Rhodospirillum salinarum sp. nov., a halophilic photosynthetic bacterium isolated from a Portuguese saltern

A new species of halophilic photosynthetic bacteria, Rhodospirillum salinarum, has been isolated and described. Its natural habitat are the terminal crystallization ponds of solar salt production plants. R. salinarum grows optimally at 42°C in the presence of 6–18% NaCl (w/v). Growth requirements are complex, yeast extract and peptone being required both for aerobic heterotrophic and for anaerobic phototrophic growth. Increasing concentrations of NaCl in the growth media did not give rise to any corresponding increase in intracellular concentrations of K⁺, Na⁺, polyalcohols or amino acids. Malate dehydrogenase from R. salinarum is not halophilic, being inhibited even at low concentrations of Na⁺ or K⁺. The GC mol % of DNA from R. salinarum is markedly higher than that for DNA from R. salexigens, the only previously described halophilic species of the genus Rhodospirillum.     

Lipopolysaccharide-induced gene expression in murine macrophages is enhanced by prior exposure to oxLDL

Uptake of modified lipoproteins by macrophages results in the formation of foam cells. We investigated how foam cell formation affects the inflammatory response of macrophages. Murine bone marrow-derived macrophages were treated with oxidized LDL (oxLDL) to induce foam cell formation. Subsequently, the foam cells were activated with lipopolysaccharide (LPS), and the expression of lipid metabolism and inflammatory genes was analyzed. Furthermore, gene expression profiles of foam cells were analyzed using a microarray. We found that prior exposure to oxLDL resulted in enhanced LPS-induced tumor necrosis factor (TNF) and interleukin-6 (IL-6) gene expression, whereas the expression of the anti-inflammatory cytokine IL-10 and interferon-beta was decreased in foam cells. Also, LPS-induced cytokine secretion of TNF, IL-6, and IL-12 was enhanced, whereas secretion of IL-10 was strongly reduced after oxLDL preincubation. Microarray experiments showed that the overall inflammatory response induced by LPS was enhanced by oxLDL loading of the macrophages. Moreover, oxLDL loading was shown to result in increased nuclear factor-kappaB activation. In conclusion, our experiments show that the inflammatory response to LPS is enhanced by loading of macrophages with oxLDL. These data demonstrate that foam cell formation may augment the inflammatory response of macrophages during atherogenesis, possibly in an IL-10-dependent manner.     

Bovine Brain Myelin Glycerophosphocholine Choline Phosphodiesterase is an Alkaline Lysosphingomyelinase of the eNPP-Family, Regulated by Lysosomal Sorting

Glycerophosphocholine choline phosphodiesterase (GPC-Cpde) is a glycosylphosphatidylinositol (GPI)-anchored alkaline hydrolase that is expressed in the brain and kidney. In brain the hydrolase is synthesized by the oligodendrocytes and expressed on the myelin membrane. There are two forms of brain GPC-Cpde, a membrane-linked (mGPC-Cpde) and a soluble (sGPC-Cpde). Here we report the characterisation sGPC-Cpde from bovine brain. The amino acid sequence was identical to ectonucleotide pyrophosphatase/phosphodiesterase 6 (eNPP6) precursor, lacking the N-terminal signal peptide region and a C-terminal stretch, suggesting that the hydrolase was solubilised by C-terminal proteolysis, releasing the GPI-anchor. sGPC-Cpde existed as two isoforms, a homodimer joined by a disulfide bridge linking C414 from each monomer, and a monomer resulting from proteolysis N-terminally to this disulfide bond. The only internal disulfide bridge, linking C142 and C154, stabilises the choline-binding pocket. sGPC-Cpde was specific for lysosphingomyelin, displaying 1 to 2 orders of magnitude higher catalytic activity than towards GPC and lysophosphatidylcholine, suggesting that GPC-Cpde may function in the sphingomyelin signaling, rather than in the homeostasis of acylglycerophosphocholine metabolites. The truncated high mannose and bisected hybrid type glycans linked to N118 and N341 of sGPC-Cpde is a hallmark of glycans in lysosomal glycoproteins, subjected to GlcNAc-1-phosphorylation en route through Golgi. Thus, sGPC-Cpde may originate from the lysosomes, suggesting that lysosomal sorting contributes to the level of mGPC-Cpde on the myelin membrane.     

Development of floating rafts after the rewetting of cut-over bogs: the importance of peat quality

The usual method of restoring cut-over bogs is to rewet the peat surface, but this often leads to the remaining peat layers being deeply inundated. For Sphagnum-dominated vegetation to develop at deeply inundated locations, it is important for floating rafts of buoyant residual peat to develop. In this study, the chemical and physical characteristics of buoyant and inundated peat collected from rewetted cut-over bog were compared. In general, buoyant peat was poorly humified; high methane (CH₄) production rates (≥2?µmol?g^?1?DW?day^?1) were important to ensure buoyancy. Although the peat water CH₄ concentrations increased with depth, the CH₄ production rates were higher in the uppermost peat layers. High CH₄ production rates were related positively with P concentrations and negatively with lignin concentrations. The pH to bulk density ratio (≥0.05) also appeared to be a good indicator of CH₄ production rates, providing an easy and cheap way to measure the variable for restoration practitioners. Our results indicated that analysing certain simple characteristics of the residual peat can greatly improve the success of the rewetting measures taken in cut-over bogs. If the analysis reveals that the residual peat is unsuitable for floating raft formation, deep inundation is inappropriate unless suitable peat from other locations can be introduced.     

In vivo modulation of extracellular hippocampal glutamate and GABA levels and limbic seizures by group I and II metabotropic glutamate receptor ligands

The effects of several metabotropic receptor (mGluR) ligands on baseline hippocampal glutamate and GABA overflow in conscious rats and the modulation of limbic seizure activity by these ligands were investigated. Intrahippocampal mGluR group I agonist perfusion via a microdialysis probe [1 mm (R,S)-3,5-dihydroxyphenylglycine] induced seizures and concomitant augmentations in amino acid dialysate levels. The mGlu1a receptor antagonist LY367385 (1 mm) decreased baseline glutamate but not GABA concentrations, suggesting that mGlu1a receptors, which regulate hippocampal glutamate levels, are tonically activated by endogenous glutamate. This decrease in glutamate may contribute to the reported LY367385-mediated anticonvulsant effect. The mGlu5 receptor antagonist 2-methyl-6-(phenylethynyl)-pyridine (50 mg/kg) also clearly abolished pilocarpine-induced seizures. Agonist-mediated actions at mGlu2/3 receptors by LY379268 (100 microm, 10 mg/kg intraperitoneally) decreased basal hippocampal GABA but not glutamate levels. This may partly explain the increased excitation following systemic LY379268 administration and the lack of complete anticonvulsant protection within our epilepsy model with the mGlu2/3 receptor agonist. Group II selective mGluR receptor blockade with LY341495 (1-10 microm) did not alter the rats' behaviour or hippocampal amino acid levels. These data provide a neurochemical basis for the full anticonvulsant effects of mGlu1a and mGlu5 antagonists and the partial effects observed with mGlu2/3 agonists in vivo.     

A tandem affinity purification-based technology platform to study the cell cycle interactome in Arabidopsis thaliana

Defining protein complexes is critical to virtually all aspects of cell biology because many cellular processes are regulated by stable protein complexes, and their identification often provides insights into their function. We describe the development and application of a high throughput tandem affinity purification/mass spectrometry platform for cell suspension cultures to analyze cell cycle-related protein complexes in Arabidopsis thaliana. Elucidation of this protein-protein interaction network is essential to fully understand the functional differences between the highly redundant cyclin-dependent kinase/cyclin modules, which are generally accepted to play a central role in cell cycle control, in all eukaryotes. Cell suspension cultures were chosen because they provide an unlimited supply of protein extracts of actively dividing and undifferentiated cells, which is crucial for a systematic study of the cell cycle interactome in the absence of plant development. Here we report the mapping of a protein interaction network around six known core cell cycle proteins by an integrated approach comprising generic Gateway-based vectors with high cloning flexibility, the fast generation of transgenic suspension cultures, tandem affinity purification adapted for plant cells, matrix-assisted laser desorption ionization tandem mass spectrometry, data analysis, and functional assays. We identified 28 new molecular associations and confirmed 14 previously described interactions. This systemic approach provides new insights into the basic cell cycle control mechanisms and is generally applicable to other pathways in plants.     

The Helicobacter pylori GroES Cochaperonin HspA Functions as a Specialized Nickel Chaperone and Sequestration Protein through Its Unique C-Terminal Extension

The transition metal nickel plays a central role in the human gastric pathogen Helicobacter pylori because it is required for two enzymes indispensable for colonization, the nickel metalloenzyme urease and [NiFe] hydrogenase. To sustain nickel availability for these metalloenzymes while providing protection from the metal''s harmful effects, H. pylori is equipped with several specific nickel-binding proteins. Among these, H. pylori possesses a particular chaperone, HspA, that is a homolog of the highly conserved and essential bacterial heat shock protein GroES. HspA contains a unique His-rich C-terminal extension and was demonstrated to bind nickel in vitro. To investigate the function of this extension in H. pylori, we constructed mutants carrying either a complete deletion or point mutations in critical residues of this domain. All mutants presented a decreased intracellular nickel content measured by inductively coupled plasma mass spectrometry (ICP-MS) and reduced nickel tolerance. While urease activity was unaffected in the mutants, [NiFe] hydrogenase activity was significantly diminished when the C-terminal extension of HspA was mutated. We conclude that H. pylori HspA is involved in intracellular nickel sequestration and detoxification and plays a novel role as a specialized nickel chaperone involved in nickel-dependent maturation of hydrogenase.Helicobacter pylori is a Gram-negative, microaerophilic bacterium that is the only persistent inhabitant of the human stomach. Its presence in humans is associated with a variety of pathologies, ranging from gastric and duodenal peptic ulcers to the development of gastric adenocarcinoma and mucosa-associated lymphoid tissue (MALT) lymphoma (1, 39). Indeed, H. pylori is the only formally recognized bacterial carcinogen for humans (17), infecting half of the world''s population (19).In H. pylori, metal ions play a central role, since the transition metal nickel is the cofactor of the urease enzyme and is also required for [NiFe] hydrogenase. Urease catalyzes the hydrolysis of urea into the buffering compounds bicarbonate and ammonia, enabling H. pylori to persist in the acidic environment of the stomach. This enzyme accounts for up to 6% of the soluble cellular proteins and requires 24 nickel ions per active enzymatic complex (16). The uptake-type hydrogenase of H. pylori is a nickel-dependent enzyme containing a binuclear [NiFe] active site. This [NiFe] hydrogenase catalyzes the oxidation of molecular hydrogen and permits the utilization of hydrogen as an energy source during respiration-based energy production in the mucosa (21). Both enzymes are important for host colonization, as shown with several animal models (9, 10, 28, 42, 43). To sustain nickel availability for urease and hydrogenase while providing protection from the metal''s harmful effects, H. pylori possesses an elaborate and strictly controlled nickel metabolism.The incorporation of nickel ions into apohydrogenase requires the participation of the HypAB (HP0869 and HP0900) accessory proteins; for apourease, both the UreEFGH (HP0070-0067) accessory proteins and HypAB are necessary (4, 29). Besides these widely distributed accessory proteins, H. pylori possesses several specific proteins that are present in all H. pylori strains, namely, the histidine-rich proteins Hpn (HP1427) and Hpn-like (HP1432). These cytoplasmic and abundant proteins (Hpn represents 2% of the total protein content) bind nickel ions (five Ni²⁺ ions per monomer; dissociation constant [K_d] for nickel of 7.1 μM) and protect H. pylori against metal overload (15). Furthermore, it has recently been proposed that Hpn and Hpn-like can compete for nickel ions with the urease enzyme and thus regulate its enzymatic activity. In vivo and in vitro experiments indicate that Hpn and Hpn-like sequester nickel ions at neutral pH but donate them for urease activation under acidic pH conditions (14, 35, 44). Hydrogenase activity was unchanged in the Δhpn and Δhpn-like mutants (35).In addition to these proteins, H. pylori possesses a particular chaperone, HspA (HP0011), that is a homolog of the highly conserved and essential bacterial heat shock protein GroES (40). No other gene encoding a GroES homolog is found in the genome of H. pylori. GroES is the cochaperonin of the heptameric GroEL-GroES barrel complex, which mediates the correct folding of a variety of cellular proteins and which is conserved and essential in prokaryotes and eukaryotes (30). In addition to the conserved GroES chaperonin domain (domain A, amino acids 1 to 90) (Fig. ​(Fig.1A),1A), HspA contains a C-terminal extension of 28 amino acids (domain B, amino acids 91 to 118) (Fig. 1A and B) that contains 8 His and 4 Cys residues. Based on this high number of His and Cys residues known to bind transition metal ions, the purified recombinant HspA protein specifically binds two nickel ions per molecule (K_d of 1.1 to 1.8 μM) (7, 18). This domain also contains an HX₄DH motif (boxed in Fig. ​Fig.1B)1B) that is considered to be a nickel-binding signature sequence in the nickel-cobalt (NiCoT) transporter family (11). In addition, Loguercio et al. (20) observed that in vitro, the HspA C-terminal domain is folding into two vicinal disulfide bounds engaging two cysteine pairs that form a unique closed-loop structure. However, since HspA is a cytoplasmic protein, the in vivo relevance of this structure is uncertain.Open in a separate windowFIG. 1.(A) Representation of the HspA protein of H. pylori with the GroES-like domain A and the nickel-binding domain B. (B) Amino acid sequence of domain B of wild-type HspA and of three mutants: HspA-ΔC, with a complete deletion of this domain, and HspA-NB and -CC, each carrying two substitutions that are underlined. Cysteine and histidine residues are in blue and red, respectively. The HX₄DH motif, which in the nickel-cobalt (NiCoT) transporter family is considered to be a nickel-binding signature sequence, is boxed. (C) Immunoblot experiment with whole-cell lysates from the H. pylori wild-type strain and from the three hspA mutants after denaturing SDS-PAGE and using the monoclonal antibody P1-1, which specifically recognizes a conserved epitope of HspA domain A. The predicted molecular mass of the wild-type HspA monomer is 13 kDa, and that of HspA-ΔC is 9.8 kDa. The monomeric (M) and dimeric (D) forms of the HspA wild type (WT) are indicated on the left side of the blot. A cross-reacting unspecific protein band is marked with a star (*) and served as a loading control. Molecular mass standards are indicated at right.The domain B sequence is conserved in and restricted to H. pylori and the closely related Helicobacter acinonychis species but is absent from all other available sequenced Helicobacter species (see Fig. S1 in the supplemental material). When expressed in Escherichia coli, HspA protected bacteria from nickel overload (7) and increased urease activity 4-fold from the coexpressed H. pylori urease gene cluster (18). Therefore, HspA was hypothesized to function in nickel sequestration and as a specialized nickel donor protein for urease (18). However, no functional characterization of the C terminus was carried out for H. pylori due to the essential nature of HspA (40).In this study, we investigated the role of the nickel-binding C terminus of HspA in H. pylori. We found that the unique C terminus of HspA is involved in nickel sequestration and protection against nickel overload. Contrary to previous data from heterologous studies of E. coli, HspA seemed not to provide nickel ions for urease activation. In contrast, we have found an unexpected and specific function of the HspA C-terminal region in the nickel-dependent maturation of the important colonization factor hydrogenase.