September 12, 2011
Microbes Travel Through The Air; It Would Be Good To Know How And Where
Preliminary research on Fusarium, a group of fungi that includes devastating pathogens of plants and animals, shows how these microbes travel through the air. Researchers now believe that with improvements on this preliminary research, there will be a better understanding about crop security, disease spread, and climate change.
Engineers and biologists are steering their efforts towards a new aerobiological modeling technique, one they think may assist farmers in the future by providing an early warning system for high-risk plant pathogens. It will also provide the basis for more effective management strategies to address the spread of infectious diseases affecting plants, domestic animals, and humans.
In preliminary work leading to their new study, also funded by the National Science Foundation, but through a different project led by Schmale and Ross, more than 100 airborne samples of Fusarium were obtained using UAVs. “The resulting information has led to strong evidence that specific atmospheric structures play a role in determining atmospheric concentrations of Fusarium,” Ross said. This work was published on line Sept. 9, 2011 in the American Institute of Physics´ journal Chaos.
In engineering terms, the atmospheric structures are called Lagrangian coherent structures, named after the 18th Century Italian-French mathematician Joseph Lagrange. He introduced a point of view into the study of fluids, like the atmosphere, which the research will employ.
Ross and Schmale will be able to compute, track, and predict atmospheric transport barriers governing the motion of microorganisms such as Fusarium between habitats, using engineering methods including the Lagrangian methods.
“By comparison with results of microbiological analysis, we expect to reveal how dynamical structures partition and mix airborne populations of microorganisms, and relatedly, how mixtures of microorganisms might encode their recent history of large-scale atmospheric mixing,” they said.
For microbes to move through the atmosphere to a new habitat, they must pass through a series of ℠layers´- the laminar boundary layer, the surface boundary layer, and the planetary boundary layer. The surface boundary layer often contains strong vertical gradients in wind speed, temperature, and humidity, accounting for the turbulence. “The small-scale motion can be characterized as random,” Ross added.
If the microbes make it above this surface boundary layer, and enter the second layer of the atmosphere, defined as being at a height of about 50 meters to about three kilometers above the ground, they can be transported over long distances. In this second layer, known as planetary boundary layer, “there are a lot of uncertainties in the trajectory computations,” Ross explained.
With Ross and Schmale´s research they hope to reduce some of these uncertainties. Schmale has already published his findings about reliable methods for collecting and studying populations of Fusarium in the lower atmosphere. (see: http://onlinelibrary.wiley.com/doi/10.1002/rob.20232/abstract and http://www.springerlink.com/content/d203130563348570/
Using UAVs, Schmale has collected data that shows the lower atmosphere is “teeming with Fusarium.” Schmale has DNA sequence data for hundreds of strains of Fusarium collected from the atmosphere, and they have preliminary data validating the important role that atmospheric transport barriers play in the transport of the microorganisms.
Ross said their work should allow them to make more predictable assessments of the transport of the microbes.
“In the future our work may be able to assist farmers by providing an early warning systems for high risk plant pathogens,” Ross said. “It might also pave the way for more effective management strategies for the spread of infectious diseases affecting plants, domestic animals, and humans.”
On the Net: