Relationship between fruit phenotypes and domestication in hexaploid populations of biribá (Annona mucosa) in Brazilian Amazonia.

Background: Biribá (Annona mucosa Jacq.) is a fruit tree domesticated in Amazonia and has polyploid populations. The species presents ample phenotypic variation in fruit characteristics, including weight (100-4,000 g) and differences in carpel protrusions. Two cytotypes are recorded in the literature (2n = 28, 42) and genome size records are divergent (2C = 4.77, 5.42 and 6.00 pg). To decipher the role of polyploidy in the domestication of A. mucosa, we examined the relationships among phenotypic variation, chromosome number and genome size, and which came first, polyploidization or domestication. Methodology: We performed chromosome counts of A. mucosa from central and western Brazilian Amazonia, and estimated genome size by flow cytometry. We performed phylogenetic reconstruction with publicly available data using a Bayesian framework, time divergence analysis and reconstructed the ancestral chromosome number for the genus Annona and for A. mucosa. Results: We observed that variation in fruit phenotypes is not associated with variation in chromosome number and genome size. The most recent common ancestor of A. mucosa is inferred to be polyploid and diverged before domestication. Conclusions: We conclude that, when domesticated, A. mucosa was already polyploid and we suggest that human selection is the main evolutionary force behind fruit size and fruit morphological variation in Annona mucosa.

Phylogeny, divergence times, and diversification in Calophyllaceae: Linking key characters and habitat changes to the evolution of Neotropical Calophylleae.

The clusioid clade comprises five monophyletic families: Bonnetiaceae, Calophyllaceae, Clusiaceae s.s., Hypericaceae, and Podostemaceae. Even though the circumscription of these families is well established, phylogenetic relationships within some families remain unresolved. This study aims to infer phylogenetic relationships within the Neotropical Calophylleae based on a broad sampling of taxa and a multilocus approach. We then use our phylogenetic framework as basis to investigate the evolution and biogeography of Calophylleae and diversification shifts in Calophyllaceae. To reconstruct the phylogeny of the Neotropical Calophylleae, we used five plastid (matK, ndhF, rbcL, psbA-trnH, and trnK), two mitochondrial (matR and rps3), and two nuclear (EMB2765 and ITS) markers, including previously published and newly generated sequences. We sampled 74 species, increasing sampling of Neotropical taxa by 500%. Our phylogenetic hypothesis for Calophyllaceae provides additional support for the monophyly of all genera and allowed us to identify four main clades: Calophyllum, Kayea, Mammea, and the Neotropical clade. The Neotropical clade includes three main lineages, a small clade composed of Clusiella and Marila, and a large HaCaKi clade (i.e., Haplocarpa, Caraipa, and Kilmeyera) that is sister to Mahurea exstipulata. The evolution of three morphological traits (i.e., fleshy fruits, anther glands, and winged seeds) were shown to be associated with changes in evolutionary dynamics in Calophyllaceae, while a biome shift was detected in Kielmeyera, affecting net diversification within this genus. Major geological and climatic events such as the Andean uplift and a gradual decrease in temperatures seem to have influenced diversification rates within the Neotropical Calophylleae.