The evolutionary history and phylogeographic pattern of Hippuris vulgaris: hybridization and long-distance dispersal from China

Several plant traits are known to evolve in predictable ways on islands. For example, herbaceous species often evolve to become woody and species frequently evolve larger leaves, regardless of growth form. However, our understanding of how seed sizes might evolve on islands lags far behind other plant traits. Here, we conduct the first test for macroevolutionary patterns of seed size on islands. We tested for differences in seed size between 40 island–mainland taxonomic pairings from four island groups surrounding New Zealand. Seed size data were collected in the field and then augmented by published seed descriptions to produce a more comprehensive dataset. Seed sizes of insular plants were consistently larger than mainland relatives, even after accounting for differences in growth form, dispersal mode and evolutionary history. Selection may favour seed size increases on islands to reduce dispersibility, as long-distance dispersal may result in propagule mortality at sea. Alternatively, larger seeds tend to generate larger seedlings, which are more likely to establish and outcompete neighbours. Our results indicate there is a general tendency for the evolution of large seeds on islands, but the mechanisms responsible for this evolutionary pathway have yet to be fully resolved.

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The Evolutionary History of New Zealand Deschampsia Is Marked by Long-Distance Dispersal, Endemism, and Hybridization

Biology ◽

10.3390/biology10101001 ◽

2021 ◽

Vol 10 (10) ◽

pp. 1001

Author(s):

Zhiqing Xue ◽

Josef Greimler ◽

Ovidiu Paun ◽

Kerry Ford ◽

Michael H. J. Barfuss ◽

...

Keyword(s):

New Zealand ◽

Evolutionary History ◽

Dna Analysis ◽

Common Ancestor ◽

Plastid Dna ◽

Last Common Ancestor ◽

Long Distance Dispersal ◽

Long Distance ◽

Test Species ◽

History Of

The contrasting evolutionary histories of endemic versus related cosmopolitan species provide avenues to understand the spatial drivers and limitations of biodiversity. Here, we investigated the evolutionary history of three New Zealand endemic Deschampsia species, and how they are related to cosmopolitan D. cespitosa. We used RADseq to test species delimitations, infer a dated species tree, and investigate gene flow patterns between the New Zealand endemics and the D. cespitosa populations of New Zealand, Australia and Korea. Whole plastid DNA analysis was performed on a larger worldwide sampling. Morphometrics of selected characters were applied to New Zealand sampling. Our RADseq review of over 55 Mbp showed the endemics as genetically well-defined from each other. Their last common ancestor with D. cespitosa lived during the last ten MY. The New Zealand D. cespitosa appears in a clade with Australian and Korean samples. Whole plastid DNA analysis revealed the endemics as members of a southern hemisphere clade, excluding the extant D. cespitosa of New Zealand. Both data provided strong evidence for hybridization between D. cespitosa and D. chapmanii. Our findings provide evidence for at least two migration events of the genus Deschampsia to New Zealand and hybridization between D. cespitosa and endemic taxa.

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Evolutionary significance of long-distance dispersal and hybridisation in the New Zealand endemic genus Hoheria (Malvaceae)

Australian Systematic Botany ◽

10.1071/sb09017 ◽

2010 ◽

Vol 23 (2) ◽

pp. 112 ◽

Cited By ~ 5

Author(s):

Steven J. Wagstaff ◽

Brian P. J. Molloy ◽

Jennifer A. Tate

Keyword(s):

New Zealand ◽

Urban Areas ◽

Evolutionary History ◽

Evolutionary Significance ◽

Long Distance Dispersal ◽

Long Distance ◽

Endemic Genus ◽

Its Phylogeny ◽

Extant Species ◽

History Of

Parsimony and SplitsTree analyses of ITS and 5′ trnK/matK sequence data were used to assess the extent of hybridisation and its evolutionary significance in the New Zealand endemic genus Hoheria A.Cunn. The seven species of Hoheria form a monophyletic group along with the New Zealand endemic genus Plagianthus J.R.Forst. & G.Forst. and the Australian endemics Asterotrichion Klotzsch. and Gynatrix Alef. This strongly supported clade is sister to a clade of Australian species of Lawrencia Hook. The inferred evolutionary history of Hoheria suggests that the extant species are derived from a common ancestor that arrived in New Zealand by long-distance dispersal. There was little divergence among the species of Hoheria in either their ITS or trnK/matK sequences. Two known Hoheria hybrids exhibited overlapping heteromorphic nucleotides at virtually all of the variable positions. Approximately 40% of the other Hoheria accessions in our study retain similar heteromorphic sites. These polymorphisms were shared among the deepest branches in the ITS phylogeny, which potentially suggests that hybridisation has occurred throughout the evolutionary history of Hoheria. The phylogenetic structure of the ITS phylogeny completely collapsed in the strict consensus tree, and there was significant conflict between the biparentally inherited ITS phylogeny and the maternally inherited trnK/matK phylogeny. However, the removal of known and suspected hybrids resulted in parsimony trees that were more resolved. SplitsTree analyses revealed incompatible signals in the data, but recovered well supported groups that diverged from a central boxy network. Although the species of Hoheria are isolated by their ecological preferences or geographical distributions, interspecific hybrids are common in urban areas where the species are often planted.

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