Identification of peptide inhibitors of pre-mRNA splicing derived from the essential interaction domains of CDC5L and PLRG1

CDC5L and PLRG1 are both spliceosomal proteins that are highly conserved across species. They have both been shown to be part of sub- spliceosomal protein complexes that are essential for pre-mRNA splicing in yeast and humans. CDC5L and PLRG1 interact directly in vitro. This interaction is mediated by WD40 regions in PLRG1 and the C-terminal domain of CDC5L. In order to determine whether this interaction is important for the splicing mechanism, we have designed peptides corresponding to highly conserved sequences in the interaction domains of both proteins. These peptides were used in in vitro splicing experiments as competitors to the cognate sequences in the endogenous proteins. Certain peptides derived from the binding domains of both proteins were found to inhibit in vitro splicing. This splicing inhibition could be prevented by preincubating the peptides with the corresponding partner protein that had been expressed in Escherichia coli. The results from this study indicate that the interaction between CDC5L and PLRG1 is essential for pre-mRNA splicing and further demonstrate that small peptides can be used as effective splicing inhibitors.     

A downstream splicing enhancer is essential for in vitro pre-mRNA splicing.

Splicing enhancers have previously been shown to promote processing of introns containing weak splicing signals. Here, we extend these studies by showing that also 'strong' constitutively active introns are absolutely dependent on a downstream splicing enhancer for activity in vitro. SR protein binding to exonic enhancer elements or U1 snRNP binding to a downstream 5' splice site serve redundant functions as activators of splicing. We further show that a 5' splice site is most effective as an enhancer of splicing. Thus, a 5' splice site is functional in S100 extracts, under conditions where a SR enhancer is nonfunctional. Also, splice site pairing occurs efficiently in the absence of exonic SR enhancers, emphasizing the significance of a downstream 5' splice site as the enhancer element in vertebrate splicing.     

NIPP1-mediated interaction of protein phosphatase-1 with CDC5L, a regulator of pre-mRNA splicing and mitotic entry

NIPP1 is a regulatory subunit of a species of protein phosphatase-1 (PP1) that co-localizes with splicing factors in nuclear speckles. We report that the N-terminal third of NIPP1 largely consists of a Forkhead-associated (FHA) protein interaction domain, a known phosphopeptide interaction module. A yeast two-hybrid screening revealed an interaction between this domain and a human homolog (CDC5L) of the fission yeast protein cdc5, which is required for G(2)/M progression and pre-mRNA splicing. CDC5L and NIPP1 co-localized in nuclear speckles in COS-1 cells. Furthermore, an interaction between CDC5L, NIPP1, and PP1 in rat liver nuclear extracts could be demonstrated by co-immunoprecipitation and/or co-purification experiments. The binding of the FHA domain of NIPP1 to CDC5L was dependent on the phosphorylation of CDC5L, e.g. by cyclin E-Cdk2. When expressed in COS-1 or HeLa cells, the FHA domain of NIPP1 did not affect the number of cells in the G(2)/M transition. However, the FHA domain blocked beta-globin pre-mRNA splicing in nuclear extracts. A mutation in the FHA domain that abolished its interaction with CDC5L also canceled its anti-splicing effects. We suggest that NIPP1 either targets CDC5L or an associated protein for dephosphorylation by PP1 or serves as an anchor for both PP1 and CDC5L.     

Direct interaction between hnRNP‐M and CDC5L/PLRG1 proteins affects alternative splice site choice

Heterogeneous nuclear ribonucleoprotein‐M (hnRNP‐M) is an abundant nuclear protein that binds to pre‐mRNA and is a component of the spliceosome complex. A direct interaction was detected in vivo between hnRNP‐M and the human spliceosome proteins cell division cycle 5‐like (CDC5L) and pleiotropic regulator 1 (PLRG1) that was inhibited during the heat‐shock stress response. A central region in hnRNP‐M is required for interaction with CDC5L/PLRG1. hnRNP‐M affects both 5′ and 3′ alternative splice site choices, and an hnRNP‐M mutant lacking the CDC5L/PLRG1 interaction domain is unable to modulate alternative splicing of an adeno‐E1A mini‐gene substrate.     

The carboxy terminal WD domain of the pre-mRNA splicing factor Prp17p is critical for function

In Saccharomyces cerevisiae, Prp17p is required for the efficient completion of the second step of pre-mRNA splicing. The function and interacting factors for this protein have not been elucidated. We have performed a mutational analysis of yPrp17p to identify protein domains critical for function. A series of deletions were made throughout the region spanning the N-terminal 158 amino acids of the protein, which do not contain any identified structural motifs. The C-terminal portion (amino acids 160-455) contains a WD domain containing seven WD repeats. We determined that a minimal functional Prp17p consists of the WD domain and 40 amino acids N-terminal to it. We generated a three-dimensional model of the WD repeats in Prp17p based on the crystal structure of the beta-transducin WD domain. This model was used to identify potentially important amino acids for in vivo functional characterization. Through analysis of mutations in four different loops of Prp17p that lie between beta strands in the WD repeats, we have identified four amino acids, 235TETG238, that are critical for function. These amino acids are predicted to be surface exposed and may be involved in interactions that are important for splicing. Temperature-sensitive prp17 alleles with mutations of these four amino acids are defective for the second step of splicing and are synthetically lethal with a U5 snRNA loop I mutation, which is also required for the second step of splicing. These data reinforce the functional significance of this region within the WD domain of Prp17p in the second step of splicing.     

BCAS2 is essential for Drosophila viability and functions in pre-mRNA splicing

Here, we show that dBCAS2 (CG4980, human Breast Carcinoma Amplified Sequence 2 ortholog) is essential for the viability of Drosophila melanogaster. We find that ubiquitous or tissue-specific depletion of dBCAS2 leads to larval lethality, wing deformities, impaired splicing, and apoptosis. More importantly, overexpression of hBCAS2 rescues these defects. Furthermore, the C-terminal coiled-coil domain of hBCAS2 binds directly to CDC5L and recruits hPrp19/PLRG1 to form a core complex for splicing in mammalian cells and can partially restore wing damage induced by knocking down dBCAS2 in flies. In summary, Drosophila and human BCAS2 share a similar function in RNA splicing, which affects cell viability.     

Ubiquitin-like protein Hub1 is required for pre-mRNA splicing and localization of an essential splicing factor in fission yeast

Hub1/Ubl5 is a member of the family of ubiquitin-like proteins (UBLs). The tertiary structure of Hub1 is similar to that of ubiquitin; however, it differs from known modifiers in that there is no conserved glycine residue near the C terminus which, in ubiquitin and UBLs, is required for covalent modification of target proteins. Instead, there is a conserved dityrosine motif proximal to the terminal nonconserved amino acid. In S. cerevisiae, high molecular weight adducts can be formed in vivo from Hub1, but the structure of these adducts is not known, and they could be either covalent or noncovalent. The budding yeast HUB1 gene is not essential, but Delta hub1 mutants display defects in mating. Here, we report that fission yeast hub1 is an essential gene, whose loss results in cell cycle defects and inefficient pre-mRNA splicing. A screen for Hub1 interactors identified Snu66, a component of the U4/U6.U5 tri-snRNP splicing complex. Furthermore, overexpression of Snu66 suppresses the lethality of a hub1ts mutant. In cells lacking functional hub1, the nuclear localization of Snu66 is disrupted, suggesting that an important role for Hub1 is the correct subcellular targeting of Snu66, although our data suggest that Hub1 is likely to perform other roles in splicing as well.     

Cef1p is a component of the Prp19p-associated complex and essential for pre-mRNA splicing

The Prp19p protein of the budding yeast Saccharomyces cerevisiae is an essential splicing factor and is associated with the spliceosome during the splicing reaction. We have previously shown that Prp19p is not tightly associated with small nuclear ribonucleoprotein particles but is associated with a protein complex consisting of at least eight protein components. By sequencing components of the affinity-purified complex, we have identified Cef1p as a component of the Prp19p-associated complex, Ntc85p. Cef1p could directly interact with Prp19p and was required for pre-mRNA splicing both in vivo and in vitro. The c-Myb DNA binding motif at the amino terminus of Cef1p was required for cellular growth but not for interaction of Cef1p with Prp19p or Cef1p self-interaction. We have identified a small region of 30 amino acid residues near the carboxyl terminus required for both cell viability and protein-protein interactions. Cef1p was associated with the spliceosome in the same manner as Prp19p, i.e. concomitant with or immediately after dissociation of U4. The anti-Cef1p antibody inhibited binding to the spliceosome of Cef1p, Prp19p, and at least three other components of the Prp19p-associated complex, suggesting that the Prp19p-associated complex is likely associated with the spliceosome and functions as an integral complex.     

Human splicing factor SF3a, but not SF1, is essential for pre-mRNA splicing in vivo

The three subunits of human splicing factor SF3a are essential for the formation of the functional 17S U2 snRNP and prespliceosome assembly in vitro. RNAi-mediated depletion indicates that each subunit is essential for viability of human cells. Knockdown of single subunits results in a general block in splicing strongly suggesting that SF3a is a constitutive splicing factor in vivo. In contrast, splicing of several endogenous and reporter pre-mRNAs is not affected after knockdown of SF1, which functions at the onset of spliceosome assembly in vitro and is essential for cell viability. Thus, SF1 may only be required for the splicing of a subset of pre-mRNAs. We also observe a reorganization of U2 snRNP components in SF3a-depleted cells, where U2 snRNA and U2-B' are significantly reduced in nuclear speckles and the nucleoplasm, but still present in Cajal bodies. Together with the observation that the 17S U2 snRNP cannot be detected in extracts from SF3a-depleted cells, our results provide further evidence for a function of Cajal bodies in U2 snRNP biogenesis.     

Structure of the WD40‐domain of human ATG16L1

Autophagy‐related protein ATG16L1 is a component of the mammalian ATG12～ATG5/ATG16L1 complex, which acts as E3‐ligase to catalyze lipidation of LC3 during autophagosome biogenesis. The N‐terminal part of ATG16L1 comprises the ATG5‐binding site and coiled‐coil dimerization domain, both also present in yeast ATG16 and essential for bulk and starvation induced autophagy. While absent in yeast ATG16, mammalian ATG16L1 further contains a predicted C‐terminal WD40‐domain, which has been shown to be involved in mediating interaction with diverse factors in the context of alternative functions of autophagy, such as inflammatory control and xenophagy. In this work, we provide detailed information on the domain boundaries of the WD40‐domain of human ATG16L1 and present its crystal structure at a resolution of 1.55 Å.     

SMNrp is an essential pre-mRNA splicing factor required for the formation of the mature spliceosome

SMNrp, also termed SPF30, has recently been identified in spliceosomes assembled in vitro. We have functionally characterized this protein and show that it is an essential splicing factor. We show that SMNrp is a 17S U2 snRNP-associated protein that appears in the pre-spliceosome (complex A) and the mature spliceosome (complex B) during splicing. Immunodepletion of SMNrp from nuclear extract inhibits the first step of pre-mRNA splicing by preventing the formation of complex B. Re-addition of recombinant SMNrp to immunodepleted extract reconstitutes both spliceosome formation and splicing. Mutations in two domains of SMNrp, although similarly deleterious for splicing, differed in their consequences on U2 snRNP binding, suggesting that SMNrp may also engage in interactions with splicing factors other than the U2 snRNP. In agreement with this, we present evidence for an additional interaction between SMNrp and the [U4/U6.U5] tri-snRNP. A candidate that may mediate this interaction, namely the U4/U6-90 kDa protein, has been identified. We suggest that SMNrp, as a U2 snRNP-associated protein, facilitates the recruitment of the [U4/U6.U5] tri-snRNP to the pre-spliceosome.     

Serological homologies between H1 degrees and H5 include the carboxyl-terminal domain

We have reported previously that antibodies to chicken H5 and antibodies to H1 both cross-react with mammalian H1 degree (Mura, C. V., and Stollar, B. D. (1981) J. Biol. Chem. 256, 9767-9769). The antigenic sites in H1 degree recognized by these antibodies were analyzed using immunoblotting. Peptides of H1 degree were prepared by partial digestion with acetic acid and tested for reactivity with: 1) antibodies induced by H5 alone, which reacted primarily with the central globular region of H5; 2) antibodies induced by H5 X RNA complexes, which reacted with this domain as well as the basic COOH-terminal domain; and 3) antiserum to calf thymus H1. Anti-H5 antibodies (anti-globular region) cross-reacted with H1 degree peptides that co-migrated with peptides of H5 that contain the globular region, but did not cross-react with H1. Anti-H5/RNA antibodies (anti-globular + anti-COOH-terminal) cross-reacted with these peptides and, in addition, with a lysine-rich H1 degree peptide that co-migrated with the basic COOH-terminal H5 peptide. This H1 degree peptide, but not the putative globular H1 degree peptides, was also recognized by an antiserum to calf H1 which was primarily reactive with the large, COOH-terminal N-bromosuccinimide fragment of calf H1. A weaker cross-reaction between this antiserum and the carboxyl-terminal domain of H5 could be visualized when large quantities of H5 were used in immunoblots. The results indicate that structural homologies between H5 and H1 degree extend beyond the globular region and into the lysine-rich carboxyl-terminal domain. Antigenic homologies between H1 degree and H1 are also at least partially localized in this domain. H1 degree is serologically intermediate between H5 and H1.     

A direct interaction between the Utp6 half-a-tetratricopeptide repeat domain and a specific peptide in Utp21 is essential for efficient pre-rRNA processing

The small subunit (SSU) processome is a ribosome biogenesis intermediate that assembles from its subcomplexes onto the pre-18S rRNA with yet unknown order and structure. Here, we investigate the architecture of the UtpB subcomplex of the SSU processome, focusing on the interaction between the half-a-tetratricopeptide repeat (HAT) domain of Utp6 and a specific peptide in Utp21. We present a comprehensive map of the interactions within the UtpB subcomplex and further show that the N-terminal domain of Utp6 interacts with Utp18 while the HAT domain interacts with Utp21. Using a panel of point and deletion mutants of Utp6, we show that an intact HAT domain is essential for efficient pre-rRNA processing and cell growth. Further investigation of the Utp6-Utp21 interaction using both genetic and biophysical methods shows that the HAT domain binds a specific peptide ligand in Utp21, the first example of a HAT domain peptide ligand, with a dissociation constant of 10 μM.     

A conditional U5 snRNA mutation affecting pre-mRNA splicing and nuclear pre-mRNA retention identifies SSD1/SRK1 as a general splicing mutant suppressor.

A combination of point mutations disrupting both stem 1 and stem 2 of U5 snRNA (U5AI) was found to confer a thermosensitive phenotype in vivo. In a strain expressing U5AI, pre-mRNA splicing was blocked before the first step through an inability of the mutant U5 snRNA to efficiently associate with the U4/U6 di-snRNP. Formation of early splicing complexes was not affected in extracts prepared from U5 snRNA mutant cells, while the capacity of these extracts to splice a pre-mRNA in vitro was greatly diminished. In addition, significant levels of a translation product derived from intron containing pre-mRNAs could be detected in vivo. The SSD1/SRK1 gene was identified as a multi-copy suppressor of the U5AI snRNA mutant. Single copy expression of SSD1/SRK1 was sufficient to suppress the thermosensitive phenotype, and high copy expression partially suppressed the splicing and U4/U6.U5 tri-snRNP assembly pheno-types. SSD1/SRK1 also suppressed thermosensitive mutations in the Prp18p and U1-70K proteins, while inhibiting growth of the cold sensitive U1-4U snRNA mutant at 30 degrees C. Thus we have identified SSD1/SRK1 as a general suppressor of splicing mutants.     

Unconventional autophagy mediated by the WD40 domain of ATG16L1 is derailed by the T300A Crohn disease risk polymorphism

A coding polymorphism of the critical autophagic effector ATG16L1 (T300A) increases the risk of Crohn disease, but how this mutation influences the function of ATG16L1 has remained unclear. In a recent report, we showed that the A300 allele alters the ability of the C-terminal WD40 domain of ATG16L1 to interact with proteins containing a specific amino acid motif able to recognize this region. This defect impairs the capacity of the motif-containing transmembrane molecule TMEM59 to induce the unconventional autophagic labeling of the same single-membrane vesicles where this protein is located. Such alteration derails the intracellular trafficking of TMEM59 and the xenophagic response against bacterial infection. In contrast, canonical autophagy remains unaffected in the presence of ATG16L1^T300A. These data argue that the T300A polymorphism impairs the unconventional autophagic activities carried out by the WD40 domain, a region of ATG16L1 whose function has remained poorly understood.