Mount Erebus

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Mount Erebus, 1972

Introduction

Mount Erebus is a volcano located in Ross Island, Antarctica, with an elevation of 3,794 m. The area near the summit is home to several extreme environments. Microbial growth in these environments is constrained by wide temperature ranges, reduced water activity [1] and pH [2]. Yet, studies on geothermal soils on Mt. Erebus have found that bacteria are abundant and diverse around fumaroles [2] [3]. “Fumaroles” are openings on the sides of volcanoes that emit steam and hot gases such as carbon dioxide, sulfur dioxide, hydrogen chloride and hydrogen sulfide. The steam and hot liquid from the fumaroles maintain moist hot soils and provide nutrients, which allows for microbial growth. These fumaroles also generate important physiochemical gradients since temperatures, moisture and pH decrease abruptly with distance to the fumarole.

Physiochemical Conditions

Temperatures

Air temperatures can go below - 25°C [4] and soil temperature can go up to 65°C [5]. The thermal gradients at these fumaroles are steep with temperature differences of over 60 °C within less than 0.6 m. However, beneath the surface they are also relatively sustained, allowing for a stable and diverse community structure [2].

Moisture

At warm sites water is constantly present due to the condensation of steam and the melting of snow [6]. Warmer sites tend to have higher moisture content than cooler sites [2]. However, % moisture tends to vary greatly within warm sites [2] [5].

Fumaroles escape through “Fourpeaked Glacier” covering Fourpeaked Volcano in Alaska on September 24, 2006.

pH

The sulfur emitted by the fumaroles generates acidic environments near the fumaroles. However, at sites adjacent to the fumaroles the high temperatures and high concentrations of CO2 help maintain a neutral pH [2].

Light

During the winter, Mount Erebus is in darkness for approximately 16 weeks [7].

Nutrients

Before reaching the surface of fumaroles, hot liquids and steam dissolve minerals from the deep surface. When they reach the surface they cause extensive soil mineralization [8]. Iron and Manganese reach toxic levels near fumaroles [2]. Carbon levels are higher closer to the fumaroles. However, both fixed carbon and nitrogen levels are low in these areas. On the other hand, these areas are rich in CO2 [2].

Community Structure

The microbial community structure is clearly dependent on physiochemical conditions, the key factors being temperature, pH and moisture [2]. The organisms that grow adjacent to fumaroles are different to those that grow further away. Not all organisms are "thermophiles" or "psychrophiles"; the temperature gradient allows for "mesophiles" as well [5].

The bacteria present are very diverse and there are deep branching bacterial 16S phylogenetic sequences recovered from geothermal soils community analysis [2].

A recent study hypothesizes that the microbial community at Tramway Ridge is driven by chemolithoautotrophic organisms [8].

Heterotrophic "Bacillus" strains have been isolated from the soil indicating the presence of algae and other autotrophic organisms that support heterotrophic growth [5].

One strain of Planctomycetes capable of anaerobic ammonia oxidation and sulfur reduction is present in considerable amounts in the geothermal soil [2].

Two cyanobacterial sequences have been identified. The cyanobacteria cannot survive the dark winters of Mt. Erebus and are thought to be involved in long-distance airborne dispersal [2][7][9].

Archea identified bare great similarity with Crenarchaeota sourced from deep subsurface environments, which are thought to play a role in chemoautotrophic nitrification [2].

Although rarely been found in the Antarctic, representatives of OP10 (hypothesized to play a role in metal cycling) have been found in Mt. Erebus whereas proteobacteria have not [2].

In addition to these organisms, 16S rRNA gene sequence analysis of a hot site (around 60 ˚C) indicates that there are several bacterial groups present that are yet to be described. The largest clade of bacteria is branched within an unknown group between candidate division OP10 and Chloroflexi [2].

Microbial adaptations

Microorganisms that live at high temperatures require adaptations such as thermo-tolerant proteins. These proteins may have a higher ion-pair content and form higher-order oligomers [10]. Membrane lipid composition is also adapted to compensate for the increased membrane fluidity induced by high temperatures [11]. Acidophiles have mechanisms to maintain an internal pH at levels close to neutral such as “unusual permeability properties, positive surface charges, high internal buffer capacity, overexpression of H+ export enzymes and unique transporters.” [2]