Exposure to 1-Butanol Exemplifies the Response of the Thermoacidophilic Archaeon Sulfolobus acidocaldarius to Solvent Stress.

Sulfolobus acidocaldarius is a thermoacidophilic crenarchaeon with optimal growth at 80°C and pH 2 to 3. Due to its unique physiological properties, allowing life at environmental extremes, and the recent availability of genetic tools, this extremophile has received increasing interest for biotechnological applications. In order to elucidate the potential of tolerating process-related stress conditions, we investigated the response of S. acidocaldarius toward the industrially relevant organic solvent 1-butanol. In response to butanol exposure, biofilm formation of S. acidocaldarius was enhanced and occurred at up to 1.5% (vol/vol) 1-butanol, while planktonic growth was observed at up to 1% (vol/vol) 1-butanol. Confocal laser-scanning microscopy revealed that biofilm architecture changed with the formation of denser and higher tower-like structures. Concomitantly, changes in the extracellular polymeric substances with enhanced carbohydrate and protein content were determined in 1-butanol-exposed biofilms. Using scanning electron microscopy, three different cell morphotypes were observed in response to 1-butanol. Transcriptome and proteome analyses were performed comparing the response of planktonic and biofilm cells in the absence and presence of 1-butanol. In response to 1% (vol/vol) 1-butanol, transcript levels of genes encoding motility and cell envelope structures, as well as membrane proteins, were reduced. Cell division and/or vesicle formation were upregulated. Furthermore, changes in immune and defense systems, as well as metabolism and general stress responses, were observed. Our findings show that the extreme lifestyle of S.acidocaldarius coincided with a high tolerance to organic solvents. This study provides what may be the first insights into biofilm formation and membrane/cell stress caused by organic solvents in S. acidocaldariusIMPORTANCEArchaea are unique in terms of metabolic and cellular processes, as well as the adaptation to extreme environments. In the past few years, the development of genetic systems and biochemical, genetic, and polyomics studies has provided deep insights into the physiology of some archaeal model organisms. In this study, we used S. acidocaldarius, which is adapted to the two extremes of low pH and high temperature, to study its tolerance and robustness as well as its global cellular response toward organic solvents, as exemplified by 1-butanol. We were able to identify biofilm formation as a primary cellular response to 1-butanol. Furthermore, the triggered cell/membrane stress led to significant changes in culture heterogeneity accompanied by changes in central cellular processes, such as cell division and cellular defense systems, thus suggesting a global response for the protection at the population level.

Structural insights into the NAD+-dependent formate dehydrogenase mechanism revealed from the NADH complex and the formate NAD+ ternary complex of the Chaetomium thermophilum enzyme.

The removal of carbon dioxide from the waste streams of industrial processes is a major challenge for creation of a sustainable circular economy. This makes the synthesis of formate from CO2 by NAD+ dependent formate dehydrogenases (FDHs) an attractive process for this purpose. The efficiency of this reaction is however low and to achieve a viable industrial process an optimised engineered enzyme needs to be developed. In order to understand the detailed enzymatic mechanism of catalysis structures of different cofactor and substrate complexes of the FDH from the thermophilic filamentous fungus, Chaetomium thermophilum have been determined to 1.2-1.3 Å resolution. The substrate formate is shown to be held by four hydrogen bonds in the FDH catalytic site within the ternary complex with substrate and NAD+and a secondary formate binding site is observed in crystals soaked with substrate. Water molecules are excluded from the FDH catalytic site when the substrate is bound. The angle between the plane of the NAD+ cofactor pyridine ring and the plane of the formate molecule is around 27°. Additionally, structures of a FDH mutant enzyme, N120C, in complex with the reduced form of the cofactor have also been determined both in the presence and absence of formate bound at the secondary site. These structures provide further understanding of the catalytic mechanism of this fungal enzyme.