Differential transcriptome and development of human peripheral plasma cell subsets
Swetha Garimalla, … , Iñaki Sanz, F. Eun-Hyung Lee
Swetha Garimalla, … , Iñaki Sanz, F. Eun-Hyung Lee
Published April 2, 2019
Citation Information: JCI Insight. 2019;4(9):e126732. https://doi.org/10.1172/jci.insight.126732.
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Research Article Immunology

Differential transcriptome and development of human peripheral plasma cell subsets

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.

Authors

Swetha Garimalla, Doan C. Nguyen, Jessica L. Halliley, Christopher Tipton, Alexander F. Rosenberg, Christopher F. Fucile, Celia L. Saney, Shuya Kyu, Denise Kaminski, Yu Qian, Richard H. Scheuermann, Greg Gibson, Iñaki Sanz, F. Eun-Hyung Lee

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Figure 1

ASC subsets in human blood 7 days after tetanus vaccination.

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ASC subsets in human blood 7 days after tetanus vaccination. (A) Top pan...
(A) Top panels divide the CD19+ and CD19 fractions. Lower panels represent subsets of CD19IgD (left) and CD19+IgD (right) fractions. (B) Morphology of blood ASC subsets (×100 magnification) by Wright-Giemsa stain. Left column: Sorted blood ASC subsets on day 7 after tetanus vaccination. ASC populations (pops) 1 to 5 and naive B cells are shown. Right column: Percentage of intracellular BLIMP-1 staining per subset is shown in blue histograms (naive controls in red). (C) Percentage of each ASC subset and naive B cells (N) expressing IgG, IgA, or IgM isotypes after peak vaccination. (D) Quantification of each blood ASC subset (pops 1 to 5) in cells/ml (top) and percentage of PBMCs (bottom). (E) Quantitative RNA expression of 5,000 sorted ASC subsets and naive and memory B cells for Pax5 (top), BLIMP-1 (middle), and Xbp-1 (lower), normalized to GAPDH in blood. Relative mRNA expression is expressed in arbitrary units.