Project description:Investigating the intricate and rapid folding kinetics of large RNA-protein complexes (RNPs), like the bacterial ribosome, remains a formidable challenge in structural biology. Previous genetic approaches to probe assembly have focused on modulating the expression of either r-proteins or assembly factors. Here, anti-sense oligonucleotides (ASOs) were used to disrupt native RNA/RNA and RNA/protein interactions, in order to generate previously uncharacterized folding intermediates. In an in vitro co-transcriptional ribosome assembly assay, 10 assembly inhibitor ASOs were identified. Using cryo-electron microscopy, 38 intermediate structures were determined resulting from the specific inhibitions generated by 6 inhibitory ASOs. A notable intermediate class provided compelling evidence for independent rRNA domain folding before proper interdomain docking. Three PNAs targeting domain-I of 23S rRNA further subdivided the previously identified assembly core into smaller blocks representing the earliest steps in assembly. The resulting assembly graph reveals template-directed RNA docking of defined regions as foldons, and domain consolidation, which provides a hierarchical view of the RNP assembly process. This approach not only identified potential targets for antibiotic development but also established a platform for probing the structure and dynamics of RNP assemblies.

Project description:Human caseinolytic protease P (hClpP) is important for degradation of misfolded proteins in the mitochondrial unfolded protein response. We here introduce tailored hClpP inhibitors that utilize a steric discrimination in their core naphthofuran scaffold to selectively address the human enzyme. This novel inhibitor generation exhibited superior activity compared to previously introduced beta-lactones, optimized for bacterial ClpP. Further insights into the bioactivity and binding to cellular targets were obtained via chemical proteomics as well as proliferation- and migration studies in cancer cells.

Project description:Abstract The infection of drug resistant bacteria seriously threats to public health, which makes it more urgent to find novel antibacterial compounds. Compared with traditional development approaches, drug repurposing provides a faster and more effective strategy to find new antimicrobial agents. Here, we screened an FDA-approved small-molecule library upon S. aureus, and identified crizotinib as an antimicrobial agent. We confirmed the antibacterial activities of crizotinib in vitro and in vivo by MIC, growth curve, SEM and mice experiment. At the same time, crizotinib also showed low tendency to develop resistance. Mechanistically, quantitative proteomics, bioinformatics analyses, qRT-PCR and flow cytometry biochemical validation experience confirmed that crizotinib exerted its antibacterial effects by interfering pyrimidine metabolism and disrupting DNA synthesis eventually. Furthermore, our data from drug affinity responsive target stability, bio-layer interferometry and a series of functional assays demonstrated that crizotinib could target PyrG directly in pyrimidine metabolism pathway. Taken together, our results indicated that crizotinib could be a potential antimicrobial agent to treat Gram-positive bacterial infections in the future.

Project description:Many proteins require molecular chaperones to fold into their functional native forms. Previously we used limited proteolysis mass-spectrometry (LiP-MS) to find that ca. 40% of the E. coli proteome do not efficiently refold spontaneously following dilution from denaturation, a frequency that drops to ca. 15% once molecular chaperones like DnaK or GroEL are provided. However, the roles of chaperones during primary biogenesis in vivo can differ from the functions they play during in vitro refolding experiments. Here, we used LiP-MS to probe structural changes incurred by the E. coli proteome when two key chaperones, trigger factor and DnaKJ, are deleted. While knocking out DnaKJ induces pervasive structural perturbations across the soluble E. coli proteome, trigger factor deletion only impacts a small number of proteins’ structures. Overall, proteins which cannot spontaneously refold (or require chaperones to refold in vitro) are not more likely to be dependent on chaperones to fold in vivo. For instance, the glycolytic enzyme, phosphoglycerate kinase (PGK), cannot refold to its native form in vitro following denaturation (even with chaperones), but by LiP-MS we find that its structure is unperturbed upon DnaKJ or Tig deletion, which we further demonstrate with biochemical and biophysical assays. Thus, PGK folds to its native structure most efficiently during co-translational folding and does so without chaperone assistance. This behaviour is generally found among chaperone-nonrefolders (proteins that cannot refold even with chaperone assistance), strengthening the view that this class of proteins are obligate co-translational folders. Hence, for some E. coli proteins, the vectorial nature of co-translational folding is the most important “chaperone.”

Project description:Rising atmospheric CO2 concentrations are leading to ocean acidification, altering the inorganic carbon buffer system with consequences for marine organisms. Here we applied RNA-seq and iTRAQ quantification to investigate the potential impacts of ocean acidification on the temperate coastal marine diatom Skeletonema marinoi.

Project description:This project aimed to identify differentially expressed proteins between tumor-associated macrophages (TAMs) and monocyte-derived macrophages (MDMs), both obtained from hepatocellular carcinoma (HCC) patients. Macrophages were isolated from tumor tissues and matched peripheral blood, respectively. Proteins were extracted and analyzed by mass spectrometry to characterize their distinct proteomic profiles. The results provide valuable insights into the molecular differences between TAMs and MDMs, contributing to a better understanding of macrophage function and regulation in the HCC tumor microenvironment.

Project description:This study aims at characterizing the RisR regulon under non-modulating (virulent, Bvg+) and modulating (avirulent, Bvg-) conditions. We here used comparative proteomics to elucidate the functional significance of RisR in B. pertussis Tohama I by defining RisR-dependent protein synthesis.

Project description:Comparison of biofilm versus planktonic mode of growth in Staphylococcus aureus

Project description:The p53 protein is encoded by TP53 gene and plays the key role in significant number of cellular processes including proliferation, apoptosis and regulation of many stress response pathways. P53 acts like a direct transcription activator of numerous genes regulating cell cycle arrest, DNA repair, growth inhibition and many others (Mollereau and Ma, 2014). The canonical biological function of p53 is maintaining genome integrity via elimination of damaged or exposed to genotoxic stress cells. Immortalized HaCaT cells are widely used for keratinocyte research, since they maintain stable keratinocyte phenotype, have nearly unlimited proliferative potential, do not require specific growth and differentiation factors (Colombo et al., 2017). Also, HaCaT cells produce typical differentiation markers such as cytokeratins K14 and K10, involucrin (Colombo et al., 2017) and respond to keratinocyte differentiation stimuli. Taking together, HaCaT cells have similar to normal human keratinocytes (NHK) properties, however, as many of spontaneously immortalized cell lines HaCaT cells bear two mutant p53 alleles - R282Q and H179Y (Lehman et al., 1993). Mutp53 in HaCaT has an increased affinity to other p53 family members (p63, p73), which significantly expands p53 properties. Moreover, mutp53 indirectly affects specific target genes via protein-protein interactions with other transcription factors (NF-Y, E2F1, NF-KB) or by tethering p63 to new promotor locations. For more detailed investigation of mutp53 impact on various processes in HaCaT cells we performed a shRNA mediated knockdown of mutp53. For generation of stable TP53 knockdown we employed plasmid vector pLKO-p53-shRNA-941 (Addgene # #25637) followed by puromycin selection of transduced cells. Here we present proteomic dataset obtained from wild type HaCaT cells and p53 knock down HaCaT keratinocytes.

Project description:Methicillin resistance in Staphylococcus aureus depends on the production of mecA, which encodes penicillin-binding protein 2A (PBP2A), an acquired peptidoglycan transpeptidase with reduced susceptibility to beta-lactam antibiotics. Here, we show that preventing the expression of wall teichoic acids (WTAs) genetically or with a TarO inhibitor sensitizes MRSA strains to beta-lactams although PBP2A is still expressed. Using S. aureus microarrays and array data analysis protocols (NIAID's Pathogen Functional Genomics Resource Center) we have characterized the transcriptomes of S. aureus COL. in order to further understand the sensitization of strain COL to methicillin by tunicamycin we determined the tunicamycin and methicillin transcriptomes alone and in combination. Methicillin treatment of COL at 500 µg/mL had almost no effect on cell growth rate and, remarkably, the only gene in the transcriptome that showed a more than two-fold change in expression was lytM, which was downregulated. The tunicamycin transcriptome of COL, acquired at 0.4 µg/mL, shows modest changes compared to the untreated control both in terms of the total numbers of affected genes and in the degree of up- or downregulation. Several of the genes upregulated upon tunicamycin treatment are part of the cell wall stress stimulon.COL was grown with methicillin to an OD600 ~0.4, and challenged with tunicamycin for 2 hrs whereas the control culture contained methicillin alone. transcriptome for COL growing in the presence of both agents showed extensive changes in gene expression. , the cell wall stress stimulon, which was not induced by methicillin when tunicamycin was absent, was clearly induced in its presence and the changes were far more dramatic than observed with tunicamycin alone. ). vraS and vraR, which encode a two component signaling system dedicated to the cell wall regulon, were upregulated 3.8 and 3.7 fold, respectively. Other upregulated cell wall stress stimulon genes include pbp2, fmtA, mvaD (mevalonate diphosphate decarboxylase), crtN (dehydrosqualene desaturase) mvak1 (mevalonate kinase), recU, SAV1424 (methionine sulfoxide reductase A), prsA (peptidyl-prolyl cis/trans isomerase), tcaA (Tca protein) and cwrA. A considerable number of genes were also downregulated upon challenge of COL with the combination of tunicamycin and methicillin. These included sspB, lrgA, dltA, capL, SAS0988, sspA, pflB, and spa. Several of these genes have been found to be downregulated in previous studies of cell wall-active antibiotic challenge of S. aureus. Growth conditions for microarray analysis- For transcriptional profiling, an overnight-grown COL culture was diluted (2% vol/vol) to 20 ml TSB medium in a 50-ml Erlenmeyer flask and grown at 30°C with shaking at 200 rpm. For the sensitization experiment, COL was grown with methicillin to an OD600 ~0.4, and challenged with tunicamycin for 2 hrs whereas the control culture contained methicillin alone. Total bacterial RNA was isolated as previously described from S. aureus COL (30°C, 200 rpm). The RNA samples were then converted to fluorescently-labeled cDNA and hybridized to S. aureus microarrays version 7 (NIAID's Pathogen Functional Genomics Resource Center). Hybridization signals were scanned using an Axon4000B scanner (Molecular Devices, Sunnyvale, CA ) with Acuity 4.0 software and scans were saved as TIFF image. Scans were analyzed using TIGR-Spotfinder (www.tigr.org/software/) software and the local background was subsequently subtracted. The data set was normalized by applying the LOWESS algorithm using TIGR-MIDAS (www.tigr.org/software/) software. The normalized log2 ratio of test/reference signal for each spot was recorded. Genes with less than three data points were considered unreliable, and their data points were discarded. The averaged log2 ratio for each remaining gene on the four replicate slides was ultimately calculated. Significant changes of gene expression were identified with SAM (significance analysis of microarrays; www.tat.stanford.edu/~tibs/SAM/index.html. Genes analyzed using these programs were further sorted and grouped based on their function using our in-house software Staphylococcus aureus Gene Sorter (SAGS). Several controls were employed to minimize the technical and biological variations and to ensure that the data obtained were of good quality. First, each ORF was present in triplicate on the array. Second, each RNA preparation was used to make probes for at least two separate arrays for which the incorporated dye was reversed. Contents of raw data files: Channel A = Cy3 dye Channel B = Cy5 dye File names ending with S1,S3 = Cy3 untreated, Cy5 treated File names ending with S2,S4 = Cy5 untreated, Cy3 treated