Higher level organization of individual gene transcription and RNA splicing

Disruption of pre-mRNA splicing in vivo results in reorganization of splicing factors

We have examined the functional significance of the organization of pre-mRNA splicing factors in a speckled distribution in the mammalian cell nucleus. Upon microinjection into living cells of oligonucleotides or antibodies that inhibit pre-mRNA splicing in vitro, we observed major changes in the organization of splicing factors in vivo. Interchromatin granule clusters became uniform in shape, decreased in number, and increased in both size and content of splicing factors, as measured by immunofluorescence. These changes were transient and the organization of splicing factors returned to their normal distribution by 24 h following microinjection. Microinjection of these oligonucleotides or antibodies also resulted in a reduction of transcription in vivo, but the oligonucleotides did not inhibit transcription in vitro. Control oligonucleotides did not disrupt splicing or transcription in vivo. We propose that the reorganization of splicing factors we observed is the result of the inhibition of splicing in vivo.

RNA polymerase II is aberrantly phosphorylated and localized to viral replication compartments following herpes simplex virus infection

During lytic infection, herpes simplex virus subverts the host cell RNA polymerase II transcription machinery to efficiently express its own genome while repressing the expression of most cellular genes. The mechanism by which RNA polymerase II is directed to the viral delayed-early and late genes is still unresolved. We report here that RNA polymerase II is preferentially localized to viral replication compartments early after infection with herpes simplex virus type 1. Concurrent with recruitment of RNA polymerase II into viral compartments is a rapid and aberrant phosphorylation of the large subunit carboxy-terminal domain (CTD). Aberrant phosphorylation of the CTD requires early viral gene expression but is not dependent on viral DNA replication or on the formation of viral replication compartments. Localization of RNA polymerase II and modifications to the CTD may be instrumental in favoring transcription of viral genes and repressing specific transcription of cellular genes.

Splicing of Balbiani ring 1 gene pre-mRNA occurs simultaneously with transcription

The 40 kb Balbiani ring 1 (BR1) gene is at a given moment transcribed by, on average, 120 RNA polymerases. Here we directly assay the excision of introns both in the nascent and in the released nucleoplasmic BR1 pre-mRNAs, isolated by microdissection. We show that intron 3, located 3 kb from the 5' end of the pre-mRNA, is excised simultaneous with transcription. Within 2.5 min of transcription time, 50% of the pre-mRNA molecules have lost the intron. Intron 4, located 600 bases from the polyadenylation site, is excised cotranscriptionally in 5%-10% of the molecules and after or during release to the nucleoplasm in the remaining molecules. Our results demonstrate that spliceosome assembly is a cotranscriptional process in vivo and that splicing may occur during transcription but also after completed transcription, depending on the position of the intron.

Requirements for editing in the genomic RNA of hepatitis delta virus

Hepatitis delta virus is a satellite of the hepatitis B virus which provides the surface antigen for the viral coat. The genome of the hepatitis delta virus consists of a single-stranded, circular RNA of 1679 nucleotides which forms a rod structure due to a high extent of self homology and which replicates via synthesis of an antigenomic RNA in a rolling circle mechanism similar to plant viroids. The antigenomic RNA contains the open reading frame for the delta-antigen which exists in two isoforms, p24 and p27. The formation of these two isoforms is explained by RNA editing at nucleotide 1012 which changes the stop translation codon UAG at amino acid residue 196 into the codon UGG for tryptophan and extends the open reading frame for the synthesis of p27. In order to investigate whether the editing occurs cotranscriptionally during RNA replication or is a posttranscriptional base modification in the genomic or antigenomic RNA, replication defective deletion mutants of the HDV genome were constructed and expressed in COS-7 cells. Editing was demonstrated in non-replicating fragments of genomic HDV RNA but not in antigenomic HDV RNA fragments. The sequences from nucleotide position 337-1200 of the genomic RNA were sufficient to enable low levels of editing. Editing at position 1012 required the opposite strand of the RNA rod from nucleotide position 337-783. Replicating circular HDV RNA was much more efficiently edited than non-replicating full length genomic HDV RNA. Expression of delta-antigen in trans did not complement the low editing efficiency of replication defective genomic HDV RNA. These results demonstrate posttranscriptional U to C editing in the genomic HDV RNA and exclude misincorporation during HDV RNA replication as the editing mechanism. The minimal structural requirements for HDV RNA editing reside between nucleotide position 337-1200.

Stimulation of gene expression by introns: conversion of an inhibitory intron to a stimulatory intron by alteration of the splice donor sequence

Efficient expression of many mammalian genes depends on the presence of at least one intron. We previously showed that addition of almost any of the introns from the mouse thymidylate synthase (TS) gene to an intronless TS minigene led to a large increase in expression. However, addition of intron 4 led to a reduction in minigene expression. The goal of the present study was to determine why TS intron 4 was unable to stimulate expression. Insertion of intron 4 into an intron-dependent derivative of the ribosomal protein L32 gene did not lead to a significant increase in expression, suggesting that its inability to stimulate expression was due to sequences within the intron. Deleting most of the interior of intron 4, improving the putative branch point, removing purines from the pyrimidine stretch at the 3' end of the intron, or removing possible alternative splice acceptor or donor sites within the intron each had little effect on the level of expression. However, when the splice donor sequence of intron 4 was modified so that it was perfectly complementary to U1 snRNA, the modified intron 4 stimulated expression approximately 6-fold. When the splice donor site of TS intron 1 (a stimulatory intron) was changed to that of TS intron 4, the modified intron 1 was spliced very inefficiently and lost the ability to stimulate mRNA production. Our observations support the idea that introns can stimulate gene expression by a process that depends directly on the splicing reaction.

Tethering ribozymes to a retroviral packaging signal for destruction of viral RNA

Cellular compartmentalization of RNAs is thought to influence their susceptibility to ribozyme cleavage. As a test of this idea, two retroviral vectors--one encoding a hammer-head ribozyme designed to cleave lacZ transcripts and another encoding the lacZ messenger RNA--were coexpressed inside retroviral packaging cells. Because of the retroviral packaging signal, the ribozyme would be expected to colocalize with the lacZ-containing viral genomic RNA but not with the lacZ messenger RNA. The ribozyme was found to reduce the titer of infectious virus containing lacZ by 90 percent, but had no effect on translation of lacZ messenger RNA. These results indicate that sorting gene inhibitors to appropriate intracellular sites may increase their effectiveness.

Further purification and characterization of a multienzyme complex for DNA synthesis in human cells

The 21 S complex of enzymes for DNA synthesis in the combined low salt nuclear extract-post microsomal supernatant from HeLa cells [Malkas et al. (1990) Biochemistry 29:6362-6374] was purified by poly (ethylene glycol) precipitation, Q-Sepharose chromatography, Mono Q Fast Protein Liquid Chromatography (FPLC), and velocity gradient centrifugation. The procedure gives purified enzyme complex at a yield of 45%. The 21 S enzyme complex remains intact and functional in the replication of simian virus 40 DNA throughout the purification. Sedimentation analysis showed that the 21 S enzyme complex exists in the crude HeLa cell extract and that simian virus 40 in vitro DNA replication activity in the cell extract resides exclusively with the 21 S complex. The results of enzyme and immunological analysis indicate that DNA polymerase alpha-primase, a 3',5' exonuclease, DNA ligase I, RNase H, and topoisomerase I are associated with the purified enzyme complex. Denaturing polyacrylamide gel electrophoresis of the purified enzyme complex showed the presence of about 30 polypeptides in the size range of 300 to 15 kDa. Immunofluorescent imaging analysis, with antibodies to DNA polymerase alpha,beta and DNA ligase I, showed that polymerase alpha and DNA ligase I are localized to granular-like foci within the nucleus during S-phase. In contrast, DNA polymerase beta, which is not associated with the 21 S complex, is diffusely distributed throughout the nucleoplasm.

Nuclear organization of splicing snRNPs during differentiation of murine erythroleukemia cells in vitro

Murine erythroleukemia (MEL) cells are erythroid progenitors that can be induced to undergo terminal erythroid differentiation in culture. We have used MEL cells here as a model system to study the nuclear organization of splicing snRNPs during the physiological changes in gene expression which accompany differentiation. In uninduced MEL cells, snRNPs are widely distributed throughout the nucleoplasm and show an elevated concentration in coiled bodies. Within the first two days after induction of terminal erythroid differentiation, the pattern of gene expression changes, erythroid-specific transcription is activated and transcription of many other genes is repressed. During this early stage splicing snRNPs remain widely distributed through the nucleoplasm and continue to associate with coiled bodies. At later stages of differentiation (four to six days), when total transcription levels have greatly decreased, splicing snRNPs are redistributed. By six days postinduction snRNPs were concentrated in large clusters of interchromatin granules and no longer associated with coiled bodies. At the end-point of erythroid differentiation, just before enucleation, we observe a dramatic segregation of splicing snRNPs from the condensed chromatin. Analysis by EM shows that the snRNPs are packaged into a membrane-associated structure at the nuclear periphery which we term the "SCIM" domain (i.e., SnRNP Clusters Inside a Membrane).

Identification of barriers to rotation of DNA segments in yeast from the topology of DNA rings excised by an inducible site-specific recombinase

Controlled excision of DNA segments to yield intracellular DNA rings of well-defined sequences was utilized to study the determinants of transcriptional supercoiling of closed circular DNA in the yeast Saccharomyces cerevisiae. In delta top1 top2ts strains of S. cerevisiae expressing Escherichia coli DNA topoisomerase I, accumulation of positive supercoils in intracellular DNA normally occurs upon thermal inactivation of DNA topoisomerase II because of the simultaneous generation of positively and negatively supercoiled domains by transcription and the preferential relaxation of the latter by the bacterial enzyme. Positive supercoil accumulation in DNA rings is shown to depend on the presence of specific sequence elements; one likely cause of this dependence is that the persistence of oppositely supercoiled domains in an intracellular DNA ring requires the presence of barriers to rotation of the DNA segments connecting the domains. Analysis of the S. cerevisiae 2-microns plasmid partition system by this approach suggests that the plasmid-encoded REP1 and REP2 proteins are involved in forming such a barrier in DNA containing the REP3 sequence.

Determination of mRNA fate by different RNA polymerase II promoters

Translational stop mutations of the human beta-globin gene cause a reduction of cytoplasmic mRNA accumulation in thalassemia patients and in transfection models. The exact mechanism underlying this phenomenon has remained enigmatic but is known to be post-transcriptional. We have used transfected HeLa cells to study the expression of beta-globin mRNAs with nonsense or frameshift mutations within the three exons of this gene. Mutations in exons 1 or 2 reduce cytoplasmic mRNA accumulation whereas a mutation in exon 3 permits essentially normal expression. We report here that the post-transcriptional fate of mutated beta-globin mRNAs is differentially affected by the type of RNA polymerase II promoter driving expression. Replacement of the beta-globin promoter with the herpes simplex virus type 1 thymidine kinase gene promoter but not the cytomegalovirus immediate early promoter rescues the cytoplasmic accumulation of mutated mRNA to wild-type levels. This effect is shown to be independent of the absolute quantity and the kinetics of accumulation of mutated mRNA synthesized, and primer-extension analyses confirm that both viral promoters accurately utilize identical transcription start sites. These data thus reveal an unexpected property of RNA polymerase II promoters: determination of the post-transcriptional fate of the maturing mRNA, presumably by influencing alternative choices between as yet undefined processing and/or transport pathways.

In vivo cooperation between introns during pre-mRNA processing

In higher eukaryotes the large number of introns present in most genes implies that the pre-mRNA processing machinery should be efficient and accurate. Although this could be achieved at the level of each intron, an attractive alternative would be that interactions between introns improve the performance of this machinery. In this study we tested this hypothesis by comparing the processing of transcripts of the tumor necrosis factor beta gene, which differ only by their number of introns. We took advantage of the ordered splicing of the three introns present in this gene to design constructs that should generate, as primary transcripts, molecules that are normally produced by splicing. We established that the apparent splicing rate of intron 3 is increased 2.5- and 3.5-fold by the presence of one or two other introns on the primary transcript, respectively. Similarly, the apparent splicing rate of intron 2 is increased by the presence of intron 1. As these effects involve the splice sites of the upstream intron, these observations support the existence of cooperative interactions between introns during pre-mRNA processing.

Possible specific activation of RNA synthesis in PC-12 cell isolated nuclei by small acidic peptides

Three synthetic peptides, pyro-Glu-Ala-Gly-Glu-Ser-Glu-Asp (Pep A), pyro-Glu-Ala-Gly-Glu-Glu-Glu-Ser-Asn (Pep B), and pyro-Glu-Asp-Asp-Ser-Asp-Glu-Glu-Asn (Pep C), bear sequences possibly belonging to components of a naturally occurring family of strongly related small acidic chromatin peptides involved in regulation of gene expression. In a crude nuclear fraction and in purified nuclei from PC-12 cells, Pep A and Pep B activate RNA synthesis, specifically acting on the RNA polymerase II transcription system. On the other hand, Pep C shows an inhibitory effect on RNA synthesis in purified nuclei but an activation in the crude nuclear fraction. Control experiments show that the serum thymic factor does not affect RNA synthesis in the crude nuclear fraction or in purified nuclei. A possible regulation by peptide phosphorylation via casein kinase II (more active in purified nuclei than in the crude nuclear fraction) is discussed.

Nuclear RNA tracks: structural basis for transcription and splicing?

Knowledge of how the biochemical machineries governing metabolism and transport of several distinct classes of RNA may be organized and integrated into the structure of the nucleus remains very limited. Recent observations, including advances in the detection of specific nucleotide sequences directly within the nucleus, have heightened the long-standing interest in the structural organization of pre-mRNA transcription and processing.

Antisense oligonucleotides as antiviral agents: prospects and problems

One possible strategy for the development of antiviral drugs is to synthesize short antisense oligonucleotides that interfere specifically with RNA transcription and processing to prevent expression of protein. This can be readily achieved, but there are formidable technical problems to solve before routine clinical applications can be envisaged.

Nuclear organization of splicing small nuclear ribonucleoproteins in adenovirus-infected cells

We have studied the effect of adenovirus infection on the nuclear organization of splicing small nuclear ribonucleoproteins (snRNPs) in HeLa cells. In uninfected HeLa cells, snRNPs are widespread throughout the nucleoplasm but also are concentrated in specific nuclear structures, including coiled bodies, interchromatin granules, and perichromatin fibrils. We have used immunofluorescence microscopy to study the localization of splicing snRNPs relative to centers of viral DNA synthesis and accumulation identified with antiserum against the viral 72,000-molecular-weight single-stranded DNA-binding protein (72K protein). Splicing snRNPs were independently detected with both monoclonal and polyclonal antibodies specific for common snRNP antigens, snRNP-specific proteins, and the snRNA-specific 2,2,7-trimethylguanosine 5' cap structure. We have examined infected cells 2 to 24 h after infection, and, in the majority of these cells, we observed no colocalization of the snRNP and 72K-protein staining patterns. In the late phase, snRNPs were found to markedly concentrate in discrete clusters that were distinct from the centers of viral DNA synthesis and accumulation identified with anti-72K protein. We have treated cells with hydroxyurea at various times after infection to inhibit aspects of the virus infectious program. We have found that the accumulation of snRNP clusters is correlated with late gene expression rather than with DNA synthesis or early gene expression. Finally, we show that the late-phase snRNP clusters colocalize with a monoclonal antibody that primarily stains interchromatin granules. These results suggest that the centers of snRNP concentration in late-phase infected cells are likely to correspond to interchromatin granule clusters.

Reversal of terminal differentiation and control of DNA replication: cyclin A and Cdk2 specifically localize at subnuclear sites of DNA replication

DNA replication in mammalian cells occurs in discrete nuclear foci. Here we show that terminally differentiated myotubes can be induced to reenter S phase and show the same pattern of replication foci as cycling cells. We used this cellular system to analyze the interaction of cell cycle proteins with these foci in vivo. Cyclin A and cdk2, but not cyclin B1 and cdc2, were specifically localized at nuclear replication foci, just like the replication protein proliferating cell nuclear antigen. A potential target of cyclin A and cdk2 is the 34 kd subunit of replication protein A (RPA34). In contrast with the 70 kd subunit, which localizes to the foci, RPA34 was not detected at these replication sites, which may reflect a transient interaction. The specific localization of cyclin A and cdk2 at nuclear replication foci provides a direct link between cell cycle regulation and DNA replication.

In vivo observation of the puff-specific protein no-on transient A (NONA) in nuclei of Drosophila embryos

The spatial distribution of no-on transient A (NONA), a protein associated with specific puffs on polytene chromosomes, was followed in nuclei of living Drosophila embryos by microinjection of fluorescently labeled monoclonal antibody to NONA. The injected antibodies remained active until the larval stage, revealing the distribution of the NONA protein throughout embryogenesis. Most injected animals completed embryonic development and hatched as normal larvae. NONA was restricted to the cytoplasm until the end of cycle 11. We document an active uptake of the NONA-antibody complex into early interphase nuclei from nuclear cycle 14 onwards, following each mitosis. Significant differences in the distribution of the protein between fixed and living embryos were apparent, particularly at high resolution. The NONA protein was localized in the nuclei of living embryos at discrete sites, most of which lay at the periphery and some of which were tightly clustered. The constellation of sites changed with time; in some nuclei these changes were fast whereas in other nuclei the pattern was quite stable. These data suggest that specific protein complexes associated with active interphase chromatin, and possibly chromatin in general, are mobile in the living organism.

Fluorescent labeling of nascent RNA reveals transcription by RNA polymerase II in domains scattered throughout the nucleus

Several nuclear activities and components are concentrated in discrete nuclear compartments. To understand the functional significance of nuclear compartmentalization, knowledge on the spatial distribution of transcriptionally active chromatin is essential. We have examined the distribution of sites of transcription by RNA polymerase II (RPII) by labeling nascent RNA with 5-bromouridine 5'-triphosphate, in vitro and in vivo. Nascent RPII transcripts were found in over 100 defined areas, scattered throughout the nucleoplasm. No preferential localization was observed in either the nuclear interior or the periphery. Each transcription site may represent the activity of a single gene or, considering the number of active pre-mRNA genes in a cell, of a cluster of active genes. The relation between the distribution of nascent RPII transcripts and that of the essential splicing factor SC-35 was investigated in double labeling experiments. Antibodies against SC-35 recognize a number of well-defined, intensely labeled nuclear domains, in addition to labeling of more diffuse areas between these domains (Spector, D. L., X. -D. Fu, and T. Maniatis. 1991. EMBO (Eur. Mol. Biol. Organ.) J. 10:3467-3481). We observe no correlation between intensely labeled SC-35 domains and sites of pre-mRNA synthesis. However, many sites of RPII synthesis colocalize with weakly stained areas. This implies that contranscriptional splicing takes place in these weakly stained areas. These areas may also be sites where splicing is completed posttranscriptionally. Intensely labeled SC-35 domains may function as sites for assembly, storage, or regeneration of splicing components, or as compartments for degradation of introns.

Evidence for a nuclear compartment of transcription and splicing located at chromosome domain boundaries

The nuclear topography of splicing snRNPs, mRNA transcripts and chromosome domains in various mammalian cell types are described. The visualization of splicing snRNPs, defined by the Sm antigen, and coiled bodies, revealed distinctly different distribution patterns in these cell types. Heat shock experiments confirmed that the distribution patterns also depend on physiological parameters. Using a combination of fluorescence in situ hybridization and immunodetection protocols, individual chromosome domains were visualized simultaneously with the Sm antigen or the transcript of an integrated human papilloma virus genome. Three-dimensional analysis of fluorescence-stained target regions was performed by confocal laser scanning microscopy. RNA transcripts and components of the splicing machinery were found to be generally excluded from the interior of the territories occupied by the individual chromosomes. Based on these findings we present a model for the functional compartmentalization of the cell nucleus. According to this model the space between chromosome domains, including the surface areas of these domains, defines a three-dimensional network-like compartment, termed the interchromosome domain (ICD) compartment, in which transcription and splicing of mRNA occurs.

Nuclear organization of pre-mRNA processing

Recent studies have suggested that small nuclear ribonucleoprotein particles (snRNPs), non-snRNP splicing factors, and several heterogeneous nuclear RNP proteins change their organization within the cell in response to transcriptional activity. Several of the RNA substrates with which these factors interact have been shown to localize in tracks that are associated with regions in which splicing factors are concentrated (nuclear speckles). It is now thought that pre-mRNA splicing may occur within these tracks.

Germ line transmission of a yeast artificial chromosome spanning the murine alpha 1(I) collagen locus

Molecular complementation of mutant phenotypes by transgenic technology is a potentially important tool for gene identification. A technology was developed that allows the transfer of a physically intact yeast artificial chromosome (YAC) into the germ line of the mouse. A purified 150-kilobase YAC encompassing the murine gene Col1a1 was efficiently introduced into embryonic stem (ES) cells via lipofection. Chimeric founder mice were derived from two transfected ES cell clones. These chimeras transmitted the full length transgene through the germ line, generating two transgenic mouse strains. Transgene expression was visualized as nascent transcripts in interphase nuclei and quantitated by ribonuclease protection analysis. Both assays indicated that the transgene was expressed at levels comparable to the endogenous collagen gene.

A three-dimensional view of precursor messenger RNA metabolism within the mammalian nucleus

A quantitative three-dimensional analysis of nuclear components involved in precursor messenger RNA metabolism was performed with a combination of fluorescence hybridization, immunofluorescence, and digital imaging microscopy. Polyadenylate [poly(A)] RNA-rich transcript domains were discrete, internal nuclear regions that formed a ventrally positioned horizontal array in monolayer cells. A dimmer, sometimes strand-like, poly(A) RNA signal was dispersed throughout the nucleoplasm. Spliceosome assembly factor SC-35 localized within the center of individual domains. These data support a nuclear model in which there is a specific topological arrangement of noncontiguous centers involved in precursor messenger RNA metabolism, from which RNA transport toward the nuclear envelope radiates.