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Embargoed until 15 January 2025
MEDIA RELEASE: Ancient poo proves moa were key dispersers of colourful truffle-like fungi in New Zealand beech forests
In a curious case of finding something unexpected whilst looking for something else, scientists at Manaaki Whenua - Landcare Research’s palaeoecology lab have discovered that ancient moa were fond of fungi, particularly colourful truffle-like species that mimic fruit. This discovery, in turn, has helped to advance our understanding of present-day and likely future native forest resilience.
The story begins with two ancient bird coprolites – fossilised poo – collected several years ago from dry caves in two remote locations in New Zealand’s South Island beech forests. Coprolites can be carefully picked apart and analysed for DNA and microscopic remains to find out what species of birds deposited them and what they ate. Studying ancient bird coprolites helps to reconstruct what ecological roles extinct birds used to play in shaping New Zealand’s ecosystems before they died out.
Initially included in a study of kakapo droppings, the ancient poos turned out to be from the upland moa. Weighing less than 50 kg, this species was one of the smaller members of at least nine species of moa (the larger members reaching over 3m tall and 250 kg in weight). This guild of birds were flightless, herbivorous, ground-dwelling birds that all went extinct around 600 years ago.
Rather than put the coprolites back in the specimen box, the scientists took the opportunity to fully analyse them, with some surprising results.
Truffle-like fungi have fruiting bodies that never fully open and lack a way to eject their spores. Whereas other fungi do this by wind, the truffle-like fungi rely on animals to consume them and disperse their spores. Overseas such fungi – including “true” truffles – are generally drab, strong-smelling and highly appealing to mammals. By contrast, those in New Zealand are often brightly coloured and look very much like fallen berries on the forest floor.
It is likely that these fungi depended on fruit-eating birds for their dispersal, yet there is little evidence that any present-day native birds eat them. Ecologists have long debated that their original dispersers must be extinct birds, but this has never been demonstrated before now.
Previous work on coprolites has already shown that the extinct moa ate brightly coloured fruits and other plant matter, but the new analyses revealed that moa were indeed consuming these colourful truffle-like fungal species. This finding adds weight to the idea that these fungi had evolved specifically to be attractive to fruit-eating birds. Moa would have been good at dispersing the fungal spores, too – comparison with their distant cousin the ostrich, which retains food for some 36 hours after eating it, shows that moa could have carried spores in their gut over long distances.
But given the large birds are extinct, what if anything is now driving the dispersion on which these fungi once depended? What will eventually happen to these evolutionary anachronisms – species that rely on other species to establish and thrive that are no longer there? Further, how is this loss likely to affect current native forest resilience and its capacity to regenerate and expand?
The scientists say it’s unlikely that remaining species of herbivorous ground-dwelling birds, such as weka, can make up for the loss of moa in dispersing these fungi. In turn, this may be having knock-on effects on overall forest resilience to this day. Forest species such as New Zealand beeches have evolved symbiotic relationships with native fungi, such as the ones detected in the moa poos, to benefit their regeneration and resilience, so fewer or less widespread native fungi in the mix may decrease forest resilience overall.
Are non-native mammals such as possum or deer able to take the place of the moa? No, say the scientists: scent-driven mammals are not so interested in non-odorous, fruity fungi that evolved to catch a ground-dwelling bird’s eye, and native fungal spores also don’t survive so well in the mammal gut. Instead, non-native mammals tend to disperse non-native fungi, which in turn promote symbiotic relationships with non-native forest species, at the expense of native ones, with possible flow-on effects on native forest resilience.
More study is needed as this gradual turnover of fungal communities continues. What is clear, the scientists conclude, is that the long-term consequences of moa loss on the overall health of native ecosystems are still very much unfolding, some 600 years down the track.
Expert Reaction
These comments have been collated by the Science Media Centre to provide a variety of expert perspectives on this issue. Feel free to use these quotes in your stories. Views expressed are the personal opinions of the experts named. They do not represent the views of the SMC or any other organisation unless specifically stated.
Dr Nic Rawlence, Director of the Otago Palaeogenetics Laboratory, and Associate Professor in Ancient DNA, Department of Zoology, University of Otago
In Aotearoa New Zealand, there is a special type of (ectomycorrhizal) fungus that forms a symbiotic relationship with native trees. This relationship helps forest resilience and spread, and no doubt played a role in reshaping the landscape after the last Ice Age.
"For some of these fungi, their only way of dispersal is food for animals who eat the truffle-like fruiting body (the mushroom bit) and spread fungal spores to new areas in their poo. Overseas, truffle-like fungi are smelly but dull in colour to attract mammals that forage by smell. In Aotearoa, we lack native ground-dwelling mammals and are a land ruled by birds, which forage by sight. Some of Aotearoa truffle-like fungi are brightly coloured (purple, blue, and pink) and its thought evolved to attract our birds.
"But how do you prove this when >40% of Aotearoa ground-dwelling birds are extinct, and very few of our native living birds eat fungi? Fossilised poo (coprolites), which look like half-melted Cadbury Picnic bars, are a Rosetta stone for reconstructing extinct bird diet.
"Previous preliminary ancient DNA data generated by Alex Boast’s team showed that some moa and kakapo may have eaten and spread colourful truffle-like fungi, but they lacked the taxonomic (the science of naming biodiversity) resolution or the spores to pin the last meal on the mushroom.
"Taking these criticisms on board in their impressive new study, Boast’s team have found two upland moa (the mountain goat of moa) coprolites from opposite ends of the South Island that contain high proportions of colourful truffle-like fungal DNA, and importantly, spores…strong evidence that these moa made a meal of these fungi and probably played a role in their dispersal.
"While the sample size is small (welcome to ancient DNA and the fossil record cards we are dealt), this new study is a start. It will be great to see whether this behaviour is seen across more moa and other living and extinct ground-dwelling birds.
"So, what is the upshot of this new research. It looks like colourful truffle-like fungi may be affected by the ghosts of extinctions past…an evolutionary anachronism. One of the fungi life partners (the other being the forest tree) is extinct and they haven’t realised it yet.
"These lost ecological connections and the resulting extinction debt, which Aotearoa is still suffering from, could have a profound impact on native forest resilience.
"With few birds to disperse fungi, their populations may become fragmented, limiting a forests ability to respond to climate change in a fast-changing world…how can forests colonise new areas without their fungal symbiont?
"There are also no ecological surrogates (animals with a similar job vacancy in the ecosystem) to act as fungal dispersers…moa may have been exceptional and unique in this regard.
"Pests, like deer and possums, eat native colourful truffle-like fungi, but the spores do not survive passage through their gut. In contrast, exotic truffle-like fungi associated with introduced plants do survive this journey, giving them a competitive evolutionary advantage, and help the spread of another pest, wildling pines. If these pests are not controlled, we could see a biological turnover event of native to exotic fungi, and decreased forest resilience.
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