This article was originally published at The Conversation and has been republished under Creative Commons.

A solid white mass found in a broken jar in an ancient Egyptian tomb has turned out to be the world’s oldest example of solid cheese.

Probably made mostly from sheep or goat milk, the cheese was found several years ago by archaeologists in the ancient tomb of Ptahmes, who was a high-ranking Egyptian official. The substance was identified after the archaeology team carried out biomolecular identification of its proteins.

This 3,200-year-old find is exciting because it shows that the ancient Egyptians shared our love of cheese—to the extent it was given as a funerary offering. But not only that, it also fits into archaeology’s growing understanding of the importance of dairy to the development of the human diet in Europe.

Dairy in diets

About two-thirds of the world’s population is lactose intolerant. So although dairy products are a daily part of the diet for many living in Europe, northern India, and North America, drinking milk in adulthood was only possible from the Bronze Age, over the last 4,500 years.

For most of human history, adults lost the ability to consume milk after infancy—and the same is true of people who are lactose intolerant today. After weaning, people with lactose intolerance can no longer produce the enzyme lactase. This is necessary to break down the lactose sugars in fresh milk into compounds that can be easily digested. People with lactose intolerance experience unpleasant symptoms if they consume dairy products, such as bloating, flatulence, and diarrhea.

This map shows the percentage of adults that can digest lactose in the Indigenous populations of the Old World. Circles mark sample locations. Joe Roe

Ancient DNA analysis on human skeletons from prehistoric Europe places the earliest appearance of the lactase gene (LCT)—which keeps adults producing lactase—at 2500 B.C. But there is plenty of evidence from the Neolithic period (around 6000–2500 B.C. in Europe) that milk was being consumed.

This is not totally surprising though, as the Neolithic marks the start of farming in most regions of Europe—and the first time humans lived closely alongside animals. And although they were unable to digest milk, we know that Neolithic populations were processing milk into substances they could consume.

Archaeological evidence

Using a technique called lipid analysis, sherds of ancient pottery can be analyzed and fats absorbed into the clay identified. This then allows archaeologists to find out what was cooked or processed inside them.

Although it is not yet possible to identify the species of animal, dairy fats can be distinguished. It is also challenging to determine what techniques were being used to make dairy products safe to consume, with many potential options. Fermenting milk, for example, breaks down the lactose sugar into lactic acid. Cheese is low in lactose because it involves separating curd (from which cheese is made) from whey, in which the majority of the lactose sugars remain.

Clay sieves from Poland, similar to modern cheese sieves, have been found to have dairy lipids preserved in their pores, suggesting that they were being used to separate curds from the whey. Whether the curds were then consumed or attempts were made to preserve them by pressing them into a harder cheese is unknown. Fermentation of milk was also possible to our ancestors, but harder to explore with the techniques currently available to archaeology.

Early cheese making

While the techniques from bioarchaeology have provided this fantastic detail on Neolithic diets, where the science stops, experimental archaeology can explore what was possible.

We have been making cheese using the utensils, plants, and techniques available to Neolithic farmers. The aim of the experiments is not to faithfully recreate early cheeses, but to begin to capture some of the decisions available to early cheese makers—and the experiments have thrown up some interesting results.

By using these ancient techniques, we have discovered that a wealth of different means of curdling the milk would have been possible, each producing different forms, tastes, and amounts of cheese.

And such specialist knowledge may have been akin to the spread of bronze smelting at the end of the Neolithic. Dairy may have had a special status among foodstuffs. For example, at the major late Neolithic feasting site of Durrington Walls, not far from and contemporary with Stonehenge, dairy residues were found in a particular kind of pottery vessel and concentrated in the area around a timber circle—a form of late Neolithic monument.

From the Bronze Age, however, lactase persistence offered an advantage to some people who were able to pass this on to their offspring. It also seems that this advantage was not solely because of increased calorie and nutrient intake, but also because of the special status dairy foods may have had. The development of this biological adaption to fresh milk took place after humans had already found ways to safely include dairy products in the diet.

This shows not only that humans are able to manipulate our food to make it edible, but also that what we consume can lead to new adaptations in our biology.