Comment: Coral adaptation

Published on: 29 November 2024

Writing for the Conversation, Drs Liam Lachs, Adriana Humanes, James Guest and Prof Peter Mumby discuss that corals can adapt to warming oceans, but not fast enough.

A healthy Acropora coral reef in Palau, western Pacific Ocean. Liam Lachs

, ; , ; , , and ,

Heatwaves in the oceans are triggering coral bleaching on a massive scale. If greenhouse gas emissions continue unabated, such heatwaves are projected to occur at least every two years over the coming decades.

Yet, emerging research indicates that corals have at least some capacity to adapt to climate change and heat extremes. This coral heat tolerance is influenced by many different genes, each with potential variants that have arisen over vast amounts of time.

Those corals that are more heat tolerant are more likely to reproduce as the oceans warm, while those that aren鈥檛, won鈥檛鈥� natural selection in action. This is how adaptive evolution can happen, even over just a few generations in relatively short periods.

To date, some have argued that the process of adaptation cannot help corals persist because , whereas the extreme opposite view would be that adaptation can allow corals to keep pace with climate change. We set out to determine where the answer lies with the best available science today. Can coral adaptation keep pace with ocean warming?

Marine heatwaves can cause coral to 鈥榖leach鈥� and die. Peter Mumby

To answer this question, we developed a powerful computer program that can simulate coral reef ecosystems and how corals will evolve 鈥� in Palau, a nation of hundreds of islands in the western Pacific Ocean. This program, or model, focuses on one group of the coral genus Acropora that resembles small underwater bushes with vivid coloured branches (as shown in the photos in this article).

Acropora are a key ecological component of most coral reefs in the Pacific but, like many other coral groups, are very sensitive to changes in temperature. They can reproduce by around four years old, quicker than some other coral species. This makes them useful for scientists like us, as we may be able to see them adapt to climate change within our lifetime.

We used our model to simulate the consequences for Acropora coral under three future climate scenarios developed for the IPCC: (1) if we were to get climate change under control in the near future; (2) a more moderate scenario which we are currently headed toward; (3) if we do nothing and the world gets hotter and hotter. Relative to pre-industrial global temperatures, these climate scenarios lead to around 2掳C, 3掳C and 5掳C of warming, respectively, by the year 2100.

Our work, published in , shows that adaptation via natural selection may be able to keep pace with ocean warming, but only if global warming is limited to a maximum of 2掳C.

Unfortunately, we are currently more likely to experience around 3掳C of warming above pre-industrial levels by the end of the century. As things stand, coral adaptation is too slow to keep up with the rate of warming.

Under a worst-case emissions scenario with warming peaking at 5掳C, our model suggests a complete loss of Acropora coral populations is inevitable. This happens even if the corals were at their theoretical upper limit of adaptive potential, in which heat tolerance is entirely genetically determined, with perfect inheritance from parents to offspring (the blue lines in the graphs below).

A) Severely bleached Acropora colony in 2020. B) How Acropora might fare in different future climate scenarios, depending on how heritable heat tolerance is (blue line = fully heritable; black = not heritable at all). Top graphs show how much of the seafloor is covered in these corals; bottom graphs show heat tolerance. Photo: Peter Mumby; Graphs: Lachs et al (2024)

But there is some good news: our study suggests that natural selection could offset some of the projected losses of coral reefs over the 21st century.

In the 鈥渕oderate鈥� emissions scenario that we are most likely heading towards, coral populations could only survive if they are able to adapt at least somewhat to warmer oceans (the red line in the above graph). If they鈥檙e not able to adapt at all, populations will disappear by 2070.

Even with the ability to adapt, remnant populations would be heavily depleted with an elevated risk of disappearing. But so long as populations persist, the model predicts corals will become more and more heat tolerant through natural selection, keeping open the window for evolutionary rescue beyond the 21st century.

Nevertheless, the route to coral persistence in this moderate emissions scenario is fraught with challenges. For instance, there is considerable risk of reproductive failure if populations become too depleted, with surviving individuals located too far away from one another for successful fertilisation during annual spawning events.

Where we go from here

Thanks to natural selection, there is a slim yet closing window of opportunity for Acropora and other heat-sensitive corals. This is important because it implies that the case for managing such corals is not a lost cause.

In addition to redoubling global efforts to reduce greenhouse gas emissions, we must also minimise the additional threats that affect corals, thereby giving evolution a chance to work.

The authors monitoring corals they selectively bred for high heat tolerance at an ocean nursery in Palau. James Guest

There is also scope to improve upon natural adaptation rates. That鈥檚 why scientists like us are already considering innovative interventions such as 鈥渁ssisted evolution鈥�. To be clear, this does not have to involve any genetic engineering 鈥� it could be achieved by identifying exceptionally tolerant corals in nature, and breeding them to spread natural heat tolerance genes more widely back on the reef.

Our has recently shown that is a feasible option. Yet the finite scope for natural selection or even assisted evolution suggests we鈥檒l need to do it quickly, if we are to slow the projected declines in coral.

Our work reinforces the calls to reduce global greenhouse gas emissions and improve local reef management. Together, these actions can support corals as they adapt to become more heat tolerant, helping them persist even as the oceans warm.

Don鈥檛 have time to read about climate change as much as you鈥檇 like?
Every Wednesday, The Conversation鈥檚 environment editor writes Imagine, a short email that goes a little deeper into just one climate issue.

, Postdoctoral Research Associate in Climate Change Ecology and Evolution, ; , Postdoctoral Research Associate in Coral Reef Ecology, 缅北禁地, ; , Reader in Coral Reef Ecology, , and , Chair Professor, Coral Reef Ecology,

This article is republished from under a Creative Commons license. Read the .

Share:

Latest News

缅北禁地 expert highlights climate crisis in a new film

A leading 缅北禁地 climate scientist is featured in a new film about how the climate and nature breakdown will affect the UK.

published on: 14 April 2026

Neolithic tombs reveal ancient kinship ties

Male individuals buried in Neolithic chambered tombs in northern Scotland were often related to each other through the paternal line and some were interred in the same or nearby tombs, research shows.

published on: 14 April 2026

Artwork by Fine Art graduate Trish Hudson-Moses

We are our Memories

New exhibition by Fine Art graduate Trish Hudson-Moses, 22 April 鈥� 4 May 2026

published on: 10 April 2026

Facts and figures

Latest News
Archive
About Us