Abstract
BackgroundFlower bilateral symmetry (zygomorphy) has evolved multiple times independently across angiosperms and is correlated with increased pollinator specialization and speciation rates. Functional and expression analyses in distantly related core eudicots and monocots implicate independent recruitment of class II TCP genes in the evolution of flower bilateral symmetry. Furthermore, available evidence suggests that monocot flower bilateral symmetry might also have evolved through changes in B-class homeotic MADS-box gene function.MethodsIn order to test the non-exclusive hypotheses that changes in TCP and B-class gene developmental function underlie flower symmetry evolution in the monocot family Commelinaceae, we compared expression patterns of teosinte branched1 (TB1)-like, DEFICIENS (DEF)-like, and GLOBOSA (GLO)-like genes in morphologically distinct bilaterally symmetrical flowers of Commelina communis and Commelina dianthifolia, and radially symmetrical flowers of Tradescantia pallida.ResultsExpression data demonstrate that TB1-like genes are asymmetrically expressed in tepals of bilaterally symmetrical Commelina, but not radially symmetrical Tradescantia, flowers. Furthermore, DEF-like genes are expressed in showy inner tepals, staminodes and stamens of all three species, but not in the distinct outer tepal-like ventral inner tepals of C. communis.ConclusionsTogether with other studies, these data suggest parallel recruitment of TB1-like genes in the independent evolution of flower bilateral symmetry at early stages of Commelina flower development, and the later stage homeotic transformation of C. communis inner tepals into outer tepals through the loss of DEF-like gene expression.
Highlights
Flower bilateral symmetry has evolved multiple times independently across angiosperms and is correlated with increased pollinator specialization and speciation rates
At mid to late stages of development the ventral inner tepal of C. communis, but not C. dianthifolia, arrested prematurely. This resulted in strong asymmetry in the mature corolla of C. communis, with the ventral inner tepal resembling the small colorless outer tepals (Figure 2D, G versus 2E, H)
In the case of class II TCP genes, changes in expression are correlated with early developmental shifts from radial to bilateral flower symmetry in several core eudicots and commelinid monocots
Summary
Flower bilateral symmetry (zygomorphy) has evolved multiple times independently across angiosperms and is correlated with increased pollinator specialization and speciation rates. Functional and expression analyses in distantly related core eudicots and monocots implicate independent recruitment of class II TCP genes in the evolution of flower bilateral symmetry. Recent functional studies in distantly related core eudicots including Antirrhinum majus (Plantaginaceae), Iberis amara (Brassicaceae), Pisum sativum and Lotus japonicus (Leguminosae) and Gerbera hybrida (Asteraceae) - have demonstrated a role for class II TEOSINTE BRANCHED1 (TB1)/CYCLOIDEA (CYC)/PROLIFERATING CELL NUCLEAR ANTIGEN GENE-CONTROLLING ELEMENT BINDING FACTOR (PCF) (TCP) transcription factors in establishing flower symmetry by specifying identity to the dorsal (adaxial) region of the flower [8,9,10,11,12,13]. Together with the fully ventralized, and, radially symmetrical flowers of cyc:dich double mutants, these data demonstrate a role for CYC in dorsal stamen abortion, petal growth and organ number determination, and a role for DICH in shaping dorsal petal growth [8,9]
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