Published: Sept. 30, 2014

Soil microbes that thrive in the deserts, rainforests, prairies and forests of the world can also be found living beneath New York City鈥檚 Central Park, according to a surprising new study led by Colorado State University and the University of Colorado Boulder.

The research team analyzed 596 soil samples collected from across Central Park鈥檚 843 acres and discovered a stunning diversity of below-ground life, most of which had never been documented before.

Only 8.5 percent to 16.2 percent of the organisms discovered in the park soils, depending on their type, had been previously entered into existing databases that describe microbial life, according to the study results published today in the journal Proceedings of the Royal Society B.

鈥淲e found thousands of different organisms, and it was shocking how few had ever been described,鈥 said Noah Fierer, an associate professor of ecology and evolutionary biology at 抖阴旅行射-Boulder and corresponding author of the study. 鈥淣ot only do they not have a name, but we don鈥檛 know anything about them. We don鈥檛 know what sort of conditions they like to live under or what role they may play in soil habitat and soil fertility.鈥

The study was led by Kelly Ramirez, a postdoctoral researcher at Colorado State University, now at the Netherlands Institute of Ecology in The Netherlands. Ramirez did her research in the Soil Biodiversity and Ecosystem Functioning Lab at CSU, headed by biology Professor Diana Wall, director of the School of Global Environmental Sustainability and a corresponding author on the study.

Other co-authors from CSU are soil science Professor Eugene Kelly and biology doctoral student Ashley Shaw. Other 抖阴旅行射-Boulder co-authors are doctoral students Jonathan Leff and Christopher Steebock, and postdoctoral researcher Albert Barberan.

Wall, who will be speaking at the induction ceremony at the American Academy of Arts and Sciences later this month, said Ramirez鈥檚 work uncovered another melting pot of diversity in New York City -- within the soil of Central Park.

鈥淭he soil microbes in Central Park benefit us, benefit soil health, and are linked tightly to the beauty of the trees and other plants we see,鈥 she said. 鈥淭he nation鈥檚 food, cities, clean air and water and economy are all dependent on healthy, fertile soils and that motivates us to understand this fascinating hidden life beneath our feet.鈥

The scientists also compared the below-ground biodiversity in Central Park to 52 soil samples taken from locations spanning the globe, from Alaska to Antarctica. The team was surprised to find that the breadth of biodiversity beneath Central Park is similar to the biodiversity found across the world, from the frozen Artic tundra to hot deserts and nearly everything in between. The only area that did not have soil microbial communities that overlapped with the samples taken from Central Park was Antarctica, where Wall has done extensive research.

鈥淚f you want to find unique diversity and if you want to find a wide range of different below-ground organisms, you don鈥檛 have to travel around the world,鈥 said Fierer, who is also a fellow at the Cooperative Institute for Research in Environmental Sciences. 鈥淵ou can walk across Central Park.鈥

The types of plants and animals that are able to live in a particular biome, like the desert, are largely determined by the climate. But microbes appear to be more concerned about the environment in the soil, such as the acidity and the carbon availability, than how hot or dry the climate is. This allows diverse microbial communities to thrive wherever the soil conditions are equally diverse.

鈥淣o one would ever expect to find an overlap in the types of trees we see in Central Park and the type of trees we see in a tropical forest,鈥 Fierer said. 鈥淏ut that doesn鈥檛 seem to be true for the microbes living in the soil. We found all these community types just within Central Park. Below-ground biodiversity doesn鈥檛 follow the same rules as the plants and animals living above ground.鈥

Co-authors of the study from other institutions are Scott Bates of the University of Minnesota; Jason Betley of Illumina UK; and Thomas Crowther, Emily Oldfield, and Mark Bradford of Yale University. The study was partially funded by the Winslow Foundation.

The full text of the paper can be found on the Royal Society website under Journal News, .