Elusive but ubiquitous microbe fingered as gum disease culprit in Stanford study
Even biology majors may not have heard much about archaea. Along with bacteria and eukarya (which encompass every organism from fungi to mammals), the elusive microbes make up one of the three domains of life. Now researchers at the Stanford University School of Medicine have for the first time tied a specific disease to one of these unfamiliar organisms.
“Its not surprising that no one has really heard about them; archaea have still not even penetrated mainstream biology textbooks,” said David Relman, MD, associate professor of medicine (infectious diseases) and of microbiology and immunology. There are, however, at least as many of them as there are bacteria, he said.
Archaea look a lot like bacteria, but appearances can be deceiving. Genetically and biochemically they are as different from bacteria as bacteria are from humans. The microbes live in many extreme environments – from hot springs to salt lakes to submarine volcanoes – but also within animals, including the human colon, vagina and mouth.
“To me it is one of those fundamental puzzles: they are everywhere and, given that we must be exposed to them somewhat frequently, if not all the time, why is it that we cant name one disease-causing member of this enormous domain?” Relman wondered. He and his group at the Veterans Affairs Palo Alto Health Care System have shown a never-before-known connection between the abundance of archaea and the severity of a human gum disease called periodontitis.
Chronic periodontitis, which affects about one-third of Americans, may result in tooth loss and is thought to play a role in a range of conditions including atherosclerosis, stroke and early delivery of low birth-weight infants. While there is a general consensus that bacteria play a role in gum disease, no single microbe has been implicated as the culprit.
Relman and members of his lab embarked on a comprehensive, controlled study of the archaea found in the subgingival crevice – the deep gap between the gums and teeth – where periodontitis begins. They rigorously analyzed samples from 58 patients mouths taken by their collaborator, Gary Armitage, DDS, at the UC-San Francisco School of Dentistry, and found that more than one-third of the periodontitis patients had archaea in their diseased subgingival spaces, but nowhere else in their mouths. In addition, the relative abundance of archaea correlated with disease severity. Their findings are published in this weeks issue of the Proceedings of the National Academy of Sciences.
“Of course wed ultimately like to say archaea caused disease, but its a horse-and-cart problem right now because we havent shown that the archaea come before the disease,” Relman said. In the future, he noted, they will collect specimens repeatedly from the same spot in the subgingival pocket in hopes of being able to pinpoint the moment when the archaea start to increase in number and then determine whether that predicts the later development of the disease.
The papers first author, Paul Lepp, PhD, research associate in microbiology and immunology, explained that while a third of the periodontitis sufferers harbored archaea, many of the others had high levels of bacteria that – like archaea – consume hydrogen. Hydrogen consumption creates a more hospitable environment for bacteria long known to play a role in gum disease.
The group speculates that archaea may not directly cause periodontal disease. Rather, the microbes may indirectly contribute to it by helping other organisms – in this case, gum-damaging bacteria – grow more productively. Lepp said they are now looking for other hydrogen consumers to test their theory.
“In my mind, its increasingly clear that the disease may be the result of a community disturbance rather than the presence or absence of a particular organism,” Relman said.
Relman also sees a potentially broader side to this research. “Maybe we should look a little harder for evidence of archaea as promoting or causing other diseases. We certainly have them in our bodies and we are exposed to them, so the archaea have the opportunity to cause disease if they are capable of doing so. We havent been looking for them so we wouldnt know.”
Other Stanford researchers involved in this study include graduate student Mary Brinig and postdoctoral scholar Cleber Ouverney, PhD, in microbiology and immunology, and research assistant Katherine Palm, in the division of infectious diseases and geographic medicine. This study was funded by a grant from the National Institute of Dental and Craniofacial Research, one of the National Institutes of Health, along with grants from the Ellison Medical Foundation and the University Exploratory Research Program of Procter & Gamble.
Stanford University Medical Center integrates research, medical education and patient care at its three institutions – Stanford University School of Medicine, Stanford Hospital & Clinics and Lucile Packard Childrens Hospital at Stanford. For more information, please visit the Web site of the medical centers Office of Communication & Public Affairs at http://mednews.stanford.edu.
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