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Your search keyword '"Dana M. Ambruzs"' showing total 4 results
Start Over Author "Dana M. Ambruzs" Topic cell biology
4 results on '"Dana M. Ambruzs"'

1. Telomerase expression marks transitional growth-associated skeletal progenitor/stem cells

Author

Diana L. Carlone, Rebecca D. Riba‐Wolman, Alessio Tovaglieri, Rudolf Jaenisch, Dana M. Ambruzs, Benjamin E. Mead, Lijie Jiang, David T. Breault, Christopher J. Lengner, Luke T. Deary, and Manasvi S. Shah

Subjects
0301 basic medicine, Telomerase, mTert, Population, Biology, telomerase, 03 medical and health sciences, Mice, pluripotent, 0302 clinical medicine, Bone Marrow, medicine, Animals, Progenitor cell, education, Cellular Senescence, Cell Proliferation, Bone growth, education.field_of_study, Stem Cells, Mesenchymal stem cell, Cell Cycle, Epithelial Cells, Cell Biology, Endochondral bone growth, Cell biology, Tissue‐specific Stem Cells, 030104 developmental biology, medicine.anatomical_structure, skeletal stem cells, Molecular Medicine, Bone marrow, Stem cell, postnatal bone growth, 030217 neurology & neurosurgery, Developmental Biology
Abstract

Skeletal progenitor/stem cells (SSCs) play a critical role in postnatal bone growth and maintenance. Telomerase (Tert) activity prevents cellular senescence and is required for maintenance of stem cells in self‐renewing tissues. Here we investigated the role of mTert‐expressing cells in postnatal mouse long bone and found that mTert expression is enriched at the time of adolescent bone growth. mTert‐GFP+ cells were identified in regions known to house SSCs, including the metaphyseal stroma, growth plate, and the bone marrow. We also show that mTert‐expressing cells are a distinct SSC population with enriched colony‐forming capacity and contribute to multiple mesenchymal lineages, in vitro. In contrast, in vivo lineage‐tracing studies identified mTert + cells as osteochondral progenitors and contribute to the bone‐forming cell pool during endochondral bone growth with a subset persisting into adulthood. Taken together, our results show that mTert expression is temporally regulated and marks SSCs during a discrete phase of transitional growth between rapid bone growth and maintenance., In long bones, osteochondral progenitor cells function during rapid bone growth while osteoadipogenic progenitors act during bone maintenance. We showed that mTert is expressed in an age‐dependent manner and marks growth‐associated osteochondral progenitor cells during transitional growth, a discrete time period between rapid bone growth and bone maintenance.

Published
2020

2. Dormant Intestinal Stem Cells Are Regulated by PTEN and Nutritional Status

Author

Diana L. Carlone, Luke T. Deary, Camilla A. Richmond, Robert K. Montgomery, David T. Breault, Dana M. Ambruzs, Hannah Rickner, Alessio Tovaglieri, Bristol B. Whiles, Horatio R. Thomas, Manasvi S. Shah, Danny C. Trotier, and Lijie Jiang

Subjects
Male, inorganic chemicals, PTEN, fasting, Regulator, Nutritional Status, Mice, Transgenic, mTORC1, Mechanistic Target of Rapamycin Complex 1, Biology, digestive system, General Biochemistry, Genetics and Molecular Biology, Mice, Phosphatidylinositol 3-Kinases, Genes, Reporter, Animals, Phosphorylation, dormant, Telomerase, lcsh:QH301-705.5, Cell Proliferation, Phosphoinositide-3 Kinase Inhibitors, intestinal stem cells, MTORC1, 2. Zero hunger, Cell growth, Stem Cells, TOR Serine-Threonine Kinases, fungi, PTEN Phosphohydrolase, Intestinal epithelium, quiescent, Cell biology, Intestines, Mice, Inbred C57BL, lcsh:Biology (General), Multiprotein Complexes, biology.protein, Cancer research, Female, Stem cell, Signal transduction, Proto-Oncogene Proteins c-akt, Signal Transduction
Abstract

SummaryThe cellular and molecular mechanisms underlying adaptive changes to physiological stress within the intestinal epithelium remain poorly understood. Here, we show that PTEN, a negative regulator of the PI3K→AKT→mTORC1-signaling pathway, is an important regulator of dormant intestinal stem cells (d-ISCs). Acute nutrient deprivation leads to transient PTEN phosphorylation within d-ISCs and a corresponding increase in their number. This release of PTEN inhibition renders d-ISCs functionally poised to contribute to the regenerative response during re-feeding via cell-autonomous activation of the PI3K→AKT→mTORC1 pathway. Consistent with its role in mediating cell survival, PTEN is required for d-ISC maintenance at baseline, and intestines lacking PTEN have diminished regenerative capacity after irradiation. Our results highlight a PTEN-dependent mechanism for d-ISC maintenance and further demonstrate the role of d-ISCs in the intestinal response to stress.

Published
2015
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3. Insulin-Producing Endocrine Cells Differentiated In Vitro From Human Embryonic Stem Cells Function in Macroencapsulation Devices In Vivo

Author

Justin Kerr, Jonathan R. Kelly, Anindita Bhoumik, Mauro A. Frazier, Mark A. Moorman, Rosemary M. Cesario, Alan D. Agulnick, Robert Srijemac, Evert Kroon, Dana M. Ambruzs, Kevin A. D'Amour, Janice K. Payne, Alistair Wilson, and Carl Haakmeester

Subjects
Blood Glucose, medicine.medical_specialty, Cellular differentiation, Population, Cell, Human Embryonic Stem Cells, Enteroendocrine cell, Cell Separation, Biology, Cell therapy, Mice, Internal medicine, Tissue Engineering and Regenerative Medicine, Insulin-Secreting Cells, medicine, Animals, Humans, Insulin, Progenitor cell, education, Cells, Cultured, Cryopreservation, Homeodomain Proteins, education.field_of_study, Gene Expression Profiling, Reproducibility of Results, Cell Differentiation, Cell Biology, General Medicine, Cells, Immobilized, Embryonic stem cell, Cell biology, Endocrinology, medicine.anatomical_structure, Trans-Activators, PDX1, Protein Processing, Post-Translational, Biomarkers, Developmental Biology, Proinsulin
Abstract

The PEC-01 cell population, differentiated from human embryonic stem cells (hESCs), contains pancreatic progenitors (PPs) that, when loaded into macroencapsulation devices (to produce the VC-01 candidate product) and transplanted into mice, can mature into glucose-responsive insulin-secreting cells and other pancreatic endocrine cells involved in glucose metabolism. We modified the protocol for making PEC-01 cells such that 73%–80% of the cell population consisted of PDX1-positive (PDX1+) and NKX6.1+ PPs. The PPs were further differentiated to islet-like cells (ICs) that reproducibly contained 73%–89% endocrine cells, of which approximately 40%–50% expressed insulin. A large fraction of these insulin-positive cells were single hormone-positive and expressed the transcription factors PDX1 and NKX6.1. To preclude a significant contribution of progenitors to the in vivo function of ICs, we used a simple enrichment process to remove remaining PPs, yielding aggregates that contained 93%–98% endocrine cells and 1%–3% progenitors. Enriched ICs, when encapsulated and implanted into mice, functioned similarly to the VC-01 candidate product, demonstrating conclusively that in vitro-produced hESC-derived insulin-producing cells can mature and function in vivo in devices. A scaled version of our suspension culture was used, and the endocrine aggregates could be cryopreserved and retain functionality. Although ICs expressed multiple important β cell genes, the cells contained relatively low levels of several maturity-associated markers. Correlating with this, the time to function of ICs was similar to PEC-01 cells, indicating that ICs required cell-autonomous maturation after delivery in vivo, which would occur concurrently with graft integration into the host. Significance Type 1 diabetes (T1D) affects approximately 1.25 million people in the U.S. alone and is deadly if not managed with insulin injections. This paper describes the production of insulin-producing cells in vitro and a new protocol for producing the cells, representing another potential cell source for a diabetes cell therapy. These cells can be loaded into a protective device that is implanted under the skin. The device is designed to protect the cells from immune rejection by the implant recipient. The implant can engraft and respond to glucose by secreting insulin, thus potentially replacing the β cells lost in patients with T1D.

Published
2015

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