Behavioral work on many animals, ranging from insects to mammals, has shown that females prefer a certain type of male call: perhaps one that is longer, louder, or has certain combinations of sounds. We’re not sure why these preferences have evolved, though there are many theories. Those include hypotheses that males with, say, louder calls are healthier, and would confer better genes on their offspring, or that the calls are species-specific and a narrower “call window” prevents you from mating with another species and producing maladaptive offspring. The phenomenon of mate preference in females is well documented, but its evolutionary basis is poorly understood—such studies are very difficult. How can we learn what a female gains by mating with one kind of male versus another? Those studies must be done in the lab, and involve tricky preference tests combined with accurate measurements of female offspring number and quality.
Mike Ryan’s group at the University of Texas in Austin has spent years studying mating behavior (and how it relates to male calls) in túngara frogs (Engystomops pustulosus), a species found in Mexico and Central and South America. Males sit in or near streams and croak for hours, hoping to attract females with the beauty of their calls.
In most cases, female túngara frogs prefer male calls that are more complex, louder, and have lower frequencies and faster call rates, though the situation is complex. (One possibility for the louder-call preference is that those calls are producer by larger males, who not only can fertilize more eggs but may have better genes. They thus could confer a non-genetic benefit on the female (more sperm means more offspring) or a genetic one (offspring carry their father’s genes that make the sons bigger and themselves more likely to get mates). Both advantages could, over time, impose natural selection on females to prefer certain kinds of calls.
Below are some videos, audio clips, and photos of male túngara frogs calling. As you see, males put a lot of energy into attracting mates, using both their bellies and inflated vocal sacs:
Males calling:
(See also the video at the bottom of the Science News blurb.) If you click on the screenshot below, you’ll go to a page where you can listen to a typical call: a loud squawk followed by a series of “chuks,” which increase its complexity:
Calling has its dangers, too. Males who emit more elaborate calls are subject to more predation by fringe-lipped bats, who presumably can detect the frogs more easily. That counterselection may prevent males from evolving even more elaborate calls, for there might be a point beyond which the higher predation outweighs the advantage of attracting females. Here’s a calling male meeting a sad fate (photo by Christian Ziegler from Smithsonian.com):
One thing that’s tacitly assumed in studies of mate preference is that there is a continuum of call characteristics that is fixed and transitive. That is, if call A is preferred over call B, and call B over call C, then call A should be preferred over call C. And the order of preference shouldn’t change if other calls are present in the population. But a new paper in Science by Amanda Lea and Mike Ryan (reference and free download below) shows that this might not be the case, at least in this frog.
Their hypothesis was that “decoy” calls could actually change the order of preferences between two calls, making the least preferred call the most preferred. They tested this by making three artificial calls of differing attractiveness to females, and then testing the females’ preferences by playing these calls through speakers in the lab, seeing which speaker a female hopped toward. (Directional hopping towards a sound source is a common way to estimate female preferences in frogs.)
Lea and Ryan based their experiment on a human analogy: psychological preferences can change direction when a decoy preference is thrown into the system. Here’s how their paper describes the “decoy effect”:
One well-known violation of regularity is the “decoy effect”. For example, while shopping for a used vehicle, the buyer may value both low price and fuel efficiency. Of the two vehicles considered, one has a higher price tag but also better efficiency (A), whereas the second has a lower price but also lower efficiency (B). The buyer decides that he or she values lower prices over higher efficiency and so chooses B. At this point, the salesperson mentions that there is a third vehicle (C), which also has good fuel efficiency but a much higher price than both A and B. This causes the buyer to reconsider, despite no interest in the higher-priced vehicle. To the salesperson’s delight, the buyer ultimately chooses A, spending more money for better fuel efficiency. This irrational behavior has been produced by the decoy effect.
Do frogs do the same thing with calls? Lea and Ryan made three artificial calls differing in “type” (presumably complexity) and rate. The call most preferred in choice tests was call B, with call A significantly less preferred. Then they made a really lousy call, call C, which served as the decoy call, When pairs of calls were tested, B was more preferred than A, and both were preferred more than C.
The twist was then giving individual females a choice of all three calls presented simultaneously. And they did this in two ways. First, they put speakers on the floor emitting all three calls at the same time, and seeing which one the females chose (A below). Then they put the decoy call (C) on a ceiling-mounted speaker, so the female could hear it but not “choose” it, as she couldn’t hop to the ceiling! That’s design B below.
And here are the results, shown as the proportion of frogs choosing either A (light gray) calls or B (dark gray calls) in two situations: the “binary” (the decoy call not broadcast), and “trinary” (decoy call broadcast). The top plot below is from design A above, when the “trinary” situation involves females being able to hop toward the decoy speaker (those preferences aren’t given). The bottom plot is from design B, where females could hear the decoy call but not “prefer” it by moving toward it. Again, the data are just the relative preferences for A and B.
Let’s look at the top figure first (C; it’s a bit confusing because the figures are given designations that use the same letters as call type). When calls A and B are tested against each other without the decoy call, B is slightly preferred (as it was in the preliminary experiments), but the difference is not significant. However, things change when the decoy call is played: all of a sudden call A becomes strongly and significantly preferred (asterisk shows statistical significance, with a p less than 0.05). The decoy has altered the preference, but not reversed it since there was no significant preference between calls A and B in the “binary” experiment. The alteration, as shown by the comparison with three asterisks between the binary and trinary experiments, is highly significant (p < 0.001).
The results are similar, but even more striking, in experiment B, when the decoy call was played from the ceiling. In this case when only A and B were played, there’s a strong and significant (p < 0.05) preference for B, as in the preliminary experiments. But when the decoy was played from the ceiling, all of a sudden females significantly preferred call A (p < 0.05), a reversal that was significant when binary and trinary tests were compared (three asterisks: p < 0.001).
In both cases, then, throwing a third “decoy” call into the mix makes female prefer a call that was either neutral or less preferred when tested against one alternative call. In other words, the direction of mate preference was not fixed, but altered by a third call—a call that was the least attractive!
What’s the upshot? Clearly, in this experiment (and we’re not sure if the same results would occur in nature rather than the lab), mate preferences are not fixed but malleable: they change depending on what other calls abound in the environment. What we see is similar to the “decoy” effect described by Lea and Ryan for car-buying, with call C playing the role of the more expensive, gas-efficient car.
But what does that mean? First of all, we don’t know whether the result is a general one: is this intransitivity typical of animal mating systems? The authors cite one or two papers suggesting this may be the case in some other species (I haven’t read them), but we’d need a lot more experiments like this to see how general the “decoy” effect is in nature.
But why does this happen at all? Does it make any evolutionary sense, or does it simply reflect confusion on the part of the females, who are thrown off by the decoy call? But if that were the case, why would their preference all of a sudden switch to the suboptimal call A?
We don’t know, but at the end Lea and Ryan suggest some hypotheses:
In socially complex situations such as frog choruses, rational decisions could be time-consuming, potentially resulting in lost mating opportunities or the risk of further exposure to predators. Decision rules might evolve to include loss aversion, mitigating the risk of costly errors, which are more likely when there are extreme alternatives and in uncertain environments. Such heuristics could lead to stabilizing selection on male traits and maintenance of genetic variation. Moreover, as human consumers are susceptible to manipulation by salespeople, context-dependent choice rules may make female frogs vulnerable to behavioral exploitation by competing males; for instance, if males are selective of their nearest neighbors.
Although it is clear that female choice patterns do not coincide with the consistent valuation predicted by traditional models in sexual selection, it is far from clear whether perfect formal rationality is mutually compatible with optimal evolutionary fitness. Closer inspection is required to determine whether inconsistencies revealed by decoy effects are, in fact, suboptimal in the context of fitness maximization. Variation of female mate choice in different social contexts might reflect adaptations for using additional sources of information, resulting in the expression of more complex but predictable choice patterns.
What they’re saying here, in scientific jargon, is that this might just be an irrational mess without adaptive significance. (Perhaps call B just comes through more clearly than does call A when the decoy call is played.) But they also propose alternative scenarios, involving spatial proximity, predators, and loss aversion—all of them adaptive. That is, the changes in preference in the presence of a third call could be an evolutionary phenomenon that gives the female higher offspring number.
Such adaptive hypotheses might make sense, but not necessarily in light of the decoy results. For example, if females want to avoid long-distance hopping, or predators, by mating with the nearest caller rather than the most attractive, that does make adaptive sense, but doesn’t seem to relate at all to Lea and Ryan’s result that the presence of a decoy call makes the female reverse her preference. Why the reversal? And perhaps it’s adaptive to just mate with any male when the acoustic environment is confusing, but again that fails to explain the switch in preference rather than just a loss of preference.
In the end, I find the experimental results intriguing, but their meaning unclear. That’s not the experimenter’s fault, for although they expected decoy effects, their significance, and whether the explanation involves adaptation, would be very hard to disentangle. The only problem I have with the paper, and it’s a minor one, is that the adaptive hypotheses don’t seem to relate very well to the experimental findings of a reversal of preference. What is sound (pardon the pun) is the finding that relative preferences between two call types can be dramatically altered by the presence of a third call.
______
Lea, A. M. and M. J. Ryan. 2015. Irrationality in mate choice revealed by túngara frogs. Science 349:964-966.
No fair! Posting a science article after all the light-hearted stuff, just as I have to go off and do other things. Make me work overtime to brain these things.
Ah’ll be bak….
b&
Okay…I’ve had a chance to read it. I hope the paper catches the eye of somebody working on game theory…there could be some interesting modeling to do.
The chirping the frogs make at the end of the main call almost seems designed for bats to home in on.
…and:
b&
Love this kind of post. Thank you for the link to the paper.
Interesting post. Maybe the females are interested in the less interesting males when things are getting interesting because “things are getting interesting” usually ends up being bad news. Their kids won’t particularly stand out as events unravel in unexpected directions.
As the ancient Chinese curse has it “May you live in interesting times.”
ribbit
sub ribbit
That is fascinating about the dynamic range (volume, frequency) that limits the frog based on predation.
Anyhow, bats are more favorite to me than frogs…so eat little batty, you have done well. Better luck next time, froggy…or maybe not.
Is the third or decoy call always of poorer quality to get this result? If so, then does the result change if the decoy call is of yet higher quality than the others? This does not necessarily provide any answers but would be interesting to know.
They don’t know–they used only one decoy call.
I wonder if the placement of the decoy above had something to do with it and it wasn’t just that it changed the environment with the other two – maybe they need to test at different locations.
Imagine how depressed the frogs must be: “Really? This is how dating works nowadays? Listening to a black box in an empty room?”
Imagine speed dating!
yikes!
Though they did jump on the opportunity…
I’m finding it hard to think like a gravid female frog – I’ve decided that is a good thing. I’d try a variation on Randy’s suggestion above. Play call A through 2 of the 3 speakers (B through the remaining one) and do the reverse – call B through 2 of the 3 (A through the other). This might begin to get to the opportunity issue. More calling males means more females seeking mates in the area = more interference competition among females. A female frog may need to hop to it under these circumstances.
On a related anuran chorusing note, I just listened to part of a TED talk by Bernie Krause, about recording and archiving natural soundscapes as they change and disappear because of human activities. Krause describes how male Great Basin Spadefoot toads in Mono Lake synchronize their calls, presumably as a cooperative adaptation that reduces chances of being nabbed by a predator. Apparently Navy fighter pilots fly over this area in their training runs, which disrupts the chorusing, and it takes the toads ~45 minutes to re-synchronize their calls.
Krause has a website, Wild Sanctuary, devoted to soundscapes (biophony, geophony, anthrophony – all new words to me), and of course he was an electronic music pioneer as well, playing the Moog synthesizer for the Byrds, the Doors, etc.
Fascinating post. Thanks a lot!
Hm, decision theory is often criticized for requiring the transitivity of preference. Interesting that the breakdown of transitivity plays a role here too.
I liked the pictures of the frog among the speakers!
It’s not clear to me that the relative preferences between calls A and B are consistent or stable even in the absence of a third call.
Compare the binary case in diagram C with that in diagram D. Ostensibly these are identical conditions from the frog’s point of view; the only difference (if I’m understanding the setup correctly) is whether the mute third speaker is mounted on the floor or the ceiling. Yet these two cases give different results, undermining the assumption that call B is clearly preferable to call A (or so it seems to me).
And if the placement of the third speaker affects the frogs’ choice, why aren’t we shown the data for frogs choosing the third speaker in either the binary or the trinary case? How is the comparison of A/B ratios meaningful without the C data?
Thanks Jerry – great read!
I think that buying car A (higher price but more fuel efficient) would pay off in fuel savings in the long run.
It would depend on a great many factors. Simplest…imagine a car that had no fuel or other maintenance costs, but could only be purchased for a million dollars. Or, a car that’s given away, but only runs on fuel that costs a million dollars a mile to operate.
…and that’s before we start to consider how many miles a year you drive it and various other factors….
b&
Whenever I see these kinds of experimental designs, I keep getting blown away by their ingenuity. I try to imagine just the process of conceiving of how to go about answering such questions and draw a blank.
Thank you so very much for these digests, and taking the time to put them together. It really helps to unstick me from some mental ruts, as getting way too focused on my (frankly depressing) work makes the brain go stale.
Being rather slow, I do have to switch gears back to work, then revisit this again – then back & forth again before more things click. (and then it’s a week later) This forum, with its bright commenters bringing up such great questions & pointing out possible alternate explanations before I’ve had a chance to turn my brain on… it’s just so damned cool.
Agree.
Thanks, this was a very interesting read! Just wondering about this sentence:
Should A and B be swapped here? Or are you suggesting that females can’t hear the imperfections in call A when the decoy is played?
I think it could be a situation like when you put your hand in ice cold water, then follow it with warm water, the warm water will feel hotter than it is. Or vice versa. There is probably some female frog memory of the C call operating which is changing the perception of both B and A calls, even though they haven’t changed.
Or (I haven’t read the research paper), if all three calls were played simultaneously with at least some overlap, the C call made of sound waves, is constructively or destructively interfering with important (to a female frog) parts of the B and A sound waves.
Further research required to suss all this out. 🙂
And I wanted to add :
This is why teaching science is so cool. Students are amazed when they first learn that people study these sorts of things at all, and are doubly amazed that some devote major portions of their lives and brains to questions such as this.
The really smart students already think it’s cool; the less so think it’s “stupid”. A good teacher’s job is to get the less so and the “not sures” to embrace the type of thinking and openness to inquiry and wonder that makes all science study worthwhile.
Baffling.
My take home observation is that frog calls aren’t as simple (a nuisance) as they appear.
Thanks Jerry this was really interesting! I’ve not had time to read the full paper but I did have one idea.
When call C is introduced call A suddenly becomes more appealing as it is not the poorest of the lot any more. While call B is the strongest, suggesting a frog with better genes, it is also likelier to be heard by a predator. This could also mean that the female is more likely to be found and eaten by a predator when she mates with him. The female may therefore make a trade-off: the frog producing call A provides her with the likeliest chance of mating with a relatively fit male (when call C is taken in to account) and not getting eaten at the same time. It is a far better strategy to mate with a less than perfect frog if it means not getting eaten. Of course this also raises another point: if stronger calls increase the chance of a mating female being eaten, why have stronger calls evolved and persisted in males?
There’s another possible reason females would prefer one call over another: No reason at all.
Mate preferences don’t have to be at all related to fitness in any way beyond their effect on mate choice. In this case, whatever sound the females prefer could have no bearing on what the male can contribute to her offspring other than their future ability to make the right sound to attract a mate. And with those genes go her own for preferring that type of sound.
In other words, any random preference can be selected and amplified without any effect on fitness other than mate selection.