Elimination of CD4HLA-G T Cells Overcomes Castration-resistance in Prostate Cancer Therapy

Overview

Journal Cell Res

Specialty Cell Biology

Date 2018 Oct 10

PMID 30297869

Citations 13

Authors

Chao Wang

Jiahuan Chen

Qianfei Zhang

Wang Li

Shengbo Zhang

Yanjie Xu

Fang Wang

Bing Zhang

Yan Zhang

Wei-Qiang Gao

Affiliations

Soon will be listed here.

Abstract

Androgen deprivation therapy (ADT) is a main treatment for prostate cancer (PCa) but the disease often recurs and becomes castration-resistant in nearly all patients. Recent data implicate the involvement of immune cells in the development of this castration-resistant prostate cancer (CRPC). In particular, T cells have been found to be expanded in both PCa patients and mouse models shortly after androgen deprivation. However, whether or which of the T cell subtypes play an important role during the development of CRPC is unknown. Here we identified a novel population of CD4HLA-G T cells that undergo significant expansion in PCa patients after ADT. In mouse PCa models, a similar CD4 T cell population expands during the early stages of CRPC onset. These cells are identified as IL-4-expressing T17 cells, and are shown to be associated with CRPC onset in patients and essential for the development of CRPC in mouse models. Mechanistically, CD4HLA-G T cells drive androgen-independent growth of prostate cancer cells by modulating the activity and migration of CD11bF4/80 macrophages. Furthermore, following androgen deprivation, elevated PGE-EP2 signaling inhibited the expression of CD4 in thymocytes, and subsequently induced the polarization of CD4 naïve T cells towards the IL-4-expressing T17 phenotype via up-regulation of IL23R. Therapeutically, inactivating PGE signaling with celecoxib at a time when CD4HLA-G T cells appeared, but not immediately following androgen deprivation, dramatically suppressed the onset of CRPC. Collectively, our results indicate that an unusual population of CD4HLA-G T cells is essential for the development of CRPC and point to a new therapeutic avenue of combining ADT with PGE inhibition for the treatment of prostate cancer.

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