Cryo-electron microscopy of an extremely halophilic microbe: technical aspects.

Most halophilic Archaea of the class Halobacteriaceae depend on the presence of several molar sodium chloride for growth and cell integrity. This poses problems for structural studies, particularly for electron microscopy, where the high salt concentration results in diminished contrast. Since cryo-electron microscopy of intact cells provides new insights into the cellular and molecular organization under close-to-live conditions, we evaluated strategies and conditions to make halophilic microbes available for investigations in situ. Halobacterium salinarum, the test organism for this study, usually grows at 4.3 M NaCl. Adaptation to lower concentrations and subsequent NaCl reduction via dialysis led to still vital cells at 3 M salt. A comprehensive evaluation of vitrification parameters, thinning of frozen cells by focused-ion-beam micromachining, and cryo-electron microscopy revealed that structural studies under high salt conditions are possible in situ.

Gas vesicles isolated from Halobacterium cells by lysis in hypotonic solution are structurally weakened.

Analysis of pressure-collapse curves of Halobacterium cells containing gas vesicles and of gas vesicles released from such cells by hypotonic lysis shows that the isolated gas vesicles are considerably weaker than those present within the cells: their mean critical collapse pressure was around 0.049-0.058 MPa, as compared to 0.082-0.095 MPa for intact cells. The hypotonic lysis procedure, which is widely used for the isolation of gas vesicles from members of the Halobacteriaceae, thus damages the mechanical properties of the vesicles. The phenomenon can possibly be attributed to the loss of one or more structural gas vesicle proteins such as GvpC, the protein that strengthens the vesicles built of GvpA subunits: Halobacterium GvpC is a highly acidic, typically "halophilic" protein, expected to denature in the absence of molar concentrations of salt.

Complexity of gas vesicle biogenesis in Halobacterium sp. strain NRC-1: identification of five new proteins.

The genome of Halobacterium sp. strain NRC-1 contains a large gene cluster, gvpMLKJIHGFEDACNO, that is both necessary and sufficient for the production of buoyant gas-filled vesicles. Due to the resistance of gas vesicles to solubilization, only the major gas vesicle protein GvpA and a single minor protein, GvpC, were previously detected. Here, we used immunoblotting analysis to probe for the presence of gas vesicle proteins corresponding to five additional gvp gene products. Polyclonal antisera were raised in rabbits against LacZ-GvpF, -GvpJ, and -GvpM fusion proteins and against synthetic 15-amino-acid peptides from GvpG and -L. Immunoblotting analysis was performed on cell lysates of wild-type Halobacterium sp. strain NRC-1, gas vesicle-deficient mutants, and purified gas vesicles, after purification of LacZ fusion antibodies on protein A and beta-galactosidase affinity columns. Our results show the presence of five new gas vesicle proteins (GvpF, GvpG, GvpJ, GvpL, and GvpM), bringing the total number of proteins identified in the organelles to seven. Two of the new gas vesicle proteins are similar to GvpA (GvpJ and GvpM), and two proteins contain predicted coiled-coil domains (GvpF and GvpL). GvpL exhibited a multiplet ladder on sodium dodecyl sulfate-polyacrylamide gels indicative of oligomerization and self-assembly. We discuss the possible functions of the newly discovered gas vesicle proteins in biogenesis of these unique prokaryotic flotation organelles.

Regulation of gas vesicle formation in halophilic archaea.

The halophilic archaea Halobacterium salinarum and Haloferax mediterranei produce gas vesicles depending on the growth phase and on environmental factors such as light, salt, or oxygen. Fourteen different gvp genes (gvpACNO and gvpDEFGHIJKLM) are involved in their formation, and the regulation of gvp gene expression occurs at the transcriptional and translational level. Haloferax volcanii offers a clean genetic background for the functional analysis of gas vesicle genes by transformation experiments. Such experiments show that the promoter of the gvpA gene encoding the major gas vesicle structural protein is activated by the endogenous basic leucine-zipper protein GvpE. On the other hand, the GvpD protein, which contains a p-loop motif, is involved either directly or indirectly in the repression of the gvpA promoter activity. Eight of the fourteen p-gvp genes (p-gvpAO and p-gvpFGJKLM) enable gas vesicle formation in Hf. volcanii transformants and thus constitute the minimal p-vac region.

The fla gene cluster is involved in the biogenesis of flagella in Halobacterium salinarum.

In this study, a flagella-related protein gene cluster is described for Halobacterium salinarum. The fla gene cluster is located upstream of the flagellin genes flgB1-3 and oriented in the opposite direction. It consists of nine open reading frames (ORFs): htpIX, a member of the halobacterial transducer protein gene family, and the genes flaD-K. The genes flaD, E, G, H, I and J share high homologies with genes from other Archaea. Interestingly, flaK shows similarities to bacterial genes involved in the regulation of flagellar synthesis. The ORFs of flaH, flaI and flaK contain sequences coding for nucleotide binding sites. Furthermore, flaI contains a motif called the bacterial type II secretion protein E signature, indicating a functional relation to members of the bacterial pili type IV-type II secretion protein superfamily. Reverse transcription-polymerase chain reaction (RT-PCR) analysis revealed that the genes flaE to flaK are transcribed into one polycistronic message. In frame deletion mutants of flaI were generated by gene replacement. The deletion strain lacks motility and belongs to the fla(-) mutant class, indicating that it is deficient in flagellar biogenesis. The overall amount of flagellin protein in Delta flaI cells is reduced, although transcription of the flagellin genes is unaffected. Therefore, the flaI gene product is involved in the biosynthesis, transport or assembly of flagella in H. salinarum.

Eight of fourteen gvp genes are sufficient for formation of gas vesicles in halophilic archaea.

The minimal number of genes required for the formation of gas vesicles in halophilic archaea has been determined. Single genes of the 14 gvp genes present in the p-vac region on plasmid pHH1 of Halobacterium salinarum (p-gvpACNO and p-gvpDEFGHIJKLM) were deleted, and the remaining genes were tested for the formation of gas vesicles in Haloferax volcanii transformants. The deletion of six gvp genes (p-gvpCN, p-gvpDE, and p-gvpHI) still enabled the production of gas vesicles in H. volcanii. The gas vesicles formed in some of these gvp gene deletion transformants were altered in shape (Delta I, Delta C) or strength (Delta H) but still functioned as flotation devices. A minimal p-vac region (minvac) containing the eight remaining genes (gvpFGJKLM-gvpAO) was constructed and tested for gas vesicle formation in H. volcanii. The minvac transformants did not form gas vesicles; however, minvac/gvpJKLM double transformants contained gas vesicles seen as light refractile bodies by phase-contrast microscopy. Transcript analyses demonstrated that minvac transformants synthesized regular amounts of gvpA mRNA, but the transcripts derived from gvpFGJKLM were mainly short and encompassed only gvpFG(J), suggesting that the gvpJKLM genes were not sufficiently expressed. Since gvpAO and gvpFGJKLM are the only gvp genes present in minvac/JKLM transformants containing gas vesicles, these gvp genes represent the minimal set required for gas vesicle formation in halophilic archaea. Homologs of six of these gvp genes are found in Anabaena flos-aquae, and homologs of all eight minimal halobacterial gvp genes are present in Bacillus megaterium and in the genome of Streptomyces coelicolor.

Role of flagellins from A and B loci in flagella formation of Halobacterium salinarum.

Haloarchaeal flagella are composed of a number of distinct flagellin proteins, specified by genes in two separate operons (A and B). The roles of these flagellins were assessed by studying mutants of H. salinarum with insertions in either the A or the B operon. Cells of the flgA- mutant produced abnormally short, curved flagella that were distributed all over the cell surface. The flgA2- strain produced straight flagella, mainly found at the poles. The flgB- mutant had flagella of the same size and spiral shape as wild-type cells, but these cells also showed unusual outgrowths, which appeared to be sacs filled with basal body-like structures. In broth cultures of this mutant, the medium accumulated flagella with basal body-like structures at their ends.

Structural characteristics of halobacterial gas vesicles.

Gas vesicle formation in halophilic archaea is encoded by a DNA region (the vac region) containing 14 different genes: gvpACNO and gvpDEFGHIJKLM. In Halobacterium salinarum PHH1 (which expresses the p-vac region from plasmid pHH1), gas vesicles are spindle shaped, whereas predominantly cylindrical gas vesicles are synthesized by the chromosomal c-vac region of H. salinarum PHH4 and the single chromosomal mc-vac region of Haloferax mediterranei. Homologous complementation of gvp gene clusters derived from the chromosomal c-vac region led to cylindrical gas vesicles in transformants and proved that the activity of the c-gvpA promoter depended on a gene product from the c-gvpE-M DNA region. Heterologous complementation experiments with transcription units of different vac regions demonstrated that the formation of chimeric gas vesicles was possible. Comparison of micrographs of wild-type and chimeric gas vesicles indicated that the shape was not exclusively determined by GvpA, the major structural protein of the gas vesicle wall. More likely, a dynamic equilibrium of several gvp gene products was responsible for determination of the shape. Transmission electron microscopy of frozen hydrated, wild-type gas vesicles showed moiré patterns due to the superposition of the front and back parts of the ribbed gas vesicle envelope. Comparison of projections of model helices with the moiré pattern seen on the cylindrical part of the gas vesicles provided evidence that the ribs formed a helix of low pitch and not a stack of hoops.

Dynamics of different functional parts of bacteriorhodopsin: H-2H labeling and neutron scattering.

We show that dynamics of specific amino acids within a protein can be characterized by neutron spectroscopy and hydrogen-deuterium labeling, and we present data on the motions of a selected set of groups within bacteriorhodopsin (BR), the retinal-based proton pump in the purple membrane of halophilic Archaea. Elastic incoherent neutron scattering experiments allow the definition of motions in the nano- to picosecond time scale and have revealed a dynamical transition from a harmonic to a softer, anharmonic atomic fluctuation regime in the global behavior of proteins. Biological activity in proteins is correlated with this transition, suggesting that flexibility is required for function. Elastic incoherent neutron scattering is dominated by H atom scattering, and to study the dynamics of a selected part of BR, fully deuterated purple membrane with BR containing H-retinal, H-tryptophan, and H-methionine was prepared biosynthetically in Halobacterium salinarum. These amino acids cluster in the functional center of the protein. In contrast to the protein globally, the thermal motions of the labeled atoms were found to be shielded from solvent melting effects at 260 K. Above this temperature, the labeled groups appear as more rigid than the rest of the protein, with a significantly smaller mean square amplitude of motion. These experimental results quantify the dynamical heterogeneity of BR (which meets the functional requirements of global flexibility), on the one hand, to allow large conformational changes in the molecule and of a more rigid region in the protein, on the other, to control stereo-specific selection of retinal conformations.

Protonation dynamics of the extracellular and cytoplasmic surface of bacteriorhodopsin in the purple membrane.

The dynamics of proton binding to the extracellular and the cytoplasmic surfaces of the purple membrane were measured by laser-induced proton pulses. Purple membranes, selectively labeled by fluorescein at Lys-129 of bacteriorhodopsin, were pulsed by protons released in the aqueous bulk from excited pyranine (8-hydroxy-1,3,6-pyrenetrisulfonate) and the reaction of protons with the indicators was measured. Kinetic analysis of the data imply that the two faces of the membrane differ in their buffer capacities and in their rates of interaction with bulk protons. The extracellular surface of the purple membrane contains one anionic proton binding site per protein molecule with pK = 5.1. This site is within a Coulomb cage radius (approximately 15 A) from Lys-129. The cytoplasmic surface of the purple membrane bears 4-5 protonable moieties (pK = 5.1) that, due to close proximity, function as a common proton binding site. The reaction of the proton with this cluster is at a very fast rate (3.10(10) M-1.s-1). The proximity between the elements is sufficiently high that even in 100 mM NaCl they still function as a cluster. Extraction of the chromophore retinal from the protein has a marked effect on the carboxylates of the cytoplasmic surface, and two to three of them assume positions that almost bar their reaction with bulk protons. The protonation dynamics determined at the surface of the purple membrane is of relevance both for the vectorial proton transport mechanism of bacteriorhodopsin and for energy coupling, not only in halobacteria, but also in complex chemiosmotic systems such as mitochondrial and thylakoid membranes.

Functional studies of the gvpACNO operon of Halobacterium salinarium reveal that the GvpC protein shapes gas vesicles.

Gas vesicle (Vac) synthesis in Halobacterium salinarium PHH1 involves the expression of the plasmid pHH1-encoded vac (p-vac) region consisting of 14 different gvp genes that are arranged in two clusters, p-gvpACNO and, oriented in the direction opposite to that of gvpA, p-gvpDEFGHIJKLM. The p-gvpACNO region was analyzed at the transcriptional and functional levels in H. salinarium and in Haloferax volcanii transformants containing subfragments of the p-vac region. The p-gvpACNO genes were transcribed as several mRNAs: the 270-nucleotide (nt) p-gvpA transcript, encoding the major structural protein, occurred in large amounts, and minor amounts of three different readthrough transcripts (p-gvpACN, and p-gvpACNO mRNA) were found. In addition, the p-gvpO gene gave rise to two separate mRNA species: a 550-nt mRNA starting at the ATG and spanning the entire reading frame and a 420-nt RNA encompassing the second half of the p-gvpO gene. The requirement of p-gvpC, p-gvpN, and p-gvpO gene expression for gas vesicle synthesis was assessed by transformation experiments using the VAC- species Haloferax volcanii as the recipient. A delta C transformant, harboring the p-vac region with a deletion of the p-gvpC gene, produced large amounts of irregularly shaped gas vesicles. A shape-forming function of p-GvpC was demonstrated by complementation of the delta C transformant with the p-gvpC gene, resulting in wild-type-shaped gas vesicles. In the delta N transformant, the level of gas vesicle synthesis was very low, indicating that the p-GvpN protein is not required for gas vesicle assembly but may enhance gas vesicle synthesis. The p-gvpN deletion did not affect accumulation of p-gvpACO mRNA but reduced the separate p-gvpO transcription. The delta O transformant was Vac- and had a strongly decreased level of p-gvpACN mRNAs, demonstrating that the p-GvpO protein is required for gas vesicle synthesis and may affect transcription of this DNA region.

Gas vesicles.

The gas vesicle is a hollow structure made of protein. It usually has the form of a cylindrical tube closed by conical end caps. Gas vesicles occur in five phyla of the Bacteria and two groups of the Archaea, but they are mostly restricted to planktonic microorganisms, in which they provide buoyancy. By regulating their relative gas vesicle content aquatic microbes are able to perform vertical migrations. In slowly growing organisms such movements are made more efficiently than by swimming with flagella. The gas vesicle is impermeable to liquid water, but it is highly permeable to gases and is normally filled with air. It is a rigid structure of low compressibility, but it collapses flat under a certain critical pressure and buoyancy is then lost. Gas vesicles in different organisms vary in width, from 45 to > 200 nm; in accordance with engineering principles the narrower ones are stronger (have higher critical pressures) than wide ones, but they contain less gas space per wall volume and are therefore less efficient at providing buoyancy. A survey of gas-vacuolate cyanobacteria reveals that there has been natural selection for gas vesicles of the maximum width permitted by the pressure encountered in the natural environment, which is mainly determined by cell turgor pressure and water depth. Gas vesicle width is genetically determined, perhaps through the amino acid sequence of one of the constituent proteins. Up to 14 genes have been implicated in gas vesicle production, but so far the products of only two have been shown to be present in the gas vesicle: GvpA makes the ribs that form the structure, and GvpC binds to the outside of the ribs and stiffens the structure against collapse. The evolution of the gas vesicle is discussed in relation to the homologies of these proteins.

Glucose alone does not completely hydrate bacteriorhodopsin in glucose-embedded purple membrane.

Glucose embedding is a simple and highly effective method for preparing biological macromolecules for high-resolution electron microscopy. The investigation of conditions that can trap the M-state intermediate in the bacteriorhodopsin (bR) photocycle has revealed, however, that when glucose-embedded bR is prepared at ambient humidity, it does not fully retain the capability to execute a proper photocycle. However, 'native' photocycle properties are returned after glucose-embedded samples are equilibrated at 81% relative humidity. Equilibration at relative humidities significantly higher than 81% causes glucose to dissolve in its own water of hydration, resulting in samples that may be too thick to be suitable for electron microscopy. The results obtained with bR indicate that caution should be taken with other biological specimens, and it cannot be assumed that glucose-embedded biological macromolecules retain completely their native, hydrated structure, even when high-resolution electron diffraction patterns are obtained. Equilibration of such samples at high humidity may generally be a worthwhile precaution when using the glucose-embedding technique.

Function and biosynthesis of gas vesicles in halophilic Archaea.

The proteinaceous gas vesicles produced by various microorganisms including halophilic Archaea are hollow, gas-filled structures with a hydrophobic inner and a hydrophilic outer surface. The structural components of gas vesicles and their biosynthesis are still under investigation; an 8-kDa polypeptide appears to be the major constituent of the gas-vesicle envelope. Genetic analysis of the halobacterial gas-vesicle synthesis revealed an unexpected complexity: about 14 genes organized in three transcription units are involved in gas-vesicle structure, assembly, and gene regulation. Here we describe the comparison of three different genomic regions encoding gas vesicles in Halobacterium salinarium (p-vac and c-vac regions) and Haloferax mediterranei (mc-vac region) and speculate on the function of the gene products involved in gas-vesicle synthesis.

Chromosomal structure of the halophilic archaebacterium Halobacterium salinarium.

The chromosomal structure of the extremely halophilic archaebacterium Halobacterium salinarium was examined. Sheared chromosomes prepared from the bacteria in the late exponential phase were separated into two peaks (peaks I and II) by sucrose gradient centrifugation, suggesting that the chromosomes consist of two parts differing in quality. The UV spectra of peaks I and II resembled those of DNA and eukaryotic chromatin, respectively. Electron microscopic observations revealed that the major component of peak I was protein-free DNA, while the major components of peak II were rugged thick fibers with a diameter of 17 to 20 nm. The rugged fibers basically consisted of bacterial nucleosome-like structures composed of DNA and protein, as demonstrated in experiments with proteinase and nuclease digestion. Whole-mount electron microscopic observations of the chromosomes directly spread onto a water surface revealed a configuration in which the above-described regions were localized on a continuous DNA fiber. From these results it is concluded that the H. salinarium chromosome is composed of regions of protein-free DNA and DNA associated with nucleosome-like structures. Peaks I and II were predominant in the early exponential phase and stationary phase, respectively; therefore, the transition of the chromosome structure between non-protein-associated and protein-associated forms seems to be related to the bacterial growth phase.

Characterization and preliminary attempts for derivatization of crystals of large ribosomal subunits from Haloarcula marismortui diffracting to 3 A resolution.

An improved form of crystals of large (50 S) ribosomal subunits from Haloarcula marismortui, formally named Halobacterium marismortui, diffracting to 3 A resolution, has been obtained by the addition of 1 mM-Cd2+ to the crystallization medium, which contained more than 1.9 M of other salts. The improved crystals, grown from functionally active particles to an average size of 0.3 mm x 0.3 mm x 0.08 mm, are isomorphous with the previously reported ones, which diffracted to 4.5 A. They are of space group C222(1), cell dimensions a = 210 A, b = 300 A, c = 581 A, and contain one particle in the asymmetric unit. Their superior internal order is reflected not only in their high resolution, but also in their reasonable mosaicity (less than 0.3 degrees). In contrast to the previously grown crystals, the new ones are of adequate mechanical strength and survive well the shock-cooling treatment. Due to their weak diffracting power, all crystallographic studies have been performed with synchrotron radiation. At cryotemperature, these crystals showed no measurable decay for a few days of irradiation and a complete diffraction data set could be collected from a single crystal. Efforts for initial phasing by specific and quantitative derivatization with super-dense heavy-atom clusters are in progress.

The interplay between X-ray crystallography, neutron diffraction, image reconstruction, organo-metallic chemistry and biochemistry in structural studies of ribosomes.

Crystals of ribosomes, their complexes with components of protein biosynthesis, their natural, mutated and modified subunits, have been subjected to X-ray and neutron crystallographic analyses. Electron microscopy and 3-dimensional image reconstruction, supported by biochemistry, genetic, functional and organo-metallic studies were employed for facilitating phasing of the crystallographic data. For example, a monofunctional multi heavy-atom cluster (undecagold) was designed for covalent and quantitative binding to ribosomes. The modified particles were crystallized isomorphously with the native ones. Their difference-Patterson maps contain indications for the usefulness of these derivatives for subsequent phasing. Models of the ribosome and its large subunit were reconstructed from tilt series of 2-dimensional sheets. The comparison of the various reconstructed images enabled an initial assessment of the reliability of these models and led to tentative assignments of several functional features. These include the presumed sites for binding mRNA and for codon-anticodon interactions, the path taken by the nascent protein chain and the mode for tRNA binding to ribosomes. These assignments assisted in the design of biologically meaningful crystal systems. The reconstructed models are being used to identify structural features in initial density maps derived from X-ray and neutron diffraction data.

A DNA region of 9 kbp contains all genes necessary for gas vesicle synthesis in halophilic archaebacteria.

We determined the minimal size of the genomic region necessary for gas vesicle synthesis in halophilic archaebacteria by transformation experiments, comparative DNA sequence analysis and investigation of gas vesicle (Vac) mutants. The comparison of the three genomic regions encoding gas vesicles in Halobacterium halobium (p-vac- and c-vac-region) and Haloferax mediterranei (mc-vac-region) indicates high DNA sequence similarity throughout a contiguous sequence of 9 kbp. In each case, this area encompassed at least 13 open reading frames (ORFs). Ten of these ORFs (gvpD to gvpM) were located 5' to the vac gene encoding the major gas vesicle protein, but were transcribed from the opposite strand. At least two ORFs (gvpC, and gvpN) were located 3' to each vac gene and transcribed from the same strand as the respective vac gene. In the p-vac-region present on plasmid pHH1 these ORFs were transcribed as at least three units, one transcript encompassing gvpD-gvpE, the second encompassing ORFs gvpF to gvpM, and the third unit comprising the ORFs located 3' to the p-vac gene. In H. halobium Vac mutants copies of the insertion elements ISH2, ISH23, ISH26 or ISH27 were found to be integrated throughout the p-vac-region. The de novo synthesis of gas vesicles was tested by transformation of the Vac-negative species, Haloferax volcanii, with various subfragments of the mc-vac- or p-vac-region cloned into vector plasmids. In contrast to a fragment containing the entire 9 kbp region, none of the subfragments tested was sufficient to promote gas vesicle synthesis. However, gas vesicle synthesis could be restored in each Vac mutant containing an ISH element when the entire transcription unit encompassing the mutated gene on pHH1 was present in the wild-type form on the vector construct.

Segregation of modified bacteriorhodopsin aggregations in reconstituted vesicle membrane induced by the change of thermodynamical parameters.

It was clearly shown that the change in thermodynamical parameters could cause the segregation of membrane protein aggregations in the phospholipid membrane. At first, reconstituted vesicles were prepared with a membrane protein, bacteriorhodopsin and a constituent phospholipid of biomembranes, L-alpha-dimyristoyl phosphatidylcholine. When the temperature of the suspension was decreased or the osmotic pressure was increased by adding poly(ethylene glycol) to this vesicle suspension at 23 degrees, the circular dichroism spectra showed a typical band indicating bacteriorhodopsin trimer formation implying their aggregation. This suggests that the aggregation of trimers proceeded by adding poly(ethylene glycol) into vesicle suspension, just as it proceeded by decreasing the temperature. Next, vesicles were prepared with fluorescein isothiocyanate-labeled bacteriorhodopsin, photoemissive bacteriorhodopsin and L-alpha-dimyristoyl phosphatidylcholine. The excitation energy transfer between the two modified proteins was measured by fluorescence spectroscopy. In this case, however, when poly(ethylene glycol) was added into the suspension, the yield of the excitation energy transfer decreased. This result indicates that modified proteins aggregate separately in a segregated form in the vesicle membrane.