Australia's Great Southern Reef is built not by coral but by seaweed. The seaweed forests on these rocky reefs stretch more than 8,000 kilometres around southern Australia.
Amid the swaying fronds live seadragons, rock lobsters, giant cuttlefish and southern blue devils. The reef is home to more than 1,500 seaweed species and contributes billions to the economy each year .
But these remarkable cold water forests face a worsening threat. The ocean is getting steadily warmer, pushing seaweed species outside their survival zone. Much of this damage is done by sudden marine heatwaves, where temperatures spike and remain high for some time. Heatwaves have driven the decline of seaweed forests across the country.
To protect these underwater forests, we need to preserve their genetic diversity. We led the first attempt to cryopreserve (freezing and storing reproductive material at ultra-low temperatures) a key Australian seaweed, crayweed, and found the idea shows promise , though the techniques need to be perfected.
Why does seaweed matter?
Most of us encounter seaweed as a slightly stinky mass spotted when walking along a beach. But underwater, these large algae (not plants) form beautiful forests swaying in the current - some as tall as 30 metres .
Seaweed forests are among the most productive ecosystems on Earth. Like forests on land, they provide habitat, shelter and food for many creatures. They underpin valuable fisheries such as lobster and abalone.
When local populations are wiped out, they take something important with them - genetic diversity. Species with high genetic diversity can better adapt to change. Some populations will be able to tolerate heat better, for instance. But if these populations disappear, their unique genes go with them .
In 2011, an extreme marine heatwave in Western Australia led to two common seaweed species losing an estimated 30 to 65% of their genetic diversity. These losses may mean poorer outcomes in response to intensifying threats.
Consider the crayweed
Golden-brown crayweed (Phyllospora comosa) once formed extensive underwater forests along Sydney's coastline. Many of these disappeared in the 1980s, likely due to sewage pollution. But crayweed didn't return even after pollution levels fell.
Over the past 14 years, scientists and divers have replanted this species around Sydney through Operation Crayweed . Their work has led to the return of self-sustaining populations, including Australia's first named seaweed forest - Yanggaa forest at Coogee Beach.
But restoration may not be enough in a rapidly warming ocean. Our research shows separate crayweed populations harbour unique genetic diversity - and some individuals appear better equipped to tolerate heat. It may make sense to plant germlings (baby seaweed) from these individuals in vulnerable populations to boost their chances of survival .
Of seed banks, biobanks and cryopreservation
For decades, thousands of land-based plant species have had their genetic diversity preserved through seed banks . The seeds stored are sleeping but still alive. If planted in the right conditions, they will grow.
Some kelp species can also be kept alive in biobanks - not as seeds, but in a microscopic form (gametophytes) able to be kept alive in laboratories for years. Current kelp collections support research, aquaculture and restoration programs around the world , including in Australia .
These banks are important. But they won't be enough. The majority of seaweed species dominating the Great Southern Reef are known as fucoids. Unlike true kelps, fucoids don't have this microscopic life stage - they release sperm and eggs directly into seawater that fertilise and form germlings. This makes species such as crayweed, bull kelp (Durvillaea potatorum), Cystophora sp. and Scytothalia dorycarpa more challenging to conserve.
It is possible to bank species which rely on sexual reproduction, such as humans, cows, corals and fucoids. Assisted reproduction methods such as IVF rely on cryopreservation : storing reproductive material, tissue or early life stages at ultra-low temperatures (around -196 °C) so it remains viable for future use.
Our recent research tested whether frozen crayweed sperm and germlings were viable after being thawed. We found the sperm did well, but the germlings did not (for now). Our ultimate goal is to develop proven methods able to work across a broader range of Australian seaweed species.
Preserving the genetic diversity of seaweed species would mean these genes can be drawn on to bring them back. This buys valuable time and keeps the door open for new methods such as assisted gene flow , where individuals from better-adapted populations are used to help vulnerable ones cope with warmer conditions.
Time for seaweed biobanks?
Australia already has an impressive algal culture collection and is a global leader in coral cryobanking .
Even so, it will take real work to develop methods of preserving the forest-forming seaweed species that rely on sexual reproduction. We need to learn which populations contain unique or threatened genetic diversity, understand which are most vulnerable to climate change and improve freezing and recovery techniques.
Choosing which species and populations should be done alongside Indigenous custodians , governments, conservation organisations and local communities.
Cryobanking doesn't solve climate change or replace the need to protect habitat. It's an insurance policy for biodiversity. Much has already been lost. Preserving the remaining genetic diversity of our seaweed forests may well be critical to the survival of the Great Southern Reef.
Catalina A. Musrri received funding from the Australian Government International Research Training Program scholarship and the University of Sydney, Marine Studies Institute Ruhm Award in Marine Ecology. This work is funded by an Australian Research Council Linkage Grant.
Georgina Wood is supported by the Australian Research Council through an Industry Fellowship and Linkage Grant, and a Revive & Restore Wild Genomes grant.
