Project description:Comprehensive global proteome profiling that is amenable to high throughput processing will broaden our understanding of complex biological systems. Here, we evaluated two leading mass spectrometry techniques—Data-Independent Acquisition (DIA) and Tandem Mass Tagging (TMT)—for extensive protein abundance profiling. DIA provides label-free quantification with a broad dynamic range, while TMT enables multiplexed analysis using isobaric tags for efficient cross-sample comparisons. We analyzed 18 samples, including four cell lines (IHCF, HCT116, HeLa, MCF7) under standard growth conditions, in addition to IHCF treated with two H₂O₂ concentrations, all in triplicate. Experiments were conducted on an Orbitrap Astral mass spectrometer, employing Field Asymmetric Ion Mobility Spectrometry (FAIMS). Despite utilizing different acquisition strategies, both the DIA and TMT approaches achieved comparable proteome depth and quantitative consistency, with each method quantifying over 10,000 proteins across all samples, with slightly more protein-level precision for the TMT strategy. Relative abundance correlation analysis showed strong agreement at both peptide and protein levels. Our findings highlight the complementary strengths of DIA and TMT for high-coverage proteomic studies, providing flexibility in method selection based on specific experimental needs.

Project description:Proteome-wide abundance profiling across tissues can help to provide insight into the biological mechanisms underlying tissue-specific function and potential related dysfunction and amelioration thereof. Here, we use sample multiplexing to profile the proteomes of ten diverse mouse tissues using TMTpro-based quantitative mass spectrometry. Our optimized workflow, incorporating two-dimensional peptide pre-fractionation (which included both basic pH reversed-phase and strong ion exchange chromatography) enabled the quantification of over 13,000 proteins across brain, brown fat, heart, kidney, liver, lung, skeletal muscle, spleen, ovaries, and testes. Global analysis revealed distinct proteome profiles for each tissue, with clear clustering patterns reflecting functional similarities and differences. We highlighted the abundance of numerous tissue-specific proteins, exemplified by Synapsin-1 in brain, Uncoupling protein 1 in brown fat, and Zona pellucida proteins in reproductive tissues. Gene ontologies and pathway analyses of the most relatively abundant proteins in each tissue revealed enrichment patterns consistent with known physiological functions. For instance, brain tissue showed enrichment for synaptic components and neurotransmission processes, while liver tissue was enriched for metabolic pathways. This dataset serves as a valuable resource for mapping tissue-specific protein landscapes in mammals, offering potential insights into the molecular mechanisms of tissue function.

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 reduction of disulfide bonds and their subsequent alkylation is commonplace in typical proteomics workflows. Here, we highlight a sulfhydryl-reactive alkylating reagent with a phosphonic acid group (iodoacetamido-LC-phosphonic acid, 6C-CysPAT) that facilitates the enrichment of cysteine-containing peptides for isobaric tag-based proteome abundance profiling. Specifically, we profile the proteome of SH-SY5Y cells following 24 hr treatments with two proteasome inhibitors (bortezomib and MG-132) in a TMTpro9-plex experiment. We acquired three datasets - 1) Cys-enriched, 2) Cys-depleted, and 3) non-depleted - and compared the peptides and proteins quantified in each dataset, with emphasis on Cys-containing peptides. The data show that enrichment using 6C-CysPAT quantified over 38,000 Cys-containing peptides in 5 hr with >90% specificity. In addition, our combined dataset provides the research community with a resource of over 9,900 protein abundance profiles that exhibit the effects of two different proteosome inhibitors. Overall, the seamless incorporation of alkylation by 6C-CysPAT into a current TMT-based workflow permits the enrichment of a Cys-containing peptide subproteome. The acquisition of this “Mini-Cys” dataset can be used to preview and assess the quality of a deep, fractionated dataset.

Project description:Sample multiplexing-based proteomic strategies rely on fractionation to improve proteome coverage. Tandem mass tag (TMT) experiments, for example, can currently accommodate up to 18 samples with proteins spanning several orders of magnitude, thus necessitating fractionation to achieve reasonable proteome coverage. Here, we present a simple yet effective peptide fractionation strategy that partitions a pooled TMT sample with a two-step elution using a strong anion exchange (SAX) spin column prior to gradient-based basic pH reversed-phase (BPRP) fractionation. We highlight our strategy with a TMTpro18-plex experiment using nine diverse human cell lines in biological duplicate. We collected three datasets, one using only BPRP fractionation, and two others of each SAX-partition followed by BPRP. The three datasets quantified a similar number of proteins and peptides, and the data highlight noticeable differences in the distribution of peptide charge and isoelectric point between the SAX partitions. The combined SAX partition dataset contributed 10% more proteins and 20% more unique peptides that were not quantified by BPRP fractionation alone. In addition to this improved fractionation strategy, we provide an online resource of relative abundance profiles for over 11,000 proteins across the nine human cell lines investigated herein.

Project description:The yeast ATPase Cdc48 (known as p97/VCP in human cells) plays an important role in the Ubiquitin Proteasome System. VCP is essential for cancer cell proliferation and its dysregulation has been implicated in several neurodegenerative diseases. Cdc48 functions by extracting ubiquitylated proteins from membranes, protein complexes and chromatin by often facilitating their proteasomal degradation. Specific adaptors or cofactors, primarily belonging to the UBX domain-containing protein family (which has seven members in S. cerevisiae), recruit Cdc48 to ubiquitylated proteins. Here, we employed sample multiplexing-based quantitative mass spectrometry to profile global protein abundance in p97 adaptors deleted strains, specifically comparing seven single deletion strains of UBX domain-containing proteins and the Cuz1 deletion strain which belongs to the zinc finger AN1-type domain protein family. We observed that each strain showed unique sets of differentially abundant proteins compared to wildtype. Our analysis also revealed a role for Ubx3 in maintaining wildtype levels of mitochondrial proteins. Overall, we identified ~1400 differentially abundant proteins in the absence of a specific Cdc48 adaptor. This unique dataset offers a valuable resource for studying the functions of these adaptors aiming to achieve a better understanding of the cellular processes regulated by Cdc48 itself and to deepen our understanding of the Ubiquitin Proteasome System.

Project description:Nicotine is a prominent active compound in tobacco and many smoking cessation products. Some of the biological effects of nicotine are well documented in in vitro and in vivo systems; however, nominal data are available concerning the time-dependent changes on protein and phosphorylation events in response to nicotine. Here, we profiled the proteomes of SH-SY5Y and A549 cell lines subjected to acute (15min, 1h and 4h) or chronic (24h, 48h) nicotine exposures. We used sample multiplexing (TMTpro16) and quantified more than 9,000 proteins and over 7,000 phosphorylation events per cell line. Among our findings, we determined a decrease in mitochondrial protein abundance for SH-SY5Y, while we detected alterations in several immune pathways, such as the complement system, for A549. We also explored the proposed association between smoking and SARS-CoV2. Here, we found several host proteins known to interact with viral proteins that were affected by nicotine in a time dependent manner. This dataset can be mined further to investigate the potential role of nicotine in different biological contexts.

Project description:Targeted protein degradation (TPD) via molecular glues or PROTACs (Proteolysis-targeting chimeras) is an up-and-coming drug modality holding promise to drug the “undrugabbles.” Further expanding the collection of targetable E3 ligases for TPD, we report the discovery of ligands targeting the C-END degron receptor KLHDC2. Utilizing the BRD targeting ligand JQ1 as a test case, we demonstrate that KLHDC2 ligands can be readably converted to PROTACs for TPD, enabling remarkable isoform selectivity and cooperative ternary complex formation with BRD3BD2. We demonstrate that formation of cooperative neo-substrate ternary complexes with KLHDC2 is largely reliant on the exit vector emanating from the ligand bound deep in KLHDC2s U-shaped di-Gly binding pocket. Additionally, we establish the feasibility of generating selective ligands targeting KLHDC2, as the ligands developed here are unable to target the related binding pockets of the KLH family members KLHDC1, KLHDC3, or KLHDC10. Finally, we establish that KLHDC2 targeting ligands can effortlessly overcome the degron-mimic mediated tetramerization and inhibition of KLHDC2-EloB/C and that pro-drug variants can overt cellular permeability limitations of small molecules retaining acid binding moieties. In sum, our study confirms prior observations suggesting KLHDC2 might be amendable to TPD and establish principles to guide PROTAC development targeting C-END E3 ligases.

Project description:A vast assortment of human cell lines is available for cell culture model-based studies, and as such the potential exists for discrepancies in findings due to cell line selection. To investigate this concept, we determined the relative protein abundance profiles of a panel of eight diverse, but commonly studied, human cell lines. This panel includes: HAP1, HEK293T, HeLa, HepG2, Jurkat, Panc1, SH-SY5Y, and SVGp12. We use a mass spectrometry-based proteomics workflow designed to enhance quantitative accuracy while maintaining analytical depth. To this end, our strategy leverages TMTpro16-based sample multiplexing, high-Field Asymmetric Ion Mobility Spectrometry (FAIMS), and real-time database searching (RTS). The data show that cell line diversity was reflective of differences in the relative protein abundance profiles. We also determined that several hundred proteins were highly enriched for a given cell line and performed gene ontology and pathway analysis on these cell line-enriched proteins. We provide an R Shiny application to query protein abundance profiles and retrieve proteins with similar patterns. The workflows used herein can be applied to additional cell lines to aid cell line selection in addressing a given scientific inquiry or in improving an experimental design.

Project description:Epidermal growth factor receptor (Egfr)-driven signaling regulates fundamental homeostatic processes. Dysregulated signaling via Egfr is implicated in numerous disease pathologies and distinct Egfr-associated disease etiologies are known to be tissue-specific. The molecular basis of this tissue specificity remains poorly understood. Most studies of Egfr signaling to date have been performed in vitro or in tissue-specific mouse models of disease, which has limited insight into Egfr signaling patterns in healthy tissues. Here, we carried out integrated phosphoproteomic, proteomic, and transcriptomic analyses of signaling changes across various mouse tissues in response to short-term stimulation with the Egfr ligand Egf. We show how both baseline and Egf-stimulated signaling behaviors differ between tissues. Moreover, we propose how baseline phosphorylation and total protein levels may be associated with clinically relevant tissue-specific Egfr-associated phenotypes. Altogether, our analyses illustrate tissue-specific effects of Egf stimulation and highlight potential links between underlying tissue biology and Egfr signaling output.