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Resurrected Protein Interaction Networks Reveal the Innovation Potential of Ancient Whole-Genome Duplication.

Zhicheng ZhangHeleen CoenenPhilip RuelensRashmi R HazarikaTareq AlhindiGeorgianna K OguisAnja VandeperreMarília Cristina Santos de MedeirosKoen Geuten
Published in: The Plant cell (2018)
The evolution of plants is characterized by whole-genome duplications, sometimes closely associated with the origin of large groups of species. The gamma (γ) genome triplication occurred at the origin of the core eudicots, which comprise ∼75% of flowering plants. To better understand the impact of whole-genome duplication, we studied the protein interaction network of MADS domain transcription factors, which are key regulators of reproductive development. We reconstructed, synthesized, and tested the interactions of ancestral proteins immediately before and closely after the triplication and directly compared these ancestral networks to the extant networks of Arabidopsis thaliana and tomato (Solanum lycopersicum). We found that gamma expanded the MADS domain interaction network more strongly than subsequent genomic events. This event strongly rewired MADS domain interactions and allowed for the evolution of new functions and installed robustness through new redundancy. Despite extensive rewiring, the organization of the network was maintained through gamma. New interactions and protein retention compensated for its potentially destructive impact on network organization. Post gamma, the network evolved from an organization around the single hub SEP3 to a network organized around multiple hubs and well-connected proteins lost, rather than gained, interactions. The data provide a resource for comparative developmental biology in flowering plants.
Keyphrases
  • arabidopsis thaliana
  • transcription factor
  • network analysis
  • genome wide
  • machine learning
  • dna methylation
  • artificial intelligence
  • electronic health record
  • risk assessment
  • single cell
  • deep learning
  • big data