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A comparative proteome and transcriptome analysis of Thermoplasma acidophilum cultured under aerobic and anaerobic conditions has been performed. One-thousand twenty-five proteins were identified covering 88% of the cytosolic proteome. Using a label-free quantitation method, we found that approximately one-quarter of the identified proteome (263 proteins) were significantly induced (>2 fold) under anaerobic conditions. Thirty-nine macromolecular complexes were identified, of which 28 were quantified and 15 were regulated under anaerobiosis. In parallel, a whole genome cDNA microarray analysis was performed showing that the expression levels of 445 genes were influenced by the absence of oxygen. Interestingly, more than 40% of the membrane protein-encoding genes (145 out of 335 ORFs) were up- or down-regulated at the mRNA level. Many of these proteins are functionally associated with extracellular protein or peptide degradation or ion and amino acid transport. Comparison of the transcriptome and proteome showed only a weak positive correlation between mRNA and protein expression changes, which is indicative of extensive post-transcriptional regulatory mechanisms in T. acidophilum. Integration of transcriptomics and proteomics data generated hypotheses for physiological adaptations of the cells to anaerobiosis, and the quantitative proteomics data together with quantitative analysis of protein complexes provide a platform for correlation of MS-based proteomics studies with cryo-electron tomography-based visual proteomics approaches.

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The 20S core of the proteasome, which together with the regulatory particle plays a major role in the degradation of proteins in eukaryotic cells, is traversed by an internal system of cavities, namely two antechambers and one central proteolytic chamber. Little is known about the mechanisms underlying substrate binding and translocation of polypeptide chains into the interior of 20S proteasomes. Specifically, the role of the antechambers is not fully understood, and the number of substrate molecules sequestered within the internal cavities at any one time is unknown. Here we have shown that by applying both electron microscopy and tandem mass spectrometry (MS) approaches to this multisubunit complex we obtain precise information regarding the stoichiometry and location of substrates within the three chambers. The dissociation pattern in tandem MS allows us to conclude that a maximum of three green fluorescent protein and four cytochrome c substrate molecules are bound within the cavities. Our results also show that >95% of the population of proteasome molecules contain the maximum number of partially folded substrates. Moreover, we deduce that one green fluorescent protein or two cytochrome c molecules must reside within the central proteolytic chamber while the remaining substrate molecules occupy, singly, both antechambers. The results imply therefore an additional role for 20S proteasomes in the storage of substrates prior to their degradation, specifically in cases where translocation rates are slower than proteolysis. More generally, the ability to locate relatively small protein ligands sequestered within the 28-subunit core particle highlights the tremendous potential of tandem MS for deciphering substrate binding within large macromolecular assemblies.

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By using a functional approach of reconstituting detergent-solubilized membrane proteins into liposomes and following their function in patch-clamp experiments, we identified a novel mechanosensitive (MS) channel in the thermophilic cell wall-less archaeon Thermoplasma volcanium. Sodium dodecyl sulfate polyacrylamide gel electrophoresis (SDS-PAGE) of the enriched protein fractions revealed a band of approx 15 kDa comparable to MscL, the bacterial MS channel of large conductance. 20 N-terminal residues determined by protein microsequencing, matched the sequence to an unknown open reading frame in the genome of a related species Thermoplasma acidophilum. The protein encoded by the T. acidophilum gene was cloned and expressed in Escherichia coli and reconstituted into liposomes. When examined for function, the reconstituted protein exhibited properties typical of an MS ion channel: 1) activation by negative pressure applied to the patch-clamp pipet, 2) blockage by gadolinium, and 3) activation by the anionic amphipath trinitrophenol. In analogy to the nomenclature used for bacterial MS channels, the MS channel of T acidophilum was termed MscTA. Secondary structural analysis indicated that similar to MscL, the T. acidophilum MS protein may have two transmembrane domains, suggesting that MS channels of thermophilic Archaea belong to a family of structurally related MscL-like ion channels with two membrane-spanning regions. When the mscTA gene was expressed in the mscL- knockout strain and the MscTA protein reconstituted into liposomes, the gating of MscTA was characterized by very brief openings of variable conductance. In contrast, when the mscTA gene was expressed in the wild-type mscL+ strain of E. coli, the gating properties of the channel resembled MscL. However, the channel had reduced conductance and differed from MscL in its kinetics and in the free energy of activation, suggesting that MscTA and MscL can form functional complexes and/or modulate each other activity. Similar to MscL, MscTA exhibited an increase in activity in liposomes made of phospholipids having shorter acyl chain, suggesting a role of hydrophobic mismatch in the function of prokaryotic MS channels.

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The main glycophospholipid of Thermoplasma acidophilum, grown at 39 degrees C, is composed of a di-isopranol-2,3-glycerotetraether. It has been characterized in hydrated systems by calorimetry. Unlike its equivalent grown at 59 degrees C, it shows complex phase properties, which include at least three different phases, (1) a liquid-analogue state (C), which is stable above 20 degrees C, (2) a metastable solid-analogue state (A) formed by supercooling of the liquid-analogue state (C) and (3) a stable solid-analogue state (B), which is slowly formed and may include a close chain packing of lipids and a network of hydrogen bonds between the headgroups. A high fraction of acyclic isopranol chains seems to be a prerequisite for the formation of state (B). A phase diagram, displaying the observed states and the transitions between them is proposed.

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The mechanism by which acidophilic bacteria generate and maintain their cytoplasmic pH close to neutrality was investigated. For this purpose we determined the components of proton motive force in the eubacterium Bacillus acidocaldarius and the archaebacterium Thermoplasma acidophilum. After correction for probe binding, the proton motive force of untreated cells was 190 to 240 mV between external pH 2 and 4. Anoxia diminished total proton motive force and the transmembrane pH difference by 60 to 80 mV. The protonophore 2,4-dinitrophenol abolished the total proton motive force almost completely and diminished the transmembrane pH difference by at least two units. However, even after correction for probe binding, protonophore-treated cells maintained a pH difference of approximately one unit.

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Thermoplasma acidophilum, a mycoplasma-like organism, grows optimally at 56 degrees C and pH2. The low temperature extreme of growth is 37 degrees C. The plasma membrane of cells grown at 37 degrees C was isolated and characterized physicobiochemically. Membrane lipids which comprise 25% of the membrane dry weight consist mainly of two repetitively methyl-branched C40 side chains that were ether-linked to two glycerol molecules. The lipid structures were elucidated by combined gas chromatography-mass spectroscopy, direct probe mass spectroscopy and 13C NMR. 37 degrees C-grown cells contained lipids with 42% more pentane cyclization than the 56 degrees C-grown cells. In 37 degrees C-grown cells, phospholipid and serine content decreased by about 10% each, carbohydrate content increased by 5%. EPR studies demonstrated an increase in membrane lipid fluidity of 37 degrees C-grown cells with an upper transition temperature at 35 degrees C which was shifted down by 10 degrees C compared with cells grown at 56 degrees C. Membrane-bound ATPase activities also indicated similar changes upon adaptation. There is a close correlation between membrane fluidity and physiological functioning of this membrane-bound enzyme.

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Electron microscopy of thin sections of Thermoplasma acidophilum confirmed previous observations of the absence of a typical cell wall in this organism. Negatively stained specimens revealed the almost consistent occurrence in both strains examined of monotrichously arranged flagella, about 9 micrometer long, which describe a sinuous curve with a wavelength of 1.5 to 2.0 micrometer and an amplitude of 0.33 to 0.59 micrometer. Motility of T. acidophilum could be demonstrated microscopically by microcinematography and macroscopically. The theoretical implications of the demonstration of functioning flagella in a wall-defective organism are discussed in the light of current theories of the mechanism of flagellar motility and from a taxonomic point of view.

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The thermophilic mycoplasma Thermoplasma acidophilum has tightly bound to its DNA a protein that closely resembles the histones of eukaryotes. DNA associated with this protein is more stable than free DNA against thermal denaturation by about 40 degrees C, as shown in both native nucleoprotein and in hybrid nucleoprotein reconstituted in vitro with calf DNA. Since only about 20 percent of the DNA in this organism is associated with the histone-like protein, we suggest that its physiological function is to prevent complete separation of the DNA strands during brief exposures of the organism to denaturing conditions, and thus to facilitate rapid renaturation when normal environmental conditions return.

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The surface charge density and the zeta-potential of Thermoplasma acidophila was estimated from microscopic electrophoresis experiments. The cells moved towards the positive electrode. The mobility remained constant from pH 2 to 5, and increased for pH values higher than 6. The mobility at pH 6 decreased dramatically with increased external Ca2+ concentration. At pH 2 and an ionic strength similar to that of the growth medium, the zeta-potential was about 8 mV, negative relative to the bulk medium; the surface charge density was 1360esu/cm-2 which corresponds to one elementary charge per 3500 A2.

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