An unusual RNA recognition motif acts as a scaffold for multiple proteins in the pre-mRNA retention and splicing complex.

The yeast pre-mRNA retention and splicing complex counteracts the escape of unspliced pre-mRNAs from the nucleus and activates splicing of a subset of Mer1p-dependent genes. A homologous complex is present in activated human spliceosomes. In many components of the spliceosome, RNA recognition motifs (RRMs) serve as versatile protein-RNA or protein-protein interaction platforms. Here, we show that in the retention and splicing complex, an atypical RRM of the Snu17p (small nuclear ribonucleoprotein-associated protein 17) subunit acts as a scaffold that organizes the other two constituents, Bud13p (bud site selection 13) and Pml1p (pre-mRNA leakage 1). GST pull-down experiments and size exclusion chromatography revealed that Snu17p constitutes the central platform of the complex, whereas Bud13p and Pml1p do not interact with each other. Fluorimetric structure probing showed the entire Bud13p and the N-terminal third of Pml1p to be natively disordered in isolation. Mutational analysis and tryptophan fluorescence confirmed that a conserved tryptophan-containing motif in the C terminus of Bud13p binds to the core RRM of Snu17p, whereas a different interaction surface encompassing a C-terminal extension of the Snu17p RRM is required to bind an N-terminal peptide of Pml1p. Isothermal titration calorimetry revealed 1: 1 interaction stoichiometries, large negative binding entropies, and dissociation constants in the low nanomolar and micromolar ranges for the Snu17p-Bud13p and the Snu17p-Pml1p interactions, respectively. Our results demonstrate that the noncanonical Snu17p RRM concomitantly binds multiple ligand proteins via short, intrinsically unstructured peptide epitopes and thereby acts as a platform that displays functional modules of the ligands, such as a forkhead-associated domain of Pml1p and a conserved polylysine motif of Bud13p.Max-Planck-Societ

Crystal structure of the Pml1p subunit of the yeast precursor mRNA retention and splicing complex.

The precursor mRNA retention and splicing (RES) complex mediates nuclear retention and enhances splicing of precursor mRNAs. The RES complex from yeast comprises three proteins, Snu17p, Bud13p and Pml1p. Snu17p acts as a central platform that concomitantly binds the Bud13p and Pml1p subunits via short peptide epitopes. As a step to decipher the molecular architecture of the RES complex, we have determined crystal structures of full-length Pml1p and N-terminally truncated Pml1p. The first 50 residues of full-length Pml1p, encompassing the Snu17p-binding region, are disordered, showing that Pml1p binds to Snu17p via an intrinsically unstructured region. The remainder of Pml1p folds as a forkhead-associated (FHA) domain, which is expanded by a number of noncanonical elements compared with known FHA domains from other proteins. An atypical N-terminal appendix runs across one beta-sheet and thereby stabilizes the domain as shown by deletion experiments. FHA domains are thought to constitute phosphopeptide-binding elements. Consistently, a sulfate ion was found at the putative phosphopeptide-binding loops of full-length Pml1p. The N-terminally truncated version of the protein lacked a similar phosphopeptide mimic but retained an almost identical structure. A long loop neighboring the putative phosphopeptide-binding site was disordered in both structures. Comparison with other FHA domain proteins suggests that this loop adopts a defined conformation upon ligand binding and thereby confers ligand specificity. Our results show that in the RES complex, an FHA domain of Pml1p is flexibly tethered via an unstructured N-terminal region to Snu17p. (C) 2008 Elsevier Ltd. All rights reserved.Max Planck Societ

Viral immune evasins impact antigen presentation by allele-specific trapping of MHC I at the peptide-loading complex

Major histocompatibility complex class I (MHC I) molecules present antigenic peptides to cytotoxic T cells to eliminate infected or cancerous cells. The transporter associated with antigen processing (TAP) shuttles proteasomally generated peptides into the ER for MHC I loading. As central part of the peptide-loading complex (PLC), TAP is targeted by viral factors, which inhibit peptide supply and thereby impact MHC I-mediated immune responses. However, it is still poorly understood how antigen presentation via different MHC I allotypes is affected by TAP inhibition. Here, we show that conditional expression of herpes simplex viral ICP47 suppresses surface presentation of HLA-A and HLA-C, but not of HLA-B, while the human cytomegaloviral US6 reduces surface levels of all MHC I allotypes. This marked difference in HLA-B antigen presentation is echoed by an enrichment of HLA-B allomorphs at US6-arrested PLC in comparison to ICP47-PLC. Although both viral factors prevent TAP-mediated peptide supply, our data imply that MHC I allomorphs favor different conformationally arrested states of the PLC, leading to differential downregulation of MHC I surface presentation. These findings will help understand MHC I biology in general and will even advance the targeted treatment of infections depending on patients’ allotypes.Publikationsfonds ML

Внедрение и принцип работы системы сейсмического мониторинга горного массива для работы в условиях ООО "Шахта "Усковская"

The status of the Silicon Microvertex Detector (SMD) and its installation into the LEP-L3 experiment are presented, highlighting novel features and sophisticated techniques. Preliminary results based on 1993 data are given and compared with Monte Carlo predictions, to understand the detector performances and its tracking capabilities