The RNA polymerase I transcription factor UBF is the product of a primary response gene

Inhibitor of Growth 4 (ING4) is a positive regulator of rRNA synthesis

Ribosome biogenesis is essential for maintaining basic cellular activities although its mechanism is not fully understood. Inhibitor of growth 4 (ING4) is a member of ING family while its cellular functions remain controversial. Here, we identified several nucleolar proteins as novel ING4 interacting proteins. ING4 localized in the nucleus with strong accumulation in the nucleolus through its plant homeodomain, which is known to interact with histone trimethylated H3K4, commonly present in the promoter of active genes. ING4 deficient cells exhibited slower proliferation and the alteration in nucleolar structure with reduced rRNA transcription, which was rescued by exogenous expression of GFP-ING4 to the similar levels of wild type cells. In the ING4 deficient cells, histone H3K9 acetylation and the key rRNA transcription factor UBF at the promoter of rDNA were reduced, both of which were also recovered by exogenous GFP-ING4 expression. Thus, ING4 could positively regulate rRNA transcription through modulation of histone modifications at the rDNA promoter.

Syncytial knots (Tenney-Parker changes) in the human placenta: evidence of loss of transcriptional activity and oxidative damage

Syncytiotrophoblast is the multinucleated epithelium of the placenta. Although many nuclei are dispersed within the syncytioplasm, others are aggregated into specializations referred to as true and false syncytial knots, and syncytial sprouts. Nuclei within true knots display highly condensed chromatin and are thought to be aged and effete. True knots increase in frequency with gestational age. Excessive formation (Tenney-Parker change) is associated with placental pathology, and a knotting index is used to assess severity. However, this index is potentially confounded by the creation of artifactual appearances (false knots) through tangential sectioning. In addition, knots must be distinguished from syncytial sprouts, which are markers of trophoblast proliferation. Here, we distinguish between sprouts, true knots, and false knots using serial sections and perform IHC for proliferating cell nuclear antigen, upstream binding factor, RNA polymerase II, and 8-oxo-deoxyguanosine as markers of recent incorporation, transcriptional activity, and oxidative damage. Villous explants were exposed to hydrogen peroxide to test the relationship between transcriptional activity and oxidative damage. Sprouts and false knots were found to contain recently incorporated and transcriptionally active nuclei. By contrast, most nuclei within true knots are negative for transcriptional markers but positive for 8-oxo-deoxyguanosine. In vitro, we observed a negative correlation between transcriptional activity and oxidative damage. These findings demonstrate that true knots contain effete damaged nuclei and provide IHC markers for their identification.

A quantitative analysis of transcriptionally active syncytiotrophoblast nuclei across human gestation

The syncytiotrophoblast (STB) epithelial covering of the human placenta is a unique terminally differentiated, multi-nucleated syncytium. No mitotic bodies are observed in the STB, which is sustained by continuous fusion of underlying cytotrophoblast cells (CTB). As a result, STB nuclei are of different ages. Morphologically, they display varying degrees of chromatin compaction, suggesting progressive maturational changes. Until recently, it was thought that STB nuclei were transcriptionally inactive, with all the mRNAs required by the syncytium being incorporated upon fusion of CTB. However, recent research has shown the presence of the active form of RNA polymerase II (RNA Pol II) in some STB nuclei. In this study, we confirm the presence of transcriptional activity in STB nuclei by demonstrating immunoreactivity for a transcription factor and an RNA polymerase I (RNA Pol I) co-factor, phospho-cAMP response element-binding protein and phospho-upstream binding factor, respectively. We also show, through immunoco-localisation studies, that a proportion of STB nuclei are both RNA Pol I and II transcriptionally active. Finally, we quantify the numerical densities of nuclei immunopositive and immunonegative for RNA Pol II in the STB of normal placentas of 11-39 weeks gestational age using an unbiased stereological counting tool, the physical disector. These data were combined with estimates of the volume of trophoblast to calculate total numbers of both types of nuclei at each gestational age. We found no correlation between gestational age and the numerical density of RNA Pol II-positive nuclei in the villous trophoblast (r = 0.39, P > 0.05). As the number of STB nuclei increases exponentially during gestation, we conclude that the number of transcriptionally active nuclei increases in proportion to trophoblast volume. The ratio of active to inactive nuclei remains constant at 3.9:1. These findings confirm that the majority of STB nuclei have intrinsic transcriptional activity, and that the STB is not dependent on CTB fusion for the provision of transcripts.

The balance between rRNA and ribosomal protein synthesis up- and downregulates the tumour suppressor p53 in mammalian cells

Data on the relationship between ribosome biogenesis and p53 function indicate that the tumour suppressor can be activated by either nucleolar disruption or ribosomal protein defects. However, there is increasing evidence that the induction of p53 does not always require these severe cellular changes, and data are still lacking on a possible role of ribosome biogenesis in the downregulation of p53. Here, we studied the effect of the up- and downregulation of the rRNA transcription rate on p53 induction in mammalian cells. We found that a downregulation of rRNA synthesis, induced by silencing the POLR1A gene coding for the RNA polymerase I catalytic subunit, stabilised p53 without altering the nucleolar integrity in human cancer cells. p53 stabilisation was due to the inactivation of the MDM2-mediated p53 degradation by the binding of ribosomal proteins no longer used for ribosome building. p53 stabilisation did not occur when rRNA synthesis downregulation was associated with a contemporary reduction of protein synthesis. Furthermore, we demonstrated that in three different experimental models characterised by an upregulation of rRNA synthesis, cancer cells treated with insulin or exposed to the insulin-like growth factor 1, rat liver stimulated by cortisol and regenerating rat liver after partial hepatectomy, the p53 protein level was reduced due to a lowered ribosomal protein availability for MDM2 binding. It is worth noting that the upregulation of rRNA synthesis was responsible for a decreased p53-mediated response to cytotoxic stresses. These findings demonstrated that the balance between rRNA and ribosomal protein synthesis controls the function of p53 in mammalian cells, that p53 can be induced without the occurrence of severe changes of the cellular components controlling ribosome biogenesis, and that conditions characterised by an upregulated rRNA synthesis are associated with a reduced p53 response.

Case study: Using microbe molecular biology for Gulf oil spill clean up

This case has the student actively investigate the regulation of expression of a novel bacterial gene in the context of attempts to solve a real world problem, clean up of the April 2010 Deep Water Horizon oil spill in the Gulf of Mexico. Although the case is fictitious, it is based on factual gene regulatory characteristics of oil-degrading microbes. The case is written for a sophomore Cell Biology lecture course at Indiana Wesleyan University that is taught to Biology/Pre-Med majors. This study is also appropriate for use in undergraduate microbiology, biochemistry, molecular biology, and molecular genetics courses. The case is intended to enhance coverage of transcription, translation, control of gene expression, and selected molecular biology techniques. Opportunities to practice critical thinking skills and to a lesser extent an introduction to the paradigm of life science research at the industry level are provided.

MAD1 and c-MYC regulate UBF and rDNA transcription during granulocyte differentiation

The regulation of cell mass (cell growth) is often tightly coupled to the cell division cycle (cell proliferation). Ribosome biogenesis and the control of rDNA transcription through RNA polymerase I are known to be critical determinants of cell growth. Here we show that granulocytic cells deficient in the c-MYC antagonist MAD1 display increased cell volume, rDNA transcription and protein synthesis. MAD1 repressed and c-MYC activated rDNA transcription in nuclear run-on assays. Repression of rDNA transcription by MAD1 was associated with its ability to interact directly with the promoter of upstream binding factor (UBF), an rDNA regulatory factor. Conversely, c-MYC activated transcription from the UBF promoter. Using siRNA, UBF was shown to be required for c-MYC-induced rDNA transcription. These data demonstrate that MAD1 and c-MYC reciprocally regulate rDNA transcription, providing a mechanism for coordination of ribosome biogenesis and cell growth under conditions of sustained growth inhibition such as granulocyte differentiation.

mTOR-dependent regulation of ribosomal gene transcription requires S6K1 and is mediated by phosphorylation of the carboxy-terminal activation domain of the nucleolar transcription factor UBF

Mammalian target of rapamycin (mTOR) is a key regulator of cell growth acting via two independent targets, ribosomal protein S6 kinase 1 (S6K1) and 4EBP1. While each is known to regulate translational efficiency, the mechanism by which they control cell growth remains unclear. In addition to increased initiation of translation, the accelerated synthesis and accumulation of ribosomes are fundamental for efficient cell growth and proliferation. Using the mTOR inhibitor rapamycin, we show that mTOR is required for the rapid and sustained serum-induced activation of 45S ribosomal gene transcription (rDNA transcription), a major rate-limiting step in ribosome biogenesis and cellular growth. Expression of a constitutively active, rapamycin-insensitive mutant of S6K1 stimulated rDNA transcription in the absence of serum and rescued rapamycin repression of rDNA transcription. Moreover, overexpression of a dominant-negative S6K1 mutant repressed transcription in exponentially growing NIH 3T3 cells. Rapamycin treatment led to a rapid dephosphorylation of the carboxy-terminal activation domain of the rDNA transcription factor, UBF, which significantly reduced its ability to associate with the basal rDNA transcription factor SL-1. Rapamycin-mediated repression of rDNA transcription was rescued by purified recombinant phosphorylated UBF and endogenous UBF from exponentially growing NIH 3T3 cells but not by hypophosphorylated UBF from cells treated with rapamycin or dephosphorylated recombinant UBF. Thus, mTOR plays a critical role in the regulation of ribosome biogenesis via a mechanism that requires S6K1 activation and phosphorylation of UBF.

ERK-dependent phosphorylation of the transcription initiation factor TIF-IA is required for RNA polymerase I transcription and cell growth

Phosphorylation of transcription factors by mitogen-activated protein kinase (MAPK) cascades links cell signaling with the control of gene expression. Here we show that growth factors induce rRNA synthesis by activating MAPK-dependent signaling cascades that target the RNA polymerase I-specific transcription initiation factor TIF-IA. Activation of TIF-IA and ribosomal gene transcription is sensitive to PD98059, indicating that TIF-IA is targeted by MAPK in vivo. Phosphopeptide mapping and mutational analysis reveals two serine residues (S633 and S649) that are phosphorylated by ERK and RSK kinases. Replacement of S649 by alanine inactivates TIF-IA, inhibits pre-rRNA synthesis, and retards cell growth. The results provide a link between growth factor signaling, ribosome production, and cell growth, and may have a major impact on the mechanism of cell transformation.

Early molecular changes in bladder hypertrophy due to bladder outlet obstruction

OBJECTIVES

To determine the temporal relationship between the increase in bladder mass and the expression of growth-associated gene products during bladder hypertrophy due to partial bladder outlet obstruction.

METHODS

Adult female rats, subjected to partial bladder outlet obstruction, were killed at defined points, and their bladder weight and total protein were determined and compared with sham-operated and nonoperated controls. Hyperplasia was determined by the expression of proliferating cell nuclear antigen, transcription factors, and cyclins in obstructed rat bladders. Bladder protein was fractionated by sodium dodecyl sulfate-polyacrylamide gel electrophoresis, and expression of the indicated proteins was determined by Western analysis and immunohistochemistry.

RESULTS

The mean bladder weight in sham-operated rats remained at 127 +/- 17 mg, and the weight in the obstructed animals increased to 239 +/- 56 mg at 12 hours, increasing to 486 +/- 168 mg by 168 hours. The total bladder protein increased 1.8-fold after 12 hours and continued to increase for the duration of obstruction. The expression of proliferating cell nuclear antigen in the obstructed group did not begin until 24 hours of obstruction. The expression of the transcription factors, upstream binding factor, and c-Jun followed a similar pattern. Cyclin E and C expression increased most significantly after 48 hours.

CONCLUSIONS

Bladder growth after 12 hours of partial outlet obstruction represents cellular hypertrophy based on the increases in bladder weight and total protein accumulation. Cellular hyperplasia occurs after 24 hours of obstruction as represented by increases in transcription factors and cell cycle-specific proteins.

An immediate response of ribosomal transcription to growth factor stimulation in mammals is mediated by ERK phosphorylation of UBF

Ribosomal transcription in mammals is regulated in response to growth, differentiation, disease, and aging, but the mechanisms of this regulation have remained unresolved. We show that epidermal growth factor induces immediate, ERK1/2-dependent activation of endogenous ribosomal transcription, while inactivation of ERK1/2 causes an equally immediate reversion to the basal transcription level. ERK1/2 was found to phosphorylate the architectural transcription factor UBF at amino acids 117 and 201 within HMG boxes 1 and 2, preventing their interaction with DNA. Mutation of these sites inhibited transcription activation and abrogated the transcriptional response to ERK1/2. Thus, growth factor regulation of ribosomal transcription likely acts by a cyclic modulation of DNA architecture. The data suggest a central role for ribosome biogenesis in growth regulation.

The role of acetylation in rDNA transcription

Treatment of NIH 3T3 cells with trichostatin A (TSA), an inhibitor of histone deacetylase (HDAC), resulted in a dose-dependent increase in transcription from a rDNA reporter and from endogenous rRNA genes. Chromatin immunoprecipitation using anti-acetyl-histone H4 antibodies demonstrated a direct effect of TSA on the acetylation state of the ribosomal chromatin. TSA did not reverse inhibition of transcription from the rDNA reporter by retinoblastoma (Rb) protein, suggesting that the main mechanism by which Rb blocks rDNA transcription may not involve recruitment of deacetylases to rDNA chromatin. Overexpression of histone transacetylases p300, CBP and PCAF stimulated transcription in transfected NIH 3T3 cells. Recombinant p300, but not PCAF, stimulated rDNA transcription in vitro in the absence of nucleosomes, suggesting that the stimulation of rDNA transcription by TSA might have a chromatin-independent component. We found that the rDNA transcription factor UBF was acetylated in vivo. Finally, we also demonstrated the nucleolar localization of CBP. Our results suggest that the organization of ribosomal chromatin of higher eukaryotes is not static and that acetylation may be involved in affecting these dynamic changes directly through histone acetylation and/or through acetylation of UBF or one of the other components of rDNA transcription.

Group B Streptococci and inducible nitric oxide synthase: modulation by nuclear factor kappa B and ibuprofen

Group B Streptococci (GBS) neonatal infections cause a complex inflammatory process involving numerous biochemical mediators. Nitric Oxide (NO) is generated by many cell types in response to different inflammatory signals. Nuclear factor kappa B (NFkappaB) plays an important role in the inflammatory process and may induce a number of biochemical mediator genes, including the inducible nitric oxide synthase (iNOS). We tested the hypothesis that GBS induces iNOS gene expression through activation of NFkappaB. We also tested whether ibuprofen (IBU) will suppress iNOS expression by blocking NFkappaB activation. Cerebral microvascular endothelial cells isolated from newborn piglets were harvested for the determination of iNOS gene expression and activation of NFkappaB. GBS significantly induced iNOS mRNA expression (5- to 6-fold, P < .005) and iNOS protein (3- to 4-fold, P < .01) at 24 hours. DNA-NFkappaB binding activity was detected within 15 minutes of GBS treatment and reached a maximal effect at 3 hours. Treatment with IBU significantly suppressed GBS-induced iNOS mRNA expression at 24 hours, and NFkappaB activity at 3 hours, suggesting that suppression of GBS-induced iNOS mRNA expression by IBU occurs by blocking of NFkappaB activation. These data show that NFkappaB activation is an early step in the induction of iNOS gene expression by GBS and that this interaction may play a vital role in the pathogenesis of GBS neonatal infections.

RNA polymerase I transcription in confluent cells: Rb downregulates rDNA transcription during confluence-induced cell cycle arrest

When 3T6 cells are confluent, they withdraw from the cell cycle. Concomitant with cell cycle arrest a significant reduction in RNA polymerase I transcription (80% decrease at 100% confluence) is observed. In the present study, we examined mechanism(s) through which transcription of the ribosomal genes is coupled to cell cycle arrest induced by cell density. Interestingly with an increase in cell density (from 3 - 43% confluence), a significant accumulation in the cellular content of hyperphosphorylated Rb was observed. As cell density increased further, the hypophosphorylated form of Rb became predominant and accumulated in the nucleoli. Co-immunoprecipitation experiments demonstrated there was also a significant rise in the amount of hypophosphorylated Rb associated with the rDNA transcription factor UBF. This increased interaction between Rb and UBF correlated with the reduced rate of rDNA transcription. Furthermore, overexpression of recombinant Rb inhibited UBF-dependent activation of transcription from a cotransfected rDNA reporter in either confluent or exponential cells. The amounts or activities of the rDNA transcription components we examined did not significantly change with cell cycle arrest. Although the content of PAF53, a polymerase associated factor, was altered marginally (decreased 38%), the time course and magnitude of the decrease did not correlate with the reduced rate of rDNA transcription. The results presented support a model wherein regulation of the binding of UBF to Rb and, perhaps the cellular content of PAF53, are components of the mechanism through which cell cycle and rDNA transcription are linked. Oncogene (2000) 19, 3487 - 3497

Nitric oxide, prostaglandins, and impaired cerebral blood flow autoregulation in group B streptococcal neonatal meningitis

Impaired autoregulation of cerebral blood flow (CBF) contributes to CNS damage during neonatal meningitis. We tested (i) the hypothesis that cerebrovascular autoregulation is impaired during early onset group B streptococcal (GBS) meningitis, (ii) whether this impairment is regulated by vasoactive mediators such as prostaglandins and (or) nitric oxide (NO), and (iii) whether this impairment is preventable by specific and (or) nonspecific inhibitors: dexamethasone, ibuprofen, and Nω-nitro-L-arginine, a NO inhibitor. Sterile saline or 109colony-forming units (cfu) of heat-killed GBS was injected into the cerebral ventricle of newborn piglets. CBF autoregulation was determined by altering cerebral perfusion pressure (CPP) with balloon-tipped catheters placed in the aorta. GBS produced a narrow range of CBF autoregulation due to an impairment at the upper limit of CPP. We report that in vivo in the early stages (first 2 h) of induced GBS inflammation (i) GBS impairs the upper limit of cerebrovascular autoregulation; (ii) ibuprofen, dexamethasone, and Nω-nitro-L-arginine not only prevent this GBS-induced autoregulatory impairment but improve the range of cerebrovascular autoregulation; (iii) these autoregulatory changes do not involve circulating cerebral prostanoids; and (iv) the observed changes correlate with the induction of NO synthase gene expression. Thus, acute early onset GBS-induced impairment of the upper limit of CBF autoregulation can be correlated with increases of NO synthase production, suggesting that NO is a vasoactive mediator of CBF.Key words: cerebrovascular autoregulation, group B Streptococcus, neonatal meningitis, anti-inflammatory agents, prostanoids, nitric oxide synthase, gene expression, nitric oxide.

Phosphorylation by G1-specific cdk-cyclin complexes activates the nucleolar transcription factor UBF

Transcription of rRNA genes by RNA polymerase I increases following serum stimulation of quiescent NIH 3T3 fibroblasts. To elucidate the mechanism underlying transcriptional activation during progression through the G1 phase of the cell cycle, we have analyzed the activity and phosphorylation pattern of the nucleolar transcription factor upstream binding factor (UBF). Using a combination of tryptic phosphopeptide mapping and site-directed mutagenesis, we have identified Ser484 as a direct target for cyclin-dependent kinase 4 (cdk4)-cyclin D1- and cdk2-cyclin E-directed phosphorylation. Mutation of Ser484 impairs rDNA transcription in vivo and in vitro. The data demonstrate that UBF is regulated in a cell cycle-dependent manner and suggest a link between G1 cdks-cyclins, UBF phosphorylation and rDNA transcription activation.

A kinase activity associated with simian virus 40 large T antigen phosphorylates upstream binding factor (UBF) and promotes formation of a stable initiation complex between UBF and SL1

Simian virus 40 large T antigen is a multifunctional protein which has been shown to modulate the expression of genes transcribed by RNA polymerase I (Pol I), II, and III. In all three transcription systems, a key step in the activation process is the recruitment of large T antigen to the promoter by direct protein-protein interaction with the TATA binding protein (TBP)-TAF complexes, namely, SL1, TFIID, and TFIIIB. However, our previous studies on large T antigen stimulation of Pol I transcription also revealed that the binding to the TBP-TAFI complex SL1 is not sufficient to activate transcription. To further define the molecular mechanism involved in large T antigen-mediated Pol I activation, we examined whether the high-mobility group box-containing upstream binding factor (UBF) plays any role in this process. Here, using cell labeling experiments, we showed that large T antigen expression induces an increase in UBF phosphorylation. Further biochemical analysis demonstrated that UBF is phosphorylated by a kinase activity that is strongly associated with large T antigen, and that the carboxy-terminal activation domain of UBF is required for the phosphorylation to occur. Using in vitro reconstituted transcription assays, we demonstrated that the inability of alkaline phosphatase treated UBF to efficiently activate transcription can be rescued by large T antigen. Moreover, we showed that large T antigen-induced UBF phosphorylation promotes the formation of a stable UBF-SL1 complex. Together, these results provide strong evidence for an important role for the large T antigen-associated kinase in mediating the stimulation of RNA Pol I transcription.

Regulation of mammalian ribosomal gene transcription by RNA polymerase I

All cells, from prokaryotes to vertebrates, synthesize vast amounts of ribosomal RNA to produce the several million new ribosomes per generation that are required to maintain the protein synthetic capacity of the daughter cells. Ribosomal gene (rDNA) transcription is governed by RNA polymerase I (Pol I) assisted by a dedicated set of transcription factors that mediate the specificity of transcription and are the targets of the pleiotrophic pathways the cell uses to adapt rRNA synthesis to cell growth. In the past few years we have begun to understand the specific functions of individual factors involved in rDNA transcription and to elucidate on a molecular level how transcriptional regulation is achieved. This article reviews our present knowledge of the molecular mechanism of rDNA transcriptional regulation.

Regulation of ribosomal DNA transcription by insulin

The experiments reported here used 3T6-Swiss albino mouse fibroblasts and H4-II-E-C3 rat hepatoma cells as model systems to examine the mechanism(s) through which insulin regulates rDNA transcription. Serum starvation of 3T6 cells for 72 h resulted in a marked reduction in rDNA transcription. Treatment of serum-deprived cells with insulin was sufficient to restore rDNA transcription to control values. In addition, treatment of exponentially growing H4-II-E-C3 with insulin stimulated rDNA transcription. However, for both cell types, the stimulation of rDNA transcription in response to insulin was not associated with a change in the cellular content of RNA polymerase I. Thus we conclude that insulin must cause alterations in formation of the active RNA polymerase I initiation complex and/or the activities of auxiliary rDNA transcription factors. In support of this conclusion, insulin treatment of both cell types was found to increase the nuclear content of upstream binding factor (UBF) and RNA polymerase I-associated factor 53. Both of these factors are thought to be involved in recruitment of RNA polymerase I to the rDNA promoter. Nuclear run-on experiments demonstrated that the increase in cellular content of UBF was due to elevated transcription of the UBF gene. In addition, overexpression of UBF was sufficient to directly stimulate rDNA transcription from a reporter construct. The results demonstrate that insulin is capable of stimulating rDNA transcription in both 3T6 and H4-II-E-C3 cells, at least in part by increasing the cellular content of components required for assembly of RNA polymerase I into an active complex.

Serum- and polypeptide growth factor-inducible gene expression in mouse fibroblasts

Complex cellular processes such as proliferation, differentiation, and apoptosis are regulated in part by extracellular signaling molecules: for example, polypeptide growth factors, cytokines, and peptide hormones. Many polypeptide growth factors exert their mitogenic effects by binding to specific cell surface receptor protein tyrosine kinases. This interaction triggers numerous biochemical responses, including changes in phospholipid metabolism, the activation of a protein phosphorylation cascade, and the enhanced expression of specific immediate-early, delayed-early, or late response genes. In this review, I summarize the major findings obtained from studies investigating the effects of serum or individual polypeptide growth factors on gene expression in murine fibroblasts. Several experimental approaches, including differential hybridization screening of cDNA libraries and differential display, have been employed to identify mRNA species that are expressed at elevated levels in serum- or polypeptide growth factor-stimulated cells. These studies have demonstrated that serum- and growth factor-inducible genes encode a diverse family of proteins, including DNA-binding transcription factors, cytoskeletal and extracellular matrix proteins, metabolic enzymes, secreted chemokines, and serine-threonine kinases. Some of these gene products act as effectors of specific cell cycle functions (e.g., enzymes involved in nucleotide and DNA synthesis), others are required to successfully convert a metabolically inactive cell to a metabolically active cell that will eventually increase in size and then divide (e.g., glucose-metabolizing enzymes), and some actually function as positive or negative regulators of cell cycle progression. In conclusion, research conducted during the past 15 years on serum- and growth factor-regulated gene expression in murine fibroblasts has provided significant insight into mitogenic signal transduction and cell growth control.

Involvement of in situ conformation of ribosomal genes and selective distribution of upstream binding factor in rRNA transcription

The distribution of the ribosomal genes (rDNA) and the upstream binding factor (UBF), correlatively with their RNA transcripts, was investigated in G1, S-phase, and G2. rDNA was distributed in nucleoli, with alternate sites of clustered and dispersed genes. UBF was found associated with some but not all clustered genes and proportionally more with dispersed genes. It was distributed in several foci that were more numerous and heterogeneous in size during G2 than G1. We suggest that UBF associated with rDNA during S-phase because its nucleolar amount increased during that time and remained stable in G2. 5,6-Dichloro-1-beta-D-ribofuranosylbenzimidazole treatment indicated a similar amount of UBF per transcription unit, and consequently heterogeneous size of the UBF foci can represent a variable number of transcription units per foci. Direct visualization of the transcripts demonstrated that only part of UBF is associated with active transcription and that rDNA distribution varied with transcription. We propose that in the same rDNA locus three types of configuration coexist that are correlated with gene activity: 1) clustered genes without UBF; 2) clustered genes with UBF, of which some are associated with transcription; and 3) dispersed genes with UBF and transcription. These results support the hypothesis that rDNA transcription involved several steps of regulation acting successively and locally in the same locus to promote the repressed clustered genes to become actively transcribed dispersed genes.

Androgen regulation of ribosomal RNA synthesis in LNCaP cells and rat prostate

Androgen-dependent growth of prostate tissue has been well documented. An additional prerequisite for cellular growth is the accumulation of ribosomes. It is thus reasonable to hypothesize that ribosomal DNA (rDNA) transcription in prostate tissue must be stimulated by androgen either directly or indirectly. This hypothesis was tested using both LNCaP cells, an androgen-dependent tissue culture line and in a rat animal model. Nuclear run-on assays confirmed that the administration of DHT to LNCaP cells resulted in a two- to three-fold increase in the rate of rRNA synthesis when compared to cells maintained in the absence of androgen. Enzymatic analysis and Western blots were carried out to measure the amount (activity and mass) of RNA polymerase I in DHT treated LNCaP cells. These assays demonstrated that neither the catalytic activity of RNA polymerase I nor the amount of the enzyme varied in response to DHT. However, Western blots revealed that the amount of the auxiliary RNA polymerase I transcription factor UBF, was significantly increased (two- to three-fold) in cells grown in the presence of DHT. Similar experiments were carried out with prostatic tissue obtained from orchiectomized rats maintained on either placebo or testosterone pellets. In this model, both the catalytic activity as well as the amount of RNA polymerase I protein decreased. However, in agreement with the tissue culture model, UBF protein decreased in prostates from orchiectomized rats and was maintained in animals supplemented with testosterone. These lines of evidence are consistent with the hypothesis that androgens stimulate rRNA synthesis by increasing the quantities of the components of the rDNA transcription system.

Structure of recombinant rat UBF by electron image analysis and homology modelling

We have studied the structure of recombinant rat UBF (rrUBF), an RNA polymerase I transcription factor, by electron microscopy and image analysis of single particles contrasted with methylamine tungstate. Recombinant rat UBF appeared to be a flat, U-shaped protein with a central region of low density. In the dominant projections, 2-fold mirror symmetry was seen, consistent with the dimerization properties of this molecule, and of dimensions in agreement with the length of DNA that rat UBF protects in footprinting studies. Electron microscopy of various rrUBF-DNA complexes confirmed that our recombinant protein was fully able to bind the 45S rDNA promoter, and that it caused substantial bends in the DNA. Upon extended incubation in a droplet covered by a lipid monolayer at the liquid-air interface, rrUBF formed long filamentous arrays with a railway track appearance. This structure was interpreted to consist of overlapping rrUBF dimers 3.5 nm apart, which value would represent the thickness of the protein. Our results show rrUBF to interact with and bend the promoter DNA into a roughly 10 nm diameter superhelix. Based on all these electron microscopical results, an atomic structure was predicted by homology modelling of the HMG fingers, and connected by energy minimized intervening segments.

Regulation of rDNA transcription during endothelin-1-induced hypertrophy of neonatal cardiomyocytes. Hyperphosphorylation of upstream binding factor, an rDNA transcription factor

Treatment of cultured neonatal cardiomyocytes with endothelin-1 and phorbol 12-myristate 13-acetate (PMA) results in cardiomyocyte hypertrophy. However, the signal transduction pathways involved in this process are poorly understood. Because increased ribosome biogenesis is a requisite for hypertrophy, we sought to (1) confirm the hypothesis that these two hypertrophic agents did indeed induce rRNA synthesis and (2) examine the mechanism through which this induction was accomplished. In this study, hypertrophy of contraction-arrested neonatal cardiomyocytes induced by treatment with either endothelin-1 or PMA was associated with increased rDNA transcription. Western blots demonstrated that the enhanced rates of rDNA transcription were not mediated by increased amounts of either RNA polymerase I or upstream binding factor (UBF), an rDNA transcription factor. However, immunoprecipitation of [32P] orthophosphate-labeled UBF from hypertrophying neonatal cardiomyocytes suggested that the increased rate of rDNA transcription may be due to the hyperphosphorylation of UBF, which would increase the activity of UBF. The increase in UBF phosphorylation occurred within 3 to 6 hours after exposure to either agent, was maximal at 12 hours, and was sustained for at least the first 24 hours of exposure. Phosphoamino acid analysis of UBF immunoprecipitated from control and treated cardiomyocytes demonstrated that UBF was phosphorylated exclusively on serine residues. Our previous studies have shown that the cellular UBF content increased in adrenergic- and contraction-induced models of cardiac hypertrophy. This study with endothelin-1 and PMA demonstrates that the modulation of UBF phosphorylation is an additional pathway by which ribosome biogenesis may be regulated in neonatal cardiomyocytes. These results support the hypothesis that UBF is an important regulatory factor during the initiation and maintenance of the accelerated rate of rDNA transcription observed during neonatal cardiomyocyte hypertrophy mediated by both phorbol esters and endothelin-1.

Regulation of ribosomal DNA transcription during contraction-induced hypertrophy of neonatal cardiomyocytes

Cardiac hypertrophy requires protein accumulation. This results largely from an increased capacity for protein synthesis, which in turn is the result of an elevated rate of ribosome biogenesis. The process of ribosome formation is regulated at the level of transcription of the ribosomal RNA genes. In this study, we examined the amounts and activities of various components of the ribosomal DNA transcription apparatus in contraction-arrested neonatal cardiomyocytes and in spontaneously contracting cardiomyocytes that hypertrophy. Nuclear run-on assays demonstrated that spontaneously contracting cardiomyocytes supported a 2-fold increased rate of ribosomal DNA transcription. However, enzymatic assay of total solubilized RNA polymerase I and Western blots demonstrated that contraction-induced increases in ribosomal RNA synthesis were not accompanied by increased activity or amounts of RNA polymerase I. In contrast, accelerated ribosome biogenesis was accompanied by an increased amount of the ribosomal DNA transcription factor, UBF. Immunoprecipitation of [32P]orthophosphate-labeled UBF from hypertrophying, neonatal cardiomyocytes indicated that the accumulated UBF protein was phosphorylated and, thus, in the active form. UBF mRNA levels began to increase within 3-6 h of the initiation of contraction and preceded the elevation in rDNA transcription. Nuclear run-on assays demonstrated increased rates of transcription of the UBF gene. Transfection of chimeric reporter constructs containing deletions of the 5'-flanking region of the UBF gene revealed the presence of contraction response elements between -1189 and -665 relative to the putative start of transcription. These results are consistent with the hypothesis that UBF is an important factor in the regulation of rDNA transcription during contraction-mediated neonatal cardiomyocyte hypertrophy.