Your search keyword '"William J. Burlingham"' showing total 5 results

1. A Human Pluripotent Stem Cell-Based Screen for Smooth Muscle Cell Differentiation and Maturation Identifies Inhibitors of Intimal Hyperplasia

Author

Jue Zhang, Brian E. McIntosh, Bowen Wang, Matthew E. Brown, Mitchell D. Probasco, Sarah Webster, Bret Duffin, Ying Zhou, Lian-Wang Guo, William J. Burlingham, Craig Kent, Michael Ferris, and James A. Thomson

Subjects

Medicine (General), R5-920, Biology (General), QH301-705.5

Abstract

Summary: Contractile to synthetic phenotypic switching of smooth muscle cells (SMCs) contributes to stenosis in vascular disease and vascular transplants. To generate more contractile SMCs, we performed a high-throughput differentiation screen using a MYH11-NLuc-tdTomato human embryonic stem cell reporter cell line. We identified RepSox as a factor that promotes differentiation of MYH11-positive cells by promoting NOTCH signaling. RepSox induces SMCs to exhibit a more contractile phenotype than SMCs generated using PDGF-BB and TGF-β1, two factors previously used for SMC differentiation but which also cause intimal hyperplasia. In addition, RepSox inhibited intimal hyperplasia caused by contractile to synthetic phenotypic switching of SMCs in a rat balloon injury model. Thus, in addition to providing more contractile SMCs that could prove useful for constructing artificial blood vessels, this study suggests a strategy for identifying drugs for inhibiting intimal hyperplasia that act by driving contractile differentiation rather than inhibiting proliferation non-specifically. : Thomson, Zhang, and colleagues report a high-throughput screen that can be used for optimization of the fully defined differentiation of contractile smooth muscle cells and identification of intimal hyperplasia inhibitors. Both in vitro and in vivo evidence revealed that RepSox is better than PDGF-BB and TGF-β1 in inducing contractile phenotype of smooth muscle cells and reducing the risk of intimal hyperplasia. Keywords: pluripotent stem cells, contractile smooth muscle cells, differentiation, maturation, RepSox, NOTCH, intima hyperplasia, MYH11-NLuc-tdTomato reporter cell line, high-throughput screen, restenosis

Published

2019

2. Treg-Cell-Derived IL-35-Coated Extracellular Vesicles Promote Infectious Tolerance

Author

Jeremy A. Sullivan, Yusuke Tomita, Ewa Jankowska-Gan, Diego A. Lema, Matt P. Arvedson, Ashita Nair, William Bracamonte-Baran, Ying Zhou, Kristy K. Meyer, Weixiong Zhong, Deepali V. Sawant, Andrea L. Szymczak-Workman, Qianxia Zhang, Creg J. Workman, Seungpyo Hong, Dario A.A. Vignali, and William J. Burlingham

Subjects

Biology (General), QH301-705.5

Abstract

Summary: Interleukin-35 (IL-35) is an immunosuppressive cytokine composed of Epstein-Barr-virus-induced protein 3 (Ebi3) and IL-12α chain (p35) subunits, yet the forms that IL-35 assume and its role in peripheral tolerance remain elusive. We induce CBA-specific, IL-35-producing T regulatory (Treg) cells in TregEbi3WT C57BL/6 reporter mice and identify IL-35 producers by expression of Ebi3TdTom gene reporter plus Ebi3 and p35 proteins. Curiously, both subunits of IL-35 are displayed on the surface of tolerogen-specific Foxp3+ and Foxp3neg (iTr35) T cells. Furthermore, IL-35 producers, although rare, secrete Ebi3 and p35 on extracellular vesicles (EVs) targeting a 25- to 100-fold higher number of T and B lymphocytes, causing them to acquire surface IL-35. This surface IL-35 is absent when EV production is inhibited or if Ebi3 is genetically deleted in Treg cells. The unique ability of EVs to coat bystander lymphocytes with IL-35, promoting exhaustion in, and secondary suppression by, non-Treg cells identifies a novel mechanism of infectious tolerance. : Sullivan et al. show that while many factors and cytokines contribute to primary immunosuppression, EV-associated IL-35 uniquely promotes “infectious” tolerance not only by inducing IL-35 production in non-Treg cells but also by causing an immunosuppressive phenotype in EV-acquiring T and B cells, leading to secondary suppression of immune responses. Keywords: IL-35, extracellular vesicles, cytokines, tolerance, Treg, tetraspanin, Ebi3, p35, CD81

Published

2020

3. A Humanized Mouse Model Generated Using Surplus Neonatal Tissue

Author

Matthew E. Brown, Ying Zhou, Brian E. McIntosh, Ian G. Norman, Hannah E. Lou, Mitch Biermann, Jeremy A. Sullivan, Timothy J. Kamp, James A. Thomson, Petros V. Anagnostopoulos, and William J. Burlingham

Subjects

Medicine (General), R5-920, Biology (General), QH301-705.5

Abstract

Summary: Here, we describe the NeoThy humanized mouse model created using non-fetal human tissue sources, cryopreserved neonatal thymus and umbilical cord blood hematopoietic stem cells (HSCs). Conventional humanized mouse models are made by engrafting human fetal thymus and HSCs into immunocompromised mice. These mice harbor functional human T cells that have matured in the presence of human self-peptides and human leukocyte antigen molecules. Neonatal thymus tissue is more abundant and developmentally mature and allows for creation of up to ∼50-fold more mice per donor compared with fetal tissue models. The NeoThy has equivalent frequencies of engrafted human immune cells compared with fetal tissue humanized mice and exhibits T cell function in assays of ex vivo cell proliferation, interferon γ secretion, and in vivo graft infiltration. The NeoThy model may provide significant advantages for induced pluripotent stem cell immunogenicity studies, while bypassing the requirement for fetal tissue. : Corresponding author William Burlingham and colleagues created a humanized mouse model called the NeoThy. The NeoThy uses human neonatal, rather than fetal, tissue sources for generating a human immune system within immunocompromised mouse hosts. NeoThy mice are an attractive alternative to conventional humanized mouse models, as they enable robust and reproducible iPSC immunogenicity experiments in vivo. Keywords: NeoThy, humanized mouse, iPSC, PSC, immunogenicity, transplantation, immunology, hematopoietic stem cells, induced pluripotent stem cells, thymus

Published

2018

4. Contributors

Author

Joseph M. Ahearn, Matthew L. Albert, Farzad Alemi, Rachel Allen, Beatriz Garcia Alvarez, Daniel R. Ambruso, Beau M. Ances, Donald D. Anthony, Philip E. Auron, Laura J. Balcer, Edward D. Ball, Penelope A. Bedford, Jeff L Bidwell, Jeffrey A. Bluestone, Ezio Bonifacio, Franklin A. Bontempo, Deborah Braun, William J. Burlingham, Sharon Chambers, Amy Y. Chow, Timothy M. Clay, Jan Willem Cohen Tervaert, Bonnie A. Colleton, Anne Cooke, Darshana Dadhania, Jan Damoiseaux, Richard DeMarco, Mary L. Disis, Manuel Matas Docampo, Albert D. Donnenberg, Vera S. Donnenberg, Diane Dubois, Clemens Esche, Joyce Eskdale, Zoltán Fehérvari, Jennifer E. Fenner, Kenneth Field, Kenneth A. Foon, Grant Gallagher, Dmitriy W. Gutkin, Derek N.J. Hart, Choli Hartono, Milos Hauskrecht, Thomas Hawn, Theodore L. Hazlett, Peter S. Heeger, Paul J. Hertzog, Gottfried Himmler, Amy C. Hobeika, Peter Holman, Donald E. Hricik, David A. Isenberg, Ewa Jankowska-Gan, Kenneth Kalunian, Tatsuya Kanto, Sirid-Aimée Kellermann, Stella C. Knight, Andres Kriete, Martin A.F.J. van de Laar, Vito Lampasona, Peter P. Lee, Chau-Ching Liu, Hans Loibner, Anna Lokshin, Brian J. Lopresti, Michael T. Lotze, Matthew J. Loza, Lina Lu, Patrizia Luppi, H. Kim Lyerly, James Lyons-Weiler, David Malehorn, Ashley Mansell, Francesco M. Marincola, N. Scott Mason, Chester A. Mathis, David H. McDermott, Maureen McMahon, Ira Mellman, Diana Metes, Michael A. Morse, Paul J. Mosca, Salvador Nares, Nancy J. Newman, Andreas Obwaller, Charles G. Orosz, Takuya Osada, Monica C. Panelli, Robertson Parkman, Patricia Paukovits, Richard Pelikan, Ronald P. Pelletier, Bice Perussia, Popovic Petar, Paolo Piazza, Scott E. Plevy, Jillian A. Poole, Bruce S. Rabin, Miguel Reguiero, Charles R. Rinaldo, Lanny J. Rosenwasser, Lorin K. Roskos, David Rowe, Shimon Sakaguchi, Russell D. Salter, Minnie Sarwal, Vicki Seyfert-Margolis, Michael R. Shurin, Craig L. Slingluff, Andrew J. Stagg, Michael T. Stang, Manikkam Suthanthiran, D. Lansing Taylor, Peter C. Taylor, Sergey Y. Tetin, Angus W. Thomson, Massimo Trucco, David M. Underhill, Julia J. Unternaehrer, Anne M. VanBuskirk, Jean-Pierre Vendrell, Slavica Vuckovic, Nikola L. Vujanovic, Sharon M. Wahl, Theresa L. Whiteside, Stephen E. Winikoff, Galina V. Yamshchikov, John H. Yim, and Herbert J. Zeh

Published

2005

5. Delayed Type Hypersensitivity Responses

Author

Charles G. Orosz, Anne M. VanBuskirk, William J. Burlingham, Ewa Jankowska-Gan, and Ronald P. Pelletier

Subjects

biology, business.industry, chemical and pharmacologic phenomena, biology.organism_classification, Dth response, Vaccination, Mycobacterium tuberculosis, medicine.anatomical_structure, Immune system, Antigen, Immunology, medicine, Immunocompetence, business, Memory T cell, Sensitization

Abstract

This chapter discusses delayed type hypersensitivity (DTH) responses. DTH responses require prior immunologic sensitization to a specific antigen and thus are categorized as recall or memory T cell responses. As such, they cannot be used to measure the potential to respond to an antigen that has not yet been encountered by a given individual. Rather, they can identify specific antigens to which the individual has already made an immune response, and provide an index of the current T cell reactivity to specific recall antigens. Clinically, the DTH response is utilized to identify pathogens with which a patient is previously infected; for example, Mycobacterium tuberculosis . Specifically, a purified protein derivative (PPD), usually used at intermediate strength, is applied to assess evidence of prior exposure to the organism. In addition, DTH responses can be used to confirm successful vaccination, or to determine the degree of residual immunocompetence after injury or immunosuppressive therapy. The chapter discusses technical design and execution of the transvivo DTH assay. It explains the use of the transvivo DTH assay for detection of donor antigen-driven immune regulation, and presents various clinical studies with the transvivo DTH assay.

Published

2005