Targeting SPINK1 in the damaged tumour microenvironment alleviates therapeutic resistance

Chen, Fei; Long, Qilai; Fu, Da; Zhu, Dexiang; Ji, Yan; Liu, Han; Zhang, Boyi; Xu, Qixia; Liu, Bingjie; Li, Yan; Wu, Shanshan; Yang, Chen; Qian, Min; Xu, Jianmin; Liu, Suling; Cao, Liu; Chin, Y. Eugene; Lam, Eric; Coppé, Jean‐Philippe; Sun, Yu

doi:10.1038/s41467-018-06860-4

Cited by 90 publications

(92 citation statements)

References 66 publications

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“…Previous studies indicate the role of AKT signaling in advancement of PCa to poorly differentiated small cell prostate carcinoma 42 . Moreover, several studies have shown a critical role of SPINK1 in activating PI3K-AKT signaling cascade in multiple SPINK1-positive cancers 11,12,15 . In concordance to these reports, we also observed a remarkable decrease in AKT signaling in LNCaP-AI-shSPINK1 cells as compared to control cells (Fig.…”

Section: Articlementioning

confidence: 99%

“…Under normal physiological condition, SPINK1 inhibits the premature activation of pancreatic proteases, however, multiple reports have observed elevated levels of SPINK1 in cancer tissues, and shown its role in cancer progression [11][12][13][14] . Moreover, SPINK1 acts as an autocrine/paracrine factor and imparts oncogenic traits via EGFR downstream signaling 11,15 .…”

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confidence: 99%

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Androgen deprivation upregulates SPINK1 expression and potentiates cellular plasticity in prostate cancer

et al. 2020

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Emergence of an aggressive androgen receptor (AR)-independent neuroendocrine prostate cancer (NEPC) after androgen-deprivation therapy (ADT) is well-known. Nevertheless, the majority of advanced-stage prostate cancer patients, including those with SPINK1-positive subtype, are treated with AR-antagonists. Here, we show AR and its corepressor, REST, function as transcriptional-repressors of SPINK1, and AR-antagonists alleviate this repression leading to SPINK1 upregulation. Increased SOX2 expression during NE-transdifferentiation transactivates SPINK1, a critical-player for maintenance of NE-phenotype. SPINK1 elicits epithelial-mesenchymal-transition, stemness and cellular-plasticity. Conversely, pharmacological Casein Kinase-1 inhibition stabilizes REST, which in cooperation with AR causes SPINK1 transcriptional-repression and impedes SPINK1-mediated oncogenesis. Elevated levels of SPINK1 and NEPC markers are observed in the tumors of AR-antagonists treated mice, and in a subset of NEPC patients, implicating a plausible role of SPINK1 in treatment-related NEPC. Collectively, our findings provide an explanation for the paradoxical clinical-outcomes after ADT, possibly due to SPINK1 upregulation, and offers a strategy for adjuvant therapies.

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Section: Articlementioning

confidence: 99%

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confidence: 99%

Androgen deprivation upregulates SPINK1 expression and potentiates cellular plasticity in prostate cancer

et al. 2020

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“…7Eand Extended DataFig. 6B).However, these changes seem to be generally limited to stromal cells, rather than their adjacent epithelial cell counterparts, which have repopulated upon development of drug resistance in the course of treatment as previously characterized31,38 . We further assessed the in situ inducibility of KDM4A/B in tumor samples, and noticed substantial expression of these factors in animals experiencing MIT-involved treatments (Extended DataFig.…”

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confidence: 86%

KDM4 Orchestrates Epigenomic Remodeling of Senescent Cells and Potentiates the Senescence-Associated Secretory Phenotype

Zhang

Long

et al. 2020

Preprint

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Cellular senescence restrains the expansion of neoplastic cells through several layers of regulation, including epigenetic decoration of chromatin structure and functional modulation of bioactive components. Here we report that expression of the histone H3-specific demethylase KDM4 is upregulated in human stromal cells upon cellular senescence. In clinical oncology, upregulated KDM4 and diminished H3K9/H3K36 methylation are correlated with adverse survival of cancer patients post-chemotherapy. Global chromatin accessibility mapping via ATAC-seq and expression profiling through RNA-seq reveal extensive reorganization of chromosomes and spatiotemporal reprogramming of the transcriptomic landscape, events responsible for development of the senescence-associated secretory phenotype (SASP). Selectively targeting KDM4 dampens the SASP of senescent stromal cells and enhances the apoptotic index of cancer cells in the treatment-damaged tumor microenvironment (TME), together prolonging overall survival of experimental animals. Our study supports the dynamic change of H3K9/H3K36 methylation marks during cellular senescence, identifies an unusually permissive chromatin state, unmasks KDM4 as a key modulator of the SASP, and presents a novel therapeutic avenue to manipulate cellular senescence and curtail age-related pathologies.

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“…However, whether SIRT1 loss is subject to NF-κB regulation remains unknown. We used Bay 11-7082 (BAY) to treat PSC27 cells, and found that SIRT1 protein level appeared even bounced upon NF-κB suppression, in sharp contrast to many of the SASP factors such as IL8 and MMP3 whose expression was markedly diminished after BAY treatment 41 To substantiate the correlation of SIRT1 with sEV production, we used suberoylanilide hydroxamine acid (SAHA) and nicotinamide (NAM), a pan-histone deacetylase (HDAC) inhibitor and a SIRT1-specific inhibitor, respectively, to treat PSC27 cells. Immunoblots indicated that expression of SIRT1, IL8 and MMP3 remained unchanged, HSP70 decreased, while sEV markers including ALIX and CD63 increased when cells were treated by either agent even in the absence of DNA damage, suggesting that SIRT1 activity is critical for the synthesis of sEV-central molecules but not for development of the SASP (Fig.…”

Section: Sirt1 Decline Supports Deficient Lysosomal Acidification Andmentioning

confidence: 99%

Senescent stromal cells promote cancer resistance through SIRT1 loss-potentiated overproduction of small extracellular vesicles

Liu

Long

Li³

et al. 2020

Preprint

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ABSTRACTCellular senescence is a potent tumor-suppressive program that prevents neoplastic events. Paradoxically, senescent cells develop an inflammatory secretome, termed the senescence-associated secretory phenotype (SASP) and implicated in age-related pathologies including cancer. Here we report that senescent cells actively synthesize and release small extracellular vesicles (sEVs) with a distinctive size distribution. Mechanistically, SIRT1 loss supports accelerated sEV production despite enhanced proteome-wide ubiquitination, a process correlated with ATP6V1A downregulation and defective lysosomal acidification. Once released, senescent stromal sEVs significantly alter the expression profile of recipient cancer cells and enhance their aggressiveness, specifically drug resistance mediated by expression of ATP binding cassette subfamily B member 4 (ABCB4). Targeting SIRT1 with an agonist SRT2104 prevents development of cancer resistance through restraining sEV production by senescent stromal cells. In clinical oncology, sEVs in peripheral blood of posttreatment cancer patients are readily detectable by routine biotechniques, presenting a novel biomarker to monitor therapeutic efficacy and to predict long term outcome. Together, our study identifies a distinct mechanism supporting pathological activities of senescent cells, and provides a novel avenue to circumvent advanced human malignancies by co-targeting cancer cells and their surrounding microenvironment, which contributes to drug resistance via secretion of sEVs from senescent stromal cells.

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Targeting SPINK1 in the damaged tumour microenvironment alleviates therapeutic resistance

Cited by 90 publications

References 66 publications

Androgen deprivation upregulates SPINK1 expression and potentiates cellular plasticity in prostate cancer

Androgen deprivation upregulates SPINK1 expression and potentiates cellular plasticity in prostate cancer

KDM4 Orchestrates Epigenomic Remodeling of Senescent Cells and Potentiates the Senescence-Associated Secretory Phenotype

Senescent stromal cells promote cancer resistance through SIRT1 loss-potentiated overproduction of small extracellular vesicles

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