How to pronounce "jewellike"

In the spirit of Jacques Cousteau, who said,

"People protect what they love,"

I want to share with you today what I love most in the ocean,

and that's the incredible number and variety

of animals in it that make light.

My addiction began with this strange looking diving suit called Wasp;

that's not an acronym -- just somebody thought it looked like the insect.

It was actually developed for use by the offshore oil industry

for diving on oil rigs down to a depth of 2,000 feet.

Right after I completed my Ph.D.,

I was lucky enough to be included with a group of scientists

that was using it for the first time

as a tool for ocean exploration.

We trained in a tank in Port Hueneme,

and then my first open ocean dive

was in Santa Barbara Channel.

It was an evening dive.

I went down to a depth of 880 feet

and turned out the lights.

And the reason I turned out the lights is because I knew I would see

this phenomenon of animals making light

called bioluminescence.

But I was totally unprepared

for how much there was

and how spectacular it was.

I saw chains of jellyfish called siphonophores

that were longer than this room,

pumping out so much light

that I could read the dials and gauges

inside the suit without a flashlight;

and puffs and billows

of what looked like luminous blue smoke;

and explosions of sparks

that would swirl up out of the thrusters --

just like when you throw a log on a campfire and the embers swirl up off the campfire,

but these were icy, blue embers.

It was breathtaking.

Now, usually if people are familiar with bioluminescence at all,

it's these guys; it's fireflies.

And there are a few other land-dwellers that can make light --

some insects, earthworms, fungi --

but in general, on land, it's really rare.

In the ocean, it's the rule

rather than the exception.

If I go out in the open ocean environment,

virtually anywhere in the world,

and I drag a net from 3,000 feet to the surface,

most of the animals --

in fact, in many places, 80 to 90 percent

of the animals that I bring up in that net --

make light.

This makes for some pretty spectacular light shows.

Now I want to share with you a little video

that I shot from a submersible.

I first developed this technique working from a little

single-person submersible called Deep Rover

and then adapted it for use on the Johnson Sea-Link,

which you see here.

So, mounted in front of the observation sphere,

there's a a three-foot diameter hoop

with a screen stretched across it.

And inside the sphere with me is an intensified camera

that's about as sensitive as a fully dark-adapted human eye,

albeit a little fuzzy.

So you turn on the camera, turn out the lights.

That sparkle you're seeing is not luminescence,

that's just electronic noise

on these super intensified cameras.

You don't see luminescence until the submersible

begins to move forward through the water,

but as it does, animals bumping into the screen

are stimulated to bioluminesce.

Now, when I was first doing this,

all I was trying to do was count the numbers of sources.

I knew my forward speed, I knew the area,

and so I could figure out how many hundreds of sources

there were per cubic meter.

But I started to realize that I could actually identify animals

by the type of flashes they produced.

And so, here, in the Gulf of Maine

at 740 feet,

I can name pretty much everything you're seeing there to the species level.

Like those big explosions, sparks,

are from a little comb jelly,

and there's krill and other kinds of crustaceans,

and jellyfish.

There was another one of those comb jellies.

And so I've worked with computer image analysis engineers

to develop automatic recognition systems

that can identify these animals

and then extract the XYZ coordinate of the initial impact point.

And we can then do the kinds of things that ecologists do on land,

and do nearest neighbor distances.

But you don't always have to go down to the depths of the ocean

to see a light show like this.

You can actually see it in surface waters.

This is some shot, by Dr. Mike Latz at Scripps Institution,

of a dolphin swimming through bioluminescent plankton.

And this isn't someplace exotic

like one of the bioluminescent bays in Puerto Rico,

this was actually shot in San Diego Harbor.

And sometimes you can see it even closer than that,

because the heads on ships --

that's toilets, for any land lovers that are listening --

are flushed with unfiltered seawater

that often has bioluminescent plankton in it.

So, if you stagger into the head late at night

and you're so toilet-hugging sick

that you forget to turn on the light,

you may think that you're having a religious experience. (Laughter)

So, how does a living creature make light?

Well, that was the question that 19th century

French physiologist Raphael Dubois,

asked about this bioluminescent clam.

He ground it up and he managed to get out a couple of chemicals;

one, the enzyme, he called luciferase;

the substrate, he called luciferin

after Lucifer the Lightbearer.

That terminology has stuck, but it doesn't actually refer to specific chemicals

because these chemicals come in a lot of different shapes and forms.

In fact, most of the people

studying bioluminescence today

are focused on the chemistry, because these chemicals

have proved so incredibly valuable

for developing antibacterial agents,

cancer fighting drugs,

testing for the presence of life on Mars,

detecting pollutants in our waters --

which is how we use it at ORCA.

In 2008,

the Nobel Prize in Chemistry

was awarded for work done

on a molecule called green fluorescent protein

that was isolated from the bioluminescent chemistry

of a jellyfish,

and it's been equated to the invention of the microscope,

in terms of the impact that it has had

on cell biology and genetic engineering.

Another thing all these molecules are telling us

that, apparently, bioluminescence has evolved

at least 40 times, maybe as many as 50 separate times

in evolutionary history,

which is a clear indication

of how spectacularly important

this trait is for survival.

So, what is it about bioluminescence

that's so important to so many animals?

Well, for animals that are trying to avoid predators

by staying in the darkness,

light can still be very useful

for the three basic things that animals have to do to survive:

and that's find food,

attract a mate and avoid being eaten.

So, for example, this fish

has a built-in headlight behind its eye

that it can use for finding food

or attracting a mate.

And then when it's not using it, it actually can roll it down into its head

just like the headlights on your Lamborghini.

This fish actually has high beams.

And this fish, which is one of my favorites,

has three headlights on each side of its head.

Now, this one is blue,

and that's the color of most bioluminescence in the ocean

because evolution has selected

for the color that travels farthest through seawater

in order to optimize communication.

So, most animals make blue light,

and most animals can only see blue light,

but this fish is a really fascinating exception

because it has two red light organs.

And I have no idea why there's two,

and that's something I want to solve some day --

but not only can it see blue light,

but it can see red light.

So it uses its red bioluminescence like a sniper's scope

to be able to sneak up on animals

that are blind to red light

and be able to see them without being seen.

It's also got a little chin barbel here

with a blue luminescent lure on it

that it can use to attract prey from a long way off.

And a lot of animals will use their bioluminescence as a lure.

This is another one of my favorite fish.

This is a viperfish, and it's got a lure

on the end of a long fishing rod

that it arches in front of the toothy jaw

that gives the viperfish its name.

The teeth on this fish are so long

that if they closed inside the mouth of the fish,

it would actually impale its own brain.

So instead, it slides in grooves

on the outside of the head.

This is a Christmas tree of a fish;

everything on this fish lights up,

it's not just that lure.

It's got a built-in flashlight.

It's got these jewel-like light organs on its belly

that it uses for a type of camouflage

that obliterates its shadow,

so when it's swimming around and there's a predator looking up from below,

it makes itself disappear.

It's got light organs in the mouth,

it's got light organs in every single scale, in the fins,

in a mucus layer on the back and the belly,

all used for different things --

some of which we know about, some of which we don't.

And we know a little bit more about bioluminescence thanks to Pixar,

and I'm very grateful to Pixar for sharing

my favorite topic with so many people.

I do wish, with their budget,

that they might have spent just a tiny bit more money

to pay a consulting fee to some poor, starving graduate student,

who could have told them that those are the eyes

of a fish that's been preserved in formalin.

These are the eyes of a living anglerfish.

So, she's got a lure that she sticks out

in front of this living mousetrap

of needle-sharp teeth

in order to attract in some unsuspecting prey.

And this one has a lure

with all kinds of little interesting threads coming off it.

Now we used to think that the different shape of the lure

was to attract different types of prey,

but then stomach content analyses on these fish

done by scientists, or more likely their graduate students,

have revealed that

they all eat pretty much the same thing.

So, now we believe that the different shape of the lure

is how the male recognizes the female

in the anglerfish world,

because many of these males

are what are known as dwarf males.

This little guy

has no visible means of self-support.

He has no lure for attracting food

and no teeth for eating it when it gets there.

His only hope for existence on this planet

is as a gigolo. (Laughter)

He's got to find himself a babe

and then he's got to latch on for life.

So this little guy

has found himself this babe,

and you will note that he's had the good sense

to attach himself in a way that he doesn't actually have to look at her.

(Laughter)

But he still knows a good thing when he sees it,

and so he seals the relationship with an eternal kiss.

His flesh fuses with her flesh,

her bloodstream grows into his body,

and he becomes nothing more than a little sperm sac.

(Laughter)

Well, this is a deep-sea version of Women's Lib.

She always knows where he is,

and she doesn't have to be monogamous,

because some of these females

come up with multiple males attached.

So they can use it for finding food, for attracting mates.

They use it a lot for defense, many different ways.

A lot of them can release their luciferin or luferase in the water

just the way a squid or an octopus will release an ink cloud.

This shrimp is actually

spewing light out of its mouth

like a fire breathing dragon

in order to blind or distract this viperfish

so that the shrimp can swim away into the darkness.

And there are a lot of different animals that can do this:

There's jellyfish, there's squid,

there's a whole lot of different crustaceans,

there's even fish that can do this.

This fish is called the shining tubeshoulder

because it actually has a tube on its shoulder

that can squirt out light.

And I was luck enough to capture one of these

when we were on a trawling expedition

off the northwest coast of Africa for "Blue Planet,"

for the deep portion of "Blue Planet."

And we were using a special trawling net

that we were able to bring these animals up alive.

So we captured one of these, and I brought it into the lab.

So I'm holding it,

and I'm about to touch that tube on its shoulder,

and when I do, you'll see bioluminescence coming out.

But to me, what's shocking

is not just the amount of light,

but the fact that it's not just luciferin and luciferase.

For this fish, it's actually whole cells

with nuclei and membranes.

It's energetically very costly for this fish to do this,

and we have no idea why it does it --

another one of these great mysteries that needs to be solved.

Now, another form of defense

is something called a burglar alarm --

same reason you have a burglar alarm on your car;

the honking horn and flashing lights

are meant to attract the attention of, hopefully,

the police that will come and take the burglar away --

when an animal's caught in the clutches of a predator,

its only hope for escape may be

to attract the attention of something bigger and nastier

that will attack their attacker,

thereby affording them a chance for escape.

This jellyfish, for example, has

a spectacular bioluminescent display.

This is us chasing it in the submersible.

That's not luminescence, that's reflected light from the gonads.

We capture it in a very special device on the front of the submersible

that allows us to bring it up in really pristine condition,

bring it into the lab on the ship.

And then to generate the display you're about to see,

all I did was touch it once per second

on its nerve ring with a sharp pick

that's sort of like the sharp tooth of a fish.

And once this display gets going, I'm not touching it anymore.

This is an unbelievable light show.

It's this pinwheel of light,

and I've done calculations that show that this could be seen

from as much as 300 feet away by a predator.

And I thought, "You know,

that might actually make a pretty good lure."

Because one of the things that's frustrated me

as a deep-sea explorer

is how many animals there probably are in the ocean that we know nothing about

because of the way we explore the ocean.

The primary way that we know about what lives in the ocean

is we go out and drag nets behind ships.

And I defy you to name any other branch of science

that still depends on hundreds of year-old technology.

The other primary way is we go down

with submersibles and remote-operated vehicles.

I've made hundreds of dives in submersibles.

When I'm sitting in a submersible though,

I know that I'm not unobtrusive at all --

I've got bright lights and noisy thrusters --

any animal with any sense is going to be long gone.

So, I've wanted for a long time

to figure out a different way to explore.

And so, sometime ago, I got this idea for a camera system.

It's not exactly rocket science. We call this thing Eye-in-the-Sea.

And scientists have done this on land for years;

we just use a color that the animals can't see

and then a camera that can see that color.

You can't use infrared in the sea.

We use far-red light, but even that's a problem

because it gets absorbed so quickly.

Made an intensified camera,

wanted to make this electronic jellyfish.

Thing is, in science,

you basically have to tell the funding agencies what you're going to discover

before they'll give you the money.

And I didn't know what I was going to discover,

so I couldn't get the funding for this.

So I kluged this together, I got the Harvey Mudd Engineering Clinic

to actually do it as an undergraduate student project initially,

and then I kluged funding from a whole bunch of different sources.

Monterey Bay Aquarium Research Institute

gave me time with their ROV

so that I could test it and we could figure out,

you know, for example, which colors of red light we had to use

so that we could see the animals, but they couldn't see us --

get the electronic jellyfish working.

And you can see just what a shoestring operation this really was,

because we cast these 16 blue LEDs in epoxy

and you can see in the epoxy mold that we used,

the word Ziploc is still visible.

Needless to say, when it's kluged together like this,

there were a lot of trials and tribulations getting this working.

But there came a moment when it all came together,

and everything worked.

And, remarkably, that moment got caught on film

by photographer Mark Richards,

who happened to be there at the precise moment

that we discovered that it all came together.

That's me on the left,

my graduate student at the time, Erika Raymond,

and Lee Fry, who was the engineer on the project.

And we have this photograph posted in our lab in a place of honor

with the caption: "Engineer satisfying two women at once." (Laughter)

And we were very, very happy.

So now we had a system

that we could actually take to some place

that was kind of like an oasis on the bottom of the ocean

that might be patrolled by large predators.

And so, the place that we took it to

was this place called a Brine Pool,

which is in the northern part of the Gulf of Mexico.

It's a magical place.

And I know this footage isn't going to look like anything to you --

we had a crummy camera at the time --

but I was ecstatic.

We're at the edge of the Brine Pool,

there's a fish that's swimming towards the camera.

It's clearly undisturbed by us.

And I had my window into the deep sea.

I, for the first time, could see what animals were doing down there

when we weren't down there disturbing them in some way.

Four hours into the deployment,

we had programmed the electronic jellyfish

to come on for the first time.

Eighty-six seconds after

it went into its pinwheel display,

we recorded this:

This is a squid, over six feet long,

that is so new to science,

it cannot be placed in any known scientific family.

I could not have asked for a better proof of concept.

And based on this, I went back to the National Science Foundation

and said, "This is what we will discover."

And they gave me enough money to do it right,

which has involved developing the world's first deep-sea webcam --

which has been installed in

the Monterey Canyon for the past year --

and now, more recently,

a modular form of this system,

a much more mobile form

that's a lot easier to launch and recover,

that I hope can be used on Sylvia's "hope spots"

to help explore

and protect these areas,

and, for me, learn more about

the bioluminescence in these "hope spots."

So one of these take-home messages here

is, there is still a lot to explore in the oceans.

And Sylvia has said

that we are destroying the oceans before we even know what's in them,

and she's right.

So if you ever, ever get an opportunity

to take a dive in a submersible,

say yes -- a thousand times, yes --

and please turn out the lights.

I promise, you'll love it.

Thank you.

(Applause)