Stability of pressure-extruded liposomes made from archaeobacterial ether lipids.

Ether lipids were obtained from a wide range of archaeobacteria grown at extremes of pH, temperature, and salt concentration. With the exception of Sulfolobus acidocaldarius, unilamellar and/or multilamellar liposomes could be prepared from emulsions of total polar lipid extracts by pressure extrusion through filters of various pore sizes. Dynamic light scattering, and electron microscopy revealed homogeneous liposome populations with sizes varying from 40 to 230 nm, depending on both the lipid source and the pore size of the filters. Leakage rates of entrapped fluorescent or radioactive compounds established that those archaeobacterial liposomes that contained tetraether lipids were the most stable to high temperatures, alkaline pH, and serum proteins. Most ether liposomes were stable to phospholipase A2, phospholipase B and pancreatic lipase. These properties of archaeobacterial liposomes make them attractive for applications in biotechnology.

Hydroxydiether Lipid Structures in Methanosarcina spp. and Methanococcus voltae.

Hydroxylated diether lipids are the most abundant lipids in Methanosarcina acetivorans, Methanosarcina thermophila, and Methanosarcina barkeri MS and Fusaro, regardless of the substrate used for growth. Structural analysis of the lipid moiety freed of polar head groups revealed that the hydroxydiether lipids of all the Methanosarcina strains were hydroxylated at position 3 of sn-2 phytanyl chains. The finding that Methanosarcina strains synthesize the same hydroxydiether structure suggests that this is a taxonomic characteristic of the genus. Methanococcus voltae produced minor amounts of the 3-hydroxydiether characteristic of Methanosarcina spp. and also the 3'-hydroxydiether described previously for Methanosaeta concilii.

Freeze-fracture planes of methanogen membranes correlate with the content of tetraether lipids.

Methanospirillum hungatei GP1 contained 50% of its ether core lipids (polar lipids less head groups) as tetraether lipids, and its plasma membrane failed to fracture along its hydrophobic domain during freeze-etching. The membrane of Methanosaeta ("Methanothrix") concilii did not contain tetraether lipids and easily fractured to reveal typical intramembranous particles. Methanococcus jannaschii grown at 50 degrees C contained 20% tetraether core lipids, which increased to 45% when cells were grown at 70 degrees C. The frequency of membrane fracture was reduced as the membrane-spanning tetraether lipids approached 45%. As the tetraether lipid content increased, and while fracture was still possible, the particle density in the membrane increased; these added particles could be tetraether lipid complexes torn from the opposing membrane face. The diether membrane (no tetraether lipid) of Methanococcus voltae easily fractured, and the intramembranous particle density was low. Protein-free liposomes containing tetraether core lipids (ca. 45%) also did not fracture, whereas those made up exclusively of diether lipids did split, indicating that tetraether lipids add considerable vertical stability to the membrane. At tetraether lipid concentrations below 45%, liposome bilayers fractured to reveal small intramembranous particles which we interpret to be tetraether lipid complexes.

Formation and Regeneration of Methanococcus voltae Protoplasts.

Methanococcus voltae cells were converted into protoplasts by suspension in anaerobic 0.1 M Tris-HCl buffer containing 0.4 M sucrose and 0.05 M NaCl as osmoprotectants. Protoplast formation was monitored microscopically by observing the conversion of the typical irregularly shaped (uneven peripheries) coccoid whole cells to rounded forms with smooth peripheries. Although the procedure resulted in about 50% lysis of the initial number of cells, the remainder were converted to the rounded form. Analysis by sodium dodecyl sulfate-polyacrylamide gel electrophoresis and electron microscopy of negatively stained cell preparations indicated that the treatment removed the wall layer from whole cells to yield protoplasts. Protoplast regeneration was evaluated by using optimized plating conditions and an anaerobic microplating technique. Between 50 and 63% of the initial number of protoplasts regenerated as colonies on agar medium (35 degrees C, 7 days). The colony and cell morphologies of the regenerated protoplasts were indistinguishable from those of whole cells plated under identical conditions.

Formation of unilamellar liposomes from total polar lipid extracts of methanogens.

Unilamellar liposomes were formed by controlled detergent dialysis of mixed micelles consisting of acetone-insoluble total polar lipids extracted from various methanogens and the detergent n-octyl-beta-D-glucopyranoside. The final liposome populations were studied by dynamic light scattering and electron microscopy. Unilamellar liposomes with mean diameters smaller than 100 nm were obtained with lipid extracts of Methanococcus voltae, Methanosarcina mazei, Methanosaeta concilii, and Methanococcus jannaschii (grown at 50 degrees C), whereas larger (greater than 100-nm) unilamellar liposomes were obtained with lipid extracts of M. jannaschii grown at 65 degrees C. These liposomes were shown to be closed intact vesicles capable of retaining entrapped [14C]sucrose for extended periods of time. With the exception of Methanospirillum hungatei liposomes, all size distributions of the different liposome populations were fairly homogeneous.

Use of natural mRNAs in the cell-free protein-synthesizing systems of the moderate halophile Vibrio costicola.

In vitro protein synthesis was studied in extracts of the moderate halophile Vibrio costicola by using as mRNAs the endogenous mRNA of V. costicola and the RNA of the R17 bacteriophage of Escherichia coli. Protein synthesis (amino acid incorporation) was dependent on the messenger, ribosomes, soluble cytoplasmic factors, energy source, and tRNA(FMet) (in the R17 RNA system) and was inhibited by certain antibiotics. These properties indicated de novo protein synthesis. In the V. costicola system directed by R17 RNA, a protein of the same electrophoretic mobility as the major coat protein of the R17 phage was synthesized. Antibiotic action and the response to added tRNA(FMet) showed that protein synthesis in the R17 RNA system, but not in the endogenous messenger system, absolutely depended on initiation. Optimal activity of both systems was observed in 250 to 300 mM NH4+ (as glutamate). Higher salt concentrations, especially those with Cl- as anion, were generally inhibitory. The R17 RNA-directed system was more sensitive to Cl- ions than the endogenous system was. Glycine betaine stimulated both systems and partly overcame the toxic effects of Cl- ions. Both systems required Mg2+, but in lower concentrations than the polyuridylic acid-directed system previously studied. Initiation factors were removed from ribosomes by washing with 3.0 to 3.5 M NH4Cl, concentrations about three times as high as that needed to remove initiation factors from E. coli ribosomes. Washing with 4.0 M NH4Cl damaged V. costicola ribosomes, although the initiation factors still functioned. Cl- ions inhibited the attachment of initiation factors to tRNA(FMet) but had little effect on binding of initiation factors to R17 RNA.

In vitro protein synthesis by the moderate halophile Vibrio costicola: site of action of Cl- ions.

In vitro protein synthesis in Vibrio costicola [poly(U)-directed incorporation of phenylalanine] was studied. The extent of protein synthesis was limited by the number of ribosomes present. Density gradient centrifugation experiments suggested that, after runoff of ribosomes from the artificial messenger, the 50S subunit was unable to attach to the 30S-messenger complex. As shown previously (M. Kamekura and D. J. Kushner, J. Bacteriol. 160:385-390, 1984), Cl- ions inhibited protein synthesis; indeed, the highest rate of synthesis took place in the lowest attainable Cl- concentration (37 mM). The inhibitory effects were partly reversed by glutamate and betaine, both of which are concentrated within cells of V. costicola. The strongest reversal was seen when both glutamate and betaine were present. Cl- ions can prevent binding of ribosomes to poly(U) and displace ribosomes already bound to this artificial messenger. The effects of Cl- ions on binding were also reversed by glutamate and betaine. Cl- ions did not affect accuracy of translation; they were shown previously (Kamekura and Kushner, J. Bacteriol. 160:385-390, 1984) not to affect phenylalanyl-tRNA synthetase. It was also found that washing ribosomes with inhibitory NaCl concentrations did not interfere with their ability to carry out protein synthesis later in optimal (low) salt concentrations. On the contrary, these ribosomes were more active than before they were washed. We conclude that the main site of action of Cl- in the system studied is on the binding of ribosomes to the mRNA.