Humans aren’t the only mammals that form long-term bonds with a single, special mate – some bats, wolves, beavers, foxes, and other animals do, too. But new research from Duke University suggests the brain circuitry that makes love last in some species may not be the same in others.

The study compares monogamous and promiscuous species within a closely related group of lemurs, distant primate cousins of humans from Madagascar. Red-bellied lemurs and mongoose lemurs are among the few species in the lemur family tree in which male-female partners stick together year after year, working together to raise their young and defend their territory. Once bonded, pairs spend much of their waking hours grooming each other or huddled side by side, often with their tails wrapped around each other’s bodies. Males and females of these species spend a third of a lifetime with the same mate. The same cannot be said of their closest relatives, who change partners often.

To biologists, monogamy is somewhat a mystery. In part, it’s because monogamy is rare in many animal groups. While around 90% of bird species practice some form of fidelity to one partner, only 3% to 5% of mammals do. “It's an uncommon arrangement,” said Nicholas Grebe, a postdoctoral associate at Duke and the study’s lead author.

So, what makes some species biologically inclined to pair up for the long haul while others play the field?

Studies over the last 30 years in rodents point to two hormones released during mating, oxytocin and vasopressin, suggesting that the key to lasting love may lie in differences in how they act on the brain. These “cuddle chemicals” were found to enhance male-female bonds in prairie voles, mouse-like mammals that, unlike most rodents, mate for life.

Researchers have long wondered if they might work the same way in humans. That’s why the Duke-led team turned to lemurs. Despite being our most distant primate relatives, lemurs are a closer genetic match to humans than voles are.

The researchers used an imaging technique called autoradiography to map binding sites for oxytocin and vasopressin in the brains of 12 lemurs that had died of natural causes at the Duke Lemur Center. The animals represented seven species: monogamous red-bellied and mongoose lemurs along with five promiscuous species in the same genus. “They’re really the only comparable natural experiment to look for biological signatures of monogamy in primates,” Grebe said.

Comparing the brain imaging results in lemurs with previous results in voles and monkeys revealed some noticeable differences in the density and distribution of hormone receptors. In other words, oxytocin and vasopressin appear to act on different parts of the brain in lemurs, which means they may also have different effects, depending on their target cell’s location. But within lemurs, the researchers were surprised to find few consistent differences between monogamous species and promiscuous ones. “We don’t see evidence of a pair-bond circuit” akin to that found in rodent brains, Grebe said.

As a next step, the team is looking at how lemur couples behave toward each other if the actions of oxytocin are blocked, by feeding them an antagonist that temporarily prevents oxytocin from binding to its receptors in the brain.

So what can lemurs teach us about love? The authors say their findings caution against drawing simple conclusions based on rodent experiments about how human social behaviors came to be. Oxytocin may be the “potion of devotion” for voles, but it may be the combined actions and interactions of multiple brain chemicals, along with ecological factors, that create long-lasting bonds in lemurs and other primates, including humans, Grebe said.

“There are probably a number of different ways through which monogamy is instantiated within the brain, and it depends on what animals we're looking at,” Grebe said. “There's more going on than we originally thought.”

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