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RESEARCH ARTICLE (Open Access)
Contents Vol 29(2)

Cross-pollination and pollen storage to assist conservation of Metrosideros bartlettii (Myrtaceae), a critically endangered tree from Aotearoa New Zealand

Karin van der Walt https://orcid.org/0000-0002-4957-7017 A B * , Jennifer Alderton-Moss https://orcid.org/0000-0003-4859-3506 C and Carlos A. Lehnebach https://orcid.org/0000-0001-7368-013X D
+ Author Affiliations
- Author Affiliations

A Ōtari Native Botanic Garden and Wilton’s Bush Reserve, Wellington, New Zealand.

B Massey University, Palmerston North, New Zealand.

C Victoria University of Wellington, Wellington, New Zealand.

D Museum of New Zealand Te Papa Tongarewa, Wellington, New Zealand.

* Correspondence to: karinvanderwalt@outlook.com

Handling Editor: Mike van Keulen

Pacific Conservation Biology 29(2) 141-152 https://doi.org/10.1071/PC21054
Submitted: 13 August 2021  Accepted: 2 February 2022   Published: 1 March 2022

© 2023 The Author(s) (or their employer(s)). Published by CSIRO Publishing. This is an open access article distributed under the Creative Commons Attribution-NonCommercial-NoDerivatives 4.0 International License (CC BY-NC-ND)

Abstract

Context: Metrosideros bartlettii is one of the most threatened trees in New Zealand and with less than 14 individuals spread across three populations, the species is at high risk of extinction. Despite reproductive failure being identified as one of the factors contributing to population decline, little is known about its pollination biology.

Aim: The current study aimed to gain knowledge of the reproductive biology of M. bartlettii by using trees in cultivation of which origin is known.

Methods: We tested the effect of self-pollination, cross-pollination and hybridisation treatments on reproductive output. In addition, the viability of fresh pollen was determined for each tree and the impact of desiccation and storage temperature (5°C, −18°C and −196°C) on pollen viability assessed.

Key results: Metrosideros bartlettii was found to be highly self-incompatible with seed formed via autonomous self-pollination having low viability. Hybridisation with Metrosideros excelsa, another native species commonly found in cultivation, produced viable seeds, but seedlings failed to survive. Pollen viability differed significantly among trees, and pollen stored at −18°C and −196°C retained viability after 6 months.

Conclusion: Metrosideros bartlettii is self-incompatible and cross-pollination is required to increase seed production and supplement wild populations.

Implications: Trees in cultivation provide a valuable tool for the conservation of M. bartlettii. However, cross-pollination is essential to prevent hybridisation and ensure genetically robust seed. Long-term storage of pollen at the temperatures determined here will help to overcome challenges in cross-pollination of trees that are spatially and geographically isolated.

Keywords: botanic garden, breeding system, cryopreservation, extinction, hybridisation, integrated conservation, liquid nitrogen, long-term storage, myrtle rust, threatened.


References

Abeli, T, Dalrymple, S, Godefroid, S, Mondoni, A, Müller, JV, Rossi, G, and Orsenigo, S (2020). Ex situ collections and their potential for the restoration of extinct plants. Conservation Biology 34, 303–313.
Ex situ collections and their potential for the restoration of extinct plants.Crossref | GoogleScholarGoogle Scholar | 31329316PubMed |

Asmussen-Lange, CB, Maunder, M, and Fay, MF (2011). Conservation genetics of the critically endangered Round Island bottle palm, Hyophorbe lagenicaulis (Arecaceae): can cultivated stocks supplement a residual wild population? Botanical Journal of the Linnean Society 167, 301–310.
Conservation genetics of the critically endangered Round Island bottle palm, Hyophorbe lagenicaulis (Arecaceae): can cultivated stocks supplement a residual wild population?Crossref | GoogleScholarGoogle Scholar |

Beardsell, DV, Knox, RB, and Williams, EG (1993). Breeding system and reproductive success of Thryptomene calycina (Myrtaceae). Australian Journal of Botany 41, 333–353.
Breeding system and reproductive success of Thryptomene calycina (Myrtaceae).Crossref | GoogleScholarGoogle Scholar |

Beyhan, N, and Serdar, U (2008). Assessment of pollen viability and germinability in some European chestnut genotypes (Castanea sativa L.). Horticultural Science 35, 171–178.
Assessment of pollen viability and germinability in some European chestnut genotypes (Castanea sativa L.).Crossref | GoogleScholarGoogle Scholar |

Brewbaker, JL, and Kwack, BH (1963). The essential role of calcium ion in pollen germination and pollen tube growth. American Journal of Botany 50, 859–865.
The essential role of calcium ion in pollen germination and pollen tube growth.Crossref | GoogleScholarGoogle Scholar |

Carpenter, FL (1976). Plant-pollinator interactions in Hawaii: pollination energetics of Metrosideros collina (Myrtaceae). Ecology 57, 1125–1144.
Plant-pollinator interactions in Hawaii: pollination energetics of Metrosideros collina (Myrtaceae).Crossref | GoogleScholarGoogle Scholar |

Chen, Y, Chen, G, Yang, J, and Sun, W (2016). Reproductive biology of Magnolia sinica (Magnoliaecea), a threatened species with extremely small populations in Yunnan, China. Plant Diversity 38, 253–258.
Reproductive biology of Magnolia sinica (Magnoliaecea), a threatened species with extremely small populations in Yunnan, China.Crossref | GoogleScholarGoogle Scholar | 30159474PubMed |

Christe, C, Kozlowski, G, Frey, D, Fazan, L, Bétrisey, S, Pirintsos, S, Gratzfeld, J, and Naciri, Y (2014). Do living ex situ collections capture the genetic variation of wild populations? A molecular analysis of two relict tree species, Zelkova abelica and Zelkova carpinifolia. Biodiversity and Conservation 23, 2945–2959.
Do living ex situ collections capture the genetic variation of wild populations? A molecular analysis of two relict tree species, Zelkova abelica and Zelkova carpinifolia.Crossref | GoogleScholarGoogle Scholar |

Cibrian-Jaramillo, A, Hird, A, Oleas, N, Ma, H, Meerow, AW, Francisco-Ortega, J, and Griffith, MP (2013). What is the conservation value of a plant in a botanic garden? Using indicators to improve management of ex situ collections. The Botanical Review 79, 559–577.
What is the conservation value of a plant in a botanic garden? Using indicators to improve management of ex situ collections.Crossref | GoogleScholarGoogle Scholar |

Cochrane A (2004) Western Australia’s ex situ program for threatened species: a model integrated strategy for conservation. In ‘Ex situ plant conservation: Supporting Species Survival in the Wild’. (Eds EO Guerrant, K Havens, M Maunder) pp. 40–66. (Island Press: Washington, DC)

Cruzatty, LCG, Droppelmann, F, and Izaguirre-Mayoral, ML (2020). New protocol for storage of viable pollen of Lapageria rosea (Philesiaceae), an endangered plant species endemic to temperate forests of Chile. Plant Species Biology 35, 332–337.
New protocol for storage of viable pollen of Lapageria rosea (Philesiaceae), an endangered plant species endemic to temperate forests of Chile.Crossref | GoogleScholarGoogle Scholar |

Dawson, JW (1985). Metrosideros bartlettii (Myrtaceae) a new species from North Cape, New Zealand. New Zealand Journal of Botany 23, 607–610.
Metrosideros bartlettii (Myrtaceae) a new species from North Cape, New Zealand.Crossref | GoogleScholarGoogle Scholar |

de Lange P (2014) ‘Metrosideros bartlettii. The IUCN Red List of Threatened Species 2014. Vol. 2020.’ (International Union for the Conservation of Nature)

de Lange PJ, Rolfe JR, Barkla JW, Courtney SP, Champion PD, Perrie LR, Beadel SM, Ford KA, Breitwieser I, Schonberger I, Hindmarsh-Walls R, Heenan PB, Landley K (2018) ‘Conservation status of New Zealand indigenous vascular plants, 2017.’ (Department of Conservation: Wellington)

Del Vecchio, S, Pierce, S, Fantinato, E, and Buffa, G (2019). Increasing the germination percentage of a declining native orchid (Himantoglossum adriaticum) by pollen transfer and outbreeding between populations. Plant Biology 21, 935–941.
Increasing the germination percentage of a declining native orchid (Himantoglossum adriaticum) by pollen transfer and outbreeding between populations.Crossref | GoogleScholarGoogle Scholar | 30907053PubMed |

DeMauro, MM (1993). Relationship of breeding system to rarity in the lakeside daisy (Hymenoxys acaulis var. glabra). Conservation Biology 7, 542–550.
Relationship of breeding system to rarity in the lakeside daisy (Hymenoxys acaulis var. glabra).Crossref | GoogleScholarGoogle Scholar |

Drummond, RSM, Keeling, DJ, Richardson, TE, Gardner, RC, and Wright, SD (2000). Genetic analysis and conservation of 31 surviving individuals of a rare New Zealand tree, Metrosideros bartlettii (Myrtaceae). Molecular Ecology 9, 1149–1157.
Genetic analysis and conservation of 31 surviving individuals of a rare New Zealand tree, Metrosideros bartlettii (Myrtaceae).Crossref | GoogleScholarGoogle Scholar |

Ensslin, A, and Godefroid, S (2020). Ex situ cultivation impacts on plant traits and drought stress response in a multi-species experiment. Biological Conservation 248, 108630.
Ex situ cultivation impacts on plant traits and drought stress response in a multi-species experiment.Crossref | GoogleScholarGoogle Scholar |

Gardner, RC, De Lange, PJ, Keeling, DJ, Bowala, T, Brown, HA, and Wright, SD (2004). A late Quaternary phylogeography for Metrosideros (Myrtaceae) in New Zealand inferred from chloroplast DNA haplotypes. Biological Journal of the Linnean Society 83, 399–412.
A late Quaternary phylogeography for Metrosideros (Myrtaceae) in New Zealand inferred from chloroplast DNA haplotypes.Crossref | GoogleScholarGoogle Scholar |

Griffin, AR (1980). Floral phenology of a stand of mountain ash (Eucalyptus regnans F. Muell.) In Gippsland, Victoria. Australian Journal of Botany 28, 393–404.
Floral phenology of a stand of mountain ash (Eucalyptus regnans F. Muell.) In Gippsland, Victoria.Crossref | GoogleScholarGoogle Scholar |

GTA (2021) ‘Global tree assessment.’ (Botanic Gardens Conservation International)

Hanna, C, Foote, D, and Kremen, C (2013). Invasive species management restores a plant–pollinator mutualism in Hawaii. Journal of Applied Ecology 50, 147–155.
Invasive species management restores a plant–pollinator mutualism in Hawaii.Crossref | GoogleScholarGoogle Scholar |

Hitchcock, A, Williams, J, and Cowell, C (2020). Lessons learned as Erica turgida is returned. Journal for Nature Conservation 56, 125858.
Lessons learned as Erica turgida is returned.Crossref | GoogleScholarGoogle Scholar |

Horiuchi, Y, Kamijo, T, and Tanaka, N (2020). Biological and ecological constraints to the reintroduction of Eriocaulon heleocharioides (Eriocaulaceae): a species extinct in the wild. Journal for Nature Conservation 56, 125866.
Biological and ecological constraints to the reintroduction of Eriocaulon heleocharioides (Eriocaulaceae): a species extinct in the wild.Crossref | GoogleScholarGoogle Scholar |

Hyvärinen, M-T (2020). Rubus humulifolius rescued by narrowest possible margin, conserved ex situ, and reintroduced in the wild. Journal for Nature Conservation 55, 125819.
Rubus humulifolius rescued by narrowest possible margin, conserved ex situ, and reintroduced in the wild.Crossref | GoogleScholarGoogle Scholar |

Iglesias-Andreu, LG, Octavio-Aguilar, P, Vovides, AP, Meerow, AW, de Cáceres-González, FN, and Galván-Hernández, DM (2017). Extinction risk of Zamia inermis (Zamiaceae): a genetic approach for the conservation of its single natural population. International Journal of Plant Sciences 178, 715–723.
Extinction risk of Zamia inermis (Zamiaceae): a genetic approach for the conservation of its single natural population.Crossref | GoogleScholarGoogle Scholar |

Kaneko, S, Isagi, Y, and Nobushima, F (2008). Genetic differentiation among populations of an oceanic island: the case of Metrosideros boninensis, an endangered endemic tree species in the Bonin Islands. Plant Species Biology 23, 119–128.
Genetic differentiation among populations of an oceanic island: the case of Metrosideros boninensis, an endangered endemic tree species in the Bonin Islands.Crossref | GoogleScholarGoogle Scholar |

Koelling, VA, Hamrick, JL, and Mauricio, R (2011). Genetic diversity and structure in two species of Leavenworthia with self-incompatible and self-compatible populations. Heredity 106, 310–318.
Genetic diversity and structure in two species of Leavenworthia with self-incompatible and self-compatible populations.Crossref | GoogleScholarGoogle Scholar | 20485327PubMed |

Kormuťák, A, Galgóci, M, Boleček, P, and Gőmőry, D (2019). Effect of storage on pollen viability in Pinus sylvestris L., Pinus mugo turra and their hybrid swarms. Dendrobiology 82, 43–51.
Effect of storage on pollen viability in Pinus sylvestris L., Pinus mugo turra and their hybrid swarms.Crossref | GoogleScholarGoogle Scholar |

Lozada-Gobilard, S, Pánková, H, Zhu, J, Stojanova, B, and Münzbergová, Z (2020). Potential risk of interspecific hybridization in ex situ collections. Journal for Nature Conservation 58, 125912.
Potential risk of interspecific hybridization in ex situ collections.Crossref | GoogleScholarGoogle Scholar |

Melesse K (2017) Molecular phylogeny of the genus Metrosideros and population genetics of some New Zealand species within the genus. Doctor of Philosophy in Biology, University of Canterbury.

Montagna, T, Silva, JZ, Pikart, TG, and Reis, MS (2018). Reproductive ecology of Ocotea catharinensis, an endangered tree species. Plant Biology 20, 926–935.
Reproductive ecology of Ocotea catharinensis, an endangered tree species.Crossref | GoogleScholarGoogle Scholar | 29786924PubMed |

Nadarajan, J, Benson, EE, Xaba, P, Harding, K, Lindstrom, A, Donaldson, J, Seal, CE, Kamoga, D, Agoo, EMG, Li, N, King, E, and Pritchard, HW (2018). Comparative biology of cycad pollen, seed and tissue - a plant conservation perspective. The Botanical Review 84, 295–314.
Comparative biology of cycad pollen, seed and tissue - a plant conservation perspective.Crossref | GoogleScholarGoogle Scholar |

Nadarajan, J, van der Walt, K, Lehnebach, CA, Saeiahagh, H, and Pathirana, R (2021). Integrated ex situ conservation strategies for endangered New Zealand Myrtaceae species. New Zealand Journal of Botany 59, 72–89.
Integrated ex situ conservation strategies for endangered New Zealand Myrtaceae species.Crossref | GoogleScholarGoogle Scholar |

Neal, RP, and Anderson, GJ (2004). Does the ‘old bag’ make a good ‘wind bag’?: comparison of four fabrics commonly used as exclusion bags in studies of pollination and reproductive biology. Annals of Botany 93, 603–607.
Does the ‘old bag’ make a good ‘wind bag’?: comparison of four fabrics commonly used as exclusion bags in studies of pollination and reproductive biology.Crossref | GoogleScholarGoogle Scholar |

Nikkanen, T, Aronen, T, Häggman, H, and Venäläinen, M (2000). Variation in pollen viability among Picea abies genotypes – potential for unequal paternal success. Theoretical and Applied Genetics 101, 511–518.
Variation in pollen viability among Picea abies genotypes – potential for unequal paternal success.Crossref | GoogleScholarGoogle Scholar |

Page, T, Moore, GM, Will, J, and Halloran, GM (2006). Pollen viability in Kunzea pomifera (Myrtaceae) as influenced by sucrose concentration and storage. Australian Journal of Botany 54, 553–558.
Pollen viability in Kunzea pomifera (Myrtaceae) as influenced by sucrose concentration and storage.Crossref | GoogleScholarGoogle Scholar |

Schmidt-Adam, G, Gould, KS, and Murray, BG (1999). Floral biology and breeding system of pohutukawa (Metrosideros excelsa, Myrtaceae). New Zealand Journal of Botany 37, 687–702.
Floral biology and breeding system of pohutukawa (Metrosideros excelsa, Myrtaceae).Crossref | GoogleScholarGoogle Scholar |

Schmidt-Adam, G, Murray, BG, and Young, AG (2009). The relative importance of birds and bees in the pollination of Metrosideros excelsa (Myrtaceae). Austral Ecology 34, 490–498.
The relative importance of birds and bees in the pollination of Metrosideros excelsa (Myrtaceae).Crossref | GoogleScholarGoogle Scholar |

Sharrock S (2020) Plant Conservation Report 2020. A review of progress in implementation of the Global Strategy for Plant Conservation 2011-2020. Secretariat of the Convention on Biological Diversity, Montreal, Canada and Botanic Gardens Conservation International, Richmond, UK.

Sudarmono, LD, Hartini, S, and Wawangningrum, H (2016). Hand-pollination of the giant corpse flower in the Bogor Botanic Gardens. International Journal of Conservation Science 7, 1153–1160.

Tani, N, Yoshimaru, H, Kawahara, T, Hoshi, Y, Nobushima, F, and Yasui, T (2006). Determination of the genetic structure of remnant Morus boninensis Koidz. trees to establish a conservation program on the Bonin Islands, Japan. BMC Ecology 6, 14.
Determination of the genetic structure of remnant Morus boninensis Koidz. trees to establish a conservation program on the Bonin Islands, Japan.Crossref | GoogleScholarGoogle Scholar | 17034624PubMed |

Towill LE (2004) Pollen storage as a conservation tool. In ‘Ex situ plant conservation: supporting species survival in the wild’. (Eds E Guerrant, K Havens, M Maunder) pp. 180–188. (Island Press: Washington, USA)

Volis, S (2017). Conservation utility of botanic garden living collections: setting a strategy and appropriate methodology. Plant Diversity 39, 365–372.
Conservation utility of botanic garden living collections: setting a strategy and appropriate methodology.Crossref | GoogleScholarGoogle Scholar | 30159530PubMed |

Wheeler, MA, and McComb, JA (2006). In vitro pollen viability and pollen storage in Eucalyptus marginata (Myrtaceae). Australian Forestry 69, 32–37.
In vitro pollen viability and pollen storage in Eucalyptus marginata (Myrtaceae).Crossref | GoogleScholarGoogle Scholar |