Is camouflage better than warning colors? For insects, it depends

The Evolution of Color in Prey: Camouflage vs. Warning Signals

Prey animals utilize their colors strategically to either blend in with their surroundings or to communicate potential danger to predators. The environment plays a critical role in determining which of these strategies is most effective.

A comprehensive global study comparing defensive coloration in insects indicates that both camouflage and warning colors thrive under specific environmental conditions. This significant research, published on September 25 in Science, highlights essential factors influencing the evolution of these two survival strategies worldwide.

“This is the most thorough experimental investigation of warning signal efficacy that I have ever encountered,” remarks David Kikuchi, an evolutionary biologist at Oregon State University in Corvallis, who was not part of the research team. His acknowledgment underscores the patterns identified in the study that had been theorized before but lacked empirical validation.

From the vibrant hues of beetles to the striking colors of poison dart frogs, animals deploy either camouflage or bold warning colors to deter predation. “These are the predominant color-based defense mechanisms in the animal kingdom,” states Iliana Medina Guzman, an evolutionary ecologist at the University of Melbourne in Australia.

Guzman and her research team aimed to explore why these two evolutionary paths frequently occur across diverse species and why certain animals favor one strategy over the other.

While smaller studies have delved into the effectiveness of these strategies in nature, understanding the complete picture requires examining a wider array of environmental conditions. Guzman emphasizes, “A comprehensive analysis is only feasible when experiments are conducted in multiple ecosystems with varying circumstances.”

Between 2020 and 2022, the research team executed experiments across 21 wooded locations on six continents, ranging from colder climates such as Finland and Canada to warmer locales in Kenya, Australia, and Brazil. Over this period, more than 15,000 paper triangles mimicking moths or butterflies were prepared.

Some mock moths displayed traditional orange-black warning patterns typical of many defensive species, while others featured a rare turquoise-black color scheme. A third category was designed to resemble the camouflage of tree bark. These paper moths were baited with mealworms and placed in forests, allowing researchers to monitor how many mealworms were consumed by local bird populations over eight days. Additionally, the team gathered data on forest light levels and the populations of both predator and prey insects through bird and butterfly surveys.

The findings revealed that neither defensive approach was universally superior; instead, the effectiveness of the mock moths relied heavily on local conditions. For example, warning colors were notably more successful in environments where predator populations were low.

“This aligns well with theories suggesting that when predator competition intensifies, they may consume whatever prey is available, making bright colors less effective as warning signs,” Guzman explains. “In such situations, colors may simply act as attention grabbers rather than deterrents.”

Kikuchi expressed his surprise at how consistently the common orange-black warning pattern performed across varied ecosystems. He notes, “There is often significant selection pressure against even minor variations in local warning signals. Patterns that deviate from the norm may not function effectively as warnings, potentially leaving those insects vulnerable.”

Interestingly, light levels influenced the utility of the warning signals, while camouflage was less effective under low-light conditions.

“In habitats experiencing drastic changes in light due to factors like logging, the impact on prey communities could be substantial,” Guzman warns. This shift could undermine the effectiveness of camouflage, leading to increased predation while not necessarily affecting species that rely on warning signals as significantly.

The implications suggest that camouflage could be less stable over evolutionary time scales than warning signals, which may possess greater resilience.

Guzman has expressed interest in exploring how human-induced environmental changes influence the relative success of these adaptive strategies in the animal kingdom.