RNA sequencing identifies fusion of the EWSR1 and YY1 genes in mesothelioma with t(14;22)(q32;q12).

Mesothelioma is a rare but very aggressive tumor derived from mesothelial cells. A number of often complex but nonrandom cytogenetic abnormalities have been found in these tumors, resulting in loss of chromosome bands 14q32 and 22q12 in more than 35% of the cases. In this study, we used RNA sequencing to search for fusion transcripts in a mesothelioma carrying a t(14;22)(q32;q12) as the sole chromosomal aberration and found an EWSR1-YY1 and its reciprocal YY1-EWSR1 fusion transcript. Screening 15 additional cases of mesothelioma from which we had RNA but no cytogenetic information, we identified one more tumor carrying an EWSR1-YY1 fusion gene but not the reciprocal YY1-EWSR1 transcript. RT-polymerase chain reaction and sequencing showed that in both cases exon 8 of EWSR1 (nucleotide 1,139, accession number NM_013986 version 3, former exon 7 in sequence with accession number X66899) was fused to exon 2 of YY1 (nucleotide 1,160, accession number NM_003403 version 3). The EWSR1 breakpoint in exon 8 in the EWSR1-YY1 chimeric transcript is similar to what is found in other fusions involving EWSR1 such as EWSR1-FLI1, EWSR1-DDIT3, and EWSR1-ATF1. The EWSR1-YY1-encoded protein is an abnormal transcription factor with the transactivation domain of EWSR1 and the DNA-binding domain of YY1. This is the first study to detect a specific fusion gene in mesothelioma (the reason how frequent the EWSR1-YY1 fusion is remains uncertain) and also the first time that direct involvement of YY1 in oncogenesis has been demonstrated.

Functional RNA microarrays for high-throughput screening of antiprotein aptamers.

High-throughput methods for generating aptamer microarrays are described. As a proof-of-principle, the microarrays were used to screen the affinity and specificity of a pool of robotically selected antilysozyme RNA aptamers. Aptamers were transcribed in vitro in reactions supplemented with biotinyl-guanosine 5'-monophosphate, which led to the specific addition of a 5' biotin moiety, and then spotted on streptavidin-coated microarray slides. The aptamers captured target protein in a dose-dependent manner, with linear signal response ranges that covered seven orders of magnitude and a lower limit of detection of 1 pg/mL (70 fM). Aptamers on the microarray retained their specificity for target protein in the presence of a 10,000-fold (w/w) excess of T-4 cell lysate protein. The RNA aptamer microarrays performed comparably to current antibody microarrays and within the clinically relevant ranges of many disease biomarkers. These methods should also prove useful for generating other functional RNA microarrays, including arrays for genomic noncoding RNAs that bind proteins. Integrating RNA aptamer microarray production with the maturing technology for automated in vitro selection of antiprotein aptamers should result in the high-throughput production of proteome chips.

Cloning and characterization of glycine-rich RNA-binding protein cDNAs in the moss Physcomitrella patens.

We isolated three cDNAs for the genes PpGRP1, PpGRP2 and PpGRP3 that encode glycine-rich RNA-binding proteins (GRPs) from Physcomitrella patens. Three full-length cDNA clones were isolated from a cDNA library prepared from poly(A)(+) RNA from 7-day-old protonemata of P. patens. They were named PpGRP1, PpGRP2 and PpGRP3, which encode putative polypeptides of 162, 178 and 155 residues, respectively. Preliminary genomic sequencing suggested that the positions of the three introns in the PpGRP3 gene are similar to those of introns in Arabidopsis GRP genes. PpGRP3 had a putative transit sequence. The PpGRP1-sGFP and PpGRP2-sGFP fusions were targeted to the cell nucleus, while PpGRP3-sGFP fusion was targeted to mitochondria. The level of these PpGRP transcripts as well as that of PpGRP proteins increased after cold treatment. Homoribopolymer RNA assay revealed that PpGRP3 protein show high affinity for poly(U) and poly(G). Results of phylogenetic analysis suggest that the nuclear and mitochondrial forms of GRP have been established early during the evolution of green plants.

hRUL138, a novel human RNA-binding RING-H2 ubiquitin-protein ligase.

Cellular as well as viral RNAs are usually found complexed with proteins. In an attempt to identify proteins that interact with transcripts of hepatitis B virus (HBV), a DNA virus that replicates through reverse transcription, a partial cDNA was isolated from a human cDNA expression library whose gene product bound to an HBV-derived RNA. Using an overlapping clone from a molecular hybridization screen a full-length cDNA was assembled. It contained a large open reading frame for a 1208 amino-acid protein of 138 kDa identical to the hypothetical product of the KIAA0675 clone. Closely related sequences are present in mouse cDNA libraries but not in the genomes of lower organisms. The protein sequence contained no known RNA-binding domain and, apart from a probable coiled-coil domain, the only significant homology involved a complete RING-H2 motif. This suggested that the protein might be a novel RNA-binding RING-dependent ubiquitin-protein ligase or E3 enzyme. A motif critical for RNA binding was experimentally mapped to a central Lys-rich region. Binding specificity is either broad or the protein has as yet unknown physiological targets; hence, at present, a potential importance for HBV biology remains open. The RING-H2 domain was functional in and essential for self- and trans-ubiquitylation in vitro and for proteasome-mediated turnover of the protein in vivo. We therefore termed it hRUL138 for human RNA-binding ubiquitin ligase of 138 kDa. hRUL138 mRNAs are expressed at low levels in most tissues. GFP-tagged hRUL138 derivatives were found associated with cytoplasmic structures, possibly the ER, but excluded from the nucleus. The combined presence of RNA binding and E3 activity in hRUL138 raises the possibility that both are mechanistically linked.

Mitochondrial aconitase binds to the 3' untranslated region of the mouse hepatitis virus genome.

Mouse hepatitis virus (MHV), a member of the Coronaviridae, contains a polyadenylated positive-sense single-stranded genomic RNA which is 31 kb long. MHV replication and transcription take place via the synthesis of negative-strand RNA intermediates from a positive-strand genomic template. A cis-acting element previously identified in the 3' untranslated region binds to trans-acting host factors from mouse fibroblasts and forms at least three RNA-protein complexes. The largest RNA-protein complex formed by the cis-acting element and the lysate from uninfected mouse fibroblasts has a molecular weight of about 200 kDa. The complex observed in gel shift assays has been resolved by second-dimension sodium dodecyl sulfate-polyacrylamide gel electrophoresis into four proteins of approximately 90, 70, 58, and 40 kDa after RNase treatment. Specific RNA affinity chromatography also has revealed the presence of a 90-kDa protein associated with RNA containing the cis-acting element bound to magnetic beads. The 90-kDa protein has been purified from uninfected mouse fibroblast crude lysates. Protein microsequencing identified the 90-kDa protein as mitochondrial aconitase. Antibody raised against purified mitochondrial aconitase recognizes the RNA-protein complex and the 90-kDa protein, which can be released from the complex by RNase digestion. Furthermore, UV cross-linking studies indicate that highly purified mitochondrial aconitase binds specifically to the MHV 3' protein-binding element. Increasing the intracellular level of mitochondrial aconitase by iron supplementation resulted in increased RNA-binding activity in cell extracts and increased virus production as well as viral protein synthesis at early hours of infection. These results are particularly interesting in terms of identification of an RNA target for mitochondrial aconitase, which has a cytoplasmic homolog, cytoplasmic aconitase, also known as iron regulatory protein 1, a well-recognized RNA-binding protein. The binding properties of mitochondrial aconitase and the functional relevance of RNA binding appear to parallel those of cytoplasmic aconitase.

Purification and characterization of a 29 kDa poly(A)-binding protein from chickpea (Cicer arietinum) epicotyl.

A poly(A)-binding protein (PABP) with mol wt 29,000 has been purified from chickpea (Cicer arietinum) epicotyl by ammonium sulfate fractionation and Cibacron blue F3-GA chromatography, making a complex with poly(A) and elution of PABP-poly(A) complex at 45 degrees C from oligo d(T)-cellulose. The elution pattern and binding properties show that the purified protein is different from the PABP (mol. wt 72,000) reported earlier from our laboratory.

Purification and characterization of a poly(A)-binding protein from chickpea (Cicer arietinum) epicotyl.

A poly(A)-binding protein (PABP) with mol wt 72,000 has been purified from chickpea (Cicer arietinum) epicotyls by ammonium sulfate fractionation, Cibacron blue F3-GA and poly(A) agarose chromatography. The binding properties and the specificity of binding show that the purified protein is an analogue of PABPs in other eukaryotes. This PABP is highly susceptible to proteolysis and upon degradation forms a polypeptide fragment of mol wt 21,000 which has an independent poly(A) binding activity.

SYNCRIP, a cytoplasmic counterpart of heterogeneous nuclear ribonucleoprotein R, interacts with ubiquitous synaptotagmin isoforms.

Synaptotagmins (Syts) are a large family of membrane proteins consisted of at least 12 isoforms. They are categorized in neuron-specific isoforms (I-V, X, and XI) and ubiquitous isoforms (VI-IX) based on their expression patterns. Syt-I, a neuron-specific and abundant isoform, has been well characterized and postulated to be the exocytotic Ca(2+) sensor. However, the functions of other isoforms remain obscure. Here, we report that ubiquitous isoforms of synaptotagmins, Syt-VII, Syt-VIII, and Syt-IX, interacted with a cytoplasmic RNA-binding protein, SYNCRIP (Synaptotagmin-binding, cytoplasmic RNA-interacting protein), through their C2B domains. SYNCRIP was originally found in the Syt-II C2AB domain bound fraction from the mouse brain lysate. cDNA cloning of SYNCRIP cDNA revealed that the protein was highly homologous to heterogeneous nuclear ribonucleoprotein R (hnRNP R) recently identified. SYNCRIP protein was ubiquitously and constantly expressed in various tissues of mice parallel to hnRNP R. SYNCRIP indeed bound RNA with preference to poly(A) RNA; however, in contrast to the nuclear localization of hnRNP R, SYNCRIP was distributed predominantly in the cytoplasm as judged by both biochemical fractionation and immunohistochemical studies. In vitro binding experiments showed the potential interaction of SYNCRIP with C2B domains of Syts except for those of Syt-V, -VI, and -X. Furthermore, the interaction between SYNCRIP and Syt-VII, -VIII, or -IX was revealed by co-immunoprecipitation experiments using COS cells transiently expressing each Syt isoform. These findings suggested that SYNCRIP was a target of ubiquitous type of Syts and implied the involvement of ubiquitous Syts in the regulation of dynamics of the cytoplasmic mRNA.

Characterization of a plant mitochondrial active chromosome.

A method is presented for the partial purification of a plant mitochondrial active chromosome (MAC). This method is based on the presence of the mitochondrial chromosome in the insoluble mitochondrial fraction which allows for its rapid purification from the bulk of detergent-solubilized proteins by ultra-centrifugation. The resuspended MAC carrying DNA and RNA-binding proteins retains DNA synthesis and transcription activities comparable to the ones found in isolated mitochondria. In comparison, tRNA-nucleotidyl terminal transferase taken as an example of RNA modifying activities remains in the soluble fraction. MAC purification is proposed as a rapid and efficient first step in the purification of DNA-binding proteins involved in DNA replication and transcription.

Chloroplast endoribonuclease p54 involved in RNA 3'-end processing is regulated by phosphorylation and redox state.

Chloroplast RNA-binding protein p54 is an endoribonuclease required for 3'end-processing of plastid precursor transcripts. We find that purified p54 can serve as a phosphate acceptor for protein kinases in vitro. Both the processing and RNA-binding activities of p54 are enhanced by phosphorylation and decreased by dephosphorylation. In addition, the enzyme is activated by the oxidized form of glutathione and inhibited by the reduced form, whereas other redox reagents that were tested showed no effect. Kinase treatment of p54 prior to oxidation by glutathione resulted in highest levels of activation, suggesting that phosphorylation and redox state act together to control p54 activity in vitro and possibly also in vivo.

Distinct mRNA-binding proteins interacting with short repeat sequences of the 3' UTR may be involved in the post-transcriptional regulation of the mouse catalase gene, Cas-1.

The 3' untranslated region (UTR) of the mouse catalase gene (Cas-1) is demonstrated to be an active site for specific protein interactions. We have identified two regions of the Cas-1 3' UTR mRNA that bind to distinct cytoplasmic proteins: one containing a (CA)31 repeat with UA octomer (RNA 5) and another with a (U)15 tract (RNA 6). RNA 5 interacts with one set of protein complexes (a, b, and c) whereas RNA 6 interacts with another (x, y, and z) in a sequence-specific manner. These RNA-protein complexes are development-, tissue-, and genotype-specific. The proteins involved in the two sets of complexes are different. Further characterization of the proteins involved in these interactions has revealed the presence of a single protein of approximately 70 kD that binds RNA 5, and two proteins approximately 38 kD and approximately 47 kD that bind to RNA 6. The approximately 70-k D and approximately 38-kD proteins are also associated with the polysomal fractions and may play a role in the post-transcriptional regulation of Cas-1. Although the observed 3' UTR RNA-protein interactions are hypothesized to be important in post-transcriptional regulation of this gene in rodents, specific RNA sequences and their associated proteins identified in this report would now permit the elucidation of the mechanisms of their action at the molecular level.

Isolation of a novel RNA-binding protein and its association with a large ribonucleoprotein particle present in the nucleoplasm of tobacco cells.

A cDNA encoding a protein with a consensus sequence-type RNA-binding domain (CS-RBD) has been isolated from a Nicotiana sylvestris cDNA library. The deduced protein (designated 'RZ-1') contains CS-RBD in its N-terminal half, arginine/aspartic acid repeats in its center and a glycine-rich-C-terminal region in which a zinc finger motif of the CCHC type is present. The corresponding gene appears to be expressed constitutively in all tobacco organs. Immunocytochemical assays revealed that RZ-1 is localized in the nucleoplasm of tobacco cultured cells. Glycerol gradient fractionation of tobacco nuclear lysates showed that RZ-1 is associated with a large ribonucleoprotein particle of around 60 S in size. Nucleic acid-binding assays indicated that RZ-1 binds preferentially to poly (G) and both the CS-RBD and glycine-rich region are necessary for its binding activity. A possible role of RZ-1 is discussed.

Identification, nuclear localization, and binding activities of OZF, a human protein solely composed of zinc-finger motifs.

The OZF cDNA was identified in a human mammary cell line and encodes a polypeptide solely composed of ten zinc-finger motifs which belongs to the Kruppel family of zinc-finger proteins. The OZF protein produced in Escherichia coli binds zinc ions, DNA and heparin. These binding activities are characteristic of zinc-finger proteins. Immunochemical analysis using antibodies produced against the recombinant protein detected its expression in human mammary epithelial cells but not in stroma cells, which is consistent with the pattern of expression observed at the RNA level in cell cultures. Western blot analysis demonstrated the expression of a 33-kDa nuclear protein similar in size to the predicted protein and therefore excluded the presence of an additional trans-acting domain. These data establish the unique structure of the OZF protein which is distinct from previously identified zinc-finger proteins. In addition, OZF protein overexpression was found in a tumor cell line, which suggests a possible involvement in carcinogenesis.

Characterization of the 5 S RNA binding activity of Xenopus zinc finger protein p43.

One major component of the Xenopus 42 S ribonucleoprotein (RNP) storage particle is the p43 protein. The 5 S RNA binding protein is structurally similar to TFIIIA, containing nine zinc finger domains. The RNA binding properties of recombinant p43 were characterized using a nitrocellulose filter binding assay. The experimental conditions necessary for in vitro p43-5 S RNA complex formation include: pH 7.5, 0.1 M KCl and incubation at 22 degrees C. Under these conditions, the protein binds to Xenopus oocyte 5 S RNA with an apparent association constant of 1.61(+/- 0.12) x 10(9) M-1. A series of mutations in 5 S RNA were used to determine which sequence and structural features of the 5 S RNA are required for high affinity binding of p43. The primary contact points for p43 include the sequences and structures of stems II, V and loop D of the 5 S RNA. Although p43 and TFIIIA are structurally similar and are both relatively insensitive to mutations in the 5 S RNA, they do require different features of the 5 S RNA molecule for high affinity binding.

Splicing factor SF3a60 is the mammalian homologue of PRP9 of S.cerevisiae: the conserved zinc finger-like motif is functionally exchangeable in vivo.

A cDNA encoding the 60 kDa subunit of mammalian splicing factor SF3a has been isolated. The deduced protein sequence reveals a 30% identity to the PRP9 splicing protein of the yeast S.cerevisiae. The highest homology is present in a zinc finger-like region in the C-terminal domain of both proteins. The PRP9 zinc finger-like motif has been replaced by the equivalent region of mammalian SF3a60. The chimeric protein rescues the temperature-sensitive phenotype of the prp9-1 mutant strain demonstrating that not only the structure but also the function of this domain has been conserved during evolution.

Hypoxia stimulates binding of a cytoplasmic protein to a pyrimidine-rich sequence in the 3'-untranslated region of rat tyrosine hydroxylase mRNA.

Reduced oxygen tension (hypoxia) induces a 3-fold increase in stability of mRNA for tyrosine hydroxylase (TH), the rate-limiting enzyme in catecholamine synthesis, in the pheochromocytoma (PC12) clonal cell line. To investigate the possibility that RNA-protein interactions are involved in mediating this increase in stability, RNA gel shift assays were performed using different fragments of labeled TH mRNA and the S-100 fraction of PC12 cytoplasmic protein extracts. We identified a sequence within the 3'-untranslated region of TH mRNA that binds cytoplasmic protein. RNase T1 mapping revealed that the protein was bound to a 28 nucleotide long sequence that is located between bases 1551-1579 of TH mRNA. Moreover, protein binding to this fragment was prevented with an antisense oligonucleotide directed against bases 1551-1579 and subsequent RNase H digestion. This fragment of the 3'-untranslated region of TH mRNA is rich in pyrimidine nucleotides, and the binding of cytoplasmic protein to this fragment was reduced by competition with other polypyrimidine sequences including poly(C) but not poly(U) polymers. The binding of the protein to TH mRNA was increased when cytoplasmic proteins were extracted from PC12 cells exposed to hypoxia (5% O2) for 24 h. Electrophoresis of the UV cross-linked RNA-protein complex on SDS-polyacrylamide gel electrophoresis revealed a complex of 74 kDa. The potential role of this protein-TH mRNA interaction in regulation of TH mRNA stability during hypoxia is discussed.

Transcriptional and posttranscriptional mechanisms modulate creatine kinase expression during differentiation of osteoblastic cells.

Enhancement of energy metabolism is fundamental to the developmental programs of many cell types. This work examines the molecular mechanisms that mediate changes in energy metabolism during differentiation of osteoblastic cells. When the rat osteoblastic cell line, ROS 17/2.8, is induced to differentiate with 1,25-dihydroxyvitamin D3, expression of creatine kinase-b (ck-b), a pivotal enzyme in energy metabolism, is enhanced. Maximum enhancement occurs at 48 h of induction with 10 nM 1,25-dihydroxyvitamin D3 when creatine kinase activity is 2.1-fold over uninduced cells. This is associated with a 2-fold increase in transcription rate and the formation of a second protein-DNA complex on the ck-b gene promoter that is supplementary to the one present in undifferentiated cells. In addition, the contribution of posttranscriptional regulatory mechanisms is suggested by (1) the increase in ck-b mRNA abundance exceeds that of transcription rate, indicating an increase in message stability, (2) the increase in ck-b mRNA precedes and exceeds that of protein activity, indicating translational modulation, and (3) RNA mobility-shift assays indicate that a cytosolic factor in ROS 17/2.8 cells interacts specifically with the highly conserved 3'-untranslated region of the ck-b mRNA. We have previously reported that such an interaction mediates translational control (Ch'ng, J. L. C., Shoemaker, D. L., Schimmel, P., and Holmes, E.W. (1990) Science 248, 1003-1006). The physiological roles of these regulatory mechanisms during osteoblast differentiation are discussed.

The 54 kDa RNA-binding protein from mustard chloroplasts mediates endonucleolytic transcript 3' end formation in vitro.

A 54 kDa protein from mustard chloroplasts was previously shown to interact specifically with a conserved U-rich sequence element in RNA derived from the 3' flanking regions of the plastid trnK and rps16 genes, which code for tRNA(Lys) and ribosomal protein CS19, respectively (Nickelsen and Link, 1991). This RNA-binding protein has now been purified by affinity chromatography on heparin Sepharose and poly(U) Sepharose. In vitro processing experiments and nuclease S1 analyses of the processing products revealed that the 54 kDa polypeptide is an endonuclease. The in vitro cleavage sites are consistent with the positions of corresponding transcript in vivo 3' ends downstream of trnK and rps16, suggesting that RNA 3' end formation takes place endonucleolytically also in vivo.