Project description:Abstract: Quality control requires discrimination between functional and aberrant species to selectively target substrates for destruction. Nuclear RNA quality control in Saccharomyces cerevisiae includes the TRAMP complex that marks RNA for decay via polyadenylation and helicase-dependent 3′ to 5′ degradation by the RNA exosome. Using reconstitution biochemistry we show that polyadenylation and helicase activities of TRAMP cooperate with processive and distributive exoribonuclease activities of the nuclear RNA exosome to selectively target and degrade an unmodified tRNA while leaving native tRNA intact. Inactivation of the distributive exoribonuclease activity of Rrp6 results in loss of substrate discrimination, leading to degradation of all RNAs. These data suggest that the activities of the Mtr4 helicase and Rrp6 exoribonuclease endow the TRAMP-RNA exosome complex with the ability to protect stable RNA while degrading defective RNA species. Rrp6 and its 3′-5′ exonuclease activity have previously been shown to contribute to quality control and processing of various types of nuclear RNAs. Our sequencing analysis further confirms that Rrp6 contributes to this process.

Project description:The Saccharomyces cerevisiae TRAMP4 and TRAMP5 complexes, which consist of the poly(A) polymerase Trf4 or Trf5, respectively, the zinc knuckle proteins Air1 or Air2, and the RNA helicase Mtr4, play a critical role in nuclear RNA surveillance. Although it is known to enhance the nuclease activity of the exosome, relatively little is known about the exact mechanism and specificity of TRAMP. To better define the specificities of the TRAMP complexes, we used phenotypic analysis and RNA deep-sequencing technology to measure differences in global RNA polyadenylation in air mutants, revealing specific requirements for each Air protein in the regulation of the levels of non-coding and coding RNAs. These findings reveal differential functions for Air proteins in eukaryotic RNA metabolism and indicate that they control the substrate specificity of the RNA exosome. Poly(A)+ RNA from WT, rrp6-M-NM-^T, air1-M-NM-^T rrp6-M-NM-^T and air2-M-NM-^T rrp6-M-NM-^T was sequenced using ABI SOLiD platform, in duplicate.

Project description:Metabolic switch from oxidative phosphorylation to glycolysis is required for tumorigenesis by providing cancer cells with energy and substrates of biosynthesis, and also plays a key role in inducing immune suppressive tumor microenvironment that inhibits tumor immunotherapy. Therefore, to develop more effective cancer therapy, it is important to elucidate mechanisms that control cancer metabolic switch. MTR4 is a RNA helicase associated with nuclear exosome that plays key roles in RNA processing and surveillance. We demonstrated that MTR4 is frequently overexpressed in hepatocellular carcinoma (HCC) and this predicts poor prognosis of HCC patients. MTR4 is required for HCC tumorigenesis by maintaining cancer metabolic switch. Mechanistically, MTR4 is required for the expression of critical glycolytic proteins such as GLUT1 and PKM2 by binding to their pre-mRNA and ensuring correct alternative splicing. c-Myc binds to the promoter of MTR4 gene and is required for MTR4 expression, indicating that MTR4 is a key mediator of c-Myc function in promoting cancer metabolism. These findings reveal an important pathway to drive cancer metabolic switch and present MTR4 as a promising therapeutic target for treating HCC.

Project description:Mtr4 is a eukaryotic RNA helicase required for RNA decay by the nuclear exosome. Previous studies have shown how RNA enroute to the exosome threads through the highly conserved helicase core of Mtr4. Mtr4 also contains an arch domain, although details of potential interactions between the arch and RNA have been elusive. To understand the interaction of Saccharomyces cerevisiae Mtr4 with various RNAs, we have characterized RNA binding in solution using hydrogen-deuterium exchange mass spectrometry, and affinity and unwinding assays. We have identified RNA interactions within the helicase core that are consistent with existing structures and do not vary between tRNA, single-stranded RNA, and double-stranded RNA constructs. We have also identified novel RNA interactions with a region of the arch known as the fist or KOW. These interactions are important for RNA unwinding and vary in strength depending on RNA structure and length. They account for Mtr4 discrimination between different RNAs. These interactions further drive Mtr4 to adopt a closed conformation characterized by reduced dynamics of the arch arm and intra-domain contacts between the fist and helicase core.

Project description:Abstract: RNA quality control relies on co-factors and adaptors to identify and prepare substrates for degradation by ribonucleases such as the 3′ to 5′ ribonucleolytic RNA exosome. Here, we determined cryo-electron microscopy structures of human Nuclear Exosome Targeting (NEXT) complexes bound to RNA, that reveal mechanistic insights to substrate recognition and early steps that precede RNA handover to the exosome. The structures illuminate ZCCHC8 as a scaffold, mediating homodimerization while embracing the MTR4 helicase and flexibly anchoring RBM7 to the helicase core. All three subunits collaborate to bind the RNA, with RBM7 and ZCCHC8 engaging sequences upstream of the 3′ end that is bound by MTR4. ZCCHC8 obscures MTR4 surfaces that are important for RNA binding and extrusion as well as surfaces important for MPP6-dependent recruitment and docking onto the RNA exosome core, features of which might contribute to coordinating RNA translocation and extrusion from the helicase to exosome recruitment and decay.

Project description:To investigate the role of the helicases Dbp2 and Mtr4 in the decay of Xrn1-sensitive lncRNAs, we performed RNA-Seq in yeast cells lacking Dbp2 or depleted for Mtr4.

Project description:til-ath-2011_3 - tiling hen2 and mtr4 - Identification and comparison of the RNA substrates that accumulate in hen2 and mtr4 mutants. Total RNA extracted from WT, hen2 and mtr4 mutants was used for oligo-dT primed cDNA preparation. Samples were hybridised to NimbleGen whole genome tiling arrays. 8 dye-swapped samples. Gene knockout, genotype comparison, normal vs. transgenic comparison.

Project description:The RNA exosome complex functions in both the accurate processing and rapid degradation of many different classes of RNA. Functional and structural analyses indicate that RNA can either be threaded through the central channel of the exosome or more directly access the active sites of the ribonucleases Rrp44 and Rrp6, but it was unclear how many substrates follow each pathway in vivo. To address this we used UV crosslinking in growing cells to identify transcriptome-wide interactions of RNAs with the major nuclear exosome-cofactor Mtr4 and with individual exosome subunits (Rrp6, Csl4, Rrp41 and Rrp44) along the threaded RNA path. We performed comparative analyses on exosome complexes lacking the exonucleolytic activity of Rrp44, either carrying a mutation in the Rrp44 S1 RNA-binding domain, predicted to disfavor direct access to the Rrp44 exonuclease active site, or with multiple mutations in Rrp41, reported to block RNA passage through the central channel. Our analysis identified targets using preferentially channel-threading pathway such as mRNAs, 5S rRNA or scR1. Our results suggest as well that aborted tRNAs transcripts, released during transcription, would be rapidly degraded using this route. Alternatively, pre-tRNAs appears to access Rrp44 directly. Both routes seems to be involved for degradation or maturation of RNAPI transcripts. The Rrp41 mutations were found to block substrate passage to Rrp44 only for cytoplasmic mRNAs, apparently confirming the prediction of widening of the lumen in the nuclear, Rrp6-associated complex.

Project description:til-ath-2011_3 - tiling hen2 and mtr4 - Identification and comparison of the RNA substrates that accumulate in hen2 and mtr4 mutants. Total RNA extracted from WT, hen2 and mtr4 mutants was used for oligo-dT primed cDNA preparation. Samples were hybridised to NimbleGen whole genome tiling arrays.

Project description:Recruitment of the human ribonucleolytic RNA exosome to nuclear polyadenylated (pA+) RNA is facilitated by the Poly(A) Tail eXosome Targeting (PAXT) connection. Besides its core dimer, formed by the exosome co-factor MTR4 and the ZFC3H1 protein, the PAXT connection remains poorly defined. By characterizing nuclear pA+-RNA bound proteomes as well as MTR4-ZFC3H1 containing complexes in conditions favoring PAXT assembly, we here uncover three additional proteins required for PAXT function: ZC3H3, RBM26 and RBM27 along with the known PAXT-associated protein, PABPN1. The zinc-finger protein ZC3H3 interacts directly with MTR4-ZFC3H1 and loss of any of the newly identified PAXT components results in the accumulation of PAXT substrates. Collectively, our results establish new factors involved in the turnover of nuclear pA+ RNA and suggest that these are limiting for PAXT activity.