Selective interactions of hnRNP M isoforms with the TET proteins TAF15 and TLS/FUS.

The molecular composition of macromolecular assemblies engaged in transcription and splicing influences biogenesis of mRNA transcripts. Preference for one over the other interactive protein partner within those complexes is expected to change the gene expression pattern and to affect subsequent cellular events. We report here the novel and selective associations between RNA-binding proteins, namely the hnRNP M1-4 isoforms-involved in early spliceosome assembly and alternative splicing-and the transcription factors TAF15 and TLS/FUS. In immunoprecipitation studies on HeLa nuclear extracts, TAF15 co-immunoprecipitates preferably with the higher molecular weight hnRNP M3/4 isoforms, opposite to TLS/FUS that associates with the lower molecular weight hnRNP M1/2 species. We demonstrate that these associations can be mediated through direct protein-protein interactions via the amino-termini of the TET proteins, independently of RNA. Finally, we show partial co-localization of TAF15 and TLS/FUS with hnRNP M proteins in HeLa nuclei, supporting the biochemically obtained data. The participation of hnRNP M in an expanding network of protein-protein interactions suggests its important functioning in the coordination of transcriptional and post-transcriptional events.

HuR-regulated mRNAs associated with nuclear hnRNP A1-RNP complexes.

Post-transcriptional regulatory networks are dependent on the interplay of many RNA-binding proteins having a major role in mRNA processing events in mammals. We have been interested in the concerted action of the two RNA-binding proteins hnRNP A1 and HuR, both stable components of immunoselected hnRNP complexes and having a major nuclear localization. Specifically, we present here the application of the RNA-immunoprecipitation (RIP)-Chip technology to identify a population of nuclear transcripts associated with hnRNP A1-RNPs as isolated from the nuclear extract of either HuR WT or HuR-depleted (KO) mouse embryonic fibroblast (MEF) cells. The outcome of this analysis was a list of target genes regulated via HuR for their association (either increased or reduced) with the nuclear hnRNP A1-RNP complexes. Real time PCR analysis was applied to validate a selected number of nuclear mRNA transcripts, as well as to identify pre-spliced transcripts (in addition to their mature mRNA counterpart) within the isolated nuclear hnRNP A1-RNPs. The differentially enriched mRNAs were found to belong to GO categories relevant to biological processes anticipated for hnRNP A1 and HuR (such as transport, transcription, translation, apoptosis and cell cycle) indicating their concerted function in mRNA metabolism.

HuR-hnRNP interactions and the effect of cellular stress.

The heterogeneous nuclear ribonucleoproteins (hnRNPs) constitute an important group of RNA-binding proteins (RBPs) that play an active role in post-transcriptional gene regulation. Here, we focus on representative members of the hnRNP group of RBPs, namely hnRNP A1 and hnRNP C1/C2, which participate mainly in RNA splicing, as well as on HuR, a prototype of the AU-rich element-binding proteins (ARE-BP), which has an established role in regulating the stability and translation of target mRNAs. HuR and most hnRNPs are primarily localized in the nucleoplasm, and they can shuttle between the nucleus and the cytoplasm. Herein, we have extended our recently reported findings on the ability of HuR to associate with the immunopurified from mammalian cell extracts hnRNP and mRNP complexes by the application of an anti-HuR antibody that selects HuR-RNP complexes. We find that the protein components precipitated by the anti-HuR antibody are very similar to the hnRNP-HuR complexes reported previously. The in vivo association of HuR and hnRNP proteins is examined in the presence and the absence of thermal stress by confocal microscopy of intact cells and by in situ nuclear matrix preparation. We find notable heat-induced changes of HuR and of hnRNP A1, which exit the nucleus and co-localize to large cytoplasmic foci that represent heat-induced stress granules. The functional implications of HuR-hnRNP interactions in stressed and unstressed cells are discussed.

Domains involved in TAF15 subcellular localisation: dependence on cell type and ongoing transcription.

TAF15 (TBP associated factor 15) is a member of the highly conserved TET (also known as FET) protein family of RNA binding proteins (RBP), which comprises in addition FUS (fused in sarcoma, also known as TLS, translocated in liposarcoma) and EWS (Ewing sarcoma protein). The TET proteins are implied to play important roles in the onset of specific tumours, certain forms of amyotrophic lateral sclerosis (ALS) and frontotemporal lobar degeneration (FTLD). In this study we identified the domains of TAF15 responsible for its subcellular localisation in human (HeLa) cells and experimentally confirmed the presence of a transportin-dependent nuclear localisation signal (NLS) at its carboxy-terminus. We demonstrated that additional domains of TAF15 contributed, albeit to a less prominent extent, to its subcellular localisation. In the carboxy-terminus we identified an arginine and glycine rich (RGG) domain, capable of being targeted to stress granules. We, moreover, showed that TAF15 cellular localisation depended on ongoing transcription and that independent domains of TAF15 engaged in nucleolar capping upon transcription inhibition. Finally, we demonstrated that TAF15 localisation was differentially regulated in the HeLa and the neuronal HT22 cell lines and that TAF15 co-localised with a minor subset of RNA granules in the cytoplasm of HT22 cells, supporting a model whereupon TAF15 plays a role in RNA transport and/or local RNA translation.

Expression profile and interactions of hnRNP A3 within hnRNP/mRNP complexes in mammals.

The hnRNP A/B family contains abundant nuclear proteins with major roles in alternative splicing and the ability for nucleo-cytoplasmic shuttling. Compared to the best known members of this family (hnRNP A1, A2/B1), hnRNP A3 is a relatively less known protein. We report herein immunochemical studies with the hnRNP A3 isoforms (A3a and A3b) that provided evidence for species-specific expression. The unspliced A3a was found in human and murine cells, while the spliced A3b was a unique and abundant isoform in mouse/rat. In addition, a tissue-specific variation was observed in mice, as the brain was the only tissue found to overexpress hnRNP A3a. Both hnRNP A3a and A3b were able to stably associate with immunoselected hnRNP and mRNP complexes. Use of the auxiliary domain of hnRNP A3 in pull-down assays on human cell extracts revealed its unique ability to form a network of interactions not only with other A/B proteins but also with additional hnRNPs. All interactions, except those of hnRNP A1, were highly enhanced by previous RNase A digestion of the extracts. Our findings revealed novel characteristics of hnRNP A3 and supported its extensive involvement in the many aspects of mRNA maturation processes along with the other hnRNP A/B proteins.

A fraction of the transcription factor TAF15 participates in interactions with a subset of the spliceosomal U1 snRNP complex.

RNA/ssDNA-binding proteins comprise an emerging class of multifunctional proteins with an anticipated role in coupling transcription with RNA processing. We focused here on the highly related transcription factors of the TET sub-class: TLS/FUS, EWS and in particular the least studied member TAF15. An extensive array of immunoprecipitation studies on differentially extracted HeLa nuclei revealed the specific association of TAF15 with the spliceosomal U1 snRNP complex, as deduced by the co-precipitating U1 snRNA, U1-70K and Sm proteins. Additionally, application of anti-U1 RNP autoantibodies identified TAF15 in the immunoprecipitates. Minor fractions of nuclear TAF15 and U1 snRNP were involved in this association. Pull-down assays using recombinant TAF15 and U1 snRNP-specific proteins (U1-70K, U1A and U1C) provided in vitro evidence for a direct protein-protein interaction between TAF15 and U1C, which required the N-terminal domain of TAF15. The ability of TAF15 to directly contact RNA, most likely RNA pol II transcripts, was supported by in vivo UV cross-linking studies in the presence of α-amanitin. By all findings, the existence of a functionally discrete subset of U1 snRNP in association with TAF15 was suggested and provided further support for the involvement of U1 snRNP components in early steps of coordinated gene expression.

Deregulated expression of hnRNP A/B proteins in human non-small cell lung cancer: parallel assessment of protein and mRNA levels in paired tumour/non-tumour tissues.

BACKGROUND: Heterogeneous nuclear ribonucleoproteins (hnRNPs) of the A/B type (hnRNP A1, A2/B1, A3) are highly related multifunctional proteins participating in alternative splicing by antagonising other splicing factors, notably ASF/SF2. The altered expression pattern of hnRNP A2/B1 and/or splicing variant B1 alone in human lung cancer and their potential to serve as molecular markers for early diagnosis remain issues of intense investigation. The main objective of the present study was to use paired tumour/non-tumour biopsies from patients with non-small cell lung cancer (NSCLC) to investigate the expression profiles of hnRNP A1, A2/B1 and A3 in conjunction with ASF/SF2. METHODS: We combined western blotting of tissue homogenates with immunohistochemical examination of fixed tissue sections and quantification of mRNA expression levels in tumour versus adjacent normal-looking areas of the lung in the same patient. RESULTS: Our study, in addition to clear evidence of mostly uncoupled deregulation of hnRNPs A/B, has revealed hnRNP A1 to be the most deregulated protein with a high frequency of over-expression (76%), followed by A3 (52%) and A2/B1 (43%). Moreover, direct comparison of protein/mRNA levels showed a lack of correlation in the case of hnRNP A1 (as well as of ASF/SF2), but not of A2/B1, suggesting that different mechanisms underlie their deregulation. CONCLUSION: Our results provide strong evidence for the up-regulation of hnRNP A/B in NSCLC, and they support the existence of distinct mechanisms responsible for their deregulated expression.

Extensive association of HuR with hnRNP proteins within immunoselected hnRNP and mRNP complexes.

Regulated gene expression at the post-transcriptional level in higher eukaryotes is based on a network of interactions among RNA-binding proteins (RBPs) operating within multifactorial ribonucleoprotein (RNP) complexes, notably heterogeneous nuclear ribonucleoprotein (hnRNP) and mRNP complexes. We are interested in interactions involving hnRNP proteins participating in several steps of mRNA processing (mainly pre-mRNA splicing) and HuR with an established role in stability/translation of associated mRNAs. hnRNP and HuR proteins have a major nucleoplasmic localization and ability to shuttle between nucleus and cytoplasm. We report here on interactions between hnRNP and HuR proteins that were identified in the context of isolated hnRNP and mRNP complexes. This was done by the application of immunoprecipitation and pull-down assays on different sub-cellular fractions prepared from cells of human and mouse origin, as well as in vivo localization studies. A range of specific associations of HuR with the shuttling hnRNP A1 and A3 and the non-shuttling hnRNP C1/C2 was identified and ascribed discrete properties with respect to stability to RNase A and increasing salt, as well as to cellular distribution. The likelihood of a biological relevance of these associations was tested under heat shock conditions in growing cells, which appeared to affect both the sub-nuclear distribution and interaction of HuR with hnRNPs. The establishment of an extensive association of HuR with hnRNP components of nuclear hnRNP/mRNP and cytoplasmic mRNP complexes supports its broader participation in mRNA processing events than initially anticipated.

hnRNP M interacts with PSF and p54(nrb) and co-localizes within defined nuclear structures.

The abundant heterogeneous nuclear ribonucleoprotein M (hnRNP M) is able to associate with early spliceosomes and to influence splicing patterns of specific pre-mRNAs. Here, by a combination of immunoprecipitation and pull-down assays, we have identified PSF (polypyrimidine tract-binding protein-associated splicing factor) and p54(nrb), two highly related proteins involved in transcription and RNA processing, as new binding partners of hnRNP M. HnRNP M was found to co-localize with PSF within a subset of nuclear paraspeckles and to largely co-fractionate with PSF and p54(nrb) in biochemical nuclear matrix preparations. In cells transfected with an alternatively spliced preprotachykinin (PPT) minigene expression of hnRNP M promoted exon skipping while expression of PSF favours exon inclusion. The latter effect was reverted specifically by co-expressing the full length hnRNP M or a deletion mutant capable of interaction with PSF and p54(nrb). Together our data provide new insights and some functional implications on the hnRNP M network of interactions.

Human U1 snRNA forms a new chromatin-associated snRNP with TAF15.

The U1 small nuclear RNA (snRNA)--in the form of the U1 spliceosomal Sm small nuclear ribonucleoprotein particle (snRNP) that contains seven Sm and three U1-specific RNP proteins-has a crucial function in the recognition and removal of pre-messenger RNA introns. Here, we show that a fraction of human U1 snRNA specifically associates with the nuclear RNA-binding protein TBP-associated factor 15 (TAF15). We show that none of the known protein components of the spliceosomal U1-Sm snRNP interacts with the newly identified U1-TAF15 snRNP. In addition, the U1-TAF15 snRNP tightly associates with chromatin in an RNA-dependent manner and accumulates in nucleolar caps upon transcriptional inhibition. The Sm-binding motif of U1 snRNA is essential for the biogenesis of both U1-Sm and U1-TAF15 snRNPs, suggesting that the U1-TAF15 particle is produced by remodelling of the U1-Sm snRNP. A demonstration that human U1 snRNA forms at least two structurally distinct snRNPs supports the idea that the U1 snRNA has many nuclear functions.

Comparative qualitative and quantitative analysis of scleroderma (systemic sclerosis) serologic immunoassays.

The heterogeneity of autoantibody specificities occurring in sera from patients with systemic sclerosis (SSc) raised the necessity of developing various methodologies for their detection. A cohort of 150 SSc patients were selected and tested by Indirect Immunofluorescence (IIF), Counterimmunoelectrophoresis (CIE), Immunoblot (IB) using various extracts as antigenic source and RNA precipitation. By preparing a nuclear (IB-nuclear) and a metaphase chromosomal-enriched extract (IB-MC-pellet) from HeLa cells as well as a nucleolar (IB-nucleolar) and a histone (IB-histone) extract from rat liver nuclei, we assessed their sensitivity and specificity for anti-Topo I, anti-U3RNP, anti-H1, anti-snRNPs antibodies and ACA. IB-nuclear revealed the highest frequency of anti-Topo I antibodies, while CIE, IB-nucleolar and IB-MC-pellet, when compared to IB-nuclear showed a sensitivity of 89%, 87% and 95%, respectively. IB-MC-pellet was unique for ACA recognition, while IB-nucleolar and IB-MC-pellet showed excellent sensitivity for anti-U3RNP and anti-H1 antibody detection. We conclude that IB-nuclear is a highly sensitive system for anti-Topo I antibodies determination, but CIE reveals a good sensitivity to be used as a first screening test. IB-nucleolar or IB-MC-pellet are important techniques to detect the variety of antibodies to nucleolus and chromatin-related constituents. A novel specificity against a 28kD nucleolar protein, non-associated with RNAs is also presented.

Multiple specificities of autoantibodies against hnRNP A/B proteins in systemic rheumatic diseases and hnRNP L as an associated novel autoantigen.

Spliceosomal small nuclear ribonucleoproteins (U-snRNPs) are frequent and specific targets of autoantibodies in systemic rheumatic diseases. The abundant, functionally related heterogeneous nuclear ribonucleoprotein complexes (hnRNPs) have later defined as a new target of autoantibodies, of which their immunochemical/immunogenic and pathogenic properties are still under investigation. Among hnRNP proteins, those belonging to the A/B type are considered as the major autoantigens targeted by antibodies in sera of patients suffering with rheumatoid arthritis (RA), systemic lupus erythematosus (SLE) and mixed connective tissue disease (MCTD). By performing an extensive screening using rat liver 40S hnRNP antigenic material, we document here the existence of multiple specificities of anti-hnRNP A/B autoantibodies in sera of Greek patients suffering with a spectrum of systemic rheumatic diseases. This included patients with SLE, Sjogren's syndrome (SS), Scleroderma (SSc) and a specific group of patients mostly with undifferentiated disease (UD patients). In total, four distinct types of anti-hnRNP A/B autoantibodies have been recognized. The first two referred to the known anti-hnRNPA2(RA33) and anti-hnRNP A1; the latter appearing very rarely. The third was of the new type selectively reacting with hnRNP B2 and an hnRNP A3 variant, while the fourth was a rare case of anti-hnRNP B2 alone. In addition, a novel specificity of autoantibodies against hnRNP L protein was identified in association with anti-hnRNP A/B antibodies. The co-existence within a serum of autoantibodies having variable specificity for hnRNP A/B and L autoantigens was shown. Specific immunochemical features of the identified autoantibodies are presented and a possible mechanism of autoepitope spreading within protein components of hnRNP complexes is discussed.

Microarray analysis of the differential transformation mediated by Kirsten and Harvey Ras oncogenes in a human colorectal adenocarcinoma cell line.

Colorectal cancer arises after a series of mutational events in the colon epithelia and is often used as a model of the multistep progression of tumorigenesis. Mutations in Ki-Ras have been detected in some 50% of cases and are thought to occur at an early stage. Almost never do mutations arise in the loci of other Ras isoforms (Ha- and N-), leading to the assumption that Ki-Ras plays a unique role in tumorigenesis. In order to examine the distinctive function that Ki-Ras plays in cancer development in the colon, we introduced constitutively active mutant Ki- and Ha-Ras genes into an intermediate-stage colon adenoma cell line (Caco-2). We found that mutant active Ha-RasV12 was more efficient at transforming these colon epithelial cells as assessed by anchorage-independent growth, tumor formation in SCID mice and the development of mesenchymal morphology compared to transformation by Ki-RasV12. We conducted microarray analysis in an attempt to reveal the genes whose aberrant expression is a direct result of overexpression of either Ki-RasV12 or Ha-RasV12. We used Clontech's Atlas cancer cDNA (588 genes) and RZPD's Onco Set 1 (1,544 genes) arrays. We identified fewer genes that were commonly regulated than were differentially expressed between Ki- and Ha-RasV12 isoforms. Specifically, we found that Ki-RasV12 regulated genes involved in cytokine signaling, cell adhesion and colon development, whereas Ha-RasV12 mainly regulated genes involved in controlling cell morphology, correlating to an epithelial-mesenchymal transition only observed in these cells. Our results demonstrate how 2 Ras isoforms regulate disparate biologic processes, revealing a number of genes whose deregulated expression may influence colon carcinogenesis (supplementary material for this article can be found on the International Journal of Cancer website at http://www.interscience.wiley.com/jpages/0020-7136/suppmat/index.html).

Association of the 72/74-kDa proteins, members of the heterogeneous nuclear ribonucleoprotein M group, with the pre-mRNA at early stages of spliceosome assembly.

We have investigated the role played in precursor mRNA (pre-mRNA) splicing by the protein pair of molecular size 72/74 kDa, which are integral components of a discrete subset of heterogeneous nuclear (hn) ribonucleoproteins (RNPs) named large heterogeneous nuclear RNP (LH-nRNP). This 72/74 kDa pair of proteins has been shown to belong to the hnRNP M group, and are referred to as 72/74(M). By applying specific immunoprecipitation assays in a consecutive series of splicing reactions in vitro, the antigenic 72/74(M) protein species were found to associate with the pre-mRNA and not the intermediate or final products of splicing. Kinetic studies, combined with isolation of pre-spliceosomal and spliceosomal complexes from the splicing reaction, indicated a loose association of 72/74(M) with both the initially formed H assembly and the first splicing-committed E complex. Stable binding was seen at a later stage of the reaction, well in advance of the appearance of the first intermediate products of RNA splicing. Evidence is provided that supports the almost exclusive association of 72/74(M) with pre-mRNA within the pre-spliceosomal A complex. This dynamic binding appeared to involve pre-mRNA sites similar to those of spliceosomal U1 and U2 small nuclear RNP complexes. Moreover, a preferential binding to a truncated RNA containing the 5' exon-intron part, rather than the intron-3' exon part, of pre-mRNA was observed.

Nuclear actin is associated with a specific subset of hnRNP A/B-type proteins.

Pre-mRNP complexes were isolated from rat liver nuclei as 40S hnRNP particles, and actin-binding proteins were collected by DNase I affinity chromatography. The bound proteins were analyzed by 2D gel electrophoresis, and the following five hnRNP A/B-type proteins were identified by tandem mass spectrometry: DBP40/CBF-A (CArG binding factor A), a minor hnRNP A2 variant and three minor hnRNP A3 (mBx) variants. DBP40 was chosen for further analysis of the association of actin with the pre-mRNP complex. It was shown in vitro that purified actin binds to recombinant DBP40 suggesting that the interaction between actin and DBP40 is direct in the pre-mRNP particles. The association of actin with DBP40 was further explored in vivo. It was shown in a transfection study that DBP40 appears both in the nucleus and cytoplasm. Microinjection experiments revealed that DBP40 is exported from the nucleus to the cytoplasm. Finally, RNA-protein and protein-protein cross-linking experiments showed that DBP40 interacts with poly(A)(+) RNA as well as actin, both in the nucleus and cytoplasm. We propose that actin associated with DBP40, and perhaps with additional hnRNP A/B-type proteins, is transferred from nucleus to cytoplasm bound to mRNA.