Your search keyword '"Cazzetta, Valentina"' showing total 14 results

1. Expansion of memory Vδ2 T cells following SARS-CoV-2 vaccination revealed by temporal single-cell transcriptomics

Author

Terzoli, Sara, Marzano, Paolo, Cazzetta, Valentina, Piazza, Rocco, Sandrock, Inga, Ravens, Sarina, Tan, Likai, Prinz, Immo, Balin, Simone, Calvi, Michela, Carletti, Anna, Cancellara, Assunta, Coianiz, Nicolò, Franzese, Sara, Frigo, Alessandro, Voza, Antonio, Calcaterra, Francesca, Di Vito, Clara, Della Bella, Silvia, Mikulak, Joanna, and Mavilio, Domenico

Published

2024

2. The long Pentraxin PTX3 serves as an early predictive biomarker of co-infections in COVID-19

Author

Accornero, Stefano, Aghemo, Alessio, Ali, Hussam, Angelini, Claudio, Arcari, Ivan, Arosio, Paola, Azzolini, Elena, Baccarin, Alessandra, Badalamenti, Salvatore, Baggio, Sara, Barbagallo, Michela, Barberi, Caterina, Barbic, Franca, Barbieri, Viviana, Barbone, Alessandro, Basciu, Alessio, Bocciolone, Monica, Borea, Federica, Borroni, Mario, Bresciani, Gianluigi, Brunetta, Enrico, Bulletti, Cinzia, Cadonati, Cristina, Calabro', Lorenzo, Calatroni, Marta, Calvetta Albania, Antonietta, Cannata, Francesco, Canziani, Lorenzo, Capretti Giovanni, Luigi, Carlani, Elisa, Carrone, Flaminia, Casana, Maddalena, Cecconi, Maurizio, Ceriotti, Carlo, Ciccarelli, Michele, Cimino, Matteo, Ciuffini, Leonardo, Colaizzi, Chiara, Colapietro, Francesca, Costa, Guido, Cozzi, Ottavia, Craviotto, Vincenzo, Crespi, Chiara, Crippa, Massimo, Da Rio, Leonardo, Dal Farra, Sara, D'Antonio, Federica, De Ambroggi, Guido, De Donato, Massimo, De Lucia, Francesca, De Santis, Maria, Delle Rose, Giacomo, Di Pilla, Marina, Dipaola, Franca, Dipasquale, Andrea, Dipasquale, Angelo, Droandi, Ginevra, Fazio, Roberta, Ferrante, Giuseppe, Ferrara Elisa, Chiara, Ferrari Matteo, Carlo, Ferri, Sebastian, Folci, Marco, Foresti, Sara, Franchi, Eloisa, Fraolini, Elia, Fugazza, Alessandro, Furfaro, Federica, Galimberti, Paola, Galtieri Alessia, Piera, Gavazzi, Francesca, Generali, Elena, Goletti, Benedetta, Guidelli, Giacomo, Jacobs, Flavia, Kurihara, Hayato, Lagioia, Michele, Libre', Luca, Lleo, Ana, Loiacono, Ferdinando, Lughezzani, Giovanni, Maccallini, Marta, Maiorino Alfonso, Francesco, Malesci, Alberto, Mantovani, Riccardo, Marchettini, Davide, Marinello, Arianna, Markopoulos, Nikolaos, Masetti, Chiara, Milani, Angelo, Mirani, Marco, Morelli, Paola, Motta, Francesca, Mundula, Valeria, Nigro, Mattia, Omodei, Paolo, Ormas, Monica, Pagliaro, Arianna, Paliotti, Roberta, Parigi Tommaso, Lorenzo, Pedale, Rosa, Pegoraro, Francesco, Pellegatta, Gaia, Pellegrino, Marta, Petriello, Gennaro, Piccini, Sara, Pocaterra, Daria, Poliani, Laura, Preatoni, Paoletta, Procopio, Fabio, Puggioni, Francesca, Pugliese, Luca, Racca, Francesca, Randazzo, Michele, Regazzoli Lancini, Damiano, Reggiani, Francesco, Rodolfi, Stefano, Ruongo, Lidia, Sacco, Clara, Sandri Maria, Teresa, Savi, Marzia, Scarfo', Iside, Shiffer, Dana, Sicoli, Federico, Solano, Simone, Solitano, Virginia, Stainer, Anna, Stella Matteo, Carlo, Strangio, Giuseppe, Taormina, Antonio, Testoni, Lucia, Tordato, Federica, Trabucco, Angela, Ulian, Luisa, Valentino, Rossella, Valeriano, Chiara, Vena, Walter, Verlingieri, Simona, Vespa, Edoardo, Voza, Antonio, Zanuso, Valentina, Zilli, Alessandra, Anfray, Clement, Belgiovine, Cristina, Bertocchi, Alice, Bombace, Sara, Brescia, Paola, Calcaterra, Francesca, Calvi, Michela, Cancellara, Assunta, Capucetti, Arianna, Carenza, Claudia, Carloni, Sara, Carnevale, Silvia, Cazzetta, Valentina, Coianiz, Nicolò, Darwich, Abbass, Davoudian, Sadaf, De Paoli, Federica, Di Donato, Rachele, Digifico, Elisabeth, Durante, Barbara, Farina Floriana, Maria, Ferrari, Valentina, Fornasa, Giulia, Franzese, Sara, Ghasemi, Somayehsadat, Gil Gomez, Antonio, Giugliano, Silvia, Gomes Ana, Rita, Lizier, Michela, Lo Cascio, Antonino, Melacarne, Alessia, Mozzarelli, Alessandro, My, Ilaria, Oresta, Bianca, Pasqualini, Fabio, Pastò, Anna, Pelamatti, Erica, Perucchini, Chiara, Pozzi, Chiara, Rimoldi, Valeria, Rimoldi, Monica, Scarpa, Alice, Scavello, Francesco, Silvestri, Alessandra, Sironi, Marina, Spadoni, Ilaria, Spano', Salvatore, Spata, Gianmarco, Supino, Domenico, Tentorio, Paolo, Ummarino, Aldo, Valentino, Sonia, Zaghi, Elisa, Zanon, Veronica, Mapelli, Sarah N., Nappi, Emanuele, García Martín, Ian David, Leone, Roberto, Angelotti, Giovanni, Zhong, Hang, Magrini, Elena, Stravalaci, Matteo, Protti, Alessandro, Santini, Alessandro, Costantini, Elena, Savevski, Victor, Bottazzi, Barbara, Bartoletti, Michele, Mantovani, Alberto, and Garlanda, Cecilia

Published

2024

3. BNT162b2 vaccine induces antibody release in saliva: a possible role for mucosal viral protection?

Author

Abbass Darwich, Chiara Pozzi, Giulia Fornasa, Michela Lizier, Elena Azzolini, Ilaria Spadoni, Francesco Carli, Antonio Voza, Antonio Desai, Carlo Ferrero, Luca Germagnoli, ICH COVID‐19 Task‐force, Alberto Mantovani, Maria Rescigno, Aghemo Alessio, Anfray Clement, Badalamenti Salvatore, Belgiovine Cristina, Bertocchi Alice, Bombace Sara, Brescia Paola, Calcaterra Francesca, Calvi Michela, Cancellara Assunta, Capucetti Arianna, Carenza Claudia, Carloni Sara, Carnevale Silvia, Cazzetta Valentina, Cecconi Maurizio, Ciccarelli Michele, Coianiz Nicolò, Darwich Abbass, Ana Lleo De Nalda, De Paoli Federica, Di Donato Rachele, Digifico Elisabeth, Durante Barbara, Farina Floriana Maria, Ferrari Valentina, Fornasa Giulia, Franzese Sara, Gil Gomez Antonio, Giugliano Silvia, Ana Rita Gomes, Lizier Michela, Lo Cascio Antonino, Melacarne Alessia, Mozzarelli Alessandro, My Ilaria, Oresta Bianca, Pasqualini Fabio, Pastò Anna, Pelamatti Erica, Perucchini Chiara, Pozzi Chiara, Rimoldi Valeria, Rimoldi Monica, Scarpa Alice, Selmi Carlo, Silvestri Alessandra, Sironi Marina, Spadoni Ilaria, Spano' Salvatore, Spata Gianmarco, Supino Domenico, Tentorio Paolo, Ummarino Aldo, Valentino Sonia, Voza Antonio, Zaghi Elisa, and Zanon Veronica

Subjects

BNT162b2, IgA, IgG, mucosal immunity, SARS‐CoV‐2, Medicine (General), R5-920, Genetics, QH426-470

Abstract

Abstract Vaccination against an airborne pathogen is very effective if it induces also the development of mucosal antibodies that can protect against infection. The mRNA‐based vaccine‐encoding SARS‐CoV‐2 full‐length spike protein (BNT162b2, Pfizer/BioNTech) protects also against infection despite being administered systemically. Here, we show that upon vaccination, cognate IgG molecules are also found in the saliva and are more abundant in SARS‐CoV‐2 previously exposed subjects, paralleling the development of plasma IgG. The antibodies titer declines at 3 months from vaccination. We identified a concentration of specific IgG in the plasma above which the relevant IgG can be detected in the saliva. Regarding IgA antibodies, we found only protease‐susceptible IgA1 antibodies in plasma while they were present at very low levels in the saliva over the course of vaccination of SARS‐CoV‐2‐naïve subjects. Thus, in response to BNT162b2 vaccine, plasma IgG can permeate into mucosal sites and participate in viral protection. It is not clear why IgA1 are detected in low amount, they may be proteolytically cleaved.

Published

2022

4. A ‘Multiomic’ Approach of Saliva Metabolomics, Microbiota, and Serum Biomarkers to Assess the Need of Hospitalization in Coronavirus Disease 2019

Author

Chiara Pozzi, Riccardo Levi, Daniele Braga, Francesco Carli, Abbass Darwich, Ilaria Spadoni, Bianca Oresta, Carola Conca Dioguardi, Clelia Peano, Leonardo Ubaldi, Giovanni Angelotti, Barbara Bottazzi, Cecilia Garlanda, Antonio Desai, Antonio Voza, Elena Azzolini, Maurizio Cecconi, Alberto Mantovani, Giuseppe Penna, Riccardo Barbieri, Letterio S. Politi, Maria Rescigno, Aghemo Alessio, Anfray Clement, Badalamenti Salvatore, Belgiovine Cristina, Bertocchi Alice, Bombace Sara, Brescia Paola, Calcaterra Francesca, Calvi Michela, Cancellara Assunta, Capucetti Arianna, Carenza Claudia, Carloni Sara, Carnevale Silvia, Cazzetta Valentina, Cecconi Maurizio, Ciccarelli Michele, Coianiz Nicolò, Darwich Abbass, Lleo de Nalda Ana, De Paoli Federica, Di Donato Rachele, Digifico Elisabeth, Durante Barbara, FARINA Floriana Maria, Ferrari Valentina, Fornasa Giulia, Franzese Sara, Gil Gomez Antonio, Giugliano Silvia, Gomes Ana Rita, Lizier Michela, Lo Cascio Antonino, Melacarne Alessia, Mozzarelli Alessandro, My Ilaria, Oresta Bianca, Pasqualini Fabio, Pastò Anna, Pelamatti Erica, Perucchini Chiara, Pozzi Chiara, Rimoldi Valeria, Rimoldi Monica, Scarpa Alice, Selmi Carlo, Silvestri Alessandra, Sironi Marina, Spadoni Ilaria, Spano' Salvatore, Spata Gianmarco, Supino Domenico, Tentorio Paolo, Ummarino Aldo, Valentino Sonia, Voza Antonio, Zaghi Elisa, and Zanon Veronica

Subjects

Metabolome, Microbiota, CHI3L1, COVID-19, Diseases of the digestive system. Gastroenterology, RC799-869

Abstract

Background and Aims: The SARS-CoV-2 pandemic has overwhelmed the treatment capacity of the health care systems during the highest viral diffusion rate. Patients reaching the emergency department had to be either hospitalized (inpatients) or discharged (outpatients). Still, the decision was taken based on the individual assessment of the actual clinical condition, without specific biomarkers to predict future improvement or deterioration, and discharged patients often returned to the hospital for aggravation of their condition. Here, we have developed a new combined approach of omics to identify factors that could distinguish coronavirus disease 19 (COVID-19) inpatients from outpatients. Methods: Saliva and blood samples were collected over the course of two observational cohort studies. By using machine learning approaches, we compared salivary metabolome of 50 COVID-19 patients with that of 270 healthy individuals having previously been exposed or not to SARS-CoV-2. We then correlated the salivary metabolites that allowed separating COVID-19 inpatients from outpatients with serum biomarkers and salivary microbiota taxa differentially represented in the two groups of patients. Results: We identified nine salivary metabolites that allowed assessing the need of hospitalization. When combined with serum biomarkers, just two salivary metabolites (myo-inositol and 2-pyrrolidineacetic acid) and one serum protein, chitinase 3-like-1 (CHI3L1), were sufficient to separate inpatients from outpatients completely and correlated with modulated microbiota taxa. In particular, we found Corynebacterium 1 to be overrepresented in inpatients, whereas Actinomycetaceae F0332, Candidatus Saccharimonas, and Haemophilus were all underrepresented in the hospitalized population. Conclusion: This is a proof of concept that a combined omic analysis can be used to stratify patients independently from COVID-19.

Published

2022

5. APOL1 polymorphism modulates sphingolipid profile of human podocytes

Author

Valsecchi, Manuela, Cazzetta, Valentina, Oriolo, Ferdinando, Lan, Xiqian, Piazza, Rocco, Saleem, Moin A., Singhal, Pravin C., Mavilio, Domenico, Mikulak, Joanna, and Aureli, Massimo

Published

2020

6. Chemotherapy accelerates immune-senescence and functional impairments of Vδ2pos T cells in elderly patients affected by liver metastatic colorectal cancer

Author

Bruni, Elena, Cazzetta, Valentina, Donadon, Matteo, Cimino, Matteo, Torzilli, Guido, Spata, Gianmarco, Leonardi, Gloria, Dieli, Francesco, Mikulak, Joanna, and Mavilio, Domenico

Published

2019

7. Transcriptomic profile of TNFhigh MAIT cells is linked to B cell response following SARS-CoV-2 vaccination.

Author

Marzano, Paolo, Balin, Simone, Terzoli, Sara, Bella, Silvia Della, Cazzetta, Valentina, Piazza, Rocco, Sandrock, Inga, Ravens, Sarina, Tan, Likai, Prinz, Immo, Calcaterra, Francesca, Di Vito, Clara, Cancellara, Assunta, Calvi, Michela, Carletti, Anna, Franzese, Sara, Frigo, Alessandro, Darwish, Ahmed, Voza, Antonio, and Mikulak, Joanna

Subjects

B cells, MONONUCLEAR leukocytes, SARS-CoV-2, VACCINATION, IMMUNOLOGIC memory

Abstract

Introduction: Higher frequencies of mucosal-associated invariant T (MAIT) cells were associated with an increased adaptive response to mRNA BNT162b2 SARSCoV- 2 vaccine, however, the mechanistic insights into this relationship are unknown. In the present study, we hypothesized that the TNF response of MAIT cells supports B cell activation following SARS-CoV-2 immunization. Methods: To investigate the effects of repeated SARS-CoV-2 vaccinations on the peripheral blood mononuclear cells (PBMCs), we performed a longitudinal single cell (sc)RNA-seq and scTCR-seq analysis of SARS-CoV-2 vaccinated healthy adults with two doses of the Pfizer-BioNTech BNT162b2 mRNA vaccine. Collection of PBMCs was performed 1 day before, 3 and 17 days after prime vaccination, and 3 days and 3 months following vaccine boost. Based on scRNA/TCR-seq data related to regulatory signals induced by the vaccine, we used computational approaches for the functional pathway enrichment analysis (Reactome), dynamics of the effector cell-polarization (RNA Velocity and CellRank), and cell-cell communication (NicheNet). Results: We identified MAIT cells as an important source of TNF across circulating lymphocytes in response to repeated SARS-CoV-2 BNT162b2 vaccination. The TNFhigh signature of MAIT cells was induced by the second administration of the vaccine. Notably, the increased TNF expression was associated with MAIT cell proliferation and efficient anti-SARS-CoV-2 antibody production. Finally, by decoding the ligand-receptor interactions and incorporating intracellular signaling, we predicted TNFhigh MAIT cell interplay with different B cell subsets. In specific, predicted TNF-mediated activation was selectively directed to conventional switched memory B cells, which are deputed to high-affinity long-term memory. Discussion: Overall, our results indicate that SARS-CoV-2 BNT162b2 vaccination influences MAIT cell frequencies and their transcriptional effector profile with the potential to promote B cell activation. This research also provides a blueprint for the promising use of MAIT cells as cellular adjuvants in mRNA-based vaccines. [ABSTRACT FROM AUTHOR]

Published

2023

8. Identification of Tissue-Resident Natural Killer and T Lymphocytes with Anti-Tumor Properties in Ascites of Ovarian Cancer Patients.

Author

Bernson, Elin, Huhn, Oisín, Karlsson, Veronika, Hawkes, Delia, Lycke, Maria, Cazzetta, Valentina, Mikulak, Joanna, Hall, James, Piskorz, Anna M., Portuesi, Rosalba, Vitobello, Domenico, Fiamengo, Barbara, Siesto, Gabriele, Horowitz, Amir, Ghadially, Hormas, Mavilio, Domenico, Brenton, James D., Sundfeldt, Karin, and Colucci, Francesco

Subjects

OVARIAN tumors, ANIMAL experimentation, KILLER cells, ANTINEOPLASTIC agents, CELL receptors, ASCITES, CANCER patients, GENE expression, T cells, TUMOR markers, IMMUNOTHERAPY

Abstract

Simple Summary: Ovarian cancer is the deadliest among gynecological cancers, and there is a huge demand for new treatments for these patients. Immunotherapy holds great potential in cancer treatment, but has not yet proven successful for the majority of ovarian cancer patients. To better understand the immunological landscape of the disease, we have characterized lymphocytes in patients with high-grade serous ovarian cancer. Natural killer cells and T cells are present in both primary tumors and in the metastasizing environment of ascites, a fluid in the abdominal cavity that is developed in many patients with ovarian cancer. Our data reveal that a large fraction of these natural killer cells and T cells express tissue-resident markers and the inhibitory receptor, NKG2A, and are able to kill ovarian cancer cells. In summary, we report a functional subset of lymphocytes that may be targeted in future immunotherapeutic approaches. Women with ovarian cancer have limited therapy options, with immunotherapy being unsatisfactory for a large group of patients. Tumor cells spread from the ovary or the fallopian tube into the abdominal cavity, which is commonly accompanied with massive ascites production. The ascites represents a unique peritoneal liquid tumor microenvironment with the presence of both tumor and immune cells, including cytotoxic lymphocytes. We characterized lymphocytes in ascites from patients with high-grade serous ovarian cancer. Our data reveal the presence of NK and CD8+ T lymphocytes expressing CD103 and CD49a, which are markers of tissue residency. Moreover, these cells express high levels of the inhibitory NKG2A receptor, with the highest expression level detected on tissue-resident NK cells. Lymphocytes with these features were also present at the primary tumor site. Functional assays showed that tissue-resident NK cells in ascites are highly responsive towards ovarian tumor cells. Similar results were observed in an in vivo mouse model, in which tissue-resident NK and CD8+ T cells were detected in the peritoneal fluid upon tumor growth. Together, our data reveal the presence of highly functional lymphocyte populations that may be targeted to improve immunotherapy for patients with ovarian cancer. [ABSTRACT FROM AUTHOR]

Published

2023

9. NKG2A Immune Checkpoint in Vδ2 T Cells: Emerging Application in Cancer Immunotherapy.

Author

Cazzetta, Valentina, Depierreux, Delphine, Colucci, Francesco, Mikulak, Joanna, and Mavilio, Domenico

Subjects

*TUMOR treatment, *IMMUNE checkpoint inhibitors, *CELL receptors, *IMMUNOMODULATORS, *KILLER cells, *CELL physiology, *MONOCLONAL antibodies, *GENE expression, *T cells, *CELL lines, *IMMUNOTHERAPY

Abstract

Simple Summary: Boosting effector T cell anti-tumor response remains a challenge, in part owing to the expression of immune checkpoints and their ligands, such as NKG2A and HLA-E. Targeting NKG2A by gene knockout or blocking antibodies improves the cytotoxicity of Vδ2 T cells, a specific subset of human unconventional γδ T lymphocytes. Thus, a suitable selection of NKG2A+ or NKG2A− Vδ2 T cells for expansion or engineering could help to narrow the Vδ2 T cell population according to the expression of HLA-E on tumor cells. With this emerging knowledge, approaches to target NKG2A in Vδ2 T cells might be a promising step forward to boosting Vδ2 T cell-based cancer immunotherapies. Immune regulation has revolutionized cancer treatment with the introduction of T-cell-targeted immune checkpoint inhibitors (ICIs). This successful immunotherapy has led to a more complete view of cancer that now considers not only the cancer cells to be targeted and destroyed but also the immune environment of the cancer cells. Current challenges associated with the enhancement of ICI effects are increasing the fraction of responding patients through personalized combinations of multiple ICIs and overcoming acquired resistance. This requires a complete overview of the anti-tumor immune response, which depends on a complex interplay between innate and adaptive immune cells with the tumor microenvironment. The NKG2A was revealed to be a key immune checkpoint for both Natural Killer (NK) cells and T cells. Monalizumab, a humanized anti-NKG2A antibody, enhances NK cell activity against various tumor cells and rescues CD8 αβ T cell function in combination with PD-1/PD-L1 blockade. In this review, we discuss the potential for targeting NKG2A expressed on tumor-sensing human γδ T cells, mostly on the specific Vδ2 T cell subset, in order to emphasize its importance and potential in the development of new ICI-based therapeutic approaches. [ABSTRACT FROM AUTHOR]

Published

2023

10. NKG2A expression identifies a subset of human Vδ2 T cells exerting the highest antitumor effector functions.

Author

Cazzetta, Valentina, Bruni, Elena, Terzoli, Sara, Carenza, Claudia, Franzese, Sara, Piazza, Rocco, Marzano, Paolo, Donadon, Matteo, Torzilli, Guido, Cimino, Matteo, Simonelli, Matteo, Bello, Lorenzo, Villa, Anna, Tan, Likai, Ravens, Sarina, Prinz, Immo, Supino, Domenico, Colombo, Federico S., Lugli, Enrico, and Marcenaro, Emanuela

Abstract

Human Vδ2 cells are innate-like γδ T effectors performing potent immune surveillance against tumors. The constitutive expression of NKG2A identifies a subset of Vδ2 T cells licensed with an intrinsic hyper-responsiveness against cancer. Indeed, the transcriptomic profiles of NKG2A+ and NKG2A− cells characterize two distinct "intralineages" of Vδ2 T lymphocytes that appear early during development, keep their phenotypes, and show self-renewal capabilities in adult life. The hyper-responsiveness of NKG2A+ Vδ2 T cells is counterbalanced by the inhibitory signaling delivered by human leukocyte antigen E (HLA-E) expressed on malignant cells as a tumor-escape mechanism. However, either masking or knocking out NKG2A restores the capacity of Vδ2 T cells to exert the highest effector functions even against HLA-E+ tumors. This is highly relevant in the clinic, as the different degrees of engagement of the NKG2A-HLA-E checkpoint in hepatocellular carcinoma, glioblastoma, and non-small cell lung cancer directly impact patients' overall survival. These findings open avenues for developing combined cellular and immunologic anticancer therapies. [Display omitted] • NKG2A identifies a Vδ2 T cell cluster "educated" to hyper-responsiveness against cancer • Vδ2 T cell activation is finely tuned by NKG2A binding with HLA-E on cancer cells • NKG2A+ Vδ2 T cells are expandable in vitro from their precursors and are self-renewable • Targeting NKG2A on Vδ2 T cells can prevent tumor escape from immune surveillance Cazzetta et al. show that NKG2A expression identifies a subset of human self-renewable Vδ2 T cells "educated" to perform the highest effector functions in the clearance of cancer cells. The development of immunotherapy protocols targeting tumor-infiltrating NKG2A+ Vδ2 T cells can be effective in improving patients' prognosis in several solid tumors. [ABSTRACT FROM AUTHOR]

Published

2021

11. Natural Killer–Dendritic Cell Interactions in Liver Cancer: Implications for Immunotherapy.

Author

Cazzetta, Valentina, Franzese, Sara, Carenza, Claudia, Della Bella, Silvia, Mikulak, Joanna, Mavilio, Domenico, and Di Tommaso, Luca

Subjects

*THERAPEUTIC use of antineoplastic agents, *DENDRITIC cells, *CYTOKINES, *LIVER tumors, *CHOLANGIOCARCINOMA, *KILLER cells, *CELL communication, *CELL motility, *CELL proliferation, *CHEMOKINES, *TUMOR antigens, *IMMUNOTHERAPY, *HEPATOCELLULAR carcinoma

Abstract

Simple Summary: The reciprocal crosstalk between dendritic cells (DCs) and natural killer (NK) cells plays a pivotal role in regulating immune defense against viruses and tumors. The Th-cell polarizing ability, cytokine-producing capacity, chemokine expression, and migration of DCs are regulated by activated NK cells. Conversely, the effector functions including lysis and cytokine production, proliferation, and migration of NK cells are influenced by close interactions with activated DCs. In this review, we explore the impact of DC–NK cell crosstalk and its therapeutic potential in immune control of liver malignances. Natural killer (NK) and dendritic cells (DCs) are innate immune cells that play a crucial role in anti-tumor immunity. NK cells kill tumor cells through direct cytotoxicity and cytokine secretion. DCs are needed for the activation of adaptive immune responses against tumor cells. Both NK cells and DCs are subdivided in several subsets endowed with specialized effector functions. Crosstalk between NK cells and DCs leads to the reciprocal control of their activation and polarization of immune responses. In this review, we describe the role of NK cells and DCs in liver cancer, focusing on the mechanisms involved in their reciprocal control and activation. In this context, intrahepatic NK cells and DCs present unique immunological features, due to the constant exposure to non-self-circulating antigens. These interactions might play a fundamental role in the pathology of primary liver cancer, namely hepatocellular carcinoma (HCC) and intrahepatic cholangiocarcinoma (ICC). Additionally, the implications of these immune changes are relevant from the perspective of improving the cancer immunotherapy strategies in HCC and ICC patients. [ABSTRACT FROM AUTHOR]

Published

2021

12. Transcriptomic profile of TNF high MAIT cells is linked to B cell response following SARS-CoV-2 vaccination.

Author

Marzano P, Balin S, Terzoli S, Della Bella S, Cazzetta V, Piazza R, Sandrock I, Ravens S, Tan L, Prinz I, Calcaterra F, Di Vito C, Cancellara A, Calvi M, Carletti A, Franzese S, Frigo A, Darwish A, Voza A, Mikulak J, and Mavilio D

Subjects

Adult, Humans, COVID-19 Vaccines, BNT162 Vaccine, Leukocytes, Mononuclear, Transcriptome, SARS-CoV-2, Vaccination, Mucosal-Associated Invariant T Cells, COVID-19 prevention & control

Abstract

Introduction: Higher frequencies of mucosal-associated invariant T (MAIT) cells were associated with an increased adaptive response to mRNA BNT162b2 SARS-CoV-2 vaccine, however, the mechanistic insights into this relationship are unknown. In the present study, we hypothesized that the TNF response of MAIT cells supports B cell activation following SARS-CoV-2 immunization., Methods: To investigate the effects of repeated SARS-CoV-2 vaccinations on the peripheral blood mononuclear cells (PBMCs), we performed a longitudinal single cell (sc)RNA-seq and scTCR-seq analysis of SARS-CoV-2 vaccinated healthy adults with two doses of the Pfizer-BioNTech BNT162b2 mRNA vaccine. Collection of PBMCs was performed 1 day before, 3 and 17 days after prime vaccination, and 3 days and 3 months following vaccine boost. Based on scRNA/TCR-seq data related to regulatory signals induced by the vaccine, we used computational approaches for the functional pathway enrichment analysis (Reactome), dynamics of the effector cell-polarization (RNA Velocity and CellRank), and cell-cell communication (NicheNet)., Results: We identified MAIT cells as an important source of TNF across circulating lymphocytes in response to repeated SARS-CoV-2 BNT162b2 vaccination. The TNF high signature of MAIT cells was induced by the second administration of the vaccine. Notably, the increased TNF expression was associated with MAIT cell proliferation and efficient anti-SARS-CoV-2 antibody production. Finally, by decoding the ligand-receptor interactions and incorporating intracellular signaling, we predicted TNF high MAIT cell interplay with different B cell subsets. In specific, predicted TNF -mediated activation was selectively directed to conventional switched memory B cells, which are deputed to high-affinity long-term memory., Discussion: Overall, our results indicate that SARS-CoV-2 BNT162b2 vaccination influences MAIT cell frequencies and their transcriptional effector profile with the potential to promote B cell activation. This research also provides a blueprint for the promising use of MAIT cells as cellular adjuvants in mRNA-based vaccines., Competing Interests: The authors declare that the research was conducted in the absence of any commercial or financial relationships that could be construed as a potential conflict of interest., (Copyright © 2023 Marzano, Balin, Terzoli, Della Bella, Cazzetta, Piazza, Sandrock, Ravens, Tan, Prinz, Calcaterra, Di Vito, Cancellara, Calvi, Carletti, Franzese, Frigo, Darwish, Voza, Mikulak and Mavilio.)

Published

2023

13. Intrahepatic CD69 + Vδ1 T cells re-circulate in the blood of patients with metastatic colorectal cancer and limit tumor progression.

Author

Bruni E, Cimino MM, Donadon M, Carriero R, Terzoli S, Piazza R, Ravens S, Prinz I, Cazzetta V, Marzano P, Kunderfranco P, Peano C, Soldani C, Franceschini B, Colombo FS, Garlanda C, Mantovani A, Torzilli G, Mikulak J, and Mavilio D

Subjects

Humans, Immunotherapy, Lymphocytes, Tumor-Infiltrating, Receptors, Antigen, T-Cell, gamma-delta, Tumor Microenvironment, Colorectal Neoplasms immunology, Colorectal Neoplasms pathology, T-Lymphocyte Subsets cytology

Abstract

Background: More than 50% of all patients with colorectal cancer (CRC) develop liver metastases (CLM), a clinical condition characterized by poor prognosis and lack of reliable prognostic markers. Vδ1 cells are a subset of tissue-resident gamma delta (γδ) T lymphocytes endowed with a broad array of antitumor functions and showing a natural high tropism for the liver. However, little is known about their impact in the clinical outcomes of CLM., Methods: We isolated human γδ T cells from peripheral blood (PB) and peritumoral (PT) tissue of 93 patients undergone surgical procedures to remove CLM. The phenotype of freshly purified γδ T cells was assessed by multiparametric flow cytometry, the transcriptional profiles by single cell RNA-sequencing, the functional annotations by Gene Ontology enrichment analyses and the clonotype by γδ T cell receptor (TCR)-sequencing., Results: The microenvironment of CLM is characterized by a heterogeneous immune infiltrate comprising different subsets of γδ tumor-infiltrating lymphocytes (TILs) able to egress the liver and re-circulate in PB. Vδ1 T cells represent the largest population of γδ TILs within the PT compartment of CLM that is greatly enriched in Vδ1 T effector (T EF ) cells expressing constitutive high levels of CD69. These Vδ1 CD69 + TILs express a distinct phenotype and transcriptional signature, show high antitumor potential and correlate with better patient clinical outcomes in terms of lower numbers of liver metastatic lesions and longer overall survival (OS). Moreover, intrahepatic CD69 + Vδ1 TILs can egress CLM tissue to re-circulate in PB, where they retain a phenotype, transcriptional signature and TCR clonal repertoires resembling their liver origin. Importantly, even the increased frequencies of the CD69 + terminally differentiated (T EMRA ) Vδ1 cells in PB of patients with CLM significantly correlate with longer OS. The positive prognostic score of high frequencies of CD69 + T EMRA Vδ1 cells in PB is independent from the neoadjuvant chemotherapy and immunotherapy regimens administered to patients with CLM prior surgery., Conclusions: The enrichment of tissue-resident CD69 + Vδ1 T EMRA cells re-circulating at high frequencies in PB of patients with CLM limits tumor progression and represents a new important clinical tool to either predict the natural history of CLM or develop alternative therapeutic protocols of cellular therapies., Competing Interests: Competing interests: None declared., (© Author(s) (or their employer(s)) 2022. Re-use permitted under CC BY-NC. No commercial re-use. See rights and permissions. Published by BMJ.)

Published

2022

14. Tumor microenvironment in primary liver tumors: A challenging role of natural killer cells.

Author

Polidoro MA, Mikulak J, Cazzetta V, Lleo A, Mavilio D, Torzilli G, and Donadon M

Subjects

Bile Ducts, Intrahepatic, Endothelial Cells, Humans, Killer Cells, Natural, Tumor Microenvironment, Bile Duct Neoplasms, Carcinoma, Hepatocellular, Liver Neoplasms

Abstract

In the last years, several studies have been focused on elucidate the role of tumor microenvironment (TME) in cancer development and progression. Within TME, cells from adaptive and innate immune system are one of the main abundant components. The dynamic interactions between immune and cancer cells lead to the activation of complex molecular mechanisms that sustain tumor growth. This important cross-talk has been elucidate for several kind of tumors and occurs also in patients with liver cancer, such as hepatocellular carcinoma (HCC) and intrahepatic cholangiocarcinoma (iCCA). Liver is well-known to be an important immunological organ with unique microenvironment. Here, in normal conditions, the rich immune-infiltrating cells cooperate with non-parenchymal cells, such as liver sinusoidal endothelial cells and Kupffer cells, favoring self-tolerance against gut antigens. The presence of underling liver immunosuppressive microenvironment highlights the importance to dissect the interaction between HCC and iCCA cells with immune infiltrating cells, in order to understand how this cross-talk promotes tumor growth. Deeper attention is, in fact, focused on immune-based therapy for these tumors, as promising approach to counteract the intrinsic anti-tumor activity of this microenvironment. In this review, we will examine the key pathways underlying TME cell-cell communications, with deeper focus on the role of natural killer cells in primary liver tumors, such as HCC and iCCA, as new opportunities for immune-based therapeutic strategies., Competing Interests: Conflict-of-interest statement: All other authors have nothing to disclose., (©The Author(s) 2020. Published by Baishideng Publishing Group Inc. All rights reserved.)

Published

2020