Flower evolution in species of Croton L. (Euphorbiaceae): ontogeny and global profile of gene expression

The Euphorbiaceae are notable for floral and inflorescence diversity and evolutionary complexity. Croton, is the second largest genus in the family and exhibits particular diversity in its flowers, especially regarding perianth and number of stamens, besides the inflorescences, which are also very diverse. Considering Croton\'s great variability in the reproductive structures, the aim of this thesis was to study flowers and inflorescences with an evolutionary approach, including morphology, ontogeny, vasculature, auxin regulation and genetic expression. Flowers in several stages of development were analyzed using light microscopy and scanning electron microscopy. Inflorescences were analyzed in stereomicroscope and the traits were plotted on the most recent phylogeny of the genus. The genetic expression was tested using RNAseq. In the first chapter the flowers showed similarity in the initiation of sepals and the presence of filamentous, petaloid structures in Croton lundianus (Didr.) Müll. Arg., interpreted here as staminodes. In Croton sphaerogynus Baill., staminodes were described for the first time. The staminodes reported here could be interpreted as transitional structures that we considered as evolutionary reductions. In the second chapter, the staminate flowers showed polystemonous androecium and the delay in petals\' initiation and the antesepalous nectaries development interfered in the development of the stamens, characterizing obdiplostemony. Vasculature corroborated obdiplostemony and revealed a central stamen in C. fuscescens with carpelar features, interpreted here as a homeosis case. Glandular staminodes were registered and interpreted as a heterotopy case. The obdiplostemony may be related to modulation of the free IAA concentrations during floral developmental steps and Croton flowers can be used as good models for obdiplostemony, homeosis and heterotopy. In the third and fourth chapter we studied Croton inflorescences, which showed 17 patterns with differences on the organization and distribution of pistillate flowers. The inflorescence traits analyzed were very homoplastic, most likely determined by convergent evolution in distantly related lineages distributed in similar habitats. The genetic expression of C. fuscescens was particularly analyzed and the transcriptome showed that the different zones have their development guided through the same transcripts set. Each zone has different expression level and these variations and gradient could be interpreted as the boundary between each inflorescence zone. The floral developmental novelties and evolutionary links identified here raise the importance of future floral studies with the genus, what would bring a better understanding on how the reproductive structures evolved in the history of the group (AU)