Polycation-π interactions are a driving force for molecular recognition by an intrinsically disordered oncoprotein family.

Molecular recognition by intrinsically disordered proteins (IDPs) commonly involves specific localized contacts and target-induced disorder to order transitions. However, some IDPs remain disordered in the bound state, a phenomenon coined "fuzziness", often characterized by IDP polyvalency, sequence-insensitivity and a dynamic ensemble of disordered bound-state conformations. Besides the above general features, specific biophysical models for fuzzy interactions are mostly lacking. The transcriptional activation domain of the Ewing's Sarcoma oncoprotein family (EAD) is an IDP that exhibits many features of fuzziness, with multiple EAD aromatic side chains driving molecular recognition. Considering the prevalent role of cation-π interactions at various protein-protein interfaces, we hypothesized that EAD-target binding involves polycation- π contacts between a disordered EAD and basic residues on the target. Herein we evaluated the polycation-π hypothesis via functional and theoretical interrogation of EAD variants. The experimental effects of a range of EAD sequence variations, including aromatic number, aromatic density and charge perturbations, all support the cation-π model. Moreover, the activity trends observed are well captured by a coarse-grained EAD chain model and a corresponding analytical model based on interaction between EAD aromatics and surface cations of a generic globular target. EAD-target binding, in the context of pathological Ewing's Sarcoma oncoproteins, is thus seen to be driven by a balance between EAD conformational entropy and favorable EAD-target cation-π contacts. Such a highly versatile mode of molecular recognition offers a general conceptual framework for promiscuous target recognition by polyvalent IDPs.

Molecular recognition by the EWS transcriptional activation domain.

Interactions between Intrinsically Disordered Protein Regions (IDRs) and their targets commonly exhibit localised contacts via target-induced disorder to order transitions. Other more complex IDR target interactions have been termed "fuzzy" because the IDR does not form a well-defined induced structure. In some remarkable cases of fuzziness IDR function is apparently sequence independent and conferred by amino acid composition. Such cases have been referred to as "random fuzziness" but the molecular features involved are poorly characterised. The transcriptional activation domain (EAD) of oncogenic Ewing's Sarcoma Fusion Proteins (EFPs) is an ≈280 residue IDR with a biased composition restricted to Ala, Gly, Gln, Pro, Ser, Thr and Tyr. Multiple aromatic side chains (exclusively from Try residues) and the particular EAD composition are crucial for molecular recognition but there appears to be no other major geometrically constrained requirement. Computational analysis of the EAD using PONDR (Molecular Kinetics, Inc. http://www.pondr. com) complements the functional data and shows, accordingly, that propensity for structural order within the EAD is conferred by Tyr residues. To conclude, molecular recognition by the EAD is extraordinarily malleable and involves multiple aromatic contacts facilitated by a flexible peptide backbone and, most likely, a limited number of weaker contributions from amenable side chains. I propose to refer to this mode of fuzzy recognition as "polyaromatic", noting that it shares some fundamental features with the "polyelectrostatic" (phosphorylation-dependent) interaction of the Sic1 Cdk inhibitor and Cdc4._I will also speculate on more detailed models for molecular recognition by the EAD and their relationship to native (non-oncogenic) EAD function.

In vitro activity of the EWS oncogene transcriptional activation domain.

Aberrant chromosomal fusion of the Ewings sarcoma oncogene (EWS) to several different cellular partners gives rise to the Ewing's family of oncogenic proteins [EWS fusion proteins (EFPs)] and associated tumors (EFTs). EFPs are potent transcriptional activators dependent on the N-terminal region of EWS [the EWS activation domain (EAD)], and this function is thought to be central to EFT oncogenesis and maintenance. Thus, EFPs are promising therapeutic targets, and detailed molecular studies of the EAD will be pivotal for exploring this potential. For many reasons, the molecular mechanism of EAD action is poorly understood and one major obstacle to progress is the lack of an in vitro transcription assay. Using well-characterized EAD-dependent activators and soluble nuclear extracts, we have attempted to recapitulate EAD transcriptional activity in vitro. We report that while the EAD activates transcription strongly in vitro, the effect of EAD mutations is strikingly different from that observed in vivo. Our results therefore suggest that crude soluble extracts do not support bona fide EAD activity in vitro, and we discuss our findings in relation to future assay development and potential mechanisms of EAD action.

Differential interaction of PRMT1 with RGG-boxes of the FET family proteins EWS and TAF15.

The FET sub-family (FUS/TLS, EWS, TAF15) of RNA-binding proteins have remarkably similar overall structure but diverse biological and pathological roles. The molecular basis for FET protein specialization is largely unknown. Gly-Arg-Rich regions (RGG-boxes) within FET proteins are targets for methylation by Protein-Arginine-Methyl-Transferase-1 (PRMT1) and substrate capture is thought to involve electrostatic attraction between positively charged polyRGG substrates and negatively charged surface channels of PRMT1. Unlike FUS and EWS, a high proportion of TAF15 RGG-boxes are embedded within neutrally charged YGGDR(S/G)G repeats, suggesting that they might not bind well to PRMT1. This notion runs contrary however to a report that YGGDR(S/G)G repeats are methylated by PRMT1. Using peptide-based polyRGG substrates and a novel 2-hybrid binding assay, we find that the Asp residue in YGGDR(S/G)G repeats confers poor binding to PRMT1. Our results therefore indicate that YGGDR(S/G)G repeats may contribute to TAF15 specialization by enabling differential interactions with PRMT1 and reduced overall levels of TAF15 methylation compared with other FET proteins. By analogy with molecular recognition of other disordered polyvalent ligands by globular protein partners, we also propose a dynamic polyelectrostatic model for substrate capture by PRMT1.

RGG-boxes of the EWS oncoprotein repress a range of transcriptional activation domains.

The Ewings Sarcoma Oncoprotein (EWS) interacts with several components of the mammalian transcriptional and pre-mRNA splicing machinery and is also found in the cytoplasm and even on the cell surface. The apparently diverse cellular functions of EWS are, however, not well characterized. EWS harbours a potent N-terminal transcriptional activation domain (the EAD) that is revealed in the context of oncogenic EWS-fusion proteins (EFPs) and a C-terminal RNA-binding domain (RBD) that recruits pre-mRNA splicing factors and may couple transcription and splicing. In contrast to EFPs, the presumed transcriptional role of normal EWS remains enigmatic. Here, we report that multiple RGG-boxes within the RBD are necessary and sufficient for cis-repression of the EAD and that RGG-boxes can also repress in-trans, within dimeric partners. Lys can functionally substitute for Arg, indicating that the basic nature of the Arg side chain is the critical determinant of RGG-box-mediated repression. In addition to the EAD, RGG-boxes can repress a broad range of activation domains (including those of VP16, E1a and CREB), but repression can be alleviated by the simultaneous presence of more than one activation domain. We therefore propose that a key function of RGG boxes within native EWS is to restrict promiscuous activation by the EAD while still allowing EWS to enter functional transcription complexes and participate in other transactions involving pre-mRNAs.

Expression profiling of t(12;22) positive clear cell sarcoma of soft tissue cell lines reveals characteristic up-regulation of potential new marker genes including ERBB3.

Clear cell sarcoma of soft tissue (CCSST), also known as malignant melanoma of soft parts, represents a rare lesion of the musculoskeletal system usually affecting adolescents and young adults. CCSST is typified by a chromosomal t(12;22)(q13;q12) translocation resulting in a fusion between the Ewing sarcoma gene (EWSR1) and activating transcription factor 1 (ATF1), of which the activity in nontransformed cells is regulated by cyclic AMP. Our aim was to identify critical differentially expressed genes in CCSST tumor cells in comparison with other solid tumors affecting children and young adults to better understand signaling pathways regulating specific features of the development and progression of this tumor entity. We applied Affymetrix Human Genome U95Av2 oligonucleotide microarrays representing approximately 12,000 genes to generate the expression profiles of the CCSST cell lines GG-62, DTC-1, KAO, MST2, MST3, and Su-CC-S1 in comparison with 8 neuroblastoma, 7 Ewing tumor, and 6 osteosarcoma cell lines. Subsequent hierarchical clustering of microarray data clearly separated all four of the tumor types from each other and identified differentially expressed transcripts, which are characteristically up-regulated in CCSST. Statistical analysis revealed a group of 331 probe sets, representing approximately 300 significant (P < 0.001) differentially regulated genes, which clearly discriminated between the CCSST and other tumor samples. Besides genes that were already known to be highly expressed in CCSST, like S100A11 (S100 protein) or MITF (microphthalmia-associated transcription factor), this group shows an obvious portion of genes that are involved in cyclic AMP response or regulation, in pigmentation processes, or in neuronal structure and signaling. Comparison with other expression profile analyses on neuroectodermal childhood tumors confirms the high robustness of this strategy to characterize tumor entities based on their gene expression. We found the avian erythroblastic leukemia viral oncogene homologue 3 (ERBB3) to be one of the most dramatically up-regulated genes in CCSST. Quantitative real-time PCR and Northern blot analysis verified the mRNA abundance and confirmed the absence of the inhibitory transcript variant of this gene. The protein product of the member of the epidermal growth factor receptor family ERBB3 could be shown to be highly present in all of the CCSST cell lines investigated, as well as in 18 of 20 primary tumor biopsies. In conclusion, our data demonstrate new aspects of the phenotype and the biological behavior of CCSST and reveal ERBB3 to be a useful diagnostic marker.

RGG boxes within the TET/FET family of RNA-binding proteins are functionally distinct.

The multi-functional TET (TAF15/EWS/TLS) or FET (FUS/EWS/TLS) protein family of higher organisms harbor a transcriptional-activation domain (EAD) and an RNA-binding domain (RBD). The transcriptional activation function is, however, only revealed in oncogenic TET-fusion proteins because in native TET proteins it is auto-repressed by RGG-boxes within the TET RBD. Auto-repression is suggested to involve direct cation-pi interactions between multiple Arg residues within RGG boxes and EAD aromatics. Via analysis of TET transcriptional activity in different organisms, we report herein that repression is not autonomous but instead requires additional trans-acting factors. This finding is not supportive of a proposed model whereby repression occurs via a simple intramolecular EAD/RGG-box interaction. We also show that RGG-boxes present within reiterated YGGDRGG repeats that are unique to TAF15, are defective for repression due to the conserved Asp residue. Thus, RGG boxes within TET proteins can be functionally distinguished. While our results show that YGGDRGG repeats are not involved in TAF15 auto-repression, their remarkable number and conservation strongly suggest that they may confer specialized properties to TAF15 and thus contribute to functional differentiation within the TET/FET protein family.

The RNA Pol II sub-complex hsRpb4/7 is required for viability of multiple human cell lines.

The evolutionarily conserved RNA Polymerase II Rpb4/7 sub-complex has been thoroughly studied in yeast and impacts gene expression at multiple levels including transcription, mRNA processing and decay. In addition Rpb4/7 exerts differential effects on gene expression in yeast and Rpb4 is not obligatory for yeast (S. cerevisiae) survival. Specialised roles for human (hs) Rpb4/7 have not been extensively described and we have probed this question by depleting hsRpb4/7 in established human cell lines using RNA interference. We find that Rpb4/7 protein levels are inter-dependent and accordingly, the functional effects of depleting either protein are co-incident. hsRpb4/7 exhibits gene-specific effects and cells initially remain viable upon hsRpb4/7 depletion. However prolonged hsRpb4/7 depletion is cytotoxic in the range of cell lines tested. Protracted cell death occurs by an unknown mechanism and in some cases is accompanied by a pronounced elongated cell morphology. In conclusion we provide evidence for a gene-specific role of hsRpb4/7 in human cell viability.

A transcription assay for EWS oncoproteins in Xenopus oocytes.

Aberrant chromosomal fusion of the Ewing's sarcoma oncogene (EWS) to several different cellular partners produces the Ewing's family of oncoproteins (EWS-fusion-proteins, EFPs) and associated tumors (EFTs). EFPs are potent transcriptional activators, dependent on the N-terminal region of EWS (the EWS-activation-domain, EAD) and this function is thought to be central to EFT oncogenesis and maintenance. Thus EFPs are promising therapeutic targets, but detailed molecular studies will be pivotal for exploring this potential. Such studies have so far largely been restricted to intact mammalian cells while recent evidence has indicated that a mammalian cell-free transcription system may not support bona fide EAD function. Therefore, the lack of manipulatable assays for the EAD presents a significant barrier to progress. Using Xenopus laevis oocytes we describe a plasmid-based micro-injection assay that supports efficient, bona fide EAD transcriptional activity and hence provides a new vehicle for molecular dissection of the EAD.

Multiple aromatic side chains within a disordered structure are critical for transcription and transforming activity of EWS family oncoproteins.

Chromosomal translocations involving the N-terminal approximately 250 residues of the Ewings sarcoma (EWS) oncogene produce a group of EWS fusion proteins (EFPs) that cause several distinct human cancers. EFPs are potent transcriptional activators and interact with other proteins required for mRNA biogenesis, indicating that EFPs induce tumorigenesis by perturbing gene expression. Although EFPs were discovered more than a decade ago, molecular analysis has been greatly hindered by the repetitive EWS activation domain (EAD) structure, containing multiple degenerate hexapeptide repeats (consensus SYGQQS) with a conserved tyrosine residue. By exploiting total gene synthesis, we have been able to systematically mutagenize the EAD and determine the effect on transcriptional activation by EWS/ATF1 and cellular transformation by EWS/Fli1. In both assays, we find the following requirements for EAD function. First, multiple tyrosine residues are essential. Second, phenylalanine can effectively substitute for tyrosine, showing that an aromatic ring can confer EAD function in the absence of tyrosine phosphorylation. Third, there is little requirement for specific peptide sequences and, thus, overall sequence composition (and not the degenerate hexapeptide repeat) confers EAD activity. Consistent with the above findings, we also report that the EAD is intrinsically disordered. However, a sensitive computational predictor of natural protein disorder (PONDR VL3) identifies potential molecular recognition features that are tyrosine-dependent and that correlate well with EAD function. In summary we have uncovered several molecular features of the EAD that will impact future studies of the broader EFP family and molecular recognition by complex intrinsically disordered proteins.