Browsing by Author "Konkimalla, Arvind"
- Results Per Page
- Sort Options
Item Embargo Cellular Ensembles in Alveolar Homeostasis and Repair(2023) Konkimalla, ArvindLung epithelium, the lining that covers the inner surface of the respiratory tract, is directly exposed to the environment and thus susceptible to airborne toxins, irritants, and pathogen-induced damages. In adult mammalian lungs, epithelial cells are generally quiescent but can respond rapidly to repair damaged tissues. Evidence from experimental injury models in rodents and human clinical samples has led to the identification of these regenerative cells, as well as pathological metaplastic states specifically associated with different forms of damages. The primary alveolar stem cell, alveolar type-2 cells (AT2s) are sparsely distributed and make up only 5% of the surface area. Despite this organization, AT2s are still able to maintain tissue homeostasis and achieve efficient repair after injury. However, the underlying mechanisms of stem cell activation, injury response, and subsequent cell-cell communication signals mediating resolution of injury and restoration of alveolar homeostasis remain elusive. Additionally, modulation of these regenerative cells for therapeutic potential has not been well established, primarily due to a lack of viable gene editing tools and vehicles for gene delivery to the alveolar stem cells, and neighboring niche. First, to better target the lung alveolus, we screened and identified cell-type specific adeno-associated virus (AAV) serotypes, enabling efficient targeting and gene expression of exogenous genes in alveolar stem cells as well neighboring mesenchyme. These tools were also capable for both in vitro and in vivo gene editing, forgoing the need for development of complex genetic mouse models as well as enabling diverse, viral-based screens. Second, using 3-dimensional, thick tissue imaging we reveal that a single AT2 cell can enface multiple alveolar compartments by virtue of a unique, multi-apical domain architecture. Lineage tracing and live imaging coupled with genetic and AAV-mediated selective ablation of AT2s was used to show robust recovery of AT2 numbers and distribution via clonal proliferation and migration, even after three successive rounds of ablation. Clonal tracing revealed that a single AT2 can differentiate to cover multiple alveolar cups. During injury repair, AT2s dynamically reorganize their apical domains to facilitate either migration or differentiation. Single- cell transcriptome profiling, genetic and pharmacologic disruption of actin dynamics, and evaluation of multiple physiologically relevant disease states identified the roles of actin cytoskeleton, cell migration, and multi-apical domains in AT2 recovery and regenerative potency. Lastly, using cell-type specific ablation of alveolar type 1 cells (AT1s), we identified novel mechanisms of epithelium-mediated signaling to mesenchymal fibroblasts, thereby uncovering novel mechanisms of fibrosis initiation and progression. Modulation of AT1 ablation dynamics preferentially drives fibrosis or, in contrast, emphysema, both at histological and physiological levels, as assessed by whole body plethysmography. Single-cell sequencing identified the epithelial and mesenchymal cell identities involved in regenerative processes, as well as identification of a PDGFA signaling axis between AT1s and resident alveolar fibroblasts necessary for fibroblast maintenance. We demonstrate that modulation of these signaling pathways during lung regeneration could enhance fibrosis or convert fibrosis to emphysema. In sum, the work presented herein both develops functional tools for perturbation of alveolar stem cells, as well as an improved understanding of alveolar architecture, stem cell dynamics during injury repair, homeostatic intercellular signaling, and mechanisms of disease progression.
Item Open Access Human Lung Stem Cell-Based Alveolospheres Provide Insights into SARS-CoV-2-Mediated Interferon Responses and Pneumocyte Dysfunction.(Cell stem cell, 2020-10-21) Katsura, Hiroaki; Sontake, Vishwaraj; Tata, Aleksandra; Kobayashi, Yoshihiko; Edwards, Caitlin E; Heaton, Brook E; Konkimalla, Arvind; Asakura, Takanori; Mikami, Yu; Fritch, Ethan J; Lee, Patty J; Heaton, Nicholas S; Boucher, Richard C; Randell, Scott H; Baric, Ralph S; Tata, Purushothama RaoCoronavirus infection causes diffuse alveolar damage leading to acute respiratory distress syndrome. The absence of ex vivo models of human alveolar epithelium is hindering an understanding of coronavirus disease 2019 (COVID-19) pathogenesis. Here, we report a feeder-free, scalable, chemically defined, and modular alveolosphere culture system for the propagation and differentiation of human alveolar type 2 cells/pneumocytes derived from primary lung tissue. Cultured pneumocytes express the severe acute respiratory syndrome coronavirus 2 (SARS-CoV-2) receptor angiotensin-converting enzyme receptor type-2 (ACE2) and can be infected with virus. Transcriptome and histological analysis of infected alveolospheres mirror features of COVID-19 lungs, including emergence of interferon (IFN)-mediated inflammatory responses, loss of surfactant proteins, and apoptosis. Treatment of alveolospheres with IFNs recapitulates features of virus infection, including cell death. In contrast, alveolospheres pretreated with low-dose IFNs show a reduction in viral replication, suggesting the prophylactic effectiveness of IFNs against SARS-CoV-2. Human stem cell-based alveolospheres, thus, provide novel insights into COVID-19 pathogenesis and can serve as a model for understanding human respiratory diseases.Item Open Access Lung Regeneration: Cells, Models, and Mechanisms.(Cold Spring Harbor perspectives in biology, 2022-10) Konkimalla, Arvind; Tata, Aleksandra; Tata, Purushothama RaoLung epithelium, the lining that covers the inner surface of the respiratory tract, is directly exposed to the environment and thus susceptible to airborne toxins, irritants, and pathogen-induced damages. In adult mammalian lungs, epithelial cells are generally quiescent but can respond rapidly to repair of damaged tissues. Evidence from experimental injury models in rodents and human clinical samples has led to the identification of these regenerative cells, as well as pathological metaplastic states specifically associated with different forms of damages. Here, we provide a compendium of cells and cell states that exist during homeostasis in normal lungs and the lineage relationships between them. Additionally, we discuss various experimental injury models currently being used to probe the cellular sources-both resident and recruited-that contribute to repair, regeneration, and remodeling following acute and chronic injuries. Finally, we discuss certain maladaptive regeneration-associated cell states and their role in disease pathogenesis.Item Open Access Multi-apical polarity of alveolar stem cells and their dynamics during lung development and regeneration.(iScience, 2022-10) Konkimalla, Arvind; Konishi, Satoshi; Kobayashi, Yoshihiko; Kadur Lakshminarasimha Murthy, Preetish; Macadlo, Lauren; Mukherjee, Ananya; Elmore, Zachary; Kim, So-Jin; Pendergast, Ann Marie; Lee, Patty J; Asokan, Aravind; Knudsen, Lars; Bravo-Cordero, Jose Javier; Tata, Aleksandra; Tata, Purushothama RaoEpithelial cells of diverse tissues are characterized by the presence of a single apical domain. In the lung, electron microscopy studies have suggested that alveolar type-2 epithelial cells (AT2s) en face multiple alveolar sacs. However, apical and basolateral organization of the AT2s and their establishment during development and remodeling after injury repair remain unknown. Thick tissue imaging and electron microscopy revealed that a single AT2 can have multiple apical domains that enface multiple alveoli. AT2s gradually establish multi-apical domains post-natally, and they are maintained throughout life. Lineage tracing, live imaging, and selective cell ablation revealed that AT2s dynamically reorganize multi-apical domains during injury repair. Single-cell transcriptome signatures of residual AT2s revealed changes in cytoskeleton and cell migration. Significantly, cigarette smoke and oncogene activation lead to dysregulation of multi-apical domains. We propose that the multi-apical domains of AT2s enable them to be poised to support the regeneration of a large array of alveolar sacs.