Spatial genetic structure in the Madeiran endemic Dactylorhiza foliosa (Orchidaceae)
(2022) In Plant Systematics and Evolution 308(4).- Abstract
Oceanic islands have isolated biota, which typically include many endemic species. However, island endemics are vulnerable due to small population sizes, and they are often threatened by habitat destruction or by introduced pests and predators. Adequate conservation planning requires good information on genetic variability and population structure, also when seemingly viable species are considered. Here, I analysed the genetic structure in the terrestrial orchid Dactylorhiza foliosa, which is endemic to Madeira. This species is a characteristic component of evergreen laurel forests occupying the northern slopes of the island. Levels of diversity in both the plastid genome and in the nuclear genome were comparable to levels of diversity... (More)
Oceanic islands have isolated biota, which typically include many endemic species. However, island endemics are vulnerable due to small population sizes, and they are often threatened by habitat destruction or by introduced pests and predators. Adequate conservation planning requires good information on genetic variability and population structure, also when seemingly viable species are considered. Here, I analysed the genetic structure in the terrestrial orchid Dactylorhiza foliosa, which is endemic to Madeira. This species is a characteristic component of evergreen laurel forests occupying the northern slopes of the island. Levels of diversity in both the plastid genome and in the nuclear genome were comparable to levels of diversity found in congeners growing in continental regions. Within populations, plants separated by distances up to 256 m shared plastid haplotypes significantly more often than plants at random, but when nuclear markers were considered, only plants growing closer than eight metres were significantly more closely related. Analysis of plastid marker variation revealed that gene dispersal by seeds is not sufficiently large to counterbalance the accumulation of mutations that build up divergence between the most distant populations. However, differentiation in the nuclear genome was considerably smaller, suggesting that gene dispersal by pollen is much more efficient than gene dispersal by seeds in D. foliosa. The overall pollen to seed dispersal ratio, mp/ms, was 7.30. Considering genetic parameters, conditions for long-term persistence of D. foliosa on Madeira seem to be good.
(Less)
- author
- Hedren, Mikael LU
- organization
- publishing date
- 2022
- type
- Contribution to journal
- publication status
- published
- subject
- keywords
- Dactylorhiza foliosa, Kinship, Madeira, Pollen dispersal, Seed dispersal, Spatial genetic structure
- in
- Plant Systematics and Evolution
- volume
- 308
- issue
- 4
- article number
- 30
- publisher
- Springer
- external identifiers
-
- scopus:85135235393
- ISSN
- 0378-2697
- DOI
- 10.1007/s00606-022-01822-2
- language
- English
- LU publication?
- yes
- id
- 80280875-2d57-498d-8352-05c05295140c
- date added to LUP
- 2022-09-06 13:22:30
- date last changed
- 2022-09-06 13:22:30
@article{80280875-2d57-498d-8352-05c05295140c,
abstract = {{<p>Oceanic islands have isolated biota, which typically include many endemic species. However, island endemics are vulnerable due to small population sizes, and they are often threatened by habitat destruction or by introduced pests and predators. Adequate conservation planning requires good information on genetic variability and population structure, also when seemingly viable species are considered. Here, I analysed the genetic structure in the terrestrial orchid Dactylorhiza foliosa, which is endemic to Madeira. This species is a characteristic component of evergreen laurel forests occupying the northern slopes of the island. Levels of diversity in both the plastid genome and in the nuclear genome were comparable to levels of diversity found in congeners growing in continental regions. Within populations, plants separated by distances up to 256 m shared plastid haplotypes significantly more often than plants at random, but when nuclear markers were considered, only plants growing closer than eight metres were significantly more closely related. Analysis of plastid marker variation revealed that gene dispersal by seeds is not sufficiently large to counterbalance the accumulation of mutations that build up divergence between the most distant populations. However, differentiation in the nuclear genome was considerably smaller, suggesting that gene dispersal by pollen is much more efficient than gene dispersal by seeds in D. foliosa. The overall pollen to seed dispersal ratio, mp/ms, was 7.30. Considering genetic parameters, conditions for long-term persistence of D. foliosa on Madeira seem to be good.</p>}},
author = {{Hedren, Mikael}},
issn = {{0378-2697}},
keywords = {{Dactylorhiza foliosa; Kinship; Madeira; Pollen dispersal; Seed dispersal; Spatial genetic structure}},
language = {{eng}},
number = {{4}},
publisher = {{Springer}},
series = {{Plant Systematics and Evolution}},
title = {{Spatial genetic structure in the Madeiran endemic Dactylorhiza foliosa (Orchidaceae)}},
url = {{http://dx.doi.org/10.1007/s00606-022-01822-2}},
doi = {{10.1007/s00606-022-01822-2}},
volume = {{308}},
year = {{2022}},
}