A RNA helix-destabilizing protein is a major component of Artemia salina nuclear ribonucleoproteins

Isolation of hnRNP complexes from Drosophila melanogaster

Nascent RNA polymerase II transcripts, heterogeneous nuclear RNAs (hnRNAs), become associated with nuclear proteins (hnRNP Proteins), and their processing into mRNAs takes place in these hnRNP complexes. hnRNP complexes have previously been purified from vertebrate cells. Here we report the isolation of hnRNP complexes from an invertebrate organism, the fruitfly Drosophila melanogaster. Candidate hnRNP proteins were purified from D. melanogaster embryos by ssDNA affinity chromatography, and mAbs were produced to many of the major proteins. Genuine hnRNP proteins were identified by several criteria, including nucleoplasmic localization, association with nascent transcripts, crosslinking to poly(A)-containing RNA in living cells, and amino acid sequence. In addition, mAbs that cross-react between the fruitfly and human hnRNP proteins were obtained. Most importantly, using hnRNP-specific mAbs we have purified the hnRNP complexes from D. melanogaster cells. These RNAase-sensitive complexes contain at least 10 major proteins designated hrps, the most abundant proteins having apparent molecular masses of 36, 38, 39, 40, 44, 48, 54, 62, 70, and 75 kD. cDNAs and complete sequences for several of these proteins have been obtained and are presented in the accompanying paper (Matunis, E. L., M. J. Matunis, and G. Dreyfuss. 1992. J. Cell Biol. 116:257-269). The purification of D. melanogaster hnRNP complexes will facilitate genetic and cytological studies on the function of hnRNA-binding proteins and on the posttranscriptional regulation of gene expression.

A suppressor of yeast spp81/ded1 mutations encodes a very similar putative ATP-dependent RNA helicase

The spp81/ded1 mutations were isolated as suppressors of a Saccharomyces cerevisiae pre-mRNA splicing mutation, prp8-1. The SPP81/DED1 gene encodes a putative ATP-dependent RNA helicase. While attempting to clone the wild-type SPP81/DED1 gene we isolated plasmids which were able to suppress the cold-sensitive growth defect of spp81 mutants. These plasmids encoded a gene (named DBP1) which mapped to chromosome XVI and not to the SPP81/DED1 locus on chromosome XV. The cloned gene suppressed the defect of spp81/ded1 mutants when present on both high and low copy-number plasmids but complemented spp81/ded1 null mutants only when present on high copy-number plasmids. In contrast to the SPP81/DED1 gene the DBP1 gene was not essential for cell viability. The nucleotide sequence of the DBP1 gene revealed that it also encoded a putative ATP-dependent RNA helicase which showed considerable similarity at the amino acid level to the SPP81/DED1 protein.

Splice site selection, rate of splicing, and alternative splicing on nascent transcripts

Based on ultrastructural analysis of actively transcribing genes seen in electron micrographs, we present evidence that pre-mRNA splicing occurs with a reasonable frequency on the nascent transcripts of early Drosophila embryo genes and that splice site selection may generally precede polyadenylation. The details of the process observed are in agreement with results from in vitro splicing systems but differ in the more rapid completion of in vivo splicing. For those introns that are removed cotranscriptionally, a series of events is initiated following 3' splice site synthesis, beginning with ribonucleoprotein (RNP) particle formation at the 3' splice site within 48 sec, intron loop formation within 2 min, and splicing within 3 min. The initiation of the process is correlated with 3' splice site synthesis but is independent of 5' splice site synthesis, the position of the intron within the transcript, and the age or length of the transcript. In some cases, introns are removed from the 5' end of a transcript before introns are synthesized at the 3' end, supporting a possible role for the order of transcription in splice site pairing. In general, our observations are consistent with the 'first-come-first-served' principle of splice site selection, although an observed example of exon skipping indicates that alternative splicing possibilities can be accommodated within this general framework.

Cloning of cDNA sequences for an Artemia salina hnRNP protein: evidence for conservation through evolution

A cDNA clone was isolated for Artemia salina protein HD40, a component of heterogenous nuclear ribonucleoproteins. Enriched Artemia 15S poly(A)+ RNA was used as a template and double-stranded cDNA sequences were inserted into the Pst I restriction endonuclease site of E. coli plasmid pBR322. Recombinant colonies were analyzed by positive hybrid selection of poly(A)+ RNA that directs the synthesis of protein HD40 in an in vitro assay. In vitro translation of the mRNA selected by recombinant clone 87HD yields a protein that is immunoprecipitated by anti-HD40 antibodies and that comigrates with authentic HD40 on gel electrophoresis. Partial proteolysis of protein HD40 and the in vitro translated product selected by clone 87HD produces the same peptide patterns. The size of the cloned insert is about 820 bp. The length of HD40 mRNA as determined by Northern blot analysis, is about 1500 nucleotides. Southern blot analysis performed with DNA of different species (plant, avian, mammal) shows cross-hybridizing bands when probed with clone 87HD DNA suggesting that the HD40 gene is evolutionarily conserved.

Secondary structure of splice sites in adenovirus mRNA precursors

In order to investigate the possible role of RNA secondary structure in determining the efficiency and specificity of mRNA splicing, the structures of sequences at three acceptor splice sites in adenovirus were studied. Transcripts spanning intron-exon junctions were synthesized using SP6 RNA polymerase and analyzed using single and double-strand specific nucleases. Distinctive patterns of nuclease cleavage were observed for each of the 3 sites examined. At both sites in the E2a region sequences adjacent to the splice sites were particularly susceptible to digestion with T1 and S1 nucleases. In contrast, a splice site for hexon mRNA was largely resistant to these nucleases. The results obtained suggest that the conformation of the RNA at some, but not all, acceptor sites may enhance the accessibility of these sites to factors involved in splicing nuclear RNA and confirm the presence of a large, previously predicted hairpin structure centered on the acceptor site at 67 map units.

Identification and properties of the 38 000-Mr poly(A)-binding protein of non-polysomal messenger ribonucleoproteins of cryptobiotic gastrulae of Artemia salina

The Mr-38 000 poly(A)-binding protein interacts with synthetic and natural RNA. A sequence-independent stoichiometry of one protein per 8 - 12 nucleotides is measured by filter binding and sucrose gradient centrifugation. Specificity for the poly(A) sequence is demonstrated from poly(A)/RNA mixing experiments. The poly(A)-binding protein has been identified as the helix-destabilizing protein HD40[Marvil, D. K., Nowak, L. and Szer, W. (1980) J. Biol. Chem. 255, 6466 - 6472] and is characterized by the existence of at least seven ionic species with a pI ranging from 9.2 to 6.6. Acidic ionic species are generated by phosphorylation with mRNP-associated protein kinase. Different ionic species are present on free mRNP and ribosomes-mRNP preinitiation complexes. The poly(A)-binding protein affects mRNA translation and (A)4 polyadenylation. The multifunctionality of the protein is discussed.

A large inverted repeat sequence overlaps two acceptor splice sites in adenovirus

The distribution of nucleotide sequences resembling functional sites for mRNA splicing was examined by computer-directed searches in order to determine what factors may influence splice site selection in nuclear precursors. In particular, the distribution of large potentially stable hairpin structures or regions of extensive dyad symmetry was studied in adenovirus sequences. One region, spanning 106 nucleotides, was found at 66.4 map units, overlapping back-to-back acceptor sites for two mRNA molecules, those coding for the 100K protein and the 72K DNA binding protein, which are transcribed from opposite strands. This region displays exceptional dyad symmetry and is potentially capable of forming a single, highly stable hairpin when transcribed. It seems likely that the secondary structure as well as the primary structure of RNA plays a role in determining the correct splicing of these mRNA molecules.

Reconstitution of nucleoprotein complexes with mammalian heterogeneous nuclear ribonucleoprotein (hnRNP) core proteins

Newly transcribed heterogeneous nuclear RNA (hnRNA) in the eucaryote cell nucleus is bound by proteins, giving rise to large ribonucleoprotein (RNP) fibrils with an inherent substructure consisting largely of relatively homogeneous approximately 20-nm 30S particles, which contain core polypeptides of 34,000-38,000 mol wt. To determine whether this group of proteins was sufficient for the assembly of the native beaded nucleoprotein structure, we dissociated 30S hnRNP purified from mouse ascites cells into their component proteins and RNA by treatment with the ionic detergent sodium deoxycholate and then reconstituted this complex by addition of Triton X-100 to sequester the deoxycholate. Dissociation and reassembly were assayed by sucrose gradient centrifugation, monitoring UV absorbance, protein composition, and radiolabeled nucleic acid, and by electron microscopy. Endogenous RNA was digested and reassembly of RNP complexes carried out with equivalent amounts of exogenous RNA or single-stranded DNA. These complexes are composed exclusively of groups of n 30S subunits, as determined by sucrose gradient and electron microscope analysis, where n is the length of the added nucleic acid divided by the length of nucleic acid bound by one native 30S complex (about 1,000 nucleotides). When the nucleic acid: protein stoichiometry in the reconstitution mixture was varied, only complexes composed of 30S subunits were formed; excess protein or nucleic acid remained unbound. These results strongly suggest that core proteins determine the basic structural properties of 30S subunits and hence of hnRNP. In vitro construction of RNP complexes using model nucleic acid molecules should prove useful to the further study of the processing of mRNA.

In vitro assembly of a pre-messenger ribonucleoprotein

Transcription of the Bal I E restriction fragment of adenovirus DNA by RNA polymerase II in a HeLa cell extract produces a RNA transcript 1,712 nucleotides in length. This transcript contains the first two elements of the tripartite leader that, in vivo, is spliced onto the late mRNAs. We have found that this adenovirus 2 transcript forms a specific ribonucleoprotein complex (RNP) in this in vitro system. The RNP particle sediments in sucrose gradients as a monodisperse peak at 50 S and has a buoyant density of 1.34 g/cm3 in Cs2SO4, indicating the same 4:1 protein/RNA composition as native nuclear RNPs that contain pre-mRNA sequences (hnRNP). Moreover, the in vitro-assembled RNP is resistant to concentrations of NaCl that are known to dissociate nonspecific RNA-protein complexes. The adenovirus 2 transcript is precipitated by a monoclonal antibody for hnRNP core proteins. In addition, RNA-protein crosslinking of [alpha-32P]UTP-labeled transcript/RNP complexes reveals that the major proteins in contact with the RNA are the Mr 32,500-41,500 species known to be associated with hnRNA in vivo. These results demonstrate the in vitro assembly of a specific RNA polymerase II transcript into RNP. Moreover, because the 1,712-nucleotide adenovirus 2 transcript lacks poly(A) addition sites and because the leader sequences are not spliced appreciably in this in vitro system, it follows that RNP formation requires neither polyadenylylation nor splicing, nor is it sufficient to cause the latter.

Subcellular distribution in Xenopus laevis oocytes of a microinjected poly(A)-binding protein from Artemia salina gastrulae

The poly(A)-binding protein P38 of non-polysomal mRNP from Artemia salina gastrulae was labelled by reductive methylation and microinjected into the cytoplasm of Xenopus laevis oocytes. The labelled protein has a half-life of approximately 20 h and accumulated in the nucleus of the oocyte. The kinetics of accumulation reached a plateau at about 15 h after microinjection. P38 accumulates in the nucleus to a final concentration 3.15 times higher than that reached by free diffusion. This fact suggests that P38, a cytoplasmic poly(A)-binding protein, might also play some role in the nucleus of the cell.

An assessment of the evidence for the role of ribonucleoprotein particles in the maturation of eukaryote mRNA

This article has sought to draw together, on the one hand, what is known of mRNA processing and its control and, on the other hand, what is known of the structure and validity of hnRNP and snRNP particles. At the same time, it has attempted to synthesize these two themes into a critical assessment of the evidence which suggests that the particles are intimately involved in processing. It cannot be said that the case is proven. The evidence is compelling but circumstantial. The last few years have seen the development of the first in vitro splicing systems (Weingartner and Keller, 1981; Goldenberg and Raskus, 1981; Kole and Weissman, 1982), the isolation of monoclonal antibodies to defined snRNP (Lerner et al., 1981a; Billings et al., 1982) and hnRNP proteins (Hugle et al., 1982), and the ability to use artificial lipid vesicles to transfer antisera (Lenk et al., 1982) and radioactive snRNA (Gross and Cetron, 1982) into cells. It is to be hoped that further refinements of these and other techniques will allow us to solve this, one of the major outstanding problems of molecular biology.

Nucleic acid binding properties of major proteins from the heterogeneous nuclear ribonucleoproteins of wheat

Glycine-rich core hnRNP proteins purified from wheat bind tightly to single-stranded but not to double-stranded nucleic acids with a preference for natural RNA over single-stranded DNA. Binding results in i) a progressive disruption of the residual secondary structure of the polynucleotide and the formation of an extended nucleoprotein filament until a protein to polynucleotide weight ratio of about 5:1 is attained. As more protein is added, this is followed by ii) the formation of globular structures along the polynucleotide chain with a concomitant reduction in the contour length of the nucleoprotein complex. These two features of the interaction--unwinding and condensation into beads--are analogous to the previously described behavior of the major glycine-rich core hnRNP protein from Artemia salina (Thomas et al. (1981) Proc. Natl. Acad. Sci. USA 78, 2888) and may represent the basic functional properties of this relatively well conserved group of nuclear proteins.