Your search keyword '"Minxiao Yang"' showing total 6 results

1. Alisol B 23-acetate broadly inhibits coronavirus through blocking virus entry and suppresses proinflammatory T cells responses for the treatment of COVID-19

Author

Qiaohui Du, Ronghui Liang, Meiling Wu, Minxiao Yang, Yubin Xie, Qing Liu, Kaiming Tang, Xiang Lin, Shuofeng Yuan, and Jiangang Shen

Subjects

Alisol B 23-acetate, Anti-coronavirus, COVID-19, Anti-immunoinflammatory activity, ACE2, Medicine (General), R5-920, Science (General), Q1-390

Abstract

Introduction: Emerging severe acute respiratory syndrome (SARS) coronavirus (CoV)-2 causes a global health disaster and pandemic. Seeking effective anti-pan-CoVs drugs benefit critical illness patients of coronavirus disease 2019 (COVID-19) but also may play a role in emerging CoVs of the future. Objectives: This study tested the hypothesis that alisol B 23-acetate could be a viral entry inhibitor and would have proinflammatory inhibition for COVID-19 treatment. Methods: SARS-CoV-2 and its variants infected several cell lines were applied to evaluate the anti-CoVs activities of alisol B 23-aceate in vitro. The effects of alisol B 23-acetate on in vivo models were assessed by using SARS-CoV-2 and its variants challenged hamster and human angiotensin-converting enzyme 2 (ACE2) transgenic mice. The target of alisol B 23-acetate to ACE2 was analyzed using hydrogen/deuterium exchange (HDX) mass spectrometry (MS). Results: Alisol B 23-acetate had inhibitory effects on different species of coronavirus. By using HDX-MS, we found that alisol B 23-acetate had inhibition potency toward ACE2. In vivo experiments showed that alisol B 23-acetate treatment remarkably decreased viral copy, reduced CD4+ T lymphocytes and CD11b+ macrophages infiltration and ameliorated lung damages in the hamster model. In Omicron variant infected human ACE2 transgenic mice, alisol B 23-acetate effectively alleviated viral load in nasal turbinate and reduced proinflammatory cytokines interleukin 17 (IL17) and interferon γ (IFNγ) in peripheral blood. The prophylactic treatment of alisol B 23-acetate by intranasal administration significantly attenuated Omicron viral load in the hamster lung tissues. Moreover, alisol B 23-acetate treatment remarkably inhibited proinflammatory responses through mitigating the secretions of IFNγ and IL17 in the cultured human and mice lymphocytes in vitro. Conclusion: Alisol B 23-acetate could be a promising therapeutic agent for COVID-19 treatment and its underlying mechanisms might be attributed to viral entry inhibition and anti-inflammatory activities.

Published

2024

2. Alveolar type I cells can give rise to KRAS-induced lung adenocarcinoma

Author

Minxiao Yang, Hua Shen, Per Flodby, Michael D. Koss, Rania Bassiouni, Yixin Liu, Tea Jashashvili, Aaron Neely, Ezuka Ogbolu, Jonathan Castillo, Theresa Ryan Stueve, Daniel J. Mullen, Amy L. Ryan, John Carpten, Alessandra Castaldi, W. Dean Wallace, Beiyun Zhou, Zea Borok, and Crystal N. Marconett

Subjects

CP: Cancer, Biology (General), QH301-705.5

Abstract

Summary: Lung adenocarcinoma (LUAD) is the most prevalent subtype of lung cancer and presents clinically with a high degree of biological heterogeneity and distinct clinical outcomes. The current paradigm of LUAD etiology posits alveolar epithelial type II (AT2) cells as the primary cell of origin, while the role of AT1 cells in LUAD oncogenesis remains unknown. Here, we examine oncogenic transformation in mouse Gram-domain containing 2 (Gramd2)+ AT1 cells via oncogenic KRASG12D. Activation of KRASG12D in AT1 cells induces multifocal LUAD, primarily of papillary histology. Furthermore, KRT8+ intermediate cell states were observed in both AT2- and AT1-derived LUAD, but SCGB3A2+, another intermediate cell marker, was primarily associated with AT1 cells, suggesting different mechanisms of tumor evolution. Collectively, our study reveals that Gramd2+ AT1 cells can serve as a cell of origin for LUAD and suggests that distinct subtypes of LUAD based on cell of origin be considered in the development of therapeutics.

Published

2023

3. Lack of racial and ethnic diversity in lung cancer cell lines contributes to lung cancer health disparities

Author

Christopher Leon, Eugene Manley, Aaron M. Neely, Jonathan Castillo, Michele Ramos Correa, Diego A. Velarde, Minxiao Yang, Pablo E. Puente, Diana I. Romero, Bing Ren, Wenxuan Chai, Matthew Gladstone, Nazarius S. Lamango, Yong Huang, and Ite A. Offringa

Subjects

lung cancer, cell lines, underrepresented, diversity, cancer health disparities, lung adenocarcinoma, Neoplasms. Tumors. Oncology. Including cancer and carcinogens, RC254-282

Abstract

Lung cancer is the leading cause of cancer death in the United States and worldwide, and a major source of cancer health disparities. Lung cancer cell lines provide key in vitro models for molecular studies of lung cancer development and progression, and for pre-clinical drug testing. To ensure health equity, it is imperative that cell lines representing different lung cancer histological types, carrying different cancer driver genes, and representing different genders, races, and ethnicities should be available. This is particularly relevant for cell lines from Black men, who experience the highest lung cancer mortality in the United States. Here, we undertook a review of the available lung cancer cell lines and their racial and ethnic origin. We noted a marked imbalance in the availability of cell lines from different races and ethnicities. Cell lines from Black patients were strongly underrepresented, and we identified no cell lines from Hispanic/Latin(x) (H/L), American Indian/American Native (AI/AN), or Native Hawaiian or other Pacific Islander (NHOPI) patients. The majority of cell lines were derived from White and Asian patients. Also missing are cell lines representing the cells-of-origin of the major lung cancer histological types, which can be used to model lung cancer development and to study the effects of environmental exposures on lung tissues. To our knowledge, the few available immortalized alveolar epithelial cell lines are all derived from White subjects, and the race and ethnicity of a handful of cell lines derived from bronchial epithelial cells are unknown. The lack of an appropriately diverse collection of lung cancer cell lines and lung cancer cell-of-origin lines severely limits racially and ethnically inclusive lung cancer research. It impedes the ability to develop inclusive models, screen comprehensively for effective compounds, pre-clinically test new drugs, and optimize precision medicine. It thereby hinders the development of therapies that can increase the survival of minority and underserved patients. The noted lack of cell lines from underrepresented groups should constitute a call to action to establish additional cell lines and ensure adequate representation of all population groups in this critical pre-clinical research resource.

Published

2023

4. Lack of racial and ethnic diversity in lung cancer cell lines contributes to lung cancer health disparities.

Author

Leon, Christopher, Manley Jr., Eugene, Neely, Aaron M., Castillo, Jonathan, Correa, Michele Ramos, Velarde, Diego A., Minxiao Yang, Puente, Pablo E., Romero, Diana I., Bing Ren, Wenxuan Chai, Gladstone, Matthew, Lamango, Nazarius S., Yong Huang, and Offringa, Ite A.

Subjects

CELL lines, LUNG cancer, CULTURAL pluralism, HEALTH equity, CANCER cells

Abstract

Lung cancer is the leading cause of cancer death in the United States and worldwide, and a major source of cancer health disparities. Lung cancer cell lines provide key in vitro models for molecular studies of lung cancer development and progression, and for pre-clinical drug testing. To ensure health equity, it is imperative that cell lines representing different lung cancer histological types, carrying different cancer driver genes, and representing different genders, races, and ethnicities should be available. This is particularly relevant for cell lines from Black men, who experience the highest lung cancer mortality in the United States. Here, we undertook a review of the available lung cancer cell lines and their racial and ethnic origin. We noted a marked imbalance in the availability of cell lines from different races and ethnicities. Cell lines from Black patients were strongly underrepresented, and we identified no cell lines from Hispanic/Latin(x) (H/L), American Indian/American Native (AI/AN), or Native Hawaiian or other Pacific Islander (NHOPI) patients. The majority of cell lines were derived from White and Asian patients. Also missing are cell lines representing the cells-oforigin of the major lung cancer histological types, which can be used to model lung cancer development and to study the effects of environmental exposures on lung tissues. To our knowledge, the few available immortalized alveolar epithelial cell lines are all derived from White subjects, and the race and ethnicity of a handful of cell lines derived from bronchial epithelial cells are unknown. The lack of an appropriately diverse collection of lung cancer cell lines and lung cancer cell-of-origin lines severely limits racially and ethnically inclusive lung cancer research. It impedes the ability to develop inclusive models, screen comprehensively for effective compounds, pre-clinically test new drugs, and optimize precision medicine. It thereby hinders the development of therapies that can increase the survival of minority and underserved patients. The noted lack of cell lines from underrepresented groups should constitute a call to action to establish additional cell lines and ensure adequate representation of all population groups in this critical pre-clinical research resource. [ABSTRACT FROM AUTHOR]

Published

2023

5. CLOCK’ing differences in DNA methylation signatures to understand the molecular etiology of lung cancer

Author

Aaron M. Neely, Minxiao Yang, and Crystal N. Marconett

Subjects

Oncology

Published

2023

6. Alveolar epithelial type 1 cells serve as a cell of origin for lung adenocarcinoma with distinct molecular and phenotypic presentation

Author

Minxiao Yang, Hua Shen, Per Flodby, Michael D. Koss, Rania Bassiouni, Yixin Liu, Tea Jashashvili, Theresa R. Stueve, Daniel J. Mullen, Amy L. Ryan, John Carpten, Alessandra Castaldi, W. Dean Wallace, Beiyun Zhou, Zea Borok, and Crystal N. Marconett

Abstract

Lung adenocarcinoma (LUAD) is the most common subtype of cancer arising in the distal lung. LUAD encompasses several pathologic subtypes, each with differing clinical outcomes and biological behaviors. However, the molecular and cellular underpinnings of the different subtypes are largely unknown. Understanding which cell populations in the distal lung contribute to LUAD could provide insights into the marked heterogeneity in pathologic features, clinical presentation and responses to therapy of LUAD. Differential expression analysis of lung adenocarcinoma transcriptomes from The Cancer Genome Atlas revealed distinct alveolar epithelial type 1 (AT1) and alveolar epithelial type 2 (AT2) cell signatures within human LUAD with significantly different survival outcomes between tumors expressing AT2 and AT1 gene signatures, suggesting AT1 cells might contribute to a subset of LUAD cases. To address this, we tested the ability of AT1 cells to give rise to LUAD following induction of KrasG12D, a known oncogenic driver of human LUAD. Activation of KrasG12Din Gram-domain containing 2 (Gramd2)+AT1 cells gave rise to multiple LUAD lesions, primarily of papillary histology. In contrast, activation of KrasG12Din surfactant protein C (Sftpc+) AT2 cells resulted in LUAD lesions of lepidic histology. Immunohistochemistry established thatGramd2:KrasG12Dlesions were of primary lung origin and not metastatic events. Spatial transcriptomic profiling revealed distinct pathway alterations within Gramd2- and Sftpc-derived LUAD. Immunofluorescence confirmed differences observed in the spatial transcriptomic analysis in expression patterns and distribution of cell-specific markers depending on cell of origin, while universal upregulation of the Krt8 intermediate cell state marker was observed. Our results are consistent with Gramd2+AT1 cells serving as a putative cell of origin for LUAD and suggest that LUAD may be a collection of adenocarcinomas that share a common location within the distal lung but arise from different cells of origin.

Published

2022