Project description:PROteolysis TArgeting Chimeras (PROTACs) are bifunctional small molecules that can simultaneously recruit target protein and E3 ligase to form a ternary complex (target protein / PROTAC / E3 ligase), leading to target protein ubiquitination and degradation via the Ubiquitin-Proteasome System (UPS). PROTACs have gained increasing attention in recent years due to certain advantages over traditional therapeutic modalities enabling targeting of previously "undruggable" proteins. To better understand the mechanism of PROTAC-induced Target Protein Degradation (TPD), several computational approaches have recently been developed to study and predict ternary complex formation. However, mounting evidence suggests that ubiquitination can also be a rate-limiting step in PROTAC induced TPD. Here, we propose a structure-based computational approach to predict target protein ubiquitination induced by CRBN-based PROTACs,

Project description:We present a novel immune-affinity-based method UbiSite for capture and further identification of ubiquitination sites by MS for any cell line or tissue sample. Implementing the UbiSite methodology for a large-scale experiment we successfully mapped 62000 unique ubiquitination sites on protein substrates for two different human cell lines.

Project description:We present a novel immune-affinity-based method UbiSite for capture and further identification of ubiquitination sites by MS for any cell line or tissue sample. Implementing the UbiSite methodology for a large-scale experiment we successfully mapped 62000 unique ubiquitination sites on protein substrates for two different human cell lines.

Project description:We present a novel immune-affinity-based method UbiSite for capture and further identification of ubiquitination sites by MS for any cell line or tissue sample. Implementing the UbiSite methodology for a large-scale experiment we successfully mapped 62000 unique ubiquitination sites on protein substrates for two different human cell lines.

Project description:Epstein-Barr virus (EBV) reactivation in latently infected B cells is essential for persistent infection and B cell receptor (BCR) activation is a physiologically relevant stimulus for EBV reactivation. Post-translational modifications, such as phosphorylation and ubiquitination, are known to be regulated by antigen binding to BCR within minutes. However, a detailed understanding of the signaling alterations at later time when EBV is being actively replicated remains elusive. To gain insights into BCR activation-mediated reprogramming of the cellular environment in both Akata-BX1 (EBV+) and Akata-4E3 (EBV-) B cells, we utilized a 3-plex stable isotope labeling by amino acid in cell culture (SILAC)-based quantitative proteomic approach to monitor the dynamic changes of protein ubiquitination during the course of immunoglobulin G (IgG) cross-linking of BCRs. We observed temporal alterations in the level of ubiquitination on approximately 150 sites in both Akata-BX1 (EBV+) and Akata-4E3 (EBV-) B cells post-IgG cross-linking compared with no cross-linking controls, with the majority of protein ubiquitination down-regulated. Our analysis revealed that IgG cross-linking plays a major role in the regulation of protein ubiquitination in both EBV+ and EBV- B cells. Bioinformatic analyses of up-regulated ubiquitination events revealed significant enrichment of proteins involved in RNA processing. Among the down-regulated ubiquitination events are proteins enriched in apoptosis and the ubiquitin-proteasome pathway. The comparative and quantitative studies provide a foundation for further understanding how BCR activation regulates cellular protein ubiquitination and how EBV utilizes or subverts BCR engagement-mediated changes to facilitate viral replication.

Project description:Protein phosphorylation and ubiquitination are two of the most abundant forms of post-translational modifications in eukaryotes, regulated by thousands of protein kinases, phosphatases, E3 ubiquitin ligases, and ubiquitin proteases. Although previous studies have catalogued several ubiquitinated proteins in plants (Walton et al., 2016), few membrane-localized proteins have been identified. Receptor kinases (RKs) initiate phosphorylation signal relays that regulate plant growth, development, and stress responses. While the regulatory role of phosphorylation on protein kinase function is well-documented (Couto and Zipfel, 2016), considerably less is known about the role of ubiquitination on protein kinase function, even though protein turnover is critical to their signaling competence and cellular homeostasis. Here we describe the large-scale identification of ubiquitination sites on Arabidopsis proteins associated with or integral to the plasma membrane, including over 100 protein kinases.

Project description:Protein ubiquitination, which is a major post-translational modifications that occurs in eukaryotic cells, is involved in diverse biological processes. To date, large-scale profiling of the ubiquitome in common wheat has not been reported, despite its status as the major cereal crop in the world. Here, we performed the first ubiquitome analysis of the common wheat (Triticum aestivum L.) variety, Aikang 58. Overall, 433 lysine modification sites were identified in 285 proteins in wheat seedlings, and four putative ubiquitination motifs were revealed. Moreover, ubiquitylated lysines were found to have a significantly different preference for secondary structures when compared with the all lysines. Bioinformatics analysis revealed that the ubiquitinated proteins were involved in a wide variety of biological processes and diverse subcellular localizations. In accordance with previous studies, proteins related to binding and catalytic activity were predicted to be the preferential targets of lysine ubiquitination. Besides, protein interaction network analysis reveals that diverse interactions are modulated by protein ubiquitination. The results presented herein provide a global view of the ubiquitome in common wheat for the first time and lays a foundation for exploring the physiological role of lysine ubiquitination in wheat and other plants.

Project description:The human CTLH complex is a newly discovered multi-subunit E3 ligase. At present, only a few of its ubiquitination targets are known. Here, we use proteomic techniques in RanBPM-depleted HeLa cells to identify ubiquitination substrates of the CTLH complex. First, global proteomics determined proteins that were significantly increased in cells depleted of RanBPM. This analysis revealed potential degradation-induced ubiquitination substrates of the complex. Ubiquitination differences using diGLY-enriched proteomics in shRanBPM cells compared with the endogenous RanBPM interactome also revealed candidate ubiquitination targets.

Project description:To identify sites of ubiquitination in Myc-6His-Tagged forms of RAD23A and UBQLN1 for wild-type and forms with some arginine residues mutated to lysines (see FASTA file for details).

Project description:Xylem vessels function in the long-distance conduction of water in land plants. The NAC transcription factor VASCULAR-RELATED NAC-DOMAIN7 (VND7) is a master regulator of xylem vessel cell differentiation in Arabidopsis (Arabidopsis thaliana). We previously isolated seiv (suppressor of ectopic xylem vessel cell differentiation induced by VND7) mutants, which are suppressor mutants of VND7-inducible xylem vessel cell differentiation. Here, we report that the responsible genes for seiv3, seiv4, seiv6, and seiv9 are protein ubiquitination-related genes encoding PLANT U-BOX46 (PUB46), uncharacterized F-BOX protein, PUB36, and UBIQUITIN-SPECIFIC PROTEASE1, respectively. We also found the decreased expression of genes downstream of VND7 and abnormal xylem transport activity in the seiv mutants. Upon VND7 induction, ubiquitinated levels from 492 and 180 protein groups were up- and down-regulated, respectively. Proteins for cell wall biosynthesis and protein transport were ubiquitinated by the VND7 induction, whereas such active protein ubiquitination was not observed in the seiv mutants. We detected the ubiquitination of three lysine residues in VND7: K94, K105, and K260. Substituting K94 with arginine significantly decreased the transactivation activity of VND7, suggesting that the ubiquitination of K94 is crucial for regulating VND7 activity. Our findings highlight the crucial roles of target protein ubiquitination in regulating xylem vessel activity.