The c-myc gene encodes superimposed RNA polymerase II and III promoters

NRF2 Is an Upstream Regulator of MYC-Mediated Osteoclastogenesis and Pathological Bone Erosion

Osteoclasts are the sole bone-resorbing cells that play an essential role in homeostatic bone remodeling and pathogenic bone destruction such as inflammatory arthritis. Pharmacologically targeting osteoclasts has been a promising approach to alleviating bone disease, but there remains room for improvement in mitigating drug side effects and enhancing cell specificity. Recently, we demonstrated the crucial role of MYC and its downstream effectors in driving osteoclast differentiation. Despite these advances, upstream regulators of MYC have not been well defined. In this study, we identify nuclear factor erythroid 2-related factor 2 (NRF2), a transcription factor known to regulate the expression of phase II antioxidant enzymes, as a novel upstream regulator of MYC. NRF2 negatively regulates receptor activator of nuclear factor-κB ligand (RANKL)-induced osteoclastogenesis through the ERK and p38 signaling-mediated suppression of MYC transcription. Furthermore, the ablation of MYC in osteoclasts reverses the enhanced osteoclast differentiation and activity in NRF2 deficiency in vivo and in vitro in addition to protecting NRF2-deficient mice from pathological bone loss in a murine model of inflammatory arthritis. Our findings indicate that this novel NRF2-MYC axis could be instrumental for the fine-tuning of osteoclast formation and provides additional ways in which osteoclasts could be therapeutically targeted to prevent pathological bone erosion.

Principles of miRNA-target regulation in metazoan models

MicroRNAs (miRs) are key post-transcriptional regulators that silence gene expression by direct base pairing to target sites of RNAs. They have a wide variety of tissue expression patterns and are differentially expressed during development and disease. Their activity and abundance is subject to various levels of control ranging from transcription and biogenesis to miR response elements on RNAs, target cellular levels and miR turnover. This review summarizes and discusses current knowledge on the regulation of miR activity and concludes with novel non-canonical functions that have recently emerged.

Chromatin structure analyses identify miRNA promoters

Although microRNAs (miRNAs) are key regulators of gene expression in normal human physiology and disease, transcriptional regulation of miRNAs is poorly understood, because most miRNA promoters have not yet been characterized. We identified the proximal promoters of 175 human miRNAs by combining nucleosome mapping with chromatin signatures for promoters. We observe that one-third of intronic miRNAs have transcription initiation regions independent from their host promoters and present a list of RNA polymerase II- and III-occupied miRNAs. Nucleosome mapping and linker sequence analyses in miRNA promoters permitted accurate prediction of transcription factors regulating miRNA expression, thus identifying nine miRNAs regulated by the MITF transcription factor/oncoprotein in melanoma cells. Furthermore, DNA sequences encoding mature miRNAs were found to be preferentially occupied by positioned-nucleosomes, and the 3' end sites of known genes exhibited nucleosome depletion. The high-throughput identification of miRNA promoter and enhancer regulatory elements sheds light on evolution of miRNA transcription and permits rapid identification of transcriptional networks of miRNAs.

Defective RNA-mediated c-myc gene silencing pathway in Burkitt's lymphoma

Keeping in view the fact that molecular basis of Burkitt's lymphoma (BL) is poorly understood, we attempted to explore the small interfering RNA (siRNA) mediated c-myc gene regulation using BL-derived EB-3 cell line as archetype cellular model. Such a study revealed that EB-3 cells possess 4-fold higher expression of Dicer gene coupled with 2-fold higher activity of RNA polymerase III than that observed in normal human lymphocytes. siRNAs derived from EB-3 cells had the inherent capacity to suppress c-myc gene expression in normal cells but not in native cells. Based on these findings we have proposed a novel RNA-mediated c-myc gene regulation pathway that may be responsible for BL.

Unusual properties of adenovirus E2E transcription by RNA polymerase III

In adenovirus type 5-infected cells, RNA polymerase III transcription of a gene superimposed on the 5' end of the E2E RNA polymerase II transcription unit produces two small (<100-nucleotide) RNAs that accumulate to low steady-state concentrations (W. Huang, R. Pruzan, and S. J. Flint, Proc. Natl. Acad. Sci. USA 91:1265-1269, 1984). To gain a better understanding of the function of this RNA polymerase III transcription, we have examined the properties of the small E2E RNAs and E2E RNA polymerase III transcription in more detail. The accumulation of cytoplasmic E2E RNAs and the rates of E2E transcription by the two RNA polymerases during the infectious cycle were analyzed by using RNase T(1) protection and run-on transcription assays, respectively. Although the RNA polymerase III transcripts were present at significantly lower concentrations than E2E mRNA throughout the period examined, E2E transcription by RNA polymerase III was found to be at least as efficient as that by RNA polymerase II. The short half-lifes of the small E2E RNAs estimated by using the actinomycin D chase method appear to account for their limited accumulation. The transcription of E2E sequences by RNA polymerase II and III in cells infected by recombinant adenoviruses carrying ectopic E2E-CAT (chloramphenicol transferase) reporter genes with mutations in E2E promoter sequences was also examined. The results of these experiments indicate that recognition of the E2E promoter by the RNA polymerase II transcriptional machinery in infected cells limits transcription by RNA polymerase III, and vice versa. Such transcriptional competition and the properties of E2E RNAs made by RNA polymerase III suggest that the function of this viral RNA polymerase III transcription unit is unusual.

Regulation of caveolin-1 expression and secretion by a protein kinase cepsilon signaling pathway in human prostate cancer cells

Caveolin-1, androgen receptor, c-Myc, and protein kinase Cepsilon (PKCepsilon) proteins are overrepresented in most advanced prostate cancer tumors. Previously, we demonstrated that PKCepsilon has the capacity to enhance the expression of both caveolin-1 and c-Myc in cultured prostate cancer cells and is sufficient to induce the growth of androgen-independent tumors. In this study, we have uncovered further evidence of a functional interplay among these proteins in the CWR22 model of human prostate cancer. The results demonstrated that PKCepsilon expression was naturally up-regulated in recurrent CWR22 tumors and that this oncoprotein was required to sustain the androgen-independent proliferation of CWR-R1 cells in culture. Gene transfer experiments demonstrated that PKCepsilon had the potential to augment the expression and secretion of a biologically active caveolin-1 protein that supports the growth of the CWR-R1 cell line. Antisense and pharmacological experiments provided additional evidence that the sequential activation of PKCepsilon, mitogen-activated protein kinases, c-Myc, and androgen receptor signaling drove the downstream expression of caveolin-1 in CWR-R1 cells. Finally, we demonstrate that mitogen-activated protein kinases were required downstream of PKCepsilon to derepress the transcriptional elongation of the c-myc gene. Our findings support the hypothesis that PKCepsilon may advance the recurrence of human prostate cancer by promoting the expression of several important downstream effectors of disease progression.

In vivo and in vitro studies of immunoglobulin gene somatic hypermutation

Following antigen encounter, two distinct processes modify immunoglobulin genes. The variable region is diversified by somatic hypermutation while the constant region may be changed by class-switch recombination. Although both genetic events can occur concurrently within germinal centre B cells, there are examples of each occurring independently of the other. Here we compare the contributions of class-switch recombination and somatic hypermutation to the diversification of the serum immunoglobulin repertoire and review evidence that suggests that, despite clear differences, the two processes may share some aspects of their mechanism in common.

Superimposed promoter sequences of the adenoviral E2 early RNA polymerase III and RNA polymerase II transcription units

The human adenovirus type 2 E2 early (E2E) transcriptional control region contains an efficient RNA polymerase III promoter, in addition to the well characterized promoter for RNA polymerase II. To determine whether this promoter includes intragenic sequences, we examined the effects of precise substitutions introduced between positions +2 and +62 on E2E transcription in an RNA polymerase III-specific, in vitro system. Two noncontiguous sequences within this region were necessary for efficient or accurate transcription by this enzyme. The sequence and properties of the functional element proximal to the sites of initiation identified it as an A box. Although a B box sequence could not be unambiguously located, substitutions between positions +42 and +62 that severely impaired transcription also inhibited binding of the human general initiation protein TFIIIC. Thus, this region of the RNA polymerase III E2E promoter contains a B box sequence. We also identified previously unrecognized intragenic sequences of the E2E RNA polymerase II promoter. In conjunction with our previous observations, these data establish that RNA polymerase II and RNA polymerase III promoter sequences are superimposed from approximately positions -30 to +20 of the complex E2E transcriptional control region. The alterations in transcription induced by certain mutations suggest that components of the RNA polymerase II and RNA polymerase III transcriptional machines compete for access to overlapping binding sites in the E2E template.

A CBF5 mutation that disrupts nucleolar localization of early tRNA biosynthesis in yeast also suppresses tRNA gene-mediated transcriptional silencing

In the budding yeast, Saccharomyces cerevisiae, actively transcribed tRNA genes can negatively regulate adjacent RNA polymerase II (pol II)-transcribed promoters. This tRNA gene-mediated silencing is independent of the orientation of the tRNA gene and does not require direct, steric interference with the binding of either upstream pol II factors or the pol II holoenzyme. A mutant was isolated in which this form of silencing is suppressed. The responsible point mutation affects expression of the Cbf5 protein, a small nucleolar ribonucleoprotein protein required for correct processing of rRNA. Because some early steps in the S. cerevisiae pre-tRNA biosynthetic pathway are nucleolar, we examined whether the CBF5 mutation might affect this localization. Nucleoli were slightly fragmented, and the pre-tRNAs went from their normal, mostly nucleolar location to being dispersed in the nucleoplasm. A possible mechanism for tRNA gene-mediated silencing is suggested in which subnuclear localization of tRNA genes antagonizes transcription of nearby genes by pol II.

The c-MYC allele that is translocated into the IgH locus undergoes constitutive hypermutation in a Burkitt's lymphoma line

Burkitt's lymphomas harbour chromosomal translocations bringing c-MYC into the vicinity of one of the immunoglobulin gene loci. Point mutations have been described within c-MYC in several Burkitt's lymphomas and it has been proposed that translocation into the Ig loci might have transformed c-MYC into a substrate for the antibody hypermutation mechanism. Here we test this hypothesis by exploiting a Burkitt's lymphoma line (Ramos) that we have previously shown to hypermutate its immunoglobulin genes constitutively. We find that, during in vitro culture, Ramos mutates the c-MYC allele that is translocated into the IgH locus whilst leaving the untranslocated c-MYC and other control genes essentially unaffected. The mutations are introduced downstream of the c-MYC transcription start with the pattern of substitutions being characteristic of the antibody hypermutation mechanism; the mutation frequency is 2-3-fold lower than for the endogenous functional IgH allele. Thus chromosomal translocations involving the Ig loci may not only contribute to transformation by deregulating oncogene expression but could also act by potentiating subsequent oncogene hypermutation.

hTFIIIB-beta stably binds to pol II promoters and recruits RNA polymerase III in a hTFIIIC1 dependent way

It has been shown that under specific conditions, transcription of protein coding genes can be efficiently initiated by RNA polymerase (pol) III in vitro. We examined the formation and composition of such pol III transcription complexes on the duck histone H5 and alphaA-globin promoters and found that the essential step for the formation of pol III transcription complexes on these pol II promoters was the stable binding of transcription factor (TF) IIIB-beta. For this process, the intact TFIIIB-beta complex, consisting of TBP and associated factors (TAFs) was needed and the prior association of pol III assembly factors was not necessary. We demonstrate for the first time that hTFIIIB-beta alone is able to bind to pol II promoter DNA. This resulted in a very stable complex which was resistant to high concentrations of heparin. Although immunodepletion revealed that TBP is essentially required for complex formation, other components of hTFIIIB-beta must also be involved, since TBP itself is unable to form heparin-resistant complexes and does not mediate pol III commitment per se. pol III is recruited to these pol II promoters in a strictly TFIIIC1 dependent way. After binding of TFIIIB-beta, the addition of TFIIIC1 and pol III were sufficient to yield productive pol III transcription complexes, which utilized the correct pol II initiation site. From these findings, we postulate that TFIIIC1 is involved in the recruitment of pol III and may thus form a bridge between TFIIIB-beta and the enzyme. This finding provides the first evidence for functional contacts between TFIIIC1 and pol III, which could be of general importance for the assembly of pol III transcription complexes.

The HIV-1 inducer of short transcripts activates the synthesis of 5,6-dichloro-1-beta-D-benzimidazole-resistant short transcripts in vitro

The HIV-1 inducer of short transcripts (IST) is an unusual promoter element that activates the synthesis of short transcripts from the HIV-1 promoter as well as from heterologous promoters. While the DNA sequences constituting IST have been characterized in some detail, little is known about the biochemical mechanisms underlying IST activity. Here, we describe a cell-free transcription assay that faithfully reproduces the synthesis of IST-dependent HIV-1 short transcripts. As in vivo, formation of these short transcripts requires a functional IST element and is repressed in the presence of the viral trans-activator Tat. Short transcript and full-length transcript synthesis respond differently to variations in several reaction parameters, suggesting that the short and full-length transcripts are synthesized by transcription complexes with distinct biochemical properties. In particular, short transcript synthesis is resistant to the action of 5,6-dichloro-1-beta-D-benzimidazole, an inhibitor of transcript elongation. Formation of transcription complexes directed by the IST element may, therefore, not require the activity of a factor inhibited by 5, 6-dichloro-1-beta-D-benzimidazole, such as the TFIIH-associated or pTEFb kinases.

Protein kinase C inhibits transcription from the RNA polymerase III promoter of the human c-myc gene

The c-myc promoter has a unique characteristic showing both RNA polymerase II (pol II) and RNA polymerase III (pol III) activities. Previous studies demonstrated that activating PKC results in upregulation of c-myc expression from its pol II promoter. However, how PKC activation affects expression from the pol III promoter of the c-myc gene is not well understood. This study examines the effect of PKC on the pol III transcription from the c-myc gene by using an in vitro system. We report the inhibition of the c-myc pol III transcript by activating PKC. Further, either a phosphocellulose fraction of HeLa whole cell extract (WCE) enriched for transcription factor TF IIIB, or recombinant TATA-box binding protein could restore the inhibited c-myc pol III transcription under conditions that activate PKC. A role has been proposed for the c-myc pol III transcript in the regulation of c-myc gene expression. Therefore, this report discusses the significance of the downregulation of c-myc expression from its pol III promoter and the possible interplay between the pol II and pol III promoters of this gene.

Repression of host RNA polymerase II transcription by herpes simplex virus type 1

Lytic infection of mammalian cells with herpes simplex virus type 1 (HSV-1) results in rapid repression of host gene expression and selective activation of the viral genome. This transformation in gene expression is thought to involve repression of host transcription and diversion of the host RNA polymerase (RNAP II) transcription machinery to the viral genome. However, the extent of virus-induced host transcription repression and the mechanisms responsible for these major shifts in transcription specificities have not been examined. To determine how HSV-1 accomplishes repression of host RNAP II transcription, we assayed transcription patterns on several cellular genes in cells infected with mutant and wild-type HSV-1. Our results suggest that HSV-1 represses RNAP II transcription on most cellular genes. However, each cellular gene we examined responds differently to the transcription repressive effects of virus infection, both quantitatively and with respect to the involvement of viral gene products. Virus-induced shutoff of host RNAP II transcription requires expression of multiple immediate-early genes. In contrast, expression of delayed-early and late genes and viral DNA replication appear to contribute little to repression of host cell RNAP II transcription. Modification of RNAP II to the intermediately phosphorylated (II(I)) form appears unlinked to virus-induced repression of host cell transcription. However, full repression of host transcription is correlated with depletion of the hyperphosphorylated (IIO) form of RNAP II.

Role of TATA box sequence and orientation in determining RNA polymerase II/III transcription specificity

Work from a number of laboratories has indicated that the TATA box sequence can act as a basal promoter element not only for RNA polymerase II (RNAP II) transcription, but also for transcription by RNA polymerase III (RNAP III). We previously reported that, in the absence of other cis-acting elements, the canonical TATA sequence TATAAAAA specifically supported transcription by RNAP II in an unfractionated Drosophila nuclear extract, whereas the sequence TTTTTATA (the same sequence in reverse orientation) directed RNAP III transcription. We have now examined a variety of other TATA box sequences with regard to RNA polymerase selectivity and their ability to support RNAP III transcription. The results have allowed us to rank these TATA box sequences with respect to their relative strengths as RNAP III promoter elements in unfractionated Drosophila extracts. Further, the data indicate that T residues at positions 2 and 4 of the TATA box appear to be important determinants of RNAP III selectivity in this system, whereas A residues at these positions favor RNAP II transcription. Finally, the data suggest that transcription factors TFIID and TFIIIB, although both capable of binding a variety of TATA elements, have distinct sequence preferences for recognizing the TATA box and possibly the surrounding DNA.

Complex patterns of transcription of a Drosophila retrotransposon in vivo and in vitro by RNA polymerases II and III

The mdg1 retrovirus-like retrotransposon of Drosophila melanogaster was found to possess a complex promoter which can be transcribed by both RNA polymerases II and III (pol II and pol III). Pol III transcription, which is not typical of protein-coding genes, is driven by the sequences located in the long terminal repeat (LTR) of mdg1, predominantly within the transcribed region and is initiated 10 bp upstream from the regular pol II RNA start site. The pol III RNA start site is observed not only in in vitro transcription reactions, but also in total RNA isolated from tissue culture cells, larvae, pupae and adult flies. A possible role of pol III transcription in mechanisms controlling the expression of full-length mdg1-encoded transcripts in the developing fly, which are apparently relaxed in cell culture, is discussed.

RNA polymerase II/III transcription specificity determined by TATA box orientation

The TATA box sequence in eukaryotes is located about 25 bp upstream of many genes transcribed by RNA polymerase II (Pol II) and some genes transcribed by RNA polymerase III (Pol III). The TATA box is recognized in a sequence-specific manner by the TATA box-binding protein (TBP), an essential factor involved in the initiation of transcription by all three eukaryotic RNA polymerases. We have investigated the recognition of the TATA box by the Pol II and Pol III basal transcription machinery and its role in establishing the RNA polymerase specificity of the promoter. Artificial templates were constructed that contained a canonical TATA box as the sole promoter element but differed in the orientation of the 8-bp TATA box sequence. As expected, Pol II initiated transcription in unfractionated nuclear extracts downstream of the "forward" TATA box. In distinct contrast, transcription that initiated downstream of the "reverse" TATA box was carried out specifically by Pol III. Importantly, this effect was observed regardless of the source of the DNA either upstream or downstream of the TATA sequence. These findings suggest that TBP may bind in opposite orientations on Pol II and Pol III promoters and that opposite, yet homologous, surfaces of TBP may be utilized by the Pol II and Pol III basal machinery for the initiation of transcription.

Functional mRNA can be generated by RNA polymerase III

Eukaryotic cellular mRNA is believed to be synthesized exclusively by RNA polymerase II (pol II), whereas pol I produces long rRNAs and pol III produces 5S rRNA, tRNA, and other small RNAs. To determine whether this functional differentiation is obligatory, we examined the translational potential of an artificial pol III transcript. The coding region of the human immunodeficiency virus type 1 tat gene was placed under the control of a strong pol III promoter from the adenovirus type 2 VA RNAI gene. The resultant chimera, pVA-Tat, was transcribed accurately in vivo and in vitro and gave rise to Tat protein, which transactivated a human immunodeficiency virus-driven chloramphenicol acetyltransferase reporter construct in transfected HeLa cells. pol III-specific mutations down-regulated VA-Tat RNA production in vivo and in vitro and dramatically reduced chloramphenicol acetyltransferase transactivation. As expected for a pol III transcript, VA-Tat RNA was not detectably capped at its 5' end or polyadenylated at its 3' end, but, like mRNA, it was associated with polysomes in a salt-stable manner. Mutational analysis of a short open reading frame upstream of the Tat-coding sequence implicates scanning in the initiation of VA-Tat RNA translation despite the absence of a cap. In comparison with tat mRNA generated by pol II, VA-Tat RNA was present on smaller polysomes and was apparently translated less efficiently, which is consistent with a relatively low initiation rate. Evidently, human cells are capable of utilizing pol III transcripts as functional mRNAs, and neither a cap nor a poly(A) tail is essential for translation, although they may be stimulatory. These findings raise the possibility that some cellular mRNAs are made by pol I or pol III.

Transcription of the human T-cell lymphotropic virus type I promoter by an alpha-amanitin-resistant polymerase

The human T-lymphotropic virus type I (HTLV-I) promoter contains the structural features of a typical RNA polymerase II (pol II) template. The promoter contains a TATA box 30 bp upstream of the transcription initiation site and binding sites for several pol II transcription factors, and long poly(A)+ RNA is synthesized from the integrated HTLV-I proviral DNA in vivo. Consistent with these characteristics, HTLV-I transcription activity was reconstituted in vitro by using TATA-binding protein, TFIIA, recombinant TFIIB, TFIIE, and TFIIF, TFIIH, and pol II. Transcription of the HTLV-I promoter in the reconstituted system requires RNA pol II. In HeLa whole cell extracts, however, the HTLV-I long terminal repeat also contains an overlapping transcription unit (OTU). HTLV-I OTU transcription is initiated at the same nucleotide site as the RNA isolated from the HTLV-I-infected cell line MT-2 but was not inhibited by the presence of alpha-amanitin at concentrations which inhibited the adenovirus major late pol II promoter (6 micrograms/ml). HTLV-I transcription was inhibited when higher concentrations of alpha-amanitin (60 micrograms/ml) were used, in the range of a typical pol III promoter (VA-I). Neutralization and depletion experiments with three distinct pol II antibodies demonstrate that RNA pol II is not required for HTLV-I OTU transcription. Antibodies to basal transcription factors TATA-binding protein and TFIIB, but not TFIIIC, inhibited HTLV-I OTU transcription. These observations suggest that the HTLV-I long terminal repeat contains overlapping promoters, a typical pol II promoter and a unique pol III promoter which requires a distinct set of transcription factors.

Evolutionary selection against change in many Alu repeat sequences interspersed through primate genomes

Mutations have been examined in the 1500 interspersed Alu repeats of human DNA that have been sequenced and are nearly full length. There is a set of particular changes at certain positions that rarely occur (termed suppressed changes) compared to the average of identical changes of identical nucleotides in the rest of the sequence. The suppressed changes occur in positions that are clustered together in what appear to be sites for protein binding. There is a good correlation of the suppression in different positions, and therefore the joint probability of absence of mutation at many pairs of such positions is significantly higher than that expected at random. The suppression of mutation appears to result from selection that is not due to requirements for Alu sequence replication. The implication is that hundreds of thousands of Alu sequences have sequence-dependent functions in the genome that are selectively important for primates. In a few known cases Alu inserts have been adapted to function in the regulation of gene transcription.

tRNA genes as transcriptional repressor elements

Eukaryotic genomes frequently contain large numbers of repetitive RNA polymerase III (pol III) promoter elements interspersed between and within RNA pol II transcription units, and in several instances a regulatory relationship between the two types of promoter has been postulated. In the budding yeast Saccharomyces cerevisiae, tRNA genes are the only known interspersed pol III promoter-containing repetitive elements, and we find that they strongly inhibit transcription from adjacent pol II promoters in vivo. This inhibition requires active transcription of the upstream tRNA gene but is independent of its orientation and appears not to involve simple steric blockage of the pol II upstream activator sites. Evidence is presented that different pol II promoters can be repressed by different tRNA genes placed upstream at varied distances in both orientations. To test whether this phenomenon functions in naturally occurring instances in which tRNA genes and pol II promoters are juxtaposed, we examined the sigma and Ty3 elements. This class of retrotransposons is always found integrated immediately upstream of different tRNA genes. Weakening tRNA gene transcription by means of a temperature-sensitive mutation in RNA pol III increases the pheromone-inducible expression of sigma and Ty3 elements up to 60-fold.

In vivo transcription from the adenovirus E2 early promoter by RNA polymerase III

We have previously reported that the subgroup C adenovirus E2 early (E2E) RNA polymerase II promoter can specify efficient in vitro transcription by RNA polymerase III. We now show that promoter proximal sequences of the E2E transcription unit are also transcribed by RNA polymerase III in nuclei isolated from adenovirus-infected cells. Small E2E RNA species that possessed the same properties as in vitro synthesized RNA polymerase III E2E transcripts were detected in cytoplasmic RNA populations from infected cells by using blotting, primer extension, and RNase protection assays. The 3' termini of these RNAs were mapped to thymidine-rich sequences typical of RNA polymerase III termination sites. These results demonstrate that a single gene can be transcribed by both RNA polymerase II and RNA polymerase III in vivo.

tRNA genes as transcriptional repressor elements

Eukaryotic genomes frequently contain large numbers of repetitive RNA polymerase III (pol III) promoter elements interspersed between and within RNA pol II transcription units, and in several instances a regulatory relationship between the two types of promoter has been postulated. In the budding yeast Saccharomyces cerevisiae, tRNA genes are the only known interspersed pol III promoter-containing repetitive elements, and we find that they strongly inhibit transcription from adjacent pol II promoters in vivo. This inhibition requires active transcription of the upstream tRNA gene but is independent of its orientation and appears not to involve simple steric blockage of the pol II upstream activator sites. Evidence is presented that different pol II promoters can be repressed by different tRNA genes placed upstream at varied distances in both orientations. To test whether this phenomenon functions in naturally occurring instances in which tRNA genes and pol II promoters are juxtaposed, we examined the sigma and Ty3 elements. This class of retrotransposons is always found integrated immediately upstream of different tRNA genes. Weakening tRNA gene transcription by means of a temperature-sensitive mutation in RNA pol III increases the pheromone-inducible expression of sigma and Ty3 elements up to 60-fold.

Cyclic AMP downregulates c-myc expression by inhibition of transcript initiation in human B-precursor Reh cells

In the human pre-B cell line Reh, activation of the cyclic AMP signal transduction pathway induces a rapid, transient 10-fold down-regulation of steady-state c-myc mRNA. We have investigated the mechanisms involved in this cAMP-mediated regulation of c-myc expression. Forskolin did not alter c-myc mRNA stability. Initiation of c-myc transcripts was strongly inhibited after 1 h of forskolin treatment, as measured by nuclear run-on assays. Reinitiation of c-myc transcription was apparent after 3-4 h, and full transcriptional elongation was detected after 8 h of forskolin treatment. These data suggest that cyclic AMP downregulates c-myc expression by inhibition of transcriptional initiation.

Distinct properties of c-myc transcriptional elongation are revealed in Xenopus oocytes and mammalian cells and by template titration, 5,6-dichloro-1-beta-D-ribofuranosylbenzimidazole (DRB), and promoter mutagenesis

A block to c-myc transcription elongation has been observed in Xenopus oocytes and mammalian cells. Here, we show that the distribution of RNA polymerase II transcription complexes in the c-myc promoter proximal region in Xenopus oocytes is different from that observed previously in mammalian cells. Thus, there are major differences in the c-myc elongation block observed in the two systems. In addition, as first reported for a Xenopus tubulin gene (K. M. Middleton and G. T. Morgan, Mol. Cell. Biol. 10:727-735, 1990). c-myc template titration experiments reveal the existence of two classes of RNA polymerase II transcription complexes in oocytes: one (at low template concentration) that is capable of reading through downstream sites of premature termination, and another (high template concentration) that does not. We show that these classes of polymerases are distinct from those previously identified by 5,6-dichloro-1-beta-D-ribofuranosylbenzimidazole (DRB), which distinguishes transcription complexes on the basis of transcribed distance, rather than on the basis of differential elongation through sites of premature termination. We also show that mutations that affect the efficiency of initiation of transcription from the c-myc P2 promoter can influence premature termination by at least two mechanisms: TATA box mutations function by the titration effect (decrease in transcription initiation results in a relative decrease in premature termination), while an upstream activator (E2F) site functions by contributing to the assembly of polymerase complexes competent to traverse the downstream sites of premature termination.

Distinct properties of c-myc transcriptional elongation are revealed in Xenopus oocytes and mammalian cells and by template titration, 5,6-dichloro-1-beta-D-ribofuranosylbenzimidazole (DRB), and promoter mutagenesis

A block to c-myc transcription elongation has been observed in Xenopus oocytes and mammalian cells. Here, we show that the distribution of RNA polymerase II transcription complexes in the c-myc promoter proximal region in Xenopus oocytes is different from that observed previously in mammalian cells. Thus, there are major differences in the c-myc elongation block observed in the two systems. In addition, as first reported for a Xenopus tubulin gene (K. M. Middleton and G. T. Morgan, Mol. Cell. Biol. 10:727-735, 1990). c-myc template titration experiments reveal the existence of two classes of RNA polymerase II transcription complexes in oocytes: one (at low template concentration) that is capable of reading through downstream sites of premature termination, and another (high template concentration) that does not. We show that these classes of polymerases are distinct from those previously identified by 5,6-dichloro-1-beta-D-ribofuranosylbenzimidazole (DRB), which distinguishes transcription complexes on the basis of transcribed distance, rather than on the basis of differential elongation through sites of premature termination. We also show that mutations that affect the efficiency of initiation of transcription from the c-myc P2 promoter can influence premature termination by at least two mechanisms: TATA box mutations function by the titration effect (decrease in transcription initiation results in a relative decrease in premature termination), while an upstream activator (E2F) site functions by contributing to the assembly of polymerase complexes competent to traverse the downstream sites of premature termination.

Transcription of human 5S rRNA genes is influenced by an upstream DNA sequence

Six human 5S rRNA genes and gene variants and one pseudogene have been sequenced. The six genes/variants were transcribed in a HeLa cell extract with about equal efficiency. Three genes contain the Sp1 binding sequence GGGCGG in position -43 to -38 and three genes contain the Sp1 like sequence GGGCCG in this position. The six genes contain furthermore one Sp1 binding site in a position about -245 and one ATF recognition site in a position about -202. A 12 bp sequence (GGCTCTTGGGGC) found in position -32 to -21 strongly influenced the transcriptional efficiency in vitro. This 12-mer, designated the D box, has also been found upstream a 5S rRNA gene from hamster and mouse. Removal of the Sp1 binding sites had no effect on the transcription in vitro whereas the transcriptional efficiency decreased to 10% if the D box was removed from the human 5S rRNA gene.

The yeast alpha 2 protein can repress transcription by RNA polymerases I and II but not III

The alpha 2 protein of the yeast Saccharomyces cerevisiae normally represses a set of cell-type-specific genes (the a-specific genes) that are transcribed by RNA polymerase II. In this study, we determined whether alpha 2 can affect transcription by other RNA polymerases. We find that alpha 2 can repress transcription by RNA polymerase I but not by RNA polymerase III. Additional experiments indicate that alpha 2 represses RNA polymerase I transcription through the same pathway that it uses to repress RNA polymerase II transcription. These results implicate conserved components of the transcription machinery as mediators of alpha 2 repression and exclude several alternate models.

The yeast alpha 2 protein can repress transcription by RNA polymerases I and II but not III

The alpha 2 protein of the yeast Saccharomyces cerevisiae normally represses a set of cell-type-specific genes (the a-specific genes) that are transcribed by RNA polymerase II. In this study, we determined whether alpha 2 can affect transcription by other RNA polymerases. We find that alpha 2 can repress transcription by RNA polymerase I but not by RNA polymerase III. Additional experiments indicate that alpha 2 represses RNA polymerase I transcription through the same pathway that it uses to repress RNA polymerase II transcription. These results implicate conserved components of the transcription machinery as mediators of alpha 2 repression and exclude several alternate models.

In vitro transcription of the c-myc first exon may be influenced by the extent of chromatin assembly

The first exon of the human c-myc gene can be transcribed by either RNA polymerase II or RNA polymerase III. The molecular factors contributing to polymerase selection are not yet completely defined. We have examined the role of chromatin structure in regulating transcription by RNA polymerase III. Using as competitor a pol III gene in both a cis and trans arrangement, we demonstrate that c-myc gene expression is facilitated from templates containing a minimal number of fully assembled nucleosomes. The removal of excess histones by DNA titration leads to an elevated level of c-myc expression. These results suggest that either the c-myc expression is inhibited when the template is fully packaged into chromatin or that the affinity of RNA polymerase for the regulatory elements of this exon is such that a template, devoid of histones, is required for transcriptional initiation.

Specific transcription from the adenovirus E2E promoter by RNA polymerase III requires a subpopulation of TFIID

The early E2 (E2E) promoter of adenovirus type 2 possesses a TATA-like element and binding sites for the factors E2F and ATF. This promoter is transcribed by RNA polymerase II in high salt nuclear extracts, but by RNA polymerase III in standard nuclear extracts, as judged by sensitivity to low and high, respectively, concentrations of alpha-amanitin. Transcription by the two RNA polymerases initiated at the same site and depended, in both cases, on the TATA-like sequence and upstream elements. However, RNA polymerase III transcripts, unlike those synthesized by RNA polymerase II, terminated at two runs of Ts downstream of the initiation site. Although they are not essential, sequences downstream of the initiation site increased the efficiency of E2E transcription by RNA polymerase III. Such RNA polymerase III dependent transcription required a subpopulation of the general transcription factor, TFIID: TFIID that binds weakly to phosphocellulose (0.3 M eluate) complemented a TFIID-depleted extract to restore RNAp III transcription, whereas TFIID tightly associated with phosphocellulose (1 M eluate) was unable to do so.

The structure and complete sequence of the gene encoding chicken ribosomal protein L5

The nucleotide (nt) sequence of the gene encoding chicken ribosomal protein L5, which associates with 5S rRNA, was determined. The gene contains eight exons and seven introns which spread over 7252 bp. The transcription start point (tsp) is a C residue in a tract of 13 pyrimidines, and its 5'-flanking region lacks canonical TATA and CAAT boxes. The G+C content of the region around the tsp is calculated as high as 78%, and nine GC boxes exist within the 5'-flanking region and the first intron. The nt sequence at positions -36 to -22 is similar to an internal sequence at positions 56-70 of the gene encoding chicken 5S rRNA, which corresponds to the transcriptional internal control region of the 5S rRNA-encoding gene of Xenopus laevis. This region might contribute to the coordinate expression of the genes encoding protein L5 and 5S rRNA.

In vitro inhibition of c-myc transcription by mithramycin

Mithramycin is a DNA-binding antibiotic that has been reported to selectively affect c-myc expression [Snyder, R. C. et al., (1991) Biochemistry 30, 4290-4297]. We used in vitro transcription to investigate the specificity of mithramycin action. We found that mithramycin inhibited transcription from the human c-myc P1 and P2 promoters, as well as from a minimal adenovirus-2 major late promoter, with equal efficiencies. Mithramycin also inhibited transcription elongation by creating kinetic blockades to the passage of RNA polymerase II. These data suggest that mithramycin may inhibit transcription non-specifically by affecting general processes such as transcription elongation.

Control of adenovirus major late gene expression at multiple levels

Most late adenovirus (Ad) proteins are translated from mRNAs originating from the so-called major late transcription unit (MLTU). These mRNAs are grouped into five families (designated L1 to L5), where each family consists of mRNAs that have co-terminal 3' ends. We have used mutant and wild-type Ad infections to characterize levels at which major late gene expression is regulated. Our results suggest the existence of a novel intermediate stage during a lytic infection where mRNAs from regions L1 and L4 are selectively overexpressed compared to the L2, L3, and L5 mRNAs. Our data suggest that this RNA phenotype reflects the activity of the MLTU at a transient stage immediately following initiation of viral DNA replication. Early during an Ad infection only mRNA from region L1 accumulate. To efficiently accumulate mRNA from regions L1 and L5 both viral DNA replication and late protein synthesis were required. To allow for only viral DNA replication resulted in an extensive premature transcription termination and a preferential mRNA accumulation from regions L1 and L4. The surprising production of L4 mRNA under these conditions was not due to the activation of a novel r-strand promoter located in the vicinity of region L4 or due to a control at the level of RNA transport or stability. Instead our results indicate that in the absence of efficient late protein synthesis 3' end formation occurs preferentially at the L1 and L4 poly(A) addition sites.

Sequence requirements for transcriptional arrest in exon 1 of the human adenosine deaminase gene

We have previously demonstrated that a transcriptional arrest site exists in exon 1 of the human adenosine deaminase (ADA) gene and that this site may play a role in ADA gene expression (Z. Chen, M. L. Harless, D. A. Wright, and R. E. Kellems, Mol. Cell. Biol. 10:4555-4564, 1990). Sequences involved in this process are not known precisely. To further define the template requirements for transcriptional arrest within exon 1 of the human ADA gene, various ADA templates were constructed and their abilities to confer transcriptional arrest were determined following injection into Xenopus oocytes. The exon 1 transcriptional arrest signal functioned downstream of several RNA polymerase II promoters and an RNA polymerase III promoter, implying that the transcriptional arrest site in exon 1 of the ADA gene is promoter independent. We identified a 43-bp DNA fragment which functions as a transcriptional arrest signal. Additional studies showed that the transcriptional arrest site functioned only in the naturally occurring orientation. Therefore, we have identified a 43-bp DNA fragment which functions as a transcriptional arrest signal in an orientation-dependent and promoter-independent manner. On the basis of our findings, we hypothesize that tissue-specific expression of the ADA gene is governed by factors that function as antiterminators to promote transcriptional readthrough of the exon 1 transcriptional arrest site.

Complex transcriptional regulation of myc family gene expression in the developing mouse brain and liver

myc family genes (c-, N-, and L-myc) have been shown to be differentially expressed with respect to tissue type and developmental stage. To define and compare the regulatory mechanisms governing their differential developmental expression, we examined the transcriptional regulation of each myc family member during murine postnatal brain and liver development. Nuclear run-on transcription assays demonstrated that both the rate of transcriptional initiation and the degree of transcriptional blocking contribute in a complex manner to the regulation of all three genes. During postnatal brain development, the relative contribution of each transcriptional control mechanism to the regulation of myc family gene expression was found to be different for each gene. For instance, while modulation of transcriptional attenuation did not appear to contribute to the down-regulation of L-myc expression, attenuation was found to be the dominant mechanism by which steady-state N-myc mRNA levels were down-regulated. Different transcriptional strategies were found to be employed in newborn versus adult developing liver for repression of N- and L-myc expression. Undetectable steady-state N- and L-myc mRNA levels in newborn liver were associated with a very low rate of transcriptional initiation, whereas the lack of N- and L-myc expression at the adult stage was accompanied by a high rate of initiation and a striking degree of transcriptional attenuation. Transcriptional attenuation in the N-myc gene was found to map to a region encoding a potential stem-loop structure followed by a thymine tract within the first exon and was not dependent on the use of a specific transcriptional start site.

Complex transcriptional regulation of myc family gene expression in the developing mouse brain and liver

myc family genes (c-, N-, and L-myc) have been shown to be differentially expressed with respect to tissue type and developmental stage. To define and compare the regulatory mechanisms governing their differential developmental expression, we examined the transcriptional regulation of each myc family member during murine postnatal brain and liver development. Nuclear run-on transcription assays demonstrated that both the rate of transcriptional initiation and the degree of transcriptional blocking contribute in a complex manner to the regulation of all three genes. During postnatal brain development, the relative contribution of each transcriptional control mechanism to the regulation of myc family gene expression was found to be different for each gene. For instance, while modulation of transcriptional attenuation did not appear to contribute to the down-regulation of L-myc expression, attenuation was found to be the dominant mechanism by which steady-state N-myc mRNA levels were down-regulated. Different transcriptional strategies were found to be employed in newborn versus adult developing liver for repression of N- and L-myc expression. Undetectable steady-state N- and L-myc mRNA levels in newborn liver were associated with a very low rate of transcriptional initiation, whereas the lack of N- and L-myc expression at the adult stage was accompanied by a high rate of initiation and a striking degree of transcriptional attenuation. Transcriptional attenuation in the N-myc gene was found to map to a region encoding a potential stem-loop structure followed by a thymine tract within the first exon and was not dependent on the use of a specific transcriptional start site.

Sequence requirements for transcriptional arrest in exon 1 of the human adenosine deaminase gene

We have previously demonstrated that a transcriptional arrest site exists in exon 1 of the human adenosine deaminase (ADA) gene and that this site may play a role in ADA gene expression (Z. Chen, M. L. Harless, D. A. Wright, and R. E. Kellems, Mol. Cell. Biol. 10:4555-4564, 1990). Sequences involved in this process are not known precisely. To further define the template requirements for transcriptional arrest within exon 1 of the human ADA gene, various ADA templates were constructed and their abilities to confer transcriptional arrest were determined following injection into Xenopus oocytes. The exon 1 transcriptional arrest signal functioned downstream of several RNA polymerase II promoters and an RNA polymerase III promoter, implying that the transcriptional arrest site in exon 1 of the ADA gene is promoter independent. We identified a 43-bp DNA fragment which functions as a transcriptional arrest signal. Additional studies showed that the transcriptional arrest site functioned only in the naturally occurring orientation. Therefore, we have identified a 43-bp DNA fragment which functions as a transcriptional arrest signal in an orientation-dependent and promoter-independent manner. On the basis of our findings, we hypothesize that tissue-specific expression of the ADA gene is governed by factors that function as antiterminators to promote transcriptional readthrough of the exon 1 transcriptional arrest site.

In vitro and in vivo analysis of the c-myc RNA polymerase III promoter

The c-myc promoter has the unusual property of displaying both RNA polymerase II (Pol II) and RNA polymerase III (Pol III) activities. Both Pol II and Pol III utilize the same transcription initiation site. We have now examined the effects of mutations in crucial regions of the c-myc promoter to assess their effects on both transcriptional activities. In doing this we show that both Pol II and Pol III activities require sequences that are located within the stronger of the two principal c-myc promoter regions (P2). Further, we show that the Pol III activity using this initiation site does not require an A box or distal upstream sequences. Like the Pol II activity, it does require an intact TATA sequence and alterations at this site result in the simultaneous loss of both Pol II and Pol III activities. The superimposition of two apparently inseparable promoter activities makes it possible to consider common features, possible common protein elements in each holoenzyme complex, as well as a potential role for each enzyme in the regulated expression of the c-myc gene.

Analysis of premature termination in c-myc during transcription by RNA polymerase II in a HeLa nuclear extract

Transcriptional regulation of the human c-myc gene, an important aspect of cellular differentiation, occurs in part at the level of transcript elongation. In vivo, transcriptional arrest, due to either pausing or termination, occurs near the junction between the first exon and first intron and varies with the growth state of the cell. We have tested the transcription of c-myc templates in HeLa nuclear extracts. We did not observe significant arrest under standard conditions, but we found that a considerable fraction of transcription complexes stopped at the c-myc TII site (just past the first exon-intron junction) when the KCl concentration was raised to 400 mM during elongation. Transcriptional arrest at TII also was observed at KCl concentrations as low as 130 mM and when potassium acetate or potassium glutamate was substituted for KCl. Under these conditions, arrest occurred at the TII site when transcription was initiated at either the c-myc P2 promoter or the adenovirus 2 major late promoter. Further, the TII sequence itself, in forward but not reverse orientation, was sufficient to stop transcription in a HeLa nuclear extract. By separating the TII RNA from active transcription complexes by using gel filtration, we found that arrest at TII at 400 mM KCl resulted in transcript release and thus true transcriptional termination. The efficiency of termination at TII depended on the growth state of the cells from which the extracts were made, suggesting that some factor or factors control premature termination in c-myc.

Analysis of premature termination in c-myc during transcription by RNA polymerase II in a HeLa nuclear extract

Transcriptional regulation of the human c-myc gene, an important aspect of cellular differentiation, occurs in part at the level of transcript elongation. In vivo, transcriptional arrest, due to either pausing or termination, occurs near the junction between the first exon and first intron and varies with the growth state of the cell. We have tested the transcription of c-myc templates in HeLa nuclear extracts. We did not observe significant arrest under standard conditions, but we found that a considerable fraction of transcription complexes stopped at the c-myc TII site (just past the first exon-intron junction) when the KCl concentration was raised to 400 mM during elongation. Transcriptional arrest at TII also was observed at KCl concentrations as low as 130 mM and when potassium acetate or potassium glutamate was substituted for KCl. Under these conditions, arrest occurred at the TII site when transcription was initiated at either the c-myc P2 promoter or the adenovirus 2 major late promoter. Further, the TII sequence itself, in forward but not reverse orientation, was sufficient to stop transcription in a HeLa nuclear extract. By separating the TII RNA from active transcription complexes by using gel filtration, we found that arrest at TII at 400 mM KCl resulted in transcript release and thus true transcriptional termination. The efficiency of termination at TII depended on the growth state of the cells from which the extracts were made, suggesting that some factor or factors control premature termination in c-myc.

The cloned RNA polymerase II transcription factor IID selects RNA polymerase III to transcribe the human U6 gene in vitro

Although the human U2 and U6 snRNA genes are transcribed by different RNA polymerases (i.e., RNA polymerases II and III, respectively), their promoters are very similar in structure. Both contain a proximal sequence element (PSE) and an octamer motif-containing enhancer, and these elements are interchangeable between the two promoters. The RNA polymerase III specificity of the U6 promoter is conferred by a single A/T-rich element located around position -25. Mutation of the A/T-rich region converts the U6 promoter into an RNA polymerase II promoter, whereas insertion of the A/T-rich region into the U2 promoter converts that promoter into an RNA polymerase III promoter. We show that this A/T-rich element can be replaced by a number of TATA boxes derived from mRNA promoters transcribed by RNA polymerase II with little effect on RNA polymerase III transcription. Furthermore, the cloned RNA polymerase II transcription factor TFIID both binds to the U6 A/T-rich region and directs accurate RNA polymerase III transcription in vitro. Mutations in the U6 A/T-rich region that convert the U6 promoter into an RNA polymerase II promoter also abolish TFIID binding. Together, these observations suggest that in the human snRNA promoters, unlike in mRNA promoters, binding of TFIID directs the assembly of RNA polymerase III transcription complexes, whereas the lack of TFIID binding results in the assembly of RNA polymerase II snRNA transcription complexes.

Analysis of immunoglobulin heavy chain delta transcription termination in the production of delta S or delta M mRNA

mRNA encoding secreted immunoglobulin is synthesized either by termination of transcription 3' to secreted terminus sequences and 5' to the membrane terminus sequences or by cleavage of a pre-mRNA transcript containing both secreted and membrane sequences at the appropriate polyadenylation site 5' to the membrane sequences. In vitro "run-on" transcription analysis was used to examine the delta transcription termination patterns in resting membrane IgD expressing B lymphocytes, in KWD2, an IgD-secreting hybridoma, and in TEPC 1017, an IgD-secreting plasmacytoma. In resting B cells, transcription terminated in a region 4 to 7 kilobases 3' to the delta M exons. Transcription in the secreting cells continued through the delta M exons, but terminated at more upstream sites. Additionally, an increased loading of polymerases in the region of the delta S exon and its 5' flanking sequence was detected in the secreting cells and was particularly pronounced in TEPC 1017. It is hypothesized that this peak correlates with high delta S mRNA production.

Sequence requirements for premature transcription arrest within the first intron of the mouse c-fos gene

A strong block to the elongation of nascent RNA transcripts by RNA polymerase II occurs in the 5' part of the mammalian c-fos proto-oncogene. In addition to the control of initiation, this mechanism contributes to transcriptional regulation of the gene. In vitro transcription experiments using nuclear extracts and purified transcription templates allowed us to map a unique arrest site within the mouse first intron 385 nucleotides downstream from the promoter. This position is in keeping with that estimated from nuclear run-on assays performed with short DNA probes and thus suggests that it corresponds to the actual block in vivo. Moreover, we have shown that neither the c-fos promoter nor upstream sequences are absolute requirements for an efficient transcription arrest both in vivo and in vitro. Finally, we have characterized a 103-nucleotide-long intron 1 motif comprising the arrest site and sufficient for obtaining the block in a cell-free transcription assay.

Alteration of the RNA polymerase specificity of U3 snRNA genes during evolution and in vitro

We present evidence that the genes encoding U3 snRNA in plants are transcribed by RNA polymerase III (pol III) and not by RNA polymerase II (pol II) as in vertebrates or lower eukaryotes. The U3 gene is the only known example of a gene transcribed by different polymerases in different organisms. It is possible to convert the plant U3 gene into a functional pol II-transcribed gene by manipulating the spacing between the promoter elements and inserting a pol II-specific termination signal. Pol II-transcribed U3 RNA, containing the 5'-terminal cap different from that present in the wild-type counterpart, is packaged in transfected protoplasts into U3 snRNP precipitable with anti-fibrillarin antibodies. These findings provide further evidence for the common ancestry of the pol II and pol III transcription systems, and indicate that promoter diversification in some genes has occurred relatively recently.

Sequence requirements for premature transcription arrest within the first intron of the mouse c-fos gene

A strong block to the elongation of nascent RNA transcripts by RNA polymerase II occurs in the 5' part of the mammalian c-fos proto-oncogene. In addition to the control of initiation, this mechanism contributes to transcriptional regulation of the gene. In vitro transcription experiments using nuclear extracts and purified transcription templates allowed us to map a unique arrest site within the mouse first intron 385 nucleotides downstream from the promoter. This position is in keeping with that estimated from nuclear run-on assays performed with short DNA probes and thus suggests that it corresponds to the actual block in vivo. Moreover, we have shown that neither the c-fos promoter nor upstream sequences are absolute requirements for an efficient transcription arrest both in vivo and in vitro. Finally, we have characterized a 103-nucleotide-long intron 1 motif comprising the arrest site and sufficient for obtaining the block in a cell-free transcription assay.