Study: Proteins in tooth enamel offer window into human wellness

a hand wearing a blue lab glove holds small white shards
Photo courtesy of Tammy Buonasera
Scientists used samples of human tooth enamel, similar in size to these samples of wolf tooth enamel, to examine two immune proteins: immunoglobulin G and C-reactive protein.

A new way of looking at tooth enamel could give scientists a path to deeper understanding of the health of human populations, from the ancient to the modern.

The method, published this week in the Journal of Archaeological Science, examines two immune proteins found embedded in human tooth enamel: immunoglobulin G, an antibody that fights infection, and C-reactive protein, which is present during inflammation in the body.

“These proteins are present in tooth enamel, and they are something we can use to study the biological and potentially the emotional health of past human populations,” said Tammy Buonasera, an assistant professor at the ĚŔÄ·ĘÓƵ and lead author of the paper. “Analysis of immune proteins in enamel has not been done before and this opens the door to studying disease and health in the past in a more targeted way than we can today.

The study began when Buonasera was a research associate at the University of California, Davis. She and collaborators, including representatives from local Indigenous tribes, tested for the presence and amount of the proteins in tooth enamel from three groups of people:

• Ancestral Ohlone people from a mission outpost dating to the late 1700s and early 1800s in the San Francisco Bay Area. Their skeletons were inadvertently discovered during a 2016 construction project in the area. Tribal descendants gave permission for their teeth to be used in the study.

• European settlers from the late 1800s buried at a San Francisco city cemetery.

• Modern-day military cadets who donated wisdom teeth.

The research team then cross-referenced the levels of the two proteins with the known history and experiences of each of the populations. Native peoples in the California mission system experienced high rates of mortality, intense stress and introduced infectious diseases. European settlers from the 1800s had shorter lifespans than present-day populations but, as a group, were assumed to have experienced lower degrees of stress and disease than the Ohlone group. It was assumed that the present-day military cadets experienced better health and nutrition than both archaeological groups.

The researchers found a close correspondence between evidence for high levels of stress and disease in the Indigenous population and high levels of the two proteins in their teeth. Protein levels were much higher than those in the other two groups tested.

“We see certain individuals, especially children, with very high levels of immunoglobulins, which the body uses to battle disease, and C-reactive protein, which people produce when they are under stress,” said Jelmer Eerkens, an anthropology professor at University of California, Davis and one of the corresponding authors on the paper. “It’s heartbreaking to think about children who may have lost their parents and family to disease, were thrown into a new cultural environment they didn’t understand, and how it affected their well-being.”

a woman sits at a computer with data and graphs on the screen
Photo courtesy of Tammy Buonasera
Tammy Buonasera, assistant professor at the ĚŔÄ·ĘÓƵ, looks at test results from her study of proteins in tooth enamel.

Buonasera said this new way of looking at teeth could allow scientists a more detailed look at historical and prehistoric human experiences, for several reasons.

The first is that teeth form during different windows in a human’s development, starting in utero and continuing through late adolescence or early adulthood. That growth over time in each tooth is analogous to the rings in a tree.

“So, it has the potential to provide us with a record — from birth to early adulthood — of a person’s health status,” Buonasera said.

Second, immune proteins within tooth enamel could provide more specific information about health than scientists can get from looking at structural changes to bone or teeth. Many illnesses do not leave a visible trace on the skeleton, while proteins in teeth may record responses to illness or inflammation.

Finally, tooth enamel tends to degrade much slower than other tissues in the body. That means there’s potential to learn from the proteins in the teeth of ancient humans, providing a timeline of human wellness that stretches back thousands of years.

Beyond gaining new insight into the lives of ancient humans, the method has potential to fuel discoveries about the effects of stress, disease and lifestyle on modern humans as well, she said.

“Without trying to overstate things too much, looking at stresses and immune responses in past populations could provide points of comparison with modern lifestyles that can be especially valuable because you have that depth of time,” Buonasera said.

In addition to being the first to examine serum proteins trapped in enamel, the study is also innovative because of the accuracy the new method provides, said Glendon Parker, an adjunct associate professor at UC Davis and one of the co-authors of the paper.

“We see the approach Tammy and her team have taken to be relevant in many contexts, for this and other questions,” Parker said. “These new tools will give us further insight into the lives of past peoples. It is an exciting time for bio-anthropology as these tools become available.”

ADDITIONAL CONTACTS: Tammy Buonasera, tybuonasera@alaska.edu, 907-474-6758. Jelmer Eerkens, jweerkens@ucdavis.edu, 530-752-1348. Glendon Parker, gjparker@ucdavis.edu, 530-752-9870.

NOTE TO EDITORS: Access the full text of the paper on

066-25