Abstract
Alternative splicing promotes proteome diversity by using limited number of genes, a key control point of gene expression. Splicing is carried out by large macromolecular machineries, called spliceosome, composed of small RNAs and proteins. Alternative splicing is regulated by splicing regulatory cis-elements in RNA and trans-acting splicing factors that are often tightly regulated in a tissue-specific and developmental stage-specific manner. The biogenesis of ribonucleoprotein (RNP) complexes is strictly regulated to ensure that correct complements of RNA and proteins are coordinated in the right cell at the right time to support physiological functions. Any perturbations that impair formation of functional spliceosomes by disrupting the cis-elements, or by compromising RNA-binding or function of trans-factors can be deleterious to cells and result in pathological consequences. The recent discovery of oncogenic mutations in splicing factors, and growing evidence of the perturbed splicing in multiple types of cancer, underscores RNA processing defects as a critical driver of oncogenesis. These findings have resulted in a growing interest in targeting RNA splicing as a therapeutic approach for cancer treatment. This review summarizes our current understanding of splicing alterations in cancer, recent therapeutic efforts targeting splicing defects in cancer, and future potentials to develop novel cancer therapies.
Highlights
Humans and other higher metazoans have evolved by acquiring regulated diversity in their genes by inserting multiple noncoding introns into a coding region
Tumor-specific increased expression of anti-apoptotic isoforms have been documented in BCL2L1, CASP2, and FAS; alternative splicing linked with the acquisition of invasive properties has been reported in CD44, FGFR2, RAC1, and MST1R; and angiogenesis-specific splice variants are reported in VFGFA [11]
It is well established that cancer cells display widespread alterations in RNA splicing compared to normal cells. These findings suggest that modulating of RNA splicing factors by targeting specific transcripts, or even genome-wide, may have significant therapeutic potential
Summary
Humans and other higher metazoans have evolved by acquiring regulated diversity in their genes by inserting multiple noncoding introns into a coding region. Five small nuclear ribonucleoproteins (snRNPs) and multiple proteins (>100) cooperate to form the spliceosome. Recognition of intron/exon boundary is directed by essential splicing cis-elements present within the intron, termed as consensus splice site sequences. These include 50 splice site, a branch point (BP), a polypyrimidine tract (PPT), and 30 splice site. Multiple auxiliary splicing factors cooperate to form functional spliceosome to promote splicing. Spliceosome assembly initiates with the recognition of the 50 splice site by U1 snRNP, the BP by SF1, and the PPT as well as 30 terminal AG by U2AF heterodimer (U2AF65 and U2AF35, respectively) This is an ATP-independent step, known as an E complex. HnRNPH promotes the expression of active oncogenic RAF (ARAF full) while repressing the short RAF isoform (ARAF short)
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