Project description:Cytosolic iron-sulfur (Fe-S) cluster assembly (CIA) pathway delivers Fe-S clusters to nuclear and cytosolic Fe-S proteins involved in essential cellular functions. This delivery process is regulated by availability of iron and oxygen, but it remains unclear how CIA components orchestrate the cluster transfer under varying cellular environments. Here, we investigated the organization of CIA machinery under various conditions. We developed a targeted proteomics assay monitoring known CIA factors. Using this assay, we were able to detect NUBP1, CIAO3 and CIA substrates in immunoprecipitates of NUBP2, a component of the CIA scaffold complex. We also revealed that NUBP2 transiently associates with the CIA targeting complex (MMS19, CIAO1, CIAO2B), indicating the possible existence of CIA metabolons. We observed stronger interactions between CIAO3 and the CIA scaffold complex upon iron supplementation or low oxygen tension, while iron chelation and reactive oxygen species weaken CIAO3 interactions with CIA components. We further demonstrated that CIAO3 mutant with defective Fe-S cluster binding failed to integrate into the metabolons. However, these mutants unexpectedly exhibit stronger association with CIA substrates regardless of their reduced association with the CIA targeting complex, implicating that CIAO3 and CIA substrates may present in complexes independent of the CIA targeting complex. Together, our data suggested that CIA components potentially form metabolons whose assembly are regulated by environmental cues and require Fe-S cluster incorporation in CIAO3. These findings provided additional evidence that the CIA pathway adapts to changes in cellular environment through complex reorganization.

Project description:Despite the major progress made into spliceosome mechanisms through CryoEM, a major obstacle of this approach is its inability to map the positioning of helicases on the RNA substrate. Here we present a method ‘psiCLIP’ which probes protein-RNA interactions in specific spliceosomal states. The method is based on iCLIP, but is different to previous iCLIP studies in that it is performed on step-specific spliceosomes that are prepared from in vitro splicing extracts, similarly to those prepared for CryoEM. We applied psiCLIP to SmB (C complex), Prp16 (C complex) and Prp22 (C* and P complexes), using pre-mRNA substrates based on UBC4 and ACT1. We also used ATPase deficient dominant negative (dn) mutants of Prp16 and Prp22 to determine the contribution of ATPase activity to binding patterns.

Project description:During nuclear surveillance, the RNA exosome functions together with the TRAMP complexes, which include the RNA helicase Mtr4 together with a RNA binding protein (Air1 or Air2) and a poly(A) polymerase (Trf4 or Trf5). To better determine how RNA substrates are targeted, we analyzed protein and RNA interactions by TRAMP components. Mass spectrometry identified three distinct TRAMP complexes formed in vivo. These complexes preferentially assemble on different classes of transcripts. Unexpectedly, on many substrates, including pre-rRNAs and pre-mRNAs, specificity was apparently conferred by Trf4 and Trf5. Clustering of mRNAs by TRAMP association showed co-enrichment for mRNAs with functionally related products, supporting the significance of surveillance in regulating gene expression. Comparison of the binding sites of TRAMP components with multiple nuclear RNA binding proteins revealed preferential colocalization of subsets of factors. On pre-mRNAs, ∆trf5 deletion caused reduced Mtr4 binding and RNA accumulation of Trf5 top targets.

Project description:Deg proteases are involved in protein quality control and response to stress in prokaryotic organisms. Out of the 16 Deg-encoding genes of Arabidopsis, the products of three, Deg1, Deg5 and Deg8, are located in the thylakoid lumen. Deg1 forms homo-hexamers, degrading photosynthetic proteins, especially during photoinhibition. Deg5 and Deg8 form hetero-complexes, performing apparently similar functions, raising the question whether the two complexes are redundant. To answer this, single, double and triple knockout mutants were generated and their phenotypes were compared. Under optimal growth conditions deg5 and deg8 mutants looked like WT, whereas all combinations of deg1 mutants were smaller and more sensitive to photoinhibition. Under harsher conditions, deg5 and deg8 mutants were also affected, although less than deg1 mutants. Overexpression of Deg5-Deg8 could partially compensate for the loss of Deg1, but only in optimal conditions. Comparative proteomic analysis of deg1 mutants vs. WT revealed moderate up-regulation of thylakoid proteins involved in photoprotection, assembly, repair and house-keeping functions, and down-regulation of all photosynthetic complexes, consistent with the reduced growth of the deg1 mutants. Testing the steady-state level of Deg proteases in WT plants demonstrated that Deg1 was approximately two-fold more abundant than the Deg5-Deg8 complex. Moreover, recombinant Deg1 had higher in vitro proteolytic activity compared with Deg5 and Deg8. Affinity enrichment assays on transgenic plants expressing epitope-tagged Deg proteases revealed that Deg1 was pulled-down almost exclusively, whereas Deg5 and Deg8 were associated with a plethora of thylakoid membrane and lumen proteins, suggesting that they are capable of binding potential substrates, but are unable to degrade them efficiently. Two of the co-precipitated proteins, TL29 and Psb27-H1, were found slightly up-regulated in the triple mutant, suggesting that they are substrates of lumenal Deg proteases. Other pulled-down proteins were the D1 protein, LHCB proteins and subunits of the OEC of PSII, and components of the Cyt b6-f and NADH dehydrogenase complexes, suggesting that these might also be substrates of lumenal Deg proteases. Altogether, the results of this study suggest that differences in abundance and proteolytic activity are the source of the differential importance of the two Deg protease complexes observed in vivo.

Project description:Cell cycle progression in mammals is modulated by two ubiquitin ligase complexes, CRL4 and SCF, which facilitate degradation of chromatin substrates involved in the regulation of DNA replication. One member of the CRL4 complex, RepID (DCAF14/PHIP), is a WD40-containing protein that selectively binds and activates a group of replication origins. We found that RepID recruits the CRL4 complex to chromatin prior to DNA synthesis, thus playing a crucial architectural role in the proper licensing of chromosomes for replication. In the absence of RepID, cells rely on the alternative ubiquitin ligase, SKP2-containing SCF, to progress through the cell cycle. RepID depletion markedly increases cellular sensitivity to SKP2 inhibitors, which triggered massive genome re-replication. Both RepID and SKP2 interact with distinct, non-overlapping groups of replication origins, suggesting that selective interactions of replication origins with specific CRL components execute the DNA replication program and maintain genomic stability by preventing re-initiation of DNA replication.

Project description:The chromatin modifying activities inherent to polycomb repressive complexes PRC1 and PRC2 play an essential role in gene regulation, cellular differentiation, and development. However, the mechanisms by which these complexes recognize their target sites and function together to form repressive chromatin domains remain poorly understood. Recruitment of PRC1 to target sites has been proposed to occur through a hierarchical process, dependent on the prior nucleation of PRC2 and placement of H3K27me3. Here, using a de novo targeting assay in mouse embryonic stem cells we unexpectedly discover that PRC1-dependent H2AK119ub1 leads to the recruitment of PRC2 and H3K27me3 to effectively initiate a polycomb domain. Genetic ablation of catalytic subunit of the PRC1 complex (RINGA/B) and ChIP-seq analysis of PRC1 and PRC2 components confirmed genome-wide decreases in PRC2 occupancy and H3K27me3 levels at PRC target sites. This activity is restricted to variant PRC1 complexes and genetic ablation experiments reveal that targeting of the variant PCGF1/PRC1 complex by KDM2B to CpG islands is required for polycomb domain formation and normal development. Together these observations provide a surprising new PRC1-dependent logic for PRC2 occupancy and polycomb domain formation. RING1A-/-;RING1Bfl/fl ES cells were treated with 800M-BM-5M tamoxifen for 48hours and compared to untreated control cells by ChIP-seq for RING1B, SUZ12, EZH2 and H3K27me3.

Project description:Interactions of CAF1-NOT complex components from Trypanosoma brucei

Project description:The endogenous RNA substrates of Translin-TRAX complexes (also known as C3POs) and how they regulate diverse biological processes remain unknown. Here we show that Translin and TRAX do not play a significant role in RNAi in the filamentous fungus Neurospora crassa. Instead, the Neurospora C3PO complex functions as a ribonuclease that removes the 5M-bM-^@M-^Y pre-tRNA fragments after the processing of pre-tRNAs by RNase P. In translin and trax mutants, 5M-bM-^@M-^Y pre-tRNA fragments accumulate to very high levels that can be degraded specifically by both recombinant and endogenous Neurospora C3PO and recombinant Drosophila C3PO. In addition, the mutants have elevated tRNA levels and increased levels of protein translation and are more resistant to a programmed cell-death inducing agent. Together, this study identified the endogenous RNA substrates of C3PO and provides a potential explanation for its roles in seemingly diverse biological processes. Examine small RNA population changes in two different strain background

Project description:Transcriptional profiling of R. sphaeroides pRPcrZ compared to control R. sphaeroides pR4352 under low oxygen conditions. In this study we compared the transcriptome of a PcrZ over-expression strain to a control strain. PcrZ is the first small non-coding RNA, which is involved in the complex regulatory network of photosynthesis gene regulation in Rhodobacter sphaeroides. It counteracts the formation of photosynthetic complexes in a redox dependent manner. Two-strain experiment at low oxygen conditions (0.5 mg/L O2)

Project description:To identify mRNA substrates for the human RNase MRP complex, we examined the effects of siRNA-mediated depletion of RNase MRP (and RNase P) on the transcriptome of HEp-2 cells. The expression of two RNase MRP protein components, hPop1 and Rpp40, was knocked-down and after 48 hours mRNA was isolated from these cells as well as from cells transfected with an siRNA targeting the GFP mRNA (siEGFP), which was used as a control. The expression levels of mRNAs were analyzed on a genome-wide scale using 21K microarrays.