Project description:Modulation of immunomodulatory peptide activity by 2-deoxy-d-glucose

Project description:Mass spectrometry peptidomics coupled with RNA deep sequencing has revealed a large number of translated eukaryotic short open reading frames that produce genomically encoded peptides. The human LOC550643 gene, previously annotated as non-coding, encodes such a peptide (referred to as NoBody). NoBody peptide binds to EDC4 (enhancer of decapping 4) site-specifically, enriches complexes of proteins involved in 5'-3' mRNA degradation, and localizes to P-bodies, which are cellular RNA-protein granules associated with RNA degradation. Furthermore, modulating NoBody expression levels inversely regulates P-body numbers. This peptide has the potential to reveal new insights into the P-body structure-function relationship and cellular regulation of mRNA degradation. We used siRNA-mediated gene silencing coupled with biological pathway analysis to determine the cellular functions of NoBody (LOC550643), and whether it has similar cellular functions to related (Dcp2) and unrelated (DcpS) mRNA degradation proteins.

Project description:The mechanistic target of rapamycin, (mTOR) kinase plays a pivotal role in controlling critical cellular growth and survival pathways, and its aberrant induction is implicated in cancer pathogenesis. Therefore, suppression of active mTOR signaling has been of great interest to researchers; several mTOR inhibitors have been discovered to date. Ethanol (EtOH), similar to pharmacologic mTOR inhibitors, has been shown to suppress the mTOR signaling pathway, though in a non-catalytic manner. Despite population studies showing that the consumption of EtOH has a protective effect against hematological malignancies, the mechanisms behind EtOH’s modulation of mTOR activity in cells and its downstream consequences are largely unknown. Here we evaluated the effects of EtOH on the mTOR pathway, in comparison to the active-site mTOR inhibitor INK128, and compared translatome analysis of their downstream effects in diffuse large B-cell lymphoma (DLBCL).

Project description:The onset of erythropoiesis is under strict developmental control, with direct and indirect inputs influencing its derivation from the hematopoietic stem cell. A major regulator of this transition is KLF1/EKLF, a zinc finger transcription factor that plays a global role in all aspects of erythropoiesis. Here, we have identified a short, conserved enhancer element in KLF1 intron 1 that is important for establishing optimal levels of KLF1 in mouse and human cells. Chromatin accessibility of this site exhibits cell-type specificity and is under developmental control during the differentiation of human CD34+ cells towards the erythroid lineage. This site binds GATA1, SMAD1, TAL1, and ETV6. In vivo editing of this region in cell lines and primary cells reduces KLF1 expression quantitatively. However, we find that, similar to observations seen in pedigrees of families with KLF1 mutations, downstream effects are variable, suggesting that the global architecture of the site is buffered towards keeping the KLF1 genetic region in an active state. We propose that modification of intron 1 in both alleles is not equivalent to complete loss of function of one allele.

Project description:Caseinolytic protease P (ClpP) is a tetradecameric peptidase which assembles with chaperones such as ClpX to gain proteolytic activity. Acyldepsipeptides (ADEPs) represent small molecule mimics of ClpX, which bind into hydrophobic pockets on the apical site of the complex and thereby induce activation of ClpP. Detection of ClpP has so far been facilitated with active site directed probes which depend on the activity and oligomeric state of the complex. In order to expand the scope of ClpP labeling, we here introduce a stepwise synthetic approach to customized ADEP photoprobes. Structure-activity relationship studies with small fragments and ADEP derivatives paired with modeling studies revealed design principles of suitable probe molecules. The derivatives were tested for activation of ClpP and subsequently applied in labeling studies of the wild type peptidase as well as enzymes bearing mutations at the active site and an oligomerization sensor. Satisfyingly, the ADEP photoprobes provided a labeling readout of ClpP independent of its activity and oligomeric state.

Project description:Lenalidomide is a therapeutically active compound that binds to E3 ubiquitin ligase recruiter cereblon (CRBN) and induces cytotoxicity. We have identified eukaryotic translation initiation factor 2 subunit C2 (EIF2C2) as a new member of CRBN-downstream binding protein that plays an important role in microRNA (miRNA) maturation and function. The treatment of immunomodulatory drug (IMiD)-sensitive multiple myeloma (MM) cells with lenalidomide altered the steady-state levels of CRBN, EIF2C2 and miRNAs and induced apoptosis. However, although the treatment of IMiD-resistant MM cells with lenalidomide altered the steady-state levels of CRBN, EIF2C2 and miRNAs, but did not massively induce apoptosis. In contrast, silencing of EIF2C2 with its small hairpin RNA significantly altered the levels of miRNAs and induced apoptosis regardless of whether those cells are sensitive or resistant to IMiDs. Therefore, EIF2C2 could be considered as a new drug target for overcoming IMiDs resistance in MM cells.

Project description:Determine whether Streptomyces venezuelae protein SepH (vnz_27360) binds DNA and where

Project description:Interleukin-17 (IL-17)-secreting T helper 17 cells (Th17) are a recently identified CD4+ T helper subset that has been implicated in various inflammatory and autoimmune diseases. The issue of whether interleukin-17A (IL-17) contributes to hyperlipidemia-induced aortic endothelial cell activation remained unknown. Here, we reported that IL-17 contributes to hyperlipidemia-induced modulation of vascular cell gene expression during early atherosclerosis in vivo. Our results has shed lights onto the role of IL-17 on EC biology and has provided important insights for future development of novel therapeutics for early intervention of cardiovascular diseases and other inflammatory diseases.

Project description:Vitamin K epoxide reductases (VKOR) constitute a major family of integral membrane thiol oxidoreductases. In humans, VKOR sustains blood coagulation and bone mineralization through the vitamin K cycle. Previous chemical models assumed that the catalysis of human VKOR (hVKOR) starts from a fully reduced active site. This state, however, constitutes only a minor cellular fraction (5.6%). Thus, how hVKOR catalysis is carried out in the cellular environment remains largely unknown. Here we use quantitative mass spectrometry (MS) and electrophoretic mobility analysis to show that KO forms a covalent complex with a cysteine mutant mimicking hVKOR in a partially oxidized state. Trapping of this covalent reaction intermediate suggests that the partially oxidized state is catalytically active in cells. To investigate this activity, we analyze the correlation between the cellular activity and the cellular cysteine status of hVKOR. We find that the partially oxidized hVKOR has a considerably lower activity than hVKOR with a fully reduced active site. Although there are more partially oxidized hVKOR than fully reduced hVKOR in cells, these two reactive states contribute about equally to the overall hVKOR activity, and hVKOR catalysis can initiate from either of these states. Overall, the combination of MS quantification and biochemical analyses reveal the catalytic mechanism of this integral membrane enzyme in a cellular environment.

Project description:we performed ChIP-Seq to clarify whether c-Jun activated by pCMV-HBx transfection could bind to the promoter of the IL-35 gene. The results showed that the transcriptional activity of c-Jun was significantly enhanced in the 3-kb region upstream and downstream of the IL-35 transcription start site. This finding suggests that the transcription factor c-Jun binds the promoter sequence of IL-35 and activates its transcription.