Nuclear non-polyadenylated RNAs containing the first intervening sequence of the major late premessenger RNA from adenovirus-2: characterization and distribution in ribonucleoproteins

The nuclear non-polyadenylated RNA from HeLa cells infected with adenovirus-2 was examined for the presence of molecules containing the first intervening sequence (IVS1) of the major late premessenger RNA. Four molecules with the approximate size of free IVS1 in sucrose gradients (1021 nucleotides) were separated by polyacrylamide gel electrophoresis and characterized by complementary methods: S1 nuclease mapping, susceptibility to debranching enzyme, RNAase-H-directed cleavage. The results indicate that the most abundant RNA form is the excised lariat IVS1. We also find linear IVS1 and a randomly nicked lariat, the latter probably being made during RNA isolation. The fourth RNA is a leader 1-IVS1 molecule. No truncated IVS1 which might indicate that IVS1 is excised by several cycle of cleavage-ligation was detected. A study of the distribution of the four RNAs in hnRNP shows that they are part of RNPs of about 70 S. However, each RNP has distinct sedimentation characteristics and sensitivity to salt dissociation. Together, the results suggest that the excised lariat IVS1 is released from the large late premRNP under the form of a 70 S RNP, where it is linearized.     

Ribonucleoprotein complex formation during pre-mRNA splicing in vitro.

The ribonucleoprotein (RNP) structures of the pre-mRNA and RNA processing products generated during in vitro splicing of an SP6/beta-globin pre-mRNA were characterized by sucrose gradient sedimentation analysis. Early, during the initial lag phase of the splicing reaction, the pre-mRNA sedimented heterogeneously but was detected in both 40S and 60S RNP complexes. An RNA substrate lacking a 3' splice site consensus sequence was not assembled into the 60S RNP complex. The two splicing intermediates, the first exon RNA species and an RNA species containing the intron and the second exon in a lariat configuration (IVS1-exon 2 RNA species), were found exclusively in a 60S RNP complex. These two splicing intermediates cosedimented under a variety of conditions, indicating that they are contained in the same RNP complex. The products of the splicing reaction, accurately spliced RNA and the excised IVS1 lariat RNA species, are released from the 60S RNP complex and detected in smaller RNP complexes. Sequence-specific RNA-factor interactions within these RNP complexes were evidenced by the preferential protection of the pre-mRNA branch point from RNase A digestion and protection of the 2'-5' phosphodiester bond of the lariat RNA species from enzymatic debranching. The various RNP complexes were further characterized and could be distinguished by immunoprecipitation with anti-Sm and anti-(U1)RNP antibodies.     

Fate of the junction phosphate in alternating forward and reverse self-splicing reactions of group II intron RNA.

The RNA-catalysed self-splicing reaction of group II intron RNA is assumed to proceed by two consecutive transesterification steps, accompanied by lariat formation. This is effectively analogous to the small nuclear ribonucleoprotein (snRNP)-mediated nuclear pre-mRNA splicing process. Upon excision from pre-RNA, a group II lariat intervening sequence (IVS) has the capacity to re-integrate into its cognate exons, reconstituting the original pre-RNA. The process of reverse self-splicing is presumed to be a true reversion of both transesterification steps used in forward splicing. To investigate the fate of the esterified phosphate groups in splicing we assayed various exon substrates (5'E-*p3'E) containing a unique 32P-labelled phosphodiester at the ligation junction. In combined studies of alternating reverse and forward splicing we have demonstrated that the labelled phosphorus atom is displaced in conjunction with the 3' exon from the ligation junction to the 3' splice site and vice versa. Neither the nature of the 3' exon sequence nor its sequence composition acts as a prominent determinant for both substrate specificity and site-specific transesterification reactions catalysed by bI1 IVS. A cytosine ribonucleotide (pCp; pCOH) or even deoxyoligonucleotides could function as an efficient substitute for the authentic 3' exon in reverse and in forward splicing. Furthermore, the 3' exon can be single monophosphate group. Upon incubation of 3' phosphorylated 5' exon substrate (5'E-*p) with lariat IVS the 3'-terminal phosphate group is transferred in reverse and forward splicing like an authentic 3' exon, but with lower efficiency. In the absence of 3' exon nucleotides, it appears that substrate specificity is provided predominantly by the base-pairing interactions of the intronic exon binding site (EBS) sequences with the intron binding site (IBS) sequences in the 5' exon. These studies substantiate the predicted transesterification pathway in forward and reverse splicing and extend the catalytic repertoire of group II IVS in that they can act as a potential and sequence-specific transferase in vitro.     

Distinct RNP complexes of shuttling hnRNP proteins with pre-mRNA and mRNA: candidate intermediates in formation and export of mRNA

Nascent pre-mRNAs associate with hnRNP proteins in hnRNP complexes, the natural substrates for mRNA processing. Several lines of evidence indicate that hnRNP complexes undergo substantial remodeling during mRNA formation and export. Here we report the isolation of three distinct types of pre-mRNP and mRNP complexes from HeLa cells associated with hnRNP A1, a shuttling hnRNP protein. Based on their RNA and protein compositions, these complexes are likely to represent distinct stages in the nucleocytoplasmic shuttling pathway of hnRNP A1 with its bound RNAs. In the cytoplasm, A1 is associated with its nuclear import receptor (transportin), the cytoplasmic poly(A)-binding protein, and mRNA. In the nucleus, A1 is found in two distinct types of complexes that are differently associated with nuclear structures. One class contains pre-mRNA and mRNA and is identical to previously described hnRNP complexes. The other class behaves as freely diffusible nuclear mRNPs (nmRNPs) at late nuclear stages of maturation and possibly associated with nuclear mRNA export. These nmRNPs differ from hnRNPs in that while they contain shuttling hnRNP proteins, the mRNA export factor REF, and mRNA, they do not contain nonshuttling hnRNP proteins or pre-mRNA. Importantly, nmRNPs also contain proteins not found in hnRNP complexes. These include the alternatively spliced isoforms D01 and D02 of the hnRNP D proteins, the E0 isoform of the hnRNP E proteins, and LRP130, a previously reported protein with unknown function that appears to have a novel type of RNA-binding domain. The characteristics of these complexes indicate that they result from RNP remodeling associated with mRNA maturation and delineate specific changes in RNP protein composition during formation and transport of mRNA in vivo.     

Detection of beta-globin mRNA precursor in heterogeneous nuclear ribonucleoprotein associated with U1-RNP by using anti-RNP antibody

Heterogeneous nuclear RNA-ribonucleoprotein (hnRNP) fractions were isolated from Friend erythroleukemia cells and separated by 15-45% sucrose gradient centrifugation. The distribution of small nuclear RNAs (snRNAs) in hnRNP fractions indicated that the snRNAs are associated with hnRNP particles. HnRNP fractions were incubated with normal IgG or anti-U1 RNP IgG, and the resulting immunocomplexes were isolated by binding to a protein A-Sepharose column. HnRNP was found in bound fractions only when anti-U1 RNP IgG was used. By Northern hybridization of RNA extracted from the immunocomplexes with a beta-globin genomic DNA probe, 15S beta-globin mRNA precursors and 10S mature mRNA were detected. These findings suggest the existence of a complex of U1 RNP particles and hnRNP particles containing beta-globin pre-mRNA.     

hnRNP I, the polypyrimidine tract-binding protein: distinct nuclear localization and association with hnRNAs.

Many hnRNP proteins and snRNPs interact with hnRNA in the nucleus of eukaryotic cells and affect the fate of hnRNA and its processing into mRNA. There are at least 20 abundant proteins in vertebrate cell hnRNP complexes and their structure and arrangement on specific hnRNAs is likely to be important for the processing of pre-mRNAs. hnRNP I, a basic protein of ca. 58,000 daltons by SDS-PAGE, is one of the abundant hnRNA-binding proteins. Monoclonal antibodies to hnRNP I were produced and full length cDNA clones for hnRNP I were isolated and sequenced. The sequence of hnRNP I (59,632 daltons and pI 9.86) demonstrates that it is identical to the previously described polypyrimidine tract-binding protein (PTB) and shows that it is highly related to hnRNP L. The sequences of these two proteins, I and L, define a new family of hnRNP proteins within the large superfamily of the RNP consensus RNA-binding proteins. Here we describe experiments which reveal new and unique properties on the association of hnRNP I/PTB with hnRNP complexes and on its cellular localization. Micrococcal nuclease digestions show that hnRNP I, along with hnRNP S and P, is released from hnRNP complexes by nuclease digestion more readily than most other hnRNP proteins. This nuclease hypersensitivity suggests that hnRNP I is bound to hnRNA regions that are particularly exposed in the complexes. Immunofluorescence microscopy shows that hnRNP I is found in the nucleoplasm but in addition high concentrations are detected in a discrete perinucleolar structure. Thus, the PTB is one of the major proteins that bind pre-mRNAs; it is bound to nuclease-hypersensitive regions of the hnRNA-protein complexes and shows a novel pattern of nuclear localization.     

The hnRNP C proteins contain a nuclear retention sequence that can override nuclear export signals

Nascent pre-mRNAs associate with the abundant heterogeneous nuclear RNP (hnRNP) proteins and remain associated with them throughout the time they are in the nucleus. The hnRNP proteins can be divided into two groups according to their nucleocytoplasmic transport properties. One group is completely restricted to the nucleus in interphase cells, whereas the other group, although primarily nuclear at steady state, shuttles between the nucleus and the cytoplasm. Nuclear export of the shuttling hnRNP proteins is mediated by nuclear export signals (NESs). Mounting evidence indicates that NES-bearing hnRNP proteins are mediators of mRNA export. The hnRNP C proteins are representative of the nonshuttling group of hnRNP proteins. Here we show that hnRNP C proteins are restricted to the nucleus not because they lack an NES, but because they bear a nuclear retention sequence (NRS) that is capable of overriding NESs. The NRS comprises approximately 78 amino acids and is largely within the auxiliary domain of hnRNP C1. We suggest that the removal of NRS-containing hnRNP proteins from pre- mRNA/mRNA is required for mRNA export from the nucleus and is an essential step in the pathway of gene expression.     

The heterogeneous nuclear ribonucleoproteins I and K interact with a subset of the ro ribonucleoprotein-associated Y RNAs in vitro and in vivo

The hY RNAs are a group of four small cytoplasmic RNAs of unknown function that are stably associated with at least two proteins, Ro60 and La, to form Ro ribonucleoprotein complexes. Here we show that the heterogeneous nuclear ribonucleoproteins (hnRNP) I and K are able to associate with a subset of hY RNAs in vitro and demonstrate these interactions to occur also in vivo in a yeast three-hybrid system. Experiments performed in vitro and in vivo with deletion mutants of hY1 RNA revealed its pyrimidine-rich central loop to be involved in interactions with both hnRNP I and K and clearly showed their binding sites to be different from the Ro60 binding site. Both hY1 and hY3 RNAs coprecipitated with hnRNP I in immunoprecipitation experiments performed with HeLa S100 extracts and cell extracts from COS-1 cells transiently transfected with VSV-G-tagged hnRNP-I, respectively. Furthermore, both anti-Ro60 and anti-La antibodies coprecipitated hnRNP I, whereas coprecipitation of hnRNP K was not observed. Taken together, these data strongly suggest that hnRNP I is a stable component of a subpopulation of Ro RNPs, whereas hnRNP K may be transiently bound or interact only with (rare) Y RNAs that are devoid of Ro60 and La. Given that functions related to translation regulation have been assigned to both proteins and also to La, our findings may provide novel clues toward understanding the role of Y RNAs and their respective RNP complexes.     

Molecular phylogenetics and functional evolution of major RNA recognition domains of recently cloned and characterized autoimmune RNA-binding particle

Heterogeneous nuclear ribonucleoproteins (hnRNPs) are spliceosomal macromole-cular assemblages and thus actively participate in pre-mRNA metabolism. They are composed of evolutionarily conserved and tandemly repeated motifs, where both RNA-binding and protein-protein recognition occur to achieve cellular activities. By yet unknown mechanisms, these ribonucleoprotein (RNP) particles are     

DDX6 recruits translational silenced human reticulocyte 15-lipoxygenase mRNA to RNP granules

Erythroid precursor cells lose the capacity for mRNA synthesis due to exclusion of the nucleus during maturation. Therefore, the stability and translation of mRNAs that code for specific proteins, which function in late stages of maturation when reticulocytes become erythrocytes, are controlled tightly. Reticulocyte 15-lipoxygenase (r15-LOX) initiates the breakdown of mitochondria in mature reticulocytes. Through the temporal restriction of mRNA translation, the synthesis of r15-LOX is prevented in premature cells. The enzyme is synthesized only in mature reticulocytes, although r15-LOX mRNA is already present in erythroid precursor cells. Translation of r15-LOX mRNA is inhibited by hnRNP K and hnRNP E1, which bind to the differentiation control element (DICE) in its 3' untranslated region (3'UTR). The hnRNP K/E1-DICE complex interferes with the joining of the 60S ribosomal subunit to the 40S subunit at the AUG. We took advantage of the inducible human erythroid K562 cell system that fully recapitulates this process to identify so far unknown factors, which are critical for DICE-dependent translational regulation. Applying RNA chromatography with the DICE as bait combined with hnRNP K immunoprecipitation, we specifically purified the DEAD-box RNA helicase 6 (DDX6) that interacts with hnRNP K and hnRNP E1 in a DICE-dependent manner. Employing RNA interference and fluorescence in situ hybridization, we show that DDX6 colocalizes with endogenous human (h)r15-LOX mRNA to P-body-like RNP granules, from which 60S ribosomal subunits are excluded. Our data suggest that in premature erythroid cells translational silencing of hr15-LOX mRNA is maintained by DDX6 mediated storage in these RNP granules.     

PTB/hnRNP I is required for RNP remodeling during RNA localization in Xenopus oocytes

Transport of specific mRNAs to defined regions within the cell cytoplasm is a fundamental mechanism for regulating cell and developmental polarity. In the Xenopus oocyte, Vg1 RNA is transported to the vegetal cytoplasm, where localized expression of the encoded protein is critical for embryonic polarity. The Vg1 localization pathway is directed by interactions between key motifs within Vg1 RNA and protein factors recognizing those RNA sequences. We have investigated how RNA-protein interactions could be modulated to trigger distinct steps in the localization pathway and found that the Vg1 RNP is remodeled during cytoplasmic RNA transport. Our results implicate two RNA-binding proteins with key roles in Vg1 RNA localization, PTB/hnRNP I and Vg1RBP/vera, in this process. We show that PTB/hnRNP I is required for remodeling of the interaction between Vg1 RNA and Vg1RBP/vera. Critically, mutations that block this remodeling event also eliminate vegetal localization of the RNA, suggesting that RNP remodeling is required for localization.     

1H, 13C, and 15N NMR assignments and global folding pattern of the RNA-binding domain of the human hnRNP C proteins.

The hnRNP C1 and C2 proteins are abundant nuclear proteins that bind avidly to heterogeneous nuclear RNAs (hnRNAs) and appear to be involved with pre-mRNA processing. The RNA-binding activity of the hnRNP C proteins is contained in the amino-terminal 94 amino acid RNA-binding domain (RBD) that is identical for these two proteins. We have obtained the 1H, 13C, and 15N NMR assignments for the RBD of the human hnRNP C proteins. The assignment process was facilitated by extensive utilization of three- and four-dimensional heteronuclear-edited spectra. Sequential assignments of the backbone resonances were made using a combination of 15N-edited 3D NOESY-HMQC, 3D TOCSY-HMQC, and 3D TOCSY-NOESY-HSQC as well as 3D HNCA, HNCO, and HCACO spectra. Side-chain resonances were assigned using 3D HCCH-COSY and 3D HCH-TOCSY spectra. Four-dimensional 13C/13C-edited NOESY and 13C/15N-edited NOESY experiments were used to unambigously resolve NOEs. The overall global folding pattern was established by calculating a set of preliminary structures using constraints derived from the sequential NOEs and a small number of long-range NOEs. The beta alpha beta-beta alpha beta domain structure exhibits an antiparallel beta-sheet with the conserved RNP 1 and RNP 2 sequences [Dreyfuss et al. (1988) Trends Biochem. Sci. 13, 86-91] located adjacent to one another as the two inner strands of the beta-sheet.     

Ribonucleoprotein organization of eukaryotic RNA. XXX. Evidence that U1 small nuclear RNA is a ribonucleoprotein when base-paired with pre-messenger RNA in vivo

U1 small nuclear RNA is thought to be involved in messenger RNA splicing by binding to complementary sequences in pre-mRNA. We have investigated intermolecular base-pairing between pre-mRNA (hnRNA) and U1 small nuclear RNA by psoralen crosslinking in situ, with emphasis on ribonucleoprotein structure. HeLa cells were pulse-labeled with [3H]uridine under conditions in which hnRNA is preferentially labeled. Isolated nuclei were treated with aminomethyltrioxsalen , which produces interstrand crosslinks at sites of base-pairing between hnRNA and U1 RNA. hnRNA-ribonucleoprotein (hnRNP) particles were isolated in sucrose gradients containing 50% formamide, to dissociate non-crosslinked U1 RNA, and then analyzed by immunoaffinity chromatography using a human autoantibody that is specific for the ribonucleoprotein form of U1 RNA (anti-U1 RNP). After psoralen crosslinking, pulse-labeled hnRNA in hnRNP particles reproducibly bound to anti-U1 RNP. The amount of hnRNA bound to anti-U1 RNP was reduced 80 to 85% when psoralen crosslinking of nuclei was omitted, or if the crosslinks between U1 RNA and hnRNA were photo-reversed prior to immunoaffinity chromatography. Analysis of the proteins bound to anti-U1 RNP after crosslink reversal revealed polypeptides having molecular weights similar to those previously described for U1 RNP. These proteins did not bind to control, non-immune human immunoglobulin G. These results indicate that the subset of nuclear U1 RNA that is base-paired with hnRNA at a given time in the cell is a ribonucleoprotein. This raises the possibility that these proteins, as well as U1 RNA itself, may participate in pre-mRNA splice site recognition by U1 RNP.     

Monoclonal antibodies to heterogeneous nuclear RNA-protein complexes. The core proteins comprise a conserved group of related polypeptides

Hybridomas secreting monoclonal antibodies that react with heterogeneous nuclear ribonucleoprotein (hnRNP) core proteins have been isolated by immunizing BALB/c mice with RNP particles isolated from chicken and screening the fusion products with mouse RNP complexes. The antibodies show varying affinities for the hnRNP core proteins that have been blotted onto nitrocellulose. The majority of the immunoglobulins react with all the core group proteins although several recognize subsets of the hnRNP polypeptides. The clones are specific for different antigenic determinants as shown by their inability to compete with one another for binding sites. A mild proteolytic digestion of hnRNP proteins generates fragments that have uniformly lost 12 kDa and contain the antigenic determinants recognized by several of the monoclonal antibodies. Thus, it appears the core proteins comprise a family of related polypeptides possessing underlying structural similarities. Polypeptides similar in number and molecular weights that have antigenic determinants cross-reactive with those of mouse RNP have been found in a number of organisms, thereby emphasizing their possible common structure and function in higher eukaryotes. No difference in the distribution within the cell of individual or groups of core proteins has so far been detected by indirect immunofluorescence.     

Fractionation of constituents of ribonucleoproteins containing heterogeneous nuclear ribonucleic acid.

A method of fractionation of hnRNP constituents adaptable to large-scale preparation is presented. It is based on differential resistance to salt dissociation of the two classes of units of hnRNP, the 30--50S monoparticles and the heterogeneous complexes. The monoparticle proteins were released from hnRNP by 0.4 M NaCl. They were separated from the salt-resistant RNP corresponding to the heterogeneous complexes in three steps: chromatography on DEAE-cellulose, high-speed centrifugation, and Bio-Gel chromatography. The latter chromatography permitted a first fractionation of monoparticle proteins according to molecular weight. Such fractions may serve for purification of individual proteins of molecular weight below 80 000. After the two first steps, two fractions of salt-resistant RNP were obtained. In addition to heterogeneous RNA up to 30 S, small nuclear RNAs were detected which represented 6% of total RNA. The protein pattern was complex, and no clear-cut segregation of groups of proteins could be observed between the two fractions. They were both highly enriched in phosphoproteins as compared to nomoparticle proteins. In another fraction corresponding to the void volume of Bio-Gel chromatography, one-third of the RNA was small nuclear RNA. It is suggested that this fraction contains snRNP in addition to free proteins of molecular weight above 80 000 and to salt-resistant RNP similar to those described above but of small size.