Project description:To assess the effect of transplantation on human islet signature, we transplanted 500-800 human iselts under the kidney capsule of diabetic mice. The mice were rendered diabetic with allowan. The transplanted islets were collected after 30 days, and compared to non-trasnplanted islets.

Project description:Characterizing the initial stages of oncogenic transformation in bladder cancer. Littermate male mice were transferred in single-use plastic cages in order to be treated with the BBN carcinogen. The treatment dose used in this work was 0.05% BBN delivered in drinking water for up to 12 days. Bladder samples were collected at day 1, 4, 8 and 12 from treated mice along with the age-matched controls (non-treated). The drinking water was changed every fourth day. The weights of the mice and BBN water intake were measured every four days and mice were checked regularly for any signs of discomfort and pain.

Project description:The effective separation of complex peptide mixtures is a cornerstone of mass spectrometry-based proteomics analysis that enhances the accuracy and depth of proteomic analyses. Here we compare datasets collected of whole cell tryptic peptides which were fractionated by either conventional flame-pulled, C18 packed bed microcapillary columns or microfabricated pillar array columns (μPAC). Sixteen samples from four yeast strains (Δmet6, Δpfk2, Δura2, and wildtype) were analyzed in quadruplicate using data-independent acquisition (DIA). Each column enabled the quantification of >4,700 protein, with >95.4% overlap between column formats. The μPAC showed higher MS1 and MS2 signal intensities, while maintaining similar peptide characteristics as the capillary column. The capillary column favored slightly longer and more hydrophobic peptides. Both columns achieved high data completeness at the protein level (>95%) and reproducible quantification, with μPAC offering slight improvements. Principal component analysis and correlation analysis confirmed the capture of yeast strain-specific differences, with hierarchical clustering prioritizing strain over column effects. Protein quantification validated gene knockouts in both column formats, demonstrating similar accuracy of quantification. These findings highlight the μPAC as a standardized and robust alternative to capillary columns in proteomic analysis.

Project description:Terminal differentiation is characterized by a respecification of the global protein complement, as epitomized by erythrocytes, whose cytosol is ~98% globin. Remodeling of the proteome involves programmed elimination of generic cellular constituents in parallel with synthesis of cell-type-specific proteins. The erythroid proteome undergoes a rapid transition at the reticulocyte stage; however, the mechanisms driving elimination of preexisting cytosolic proteins are unidentified. UBE2O is a ubiquitin-conjugating enzyme expressed at elevated levels during late stage erythropoiesis. A Ube2o null mutation in mice results in anemia. Proteomic analysis of this mutant suggests that UBE2O is a broad-spectrum ubiquitinating enzyme that remodels the erythroid proteome. In particular, a hallmark of the reticulocyte to mature erythrocyte transition—ribosome elimination—is defective in Ube2o-/- mutants. UBE2O recognizes ribosomal proteins and other substrates directly, targeting them to proteasomes for degradation. Thus, in reticulocytes, and perhaps other highly differentiated cells, the induction of ubiquitinating factors may drive the transition from a complex to a simple proteome.

Project description:Reversed-phase high performance liquid chromatography is the most commonly applied separation technique in mass spectrometry-based proteomics. Particle-packed capillary columns are predominantly used for nano-flow systems. Despite being the broadly applied standard for many years capillary columns are still expensive and suffer from short lifetimes, particularly in combination with ultra-high-pressure chromatography systems. For this reason, and to achieve ultimate performance, many laboratories produce their own in-house packed columns, typically requiring a considerable amount of time and trained personnel. Here, we present a new packing system for capillary columns enabling rapid, multiplexed column packing with pressures up to 3000 bar. Requiring only a conventional gas pressure supply and methanol as driving fluid, our system replaces the traditional setup of helium pressured packing bombs. By using 10x multiplexing, we have reduced the production time to just under 2 minutes for several 50 cm columns with 1.9 um particle size, speeding up the process of column production 40 to 800 times. We compare capillary columns with various inner diameters and length packed under different pressure conditions with our newly designed, broadly accessible high-pressure packing station.

Project description:Isobaric labeling is a powerful strategy for quantitative mass spectrometry-based proteomic investigations. A complication of such analyses has been the co-isolation of multiple analytes of similar mass-to-charge resulting in the distortion of relative protein abundance measurements across samples. When properly implemented, triple-stage mass spectrometry and synchronous precursor selection (SPS-MS3) can reduce the occurrence of this phenomena, referred to as ion interference. However, no diagnostic tool is available currently to rapidly and accurately assess ion interference. To address this need, we developed a multiplexed TMT-based standard, termed the triple knockout (TKO). This standard is comprised of three yeast proteomes in triplicate, each from a strain deficient in a highly abundant protein (Met6, Pfk2, or Ura2). The relative abundance patterns of these proteins, which can be inferred from dozens of peptide measurements, are representative of ion interference in peptide quantification. We expect no signal in channels where the protein is knocked out, permitting maximum sensitivity for measurements of ion interference against a null background. Here, we emphasize the need to investigate further ion interference-generated ratio distortion and promote the TKO standard as a tool to investigate such issues.

Project description:Fractionation is essential to achieving deep proteome coverage for sample multiplexing experiments where currently up to 18 samples can be analyzed concurrently. However, prefractionation (i.e., upstream of LC-MS/MS analysis) with a liquid chromatography system constrains sample processing as only a single sample can be fractionated at once. Here, we highlight the use of spin column-based methods which permit multiple multiplexed samples to be prefractionated simultaneously. These methods require only a centrifuge and eliminate the need for a dedicated liquid chromatograph. We investigate prefractionation with strong anion exchange (SAX) and high-pH reversed phase (HPRP) spin columns, as well as a combination of both, as methods of prefractionation. In two separate experiments, we acquired deep proteome coverage (>8,000 quantified proteins), while starting with only 25 µg of protein per channel. Our datasets showcase the proteome alterations in two human cell lines resulting from treatment with inhibitors acting on the ubiquitin-proteasome system. We recommend this spin column-based prefractionation strategy for high-throughput screening applications or whenever a liquid chromatograph is not readily available.

Project description:The global proteomic alterations in the budding yeast Saccharomyces cerevisiae due to differences in carbon sources can be comprehensively examined using mass spectrometry-based multiplexing strategies. Here we investigate changes in the S. cerevisiae proteome resulting from cultures grown in minimal media using galactose, glucose, or raffinose as the carbon source. We used a TMT 9-plex strategy to determine alterations in relative protein abundance due to a particular carbon source, in triplicate, thereby permitting subsequent statistical analyses. We quantified over 4700 proteins across all 9 samples, of which 1003 demonstrated statistically significant differences in abundance in at least one condition. The majority of altered proteins were classified as functioning in metabolic processes and as having cellular origins of plasma membrane and mitochondria. In contrast, proteins remaining relatively unchanged in abundance included those having nucleic acid-related processes, such as transcription and RNA processing. In addition, the comprehensiveness of the dataset enabled the analysis of subsets of functionally-related proteins, such as phosphatases, kinases, and transcription factors. Moreover, alterations in protein abundance levels of full sets of proteins that comprise distinct biological pathways, such as galactose metabolism and the TCA cycle, can be examined collectively. As a resource, these data can be mined further in efforts to understand better the roles of carbon source fermentation in yeast metabolic pathways and potentially utilize observed alterations for industrial applications, such as biofuel feedstock production.

Project description:Focal adhesion kinase (FAK) is an attractive drug target due to its overexpression in cancer. FAK functions as a non-receptor tyrosine kinase and scaffolding protein, coordinating several downstream signaling effectors and cellular processes. While drug discovery efforts have largely focused on targeting FAK kinase activity, FAK inhibitors have failed to show efficacy as single agents in clinical trials. Here, using structure-guided design, we report the development of a selective FAK inhibitor (BSJ-04-175) and degrader (BSJ-04-146) to evaluate the consequences and advantages of abolishing all FAK activity in cancer models. BSJ-04-146 achieves rapid and potent FAK degradation with high proteome-wide specificity in cancer cells and induces remarkably durable degradation in tumor-bearing mice. Compared to kinase inhibition, targeted degradation of FAK exhibits pronounced improved activity on downstream signaling and cancer cell viability and migration. Together, BSJ-04-175 and BSJ-04-146 are valuable chemical tools to dissect the specific consequences of targeting FAK through small molecule inhibition or degradation.

Project description:Mitonuclear communication is essential to maintain cellular and organismal homeostasis in equilibrium and stress. Mitochondrial stress activates a concerted mitonuclear response geared to safeguard and repair mitochondrial function and to adapt cellular metabolism to the stress. However, the common mediator driving this stress response in mammals remains elusive. By using a multi-omics approach we identify that the activating transcription factor 4 (ATF4) is the main player regulating this response. ATF4 activates the expression of cytoprotective genes, which reprogram cellular metabolism, through activation of the integrated stress response (ISR). Mitochondrial stress also promotes a local proteostatic response, by inducing a decrease in mitochondrial ribosomal proteins, inhibiting mitochondrial translation and coupling as such the activation of the ISR with the attenuation of mitochondrial function. Our data illustrate the value of a multi-omics approach to characterize complex cellular networks and provide a versatile resource to identify new regulators of mitochondrial-related diseases.