An adequate response to a sudden temperature rise is crucial for cellular fitness and survival. While heat shock response (HSR) is well described in bacteria and eukaryotes, much less information is available for archaea, of which many characterized species are extremophiles thriving in habitats typified by large temperature gradients. Here, we describe known molecular aspects of archaeal heat shock proteins (HSPs) as key components of the protein homeostasis machinery and place this in a phylogenetic perspective with respect to bacterial and eukaryotic HSPs. Particular emphasis is placed on structure–function details of the archaeal thermosome, which is a major element of the HSR and of which subunit composition is altered in response to temperature changes. In contrast with the structural response, it is largely unclear how archaeal cells sense temperature fluctuations and which molecular mechanisms underlie the corresponding regulation. We frame this gap in knowledge by discussing emerging questions related to archaeal HSR and by proposing methodologies to address them. Additionally, as has been shown in bacteria and eukaryotes, HSR is expected to be relevant for the control of physiology and growth in various stress conditions beyond temperature stress. A better understanding of this essential cellular process in archaea will not only provide insights into the evolution of HSR and of its sensing and regulation, but also inspire the development of biotechnological applications, by enabling transfer of archaeal heat shock components to other biological systems and for the engineering of archaea as robust cell factories.
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Cover Image
Cover Image
In the cover image, which depicts archaeal cell division, fl uorescence microscopy shows FtsZ1-GFP localisation in pleomorphic cells of Haloferax volcanii. This archaeal model organism was originally isolated from the Dead Sea, but is well suited to live-cell studies owing to its relatively large, flat cells that show distinct differentiation. Multiple proteins from the tubulin superfamily control cell division and cell shape in this species (see article by Liao et al in this issue; pages 547–559). Archaea are expected to provide important insights into cellular evolution and fundamental cell structures such as the cytoskeleton. Image kindly provided by Iain Duggin (The ithree institute, University of Technology Sydney).
Heat shock response in archaea
Nicholas P. Robinson, Liesbeth Lemmens, Rani Baes, Eveline Peeters; Heat shock response in archaea. Emerg Top Life Sci 14 December 2018; 2 (4): 581–593. doi: https://doi.org/10.1042/ETLS20180024
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