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Literature DB >> 31045577

Differential transcriptome and development of human peripheral plasma cell subsets.

Swetha Garimalla¹, Doan C Nguyen², Jessica L Halliley³, Christopher Tipton^4,5, Alexander F Rosenberg⁶, Christopher F Fucile⁷, Celia L Saney², Shuya Kyu², Denise Kaminski⁸, Yu Qian⁹, Richard H Scheuermann⁹, Greg Gibson¹, Iñaki Sanz^4,5, F Eun-Hyung Lee^2,5.

Abstract

Human antibody-secreting cells (ASCs) triggered by immunization are globally recognized as CD19loCD38hiCD27hi. Yet, different vaccines give rise to antibody responses of different longevity, suggesting ASC populations are heterogeneous. We define circulating-ASC heterogeneity in vaccine responses using multicolor flow cytometry, morphology, VH repertoire, and RNA transcriptome analysis. We also tested differential survival using a human cell-free system that mimics the bone marrow (BM) microniche. In peripheral blood, we identified 3 CD19+ and 2 CD19- ASC subsets. All subsets contributed to the vaccine-specific responses and were characterized by in vivo proliferation and activation. The VH repertoire demonstrated strong oligoclonality with extensive interconnectivity among the 5 subsets and switched memory B cells. Transcriptome analysis showed separation of CD19+ and CD19- subsets that included pathways such as cell cycle, hypoxia, TNF-α, and unfolded protein response. They also demonstrated similar long-term in vitro survival after 48 days. In summary, vaccine-induced ASCs with different surface markers (CD19 and CD138) are derived from shared proliferative precursors yet express distinctive transcriptomes. Equal survival indicates that all ASC compartments are endowed with long-lived potential. Accordingly, in vivo survival of peripheral long-lived plasma cells may be determined in part by their homing and residence in the BM microniche.

Entities: Disease Gene Species

Keywords: Adaptive immunity; Immunoglobulins; Immunology

Year: 2019 PMID： 31045577 PMCID： PMC6538338 DOI： 10.1172/jci.insight.126732

Source DB: PubMed Journal: JCI Insight ISSN： 2379-3708

60 in total

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