Science Friday - Octopuses Use Suckers To ‘Taste’ Harmful Microbes
Episode Date: September 8, 2025Put on your party hat and wet suit because it is Cephalopod Week, Science Friday’s annual celebration of all things, octopuses, squid, and cuttlefish. To kick things off, we’re bringing you an ode... to the octopus arm. You may have heard that octopuses can use their arms to “taste” their surroundings, which they use for finding food. Now, researchers have unlocked a key mechanism in the octopus sensory system. Octopuses use their suckers to detect harmful microbes on the surface of crab shells or even their own eggs. Host Flora Lichtman talks with molecular biologist Nicholas Bellono about the latest in octopus sensory science. Guest: Dr. Nicholas Bellono is a professor of molecular and cellular biology at Harvard University.Transcripts for each episode are available within 1-3 days at sciencefriday.com. Subscribe to this podcast. Plus, to stay updated on all things science, sign up for Science Friday's newsletters.
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Hey, this is Flora Lichten, and you are listening to Science Friday.
Today in the show, the mysterious ways that octopuses use their arms to sense the world around them.
Could it be that certain arms are specialized for certain functions?
Maybe it's not that they're all tongues, as you said.
Maybe they're all doing different things.
Put on your party hat and wetsuit because it's cephalopod week, our annual celebration of all things.
Squids, squid, and cuttlefish.
And to kick things off, we are bringing you an ode to the octopus arm, which I learned is not called a tentacle. Believe it, it's an arm.
You may have heard that octopuses can use their arms to taste their surroundings.
But how exactly does that work?
New research provides some clues.
Here to tell us more is Dr. Nicholas Bolono, Professor of Molecular and Cellular Biology at Harvard University in Cambridge, Massachusetts.
Nick, welcome back to Science Friday.
Thank you.
Okay, tell me what you've found.
So years ago now, we found that octopuses actually have receptors in the suckers of their arms,
which are proteins that bind molecules from the environment to inform an animal about its surroundings,
similar to how we taste or smell.
And so we came up with this story, basically, which was that if the octaves,
is exploring its environment using this chemotactile sense or this taste-by-touch sense,
then it would make a lot of sense that the animal would be detecting these relatively insoluble
molecules that would adhere to surfaces.
And that would be different than, let's say, a soluble molecule that would diffuse through
the water that maybe a fish uses to track down prey at a distance.
But the octopus is exploring by touch.
That's kind of where we started with this whole exploration of the arms. And that was a surprising discovery.
And that's sort of the story that we had. But we actually didn't know what they sense in their environment.
Like what are those insoluble molecules? Exactly. What are the molecules? And how is the octopus distinguishing its prey from, let's say, rocks along the seafloor?
Okay, so I know you looked at crab shells, which octopus eat, to figure out what they're sensing.
That's right. And the crab shell turns out not to be so interesting upon first inspection,
but what we noticed is that there's actually a lot of things growing on the crab. And that got us thinking,
maybe what's different about these surfaces isn't necessarily the surface itself, but it's the
community of microbes that lives on the surface because almost all surfaces are covered in
microbes. We're covered in microbes. Everything the octopus is touching is covered in microbes. And so
could it be that the diversity in these different communities is actually what's informing the
octopus about what it's exploring? And the one thing I'll say that really convinced me early on
was looking at the eggs. So we did some microscopy just to look at the surface of eggs. And
Octopuses do this interesting thing when they're taking care of their eggs. So the mom will
guard her clutch and clean and errate her clutch until her death. So she won't leave to eat. She
won't do anything. She really guards those eggs. And she's constantly cleaning them. And you can
see that the behavior of the arms and cleaning the eggs is very gentle, very delicate, very different
than if you see it go capture a crab. And so there seems to be some different signal that the
animal has from the eggs. In addition to taking care of the eggs very closely, the octopus will
actually reject every so often a couple of eggs from the clutch. And so we looked at the eggs,
and what was really surprising was that the eggs did have microbes on them, but the microbial
community was very different once the eggs weren't in the clutch. We wondered, could it be that
the animal can clean airate the eggs and then sense, okay, this one's bad, I'm going to get
rid of this one so that I don't contaminate this entire clutch and not allow these eggs to develop.
And so through seeing that, we really, you know, wanted to explore this idea.
Okay. So to explore this idea, this hypothesis that the octopus is sensing microbes with its arms,
you do all this fancy biology footwork. You figure out which molecules the sensors are responding
to from the crabs. You start making these crab microbe molecules in large quantities. And then what?
and then you expose the octopus to them?
Exactly, and this allowed us to ask questions about animal behavior,
because now we had, again, true molecules from the environment,
and we could ask, what do they tell the octopus,
or what does the octopus do when it senses these molecules?
Because, as you mentioned, you might have heard about how the octopus can taste with its arms,
but we actually don't know what it's tasting.
We actually don't know what information that relays to the octopus,
but you'd be surprised that these behavioral experiments,
which are kind of silly in the end,
are really challenging to figure out
because the octopus just does whatever it wants.
And so we always have to figure out some kind of,
I don't know, a relatively simple approach
to ask what it will do with, you know, a new stimulus.
And so the experiment that we came up with was to coat crabs with this molecule.
And because crabs themselves are pretty,
complicated, they move around. They also have their own molecular composition. We decided to use
some fake plastic crabs that we then coated with auger, and we could either give them the fake
crab. And you might think that the octopus is, you know, this overly intelligent animal,
won't ever know the difference. But actually it doesn't. It tries to eat the fake crab. A lot of us
eat fake crab, Nick. So just to say, you know. So yeah, anyway, the octopus would go for the fake
crab and it will it'll actually try to eat it. We can even find little piercings of its beak.
But if we give it a fake crab coated in this microbial drive queue, it actually avoids the
crab. And we later learned that this microbe is greatly enriched in crabs as they decay. And so actually
what this molecule that's produced by microbes is informing the animal is of crabs becoming
basically foul. So crabs that the octopus shouldn't eat. So it's like, that's like, oh,
stinky rotten molecule. It may be equivalent to a stinky rotten molecule exactly. And we don't know,
you know, to us, that's sort of what we can imagine for stinky rotten food. I don't know what
that means for the octopus, you know, tasting by touch might be a very different kind of
sensation. It's hard to imagine. But I think that that would be sort of the analogous scenario.
that it realizes, oh, this crab is actually really gross because it has, you know, a lot of
this particular microbe on it. And the microbe is really what is informing the octopus of this
difference and of what it should and what it should not consume. Does the stinky molecule only get
produced? You know, do those microbes only exist in large abundance when the crab is dead?
Yeah. So the microbe can be found on live crabs or recently.
disease crabs. But it grows and it starts to make up the majority of the microbiome or
contributes to most of the diversity of the microbiome as the crab decays over time.
Did you find the delicious, you know, if we're going to stay with the analogy? Did you find
the delicious yummy molecule? We haven't yet. We are trying to figure that out. And we actually
have some experiments in the lab now, not only looking at the arms for taste, but we actually
find that there's another sense organ that surrounds the octopus's beak. So it's actually
traditionally called the lip, I guess, lip equivalent for an octopus. And it seems that this
sensor actually might be the one that detects the delicious molecule, but more to come.
Please do not go away because you're not going to want to miss this.
Our ode to Octopus Arms continues with details on the absolutely mind-boggling ways that octopus is made.
The male will find the female and then it uses the hecticottles by inserting the hectocados into the female mantle.
And it searches around in the mantle for the ovaries.
Are you enjoying the Sepulopod Week deep dive?
Well, we've only just dipped a toe in. We'll have more cephala stories all week plus hands-on family activities like building your own octopus den. You can also join our sea of support with a small contribution to keep programming like this happening all year long.
Swim over to Science Friday.com to see it all. How does your work reframe how we think about these octopus arms? Like, should I be thinking about them as giant tongues or like a sensory body that is actually.
that is totally foreign to us.
Yeah, I'm not really sure.
We've been thinking about this
from some of the behavioral experiments I just mentioned,
and we used to think that the arms
were basically used to warn the octopus.
And so the octopus is constantly probing its environment,
it's feeling around,
it's looking for stuff all the time.
And we thought maybe it's the case
that it uses its arms to explore cracks and crevices
and a prey moves, it grabs it.
unless the prey is gross, like you just talked about,
in which case it would expel it so that it wouldn't capture something dangerous.
And this is sort of what I thought for a while,
that these arms are sort of the detectors of harm.
But I don't know if this is true anymore
because we just had this pretty surprising finding,
which is not published yet,
where we were trying to figure out,
could it be that certain arms are specialized for certain finds,
Maybe it's not that they're all tongues, as you said.
Maybe they're all doing different things.
I don't know.
And so we looked at the various arms, and we paid close attention to the specialized arm
of the male octopus called the hectoratolus.
And the hectoratocotilus is used specifically for mating.
And so how octopus is mate is the male finds the female.
They're not very social creatures generally.
And so upon rare encounter, the male will find the female.
And then it uses the hectoratolus by inserting the hectocotolus into the female mantle.
And it searches around in the mantle for the ovaries.
And once it detects the ovaries, the two animals pause.
And then the male will transfer a spermatophore, which is a packet of sperm from its mantle,
down the length of its arm to the tip where the ovary is.
and this is how they made.
That's wild.
Just need to pause to say that's wild.
Exactly.
That's wild.
Okay, go on.
So how could this arm, this one specialized arm, find the female one,
and then how could it find the ovary amongst the other organs when it has no other cue, right?
And so we look to see, is this arm specialized?
And actually what we've been finding is that the male hectocotolus does have
have the same sensory receptors that we find in the other arms.
It has a couple that are particularly enriched.
And these sensory receptors also bind metabolites that are secreted by the female ovary.
And so this is telling us that, in fact, these receptors are specialized to bind lots of stuff
and probably to facilitate a vast array of behaviors beyond how we're thinking of taste-by-touch
in context of food, but also to take care of their eggs and to find mates and so on, because this is
a very, you know, chemosensory-driven animal. How are their other senses? How's their vision?
Their vision is exceptionally good. They have a huge visual system. A big part of their brain, the optic
globe, is devoted to vision. Vision is another puzzling aspect of the cephalopod, one in
which we're also actively exploring right now.
So cephalopods are traditionally thought to be colorblind,
yet they can do, as you probably know,
very complicated camouflage displays of all different kinds of colors.
So how is it that they can color match if they can't see color?
Yeah, that's mysterious.
The reason that they're thought to be colorblind
is they have only one option,
which is the protein that's used to detect light.
And so we have several different options,
which absorb several different wavelengths,
and that's why we can see color.
So if the octopus only has one, how can it see color?
And so this is something that we're exploring,
which is how can this option in this context?
Does it truly absorb in one wavelength?
Are there many?
Are there other light signals that contribute?
This is a very puzzling area of cephal.
behavior. Do you think they can see color? I don't know. I would say that all the evidence in literature
suggests that they can't. What I'll say is pretty much every time that we've went into studying
these animals, we end up finding something unexpected and different than what we imagined. And
I think that that's fascinating for learning about cephalopods, learning about octopuses. But it's
really also a nice reminder as a scientist to be open-minded and to let biology guide you to something
different. And that's something that the cephalopod to us has been great for, you know,
training people to learn how to do science, too. That's a lovely thought. Have you always been an
octopus freak? Has this been a lifelong dream to work with cephalopods? I don't know. I would say no.
We have, my lab has had over 100 different species of animals.
We have lots of stuff in here that we're studying.
We also have protists, plants, fungi.
We study lots of different organisms and we try to compare different evolutionary
novelties like what we're talking about and octopus to see, you know, what are broad
principles, what are extremes.
So I would say scientifically no.
But then again, I don't.
I don't know. I didn't plan to study octopus even when I came here. But if you go and visit one in an
aquarium, they're just such striking creatures. And even if I remove myself from being a scientist,
they really do inspire wonder in the natural world, which is why we do science. And so in that way,
they've always been an attractive model. Attractive model isn't making my heart sing exactly. You have
over 100 species in your lab. What animal is really capturing your heart right now? Maybe my favorite
animal of all time. And I don't want to say, I mean, we have a lot of great projects. I like
everyone's stuff. But maybe my personal favorite animal is the so-called photosynthetic sea slug,
which I think is just totally nuts. They eat algae and then they suck out the chloroplas and they
retain them in their own bodies to do photosynthesis, which is very weird.
And then they'll eventually digest these chloroplasts once they're severely starved,
and then they can resist starvation for an incredibly long period.
It's something that we've just published a new study about and how they do this.
How can they retain these chloroplast?
Because the question is, if the chloroplast is removed from its natural habitat,
which is the algal or plant cell, how does it get new proteins?
How does it keep functioning?
How does the slug do that because it's now in a slug cell?
And what we found is that the slug actually has this organelle it makes
that takes up the chloroplast, sort of like an endosimbiosis,
like how mitochondria are, mitochondria formed a really long time ago
from an ancient prokaryotic cell.
But the slug managed to do this in one lifetime.
It takes in the chloroplast.
It houses it in this organelle.
It sustains it to do photosynthesis.
And then once it's really hungry, it digest the chloroplasts
and gets an extra boost of energy.
Okay.
I'm sold.
We can have two weeks.
Ceplepod week, which we're giving our full heart and love and attention to right now.
But I see C-slug week on the horizon.
Sounds good.
Thanks, Nick.
All right, thank you.
Dr. Nicholas Bolono, Professor of Molecular and Cellular Biology at Harvard University in Cambridge, Massachusetts.
Are you hungry for more octopus stories?
Head over to ScienceFriday.com to read about an octopus garden discovered in Canada.
This is an underwater nursery where a group of octomoms care for their babies,
and yes, obviously we have baby octopus picks.
You can also find cephalopod,
themed games and hands-on educational activities all at Science Friday.com.
Thanks for listening. Don't forget to rate and review us wherever you listen. It really does help
us get the word out and get the show in front of new listeners. Today's episode was produced
by Shoshana Bucksbaum. I'm Flora Lichtman. Thanks for listening.