Abstract
Glaciers and ice sheets, like other biomes, occupy a significant area of the planet and harbour biological communities with distinct interactions and feedbacks with their physical and chemical environment. In the case of the glacial biome, the biological processes are dominated almost exclusively by microbial communities. Habitats on glaciers and ice sheets with enough liquid water to sustain microbial activity include snow, surface ice, cryoconite holes, englacial systems and the interface between ice and overridden rock/soil. There is a remarkable similarity between the different specific glacial habitats across glaciers and ice sheets worldwide, particularly regarding their main primary producers and ecosystem engineers. At the surface, cyanobacteria dominate the carbon production in aquatic/sediment systems such as cryoconite holes, while eukaryotic Zygnematales and Chlamydomonadales dominate ice surfaces and snow dynamics, respectively. Microbially driven chemolithotrophic processes associated with sulphur and iron cycle and C transformations in subglacial ecosystems provide the basis for chemical transformations at the rock interface under the ice that underpin an important mechanism for the delivery of nutrients to downstream ecosystems. In this review, we focus on the main ecosystem engineers of glaciers and ice sheets and how they interact with their chemical and physical environment. We then discuss the implications of this microbial activity on the icy microbiome to the biogeochemistry of downstream ecosystems.
Highlights
Glaciers and ice sheets have recently been recognised as one of the biomes on Earth.[1]
The surfaces of glaciers and ice sheets are pockmarked by characteristic pits known as cryoconite holes (Fig. 2j–i)
EPS is known to act as a cryoprotectant that prevents the disruption of cell membranes by freezing,[72] can act as a site to deposit UV protective in establishing microbe—cryoconite interactions, both in terms of cyanobacterial motility and attachment to cryoconite granules[79] and chemotaxis of heterotrophs to cyanobacterial exudates.[80] compounds, and may assist in scavenging of metal ions and Overall, such activity is instrumental in collecting material on other nutrients.[71]
Summary
Like other biomes, occupy a significant area of the planet and harbour biological communities with distinct interactions and feedbacks with their physical and chemical environment. Habitats on glaciers and ice sheets with enough liquid water to sustain microbial activity include snow, surface ice, cryoconite holes, englacial systems and the interface between ice and overridden rock/ soil. There is a remarkable similarity between the different specific glacial habitats across glaciers and ice sheets worldwide, regarding their main primary producers and ecosystem engineers. Driven chemolithotrophic processes associated with sulphur and iron cycle and C transformations in subglacial ecosystems provide the basis for chemical transformations at the rock interface under the ice that underpin an important mechanism for the delivery of nutrients to downstream ecosystems. We focus on the main ecosystem engineers of glaciers and ice sheets and how they interact with their chemical and physical environment. We discuss the implications of this microbial activity on the icy microbiome to the biogeochemistry of downstream ecosystems
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