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ETHER NOT GLYCEROL MEMBRANES. "The membrane structure unique to Archaea plays a significant role in their survival as a barrier between the cytoplasm and the hostile environments. Archaeal membranes are composed of isoprenoid alcohols ether-linked to glycerol, instead of the usual Eukaryotic and Prokaryotic fatty acids which are ester-linked to glycerol." https://lnkd.in/dz9R9uY View in LinkedIn

RESISTANT LIPID MEMBRANES. "Cell components such as lipids, nucleic acids and proteins are usually quite heat-sensitive. Membrane lipids of the bacterial hyperthermophile T. maritima contain a novel glycerol ether lipid ... it may significantly increase the stability of membranes against hydrolysis at high temperatures." https://lnkd.in/dk75SNX View in LinkedIn

"HYPERTHERMOPHILES grow fastest at temperatures between 80 and 106°C. This is already the temperature range where some small biomolecules rapidly decompose. The highest growth temperature observed at all is 113°C for Pyrolobus fumarii. As a consequence, cell components like proteins, nucleic acids and membranes have to be stable and even function best at temperatures around 100°C." https://lnkd.in/dk75SNX View in LinkedIn

TOUGHER FATTY ACIDS. "The lipid composition in the membranes of the thermophiles consists of more branched and saturated fatty acids than other organisms. Having a stronger lipid complex within the membrane helps the Archaean thermophiles to withstand higher temperatures better than other organisms. Aside from having to stabilize the plasma membrane at high temperatures, thermophiles must also stabilize their proteins, DNA, RNA, and ATP." https://lnkd.in/dFvvrKf View in LinkedIn

KEY LIPID. "One of the most important attributes to the maintenance of homeostasis within the organism is that of the plasma membrane surrounding the organism. Archaean thermophiles, and also acidophiles, have membranes containing unique ether lipids. These tetraether lipids span the entire membrane forming a rigid monolayer that is impermeable to both ions and protons. Ether-type lipids, such as these, are much stronger than the ester-type lipids found in non-thermophilic Bacteria and Eukarya." https://lnkd.in/dFvvrKf View in LinkedIn

ADAPTIVE SOLUTIONS. "Due to the hazards of living at such extreme temperatures, thermophiles have evolved a variety of mechanisms that allow them to survive at temperatures no other organisms can thrive at. These traits include unique membrane lipid composition, thermostable membrane proteins, and higher turnover rates for various protein enzymes." https://lnkd.in/dFvvrKf View in LinkedIn

THERMOPHILES. "Over sixty species of Bacteria and Archea have been isolated and grown between 80°C and 110°C. Thermophiles can grow in both terrestrial and marine environments, including: solfataric fields, geothermal soils, volcanically heated surface waters, hot fumaroles, deep-sea vents, and even black smokers. These can also thrive in ... smoldering coal refuse and geothermal powerplants." (2001). https://lnkd.in/dFvvrKf View in LinkedIn

EMBEDDED CODE. "The fourth dimension in this experimental manufacturing process is inserted via a customized “code” that is embedded into the 3D printed material. These predefined instructions are dependent upon the object’s constructed geometry, and would also predictably dictate the direction, the iterations and the angles of its transformation, and is activated only when certain environmental conditions change." https://lnkd.in/d7VC6uu View in LinkedIn

FRAGMENT FROM NATURE continues this weekend to see how the cell membrane adapts in extreme environments in creatures who master these immensely challenging niches. These membrane adaptations are quite startling and fully reflect the creative resources of evolution to solve really difficult problems. View in LinkedIn

4D PRINTING. "What if things could be made to have a kind of memory, allowing it to transform, assemble or replicate itself? Or even repair themselves, adapting to various functions, over time." https://lnkd.in/d7VC6uu View in LinkedIn