Literature DB >> 33414441

Loss of EHF facilitates the development of treatment-induced neuroendocrine prostate cancer.

Zhi Long1, Liang Deng1, Chao Li1, Qiangrong He1, Yao He2, Xiheng Hu2, Yi Cai2, Yu Gan3.   

Abstract

The rising of a highly aggressive subtype of castration-resistant prostate cancer (CRPC) named treatment-induced neuroendocrine prostate cancer (t-NEPC) after androgen deprivation therapy (ADT) is well known for its features of the neuroendocrine differentiation (NED) and androgen receptor (AR) independence. However, t-NEPC is still largely unknown. Here, we found that EHF is notably depressed in t-NEPC tumors, patient-derived xenografts, transgenic mice, and cell models. Results from cell lines uncovered that ADT represses EHF expression, which is required for the ADT-induced NED. Mechanism dissection revealed that ADT decreases the EHF transcription via relieving the AR binding to different androgen-responsive elements, which then promotes the expression and enzymatic activity of enhancer of zeste homolog 2 (EZH2), consequently catalyzing tri-methylation lysine 27 of histone H3 for transcriptional repression of its downstream genes to promote the NED. Furthermore, preclinical studies from cell and mice models proved that recovery of EHF expression or using EZH2 inhibitor can attenuate aggressive properties of CRPC cells, hinder the progression of t-NEPC, and promote the response of CPRC cells to enzalutamide. Together, we elucidate that the ADT/AR/EHF/EZH2 signaling is required for the ADT-enhanced NED and plays a critical role in the progression of t-NEPC.

Entities:  

Year:  2021        PMID: 33414441      PMCID: PMC7790822          DOI: 10.1038/s41419-020-03326-8

Source DB:  PubMed          Journal:  Cell Death Dis            Impact factor:   8.469


  47 in total

Review 1.  Concise Review: Prostate Cancer Stem Cells: Current Understanding.

Authors:  Sergej Skvortsov; Ira-Ida Skvortsova; Dean G Tang; Anna Dubrovska
Journal:  Stem Cells       Date:  2018-08-27       Impact factor: 6.277

Review 2.  Epigenetic modulations and lineage plasticity in advanced prostate cancer.

Authors:  R Ge; Z Wang; R Montironi; Z Jiang; M Cheng; M Santoni; K Huang; F Massari; X Lu; A Cimadamore; A Lopez-Beltran; L Cheng
Journal:  Ann Oncol       Date:  2020-02-13       Impact factor: 32.976

3.  LIN28B promotes the development of neuroendocrine prostate cancer.

Authors:  Jessica Lovnicki; Yu Gan; Tingting Feng; Yinan Li; Ning Xie; Chia-Hao Ho; Ahn R Lee; Xufeng Chen; Lucia Nappi; Bo Han; Ladan Fazli; Jiaoti Huang; Martin E Gleave; Xuesen Dong
Journal:  J Clin Invest       Date:  2020-10-01       Impact factor: 14.808

4.  MicroRNA-424 impairs ubiquitination to activate STAT3 and promote prostate tumor progression.

Authors:  Cecilia Dallavalle; Domenico Albino; Gianluca Civenni; Jessica Merulla; Paola Ostano; Maurizia Mello-Grand; Simona Rossi; Marco Losa; Gioacchino D'Ambrosio; Fausto Sessa; George N Thalmann; Ramon Garcia-Escudero; Andrea Zitella; Giovanna Chiorino; Carlo V Catapano; Giuseppina M Carbone
Journal:  J Clin Invest       Date:  2016-11-07       Impact factor: 14.808

5.  Integrative Clinical Genomics of Advanced Prostate Cancer.

Authors:  Dan Robinson; Eliezer M Van Allen; Yi-Mi Wu; Nikolaus Schultz; Robert J Lonigro; Juan-Miguel Mosquera; Bruce Montgomery; Mary-Ellen Taplin; Colin C Pritchard; Gerhardt Attard; Himisha Beltran; Wassim Abida; Robert K Bradley; Jake Vinson; Xuhong Cao; Pankaj Vats; Lakshmi P Kunju; Maha Hussain; Felix Y Feng; Scott A Tomlins; Kathleen A Cooney; David C Smith; Christine Brennan; Javed Siddiqui; Rohit Mehra; Yu Chen; Dana E Rathkopf; Michael J Morris; Stephen B Solomon; Jeremy C Durack; Victor E Reuter; Anuradha Gopalan; Jianjiong Gao; Massimo Loda; Rosina T Lis; Michaela Bowden; Stephen P Balk; Glenn Gaviola; Carrie Sougnez; Manaswi Gupta; Evan Y Yu; Elahe A Mostaghel; Heather H Cheng; Hyojeong Mulcahy; Lawrence D True; Stephen R Plymate; Heidi Dvinge; Roberta Ferraldeschi; Penny Flohr; Susana Miranda; Zafeiris Zafeiriou; Nina Tunariu; Joaquin Mateo; Raquel Perez-Lopez; Francesca Demichelis; Brian D Robinson; Andrea Sboner; Marc Schiffman; David M Nanus; Scott T Tagawa; Alexandros Sigaras; Kenneth W Eng; Olivier Elemento; Andrea Sboner; Elisabeth I Heath; Howard I Scher; Kenneth J Pienta; Philip Kantoff; Johann S de Bono; Mark A Rubin; Peter S Nelson; Levi A Garraway; Charles L Sawyers; Arul M Chinnaiyan
Journal:  Cell       Date:  2015-07-16       Impact factor: 41.582

Review 6.  Neuroendocrine tumors of the prostate.

Authors:  Samson W Fine
Journal:  Mod Pathol       Date:  2018-01       Impact factor: 7.842

7.  Increased Serine and One-Carbon Pathway Metabolism by PKCλ/ι Deficiency Promotes Neuroendocrine Prostate Cancer.

Authors:  Miguel Reina-Campos; Juan F Linares; Angeles Duran; Thekla Cordes; Antoine L'Hermitte; Mehmet G Badur; Munveer S Bhangoo; Phataraporn K Thorson; Alicia Richards; Tarmo Rooslid; Dolores C Garcia-Olmo; Syongh Y Nam-Cha; Antonio S Salinas-Sanchez; Ken Eng; Himisha Beltran; David A Scott; Christian M Metallo; Jorge Moscat; Maria T Diaz-Meco
Journal:  Cancer Cell       Date:  2019-02-28       Impact factor: 31.743

8.  PC3 is a cell line characteristic of prostatic small cell carcinoma.

Authors:  Sheng Tai; Yin Sun; Jill M Squires; Hong Zhang; William K Oh; Chao-Zhao Liang; Jiaoti Huang
Journal:  Prostate       Date:  2011-03-22       Impact factor: 4.104

9.  Proteogenomic Characterization of Patient-Derived Xenografts Highlights the Role of REST in Neuroendocrine Differentiation of Castration-Resistant Prostate Cancer.

Authors:  Amilcar Flores-Morales; Tobias B Bergmann; Charlotte Lavallee; Tanveer S Batth; Dong Lin; Mads Lerdrup; Stine Friis; Anette Bartels; Gitte Kristensen; Agnieszka Krzyzanowska; Hui Xue; Ladan Fazli; Klaus H Hansen; Martin A Røder; Klaus Brasso; José M Moreira; Anders Bjartell; Yuzhuo Wang; Jesper V Olsen; Colin C Collins; Diego Iglesias-Gato
Journal:  Clin Cancer Res       Date:  2018-10-01       Impact factor: 12.531

Review 10.  ADT with antiandrogens in prostate cancer induces adverse effect of increasing resistance, neuroendocrine differentiation and tumor metastasis.

Authors:  Yuanjie Niu; Changcheng Guo; Simeng Wen; Jing Tian; Jie Luo; Keliang Wang; Hao Tian; Shuyuan Yeh; Chawnshang Chang
Journal:  Cancer Lett       Date:  2018-09-15       Impact factor: 8.679
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  5 in total

1.  The ETS Homologous Factor (EHF) Represents a Useful Immunohistochemical Marker for Predicting Prostate Cancer Metastasis.

Authors:  Manuel Scimeca; Manuela Montanaro; Rita Bonfiglio; Lucia Anemona; Enrico Finazzi Agrò; Anastasios D Asimakopoulos; Roberto Bei; Vittorio Manzari; Nicoletta Urbano; Erica Giacobbi; Francesca Servadei; Elena Bonanno; Orazio Schillaci; Alessandro Mauriello
Journal:  Diagnostics (Basel)       Date:  2022-03-24

Review 2.  Serine and one-carbon metabolisms bring new therapeutic venues in prostate cancer.

Authors:  Carlo Ganini; Ivano Amelio; Riccardo Bertolo; Eleonora Candi; Angela Cappello; Chiara Cipriani; Alessandro Mauriello; Carla Marani; Gerry Melino; Manuela Montanaro; Maria Emanuela Natale; Giuseppe Tisone; Yufang Shi; Ying Wang; Pierluigi Bove
Journal:  Discov Oncol       Date:  2021-10-27

3.  Superselective Prostate Artery Embolization for Treatment of Severe Haematuria Secondary to Rapid Progression of Treatment-Induced Neuroendocrine Prostate Cancer: A Case Report.

Authors:  Liang Deng; Chao Li; Qiangrong He; Chenghui Huang; Qian Chen; Shengwang Zhang; Long Wang; Yu Gan; Zhi Long
Journal:  Onco Targets Ther       Date:  2022-01-20       Impact factor: 4.147

Review 4.  Focus on the tumor microenvironment: A seedbed for neuroendocrine prostate cancer.

Authors:  Hengfeng Zhou; Qiangrong He; Chao Li; Bassam Lutf Mohammed Alsharafi; Liang Deng; Zhi Long; Yu Gan
Journal:  Front Cell Dev Biol       Date:  2022-07-22

Review 5.  Regulation of Neuroendocrine-like Differentiation in Prostate Cancer by Non-Coding RNAs.

Authors:  Eva Slabáková; Zuzana Kahounová; Jiřina Procházková; Karel Souček
Journal:  Noncoding RNA       Date:  2021-12-02
  5 in total

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