12 research outputs found
A Genome-Wide Characterization of MicroRNA Genes in Maize
MicroRNAs (miRNAs) are small, non-coding RNAs that play essential roles in plant growth, development, and stress response. We conducted a genome-wide survey of maize miRNA genes, characterizing their structure, expression, and evolution. Computational approaches based on homology and secondary structure modeling identified 150 high-confidence genes within 26 miRNA families. For 25 families, expression was verified by deep-sequencing of small RNA libraries that were prepared from an assortment of maize tissues. PCR–RACE amplification of 68 miRNA transcript precursors, representing 18 families conserved across several plant species, showed that splice variation and the use of alternative transcriptional start and stop sites is common within this class of genes. Comparison of sequence variation data from diverse maize inbred lines versus teosinte accessions suggest that the mature miRNAs are under strong purifying selection while the flanking sequences evolve equivalently to other genes. Since maize is derived from an ancient tetraploid, the effect of whole-genome duplication on miRNA evolution was examined. We found that, like protein-coding genes, duplicated miRNA genes underwent extensive gene-loss, with ∼35% of ancestral sites retained as duplicate homoeologous miRNA genes. This number is higher than that observed with protein-coding genes. A search for putative miRNA targets indicated bias towards genes in regulatory and metabolic pathways. As maize is one of the principal models for plant growth and development, this study will serve as a foundation for future research into the functional roles of miRNA genes
Evolutionary food web model based on body masses gives realistic networks with permanent species turnover
The networks of predator-prey interactions in ecological systems are
remarkably complex, but nevertheless surprisingly stable in terms of long term
persistence of the system as a whole. In order to understand the mechanism
driving the complexity and stability of such food webs, we developed an
eco-evolutionary model in which new species emerge as modifications of existing
ones and dynamic ecological interactions determine which species are viable.
The food-web structure thereby emerges from the dynamical interplay between
speciation and trophic interactions. The proposed model is less abstract than
earlier evolutionary food web models in the sense that all three evolving
traits have a clear biological meaning, namely the average body mass of the
individuals, the preferred prey body mass, and the width of their potential
prey body mass spectrum. We observed networks with a wide range of sizes and
structures and high similarity to natural food webs. The model networks exhibit
a continuous species turnover, but massive extinction waves that affect more
than of the network are not observed