This image shows Acropora millepora light-mediated upregulation of red fluorescent protein amilFP59. Credit: Professor Wiedenmann and Celia D'Angelo
Scientists from the University of Southampton have discovered the genetic basis which allows corals to produce their stunning range of colors.
They have found that instead of using a single gene to control pigment production, corals use multiple copies of the same gene. Depending on how many genes are active, the corals will become more or less colorful.
Dr Jörg Wiedenmann, Professor of Biological Oceanography and Head of the University's Coral Reef Laboratory, says: "It was one of the longstanding mysteries of coral reef biology - why sometimes individuals of the same coral species can show such dramatic differences in their color, despite sitting side-by-side on the reef and being exposed to the same environmental conditions. The key finding is that these so-called 'color morphs' do not use just one single gene to control the pigment production, but multiple identical copies thereof."
The research, which is published in Molecular Ecology, also explained how this strategy could help corals to survive in stressful environments.
Using the staghorn coral Acropora millepora as a model, the team found that the fluorescent pigments that are mostly responsible for coral colors act as sunscreens for the symbiotic algae that live in the coral tissue. These alga require light to produce sugars, which they can contribute to the nutrition of the corals in return for the shelter and the supply of nutrients that are provided by the coral host.
However, the light intensities on coral reefs can, on occasions, exceed the levels that are healthy for the alga and the light becomes dangerous for the symbiotic partnership. This light stress can ultimately contribute to the loss of the symbiotic algae, a process known as coral bleaching. If the partnership cannot be re-established, the corals often die.
Dr Wiedenmann explains: "Corals are firmly attached to the substrate, so they can't just move in the shade when they receive too much sunlight. Instead, they need to boost their capacity to cope with too much sun during these times. We show that increased light levels switch the genes on that are responsible for the production of the colorful sunscreening pigments. This is why corals are usually more colorful in the most light exposed colony parts."
However, the enhanced protection comes at a cost and the corals need to allocate substantial energy reserves to accumulate the high amounts of protein pigments that are characteristically found in brightly colored corals. This energy might be divided away from other important processes, potentially resulting in reduced growth rates or lower numbers of offspring. Therefore, being brightly color might not be a good investment for corals settling in less light exposed parts of the reefs.
Dr Wiedenmann says: "The genetic framework provided by gene copy number variation ensures that some individuals within a coral population can protect themselves very well, these are likely to survive better in stressful environments. Others are less protected, but can invest their energy in processes that could help them to succeed in habitats with less light stress. The resulting color polymorphism increases the potential of the coral species to extend their distribution range along the steep light gradients of coral reefs and to inhabit more ecological niches.
"Our finding suggests that the repertoire of reef corals' stress responses is larger than previously thought."