Your search keyword '"Brandas, Chiara"' showing total 12 results

1. CD32 captures committed haemogenic endothelial cells during human embryonic development

Author

Scarfò, Rebecca, Randolph, Lauren N., Abou Alezz, Monah, El Khoury, Mahassen, Gersch, Amélie, Li, Zhong-Yin, Luff, Stephanie A., Tavosanis, Andrea, Ferrari Ramondo, Giulia, Valsoni, Sara, Cascione, Sara, Didelon, Emma, Passerini, Laura, Amodio, Giada, Brandas, Chiara, Villa, Anna, Gregori, Silvia, Merelli, Ivan, Freund, Jean-Noël, Sturgeon, Christopher M., Tavian, Manuela, and Ditadi, Andrea

Published

2024

2. A p38 MAPK-ROS axis fuels proliferation stress and DNA damage during CRISPR-Cas9 gene editing in hematopoietic stem and progenitor cells

Author

della Volpe, Lucrezia, Midena, Federico, Vacca, Roberta, Tavella, Teresa, Alessandrini, Laura, Farina, Giacomo, Brandas, Chiara, Lo Furno, Elena, Giannetti, Kety, Carsana, Edoardo, Naldini, Matteo M., Barcella, Matteo, Ferrari, Samuele, Beretta, Stefano, Santoro, Antonella, Porcellini, Simona, Varesi, Angelica, Gilioli, Diego, Conti, Anastasia, Merelli, Ivan, Gentner, Bernhard, Villa, Anna, Naldini, Luigi, and Di Micco, Raffaella

Published

2024

3. Exonic knockout and knockin gene editing in hematopoietic stem and progenitor cells rescues RAG1 immunodeficiency

Author

Castiello, M, Brandas, C, Ferrari, S, Porcellini, S, Sacchetti, N, Canarutto, D, Draghici, E, Merelli, I, Barcella, M, Pelosi, G, Vavassori, V, Varesi, A, Jacob, A, Scala, S, Basso Ricci, L, Paulis, M, Strina, D, Di Verniere, M, Sergi Sergi, L, Serafini, M, Holland, S, Bergerson, J, De Ravin, S, Malech, H, Pala, F, Bosticardo, M, Brombin, C, Cugnata, F, Calzoni, E, Crooks, G, Notarangelo, L, Genovese, P, Naldini, L, Villa, A, Castiello, Maria Carmina, Brandas, Chiara, Ferrari, Samuele, Porcellini, Simona, Sacchetti, Nicolò, Canarutto, Daniele, Draghici, Elena, Merelli, Ivan, Barcella, Matteo, Pelosi, Gabriele, Vavassori, Valentina, Varesi, Angelica, Jacob, Aurelien, Scala, Serena, Basso Ricci, Luca, Paulis, Marianna, Strina, Dario, Di Verniere, Martina, Sergi Sergi, Lucia, Serafini, Marta, Holland, Steven M., Bergerson, Jenna R. E., De Ravin, Suk See, Malech, Harry L., Pala, Francesca, Bosticardo, Marita, Brombin, Chiara, Cugnata, Federica, Calzoni, Enrica, Crooks, Gay M., Notarangelo, Luigi D., Genovese, Pietro, Naldini, Luigi, Villa, Anna, Castiello, M, Brandas, C, Ferrari, S, Porcellini, S, Sacchetti, N, Canarutto, D, Draghici, E, Merelli, I, Barcella, M, Pelosi, G, Vavassori, V, Varesi, A, Jacob, A, Scala, S, Basso Ricci, L, Paulis, M, Strina, D, Di Verniere, M, Sergi Sergi, L, Serafini, M, Holland, S, Bergerson, J, De Ravin, S, Malech, H, Pala, F, Bosticardo, M, Brombin, C, Cugnata, F, Calzoni, E, Crooks, G, Notarangelo, L, Genovese, P, Naldini, L, Villa, A, Castiello, Maria Carmina, Brandas, Chiara, Ferrari, Samuele, Porcellini, Simona, Sacchetti, Nicolò, Canarutto, Daniele, Draghici, Elena, Merelli, Ivan, Barcella, Matteo, Pelosi, Gabriele, Vavassori, Valentina, Varesi, Angelica, Jacob, Aurelien, Scala, Serena, Basso Ricci, Luca, Paulis, Marianna, Strina, Dario, Di Verniere, Martina, Sergi Sergi, Lucia, Serafini, Marta, Holland, Steven M., Bergerson, Jenna R. E., De Ravin, Suk See, Malech, Harry L., Pala, Francesca, Bosticardo, Marita, Brombin, Chiara, Cugnata, Federica, Calzoni, Enrica, Crooks, Gay M., Notarangelo, Luigi D., Genovese, Pietro, Naldini, Luigi, and Villa, Anna

Abstract

Recombination activating genes (RAGs) are tightly regulated during lymphoid differentiation, and their mutations cause a spectrum of severe immunological disorders. Hematopoietic stem and progenitor cell (HSPC) transplantation is the treatment of choice but is limited by donor availability and toxicity. To overcome these issues, we developed gene editing strategies targeting a corrective sequence into the human RAG1 gene by homology-directed repair (HDR) and validated them by tailored two-dimensional, three-dimensional, and in vivo xenotransplant platforms to assess rescue of expression and function. Whereas integration into intron 1 of RAG1 achieved suboptimal correction, in-frame insertion into exon 2 drove physiologic human RAG1 expression and activity, allowing disruption of the dominant-negative effects of unrepaired hypomorphic alleles. Enhanced HDR-mediated gene editing enabled the correction of human RAG1 in HSPCs from patients with hypomorphic RAG1 mutations to overcome T and B cell differentiation blocks. Gene correction efficiency exceeded the minimal proportion of functional HSPCs required to rescue immunodeficiency in Rag1(-/- )mice, supporting the clinical translation of HSPC gene editing for the treatment of RAG1 deficiency.

Published

2024

4. Genome editing strategy to treat Severe Combined Immunodeficiency due to Recombination Activating Gene 1 (RAG1) defects

Author

Brandas, C, SERAFINI, MARTA, BRANDAS, CHIARA, Brandas, C, SERAFINI, MARTA, and BRANDAS, CHIARA

Abstract

I Geni Attivatori di Ricombinazione (RAG) sono strettamente regolati durante la differenziazione linfocitaria e le loro mutazioni causano una serie di gravi disturbi immunologici. Il trapianto di cellule staminali/progenitrici ematopoietiche (HSPC) è il trattamento di elezione, ma è limitato dalla disponibilità dei donatori e dalla tossicità. Per superare questi problemi, abbiamo sviluppato strategie di modifica genetica mirate all'inserimento di una sequenza correttiva nel gene RAG1 umano mediante riparazione diretta dell'omologia (HDR) e le abbiamo convalidate attraverso piattaforme su misura in 2D, 3D e in vivo per valutare rigorosamente il ripristino dell'espressione e della funzione. Mentre l'integrazione nell'introne 1 ha raggiunto livelli di correzione subottimali, l'inserimento in fase nell'esone 2 ha consentito una fedele riproduzione dell'espressione e dell'attività fisiologica di RAG1, permettendo contemporaneamente di interrompere gli effetti dominanti-negativi degli alleli ipomorfici non riparati. La nostra strategia di editing mediante HDR ha reso altamente efficiente la ricostituzione di RAG1 nelle HSPC da donatori sani e pazienti con mutazioni ipomorfiche di RAG1, sostenendo la differenziazione delle cellule T e superando il blocco della differenziazione delle cellule B nei pazienti. L'efficienza di correzione genetica ha superato la proporzione minima di HSPC funzionali richiesta per salvare l'immunodeficienza nei topi Rag1-/-, supportando fortemente la traduzione clinica della strategia di editing delle HSPC per il trattamento della deficienza causata da mutazioni di RAG1., Recombination Activating Genes (RAG) are tightly regulated during lymphoid differentiation and their mutations cause a spectrum of severe immunological disorders. Hematopoietic stem/progenitor cell (HSPC) transplantation is the treatment of choice but limited by donor availability and toxicity. To overcome these issues, we developed gene editing (GE) strategies targeting a corrective sequence into the human RAG1 gene by homology-directed repair (HDR) and validated them by tailored 2D, 3D and in vivo platforms to stringently assess rescue of expression and function. Whereas integration into intron 1 achieved suboptimal levels of correction, in-frame insertion into exon 2 drove faithful recapitulation of physiologic hRAG1 expression and activity, allowing to concomitantly disrupt dominant-negative effects of unrepaired hypomorphic alleles. Enhanced HDR-mediated GE enabled highly efficient hRAG1 reconstitution in HSPCs from healthy donors and hypomorphic RAG1 patients, supporting T-cell differentiation and overcoming the patients’ B-cell differentiation block. Gene correction efficiency exceeded the minimal proportion of functional HSPCs required to rescue immunodeficiency in Rag1-/- mice, strongly supporting the clinical translation of HSPC GE for treating RAG1 deficiency.

Published

2024

5. Exonic knockout and knockin gene editing in hematopoietic stem and progenitor cells rescues RAG1 immunodeficiency

Author

Castiello, Maria Carmina, primary, Brandas, Chiara, additional, Ferrari, Samuele, additional, Porcellini, Simona, additional, Sacchetti, Nicolò, additional, Canarutto, Daniele, additional, Draghici, Elena, additional, Merelli, Ivan, additional, Barcella, Matteo, additional, Pelosi, Gabriele, additional, Vavassori, Valentina, additional, Varesi, Angelica, additional, Jacob, Aurelien, additional, Scala, Serena, additional, Basso Ricci, Luca, additional, Paulis, Marianna, additional, Strina, Dario, additional, Di Verniere, Martina, additional, Sergi Sergi, Lucia, additional, Serafini, Marta, additional, Holland, Steven M., additional, Bergerson, Jenna R. E., additional, De Ravin, Suk See, additional, Malech, Harry L., additional, Pala, Francesca, additional, Bosticardo, Marita, additional, Brombin, Chiara, additional, Cugnata, Federica, additional, Calzoni, Enrica, additional, Crooks, Gay M., additional, Notarangelo, Luigi D., additional, Genovese, Pietro, additional, Naldini, Luigi, additional, and Villa, Anna, additional

Published

2024

6. In Silico and In Vitro Evaluation of the Mechanism of Action of Three VX809-Based Hybrid Derivatives as Correctors of the F508del CFTR Protein.

Author

Baroni, Debora, Scarano, Naomi, Ludovico, Alessandra, Brandas, Chiara, Parodi, Alice, Lunaccio, Dario, Fossa, Paola, Moran, Oscar, Cichero, Elena, and Millo, Enrico

Subjects

RECESSIVE genes, CHLORIDE channels, CYSTIC fibrosis transmembrane conductance regulator, AQUAPORINS, SMALL molecules

Abstract

Cystic fibrosis (CF), the most common autosomal recessive fatal genetic disease in the Caucasian population, is caused by mutations in the gene encoding the cystic fibrosis transmembrane conductance regulator (CFTR), an anion channel that regulates salt and water transport across a variety of secretory epithelia. Deletion of phenylalanine at position 508, F508del, the most common CF-causing mutation, destabilises the CFTR protein, causing folding and trafficking defects that lead to a dramatic reduction in its functional expression. Small molecules called correctors have been developed to rescue processing-defective F508del CFTR. We have combined in silico and in vitro approaches to investigate the mechanism of action and potential as CFTR correctors of three hybrid derivatives (2a, 7a, and 7m) obtained by merging the amino-arylthiazole core with the benzodioxole carboxamide moiety characterising the corrector lumacaftor. Molecular modelling analyses suggested that the three hybrids interact with a putative region located at the MSD1/NBD1 interface. Biochemical analyses confirmed these results, showing that the three molecules affect the expression and stability of the F508del NBD1. Finally, the YFP assay was used to evaluate the influence of the three hybrid derivatives on F508del CFTR function, assessing that their effect is additive to that of the correctors VX661 and VX445. Our study shows that the development and testing of optimised compounds targeting different structural and functional defects of mutant CFTR is the best strategy to provide more effective correctors that could be used alone or in combination as a valuable therapeutic option to treat an even larger cohort of people affected by CF. [ABSTRACT FROM AUTHOR]

Published

2023

7. HyperIgE in hypomorphic recombination-activating gene defects

Author

Castiello, Maria Carmina, primary, Brandas, Chiara, additional, Capo, Valentina, additional, and Villa, Anna, additional

Published

2023

8. NBD2 Is Required for the Rescue of Mutant F508del CFTR by a Thiazole-Based Molecule: A Class II Corrector for the Multi-Drug Therapy of Cystic Fibrosis

Author

Brandas, Chiara, primary, Ludovico, Alessandra, additional, Parodi, Alice, additional, Moran, Oscar, additional, Millo, Enrico, additional, Cichero, Elena, additional, and Baroni, Debora, additional

Published

2021

9. A novel L1CAM isoform with angiogenic activity generated by NOVA2-mediated alternative splicing

Author

Angiolini, Francesca, Belloni, Elisa, Giordano, Marco, Campioni, Matteo, Forneris, Federico, Paola, Paronetto Maria, Lupia, Michela, Brandas, Chiara, Pradella, Davide, Di Matteo, Anna, Giampietro, Costanza, Jodice, Giovanna, Luise, Chiara, Bertalot, Giovanni, Freddi, Stefano, Malinverno, Matteo, Irimia, Manuel, Moulton, Jon D., Summerton, James, Chiapparino, Antonella, Ghilardi, Carmen, Giavazzi, Raffaella, Nyqvist, Daniel, Gabellini, Davide, Dejana, Elisabetta, Cavallaro, Ugo, Ghigna, Claudia, Angiolini, Francesca, Belloni, Elisa, Giordano, Marco, Campioni, Matteo, Forneris, Federico, Paola, Paronetto Maria, Lupia, Michela, Brandas, Chiara, Pradella, Davide, Di Matteo, Anna, Giampietro, Costanza, Jodice, Giovanna, Luise, Chiara, Bertalot, Giovanni, Freddi, Stefano, Malinverno, Matteo, Irimia, Manuel, Moulton, Jon D., Summerton, James, Chiapparino, Antonella, Ghilardi, Carmen, Giavazzi, Raffaella, Nyqvist, Daniel, Gabellini, Davide, Dejana, Elisabetta, Cavallaro, Ugo, and Ghigna, Claudia

Abstract

The biological players involved in angiogenesis are only partially defined. Here, we report that endothelial cells (ECs) express a novel isoform of the cell-surface adhesion molecule L1CAM, termed L1-ΔTM. The splicing factor NOVA2, which binds directly to L1CAM pre-mRNA, is necessary and sufficient for the skipping of L1CAM transmembrane domain in ECs, leading to the release of soluble L1-ΔTM. The latter exerts high angiogenic function through both autocrine and paracrine activities. Mechanistically, L1-ΔTM-induced angiogenesis requires fibroblast growth factor receptor-1 signaling, implying a crosstalk between the two molecules. NOVA2 and L1-ΔTM are overexpressed in the vasculature of ovarian cancer, where L1-ΔTM levels correlate with tumor vascularization, supporting the involvement of NOVA2-mediated L1-ΔTM production in tumor angiogenesis. Finally, high NOVA2 expression is associated with poor outcome in ovarian cancer patients. Our results point to L1-ΔTM as a novel, EC-derived angiogenic factor which may represent a target for innovative antiangiogenic therapies.

Published

2019

10. A novel L1CAM isoform with angiogenic activity generated by NOVA2-mediated alternative splicing

Author

Angiolini, Francesca, primary, Belloni, Elisa, additional, Giordano, Marco, additional, Campioni, Matteo, additional, Forneris, Federico, additional, Paronetto, Maria Paola, additional, Lupia, Michela, additional, Brandas, Chiara, additional, Pradella, Davide, additional, Di Matteo, Anna, additional, Giampietro, Costanza, additional, Jodice, Giovanna, additional, Luise, Chiara, additional, Bertalot, Giovanni, additional, Freddi, Stefano, additional, Malinverno, Matteo, additional, Irimia, Manuel, additional, Moulton, Jon D, additional, Summerton, James, additional, Chiapparino, Antonella, additional, Ghilardi, Carmen, additional, Giavazzi, Raffaella, additional, Nyqvist, Daniel, additional, Gabellini, Davide, additional, Dejana, Elisabetta, additional, Cavallaro, Ugo, additional, and Ghigna, Claudia, additional

Published

2019

11. Author response: A novel L1CAM isoform with angiogenic activity generated by NOVA2-mediated alternative splicing

Author

Angiolini, Francesca, primary, Belloni, Elisa, additional, Giordano, Marco, additional, Campioni, Matteo, additional, Forneris, Federico, additional, Paronetto, Maria Paola, additional, Lupia, Michela, additional, Brandas, Chiara, additional, Pradella, Davide, additional, Di Matteo, Anna, additional, Giampietro, Costanza, additional, Jodice, Giovanna, additional, Luise, Chiara, additional, Bertalot, Giovanni, additional, Freddi, Stefano, additional, Malinverno, Matteo, additional, Irimia, Manuel, additional, Moulton, Jon D, additional, Summerton, James, additional, Chiapparino, Antonella, additional, Ghilardi, Carmen, additional, Giavazzi, Raffaella, additional, Nyqvist, Daniel, additional, Gabellini, Davide, additional, Dejana, Elisabetta, additional, Cavallaro, Ugo, additional, and Ghigna, Claudia, additional

Published

2019

12. Unravelling the Regions of Mutant F508del-CFTR More Susceptible to the Action of Four Cystic Fibrosis Correctors.

Author

Amico G, Brandas C, Moran O, and Baroni D

Subjects

Cystic Fibrosis drug therapy, Cystic Fibrosis genetics, Cystic Fibrosis metabolism, Cystic Fibrosis Transmembrane Conductance Regulator metabolism, Gene Expression Regulation drug effects, HEK293 Cells, Humans, Mutant Proteins drug effects, Mutant Proteins genetics, Mutant Proteins metabolism, Aminopyridines pharmacology, Benzamides pharmacology, Benzodioxoles pharmacology, Cystic Fibrosis Transmembrane Conductance Regulator genetics, Indoles pharmacology, Mutation, Quinazolines pharmacology, Thiazoles pharmacology

Abstract

Cystic fibrosis (CF) is a genetic disease associated with the defective function of the cystic fibrosis transmembrane conductance regulator (CFTR) protein that causes obstructive disease and chronic bacterial infections in airway epithelia. The most prevalent CF-causing mutation, the deletion of phenylalanine at position 508 (F508del), leads to CFTR misfolding, trafficking defects and premature degradation. A number of correctors that are able to partially rescue F508del-CFTR processing defects have been identified. Clinical trials have demonstrated that, unfortunately, mono-therapy with the best correctors identified to date does not ameliorate lung function or sweat chloride concentration in homozygous F508del patients. Understanding the mechanisms exerted by currently available correctors to increase mutant F508del-CFTR expression is essential for the development of new CF-therapeutics. We investigated the activity of correctors on the mutant F508del and wild type (WT) CFTR to identify the protein domains whose expression is mostly affected by the action of correctors, and we investigated their mechanisms of action. We found that the four correctors under study, lumacaftor (VX809), the quinazoline derivative VX325, the bithiazole compound corr4a, and the new molecule tezacaftor (VX661), do not influence either the total expression or the maturation of the WT-CFTR transiently expressed in human embryonic kidney 293 (HEK293) cells. Contrarily, they significantly enhance the expression and the maturation of the full length F508del molecule. Three out of four correctors, VX809, VX661 and VX325, seem to specifically improve the expression and the maturation of the mutant CFTR N-half (M1N1, residues 1-633). By contrast, the CFTR C-half (M2N2, residues 837-1480) appears to be the region mainly affected by corr4a. VX809 was shown to stabilize both the WT- and F508del-CFTR N-half isoforms, while VX661 and VX325 demonstrated the ability to enhance the stability only of the mutant F508del polypeptide., Competing Interests: The authors declare no conflict of interest.

Published

2019