Abstract
BackgroundTranscription factor (TF) binding sites (cis element) play a central role in gene regulation, and eukaryotic organisms frequently adapt a combinatorial regulation to render sophisticated local gene expression patterns. Knowing the precise cis element on a distal promoter is a prerequisite for studying a typical transcription process; however, identifications of cis elements have lagged behind those of their associated trans acting TFs due to technical difficulties. Consequently, gene regulations via combinatorial TFs, as widely observed across biological processes, have remained vague in many cases.ResultsWe present here a valid strategy for identifying cis elements in combinatorial TF regulations. It consists of bioinformatic searches of available databases to generate candidate cis elements and tests of the candidates using improved experimental assays. Taking the MYB and the bHLH that collaboratively regulate the anthocyanin pathway genes as examples, we demonstrate how candidate cis motifs for the TFs are found on multi-specific promoters of chalcone synthase (CHS) genes, and how to experimentally test the candidate sites by designing DNA fragments hosting the candidate motifs based on a known promoter (us1 allele of Ipomoea purpurea CHS-D in our case) and applying site-mutagenesis at the motifs. It was shown that TF-DNA interactions could be unambiguously analyzed by assays of electrophoretic mobility shift (EMSA) and dual-luciferase transient expressions, and the resulting evidence precisely delineated a cis element. The cis element for R2R3 MYBs including Ipomoea MYB1 and Magnolia MYB1, for instance, was found to be ANCNACC, and that for bHLHs (exemplified by Ipomoea bHLH2 and petunia AN1) was CACNNG. A re-analysis was conducted on previously reported promoter segments recognized by maize C1 and apple MYB10, which indicated that cis elements similar to ANCNACC were indeed present on these segments, and tested positive for their bindings to Ipomoea MYB1.ConclusionIdentification of cis elements in combinatorial regulation is now feasible with the strategy outlined. The working pipeline integrates the existing databases with experimental techniques, providing an open framework for precisely identifying cis elements. This strategy is widely applicable to various biological systems, and may enhance future analyses on gene regulation.
Highlights
Transcription factor (TF) binding sites play a central role in gene regulation, and eukaryotic organisms frequently adapt a combinatorial regulation to render sophisticated local gene expression patterns
Since we were interested in MYB recognition sites that governed the combinatorial regulation on the anthocyanin pathway, we carried out bioinformatic searches on promoters of all known anthocyanin pathway genes (Additional file 1)
Since Motif 1 appeared on target for the MYB1-bHLH2 -WDR1 combinatorial regulation in living cells, we further examined Motif 1 in electrophoretic mobility shift assays (EMSAs) to make sure that it was bHLH2 that bound to the cis sites
Summary
Transcription factor (TF) binding sites (cis element) play a central role in gene regulation, and eukaryotic organisms frequently adapt a combinatorial regulation to render sophisticated local gene expression patterns. Knowing the precise cis element on a distal promoter is a prerequisite for studying a typical transcription process; identifications of cis elements have lagged behind those of their associated trans acting TFs due to technical difficulties. Gene regulations via combinatorial TFs, as widely observed across biological processes, have remained vague in many cases. The transcription process can be highly dynamic and sophisticated in eukaryotic cells [1], and its initiation typically involves a recognition between a transcription factor (TF) and a cis element at the upstream region on a gene. When the correct segments are identified, their lengths can be inconsistent between reports due to uncertainties about the exact binding sites
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