Project description:We used an in-depth analysis of the characteristics of eGFP as a proof-of-principle analyte to establish a robust assay for the determination of degradation rates on the single-cell level using microinjection and live-cell microscopy. We aimed to determine the influence of the exposed n-terminal aminoacid on the proteins degradation. The high sensitivity of our single-cell analysis in combination with the controlled starting conditions of microinjection provides an unique advantage to examine differences in rates with an improved resolution and to compare the influence of different n-terminal aminoacids on eGFP-degradation without accounting for differences during translation. We produced XS-eGFP, with X being substituted by different proteinogenic amino acids, from E.coli and extensively purified it by a three column process. We could show pronounced differences in degradation rates for the constructs with differing N-terminal aminoacids. We also chemically acetylated the N-terminal α amino groups of methionine, alanine, threonine, valine and serine that would normally occur co translationally, in vitro before, microinjection to analyze the influence of acetylation on target degradation. Acetylation at the N-terminus was confirmed by LC-MS-MS. Acetylation reduced degradation of the respective construct. Finally we purified eGFP by anion-exchange from eGFP expressing HEK293 cells to elucidate modifications of eGFP after eukaryotic expression. We could show that eGFP is likely cleaved during HEK293 expression and n-terminally acetylated, which leads to a starkly reduced degradation rate. The degradation rate was similarly reduced for a N-terminally shortened eGFP produced in E.coli and acetylated in-vitro.

Project description:The SRC inhibitor PP2 can block CASK nucleus translocation in macrophage under H5N1 infection. Since PP2 is a general inhibitor for Src family kinases (SFKs), which includes nine members (Csk, Yes, Fyn, Fgr, Lck, Hck, Blk, Lyn, and Frk), we aimed to identify the specific member responsible for the nuclear translocation of CASK. First, we examined the expression of SFKs in macrophages (Csk, Fyn, Fgr, and Hck) following H5N1-IAV infection (Fig. 4A). This observation suggests that Hck is the most abundant SFK and may contribute to virus-induced nuclear translocation of CASK. To test this, we generated constitutively active forms of HCK: HCK△513-524 (deletion mutant) and HCK Y499F mutant (YF mutation) [24], then co-transfected them with an EGFP-CASK construct into 293T cells. Immunoprecipitation with anti-GFP mAb, followed by trypsin digestion and LC-MS/MS analysis, revealed that compared to the control group, the phospho/nonphospho ratio at residue Serine 395 (S395) of CASK increased approximately 10-fold (0.008 to 0.072 by HCK△513-524, 0.008 to 0.108 by HCK Y499F), while the other 8 potential phosphorylation sites did not show significant alterations (Table 1). To confirm the phosphorylation of S395 of CASK is required for nuclear translocation, we generated an EGFP-CASK S395A mutant (SA mutation) to prevent CASK phosphorylation. In the absence of HCK Y499F, both the wild type (CASK S395) and mutant (CASK S395A) remained in the cytosol (left two columns, Fig. 4B). In contrast, transfection of HCK Y499F (red color) induced the translocation of wild type CASK (green color) into the nucleus (3rd column from left, Fig. 4B), an effect not observed with the CASK S395A mutant (4th column from left, Fig. 4B). The percentage of nuclear GFP-CASK (60% and 90% in WT and 35% in S395A) resulting from the overexpression of wild type HCK and HCK Y499F is shown in Figure 4C. Thus, we concluded that activated HCK induces the phosphorylation of CASK at Ser395, facilitating its nuclear translocation.

Project description:The structural-functional organization of ammonia and glutamine metabolism in the liver acinus involves highly specialized hepatocyte subpopulations such as glutamine producing perivenous scavenger cells. However, it is still unclear whether this cell population is homogeneous and involves further subpopulations. This was investigated in the present study by proteome profiling of periportal glutamine synthetase-negative hepatocytes and perivenous glutamine synthetase (GS) expressing scavenger cells isolated from mouse and rat liver. Apart from established markers of GS+ hepatocytes such as glutamate transporter 1 (GLT1), ornithine aminotransferase (OAT) or ammonium transporter Rh type B (RHBG), we identified novel scavenger cell-specific proteins such as the basal transcription factor 3 (BTF3) and the heat-shock protein 25 (HSP25). Interestingly, BTF3 and HSP25 were heterogeneously distributed among GS+ hepatocytes as shown by immunofluorescence analyses in mouse, rat and human liver slices. Feeding experiments showed that RHBG but not GS protein levels were increased in the liver of mice fed with a high protein diet compared to standard chow. While the spatial distribution of GS and carbamoylphosphate synthetase-1 (CPS1) was not affected, periportal areas constituted by GLS2 positive hepatocytes were enlarged or reduced in response to high or low protein diet, respectively. The data suggest that the population of perivenous GS+ scavenger cells is heterogeneous and not uniform as previously suggested which may reflect a functional heterogeneity, possibly relevant for liver regeneration.

Project description:The dataset accompanying a publication describing the RNA degradosome components in Mycobacterium tuberculosis (Mtb). Individual RNA degradosome components from Mtb (PNPase, RNase E, RNase J, RhlE and Enolase) were tagged with eGFP and used as baits to pull-down their interaction partners. The protein-complexes were purified by affinity chromatography, using previously published protocols, and submitted to LC-MS analysis.

Project description:GS-5759 is a bifunctional ligand composed of a quinolinone-containing pharmacophore found in several β2-adrenoceptor agonists linked covalently to a phosphodiesterase 4 inhibitor (PDE4) related to GSK 256066 by a pent-1-yn-1-ylbenzene spacer. The object of the study was to detemine if gene expression changes induced by GS-5759 were replicated by a β2-adrenoceptor agonist (indacaterol; Ind) and a PDE4 inhibitor (GSK 256066; GSK) in combination. Microarray analysis was performed on RNA from BEAS-2B cells treated with GS-5759 and a combination of indacaterol and GSK 256066 to identify differentialy expressed genes. Confluent BEAS-2B cells were treated with vehicle, Ind/GSK or GS-5759 for 1h, 2h, 6h or 18h. Total RNA was extracted, quantified (NanoDrop 2000) and the quality of each sample determined by using the Agilent 2100 Lab-on-a-Chip system before being processed for gene expression chnages by Expression Analysis Inc (Dunham, NC, USA).

Project description:Since LAMC2 is a secreted molecule present in the extracellular matrix of the cells, was designed a strategy based on CRISPR/Cas9-mediated homologous recombination to mark LAMC2 cells in human PDACs. A Cas9 single-guide RNAs complementary to sequences overlapping the stop codon of the LAMC2 locus was designed and a donor vector that contained LAMC2 homology arms flanking an EGFP reporter cassette positioned immediately upstream of the stop codon was generated. LF2A self-cleavage peptide in frame with EGFP so that LAMC2-EGFP locus was expressed as a single mRNA was added, whereas the resulting polypeptide was cleaved in the two encoded proteins, LAMC2 and EGFP. L3.6pl and PANC-1 cells were nucleofected with the donor vector together with a guide-RNA-Cas9 (guide). The engineered cells were subcutaneously injected in CD1 male mice and RNA-seq was performed on LAMC2-EGFP+ and EGFP- -derived tumors.

Project description:A single spermatogonial stem cell can aquire pluripotentiality but that conversion into a pluripotent cell type is accompanied by loss of spermatogenic potential. We used microarrays to compare the expression profiles among the different stem cell types. Experiment Overall Design: GS, mGS and ES cells were cultured for RNA extraction and hybridization on Affymetrix microarrays. We examined the gene expression profiles of GS and mGS cells to find candidate molecules that are involved in the conversion process of GS into mGS cells.

Project description:Contaminated aquifer (Dusseldorf-Flinger, Germany) templates extracted from 5 sediment depths ranging between 6.4 and 8.4 m below ground and over 3 years of sampling were amplified for amplicon pyrosequencing using the primers Ba27f (5’-aga gtt tga tcm tgg ctc ag-3’) and Ba519r (5’- tat tac cgc ggc kgc tg-3’), extended as amplicon fusion primers with respective primer A or B adapters, key sequence and multiplex identifiers (MID) as recommended by 454/Roche. Amplicons were purified and pooled as specified by the manufacturer. Emulsion PCR (emPCR), purification of DNA-enriched beads and sequencing run were performed following protocols and using a 2nd generation pyrosequencer (454 GS FLX Titanium, Roche) as recommended by the developer. Quality filtering of the pyrosequencing reads was performed using the automatic amplicon pipeline of the GS Run Processor (Roche), with a slight modification concerning the valley filter (vfScanAllFlows false instead of TiOnly) to extract the sequences. Demultiplexed raw reads were furhter trimmed for quality and lenght (>250 bp). 15 samples examined in total from important plume zones of the aquifer sampled in Feb. 2006, Sep. 2008 and Jun. 2009 (5 every year of sampling).

Project description:Comparison of polysomal profiles of murine adult olig2 cortical progenitors, murine tumor olig2 cells derived from hPDGF-B-driven glioblastomas, and murine olig2 proliferative recruited glioma cells contributing to the tumor mass but not derived from the cell of origin An unbiased way to define a cell population lies in identification of its gene expression signature and subsequent comparison to gene expression signatures of known normal or cancer cells to define its position on the axis of tumorigenesis. To quantify similarities and differences in the expression profiles of recruited cells and tumor cells using microarray analysis, we used the bacTRAP technology that allows immunoprecipitation of polysomes from specific cell types in vivo (Heiman et al 2008, Doyle et al 2008). We compared polysomal expression profiles of hPDGFb-driven Ntv-a Ink4a/Arf+/- olig2 mouse glioma cells representing a histologically defined glioma population, recruited olig2 cells derived from Ink4a/Arf+/- olig2 RP-eGFP mice transplanted with non-fluorescent glioma cells, and normal adult cortical olig2 mouse progenitors, using Affymetrix 430 mouse 2.0 chips and Genespring GX10 software (Doyle et al 2008, Heiman et al 2008). Translational profiles of recruited olig2 cells and glioma olig2 cells were similar to each other and clearly distinct from the normal olig2 progenitors, majority of the differences accounted for by the “statistically significantly changed” set of mRNAs (ANOVA, p<0.05), and sample clustering reduced upon removal of the ANOVA-tested mRNA set. Unsupervised hierarchical mRNA clustering likewise indicated that recruited olig2 cells clustered more closely to glioma olig2 cells. The caveat is that olig2 expression in the adult normal brain of bacTRAP olig2 RP-eGFP mice labels both progenitors and mature oligodendrocytes, while recruited and tumor olig2 cells are almost entirely progenitors; therefore, some of the differences seen in the comparative analysis of normal, tumor and recruited olig2 cells may in part result from the shift in relative abundance of different progenitor and mature olig2 cell populations. Normal olig2 progenitors were collected from three replicates of pooled cortices of three olig2 RP-eGFP bacTRAP reporter mice. Mouse gliomas induced by injection of a non-fluorescent RCAS-hPDGFb (Shih et al 2004) or by transplantation of muring glioma cells derived from Ntv-a gliomas induced by the non-fluorescent RCAS-hPDGFb were collected from Ntv-a olig2 RP-eGFP bacTRAP reporter mice and immunoprecipitated; each tumor was processed as a separate sample. Briefly, mouse tissues were collected into ice-cold cyclohexamide-containing buffer, homogenized, cells were lysed in NP-40 and DHPC-containing buffer, centrifuged at 20,000g for 15 min, supernatant incubated with anti-eGFP-conjugated protein G beads 30 min at 4C, washed and RNA collected using Trizol reagent as per manufacturer’s instructions (Doyle et al., 2008; Heiman et al., 2008). RNA was purified, concentrated using Qiagen RNeasy kit, its quality confirmed by Agilent Bioanalyzer, 15ng per sample amplified using Affymetrix Two-Cycle Amplification kit and hybridized to Affymetrix 430 mouse 2.0 chips as described in Doyle et al., 2008; Heiman et al., 2008. Data was analyzed using Genespring GX10 software, as described in the text and in Doyle et al., 2008; Heiman et al., 2008. Briefly, samples were normalized using GCRMA, filtered to remove probe sets with low intensity, and analyzed using ANOVA (p<0.05) with SNK post-hoc and Benjamini and Hochberg FDR multiple testing correction. Probe quality, Pearson’s correlation, hierarchical clustering, heatmaps, gene profile plots were generated using Genespring GX10 software. Pathway analysis was performed using Ingenuity as per manufacturer’s instructions. Gliomas are thought to form by clonal expansion from a single cell-of-origin, and progression-associated mutations to occur in its progeny cells. Glioma progression is associated with elevated growth factor signaling and loss of function of tumor suppressors Ink4a, Arf and Pten. Yet, gliomas are cellularly heterogeneous; they recruit and trap normal cells during infiltration. We performed lineage tracing in a retrovirally mediated, molecularly and histologically accurate mouse model of hPDGFb-driven gliomagenesis. We were able to distinguish cells in the tumor that were derived from the cell-of-origin from those that were not. Phenotypic, tumorogenic and expression analyses were performed on both populations of these cells. Here we show that during progression of hPDGFb-induced murine gliomas, tumor suppressor loss can expand the recruited cell population not derived from the cell-of-origin within glioma microenvironment to dominate regions of the tumor, with essentially no contribution from the progeny of glioma cell-of-origin. Moreover, the recruited cells can give rise to gliomas upon transplantation and passaging, acquire polysomal expression profiles and genetic aberrations typically present in glioma cells rather than normal progenitors, aid progeny cells in glioma initiation upon transplantation, and become independent of PDGFR signaling. These results indicate that non-cell-of-origin derived cells within glioma environment in the mouse can be corrupted to become bona fide tumor, and deviate from the generally established view of gliomagenesis.

Project description:Four cDNA libraries from immature embryos, mature embryos, microspore derived embryos and mature leaves were constructed. cDNA were sequenced by the Roche-454 GS-FLX.