Project description:The dynamic interplay between ribosomes and mRNAs plays a central role in gene expression regulation, balancing protein synthesis and mRNA stability. However, traditional methods capturing static ribosome occupancy fail to resolve the temporal dynamics governing these processes. Here, we introduce Temporal Ribosome Density Profiling (TRiP), which combines metabolic RNA labeling and polysome sequencing to map ribosome density dynamics across the mRNA lifespan. TRiP reveals a striking temporal symmetry conserved across cell types: gene-specific ribosome loading rates are counterbalanced by coordinated unloading rates, creating a self-regulatory loop that, as demonstrated through biophysical modeling and experimental validation in diverse cellular contexts, directly couples ribosome dynamics to mRNA stability. We further uncover how mRNA structural motifs and m6A methylation fine-tune ribosome dynamics at the isoform level, simultaneously modulating protein output and transcript half-life. In macrophages, this dynamic control enables rapid immune responses by upregulating translation efficiency of pro-inflammatory genes. Remarkably, these principles extend to synthetic mRNAs, where machine learning-guided optimization of ribosome dynamics enhances protein production. Our work establishes ribosome density dynamics as a pervasive and tunable regulatory axis, with broad implications for adaptive immunity, RNA biology, and the design of therapeutic mRNAs.

Project description:The dynamic interplay between ribosomes and mRNAs plays a central role in gene expression regulation, balancing protein synthesis and mRNA stability. However, traditional methods capturing static ribosome occupancy fail to resolve the temporal dynamics governing these processes. Here, we introduce Temporal Ribosome Density Profiling (TRiP), which combines metabolic RNA labeling and polysome sequencing to map ribosome density dynamics across the mRNA lifespan. TRiP reveals a striking temporal symmetry conserved across cell types: gene-specific ribosome loading rates are counterbalanced by coordinated unloading rates, creating a self-regulatory loop that, as demonstrated through biophysical modeling and experimental validation in diverse cellular contexts, directly couples ribosome dynamics to mRNA stability. We further uncover how mRNA structural motifs and m6A methylation fine-tune ribosome dynamics at the isoform level, simultaneously modulating protein output and transcript half-life. In macrophages, this dynamic control enables rapid immune responses by upregulating translation efficiency of pro-inflammatory genes. Remarkably, these principles extend to synthetic mRNAs, where machine learning-guided optimization of ribosome dynamics enhances protein production. Our work establishes ribosome density dynamics as a pervasive and tunable regulatory axis, with broad implications for adaptive immunity, RNA biology, and the design of therapeutic mRNAs.

Project description:To identify proteins interacting with STAMBP, we performed co-immunoprecipitation (CoIP) assays using pancreatic cancer cells. Specifically, SW1990 cells stably overexpressing either the empty vector control or HA-tagged STAMBP (HA-STAMBP) were subjected to CoIP with an anti-HA antibody to enrich HA-associated proteins. Proteins specifically interacting with HA-STAMBP were then identified by comparative proteomic analysis between the two cell lines. Mass spectrometry-based proteomic services were provided by Shanghai Omicsspace Biotech.

Project description:Antibody–drug conjugates (ADCs) require antibodies with both high specificity and efficient internalization—features often overlooked by conventional discovery pipelines that rely on preselected antigens and recombinant proteins. Here, we present an integrated phenotypic platform that combines target-unbiased live-cell biopanning with in situ chemical crosslinking and mass spectrometry to concurrently identify internalizing 49 antibodies and their membrane-bound cognate antigens in a physiologic context.

Project description:Acute lung injury (ALI) accompanied by an inflammatory response is an important complication after drowning. Macrophage activation and polarization are implicated in the inflammatory process of lipopolysaccharide (LPS)-induced ALI (LPS-ALI), but little is known about drowning-induced ALI (drowning-ALI). SH3GLB1 is a member of the endophilin family and has been shown to be involved in mitochondrial morphological changes and autophagy. However, its role in ALI remains unclear. Here,we performed single-cell profiling of lung immune cells isolated from the lungs of drowning-ALI mouse models. We found that the regulation of macrophages in drowning-ALI was similar to that in LPS-ALI. Specifically, SH3GLB1 was highly expressed in macrophages of drowning-ALI mouse models and was related to inflammation. Furthermore, SH3GLB1 deletion ameliorated LPS-ALI or drowning-ALI. In contrast, the restoration of SH3GLB1 expression provoked LPS-ALI and drowning-ALI. Mechanistically, SH3GLB1 was shown to interact with Rab7 to contribute to mitophagy, which resulted in mitochondrial dysfunction. Overall, these findings indicated that SH3GLB1 is required for Rab7-mediated mitophagy in inflammation during ALI and could be a novel target for lung protection.

Project description:Antibody-mediated rejection (AMR) accounts for >50% of kidney allograft losses. AMR is caused by donor-specific antibodies (DSA) against HLA and non-HLA antigens in the glomeruli and the tubulointerstitium, which together with high interferon gamma (IFNɣ) and tumor necrosis factor-alpha (TNFα), trigger graft injury. Unfortunately, the mechanisms governing cell-specific injury in AMR remain unclear. We studied 30 for-cause kidney biopsies with early AMR, acute cellular rejection or acute tubular necrosis (‘non-AMR’). We laser-captured microdissected glomeruli and tubulointerstitium and subjected them to unbiased proteome analysis. 120/2026 glomerular and 180/2399 tubulointerstitial proteins were significantly differentially expressed in AMR vs. non-AMR biopsies (p<0.05). Basement membrane and extracellular matrix (ECM) proteins were significantly decreased in both AMR compartments. We verified decreased glomerular and tubulointerstitial LAMC1 expression, and decreased glomerular NPHS1 and PTPRO expression in AMR. Cathepsin-V (CTSV) was predicted to cleave ECM-proteins in the AMR glomeruli, and CTSL, CTSS and LGMN in the tubulointerstitium. We identified galectin-1, an immunomodulatory protein upregulated in AMR glomeruli and linked to the ECM. Anti-HLA class-I antibodies significantly increased CTSV expression, and galectin-1 expression and secretion, in human glomerular endothelial cells. We also studied glutathione S-transferase omega-1 (GSTO1), an ECM-modifying enzyme, increased in the AMR tubulointerstitium. GSTO1 expression was significantly increased in TNFα-treated proximal tubular epithelial cells. IFNɣ and TNFα significantly increased CTSS and LGMN expression in these cells. Basement membranes are often remodeled in chronic AMR, and we demonstrated that this remodeling begins early in glomeruli and tubulointerstitium. Targeting ECM-remodeling in AMR may represent a new therapeutic opportunity.

Project description:Objective:Dendrobium huoshanense is a renowned geo-authentic herb, and its excellent quality is closely correlated with the specific combined stress of low temperature and low humidity found in its native habitat.Methods:In this study, we profiled the protein S-sulfenylation landscape of D. huoshanense under simulated low temperature and low humidity stress using Cys-Tag labeling coupled with Data-Independent Acquisition (DIA) mass spectrometry.Results:Physiological analysis revealed a moderate accumulation of H₂O₂ at 12 h of stress, representing an early signaling phase. A total of 9,924 sulfenylation sites mapped to 6,953 proteins were identified. Following stress treatment, 226 sites showed differential modification, 202 of which were upregulated. Motif analysis demonstrated a significant enrichment of lysine and arginine residues flanking the modification sites. Enrichment analysis indicated that S-sulfenylation is primarily involved in vesicle trafficking, carbon metabolism, and amino acid biosynthesis.Conclusion:This study characterizes the response of sulfenylated proteins to low temperature and low humidity stress in D. huoshanense, providing theoretical insights into the molecular mechanisms of plant redox regulation under abiotic stress.

Project description:To elucidate the mechanism by which USP26 dictates HCC tumorigenesis, we attempted to identify the protein associated with USP26 using a triple-epitope (S-protein, FLAG tag and streptavidin binding peptide)-tagged version of USP26 (SFB-USP26). Tandem affinity purification followed by mass spectrometric analysis identified several strong interactors of USP26.

Project description:HTS of fermentation food

Project description:RAS is one of the most frequently mutated proto-oncogenes in human malignancies, with mutation sites and subtypes exhibiting tumor-type dependent distribution. Oncogenic RAS mutations will maintain continuously GTP-bound activation states that leading to dysregulation of downstream signaling, ultimately disrupting cellular homeostasis to induce malignant transformation of cells. In this study, we employed TurboID proximity-labeling technology integrated with quantitative proteomics LC-MS/MS to systematically characterize the proximal binding proteins of wild-type KRAS and three high-frequency oncogenic mutant subtypes G12C, G12D and G12V. Through comprehensive bioinformatic analysis of mutation-specific interaction networks and distinct metabolic pathways, we identified significant enrichment of mutant KRAS binding proteins in insulin signaling pathway, reactive oxygen species related pathways, glucose and lipid metabolism and so on. Metabolic reprogramming pathways in KRAS G12 mutations collectively fuel tumor proliferation and immune evasion. In addition, we also comparatively analyzed the proximal binding proteins similarity in three G12 mutants. Notably, we observed that the KRAS E3 ubiquitin ligase adaptor LZTR1 diminished binding with mutations, and the mTORC1 important regulatory protein LAMTOR1 was enhanced recruitment by mutations. This multi-dimensional profiling delineates a comprehensive mapping of KRAS WT and G12 mutant interactomes and unveils the metabolic reprogramming pathways associated with KRAS activating mutations. Our analysis result provides potential therapeutic targets for KRAS-driven tumorigenesis while establishing a mechanistic framework for developing KRAS mutation-specific therapeutic strategies.