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Summary Day neutrality, or insensitivity to photoperiod (day length), is an important domestication trait in many crop species. Although the oilseed cropCamelina sativahas been cultivated since the Neolithic era, day-neutral accessions have yet to be described. We sought to leverage genetic diversity in existing germplasms to identifyC. sativaaccessions with low photoperiod sensitivity for future engineering of this trait. We quantified variation in the photoperiod response across 161 accessions ofC. sativaby measuring hypocotyl length of four-day-old seedlings grown in long-day and short-day conditions, finding wide variation in photoperiod response. Similarly, soil-grown adult plants from selected accessions showed variation in photoperiod response in several traits; however, photoperiod responses in seedling and adult traits were not correlated, suggesting complex mechanistic underpinnings. Although RNA-seq experiments of the reference accession Licalla identified several differentially regulatedArabidopsissyntelogs involved in photoperiod response, includingCOL2, FT, LHYandWOX4, expression of these genes in the accessions did not correlate with differences in their photoperiod sensitivity. Taken together, we show that all tested accessions show some degree of photoperiod response, and that this trait is likely complex, involving several and separable seedling and adult traits. Significance StatementDay neutrality (photoperiod insensitivity) is a common trait in domesticated crops; however, the ancient oilseed cropCamelina sativahas remained photoperiod-sensitive, which likely limits seed yields. Here, we show that photoperiod sensitivity is conserved across manyC. sativacultivars, albeit to different degrees, and we establish that photoperiod sensitivity is a complex trait, which will require genetic engineering to achieve day neutrality. 

Abstract The genomes of flowering plants consist largely of transposable elements (TEs), some of which modulate gene regulation and function. However, the repetitive nature of TEs and difficulty of mapping individual TEs by short-read-sequencing have hindered our understanding of their regulatory potential. We demonstrate that long-read chromatin fiber sequencing (Fiber-seq) comprehensively identifies accessible chromatin regions (ACRs) and CpG methylation across the maize genome. We uncover stereotypical ACR patterns at young TEs that degenerate with evolutionary age, resulting in TE-enhancers preferentially marked by a novel plant-specific epigenetic feature: simultaneous hyper-CpG methylation and chromatin accessibility. We show that TE ACRs are co-opted as gene promoters and that ACR-containing TEs can facilitate gene amplification. Lastly, we uncover a pervasive epigenetic signature – hypo-5mCpG methylation and diffuse chromatin accessibility – directing TEs to specific loci, including the loci that sparked McClintock’s discovery of TEs. 

Transcription is controlled by interactions of cis -acting DNA elements with diffusible trans -acting factors. Changes in cis or trans factors can drive expression divergence within and between species, and their relative prevalence can reveal the evolutionary history and pressures that drive expression variation. Previous work delineating the mode of expression divergence in animals has largely used whole-body expression measurements in one condition. Because cis -acting elements often drive expression in a subset of cell types or conditions, these measurements may not capture the complete contribution of cis -acting changes. Here, we quantify the mode of expression divergence in the Drosophila fat body, the primary immune organ, in several conditions, using two geographically distinct lines of D. melanogaster and their F1 hybrids. We measured expression in the absence of infection and in infections with Gram-negative S. marcescens or Gram-positive E. faecalis bacteria, which trigger the two primary signaling pathways in the Drosophila innate immune response. The mode of expression divergence strongly depends on the condition, with trans -acting effects dominating in response to Gram-negative infection and cis -acting effects dominating in Gram-positive and preinfection conditions. Expression divergence in several receptor proteins may underlie the infection-specific trans effects. Before infection, when the fat body has a metabolic role, there are many compensatory effects, changes in cis and trans that counteract each other to maintain expression levels. This work shows that within a single tissue, the mode of expression divergence varies between conditions and suggests that these differences reflect the diverse evolutionary histories of host–pathogen interactions.