Mapping the binding site of snurportin 1 on native U1 snRNP by cross-linking and mass spectrometry

Mass spectrometry allows the elucidation of molecular details of the interaction domains of the individual components in macromolecular complexes subsequent to cross-linking of the individual components. Here, we applied chemical and UV cross-linking combined with tandem mass-spectrometric analysis to identify contact sites of the nuclear import adaptor snurportin 1 to the small ribonucleoprotein particle U1 snRNP in addition to the known interaction of m₃G cap and snurportin 1. We were able to define previously unknown sites of protein–protein and protein–RNA interactions on the molecular level within U1 snRNP. We show that snurportin 1 interacts with its central m₃G-cap-binding domain with Sm proteins and with its extreme C-terminus with stem-loop III of U1 snRNA. The crosslinking data support the idea of a larger interaction area between snurportin 1 and U snRNPs and the contact sites identified prove useful for modeling the spatial arrangement of snurportin 1 domains when bound to U1 snRNP. Moreover, this suggests a functional nuclear import complex that assembles around the m₃G cap and the Sm proteins only when the Sm proteins are bound and arranged in the proper orientation to the cognate Sm site in U snRNA.

'Proteomic basics--sample preparation and separation': the 1st European Summer School in Kloster Neustift, 12-18 August, 2007 Brixen/Bressanone, South Tyrol, Italy

Proteomics is rapidly developing into a routine approach for protein analysis in many laboratories. The series of European-wide Summer Schools 'Proteomics Basics' (http://www.proteomic-basics.eu/) aims at teaching of comprehensive knowledge in proteomics research and applied technologies for master and graduate students and postdocs currently moving into the field of proteomic research. In the next 3 years the series will cover the theoretical basis of the fundamental topics in the various areas of proteomic analysis, i.e. sample preparation and handling, mass spectrometry, post-translational modifications and quantitation given by leading experts in the field. This summer school series embodies a unique advantage in comparison with conventional scientific meetings and university curricula: internationally renowned experts will give a detailed perspective view of the fundamentals of their particular proteome research area, something which is usually not encountered at conferences and congresses. Here, we give a report on the first European Summer School 'Sample Preparation and Handling' within the series 'Proteomic Basics' that was held at the monastery in Neustift close to Bressanone/Brixen, Italy from August 12 to 18, 2007.

Analyzing RNA-protein crosslinking sites in unlabeled ribonucleoprotein complexes by mass spectrometry

Mass spectrometry is a powerful tool for the analysis of biomolecules, proteins, nucleic acids, carbohydrates, lipids. In combination with genome sequences that are available in the databases, it has proven to be the most straightforward and sensitive technique for the sequence analysis and hence the identification of protein components in the cells, their (post)translational modifications, and their relative and absolute abundance. In addition, mass spectrometric methods are successfully applied for the structural analysis of biomolecules (i.e., deciphering molecule-ligand interactions and spatial quartenary arrangements of molecule complexes). We describe a methodology for the mass spectrometric analysis of protein-RNA contact sites in purified ribonucleoprotein (RNP) particles. The method comprises ultraviolet (UV) crosslinking of proteins to RNA, hydrolysis of the protein and RNA moieties, isolation of cross-linked peptide-RNA oligonucleotides, MALDI (matrix-assisted laser desorption/ionization) mass spectrometry of the isolated conjugates to determine the sequence of the crosslinked peptide and RNA part. The utility of this methodology is demonstrated on crosslinks isolated from UV-irradiated spliceosomal particles; these were [15.5 K-61 K-U4atac] small nuclear ribonucleoprotein (snRNP) particles prepared by reconstitution in vitro and U1 snRNP particles purified from HeLa cells.

Improved identification of enriched peptide RNA cross-links from ribonucleoprotein particles (RNPs) by mass spectrometry

Direct UV cross-linking combined with mass spectrometry (MS) is a powerful tool to identify hitherto non-characterized protein-RNA contact sites in native ribonucleoprotein particles (RNPs) such as the spliceosome. Identification of contact sites after cross-linking is restricted by: (i) the relatively low cross-linking yield and (ii) the amount of starting material available for cross-linking studies. Therefore, the most critical step in such analyses is the extensive purification of the cross-linked peptide-RNA heteroconjugates from the excess of non-crosslinked material before MS analysis. Here, we describe a strategy that combines small-scale reversed-phase liquid chromatography (RP-HPLC) of UV-irradiated and hydrolyzed RNPs, immobilized metal-ion affinity chromatography (IMAC) to enrich cross-linked species and their analysis by matrix-assisted laser desorption/ionisation (MALDI) MS(/MS). In cases where no MS/MS analysis can be performed, treatment of the enriched fractions with alkaline phosphatase leads to unambiguous identification of the cross-linked species. We demonstrate the feasibility of this strategy by MS analysis of enriched peptide-RNA cross-links from UV-irradiated reconstituted [15.5K-61K-U4atac snRNA] snRNPs and native U1 snRNPs. Applying our approach to a partial complex of U2 snRNP allowed us to identify the contact site between the U2 snRNP-specific protein p14/SF3b14a and the branch-site interacting region (BSiR) of U2 snRNA.

Detection of protein-RNA crosslinks by NanoLC-ESI-MS/MS using precursor ion scanning and multiple reaction monitoring (MRM) experiments

Protein-RNA interactions within ribonucleoprotein particles (RNPs) can be investigated by UV-induced crosslinking of proteins to their cognate RNAs and subsequent isolation and mass-spectrometric analysis of crosslinked peptide-RNA oligonucleotides. Because of the low crosslinking yield, a major challenge in protein-RNA UV crosslinking is the detection of the crosslinked species over the excess of non-crosslinked material, especially when complex systems (native RNPs) are investigated. Here, we applied a novel approach that uses on-line nanoLC-ESI-MS/MS to detect and subsequently sequence peptide-RNA oligonucleotide crosslinks from crude mixtures. To detect the crosslinks we made use of features shared by crosslinks and phosphopeptides, that is, the phosphate groups that both carry. A precursor ion scan for m/z 79 (negative-ion mode, -ve) is applied to selectively detect analytes bearing the phosphate-containing species (i.e., residual non-crosslinked RNA and peptide-RNA crosslinks) from crude mixtures and to determine their exact m/z values. On this basis, a multiple reaction monitoring (MRM) experiment monitors the expected decomposition from the different precursor charge states of the putative crosslinks to one of the four possible RNA nucleobases [m/z 112, 113, 136, 152 (positive-ion mode, +ve)]. On detection, a high-quality MS/MS is triggered to establish the structure of the crosslink. In a feasibility study, we detected and subsequently sequenced peptide-RNA crosslinks obtained by UV-irradiation of (1) native U1 snRNPs and (2) [15.5K-61K-U4atac] snRNPs prepared by reconstitution in vitro. MRM-triggered collision-induced dissociation (CID) MS/MS enabled us to obtain sequence information about the crosslinked peptide and RNA moiety.

Complete MALDI-ToF MS analysis of cross-linked peptide-RNA oligonucleotides derived from nonlabeled UV-irradiated ribonucleoprotein particles

Protein-RNA cross-linking combined with mass spectrometry is a powerful tool to elucidate hitherto non-characterized protein-RNA contacts in ribonucleoprotein particles, as, for example, within spliceosomes. Here, we describe an improved methodology for the sequence analysis of purified peptide-RNA oligonucleotide cross-links that is based solely on MALDI-ToF mass spectrometry. The utility of this methodology is demonstrated on cross-links isolated from UV-irradiated spliceosomal particles; these were (1) [15.5K-61 K-U4 atac] small nuclear ribonucleoprotein (snRNP) particles prepared by reconstitution in vitro, and (2) U1 snRNP particles purified from HeLa cells. We show that the use of 2',4',6'-trihydroxyacetophenone (THAP) as MALDI matrix allows analysis of cross-linked peptide-RNA oligonucleotides in the reflectron mode at high resolution, enabling sufficient accuracy to assign unambiguously cross-linked RNA sequences. Most important, post-source decay (PSD) analysis under these conditions was successfully applied to obtain sequence information about the cross-linked peptide and RNA moieties within a single spectrum, including the identification of the actual cross-linking site. Thus, in U4 atac snRNA we identified His 270 in the spliceosomal U4/U6 snRNP-specific protein 61 K (hPrp31p) cross-linked to U 44; in the U1 snRNP we show that Leu175 of the U1 snRNP-specific 70K protein is cross-linked to U 30 of U1 snRNA. This type of analysis is applicable to any type of RNP complex and may be expected to pave the way for the further analysis of protein-RNA complexes in much lower abundance and/or of cross-links that are obtained in low yield.

Detecting protein-induced folding of the U4 snRNA kink-turn by single-molecule multiparameter FRET measurements

The kink-turn (k-turn), a new RNA structural motif found in the spliceosome and the ribosome, serves as a specific protein recognition element and as a structural building block. While the structure of the spliceosomal U4 snRNA k-turn/15.5K complex is known from a crystal structure, it is unclear whether the k-turn also exists in this folded conformation in the free U4 snRNA. Thus, we investigated the U4 snRNA k-turn by single-molecule FRET measurements in the absence and presence of the 15.5K protein and its dependence on the Na(+) and Mg(2+) ion concentration. We show that the unfolded U4 snRNA k-turn introduces a kink of 85 degrees +/- 15 degrees in an RNA double helix. While Na(+) and Mg(2+) ions induce this more open conformation of the k-turn, binding of the 15.5K protein was found to induce the tightly kinked conformation in the RNA that increases the kink to 52 degrees +/- 15 degrees . By comparison of the measured FRET distances with a computer-modeled structure, we show that this strong kink is due to the k-turn motif adopting its folded conformation. Thus, in the free U4 snRNA, the k-turn exists only in an unfolded conformation, and its folding is induced by binding of the 15.5K protein.

Fragile X mental retardation protein (FMRP) binds specifically to the brain cytoplasmic RNAs BC1/BC200 via a novel RNA-binding motif

Fragile X mental retardation protein (FMRP), the protein responsible for the fragile X syndrome, is an RNA-binding protein involved in localization and translation of neuronal mRNAs. One of the RNAs known to interact with FMRP is the dendritic non-translatable brain cytoplasmic RNA 1 BC1 RNA that works as an adaptor molecule linking FMRP and some of its regulated mRNAs. Here, we showed that the N terminus of FMRP binds strongly and specifically to BC1 and to its potential human analog BC200. This region does not contain a motif known to specifically recognize RNA and thus constitutes a new RNA-binding motif. We further demonstrated that FMRP recognition involves the 5' stem loop of BC1 and that this is the region that exhibits complementarity to FMRP target mRNAs, raising the possibility that FMRP plays a direct role in BC1/mRNA annealing.