First Atlas Of Airborne Microbes Across US
News Apr 22, 2015
A University of Colorado Boulder and North Carolina State University-led team has produced the first atlas of airborne microbes across the continental U.S., a feat that has implications for better understanding health and disease in humans, animals and crops.
The researchers collected outdoor dust samples from roughly 1,200 homes in all 50 states from both urban and rural areas using a powerful DNA sequencing technique to identify specific bacteria and fungal species. While standard, culture-based surveys are able to detect only a handful of different species, the high-tech molecular technique revealed that an average dust sample from the study contained roughly 4,700 different bacterial species and about 1,400 fungal species.
The total number of bacterial species identified in the study was more than 110,000, along with more than 55,000 fungal species, many unknown to science. But not all bacteria and fungi are harmful – many have health benefits, researchers now know.
“We inhale thousands of airborne microbes every hour we spend outdoors, some of which can cause illnesses or trigger allergic disorders,” said lead study author and CU-Boulder Associate Professor Noah Fierer of the ecology and evolutionary biology department. “This study provides the first glimpse of the continental-scale distributions of microorganisms in the atmosphere, giving us the baseline data to ask all sorts of interesting questions.”
It might now be possible to correlate specific areas in cities or states where people are especially sensitive to fungal allergies or asthma, for example, with areas that have particular fungal types regularly swirling in the outdoor air, said Fierer.
A paper on the subject was published in the April 20 issue of the Proceedings of the National Academy of Sciences. Co-authors include CU-Boulder’s Albert Barberan and Jonathan Leff, NCSU’s Rob Dunn and Holly Menninger and the University of California, San Francisco’s Katherine Pollard and Joshua Ladau.
Several patterns emerged during the study, said Fierer, also a fellow at the Cooperative Institute for Research in Environmental Sciences (CIRES). The team found a “bicoastal” pattern showing that microbial communities from homes on the East Coast and West Coast were more similar to each other than those from homes in the nation’s interior.
Airborne microbes are capable of being transported phenomenal distances – aerosols in Saharan dust clouds from Africa, for instance, have been shown to impact the ecology of lakes in Spain and coral reefs in the Caribbean Sea. While the microbial communities in the study were highly variable in composition across America, their geographic patterns are associated in large part with variability in climate and soils, Fierer said.
Volunteers collected the samples as part of Wild Life in Our Homes project, a national citizen-scientist effort coordinated by NCSU. Participants from all 50 states used kits mailed to them to swab the dust from the upper door trim on the outside surface of an exterior door for bacteria and fungal samples. Door trim is an ideal site: It’s found on virtually every home and collects outdoor aerosols with little or no direct contact by home occupants.
While there is the perception that those living in the country breathe in far different types of bacteria and fungi than those living in cities, that does not seem to be the case, said the study authors. Even though urban and rural samples of dust were not distinct from each other, the study does suggest urbanization leads to at least some degree of homogenization of airborne microbe types.
“If I go from a rural area near Raleigh, North Carolina, to downtown Raleigh, I don’t see a big difference in airborne microbial life between the two places,” said Dunn, a biological sciences associate professor at NCSU. “But if I go from Raleigh to New York City, the microbial life is even more similar. So there are subtle differences here.”
The Alfred P. Sloan Foundation’s Microbiology of the Built Environment program and the National Science Foundation funded the study.
Fierer likened the new United States microbial map to botanical maps of the country assembled by U.S. scientists more than 150 years ago.
“Going into this study, we didn’t even know answers to basic questions like whether the airborne bacteria and fungi in Denver were different from those in San Francisco,” said CU-Boulder co-author Albert Barberan, a CIRES postdoctoral researcher. “But we saw certain patterns, and now we have the methods and tools to answer new questions.”
The PNAS paper is a companion study to one published last week in the journal PLOS ONE by the NCSU and CU-Boulder researchers showing fungal DNA can be used to track the origin of dust samples, making it a potential forensic tool for use by law enforcement officials or archaeologists. Given a swab of dust from anywhere in the country, the team can identify its geographic origin, sometimes within 60 miles or less.
In 2010, Fierer led another CU-Boulder study that showed unique bacterial signatures from a person’s hand left behind on objects like computer keyboards and computer mice might also be effective as a forensics tool to confirm DNA and fingerprint analyses.
“Working with the public in our research is one of our lab’s guiding principles,” said Dunn. “One of the biggest challenges moving forward to manage our planet sensibly is to engage the public to help us study and understand the life around us.
“While there historically has been a glass wall through which citizens watched scientists at work, we want to take down the glass and have scientists and citizens communicate back and forth, altering the way each group thinks about the world,” Dunn said.
The research involved isolating and amplifying tiny bits of microbial DNA, then sequencing that DNA to identify the different bacteria and fungal species found in each dust sample.
New Database Catalogues Plants that Soak Up ContaminationNews
Researchers have published a database that provides easier access to information on the plant world’s hyperaccumulators. Hyperaccumulators are unusual plants that can absorb much larger amounts of metal compounds in their leaves and stems than normal plants, and they are very useful for cleaning up contaminated land.READ MORE
What’s in Your Wheat? Sequencing One of the Most Complex Genomes Known to ScienceNews
The wheat genome sequences may help biologists not only better understand the evolutionary history of wheat, but also advance the quest for hardier, more pest- and drought-resistant wheat types to help feed the world’s growing population.READ MORE
Comments | 0 ADD COMMENT
3rd Annual NGS Data Analysis and Informatics Conference
Feb 08 - Feb 09, 2018
3rd Annual Genome Editing & Engineering Conference
Feb 08 - Feb 09, 2018