Great Salt Lake: Difference between revisions

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The Great Salt Lake is a large Pleistocene lake that is a remnant of Lake Bonneville which was a fresh body of water (Spencer et al., 1984; Eardley, 1938; Post, 1977). The Great Basin, in which Lake Bonneville and other Pleistocene lakes formed, originated after the beginning of some extensive normal faulting (Eardley, 1938; Lindsay et al., 2016; Baskin, 2014; Gwynn, 1996). The Great Salt Lake is now a hypersaline body of water that is divided into a north-south end that is 300-miles long and an east-west end that is 180 miles long (Eardley, 1938). The two arms (north and south) are the result of the construction of a railroad causeway in 1959 which divided the lake (Post, 1977). Due to evaporation, the north end is slightly more saline and with replacement of water only in the south (Post, 1977). The major source of freshwater inflow comes from three major rivers, the Bear, Weber, and Jordan rivers which enter the south arm (Lindsay et al., 2016; Baskin, 2014; Gwynn, 1996). Furthermore, due to the northward migration of water, the north arm is becoming increasingly enriched in minerals while the south-arm is slowly becoming depleted (Post, 1977, Lindsay et al., 2016). The geologic record indicates that the Great Salt Lake has gone through at least ten cycles in the last 100,000 years, and the present-day Great Salt Lake is at its lowest point in the most recent cycle (Post, 1977). Furthermore, the Great Salt Lake has no natural outlet to the sea and is thus a terminal lake <ref name=Post>[https://pubmed.ncbi.nlm.nih.gov/24233467/]</ref>.  
The Great Salt Lake is a large Pleistocene lake that is a remnant of Lake Bonneville which was a fresh body of water (Spencer et al., 1984; Eardley, 1938; Post, 1977). The Great Basin, in which Lake Bonneville and other Pleistocene lakes formed, originated after the beginning of some extensive normal faulting (Eardley, 1938; Lindsay et al., 2016; Baskin, 2014; Gwynn, 1996). The Great Salt Lake is now a hypersaline body of water that is divided into a north-south end that is 300-miles long and an east-west end that is 180 miles long (Eardley, 1938). The two arms (north and south) are the result of the construction of a railroad causeway in 1959 which divided the lake <ref name=Post/>. Due to evaporation, the north end is slightly more saline and with replacement of water only in the south <ref name=Post/>. The major source of freshwater inflow comes from three major rivers, the Bear, Weber, and Jordan rivers which enter the south arm (Lindsay et al., 2016; Baskin, 2014; Gwynn, 1996). Furthermore, due to the northward migration of water, the north arm is becoming increasingly enriched in minerals while the south-arm is slowly becoming depleted (Post, 1977, Lindsay et al., 2016). The geologic record indicates that the Great Salt Lake has gone through at least ten cycles in the last 100,000 years, and the present-day Great Salt Lake is at its lowest point in the most recent cycle <ref name=Post/>. Furthermore, the Great Salt Lake has no natural outlet to the sea and is thus a terminal lake <ref name=Post>[https://pubmed.ncbi.nlm.nih.gov/24233467/]</ref>.  
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[[Image:Great_Salt_Lake.jpg|300px|thumb|left|Aerial View of the Great Salt Lake. Sept. 13, 30, 1972, Landsat 1. Image provided by the USGS Earthshots: Satellite Images of Environmental Change.]]
[[Image:Great_Salt_Lake.jpg|300px|thumb|left|Aerial View of the Great Salt Lake. Sept. 13, 30, 1972, Landsat 1. Image provided by the USGS Earthshots: Satellite Images of Environmental Change.]]
The land that surrounds the Great Salt Lake is primarily Mesozoic and Paleozoic sedimentary rock with the addition of some recent intrusive and extrusive rocks (Post, 1977).  Within the lake, there are many small islands such as Gunnison, Dolphin, Black Rock, Antelope, and Fremont just to name a few (Eardley, 1938). The east of the lake is bounded by the Wasatch Mountain and the west is bounded by the Lakeside and Hogside Mountains (Eardley, 1938). The Wasatch Mountain and most of the east of the lake is primarily pre-Cambrian crystalline rock such as gneiss, schists, pegmatites, and granite (Eardley, 1938). The western side, however, is composed of Paleozoic and Algonkian limestone, shale, sandstone, and quartzite (Eardley, 1938).  
The land that surrounds the Great Salt Lake is primarily Mesozoic and Paleozoic sedimentary rock with the addition of some recent intrusive and extrusive rocks <ref name=Post/>.  Within the lake, there are many small islands such as Gunnison, Dolphin, Black Rock, Antelope, and Fremont just to name a few (Eardley, 1938). The east of the lake is bounded by the Wasatch Mountain and the west is bounded by the Lakeside and Hogside Mountains (Eardley, 1938). The Wasatch Mountain and most of the east of the lake is primarily pre-Cambrian crystalline rock such as gneiss, schists, pegmatites, and granite (Eardley, 1938). The western side, however, is composed of Paleozoic and Algonkian limestone, shale, sandstone, and quartzite (Eardley, 1938).  
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The chemistry of both the north and south arm of the Great Salt Lake are markedly different. The south arm follows a composition that is more like the marine environment (thalassohaline) with the dominant ions being Na+ and Cl- (Post, 1977). The north arm, however, has an ionic composition that is dominated by Na+ and SO42- (Post, 1977). During the winter months in the north arm, when the temperature drops below 3°C NaSO4 will precipitate spontaneously out of solution to form an ~20 cm layer of hydrated NaSO4 at the bottom of the lake (Post, 1977). When the water temperature rises, the NaSO42- dissolves back into solution (Post, 1977).  
The chemistry of both the north and south arm of the Great Salt Lake are markedly different. The south arm follows a composition that is more like the marine environment (thalassohaline) with the dominant ions being Na+ and Cl- <ref name=Post/>. The north arm, however, has an ionic composition that is dominated by Na+ and SO42- (Post, 1977). During the winter months in the north arm, when the temperature drops below 3°C NaSO4 will precipitate spontaneously out of solution to form an ~20 cm layer of hydrated NaSO4 at the bottom of the lake <ref name=Post/>. When the water temperature rises, the NaSO42- dissolves back into solution (Post, 1977).  
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Revision as of 19:08, 12 June 2020

Overview

Salinity.jpg


By: Floyd Nichols

The Great Salt Lake is located in Utah and is a highly saline Lake (Post, 1977). The Great Salt Lake is a remnant of a prehistoric freshwater lake, which has turned saline because of the blocked rainfall from the Sierra Nevada (Post, 1977). Furthermore, it is unique in that it the Lake shows an increasing salinity gradient from south to north, ranging from seawater concentrations to saturation, respectively (Weimer et al., 2009). Despite these high saline conditions, Great Salt Lake still shows high biodiversity, (Weimer et al., 2009; Tazi et al., 2014). Considering the extreme nature of this environment, many of the microorganisms are novel and uncultured; however, as the environment might suggest, the large majority of phyla that inhabit the Great Salt Lake are halotolerant and halophiles (Tazi et al., 2014).

Interestingly, although living in highly saline environments such as the Great Salt Lake comes at an energetic cost, bacteria in this environment are less likely to be dormant (Aanderud et al., 2016). This suggests that saline environments act to filter structuring bacteria in lake ecosystems (Aanderud et al., 2016). Similarly, high primary productivity and high sulfate concentrations are associated with the Great Salt Lake as well as other hypersaline environments (Kjeldsen et al., 2007). Despite the information that has been obtained for microbial communities in the Great Salt Lake and other hypersaline environments, they still remain understudied.


Environment and Geology


The Great Salt Lake is a large Pleistocene lake that is a remnant of Lake Bonneville which was a fresh body of water (Spencer et al., 1984; Eardley, 1938; Post, 1977). The Great Basin, in which Lake Bonneville and other Pleistocene lakes formed, originated after the beginning of some extensive normal faulting (Eardley, 1938; Lindsay et al., 2016; Baskin, 2014; Gwynn, 1996). The Great Salt Lake is now a hypersaline body of water that is divided into a north-south end that is 300-miles long and an east-west end that is 180 miles long (Eardley, 1938). The two arms (north and south) are the result of the construction of a railroad causeway in 1959 which divided the lake [1]. Due to evaporation, the north end is slightly more saline and with replacement of water only in the south [1]. The major source of freshwater inflow comes from three major rivers, the Bear, Weber, and Jordan rivers which enter the south arm (Lindsay et al., 2016; Baskin, 2014; Gwynn, 1996). Furthermore, due to the northward migration of water, the north arm is becoming increasingly enriched in minerals while the south-arm is slowly becoming depleted (Post, 1977, Lindsay et al., 2016). The geologic record indicates that the Great Salt Lake has gone through at least ten cycles in the last 100,000 years, and the present-day Great Salt Lake is at its lowest point in the most recent cycle [1]. Furthermore, the Great Salt Lake has no natural outlet to the sea and is thus a terminal lake [1].

Aerial View of the Great Salt Lake. Sept. 13, 30, 1972, Landsat 1. Image provided by the USGS Earthshots: Satellite Images of Environmental Change.

The land that surrounds the Great Salt Lake is primarily Mesozoic and Paleozoic sedimentary rock with the addition of some recent intrusive and extrusive rocks [1]. Within the lake, there are many small islands such as Gunnison, Dolphin, Black Rock, Antelope, and Fremont just to name a few (Eardley, 1938). The east of the lake is bounded by the Wasatch Mountain and the west is bounded by the Lakeside and Hogside Mountains (Eardley, 1938). The Wasatch Mountain and most of the east of the lake is primarily pre-Cambrian crystalline rock such as gneiss, schists, pegmatites, and granite (Eardley, 1938). The western side, however, is composed of Paleozoic and Algonkian limestone, shale, sandstone, and quartzite (Eardley, 1938).

The chemistry of both the north and south arm of the Great Salt Lake are markedly different. The south arm follows a composition that is more like the marine environment (thalassohaline) with the dominant ions being Na+ and Cl- [1]. The north arm, however, has an ionic composition that is dominated by Na+ and SO42- (Post, 1977). During the winter months in the north arm, when the temperature drops below 3°C NaSO4 will precipitate spontaneously out of solution to form an ~20 cm layer of hydrated NaSO4 at the bottom of the lake [1]. When the water temperature rises, the NaSO42- dissolves back into solution (Post, 1977).

Despite these harsh saline conditions, the Great Salt Lake has an extensive and diverse microbial community (Post, 1977; Lindsay et al., 2016; Weimer et al., 2009; Tazi et al., 2014). Due to the extensive microbial community and shallow conditions, microbialite structures are highly associated with the Great Salt Lake (Lindsay et al., 2016). Oolitic sands provide the base for much of the microbialite formation, and in addition microbialite structures will grow on lithified crusts of oolitic sands and lime muds resulting in reef like complexes (Lindsay et al., 2016; Riding, 2000).


Microbial Diversity

GSL Diversity.jpg


The microbial abundance and diversity in the Great Salt Lake is quite high despite its salinity and other extreme conditions (Post, 1977; Lindsay et al., 2016; Weimer et al., 2009; Tazi et al., 2014). Furthermore, statistical diversity indices indicate that both bacteria and archaea are extremely diverse (Tazi et al., 2014). Since the lake has a different ionic composition at the north arm and south arm, so too does the microbes differ (Post, 1977).

Although eukaryotes do not comprise a large portion of the microorganisms in the Great Salt Lake, there still remains a variety of species. In general, the primary producers of the lake are from the genus Dunaliella (Post, 1977). The south arm has a lot of algae belonging to the cyanophyta; these consist of calcium carbonate precipitated around cells of Oscillatoria sp. and Coccochloris elegans (Post, 1977). In the north arm, there are low levels of Duniella viridis, but it is highly populated with red algae with two flagella and sluggish motility (Post, 1977). The red algae are comparable morphologically to Dunaliella salina strains (Post, 1977). The red algae do not form uniform in the lake, but in huge patches (Post, 1977). In addition, there are higher order eukaryotes that inhabit the Great Salt Lake, primarily Artemia salina (brine shrimp) and Ephydra (brine flies; Post, 1977).

The bacteria of the north arm are very abundant, and their numbers are so vast that the water becomes a rose wine color due to the carotenoid pigments (Post, 1977). The rose color caused from the pigments is very apparent from the shore, but is most visible from the air (Post, 1977). The majority bacteria that have been isolated from the lake and contribute to the majority of the carotenoid pigment are Halobacterium and Halococcus species. These bacteria have broad biochemical capabilities including acid production from carbohydrates (Post, 1977). In addition to the bacteria in the north arm, there are a variety of specific halophages such as Halobacterium halobium (Post, 1977).

Outside of the extensive study performed by Post (1977), the microbial diversity remains understudied in the present. Importantly, however, Tazi et al. (2014) has used culture independent methods to show that the Great Salt Lake shows OTUs that are significantly different and unique than other hypersaline environments in the world (Tazi et al., 2014).


Key Microbial Players


The chemical compositions of the north and south arm of the Great Salt Lake differ markedly and consequently, the key microbial players in each arm is also different.

South Arm

Oscillatoria sp.

• Oscillatoria is a genus of cyanobacterium that uses photosynthesis as its source of metabolism. There are many species within this genus, many which have not been completely identified yet at the Great Salt Lake.

Cyanophyta

Key Microbial Players at the Great Salt Lake. Halobacterium (a), Cyanophyta (b), Oscillatoria (c), Halococcus (d).

• Cyanophyta are a group of photosynthetic organisms that obtain their energy from light. These organisms are particularly responsible for fixing carbon into the south arm of the Great Salt Lake. Furthermore, due to their photosynthetic nature, they are most likely the main constituents of stromatolites found at the Great Salt Lake.

North Arm

Red Algae

• Red algae are a part of eukaryotic algae. Red algae use photosynthesis as their mode of metabolism and as such play an important role in being one of the only primary producers in the north-arm of the Great Salt Lake.

Halobacterium

• Halobacterium, an archaea, are a genus that are halophilic. Because of the salinity gradient, thus, higher salinity in the north arm, halophilic and halotolerant genus and phyla are the primary organisms. This is why halobacterium are abundant in the north arm. Halobacteria use an aerobic metabolism that requires a high concentration of salt or else their proteins may not function properly at lower salt concentrations.

Halococcus

• Like the halobacterium, halococcus are an extreme halophilic archaea. Halococcus are primarily organotrophs, but some are also able to photosynthesize. Similarly, a high presence of salt is required for their proteins to work properly.


Implications for Astrobiology

This grid of fluid inclusion images shows a variety of different microorganisms, primarily algae and prokaryotes, that have become encased in salt crystals (Connor & Benison, 2013).


The Great Salt Lake is one of the most extensively studied hypersaline environments, and as the name suggest is primarily populated by halotolerant and halophilic organisms[2]. Hypersaline environments such as the Great Salt Lake provide some of the most extreme conditions for microorganisms, thus, studying them may provide helpful metrics for studying life elsewhere in the solar system or the ancient Earth [2]. Not only do hypersaline environments provide good targets for studying for habitation on planets such as Mars that currently has a high presence of salt, but the organisms within these environments may provide insight into interplanetary travel via salt encasing [2].

Furthermore, there is implication for long-term preservation of halophiles due to the high salinity of these environments such as the Great Salt Lake (Baxter et al., 2007). Saline environments may pose to have great preservation potentials because of their ability to increase thermal stability, decrease denaturing of cellular components, and increase resistance to dehydration (Baxter et al., 2007). Because of this preservation potential, hypersaline environments may also provide a target environment for studying the ancient Earth as well as ancient metabolisms (Baxter et al., 2007). Under some circumstances, microorganisms may become encased in a growing salt crystal in a micro-aqueous environment known as a fluid inclusion (Baxter et al., 2007). Studies at the Great Salt Lake have been shown to resurrect halophiles within ancient fluid inclusions (Baxter et al., 2007).


Conclusions

References