Myrtle rust is a disease that has been infecting New Zealand’s iconic native myrtles since it arrived in the country in 2017. Researchers have now identified geographical areas (known as ‘refugia’ by ecologists) where species from the plant family Myrtaceae may be able to seek refuge from the fungal pathogen (Austropuccinia psidii) that causes the disease.
“Refugia are often thought of in terms of climate change,” says Dr James McCarthy, an ecosystems and conservation researcher at Manaaki Whenua – Landcare Research. “Refugia are areas where a population of plants or animals might still survive under extreme climate pressures.”
While refugia are not often considered in the context of invasive diseases, the same principles apply. A species may persist if it lives in an area that does not support the disease.
“Where these refugia occur will be different for each species,” says McCarthy, “since each species requires slightly different conditions to survive and thrive.”
McCarthy and colleagues used the New Zealand National Vegetation Survey Databank to determine where myrtles occur and what conditions support which myrtle species. They then used soil, climate and landscape variables to model the full habitat range of each species in New Zealand. Of the 27 Myrtaceae trees, shrubs and vines native to New Zealand, the team was able to gather enough data to establish comprehensive species range predictions for 13 of the species.
Then, they compared how the habitat range of each species overlaps with the likely range of myrtle rust in New Zealand under two scenarios – a ‘core distribution’ scenario representing places where the environment is most suitable for infection and a ‘more severe’ scenario representing the entire known distribution of myrtle rust. Doing this allowed them to identify areas for each myrtle species that could serve as refugia from disease.
“Some species have adequate refugia,” says McCarthy. “Species like southern rātā (Metrosideros umbellata) are almost entirely outside of the predicted extent of myrtle rust.”
For other species, there are few existing refugia.
“This is the case with species like ramarama (Lophomyrtus bullata), which has only 15 km2 of refugia, and swamp maire (Syzygium maire), which has only 1.4 km2 of refugia.”
These refugia could be supplemented with ‘restorable refugia’ – areas that are currently deforested but could become refugia through habitat restoration efforts. McCarthy and colleagues have identified several restorable refugia for different species. However, there are still some species that have neither refugia nor restorable refugia, as their entire probable range overlaps with the predicted range of the disease. For these species, alternative conservation measures may be required.
McCarthy and colleagues have recently published their findings in the Journal of Applied Ecology. Their results will be helpful in informing conservation efforts, including maintaining currently protected refugia, restoring potential refugia, and coming up with alternative conservation methods for species with few refugia options.
While this study tests host and disease habitat range overlap under two disease range scenarios, it does not evaluate these conditions under different climate change scenarios.
“We now need to evaluate how stable these refugia and restorable refugia are in the face of climate change,” says McCarthy.
The question of range and climate is twofold – climate change could alter the natural range of the plants, and it could also shift the range of the disease itself.
“The disease will move much more easily and readily than the plants because it’s caused by a wind-dispersed fungus,” says McCarthy. “While some plants are more easily dispersed than others, they’ll still need to get to a place, germinate, and establish a self-sustaining population in order to fully move into a new area.”
Not only will plant species’ ranges expand more slowly, they will also have to do so under duress from myrtle rust.
“Because myrtle rust attacks young, newly forming plant tissue, survival past that initial germination and young plant stage can be particularly tricky,” says McCarthy.
By modelling the future impacts of climate change on the ranges of each species and on the range of myrtle rust, conservation efforts can be fine-tuned to stay one step ahead of the disease.
Funding for this research was provided by the Ministry for Primary Industries (contract 18607), the Ministry of Business, Innovation and Employment’s Strategic Science Investment Fund, and the Ministry of Business, Innovation and Employment’s Endeavour programme Beyond Myrtle Rust
The journal article can be accessed here: