The function role of ubiquitin proteasome pathway in the ER stress-induced AECII apoptosis during hyperoxia exposure

Background Bronchopulmonary dysplasia (BPD) is a major cause of mortality and morbidity in premature infants, characterized by alveolar dysplasia and pulmonary microvascular remodeling. In the present study, we have investigated the functional roles of ubiquitin proteasome pathway (UPP) in BPD, and its relationship with endoplasmic reticulum stress (ERS) mediated type II alveolar epithelial cell (AECII) apoptosis. Methods A hyperoxia-induced BPD rat model was constructed and the pathologic changes of lung tissues were evaluated by hematoxylin–eosin staining. Cell apoptosis and protein expression were determined by TUNEL assay and Western blotting, respectively. Further reagent kit with specific fluorescent substrate was utilized to measure the activity of 20 s proteasome. Meanwhile, AECII were cultured in vitro and exposed to hyperoxia. AECII apoptosis were measured by flow cytometry. In contrast, MG132 treatment was induced to explore UPP during hyperoxia exposure on AECII apoptosis and ERS sensors expression. Results A significant increase in apoptosis and total ubiquitinated proteins expression were observed in BPD rats and AECII culture, and the change of UPP was associated with ERS. In order to confirm the role of UPP in AECII apoptosis of BPD, AECII cells were treated by MG132 with the concentration of 10 μmol/L under hyperoxia exposure. We found that the proteins expression of glucose-regulated protein 78 (GRP-78), PKR-like ER kinase (PERK), activating transcription factor 4 (ATF4), activating transcription factor 6 (ATF6) and C/EBP homologous protein (CHOP), as well as AECII apoptosis were increased following MG132 treatment. Furthermore, the relatively up-regulated in the levels of total ubiquitinated proteins expression and 20 s proteasome activity were correlated with increased ERS sensors expression. Conclusions Our findings indicate that UPP may participate in the ERS-induced AECII apoptosis under hyperoxia condition.

Artemisinin Binds and Inhibits the Activity of Plasmodium falciparum Ddi1, a Retroviral Aspartyl Protease

Reduced sensitivity of the human malaria parasite, Plasmodium falciparum, to Artemisinin and its derivatives (ARTs) threatens the global efforts towards eliminating malaria. ARTs have been shown to cause ubiquitous cellular and genetic insults, which results in the activation of the unfolded protein response (UPR) pathways. The UPR restores protein homeostasis, which otherwise would be toxic to cellular survival. Here, we interrogated the role of DNA-damage inducible protein 1 (PfDdi1), a unique proteasome-interacting retropepsin in mediating the actions of the ARTs. We demonstrate that PfDdi1 is an active A2 family protease that hydrolyzes ubiquitinated proteasome substrates. Treatment of P. falciparum parasites with ARTs leads to the accumulation of ubiquitinated proteins in the parasites and blocks the destruction of ubiquitinated proteins by inhibiting the PfDdi1 protease activity. Besides, whereas the PfDdi1 is predominantly localized in the cytoplasm, exposure of the parasites to ARTs leads to DNA fragmentation and increased recruitment of the PfDdi1 into the nucleus. Furthermore, we show that Ddi1 knock-out Saccharomycescerevisiae cells are more susceptible to ARTs and the PfDdI1 protein robustly restores the corresponding functions in the knock-out cells. Together, these results show that ARTs act in multiple ways; by inducing DNA and protein damage and might be impairing the damage recovery by inhibiting the activity of PfDdi1, an essential ubiquitin-proteasome retropepsin.

Novel Ubiquitinated Proteins Downstream of the Fanconi Anemia Core Complex

The Fanconi anemia (FA) pathway is a major player in the control of DNA replication integrity in response to replication stress. Germline defect in the pathway results in the FA syndrome characterized by developmental abnormalities, bone marrow (BM) failure, and genome instability which greatly elevates the incidence of cancers. A pivotal step in the activation of the FA DNA repair pathway is the monoubiquitination of the FANCD2 and FANCI proteins (ID2) by the FA core complex, a unique ubiquitin ligase complex which includes eight proteins (FANCA-FANCG, FANCL, and FAAP100) and UBE2T/FANCT. This monoubiquitination event enables the recruitment of the ID2 complex to chromatin and nuclear foci at sites of DNA damage. Cells with mutations in any of the FA core complex proteins lack the ability to monoubiquitinated ID2, making ID2 ubiquitination a convergence point in the pathway, with an estimation of>90% FA patients defective in this step. Additionally, somatic mutations In FA genes render tumor cells sensitive to DNA crosslinking agents, so identification of FA pathway defects provides an opportunity for therapeutic targeting. In search for additional potential target/substrate of this unique FA core ubiquitin ligase complex, we performed a high throughput genome-wide ubiquitin-specific proteomics (UbiScan) screen and found, in addition to the ID2 complex, many ubiquitinated proteins are dysregulated (mostly downregulated) in FA deficient cells compared with that of FA proficient cells. We used a Ubiquitin Remnant Motif (K- ∑-GG) Antibody Bead Conjugate (Cell Signaling Technology), a proprietary ubiquitin branch ("K- ∑-GG") antibody with specificity for a di-glycine tag that is the remnant of ubiquitin left on protein substrates after trypsin digestion, to enrich ubiquitinated peptides from trypsin digested cell samples (shNT vs shFANCA). This enrichment is followed by LC-MS/MS analysis for quantitative profiles of hundreds to over a thousand nonredundant ubiquitinated sequences. We were successful in demonstrating that under steady-state conditions (without proteasome inhibitor treatment), the ubiquitinated forms of both FANCD2 and FANCI proteins are much higher in control (shNT) HeLa cells compared with that of the cells depleted of FANCA (shFANCA). We then collaborated with the Cell signaling technology to perform a high throughput UbiScan® analysis of total ubiquitinated proteins both in total nuclei and chromatin fractions under replicative stress conditions. UbiScan® enables researchers to isolate, identify and quantitate large numbers of ubiquitin-modified cellular peptides with a high degree of specificity and sensitivity, providing a global overview of the ubiquitination sites in cellular proteins in cell and tissue samples without preconceived biases about where these modified sites occur. A total of 16,249 redundant modified peptide assignments to 7,856 modified sites for the Ubiquitin K-GG Remnant Motif Antibody were obtained. As expected, the amount of monoubiquitinated FANCD2 (at K651) and FANCI (at K523) were highly reduced in both the nuclear and chromatin fractions of Hela cells depleted of FANCA (shA). Consistent with the earlier findings, the amount of ubiquitinated ID2 proteins were extremely low in the chromatin fraction of the Hela cells depleted of FANCA. Since there are numerous ubiquitinated proteins found to be dysregulated in our UbiScan analyses, we used the following criteria to select the target proteins based on; a) -fold changes, and b) proteins that are known to participate in the DNA repair signaling pathways. We validated our UbiScan results by using an assay system to detect endogenous protein ubiquitination. We also found a significant reduction in the ubiquitination of several DNA repair-related proteins (found in our UbiScan analysis) in FANCA deficient cells. To assess FA pathway functions, we generated HAP1 and appropriate cells knock out of these select ubiquitinated target proteins by using CRISPR-Cas9 system. Then, the KO cells were examined for FA pathway functions. These results will be discussed. In conclusion, our findings reveal that the FA core ubiquitin ligase complex regulates (directly or indirectly) the ubiquitinated levels of many novel proteins outside of the ID2 complex, and these novel target proteins may provide important additional mechanistic insights into the FA DNA repair pathway. Disclosures No relevant conflicts of interest to declare.

Interactions of ubiquitin and CHMP5 with the V domain of HD-PTP reveals role for regulation of Vps4 ATPase

The family of Bro1 proteins coordinates the activity of the Endosomal Sorting Complexes Required for Transport (ESCRTs) to mediate a number of membrane remodeling events. These events culminate in membrane scission catalyzed by ESCRT-III, whose polymerization and disassembly is controlled by the AAA-ATPase, Vps4. Bro1-family members Alix and HD-PTP as well as yeast Bro1 have a central ‘V’ domains that non-covalently bind Ub and connect ubiquitinated proteins to ESCRT-driven functions such as the incorporation of ubiquitinated membrane proteins into intralumenal vesicles of multivesicular bodies. Recently, it was discovered that the V domain of yeast Bro1 binds the MIT domain of Vps4 to stimulate its ATPase activity. Here we determine the structural basis for how the V domain of human HD-PTP binds ubiquitin. The HD-PTP V domain also binds the MIT domain of Vps4 and ubiquitin-binding to the HD-PTP V domain enhances its ability to stimulate Vps4 ATPase activity. Additionally, we found V domains of both HD-PTP and Bro1 bind CHMP5 and Vps60, respectively, providing another potential molecular mechanism to alter Vps4 activity. These data support a model whereby contacts between ubiquitin, ESCRT-III, and Vps4 by V domains of the Bro1 family may coordinate late events in ESCRT-driven membrane remodeling events.

Dynamics and Functional Interplay of Non-histone Lysine Crotonylome and Ubiquitylome in Vascular Smooth Muscle Cell Phenotypic Remodeling

BackgroundsCrotonylation of histones is a recently discovered type of post-translational modification that can regulate gene expression. However, the function of crotonylation on nonhistone proteins in vascular smooth muscle cells (VSMC) is unclear. Here, we aim to use modification and proteomic analysis to find the cellular characteristic of crotonylated nonhistone proteins and the crosstalk with ubiquitinated proteins in vascular smooth muscle cell (VSMC) phenotypic remodeling. ResultsWe performed modification and proteomic analysis of VSMCs before and after platelet-derived growth factor-BB (PDGF-BB) stimulation. The crotonylated and ubiquitinated pan-antibody was used to enrich the protein and then subjected to high-throughput mass spectrometry analysis. Then we compared the enrichment analysis of differentially modified proteins in regards to GO terms, KEGG pathway and protein domain. As a result, there were 2138 crotonylation sites in 534 proteins and 1359 ubiquitination sites corresponding to 657 proteins. The crotonylated proteins participate in a variety of important cellular pathways and perform different functions in VSMCs. Among them, some proteins were found to be closely involved in the physiological process of VSMC phenotypic remodeling including glycolysis/gluconeogenesis, vascular smooth muscle contraction, and PI3K-Akt signaling pathway. Furthermore, the KEGG pathway enrichment analysis showed that the ubiquitinated proteins were found to be closely involved in the physiological process of VSMC phenotypic remodeling including glycolysis/gluconeogenesis, vascular smooth muscle contraction, RAS signaling pathway or PI3K-Akt signaling pathway. Crosstalk analysis showed that there were 199 sites within 177 proteins modified by crotonylation and ubiquitination simultaneously. PPI network analysis indicated that crotonylated and ubiquitinated proteins played an important role in cellular bioprocess commonly and possible synergistic effect. ConclusionsIn summary, our bioinformatics show that nonhistone crotonylation and ubiquitination play an important role in the VSMC phenotypic transformation induced by PDGF-BB stimulation. The crosstalk of crotonylation and ubiquitination in glycolysis is possibly a novel mechanism underlying the VSMC phenotypic remodeling.

From the Evasion of Degradation to Ubiquitin-Dependent Protein Stabilization

A hallmark of cancer is dysregulated protein turnover (proteostasis), which involves pathologic ubiquitin-dependent degradation of tumor suppressor proteins, as well as increased oncoprotein stabilization. The latter is due, in part, to mutation within sequences, termed degrons, which are required for oncoprotein recognition by the substrate-recognition enzyme, E3 ubiquitin ligase. Stabilization may also result from the inactivation of the enzymatic machinery that mediates the degradation of oncoproteins. Importantly, inactivation in cancer of E3 enzymes that regulates the physiological degradation of oncoproteins, results in tumor cells that accumulate multiple active oncoproteins with prolonged half-lives, leading to the development of “degradation-resistant” cancer cells. In addition, specific sequences may enable ubiquitinated proteins to evade degradation at the 26S proteasome. While the ubiquitin-proteasome pathway was originally discovered as central for protein degradation, in cancer cells a ubiquitin-dependent protein stabilization pathway actively translates transient mitogenic signals into long-lasting protein stabilization and enhances the activity of key oncoproteins. A central enzyme in this pathway is the ubiquitin ligase RNF4. An intimate link connects protein stabilization with tumorigenesis in experimental models as well as in the clinic, suggesting that pharmacological inhibition of protein stabilization has potential for personalized medicine in cancer. In this review, we highlight old observations and recent advances in our knowledge regarding protein stabilization.

Reconstitution defines the roles of p62, NBR1 and TAX1BP1 in ubiquitin condensate formation and autophagy initiation

The autophagic degradation of misfolded and ubiquitinated proteins is important for cellular homeostasis. In this process, which is governed by cargo receptors, ubiquitinated proteins are condensed into larger structures and subsequently become targets for the autophagy machinery. Here we employ in vitro reconstitution and cell biology to define the roles of the human cargo receptors p62/SQSTM1, NBR1 and TAX1BP1 in the selective autophagy of ubiquitinated substrates. We show that p62 is the major driver of ubiquitin condensate formation. NBR1 promotes condensate formation by equipping the p62-NBR1 heterooligomeric complex with a high-affinity UBA domain. Additionally, NBR1 recruits TAX1BP1 to the ubiquitin condensates formed by p62. While all three receptors interact with FIP200, TAX1BP1 is the main driver of FIP200 recruitment and thus the autophagic degradation of p62–ubiquitin condensates. In summary, our study defines the roles of all three receptors in the selective autophagy of ubiquitin condensates.

Interactome analysis of Bag-1 isoforms reveals novel interaction partners in endoplasmic reticulum-associated degradation

Bag-1 is a multifunctional protein that regulates Hsp70 chaperone activity, apoptosis, and proliferation. The three major Bag-1 isoforms have different subcellular localizations and partly non-overlapping functions. To identify the detailed interaction network of each isoform, we utilized mass spectrometry-based proteomics and found that interactomes of Bag-1 isoforms contained many common proteins, with variations in their abundances. Bag-1 interactomes were enriched with proteins involved in protein processing and degradation pathways. Novel interaction partners included VCP/p97; a transitional ER ATPase, Rad23B; a shuttling factor for ubiquitinated proteins, proteasome components, and ER-resident proteins, suggesting a role for Bag-1 also in ER-associated protein degradation (ERAD). Bag-1 pull-down from cells and tissues from breast cancer patients validated these interactions and showed cancer-related prominence. Using in silico predictions we detected hotspot residues of Bag-1. Mutations of these residues caused loss of binding to protein quality control elements and impaired proteasomal activity in MCF-7 cells. Following CD147 glycosylation pattern, we showed that Bag-1 downregulated VCP/p97-dependent ERAD. Overall, our data extends the interaction map of Bag-1, and broadens its role in protein homeostasis. Targeting the interaction surfaces revealed in this study might be an effective strategy in the treatment of cancer.