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Dr. Brian Hedlund holds a bachelor’s degree in biology from the University of Illinois, a doctorate in microbiology from the University of Washington, and was a postdoctoral fellow at the University of Regensburg, Germany. Hedlund was hired at UNLV in 2003 and is currently the Greg Fullmer Endowed Professor of Life Sciences. Hedlund has published over 60 peer-reviewed scientific publications and has been a principal investigator on more than $6 million in extramural grants from the National Aeronautics and Space Administration, Department of Energy, National Institutes of Health, and National Science Foundation, including a CAREER award and a large international project funded through the Partnerships for International Science and Education (PIRE) program.

Hedlund's research focuses on the microbiology and biogeochemistry of geothermal ecosystems, the genomic exploration of "microbial dark matter", and the role of the intestinal microbiome in prevention of Clostridium difficile infection. Dr. Hedlund is editor for Antonie van Leeuwenhoek journal, a member of Bergey's Manual Trust, and editor for Bergey's Manual of Systematics of Archaea and Bacteria, the authoritative reference manual for microbial taxonomy. Dr. Hedlund regularly serves on grant panel review boards both domestically and internationally and has taught more than 2,500 students at UNLV.

As a Research Division Faculty Fellow in the Office of the Vice President for Research and Economic Development, Hedlund is engaged in several projects to support and stimulate research productivity on campus. 

My research focuses on the ecology of life in high temperature habitats, particularly terrestrial hot springs. The study of high-temperature ecosystems (>73°C) is a major research frontier because temperature alters the ecology of these systems in ways that are profoundly important but poorly understood and because some springs are hot spots for novel, uncultivated organisms, so-called biological dark matter.

To work toward a comprehensive understanding of how individual microorganisms operate as parts of high temperature ecosystems, our group employs an integrated approach to microbial ecology, including thermodynamic modeling, spaciotemporal measurements of chemical species of interest in natural samples and microcosms, microbial cultivation and systematics, and genomics. This research will allow us to better understand the foundations of life in hot springs and expand our knowledge of the diversity of life on Earth.

Although much of our research focuses on hot springs of the U.S. Great Basin, we have recently expanded our work to other locations, particularly the Tengchong geothermal region of Yunnan Province in Southwest China. This work is part of the Tengchong PIRE project, which is a large international project funded by the National Science Foundation Partnerships for International Research and Education (PIRE) program. Goals of the PIRE project are to determine how geographic location and geological setting influence microbial community structure and function and to integrate complex datasets through international cooperation.



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UNLV Study Sheds Light on Ancient Microbial Dark Matter

Omnitrophota are nano-sized bacteria first discovered 25 years ago. Though common in many environments around the world, until now they've been poorly understood. An international research team produced the first large-scale analysis of Omnitrophota genomes, uncovering new details about their biology and behavior. The team’s findings are reported in the March 16 issue of the journal Nature Microbiology.
16-Mar-2023 07:25:32 PM EDT

Scientists Unveil New System for Naming Majority of the World’s Microorganisms

In an article published Sept. 19 in the journal Nature Microbiology, a team of scientists present a new system, the SeqCode, and a corresponding registration portal that could help microbiologists effectively categorize and communicate about the massive number of identified yet uncultivated single-celled microorganisms known as prokaryotes.
20-Sep-2022 01:10:13 PM EDT

"The more often something is touched, the more there is a chance for microbes to be deposited and then picked up by another person," he said. "The rougher the surface, there's more sort of, nooks and crannies for microbes to hang out in. A smoother surface would be a little bit harder to adhere to."

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“The real concern and on a daily perspective once we pull out of this is microbes from other humans, that is the best place to find a microbe that is dangerous for humans is another human.”

- Media Invited to Ask Questions - COVID-19 Testing, Drug Discovery, Infectiousness, and more

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