Characterization of mouse 45S ribosomal RNA subspecies suggests that the first processing cleavage occurs 600 +/- 100 nucleotides from the 5' end and the second 500 +/- 100 nucleotides from the 3' end of a 13.9 kb precursor

The Conserved RNA Exonuclease Rexo5 Is Required for 3' End Maturation of 28S rRNA, 5S rRNA, and snoRNAs

Non-coding RNA biogenesis in higher eukaryotes has not been fully characterized. Here, we studied the Drosophila melanogaster Rexo5 (CG8368) protein, a metazoan-specific member of the DEDDh 3'-5' single-stranded RNA exonucleases, by genetic, biochemical, and RNA-sequencing approaches. Rexo5 is required for small nucleolar RNA (snoRNA) and rRNA biogenesis and is essential in D. melanogaster. Loss-of-function mutants accumulate improperly 3' end-trimmed 28S rRNA, 5S rRNA, and snoRNA precursors in vivo. Rexo5 is ubiquitously expressed at low levels in somatic metazoan cells but extremely elevated in male and female germ cells. Loss of Rexo5 leads to increased nucleolar size, genomic instability, defective ribosome subunit export, and larval death. Loss of germline expression compromises gonadal growth and meiotic entry during germline development.

Metabolic Labeling in the Study of Mammalian Ribosomal RNA Synthesis

RNA metabolic labeling is a method of choice in the study of dynamic changes in the rate of gene transcription and RNA processing. It is particularly applicable to transcription of the ribosomal RNA genes and their processing products due to the very high levels of ribosomal RNA synthesis. Metabolic labeling can detect changes in ribosomal RNA transcription that occur within a few minutes as opposed to the still widely used RT-PCR or Northern blot procedures that measure RNA pool sizes and at best are able to detect changes occurring over several hours or several days. Here, we describe a metabolic labeling technique applicable to the measurement of ribosomal RNA synthesis and processing rates, as well as to the determination of RNA Polymerase I transcription elongation rates.

Comparison of preribosomal RNA processing pathways in yeast, plant and human cells - focus on coordinated action of endo- and exoribonucleases

Proper regulation of ribosome biosynthesis is mandatory for cellular adaptation, growth and proliferation. Ribosome biogenesis is the most energetically demanding cellular process, which requires tight control. Abnormalities in ribosome production have severe consequences, including developmental defects in plants and genetic diseases (ribosomopathies) in humans. One of the processes occurring during eukaryotic ribosome biogenesis is processing of the ribosomal RNA precursor molecule (pre-rRNA), synthesized by RNA polymerase I, into mature rRNAs. It must not only be accurate but must also be precisely coordinated with other phenomena leading to the synthesis of functional ribosomes: RNA modification, RNA folding, assembly with ribosomal proteins and nucleocytoplasmic RNP export. A multitude of ribosome biogenesis factors ensure that these events take place in a correct temporal order. Among them are endo- and exoribonucleases involved in pre-rRNA processing. Here, we thoroughly present a wide spectrum of ribonucleases participating in rRNA maturation, focusing on their biochemical properties, regulatory mechanisms and substrate specificity. We also discuss cooperation between various ribonucleolytic activities in particular stages of pre-rRNA processing, delineating major similarities and differences between three representative groups of eukaryotes: yeast, plants and humans.

PTRF/Cavin-1 promotes efficient ribosomal RNA transcription in response to metabolic challenges

Ribosomal RNA transcription mediated by RNA polymerase I represents the rate-limiting step in ribosome biogenesis. In eukaryotic cells, nutrients and growth factors regulate ribosomal RNA transcription through various key factors coupled to cell growth. We show here in mature adipocytes, ribosomal transcription can be acutely regulated in response to metabolic challenges. This acute response is mediated by PTRF (polymerase I transcription and release factor, also known as cavin-1), which has previously been shown to play a critical role in caveolae formation. The caveolae–independent rDNA transcriptional role of PTRF not only explains the lipodystrophy phenotype observed in PTRF deficient mice and humans, but also highlights its crucial physiological role in maintaining adipocyte allostasis. Multiple post-translational modifications of PTRF provide mechanistic bases for its regulation. The role of PTRF in ribosomal transcriptional efficiency is likely relevant to many additional physiological situations of cell growth and organismal metabolism.

DOI:http://dx.doi.org/10.7554/eLife.17508.001

Obesity can cause several other health conditions to develop. Type 2 diabetes is one such condition, which arises in part because fat cells become unable to store excess fats. This makes certain tissues in the body less sensitive to the hormone insulin, and so the individual is less able to adapt to changing nutrient levels. Without treatment or a change in lifestyle, this insulin resistance may develop into diabetes. However, “healthy obese” individuals also exist, who can accommodate an overabundance of fat without developing insulin resistance and diabetes.

Some forms of rare genetic disorders called lipodystrophies, which result in an almost complete lack of body fat, can also lead to type 2 diabetes. This raises the question of whether lipodystrophy and obesity share some common mechanisms that cause fat cells to trigger insulin resistance. One possible player in such mechanisms is a protein called PTRF. In rare cases, individuals with lipodystrophy lack this protein, and mice that have been engineered to lack PTRF also largely lack body fat and develop insulin resistance.

Fat cells can respond rapidly to changes in nutrients during feeding or fasting, and to do so, they must produce new proteins. Structures called ribosomes, which are made up of proteins and ribosomal RNA, build proteins; thus when the cell needs to make new proteins, it also has to produce more ribosomes. PTRF is thought to play a role in ribosome production, but it is not clear how it does so.

Liu and Pilch analyzed normal mice as well as those that lacked the PTRF protein. This revealed that in response to cycles of fasting and feeding, PTRF increases the production of ribosomal RNA in fat cells, enabling the cells to produce more proteins. By contrast, the fat cells of mice that lack PTRF have much lower levels of ribosomal RNA and proteins.

Liu and Pilch then examined mouse fat cells that were grown in the laboratory. Exposing these cells to insulin caused phosphate groups to be attached to the PTRF proteins inside the cells. This modification caused PTRF to move into the cell’s nucleus, where it increased the production of ribosomal RNA.

Overall, the results show that fat cells that lack PTRF are unable to produce the proteins that they need to deal with changing nutrient levels, leading to an increased likelihood of diabetes. The next steps are to investigate the mechanism by which PTRF is modified, and to see whether the mechanisms uncovered in this study also apply to humans.

DOI:http://dx.doi.org/10.7554/eLife.17508.002

RNA polymerase I termination: Where is the end?

The synthesis of ribosomal RNA (rRNA) precursor molecules by RNA polymerase I (Pol I) terminates with the dissociation of the protein-DNA-RNA ternary complex. Based on in vitro results the mechanism of Pol I termination appeared initially to be rather conserved and simple until this process was more thoroughly re-investigated in vivo. A picture emerged that Pol I termination seems to be connected to co-transcriptional processing, re-initiation of transcription and, possibly, other processes downstream of Pol I transcription units. In this article, our current understanding of the mechanism of Pol I termination and how this process might be implicated in other biological processes in yeast and mammals is summarized and discussed. This article is part of a Special Issue entitled: Transcription by Odd Pols.

Stabilization of ribozyme-like cis-noncoding rRNAs induces apoptotic and nonapoptotic death in lung cells

Bidirectional non-protein-coding RNAs are ubiquitously transcribed from the genome. Convergent sense and antisense transcripts may regulate each other. Here, we examined the convergent cis-noncoding rRNAs (nc-rRNAs) in A5 and E9 lung cancer models. Sense nc-rRNAs extending from rDNA intergenic region to internal transcribed spacer of around 10 kb in length were identified. nc-rRNAs in sense direction exhibited in vitro characteristics of ribozymes, namely, degradation upon incubation with MgCl(2) and stabilization by complementary oligonucleotides. Detection of endogenous cleavage-ligation products carrying internal deletion of hundreds to thousands nucleotides by massively parallel sequencing confirmed the catalytic properties. Transfection of oligonucleotides pairing with antisense nc-rRNAs stabilized both target and complementary transcripts, perturbed rRNA biogenesis, and induced massive cell death via apoptotic and/or nonapoptotic mechanisms depending on cell type and treatment. Oligonucleotides targeting cellular sense transcripts are less responsive. Spontaneously detached cells, though rare, also showed accumulation of nc-rRNAs and perturbation of rRNA biogenesis. Direct participation of nc-rRNAs in apoptotic and nonapoptotic death was demonstrated by transfection of synthetic nc-rRNAs encompassing the rDNA promoter. In sum, convergent cis-nc-rRNAs follow a feed-forward mechanism to regulate each other and rRNA biogenesis. This opens an opportunity to disrupt rRNA biogenesis, commonly upregulated in cancers, via inhibition of ribozyme-like activities in nc-rRNAs.

Biosynthesis of pyrrolopyrimidines

Pyrrolopyrimidine containing compounds, also known as 7-deazapurines, are a collection of purine-based metabolites that have been isolated from a variety of biological sources and have diverse functions which range from secondary metabolism to RNA modification. To date, nearly 35 compounds with the common 7-deazapurine core structure have been described. This article will illustrate the structural diversity of these compounds and review the current state of knowledge on the biosynthetic pathways that give rise to them.

Non-coding rRNA-mediated preferential killing in cancer cells is enhanced by suppression of autophagy in non-transformed counterpart

Interest to anticancer agents targeting rRNA biogenesis is growing. Cis-non-coding rRNAs, alternative to primary rRNA, have been shown to regulate rRNA biogenesis. We have recently detected bidirectional non-coding rRNAs that carry ribozyme-like properties. Anti-antisense oligonucleotides complementary to antisense non-coding rRNAs markedly stabilized the bidirectional transcripts and induced cell death in mouse lung cells. Here, we demonstrated that the same oligonucleotide killed mouse lung-cancer cells preferentially, compared with non-cancer sister lines, suggesting its potential utility for cancer treatment. A human version of anti-antisense oligonucleotide, complementary to an rDNA intergenic site, mediated apoptosis primarily in cancer cells. Autophagic activation was largely undifferentiable between the anti-antisense and other oligonucleotides and accounted for the undesired cytotoxicity in non-cancer cells. Co-treatment with chloroquine, an autophagy inhibitor, reduced cytotoxicity in the non-cancer cells, but retained the anti-antisense-mediated killings in cancer cells. Furthermore, the anti-antisense oligonucleotide stabilized bidirectional non-coding rRNAs predominantly in human cancer cells and perturbed rRNA biogenesis. Contributions of non-coding rRNAs to cell death were proven by transfection of in –vitro-synthesized transcripts. Taken together, cancer/non-cancer cells respond differently to stabilization of non-coding rRNAs, and such differential responses provide a window of opportunity to enhance anticancer efficacy.

Mammalian DEAD box protein Ddx51 acts in 3' end maturation of 28S rRNA by promoting the release of U8 snoRNA

Biogenesis of eukaryotic ribosomes requires a number of RNA helicases that drive molecular rearrangements at various points of the assembly pathway. While many ribosome synthesis factors are conserved among all eukaryotes, certain features of ribosome maturation, such as U8 snoRNA-assisted processing of the 5.8S and 28S rRNA precursors, are observed only in metazoan cells. Here, we identify the mammalian DEAD box helicase family member Ddx51 as a novel ribosome synthesis factor and an interacting partner of the nucleolar GTP-binding protein Nog1. Unlike any previously studied yeast helicases, Ddx51 is required for the formation of the 3' end of 28S rRNA. Ddx51 binds to pre-60S subunit complexes and promotes displacement of U8 snoRNA from pre-rRNA, which is necessary for the removal of the 3' external transcribed spacer from 28S rRNA and productive downstream processing. These data demonstrate the emergence of a novel factor that facilitates a pre-rRNA processing event specific for higher eukaryotes.

Estimation of ribosomal RNA transcription rate in situ

Traditionally, the rate of transcription is measured by metabolic labeling (e.g., the run-on assay), which can be carried out only in isolated or cultured cells. It has been difficult if not impossible to assess the rate of transcription of a gene in a specific cell type in situ. We show here that the quantity of 47S precursor ribosomal RNA (pre-rRNA), which correlates positively with the rate of rRNA transcription as measured by the run-on assay, can serve as an indicator for the rate of its transcription. We adopted this method as an in situ hybridization procedure to demonstrate its validity in vivo. The notion of using the quantity of the primary transcript as an indicator of the rate of transcription has the potential application in monitoring the rate of messenger RNA transcription in single cells within a tissue of complex cellular composition.

Cardiac hypertrophy in vivo is associated with increased expression of the ribosomal gene transcription factor UBF

The ribosomal DNA transcription-specific factor, UBF, is a key target for the regulation of ribosomal RNA synthesis and hypertrophic growth of isolated neonatal cardiomyocytes. In this study, we have examined whether UBF expression is also an important determinant of cardiac growth rates in vivo. We show that rDNA transcription, rRNA synthesis and UBF expression in left ventricular myocytes isolated from mice 1-6 weeks following transverse aortic constriction were significantly increased (2.5-3.5-fold) compared to the levels in myocytes from the left ventricle of sham-operated mice.

Functional inactivation of the mouse nucleolar protein Bop1 inhibits multiple steps in pre-rRNA processing and blocks cell cycle progression

Bop1 is a conserved nucleolar protein involved in rRNA processing and ribosome assembly in eukaryotes. Expression of its dominant-negative mutant Bop1 Delta in mouse cells blocks rRNA maturation and synthesis of large ribosomal subunits and induces a reversible, p53-dependent cell cycle arrest. In this study, we have conducted a deletion analysis of Bop1 and identified a new mutant, Bop1N2, that also acts as a potent inhibitor of cell cycle progression. Bop1N2 and Bop1 Delta are C-terminal and N-terminal deletion mutants, respectively, and share only 72 amino acid residues. Both mutant proteins are localized to the nucleolus and strongly inhibit rRNA processing, suggesting that activation of a cell cycle checkpoint by Bop1 mutants is linked to their inhibitory effects on rRNA and ribosome synthesis. By using these dominant-negative mutants as well as antisense oligonucleotides to interfere with endogenous Bop1, we identified specific rRNA processing steps that require Bop1 function in mammalian cells. Our data demonstrate that Bop1 is required for proper processing at four distinct sites located within the internal transcribed spacers ITS1 and ITS2 and the 3' external spacer. We propose a model in which Bop1 serves as an essential factor in ribosome formation that coordinates processing of the spacer regions in pre-rRNA.

Characterisation of transcriptionally active and inactive chromatin domains in neurons

The tandemly organised ribosomal DNA (rDNA) repeats are transcribed by a dedicated RNA polymerase in a specialised nuclear compartment, the nucleolus. There appears to be an intimate link between the maintenance of nucleolar structure and the presence of heterochromatic chromatin domains. This is particularly evident in many large neurons, where a single nucleolus is present, which is separated from the remainder of the nucleus by a characteristic shell of heterochromatin. Using a combined fluorescence in situ hybridisation and immunocytochemistry approach, we have analysed the molecular composition of this highly organised neuronal chromatin, to investigate its functional significance. We find that clusters of inactive, methylated rDNA repeats are present inside large neuronal nucleoli, which are often attached to the shell of heterochromatic DNA. Surprisingly, the methylated DNA-binding protein MeCP2, which is abundantly present in the centromeric and perinucleolar heterochromatin, does not associate significantly with the methylated rDNA repeats, whereas histone H1 does overlap partially with these clusters. Histone H1 also defines other, centromere-associated chromatin subdomains, together with the mammalian Polycomb group factor Eed. These data indicate that neuronal, perinucleolar heterochromatin consists of several classes of inactive DNA, that are linked to a fraction of the inactive rDNA repeats. These distinct chromatin domains may serve to regulate RNA transcription and processing efficiently and to protect rDNA repeats against unwanted silencing and/or homologous recombination events.

Processing of precursor rRNA in Euglena gracilis: identification of intermediates in the pathway to a highly fragmented large subunit rRNA

We have identified and characterized the stable steady-state intermediates that appear during formation of the cytoplasmic rRNA in Euglena gracilis. A 10.2 kb RNA is the precursor to both the small subunit (SSU) rRNA and 14 discrete fragments that comprise the large subunit (LSU) rRNA. The SSU rRNA is produced via two intermediates of 4.4 kb and 3.2 kb, whereas the LSU rRNA is generated by way of two RNA species of 5.8 kb and 5.3 kb. A number of unique intermediates are associated with a novel processing pathway by which the 14 mature fragments of the LSU rRNA are produced. Analysis of transcripts mapping within ITS1, the internal transcribed spacer separating the SSU and LSU rRNA coding regions, revealed that the LSU1 (=5.8S) rRNA is heterogeneous at its 5'-end, with a major cluster of primer extension products terminating approx. 4-5 nucleotides upstream from the predominant, mature 5'-end and a second, low-level extension product appearing further upstream within ITS1. The results reported here define the pre-rRNA processing pathway in E. gracilis and provide the basis for further studies of the mechanism of excision of the novel ITSs in this system.

Nucleolin functions in the first step of ribosomal RNA processing

The first processing step of precursor ribosomal RNA (pre-rRNA) involves a cleavage within the 5' external transcribed spacer. This processing requires sequences downstream of the cleavage site which are perfectly conserved among human, mouse and Xenopus and also several small nucleolar RNAs (snoRNAs): U3, U14, U17 and E3. In this study, we show that nucleolin, one of the major RNA-binding proteins of the nucleolus, is involved in the early cleavage of pre-rRNA. Nucleolin interacts with the pre-rRNA substrate, and we demonstrate that this interaction is required for the processing reaction in vitro. Furthermore, we show that nucleolin interacts with the U3 snoRNP. Increased levels of nucleolin, in the presence of the U3 snoRNA, activate the processing activity of a S100 cell extract. Our results suggest that the interaction of nucleolin with the pre-rRNA substrate might be a limiting step in the primary processing reaction. Nucleolin is the first identified metazoan proteinaceous factor that interacts directly with the rRNA substrate and that is required for the processing reaction. Potential roles for nucleolin in the primary processing reaction and in ribosome biogenesis are discussed.

A human 28S ribosomal RNA retropseudogene

A human genomic clone designated LhrRAX3 isolated from an X chromosome-specific library was found to have a 28S ribosomal RNA retropseudogene symbolized as RNRP2 within a 12.5-kb human DNA insert. The sequence of the rRNA retropseudogene has an identity of 96% with about 300 nucleotides at the 3'-terminus of the human 28S rRNA gene. RNRP2 is flanked by a pair of perfect direct repeats of 16 nucleotides, the hallmark characteristic of a processed pseudogene having been integrated into the genome. The structural element has a long A-rich tract at its 3'-end, apparently the result of an aberrant polyadenylation event of a RNA polymerase I transcript, prior to its subsequent reverse transcription and retroposition into the genome. An Alu repeat sequence truncated by 80 nucleotides at the 5'-region occurs about 800 base pairs downstream and is of opposite orientation to RNRP2. The Alu element is bounded by 16-nucleotide direct repeats and is a member of the Alu Y subfamily.

Analysis of nucleolar transcription and processing domains and pre-rRNA movements by in situ hybridization

We have examined the cytological localization of rRNA synthesis, transport, and processing events within the mammalian cell nucleolus by double-label fluorescent in situ hybridization analysis using probes for small selected segments of pre-rRNA, which have known half-lives. In particular, a probe for an extremely short-lived 5' region that is not found separate of the pre-rRNA identifies nascent transcripts within the nucleolus of an intact active cell, while other characterized probes identify molecules at different stages in the rRNA processing pathway. Through these studies, visualized by confocal and normal light microscopy, we (1) confirm that rDNA transcription occurs in small foci within nucleoli, (2) show that the nascent pre-rRNA transcripts and most likely also the rDNA templates are surprisingly extended in the nucleolus, (3) provide evidence that the 5' end of the nascent rRNA transcript moves more rapidly away from the template DNA than does the 3' end of the newly released transcript, and (4) demonstrate that the various subsequent rRNA processing steps occur sequentially further from the transcription site, with each early processing event taking place in a distinct nucleolar subdomain. These last three points are contrary to the generally accepted paradigms of nucleolar organization and function. Our findings also imply that the nucleolus is considerably more complex than the conventional view, inferred from electron micrographs, of only three kinds of regions - fibrillar centers, dense fibrillar components, and granular components - for the dense fibrillar component evidently consists of several functionally distinct sub-domains that correlate with different steps of ribosome biogenesis.

Early stages of pre-rRNA formation within the nucleolar ultrastructure of mouse cells studied by in situ hybridization with a 5'ETS leader probe

The first cleavage in the processing of the rRNA primary transcript in mammals occurs within the 5'-terminal region of the 5' external transcribed spacer (5'ETS), which makes the upstream portion of this spacer a selective marker of nascent transcripts. Moreover, short treatments with low doses of actinomycin D (AMD), which selectively suppress pre-rRNA synthesis and allow processing of preformed pre-rRNAs, result in the production of prematurely terminated transcripts essentially spanning the 5'ETS leader region. To gain further insight into the intranucleolar localization of early stages of preribosome formation we analyzed the distribution of this specific pre-rRNA segment by in situ hybridization at the ultrastructural level in AMD-treated or in control 3T3 mouse cells. In control cells, 5'ETS leader rRNA was detected at the border of the fibrillar centers and over the dense fibrillar component, in agreement with previous data suggesting that rRNA gene transcription takes place at the border of the fibrillar centers before a rapid transfer of the nascent trancript to the dense fibrillar component. Observation of cells subjected to a short treatment with low doses of AMD fully supports this conclusion, with the prematurely terminated 5'ETS leader-containing transcripts detected at the border of enlarged fibrillar centers. With prolonged periods of AMD treatment even the partial transcription of rRNA genes is blocked and fibrillar centers of typically segregated nucleoli show no positive signals with the 5'ETS leader probe. We also analyzed in parallel the intranucleolar distribution of U3 small nucleolar RNA, which is involved in 5'ETS processing, by hybridization with biotinylated antisense oligonucleotides. Distribution of U3 roughly paralleled that of 5'ETS leader rRNA in untreated cells. However, U3 RNA persisted in the dense fibrillar component of segregated nucleoli whatever the conditions of drug treatment, i.e., even after a thorough chase of the rRNA precursors from this nucleolar compartment.

Intranuclear retention of ribosomal RNAs in response to herpes simplex virus type 1 infection

The localization of ribosomal RNA (rRNA) was investigated at the ultrastructural level in herpes simplex virus type 1 infected HeLa cells using three distinct biotinylated probes which bind in sequence to three different segments of the ribosomal genes. Comparison of the above with the signal levels obtained from non-infected cells reveals information about the effects of HSV-1 infection on ribosome biogenesis. A probe specific for the 5′ end portion of pre-rRNA labeled all nucleoli of both non-infected and infected cells in the same way, that is, it mainly labeled the dense fibrillar component and the border of the fibrillar centers but only slightly labeled the granular component. This indicates that the initial cleavage of pre-rRNA in herpes infection still occurs in the 5′ region of the 5′ external transcribed spacer. However, a probe specific for 18 S rRNA labeled the granular component of the nucleoli more intensely after infection. In addition, significant amounts of rRNA molecules were present within the intranuclear viral region, except over the enclosed viral dense bodies, and within the virus-enlarged clusters of interchromatin granules. The data indicate that the still enigmatic viral dense bodies, which are nucleolus-related structures, are excluded from the marked intranuclear retention of ribosomal RNAs and, in addition, reveal a possible role for the interchromatin granules of infected cells in the regulation of the export of the ribosomal subunits towards the cytoplasm.

Actinomycin D stimulates the transcription of rRNA minigenes transfected into mouse cells. Implications for the in vivo hypersensitivity of rRNA gene transcription

The in vivo hypersensitivity of eukaryotic rRNA gene transcription to actinomycin D has long been known, but this effect could not be reproduced in model systems and its molecular mechanisms remain uncertain. We studied the action of actinomycin D using mouse rRNA minigenes (with RNA polymerase I promoter and terminator signals), carrying truncated mouse or human rDNA inserts, which are faithfully transcribed upon transient transfection into mouse cells. Low concentrations (0.01-0.08 micrograms/ml) of actinomycin D caused within 1-2 h a 2-7-fold stimulation of the transcription of rRNA minigenes which is inversely related to the size of the rDNA transcript. With transcripts longer than 3 kb the effect was reversed and at 4 kb a practically complete inhibition of the formation of full-length transcripts was observed, accompanied, however, by an enhanced accumulation of unfinished rDNA transcripts. The dependence of actinomycin D action on transcript length was also observed with lacZ gene segments of different size inserted into the mouse rRNA minigenes. The transcription initiation of endogenous rRNA genes was also stimulated by the low doses of actinomycin D as indicated by the enhanced synthesis of unfinished rDNA transcripts (spanning mainly the 5' external transcribed spacer), whereas the synthesis of full-length transcripts was abolished. Removal of actinomycin D from the medium caused within 8-24 h a dramatic increase of the transcription from all rRNA minigenes tested. This stimulation was also inversely related to the size of the transcripts and varied from twofold to fivefold for the 3-4-kb transcripts to about 50-80-fold for the basic minigene transcript (395 nucleotides). The amount of endogenous aborted rDNA transcripts was also markedly increased, but the synthesis of full-length transcripts was not restored even 24 h after removal of the drug. The present results reproduce in a model cellular system the in vivo hypersensitivity of rRNA gene transcription to actinomycin D and reveal that the major factor involved is the size of the rRNA gene transcript. This effect requires only the basic rRNA gene promoter and terminator signals and does not depend on the G + C content of the RNA polymerase I transcripts. We suggest that at low concentrations, the intercalation of actinomycin D changes the conformation of DNA in the promoter region in a manner that stimulates the transcription of both endogenous and transfected rRNA genes.(ABSTRACT TRUNCATED AT 400 WORDS)

Processing of truncated mouse or human rRNA transcribed from ribosomal minigenes transfected into mouse cells

The processing of pre-rRNA in eukaryotic cells involves a complex pattern of nucleolytic reactions taking place in preribosomes with the participation of several nonribosomal proteins and small nuclear RNAs. The mechanism of these reactions remains largely unknown, mainly because of the absence of faithful in vitro assays for most processing steps. We have developed a pre-rRNA processing system using the transient expression of ribosomal minigenes transfected into cultured mouse cells. Truncated mouse or human rRNA genes are faithfully transcribed under the control of mouse promoter and terminator signals. The fate of these transcripts is analyzed by the use of reporter sequences flanking the rRNA gene inserts. Both mouse and human transcripts, containing the 3' end of 18S rRNA-encoding DNA (rDNA), internal transcribed spacer (ITS) 1, 5.8S rDNA, ITS 2, and the 5' end of 28S rDNA, are processed predominantly to molecules coterminal with the natural mature rRNAs plus minor products corresponding to cleavages within ITS 1 and ITS 2. To delineate cis-acting signals in pre-rRNA processing, we studied series of more truncated human-mouse minigenes. A faithful processing at the 18S rRNA/ITS 1 junction can be observed with transcripts containing only the 60 3'-terminal nucleotides of 18S rRNA and the 533 proximal nucleotides of ITS 1. However, further truncation of 18S rRNA (to 8 nucleotides) or of ITS 1 (to 48 nucleotides) abolishes the cleavage of the transcript. Processing at the ITS 2/28S rRNA junction is observed with truncated transcripts lacking the 5.8S rRNA plus a major part of ITS 2 and containing only 502 nucleotides of 28S rRNA. However, further truncation of the 28S rRNA segment to 217 nucleotides abolishes processing. Minigene transcripts containing most internal sequences of either ITS 1 or ITS 2, but devoid of ITS/mature rRNA junctions, are not processed, suggesting that the cleavages in vivo within either ITS segment are dependent on the presence in cis of mature rRNA sequences. These results show that the major cis signals for pre-rRNA processing at the 18S rRNA/ITS 1 or the ITS2/28S rRNA junction involve solely a limited critical length of the respective mature rRNA and adjacent spacer sequences.

Processing of truncated mouse or human rRNA transcribed from ribosomal minigenes transfected into mouse cells

The processing of pre-rRNA in eukaryotic cells involves a complex pattern of nucleolytic reactions taking place in preribosomes with the participation of several nonribosomal proteins and small nuclear RNAs. The mechanism of these reactions remains largely unknown, mainly because of the absence of faithful in vitro assays for most processing steps. We have developed a pre-rRNA processing system using the transient expression of ribosomal minigenes transfected into cultured mouse cells. Truncated mouse or human rRNA genes are faithfully transcribed under the control of mouse promoter and terminator signals. The fate of these transcripts is analyzed by the use of reporter sequences flanking the rRNA gene inserts. Both mouse and human transcripts, containing the 3' end of 18S rRNA-encoding DNA (rDNA), internal transcribed spacer (ITS) 1, 5.8S rDNA, ITS 2, and the 5' end of 28S rDNA, are processed predominantly to molecules coterminal with the natural mature rRNAs plus minor products corresponding to cleavages within ITS 1 and ITS 2. To delineate cis-acting signals in pre-rRNA processing, we studied series of more truncated human-mouse minigenes. A faithful processing at the 18S rRNA/ITS 1 junction can be observed with transcripts containing only the 60 3'-terminal nucleotides of 18S rRNA and the 533 proximal nucleotides of ITS 1. However, further truncation of 18S rRNA (to 8 nucleotides) or of ITS 1 (to 48 nucleotides) abolishes the cleavage of the transcript. Processing at the ITS 2/28S rRNA junction is observed with truncated transcripts lacking the 5.8S rRNA plus a major part of ITS 2 and containing only 502 nucleotides of 28S rRNA. However, further truncation of the 28S rRNA segment to 217 nucleotides abolishes processing. Minigene transcripts containing most internal sequences of either ITS 1 or ITS 2, but devoid of ITS/mature rRNA junctions, are not processed, suggesting that the cleavages in vivo within either ITS segment are dependent on the presence in cis of mature rRNA sequences. These results show that the major cis signals for pre-rRNA processing at the 18S rRNA/ITS 1 or the ITS2/28S rRNA junction involve solely a limited critical length of the respective mature rRNA and adjacent spacer sequences.

Processing of eukaryotic ribosomal RNA

In summary, it can be argued that the understanding of eukaryotic rRNA processing is no less important than the understanding of mRNA maturation, since the capacity of a cell to carry out protein synthesis is controlled, in part, by the abundance of ribosomes. Processing of pre-rRNA is highly regulated, involving many cellular components acting either alone or as part of a complex. Some of these components are directly involved in the modification and cleavage of the precursor rRNA, while others direct the packaging of the rRNA into ribosome subunits. As is the case for pre-mRNA processing, snoRNPs are clearly involved in eukaryotic rRNA processing, and have been proposed to assemble with other proteins into at least one complex called a "processosome" (17), which carries out the ordered processing of the pre-rRNA and its assembly into ribosomes. The formation of a processing complex clearly makes possible the regulation required to coordinate the abundance of ribosomes with the physiological and developmental changes of a cell. It may be that eukaryotic rRNA processing is even more complex than pre-mRNA maturation, since pre-rRNA undergoes extensive nucleotide modification and is assembled into a complex structure called the ribosome. Undoubtedly, features of the eukaryotic rRNA-processing pathway have been conserved evolutionarily, and the genetic approach available in yeast research (6) should provide considerable knowledge that will be useful for other investigators working with higher eukaryotic systems. Interestingly, it was originally hoped that the extensive work and understanding of bacterial ribosome formation would provide a useful paradigm for the process in eukaryotes. However, although general features of ribosome structure and function are highly conserved between bacterial and eukaryotic systems, the basic strategy in ribosome biogenesis seems to be, for the most part, distinctly different. Thus, the detailed molecular mechanisms for rRNA processing in each kingdom will have to be independently deciphered in order to elucidate the features and regulation of this important process for cell survival.

A U3 small nuclear ribonucleoprotein-requiring processing event in the 5' external transcribed spacer of Xenopus precursor rRNA

A processing site has been identified within the 5' external transcribed spacer (ETS) of Xenopus laevis and X. borealis pre-RNAs, and this in vivo processing can be reproduced in vitro. It involves a stable and specific association of the pre-rRNA with factors in the cell extract, including at least four RNA-contacting polypeptides, yielding a distinct complex that sediments at 20S. Processing also requires the U3 small nuclear RNA. This processing, at residue +105 of the 713-nucleotide X. laevis 5' ETS, is highly reminiscent of the initial processing cleavage of mouse pre-rRNA within its 3.5-kb 5' ETS, previously thought to be mammal specific. The frog and mouse processing signals share a short essential sequence motif, and mouse factors can faithfully process the frog pre-rRNA. This conservation suggests that this 5' ETS processing site serves an evolutionarily selective function.

Sequence analysis of the rDNA spacer of Paracentrotus lividus and observations about pre-rRNA processing. NTS sequence of Paracentrotus lividus rDNA

We have isolated and sequenced one intergenic region and a small part of the flanking regions (18S and 26S rRNA coding regions) of the rRNA-encoding genes (rDNA) from the sea urchin Paracentrotus lividus. This region is about 3.8 Kb long. Northern blot hybridizations and S1 mapping experiments demonstrated the presence of a partially processed 21S rRNA precursor while has the same 5' terminus as the 32S primary precursor, also in developmental stages characterized by a low rate of rRNA synthesis.

A U3 small nuclear ribonucleoprotein-requiring processing event in the 5' external transcribed spacer of Xenopus precursor rRNA

A processing site has been identified within the 5' external transcribed spacer (ETS) of Xenopus laevis and X. borealis pre-RNAs, and this in vivo processing can be reproduced in vitro. It involves a stable and specific association of the pre-rRNA with factors in the cell extract, including at least four RNA-contacting polypeptides, yielding a distinct complex that sediments at 20S. Processing also requires the U3 small nuclear RNA. This processing, at residue +105 of the 713-nucleotide X. laevis 5' ETS, is highly reminiscent of the initial processing cleavage of mouse pre-rRNA within its 3.5-kb 5' ETS, previously thought to be mammal specific. The frog and mouse processing signals share a short essential sequence motif, and mouse factors can faithfully process the frog pre-rRNA. This conservation suggests that this 5' ETS processing site serves an evolutionarily selective function.

The terminal balls characteristic of eukaryotic rRNA transcription units in chromatin spreads are rRNA processing complexes

When spread chromatin is visualized by electron microscopy, active rRNA genes have a characteristic Christmas tree appearance: From a DNA "trunk" extend closely packed "branches" of nascent transcripts whose ends are decorated with terminal "balls." These terminal balls have been known for more than two decades, are shown in most biology textbooks, and are reported in hundreds of papers, yet their nature has remained elusive. Here, we show that a rRNA-processing signal in the 5'-external transcribed spacer (ETS) of the Xenopus laevis ribosomal primary transcript forms a large, processing-related complex with factors of the Xenopus oocyte, analogous to 5' ETS processing complexes found in other vertebrate cell types. Using mutant rRNA genes, we find that the same rRNA residues are required for this biochemically defined complex formation and for terminal ball formation, analyzed electron microscopically after injection of these cloned genes into Xenopus oocytes. This, plus other presented evidence, implies that rRNA terminal balls in Xenopus, and by inference, also in the multitude of other species where they have been observed, are the ultrastructural visualization of an evolutionarily conserved 5' ETS processing complex that forms on the nascent rRNA.

Alternative pre-rRNA processing pathways in human cells and their alteration by cycloheximide inhibition of protein synthesis

rRNA processing pathways in humans have been reinvestigated through systematic Northern-blot hybridizations of HeLa cell nuclear RNA with a collection of digoxigenin-labeled rDNA probes from different regions of the human rDNA transcriptional unit. In addition to the known 45S, 41S, 32S and 21S pre-rRNA, two major pre-rRNA fractions were identified; a '30S' (about 5800 nucleotides) precursor to 18S rRNA containing an external transcribed spacer at the 5' end (ETS) and internal transcribed spacer (ITS) 1 sequences and a '12S' (about 950 nucleotides) precursor to 5.8S rRNA containing ITS 2 sequences. These pre-rRNA species do not react with probes located near the 3'-terminal segments of ITS 1 or ITS 2, thus suggesting that processive endonuclease cuts occur within ITS spacer sequences. The simultaneous occurrence of at least two alternative 45S pre-rRNA processing pathways is deduced, which correspond to a different temporal order of endonuclease attack at the sites located near the 5' end of 18S rRNA and within ITS 1. In-vivo labeling experiments with [14C]uridine revealed that inhibition of protein synthesis with cycloheximide abolishes the endonuclease cut at the 5' end of 18S rRNA and the formation of 41S pre-rRNA, while the cut within ITS 1 and the processing to 32S and '30S' pre-rRNA remains relatively unaltered.

Structure analysis of the 5' external transcribed spacer of the precursor ribosomal RNA from Saccharomyces cerevisiae

Full-length precursor ribosomal RNA molecules were produced in vitro using as a template, a plasmid containing the yeast 35 S pre-rRNA gene under the control of the phage T3 promoter. The higher-order structure of the 5'-external transcribed spacer (5' ETS) sequence in the 35S pre-rRNA molecule was studied using dimethylsulfate, 1-cyclohexyl-3-(2-morpholinoethyl)-carbodiimide metho-p-toluenesulfonate, RNase T1 and RNase V1 as structure-sensitive probes. Modified residues were detected by primer extension. Data produced were used to evaluate several theoretical structure models predicted by minimum free-energy calculations. A model for the entire 5'ETS region is proposed that accommodates 82% of the residues experimentally shown to be in either base-paired or single-stranded structure in the correct configuration. The model contains a high degree of secondary structure with ten stable hairpins of varying lengths and stabilities. The hairpins are composed of the Watson-Crick A.T and G.C pairs plus the non-canonical G.U pairs. Based on a comparative analysis of the 5' ETS sequence from Saccharomyces cerevisiae and Schizosaccharomyces pombe, most of the base-paired regions in the proposed model appear to be phylogenetically supported. The two sites previously shown to be crosslinked to U3 snRNA as well as the previously proposed recognition site for processing and one of the early processing site (based on sequence homology to the vertebrate ETS cleavage site) are located in single-stranded regions in the model. The present folding model for the 5' ETS in the 35 S pre-rRNA molecule should be useful in the investigations of the structure, function and processing of pre-rRNA.

An experimental study of Saccharomyces cerevisiae U3 snRNA conformation in solution

The conformation of Saccharomyces cerevisiae U3 snRNA (snR17A RNA) in solution was studied using enzymatic and chemical probes. In vitro synthesized and authentic snR17A RNAs have a similar conformation in solution. The S. cerevisiae U3 snRNA is folded in two distinct domains. The 5'-domain has a low degree of compactness; it is constituted of two stem-loop structures separated by a single-stranded segment, which has recently been proposed to basepair with the 5'-ETS of pre-ribosomal RNA. We demonstrate that, as previously proposed, the 5'-terminal region of U3 snRNA has a different structure in higher and lower eukaryotes and that this may be related to pre-rRNA 5'-ETS evolution. The S. cerevisiae U3 snRNA 3'-domain has a cruciform secondary structure and a compact conformation resulting from an higher order structure involving the single-stranded segments at the center of the cross and the bottom parts of helices. Compared to tRNA, where long range interactions take place between terminal loops, this represents another kind of tertiary folding of RNA molecules that will deserve further investigation, especially since the implicated single-strands have highly evolutionarily conserved primary structures that are involved in snRNP protein binding.

Retroposons do jump: a B2 element recently integrated in an 18S rDNA gene

Several cDNA clones were isolated from cDNA libraries constructed with mRNA longer than 28S RNA from the murine cell line PYS-2/12. The plasmids have inserts containing 1-1.2 kb of the ribosomal 5' external transcribed spacer followed by nearly 700 nt of sequence for 18S rRNA and ending with a B2 element (retroposon). The cloned sequence differed in a few positions from published ribosomal sequences. The 3' adjacent genomic sequence was obtained by polymerase chain reaction (PCR) and showed that the B2 element has a poly(A) tail of about 50 nt and is surrounded by perfect direct repeats of 15 nt. Analysis of genomic DNA from several murine cell lines revealed that PYS cells contain at least one copy of 18S RNA with the B2 element which is not present in the genome of other murine cell lines derived from the same teratocarcinoma. Similarly, rRNA transcripts containing the B2 element were only detected in PYS cells. According to the publication dates of the different cell lines, the B2 element must have been integrated into an rRNA transcription unit during the years 1970 through 1974 thus proving that retroposons (SINEs) can still be inserted into the genome in our times.

Preribosomal RNA processing in Xenopus oocytes does not include cleavage within the external transcribed spacer as an early step

Recently it has been reported that U3 snRNA is necessary for: (a) internal cleavage at +651/+657 within the external transcribed spacer (ETS) of mouse precursor ribosomal RNA (pre-rRNA); and (b) cleavage at the 5' end of 5.8S rRNA in Xenopus oocytes. To study if U3 snRNA plays a role at more than one processing site in the same system, we have investigated whether internal cleavage sites exist within the ETS of Xenopus oocyte pre-rRNA. The ETS of Xenopus pre-rRNA contains the consensus sequence for the mammalian early processing site (+651/+657 in mouse pre-rRNA), but freshly prepared RNA from Xenopus oocytes has no cuts in this region. The only putative cleavage sites we found in the ETS of Xenopus oocyte pre-rRNA are a cluster further downstream of the mouse early processing site consensus sequence. This cluster is not homologous to the mouse +651/+657 sites because unlike the latter it is (a) not abolished by disruption of U3 snRNA, (b) not cleaved during early steps of pre-rRNA processing, and (c) lacks sequence similarity to the +651/+657 consensus. Therefore, pre-rRNA of Xenopus oocytes does not cleave within the ETS as an early step in rRNA processing. We conclude that cleavage within the ETS is not an obligatory early step needed for the rest of rRNA maturation.

Expression of mouse and frog rRNA genes: transcription and processing

This article summarizes a number of lines of investigation of rRNA gene expression that are ongoing in the laboratory. These studies focus on mouse and frog, two distant vertebrate species. One major conclusion is that the basic properties of rRNA gene expression appear remarkably well conserved in evolution, with only relatively minor perturbations between frog and mouse, contrary to the common interpretation of the species-selectively between mouse and human rDNA transcription (e.g., 1). This is true both for the process of rDNA transcription and for the subsequent rRNA processing event.

Sequence organization and RNA structural motifs directing the mouse primary rRNA-processing event

The first processing step in the maturation of mouse precursor rRNA involves cleavage at nucleotide ca. +650, at the 5' border of a 200-nucleotide region that is conserved across mammals and contains the sequences that direct the processing. To identify the relevant sequence elements, we used rRNAs with small internal mutations and short pre-rRNA substrates. Much of the region can be mutated without appreciable effect, but nucleotides +655 to +666 appear to be absolutely required and short segments surrounding +750 and +810 markedly stimulate processing. The minimal processing signal corresponds to rRNA nucleotides +645 to +672. Formation of a ribonucleoprotein complex of retarded electrophoretic mobility is evidently necessary but not sufficient for processing. Computer-assisted analysis suggested a phylogenetic- and mutant-supported secondary structure in which the minimal processing signal forms a stem with the +655 region in the loop, and there is a separate branched duplex containing the downstream stimulatory sequences. Use of antisense RNA, in trans and in cis, to sequester the +655 region in a duplex supported the hypothesis that this critical region was needed in a single-stranded conformation for processing and for specific complex formation.

Secondary structure of the 5' external transcribed spacer of vertebrate pre-rRNA. Presence of phylogenetically conserved features

Eucaryotic pre-rRNA spacers are evolutionarily highly variable in sequence and size, and are markedly expanded in vertebrates, particularly in mammals. The longest mammalian spacer by far is the 3.5-4-kb 5' external transcribed spacer (5'-ETS), which is excised in two steps. We present a folding model for the entire mammalian 5'-ETS, derived from comparative analyses and thermodynamic predictions for mouse, rat and human sequences, which should prove helpful in identifying cis-acting processing signals, particularly those involved in its early internal cleavage, for which U3 RNA is an essential factor. Although the rodent and primate sequences have extensively diverged, a series of relatively conserved sequence tracts can nevertheless be identified: they participate in base-pairing, preserved through the occurrence of compensatory base changes, which delineate four independent domains of secondary structure. The first domain is located entirely upstream from the site of internal cleavage. The second domain, immediately downstream from this cleavage site, encompasses most of the region required for faithful and efficient in vitro processing at this site. Phylogenetically supported conserved structures also define two other independent domains, encompassing most of the 5'-ETS length, with the presence of giant hairpins (extending from the conserved core elements) which exhibit both some analogous features and substantial differences between man and mouse. The comparative analysis was extended to the two other vertebrate sequences available so far, amphibians Xenopus laevis and Xenopus borealis. The amphibian folding model, supported by comparative evidence between these two species, displays some features in common with the mammalian model, with a similar organization into four separate domains of secondary structure, suggesting the functional relevance of these structures in the process of ribosome formation.

News from the nucleolus: rRNA gene expression

Although the typical, actively growing eukaryotic cell contains over 10,000 different transcripts, half of its RNA synthetic capacity is devoted to the production of a single kind of RNA. This is the pre-ribosomal RNA, which is synthesized in a special compartment of the nucleus, the nucleolus, and is the exclusive product of transcription by RNA polymerase I. In vivo and in vitro approaches have revealed the major features of rRNA gene transcription and of the subsequent processing of the primary transcript.

Sequence organization and RNA structural motifs directing the mouse primary rRNA-processing event

The first processing step in the maturation of mouse precursor rRNA involves cleavage at nucleotide ca. +650, at the 5' border of a 200-nucleotide region that is conserved across mammals and contains the sequences that direct the processing. To identify the relevant sequence elements, we used rRNAs with small internal mutations and short pre-rRNA substrates. Much of the region can be mutated without appreciable effect, but nucleotides +655 to +666 appear to be absolutely required and short segments surrounding +750 and +810 markedly stimulate processing. The minimal processing signal corresponds to rRNA nucleotides +645 to +672. Formation of a ribonucleoprotein complex of retarded electrophoretic mobility is evidently necessary but not sufficient for processing. Computer-assisted analysis suggested a phylogenetic- and mutant-supported secondary structure in which the minimal processing signal forms a stem with the +655 region in the loop, and there is a separate branched duplex containing the downstream stimulatory sequences. Use of antisense RNA, in trans and in cis, to sequester the +655 region in a duplex supported the hypothesis that this critical region was needed in a single-stranded conformation for processing and for specific complex formation.

The first pre-rRNA-processing event occurs in a large complex: analysis by gel retardation, sedimentation, and UV cross-linking

The first processing event that mouse pre-rRNA undergoes occurs within the external transcribed spacer and is efficiently reproduced in vitro. Analysis with nondenaturing polyacrylamide gels revealed the formation of heparin-resistant complexes of retarded electrophoretic mobility on the substrate rRNA. The specificity of these complexes was demonstrated by their elimination due to competition with processing-competent, but not with processing-incompetent, rRNAs. Furthermore, complex formation, like the processing cleavage, required only 28 nucleotides of rRNA sequence adjacent to the processing site but was stimulated by additional downstream conserved sequences. These processing complexes formed in a time-dependent manner, and once assembled, they were stable to challenge by competitor rRNA and remained on the processed rRNA. Their sedimentation coefficient was approximately 20S. UV cross-linking studies with 4-thiouridine-substituted rRNA have identified six polypeptides, 52 to 250 kilodaltons, that are specifically bound to the rRNA processing substrate.

The first pre-rRNA-processing event occurs in a large complex: analysis by gel retardation, sedimentation, and UV cross-linking

The first processing event that mouse pre-rRNA undergoes occurs within the external transcribed spacer and is efficiently reproduced in vitro. Analysis with nondenaturing polyacrylamide gels revealed the formation of heparin-resistant complexes of retarded electrophoretic mobility on the substrate rRNA. The specificity of these complexes was demonstrated by their elimination due to competition with processing-competent, but not with processing-incompetent, rRNAs. Furthermore, complex formation, like the processing cleavage, required only 28 nucleotides of rRNA sequence adjacent to the processing site but was stimulated by additional downstream conserved sequences. These processing complexes formed in a time-dependent manner, and once assembled, they were stable to challenge by competitor rRNA and remained on the processed rRNA. Their sedimentation coefficient was approximately 20S. UV cross-linking studies with 4-thiouridine-substituted rRNA have identified six polypeptides, 52 to 250 kilodaltons, that are specifically bound to the rRNA processing substrate.

The U3 small nucleolar ribonucleoprotein functions in the first step of preribosomal RNA processing

The first cleavage in mammalian pre-rRNA maturation occurs near the 5' end within the 5' external transcribed spacer. Using mouse cell extracts, we show that this processing is abolished by micrococcal nuclease pretreatment. Autoantibodies that recognize the U3, U8, and U13 snRNPs (anti-fibrillarin) deplete processing activity from the extract and selectively immunoprecipitate both rRNA substrates and processing products from the reaction. Specific involvement of the U3 snRNP is demonstrated by native gel electrophoresis of the processing reaction followed by Northern blotting and by oligonucleotide-directed RNAase H abolition of processing activity. Our identification of U3 function is discussed with respect to the molecular basis of pre-rRNA recognition by the U3 snRNP, possible roles of U3 and other nucleolar snRNPs in rRNA processing, and the morphological organization of the nucleolus and the ribosomal transcription complex.

The 5' end of U3 snRNA can be crosslinked in vivo to the external transcribed spacer of rat ribosomal RNA precursors

From previous work it was known that U3 RNA is hydrogen bonded to nucleolar 28 S to 35 S RNA and can be covalently crosslinked to RNA of greater than 28 S by irradiation in vivo with long-wave ultraviolet light in the presence of 4'-aminomethyl-4,5',8-trimethylpsoralen (AMT psoralen). Here we use a novel sandwich blot technique to identify these large nucleolar RNA species as rRNA precursors and to map the site(s) of crosslinking in vivo. The crosslink occurs between one or more residues near the 5' end of U3 RNA and a 380 nucleotide region of the rat rRNA external transcribed spacer (ETS1). We have sequenced this region of the rat ETS and we show that it includes an RNA-processing site analogous to those previously mapped to approximately 3.5 kb upstream from the 5' end of mouse and human 18 S rRNAs.

Enhancement of c-erbA proto-oncogene expression by glucocorticoid hormones in S49.1 lymphoma cells

The modifications of the mRNA levels of the c-myc and c-erbA proto-oncogenes during the dexamethasone-induced decrease of S49.1 cell proliferation have been studied. The levels of c-myc mRNA decreased significantly between 3 and 18 h after dexamethasone (1 microM) treatment. In contrast, a significant increase in the levels of a 2.6 kb c-erbA mRNA was observed between 6 and 18 h after hormone treatment. Cycloheximide treatment of S49.1 cells increased the levels of c-erbA RNA and overcome the enhancing effect of dexamethasone on the expression of this proto-oncogene, suggesting that ongoing protein synthesis is necessary to elicit this hormone effect. The associated decrease of cell proliferation and changes in c-myc and c-erbA mRNA levels after dexamethasone treatment suggest that such oncogenes might be involved in the dexamethasone-mediated control of lymphoid cell growth.

Analysis of pre-rRNAs in heat-shocked HeLa cells allows identification of the upstream termination site of human polymerase I transcription

Human rRNA precursor from normal or stressed HeLa cells were studied by S1 nuclease mapping of unlabeled RNA and by antisense RNase mapping of RNA from cells that had been labeled in vivo with [32P]PO4. Heating cells to 43 degrees C decreased the amount of newly synthesized rRNA to less than 5% of the control level and led to greater than 95% inhibition of transcription termination at a region 355 to 362 nucleotides downstream of the 3' end of 28S rRNA, with readthrough continuing into the next transcription unit. Heating of cells to 42 degrees C led to 60% inhibition of termination at this site; 50% of transcripts that extended into the nontranscribed spacer ended in a region 200 to 210 nucleotides upstream of the polymerase I (Pol I) initiation site. This is presumed to be the human upstream transcription termination site because of the absence of RNAs with a 5' end corresponding to this region, the location relative to the Pol I initiation site (which is similar to the location of upstream terminators in other species), and the fact that it is 15 to 25 nucleotides upstream of the sequence GGGTTGACC, which has an 8-of-9 base identity with the sequence 3' of the downstream termination site. Surprisingly, treatment of cells with sodium arsenite, which also leads to the induction of a stress response, did not inhibit termination. Pol I initiation was decreased to the same extent as termination, which lends support to the hypothesis that termination and initiation are coupled. Although termination was almost completely inhibited at 43 degrees C, the majority of the recently synthesized rRNAs were processed to have the correct 3' end of 28S. This finding suggests that 3'-end formation can involve an endonucleolytic cut and is not solely dependent on exonucleolytic trimming of correctly terminated rRNAs.

U3 small nuclear RNA can be psoralen-cross-linked in vivo to the 5' external transcribed spacer of pre-ribosomal-RNA

U3 small nuclear RNA is hydrogen-bonded to high molecular weight nucleolar RNA and can be isolated from greater than 60S pre-ribosomal ribonucleoprotein particles, suggesting that it is involved in processing of ribosomal RNA precursors (pre-rRNA) or in ribosome biogenesis. Here we have used in vivo psoralen cross-linking to identify the region of pre-rRNA interacting with U3 RNA. Quantitative hybridization selection/depletion experiments with clones of rRNA-encoding DNA (rDNA) and cross-linked nuclear RNA showed that all of the cross-linked U3 RNA was associated with a region that includes the external transcribed spacer (ETS) at the 5' end of the human rRNA precursor. To further identify the site of interaction within the approximately 3.7-kilobase ETS, Southern blots of rDNA clones were sandwich-hybridized with cross-linked RNA and then probed for cross-linked U3 RNA. These experiments showed that U3 RNA was cross-linked to a 258-base sequence between nucleotides +438 and +695, just downstream of the ETS early cleavage site (+414). The localization of U3 to this region of the rRNA precursor was not expected from previous models for a base-paired U3-rRNA interaction and suggests that U3 plays a role in the initial pre-rRNA processing event.

Structure of the 5'-external transcribed spacer of the human ribosomal RNA gene

We report the complete nucleotide sequence of the 3627 bp long 5'-external transcribed spacer (ETS) of a human ribosomal RNA gene. This sequence exhibits only very limited homologies with its mouse counterpart, the only other mammalian specimen analyzed so far. It has very peculiar compositional characteristics, with a highly biased base content (very rich in G + C, very poor in A) and also some very strong dinucleotide preferences. Interestingly, these specific features are shared by the mouse sequence, despite the extensive sequence divergence, and also apply to the other transcribed spacers of mammals indicating that a common and strong structural constraint is exerted on all these regions of the ribosomal gene. An outstanding secondary structure can be formed within the human ETS RNA, which could have a significant role in preribosome assembly.

Analysis of pre-rRNAs in heat-shocked HeLa cells allows identification of the upstream termination site of human polymerase I transcription

Human rRNA precursor from normal or stressed HeLa cells were studied by S1 nuclease mapping of unlabeled RNA and by antisense RNase mapping of RNA from cells that had been labeled in vivo with [32P]PO4. Heating cells to 43 degrees C decreased the amount of newly synthesized rRNA to less than 5% of the control level and led to greater than 95% inhibition of transcription termination at a region 355 to 362 nucleotides downstream of the 3' end of 28S rRNA, with readthrough continuing into the next transcription unit. Heating of cells to 42 degrees C led to 60% inhibition of termination at this site; 50% of transcripts that extended into the nontranscribed spacer ended in a region 200 to 210 nucleotides upstream of the polymerase I (Pol I) initiation site. This is presumed to be the human upstream transcription termination site because of the absence of RNAs with a 5' end corresponding to this region, the location relative to the Pol I initiation site (which is similar to the location of upstream terminators in other species), and the fact that it is 15 to 25 nucleotides upstream of the sequence GGGTTGACC, which has an 8-of-9 base identity with the sequence 3' of the downstream termination site. Surprisingly, treatment of cells with sodium arsenite, which also leads to the induction of a stress response, did not inhibit termination. Pol I initiation was decreased to the same extent as termination, which lends support to the hypothesis that termination and initiation are coupled. Although termination was almost completely inhibited at 43 degrees C, the majority of the recently synthesized rRNAs were processed to have the correct 3' end of 28S. This finding suggests that 3'-end formation can involve an endonucleolytic cut and is not solely dependent on exonucleolytic trimming of correctly terminated rRNAs.

Alternative mechanisms for gene activation induced by poly(rI).poly(rC) and Newcastle disease virus

After poly(rI).poly(rC) induction of FS-4 fibroblasts, both human interferon-beta (IFN-beta) mRNA and an additional induced RNA class (12S RNA) hybridize to a genomic cosmid clone containing the human IFN-beta gene as well as 35 kbp of flanking sequences. However, this coinduced 12S RNA does not originate from regions in the neighborhood of the IFN-beta gene, but hybridizes to the genomic cosmid clone via repetitive Alu-family sequences. While IFN-beta mRNA rapidly decays after reaching a maximum 2-4 h after induction, this 12S RNA is stably maintained in the fibroblast cell for more than 16 h. Contrary to IFN-beta mRNA, the level of the 12S RNA is not further elevated by superinduction conditions (cycloheximide treatment) during poly(rI).poly(rC) induction. However, subsequent to treatment with the weaker viral inducer Newcastle disease virus (NDV) both IFN-beta and the 12S RNA transcripts are induced to a higher level in the presence of cycloheximide. Cell-free translation of hybrid-selected 12S RNA leads to detection of an induced protein of 14 kDa. cDNA cloning reveals that the 12S RNA contains part of an Alu-family sequence in the 5'-untranslated region. The 12S RNA is probably not an RNA polymerase III transcript and codes for a protein of 9 kDa (as monitored by in vitro cell-free translation). This discrepancy in molecular mass can be attributed to a retarded migration of the protein in SDS/PAGE.