The proteome of the differentiating mesencephalic progenitor cell line CSM14.1 in vitro.

The treatment of Parkinson's disease by transplantation of dopaminergic (DA) neurons from human embryonic mesencephalic tissue is a promising approach. However, the origin of these cells causes major problems: availability and standardization of the graft. Therefore, the generation of unlimited numbers of DA neurons from various types of stem or progenitor cells has been brought into focus. A source for DA neurons might be conditionally immortalized progenitor cells. The temperature-sensitive immortalized cell line CSM14.1 derived from the mesencephalon of an embryonic rat has been used successfully for transplantation experiments. This cell line was analyzed by unbiased stereology of cell type specific marker proteins and 2D-gel electrophoresis followed by mass spectrometry to characterize the differentially expressed proteome. Undifferentiated CSM14.1 cells only expressed the stem cell marker nestin, whereas differentiated cells expressed GFAP or NeuN and tyrosine hydroxylase. An increase of the latter cells during differentiation could be shown. By using proteomics an explanation on the protein level was found for the observed changes in cell morphology during differentiation, when CSM14.1 cells possessed the morphology of multipolar neurons. The results obtained in this study confirm the suitability of CSM14.1 cells as an in vitro model for the study of neuronal and dopaminergic differentiation in rats.

Physiology and proteomics of drought stress acclimation in sunflower (Helianthus annuus L.).

An easy and manageable in vitro screening system for drought tolerance of sunflower seedlings based on MS media supplemented with polyethylene glycol 6000 was evaluated. Morphological and physiological parameters were compared between control (-0.05 MPa) and drought-stressed (-0.6 MPa) seedlings of Helianthus annuus L. cv. Peredovick. There was a significant growth deficit in drought-stressed plants compared to control plants in terms of hypocotyl length, and shoot and root fresh mass. Shoot growth was more restricted than root growth, resulting in an increased root/shoot ratio of drought-stressed plants. Accumulation of osmolytes such as inositol (65-fold), glucose (58-fold), proline (55-fold), fructose (11-fold) and sucrose (eightfold), in leaves of drought-stressed plants could be demonstrated by gas-liquid chromatography. Soluble protein patterns of leaves were analysed with two-dimensional gel electrophoresis (2D-PAGE) and MALDI-TOF mass spectrometry. A set of 46 protein spots allowed identification of 19 marker proteins. Quantitative changes in protein expression of drought-stressed versus control plants were detected. In leaves of drought-stressed sunflower seedlings six proteins were significantly up-regulated more than twofold: a putative caffeoyl-CoA 3-O-methyltransferase (4.5-fold), a fructokinase 3 (3.3-fold), a vegetative storage protein (2.5-fold), a glycine-rich RNA binding protein (2.2-fold), a CuZn-superoxide dismutase (2.1-fold) and an unknown low molecular weight protein (2.3-fold). These proteins represent general stress proteins induced under drought conditions or proteins contributing to basic carbon metabolism. The up-regulated proteins are interesting candidates for further physiological and molecular investigations regarding drought tolerance in sunflower.

Molecular analysis of the ggtBCD gene cluster of Synechocystis sp. strain PCC6803 encoding subunits of an ABC transporter for osmoprotective compounds.

Genes encoding a substrate-binding protein (ggtB) and two integral membrane proteins (ggtC and ggtD) of the binding-protein-dependent ABC transporter for glucosylglycerol were identified in the genome of Synechocystis sp. strain PCC6803. These genes are clustered on the chromosome about 220 kb away from the previously identified ggtA gene, which encodes the ATP-binding protein of this transport system. The deduced amino acid sequences show significant similarities to corresponding subunits of ABC transporters mediating uptake of maltose and other di- and oligosaccharides in bacteria and archaea. Mutants were constructed by inserting an aphII gene cassette into the coding region of the ggtB, ggtC and ggtD genes. These mutants lost the ability to take up glucosylglycerol, sucrose and trehalose, proving that these compounds are transported by the same system. A truncated ggtB gene lacking the putative signal-peptide-encoding sequence was expressed in Escherichia coli yielding a histidine-tagged soluble protein. The recombinant GgtB protein bound glucosylglycerol with a KD of 0.45 microM and exhibited a somewhat lower affinity towards sucrose and a substantially lower affinity towards trehalose. Transcript analysis by RT-PCR indicated that the genes of the ggtBCD gene cluster form an operon. The transcript level estimated by RNA slot blot analysis using a ggtC-specific probe was very low in cells grown in basal medium but increased significantly after a salt shock.

Salt adaptation in pseudomonads: characterization of glucosylglycerol-synthesizing isolates from brackish coastal waters and the rhizosphere.

The compatible solute glucosylglycerol (GG) is widespread among cyanobacteria, but, until now, has been reported for only two species of heterotrophic bacteria. About 120 bacterial isolates from coastal regions of the Baltic Sea were screened by HPLC for their ability to synthesize GG. Positive isolates (26) were grouped by SDS-PAGE of whole-cell proteins and representative strains of each group were investigated by sequencing their 16S rRNA genes and phenotypic characterization. All GG-synthesizing isolates were shown to belong to the genus Pseudomonas (sensu stricto) and were assigned to 4 distinct groups, although none of the GG-synthesizing isolates could be unambiguously assigned to described species. The identity of GG was verified by 13C NMR analysis and enzymatic digestion with alpha- and beta-glucosidases. Besides GG, salt adapted cultures of the aquatic isolates accumulated the dipeptide N-acetylglutaminylglutamine amide (NAGGN) and glutamate. The accumulation of noncharged compatible solutes was also tested in previously identified pseudomonads isolated from the rhizosphere of oilseed rape and potato. The majority of these strains were fluorescent species of the genus Pseudomonas and accumulated trehalose and NAGGN when grown under salt stress conditions. However, rhizosphere isolates of Stenotrophomonas maltophilia synthesized GG and trehalose or only trehalose in a strain-dependent manner. These data indicate that the ability to synthesize GG is widely distributed among slightly or moderately halotolerant pseudomonads.

Isolation of salt-induced periplasmic proteins from Synechocystis sp. strain PCC 6803.

Periplasmic proteins were obtained from control cells and salt-adapted cells of the cyanobacterium Synechocystis sp. PCC 6803 using the method of cold osmotic shock. Two of these proteins (PP 1, apparent mol. mass 27.6 kDa, and PP 3, apparent mol. mass 39.9 kDa) were accumulated in high amounts in the periplasm of salt-adapted cells, while the major periplasmic protein (PP 2, apparent mol. mass 36.0 kDa) was accumulated independently from salt. After isolation from gels and partial sequencing, the proteins could be assigned to proteins deduced from the complete genome sequence of Synechocystis. Neither salt-induced periplasmic proteins (PP 1, Slr0924 and PP 3, Slr1485) exhibited sequence similarity to proteins of known function from databases. The major protein (PP 2-Slr0513) showed significant sequence similarities to iron-binding proteins. All proteins included typical leader sequences at their N-terminus.

The ggtA gene encodes a subunit of the transport system for the osmoprotective compound glucosylglycerol in Synechocystis sp. strain PCC 6803.

The ggtA gene was sequenced during the analysis of a mutant of Synechocystis sp. strain PCC 6803 with impaired salt tolerance. It showed striking sequence similarities to ATP-binding proteins of binding-protein-dependent transport systems (ABC transporters). Mutants of ggtA and three neighboring reading frames were constructed by inserting an aphII gene cassette and were physiologically and genetically characterized. The ggtA insertion mutant lost its glucosylglycerol (GG) uptake ability, but its salt tolerance did not change. Therefore, it was concluded that active transport of the osmoprotective compound GG in Synechocystis is mediated by an ABC transporter. The genes for the GG-specific ABC transporter are not organized in an operon as usually found for comparable transporters, since the other insertion mutants showed normal GG transport activity. After cultivation of the ggtA mutant at high salt concentrations, significant amounts of GG were found in the cultivation medium, indicating that GG transport is mainly necessary for recovery of GG leaked through the cytoplasmic membrane. The Northern blot technique revealed increased transcription of the ggtA gene in cells adapted to higher salt concentrations, whereas in cells from basal medium, its transcription was weak.

Uptake and use of the osmoprotective compounds trehalose, glucosylglycerol, and sucrose by the cyanobacterium Synechocystis sp. PCC6803.

Accumulation of exogenously supplied osmoprotective compounds was analyzed in the cyanobacterium Synechocystis sp. PCC6803, which synthesizes glucosylglycerol as the principal osmoprotective compound. Glucosylglycerol and trehalose were accumulated to high levels and protected cells of a mutant unable to synthesize glucosylglycerol against the deleterious effects of salt stress. In the wild-type, uptake of trehalose repressed the synthesis of glucosylglycerol and caused metabolic conversion of originally accumulated glucosylglycerol. Trehalose cannot be synthesized by Synechocystis and was not or only insignificantly metabolized. Sucrose, which can be synthesized in low quantities by Synechocystis, was also taken up, as indicated by its disappearance from the medium. Sucrose was not accumulated to high levels, probably due to a sucrose-degrading activity found in cells adapted to both low- and high-salt conditions. Despite its low intracellular concentration, sucrose showed a weak osmoprotective effect in salt-shocked cells of a mutant unable to synthesize glucosylglycerol.

Active transport of glucosylglycerol is involved in salt adaptation of the cyanobacterium Synechocystis sp. strain PCC 6803.

An active-transport system for the osmoprotective compound glucosylglycerol (GG) was found in the cyanobacterium Synechocystis sp. strain PCC 6803. Uptake assays with 14C-labelled GG showed that the GG transport was enhanced in cells adapted to increasing concentrations of NaCl. Kinetic studies indicated a Michaelis-Menten relationship. The uptake of GG was energy dependent and occurred against a steep concentration gradient. It was inhibited by uncouplers as well as by a combination of darkness and KCN. The affinity of the transporter seems to be restricted to osmoprotective compounds of cyanobacteria; from a variety of compounds tested only sucrose and trehalose competed with GG for uptake. A salt-sensitive mutant of Synechocystis 6803 unable to synthesize GG could be complemented to salt resistance by exogenous GG. Accumulation of GG from the medium was essential for the restoration of photosynthesis and growth in mutant cells under high-salt conditions. In wild-type cells, the GG transporter probably serves to prevent GG leaking out of salt-stressed cells.