Type I IFN response associated with mTOR activation in the TAFRO subtype of idiopathic multicentric Castleman disease
Ruth-Anne Langan Pai, … , Taku Kambayashi, David C. Fajgenbaum
Ruth-Anne Langan Pai, … , Taku Kambayashi, David C. Fajgenbaum
Published May 7, 2020
Citation Information: JCI Insight. 2020;5(9):e135031. https://doi.org/10.1172/jci.insight.135031.
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Research Article Hematology Immunology

Type I IFN response associated with mTOR activation in the TAFRO subtype of idiopathic multicentric Castleman disease

Abstract

The TAFRO clinical subtype of idiopathic multicentric Castleman disease (iMCD-TAFRO) is a rare hematologic illness involving episodic disease flares of thrombocytopenia, anasarca, fever, reticulin myelofibrosis, renal dysfunction, and organomegaly (TAFRO) and progressive multiple organ dysfunction. We previously showed that the mTOR signaling pathway is elevated in lymph nodes of iMCD-TAFRO patients and that an mTOR inhibitor is effective in a small cohort of patients. However, the upstream mechanisms, cell types, and mediators involved in disease pathogenesis remain unknown. Here, we developed a targeted approach to identify candidate cellular drivers and mechanisms in iMCD-TAFRO through cellular and transcriptomic studies. Using paired iMCD-TAFRO PBMC samples collected during flare and remission, we identified T cell activation and alterations in NK cell and monocyte subset frequencies during iMCD-TAFRO flare. These changes were associated with increased Type I IFN (IFN-I) response gene signatures across CD8+ T cells, NK cells, and monocytes. Finally, we found that IFN-β stimulation of monocytes and T cells from iMCD-TAFRO patient remission samples induced increased mTOR activation compared with healthy donors, and this was abrogated with either mTORC1 or JAK1/2 inhibition. The data presented here support a potentially novel role for IFN-I signaling as a driver of increased mTOR signaling in iMCD-TAFRO.

Authors

Ruth-Anne Langan Pai, Alberto Sada Japp, Michael Gonzalez, Rozena F. Rasheed, Mariko Okumura, Daniel Arenas, Sheila K. Pierson, Victoria Powers, Awo Akosua Kesewa Layman, Charlly Kao, Hakon Hakonarson, Frits van Rhee, Michael R. Betts, Taku Kambayashi, David C. Fajgenbaum

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Figure 1

Altered number and relative frequency of circulating immune cell subsets during iMCD-TAFRO flare.

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Altered number and relative frequency of circulating immune cell subsets...
(A–C) Clinical blood counts as identified in whole blood at time of remission and flare blood draw (n = 9–10). (A) White blood cell (WBC) count representing PBMCs and neutrophils across paired remission and flare samples (P = 0.0165). (B) Absolute neutrophil count (ANC) in whole blood (P = 0.0069). (C) Absolute lymphocyte count (ALC) in whole blood (P = 0.4785). (D) Absolute monocyte count (AMC) in whole blood (P = 0.0939). (E–F) Relative percent composition of CD4+ T cells, CD8+ T cells, NK cells, B cells, and monocytes across healthy donors (n = 10) (E) and iMCD-TAFRO patients (n = 10) (F), with relative percent composition from flare (on left) and remission (on right) measured by flow cytometry. (G) Cellular composition of major immune cell types by flow cytometry. P values are based on paired 2-tailed t tests between remission and flare samples and unpaired 2-tailed t tests between healthy donor and flare. Proportion of cells were analyzed using compositional analysis (centrometric log-ratio transformation) with Welch t tests for the means (m) and Brown-Forsythe tests for the variance (s2). Data are mean ± SEM. *P < 0.05; **P < 0.01. Bonferroni’s multiple-hypotheses correction was applied to the comparisons for 3 groups, each testing for means and variances (6 independent hypotheses). P values were, therefore, adjusted by multiplication by 6; a correction was not applied for testing across 5 proportions, since these are interdependent and transformed before the statistical test.