Project description:The journey by which proteins navigate their energy landscapes to their native structures is complex, involving (and sometimes requiring) many cellular factors and processes operating in partnership with a given polypeptide chain’s intrinsic energy landscape. The cytosolic environment and its complement of chaperones play critical roles in granting proteins safe passage to their native states; however, the complexity of this medium has generally precluded biophysical techniques from interrogating protein folding under cellular-like conditions for single proteins, let alone entire proteomes. Here, we develop a limited-proteolysis mass spectrometry approach paired within an isotope-labeling strategy to globally monitor the structures of refolding E. coli proteins in the cytosolic medium and with the chaperones, GroEL/ES (Hsp60) and DnaK/DnaJ/GrpE (Hsp70/40). GroEL can refold the majority (85%) of the E. coli proteins for which we have data, and is particularly important for restoring acidic proteins and proteins with high molecular weight, trends that come to light because our assay measures the structural outcome of the refolding process itself, rather than indirect measures like binding or aggregation. For the most part, DnaK and GroEL refold a similar set of proteins, supporting the view that despite their vastly different structures, these two chaperones both unfold misfolded states, as one mechanism in common. Finally, we identify a cohort of proteins that are intransigent to being refolded with either chaperone. The data support a model in which chaperone-nonrefolders have evolved to fold efficiently once and only once, co-translationally, and remain kinetically trapped in their native conformations.

Project description:Chaperones have essential role in assist nascent peptides folding, prevent proteins aggregation and maintain cellular protein homeostasis. Considering spatial and temporal features of chaperones regulating in vivo, changes in single or combined chaperone-depleted E.coli strain is needed to be put into understand at transcriptional level. Here, we utilized expression microarrays to investigate global transcriptional response upon deletion of single or multiple chaperones in E. coli for understanding the transcriptional network affected by chaperones. To identify prokaryotic expression profiles in deletion of chaperones, several E.coli mutants were constructed in the following: Z116 (△tig 37℃), Z125(△dnaK37℃), Z625(△tig△dnaK 37℃ or 30℃), Z629(△tig△dnaK 30℃), NM (C-domain of tig was deleted 37℃), MC (N-domain of tig was deleted 37℃), NC (M-domain of tig was deleted 37℃). Two types of cDNA mixtures containing Cy3-labeled (or Cy5-labeled) control DNA (from BW25113) and Cy5-labeled (or Cy3-labeled) DNA targets (from mutant strain) were hybridized with E.coli microarrays in a dye-swap strategy. E.coli gene expression data of chaperone DnaK deletant compared control WT (BW25113). Please note that other mutant microarray data will be added in the future.

Project description:The phosphatase activirty and dephosphorylation site are determined by using the recombinant protein. After treatment, the level of specific phosphorylation site is decreased. Also, the biological importance is evaluated through a serial of experiments including immunoprecipitation, western blotting, etc,. Based on this workflow, it is possible to determine the tyrosine phosphorylation since the sample complexity is reduced. This finding suggested this phosphatase play a key role in phosphoregulation.

Project description:Data-dependent nLC-MS/MS analysis of EYA3 phosphorylation by Src protein tyrosine kinase

Project description:Application of genome-scale 'omics approaches to dissect subcellular pathways and regulatory networks governing interspecies interactions is dependent, at least initially, on the availability of model systems with well-annotated genomes and tractable genetics. We employed controlled cultivation and next-generation sequencing technology to identify transcriptional responses of euryhaline unicellular cyanobacterium Synechococcus sp. PCC 7002 and a marine facultative aerobe Shewanella putrefaciens W3-18-1 to investigate the effect of C sources and C flux directions on the interactions between these organisms.

Project description:Phosphatases play essential roles in normal cell physiology and diseases like cancer. The challenges of studying phosphatases have limited our understanding of their substrates, molecular mechanisms, and unique functions within highly complicate networks. Here we introduce a novel strategy using substrate trapping mutant coupled with quantitative mass spectrometry to identify physiological substrates of protein tyrosine phosphatase Src homology 2 containing protein tyrosine phosphatase 2 (SHP2) in a high-throughput manner. SHP2 plays a critical role in numerous cellular processes through the regulation of various signaling pathways. The method integrates three separate MS-based experiments; in vitro dephosphorylation assay, in vivo global phosphoproteomics, and pull down of substrate trapping mutant complex using HEK293SHP2KO cells. PTPN11-C459S/D425A is an optimized substrate trap mutant of SHP2. We identified eleven direct substrates, including both known and novel SHP2 substrates in EGFR signaling pathways, among which docking protein 1 (DOK1) was further validated as a new SHP2 substrate. This advanced workflow significantly improves the systemic identification of direct substrates of phosphatase, facilitating the comprehension of equally important roles of phosphatase signaling.

Project description:Armitage (Armi) is a component of Yb bodies and functions in the primary piRNA processing pathway. Armi interaction with Piwi does not require Yb expression; however, without Yb, the Armi-Piwi complex does not localize at Yb bodies and contains few piR-ILs (small RNAs associated with Armitage complex). These results suggest that only upon its localization at Yb bodies does the Armi-Piwi-Yb complex gain an opportunity to interact with piR-ILs. Currently, however, it remains unclear how piR-ILs are loaded onto the Piwi complex at Yb bodies and which protein(s) within the complex is directly bound to them. 1 sample examined: Ovarian somatic cell (OSC) line

Project description:The protein profiles of both the dnaK deletion mutant and the wild-type strain were analyzed using proteomic analysis. The dnaK deletion mutant was analyzed three times and the wild-type strain was also analyzed three times.

Project description:Background: Evolutionary engineering is a powerful approach to isolate suppressor mutants and industrially relevant genotypes. Until recently, DNA microarray analysis was the only affordable genome-wide approach to identify the responsible mutations. This situation has changed due to the rapidly decreasing costs of whole genome (re)sequencing. DNA microarray-based mRNA expression analysis and whole genome resequencing were combined in a study on lactate transport in Saccharomyces cerevisiae. Jen1p is the only S. cerevisiae lactate transporter reported in literature. To identify alternative lactate transporters, a jen1Δ strain was evolved for growth on lactate. Results: Two independent evolution experiments yielded Jen1p-independent growth on lactate (μmax 0.14 and 0.18 h-1 for single-cell lines IMW004 and IMW005, respectively). Whereas mRNA expression analysis did not provide leads, whole-genome resequencing showed different single nucleotide changes (C755G/Leu219Val and C655G/Ala252Gly) in the acetate transporter gene ADY2. Analysis of mRNA levels and depth of coverage of DNA sequencing combined with karyotyping, gene deletions and diagnostic PCR showed that in IMW004 an isochromosome III (~475 kb), which contains two additional copies of ADY2C755G, was formed via crossover between YCLWΔ15 and YCRCΔ6. Introduction of the ADY2 alleles in a jen1 ady2 strain resulted in growth on lactate (μmax 0.14 h-1 for Ady2pLeu219Val and 0.12 h-1 for Ady2pAla252Gly). Conclusions: Whole-genome resequencing of yeast strains obtained from independent evolution experiments enabled rapid identification of a key gene that was not identified by mRNA expression analysis of the same strains. Reverse metabolic engineering showed that mutated alleles of ADY2 (C655G and C755G) encode efficient lactate transporters. The goal of the present study was to investigate whether evolutionary engineering and subsequent elucidation of the underlying mutations can lead to the identification of alternative lactate transporters in S. cerevisiae. Transport of carboxylic acids plays a key role in weak organic acids stress and the responsible membrane transporters are often poorly studied and encoded by multiple redundant genes . Additionally, import of lactate is an essential step in the reutilization of lactate produced during intense exercise in mammals [8]. In S. cerevisiae, Jen1p was previously identified as the only efficient lactate importer by generation of a UV-mutant unable to grow on lactate and subsequent functional complementation with a genomic library . The lactate uptake rate of the resulting jen1 knockout strain was close to the detection limit. Interestingly, export of lactate in engineered lactate producing S. cerevisiae is unaffected by deletion of JEN1 (our unpublished results). These observations suggest the presence of at least one alternative lactate transporter. To test this, a jen1 knockout strain was constructed and evolved for faster growth on lactate as the sole carbon and energy source. The evolved strains were subjected to a combination of mRNA expression analysis and whole genome DNA (re)sequencing to identify the relevant mutations. The resulting leads were tested for lactate transport activity via knockout studies in the evolved strains and reverse engineering of the portable genetic elements into non-evolved strains.

Project description:Data-dependent nLC-MS/MS analysis of EYA3 phosphorylation by Src protein tyrosine kinase