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Plant of the Day Cyperus esculentus - Cyperaceae Chufa (tigernut) 8,000 kg/ha, 720 kcal/sq m per month Top Crop for kcal productivity! One of the world’s worst weeds Big Questions Is polyploidy an evolutionary dead-end? If so, why are all plants the products of multiple polyploidization events? How do polyploid genomes diploidize (i.e., what are the rules)? Paleopolyploidy Ancient whole genome duplication No different from neopolyploidy – except that it happened a long time ago Track the historical contribution of polyploid speciation to evolution Polyploidy = Evolutionary noise (1970) W. H. Wagner, Jr. “…polyploidy has contributed little to progressive evolution” (1971) G. L. Stebbins Diploidization • Obscures evidence of paleopolyploidy • Return to a diploid genetic system – Restoration of full bivalent pairing – Gene and chromosome loss – Chromosomal rearrangements • Proceeds at different rates in different lineages Rosa Rosids Malus Cucumis Glycine Bruguiera Populus Linum Euphorbia Eurosids 1 Phaseolus Manihot Hevea Citrus Thellungiella Arabidopsis Brassica Eucalyptus Vitis Eurosids 2 Gossypium Diploidization Methods for Identifying Paleopolyploidy • Fossils • Synteny relationships of duplicated genes – conserved gene order • Age estimates of duplicate genes Cell Size Increase • Consequence of genome size increase • 2 X increase in cell volume 2n • 1.58 X increase in cell surface area 4n Extant Platanus Miocene Platanus Fossil Estimates Extant Platanus Miocene Platanus Fossil Estimates n>7–9 70% angiosperms Synteny Analyses Whole Genome Sequences Synteny Analyses Whole Genome Sequences Duplicate Gene Age Distributions % of Duplicate Pairs No Paleopolyploidy Ks (~ Time) Duplicate Gene Age Distributions % of Duplicate Pairs Carthamus tinctorius Ks (~ Time) % of Duplicate Pairs Inferring Paleopolyploidy Ks (~ Time) Previously Known Genome Duplications Barker et al., in prep Newly Recognized Genome Duplications Barker et al., in prep Newly Recognized Genome Duplications Infer 59 Independent Paleopolyploidizations 35 are newly observed 68% of Flowering Plant Families 71.4% of Gymnosperm Families Barker et al., in prep Significant increases in diversification rates in flowering plants •Half are associated with paleopolyploidy (p = 0.005) What about neo-polyploidy? Application of BISSE: binary-state speciation and extinction (likelihood method developed by Maddison et al. 2007) Polyploidy: speciation, extinction (I. Mayrose et al. 2011, Science) Speciation Rates Speciation of number Frequency cases 5 10 20 Frequency 0 0 0 5 5 10 15 10 number of cases Frequency 15 25 Extinction 15 30 20 20 Extinction Rates Speciation Rates 0.0 0.0 0.2 0.2 0.4 0.4 0.6 0.6 0.8 0.8 percent of cases percent of cases wherewhere diploidsdiploids have higherhave rateshigher rates higher rate in diploids 1.0 0.0 0.2 0.4 0.6 0.8 percent of cases where diploids have higher rates higher rate in diploids 1.0 Resolution Polyploidy is most often an evolutionary dead end, but the expanded genomic potential of those polyploids that do persist drives longer term evolutionary success. Unanswered questions Do auto- and allopolyploids differ in their evolutionary success? What factors control the fate of duplicate genes? How long must a polyploid lineage persist before it transitions from a trajectory that favors extinction to one that favors diversification? What evolutionary genetic changes/processes underlie this transition?