Ben P. Williams

Phenotypic landscape inference reveals multiple evolutionary paths to C4 photosynthesis

C4 photosynthesis has independently evolved from the ancestral C3 pathway in at least 60 plant lineages, but, as with other complex traits, how it evolved is unclear. Here we show that the polyphyletic appearance of C4 photosynthesis is associated with diverse and flexible evolutionary paths that group into four major trajectories. We conducted a meta-analysis of 18 lineages containing species that use C3, C4, or intermediate C3–C4 forms of photosynthesis to parameterise a 16-dimensional phenotypic landscape. We then developed and experimentally verified a novel Bayesian approach based on a hidden Markov model that predicts how the C4 phenotype evolved. The alternative evolutionary histories underlying the appearance of C4 photosynthesis were determined by ancestral lineage and initial phenotypic alterations unrelated to photosynthesis. We conclude that the order of C4 trait acquisition is flexible and driven by non-photosynthetic drivers. This flexibility will have facilitated the convergent evolution of this complex trait. DOI: http://dx.doi.org/10.7554/eLife.00961.001

Molecular evolution of genes recruited into C4 photosynthesis

The C₄ pathway is found in 62 lineages of land plants. We assess evidence for parallel versus convergent evolution of C₄ photosynthesis from three approaches: (i) studies of specific genes and cis-elements controlling their expression; (ii) phylogenetic analyses of mRNAs and inferred amino acid sequences; and (iii) analysis of C₃ and C₄ genomes and transcriptomes. Evidence suggests that although convergent evolution is common, parallel evolution can underlie both changes to gene expression and amino acid sequence. cis-elements that direct cell specificity in C₄ leaves are present in C₃ orthologues of genes recruited into C₄, probably facilitating this parallel evolution. From this, and genomic data, we propose that gene duplication followed by neofunctionalisation is not necessarily important in the evolution of C₄ biochemistry.

Arabidopsis uses two gluconeogenic gateways for organic acids to fuel seedling establishment

Gluconeogenesis is a fundamental metabolic process that allows organisms to make sugars from non-carbohydrate stores such as lipids and protein. In eukaryotes only one gluconeogenic route has been described from organic acid intermediates and this relies on the enzyme phosphoenolpyruvate carboxykinase (PCK). Here we show that two routes exist in Arabidopsis, and that the second uses pyruvate, orthophosphate dikinase (PPDK). Gluconeogenesis is critical to fuel the transition from seed to seedling. Arabidopsis pck1 and ppdk mutants are compromised in seed-storage reserve mobilization and seedling establishment. Radiolabelling studies show that PCK predominantly allows sugars to be made from dicarboxylic acids, which are products of lipid breakdown. However, PPDK also allows sugars to be made from pyruvate, which is a major product of protein breakdown. We propose that both routes have been evolutionarily conserved in plants because, while PCK expends less energy, PPDK is twice as efficient at recovering carbon from pyruvate.

Stable transgenerational epigenetic inheritance requires a DNA methylation-sensing circuit

Epigenetic states are stably propagated in eukaryotes. In plants, DNA methylation patterns are faithfully inherited over many generations but it is unknown how the dynamic activities of cytosine DNA methyltransferases and 5-methylcytosine DNA glycosylases interact to maintain epigenetic homeostasis. Here we show that a methylation-sensing gene regulatory circuit centered on a 5-methylcytosine DNA glycosylase gene is required for long-term epigenetic fidelity in Arabidopsis. Disrupting this circuit causes widespread methylation losses and abnormal phenotypes that progressively worsen over generations. In heterochromatin, these losses are counteracted such that methylation returns to a normal level over four generations. However, thousands of loci in euchromatin progressively lose DNA methylation between generations and remain unmethylated. We conclude that an actively maintained equilibrium between methylation and demethylation activities is required to ensure long-term stable inheritance of epigenetic information.DNA methylation patterns are inherited over many generations in plants. Here, Williams and Gehring show that the 5-methylcytosine DNA glycosylase ROS1 functions as part of a methylation-sensitive circuit that ensures long-term epigenetic fidelity in Arabidopsis.

Ancient coding sequences underpin the spatial patterning of gene expression in C4 leaves

Photosynthesis is compromised in most plants because an enzymatic side-reaction fixes O2 instead of CO2. The energetic cost of oxygenation led to the evolution of C4 photosynthesis. In almost all C4 leaves compartmentation of photosynthesis between cells reduces oxygenation and so increases photosynthetic efficiency. Here we report that spatial expression of most C4 genes is controlled by intragenic cis-elements rather than promoter sequence. Two DNA motifs that co-operatively specify the patterning of genes required for C4 photosynthesis are identified. They are conserved in plants and algae that use the ancestral C3 pathway. As these motifs are located in exons they represent duons determining both gene expression and amino acid sequence. Our findings provide functional evidence for the importance of transcription factors recognising coding sequence as previously defined by genome-wide binding studies. Furthermore, they indicate that C4 evolution is based on ancient DNA motifs found in exonic sequence.