Your search keyword '"Vescovi, Angelo L."' showing total 7 results

1. Different states of stemness of glioblastoma stem cells sustain glioblastoma subtypes indicating novel clinical biomarkers and high-efficacy customized therapies

Author

Visioli, Alberto, Trivieri, Nadia, Mencarelli, Gandino, Giani, Fabrizio, Copetti, Massimiliano, Palumbo, Orazio, Pracella, Riccardo, Cariglia, Maria Grazia, Barile, Chiara, Mischitelli, Luigi, Soriano, Amata Amy, Palumbo, Pietro, Legnani, Federico, DiMeco, Francesco, Gorgoglione, Leonardo, Pesole, Graziano, Vescovi, Angelo L., and Binda, Elena

Published

2023

2. Growth factor independence underpins a paroxysmal, aggressive Wnt5aHigh/EphA2Low phenotype in glioblastoma stem cells, conducive to experimental combinatorial therapy

Author

Trivieri, Nadia, Visioli, Alberto, Mencarelli, Gandino, Cariglia, Maria Grazia, Marongiu, Laura, Pracella, Riccardo, Giani, Fabrizio, Soriano, Amata Amy, Barile, Chiara, Cajola, Laura, Copetti, Massimiliano, Palumbo, Orazio, Legnani, Federico, DiMeco, Francesco, Gorgoglione, Leonardo, Vescovi, Angelo L., and Binda, Elena

Published

2022

3. AQP4-dependent glioma cell features affect the phenotype of surrounding cells via extracellular vesicles

Author

Simone, Laura, Pisani, Francesco, Binda, Elena, Frigeri, Antonio, Vescovi, Angelo L., Svelto, Maria, and Nicchia, Grazia P.

Published

2022

4. BRAFV600E mutation impinges on gut microbial markers defining novel biomarkers for serrated colorectal cancer effective therapies

Author

Trivieri, Nadia, Pracella, Riccardo, Cariglia, Maria Grazia, Panebianco, Concetta, Parrella, Paola, Visioli, Alberto, Giani, Fabrizio, Soriano, Amata Amy, Barile, Chiara, Canistro, Giuseppe, Latiano, Tiziana Pia, Dimitri, Lucia, Bazzocchi, Francesca, Cassano, Dario, Vescovi, Angelo L., Pazienza, Valerio, and Binda, Elena

Published

2020

5. Growth factor independence underpins a paroxysmal, aggressive Wnt5aHigh/EphA2Low phenotype in glioblastoma stem cells, conducive to experimental combinatorial therapy.

Author

Trivieri, Nadia, Visioli, Alberto, Mencarelli, Gandino, Cariglia, Maria Grazia, Marongiu, Laura, Pracella, Riccardo, Giani, Fabrizio, Soriano, Amata Amy, Barile, Chiara, Cajola, Laura, Copetti, Massimiliano, Palumbo, Orazio, Legnani, Federico, DiMeco, Francesco, Gorgoglione, Leonardo, Vescovi, Angelo L., and Binda, Elena

Subjects

BRAIN tumors, GROWTH factors, STEM cells, TUMOR markers, GLIOBLASTOMA multiforme, PROGNOSIS, FALSE discovery rate, PROTEIN-tyrosine kinases

Abstract

Background: Glioblastoma multiforme (GBM) is an incurable tumor, with a median survival rate of only 14–15 months. Along with heterogeneity and unregulated growth, a central matter in dealing with GBMs is cell invasiveness. Thus, improving prognosis requires finding new agents to inhibit key multiple pathways, even simultaneously. A subset of GBM stem-like cells (GSCs) may account for tumorigenicity, representing, through their pathways, the proper cellular target in the therapeutics of glioblastomas. GSCs cells are routinely enriched and expanded due to continuous exposure to specific growth factors, which might alter some of their intrinsic characteristic and hide therapeutically relevant traits. Methods: By removing exogenous growth factors stimulation, here we isolated and characterized a subset of GSCs with a "mitogen-independent" phenotype (I-GSCs) from patient's tumor specimens. Differential side-by-side comparative functional and molecular analyses were performed either in vitro or in vivo on these cells versus their classical growth factor (GF)-dependent counterpart (D-GSCs) as well as their tissue of origin. This was performed to pinpoint the inherent GSCs' critical regulators, with particular emphasis on those involved in spreading and tumorigenic potential. Transcriptomic fingerprints were pointed out by ANOVA with Benjamini-Hochberg False Discovery Rate (FDR) and association of copy number alterations or somatic mutations was determined by comparing each subgroup with a two-tailed Fisher's exact test. The combined effects of interacting in vitro and in vivo with two emerging GSCs' key regulators, such as Wnt5a and EphA2, were then predicted under in vivo experimental settings that are conducive to clinical applications. In vivo comparisons were carried out in mouse-human xenografts GBM model by a hierarchical linear model for repeated measurements and Dunnett's multiple comparison test with the distribution of survival compared by Kaplan–Meier method. Results: Here, we assessed that a subset of GSCs from high-grade gliomas is self-sufficient in the activation of regulatory growth signaling. Furthermore, while constitutively present within the same GBM tissue, these GF-independent GSCs cells were endowed with a distinctive functional and molecular repertoire, defined by highly aggressive Wnt5aHigh/EphA2Low profile, as opposed to Wnt5aLow/EphA2High expression in sibling D-GSCs. Regardless of their GBM subtype of origin, I-GSCs, are endowed with a raised in vivo tumorigenic potential than matched D-GSCs, which were fast-growing ex-vivo but less lethal and invasive in vivo. Also, the malignant I-GSCs' transcriptomic fingerprint faithfully mirrored the original tumor, bringing into evidence key regulators of invasiveness, angiogenesis and immuno-modulators, which became candidates for glioma diagnostic/prognostic markers and therapeutic targets. Particularly, simultaneously counteracting the activity of the tissue invasive mediator Wnt5a and EphA2 tyrosine kinase receptor addictively hindered GSCs' tumorigenic and invasive ability, thus increasing survival. Conclusion: We show how the preservation of a mitogen-independent phenotype in GSCs plays a central role in determining the exacerbated tumorigenic and high mobility features distinctive of GBM. The exploitation of the I-GSCs' peculiar features shown here offers new ways to identify novel, GSCs-specific effectors, whose modulation can be used in order to identify novel, potential molecular therapeutic targets. Furthermore, we show how the combined use of PepA, the anti-Wnt5a drug, and of ephrinA1-Fc to can hinder GSCs' lethality in a clinically relevant xenogeneic in vivo model thus being conducive to perspective, novel combinatorial clinical application. [ABSTRACT FROM AUTHOR]

Published

2022

6. Vaccinia virus expressing bone morphogenetic protein-4 in novel glioblastoma orthotopic models facilitates enhanced tumor regression and long-term survival.

Author

Duggal, Rohit, Geissinger, Ulrike, Zhang, Qian, Aguilar, Jason, Chen, Nanhai G., Binda, Elena, Vescovi, Angelo L., and Szalay, Aladar A.

Subjects

VACCINIA, BONE morphogenetic proteins, GLIOBLASTOMA multiforme, DISEASE relapse, XENOGRAFTS, CANCER stem cells, CELL lines, LABORATORY mice

Abstract

Background: Glioblastoma multiforme (GBM) is one of the most aggressive forms of cancer with a high rate of recurrence. We propose a novel oncolytic vaccinia virus (VACV)-based therapy using expression of the bone morphogenetic protein (BMP)-4 for treating GBM and preventing recurrence. Methods: We have utilized clinically relevant, orthotopic xenograft models of GBM based on tumor-biopsy derived, primary cancer stem cell (CSC) lines. One of the cell lines, after being transduced with a cDNA encoding firefly luciferase, could be used for real time tumor imaging. A VACV that expresses BMP-4 was constructed and utilized for infecting several primary glioma cultures besides conventional serum-grown glioma cell lines. This virus was also delivered intracranially upon implantation of the GBM CSCs in mice to determine effects on tumor growth. Results: We found that the VACV that overexpresses BMP-4 demonstrated heightened replication and cytotoxic activity in GBM CSC cultures with a broad spectrum of activity across several different patient-biopsy cultures. Intracranial inoculation of mice with this virus resulted in a tumor size equal to or below that at the time of injection. This resulted in survival of 100% of the treated mice up to 84 days post inoculation, significantly superior to that of a VACV lacking BMP-4 expression. When mice with a higher tumor burden were injected with the VACV lacking BMP-4, 80% of the mice showed tumor recurrence. In contrast, no recurrence was seen when mice were injected with the VACV expressing BMP-4, possibly due to induction of differentiation in the CSC population and subsequently serving as a better host for VACV infection and oncolysis. This lack of recurrence resulted in superior survival in the BMP-4 VACV treated group. Conclusions: Based on these findings we propose a novel VACV therapy for treating GBM, which would allow tumor specific production of drugs in the future in combination with BMPs which would simultaneously control tumor maintenance and facilitate CSC differentiation, respectively, thereby causing sustained tumor regression without recurrence. [ABSTRACT FROM AUTHOR]

Published

2013

7. Human neural stem cell transplantation in ALS: initial results from a phase I trial.

Author

Mazzini L, Gelati M, Profico DC, Sgaravizzi G, Projetti Pensi M, Muzi G, Ricciolini C, Rota Nodari L, Carletti S, Giorgi C, Spera C, Domenico F, Bersano E, Petruzzelli F, Cisari C, Maglione A, Sarnelli MF, Stecco A, Querin G, Masiero S, Cantello R, Ferrari D, Zalfa C, Binda E, Visioli A, Trombetta D, Novelli A, Torres B, Bernardini L, Carriero A, Prandi P, Servo S, Cerino A, Cima V, Gaiani A, Nasuelli N, Massara M, Glass J, Sorarù G, Boulis NM, and Vescovi AL

Subjects

Adult, Aged, Animals, Cell Culture Techniques, Central Nervous System pathology, Chromosome Banding, Disease Progression, Female, Humans, Immunosuppression Therapy, Intercellular Signaling Peptides and Proteins, Italy, Karyotyping, Male, Mice, Mice, Nude, Middle Aged, Pilot Projects, Prospective Studies, Spinal Cord cytology, Amyotrophic Lateral Sclerosis therapy, Neural Stem Cells cytology, Stem Cell Transplantation

Abstract

Background: We report the initial results from a phase I clinical trial for ALS. We transplanted GMP-grade, fetal human neural stem cells from natural in utero death (hNSCs) into the anterior horns of the spinal cord to test for the safety of both cells and neurosurgical procedures in these patients. The trial was approved by the Istituto Superiore di Sanità and the competent Ethics Committees and was monitored by an external Safety Board., Methods: Six non-ambulatory patients were treated. Three of them received 3 unilateral hNSCs microinjections into the lumbar cord tract, while the remaining ones received bilateral (n = 3 + 3) microinjections. None manifested severe adverse events related to the treatment, even though nearly 5 times more cells were injected in the patients receiving bilateral implants and a much milder immune-suppression regimen was used as compared to previous trials., Results: No increase of disease progression due to the treatment was observed for up to18 months after surgery. Rather, two patients showed a transitory improvement of the subscore ambulation on the ALS-FRS-R scale (from 1 to 2). A third patient showed improvement of the MRC score for tibialis anterior, which persisted for as long as 7 months. The latter and two additional patients refused PEG and invasive ventilation and died 8 months after surgery due to the progression of respiratory failure. The autopsies confirmed that this was related to the evolution of the disease., Conclusions: We describe a safe cell therapy approach that will allow for the treatment of larger pools of patients for later-phase ALS clinical trials, while warranting good reproducibility. These can now be carried out under more standardized conditions, based on a more homogenous repertoire of clinical grade hNSCs. The use of brain tissue from natural miscarriages eliminates the ethical concerns that may arise from the use of fetal material., Trial Registration: EudraCT:2009-014484-39 .

Published

2015