Abstract
Evolutionarily, polyploidy represents a smart method for adjusting agronomically important in crops through impacts on genomic abundance and chromatin condensation. Autopolyploids have a relatively concise genetic background with great diversity and provide an ideal system to understand genetic and epigenetic mechanisms attributed to the genome-dosage effect. However, whether and how genome duplication events during autopolyploidization impact chromatin signatures are less understood in crops. To address it, we generated an autotetraploid rice line from a diploid progenitor, Oryza sativa ssp. indica 93-11. Using transposase-accessible chromatin sequencing, we found that autopolyploids lead to a higher number of accessible chromatin regions (ACRs) in euchromatin, most of which encode protein-coding genes. As expected, the profiling of ACR densities supported that the effect of ACRs on transcriptional gene activities relies on their positions in the rice genome, regardless of genome doubling. However, we noticed that genome duplication favors genic ACRs as the main drivers of transcriptional changes. In addition, we probed intricate crosstalk among various kinds of epigenetic marks and expression patterns of ACR-associated gene expression in both diploid and autotetraploid rice plants by integrating multiple-omics analyses, including chromatin immunoprecipitation sequencing and RNA-seq. Our data suggested that the combination of H3K36me2 and H3K36me3 may be associated with dynamic perturbation of ACRs introduced by autopolyploidization. As a consequence, we found that numerous metabolites were stimulated by genome doubling. Collectively, our findings suggest that autotetraploids reshape rice morphology and products by modulating chromatin signatures and transcriptional profiling, resulting in a pragmatic means of crop genetic improvement.
Highlights
Rice is one of the most important food crops in the world and provides more than 20% of the caloric intake for one-half of the world’s population (Zhang et al 2016)
Our findings indicated that the functional regulation of genic accessible chromatin regions (ACRs) on transcription was enhanced in the process of rice genome doubling
Morphological Changes Caused by Rice Genome Doubling To study the impact of whole-genome duplication (WGD) without interspecies hybridization effects, we induced autotetraploid rice (4x) from a diploid cultivar (2x), Oryza sativa ssp. indica cv. 93–11, which had been independently self-pollinated over 10 generations
Summary
Rice is one of the most important food crops in the world and provides more than 20% of the caloric intake for one-half of the world’s population (Zhang et al 2016). Given that allopolyploids can be confounded by the entanglement of both WGD and hybridization, synthesized autopolyploid systems are ideal systems to investigate the short-term effects produced by WGDs, such as those in Arabidopsis (Zhang et al 2019), rice (Chen et al 2019; Wu et al 2017; Yu et al 2020; Guo et al 2017; Wang et al 2021), potato (Stupar et al 2007), Citrus limonia (Allario et al 2011) and willows (Dudits et al 2016). To some extent, according to these results, it is possible that the change in transcriptional activity induced by autotetraploid plants could be attributed to nuclear dosage (Riddle et al 2010; Stupar et al 2007; Allario et al 2011). To explore the mechanisms controlling gene transcription changes induced by genome duplication, further investigations are still needed
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