The Chemistry of Love, According to Neuroscience
The
Chemistry of Love: In Search of the Elusive Human Pheromones
This year, science marks the 50th anniversary of the
discovery of pheromones, the sexed-up secretions that can set off a mating
frenzy in myriad species, from moths to mammals. But for all the recent
attention focused on these “love chemicals” by researchers and the media,
what’s often lost on the public (and in the hype of marketing claims from some
fragrance makers) is that no one has yet proven that pheromones exist in
humans.
That fact was underscored recently by pioneering pheromone
researcher Tristram D. Wyatt, Ph.D., who wrote in a January 2009 commentary in
Nature1: “So far, no [human] pheromones have been conclusively identified,
despite stories in the popular press.”
There’s no question that something – some kind of
chemical signaling that is picked up, consciously or non-consciously, by our
sense of smell – influences one person’s reaction to another person. It’s also
clear that species across the animal kingdom use a wide array of pheromones to
communicate with one another for mating purposes and many other behaviors (ants
use pheromones to mark trails, for example). There are solid clues that the
same sort of chemical signals do indeed influence human reproductive physiology
and behavior, although in decidedly more subtle ways than in animals. But the
debate is not settled over whether these mysterious chemical cues can be called
“pheromones.”
“There is a lot of scientific evidence that multiple
species clearly have olfactory messengers that are involved in mating
behaviors. Where it falls short is in humans,” says John G. Hildebrand, Ph.D.,
a University of Arizona neuroscientist who studies pheromones in insects.
“There is no evidence yet that stands up to scientific scrutiny, in my opinion,
to show that any factor or substance that people have isolated, marketed, or
claimed to have ‘pheromone activity’ really does in humans.”
Lifting
the Pall of Pseudoscience
But, he adds wryly: “That hasn’t stopped people from
selling what they call ‘human pheromones.’” In fact, dozens of companies are
peddling products supposedly laced with “human pheromones.” A Google search of
the term brings up a swath of them, complete with scientifically dubious – or
just plain outrageous – claims of powerful effects on the opposite sex. Such
practices have, by some accounts, cast a pall of pseudoscience over the field
of human pheromone research, which has frustrated serious scientists.
That pall may be lifting as rigorous scientific evidence
grows that humans do indeed respond physiologically and behaviorally to a broad
repertoire of chemical signals – what might be called pheromones in any other
species. (Wyatt prefers to call them “signature odors.” Other researchers use
“putative” when referring to human pheromones, which essentially means: “we think
that’s what they are but we can’t say that yet because the data is
inconclusive.”)
Hildebrand, a member of the Dana Alliance for Brain
Initiatives, is among those in the field who fully expect that “eventually,
concrete evidence will be found that there is an olfactory component to human
attraction and consummation of mating, because it’s true in so many other
species, including mammals.” He points to “tantalizing tidbits that have been
known for a long time.” Top among them is landmark research by University of
Chicago psychologist Martha McClintock, Ph.D., showing how the menstrual cycles
of women living in close proximity tend to synchronize, along with other data
showing that women’s olfactory acuity varies depending on where they are in
their ovarian cycle. “These are strong suggestions that something is going on
that is linking olfaction with reproductive function,” says Hildebrand.
The problem is that no one has yet identified the
molecular compound at the root of these reported effects. It may only be a
matter of time. As Wyatt pointed out in his Nature essay: “As we’re mammals, we
are likely to use pheromones.” Why, then, after a half-century of study into
pheromones, has their role in humans not been better clarified?
Human Love Is…Uh, Complicated
The simple answer is that humans are more complicated
than other species, particularly when it comes to love and sexual attraction.
For one thing, we clearly use more than our nose to sniff out Mr. or Ms. Right.
Unlike mice and many other animals, in which up to a third of the brain is
involved in processing odorants, primates’ brains are more oriented to visual
perception than to olfactory cues.
As humans, we also think. The neocortex, the
“higher-thinking” part of the brain that evolved most recently and sets us
apart from most other species, exerts a measure of control over more primal,
innate impulses. (Though these control brakes clearly fail at times, as anyone
who has experienced irrational lust that is later regretted knows.) The very
cognitive abilities that make us different – attention, alertness, expectation,
and learning from previous experience, for example – modulate our response to any
signals wafting our way, making it difficult to sort out the role of those
signals.
The chemical signals themselves are more complex in
humans, a fact evident by the failure to identify and characterize a single
human pheromone, despite significant efforts to do so. There are hundreds –
maybe thousands – of candidates, and they interact in complex ways. Even in
insects, where pheromone-based communications are well characterized, it’s rare
to find a single substance that has a clear pheromonal effect by itself. A
clear lesson from five decades of pheromone research in other species is that,
as Hildebrand puts it: “The message is in the mixture, not in any one
individual compound.”
Moreover, different pheromones work in different ways.
The best-known pheromones, like the sex attractants that can lure moths to a
mate from great distances, are “releaser” pheromones – they have an
instantaneous effect on behavior and fit the classic definition of pheromones.
But much less understood are so-called “primer” pheromones. Instead of
triggering an immediate behavior, these compounds “prime the organism with
changes in physiology so that the organism subsequently responds differently to
certain stimuli,” says Hildebrand. Chemical cues that affect human reproductive
behavior “could well act as a primer and not as a releaser,” he says, making
them harder to nail down.
One
Scent Does Not Fit All
Even if – or when – researchers are able to prove beyond
a shadow of doubt that they’ve pinpointed a human pheromone, any such compound
is almost certain to have different effects in different people. There’s strong
evidence that the exact same chemical odorant can elicit opposite sensations,
giving one person the warm-fuzzies and another the willies.
One possible explanation is the well-documented tendency
of animals and humans to prefer odors from genetically dissimilar individuals,
which has been shown by McClintock’s group at the University of Chicago, by
researchers at the Monell Chemical Senses Center in Philadelphia, and various
other research teams. Taken as a whole, the evidence suggests strongly that
women, in particular, can detect even subtle differences in gene variants that
code for immune-system molecules known as major histocampatibility complex, or
MHC. Such results make sense from an evolutionary standpoint, since selecting a
mate that is not too similar genetically is advantageous.
“People who have different genetics, including MHC genes,
are likely to produce different kinds of scents,” says Duke University neurobiologist
Hiroaki Matsunami, Ph.D. “So, maybe by smelling, we are actually sniffing how
genetically different the other person is compared to ourselves.”
Matsunami’s laboratory, in collaboration with Leslie
Vosshall, Ph.D., at The Rockefeller University, has recently uncovered more
compelling evidence that genetic make-up plays a role in this individual
variability of humans’ responses to putative pheromones.
Their focus was a proposed human pheromone called
androstenone, which along with a related compound, androstadienone, is derived
from the male sex steroid testosterone. Androstenone has well-established
pheromonal activity in pigs: it is secreted in the saliva of male pigs and when
female pigs in estrus detect it, it triggers a receptive posture that allows
the males to mate. In humans, its effects are less overt, but there is some
evidence that it induces physiological responses in both men and women,
including effects on autonomic nervous system function, cortisol levels, and
mood.
Some people react favorably to the scent of androstenone,
finding it pleasant or sweet, while others find it repulsive. Still others
don’t consciously perceive any smell when exposed to it. Intrigued by these
contradictory responses, and by studies of twins that suggested there might be
a genetic component to them, Matsunami and colleagues set out to find the genes
involved. They wondered if small variations in the genes – so-called single
nucleotide polymorphisms (SNPs) – might explain the observed variability in sensitivity
to smells.
They examined hundreds of candidate genes before hitting
pay dirt: a gene dubbed OR7D4 whose protein product acts as a selective and
potent receptor for androstenone. Digging further, they identified two
different SNPs, or variants of the gene, that correlated with people’s
perceptions about the smell of androstenone. People who inherited two copies of
the functional form of the gene (one from each parent) described it as “sweaty”
or “urine.” In contrast, people who inherited only one copy, or no copy, either
couldn’t smell it at all or described its smell as “sweet” or “vanilla.” The
findings represent the first time anyone has identified SNPs in odor receptor
genes that affect an individual’s discernment and perception of scents.
“Our hypothesis is that there is a sort of competition
going on in the brain between this receptor and others that have less
pronounced effects, and when OR7D4 activation wins, people feel disgusted by
the smell of androstenone,” Matsunami says. “But if you have less input from
this receptor – if the gene was mutated or you inherited just one copy of it,
for example – then those less sensitive receptors may win, leaving you feeling
more comfortable and pleasant.”
Matsunami, Vosshall, and their teams are now focused on
identifying the other gene variants and receptors that might be responsible for
the sweeter sensations of androstenone, and already have a number of candidate
genes in their sights. Notably, with one receptor for androstenone now known,
the door is wide open for a clearer examination of the compound’s specific
effects on physiology and behavior – work that might just settle the question
of whether androstenone and its chemical cousins can rightly be called human
pheromones.
Longstanding
Dogma Overturned
Another example of how rigorous scientific investigation
is changing the way people think about human pheromones is unfolding at the
Harvard laboratory of neurobiologist Catherine Dulac, Ph.D. One reason many
scientists have resisted the idea of human pheromones was the longstanding
dogma that mammals sense the chemical signals through an “accessory” olfactory
system – the so-called vomeronasal organ – that doesn’t exist in humans.
Through a series of carefully controlled experiments, Dulac’s team has effectively
shattered that tenet.
They started by disabling the vomeronasal organ in
experimental mice, essentially shutting down its pathway to the brain. If the
old dogma were true, the mice would be unresponsive to pheromones from other
mice and unable to mate. Instead, the mice performed normally. Then, in another
group of mice, the researchers disabled the main olfactory pathway, a system
that is evolutionarily conserved in humans and many other species. To the great
surprise of the scientists, these mice had profoundly abnormal behavior: they
were completely unable to mate, and males were wholly uninterested in females.
The finding confirmed that the sense of smell is essential for reproductive
behavior in mice, but the vomeronasal organ seemingly had nothing to do with
it.
“This was surprising to us because it showed that the
animals’ main sense of smell was involved in triggering these innate mating
behaviors, whereas these behaviors had previously been thought to be triggered
by non-conscious smell perception,” says Dulac. “It was also quite interesting
because humans do not have a vomeronasal organ but they do have a main sense of
smell, so it’s entirely possible that animals in general – not just mice but
maybe primates and even humans as well – are able to detect pheromones through
the main olfactory pathway.”
Dulac’s revelations have thrust open a new avenue for
pheromone research on mammals, and should put to rest the argument against
human pheromones based on the absence of a functional vomeronasal system in
humans. To Hildebrand, her work is further proof that “there are a lot of
perceptions out there about pheromone neurobiology and olfactory physiology in
mammals that turn out to be absolutely dead wrong.”
Image Source: http://www.sxc.hu/photo/1413274
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