Your search keyword '"boreotropical migration"' showing total 8 results

1. Five long-distance dispersals shaped the major intercontinental disjunctions in Tectariaceae s.l. (Polypodiales, Polypodiopsida)

Author

Wan, Xia, Zhang, Liang, Lehtonen, Samuli, Tuomisto, Hanna, Zhang, Da-Wei, Gao, Xin-Fen, and Zhang, Li-Bing

Published

2023

2. Biogeographic history of a large clade of ectomycorrhizal fungi, the Russulaceae, in the Neotropics and adjacent regions.

Author

Hackel, Jan, Henkel, Terry W., Moreau, Pierre‐Arthur, De Crop, Eske, Verbeken, Annemieke, Sà, Mariana, Buyck, Bart, Neves, Maria‐Alice, Vasco‐Palacios, Aída, Wartchow, Felipe, Schimann, Heidy, Carriconde, Fabian, Garnica, Sigisfredo, Courtecuisse, Régis, Gardes, Monique, Manzi, Sophie, Louisanna, Eliane, and Roy, Mélanie

Subjects

*ECTOMYCORRHIZAL fungi, *HOST plants, *PHYTOGEOGRAPHY, *VESICULAR-arbuscular mycorrhizas

Abstract

Summary: The biogeography of neotropical fungi remains poorly understood. Here, we reconstruct the origins and diversification of neotropical lineages in one of the largest clades of ectomycorrhizal fungi in the globally widespread family Russulaceae.We inferred a supertree of 3285 operational taxonomic units, representing worldwide internal transcribed spacer sequences. We reconstructed biogeographic history and diversification and identified lineages in the Neotropics and adjacent Patagonia.The ectomycorrhizal Russulaceae have a tropical African origin. The oldest lineages in tropical South America, most with African sister groups, date to the mid‐Eocene, possibly coinciding with a boreotropical migration corridor. There were several transatlantic dispersal events from Africa more recently. Andean and Central American lineages mostly have north‐temperate origins and are associated with North Andean uplift and the general north–south biotic interchange across the Panama isthmus, respectively. Patagonian lineages have Australasian affinities. Diversification rates in tropical South America and other tropical areas are lower than in temperate areas.Neotropical Russulaceae have multiple biogeographic origins since the mid‐Eocene involving dispersal and co‐migration. Discontinuous distributions of host plants may explain low diversification rates of tropical lowland ectomycorrhizal fungi. Deeply diverging neotropical fungal lineages need to be better documented. [ABSTRACT FROM AUTHOR]

Published

2022

3. Evolutionary history of Musaceae: ancient distribution and the rise of modern lineages.

Author

Burgos-Hernández, Mireya, Pozo, Carmen, and González, Dolores

Subjects

*MUSACEAE, *PLANT evolution, *SPECIES distribution, *FOSSIL plants, *BIOGEOGRAPHY

Abstract

We conducted a biogeographic analysis of Musaceae, emphasizing the importance of the fossil record to understand the early evolutionary history of the family. Plastid and nuclear DNA sequences were used to estimate divergence times with a Bayesian uncorrelated, lognormal relaxed-clock approach. Ancestral areas were reconstructed using the statistical dispersal-extinction-cladogenesis method under two models: one including and one excluding the fossil distribution. Molecular dating and integration of biogeographic reconstructions suggest a boreotropical origin for Musaceae across the landmasses of North America+Europe+Asia, with its diversification occurring through the Cretaceous / Palaeogene (K/Pg) (45.9–80.1 Mya; 95% HPD) and subsequent diversification occurring in southern South-east Asia. Comparison of the two models showed that biogeographic analysis based only on living species does not provide a complete reconstruction of the evolutionary history. We hypothesize that North America and Europe may be considered the grave of the more ancient lineages of Musaceae and tropical Asia as the cradle of more recent lineages of the family. The incorporation of fossil information in ancestral reconstructions improves the biogeographical history and expands hypotheses about the early evolution of Musaceae. [ABSTRACT FROM AUTHOR]

Published

2019

4. Out of Africa: Biogeography and diversification of the pantropical pond skater genus Limnogonus Stål, 1868 (Hemiptera: Gerridae).

Author

Ye, Zhen, Zhen, Yahui, Zhou, Yanyan, and Bu, Wenjun

Subjects

*GERRIDAE, *GEOGRAPHICAL distribution of insects, *INSECT diversity, *POND ecology, *INSECT migration

Abstract

Gondwanan vicariance, long-distance dispersal ( LDD), and boreotropical migration have been proposed as alternative hypotheses explaining the pantropical distribution pattern of organisms. In this study, the historical biogeography of the pond skater genus Limnogonus was reconstructed to evaluate the impact of biogeographical scenarios in shaping their modern transoceanic disjunction. We sampled almost 65% of recognized Limnogonus species. Four DNA fragments including 69 sequences were used to reconstruct a phylogram. Divergence time was estimated using a Bayesian relaxed clock method and three fossil calibrations. Diversification dynamics and ancestral area reconstruction were investigated by using maximum likelihood and Bayesian approaches. Our results showed the crown group of Limnogonus originated and diversified in Africa in the early Eocene (49 Ma, HPD: 38-60 Ma), subsequently expanding into other regions via dispersal. The colonization of the New World originated from the Oriental Region probably via the Bering Land Bridge in the late Eocene. Two split events between the Old World and New World were identified: one between Neotropics and Oriental region around the middle Oligocene (30 Ma, HPD: 22-38 Ma), and the other between Neotropics and Africa during the middle Miocene (14 Ma, HPD: 8-21 Ma). The evolutionary history of Limnogonus involved two biogeographical processes. Gondwanan vicariance was not supported in our analyses. The diversification of Limnogonus among Africa, Oriental, and Neotropical regions corresponded with the age of land bridge connection and dispersed as a member associated with the broad boreotropical belt before local cooling (34 Ma). The current transoceanic disjunctions in Limnogonus could be better explained by the disruption of 'mixed-mesophytic' forest belt; however, the direct transoceanic LDD between the Neotropics and Africa could not be ruled out. In addition, the ' LDD' model coupled with island hopping could be a reasonable explanation for the diversification of the Oriental and Australian regions during the Oligocene. [ABSTRACT FROM AUTHOR]

Published

2017

5. Out of Africa: Biogeography and diversification of the pantropical pond skater genus

Author

Zhen, Ye, Yahui, Zhen, Yanyan, Zhou, and Wenjun, Bu

Subjects

pantropical distribution, long‐distance dispersal, boreotropical migration, Limnogonus, Original Research, Gondwanan vicariance

Abstract

Gondwanan vicariance, long‐distance dispersal (LDD), and boreotropical migration have been proposed as alternative hypotheses explaining the pantropical distribution pattern of organisms. In this study, the historical biogeography of the pond skater genus Limnogonus was reconstructed to evaluate the impact of biogeographical scenarios in shaping their modern transoceanic disjunction. We sampled almost 65% of recognized Limnogonus species. Four DNA fragments including 69 sequences were used to reconstruct a phylogram. Divergence time was estimated using a Bayesian relaxed clock method and three fossil calibrations. Diversification dynamics and ancestral area reconstruction were investigated by using maximum likelihood and Bayesian approaches. Our results showed the crown group of Limnogonus originated and diversified in Africa in the early Eocene (49 Ma, HPD: 38–60 Ma), subsequently expanding into other regions via dispersal. The colonization of the New World originated from the Oriental Region probably via the Bering Land Bridge in the late Eocene. Two split events between the Old World and New World were identified: one between Neotropics and Oriental region around the middle Oligocene (30 Ma, HPD: 22–38 Ma), and the other between Neotropics and Africa during the middle Miocene (14 Ma, HPD: 8–21 Ma). The evolutionary history of Limnogonus involved two biogeographical processes. Gondwanan vicariance was not supported in our analyses. The diversification of Limnogonus among Africa, Oriental, and Neotropical regions corresponded with the age of land bridge connection and dispersed as a member associated with the broad boreotropical belt before local cooling (34 Ma). The current transoceanic disjunctions in Limnogonus could be better explained by the disruption of “mixed‐mesophytic” forest belt; however, the direct transoceanic LDD between the Neotropics and Africa could not be ruled out. In addition, the “LDD” model coupled with island hopping could be a reasonable explanation for the diversification of the Oriental and Australian regions during the Oligocene.

Published

2016

6. Diversification of myco-heterotrophic angiosperms: evidence from Burmanniaceae

Subjects

angiosperm evolution, West Gondwana, diversification, myco-heterotrophy, pantropical distribution, Burmanniaceae, reduced plastid genomes, evolutionary history, boreotropical migration, Eocene

Abstract

Background: Myco-heterotrophy evolved independently several times during angiosperm evolution. Although many species of myco-heterotrophic plants are highly endemic and longdistance dispersal seems unlikely, some genera are widely dispersed and have pantropical distributions, often with large disjunctions. Traditionally this has been interpreted as evidence for an old age of these taxa. However, due to their scarcity and highly reduced plastid genomes our understanding about the evolutionary histories of the angiosperm myco-heterotrophic groups is poor. Results: We provide a hypothesis for the diversification of the myco-heterotrophic family Burmanniaceae. Phylogenetic inference, combined with biogeographical analyses, molecular divergence time estimates, and diversification analyses suggest that Burmanniaceae originated in West Gondwana and started to diversify during the Late Cretaceous. Diversification and migration of the species-rich pantropical genera Burmannia and Gymnosiphon display congruent patterns. Diversification began during the Eocene, when global temperatures peaked and tropical forests occurred at low latitudes. Simultaneous migration from the New to the Old World in Burmannia and Gymnosiphon occurred via boreotropical migration routes. Subsequent Oligocene cooling and breakup of boreotropical flora ended New-Old World migration and caused a gradual decrease in diversification rate in Burmanniaceae. Conclusion: Our results indicate that extant diversity and pantropical distribution of mycoheterotrophic Burmanniaceae is the result of diversification and boreotropical migration during the Eocene when tropical rain forest expanded dramatically.

Published

2008

7. Diversification of myco-heterotrophic angiosperms: evidence from Burmanniaceae

Author

Merckx, V. (Vincent), Chatrou, L.W. (Lars), Lemaire, B., Sainge, M.N., Huysman, S., Smets, E.F. (Erik), Merckx, V. (Vincent), Chatrou, L.W. (Lars), Lemaire, B., Sainge, M.N., Huysman, S., and Smets, E.F. (Erik)

Abstract

Background: Myco-heterotrophy evolved independently several times during angiosperm evolution. Although many species of myco-heterotrophic plants are highly endemic and longdistance dispersal seems unlikely, some genera are widely dispersed and have pantropical distributions, often with large disjunctions. Traditionally this has been interpreted as evidence for an old age of these taxa. However, due to their scarcity and highly reduced plastid genomes our understanding about the evolutionary histories of the angiosperm myco-heterotrophic groups is poor. Results: We provide a hypothesis for the diversification of the myco-heterotrophic family Burmanniaceae. Phylogenetic inference, combined with biogeographical analyses, molecular divergence time estimates, and diversification analyses suggest that Burmanniaceae originated in West Gondwana and started to diversify during the Late Cretaceous. Diversification and migration of the species-rich pantropical genera Burmannia and Gymnosiphon display congruent patterns. Diversification began during the Eocene, when global temperatures peaked and tropical forests occurred at low latitudes. Simultaneous migration from the New to the Old World in Burmannia and Gymnosiphon occurred via boreotropical migration routes. Subsequent Oligocene cooling and breakup of boreotropical flora ended New-Old World migration and caused a gradual decrease in diversification rate in Burmanniaceae. Conclusion: Our results indicate that extant diversity and pantropical distribution of mycoheterotrophic Burmanniaceae is the result of diversification and boreotropical migration during the Eocene when tropical rain forest expanded dramatically.

Published

2008

8. Diversification of myco-heterotrophic angiosperms: Evidence from Burmanniaceae

Author

Benny Lemaire, Suzy Huysmans, Vincent S. F. T. Merckx, Moses N. Sainge, Lars W. Chatrou, Erik Smets, and Staff publications

Subjects

Time Factors, long-distance dispersal, sequence data, Burmanniaceae, SEQUENCE DATA, reduced plastid genomes, Eocene, ARBUSCULAR MYCORRHIZAL FUNGI, absolute rates, boreotropical migration, MOLECULAR PHYLOGENIES, Phylogeny, biology, historical biogeography, Ecology, FLOWERING PLANTS, CHLOROPLAST, RAIN-FOREST, Biosystematiek, GENOME, myco-heterotrophy, divergence times, HISTORICAL, Research Article, angiosperm evolution, rain-forest, diversification, Old World, Evolution, Genetic Speciation, Biogeography, Pantropical, molecular phylogenies, arbuscular mycorrhizal fungi, Diversification (marketing strategy), Boreotropical flora, DIVERGENCE TIMES, Magnoliopsida, Dioscoreales, DNA, Ribosomal Spacer, QH359-425, RNA, Ribosomal, 18S, ABSOLUTE RATES, Ecology, Evolution, Behavior and Systematics, West Gondwana, flowering plants, Biology and Life Sciences, biology.organism_classification, NAD, LONG-DISTANCE DISPERSAL, pantropical distribution, Biological dispersal, Biosystematics, evolutionary history, chloroplast genome, BIOGEOGRAPHY

Abstract

Background Myco-heterotrophy evolved independently several times during angiosperm evolution. Although many species of myco-heterotrophic plants are highly endemic and long-distance dispersal seems unlikely, some genera are widely dispersed and have pantropical distributions, often with large disjunctions. Traditionally this has been interpreted as evidence for an old age of these taxa. However, due to their scarcity and highly reduced plastid genomes our understanding about the evolutionary histories of the angiosperm myco-heterotrophic groups is poor. Results We provide a hypothesis for the diversification of the myco-heterotrophic family Burmanniaceae. Phylogenetic inference, combined with biogeographical analyses, molecular divergence time estimates, and diversification analyses suggest that Burmanniaceae originated in West Gondwana and started to diversify during the Late Cretaceous. Diversification and migration of the species-rich pantropical genera Burmannia and Gymnosiphon display congruent patterns. Diversification began during the Eocene, when global temperatures peaked and tropical forests occurred at low latitudes. Simultaneous migration from the New to the Old World in Burmannia and Gymnosiphon occurred via boreotropical migration routes. Subsequent Oligocene cooling and breakup of boreotropical flora ended New-Old World migration and caused a gradual decrease in diversification rate in Burmanniaceae. Conclusion Our results indicate that extant diversity and pantropical distribution of myco-heterotrophic Burmanniaceae is the result of diversification and boreotropical migration during the Eocene when tropical rain forest expanded dramatically.

Published

2008