Science Friday - The High-Tech Lab Unlocking Secrets Of Coral Reproduction
Episode Date: September 24, 2025In the heart of San Francisco’s Golden Gate Park, scientists are on the cutting edge of growing coral. Rising ocean temperatures have caused mass coral bleaching, and experts are racing against the ...clock to figure out how to help corals be more resilient to stress.Coral scientist Rebecca Albright joined Host Ira Flatow at our live show at the Fox Theater in Redwood City, California, to talk about the work her lab does to help corals reproduce—romantic lighting and full moons included.Guest: Dr. Rebecca Albright is a coral reef biologist, an associate curator, and a Patterson Scholar at the California Academy of Sciences.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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I'm Flor Lichtenen, and you're listening to Science Friday.
Today on the podcast, a conversation from our live show in Redwood City, California.
Ira talks with the scientist, growing baby corals to make reefs more resilient.
You know, one of the unique pleasures about being in the Bay Area is the proximity to the ocean, close to marine wildlife, live.
We love to see, like, the whales and the dolphins and the sea lions.
But there's also unexpected marine life here and not where you might expect.
Right in Golden Gate Park, you can find a lab on the cutting edge of growing coral.
Scientists are discovering the secrets of coral reproduction in an effort to bring them back from the brink.
I want to introduce you to one of these scientists.
Dr. Rebecca Albright is a coral reef biologist, an associate curator, and Patterson Scholar at the California Academy of Sciences.
Welcome to Science Friday.
I'm excited to be here.
Thank you, Ira.
Were you always involved in the water?
What drew you to being a coral scientist?
I mean, I'm sure I'm not the only person in this room
that dreamed of being a marine biologist as a kid.
I think I just stayed the course.
I was always drawn to the ocean.
I always felt very comfortable and kind of at peace in the water.
I was a competitive swimmer.
In undergrad, I was actually pre-med,
and I decided to study abroad.
in Australia. This was around the year 2000. And I wasn't going to go to Australia and not dive
on the Great Barrier Reef. So I got certified to dive. I'm from Ohio and the Midwest. And so that
certification dive was in a limestone quarry. I did the same thing with you. Yeah. In the spring,
it was cold. It was majestic, I'm sure. So our navigation dive was very much, you know,
20 kicks to the sunken school bus and then 10 kicks to the refrigerator. And then I went from there,
to the Great Barrier Reef, and my first 60 to 70 open water dives were on the Great Barrier Reef in around 2000, 2001, and I just, you know, never looked back.
You know, a lot of people see coral, but they see it in its white skeleton form, which you don't really
appreciate how beautiful it is, right? It's a very charismatic creature, isn't it?
In my completely unbiased opinion, yes, I think so. Yeah, I think one of the things that has really drawn me to corals is that they
are these incredibly charismatic complex organisms, but in a really unassuming and non-obvious way.
I mean, if you look at this animal, most people actually don't even understand that they are animals.
Most people think that they are rocks.
And when you take a closer look at them, you realize that they are these very sophisticated,
very complex animals that the extent to which you can visualize this,
What this, this is probably, this is part of a coral colony that, in a crop row colony, that is obviously no longer living.
This is the white skeleton that was underneath.
And when this animal was living, what there was was a very thin veneer of animal tissue that coated and covered this skeleton,
much like your thin tissue covers and coats your human bones.
And what's really fascinating about them is they're colonial critters.
And so what this animal started life as was one tiny little sesame seed-sized larva that swam around in the ocean, no bones, completely just tissue, swam around in the ocean, and then found a place to settle, metamorphose, and start calcifying.
And then it asexually budded new mouths and started to grow over time.
And then eventually formed a colony like this, every single one of these tiny little bumps, millimeter to centimeter size, depending on the species.
is a single polyp.
And this animal started life as a single polyp.
Wow.
And then once it grows to this size,
which this animal might have been about 8, 10 years old,
they're all sharing resources
and communicating within this animal
that allows it to exist as one singular organism.
So they have canals inside of their skeleton
and their tissue where they're sharing resources,
shunting nutrients to one another.
it's really quite a sophisticated and beautiful process.
And this was a bunch of beautiful, colorful animal,
which is now bleached white skeleton.
Yes.
What causes that?
Well, in this case, I just bleached it.
But in nature, the concern with coral bleaching worldwide right now
is that it's a stress response.
And coral bleaching is a stress response to pretty much any stressors.
Coral animals can stress bleach in response to salinity stress.
or cold water or light stress.
The elephant in the room at this point in time is global warming and warming of the oceans
causing global mass bleaching where what we're seeing are the majority 84% in the current
one that's happening, 84% of the reefs worldwide bleaching at the exact same time.
And what happens, and obviously that shouldn't be happening.
And what happens is that the animal tissue that coats this is also the
this very interesting and sophisticated relationship with a symbiotic algae that lives inside of its
tissue. And if you think about corals and coral reefs, they live in these beautiful clear waters.
And the reason those waters are so crystal clear is that there's not a lot of nutrients in that
water column. And so in order to get food, what corals have figured out over hundreds of millions of years
is to try to take on these algae and engulf them into their own cells and have them photosynthesize
in warm, high-lit waters, and then steal the sugars.
And so the algae provide up to 90% of the food and requirements for the animal.
And when the water gets too warm, what happens is they expel the algae.
And in doing so, they've just lost their primary food source,
so they can effectively starve to death.
Wow.
And the algae gives its color.
So when it loses the algae, it looks like you have taken it and dipped it in bleach.
And your job and your lab is to try to save the coral that we have alive now?
I mean, we're doing our part.
There's a lot of people trying to tackle this wicked problem from a lot of different angles.
One of the ways that we are trying to address this problem is figuring out how to get corals to reproduce in captivity for a few different reasons.
One, just as a fundamental model organism that we can study coral reproductive biology.
We want to be able to utilize that content and knowledge as a bio-banking and kind of a NOAA's arc
so that we can replace things that are lost in the wild.
And we also utilize it as an opportunity to develop new restoration techniques that we can port to on-the-ground restoration efforts in the wild.
How many other labs do you think around the world are doing this kind of work?
It's definitely gaining traction.
We were the second in the world to do it in 2018.
now I would say there's probably 50 or 60 worldwide. So it's definitely accelerating in terms of
its importance and prevalence throughout the world really quickly. Let's talk about coral reproduction.
You brought a slide of coral spawning. What is happening?
So corals can reproduce asexually and asexually. So asexually, what a coral will do is you can break
off a branch and just like a starfish, that coral will produce a new branch and the branch will
produce a new coral, but you're only propagating a single genotype. So sexually, the way that corals
reproduce is by releasing sperm and eggs into the water column, and typically this is once a year.
They're what we call broadcast spawners. Most coral species, about 75% of them worldwide are hermaphroditic,
so they have both eggs and sperm in the same colony. That's convenient. It is, except they don't self-fertilize.
Oh, they don't? No. So you still have to have a partner. I see. Does this happen every
month on like clockwork so to speak? Once a year usually. Once a year? Yes. So in most, yes, in most places
it's late summer after a full moon and a few hours after sunset. Sounds very familiar. I mean,
I'm going to ask how do you get them to spawn? Smooth jazz music or what do you, how do you do that?
So we have kind of stood on the shoulders of some researchers in London that have taken the body of literature that's tried to figure out the hierarchy of environmental cues that elicit this once a year event.
And winnowed it down to basically three things.
We have to mimic seasonal cycles because it happens after in summer, late summer.
So these animals have to experience a summer and a winter.
So we keep them in systems where every single day.
we've programmed in that the water temperature is iteratively changing, getting warmer in summer and then cooler in winter.
And then we also have LEDs with different wavelengths of light where we have to simulate sunrises and sunsets.
And we have blue LEDs and white LEDs where we mimic lunar cycles.
And in doing those three things, we have been successful in getting these animals to spawn at the exact same time that they do in the wild in Australia.
Yeah.
We have to take a quick break, but don't go away.
More on this when we come back.
So in this lovemaking tradition here, do you help them along?
Do you catch the spawn?
And you do.
Tell us what you mean by it.
We do.
So we have these nets and very sophisticated.
This is a painter's net from Home Depot.
And what we do is in order to, so it's very much.
like IVF, coral IVF, to be honest, because right now, many coral populations in the wild have
become so depopurate that even if they do spawn synchronously, which a lot of times that process
is breaking down in the wild, they might be so few and far between that the probability of
those gametes meeting up and successfully fertilizing and making new corals is very low.
So there are assisted reproductive efforts where we go out in, in, in the same year, and in the
efforts where we go out in in the wild diving at night or in the lab and we take these and we just kind of
cover the coral colony when we know it's going to spawn and then when it does spawn the gamete bundles
which are bundles that have both egg and sperm in them have a lot of lipids there's a lot of fats and so
they're very buoyant so they will float up into this little collector tube a falcon tube and then when it's
done spawning, we can note what genotype it is, what species it was, and we can take this off,
cap it off, take it back to the lab, and then cryopreserve it for biobanking. We can fertilize things
and make new genotypes that probably wouldn't happen in the wild. And then we settle the coral
larvae and we can outplant them back to the reef. So it's basically you've created a homemade,
looks like an inverted funnel with a net on it. It is. Yes. Sophistic.
Well, whatever works. I'm a big MacGyver person myself, and that looks like what you've gotten
near. So how did the coral, when they're out in the wild, how do they know where to land,
if they're spawning or they're very tiny? How do they know where to go?
Yeah, it's a great question, and I don't think we fully understand all of the details and mechanisms
of that, but basically, once a coral larva exists, you can imagine this tiny,
little sesame seed-sized thing that's in the big wide ocean trying to find a place to set up home for
you know some corals the biggest one we know of is over 500 years old and american samoa named big mama
and um so you want to find a place i mean it's an irreversible decision so you want to find a
place that is um a really good home for the next 10 to 100 years and so even though these larvae look so
simple. They are actually packed with receptors, chemoreceptors, photoreceptors,
neuroreceptive cells. And they swim around. They have two ends. There's an oral end of the larva and an
aboral end. And the aboral end is packed with receptors. And so they swim with that aboral end first
through the water column. And they will actually swim down to the bottom and kind of probe it. It's
really fascinating to watch via microscopy. They probe the bottom, and if they don't like what they
find, which a lot of studies indicate that it has to do with the microbial environment that's on
the substrate and the crustos coralline algae, there's a certain species of algae that they
like that's indicative of good reef health. If they don't like it, then they just swim up and
they'll go find someplace else and probe again. If they do like it, then that aboral end will start to get
fixed to the bottom, it will start to calcify, and it'll start to metamorphose into the oral
end that's up differentiates into polyps and a mouth, and will then start to feed and asexually
bud new mouths. Do you have to reproduce all this? No, they do that part on their own. You just, you know.
Oh, no. No. My choral dance. No, it's kind of interesting. How do you know in your lab if you've
been successful at what you're doing? Yeah, it's a great question. And I mean, success, there's many
different parts to that question. So particularly with broadcast spawners, because there are many
bottlenecks. And so ultimate success is lots of coral juveniles that are, so the biggest success we
have had so far was getting our corals to spawn, fertilizing babies, getting the larvae to settle,
and then rearing them out for three to four years so that they become reproductively viable
and then start spawning with their parent generations.
That was the ultimate success.
And then getting an F2 or a second generation.
Is this out in the wild or is this in your lab?
This was in the lab.
Still in the lab.
Yes.
Did they ever get out into the wild?
So we are not permitted at right now.
So corals are regulated by cites, which is the Convention of International Trade of Endangered
Species.
They're very heavily permanent.
And at this moment in time, we are not permitted to, it's illegal to take them from an aquarium and put them back out into the wild.
So what we do is we try to port the ideas and the concepts.
And so we have a partnership right now with the Roetan Marine Park in Honduras where we have built a lab, just like the one in San Francisco, go down there in Roatan, so that they can do this on their reefs and their backyard.
that's another metric that was really meaningful in terms of success for us.
And so that lab opened in June, and we've now done two spawning events there.
In June, we were able to outplant over 3,000 baby corals, brain corals, back out to the reef.
And the team is actually down there right now with some star corals doing the exact same work.
Is it possible to find corals that are resisting,
climate change and are able to survive and bring them in the lab and have reproduced that.
Yeah, that is something that people are tackling from different angles.
So there are people that go out after a bleaching event.
People sometimes do aerial surveys after a bleaching event and find the survivors.
And then we'll go preferentially either take tissue samples to see what was it about that individual that made it resilient
or take fragments of it and preferentially asexually propagated in a coral farm or a coral garden.
another thing that we're doing in our lab is when you have these pools of larvae very early in life
with the most number of individuals and the most genetic diversity, expose them to a heat stress
and try to select for the survivors and then breed those out with the thought that they might be
able to withstand a bleaching event later.
I want to get this youngster as a question.
Yes, go ahead.
How many creatures depend on the coral for life?
How many creatures depend on corals?
Yeah.
I'm so glad you asked that question.
So about 25% of all of the life in the oceans is supported by coral reefs.
Wow.
So a quarter of all marine life is dependent on coral reefs.
Do you think you love your job a little?
I love my job.
I'm very lucky.
I don't take that for granted.
Yes.
I bet you do.
Well, Dr. Rebecca Albright is a coral reef biologist,
the Associate Curator and Patterson Scholar at the California Academy of Sciences.
Thank you so much for coming on the program today.
Thanks for listening.
Don't forget to rate and review us.
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Today's episode was produced by Kathleen Davis.
I'm Flora Lichtman.
Thanks for listening.