Scientific American - 11.2019

20 Scientific American, November 2019

ADVANCES

BIOLOGY

Hatchlings

with Vision

Jumping spider babies are

the size of a grain of sand

but see surprisingly well

Adult jumping spiders are littler than

a fingernail, but their vision is as clear

as a small dog’s. And the babies, with

heads a hundredth the size of their par-

ents’, may see in almost as much clarity.

Researchers have now discovered a

mechanical secret behind this remarkable

hatchling ability.

“Even arachnophobic people find these

little jumping spiders to be compelling—

they dance, they sing vibratory songs to

each other,” says Nathan Morehouse, a co-

author of the study published in July in

Vision Research. (Morehouse started the

research at the University of Pittsburgh

and finished it at the University of Cincin-

nati.) And the spiders’ extraordinary visual

ability captivates many scientists.

“Everyone I know who works on vision

just loves jumping spiders,” says Jamie

Theobald, who studies insect vision at

Florida International University and was

not involved in the new study. “How they

accommodate such amazing visual behav-

iors is a pretty important question.”

Researchers have observed that young

jumping spiders can use complex visual

cues while hunting. To find out how young-

sters’ vision is so close to adults’, More-

house and his colleagues peered into one of

the spiders’ four sets of eyes (a forward-fac-

ing, motion-sensitive pair) in 22 individuals

using a micro-ophthalmoscope, a miniature

version of an eye doctor’s tool.

The researchers counted

roughly 7,000 photoreceptor

cells per eye in early juvenile, late juvenile

and adult spiders. They also examined sev-

en of the spiders twice, four months apart,

and found that none of them produced

new photoreceptors.

That measurement indicates the spi-

ders do not add receptors as they grow

but cram in all these cells by the time they

hatch—“Which is a crazy thing to do!”

Morehouse says. According to the team’s

earlier genetic research, the tiny spiders

most likely share an “ancient genetic tool

kit” with insects: their bodies first con-

struct the photoreceptors, then top them

off with lenses. That mechanism makes

sense for certain insects that add new pho-

toreceptors, capped with separate lenses,

to their eyes as they grow larger. But it is

developmentally cumbersome for spiders,

whose eyes each accommodate only one

lens and so need all their photoreceptors in

place early in life.

These results suggest spiderlings see as

much detail as adults, with a comparable

field of vision—although there are draw-

backs. For instance, baby spiders’ tiny pho-

toreceptors provide poor light sensitivity.

Morehouse has seen evidence of this him-

self: “They’re a little bit stumbly,” he says.

The eyes’ biological structure cannot

tell scientists everything about how the

spiders see. “They may be making trade-

offs at the neural level,” Theobald says,

such as restoring some sensitivity at the

expense of spatial or temporal detail. For

that reason, behavioral studies are neces-

sary to fully understand spiders’ vision. But

the biological results alone are surprising,

Theobald says: “To have to have all your

photoreceptors right from the beginning?

It’s not the way I would build a spider.”

—Leila Sloman

Adult female

and spiderling

Phidippus audax

DANIEL ZUREK

Morehouse Lab

© 2019 Scientific American

20 Scientifi c American, November 2019

ADVANCES

BIOLOGY

Hatchlings

with Vision

Jumping spider babies are

the size of a grain of sand

but see surprisingly well

Adult jumping spiders are littler than

a fi ngernail, but their vision is as clear

as a small dog’s. And the babies, with

heads a hundredth the size of their par-

ents’, may see in almost as much clarity.

Researchers have now discovered a

mechanical secret behind this remarkable

hatchling ability.

“Even arachnophobic people fi nd these

little jumping spiders to be compelling—

they dance, they sing vibratory songs to

each other,” says Nathan Morehouse, a co-

author of the study published in July in

Vision Research. (Morehouse started the

research at the University of Pittsburgh

and fi nished it at the University of Cincin-

nati.) And the spiders’ extraordinary visual

ability captivates many scientists.

“Everyone I know who works on vision

just loves jumping spiders,” says Jamie

Theobald, who studies insect vision at

Florida International University and was

not involved in the new study. “How they

accommodate such amazing visual behav-

iors is a pretty important question.”

Researchers have observed that young

jumping spiders can use complex visual

cues while hunting. To fi nd out how young-

sters’ vision is so close to adults’, More-

house and his colleagues peered into one of

the spiders’ four sets of eyes (a forward-fac-

ing, motion-sensitive pair) in 22 individuals

using a micro-ophthalmoscope, a miniature

version of an eye doctor’s tool.

The researchers counted

roughly 7,000 photoreceptor

cells per eye in early juvenile, late juvenile

and adult spiders. They also examined sev-

en of the spiders twice, four months apart,

and found that none of them produced

new photoreceptors.

That measurement indicates the spi-

ders do not add receptors as they grow

but cram in all these cells by the time they

hatch—“Which is a crazy thing to do!”

Morehouse says. According to the team’s

earlier genetic research, the tiny spiders

most likely share an “ancient genetic tool

kit” with insects: their bodies fi rst con-

struct the photoreceptors, then top them

off with lenses. That mechanism makes

sense for certain insects that add new pho-

toreceptors, capped with separate lenses,

to their eyes as they grow larger. But it is

developmentally cumbersome for spiders,

whose eyes each accommodate only one

lens and so need all their photoreceptors in

place early in life.

These results suggest spiderlings see as

much detail as adults, with a comparable

fi eld of vision—although there are draw-

backs. For instance, baby spiders’ tiny pho-

toreceptors provide poor light sensitivity.

Morehouse has seen evidence of this him-

self: “They’re a little bit stumbly,” he says.

The eyes’ biological structure cannot

tell scientists everything about how the

spiders see. “They may be making trade-

off s at the neural level,” Theobald says,

such as restoring some sensitivity at the

expense of spatial or temporal detail. For

that reason, behavioral studies are neces-

sary to fully understand spiders’ vision. But

the biological results alone are surprising,

Theobald says: “To have to have all your

photoreceptors right from the beginning?

It’s not the way I would build a spider.”

—Leila Sloman

Adult female

and spiderling

Phidippus audax

DANIEL ZUREK

Morehouse Lab

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