Computational resources to define alleles and altered regulatory motifs at genomically edited candidate response elements.

Kirk T Ehmsen,Delsy Martinez,Masako Asahina,Keith R Yamamoto,Haruna Aridomi,Matthew T Knuesel

doi:10.1093/nar/gkab700

Kirk T Ehmsen, Delsy Martinez + Show 4 more

Open Access

https://doi.org/10.1093/nar/gkab700

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Abstract

Unequivocal functional assessment of candidate genomic regulatory regions, such as transcriptional response elements, requires genetic alteration at their native chromosomal loci. Targeted DNA cleavage by Cas9 or other programmable nucleases enables analysis at virtually any genomic region, and diverse alleles generated by editing can be defined by deep sequencing for functional analysis. Interpretation of disrupted response elements, however, presents a special challenge, as these regions typically comprise clustered DNA binding motifs for multiple transcriptional regulatory factors (TFs); DNA sequence differences, natural or engineered, that affect binding by one TF can confer loss or gain of binding sites for other TFs. To address these and other analytical complexities, we created three computational tools that together integrate, in a single experiment, allele definition and TF binding motif evaluation for up to 9216 clones isolated, sequenced and propagated from Cas9-treated cell populations. We demonstrate 1) the capacity to functionally assess edited TF binding sites to query response element function, and 2) the efficacy and utility of these tools, by analyzing cell populations targeted by Cas9 for disruption of example glucocorticoid receptor (GR) binding motifs near FKBP5, a GR-regulated gene in the human adenocarcinoma cell line A549.

Highlights

The glucocorticoid receptor (GR; product of the NR3C1 gene) [1] is a ligand-gated transcriptional regulatory factor (TF) that binds to specific sequence motifs at genomic glucocorticoid response elements (GREs) and nucleates combinatorial assembly of multicomponent transcriptional regulatory complexes, which modulate expression of cognate target genes [2]
We developed computational tools to automate sequence processing from input to output of a targeted editing effort focused on candidate response elements, seeking to expedite clone selection for retrieval and archiving, to prioritize clones for analysis based on inferred genotype definitions, and to anticipate potential functional consequences based on altered transcription factor binding site (TFBS)
We have described three Python programs, which will be of value to researchers who prepare amplicons for targeted SBS on Illumina® platforms: SampleSheet.py, Genotypes.py, and CollatedMotifs.py

Summary

Introduction

The glucocorticoid receptor (GR; product of the NR3C1 gene) [1] is a ligand-gated transcriptional regulatory factor (TF) that binds to specific sequence motifs at genomic glucocorticoid response elements (GREs) and nucleates combinatorial assembly of multicomponent transcriptional regulatory complexes, which modulate expression of cognate target genes [2]. As for many vertebrate signal-activated TFs that coordinate broad gene expression programs, three features greatly complicate determination of transcriptional regulatory activity by a genomic GR-occupied region (GOR).

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