Your search keyword '"Minchun Chen"' showing total 2 results

1. PPAR-delta acts as a metabolic master checkpoint for metastasis in pancreatic cancer

Author

Quan Zheng, Shanthini M. Crusz, Jiajia Tang, Angel Lanas, Sarah Courtois, Meng-Lay Lin, Andres Cano-Galiano, Sara Compte-Sancerni, Christopher Heeschen, Laure Penin-Peyta, Zhenyang Guo, Patricia Sancho, Mariia Yuneva, Beatriz Parejo-Alonso, Bruno Sainz, Pilar Espiau-Romera, Laura Ruiz-Canas, Ulf Schmitz, Petra Jagust, Sergio Lopez-Escalona, David Barneda, Minchun Chen, Sara Trabulo, and Pilar Irún

Subjects

Paracrine signalling, Tumor progression, Pancreatic cancer, medicine, Regulator, Cancer research, Peroxisome proliferator-activated receptor delta, Glycolysis, Biology, medicine.disease, Phenotype, Metastasis

Abstract

SummaryIn pancreatic cancer, emerging evidence suggests that PPAR-δ overexpression is associated with tumor progression and metastasis, but a mechanistic link is still missing. Here we now show that PPAR-δ acts as the integrating upstream regulator for the metabolic rewiring, which is preceding the subsequent initiation of an invasive/metastatic program. Specifically, paracrine and metabolic cues regularly found in the metastasis-promoting tumor stroma consistently enhance, via induction of PPAR-δ activity, the glycolytic capacity and reserve of pancreatic cancer cells, respectively, accompanied by decreased mitochondrial oxygen consumption. Consequently, genetic or pharmacological inhibition of PPAR-δ results in reduced invasiveness and metastasis. Mechanistically, PPAR-δ acts by shifting the MYC/PGC1A balance towards MYC, enhancing metabolic plasticity. Targeting MYC similarly prevents the metabolic switch and subsequent initiation of invasiveness. Therefore, our data demonstrate that PPAR-δ is a key initiator for the metabolic reprogramming in pancreatic cancer, thereby acting as a checkpoint for the phenotypic change towards invasiveness. These findings provide compelling evidence for a novel treatment strategy to combat pancreatic cancer progression.

Published

2021

2. Transposable Element-Gene Splicing Modulates the Transcriptional Landscape of Human Pluripotent Stem Cells

Author

Jean-Baptiste Cazier, Miguel A. Esteban, Jon Frampton, Yuhao Li, Martha Duttlinger, Isaac A. Babarinde, Xiuling Fu, Minchun Chen, Carl Ward, Ralf Jauch, Boping Deng, Wenjuan Li, Zhiwei Luo, Gang Ma, Li Sun, Hao Liu, Mazid Md. Abdul, Qiang Zhuang, Jiangping He, Jiekai Chen, and Andrew P. Hutchins

Subjects

Transcriptome, Transposable element, RNA splicing, Endogenous retrovirus, Computational biology, Biology, Induced pluripotent stem cell, Gene, Genome, Function (biology)

Abstract

Transposable elements (TEs) occupy nearly 50% of mammalian genomes and are both potential dangers to genome stability and functional genetic elements. TEs can be expressed and exonised as part of a transcript, however, their full contribution to the transcript splicing remains unresolved. Here, guided by long and short read sequencing of RNAs, we show that 26% of coding and 65% of non-coding transcripts of human pluripotent stem cells (hPSCs) contain TEs. Different TE families have unique integration patterns with diverse consequences on RNA expression and function. We identify hPSC-specific splicing of endogenous retroviruses (ERVs) as well as LINE L1 elements into protein coding genes that generate TE-derived peptides. Finally, single cell RNA-seq reveals that proliferating hPSCs are dominated by ERV-containing transcripts, and subpopulations express SINE or LINE-containing transcripts. Overall, we demonstrate that TE splicing modulates the pluripotency transcriptome by enhancing and impairing transcript expression and generating novel transcripts and peptides.

Published

2020