BCMA-directed mRNA CAR-T cell therapy for myasthenia gravis: exploratory biomarker analysis of a placebo-controlled phase 2b trial

Renee Fedak(Cara Therapeutics (United States)), Rachel N. Ruggerie(Cara Therapeutics (United States)), Yufei Shan(Cara Therapeutics (United States)), Elizabeth J. Curvino(Cara Therapeutics (United States)), Juliana F. de Sousa(Cara Therapeutics (United States)), S. E. Daniel(Cara Therapeutics (United States)), Minhtran Ngo-Casi(Cara Therapeutics (United States)), Hafsa Kamboh(Cara Therapeutics (United States)), Tuan Vu(University of South Florida), Hacer Durmuş(Istanbul University), Tahseen Mozaffar(University of California, Irvine), James F. Howard(University of North Carolina at Chapel Hill), Emily English(Cara Therapeutics (United States)), Albina Benson(Cara Therapeutics (United States)), Matthew T. Duvernay(Cara Therapeutics (United States)), Michael S. Singer(Cara Therapeutics (United States)), Murat V. Kalayoglu(Cara Therapeutics (United States)), Carsten Brunn(Cara Therapeutics (United States)), Aaron Bodansky(University of California, San Francisco), Mark S. Anderson(University of California, San Francisco), Joseph L. DeRisi(University of California, San Francisco), Samantha Rocio Alcántar García(University of California, San Francisco), David J. L. Yu(University of California, San Francisco), Kelsey C. Zorn(University of California, San Francisco), Metin Kurtoğlu(Cara Therapeutics (United States)), Miloš D. Miljković(Cara Therapeutics (United States)), C. Andrew Stewart(Cara Therapeutics (United States)), Christopher M. Jewell(Cara Therapeutics (United States)), on behalf the SPPiRE Study Research Team, Juliana F. de Sousa(Cara Therapeutics (United States)), Charito S. Buensuceso(Cara Therapeutics (United States)), Lisa H. Tostanoski(Cara Therapeutics (United States)), Yi Zhang(Cara Therapeutics (United States)), Heng Xu(Cara Therapeutics (United States)), Chad Pope(Cara Therapeutics (United States)), Dina Schneider(Cara Therapeutics (United States)), Adam English(Cara Therapeutics (United States)), Atanas Filev(Cara Therapeutics (United States)), Jennifer L. Biaksangi(Cara Therapeutics (United States)), George Small(Allegheny General Hospital), Michael H. Rivner(Augusta University), Michael Badruddoja(Center for Neurosciences), Bennett Myers(Dent Neurologic Institute), Sheetal Shroff(Methodist Hospital), Adam Slanksy(Neurology Associates), Kelly Holley(Neurology Associates), Gregory Sahagian(Neurology Center of Southern California), Tara Quesnell(Neurology Center of Southern California), Marc H. Feinberg(Boca Raton Regional Hospital), Gabrielle DeMaria(Boca Raton Regional Hospital), Mithila Vullaganti(Tufts University), Carolina Barnett-Tapia(University Health Network), Meg Mendoza(University Health Network), Mona Irannejad(University Health Network), Zaeem Siddiqi(University of Alberta), Ali A. Habib(University of California, Irvine), Thomas Ragole(University of Colorado Anschutz Medical Campus), Mamatha Pasnoor(University of Kansas Medical Center), Rebecca E. Traub(University of North Carolina at Chapel Hill), Manisha Chopra(University of North Carolina at Chapel Hill), Natalie S. Grover(University of North Carolina at Chapel Hill), Yara A. Park(University of North Carolina at Chapel Hill), Matthew Karafin(University of North Carolina at Chapel Hill), Amy Trunnell(University of North Carolina at Chapel Hill), Catherine Cheng(University of North Carolina at Chapel Hill), Chafic Karam(University of Pennsylvania), Darnell Davis(University of South Florida), Jessica Shaw(University of South Florida), Naraly Requena(University of South Florida), Amanda Peltier(Vanderbilt University), Kelly Gwathmey(Virginia Commonwealth University)
Nature Medicine
January 9, 2026
10.1038/s41591-025-04170-z
Cited by 6Open Access
Full Text

Abstract

Chimeric antigen receptor (CAR)-T cell therapies have the potential to transform treatment of autoimmune disease by resetting the immune system. However, adoption of cell therapies in the autoimmune space is limited by hurdles such as inpatient administration, lymphodepletion and safety concerns around cytokine release syndrome and non-specific immunosuppression. RNA-based cell therapy has potential to address these limitations. Here we report prespecified exploratory analyses from a successful placebo-controlled, double-blind, randomized phase 2b trial in patients with generalized myasthenia gravis who received Descartes-08, an autologous, RNA-encoded anti-B cell maturation antigen (BCMA) CAR-T cell therapy. In 66.7% of patients (n = 10/15), transient targeting of BCMA with Descartes-08 administered in an outpatient setting without lymphodepletion resulted in durable clinical efficacy. Comparison of Descartes-08-treated (n ≤ 19) and placebo (n ≤ 15) cohorts by flow cytometry, serum profiling, multiplexing cytokine analysis and bulk/single-cell transcriptional analysis reveals a precision retuning of self-reactivity demonstrated by increased pro-immune function, decreased activity of BCMA+ plasma cells and plasmacytoid dendritic cells and reductions in disease-associated cytokines, such as IL-6. Furthermore, antibody and T cell receptor analysis revealed altered circulating repertoires of self-reactive antibodies and T cell clones among Descartes-08 participants. These effects occurred without immune suppression, indicated by the lack of decline in vaccine-specific antibodies or hypogammaglobulinemia. Our findings unveil a new type of immune reset and support the development of BCMA-targeted RNA cell therapies as a more accessible therapy for autoimmune diseases. ClinicalTrials.gov identifier: NCT04146051 . Analysis of a placebo-controlled trial of a BCMA-targeting CAR-T cell therapy in patients with myasthenia gravis shows that CAR-T cell infusion selectively remodels the systemic immune environment, with elimination of BCMA-high plasma cells and activated plasmacytoid dendritic cells and changes in the autoreactive B cell repertoire.

Related Papers

No related papers found

Powered by citation graph analysis