Bats and humans are a lot alike, at least in one sense: we
both rely on our friends for recommendations on which products to buy. For us,
it’s second nature—when in doubt about which thing to buy, we ask a friend what
they have. But before you bite the bullet—or the fruit, as it were—you’d want
to know whether you could trust the information you’d be getting. How reliable
is your friend’s review?
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| Everyone's looking for a good place to eat. [1] |
For fruit-eating bats, the process of picking up
recommendations is never ending. Bats like Uroderma
bilobatum, or the Tent-Making Bat, live in small social groups of typically
2-10, but up to 60, individuals and eat fig fruits. Fig trees can be found most
anywhere, and can produce a large amount of food at one time (enough for the
whole gang). However, individual trees rarely have ripe fruit at the same time—so
for bats, the location of dinner shifts around a lot. The bats feed on multiple
species of figs, which they can identify by the individual smell of the
different fruits, and which typically have ripe fruit for 5-7 days. Ripe trees
thus represent a feeding bonanza, but only for a few days. Then, the bats are
out of luck. As the supply dwindles, the bats will begin flying recon missions,
trying to find the next lucky strike.
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| U. bilobatum in a roost [2] |
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| Close up of a captured bat [3] |
For a small bat, flying around trying to find fruit is a big
investment of energy! Luckily, they don’t all need to fly everywhere—the
benefit of group living is that they can split the search effort. Letting your
friends do the work and learning from their efforts is a time-honored strategy,
for both bats and humans. In times of scarcity, the ability to learn from your
friends where dinner can be found may be critical, and may explain why bats
form groups in the first place. In order to successfully use their roost-mates' “recommendations”,
though, bats would have to be able to determine whether it actually meant food were
available.
In a study published in Behavioral Ecology, researchers tackled
the question how U. bilobatum uses
social information. They investigated whether U. bilobatum would prefer novel food (something they hadn’t
previously encountered) consumed by roost-mates (in captivity and in the wild)
and whether or not they would discern between odor on a roost-mate’s breath
(indicating that the fellow bat successfully ate the food) versus on their fur
(indicating they simply had contact with the food).
To test this, they performed four experiments:
First, the researchers needed to see if simple familiarity
with a novel food smell would make the bats more likely to prefer it to an
unfamiliar novel food. To do this, they placed individual bats in cages next to
bananas mixed with candy-flavored oil. The bats could see and smell the food,
but not eat it. After half an hour of presumable frustration, the food was
removed and the bats were given two dishes, one with bananas mixed with the familiar
flavor, and one mixed with a different novel flavor. Despite having previously
smelled the first flavor, the bats showed no significant preference for either
flavor—simply having smelled a food before didn’t make the bats more likely to
eat it.
Next, “demonstrator” bats were removed from the captive
roost and fed bananas and novel-flavored sugar solution. They were each then
introduced into a different cage with an “observer” bat, and the two bats were
allowed to interact—generally the two bats would sniff each other and rest
together. The observer was then given the choice of the demonstrator’s novel
food, or a different flavored novel food. With few exceptions, observers
approached and ate the food consumed by the demonstrators, showing that they rely
on other bats to “recommend” certain foods.
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| Observer bats preferred to eat the food they demonstrator bats had eaten. [4] |
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| Just like in captivity, wild bats preferred food their roost-mates had eaten. [5] |
Finally, it was important to see if the bats assessed the
quality of the information—do the bats distinguish whether the demonstrator has
actually eaten the food? This is important because if the demonstrators haven’t
actually eaten the food, the observer could be in for a wild goose chase trying
to find food that isn’t actually available—maybe the fruit wasn’t ripe, or it
was unpalatable. To assess this, two bats were chosen as demonstrators. The
first was fed novel-flavored sugar water, while the second had a different
novel odor applied to its fur, and was fed unflavored sugar water. They were
then put in a cage with an observer bat. Would the observer prefer food scents
that were on the breath of a bat or on its fur? Would it distinguish the two?
As it turns out, they do distinguish. When offered the two
types of novel foods, the observers overwhelmingly preferred the novel food
that had been on the breath of the demonstrator that had been fed the novel
flavor. The bats were more apt to take the “recommendation” of a fellow bat
that had actually eaten the food, compared to one that had simply been around
it.
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| Observer bats preferred food they smelled on other bats' breath over the smells on their fur. [6] |
For fruit-eating bats, the ability to use social information
to quickly and accurately locate food may be critical. In lean times, when ripe
fruit is scarce and spread out, the roost may use the collective experiences of
its members to identify the best dinner spot. Small fruit-eating bats spend enormous
amounts of energy in flight, so spending time searching for a food source that
doesn’t exist could impose a hefty fitness cost. Thus, the ability to
distinguish between the best “recommendations” of roost-mates may be an
adaptation to deal with the difficulty of finding new fruiting fig trees. Bats,
like humans, rely on their friends’ opinions to choose a place to have dinner.
Watch the primary author of the study, Teague O’Mara,
explain the bats!
[7]
Media Credits:
[1] Photo by Yelp, inc: https://flic.kr/p/9rAJFA
[2] Photo by Charles Sharp: http://commons.wikimedia.org/wiki/File:Common_tent-making_bats.JPG
[3] Photo by Roger Le Guen: https://flic.kr/p/egvUF2
[4] Graph from O'Mara et. al. http://beheco.oxfordjournals.org/content/25/5/1233.full.pdf+html
[7] Video by Virtual Field Trips http://www.youtube.com/watch?v=dZxDsyZooYI
Great article. Since a good number of bats feed on insects, blood, and even fish, I wonder if this recommendation strategy is applicable to these bats as well, and how exactly it would work for them in each case?
ReplyDeleteI think the key is that fruit is a very patchy resource. If you find a tree, it's a bonanza, but the trees can be hard to find. So, the bats have to rely on one another to figure out how to find a meal for the evening. I think for fish or insects, they would probably not need the info.
DeleteCool side note, though! Sanguivorous (blood-feeding) bats in the Vampyrum genus don't, at least to my admittedly limited knowledge, share info on how to find food, but they will regurgitate part of a blood meal to fellow roost-mates that weren't able to find an animal. They even keep track of who helps whom, so if a bat receives blood but doesn't give it, the other bats will stop feeding it. Neat, huh?
Great debrief of the experiments in the article--your blog post was very easy to follow. Now I wonder exactly what molecular or neurological processes occur in the exchange between bats. (That's the molecular biologist within me talking. ^_^)
ReplyDeleteI understand that the bats from the first few experiments were from captivity, but they born and raised in captivity, or were they caught from the wild and raised in captivity for a long time? It might not actually matter for the experiment, but I was just curious about this little detail.
Great metaphor to Yelp! :)
Yeah, the neuro stuff would be really interesting to investigate! Probably, they are able to distinguish scents that originate from fur or breath, sort of like we, at close proximity, can tell if a scent is coming from one object or another. Then they probably sniff around while flying for the breath scent.
DeleteAs far as the captive bats go, they were captured from the wild. They were caught in mist nets, then held for a little while to let them acclimate, and then they were tested. I should have clarified that in the post!
This was fun to read, great job! It makes a lot of sense that the bats can distinguish between odors in the breath and on the fur of their roost-mates. If a roost-mate fell into a pile of manure or brushed up against an inedible aromatic tree, it would not be beneficial for their roost-mates to look for "dinner" there. I wonder how the bats figure out that the odor is in the breath- maybe there is some sort of reaction between the saliva and the food that indicates to the sniffers that the food was, indeed, consumed?
ReplyDeleteI also wonder if this form of giving a recommendation is not only to help find the food that is ripe, but to show which food is safe. Maybe the bats prefer to eat the food that they haven't smelled in breath partially because they'd rather verify that it will not make them sick or kill them, by smelling it on their living mates.
Yeah, I completely agree about the use of social information for safety. If you haven't encountered a food type before, it's very helpful to know that your friend ate it and didn't get sick. That's definitely an important component.
DeleteI don't think there's anything special that goes on with the food consumption, smell-wise, though it would be worthy of further research. I think it's simply that the smell origin is different. If you were standing right next to someone, you could probably tell the difference between a smell on their breath and a smell of something they spilled on their shirt. I think it's the same with the bats.
I agree with Beverly, your post was very readable! You did a great job of explaining the many experiments the researchers did. I also like how thorough the researchers were - they tried a lot of combinations of flavors, in both captivity and the wild, so that makes their results more likely to be true.
ReplyDeleteEspecially after watching the video about the bats, I want to know how the bats communicate the location and direction of the food source once it has been recommended. Do they just follow the successful bat to the location a second time? What if multiple bats find food, would they try to follow both or just one? Also, since the bats don't seem to travel in families, I assume they don't have any strict social roles, so how do they decide who to send out for food?
Yeah, that's a great question! Maybe the bats go out on an ad hoc basis? Or perhaps there is some structure to who does the reconnaissance? From the paper, it doesn't sound like they follow other bats, they just use the other bats to figure out what they should be looking for. Bats have a pretty good sense of smell, which is how they locate their food, so I think they calibrate their senses with their roost-mates' breath--like if their roost-mate has the smell of certain fig on its breath, then the bat would fly out and smell around for that fig scent, then follow it to the source. But I could be wrong--it would be cool to investigate this further!
DeleteAnother possible way the smell could help them locate the food is if individuals know and remember the location of different types of fig trees (e.g. if there are multiple fruiting sessions in one season). It would be hard work for every individual to go out and check every possible tree every day. But if one comes back successful, the others could smell which fig it was, and go to that type (even if it wasn't exactly the same tree, perhaps it would be more likely to be in fruit at the time). I thought about this, because this is how it works for bees.
DeleteAccording to the lead author:
Delete"Since these fruit crops last for a couple of days these bats probably follow roostmates out on the next foraging flights."
"Fig eating bats have a big hippocampus - probably have great spatial maps of their foraging areas. But specific trees, not sure"
"But they can easily tell tree species apart by odor. So if the tree is rare, it might be a big clue."
"How far they can smell the fig fruit bouquet is still a big unknown. They have great senses of smell though."
Definitely an interesting read, but I feel it begs the question as to how sensitive this sense is, and whether or not they can distinguish between foods of the same type. It's really an extension on Madison's question, but because it's unlikely they come across entirely new types of food on a regular basis, would they be able to tell the quality of food from the different breaths? Like one particularly ripe and tasty patch versus a mediocre one, and use that in the decision making process?
ReplyDeleteI think the assumption is that if the fellow bat ate a particular type of fruit, then the fruit must be good source. The fellow bat probably wouldn't have eaten an unripe fruit. As far as novel food goes, they most likely don't encounter too many novel items, but if they fly out and catch multiple scents, how would they know which to follow? If they can smell a certain scent on their roost-mates' breath, then they would know to search for a specific scent, and that would allow them to avoid metabolically-costly searching for an unproductive food source. At least according to the paper, they seem to have a very strong sense of smell, so they can likely discern different foods quite well.
Delete