When your size comes down to millimeters and your eyes practically graze the ground, how do you know where to go? Scientists have long been intrigued by the way ants were able to stray dozens of meters from their nests—a long way from home for the tiny insects—yet still manage to find their way back. According to a new study by insect neuroscientists, computer scientists and ethologists based in Canada, Australia, the UK and France, the integrated use of vision and memory responsible for the navigational prowess of certain ant species proves far more sophisticated than previously thought.1 The researchers further show, by observing Spanish desert ants walking in sundry positions—forward, backward or sideways—that their bearings remain unperturbed by the direction that they face, pointing to the unsuspected complexity of ant brains and nervous systems.

Spread and conquer

If ants come in over 12,000 known species today, it is largely thanks to the diversity of their survival tactics, fostering colonies on every continent bar Antarctica. Among the strategies that vary between species are those adopted for returning to the nest after foraging trips. While some ants lay down pheromone scent trails, others, like the Spanish desert ant (Cataglypis velox), rely on vision offered by the multitude of interconnected lenses that make up their compound eyes, associated with an astounding ability to commit to memory scenery observed along a route. Scientists have previously hypothesized that ants navigate by matching the terrestrial cues in front of them to those in their memory bank, memorized from an egocentric perspective, in other words, when facing the path head-on. At the same time, such ants also show an ability to find their way home backward. So how do these two notions fit together?

Reverse, full speed ahead

In a first experiment, the researchers placed barriers around an active nest to direct foragers, goaded by pieces of cookies, along a specific route. Once the ants were familiar with the itinerary, the scientists released them on a homebound leg that involved making a 90° turn. Insects with cookie pieces light enough to lift in their jaws while walking forward dashed home, turning as required. Ants with more unwieldy pieces, however, forced to tow them while walking backward, missed the turn and continued in a straight line—a clear indication that the route’s rear-facing view rang no bells. “This result supports the idea that an ant’s memories of the visual scenes are based on an egocentric perspective,” says the CRCA researcher. “But the question still remained: how then do ants manage to navigate correctly when walking backward?”

It was the same experiment that answered the question when some backward-moving ants made an unexpected show of resourcefulness: they dropped their loads, turned around to take a peek from a front-facing position—evidently calling on their egocentric memory of the correct route—before turning again to retrieve their booty and continue backward in a rectified direction. From this interplay of three types of memory—visual memory of the right track, memory of the cookie’s existence, and memory of where to head back—the ants demonstrated an “impressive ability to coordinate different pieces of information,” which also made their navigational behavior “surprisingly versatile.”

Indeed, no matter what walking position (even sideways), the desert ants stayed on a straight-line course. “Existing literature has argued that ant travel direction was coupled with body orientation,” details Wystrach. “But our results show otherwise: ants can face one direction but move in another. This decoupling implies that their bearings aren’t centered on their own bodies but on the outside world—a system that is particularly flexible as ants can then take account of all types of directional information, including information from egocentric visual memories, regardless of their body orientation.” 

This study highlights the degree of sophistication of insect nervous systems. “Imagine the complexity of the motor control involved when the ant brain tells the legs to walk sideways in a straight line!” enthuses Wystrach. Furthermore, the ants’ behavior attests to “an unsuspected synergy between different insect brain regions.” For example, when an ant peeks frontward to check its position before continuing backward, this action requires “a transfer of information” between the ‘mushroom bodies’ (the part of the insect brain which stores memories on the visual field) and the ‘central complex’ (the one that picks up on the Sun’s position). Wystrach reveals that the team’s long-term goal is to “determine the extent to which these two brain regions work together” to orchestrate how ants find their way. 

But in the shorter term, their research will be a little bit more light-hearted. “When a backward-moving ant drops its cookie to turn around and check its position, it remembers where to pick the cookie up again. But how much does it actually remember about the cookie? How will it react when we replace its large piece with a small one?” No mere prank, the test will help scientists detect the degree of detail of ant memory.