Scientists long thought that Neanderthals were avid meat eaters. Based on chemical analysis of Neanderthal remains, it seemed like they’d been feasting on as much meat as apex predators such as lions and hyenas.
But as a group, hominins – that’s Neanderthals, our species and other extinct close relatives – aren’t specialised flesh eaters. Rather, they’re more omnivorous, eating plenty of plant foods, too.
It is possible for humans to subsist on a very carnivorous diet. In fact, many traditional northern hunter-gatherers such as the Inuit subsisted mostly on animal foods.
But hominins simply cannot tolerate consuming the high levels of protein that large predators can. If humans eat as much protein as hypercarnivores do over long periods without consuming enough other nutrients, it can lead to protein poisoning – a debilitating, even lethal condition historically known as “rabbit starvation.”
So, what could explain the chemical signatures found in Neanderthal bones that seem to suggest they were healthily eating tons of meat? I am an anthropologist who uses elements such as nitrogen to study the diets of our very ancient ancestors. New research my colleagues and I conducted suggests a secret ingredient in the Neanderthal diet that might explain what was going on: maggots.
Isotope ratios reveal what an animal ate The ratios of various elements in the bones of animals can provide insights into what they ate while alive. Isotopes are alternate forms of the same element that have slightly different masses. Nitrogen has two stable isotopes: nitrogen-14, the more abundant form, and nitrogen-15, the heavier, less common form. Scientists denote the ratio of nitrogen-15 to nitrogen-14 as d¹5N and measure it in a unit called permil.
As you go higher up the food chain, organisms have relatively more of the isotope nitrogen-15. Grass, for example, has a very low d¹5N value. An herbivore accumulates the nitrogen-15 that it consumes eating grass, so its own body has a slightly higher d¹5N value. Meat-eating animals have the highest nitrogen ratio in a food web; the nitrogen-15 from their prey concentrates in their bodies.
By analysing stable nitrogen isotope ratios, we can reconstruct the diets of Neanderthals and early Homo sapiens during the late Pleistocene, which ran from 11,700 to 129,000 years ago.
Fossils from various sites tell the same story – these hominins have high d¹5N values. High d¹5N values would typically place them at the top of the food web, together with hypercarnivores such as cave lions and hyenas, whose diet is more than 70 per cent meat.
But maybe something else about their diet was inflating Neanderthals’ d¹5N values.
Uncovering the
Neanderthal menu
We suspected that maggots could have been a different potential source of enriched nitrogen-15 in the Neanderthal diet. Maggots, which are fly larvae, can be a fat-rich source of food. They are unavoidable after you kill another animal, easily collectible in large numbers and nutritionally beneficial.
To investigate this possibility, we used a dataset that was originally created for a very different purpose: a forensic anthropology project focused on how nitrogen might help estimate time since death.
I had originally collected modern muscle tissue samples and associated maggots at the Forensic Anthropology Center at University of Tennessee, Knoxville, to understand how nitrogen values change during decomposition after death.
While the data can assist modern forensic death investigations, in our current study we repurposed it to test a very different hypothesis. We found that stable nitrogen isotope values increase modestly as muscle tissue decomposes, ranging from -0.6 permil to 7.7 permil.
This increase is more dramatic in maggots feeding on decomposing tissue: from 5.4 permil to 43.2 permil. To put the maggot values in perspective, scientists estimate d¹5N values for Pleistocene herbivores to range between 0.9 permil to 11.2 permil. Maggots are measuring up to almost four times higher.
Our research suggests that the high d¹5N values observed in Late Pleistocene hominins may be inflated by year-round consumption of ¹5N-enriched maggots found in dried, frozen or cached animal foods.
Cultural practices shape diet
In 2017, my collaborator John Speth proposed that the high d¹5N values in Neanderthals were due to the consumption of putrid or rotting meat, based on historical and cultural evidence of diets in northern Arctic foragers.
Traditionally, Indigenous peoples almost universally viewed thoroughly putrefied, maggot-infested animal foods as highly desirable fare, not starvation rations.
In fact, many such peoples routinely and often intentionally allowed animal foods to decompose to the point where they were crawling with maggots, in some cases even beginning to liquefy.
This rotting food would inevitably emit a stench so overpowering that early European explorers, fur trappers and missionaries were sickened by it.
Yet Indigenous peoples viewed such foods as good to eat, even a delicacy. When asked how they could tolerate the nauseating stench, they simply responded, “We don’t eat the smell.”
Neanderthals’ cultural practices, similar to those of Indigenous peoples, might be the answer to the mystery of their high d¹5N values.
Ancient hominins were butchering, storing, preserving, cooking and cultivating a variety of items.
All these practices enriched their paleo menu with foods in forms that nonhominin carnivores do not consume.
Research shows that d¹5N values are higher for cooked foods, putrid muscle tissue from terrestrial and aquatic species, and, with our study, for fly larvae feeding on decaying tissue.
The high d¹5N values of maggots associated with putrid animal foods help explain how Neanderthals could have included plenty of other nutritious foods beyond only meat while still registering d¹5N values we’re used to seeing in hypercarnivores.
We suspect the high d¹5N values seen in Neanderthals reflect routine consumption of fatty animal tissues and fermented stomach contents, much of it in a semi-putrid or putrid state, together with the inevitable bonus of both living and dead ¹5N-enriched maggots.
What still isn’t known
Fly larvae are a fat-rich, nutrient-dense, ubiquitous and easily procured insect resource, and both Neanderthals and early Homo sapiens, much like recent foragers, would have benefited from taking full advantage of them.
But we cannot say that maggots alone explain why Neanderthals have such high d¹5N values in their remains.
Several questions about this ancient diet remain unanswered. How many maggots would someone need to consume to account for an increase in d¹5N values above the expected values due to meat eating alone?
More experimental studies on changes in d¹5N values of foods processed, stored and cooked following Indigenous traditional practices can help us better understand the dietary practices of our ancient relatives. (The Conversation)