Summary
Improving regeneration of ribulose-1,5-bisphosphate (RUBP) is a promising approach to improve photosynthesis and plant growth. In addition to transgenic overexpression of target genes, it could be possible to directly overexpress endogenous target genes, through transcriptional enhancements. As shown by the recent discovery of a short sequence motif, that resembles the known octopine synthase (ocs) enhancer, transcriptional enhancement is achievable by relatively short endogenous sequences. In this study, we query the genome of several model and crop plant genomes for the presence of short enhancer motifs. We find hits across all genomes including some in promoter regions of genes. By using derivatives of these motifs in a transient fluorescence assay, we show that several of these are capable of inducing target gene expression in different promoter contexts. A motif scan of the created constructs, for the presence of known transcription factor binding sites, shows that the insertion of these motifs has created binding sites for different TGA-, NAC- and bZIP-transcription factors. Taken together our study shows the feasibility of finding enhancer sequences in the genomes of different plants. With advancement in gene-editing technologies, like prime editing, using such endogenous enhancer sequences, could allow for precise cisgenic promoter engineering of target genes.
Outcomes reported
Improving regeneration of ribulose-1,5-bisphosphate (RUBP) is a promising approach to improve photosynthesis and plant growth. In addition to transgenic overexpression of target genes, it could be possible to directly overexpress endogenous target genes, through transcriptional enhancements. As shown by the recent discovery of a short sequence motif, that resembles the known octopine synthase (ocs) enhancer, transcriptional enhancement is achievable by relatively short endogenous sequences. In this study, we query the genome of several model and crop plant genomes for the presence of short enhancer motifs. We find hits across all genomes including some in promoter regions of genes. By using derivatives of these motifs in a transient fluorescence assay, we show that several of these are capable of inducing target gene expression in different promoter contexts. A motif scan of the created constructs, for the presence of known transcription factor binding sites, shows that the insertion of these motifs has created binding sites for different TGA-, NAC- and bZIP-transcription factors. Taken together our study shows the feasibility of finding enhancer sequences in the genomes of different plants. With advancement in gene-editing technologies, like prime editing, using such endogenous enhancer sequences, could allow for precise cisgenic promoter engineering of target genes.
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