Genome-wide Analysis of PTB-RNA Interactions Reveals a Strategy Used by the General Splicing Repressor to Modulate Exon Inclusion or Skipping

Overview

Journal Mol Cell

Publisher Cell Press

Specialty Cell Biology

Date 2010 Jan 13

PMID 20064465

Citations 294

Authors

Yuanchao Xue

Yu Zhou

Tongbin Wu

Tuo Zhu

Xiong Ji

Young-Soo Kwon

Chao Zhang

Gene Yeo

Douglas L Black

Hui Sun

Xiang-Dong Fu

Yi Zhang

Affiliations

Soon will be listed here.

Abstract

Recent transcriptome analysis indicates that > 90% of human genes undergo alternative splicing, underscoring the contribution of differential RNA processing to diverse proteomes in higher eukaryotic cells. The polypyrimidine tract-binding protein PTB is a well-characterized splicing repressor, but PTB knockdown causes both exon inclusion and skipping. Genome-wide mapping of PTB-RNA interactions and construction of a functional RNA map now reveal that dominant PTB binding near a competing constitutive splice site generally induces exon inclusion, whereas prevalent binding close to an alternative site often causes exon skipping. This positional effect was further demonstrated by disrupting or creating a PTB-binding site on minigene constructs and testing their responses to PTB knockdown or overexpression. These findings suggest a mechanism for PTB to modulate splice site competition to produce opposite functional consequences, which may be generally applicable to RNA-binding splicing factors to positively or negatively regulate alternative splicing in mammalian cells.

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