Literature DB >> 25009205

Human XCR1+ dendritic cells derived in vitro from CD34+ progenitors closely resemble blood dendritic cells, including their adjuvant responsiveness, contrary to monocyte-derived dendritic cells.

Sreekumar Balan1, Vincent Ollion2, Nicholas Colletti3, Rabie Chelbi1, Frédéric Montanana-Sanchis1, Hong Liu3, Thien-Phong Vu Manh1, Cindy Sanchez1, Juliette Savoret1, Ivan Perrot4, Anne-Claire Doffin5, Even Fossum6, Didier Bechlian7, Christian Chabannon7, Bjarne Bogen8, Carine Asselin-Paturel4, Michael Shaw3, Timothy Soos3, Christophe Caux2, Jenny Valladeau-Guilemond2, Marc Dalod9.   

Abstract

Human monocyte-derived dendritic cell (MoDC) have been used in the clinic with moderately encouraging results. Mouse XCR1(+) DC excel at cross-presentation, can be targeted in vivo to induce protective immunity, and share characteristics with XCR1(+) human DC. Assessment of the immunoactivation potential of XCR1(+) human DC is hindered by their paucity in vivo and by their lack of a well-defined in vitro counterpart. We report in this study a protocol generating both XCR1(+) and XCR1(-) human DC in CD34(+) progenitor cultures (CD34-DC). Gene expression profiling, phenotypic characterization, and functional studies demonstrated that XCR1(-) CD34-DC are similar to canonical MoDC, whereas XCR1(+) CD34-DC resemble XCR1(+) blood DC (bDC). XCR1(+) DC were strongly activated by polyinosinic-polycytidylic acid but not LPS, and conversely for MoDC. XCR1(+) DC and MoDC expressed strikingly different patterns of molecules involved in inflammation and in cross-talk with NK or T cells. XCR1(+) CD34-DC but not MoDC efficiently cross-presented a cell-associated Ag upon stimulation by polyinosinic-polycytidylic acid or R848, likewise to what was reported for XCR1(+) bDC. Hence, it is feasible to generate high numbers of bona fide XCR1(+) human DC in vitro as a model to decipher the functions of XCR1(+) bDC and as a potential source of XCR1(+) DC for clinical use.
Copyright © 2014 by The American Association of Immunologists, Inc.

Entities:  

Mesh:

Substances:

Year:  2014        PMID: 25009205      PMCID: PMC4120898          DOI: 10.4049/jimmunol.1401243

Source DB:  PubMed          Journal:  J Immunol        ISSN: 0022-1767            Impact factor:   5.422


  52 in total

1.  Human dendritic cell subsets from spleen and blood are similar in phenotype and function but modified by donor health status.

Authors:  Diana Mittag; Anna I Proietto; Thomas Loudovaris; Stuart I Mannering; David Vremec; Ken Shortman; Li Wu; Leonard C Harrison
Journal:  J Immunol       Date:  2011-04-22       Impact factor: 5.422

2.  A large number of mature and functional dendritic cells can be efficiently generated from umbilical cord blood-derived mononuclear cells by a simple two-step culture method.

Authors:  Sreekumar Balan; Vaijayanti P Kale; Lalita S Limaye
Journal:  Transfusion       Date:  2010-11       Impact factor: 3.157

3.  Nomenclature of monocytes and dendritic cells in blood.

Authors:  Loems Ziegler-Heitbrock; Petronela Ancuta; Suzanne Crowe; Marc Dalod; Veronika Grau; Derek N Hart; Pieter J M Leenen; Yong-Jun Liu; Gordon MacPherson; Gwendalyn J Randolph; Juergen Scherberich; Juergen Schmitz; Ken Shortman; Silvano Sozzani; Herbert Strobl; Marek Zembala; Jonathan M Austyn; Manfred B Lutz
Journal:  Blood       Date:  2010-07-13       Impact factor: 22.113

4.  Generation of cytomegalovirus-specific human T-lymphocyte clones by using autologous B-lymphoblastoid cells with stable expression of pp65 or IE1 proteins: a tool to study the fine specificity of the antiviral response.

Authors:  C Retière; V Prod'homme; B M Imbert-Marcille; M Bonneville; H Vié; M M Hallet
Journal:  J Virol       Date:  2000-05       Impact factor: 5.103

5.  Fcγ receptor antigen targeting potentiates cross-presentation by human blood and lymphoid tissue BDCA-3+ dendritic cells.

Authors:  Thijs W H Flinsenberg; Ewoud B Compeer; Dan Koning; Mark Klein; Femke J Amelung; Debbie van Baarle; Jaap Jan Boelens; Marianne Boes
Journal:  Blood       Date:  2012-10-23       Impact factor: 22.113

6.  Superior antigen cross-presentation and XCR1 expression define human CD11c+CD141+ cells as homologues of mouse CD8+ dendritic cells.

Authors:  Annabell Bachem; Steffen Güttler; Evelyn Hartung; Frédéric Ebstein; Michael Schaefer; Astrid Tannert; Abdulgabar Salama; Kamran Movassaghi; Corinna Opitz; Hans W Mages; Volker Henn; Peter-Michael Kloetzel; Stephanie Gurka; Richard A Kroczek
Journal:  J Exp Med       Date:  2010-05-17       Impact factor: 14.307

7.  Thrombopoietin cooperates with FLT3-ligand in the generation of plasmacytoid dendritic cell precursors from human hematopoietic progenitors.

Authors:  Wei Chen; Svetlana Antonenko; Joel M Sederstrom; Xueqing Liang; Anissa S H Chan; Holger Kanzler; Bianca Blom; Bruce R Blazar; Yong-Jun Liu
Journal:  Blood       Date:  2003-12-11       Impact factor: 22.113

8.  Selective expression of the chemokine receptor XCR1 on cross-presenting dendritic cells determines cooperation with CD8+ T cells.

Authors:  Brigitte G Dorner; Martin B Dorner; Xuefei Zhou; Corinna Opitz; Ahmed Mora; Steffen Güttler; Andreas Hutloff; Hans W Mages; Katja Ranke; Michael Schaefer; Robert S Jack; Volker Henn; Richard A Kroczek
Journal:  Immunity       Date:  2009-11-12       Impact factor: 31.745

9.  The equivalents of human blood and spleen dendritic cell subtypes can be generated in vitro from human CD34(+) stem cells in the presence of fms-like tyrosine kinase 3 ligand and thrombopoietin.

Authors:  A I Proietto; D Mittag; A W Roberts; N Sprigg; L Wu
Journal:  Cell Mol Immunol       Date:  2012-10-22       Impact factor: 11.530

10.  Comparative transcriptional and functional profiling defines conserved programs of intestinal DC differentiation in humans and mice.

Authors:  Payal B Watchmaker; Katharina Lahl; Mike Lee; Dirk Baumjohann; John Morton; Sun Jung Kim; Ruizhu Zeng; Alexander Dent; K Mark Ansel; Betty Diamond; Husein Hadeiba; Eugene C Butcher
Journal:  Nat Immunol       Date:  2013-12-01       Impact factor: 25.606
View more
  50 in total

1.  Single-Cell RNA-Seq Mapping of Human Thymopoiesis Reveals Lineage Specification Trajectories and a Commitment Spectrum in T Cell Development.

Authors:  Justin Le; Jeong Eun Park; Vi Luan Ha; Annie Luong; Sergio Branciamore; Andrei S Rodin; Grigoriy Gogoshin; Fan Li; Yong-Hwee Eddie Loh; Virginia Camacho; Sweta B Patel; Robert S Welner; Chintan Parekh
Journal:  Immunity       Date:  2020-06-16       Impact factor: 31.745

2.  Towards superior dendritic-cell vaccines for cancer therapy.

Authors:  Mansi Saxena; Sreekumar Balan; Vladimir Roudko; Nina Bhardwaj
Journal:  Nat Biomed Eng       Date:  2018-06-11       Impact factor: 25.671

3.  High-Dimensional Phenotypic Mapping of Human Dendritic Cells Reveals Interindividual Variation and Tissue Specialization.

Authors:  Marcela Alcántara-Hernández; Rebecca Leylek; Lisa E Wagar; Edgar G Engleman; Tibor Keler; M Peter Marinkovich; Mark M Davis; Garry P Nolan; Juliana Idoyaga
Journal:  Immunity       Date:  2017-12-05       Impact factor: 31.745

4.  Constitutive resistance to viral infection in human CD141+ dendritic cells.

Authors:  Aymeric Silvin; Chun I Yu; Xavier Lahaye; Francesco Imperatore; Jean-Baptiste Brault; Sylvain Cardinaud; Christian Becker; Wing-Hong Kwan; Cécile Conrad; Mathieu Maurin; Christel Goudot; Santy Marques-Ladeira; Yuanyuan Wang; Virginia Pascual; Esperanza Anguiano; Randy A Albrecht; Matteo Iannacone; Adolfo García-Sastre; Bruno Goud; Marc Dalod; Arnaud Moris; Miriam Merad; A Karolina Palucka; Nicolas Manel
Journal:  Sci Immunol       Date:  2017-07-07

5.  Co-delivery of the NKT agonist α-galactosylceramide and tumor antigens to cross-priming dendritic cells breaks tolerance to self-antigens and promotes antitumor responses.

Authors:  Reem Ghinnagow; Julie De Meester; Luis Javier Cruz; Caroline Aspord; Stéphanie Corgnac; Elodie Macho-Fernandez; Daphnée Soulard; Josette Fontaine; Laurence Chaperot; Julie Charles; Fabrice Soncin; Fathia Mami-Chouaib; Joel Plumas; Christelle Faveeuw; François Trottein
Journal:  Oncoimmunology       Date:  2017-08-18       Impact factor: 8.110

6.  Trial watch: Dendritic cell (DC)-based immunotherapy for cancer.

Authors:  Raquel S Laureano; Jenny Sprooten; Isaure Vanmeerbeerk; Daniel M Borras; Jannes Govaerts; Stefan Naulaerts; Zwi N Berneman; Benoit Beuselinck; Kalijn F Bol; Jannie Borst; An Coosemans; Angeliki Datsi; Jitka Fučíková; Lisa Kinget; Bart Neyns; Gerty Schreibelt; Evelien Smits; Rüdiger V Sorg; Radek Spisek; Kris Thielemans; Sandra Tuyaerts; Steven De Vleeschouwer; I Jolanda M de Vries; Yanling Xiao; Abhishek D Garg
Journal:  Oncoimmunology       Date:  2022-07-04       Impact factor: 7.723

Review 7.  Human dendritic cell subsets and function in health and disease.

Authors:  Meredith O'Keeffe; Wai Hong Mok; Kristen J Radford
Journal:  Cell Mol Life Sci       Date:  2015-08-05       Impact factor: 9.261

8.  Direct Reprogramming of Mouse Embryonic Fibroblasts to Conventional Type 1 Dendritic Cells by Enforced Expression of Transcription Factors.

Authors:  Fábio F Rosa; Cristiana F Pires; Olga Zimmermannova; Carlos-Filipe Pereira
Journal:  Bio Protoc       Date:  2020-05-20

9.  Human type 1 and type 2 conventional dendritic cells express indoleamine 2,3-dioxygenase 1 with functional effects on T cell priming.

Authors:  Simone P Sittig; Jasper J P van Beek; Georgina Flórez-Grau; Jorieke Weiden; Sonja I Buschow; Mirjam C van der Net; Rianne van Slooten; Marcel M Verbeek; P Ben H Geurtz; Johannes Textor; Carl G Figdor; I Jolanda M de Vries; Gerty Schreibelt
Journal:  Eur J Immunol       Date:  2021-03-22       Impact factor: 5.532

10.  CD1c+ blood dendritic cells have Langerhans cell potential.

Authors:  Paul Milne; Venetia Bigley; Merry Gunawan; Muzlifah Haniffa; Matthew Collin
Journal:  Blood       Date:  2014-10-28       Impact factor: 25.476
View more

北京卡尤迪生物科技股份有限公司 © 2022-2023.