Abstract
Mechanisms through which the evolution of gene regulation causes morphological diversity are largely unclear. The tremendous shape variation among plant leaves offers attractive opportunities to address this question. In cruciferous plants, the REDUCED COMPLEXITY (RCO) homeodomain protein evolved via gene duplication and acquired a novel expression domain that contributed to leaf shape diversity. However, the molecular pathways through which RCO regulates leaf growth are unknown. A key question is to identify genome-wide transcriptional targets of RCO and the DNA sequences to which RCO binds. We investigate this question using Cardamine hirsuta, which has complex leaves, and its relative Arabidopsis thaliana, which evolved simple leaves through loss of RCO. We demonstrate that RCO directly regulates genes controlling homeostasis of the hormone cytokinin to repress growth at the leaf base. Elevating cytokinin signaling in the RCO expression domain is sufficient to both transform A.thaliana simple leaves into complex ones and partially bypass the requirement for RCO in C.hirsuta complex leaf development. We also identify RCO as its own target gene. RCO directly represses its own transcription via an array of low-affinity binding sites, which evolved after RCO duplicated from its progenitor sequence. This autorepression is required to limit RCO expression. Thus, evolution of low-affinity binding sites created a negative autoregulatory loop that facilitated leaf shape evolution by defining RCO expression and fine-tuning cytokinin activity. In summary, we identify a transcriptional mechanism through which conflicts between novelty and pleiotropy are resolved during evolution and lead to morphological differences between species.
Highlights
Cis-regulatory variation of developmental genes plays a pivotal role in morphological evolution of plants and animals and often involves diversification of transcriptional enhancers [1,2,3,4,5,6,7,8]
We show that REDUCED COMPLEXITY (RCO) coordinates homeostasis of the hormone cytokinin (CK) through direct regulation of multiple genes involved in CK biosynthesis and catabolism and provide evidence that this RCO/CK module is required for complex leaf development
This indicates that RCO might undergo negative autoregulation, an idea further supported by the observation that a single-copy RCO::GUS reporter gene showed broader and stronger expression in rco leaves compared to wild type (Figures 1C and 1C0)
Summary
Cis-regulatory variation of developmental genes plays a pivotal role in morphological evolution of plants and animals and often involves diversification of transcriptional enhancers [1,2,3,4,5,6,7,8]. Regulatory sequence variation is believed to facilitate morphological change while minimizing the potentially adverse effects of pleiotropy—the phenomenon by which a single gene influences multiple aspects of development [1, 9, 10]. Do cis-regulatory changes at transcription factor loci cause specific effects on downstream gene expression or global transcriptome remodeling? How do cis-regulatory changes circumvent pleiotropy, given that transcriptional enhancers can show considerable pleiotropy despite their modularity [13] Do cis-regulatory changes at transcription factor loci cause specific effects on downstream gene expression or global transcriptome remodeling? Do these transcriptional changes affect few genes with large effects on development or a multitude of downstream processes with small effect? And how do cis-regulatory changes circumvent pleiotropy, given that transcriptional enhancers can show considerable pleiotropy despite their modularity [13]
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