Your search keyword '"Rapicavoli, Rosaria Valentina"' showing total 6 results

1. Application of the PHENotype SIMulator for rapid identification of potential candidates in effective COVID-19 drug repurposing

Author

Maria, Naomi I., Rapicavoli, Rosaria Valentina, Alaimo, Salvatore, Bischof, Evelyne, Stasuzzo, Alessia, Broek, Jantine A.C., Pulvirenti, Alfredo, Mishra, Bud, Duits, Ashley J., and Ferro, Alfredo

Published

2023

2. NETME: on-the-fly knowledge network construction from biomedical literature

Author

Muscolino, Alessandro, Di Maria, Antonio, Rapicavoli, Rosaria Valentina, Alaimo, Salvatore, Bellomo, Lorenzo, Billeci, Fabrizio, Borzì, Stefano, Ferragina, Paolo, Ferro, Alfredo, and Pulvirenti, Alfredo

Published

2022

3. IGF2: A Role in Metastasis and Tumor Evasion from Immune Surveillance?

Author

Belfiore, Antonino, Rapicavoli, Rosaria Valentina, Le Moli, Rosario, Lappano, Rosamaria, Morrione, Andrea, De Francesco, Ernestina Marianna, and Vella, Veronica

Subjects

SOMATOMEDIN A, METASTASIS, INSULIN receptors, THERAPEUTICS, DISEASE risk factors

Abstract

Insulin-like growth factor 2 (IGF2) is upregulated in both childhood and adult malignancies. Its overexpression is associated with resistance to chemotherapy and worse prognosis. However, our understanding of its physiological and pathological role is lagging behind what we know about IGF1. Dysregulation of the expression and function of IGF2 receptors, insulin receptor isoform A (IR-A), insulin growth factor receptor 1 (IGF1R), and their downstream signaling effectors drive cancer initiation and progression. The involvement of IGF2 in carcinogenesis depends on its ability to link high energy intake, increase cell proliferation, and suppress apoptosis to cancer risk, and this is likely the key mechanism bridging insulin resistance to cancer. New aspects are emerging regarding the role of IGF2 in promoting cancer metastasis by promoting evasion from immune destruction. This review provides a perspective on IGF2 and an update on recent research findings. Specifically, we focus on studies providing compelling evidence that IGF2 is not only a major factor in primary tumor development, but it also plays a crucial role in cancer spread, immune evasion, and resistance to therapies. Further studies are needed in order to find new therapeutic approaches to target IGF2 action. [ABSTRACT FROM AUTHOR]

Published

2023

4. PHENSIM: Phenotype Simulator.

Author

Alaimo, Salvatore, Rapicavoli, Rosaria Valentina, Marceca, Gioacchino P., La Ferlita, Alessandro, Serebrennikova, Oksana B., Tsichlis, Philip N., Mishra, Bud, Pulvirenti, Alfredo, and Ferro, Alfredo

Subjects

*PHENOMENOLOGICAL biology, *WEB-based user interfaces, *BIOLOGICAL networks, *PHENOTYPES, *CYTOLOGY, *SYSTEMS biology

Abstract

Despite the unprecedented growth in our understanding of cell biology, it still remains challenging to connect it to experimental data obtained with cells and tissues' physiopathological status under precise circumstances. This knowledge gap often results in difficulties in designing validation experiments, which are usually labor-intensive, expensive to perform, and hard to interpret. Here we propose PHENSIM, a computational tool using a systems biology approach to simulate how cell phenotypes are affected by the activation/inhibition of one or multiple biomolecules, and it does so by exploiting signaling pathways. Our tool's applications include predicting the outcome of drug administration, knockdown experiments, gene transduction, and exposure to exosomal cargo. Importantly, PHENSIM enables the user to make inferences on well-defined cell lines and includes pathway maps from three different model organisms. To assess our approach's reliability, we built a benchmark from transcriptomics data gathered from NCBI GEO and performed four case studies on known biological experiments. Our results show high prediction accuracy, thus highlighting the capabilities of this methodology. PHENSIM standalone Java application is available at https://github.com/alaimos/phensim, along with all data and source codes for benchmarking. A web-based user interface is accessible at https://phensim.tech/. Author summary: Despite the unprecedented growth in our understanding of cell biology, it still remains challenging to connect it to experimental data obtained with cells and tissues' physiopathological status under precise circumstances. This knowledge gap often results in difficulties in designing validation experiments, which are usually labor-intensive, expensive to perform, and hard to interpret. In this context, 'in silico' simulations can be extensively applied in massive scales, testing thousands of hypotheses under various conditions, which is usually experimentally infeasible. At present, many simulation models have become available. However, complex biological networks might pose challenges to their performance. We propose PHENSIM, a computational tool using a systems biology approach to simulate how cell phenotypes are affected by the activation/inhibition of one or multiple biomolecules, and it does so by exploiting signaling pathways. We implemented our tool as a freely accessible web application, hoping to allow 'in silico' simulations to play a more central role in the modeling and understanding of biological phenomena. [ABSTRACT FROM AUTHOR]

Published

2021

5. Computational Methods for Drug Repurposing.

Author

Rapicavoli RV, Alaimo S, Ferro A, and Pulvirenti A

Subjects

Computational Biology methods, Drug Discovery methods, Drug Repositioning methods

Abstract

The wealth of knowledge and multi-omics data available in drug research has allowed the rise of several computational methods in the drug discovery field, resulting in a novel and exciting strategy called drug repurposing. Drug repurposing consists in finding new applications for existing drugs. Numerous computational methods perform a high-level integration of different knowledge sources to facilitate the discovery of unknown mechanisms. In this chapter, we present a survey of data resources and computational tools available for drug repositioning., (© 2022. Springer Nature Switzerland AG.)

Published

2022

6. Rapid Identification of Druggable Targets and the Power of the PHENotype SIMulator for Effective Drug Repurposing in COVID-19.

Author

Maria NI, Rapicavoli RV, Alaimo S, Bischof E, Stasuzzo A, Broek JAC, Pulvirenti A, Mishra B, Duits AJ, and Ferro A

Abstract

The current, rapidly diversifying pandemic has accelerated the need for efficient and effective identification of potential drug candidates for COVID-19. Knowledge on host-immune response to SARS-CoV-2 infection, however, remains limited with very few drugs approved to date. Viable strategies and tools are rapidly arising to address this, especially with repurposing of existing drugs offering significant promise. Here we introduce a systems biology tool, the PHENotype SIMulator, which - by leveraging available transcriptomic and proteomic databases - allows modeling of SARS-CoV-2 infection in host cells in silico to i) determine with high sensitivity and specificity (both > 96%) the viral effects on cellular host-immune response, resulting in a specific cellular SARS-CoV-2 signature and ii) utilize this specific signature to narrow down promising repurposable therapeutic strategies. Powered by this tool, coupled with domain expertise, we have identified several potential COVID-19 drugs including methylprednisolone and metformin, and further discern key cellular SARS-CoV-2-affected pathways as potential new druggable targets in COVID-19 pathogenesis.

Published

2021