Salt Plains (Oklahoma)

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Introduction

The barren landscape of the Great Salt Plains is comprised of salt left over from an ocean that covered Oklahoma in prehistoric times.

location = Alfalfa County, Oklahoma, USA
nearest_city = Jet, OK
lat_d = 36.7394740
long_d = -98.1442330
region = US-OK
area = 840 acre


In the introduction, briefly describe the habitat that is the topic of this page. Introduce the habitat, its ecological significance, and the importance of microorganisms in this environment. (What processes do they carry out? What functions do they perform?)

The Great Salt Plains is an 840-acre Oklahoma state park located in Alfalfa County, Oklahoma. This area is a natural hyper-saline environment. Permian brine comes up from deep in the plains to the surface where it evaporates. Scientists believe that salt was deposited during repeated water-level rises of a shallow sea millions of years ago. The supply of salt is kept intact by saline groundwater that flows just a few feet below the surface. When the water evaporates, a layer of salt remains on the surface. This process also plays a role in the formation of selenite crystals that visitors covet [1]. When the rains arrive, they dissolve the top layer of salt creating small waterways and pools of water. These small areas of water change the concentration of salt very quickly from low to high concentrations. With a huge expanse of no vegetation, there is no shade/protection from the sun's ultra violet rays. Over a typical 24-hour day the average temperature range around 30°C. The combination of the salinity, temperature, and UV makes this an extreme environment. This environment contains Halophiles which are photoheterotrophs, using light for energy and methane as a carbon source. They can be in either aerobic or anaerobic conditions. [2]

Physical environment

Describe the physical and chemical characteristics of the environment, using as many sections/subsections as you require. If it is appropriate, you can divide the physical and chemical attributes of the environment into separate sections. Look at other topics available in MicrobeWiki. Which involve processes similar to yours? Create links where relevant.

Physical

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Chemical

Microbial communities

What kind of microbes do we typically find in this environment? Or associated with important processes in this environment? Describe key groups of microbes that we find in this environment, and any special adaptations they may have evolved to survive in this environment. List examples of specific microbes that represent key groups or are associated with important processes found in this environment. Link to other MicrobeWiki pages where possible.

Are there important biological interactions that are important in this environment? Do these interactions influence microbial populations and their activities? How do these interactions influence other organisms? Describe biological interactions that might take place in this environment, using as many sections/subsections as you require. Look at other topics available in MicrobeWiki. Create links where relevant.

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pigmented in shades of red, orange, pink or purple, which captures sunlight to drive a proton pump (bacteriorhodopsin) which enables them to obtain energy for growth (Fendrihan et al. 2006)

Microbial processes

What microbial processes define this environment? Describe microbial processes that are important in this habitat, adding sections/subsections as needed. Look at other topics in MicrobeWiki. Are some of these processes already described? Create links where relevant.

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Current Research

Response of Photosynthetic Microbes of the Salt Plains National Wildlife Refuge to Dynamic Extreme Conditions

"Few studies have addressed multiple variable stress factors likely to be even more adverse to life. Evaporitic salt flats, such as at the Salt Plains National Wildlife Refuge in Oklahoma, represent such a dynamically stressful habitat: direct sunlight, up to 20-30° C diel (60-70° C annual) surface temperature range, episodically varying interstitial and surface pool salinities from near 0 to over 300 g/L, and potentially wide diel fluctuation in pH, redox potential, and dissolved gases and nutrients. Thus, the mostly undescribed photosynthetic and heterotrophic microbes in this habitat may provide unique insights into the evolution of life beyond the limits of tolerance for virtually all species on Earth. The proposed general hypothesis is that interacting stress factors determine survival, productivity and competitive outcomes in hypersaline photoautotrophs, and that halophiles are tolerant of wide fluctuations in physiocochemical conditions in addition to steady-state extreme conditions."[6]

Colorimetric microbial diversity analysis and halotolerance along a soil salinity gradient at the Great Salt Plains of Oklahoma

"Microbial diversity was measured along a salinity gradient at the Great Salt Plains of Oklahoma using colony color quantified as RGB components of microbial isolate streaks. Surface soil samples along a 6-m salinity gradient (from hypersaline soil with 7.5% salinity to oligohaline rangeland soil) at WP68 were dilution-plated on SP medium of various salinities and hundreds of random colonies were collected. These results are complementary to previous molecular genetic analyses of 16S rRNA clone libraries from soils at the Great Salt Plains. Great diversity at lower taxonomic levels supports the suggestion that gene flow is not highly fragmented, a result of less specialization, as expected given the highly variable salinity observed at the salt flats with rain events." [7]

Military

References

-[1] | John W. Morris, Charles R. Goins, and Edwin C. McReynolds, Historical Atlas of Oklahoma (Norman: University of Oklahoma Press, 1986).
-[2] | Santos, H., and da Costa, M.S. (2002) Compatible solutes of organisms that live in hot saline environments. Environmental Microbiology 4: 501-509.
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-[6] | William J. Henley, Department of Botany, Oklahoma State University
-[7] | Res Microbiol. 2013 Jan;164(1):83-9. doi: 10.1016/j.resmic.2012.10.004. Epub 2012 Oct 12. Department of Biological Sciences, Wichita State University, Wichita, KS 67260, USA.

Edited by Brian Chan, a student of Angela Kent at the University of Illinois at Urbana-Champaign.