Human CD4+ CD25hi Foxp3+ regulatory T cells are derived by rapid turnover of memory populations in vivo
Milica Vukmanovic-Stejic, Yan Zhang, Joanne E. Cook, Jean M. Fletcher, Arthur McQuaid, Joanne E. Masters, Malcolm H.A. Rustin, Leonie S. Taams, Peter C.L. Beverley, Derek C. Macallan, Arne N. Akbar
Milica Vukmanovic-Stejic, Yan Zhang, Joanne E. Cook, Jean M. Fletcher, Arthur McQuaid, Joanne E. Masters, Malcolm H.A. Rustin, Leonie S. Taams, Peter C.L. Beverley, Derek C. Macallan, Arne N. Akbar
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Research Article Immunology

Human CD4+ CD25hi Foxp3+ regulatory T cells are derived by rapid turnover of memory populations in vivo

Abstract

While memory T cells are maintained by continuous turnover, it is not clear how human regulatory CD4+CD45RO+CD25hi Foxp3+ T lymphocyte populations persist throughout life. We therefore used deuterium labeling of cycling cells in vivo to determine whether these cells could be replenished by proliferation. We found that CD4+CD45RO+Foxp3+CD25hi T lymphocytes were highly proliferative, with a doubling time of 8 days, compared with memory CD4+CD45RO+Foxp3–CD25– (24 days) or naive CD4+CD45RA+Foxp3–CD25– populations (199 days). However, the regulatory population was susceptible to apoptosis and had critically short telomeres and low telomerase activity. It was therefore unlikely to be self regenerating. These data are consistent with continuous production from another population source. We found extremely close TCR clonal homology between regulatory and memory CD4+ T cells. Furthermore, antigen-related expansions within certain TCR Vβ families were associated with parallel numerical increases of CD4+CD45RO+CD25hiFoxp3+ Tregs with the same Vβ usage. It is therefore unlikely that all human CD4+CD25+Foxp3+ Tregs are generated as a separate functional lineage in the thymus. Instead, our data suggest that a proportion of this regulatory population is generated from rapidly dividing, highly differentiated memory CD4+ T cells; this has considerable implications for the therapeutic manipulation of these cells in vivo.

Authors

Milica Vukmanovic-Stejic, Yan Zhang, Joanne E. Cook, Jean M. Fletcher, Arthur McQuaid, Joanne E. Masters, Malcolm H.A. Rustin, Leonie S. Taams, Peter C.L. Beverley, Derek C. Macallan, Arne N. Akbar

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Figure 2

Analysis of in vivo kinetics of human CD4+ CD25hi T cells.

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Analysis of in vivo kinetics of human CD4+ ...
Outline of protocol is shown in A. Subjects received 0.64 g/kg 6,6-D2-glucose by half-hourly oral dosing for 10 hours. Blood samples were taken first during labeling, for analysis of deuterium content in plasma glucose, and second after labeling, to determine deuterium content in DNA. (B) Fraction of labeled cells (F, expressed relative to a labeling phase of 1 day) for each sorted cell population from 4 younger subjects (Y1–Y4) was determined. Open circles represent CD4+CD45RO+CD25hi, filled circles represent CD4+CD45RO+CD25, and open squares represent CD4+CD45RA+ T cells. Error bars represent SD of triplicate gas chromatography mass spectrometry (GCMS) measurements (labeling of CD4+CD45RA+ T cells was too low to be detectable in individuals C16 and C17). Modeled proliferation and disappearance kinetics are best-fit curves as described in Methods. (C) The fraction of labeled cells in sorted T cell populations from t4 older subjects (O1–O2) and curve fits were analyzed and modeled in the same way.