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Abstract
Summary In Primula vulgaris outcrossing is promoted through reciprocal herkogamy with insect‐mediated cross‐pollination between pin and thrum form flowers. Development of heteromorphic flowers is coordinated by genes at the S locus. To underpin construction of a genetic map facilitating isolation of these S locus genes, we have characterised Oakleaf, a novel S locus‐linked mutant phenotype.We combine phenotypic observation of flower and leaf development, with classical genetic analysis and next‐generation sequencing to address the molecular basis of Oakleaf. Oakleaf is a dominant mutation that affects both leaf and flower development; plants produce distinctive lobed leaves, with occasional ectopic meristems on the veins. This phenotype is reminiscent of overexpression of Class I KNOX‐homeodomain transcription factors. We describe the structure and expression of all eight P. vulgaris PvKNOX genes in both wild‐type and Oakleaf plants, and present comparative transcriptome analysis of leaves and flowers from Oakleaf and wild‐type plants. Oakleaf provides a new phenotypic marker for genetic analysis of the Primula S locus. We show that none of the Class I PvKNOX genes are strongly upregulated in Oakleaf leaves and flowers, and identify cohorts of 507 upregulated and 314 downregulated genes in the Oakleaf mutant.
Highlights
Observations on different forms of Primula flowers date back nearly 400 yr
Pin flowers have a long style with the stigma at the corolla mouth and anthers attached midway down the corolla tube; thrum flowers have anthers which are positioned at the corolla mouth and a short style which presents the stigma midway up the corolla tube (Darwin, 1862; Webster & Gilmartin, 2006)
We explore the molecular basis of Oakleaf through a candidate gene approach, and via transcriptomic and genomic analyses to profile the molecular phenotype as a prelude to construction of a genetic map of the Primula S locus
Summary
Observations on different forms of Primula flowers date back nearly 400 yr Elevation of the anthers in thrum flowers is caused by increased cell division in the corolla tube below their point of attachment, whilst in pin flowers the style is extended by increased cell elongation (Heslop-Harrison et al, 1981; Webster & Gilmartin, 2006). Darwin observed that within-morph pin–pin or thrum–thrum crosses were less fertile than intermorph pin–thrum or thrum– pin crosses (Darwin, 1877) This observation is underpinned by the presence of a sporophytic incompatibility system that in combination with the structural differences between the two forms of flower inhibits self-pollination and promotes outcrossing (Shivanna et al, 1981; Richards, 1997)
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