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4. Contrasting Phenological Patterns and Reproductive Strategies in Closely Related Monoecious Fig Tree Species.

Author

Cerezini MT, Rattis L, Furini PR, and Pereira RAS

Abstract

Understanding the ecological and evolutionary aspects of mutualistic interactions is essential for predicting species responses to environmental changes. This study aimed to investigate the phenological patterns and reproductive strategies in two closely related fig tree species, Ficus citrifolia and Ficus eximia . We monitored 99 F. citrifolia and 21 F. eximia trees weekly from January 2006 to April 2011 in an area close to the southern edge of the tropical region in Brazil. Our results revealed contrasting phenological patterns between the two species, with F. citrifolia displaying an annual flowering pattern (1.4 episodes per tree per year) and F. eximia a supra-annual pattern (0.5 episodes per tree per year). We also found significant differences in reproductive strategies, with F. eximia producing more pistillate flowers and, consequently, more seeds and pollinating wasps per fig than F. citrifolia , likely as an adaptation to overcome limitations of low population density by maximizing the gene flow. As the shorter-lived organism, the fig wasp was found to influence critical processes associated with the success and stability of mutualism, such as fig development and ripening. Our findings emphasize the importance of understanding the intricate interactions between mutualistic partners and their adaptive responses to environmental conditions in shaping fig tree populations' reproductive strategies and genetic structure.

Published
2024
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5. Atlantic flower-invertebrate interactions: A data set of occurrence and frequency of floral visits.

Author

Boscolo D, Nobrega Rodrigues B, Ferreira PA, Lopes LE, Tonetti VR, Reis Dos Santos IC, Hiruma-Lima JA, Nery L, Baptista de Lima K, Perozi J, Freitas AVL, Viana BF, Antunes-Carvalho C, Amorim DS, Freitas de Oliveira F, Groppo M, Absy ML, de Almeida-Scabbia RJ, Alves-Araújo A, de Amorim FW, Antiqueira PAP, Antonini Y, Aoki C, Dos Santos Aragão D, Balbino TCT, da Silva Ferreira Bandeira M, Barbosa BC, de Vasconcellos Barbosa MR, Baronio GJ, Barros LO, Beal-Neves M, Bertollo VM, de Melo Bezerra AD, Buzatto CR, Carneiro LT, Caron E, Carpim CS, Carvalho ES, Carvalho TL, Carvalho-Leite LJ, Cascaes MF, de Castro FS, Cavalleri A, Cazetta E, Cerezini MT, Coelho LFM, Colares R, Cordeiro GD, Cordeiro J, da Silva Corrêa AM, da Costa FV, Covre C, Cruz RDM, Cruz-Neto O, Correia-da-Rocha-Filho L, Delabie JHC, da Costa Dórea M, do-Nascimento VT, Alves Dos-Santos JM, Duarte M, Duarte MC, Duarte OMP, Dutilh JHA, Emerick BP, Fabiano GDS, Farache FHA, de Faria APG, Fernandes GW, Maria Abreu Ferreira P, Ferreira-Caliman MJ, Ferreira LMN, Filgueira de Sá TF, Franceschinelli EV, Franco-Assis GA, Fregolente Faracco Mazziero F, Freitas BM, Freitas J, Galastri NA, Galetto L, Garcia CT, Amela García MT, Garcia NL, Garófalo CA, Gélvez-Zúñiga I, Goldas CDS, Guerra TJ, Guerra TM, Harter-Marques B, Hipólito J, Kamke R, Klein RP, Koch EBA, Landgref-Filho P, Laroca S, Leandro CM, Lima R, de Lima TRA, Lima-Verde LW, de Lírio EJ, Lopes AV, Luizi-Ponzo AP, Machado ICS, Machado T, Magalhães FS, Mahlmann T, Mariano CDSF, Marques TED, Martello F, Martins CF, Martins MN, Martins R, Mascarenhas ALS, de Assis Mendes G, Mendonça MS, Menini Neto L, Milward-de-Azevedo MA, Miranda AO, Montoya-Pfeiffer PM, Moraes AM, Moraes BB, Moreira EF, Morini MS, Moure-Oliveira D, De Nadai LF, Nagatani VH, Nervo MH, de Siqueira Neves F, de Novais JS, Araújo-Oliveira ÉS, de Oliveira JHF, Pacheco-Filho AJS, Palmieri L, Pareja M, Passarella MA, Passos NDM, Paulino-Neto HF, Luna Peixoto A, Pereira LC, Pereira RAS, Pereira-Silva B, Pincheira-Ulbrich J, Pinheiro M, Piratelli AJ, Podgaiski LR, Polizello DS, Prado LPD, Prezoto F, Quadros FR, Queiroz EP, Glebya Maciel Quirino Z, Rabello AM, Rabeschini GBP, Ramalho MMM, Ramos FN, Rattis L, Rezende LHG, Ribeiro C, Robe LJ, Rocha EMSR, Rodrigues RR, Romero GQ, Roque N, Sabino WO, Sano PT, Reis PDSS, Dos Santos FS, Alves Dos Santos I, Dos Santos FAR, Silva Dos Santos I, Sartorello R, Schmitz HJ, Sigrist MR, Silva Junior JC, Silva ACGE, da Silva CVC, Alves Vieira Silva BS, Silva BLF, Silva CI, da Silva FO, Silva JLSE, Silva NS, da Silva OGM, Silva Neto CME, Silva Neto ER, Silveira D, Silveira MS, Singer RB, Soares LASS, Locatelli de Souza EM, de Souza JMT, Steiner J, Teixeira-Gamarra MC, Trentin BA, Varassin IG, Vila-Verde G, Yoshikawa VN, Zanin EM, Galetti M, and Ribeiro MC

Subjects
Humans, Animals, Ecosystem, Invertebrates, Forests, Plants, Flowers, Pollination, Lepidoptera, Hymenoptera
Abstract

Encounters between flowers and invertebrates are key events for the functioning of tropical forests. Assessing the structure of networks composed of the interactions between those partners leads to a better understanding of ecosystem functioning and the effects of environmental factors on ecological processes. Gathering such data is, however, costly and time-consuming, especially in the highly diverse tropics. We aimed to provide a comprehensive repository of available flower-invertebrate interaction information for the Atlantic Forest, a South American tropical forest domain. Data were obtained from published works and "gray literature," such as theses and dissertations, as well as self-reports by co-authors. The data set has ~18,000 interaction records forming 482 networks, each containing between one and 1061 interaction links. Each network was sampled for about 200 h or less, with few exceptions. A total of 641 plant genera within 136 different families and 39 orders were reported, with the most abundant and rich families being Asteraceae, Fabaceae, and Rubiaceae. Invertebrates interacting with these plants were all arthropods from 10 orders, 129 families, and 581 genera, comprising 2419 morphotypes (including 988 named species). Hymenoptera was the most abundant and diverse order, with at least six times more records than the second-ranked order (Lepidoptera). The complete data set shows Hymenoptera interacting with all plant orders and also shows Diptera, Lepidoptera, Coleoptera, and Hemiptera to be important nodes. Among plants, Asterales and Fabales had the highest number of interactions. The best sampled environment was forest (~8000 records), followed by pastures and crops. Savanna, grasslands, and urban environments (among others) were also reported, indicating a wide range of approaches dedicated to collecting flower-invertebrate interaction data in the Atlantic Forest domain. Nevertheless, most reported data were from forest understory or lower strata, indicating a knowledge gap about flower-invertebrate interactions at the canopy. Also, access to remote regions remains a limitation, generating sampling bias across the geographical range of the Atlantic Forest. Future studies in these continuous and hard-to-access forested areas will yield important new information regarding the interactions between flowers and invertebrates in the Atlantic Forest. There are no copyright restrictions on the data set. Please cite this data paper if the data are used in publications and teaching events., (© 2022 The Ecological Society of America.)

Published
2023
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6. Exploring systematic biases, rooting methods and morphological evidence to unravel the evolutionary history of the genus Ficus (Moraceae).

Author

Rasplus JY, Rodriguez LJ, Sauné L, Peng YQ, Bain A, Kjellberg F, Harrison RD, Pereira RAS, Ubaidillah R, Tollon-Cordet C, Gautier M, Rossi JP, and Cruaud A

Subjects
Animals, DNA, Plant analysis, Plant Breeding, Pollination, Biological Evolution, DNA, Plant genetics, Ficus anatomy & histology, Ficus physiology, Phylogeny, Plant Roots physiology
Abstract

Despite many attempts in the Sanger sequencing era, the phylogeny of fig trees remains unresolved, which limits our ability to analyze the evolution of key traits that may have contributed to their evolutionary and ecological success. We used restriction-site-associated DNA sequencing (c. 420 kb) and 102 morphological characters to elucidate the relationships between 70 species of Ficus. To increase phylogenetic information for higher-level relationships, we targeted conserved regions and assembled paired reads into long loci to enable the retrieval of homologous loci in outgroup genomes. We compared morphological and molecular results to highlight discrepancies and reveal possible inference bias. For the first time, we recovered a monophyletic subgenus Urostigma (stranglers) and a clade with all gynodioecious Ficus. However, we show, with a new approach based on iterative principal component analysis, that it is not (and will probably never be) possible to homogenize evolutionary rates and GC content for all taxa before phylogenetic inference. Four competing positions for the root of the molecular tree are possible. The placement of section Pharmacosycea as sister to other fig trees is not supported by morphological data and considered a result of a long-branch attraction artefact to the outgroups. Regarding morphological features and indirect evidence from the pollinator tree of life, the topology that divides Ficus into monoecious versus gynodioecious species appears most plausible. It seems most likely that the ancestor of fig trees was a freestanding tree and active pollination is inferred as the ancestral state, contrary to previous hypotheses. However, ambiguity remains on the ancestral breeding system. Despite morphological plasticity, we advocate restoring a central role to morphology in our understanding of the evolution of Ficus, as it can help detect systematic errors that appear more pronounced with larger molecular datasets., (© 2020 Willi Hennig Society.)

Published
2021
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7. What makes a fig: insights from a comparative analysis of inflorescence morphogenesis in Moraceae.

Author

Leite VG, Kjellberg F, Pereira RAS, and Teixeira SP

Subjects
Biological Evolution, Flowers, Morphogenesis, Pollination, Ficus, Inflorescence
Abstract

Background and Aims: Moraceae, the family of mulberry and fig trees, displays small homogeneous flowers but extremely diverse inflorescences ranging from simple and branched to complex and condensed. Inflorescences also vary in flower organization in the receptacle, in the degree of flower condensation and in receptacle shape. Thus, the objective of the present study was to compare the inflorescence morphogenesis of Moraceae species, to investigate whether clades with a similar pollination mode share the same patterns of inflorescence development and the developmental stages at which we observe the key changes resulting in the diversified inflorescence architecture that culminates in the Ficus syconium., Methods: Inflorescences at different developmental stages were sampled from Brosimum gaudichaudii, Castilla elastica, Clarisia ilicifolia, Ficus pertusa, Maclura tinctoria and Morus nigra and processed for surface and anatomical analyses., Key Results: The inflorescence morphogenesis of the studied species is highly variable. The shape of the inflorescence meristem (bulging, hemispheric or elongated), the initiation order and arrangement of flowers along the receptacle and the occurrence of bracts vary between related species. This diversity originates early during inflorescence development. Brosimum gaudichaudii, C. elastica and F. pertusa have flowers enclosed or immersed within the receptacle, although inflorescences begin their development as flat and open structures, as occurs in the other three study species., Conclusion: Comparison of the inflorescence morphogenesis in Moraceae species allows us to infer that evolutionary ontogenetic changes driven by pollinators culminate in the enclosure of flowers inside the receptacle, as occurs in the Ficus syconium., (© The Author(s) 2020. Published by Oxford University Press on behalf of the Annals of Botany Company. All rights reserved. For permissions, please e-mail: journals.permissions@oup.com.)

Published
2021
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8. Genomic evidence of prevalent hybridization throughout the evolutionary history of the fig-wasp pollination mutualism.

Author

Wang G, Zhang X, Herre EA, McKey D, Machado CA, Yu WB, Cannon CH, Arnold ML, Pereira RAS, Ming R, Liu YF, Wang Y, Ma D, and Chen J

Subjects
Animals, Biological Evolution, Hybridization, Genetic, Phylogeny, Pollination physiology, Symbiosis physiology, Ficus physiology, Wasps physiology
Abstract

Ficus (figs) and their agaonid wasp pollinators present an ecologically important mutualism that also provides a rich comparative system for studying functional co-diversification throughout its coevolutionary history (~75 million years). We obtained entire nuclear, mitochondrial, and chloroplast genomes for 15 species representing all major clades of Ficus. Multiple analyses of these genomic data suggest that hybridization events have occurred throughout Ficus evolutionary history. Furthermore, cophylogenetic reconciliation analyses detect significant incongruence among all nuclear, chloroplast, and mitochondrial-based phylogenies, none of which correspond with any published phylogenies of the associated pollinator wasps. These findings are most consistent with frequent host-switching by the pollinators, leading to fig hybridization, even between distantly related clades. Here, we suggest that these pollinator host-switches and fig hybridization events are a dominant feature of fig/wasp coevolutionary history, and by generating novel genomic combinations in the figs have likely contributed to the remarkable diversity exhibited by this mutualism.

Published
2021
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9. The Role of Baccharis dracunculifolia and its Chemical Profile on Green Propolis Production by Apis mellifera.

Author

Rodrigues DM, De Souza MC, Arruda C, Pereira RAS, and Bastos JK

Subjects
Animals, Baccharis metabolism, Behavior, Animal drug effects, Chromatography, High Pressure Liquid, Female, Male, Mass Spectrometry, Phenol analysis, Phenol chemistry, Phenol pharmacology, Plant Leaves chemistry, Plant Leaves metabolism, Plant Tumors parasitology, Propolis analysis, Propolis pharmacology, Volatile Organic Compounds analysis, Volatile Organic Compounds chemistry, Volatile Organic Compounds pharmacology, Baccharis chemistry, Bees physiology, Propolis chemistry
Abstract

The botanical source of Brazilian green propolis (BGP) is Baccharis dracunculifolia DC, which interacts not only with Apis mellifera, but also with galling insects. In the last decade, because of green propolis´ important biologic activities, the international demand for BGP overcame the production capacity, consequently, new approaches are required to increase this production. Hence, the understanding of the chemical ecology interactions of B. dracunculifolia with galls and bees in field conditions may provide insights to increase BGP's production. A "bee pasture" experiment aiming to better understand this plant-insect interaction was therefore performed. For that, 48 B. dracunculifolia individuals, being 24 females and 24 males, were cultivated and investigated for the following parameters: (1) phenolic and volatile compounds in both B. dracunculifolia leaves and green propolis, (2) environmental variables, (3) visiting rate by bees, (4) time of resin collection, and (5) number of galls. Regression analyses by independent linear mixed-effect models were run to correlate phenolic and volatile compounds concentration with the environmental and field variables. Significant differences in chemical profile and field variables were observed between male and female plants. Male plants showed higher infestation by galling insects while female plants showed higher number of visiting bees, time of resin collection and terpenes concentration, contributing to the differences observed in the field. The obtained results suggest that increasing the percentage of female B. dracunculifolia plants in the field may attract more bees and therefore enhance propolis production.

Published
2020
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10. ATLANTIC EPIPHYTES: a data set of vascular and non-vascular epiphyte plants and lichens from the Atlantic Forest.

Author

Ramos FN, Mortara SR, Monalisa-Francisco N, Elias JPC, Neto LM, Freitas L, Kersten R, Amorim AM, Matos FB, Nunes-Freitas AF, Alcantara S, Alexandre MHN, de Almeida-Scabbia RJ, de Almeida OJG, Alves FE, de Oliveira Alves RM, Alvim FS, de Andrade ACS, de Andrade S, Aona LYS, Araujo AC, de Araújo KCT, Ariati V, Assis JC, de Azevedo CO, Barbosa BF, Barbosa DEF, Barbosa FDR, de Barros F, Basilio GA, Bataghin FA, Bered F, Bianchi JS, Blum CT, Boelter CR, Bonnet A, Brancalion PHS, Breier TB, Brion CT, Buzatto CR, Cabral A, Cadorin TJ, Caglioni E, Canêz L, Cardoso PH, de Carvalho FS, Carvalho RG, Catharino ELM, Ceballos SJ, Cerezini MT, César RG, Cestari C, Chaves CJN, Citadini-Zanette V, Coelho LFM, Coffani-Nunes JV, Colares R, Colletta GD, Corrêa NM, da Costa AF, da Costa GM, Costa LMS, Costa NGS, Couto DR, Cristofolini C, da Cruz ACR, Del Neri LA, di Pasquo M, Dos Santos Dias A, Dias LDCD, Dislich R, Duarte MC, Fabricante JR, Farache FHA, de Faria APG, Faxina C, Ferreira MTM, Fischer E, Fonseca CR, Fontoura T, Francisco TM, Furtado SG, Galetti M, Garbin ML, de Gasper AL, Goetze M, Gomes-da-Silva J, Gonçalves MFA, Gonzaga DR, Silva ACGE, Guaraldo AC, Guarino ESG, Guislon AV, Hudson LB, Jardim JG, Jungbluth P, Kaeser SDS, Kessous IM, Koch NM, Kuniyoshi YS, Labiak PH, Lapate ME, Santos ACL, Leal RLB, Leite FS, Leitman P, Liboni AP, Liebsch D, Lingner DV, Lombardi JA, Lucas E, Luzzi JDR, Mai P, Mania LF, Mantovani W, Maragni AG, Marques MCM, Marquez G, Martins C, Martins LDN, Martins PLSS, Mazziero FFF, Melo CA, de Melo MMF, Mendes AF, Mesacasa L, Morellato LPC, Moreno VS, Muller A, Murakami MMDS, Cecconello E, Nardy C, Nervo MH, Neves B, Nogueira MGC, Nonato FR, de Oliveira-Filho AT, de Oliveira CPL, Overbeck GE, Marcusso GM, Paciencia MLB, Padilha P, Padilha PT, Pereira ACA, Pereira LC, Pereira RAS, Pincheira-Ulbrich J, Pires JSR, Pizo MA, Pôrto KC, Rattis L, Reis JRM, Reis SGD, da Rocha-Pessôa TC, Rocha CFD, Rocha FS, Rodrigues ARP, Rodrigues RR, Rogalski JM, Rosanelli RL, Rossado A, Rossatto DR, Rother DC, Ruiz-Miranda CR, Saiter FZ, Sampaio MB, Santana LD, Santos JSD, Sartorello R, Sazima M, Schmitt JL, Schneider G, Schroeder BG, Sevegnani L, Júnior VOS, da Silva FR, da Silva MJ, Silva MPP, Silva RG, Silva SM, Singer RB, Siqueira G, Soares LE, de Sousa HC, Spielmann A, Tonetti VR, Toniato MTZ, Ulguim PSB, van den Berg C, van den Berg E, Varassin IG, da Silva IBV, Vibrans AC, Waechter JL, Weissenberg EW, Windisch PG, Wolowski M, Yañez A, Yoshikawa VN, Zandoná LR, Zanella CM, Zanin EM, Zappi DC, Zipparro VB, Zorzanelli JPF, and Ribeiro MC

Abstract

Epiphytes are hyper-diverse and one of the frequently undervalued life forms in plant surveys and biodiversity inventories. Epiphytes of the Atlantic Forest, one of the most endangered ecosystems in the world, have high endemism and radiated recently in the Pliocene. We aimed to (1) compile an extensive Atlantic Forest data set on vascular, non-vascular plants (including hemiepiphytes), and lichen epiphyte species occurrence and abundance; (2) describe the epiphyte distribution in the Atlantic Forest, in order to indicate future sampling efforts. Our work presents the first epiphyte data set with information on abundance and occurrence of epiphyte phorophyte species. All data compiled here come from three main sources provided by the authors: published sources (comprising peer-reviewed articles, books, and theses), unpublished data, and herbarium data. We compiled a data set composed of 2,095 species, from 89,270 holo/hemiepiphyte records, in the Atlantic Forest of Brazil, Argentina, Paraguay, and Uruguay, recorded from 1824 to early 2018. Most of the records were from qualitative data (occurrence only, 88%), well distributed throughout the Atlantic Forest. For quantitative records, the most common sampling method was individual trees (71%), followed by plot sampling (19%), and transect sampling (10%). Angiosperms (81%) were the most frequently registered group, and Bromeliaceae and Orchidaceae were the families with the greatest number of records (27,272 and 21,945, respectively). Ferns and Lycophytes presented fewer records than Angiosperms, and Polypodiaceae were the most recorded family, and more concentrated in the Southern and Southeastern regions. Data on non-vascular plants and lichens were scarce, with a few disjunct records concentrated in the Northeastern region of the Atlantic Forest. For all non-vascular plant records, Lejeuneaceae, a family of liverworts, was the most recorded family. We hope that our effort to organize scattered epiphyte data help advance the knowledge of epiphyte ecology, as well as our understanding of macroecological and biogeographical patterns in the Atlantic Forest. No copyright restrictions are associated with the data set. Please cite this Ecology Data Paper if the data are used in publication and teaching events., (© 2019 The Authors. Ecology © 2019 The Ecological Society of America.)

Published
2019
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11. A comparative venomic fingerprinting approach reveals that galling and non-galling fig wasp species have different venom profiles.

Author

Elias LG, Silva DB, Silva R, Peng YQ, Yang DR, Lopes NP, and Pereira RAS

Subjects
Animals, Molecular Weight, Pollination, Venoms chemistry, Wasps physiology, Ficus physiology, Symbiosis, Venoms metabolism, Wasps metabolism
Abstract

The galling habit represents a complex type of interaction between insects and plants, ranging from antagonism to mutualism. The obligate pollination mutualism between Ficus and fig wasps relies strongly on the induction of galls in Ficus flowers, where wasps' offspring develop. Even though gall induction plays an important role in many insect-plant interactions, the mechanisms that trigger gall formation are still not completely known. Using a fingerprinting approach, we show here that venom protein profiles from galling fig wasps differ from the venom profiles of non-galling species, suggesting the secretion plays different roles according to the type of interaction it is involved in. Each studied cleptoparasitic species had a distinct venom profile, suggesting that cleptoparasitism in fig wasps covers a vast diversity of molecular interactions. Fig wasp venoms are mainly composed of peptides. No low molecular weight compounds were detected by UPLC-DAD-MS, suggesting that such compounds (e.g., IAA and cytokinines) are not involved in gall induction. The differences in venom composition observed between galling and non-galling fig wasp species bring new perspectives to the study of gall induction processes and the role of insect secretions., Competing Interests: The authors have declared that no competing interests exist.

Published
2018
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12. Atlantic forests to the all Americas: Biogeographical history and divergence times of Neotropical Ficus (Moraceae).

Author

Machado AFP, Rønsted N, Bruun-Lund S, Pereira RAS, and Paganucci de Queiroz L

Subjects
Americas, Animals, Bayes Theorem, Biodiversity, Forests, Phylogeny, Phylogeography, Ficus classification
Abstract

Ficus (Moraceae) is well diversified in the Neotropics with two lineages inhabiting the wet forests of this region. The hemiepiphytes of section Americanae are the most diversified with c. 120 species, whereas section Pharmacosycea includes about 20 species mostly with a terrestrial habit. To reconstruct the biogeographical history and diversification of Ficus in the Americas, we produced a dated Bayesian phylogenetic hypothesis of Neotropical Ficus including two thirds of the species sequenced for five nuclear regions (At103, ETS, G3pdh, ITS/5.8S and Tpi). Ancestral range was estimated using all models available in Biogeobears and Binary State Speciation and Extinction analysis was used to evaluate the role of the initial habit and propagule size in diversification. The phylogenetic analyses resolved both Neotropical sections as monophyletic but the internal relationships between species in section Americanae remain unclear. Ficus started their diversification in the Neotropics between the Oligocene and Miocene. The genus experienced two bursts of diversification: in the middle Miocene and the Pliocene. Colonization events from the Amazon to adjacent areas coincide with the end of the Pebas system (10 Mya) and the connection of landmasses. Divergence of endemic species in the Atlantic forest is inferred to have happened after its isolation and the opening and consolidation of the Cerrado. Our results suggest a complex diversification in the Atlantic forest differing between postulated refuges and more instable areas in the South distribution of the forest. Finally the selection for initial hemiepiphytic habit and small to medium propagule size influenced the diversification and current distribution of the species at Neotropical forests marked by the historical instability and long-distance dispersal., (Copyright © 2018 Elsevier Inc. All rights reserved.)

Published
2018
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