecht, Israel

Abstract

The cd(1) nitrite reductases, which catalyze the reduction of nitrite to nitric oxide, are homodimers of 60 kDa subunits, each containing one heme-c and one heme-d(1). Heme-c is the electron entry site, whereas heme-d(1) constitutes the catalytic center. The 3D structure of Pseudomonas aeruginosa nitrite reductase has been determined in both fully oxidized and reduced states. Intramolecular electron transfer (ET), between c and d(1) hemes is an essential step in the catalytic cycle. In earlier studies of the Pseudomonas stutzeri enzyme, we observed that a marked negative cooperativity is controlling this internal ET step. In this study we have investigated the internal ET in the wild-type and His369Ala mutant of P. aeruginosa nitrite reductases and have observed similar cooperativity to that of the Pseudomonas stutzeri enzyme. Heme-c was initially reduced, in an essentially diffusion-controlled bimolecular process, followed by unimolecular electron equilibration between the c and d(1) hemes (k(ET) = 4.3 s(-1) and K = 1.4 at 298 K, pH 7.0). In the case of the mutant, the latter ET rate was faster by almost one order of magnitude. Moreover, the internal ET rate dropped (by approximately 30-fold) as the level of reduction increased in both the WT and the His mutant. Equilibrium standard enthalpy and entropy changes and activation parameters of this ET process were determined. We concluded that negative cooperativity is a common feature among the cd(1) nitrite reductases, and we discuss this control based on the available 3D structure of the wild-type and the H369A mutant, in the reduced and oxidized states.

Published

2009

10. New insights into the activity of Pseudomonas aeruginosa cd(1), nitrite reductase

Author

Rinaldo, Serena, Arcovito, Alessandro, Giardina, Giorgio, Castiglione, Nicoletta, Brunori, Maurizio, Cutruzzolà, Francesca, Arcovito, Alessandro (ORCID:0000-0002-8384-4844), Rinaldo, Serena, Arcovito, Alessandro, Giardina, Giorgio, Castiglione, Nicoletta, Brunori, Maurizio, Cutruzzolà, Francesca, and Arcovito, Alessandro (ORCID:0000-0002-8384-4844)

Abstract

The cytochrome cd(1) nitrite reductases are enzymes that catalyse the reduction of nitrite to nitric oxide (NO) in the bacterial energy conversion denitrification process. These enzymes contain two different redox centres: one covalently bound c-haem, which is reduced by external donors, and one peculiar d(1)-haem, where catalysis occurs. in the present paper, we summarize the current understanding of the reaction of nitrite reduction in the light of the most recent results on the enzyme from Pseudomonas aeruginosa and discuss the differences between enzymes from different organisms. We have evidence that release of NO from the ferrous d(1)-haem occurs rapidly enough to be fully compatible with the turnover, in contrast with previous hypotheses, and that the substrate nitrite is able to displace NO from the d(1)-haem iron. These results shed light on the mechanistic details of the activity of cd(1) nitrite reductases and on the biological role of the d(1)-haem, whose presence in this class of enzymes has to date been unexplained

Published

2008

11. Fast dissociation of nitric oxide from ferrous Pseudomonas aeruginosa cd1 nitrite reductase: A novel outlook on the catalytic mechanism

Author

Rinaldo, Serena, Arcovito, Alessandro, Brunori, Maurizio, Cutruzzolà, Francesca, Arcovito, Alessandro (ORCID:0000-0002-8384-4844), Rinaldo, Serena, Arcovito, Alessandro, Brunori, Maurizio, Cutruzzolà, Francesca, and Arcovito, Alessandro (ORCID:0000-0002-8384-4844)

Abstract

The heme-containing periplasmic nitrite reductase (cd1 NIR) is responsible for the production of nitric oxide (NO) in denitrifying bacterial species, among which are several animal and plant pathogens. Heme NIRs are homodimers, each subunit containing one covalently bound c-heme and one d 1-heme. The reduction of nitrite to NO involves binding of nitrite to the reduced protein at the level of d1-heme, followed by dehydration of nitrite to yield NO and release of the latter. The crucial ratelimiting step in the catalytic mechanism is thought to be the release of NO from the d 1-heme, which has been proposed, but never demonstrated experimentally, to occur when the iron is in the ferric form, given that the reduced NO-bound derivative was presumed to be very stable, as in other hemeproteins. We have measured for the first time the kinetics of NO binding and release from fully reduced cd1 NIR, using the enzyme from Pseudomonas aeruginosa and its site-directed mutant H369A. Quite unexpectedly, we found that NO dissociation from the reduced d1-heme is very rapid, several orders of magnitude faster than that measured for b-type heme containing reduced hemeproteins. Because the rate of NO dissociation from reduced cd1 NIR, measured in the present report, is faster than or comparable with the turnover number, contrary to expectations this event may well be on the catalytic cycle and not necessarily rate-limiting. This finding also provides a rationale for the presence in cd1 NIR of the peculiar d1-heme cofactor, which has probably evolved to ensure fast product dissociation

Published

2007