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How young coqu铆 frogs balance the competing demands of growth and fighting聽disease

By Zuania Col贸n-Pi帽eiro, Ana V. Longo, Miguel A. Acevedo, Nich W. Martin | The Conversation

July 2, 2026 at 8:00 AM EDT

This article is republished from The Conversation, an independent and nonprofit source of news, analysis and commentary from academic experts. Zuania Col贸n-Pi帽eiro is a Posdoctoral Research Fellow in Biology at the University of Florida; Ana V. Longo is an Associate Professor of Biology at the University of Florida; Miguel A. Acevedo is an Associate Professor of Quantitative Wildlife Population Ecology at the University of Florida, and Nich W. Martin is a Postdoctoral Research Associate at the Florida Museum of Natural History at the University of Florida.

The is a small but iconic species in Puerto Rico. Their melodic 鈥渃o-qu铆鈥 call is a lullaby for people on the island.

But it鈥檚 far less welcome in places like Florida and Hawaii, where the . In those states, these little frogs can seem impossible to get rid of.

But in fact, a has been contributing to declines in more than 500 amphibian species worldwide, including the common coqu铆.

In Puerto Rico, where , infected frogs . Smaller frogs of any species are .

For tiny frogs, survival is a high-stakes game with no pause button. Any energy put toward immune defense to prevent infection cannot be used to grow, and vice versa. And for young frogs, this energy allocation game is especially critical because getting it wrong can mean game over.

So what processes are driving differences in size and survival between infected and healthy frogs?

at the University of Florida how disease shapes wildlife populations. In , we integrated field data and mathematical models to examine how young coqu铆s allocate energy as they grow while coping with infection.

We wanted to understand how these trade-offs play out over time and whether the season 鈥 that is, whether it鈥檚 warm or cool 鈥 when frogs hatch from their eggs affects their chances of surviving to maturity and their lifetime reproduction.

Tiny frogs, big challenges

Coqu铆 frogs lay eggs on land, skipping the tadpole stage in a process called direct development. This means , smaller than your pinky nail.

Males guard the eggs and newborn frogs, called neonates. Young froglets hatch at less than 0.4 inches (1 centimeter) long. They take about a year to reach adulthood, growing to a bit more than an inch long (2.9 centimeters).

Their small size makes them difficult to track in the wild. That means the most important periods for growth and survival are also the hardest to study directly.

Coqu铆s reproduce , peaking of May through August. During this time, .

Frogs that hatch during the cooler months of December through April are exposed to fewer infected frogs, but those they do encounter have more of the deadly fungus in their skin. Cooler temperatures , and . This leads to higher fungal loads.

Independent of hatching time, all of the coqu铆s are exposed to the deadly pathogen early in life, when they are more susceptible to dying.

A strategic survival game

Because these tiny frogs are so tricky to monitor, we used mathematical models to simulate how young frogs might grow, become infected and survive under different environmental conditions.

The optimization models we used to identify the strategic behaviors for frog survival have been applied across many disciplines, from to .

Our model allowed us to change factors like food supply, the probability of getting infected and mortality risk, mirroring the patterns that we observe in the field and in experiments. For instance, we know that there are and during warmer seasons, and that the in infected froglets.

In our model, we think of this process as a strategic single-player game: At every stage of life, frogs appear to 鈥渄ecide鈥 how to use energy. They can use it to grow, they can use it to fight infection, or they can split it between the two processes.

Of course, the frogs are not consciously making these decisions. Rather, the patterns of frog behavior reflect strategies shaped by evolution. Over generations, individuals who allocate energy in ways that improve survival rates are more likely to reach sexual maturity and pass on their traits.

Using this approach, we identified a few simple rules for surviving as a young coqu铆 frog.

Rule 1: Grow first, until it gets too risky

When infection levels are low, frogs tend to prioritize growth. Growing quickly helps them to avoid predators and reach sexual maturity. As infection levels rise, that strategy shifts. Frogs begin to invest more energy in immune defense, even though it slows their growth. In other words, they tolerate infection up to a point, but once it becomes life-threatening, fighting disease takes priority.

Rule 2: Infection has hidden costs

Our results showed that infected frogs grow more slowly and take longer to reach maturity. These delays reduce survival and lifetime fertility.

This result from our model helped explain the pattern we observed in the wild: Infected frogs are often smaller than healthy ones. Infection does not just determine whether frogs live or die; it also shapes how they grow and develop.

Rule 3: Timing is everything

The time of year when frogs hatch strongly affects survival. In tropical environments, and vary throughout the year. Frogs born at the start of the warm season, around May, when food is more abundant, grew faster, reached maturity sooner and survived at higher rates. Frogs born under less favorable conditions faced a slower start and less chance of survival.

Why these trade-offs matter

Our findings show that the effects of pathogens go beyond immediate death. Even nonlethal infections can influence growth, development and future reproduction 鈥 hidden costs that shape population recovery.

Besides helping us to learn more about coqu铆 frogs in the wild, understanding these trade-offs can also guide conservation. For example, captive breeding programs often release frogs into the wild, and timing releases with favorable environmental conditions could improve their survival chances. On the other hand, our models also identify times when these frogs are more vulnerable to invasive species control measures.

More broadly, this approach helps researchers predict how animals will respond to environmental change, disease outbreaks and shifting climates.

The next time you hear a frog calling at night, remember that its survival depended on a series of invisible 鈥渄ecisions鈥 early in life. These moves are not shaped by conscious choice, but by evolution, timing and the challenges of a changing world.

, Posdoctoral Research Fellow in Biology, ; , Associate Professor of Biology, ; , Associate Professor of Quantitative Wildlife Population Ecology, , and , Postdoctoral Research Associate, Florida Museum of Natural History,

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