Summary:
A person's home is their castle, and they populate it with their own subjects: millions and millions of bacteria. Scientists have detailed the microbes that live in houses and apartments. The results shed light on the complicated interaction between humans and the microbes that live on and around us. Mounting evidence suggests that these microscopic, teeming communities play a role in human health and disease treatment and transmission.
A person's home is their castle, and they populate it with their own subjects: millions and millions of bacteria.
A study published today in Science provides a detailed analysis of the microbes that live in houses and apartments. The study was conducted by researchers from the U.S. Department of Energy's Argonne National Laboratory and the University of Chicago.
The results shed light on the complicated interaction between humans and the microbes that live on and around us.
Mounting evidence suggests that these microscopic, teeming communities play a role in human health and disease treatment and transmission.
It is known that certain bacteria can make it easier for mice to put on weight, for example, and that others influence brain development in young mice.
We want to know where these bacteria come from, and as people spend more and more time indoors, we wanted to map out the microbes that live in our homes and the likelihood that they will settle on us.
They are essential for us to understand our health in the 21st century.
The Home Microbiome Project followed seven families, which included eighteen people, three dogs and one cat, over the course of six weeks.
The participants in the study swabbed their hands, feet and noses daily to collect a sample of the microbial populations living in and on them. They also sampled surfaces in the house, including doorknobs, light switches, floors and countertops.
Then the samples came to Argonne, where researchers performed DNA analysis to characterize the different species of microbes in each sample.
We wanted to know how much people affected the microbial community on a house's surfaces and on each other.
They found that people substantially affected the microbial communities in a house -- when three of the families moved, it took less than a day for the new house to look just like the old one, microbially speaking.
Regular physical contact between individuals also mattered -- in one home where two of the three occupants were in a relationship with one another, the couple shared many more microbes.
Married couples and their young children also shared most of their microbial community.
Married couples and their young children also shared most of their microbial community.
Within a household, hands were the most likely to have similar microbes, while noses showed more individual variation.
Adding pets changed the makeup as well, Gilbert said -- they found more plant and soil bacteria in houses with indoor-outdoor dogs or cats.
In at least one case, the researchers tracked a potentially pathogenic strain of bacteria called Enterobacter, which first appeared on one person's hands, then the kitchen counter, and then another person's hands.
This doesn't mean that the countertop was definitely the mode of transmission between the two humans, but it's certainly a smoking gun.
It's also quite possible that we are routinely exposed to harmful bacteria -- living on us and in our environment -- but it only causes disease when our immune systems are otherwise disrupted.
Home microbiome studies also could potentially serve as a forensic tool.
Given an unidentified sample from a floor in this study, we could easily predict which family it came from.
The research also suggests that when a person (and their microbes) leaves a house, the microbial community shifts noticeably in a matter of days.
You could theoretically predict whether a person has lived in this location, and how recently, with very good accuracy.
Researchers used Argonne's Magellan cloud computing system to analyze the data; additional support came from the University of Chicago Research Computing Center.
The study was funded by the Alfred P. Sloan Foundation. Additional funding also came from the National Institutes of Health, the Environmental Protection Agency, and the National Science Foundation.
The Argonne researchers on the study included, Jack Gilbert, the leader, Argonne computational biologist Peter Larsen, postdoctoral researchers Daniel Smith, Kim Handley, and Nicole Scott, and contractors Sarah Owens and Jarrad Hampton-Marcell. University of Chicago graduate students Sean Gibbons and Simon Lax contributed to the paper, as well as collaborators from Washington University in St. Louis and the University of Colorado at Boulder.
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Story Source:
The above story is based on materials provided by DOE/Argonne National Laboratory. The original article was written by Louise Lerner. Note: Materials may be edited for content and length.
Journal Reference:
- S. Lax, D. P. Smith, J. Hampton-Marcell, S. M. Owens, K. M. Handley, N. M. Scott, S. M. Gibbons, P. Larsen, B. D. Shogan, S. Weiss, J. L. Metcalf, L. K. Ursell, Y. Vazquez-Baeza, W. Van Treuren, N. A. Hasan, M. K. Gibson, R. Colwell, G. Dantas, R. Knight, J. A. Gilbert. Longitudinal analysis of microbial interaction between humans and the indoor environment. Science, 2014; 345 (6200): 1048 DOI: 10.1126/science.1254529
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