Abstract
Regulatory elements (REs) consist of enhancers and promoters that occupy a significant portion of the noncoding genome and control gene expression programs either in cis or in trans Putative REs have been identified largely based on their regulatory features (co-occupancy of ESC-specific transcription factors, enhancer histone marks, and DNase hypersensitivity) in mouse embryonic stem cells (mESCs). However, less has been established regarding their regulatory functions in their native context. We deployed cis- and trans-regulatory elements scanning through saturating mutagenesis and sequencing (ctSCAN-SMS) to target elements within the ∼12-kb cis-region (cis-REs; CREs) of the Oct4 gene locus, as well as genome-wide 2,613 high-confidence trans-REs (TREs), in mESCs. ctSCAN-SMS identified 10 CREs and 12 TREs as novel candidate REs of the Oct4 gene in mESCs. Furthermore, deletions of these candidate REs confirmed that the majority of the REs are functionally active, and CREs are more active than TREs in controlling Oct4 gene expression. A subset of active CREs and TREs physically interact with the Oct4 promoter to varying degrees; specifically, a greater number of active CREs, compared with active TREs, physically interact with the Oct4 promoter. Moreover, comparative genomics analysis reveals that a greater number of active CREs than active TREs are evolutionarily conserved between mice and primates, including humans. Taken together, our study demonstrates the reliability and robustness of ctSCAN-SMS screening to identify critical REs and investigate their roles in the regulation of transcriptional output of a target gene (in this case Oct4) in their native context.
Highlights
Regulatory elements (REs) consist of enhancers and promoters that occupy a significant portion of the noncoding genome and control gene expression programs either in cis or in trans
We deployed cis- and trans-regulatory elements scanning through saturating mutagenesis and sequencing to target elements within the ~12-kb cis-region of the Oct4 gene locus, as well as genome-wide 2,613 high-confidence transREs (TREs), in mouse ESC (mESC). ctSCAN-SMS identified 10 CREs and 12 TREs as novel candidate REs of the Oct4 gene in mESCs
1,827 single guide RNA (sgRNA) were designed at the surrounding ;12-kb (210 to 12 kb of the Transcription start site (TSS) of the Oct4) region of the mouse Oct4 gene locus to dissect the CREs of Oct4 (Fig. 1, b and c)
Summary
In mESCs, several putative REs, including 8,563 enhancers (ENs) and 231 superenhancers (SEs) have been identified based on co-occupancy of ESC-specific TFs (OCT4, NANOG, SOX2, KLF4, and ESRRB), mediators (MED1), enhancer histone marks (H3K4me and H3K27ac), and DNase I hypersensitivity [30]. Control CREs exhibited lowlevel co-occupancy of ONS, H3K27ac, H3K4me, and dynamic open chromatin regions (Fig. 2 (d and e) and Fig. S3 (b and c)) These data confirm the existence of multiple “active” CREs (active REs depict REs that reduce the Oct expression upon their deletions), including newly identified active CREs of the Oct. A high-resolution Micro-C (micrococcal nuclease– based Hi-C assay that captures genome-wide 3D chromatin organization/contact frequencies at single-nucleosome resolution (;100–200 bp)) from mESCs [38], displayed ranges of intrachromosomal interactions between active CREs and the Oct promoter (Fig. S5, b and c) These data evaluated all other intrachromosomal interactions between any two genomic loci around the ;20-kb region of the Oct gene locus at 200 bp resolution (Fig. S5b). These observations support the existence of both conserved and nonconserved REs of Oct among mice and primates (including humans), which is consistent with “RE turnover/divergence” (gain and loss of REs) at the Oct locus during evolution that may be critical for positive selection, as proposed earlier [17, 39]
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