Messenger RNA processing and nuclear structure: isolation of nuclear ribonucleoprotein particles containing beta-globin messenger RNA precursors

Identification of differentially expressed genes associated with androgen-independent growth of prostate cancer

BACKGROUND

The human prostate cancer xenograft, CWR22, similar to most human prostate cancers, regresses after castration and recurs several months after the removal of androgen. Genes uniquely associated with proliferation were identified by comparison of tumors that exist in androgen absence but differ in proliferative capacity.

METHODS

cDNA libraries from CWR22 tumors from 20-day castrate mice (proliferation undetectable) and recurrent CWR22 tumors (proliferation rate similar to androgen-dependent CWR22) were compared to evaluate the possibility that proliferation is triggered by either gain of function or loss of suppression. Differentially expressed genes were evaluated further for their temporal association with the onset of cellular proliferation using northern and western analysis and immunohistochemistry of a series of CWR22 tumors that spanned the transition from androgen-dependent to recurrent growth.

RESULTS

Subtractive hybridization identified 11 candidate genes from among 1,057 clones examined. Northern analysis confirmed differential expression of 8 genes. Western analysis revealed an association between tomoregulin, translation elongation factor-1 alpha (EF-1 alpha), Mxi-1, and thioredoxin-binding protein 2/vitamin D up-regulated protein, and the onset of recurrent growth. Immunohistochemistry revealed expression of tomoregulin, EF-1 alpha, Mxi-1, and thioredoxin reductase-1 coincidental with the onset of cellular proliferation on day 120 after castration.

CONCLUSIONS

One or more of these genes may represent an appropriate target to prevent, delay or treat recurrent prostate cancer.

A unique ribonucleoprotein complex assembles preferentially on ecdysone-responsive sites in Drosophila melanogaster

The protein on ecdysone puffs (PEP) is associated preferentially with active ecdysone-inducible puffs on Drosophila polytene chromosomes and contains sequence motifs characteristic of transcription factors and RNA-binding proteins (S. A. Amero, S. C. R. Elgin, and A. L. Beyer, Genes Dev. 5:188-200, 1991). PEP is associated with RNA in vivo, as demonstrated here by the sensitivity of PEP-specific chromosomal immunostaining in situ to RNase digestion and by the immunopurification of PEP in Drosophila cell extract with heterogeneous nuclear ribonucleoprotein (hnRNP) complexes. As revealed by sequential immunostaining, PEP is found on a subset of chromosomal sites bound by the HRB (heterogeneous nuclear RNA-binding) proteins, which are basic Drosophila hnRNPs. These observations lead us to suggest that a unique, PEP-containing hnRNP complex assembles preferentially on the transcripts of ecdysone-regulated genes in Drosophila melanogaster presumably to expedite the transcription and/or processing of these transcripts.

A unique ribonucleoprotein complex assembles preferentially on ecdysone-responsive sites in Drosophila melanogaster

The protein on ecdysone puffs (PEP) is associated preferentially with active ecdysone-inducible puffs on Drosophila polytene chromosomes and contains sequence motifs characteristic of transcription factors and RNA-binding proteins (S. A. Amero, S. C. R. Elgin, and A. L. Beyer, Genes Dev. 5:188-200, 1991). PEP is associated with RNA in vivo, as demonstrated here by the sensitivity of PEP-specific chromosomal immunostaining in situ to RNase digestion and by the immunopurification of PEP in Drosophila cell extract with heterogeneous nuclear ribonucleoprotein (hnRNP) complexes. As revealed by sequential immunostaining, PEP is found on a subset of chromosomal sites bound by the HRB (heterogeneous nuclear RNA-binding) proteins, which are basic Drosophila hnRNPs. These observations lead us to suggest that a unique, PEP-containing hnRNP complex assembles preferentially on the transcripts of ecdysone-regulated genes in Drosophila melanogaster presumably to expedite the transcription and/or processing of these transcripts.

Serine/threonine phosphorylation regulates binding of C hnRNP proteins to pre-mRNA

The C hnRNP proteins bind to nascent pre-mRNA and are thought to participate in an early step of the pre-mRNA splicing pathway. We report here that C hnRNP proteins are phosphorylated by a casein kinase II activity in a HeLa cell nuclear extract and that dephosphorylation of C hnRNP proteins is inhibited by the specific protein-serine/threonine-phosphatase 1/2A inhibitor okadaic acid. We further find that dephosphorylation of C hnRNP proteins is required for their binding to adenovirus and human beta-globin pre-mRNAs. These results indicate that the participation of C hnRNP proteins in pre-spliceosome assembly is coupled to a dynamic cycle of their phosphorylation and dephosphorylation.

Localization of heterogeneous nuclear ribonucleoprotein in the interphase nuclear matrix core filaments and on perichromosomal filaments at mitosis

Although heterogeneous nuclear RNA (hnRNA) has been localized to the core filament substructure of the nuclear matrix, its precise location in the filament network has been unknown. The fA12 monoclonal antibody can localize, at high resolution, hn ribonucleoproteins (hnRNPs) and, presumably, hnRNA. Gold bead immunolabeling of resinless electron microscopy sections showed the fA12 antigens were in the fibrogranular material enmeshed in the filament network and not in the filaments themselves. At mitosis, hnRNP antigens became dispersed into a halo surrounding the chromosomes and spindle poles. Immunogold staining showed fA12 stained fibrogranular material associated with perichromosomal and pericentriolar filaments distinct from the mitotic spindle fibers. fA12 also labeled the midbody remaining after cytokinesis.

Crosslinking of hnRNP proteins to pre-mRNA requires U1 and U2 snRNPs

Proteins interacting with pre-mRNAs during early stages of spliceosome formation in a HeLa nuclear extract were investigated by photochemical RNA-protein crosslinking. The level of protein crosslinking to a beta-globin pre-mRNA was positively correlated with the presence of an intron. Proteins of 110,000, 59,000 and 39,000 mol. wt. were crosslinked to the beta-globin pre-mRNA, the latter of which was identified as the A1 hnRNP protein. Comparable experiments with an adenovirus pre-mRNA revealed crosslinked proteins of 110,000, 56,000 and 45,000 mol. wt., with the latter identified as belonging to the C group hnRNP proteins. Crosslinking of hnRNP proteins to both the beta-globin and adenovirus pre-mRNAs was eliminated by oligodeoxynucleotide-directed RNase H excision of an internal region (nt 28-42) of U2 RNA, but was not affected by oligo/RNase H cleavage of the 5'-terminal 15 nucleotides of U2 RNA. Cleavage of the 5'-terminal 15 nucleotides of U1 RNA preferentially eliminated crosslinking of the hnRNP A1 protein to both pre-mRNAs. The requirement of intact U1 snRNP for A1 protein crosslinking was further demonstrated by the fact that although micrococcal nuclease-treated extracts did not support crosslinking of A1 hnRNP protein to beta-globin pre-mRNA, crosslinking was restored by addition of a U1 snRNP-enriched fraction.

Highly localized tracks of specific transcripts within interphase nuclei visualized by in situ hybridization

Use of in situ hybridization optimized for fluorescent detection of nuclear RNA has revealed a striking localization of specific viral RNAs within nuclei of cells latently infected with EBV. Several hundred kb of specific transcripts is sharply restricted to a small region of the nucleus, frequently in a curvilinear "track". Detection of nuclear RNA was evidenced by hybridization without denaturation, sensitivity to RNAase, inhibition by actinomycin D, and specificity of transcribed sequences. Results indicate that RNA "tracks" extend from an internal genome into the nuclear periphery, and that RNA transport may be coupled to transcription. Localized nRNA is apparent for other viral sequences, different lymphoblastoid cell lines, nuclei prepared by two different methods, and an abundant, nonviral transfected sequence. Implications for understanding nuclear organization and the investigation of gene expression are discussed.

In vitro reconstitution of hnRNP particles

The assembly of hnRNP-like particles was studied by in vitro reconstitution, UV-crosslinking and CsCl-equilibrium centrifugation. Using total nuclear protein and RNA extracts from HeLa cells for RNP reconstitution, RNP particles sedimenting with the same buoyant density of p = 1.4 g/cm3 as 'native' 40 S core hnRNPs were obtained. Under the stringent reconstitution conditions used, hnRNP complexes containing only the Cl-core hnRNP protein could be identified.

Chemical modification as a tool for analysis of messenger RNA secondary structure in ribonucleoprotein particles

Chemical modification of unpaired bases is demonstrated in this study to be a reliable method for determining the conformation of nucleotides in mRNA. The modified nucleotides are identified by primer extension using reverse transcriptase. We have used this procedure to compare the structure of limited regions of SV40 T-antigen mRNA in solution, in nonpolysome-bound cytoplasmic messenger ribonucleoprotein particles, and in nuclear ribonucleoprotein complexes. The results indicate that SV40 T-antigen mRNA adopts a specific structure both in solution and when complexed with cellular proteins. The structures adopted by the mRNA in solution and in native cellular protein particles are very similar.

U1, U2, and U6 small nuclear ribonucleoproteins (snRNPs) are associated with large nuclear RNP particles containing transcripts of an amplified gene in vivo

Nuclear ribonucleoprotein (RNP) complexes that contain intact transcripts of the amplified gene for CAD, the multifunctional protein that initiates UMP synthesis in Syrian hamster cells, have been released from nuclei of Syrian hamster cells as large particulate structures that sediment at the 200S region in a sucrose gradient. By the technique of RNA hybridization, we have shown that U1, U2, and U6 small nuclear RNAs (snRNAs) cosediment with the large RNP particles in the sucrose gradients. Autoimmune sera from systemic lupus erythematosus and mixed connective tissue disease patients, characterized as anti-(U1)RNP, have further been shown to immunoprecipitate CAD RNA along with U1 and U2 snRNAs from the fractionated nuclear 200S RNP particles. We conclude that U1, U2, and U6 snRNPs are integral constituents of the 200S RNP particles. The requirement of snRNPs for RNA processing that evidently occurs on RNP particles has been recently demonstrated. Our results thus suggest that the 200S RNPs are structurally and functionally close to the native particles on which RNA processing occurs.

Identification of proteins that bind tightly to pre-mRNA during in vitro splicing

Incubation of a human beta-globin pre-mRNA in a HeLa cell nuclear extract under conditions permissive for efficient splicing resulted in the assembly of the RNA into ribonucleoprotein (RNP) complexes. This RNP formation occurred largely within the characteristic lag period that precedes splicing. Two classes of RNP were detected by the criterion of their stability in Cs2SO4 gradients. One was unstable and contained mainly aberrant RNA cleavage products. The other class of RNP complexes comprised 50-85% of the beta-globin RNA, formed only under splicing-permissive conditions, was stable in Cs2SO4 gradients, and contained both unspliced pre-mRNA molecules and the lariat intron 1-exon 2 splicing intermediate. This latter class of RNP complexes banded at approximately equal to 1.30 g/cm3, a density very similar to that of native heterogeneous nuclear RNP particles that contain pre-mRNA. RNA-protein crosslinking revealed major proteins of Mr approximately equal to 38,000 and 41,000 in the stable class of RNP. The use of antibodies specific for heterogeneous nuclear RNP core proteins and for small nuclear RNA-associated proteins, in conjunction with [32P]RNA-protein crosslinking, revealed polypeptides having the molecular weights of both sets of antigens. These results show that both heterogeneous nuclear RNP particle core proteins and small nuclear RNA-associated proteins bind tightly to pre-mRNA during splicing in vitro.

The nonchromatin substructures of the nucleus: the ribonucleoprotein (RNP)-containing and RNP-depleted matrices analyzed by sequential fractionation and resinless section electron microscopy

The nonchromatin structure or matrix of the nucleus has been studied using an improved fractionation in concert with resinless section electron microscopy. The resinless sections show the nucleus of the intact cell to be filled with a dense network or lattice composed of soluble proteins and chromatin in addition to the structural nuclear constituents. In the first fractionation step, soluble proteins are removed by extraction with Triton X-100, and the dense nuclear lattice largely disappears. Chromatin and nonchromatin nuclear fibers are now sharply imaged. Nuclear constituents are further separated into three well-defined, distinct protein fractions. Chromatin proteins are those that require intact DNA for their association with the nucleus and are released by 0.25 M ammonium sulfate after internucleosomal DNA is cut with DNAase I. The resulting structure retains most heterogeneous nuclear ribonucleoprotein (hnRNP) and is designated the RNP-containing nuclear matrix. The proteins of hnRNP are those associated with the nucleus only if RNA is intact. These are released when nuclear RNA is briefly digested with RNAase A. Ribonuclease digestion releases 97% of the hnRNA and its associated proteins. These proteins correspond to the hnRNP described by Pederson (Pederson, T., 1974, J. Mol. Biol., 83:163-184) and are distinct from the proteins that remain in the ribonucleoprotein (RNP)-depleted nuclear matrix. The RNP-depleted nuclear matrix is a core structure that retains lamins A and C, the intermediate filaments, and a unique set of nuclear matrix proteins (Fey, E. G., K. M. Wan, and S. Penman, 1984, J. Cell Biol. 98:1973-1984). This core had been previously designated the nuclear matrix-intermediate filament scaffold and its proteins are a third, distinct, and nonoverlapping subset of the nuclear nonhistone proteins. Visualizing the nuclear matrix using resinless sections shows that nuclear RNA plays an important role in matrix organization. Conventional Epon-embedded electron microscopy sections show comparatively little of the RNP-containing and RNP-depleted nuclear matrix structure. In contrast, resinless sections show matrix interior to be a three-dimensional network of thick filaments bounded by the nuclear lamina. The filaments are covered with 20-30-nm electron dense particles which may contain the hnRNA. The large electron dense bodies, enmeshed in the interior matrix fibers, have the characteristic morphology of nucleoli. Treatment of the nuclear matrix with RNAase results in the aggregation of the interior fibers and the extensive loss of the 20-30-nm particles.(ABSTRACT TRUNCATED AT 400 WORDS)

Extraction and quantitative precipitation of nuclear ribonucleoprotein particles

Ribonucleoprotein particles (RNPs) were extracted from monkey cell nuclei in media of low ionic strength. The rapidly labeled RNPs were comparable in terms of size, protein patterns and protein content to those extracted by sonication. The overnight labeled RNPs were homogenous (sedimenting at 60-65S and containing RNA of 30-31S), and appear to be a subset of pre-ribosomal RNPs. This procedure produces nuclear RNPs free of contaminating chromatin. Nuclear RNPs (rapidly-labeled and overnight-labeled RNPs, extracted by either our procedure or by sonication), quantitatively precipitated in 10 mM MgCl2 when the concentration of monovalent cations was low. There was no detectable degradation of the RNA components, nor was there loss of enzymatic activity of an RNP associated protein kinase. Precipitation in Mg++ provides a rapid, gentle and convenient method of concentrating RNPs.

Specific regions of beta-globin RNA are resistant to nuclease digestion in RNA-protein complexes in chicken reticulocyte nuclei

The interaction between beta-globin RNA and proteins in chicken reticulocyte nuclei was studied by determining the sequence of nuclease-resistant beta-globin RNA. Two types of nuclease-resistant RNAs were isolated for this study: endogenous nuclease-resistant RNA from 50S heterogeneous nuclear RNA-protein complexes and micrococcal nuclease-resistant nuclear RNA from whole nuclei. The nuclease-resistant regions were identified with the use of a RNA mapping method we recently developed (J.R. Patton and C.-B. Chae, J. Biol. Chem. 258:3991-3995, 1983). We found that beta-globin RNA is assembled into heterogeneous nuclear RNA-protein complexes in a specific manner. There are several regions of nuclease resistance in the first and third exons interrupted at regular intervals by sensitive regions. The second exon has only one nuclease-resistant region. The resistant regions range in size from 20 to 50 nucleotides. This organization may reflect a specific mode of assembly for heterogeneous nuclear RNA-protein complexes.

Localization and structure of snRNPs during mitosis. Immunofluorescent and biochemical studies

The distribution of U snRNAs during mitosis was studied by indirect immunofluorescence microscopy with snRNA cap-specific anti-m3G antibodies. Whereas the snRNAs are strictly nuclear at late prophase, they become distributed in the cell plasm at metaphase and anaphase. They re-enter the newly formed nuclei of the two daughter cells at early telophase, producing speckled nuclear fluorescent patterns typical of interphase cells. While the snRNAs become concentrated at the rim of the condensing chromosomes and at interchromosomal regions at late prophase, essentially no association of the snRNAs was observed with the condensed chromosomes during metaphase and anaphase. Independent immunofluorescent studies with anti-(U1)RNP autoantibodies, which react specifically with proteins unique to the U1 snRNP species, showed the same distribution of snRNP antigens during mitosis as was observed with the snRNA-specific anti-m3G antibody. Immunoprecipitation studies with anti-(U1)RNP and anti-Sm autoantibodies, as well as protein analysis of snRNPs isolated from extracts of mitotic cells, demonstrate that the snRNAs remain associated in a specific manner with the same set of proteins during interphase and mitosis. The concept that the overall structure of the snRNPs is maintained during mitosis also applies to the coexistence of the snRNAs U4 and U6 in a single ribonucleoprotein complex. Particle sedimentation studies in sucrose gradients reveal that most of the snRNPs present in sonicates of mitotic cells do not sediment as free RNP particles, but remain associated with high molecular weight (HMW) structures other than chromatin, most probably with hnRNA/RNP.

Abundant nuclear ribonucleoprotein form of CAD RNA

Transcripts of the CAD gene in Syrian hamster cells are as abundant in the nucleus as in the cytoplasm. This was shown by in situ hybridization of whole cells and by solution and blot hybridization of subcellular fractions. Similar results were obtained both for wild-type cells and for a mutant containing amplified CAD genes in which the level of CAD RNA is 150-fold greater. CAD nuclear RNA is indistinguishable from mature mRNA by gel electrophoresis and blot hybridization. Discrete higher-molecular-weight precursors are undetectable, although the persistence of a short length of intervening sequence in the otherwise fully processed RNA is not excluded. CAD RNA is released from nuclei by sonication in physiological conditions in a ribonucleoprotein form that sediments as a broad peak at about 200S in a sucrose gradient. CAD sequences extracted from nuclei by treatment with EDTA and RNase are found in the 30S particles previously described.

Specific regions of beta-globin RNA are resistant to nuclease digestion in RNA-protein complexes in chicken reticulocyte nuclei

The interaction between beta-globin RNA and proteins in chicken reticulocyte nuclei was studied by determining the sequence of nuclease-resistant beta-globin RNA. Two types of nuclease-resistant RNAs were isolated for this study: endogenous nuclease-resistant RNA from 50S heterogeneous nuclear RNA-protein complexes and micrococcal nuclease-resistant nuclear RNA from whole nuclei. The nuclease-resistant regions were identified with the use of a RNA mapping method we recently developed (J.R. Patton and C.-B. Chae, J. Biol. Chem. 258:3991-3995, 1983). We found that beta-globin RNA is assembled into heterogeneous nuclear RNA-protein complexes in a specific manner. There are several regions of nuclease resistance in the first and third exons interrupted at regular intervals by sensitive regions. The second exon has only one nuclease-resistant region. The resistant regions range in size from 20 to 50 nucleotides. This organization may reflect a specific mode of assembly for heterogeneous nuclear RNA-protein complexes.

Abundant nuclear ribonucleoprotein form of CAD RNA

Transcripts of the CAD gene in Syrian hamster cells are as abundant in the nucleus as in the cytoplasm. This was shown by in situ hybridization of whole cells and by solution and blot hybridization of subcellular fractions. Similar results were obtained both for wild-type cells and for a mutant containing amplified CAD genes in which the level of CAD RNA is 150-fold greater. CAD nuclear RNA is indistinguishable from mature mRNA by gel electrophoresis and blot hybridization. Discrete higher-molecular-weight precursors are undetectable, although the persistence of a short length of intervening sequence in the otherwise fully processed RNA is not excluded. CAD RNA is released from nuclei by sonication in physiological conditions in a ribonucleoprotein form that sediments as a broad peak at about 200S in a sucrose gradient. CAD sequences extracted from nuclei by treatment with EDTA and RNase are found in the 30S particles previously described.

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.

Intracellular site of U1 small nuclear RNA processing and ribonucleoprotein assembly

We have investigated the intracellular site and posttranscriptional immediacy of U1 small nuclear RNA processing and ribonucleoprotein (RNP) assembly in HeLa cells. After 30 or 45 min of labeling with [3H]uridine, a large amount of U1-related RNA radioactivity in the cytoplasm was found by using either hypotonic or isotonic homogenization buffers. The pulse-labeled cytoplasmic U1 RNA was resolved as a ladder of closely spaced bands running just behind mature-size U1 (165 nucleotides) on RNA sequencing gels, corresponding to a series of molecules between one and at least eight nucleotides longer than mature U1. They were further identified as U1 RNA sequences by gel blot hybridization with cloned U1 DNA. The ladder of cytoplasmic U1 RNA bands reacted with both RNP and Sm autoimmune sera and with a monoclonal Sm antibody, indicating a cytoplasmic assembly of these U1 RNA-related molecules into complexes containing the same antigens as nuclear U1 RNP particles. The cytoplasmic molecules behave as precursors to mature nuclear U1 RNA in both pulse-chase and continuous labeling experiments. While not excluding earlier or subsequent nuclear stages, these results suggest that the cytoplasm is a site of significant U1 RNA processing and RNP assembly. This raises the possibility that nuclear-transcribed eucaryotic RNAs are always processed in the cell compartment other than that in which they ultimately function, which suggests a set of precise signals regulating RNA and ribonucleoprotein traffic between nucleus and cytoplasm.

Nuclear RNA-protein interactions and messenger RNA processing

Eucaryotic messenger RNA precursors are processed in nuclear ribonucleoprotein particles (hnRNP). Here recent work on the structure of hnRNP is reviewed, with emphasis on function. Detailed analysis of a specific case, the altered assembly of hnRNP in heat-shocked Drosophila and mammalian cells, leads to a general hypothesis linking hnRNP structure and messenger RNA processing.

A sequence related to 4.5 S RNA and the B1 family of repeated DNA in the 5' flanking region of the mouse beta-globin gene

A beta-globin gene probe containing 5' flanking DNA hybridizes to a small nuclear RNA from Friend erythroleukemia cells, which was subsequently identified as 4.5 S RNA. This hybridization is shown to reflect complementarity between the Alu consensus region of 4.5 S RNA and the DNA sequence between nucleotides -33 and -48 from the beta-globin gene transcription initiation site.

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.

Nonpackaging and packaging proteins of hnRNA in Drosophila melanogaster

Monoclonal antibodies have previously been raised against chromosomal proteins of Drosophila. Using a biochemical fractionation method for the isolation of large hnRNA-containing structures (hnRNP) of Drosophila tissue culture cells, we show that seven of these antibodies recognize different antigens, and that these antigens are associated with RNA. Analysis of the sedimentation behavior of antigen-containing structures in sucrose gradients reveals that the antigens are differentially distributed with respect both to one another and to pulse-labeled RNA. We demonstrate that the antigens are minor components of hnRNP and are different from the major Drosophila hnRNP packaging proteins, which we have also identified. The antigens are probably involved in the processing of hnRNA in the nucleus.

Heat shock alters nuclear ribonucleoprotein assembly in Drosophila cells

Heterogeneous nuclear RNA is normally complexed with a specific set of proteins, forming ribonucleoprotein particles termed hnRNP. These particles are likely to be involved in mRNA processing. We have found that the structure of hnRNP is profoundly altered during the heat shock response in Drosophila cultured cells. Although hnRNA continues to be synthesized at a near-normal rate during heat shock, its assembly into hnRNP is incomplete, as evidenced by a greatly decreased protein content of the particles in Cs2SO4 density gradients. RNA-protein cross-linking conducted in vivo (Mayrand and Pederson, Proc. Natl. Acad. Sci. U.S.A. 78:2208-2212, 1981) also reveals that hnRNA made during heat shock is complexed with greatly reduced amounts of protein. The block of hnRNP assembly occurs immediately upon heat shock, even before the onset of heat shock protein synthesis. Additional experiments reveal that hnRNP assembled normally at 25 degrees C subsequently disassembles during heat shock. The capacity for normal hnRNP assembly is gradually restored after heat-shocked cells are returned to 25 degrees C. Heat-shocked mammalian cells also show a similar block in hnRNP assembly. We suggest that incomplete assembly of hnRNP during heat shock leads to abortive processing of most mRNA precursors and favors the processing or export (or both) of others whose pathway of nuclear maturation is less dependent on, or even independent of, normal hnRNP particle structure. This hypothesis is compatible with a large number of previous observations.

Changes in structure and composition of lymphocyte nuclei during mitogenic stimulation

Nuclei of lymphocytes stimulated in vitro with concanavalin A (Con A) were classified into three morphotypes: I--unstimulated; II--partially stimulated; III--fully stimulated, lymphoblastic nuclei. During the Con A-induced change from morphotype I to III nuclear volume increased up to sixfold, due to a near 10-fold increase in the interchromatinic region. At the same time, condensed chromatin rose in volume by only about 1.5-fold and became disaggregated in to small clumps. Regressive EDTA-uranyl staining demonstrated a large increase in interchromatinic fibrillar material in morphotypes II and III. Nuclear matrices isolated from stimulated murine lymphocytes showed structures comparable to the interchromatinic region of the morphotypes. The Con A-stimulated change in nuclear structure preceded onset of DNA replication and was unaffected by hydroxyurea or cytosine arabinoside. Cycloheximide blocked the structural change, even when given 20 hr after Con A. Autoradiography after [3H]leucine showed incorporation of label in the interchromatinic region of morphotype II and III nuclei, much of which remained stable during a 48-hr chase period. Nuclear structural activation was inhibited by alpha-amanitin but a significant stable nuclear RNA fraction was not detected. We conclude that an important event in lymphocyte activation is extensive synthesis of stable proteinaceous interchromatinic matrix which may be involved in chromatin remodeling and DNA replication and/or transcription.

Serum-induced stimulation of nucleoplasmic and nucleolar transcription in mouse 3T3 fibroblasts revisited

Transition of 3T3 mouse fibroblasts from a quiescent to a growing state was induced by the addition of 10% fresh bovine serum to the culture medium. The number of DNA-synthesizing cells began to increase 10-11 h after the addition of serum and reached a maximum of 70-80% around 24 h. In quiescent cells, maintained in 0.5% serum, residual RNA synthesis represented mainly nucleoplasmic transcription (hnRNA, 5-S RNA and tRNA). Synthesis of tRNA was 2-3-fold increased by 1-2 h after addition of serum; however, a significant stimulation of hnRNA, 5-S RNA and 45-S pre-rRNA synthesis could only be observed around 4h. The experimental data also revealed a close temporal relationship between the onset of serum-stimulated hnRNA and overall protein synthesis. Determined colorimetrically, the cellular RNA and protein content began to increase by 4-5 h and had doubled by 24 h. Virtually the same results on RNA and protein synthesis were obtained when the experiments were performed in the presence of cytosine arabinoside, an inhibitor of DNA synthesis. From our results we concluded that serum-stimulated overall RNA and protein synthesis preceded by several hours serum-induced S phase and was independent of DNA replication.

Structure of nuclear ribonucleoprotein: heterogeneous nuclear RNA is complexed with a major sextet of proteins in vivo

Mouse erythroleukemia cells were pulse-labeled with [3H]uridine and irradiated with 254-nm light to produce covalent crosslinks between RNA and proteins in close proximity to one another in vivo. Nuclear ribonucleoprotein particles containing heterogeneous nuclear RNA were isolated and digested with nucleases, and the resulting proteins were subjected to gel electrophoresis. Proteins carrying covalently crosslinked [3H]uridine nucleotides were identified by fluorography. The results demonstrate that heterogeneous nuclear RNA is complexed in vivo with a set of six major proteins having molecular weights between 32,500 and 41,500. Analysis of chromatin fractions indicates that nascent heterogeneous nuclear RNA chains assemble with these six proteins as a very early post-transcriptional event. These data, and other results [Nevins, J. R. & Darnell, J. E. (1981) Cell 15, 1477-1493], lead us to propose the usual order of post-transcriptional events to be: heterogeneous nuclear RNA-ribonucleoprotein particle assembly leads to poly(A) addition leads to splicing.

Heat shock alters nuclear ribonucleoprotein assembly in Drosophila cells

Heterogeneous nuclear RNA is normally complexed with a specific set of proteins, forming ribonucleoprotein particles termed hnRNP. These particles are likely to be involved in mRNA processing. We have found that the structure of hnRNP is profoundly altered during the heat shock response in Drosophila cultured cells. Although hnRNA continues to be synthesized at a near-normal rate during heat shock, its assembly into hnRNP is incomplete, as evidenced by a greatly decreased protein content of the particles in Cs2SO4 density gradients. RNA-protein cross-linking conducted in vivo (Mayrand and Pederson, Proc. Natl. Acad. Sci. U.S.A. 78:2208-2212, 1981) also reveals that hnRNA made during heat shock is complexed with greatly reduced amounts of protein. The block of hnRNP assembly occurs immediately upon heat shock, even before the onset of heat shock protein synthesis. Additional experiments reveal that hnRNP assembled normally at 25 degrees C subsequently disassembles during heat shock. The capacity for normal hnRNP assembly is gradually restored after heat-shocked cells are returned to 25 degrees C. Heat-shocked mammalian cells also show a similar block in hnRNP assembly. We suggest that incomplete assembly of hnRNP during heat shock leads to abortive processing of most mRNA precursors and favors the processing or export (or both) of others whose pathway of nuclear maturation is less dependent on, or even independent of, normal hnRNP particle structure. This hypothesis is compatible with a large number of previous observations.

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.

Sequence dependent interaction of hnRNP proteins with late adenoviral transcripts

Irradiation with ultraviolet light was used to induce covalent linkage between hnRNA and its associated proteins in intact HeLa cells, late after infection with adenovirus type 2. Covalently linked hnRNA-protein complexes, containing polyadenylated adenoviral RNA, were isolated and their protein moiety characterized. Host 42,000 Mr hnRNP proteins proved to be the major proteins crosslinked to viral hnRNA. To investigate their possible involvement in RNA processing, the localization of these cross-linked polypeptides on adenoviral late transcripts was determined. Sequences of RNA around the attachment sites of the protein were isolated. After in vitro labeling they were hybridized to Southern blots of adeno DNA fragments. The hybridization patterns revealed that the 42,000 Mr polypeptides can be linked to adenoviral transcripts over the entire length of the RNA, corresponding to 16.2-91.5 m.u. of the viral genome. Fine mapping within the Hind III B region (16.8-31.5 m.u.) established, however, that the localization of the cross-linked polypeptides was not random in all parts of the transcript. Sequences around the third leader and the 3' part of the i-leader were overrepresented, whereas the regions encoding VA I and VA II RNA and the late region 1 mRNA bodies were underrepresented in the cross-linked RNA. Using genomic DNA fragments and a cDNA clone containing the tripartite leader it appeared that leader and intervening sequences were represented about equally in cross-linked RNA fragments. Although these results do not support the notion that introns or exons are specifically interacting with one RNP protein, they demonstrate that the 42,000 hnRNP proteins are non randomly positioned on the RNA sequence.

Ribonucleic acid precursors are associated with the chick oviduct nuclear matrix

Nuclear matrix was prepared by sequential treatment of oviduct nuclei with Triton X-100, DNase I, and 2 M NaCl. Published procedures were modified such that as many steps as possible were performed at -20 degrees C to minimize endogenous ribonuclease activity. Examination of electron micrographs confirmed the isolation of intact nuclear matrix structures. Sodium dodecyl sulfate-polyacrylamide gel electrophoresis of the proteins in these structures showed an absence of histones and an enrichment of certain nonhistone proteins. RNA was isolated from the nuclear matrix preparations and subjected to denaturing gel electrophoresis. Gels were analyzed by ethidium bromide staining and by hybridization of Northern blots to cloned DNA probes for ovalbumin, ovomucoid, 5.8S ribosomal RNA, and U1 RNA. All of the precursors to ovalbumin and ovomucoid mRNAs (including various splicing intermediates) and all of the precursors to ribosomal RNA were associated exclusively with the nuclear matrix fraction. By contrast, mature ovalbumin and ovomucoid mRNAs were distributed between matrix and nonmatrix fractions. These observations were further supported by quantitative hybridization analysis of the RNA in nuclear and matrix fractions. It was found that less than 50% of the mature message of intact nuclei was recovered in the matrix, while most significantly, over 95% of the mRNA precursors remained associated with the matrix. Finally, mature ribosomal RNAs and virtually all of the small nuclear RNAs (including U1 RNA) were also distributed between matrix and nonmatrix fractions. Our results suggest that all precursor RNAs (be they precursors to mRNA or rRNA) are exclusively associated with the nuclear matrix and support the notion that the nuclear matrix may be the structural site for RNA processing within the nuclei of eucaryotic cells.

Ultrastructure of free ribonucleoprotein complexes in spread mammalian nuclei

Mouse erythroleukemia cell nuclei obtained by three different methods were spread for electron microscopy under low ionic conditions. It was found that this procedure allows the observation of free large ribonucleoprotein (RNP) complexes released from the nuclei during the centrifugation. The morphology of these complexes was readily affected by the conditions of cell treatment and spreading. Two extreme forms of free nuclear RNP structures were obtained, both consisting of spherical particles with diameters of approximately 17-20 nm. The first type was of loosened complexes of irregularly assembled particles interconnected with RNA fibrils. The second represented tightly packed particles forming mostly branched structures. The latter structures appeared to be closer to the native form of the nuclear RNP particles, differing from polyribosomes by their characteristic branching and stability in EDTA solutions.

Small nuclear RNA U2 is base-paired to heterogeneous nuclear RNA

Eukaryotic cells contain a set of low molecular weight nuclear RNA's. One of the more abundant of these is termed U2 RNA. The possibility that U2 RNA is hydrogen-bonded to complementary sequences in other nuclear RNA's was investigated. Cultured human (HeLa) cells were treated with a psoralen derivative that cross-links RNA chains that are base-paired with one another. High molecular weight heterogeneous nuclear RNA was isolated under denaturing conditions, and the psoralen cross-links were reversed. Electrophoresis of the released RNA and hybridization with a human cloned U2 DNA probe revealed that U2 is hydrogen-bonded to complementary sequences in heterogeneous nuclear RNA in vivo. In contrast, U2 RNA is not base-paired with nucleolar RNA, which contains the precursors of ribosomal RNA. The results suggest that U2 RNA participates in messenger RNA processing in the nucleus.

Assembly of nuclear ribonucleoprotein particles during in vitro transcription

The assembly of heterogeneous nuclear RNA (hnRNA) into ribonucleoprotein (RNP) particles has been investigated during in vitro transcription in isolated nuclei. Approximately 80% of the in vitro transcription observed in mouse Friend erythroleukemia cell nuclei is attributable to the activity of RNA polymerase II. In vitro hnRNA transcripts are assembled into particles having the same properties as the nuclear ribonucleoprotein (hnRNP) particles in which hnRNA is found in vivo. Direct contact of hnRNP proteins with newly transcribed hnRNA was demonstrated by nuclease protection experiments and by the covalent transfer of 32P-labeled nucleotides from [alpha-32P]UTP-labeled hnRNA transcripts to specific proteins by RNA--protein crosslinking followed by nuclease digestion and electrophoresis of the nucleotide-bearing proteins. The availability of an in vitro system for hnRNP assembly opens a new route for investigating the functional relationship between nuclear structure and mRNA processing.

Base-pairing interactions between small nuclear RNAs and nuclear RNA precursors as revealed by psoralen cross-linking in vivo

The psoralen derivative 4'-aminomethyl-4,5',8-trimethylpsoralen (AMT) reacts with base-paired regions of RNA and forms interstrand covalent cross-links. Since psoralens permeate living cells, they can be used to probe RNA-tRNA interactions in vivo. We used AMT to investigate whether small nuclear RNAs are base-paired with high molecular weight nuclear RNA in the cell. Intact HeLa cells were treated with AMT, and high molecular weight RNA was isolated under denaturing conditions from nuclei or from subnuclear fractions. The presence of base-paired snRNAs in the high molecular weight nuclear RNA was examined by electrophoresis after photochemical reversal of the cross-links. We found snRNA U3 and 5.8S rRNA to be cross-linked to nucleolar RNA. IN contrast, snRNA U1 was crosslinked to high molecular weight RNA in ribonucleoprotein particles containing hnRNA. The U1 base-paired to hnRNA was identified by its hybridization with a cloned U1 DNA sequence after reversal of the cross-links. These results demonstrate that U1 is base-paired with hnRNA in vivo, suggesting a role in mRNA processing.

Structure of nuclear ribonucleoprotein: identification of proteins in contact with poly(A)+ heterogeneous nuclear RNA in living HeLa cells

The processing of heterogeneous nuclear RNA into messenger RNA takes place in special nuclear ribonucleoprotein particles known as hnRNP. We report here the identification of proteins tightly complexed with poly(A)+ hnRNA in intact HeLa cells, as revealed by a novel in situ RNA-protein cross-linking technique. The set of cross-linked proteins includes the A, B, and C "core" hnRNP proteins, as well as the greater than 42,000 mol wt species previously identified in noncross-linked hnRNP. These proteins are shown to be cross-linked by virtue of remaining bound to the poly(A)+ hnRNA in the presence of 0.5% sodium dodecyl sulfate, 0.5 M NaCl, and 60% formamide, during subsequent oligo(dT)-cellulose chromatography, and in isopycnic banding in Cs2SO4 density gradients. These results establish that poly(A)+ hnRNA is in direct contact with a moderately complex set of nuclear proteins in vivo. This not only eliminates earlier models of hnRNP structure that were based upon the concept of a single protein component but also suggests that these proteins actively participate in modulating hnRNA structure and processing in the cell.

Nuclear ribonucleoprotein particles probed in living cells

Contacts between heterogeneous nuclear RNA (hnRNA) and protein in nuclear ribonucleoprotein particles have been photochemically crosslinked in intact HeLa or Friend erythroleukemia cell by irradiation with 254-nm light at doses of 10(1) to 10(5) ergs/mm2 (1 to 10(4) microJ/mm2). The resulting crosslinked particles were isolated and compared with conventional hnRNA . protein (hnRNP) preparations. By the criteria of nuclear fractionation behavior, sedimentation coefficients, nuclease digestion profiles, and RNA-to-protein ratio measured by banding in Cs2SO4 density gradients, the hnRNP particles crosslinked in vivo are identical to nonirradiated particles. Gel blot hybridization of RNA from Friend cell hnRNP crosslinked in vivo reveals that beta-globin RNA sequences remain both intact and hybridizable after the irradiation procedure. The crosslinked hnRNA--protein bonds are stable in 8 M urea/0.5% sodium dodecyl sulfate and withstand centrifugation in Cs2SO4 gradients of initial density 1.50 g/cm3. These results establish that hnRNA is tightly complexed with nuclear proteins in vivo and that hnRNP particles isolated by nuclear fractionation represent native structures.