FEAR-OMONEVIDEO | The Grueneberg ganglion, composed of about 500 neurons, is an alarm pheromone sensor.Science/AAAS
Fear stinks. And its stench tickles a recently re-discovered
set of nerves in the tip of a mouse’s nose.
Swiss researchers report in the Aug. 22 Science that they have finally found a function for a structure
called the Grueneberg ganglion. The structure, composed of about 500 neurons, is
an alarm pheromone sensor, say Marie-Christine Broillet, a neurophysiologist at
the University of
Lausanne, and her colleagues.
“It’s an interesting paper and something the field has been
waiting for, to know what these cells are doing,” comments Minghong Ma, a
neuroscientist at the University of Pennsylvania School of Medicine in Philadelphia.
Alarm pheromones are mysterious substances given off by
animals under stress. The chemicals — no one really knows exactly what
mammalian alarm pheromones look like — signal other members of a species that
something bad is happening. Animals typically respond to the signals by running
away, freezing (so predators won’t notice them) or attacking, Broillet says.
Researchers have yet to identify the source of the alarm
pheromones in mammals and until now had no idea how mice, humans and other
animals detected chemical fear cues.
First described in 1973, the Grueneberg ganglion was largely
forgotten until a few years ago when mice were genetically engineered to
produce a green fluorescent protein in their neurons, Broillet says.
Scientists were surprised to see the clusters of green neurons
sitting all alone at the tip of the mice’s noses. The Grueneberg ganglion sends
long projections, called axons, to the brain’s scent-processing center. But the
ganglion is separate from other odor and pheromone-sensing structures and its
function was unknown.
The structure is fully developed at birth, so some researchers
believe it is involved in helping mothers and pups recognize each other. But the
new study found that neurons in the ganglion don’t respond to milk or other
mammary secretions. The neurons are also oblivious to odors, known mouse
pheromones, urine, temperature, pressure and acidity.
Because the Grueneberg ganglion didn’t respond to anything
the team tried, the researchers decided to look at its structure instead.
“We learned a lot
from the electron microscopy,” Broillet says. The neurons in the Grueneberg
ganglion are covered with skin, have cilia — fingerlike projections often found
on scent-detecting cells — and are wrapped with support cells called glia. The
skin and wrappings shield the cells from direct contact with irritants.
“It’s a dangerous world out there,” says Charles Derby, a
chemical ecologist and neuroscientist at GeorgiaStateUniversity
in Atlanta, who
studies chemical sensing in spiny lobsters. “You need your sensors out there
interacting with the environment, but you also need protection.”
Such protective measures mean the cells probably detect
volatile, water-soluble substances that can pass through the protective barrier.
Alarm pheromones fit the bill. The Swiss researchers collected alarm cues from
mice dying of carbon dioxide poisoning. Those alarm chemicals sparked activity
in Grueneberg ganglion cells, and affected other mice’s behavior. Normal mice
ran away from a tray of water containing the alarm pheromones and froze in the
corner. Mice that had surgery to remove the ganglion continued exploring as if
they were blind to the smell of fear, but had no trouble locating an Oreo
cookie hidden in bedding.
Not everyone is convinced that the Grueneberg ganglion
actually detects alarm pheromones.
“I don’t think that their ‘alarm pheromone’ is a pheromone,”
says Yasushi Kiyokawa, a veterinary researcher at the University of Tokoyo
who studies alarm pheromones in rats. The signal could be a non-specific odor
given off by dead and dying animals. “However,
I am convinced that this organ detects some aversive odor in mice.”
Humans have a Grueneberg ganglion. But other structures that
humans and rodents share detect pheromones and odors for rodents, but don’t
work in people, Ma says. Rodents are visually challenged so they rely on their
sense of smell. But humans have language. “We probably yell out instead of
waiting for a chemical signal,” she says.
They should have tried CO2 or ammonia. It's really strange that they didn't. A human fear pheromone has been detected by an Austrian group. Doubtless it's been identified, synthesized, and weaponized by America by now. The human pheromone that stops criminal, addictive, and sexually perverse behavior is adult male facial skin surface lipid (700+ chemicals that all look just like butterfly pheromones, including sebaleic acid found nowhere else in nature), 150 mg p.o. usually does the trick in a single dose. Nicholson
Ross Nicholson
Aug. 28, 2008 at 10:35pm
It would be interesting to test the human fear response through smell, as it seems to appear in very young children. Mine picked up on the fear of others before they put two words together, in other words before they understood linguistic cues to danger. It was not always facial expression, either, since they got the message from cartoon characters in distress -- although that would not have been from smell, either! It may have been tone of voice.
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A human fear pheromone has been detected by an Austrian group. Doubtless it's been identified, synthesized, and weaponized by America by now.
The human pheromone that stops criminal, addictive, and sexually perverse behavior is adult male facial skin surface lipid (700+ chemicals that all look just like butterfly pheromones, including sebaleic acid found nowhere else in nature), 150 mg p.o. usually does the trick in a single dose. Nicholson
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