The spliceosomal PRP19 complex of trypanosomes.

In trypanosomes, mRNAs are processed by spliced leader (SL) trans splicing, in which a capped SL, derived from SL RNA, is spliced onto the 5' end of each mRNA. This process is mediated by the spliceosome, a large and dynamic RNA-protein machinery consisting of small nuclear ribonucleoproteins (snRNPs) and non-snRNP proteins. Due to early evolutionary divergence, the amino acid sequences of trypanosome splicing factors exhibit limited similarity to those of their eukaryotic orthologs making their bioinformatic identification challenging. Most of the ~ 60 protein components that have been characterized thus far are snRNP proteins because, in contrast to individual snRNPs, purification of intact spliceosomes has not been achieved yet. Here, we characterize the non-snRNP PRP19 complex of Trypanosoma brucei. We identified a complex that contained the core subunits PRP19, CDC5, PRL1, and SPF27, as well as PRP17, SKIP and PPIL1. Three of these proteins were newly annotated. The PRP19 complex was associated primarily with the activated spliceosome and, accordingly, SPF27 silencing blocked the first splicing step. Interestingly, SPF27 silencing caused an accumulation of SL RNA with a hypomethylated cap that closely resembled the defect observed previously upon depletion of the cyclin-dependent kinase CRK9, indicating that both proteins may function in spliceosome activation.

An automated in-gel digestion/iTRAQ-labeling workflow for robust quantification of gel-separated proteins.

Simple protein separation by 1DE is a widely used method to reduce sample complexity and to prepare proteins for mass spectrometric identification via in-gel digestion. While several automated solutions are available for in-gel digestion particularly of small cylindric gel plugs derived from 2D gels, the processing of larger 1D gel-derived gel bands with liquid handling work stations is less well established in the field. Here, we introduce a digestion device tailored to this purpose and validate its performance in comparison to manual in-gel digestion. For relative quantification purposes, we extend the in-gel digestion procedure by iTRAQ labeling of the tryptic peptides and show that automation of the entire workflow results in robust quantification of proteins from samples of different complexity and dynamic range. We conclude that automation improves accuracy and reproducibility of our iTRAQ workflow as it minimizes the variability in both, digestion and labeling efficiency, the two major causes of irreproducible results in chemical labeling approaches.

Composition of yeast snRNPs and snoRNPs in the absence of trimethylguanosine caps reveals nuclear cap binding protein as a gained U1 component implicated in the cold-sensitivity of tgs1Δ cells.

Small nuclear and nucleolar RNAs that program pre-mRNA splicing and rRNA processing have a signature 5'-trimethylguanosine (TMG) cap. Whereas the mechanism of TMG synthesis by Tgs1 methyltransferase has been elucidated, we know little about whether or how RNP biogenesis, structure and function are perturbed when TMG caps are missing. Here, we analyzed RNPs isolated by tandem-affinity purification from TGS1 and tgs1Δ yeast strains. The protein and U-RNA contents of total SmB-containing RNPs were similar. Finer analysis revealed stoichiometric association of the nuclear cap-binding protein (CBP) subunits Sto1 and Cbc2 with otherwise intact Mud1- and Nam8-containing U1 snRNPs from tgs1Δ cells. CBP was not comparably enriched in Lea1-containing U2 snRNPs from tgs1Δ cells. Moreover, CBP was not associated with mature Nop58-containing C/D snoRNPs or mature Cbf5- and Gar1-containing H/ACA snoRNPs from tgs1Δ cells. The protein composition and association of C/D snoRNPs with the small subunit (SSU) processosome were not grossly affected by absence of TMG caps, nor was the composition of H/ACA snoRNPs. The cold-sensitive (cs) growth defect of tgs1Δ yeast cells could be suppressed by mutating the cap-binding pocket of Cbc2, suggesting that ectopic CBP binding to the exposed U1 m(7)G cap in tgs1Δ cells (not lack of TMG caps per se) underlies the cs phenotype.

Reconstitution of both steps of Saccharomyces cerevisiae splicing with purified spliceosomal components.

The spliceosome is a ribonucleoprotein machine that removes introns from pre-mRNA in a two-step reaction. To investigate the catalytic steps of splicing, we established an in vitro splicing complementation system. Spliceosomes stalled before step 1 of this process were purified to near-homogeneity from a temperature-sensitive mutant of the RNA helicase Prp2, compositionally defined, and shown to catalyze efficient step 1 when supplemented with recombinant Prp2, Spp2 and Cwc25, thereby demonstrating that Cwc25 has a previously unknown role in promoting step 1. Step 2 catalysis additionally required Prp16, Slu7, Prp18 and Prp22. Our data further suggest that Prp2 facilitates catalytic activation by remodeling the spliceosome, including destabilizing the SF3a and SF3b proteins, likely exposing the branch site before step 1. Remodeling by Prp2 was confirmed by negative stain EM and image processing. This system allows future mechanistic analyses of spliceosome activation and catalysis.

Detection and localization of small nuclear ribonucleoproteins (snRNPs) in trypanosomatids using anti-m3G antibodies.

This work reports for the first time the identification and immunolocalization, by confocal and conventional indirect immunofluorescence, of m3G epitopes present in ribonucleoproteins of the following trypanosomatids: Trypanosoma cruzi epimastigotes of three different strains, Blastocrithidia ssp., and Leishmania major promastigotes. The identity of these epitopes and hence the specificity of the anti-m3G monoclonal antibody were ascertained through competition reaction with 7-methylguanosine that blocks the Ig binding sites, abolishing the fluorescence in all the parasites tested and showing a specific perinuclear localization of the snRNPs, which suggests their nuclear reimport in the parasites. Using an immunoprecipitation technique, it was also possible to confirm the presence of the trimethylguanosine epitopes in trypanosomatids.

In vitro reconstitution and affinity purification of catalytically active archaeal box C/D sRNP complexes.

Archaeal box C/D RNAs guide the site-specific 2'-O-methylation of target nucleotides in ribosomal RNAs and tRNAs. In vitro reconstitution of catalytically active box C/D RNPs by use of in vitro transcribed box C/D RNAs and recombinant core proteins provides model complexes for the study of box C/D RNP assembly, structure, and function. Described here are protocols for assembly of the archaeal box C/D RNP and assessment of its nucleotide modification activity. Also presented is a novel affinity purification scheme that uses differentially tagged core proteins and a sequential three-step affinity selection protocol that yields fully assembled and catalytically active box C/D RNPs. This affinity selection protocol can provide highly purified complex in sufficient quantities not only for biochemical analyses but also for biophysical approaches such as cryoelectron microscopy and X-ray crystallography.

Dynamic remodelling of human 7SK snRNP controls the nuclear level of active P-TEFb.

The 7SK small nuclear RNA (snRNA) regulates RNA polymerase II transcription elongation by controlling the protein kinase activity of the positive transcription elongation factor b (P-TEFb). In cooperation with HEXIM1, the 7SK snRNA sequesters P-TEFb into the kinase-inactive 7SK/HEXIM1/P-TEFb small nuclear ribonucleoprotein (snRNP), and thereby, controls the nuclear level of active P-TEFb. Here, we report that a fraction of HeLa 7SK snRNA that is not involved in 7SK/HEXIM1/P-TEFb formation, specifically interacts with RNA helicase A (RHA), heterogeneous nuclear ribonucleoprotein A1 (hnRNP), A2/B1, R and Q proteins. Inhibition of cellular transcription induces disassembly of 7SK/HEXIM1/P-TEFb and at the same time, increases the level of 7SK snRNPs containing RHA, hnRNP A1, A2/B1, R and Q. Removal of transcription inhibitors restores the original levels of the 7SK/HEXIM1/P-TEFb and '7SK/hnRNP' complexes. 7SK/HEXIM1/P-TEFb snRNPs containing mutant 7SK RNAs lacking the capacity for binding hnRNP A1, A2, R and Q are resistant to stress-induced disassembly, indicating that recruitment of the novel 7SK snRNP proteins is essential for disruption of 7SK/HEXIM1/P-TEFb. Thus, we propose that the nuclear level of active P-TEFb is controlled by dynamic and reversible remodelling of 7SK snRNP.

Proteomic analysis of the U1 snRNP of Schizosaccharomyces pombe reveals three essential organism-specific proteins.

Characterization of spliceosomal complexes in the fission yeast Schizosaccharomyces pombe revealed particles sedimenting in the range of 30-60S, exclusively containing U1 snRNA. Here, we report the tandem affinity purification (TAP) of U1-specific protein complexes. The components of the complexes were identified using (LC-MS/MS) mass spectrometry. The fission yeast U1 snRNP contains 16 proteins, including the 7 Sm snRNP core proteins. In both fission and budding yeast, the U1 snRNP contains 9 and 10 U1 specific proteins, respectively, whereas the U1 particle found in mammalian cells contains only 3. Among the U1-specific proteins in S. pombe, three are homolog to the mammalian and six to the budding yeast Saccharomyces cerevisiae U1-specific proteins, whereas three, called U1H, U1J and U1L, are proteins specific to S. pombe. Furthermore, we demonstrate that the homolog of U1-70K and the three proteins specific to S. pombe are essential for growth. We will discuss the differences between the U1 snRNPs with respect to the organism-specific proteins found in the two yeasts and the resulting effect it has on pre-mRNA splicing.

Functional spliceosomal A complexes can be assembled in vitro in the absence of a penta-snRNP.

Two different models currently exist for the assembly pathway of the spliceosome, namely, the traditional model, in which spliceosomal snRNPs associate in a stepwise, ordered manner with the pre-mRNA, and the holospliceosome model, in which all spliceosomal snRNPs preassemble into a penta-snRNP complex. Here we have tested whether the spliceosomal A complex, which contains solely U1 and U2 snRNPs bound to pre-mRNA, is a functional, bona fide assembly intermediate. Significantly, A complexes affinity-purified from nuclear extract depleted of U4/U6 snRNPs (and thus unable to form a penta-snRNP) supported pre-mRNA splicing in nuclear extract depleted of U2 snRNPs, whereas naked pre-mRNA did not. Mixing experiments with purified A complexes and naked pre-mRNA additionally confirmed that under these conditions, A complexes do not form de novo. Thus, our studies demonstrate that holospliceosome formation is not a prerequisite for generating catalytically active spliceosomes and that, at least in vitro, the U1 and U2 snRNPs can functionally associate with the pre-mRNA, prior to and independent of the tri-snRNP. The ability to isolate functional spliceosomal A complexes paves the way to study in detail subsequent spliceosome assembly steps using purified components.

Reconstitution of two recombinant LSm protein complexes reveals aspects of their architecture, assembly, and function.

Sm and Sm-like (LSm) proteins form complexes engaging in various RNA-processing events. Composition and architecture of the complexes determine their intracellular distribution, RNA targets, and function. We have reconstituted the human LSm1-7 and LSm2-8 complexes from their constituent components in vitro. Based on the assembly pathway of the canonical Sm core domain, we used heterodimeric and heterotrimeric sub-complexes to assemble LSm1-7 and LSm2-8. Isolated sub-complexes form ring-like higher order structures. LSm1-7 is assembled and stable in the absence of RNA. LSm1-7 forms ring-like structures very similar to LSm2-8 at the EM level. Our in vitro reconstitution results illustrate likely features of the LSm complex assembly pathway. We prove the complexes to be functional both in an RNA bandshift and an in vivo cellular transport assay.

Pre-mRNA splicing: awash in a sea of proteins.

What's in a spliceosome? More than we ever imagined, according to recent reports employing proteomics techniques to analyze this multi-megadalton machine. As of 1999, around 100 splicing factors were identified (Burge et al., 1999); however, that number has now nearly doubled due primarily to improved purification of spliceosomes coupled with advances in mass spectrometry analyses of complex mixtures. Gratifyingly, most of the previously identified splicing factors were found in the recent mass spec studies. Nonetheless, the number of new proteins emerging with no prior connection to splicing was surprising. Without functional validation, it would be premature to label these proteins as bona fide splicing factors. Yet many were identified multiple times in complexes purified under diverse conditions or from different organisms. Another recurring theme regards the dynamic nature of spliceosomal complexes, which may be even more intricate than previously thought.

Essential role for the SMN complex in the specificity of snRNP assembly.

The Survival of Motor Neurons (SMN) protein, the product of the spinal muscular atrophy-determining gene, is part of a large macromolecular complex (SMN complex) that functions in the assembly of spliceosomal small nuclear ribonucleoproteins (snRNPs). Using cell extracts and purified components, we demonstrated that the SMN complex is necessary and sufficient to mediate the ATP-dependent assembly of the core of seven Sm proteins on uridine-rich, small nuclear ribonucleic acids (U snRNAs). In vitro experiments revealed strict requirements for ordered binding of the Sm proteins and the U snRNAs to the SMN complex. Importantly, the SMN complex is necessary to ensure that Sm cores assemble only on correct RNA targets and prevent their otherwise promiscuous association with other RNAs. Thus, the SMN complex functions as a specificity factor essential for the efficient assembly of Sm proteins on U snRNAs and likely protects cells from illicit, and potentially deleterious, nonspecific binding of Sm proteins to RNAs.

Nuclear estrogen receptor II (nER-II) is involved in the estrogen-dependent ribonucleoprotein transport in the goat uterus: II. Isolation and characterization of three small nuclear ribonucleoprotein proteins which bind to nER-II.

Three proteins of a goat uterine small nuclear ribonucleoprotein (snRNP) fraction, which bind to nuclear estrogen receptor-II (nER-II) have been isolated and purified. These are the p32, p55, and p60 of which p32 is the major nER-II binding protein. Indirect evidence reveals that p32 binds to the nuclear export signal (NES) on the nER-II. nER-II is a snRNA binding protein while p32 does not bind to the RNA. nER-II along with p32 and p55 form an effective Mg(++)ATPase complex, the activation of which appears to be the immediate reason behind the RNP exit from the nuclei following estradiol exposure. The three nER-II binding proteins bind to the nuclear pore complex; nER-II does not possess this property.

Casein is an essential cofactor in autoantibody reactivity directed against the C-terminal SmD1 peptide AA 83-119 in systemic lupus erythematosus.

The C-terminal peptide SmD1(83-119) has been identified as an important autoantigen in systemic lupus erythematosus (SLE). ELISA studies have shown that roughly 70% of all sera from patients with SLE react with this peptide. Previous findings revealed that the addition of blocking agents and sample dilution buffers influences the discrimination between positive and negative anti-SmD1(83-119) sera in SLE. The aim of the present study was to identify possible cofactors in the anti-SmD1(83-119) reactivity. We therefore tested SLE sera (n=6) for anti-SmD1(83-119) reactivity by ELISA and analysed the effects of different blocking agents (1% skim milk, 1% gelatin, and 1% BSA). In our investigation, lipids were extracted from skim milk using dichlomethane, and the putative fraction was tested to assess the assay's ability to discriminate between positive and negative sera. The effects of enzymatic digestion by casein were analyzed, and different concentrations of casein were used to determine the role of this protein in the detection of anti-SmD1(83-119) antibodies by ELISA. Furthermore, rabbits were immunized with SmD1(83-119) adsorbed to casein and control proteins. One percent skim milk was the most effective blocking agent and sample dilution buffer for the discrimination between positive and negative sera. As demonstrated by SDS electrophoresis, the discriminative capacity was influenced by enzymatic digestion of skim milk proteins, but not by lipid extraction. Differences in anti-SmD1(83-119) reactivity upon variation of the casein concentration suggest that the protein plays a significant role in the detection of anti-SmD1(83-119) antibodies. However, our immunisation studies did not show any effect of casein on anti-SmD1(83-119) reactivity, suggesting that it has no immunogenic effect on the anti-SmD1(83-119) response. In conclusion, casein seems to be an important cofactor in autoantibody reactivity directed against the C-terminal SmD1(83-119) peptide and probably functions by changing the conformation of the peptide's critical epitope.

Biochemical and genetic analyses of the U5, U6, and U4/U6 x U5 small nuclear ribonucleoproteins from Saccharomyces cerevisiae.

We have purified the yeast U5 and U6 pre-mRNA splicing small nuclear ribonucleoproteins (snRNPs) by affinity chromatography and analyzed the associated polypeptides by mass spectrometry. The yeast U5 snRNP is composed of the two variants of U5 snRNA, six U5-specific proteins and the 7 proteins of the canonical Sm core. The U6 snRNP is composed of the U6 snRNA, Prp24, and the 7 Sm-Like (LSM) proteins. Surprisingly, the yeast DEAD-box helicase-like protein Prp28 is stably associated with the U5 snRNP, yet is absent from the purified U4/U6 x U5 snRNP. A novel yeast U5 and four novel yeast U4/U6 x U5 snRNP polypeptides were characterized by genetic and biochemical means to demonstrate their involvement in the pre-mRNA splicing reaction. We also show that, unlike the human tri-snRNP, the yeast tri-snRNP dissociated upon addition of ATP or dATP.

Nuclear eukaryotic initiation factor 4E (eIF4E) colocalizes with splicing factors in speckles.

The eukaryotic initiation factor 4E (eIF4E) plays a pivotal role in the control of protein synthesis. eIF4E binds to the mRNA 5' cap structure, m(7)GpppN (where N is any nucleotide) and promotes ribosome binding to the mRNA. It was previously shown that a fraction of eIF4E localizes to the nucleus (Lejbkowicz, F., C. Goyer, A. Darveau, S. Neron, R. Lemieux, and N. Sonenberg. 1992. Proc. Natl. Acad. Sci. USA. 89:9612-9616). Here, we show that the nuclear eIF4E is present throughout the nucleoplasm, but is concentrated in speckled regions. Double label immunofluorescence confocal microscopy shows that eIF4E colocalizes with Sm and U1snRNP. We also demonstrate that eIF4E is specifically released from the speckles by the cap analogue m(7)GpppG in a cell permeabilization assay. However, eIF4E is not released from the speckles by RNase A treatment, suggesting that retention of eIF4E in the speckles is not RNA-mediated. 5,6-dichloro-1-beta-d-ribofuranosylbenzimidazole (DRB) treatment of cells causes the condensation of eIF4E nuclear speckles. In addition, overexpression of the dual specificity kinase, Clk/Sty, but not of the catalytically inactive form, results in the dispersion of eIF4E nuclear speckles.

Resolution of the mammalian E complex and the ATP-dependent spliceosomal complexes on native agarose mini-gels.

A great deal of progress in elucidating the mechanisms of spliceosome assembly has been achieved by analyzing the A, B, and C spliceosomal complexes on native polyacrylamide gels. In contrast, progress in understanding the earliest spliceosomal complex E has been hampered because this complex dissociates on native gels and is difficult to detect by other methods. Here we report conditions for resolving the spliceosomal complex E using a native horizontal agarose mini-gel system. This system also provides a simple alternative to polyacrylamide gels for resolving the ATP-dependent spliceosomal complexes.

StreptoTag: a novel method for the isolation of RNA-binding proteins.

We describe a fast and simple one-step affinity-purification method for the isolation of specific RNA-binding proteins. An in vitro-transcribed hybrid RNA consisting of an aptamer sequence with high binding specificity to the antibiotic streptomycin and a putative protein-binding RNA sequence is incubated with crude extract. After complex formation, the sample is applied to an affinity column containing streptomycin immobilized to Sepharose. The binding of the in vitro-assembled RNA-protein complex to streptomycin-Sepharose is mediated by the aptamer RNA and the specifically bound proteins are recovered from the affinity matrix by elution with the antibiotic. Employing two well-characterized RNA-protein interactions, we tested the performance of this new method. The spliceosomal U1A protein and the bacteriophage MS2 coat protein could be isolated via their appropriate RNA motif containing hybrid RNA from crude yeast extracts in high yield and purity after only one round of affinity purification. As the purification principle is independent of the extract source, this new affinity chromatography strategy that makes use of an in vitro-selected antibiotic-binding RNA as a tag, "StreptoTag," should be applicable to extracts from other organisms as well. Therefore, we propose StreptoTag to be a versatile tool for the isolation of unknown RNA-binding proteins.