Your search keyword '"Giannou, Anastasios D."' showing total 5 results

1. Fetal lung growth predicts the risk for early-life respiratory infections and childhood asthma.

Author

Zazara DE, Giannou O, Schepanski S, Pagenkemper M, Giannou AD, Pincus M, Belios I, Bonn S, Muntau AC, Hecher K, Diemert A, and Arck PC

Subjects

Humans, Female, Pregnancy, Male, Child, Preschool, Risk Assessment, Infant, Predictive Value of Tests, Machine Learning, Adult, Infant, Newborn, Cohort Studies, Risk Factors, Asthma epidemiology, Respiratory Tract Infections diagnostic imaging, Respiratory Tract Infections epidemiology, Lung diagnostic imaging, Ultrasonography, Prenatal, Fetal Development

Abstract

Background: Early-life respiratory infections and asthma are major health burdens during childhood. Markers predicting an increased risk for early-life respiratory diseases are sparse. Here, we identified the predictive value of ultrasound-monitored fetal lung growth for the risk of early-life respiratory infections and asthma., Methods: Fetal lung size was serially assessed at standardized time points by transabdominal ultrasound in pregnant women participating in a pregnancy cohort. Correlations between fetal lung growth and respiratory infections in infancy or early-onset asthma at five years were examined. Machine-learning models relying on extreme gradient boosting regressor or classifier algorithms were developed to predict respiratory infection or asthma risk based on fetal lung growth. For model development and validation, study participants were randomly divided into a training and a testing group, respectively, by the employed algorithm., Results: Enhanced fetal lung growth throughout pregnancy predicted a lower early-life respiratory infection risk. Male sex was associated with a higher risk for respiratory infections in infancy. Fetal lung growth could also predict the risk of asthma at five years of age. We designed three machine-learning models to predict the risk and number of infections in infancy as well as the risk of early-onset asthma. The models' R 2 values were 0.92, 0.90 and 0.93, respectively, underscoring a high accuracy and agreement between the actual and predicted values. Influential variables included known risk factors and novel predictors, such as ultrasound-monitored fetal lung growth., Conclusion: Sonographic monitoring of fetal lung growth allows to predict the risk for early-life respiratory infections and asthma., (© 2024. The Author(s).)

Published

2024

2. Tissue-resident immunity in the lung: a first-line defense at the environmental interface.

Author

Zazara DE, Belios I, Lücke J, Zhang T, and Giannou AD

Subjects

Humans, Adaptive Immunity, Homeostasis, Immunity, Innate, Lung

Abstract

The lung is a vital organ that incessantly faces external environmental challenges. Its homeostasis and unimpeded vital function are ensured by the respiratory epithelium working hand in hand with an intricate fine-tuned tissue-resident immune cell network. Lung tissue-resident immune cells span across the innate and adaptive immunity and protect from infectious agents but can also prove to be pathogenic if dysregulated. Here, we review the innate and adaptive immune cell subtypes comprising lung-resident immunity and discuss their ontogeny and role in distinct respiratory diseases. An improved understanding of the role of lung-resident immunity and how its function is dysregulated under pathological conditions can shed light on the pathogenesis of respiratory diseases., (© 2022. The Author(s).)

Published

2022

3. A prenatally disrupted airway epithelium orchestrates the fetal origin of asthma in mice.

Author

Zazara DE, Wegmann M, Giannou AD, Hierweger AM, Alawi M, Thiele K, Huber S, Pincus M, Muntau AC, Solano ME, and Arck PC

Subjects

Animals, Bone Marrow immunology, Cells, Cultured, Disease Models, Animal, Female, Immunity immunology, Inflammation immunology, Male, Mice, Mice, Inbred C57BL, Ovalbumin immunology, Pregnancy, Respiratory Hypersensitivity immunology, Tight Junctions immunology, Asthma immunology, Lung immunology, Prenatal Exposure Delayed Effects immunology, Respiratory Mucosa immunology

Abstract

Background: Prenatal challenges such as maternal stress perception increase the risk and severity of asthma during childhood. However, insights into the trajectories and targets underlying the pathogenesis of prenatally triggered asthma are largely unknown. The developing lung and immune system may constitute such targets., Objective: Here we have aimed to identify the differential sex-specific effects of prenatal challenges on lung function, immune response, and asthma severity in mice., Methods: We generated bone marrow chimeric (BMC) mice harboring either prenatally stress-exposed lungs or a prenatally stress-exposed immune (hematopoietic) system and induced allergic asthma via ovalbumin. Next-generation sequencing (RNA sequencing) of lungs and assessment of airway epithelial barrier function in ovalbumin-sensitized control and prenatally stressed offspring was also performed., Results: Profoundly enhanced airway hyperresponsiveness, inflammation, and fibrosis were exclusively present in female BMC mice with prenatally stress-exposed lungs. These effects were significantly perpetuated if both the lungs and the immune system had been exposed to prenatal stress. A prenatally stress-exposed immune system alone did not suffice to increase the severity of these asthma features. RNA sequencing analysis of lungs from prenatally stressed, non-BMC, ovalbumin-sensitized females unveiled a deregulated expression of genes involved in asthma pathogenesis, tissue remodeling, and tight junction formation. It was also possible to independently confirm a tight junction disruption. In line with this, we identified an altered perinatal and/or postnatal expression of genes involved in lung development along with an impaired alveolarization in female prenatally stressed mice., Conclusion: Here we have shown that the fetal origin of asthma is orchestrated by a disrupted airway epithelium and further perpetuated by a predisposed immune system., (Copyright © 2020 The Authors. Published by Elsevier Inc. All rights reserved.)

Published

2020

4. NRAS destines tumor cells to the lungs.

Author

Giannou AD, Marazioti A, Kanellakis NI, Giopanou I, Lilis I, Zazara DE, Ntaliarda G, Kati D, Armenis V, Giotopoulou GA, Krontira AC, Lianou M, Agalioti T, Vreka M, Papageorgopoulou M, Fouzas S, Kardamakis D, Psallidas I, Spella M, and Stathopoulos GT

Subjects

Animals, Cell Line, Tumor, GTP Phosphohydrolases immunology, Gene Expression Regulation, Neoplastic, Humans, Inflammation genetics, Inflammation immunology, Inflammation pathology, Interleukin-8 immunology, Lung immunology, Lung metabolism, Lung Neoplasms genetics, Lung Neoplasms immunology, Membrane Proteins immunology, Mice, Inbred BALB C, Mice, Inbred C57BL, Monomeric GTP-Binding Proteins, Mutation, Signal Transduction, GTP Phosphohydrolases genetics, Lung blood supply, Lung Neoplasms blood supply, Lung Neoplasms secondary, Membrane Proteins genetics, Up-Regulation

Abstract

The lungs are frequently affected by cancer metastasis. Although NRAS mutations have been associated with metastatic potential, their exact role in lung homing is incompletely understood. We cross-examined the genotype of various tumor cells with their ability for automatic pulmonary dissemination, modulated NRAS expression using RNA interference and NRAS overexpression, identified NRAS signaling partners by microarray, and validated them using Cxcr1 - and Cxcr2 -deficient mice. Mouse models of spontaneous lung metastasis revealed that mutant or overexpressed NRAS promotes lung colonization by regulating interleukin-8-related chemokine expression, thereby initiating interactions between tumor cells, the pulmonary vasculature, and myeloid cells. Our results support a model where NRAS -mutant, chemokine-expressing circulating tumor cells target the CXCR1-expressing lung vasculature and recruit CXCR2-expressing myeloid cells to initiate metastasis. We further describe a clinically relevant approach to prevent NRAS-driven pulmonary metastasis by inhibiting chemokine signaling. In conclusion, NRAS promotes the colonization of the lungs by various tumor types in mouse models. IL-8-related chemokines, NRAS signaling partners in this process, may constitute an important therapeutic target against pulmonary involvement by cancers of other organs., (© 2017 The Authors. Published under the terms of the CC BY 4.0 license.)

Published

2017

5. Automatic Semi-quantitative Histological Assessment of Tissue Traits Using a Smart Web Application

Author

Giannou, Olympia, Zazara, Dimitra E., Giannou, Anastasios D., Arck, Petra Clara, Pavlidis, Georgios, Rannenberg, Kai, Editor-in-Chief, Soares Barbosa, Luís, Editorial Board Member, Goedicke, Michael, Editorial Board Member, Tatnall, Arthur, Editorial Board Member, Neuhold, Erich J., Editorial Board Member, Stiller, Burkhard, Editorial Board Member, Tröltzsch, Fredi, Editorial Board Member, Pries-Heje, Jan, Editorial Board Member, Kreps, David, Editorial Board Member, Reis, Ricardo, Editorial Board Member, Furnell, Steven, Editorial Board Member, Mercier-Laurent, Eunika, Editorial Board Member, Winckler, Marco, Editorial Board Member, Malaka, Rainer, Editorial Board Member, Maglogiannis, Ilias, editor, Iliadis, Lazaros, editor, Macintyre, John, editor, and Cortez, Paulo, editor

Published

2022