Your search keyword '"Jayaraj J"' showing total 13 results

1. Airway hillocks are injury-resistant reservoirs of unique plastic stem cells.

Author

Lin B, Shah VS, Chernoff C, Sun J, Shipkovenska GG, Vinarsky V, Waghray A, Xu J, Leduc AD, Hintschich CA, Surve MV, Xu Y, Capen DE, Villoria J, Dou Z, Hariri LP, and Rajagopal J

Subjects

Animals, Female, Humans, Male, Mice, Metaplasia etiology, Metaplasia pathology, Tretinoin metabolism, Tretinoin pharmacology, Vitamin A metabolism, Vitamin A pharmacology, Lung Neoplasms etiology, Lung Neoplasms pathology, Mice, Inbred C57BL, Cell Plasticity, Epithelial Cells cytology, Epithelial Cells pathology, Regeneration, Respiratory Mucosa cytology, Respiratory Mucosa injuries, Respiratory Mucosa pathology, Stem Cells cytology

Abstract

Airway hillocks are stratified epithelial structures of unknown function 1 . Hillocks persist for months and have a unique population of basal stem cells that express genes associated with barrier function and cell adhesion. Hillock basal stem cells continually replenish overlying squamous barrier cells. They exhibit dramatically higher turnover than the abundant, largely quiescent classic pseudostratified airway epithelium. Hillocks resist a remarkably broad spectrum of injuries, including toxins, infection, acid and physical injury because hillock squamous cells shield underlying hillock basal stem cells from injury. Hillock basal stem cells are capable of massive clonal expansion that is sufficient to resurface denuded airway, and eventually regenerate normal airway epithelium with each of its six component cell types. Hillock basal stem cells preferentially stratify and keratinize in the setting of retinoic acid signalling inhibition, a known cause of squamous metaplasia 2,3 . Here we show that mouse hillock expansion is the cause of vitamin A deficiency-induced squamous metaplasia. Finally, we identify human hillocks whose basal stem cells generate functional squamous barrier structures in culture. The existence of hillocks reframes our understanding of airway epithelial regeneration. Furthermore, we show that hillocks are one origin of 'squamous metaplasia', which is long thought to be a precursor of lung cancer., (© 2024. The Author(s), under exclusive licence to Springer Nature Limited.)

Published

2024

2. Airway basal stem cells generate distinct subpopulations of PNECs.

Author

Mou H, Yang Y, Riehs MA, Barrios J, Shivaraju M, Haber AL, Montoro DT, Gilmore K, Haas EA, Paunovic B, Rajagopal J, Vargas SO, Haynes RL, Fine A, Cardoso WV, and Ai X

Subjects

Animals, Basic Helix-Loop-Helix Transcription Factors genetics, Basic Helix-Loop-Helix Transcription Factors metabolism, Cell Differentiation, Epithelial Cells classification, Epithelial Cells metabolism, Female, Gene Expression Regulation, Humans, Hyperplasia genetics, Hyperplasia metabolism, Hyperplasia pathology, Infant, Influenza A Virus, H1N1 Subtype growth & development, Influenza A Virus, H1N1 Subtype pathogenicity, Lung, Male, Mice, Mice, Transgenic, Neuroendocrine Cells classification, Neuroendocrine Cells metabolism, Neuropeptides genetics, Neuropeptides metabolism, Orthomyxoviridae Infections genetics, Orthomyxoviridae Infections metabolism, Orthomyxoviridae Infections pathology, Orthomyxoviridae Infections virology, Signal Transduction, Stem Cells classification, Stem Cells metabolism, Sudden Infant Death genetics, Sudden Infant Death pathology, Transcription Factors genetics, Transcription Factors metabolism, Tubulin metabolism, Tumor Suppressor Proteins genetics, Tumor Suppressor Proteins metabolism, Cell Lineage genetics, Epithelial Cells pathology, Neuroendocrine Cells pathology, Stem Cells pathology, Tubulin genetics

Abstract

Pulmonary neuroendocrine cells (PNECs) have crucial roles in airway physiology and immunity by producing bioactive amines and neuropeptides (NPs). A variety of human diseases exhibit PNEC hyperplasia. Given accumulated evidence that PNECs represent a heterogenous population of cells, we investigate how PNECs differ, whether the heterogeneity is similarly present in mouse and human cells, and whether specific disease involves discrete PNECs. Herein, we identify three distinct types of PNECs in human and mouse airways based on single and double positivity for TUBB3 and the established NP markers. We show that the three PNEC types exhibit significant differences in NP expression, homeostatic turnover, and response to injury and disease. We provide evidence that these differences parallel their distinct cell of origin from basal stem cells (BSCs) or other airway epithelial progenitors., Competing Interests: Declaration of interests The authors declare no competing interests., (Copyright © 2021 The Author(s). Published by Elsevier Inc. All rights reserved.)

Published

2021

3. Airway stem cells sense hypoxia and differentiate into protective solitary neuroendocrine cells.

Author

Shivaraju M, Chitta UK, Grange RMH, Jain IH, Capen D, Liao L, Xu J, Ichinose F, Zapol WM, Mootha VK, and Rajagopal J

Subjects

Anaerobiosis, Animals, Calcitonin Gene-Related Peptide metabolism, Calcitonin Gene-Related Peptide pharmacology, Calcitonin Receptor-Like Protein metabolism, Cell Count, Gene Deletion, Humans, Hypoxia metabolism, Hypoxia-Inducible Factor 1, alpha Subunit metabolism, Mice, Mice, Mutant Strains, Neuroendocrine Cells cytology, Prolyl Hydroxylases metabolism, Stem Cells cytology, Stem Cells drug effects, Trans-Activators genetics, Cell Differentiation, Hypoxia pathology, Neuroendocrine Cells physiology, Oxygen physiology, Stem Cells physiology, Trachea cytology

Abstract

Neuroendocrine (NE) cells are epithelial cells that possess many of the characteristics of neurons, including the presence of secretory vesicles and the ability to sense environmental stimuli. The normal physiologic functions of solitary airway NE cells remain a mystery. We show that mouse and human airway basal stem cells sense hypoxia. Hypoxia triggers the direct differentiation of these stem cells into solitary NE cells. Ablation of these solitary NE cells during hypoxia results in increased epithelial injury, whereas the administration of the NE cell peptide CGRP rescues this excess damage. Thus, we identify stem cells that directly sense hypoxia and respond by differentiating into solitary NE cells that secrete a protective peptide that mitigates hypoxic injury., (Copyright © 2021, American Association for the Advancement of Science.)

Published

2021

4. Submucosal Gland Myoepithelial Cells Are Reserve Stem Cells That Can Regenerate Mouse Tracheal Epithelium.

Author

Lynch TJ, Anderson PJ, Rotti PG, Tyler SR, Crooke AK, Choi SH, Montoro DT, Silverman CL, Shahin W, Zhao R, Jensen-Cody CW, Adamcakova-Dodd A, Evans TIA, Xie W, Zhang Y, Mou H, Herring BP, Thorne PS, Rajagopal J, Yeaman C, Parekh KR, and Engelhardt JF

Subjects

Animals, Cells, Cultured, Female, Male, Mice, Mice, Inbred Strains, Mice, Transgenic, Epithelial Cells cytology, Exocrine Glands cytology, Respiratory Mucosa cytology, Stem Cells cytology, Trachea cytology

Abstract

The mouse trachea is thought to contain two distinct stem cell compartments that contribute to airway repair-basal cells in the surface airway epithelium (SAE) and an unknown submucosal gland (SMG) cell type. Whether a lineage relationship exists between these two stem cell compartments remains unclear. Using lineage tracing of glandular myoepithelial cells (MECs), we demonstrate that MECs can give rise to seven cell types of the SAE and SMGs following severe airway injury. MECs progressively adopted a basal cell phenotype on the SAE and established lasting progenitors capable of further regeneration following reinjury. MECs activate Wnt-regulated transcription factors (Lef-1/TCF7) following injury and Lef-1 induction in cultured MECs promoted transition to a basal cell phenotype. Surprisingly, dose-dependent MEC conditional activation of Lef-1 in vivo promoted self-limited airway regeneration in the absence of injury. Thus, modulating the Lef-1 transcriptional program in MEC-derived progenitors may have regenerative medicine applications for lung diseases., (Copyright © 2018 Elsevier Inc. All rights reserved.)

Published

2018

5. Plasticity in the lung: making and breaking cell identity.

Author

Tata PR and Rajagopal J

Subjects

Animals, Cell Differentiation, Epithelial Cells physiology, Homeostasis, Humans, Immune System, Lung Diseases pathology, Mice, Stem Cells cytology, Cell Lineage, Lung growth & development, Lung physiology, Regeneration physiology, Stem Cells physiology

Abstract

In contrast to a prior emphasis on the finality of cell fate decisions in developmental systems, cellular plasticity is now emerging as a general theme in the biology of multiple adult organ systems. In the lung, lineage tracing has been used to identify distinct epithelial stem and progenitor cell populations. These cells, together with their differentiated progeny, maintain a stable identity during steady state conditions, but can display remarkable lineage plasticity following injury. This Review summarizes our current understanding of the different cell lineages of the adult mammalian lung and their responses to injury. In the lung, which is constantly exposed to infection and aerosolized toxins, epithelial plasticity might be more of a rule than an exception, and it is likely that different injuries elicit different facultative responses., (© 2017. Published by The Company of Biologists Ltd.)

Published

2017

6. Regulatory Circuits and Bi-directional Signaling between Stem Cells and Their Progeny.

Author

Tata PR and Rajagopal J

Subjects

Animals, Autocrine Communication, Cell Lineage, Feedback, Physiological, Humans, Models, Biological, Signal Transduction, Stem Cells cytology, Stem Cells metabolism

Abstract

Feedback signals from daughter cells to stem cells are well studied and known to provide important feedback cues. Emerging evidence shows that stem cells also send feedforward signals to their progeny. Complex circuits involving both negative and positive feedback and feedforward signals likely contribute to robust tissue maintenance and regeneration., (Copyright © 2016 Elsevier Inc. All rights reserved.)

Published

2016

7. Parent stem cells can serve as niches for their daughter cells.

Author

Pardo-Saganta A, Tata PR, Law BM, Saez B, Chow RD, Prabhu M, Gridley T, and Rajagopal J

Subjects

Animals, Cell Communication, Cell Differentiation, Cell Division, Cilia metabolism, Female, Jagged-2 Protein, Male, Membrane Proteins metabolism, Mice, Receptor, Notch2 metabolism, Signal Transduction, Stem Cells metabolism, Trachea cytology, Stem Cell Niche physiology, Stem Cells cytology

Abstract

Stem cells integrate inputs from multiple sources. Stem cell niches provide signals that promote stem cell maintenance, while differentiated daughter cells are known to provide feedback signals to regulate stem cell replication and differentiation. Recently, stem cells have been shown to regulate themselves using an autocrine mechanism. The existence of a 'stem cell niche' was first postulated by Schofield in 1978 to define local environments necessary for the maintenance of haematopoietic stem cells. Since then, an increasing body of work has focused on defining stem cell niches. Yet little is known about how progenitor cell and differentiated cell numbers and proportions are maintained. In the airway epithelium, basal cells function as stem/progenitor cells that can both self-renew and produce differentiated secretory cells and ciliated cells. Secretory cells also act as transit-amplifying cells that eventually differentiate into post-mitotic ciliated cells . Here we describe a mode of cell regulation in which adult mammalian stem/progenitor cells relay a forward signal to their own progeny. Surprisingly, this forward signal is shown to be necessary for daughter cell maintenance. Using a combination of cell ablation, lineage tracing and signalling pathway modulation, we show that airway basal stem/progenitor cells continuously supply a Notch ligand to their daughter secretory cells. Without these forward signals, the secretory progenitor cell pool fails to be maintained and secretory cells execute a terminal differentiation program and convert into ciliated cells. Thus, a parent stem/progenitor cell can serve as a functional daughter cell niche.

Published

2015

8. Injury induces direct lineage segregation of functionally distinct airway basal stem/progenitor cell subpopulations.

Author

Pardo-Saganta A, Law BM, Tata PR, Villoria J, Saez B, Mou H, Zhao R, and Rajagopal J

Subjects

Animals, Cell Differentiation, Cells, Cultured, Chlorine, Doxycycline, Mice, Respiratory Mucosa metabolism, Sulfur Dioxide, Wounds and Injuries chemically induced, Cell Lineage, Respiratory Mucosa cytology, Stem Cells cytology, Wounds and Injuries therapy

Abstract

Following injury, stem cells restore normal tissue architecture by producing the proper number and proportions of differentiated cells. Current models of airway epithelial regeneration propose that distinct cytokeratin 8-expressing progenitor cells, arising from p63(+) basal stem cells, subsequently differentiate into secretory and ciliated cell lineages. We now show that immediately following injury, discrete subpopulations of p63(+) airway basal stem/progenitor cells themselves express Notch pathway components associated with either secretory or ciliated cell fate commitment. One basal cell population displays intracellular Notch2 activation and directly generates secretory cells; the other expresses c-myb and directly yields ciliated cells. Furthermore, disrupting Notch ligand activity within the basal cell population at large disrupts the normal pattern of lineage segregation. These non-cell-autonomous effects demonstrate that effective airway epithelial regeneration requires intercellular communication within the broader basal stem/progenitor cell population. These findings have broad implications for understanding epithelial regeneration and stem cell heterogeneity., (Copyright © 2015 Elsevier Inc. All rights reserved.)

Published

2015

9. Dedifferentiation of committed epithelial cells into stem cells in vivo.

Author

Tata PR, Mou H, Pardo-Saganta A, Zhao R, Prabhu M, Law BM, Vinarsky V, Cho JL, Breton S, Sahay A, Medoff BD, and Rajagopal J

Subjects

Animals, Antineoplastic Agents, Hormonal pharmacology, Cell Proliferation drug effects, Cell Survival, Cells, Cultured, Doxycycline pharmacology, Epithelial Cells drug effects, Female, Male, Mice, Transgenic, Stem Cells drug effects, Tamoxifen pharmacology, Cell Dedifferentiation, Epithelial Cells cytology, Stem Cells cytology

Abstract

Cellular plasticity contributes to the regenerative capacity of plants, invertebrates, teleost fishes and amphibians. In vertebrates, differentiated cells are known to revert into replicating progenitors, but these cells do not persist as stable stem cells. Here we present evidence that differentiated airway epithelial cells can revert into stable and functional stem cells in vivo. After the ablation of airway stem cells, we observed a surprising increase in the proliferation of committed secretory cells. Subsequent lineage tracing demonstrated that the luminal secretory cells had dedifferentiated into basal stem cells. Dedifferentiated cells were morphologically indistinguishable from stem cells and they functioned as well as their endogenous counterparts in repairing epithelial injury. Single secretory cells clonally dedifferentiated into multipotent stem cells when they were cultured ex vivo without basal stem cells. By contrast, direct contact with a single basal stem cell was sufficient to prevent secretory cell dedifferentiation. In analogy to classical descriptions of amphibian nuclear reprogramming, the propensity of committed cells to dedifferentiate is inversely correlated to their state of maturity. This capacity of committed cells to dedifferentiate into stem cells may have a more general role in the regeneration of many tissues and in multiple disease states, notably cancer.

Published

2013

10. Ciliated cells of pseudostratified airway epithelium do not become mucous cells after ovalbumin challenge.

Author

Pardo-Saganta A, Law BM, Gonzalez-Celeiro M, Vinarsky V, and Rajagopal J

Subjects

Allergens immunology, Animals, Asthma pathology, Cell Proliferation drug effects, Cells, Cultured, Epithelial Cells drug effects, Goblet Cells cytology, Goblet Cells drug effects, Hyperplasia pathology, Male, Metaplasia pathology, Mice, Mice, Inbred C57BL, Respiratory Mucosa drug effects, Stem Cells drug effects, Epithelial Cells cytology, Ovalbumin pharmacology, Respiratory Mucosa cytology, Stem Cells cytology

Abstract

Mucous cell metaplasia is a hallmark of airway diseases, such as asthma and chronic obstructive pulmonary disease. The majority of human airway epithelium is pseudostratified, but the cell of origin of mucous cells has not been definitively established in this type of airway epithelium. There is evidence that ciliated, club cell (Clara), and basal cells can all give rise to mucus-producing cells in different contexts. Because pseudostratified airway epithelium contains distinct progenitor cells from simple columnar airway epithelium, the lineage relationships of progenitor cells to mucous cells may be different in these two epithelial types. We therefore performed lineage tracing of the ciliated cells of the murine basal cell-containing airway epithelium in conjunction with the ovalbumin (OVA)-induced murine model of allergic lung disease. We genetically labeled ciliated cells with enhanced Yellow Fluorescent Protein (eYFP) before the allergen challenge, and followed the fate of these cells to determine whether they gave rise to newly formed mucous cells. Although ciliated cells increased in number after the OVA challenge, the newly formed mucous cells were not labeled with the eYFP lineage tag. Even small numbers of labeled mucous cells could not be detected, implying that ciliated cells make virtually no contribution to the new goblet cell pool. This demonstrates that, after OVA challenge, new mucous cells do not originate from ciliated cells in a pseudostratified basal cell-containing airway epithelium.

Published

2013

11. Wnt7b stimulates embryonic lung growth by coordinately increasing the replication of epithelium and mesenchyme.

Author

Rajagopal J, Carroll TJ, Guseh JS, Bores SA, Blank LJ, Anderson WJ, Yu J, Zhou Q, McMahon AP, and Melton DA

Subjects

Animals, Autocrine Communication, Cell Proliferation, Epithelium embryology, Epithelium metabolism, Glycoproteins genetics, Lung abnormalities, Lung cytology, Male, Mesoderm cytology, Mesoderm metabolism, Mice, Mice, Knockout, Muscle, Smooth, Vascular cytology, Muscle, Smooth, Vascular embryology, Paracrine Communication, Protein Isoforms genetics, Protein Isoforms physiology, Proto-Oncogene Proteins genetics, Signal Transduction, Stem Cells physiology, Wnt Proteins genetics, Cell Differentiation physiology, Epithelial Cells physiology, Glycoproteins physiology, Lung embryology, Mesoderm embryology, Proto-Oncogene Proteins physiology, Stem Cells cytology, Wnt Proteins physiology

Abstract

The effects of Wnt7b on lung development were examined using a conditional Wnt7b-null mouse. Wnt7b-null lungs are markedly hypoplastic, yet display largely normal patterning and cell differentiation. In contrast to findings in prior hypomorphic Wnt7b models, we find decreased replication of both developing epithelium and mesenchyme, without abnormalities of vascular smooth muscle development. We further demonstrate that Wnt7b signals to neighboring cells to activate both autocrine and paracrine canonical Wnt signaling cascades. In contrast to results from hypomorphic models, we show that Wnt7b modulates several important signaling pathways in the lung. Together, these cascades result in the coordinated proliferation of adjacent epithelial and mesenchymal cells to stimulate organ growth with few alterations in differentiation and patterning.

Published

2008

12. Artifactual insulin release from differentiated embryonic stem cells.

Author

Hansson M, Tonning A, Frandsen U, Petri A, Rajagopal J, Englund MC, Heller RS, Håkansson J, Fleckner J, Sköld HN, Melton D, Semb H, and Serup P

Subjects

Animals, Apoptosis physiology, Artifacts, Cell Culture Techniques, Cell Differentiation drug effects, Glucose pharmacology, Humans, In Situ Nick-End Labeling, Insulin Secretion, Mice, Stem Cells cytology, Stem Cells drug effects, C-Peptide metabolism, Cell Differentiation physiology, Insulin metabolism, Stem Cells metabolism

Abstract

Several recent reports claim the generation of insulin-producing cells from embryonic stem cells via the differentiation of progenitors that express nestin. Here, we investigate further the properties of these insulin-containing cells. We find that although differentiated cells contain immunoreactive insulin, they do not contain proinsulin-derived C-peptide. Furthermore, we find variable insulin release from these cells upon glucose addition, but C-peptide release is never detected. In addition, many of the insulin-immunoreactive cells are undergoing apoptosis or necrosis. We further show that cells cultured in the presence of a phosphoinositide 3-kinase inhibitor, which previously was reported to facilitate the differentiation of insulin(+) cells, are not C-peptide immunoreactive but take up fluorescein isothiocyanate-labeled insulin from the culture medium. Together, these data suggest that nestin(+) progenitor cells give rise to a population of cells that contain insulin, not as a result of biosynthesis but from the uptake of exogenous insulin. We conclude that C-peptide biosynthesis and secretion should be demonstrated to claim insulin production from embryonic stem cell progeny.

Published

2004

13. Insulin staining of ES cell progeny from insulin uptake.

Author

Rajagopal J, Anderson WJ, Kume S, Martinez OI, and Melton DA

Subjects

Animals, Antibodies immunology, Apoptosis, Cell Differentiation, Cell Line, Humans, Insulin genetics, Insulin immunology, Islets of Langerhans metabolism, Mice, Microscopy, Confocal, RNA, Messenger genetics, RNA, Messenger metabolism, Reverse Transcriptase Polymerase Chain Reaction, Stem Cells metabolism, Embryo, Mammalian cytology, Insulin analysis, Insulin metabolism, Islets of Langerhans cytology, Stem Cells cytology

Published

2003