Abstract
Many studies using reporter assays have demonstrated that 3′ untranslated regions (3′-UTRs) regulate gene expression by controlling mRNA stability and translation. Due to intrinsic limitations of heterologous reporter assays, we sought to develop a gene editing approach to investigate the regulatory activity of 3′-UTRs in their native context. We initially used dual-CRISPR (clustered, regularly interspaced, short palindromic repeats)-Cas9 targeting to delete DNA regions corresponding to nine chemokine 3′-UTRs that destabilized mRNA in a reporter assay. Targeting six chemokine 3′-UTRs increased chemokine mRNA levels as expected. However, targeting CXCL1, CXCL6 and CXCL8 3′-UTRs unexpectedly led to substantial mRNA decreases. Metabolic labeling assays showed that targeting these three 3′-UTRs increased mRNA stability, as predicted by the reporter assay, while also markedly decreasing transcription, demonstrating an unexpected role for 3′-UTR sequences in transcriptional regulation. We further show that CRISPR–Cas9 targeting of specific 3′-UTR elements can be used for modulating gene expression and for highly parallel localization of active 3′-UTR elements in the native context. Our work demonstrates the duality and complexity of 3′-UTR sequences in regulation of gene expression and provides a useful approach for modulating gene expression and for functional annotation of 3′-UTRs in the native context.
Highlights
3 untranslated regions (3 -UTRs) have extensive effects on gene expression during development [1], aging [2], inflammation [3] and in diseases including cancer [4]
We demonstrated that CRISPR–Cas9 targeting of 3 -UTR cis-elements could be used to modulate gene expression
We developed a highly parallel approach based on a guide RNA library for localizing specific 3 -UTR elements in their native context
Summary
3 untranslated regions (3 -UTRs) have extensive effects on gene expression during development [1], aging [2], inflammation [3] and in diseases including cancer [4]. These processes are precisely controlled by many types of cisregulatory elements such as AU-rich elements (AREs) [5], Pumilio motifs [5], constitutive decay elements [6] and microRNA targeting sites [7], which modulate mRNA stability and/or translation through binding to RNA binding proteins or microRNAs [8]. We developed a highly parallel approach based on a guide RNA (gRNA) library for localizing specific 3 -UTR elements in their native context
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