Bárbara Simões Santos Leal1, Vanessa Araujo Graciano1, Cleber Juliano Neves Chaves1, Luis Alberto Pillaca Huacre2, Myriam Heuertz3, Clarisse Palma-Silva1,4. 1. Departamento de Ecologia, Instituto de Biociências, Universidade Estadual Paulista, Rio Claro, São Paulo, Brazil. 2. Departamento de Ecología, Museo de Historia Natural de la Universidad Nacional Mayor de San Marcos, Lima, Peru. 3. Biogeco, INRA, Université de Bordeaux, Cestas, France. 4. Departamento de Biologia Vegetal, Instituto de Biologia, Universidade Estadual de Campinas, Campinas, São Paulo, Brazil.
Abstract
BACKGROUND AND AIMS: Isolated populations constitute an ideal laboratory to study the consequences of intraspecific divergence, because intrinsic incompatibilities are more likely to accumulate under reduced gene flow. Here, we use a widespread bromeliad with a patchy distribution, Pitcairnia lanuginosa, as a model to infer processes driving Neotropical diversification and, thus, to improve our understanding of the origin and evolutionary dynamics of biodiversity in this highly speciose region. METHODS: We assessed the timing of lineage divergence, genetic structural patterns and historical demography of P. lanuginosa, based on microsatellites, and plastid and nuclear sequence data sets using coalescent analyses and an Approximate Bayesian Computation framework. Additionally, we used species distribution models (SDMs) to independently estimate potential changes in habitat suitability. KEY RESULTS: Despite morphological uniformity, plastid and nuclear DNA data revealed two distinct P. lanuginosa lineages that probably diverged through dispersal from the Cerrado to the Central Andean Yungas, following the final uplift of the Andes, and passed through long-term isolation with no evidence of migration. Microsatellite data indicate low genetic diversity and high levels of inbreeding within populations, and restricted gene flow among populations, which are likely to be a consequence of bottlenecks (or founder events), and high selfing rates promoting population persistence in isolation. SDMs showed a slight expansion of the suitable range for P. lanuginosa lineages during the Last Glacial Maximum, although molecular data revealed a signature of older divergence. Pleistocene climatic oscillations thus seem to have played only a minor role in the diversification of P. lanuginosa, which probably persisted through adverse conditions in riparian forests. CONCLUSIONS: Our results imply drift as a major force shaping the evolution of P. lanuginosa, and suggest that dispersal events have a prominent role in connecting Neotropical open and forest biomes.
BACKGROUND AND AIMS: Isolated populations constitute an ideal laboratory to study the consequences of intraspecific divergence, because intrinsic incompatibilities are more likely to accumulate under reduced gene flow. Here, we use a widespread bromeliad with a patchy distribution, Pitcairnia lanuginosa, as a model to infer processes driving Neotropical diversification and, thus, to improve our understanding of the origin and evolutionary dynamics of biodiversity in this highly speciose region. METHODS: We assessed the timing of lineage divergence, genetic structural patterns and historical demography of P. lanuginosa, based on microsatellites, and plastid and nuclear sequence data sets using coalescent analyses and an Approximate Bayesian Computation framework. Additionally, we used species distribution models (SDMs) to independently estimate potential changes in habitat suitability. KEY RESULTS: Despite morphological uniformity, plastid and nuclear DNA data revealed two distinct P. lanuginosa lineages that probably diverged through dispersal from the Cerrado to the Central Andean Yungas, following the final uplift of the Andes, and passed through long-term isolation with no evidence of migration. Microsatellite data indicate low genetic diversity and high levels of inbreeding within populations, and restricted gene flow among populations, which are likely to be a consequence of bottlenecks (or founder events), and high selfing rates promoting population persistence in isolation. SDMs showed a slight expansion of the suitable range for P. lanuginosa lineages during the Last Glacial Maximum, although molecular data revealed a signature of older divergence. Pleistocene climatic oscillations thus seem to have played only a minor role in the diversification of P. lanuginosa, which probably persisted through adverse conditions in riparian forests. CONCLUSIONS: Our results imply drift as a major force shaping the evolution of P. lanuginosa, and suggest that dispersal events have a prominent role in connecting Neotropical open and forest biomes.
Authors: Magali Gonçalves Garcia; Roberta Santos Silva; Maria Antonia Carniello; Joseph William Veldman; Ana Aparecida Bandini Rossi; Luiz Orlando de Oliveira Journal: Mol Phylogenet Evol Date: 2011-09-10 Impact factor: 4.286
Authors: Rafael B Louzada; Katharina Schulte; Maria das Graças L Wanderley; Daniele Silvestro; Georg Zizka; Michael H J Barfuss; Clarisse Palma-Silva Journal: Mol Phylogenet Evol Date: 2014-03-21 Impact factor: 4.286
Authors: Juan J Ancona; Juan P Pinzón-Esquivel; Eduardo Ruiz-Sánchez; Clarisse Palma-Silva; Juan J Ortiz-Díaz; Juan Tun-Garrido; Germán Carnevali; Néstor E Raigoza Journal: Plants (Basel) Date: 2022-06-28