An intracellular protease of the crenarchaeon Sulfolobus solfataricus, which has sequence similarity to eukaryotic peptidases of the CD clan

Sulfolobus - A Potential Key Organism in Future Biotechnology

Extremophilic organisms represent a potentially valuable resource for the development of novel bioprocesses. They can act as a source for stable enzymes and unique biomaterials. Extremophiles are capable of carrying out microbial processes and biotransformations under extremely hostile conditions. Extreme thermoacidophilic members of the well-characterized genus Sulfolobus are outstanding in their ability to thrive at both high temperatures and low pH. This review gives an overview of the biological system Sulfolobus including its central carbon metabolism and the development of tools for its genetic manipulation. We highlight findings of commercial relevance and focus on potential industrial applications. Finally, the current state of bioreactor cultivations is summarized and we discuss the use of Sulfolobus species in biorefinery applications.

Genetic Analysis of the Major Capsid Protein of the Archaeal Fusellovirus SSV1: Mutational Flexibility and Conformational Change

Viruses with spindle or lemon-shaped virions are rare in the world of viruses, but are common in viruses of archaeal extremophiles, possibly due to the extreme conditions in which they thrive. However, the structural and genetic basis for the unique spindle shape is unknown. The best-studied spindle-shaped virus, Sulfolobus Spindle-shaped Virus 1 (SSV1), is composed mostly of the major capsid protein VP1. Similar to many other viruses, proteolytic cleavage of VP1 is thought to be critical for virion formation. Unlike half of the genes in SSV1, including the minor capsid protein gene VP3, the VP1 gene does not tolerate deletion or transposon insertion. To determine the role of the VP1 gene and its proteolysis for virus function, we developed techniques for site-directed mutagenesis of the SSV1 genome and complemented deletion mutants with VP1 genes from other SSVs. By analyzing these mutants, we demonstrate that the N-terminus of the VP1 protein is required, but the N-terminus, or entire SSV1 VP1 protein, can be exchanged with VP1s from other SSVs. However, the conserved glutamate at the cleavage site is not essential for infectivity. Interestingly, viruses containing point mutations at this position generate mostly abnormal virions.

Evolution of the thermopsin peptidase family (A5)

Thermopsin is a peptidase from Sulfolobus acidocaldarius that is active at low pH and high temperature. From reversible inhibition with pepstatin, thermopsin is thought to be an aspartic peptidase. It is a member of the only family of peptidases to be restricted entirely to the archaea, namely peptidase family A5. Evolution within this family has been mapped, using a taxonomic tree based on the known classification of archaea. Homologues are found only in archaeans that are both hyperthermophiles and acidophiles, and this implies lateral transfer of genes between archaea, because species with homologues are not necessarily closely related. Despite the remarkable stability and activity in extreme conditions, no tertiary structure has been solved for any member of the family, and the catalytic mechanism is unknown. Putative catalytic residues have been predicted here by examination of aligned sequences.

An archaeal protein evolutionarily conserved in prokaryotes is a zinc-dependent metalloprotease

A putative protease gene (tldD) was previously identified from studying tolerance of letD encoding the CcdB toxin of a toxin–antidote system of the F plasmid in Escherichia coli. While this gene is evolutionarily conserved in archaea and bacteria, the proteolytic activity of encoded proteins remained to be demonstrated experimentally. Here we studied Sso0660, an archaeal TldD homologue encoded in Sulfolobus solfataricus by overexpression of the recombinant protein and characterization of the purified enzyme. We found that the enzyme is active in degrading azocasein and FITC–BSA substrates. Protease inhibitor studies showed that EDTA and o-phenanthroline, two well-known metalloprotease inhibitors, either abolished completely or strongly inhibited the enzyme activity, and flame spectrometric analysis showed that a zinc ion is a cofactor of the protease. Furthermore, the protein forms disulfide bond via the Cys⁴¹⁶ residue, yielding protein dimer that is the active form of the enzyme. These results establish for the first time that tidD genes encode zinc-containing proteases, classifying them as a family in the metalloprotease class.

Characterization of prolyl oligopeptidase from hyperthermophilic archaeon Thermococcus sp. NA1

The prolyl oligopeptidase TNA1_POP was found to be encoded in the genome of the hyperthermophilic archaeon Thermococcus sp. NA1 and showed high similarities to its archaeal homologs (76-83%). The enzyme was found to be a single polypeptide composed of 616 amino acids with conserved signature domains. A recombinant TNA1_POP expressed in Escherichia coli was capable of hydrolyzing succinyl-Ala-Pro-p-nitroanilide (Suc-Ala-Pro-pNA) with temperature and pH optimums of 80 degrees C and 7, respectively. TNA1_POP activity appeared to be significantly activated by pre-incubation at 80 degrees C and 90 degrees C with the optimum temperature unchanged. The heat-activated enzyme exhibited a k(cat) approximately twofold higher than that of the unheated enzyme, however, both enzymes showed the same K(m). TNA1_POP was thermostable at 80 degrees C retaining 80% of its heat-activated activity even after 23 h, but it lost its enzymatic activity at 90 degrees C with a half-life of 3 h. The loss of the enzymatic activity at 90 degrees C seemed to be caused by the autodegradation of the enzyme, not by thermal denaturation, as supported by circular dichroism spectropolarimetry. Autodegradation fragments ranging from 2 to 18 kDa were mapped by matrix-assisted laser desorption/ionization time-of-flight (MALDI-TOF) mass spectrometry.

Cloning, expression, and characterization of aminopeptidase P from the hyperthermophilic archaeon Thermococcus sp. strain NA1

Genomic analysis of a hyperthermophilic archaeon, Thermococcus sp. strain NA1, revealed the presence of a 1,068-bp open reading frame encoding a protein consisting of 356 amino acids with a calculated molecular mass of 39,714 Da (GenBank accession no. DQ144132). Sequence analysis showed that it was similar to the putative aminopeptidase P (APP) of Thermococcus kodakaraensis KOD1. Amino acid residues important for catalytic activity and the metal binding ligands conserved in bacterial, nematode, insect, and mammalian APPs were also conserved in the Thermococcus sp. strain NA1 APP. The archaeal APP, designated TNA1_APP (Thermococcus sp. strain NA1 APP), was cloned and expressed in Escherichia coli. The recombinant enzyme hydrolyzed the amino-terminal Xaa-Pro bond of Lys(Nepsilon-Abz)-Pro-Pro-pNA and the dipeptide Met-Pro (Km, 0.96 mM), revealing its functional identity. Further enzyme characterization showed the enzyme to be a Co2+-, Mn2+-, or Zn2+-dependent metallopeptidase. Optimal APP activity with Met-Pro as the substrate occurred at pH 5 and a temperature of 100 degrees C. The APP was thermostable, with a half-life of >100 min at 80 degrees C. This study represents the first characterization of a hyperthermophilic archaeon APP.

Extreme environments as a resource for microorganisms and novel biocatalysts

The steady increase in the number of newly isolated extremophilic microorganisms and the discovery of their enzymes by academic and industrial institutions underlines the enormous potential of extremophiles for application in future biotechnological processes. Enzymes from extremophilic microorganisms offer versatile tools for sustainable developments in a variety of industrial application as they show important environmental benefits due to their biodegradability, specific stability under extreme conditions, improved use of raw materials and decreased amount of waste products. Although major advances have been made in the last decade, our knowledge of the physiology, metabolism, enzymology and genetics of this fascinating group of extremophilic microorganisms and their related enzymes is still limited. In-depth information on the molecular properties of the enzymes and their genes, however, has to be obtained to analyze the structure and function of proteins that are catalytically active around the boiling and freezing points of water and extremes of pH. New techniques, such as genomics, metanogenomics, DNA evolution and gene shuffling, will lead to the production of enzymes that are highly specific for countless industrial applications. Due to the unusual properties of enzymes from extremophiles, they are expected to optimize already existing processes or even develop new sustainable technologies.

Recent progress towards the application of hyperthermophiles and their enzymes

The discovery of extremophiles has drastically changed our understanding towards the diversity of life itself and the conditions under which it can be sustained. Extremophiles have evolved to withstand and multiply under the extremes of temperature, pressure, pH and salinity. Hyperthermophiles are the group that have adapted to high temperature; many have been found to grow at temperatures above the boiling point of water. This review focuses on recent advances in application-based research on hyperthermophiles and their thermostable enzymes.

Reversion of protein aggregation mediated by Sso7d in cell extracts of Sulfolobus solfataricus

In eukaryotic cells and in Escherichia coli, reversion of protein aggregation is mediated by the network of chaperones belonging to Hsp70 and Hsp100 families [Weibezahn, Bukau and Mogk (2004) Microb. Cell Fact. 3, 1-12]. The thermophilic prokaryotes of the archaea domain lack homologues of these chaperone families, and the mechanisms they use to rescue aggregated proteins are unknown [Macario, Malz and Conway de Macario (2004) Front. Biosci. 9, 1318-1332]. In the present study, we show that stable protein aggregates can be detected in extracts of starved cells of the thermophilic archaeon Sulfolobus solfataricus, and that the protein Sso7d interacts with the aggregates and mediates the disassembly of the aggregates and the re-activation of insolubilized beta-glycosidase in the presence of ATP hydrolysis. Furthermore, we report that heat-induced protein aggregates in extracts of exponential cells of S. solfataricus contain Sso7d that rescues insolubilized proteins in the presence of ATP hydrolysis. Results of these experiments performed in cell extracts are consistent with an in vivo role of Sso7d in reverting protein aggregation.