Evolutionary Genomics

Plant Systems Biology @ The Coruzzi Lab

From predictive network modeling to trait evolution



Evolutionary Genomics

A functional phylogenomic approach to seed plant evolution


The goal of our work in Evolutionary Genomics is to develop methods that enable us to explore and compare the genomes of diverse plant species to identify genes associated with the important agronomic traits that have evolved in nature. Working as a team of plant systematists, genomicists, and computer scientists, we have developed approaches and tools to enable functional genomic studies within a phylogenetic context. Our goal was to generate and use phylogenomic trees not simply to identify the relationship between species, but more importantly to identify the genes and associated biological processes (e.g. GO terms) that provide positive support for key nodes of trait evolution within plant phylogenies. As proof-of-principle, we conducted a functional phylogenomic analysis of the primitive gymnosperms, the species in which seeds first evolved. We first developed tools to enable genome-scale ortholog identification within a parsimony framework (OrthologID) [1].   We next developed an automated pipeline for the construction of phylogenomic-scale trees, to include all fully sequenced plant genomes and those with > 2,000 unigenes. The resulting matrix and phylogenomic tree, “BigPlantv1.0,” is composed of 22,833 sets of orthologs from the genomes of 150 plant species in 101 genera, analyzed in a combined analysis [2]. This phylogenomic framework enables us to identify overrepresented functional gene categories (GO terms) at major nodes in seed plant phylogeny, revealing critical genes important to angiosperm evolution. This analysis suggests, for example, that RNA interference (RNAi) played a significant role in the divergence of monocots from other angiosperms, a prediction that has experimental support in Arabidopsis and rice.  BigPlant v1.0 is now a community resource that enables researchers to explore the genomic origins of plant diversification (  This project is the result of a highly successful collaboration between PIs at New York University (Gloria Coruzzi), The New York Botanical Garden (Dennis Stevenson), The American Museum of Natural History (Rob DeSalle), and Cold Spring Harbor Labs (Dick McCombie, R. Martienssen).


[1] Chiu et al (2006) Bioinformatics. 22: 699-707; [2] Lee et al (2011) PLoS Genetics 7(12): e1002411