Literature DB >> 27648464

Restoring immune tolerance in neuromyelitis optica: Part II.

Amit Bar-Or1, Larry Steinman1, Jacinta M Behne1, Daniel Benitez-Ribas1, Peter S Chin1, Michael Clare-Salzler1, Donald Healey1, James I Kim1, David M Kranz1, Andreas Lutterotti1, Roland Martin1, Sven Schippling1, Pablo Villoslada1, Cheng-Hong Wei1, Howard L Weiner1, Scott S Zamvil1, Terry J Smith1, Michael R Yeaman1.   

Abstract

Neuromyelitis optica spectrum disorder (NMO/SD) and its clinical variants have at their core the loss of immune tolerance to aquaporin-4 and perhaps other autoantigens. The characteristic phenotype is disruption of astrocyte function and demyelination of spinal cord, optic nerves, and particular brain regions. In this second of a 2-part article, we present further perspectives regarding the pathogenesis of NMO/SD and how this disease might be amenable to emerging technologies aimed at restoring immune tolerance to disease-implicated self-antigens. NMO/SD appears to be particularly well-suited for these strategies since aquaporin-4 has already been identified as the dominant autoantigen. The recent technical advances in reintroducing immune tolerance in experimental models of disease as well as in humans should encourage quantum leaps in this area that may prove productive for novel therapy. In this part of the article series, the potential for regulatory T and B cells is brought into focus, as are new approaches to oral tolerization. Finally, a roadmap is provided to help identify potential issues in clinical development and guide applications in tolerization therapy to solving NMO/SD through the use of emerging technologies. Each of these perspectives is intended to shine new light on potential cures for NMO/SD and other autoimmune diseases, while sparing normal host defense mechanisms.

Entities:  

Year:  2016        PMID: 27648464      PMCID: PMC5015540          DOI: 10.1212/NXI.0000000000000277

Source DB:  PubMed          Journal:  Neurol Neuroimmunol Neuroinflamm        ISSN: 2332-7812


  59 in total

Review 1.  A case for regulatory B cells.

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Journal:  J Immunol       Date:  2006-01-15       Impact factor: 5.422

2.  Regulatory B cells are identified by expression of TIM-1 and can be induced through TIM-1 ligation to promote tolerance in mice.

Authors:  Qing Ding; Melissa Yeung; Geoffrey Camirand; Qiang Zeng; Hisaya Akiba; Hideo Yagita; Geetha Chalasani; Mohamed H Sayegh; Nader Najafian; David M Rothstein
Journal:  J Clin Invest       Date:  2011-08-08       Impact factor: 14.808

3.  CD4+CD25high regulatory cells in human peripheral blood.

Authors:  C Baecher-Allan; J A Brown; G J Freeman; D A Hafler
Journal:  J Immunol       Date:  2001-08-01       Impact factor: 5.422

Review 4.  Mechanisms of impaired regulation by CD4(+)CD25(+)FOXP3(+) regulatory T cells in human autoimmune diseases.

Authors:  Jane Hoyt Buckner
Journal:  Nat Rev Immunol       Date:  2010-12       Impact factor: 53.106

5.  CD19(+)CD24(hi)CD38(hi) B cells exhibit regulatory capacity in healthy individuals but are functionally impaired in systemic Lupus Erythematosus patients.

Authors:  Paul A Blair; Lina Yassin Noreña; Fabian Flores-Borja; David J Rawlings; David A Isenberg; Michael R Ehrenstein; Claudia Mauri
Journal:  Immunity       Date:  2010-01-14       Impact factor: 31.745

6.  Human regulatory T cells with alloantigen specificity are more potent inhibitors of alloimmune skin graft damage than polyclonal regulatory T cells.

Authors:  Pervinder Sagoo; Niwa Ali; Garima Garg; Frank O Nestle; Robert I Lechler; Giovanna Lombardi
Journal:  Sci Transl Med       Date:  2011-05-18       Impact factor: 17.956

7.  Selective depletion of Foxp3+ regulatory T cells induces a scurfy-like disease.

Authors:  Katharina Lahl; Christoph Loddenkemper; Cathy Drouin; Jennifer Freyer; Jon Arnason; Gérard Eberl; Alf Hamann; Hermann Wagner; Jochen Huehn; Tim Sparwasser
Journal:  J Exp Med       Date:  2007-01-02       Impact factor: 14.307

8.  IgG marker of optic-spinal multiple sclerosis binds to the aquaporin-4 water channel.

Authors:  Vanda A Lennon; Thomas J Kryzer; Sean J Pittock; A S Verkman; Shannon R Hinson
Journal:  J Exp Med       Date:  2005-08-08       Impact factor: 14.307

9.  Clinical grade manufacturing of human alloantigen-reactive regulatory T cells for use in transplantation.

Authors:  A L Putnam; N Safinia; A Medvec; M Laszkowska; M Wray; M A Mintz; E Trotta; G L Szot; W Liu; A Lares; K Lee; A Laing; R I Lechler; J L Riley; J A Bluestone; G Lombardi; Q Tang
Journal:  Am J Transplant       Date:  2013-09-18       Impact factor: 8.086

10.  CD25+ CD4+ T cells, expanded with dendritic cells presenting a single autoantigenic peptide, suppress autoimmune diabetes.

Authors:  Kristin V Tarbell; Sayuri Yamazaki; Kara Olson; Priscilla Toy; Ralph M Steinman
Journal:  J Exp Med       Date:  2004-06-07       Impact factor: 14.307
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  14 in total

Review 1.  Emerging therapeutic targets for neuromyelitis optica spectrum disorder.

Authors:  Lukmanee Tradtrantip; Nithi Asavapanumas; Alan S Verkman
Journal:  Expert Opin Ther Targets       Date:  2020-03-02       Impact factor: 6.902

Review 2.  [Optical coherence tomography in neuromyelitis optica spectrum disorders].

Authors:  F C Oertel; H Zimmermann; A U Brandt; F Paul
Journal:  Nervenarzt       Date:  2017-12       Impact factor: 1.214

Review 3.  Diffusion tensor imaging for multilevel assessment of the visual pathway: possibilities for personalized outcome prediction in autoimmune disorders of the central nervous system.

Authors:  Joseph Kuchling; Alexander U Brandt; Friedemann Paul; Michael Scheel
Journal:  EPMA J       Date:  2017-07-25       Impact factor: 6.543

Review 4.  Optical coherence tomography in neuromyelitis optica spectrum disorders: potential advantages for individualized monitoring of progression and therapy.

Authors:  Frederike C Oertel; Hanna Zimmermann; Friedemann Paul; Alexander U Brandt
Journal:  EPMA J       Date:  2017-12-22       Impact factor: 6.543

Review 5.  Diagnosis and Treatment of NMO Spectrum Disorder and MOG-Encephalomyelitis.

Authors:  Nadja Borisow; Masahiro Mori; Satoshi Kuwabara; Michael Scheel; Friedemann Paul
Journal:  Front Neurol       Date:  2018-10-23       Impact factor: 4.003

6.  Immune tolerance in multiple sclerosis and neuromyelitis optica with peptide-loaded tolerogenic dendritic cells in a phase 1b trial.

Authors:  Irati Zubizarreta; Georgina Flórez-Grau; Gemma Vila; Raquel Cabezón; Carolina España; Magi Andorra; Albert Saiz; Sara Llufriu; Maria Sepulveda; Nuria Sola-Valls; Elena H Martinez-Lapiscina; Irene Pulido-Valdeolivas; Bonaventura Casanova; Marisa Martinez Gines; Nieves Tellez; Celia Oreja-Guevara; Marta Español; Esteve Trias; Joan Cid; Manel Juan; Miquel Lozano; Yolanda Blanco; Lawrence Steinman; Daniel Benitez-Ribas; Pablo Villoslada
Journal:  Proc Natl Acad Sci U S A       Date:  2019-04-08       Impact factor: 11.205

Review 7.  New Therapeutic Landscape in Neuromyelitis Optica.

Authors:  Madina Tugizova; Luka Vlahovic; Anna Tomczak; Nora Sandrine Wetzel; May Htwe Han
Journal:  Curr Treat Options Neurol       Date:  2021-03-30       Impact factor: 3.972

Review 8.  Soluble IL-7Rα/sCD127 in Health, Disease, and Its Potential Role as a Therapeutic Agent.

Authors:  Priscila O Barros; Tamara K Berthoud; Nawaf Aloufi; Jonathan B Angel
Journal:  Immunotargets Ther       Date:  2021-03-08

Review 9.  Treatment strategies for autoimmune encephalitis.

Authors:  Yong-Won Shin; Soon-Tae Lee; Kyung-Il Park; Keun-Hwa Jung; Ki-Young Jung; Sang Kun Lee; Kon Chu
Journal:  Ther Adv Neurol Disord       Date:  2017-08-16       Impact factor: 6.570

Review 10.  Review of approved NMO therapies based on mechanism of action, efficacy and long-term effects.

Authors:  Staley A Brod
Journal:  Mult Scler Relat Disord       Date:  2020-10-07       Impact factor: 4.339
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