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16 results on '"Di Sante, G"'

1. Time-lapse video microscopy for assessment of EYFP-Parkin aggregation as a marker for cellular mitophagy

Author

Di Sante G., Casimiro M., Pestell T., and Pestell R.

Subjects
FCCP, Issue 111, Mitophagy, Fibroblast, Cellular biology, Time-lapse video microscopy, Mitochondria, Parkin
Abstract

© 2016 Journal of Visualized Experiments.Time-lapse video microscopy can be defined as the real time imaging of living cells. This technique relies on the collection of images at different time points. Time intervals can be set through a computer interface that controls the microscope-integrated camera. This kind of microscopy requires both the ability to acquire very rapid events and the signal generated by the observed cellular structure during these events. After the images have been collected, a movie of the entire experiment is assembled to show the dynamic of the molecular events of interest. Time-lapse video microscopy has a broad range of applications in the biomedical research field and is a powerful and unique tool for following the dynamics of the cellular events in real time. Through this technique, we can assess cellular events such as migration, division, signal transduction, growth, and death. Moreover, using fluorescent molecular probes we are able to mark specific molecules, such as DNA, RNA or proteins and follow them through their molecular pathways and functions. Time-lapse video microscopy has multiple advantages, the major one being the ability to collect data at the single-cell level, that make it a unique technology for investigation in the field of cell biology. However, time-lapse video microscopy has limitations that can interfere with the acquisition of high quality images. Images can be compromised by both external factors; temperature fluctuations, vibrations, humidity and internal factors; pH, cell motility. Herein, we describe a protocol for the dynamic acquisition of a specific protein, Parkin, fused with the enhanced yellow fluorescent protein (EYFP) in order to track the selective removal of damaged mitochondria, using a time-lapse video microscopy approach.

Published
2016

2. Cyclin D1 promotes androgen-dependent DNA damage repair in prostate cancer cells

Author

Casimiro M., Di Sante G., Ju X., Li Z., Chen K., Crosariol M., Yaman I., Gormley M., Meng H., Lisanti M., and Pestell R.

Abstract

© 2016 American Association for Cancer Research.Therapy resistance and poor outcome in prostate cancer is associated with increased expression of cyclin D1. Androgens promoteDNAdouble-strand break repair to reduceDNAdamage, and cyclin D1 was also shown to enhance DNA damage repair (DDR). In this study, we investigated the significance of cyclin D1 in androgen-induced DDR using established prostate cancer cells and prostate tissues from cyclin D1 knockout mice. We demonstrate that endogenous cyclin D1 further diminished the dihydrotestosterone (DHT)-dependent reduction of γH2AX foci in vitro. We also show that cyclin D1 was required for the androgen-dependent DNA damage response both in vitro and in vivo. Furthermore, cyclin D1 was required for androgenenhanced DDR and radioresistance of prostate cancer cells. Moreover, microarray analysis of primary prostate epithelial cells from cyclin D1-deficient and wild-type mice demonstrated that most of the DHT-dependent gene expression changes are also cyclin D1 dependent. Collectively, our findings suggest that the hormonemediated recruitment of cyclin D1 to sites of DDR may facilitate the resistance of prostate cancer cells to DNA damage therapies and highlight the need to explore other therapeutic approaches in prostate cancer to prevent or overcome drug resistance.

Published
2016

3. Kinase-independent role of cyclin D1 in chromosomal instability and mammary tumorigenesis

Author

Casimiro M., Di Sante G., Crosariol M., Loro E., Dampier W., Ertel A., Yu Z., Saria E., Papanikolaou A., Li Z., Wang C., Addya S., Lisanti M., Fortina P., Cardiff R., Tozeren A., Knudsen E., Arnold A., and Pestell R.

Subjects
Breast cancer, Cyclin D1, Chromosomal instability
Abstract

Cyclin D1 is an important molecular driver of human breast cancer but better understanding of its oncogenic mechanisms is needed, especially to enhance efforts in targeted therapeutics. Currently, pharmaceutical initiatives to inhibit cyclin D1 are focused on the catalytic component since the transforming capacity is thought to reside in the cyclin D1/CDK activity. We initiated the following study to directly test the oncogenic potential of catalytically inactive cyclin D1 in an in vivo mouse model that is relevant to breast cancer. Herein, transduction of cyclin D1-/- mouse embryonic fibroblasts (MEFs) with the kinase dead KE mutant of cyclin D1 led to aneuploidy, abnormalities in mitotic spindle formation, autosome amplification, and chromosomal instability (CIN) by gene expression profiling. Acute transgenic expression of either cyclin D1WT or cyclin D1KE in the mammary gland was sufficient to induce a high CIN score within 7 days. Sustained expression of cyclin D1KE induced mammary adenocarcinoma with similar kinetics to that of the wild-type cyclin D1. ChIP-Seq studies demonstrated recruitment of cyclin D1WT and cyclin D1KE to the genes governing CIN. We conclude that the CDK-activating function of cyclin D1 is not necessary to induce either chromosomal instability or mammary tumorigenesis.

Published
2015

14. Skewed T-cell receptor repertoire: More than a marker of malignancy, a tool to dissect the immunopathology of inflammatory diseases

Author

Pandolfi, F., Cianci, R., Casciano, F., Pagliari, D., Pasquale, T., Raffaele Landolfi, Di Sante, G., Kurnick, J. T., and Ria, F.

Subjects
rheumatoid arthritis, T-Lymphocytes, Receptors, Antigen, T-Cell, T-Cell Antigen Receptor Specificity, Immunopathology, Gene Rearrangement, T-Lymphocyte, Lymphocyte Activation, NO, Autoimmune Diseases, Major Histocompatibility Complex, skewed TCR repertoire, Settore MED/04 - PATOLOGIA GENERALE, T-Lymphocyte Subsets, Neoplasms, Receptors, Humans, T-cell receptor, solid tumors melanoma, spectratyping, Gene Rearrangement, Inflammation, Settore MED/09 - MEDICINA INTERNA, Genetic Variation, T-Cell, T-Lymphocyte, Antigen, Biological Markers, TCR, Biomarkers, Spleen
Abstract

The highly diverse heterodimeric surface T cell receptor (TCR) gives the T lymphocyte its specificity for MHC-bound peptides needed to initiate antigen-recognition. In normal peripheral blood, spleen and lymph nodes, the TCR repertoire of the T lymphocytes is usually polyclonal. However, in malignancies such as leukemias, as well as in lymphoproliferative diseases of mature T cells, the TCR is a reflection of the clonality of the malignant cells and is therefore monoclonal. Several clinical conditions (mainly solid tumors and autoimmune diseases) have been described where the TCR repertoire is restricted. The ability to demonstrate clonal TCR usage provides a useful tool to dissect the immunopathology of inflammatory diseases. In this review we discuss these findings and propose to sub-divide diseases with restricted TCR repertoire into a group of conditions in which there is a known TCR ligand, as opposed to diseases in which the restricted TCR repertoire is the result of impaired T-cell development. This classification sheds light on the pathogenesis of several inflammatory diseases.

16. A TLR/CD44 axis regulates T cell trafficking in experimental and human multiple sclerosis

Author

Maria Tredicine, Chiara Camponeschi, Davide Pirolli, Matteo Lucchini, Mariagrazia Valentini, Maria Concetta Geloso, Massimiliano Mirabella, Marco Fidaleo, Benedetta Righino, Camilla Moliterni, Ezio Giorda, Mario Rende, Maria Cristina De Rosa, Maria Foti, Gabriela Constantin, Francesco Ria, Gabriele Di Sante, Tredicine, M, Camponeschi, C, Pirolli, D, Lucchini, M, Valentini, M, Geloso, M, Mirabella, M, Fidaleo, M, Righino, B, Moliterni, C, Giorda, E, Rende, M, De Rosa, M, Foti, M, Constantin, G, Ria, F, and Di Sante, G

Subjects
Settore BIO/16 - ANATOMIA UMANA, Cell biology, Multidisciplinary, Settore MED/04 - PATOLOGIA GENERALE, Molecular biology, Science, Immunology, Molecular modeling, CD44, multiple sclerosis, Article
Abstract

Summary In the pathogenesis of autoimmune disorders, the modulation of leukocytes′ trafficking plays a central role, still poorly understood. Here, we focused on the effect of TLR2 ligands in trafficking of T helper cells through reshuffling of CD44 isoforms repertoire. Concurrently, strain background and TLR2 haplotype affected Wnt/β-catenin signaling pathway and expression of splicing factors. During EAE, mCD44v9-v10 was specifically enriched in the forebrain and showed an increased ability to bind stably to osteopontin. Similarly, we observed that hCD44v7 was highly enriched in cells of cerebrospinal fluid from MS patients with active lesions. Moreover, TLRs engagement modulated the composition of CD44 variants also in human T helper cells, supporting the hypothesis that pathogens or commensals, through TLRs, in turn modulate the repertoire of CD44 isoforms, thereby controlling the distribution of lesions in the CNS. The interference with this mechanism(s) represents a potential tool for prevention and treatment of autoimmune relapses and exacerbations., Graphical abstract Host-Pathogen interaction modulating T cell trafficking and tissue infiltration through CD44 variants (CD44v). Circulating T cells through lymphoid and non-lymphoid organs, regulate homeostasis of immune system. The environment could lead an imbalance, also acting on the ability of T cells to move. The expression of certain CD44 isoforms can explain the ability of T cells to infiltrate into the CNS of patients affected by multiple sclerosis, crossing the blood brain barrier. This effect seems to be associated with microbial products, able to modulate CD44 splicing on T cells, that regulate their ability to move (Vestweber, 2015). Created with Biorender.com., Highlights • Environment and genetic are both involved in the regulation of T cell motility • Pathogens and commensals impact on T cell trafficking through a TLRs/CD44v axis • Regulation of CD44 isoforms by TLRs is a new pathogenetic mechanism of autoimmunity • Modulation of CD44 isoform can be a new target for therapy of multiple sclerosis, Molecular biology; Immunology; Cell biology

Published
2022

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