Journal of Biological Chemistry

Journal of Biological Chemistry

Volume 295, Issue 41, 9 October 2020, Pages 14214-14221
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Signal Transduction
Annexin A5 is essential for PKCθ translocation during T-cell activation

https://doi.org/10.1074/jbc.RA120.015143Get rights and content
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T-cell activation is a critical part of the adaptive immune system, enabling responses to foreign cells and external stimulus. In this process, T-cell antigen receptor (TCR) activation stimulates translocation of the downstream kinase PKCθ to the membrane, leading to NF-κB activation and thus transcription of relevant genes. However, the details of how PKCθ is recruited to the membrane remain enigmatic. It is known that annexin A5 (ANXA5), a calcium-dependent membrane-binding protein, has been reported to mediate PKCδ activation by interaction with PKCδ, a homologue of PKCθ, which implicates a potential role of ANXA5 involved in PKCθ signaling. Here we demonstrate that ANXA5 does play a critical role in the recruitment of PKCθ to the membrane during T-cell activation. ANXA5 knockout in Jurkat T cells substantially inhibited the membrane translocation of PKCθ upon TCR engagement and blocked the recruitment of CARMA1-BCL10-MALT1 signalosome, which provides a platform for the catalytic activation of IKKs and subsequent activation of canonical NF-κB signaling in activated T cells. As a result, NF-κB activation was impaired in ANXA5-KO T cells. T-cell activation was also suppressed by ANAX5 knockdown in primary T cells. These results demonstrated a novel role of ANXA5 in PKC translocation and PKC signaling during T-cell activation.

ANXA5
PKCθ
NF-κB
T-cell activation
TCR
annexin
T-cell receptor (TCR)
protein kinase C (PKC)
T-cell biology
NF-κB (NF-KB)

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Author contributions—Z. Hu, L. L., X. Z., J. Z., and Z. Hua conceptualization; Z. Hu, L. L., M. L., P. X., and X. Z. resources; Z. Hu, L. L., B. Z., Y. H., X. W., and X. Z. data curation; Z. Hu, L. L., B. Z., and X. Z. formal analysis; Z. Hu, L. L., and X. Z. supervision; Z. Hu, L. L., Y. H., and X. Z. validation; Z. Hu, L. L., B. Z., X. W., X. L., X. Z., and J. Z. investigation; Z. Hu, L. L., and X. Z. visualization; Z. Hu, L. L., M. L., X. Z., and J. Z. methodology; Z. Hu and X. Z. project administration; X. Z. software; X. Z. writing-original draft; X. Z. and J. Z. writing-review and editing; Z. Hua funding acquisition.

Funding and additional information—This study was supported in part by Chinese National Natural Sciences Foundation Grants 81630092 and 81773099 (to Z. H.) and by National Key R&D Research Program, Ministry of Science and Technology, Grant 2017YFA0506002 (to Z. H.).

Conflict of interest—The authors declare that they have no conflicts of interest with the contents of this article.

Abbreviations—The abbreviations used are:

    TCR

    T-cell receptor

    PKC

    protein kinase C

    PS

    phosphatidylserine

    TPA

    12-O-tetradecanoylphorbol-13-acetate

    ConA

    concanavalin A

    IL

    interleukin

    ERK

    extracellular signal–regulated kinase

    MAPK

    mitogen-activated protein kinase

    CBM

    CARMA1-Bcl10-MALT1

    KO

    knockout.

These authors contributed equally to this work.

© 2020 Hu et al.