Abstract
Microbial communication, particularly that of quorum sensing, plays an important role in regulating gene expression in a range of organisms. Although this phenomenon has been well studied in relation to, for example, virulence gene regulation, the focus of this article is to review our understanding of the role of microbial communication in extreme environments. Cell signaling regulates many important microbial processes and may play a pivotal role in driving microbial functional diversity and ultimately ecosystem function in extreme environments. Several recent studies have characterized cell signaling in modern analogs to early Earth communities (microbial mats), and characterization of cell signaling systems in these communities may provide unique insights in understanding the microbial interactions involved in function and survival in extreme environments. Cell signaling is a fundamental process that may have co-evolved with communities and environmental conditions on the early Earth. Without cell signaling, evolutionary pressures may have even resulted in the extinction rather than evolution of certain microbial groups. One of the biggest challenges in extremophile biology is understanding how and why some microbial functional groups are located where logically they would not be expected to survive, and tightly regulated communication may be key. Finally, quorum sensing has been recently identified for the first time in archaea, and thus communication at multiple levels (potentially even inter-domain) may be fundamental in extreme environments.
Highlights
Quorum sensing is a type of microbial communication that regulates gene expression in high cell densities [1]
The potential for interspecies and even interdomain signaling is quite significant and an area worthy of further investigation. Both N. occultus and N. magadii are sourced from extremely alkaphillic environments, and it implies that modifications to the traditional quorum sensing molecules would be necessary for them to function under the extreme environmental conditions, as short-chain acylated homoserine lactones (AHLs) are unstable in alkaline conditions [13]
This review has focused primarily on quorum sensing in individual organisms, this discussion will illustrate this phenomenon in a particular environmental setting, that of microbial mats
Summary
Quorum sensing is a type of microbial communication that regulates gene expression in high cell densities [1] It relies on the production of signaling molecules that are released from the cell into the surrounding environment. Short-term fluctuations in environmental parameters can be considered as an extreme condition, as microorganisms need to be able to rapidly adapt to survive in a given niche This is relevant in an environment of interest, microbial mats, to be covered later in this review. The advent of bioinformatic technologies and extensive databases has allowed for a relative wealth of information regarding the extremophiles As they live in such harsh conditions culturing in the laboratory is often difficult, though not impossible. This review aims to assess our current understanding of quorum sensing in extreme environments and present the evidence for its potential role and function in these ecosystems
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