Project description:Competing exonucleases that promote 3’ end maturation or degradation direct quality control of small non-coding RNAs, but how these enzymes distinguish normal from aberrant RNAs is poorly understood. The Pontocerebellar Hypoplasia 7 (PCH7)-associated 3’ exonuclease TOE1 promotes maturation of canonical small nuclear RNAs (snRNAs). Here, we demonstrate that TOE1 achieves specificity towards canonical snRNAs by recognizing Sm complex assembly and cap trimethylation, two features that distinguish snRNAs undergoing correct biogenesis from other small non-coding RNAs. Indeed, disruption of Sm complex assembly via snRNA mutations or protein depletions obstructs snRNA processing by TOE1, and in vitro snRNA processing by TOE1 is stimulated by a trimethylated cap. An unstable snRNA variant that normally fails to undergo maturation becomes fully processed by TOE1 when its degenerate Sm binding motif is converted into a canonical one. Our findings uncover the molecular basis for how TOE1 distinguishes snRNAs from other small non-coding RNAs and explain how TOE1 promotes maturation specifically of canonical snRNAs undergoing proper processing.

Project description:Competing exonucleases that promote 3’ end maturation or degradation direct quality control of small non-coding RNAs, but how these enzymes distinguish normal from aberrant RNAs is poorly understood. The Pontocerebellar Hypoplasia 7 (PCH7)-associated 3’ exonuclease TOE1 promotes maturation of canonical small nuclear RNAs (snRNAs). Here, we demonstrate that TOE1 achieves specificity towards canonical snRNAs by recognizing Sm complex assembly and cap trimethylation, two features that distinguish snRNAs undergoing correct biogenesis from other small non-coding RNAs. Indeed, disruption of Sm complex assembly via snRNA mutations or protein depletions obstructs snRNA processing by TOE1, and in vitro snRNA processing by TOE1 is stimulated by a trimethylated cap. An unstable snRNA variant that normally fails to undergo maturation becomes fully processed by TOE1 when its degenerate Sm binding motif is converted into a canonical one. Our findings uncover the molecular basis for how TOE1 distinguishes snRNAs from other small non-coding RNAs and explain how TOE1 promotes maturation specifically of canonical snRNAs undergoing proper processing.

Project description:In animal cells, replication-dependent histone pre-mRNAs are cleaved at the 3’ end by U7 snRNP consisting of two core components: a ~60-nucleotide U7 snRNA and a ring of seven proteins, with Lsm10 and Lsm11 replacing the spliceosomal SmD1 and SmD2. Lsm11 interacts with FLASH and together they recruit the endonuclease CPSF73 and other polyadenylation factors, forming catalytically active holo U7 snRNP. Here, we assembled core U7 snRNP bound to FLASH from recombinant components and analyzed its appearance by electron microscopy and ability to support histone pre-mRNA processing in the presence of polyadenylation factors from nuclear extracts. We demonstrate that semi-recombinant holo U7 snRNP reconstituted in this manner has the same composition and functional properties as endogenous U7 snRNP, being capable of accurately cleaving histone pre-mRNAs in a reconstituted in vitro processing reaction. We also demonstrate that the U7-specific Sm ring assembles efficiently in vitro on a spliceosomal Sm site but the resultant semi-recombinant holo U7 snRNP fails to accurately cleave histone pre-mRNAs. This approach offers a unique opportunity to create engineered U7 snRNPs to study the role of various regions in the Sm proteins and U7 snRNA in the biogenesis of a functional holo U7 snRNP.

Project description:26S proteasomes direct the degradation of many short-lived regulatory proteins and dysfunctional polypeptides, and thus are essential effectors of eukaryotic proteostasis. Proteolysis by this multi-subunit complex occurs inside a barrel-shaped 20S core protease (CP) whose quaternary structure is conserved across all domains of life, and comprises four co-axially stacked heptameric rings formed by structurally related α- and β-subunits in an αββα configuration. CP biogenesis typically begins with the assembly of the α-rings, which then serve as templates for β-subunit integration, three of which present a peptidase active site within the central β-ring chamber. In eukaryotes, α-ring assembly is partially mediated by two hetero-dimeric chaperones, termed Pba1-Pba2 and Pba3-Pba4 in yeast (or PAC1-PAC2 and PAC3-PAC4 in mammals). Pba1-Pba2 initially promotes orderly recruitment of the α-subunits through interactions between their C-terminal HbYX/HbF motifs and shallow pockets at the α5-α6 and α6-α7 interfaces. Here, we identify PBAC5 as a fifth α-ring assembly chaperone in Arabidopsis that directly associates with the Pba1 homolog PBAC1 to form a trimeric PBAC5-PBAC1-PBAC2 complex that can functionally replace the yeast Pba1-Pba2 pair. PBAC5 contains a HbYX motif that likely docks with the pocket formed between the α4 and α5 subunits during α-ring formation. Arabidopsis missing PBAC5, PBAC1, and/or PBAC2 are hypersensitive to proteotoxic, salt and osmotic stress, and display proteasome assembly defects, consistent with a role in CP assembly. Remarkably, while PBAC5 is evolutionarily conserved in plants, it is also present in other kingdoms, with homologs evident in a limited array of fungal, metazoan, and oomycete species.

Project description:Background: Sm proteins are multimeric RNA-binding factors, found in all three domains of life. Eukaryotic Sm proteins, together with their associated RNAs, form small ribonucleoprotein (RNP) complexes important in multiple aspects of gene regulation. Comprehensive knowledge of the RNA components of Sm RNPs is critical for understanding their functions. Results: We developed a multi-targeting RNA-immunoprecipitation sequencing (RIP-seq) strategy to reliably identify Sm-associated RNAs from Drosophila ovaries and cultured human cells. Using this method, we discovered three major categories of Sm-associated transcripts: small nuclear (sn)RNAs, small Cajal body (sca)RNAs and mRNAs. Additional RIP-PCR analysis showed both ubiquitous and tissue-specific interactions. We provide evidence that the mRNA-Sm interactions are mediated by snRNPs, and that one of the mechanisms of interaction is via base pairing. Moreover, the Sm-associated mRNAs are mature, indicating a splicing-independent function for Sm RNPs. Conclusions: This study represents the first comprehensive analysis of eukaryotic Sm-containing RNPs, and provides a basis for additional functional analyses of Sm proteins and their associated snRNPs outside of the context of pre-mRNA splicing. Our findings expand the repertoire of eukaryotic Sm-containing RNPs and suggest new functions for snRNPs in mRNA metabolism.

Project description:Background: Sm proteins are multimeric RNA-binding factors, found in all three domains of life. Eukaryotic Sm proteins, together with their associated RNAs, form small ribonucleoprotein (RNP) complexes important in multiple aspects of gene regulation. Comprehensive knowledge of the RNA components of Sm RNPs is critical for understanding their functions. Results: We developed a multi-targeting RNA-immunoprecipitation sequencing (RIP-seq) strategy to reliably identify Sm-associated RNAs from Drosophila ovaries and cultured human cells. Using this method, we discovered three major categories of Sm-associated transcripts: small nuclear (sn)RNAs, small Cajal body (sca)RNAs and mRNAs. Additional RIP-PCR analysis showed both ubiquitous and tissue-specific interactions. We provide evidence that the mRNA-Sm interactions are mediated by snRNPs, and that one of the mechanisms of interaction is via base pairing. Moreover, the Sm-associated mRNAs are mature, indicating a splicing-independent function for Sm RNPs. Conclusions: This study represents the first comprehensive analysis of eukaryotic Sm-containing RNPs, and provides a basis for additional functional analyses of Sm proteins and their associated snRNPs outside of the context of pre-mRNA splicing. Our findings expand the repertoire of eukaryotic Sm-containing RNPs and suggest new functions for snRNPs in mRNA metabolism. RNA-Immunoprecipitation sequencing of RNA-Sm protein complexes.

Project description:Pre-mRNA splicing catalyzed by the spliceosome represents a critical step in the regulation of gene expression contributing to transcriptome and proteome diversity. The spliceosome consists of five small nuclear ribonucleoprotein particles (snRNPs) biogenesis of which remains only partially understood. Here we define the evolutionarily conserved protein Ecdysoneless (Ecd) as a critical regulator of U5 snRNP assembly and Prp8 stability. Combining Drosophila genetics with proteomic approaches we demonstrate Ecd requirement for the maintenance of adult healthspan and lifespan and identify the Sm ring protein SmD3 as a novel interaction partner of Ecd. We show that the predominant task of Ecd is to deliver Prp8 to the Sm protein ring within emerging U5 snRNPs. Ecd deficiency leads to reduced Prp8 protein levels and compromised U5 snRNP biogenesis, causing loss of splicing fidelity and transcriptome integrity. Based on our findings, we propose that Ecd acts as a chaperone that delivers Prp8 to the forming U5 snRNP allowing completion of the cytoplasmic part of the U5 snRNP biogenesis necessary to meet the demand of cells for functional spliceosomes.

Project description:Rings or arcs of fungus-stimulated plant growth occur often on the floor of woodlands which are commonly called “fairy rings”. We purified a plant growth-stimulating compound, 2-azahypoxanthine (AHX), from the fairy ring-forming fungus Lepista sordida, and the detection of AHX in the fungus-infected soil near the growth-stimulated turfgrass roots. The growth-promoting activity of AHX towards rice was further analyzed by oligo DNA microarrays.

Project description:Kinetochores form the link between chromosomes and microtubules of the mitotic spindle. The heterodecameric Dam1 complex (Dam1c) is a major component of the S. cerevisiae outer kinetochore, assembling into 3 MDa-sized microtubule-embracing rings, but how ring assembly is specifically initiated at kinetochores remains to be understood. Here, we describe a molecular pathway that provides local control of ring assembly during the establishment of sister kinetochore bi-orientation. We show that Dam1c and the general microtubule plus-end-associated protein (+TIP) Bim1/EB1 form a stable complex depending on a conserved motif in the Duo1 subunit of Dam1c. EM analyses reveal that Bim1 crosslinks protrusion domains of adjacent Dam1c heterodecamers and promotes the formation of oligomers with defined curvature. Disruption of the Dam1c-Bim1 interaction impairs kinetochore localization of Dam1c in metaphase and delays mitosis. Phosphorylation promotes Dam1c-Bim1 binding by relieving an intramolecular inhibition of the Dam1 C-terminus. In addition, Bim1 recruits Bik1/CLIP-170 to Dam1c and induces formation of full rings even in the absence of microtubules. Our data help to explain how new kinetochore end-on attachments are formed during the process of attachment error correction.

Project description:Viruses express several classes of non-coding (nc) RNAs1. For most of them, the functions and mechanisms by which they act are unknown. Herpesvirus saimiri (HVS), a g-herpesvirus that establishes latency in T cells of New World primates and has the ability to cause aggressive leukemias and lymphomas in non-natural hosts2, expresses seven small nuclear (sn), U-rich ncRNAs called HSURs in latently infected cells3-5. HSURs associate with Sm proteins and share biogenesis and structural features with cellular Sm-class snRNAs4,6. One of these viral snRNAs, HSUR 2, base-pairs with two host microRNAs (miRNAs), miR-142-3p and miR-167. However, HSUR 2 does not affect the abundance or activity of these two cellular miRNAs, suggesting alternative functions for these interactions. Here we show that HSUR 2 also base-pairs with messenger RNAs (mRNAs) in infected cells. We combined in vivo psoralen-mediated RNA-RNA crosslinking and high-throughput sequencing to identify mRNAs targeted by HSUR 2. HSUR 2 targets include mRNAs encoding Retinoblastoma (pRb) and factors involved in p53 signaling and apoptosis. We show that HSUR 2 represses expression of target mRNAs. Base-pairing between HSUR 2 and miR-142-3p and miR-16 is essential for HSUR 2-mediated mRNA repression, suggesting that HSUR 2 recruits these two cellular miRNAs to target mRNAs. Moreover, we show that HSUR 2 utilizes this mechanism to inhibit apoptosis. Our results uncover a role for a viral Sm-class RNA as a miRNA adaptor in post pre-mRNA-processing regulation of gene expression.