Deregulation of RNA polymerase III transcription in cervical epithelium in response to high-risk human papillomavirus

RNA polymerase (pol) III transcription is a major determinant of biosynthetic capacity, providing essential products such as tRNA and 5S rRNA. It is controlled directly by the tumour suppressors RB and p53. High-risk types of human papillomavirus (HPV), such as HPV16, express the oncoproteins E6 and E7 that can inactivate p53 and RB, respectively. Accordingly, both E6 and E7 stimulate pol III transcription in cultured cells. HPV16-positive cervical biopsies express elevated levels of tRNA and 5S rRNA when compared to biopsies that test negative for HPV or are infected with the lower risk HPV11. Integration of viral DNA into the host cell genome stimulates expression of E6 and E7 and correlates with induction of tRNA and 5S rRNA. Expression of mRNA encoding the pol III-specific transcription factor Brf1 also correlates with the presence of integrated HPV16. Brf1 levels are limiting for tRNA and 5S rRNA synthesis in cervical cells. Furthermore, pol III-transcribed genes that do not use Brf1 are not induced in HPV16-positive biopsies. Three complementary mechanisms may therefore allow high-risk HPV to stimulate production of tRNA and 5S rRNA: E6-mediated removal of p53; E7-mediated neutralization of RB; and induction of Brf1. The resultant increase in biosynthetic capacity may contribute to deregulated cell growth.

RNA polymerases I and III, growth control and cancer

Transcription of rRNA and tRNA genes by RNA polymerases I and III is essential for sustained protein synthesis and is therefore a fundamental determinant of the capacity of a cell to grow. When cell growth is not required, this transcription is repressed by retinoblastoma protein, p53 and ARF. However, inactivation of these tumour suppressors in cancers deregulates RNA polymerases I and III, and oncoproteins such as Myc can stimulate these systems further. Such events might have a significant impact on the growth potential of tumours.

c-Myc binds to human ribosomal DNA and stimulates transcription of rRNA genes by RNA polymerase I

c-Myc coordinates cell growth and division through a transcriptional programme that involves both RNA polymerase (Pol) II- and Pol III-transcribed genes. Here, we demonstrate that human c-Myc also directly enhances Pol I transcription of ribosomal RNA (rRNA) genes. rRNA synthesis and accumulation occurs rapidly following activation of a conditional MYC-ER allele (coding for a Myc-oestrogen-receptor fusion protein), is resistant to inhibition of Pol II transcription and is markedly reduced by c-MYC RNA interference. Furthermore, by using combined immunofluorescence and rRNA-FISH, we have detected endogenous c-Myc in nucleoli at sites of active ribosomal DNA (rDNA) transcription. Our data also show that c-Myc binds to specific consensus elements located in human rDNA and associates with the Pol I-specific factor SL1. The presence of c-Myc at specific sites on rDNA coincides with the recruitment of SL1 to the rDNA promoter and with increased histone acetylation. We propose that stimulation of rRNA synthesis by c-Myc is a key pathway driving cell growth and tumorigenesis.

EACR-18: the best of European cancer research

EACR-18 was the 18th biennial meeting of the European Association for Cancer Research (EACR). It attracted more than 700 delegates, providing a pivotal European forum for basic scientists, translational researchers and clinical oncologists alike. It covered most of the key areas and recent developments in cancer research. This Review presents a meeting report.

RNA polymerase III transcription and cancer

RNA polymerase (pol) III synthesizes a range of essential products, including tRNA, 5S rRNA and 7SL RNA, which are required for protein synthesis and trafficking. High rates of pol III transcription are necessary for cells to sustain growth. A wide range of transformed and tumour cell types have been shown to express elevated levels of pol III products. This review will summarize what is known about the mechanisms responsible for this deregulation. Some transforming agents have been shown to stimulate expression of the pol III-specific transcription factors TFIIIB or TFIIIC2. In addition, TFIIIB is bound and activated by several oncogenic proteins, including c-Myc. Conversely, TFIIIB interacts in healthy cells with the tumour suppressors RB and p53. Indeed, the ability to limit pol III transcription through TFIIIB may contribute to their growth-suppression capacities. The function of p53 and/or RB is compromised in most if not all transformed cells; the resultant derepression of TFIIIB may provide an almost universal route to deregulate pol III transcription in cancers. In addition to effects on protein synthesis and growth, there is a precedent for a pol III product having oncogenic activity.

RNA polymerase III transcription--a battleground for tumour suppressors and oncogenes

This review provides a summary of the European Association for Cancer Research Award Lecture, presented at the ECCO12 meeting in Copenhagen in September 2003. It describes what we have learnt about the mechanisms responsible for deregulating RNA polymerase III transcription in transformed cells. A network has been discovered of unanticipated links to key tumour suppressors and oncogenes. Novel functions have been revealed for RB, p53 and c-Myc, that may help explain their profound biological effects.

Peptide deformylase inhibitors as antibacterial agents: identification of VRC3375, a proline-3-alkylsuccinyl hydroxamate derivative, by using an integrated combinatorial and medicinal chemistry approach

Peptide deformylase (PDF), a metallohydrolase essential for bacterial growth, is an attractive target for use in the discovery of novel antibiotics. Focused chelator-based chemical libraries were constructed and screened for inhibition of enzymatic activity, inhibition of Staphylococcus aureus growth, and cytotoxicity. Positive compounds were selected based on the results of all three assays. VRC3375 [N-hydroxy-3-R-butyl-3-(2-S-(tert-butoxycarbonyl)-pyrrolidin-1-ylcarbonyl)propionamide] was identified as having the most favorable properties through an integrated combinatorial and medicinal chemistry effort. This compound is a potent PDF inhibitor with a K(i) of 0.24 nM against the Escherichia coli Ni(2+) enzyme, possesses activity against gram-positive and gram-negative bacterial pathogens, and has a low cytotoxicity. Mechanistic experiments demonstrate that the compound inhibits bacterial growth through PDF inhibition. Pharmacokinetic studies of this drug in mice indicate that VRC3375 is orally bioavailable and rapidly distributed among various tissues. VRC3375 has in vivo activity against S. aureus in a murine septicemia model, with 50% effective doses of 32, 17, and 21 mg/kg of body weight after dosing by intravenous (i.v.), subcutaneous (s.c.), and oral (p.o.) administration, respectively. In murine single-dose toxicity studies, no adverse effects were observed after dosing with more than 400 mg of VRC3375 per kg by i.v., p.o., or s.c. administration. The in vivo efficacy and low toxicity of VRC3375 suggest the potential for developing this class of compounds to be used in future antibacterial drugs.

TFIIIB is phosphorylated, disrupted and selectively released from tRNA promoters during mitosis in vivo

Mitosis involves a generalized repression of gene expression. In the case of RNA polymerase III transcription, this is due to phosphorylation-mediated inactivation of TFIIIB, an essential complex comprising the TATA-binding protein TBP and the TAF subunits Brf1 and Bdp1. In HeLa cells, this repression is mediated by a mitotic kinase other than cdc2-cyclin B and is antagonized by protein phosphatase 2A. Brf1 is hyperphosphorylated in metaphase-arrested cells, but remains associated with promoters in condensed chromosomes, along with TBP. In contrast, Bdp1 is selectively released. Repression can be reversed by raising the concentration of Brf1 or Bdp1. The data support a model in which hyperphosphorylation disrupts TFIIIB during mitosis, compromising its ability to support transcription.

The TATA-binding protein as a regulator of cellular transformation

The TATA-binding protein, TBP, is used by all three RNA polymerases and is therefore central to the process of gene expression. TBP associates with several subsets of proteins, called TATA-binding protein-associated factors (TAFs). This results in the formation of at least three distinct complexes, SL1, TFIID, and TFIIIB, which dictates whether TBP functions in RNA polymerase (pol) I, pol II, or pol III transcription, respectively. The regulation of gene expression has focused largely on proteins that serve to modulate the efficiency by which the general transcription components, such as TBP, interact with promoters. The possibility of a basal transcription factor, itself, being regulated, and influencing cellular homeostasis, has not been extensively considered. However, recent studies have indicated that TBP is indeed regulated, and that modulation of its cellular concentration has a profound, and surprisingly selective, impact on gene expression that can mediate the normal proliferative responses of cells to growth stimuli as well as the transformation potential of cells.

Physiology, medicine, long-duration space flight and the NSBRI

The hazards of long-duration space flight are real and unacceptable. In order for humans to participate effectively in long-duration orbital missions or continue the exploration of space, we must first secure the health of the astronaut and the success of such missions by assessing in detail the biomedical risks of space flight and developing countermeasures to these hazards. Acquiring the understanding necessary for building a sound foundation for countermeasure development requires an integrated approach to research in physiology and medicine and a level of cooperative action uncommon in the biomedical sciences. The research program of the National Space Biomedical Research Institute (NSBRI) was designed to accomplish just such an integrated research goal, ameliorating or eliminating the biomedical risks of long-duration space flight and enabling safe and productive exploration of space. The fruits of these labors are not limited to the space program. We can also use the gained understanding of the effects and mechanisms of the physiological changes engendered in space and the applied preventive and rehabilitative methods developed to combat these changes to the benefit of those on Earth who are facing similar physiological and psychological difficulties. This paper will discuss the innovative approach the NSBRI has taken to integrated research management and will present some of the successes of this approach.

Quantitative description and discrimination of butterfly wing patterns using moment invariant analysis

Studies examining and using pattern variation in insects for identification and characterization of individuals and populations have been limited by the methods available for quantifying wing patterns objectively. In this paper, differences in wing pattern are demonstrated statistically using moment invariant data sets generated automatically from digitized images of the speckled wood butterfly, Pararge aegeria (Linnaeus). Studies with other biological subjects have already shown moment invariants to work well with outline shapes and silhouettes. A pilot study with replicated monochrome photographs of a single butterfly showed the method could detect pattern differences between wing surfaces, even in the presence of simulated wing fading and damage. In a further study of the wings of 228 specimens, multivariate analyses of variance using the moment data reliably detected differences between groups of butterflies according to sex, geographical origin and culture history. Potential applications and future improvements of the moment methodology are considered.

The prevalence of clinically significant endoscopic findings in primary care patients with uninvestigated dyspepsia: the Canadian Adult Dyspepsia Empiric Treatment - Prompt Endoscopy (CADET-PE) study

BACKGROUND

Uninvestigated dyspepsia is common in family practice. The prevalence of clinically significant upper gastrointestinal findings (CSFs) in adult uninvestigated dyspepsia patients, and their predictability based on history, is unknown.

METHODS

Prompt endoscopy was performed within 10 days of referral, in 1040 adult patients presenting with uninvestigated dyspepsia at 49 Canadian family practitioner centres. Subsequent management strategies during a 6-month follow-up period were determined by the individual family practitioners.

RESULTS

CSFs were identified in 58% (603/1040) of patients. Erosive oesophagitis was most common (43%; N = 451); peptic ulcer was uncommon (5.3%; N = 55). Alarm symptoms were uncommon (2.8%; N = 29). Most patients had at least three dyspepsia symptoms, more than 80% had at least six, and approximately half had eight or more. Based on the dominant symptom, 463 (45%) patients had ulcer-like, 393 (38%) had reflux-like and 184 (18%) had dysmotility-like dyspepsia. The patients' dominant symptom was not predictive of endoscopic findings. Oesophagitis was more common in those with dominant reflux-like symptoms and was the most common finding in all subgroups. The prevalence of gastroduodenal findings was similar in all symptom subgroups. Helicobacter pylori (H. pylori) infection (30%; 301/1013) was associated with gastroduodenal findings.

CONCLUSIONS

Dyspepsia subclassifications, based on dominant symptom, are of limited value in predicting the presence and nature of CSFs. Oesophagitis was by far the most common diagnosis (43% of patients). CSFs were common in uninvestigated dyspepsia patients and their nature suggests patients could be initially treated effectively, without endoscopy, using empirical acid suppressive therapy.

p53 represses RNA polymerase III transcription by targeting TBP and inhibiting promoter occupancy by TFIIIB

The tumor suppressor p53 is a transcription factor that controls cellular growth and proliferation. p53 targets include RNA polymerase (pol) III-dependent genes encoding untranslated RNAs such as tRNA and 5S rRNA. These genes are repressed through interaction of p53 with TFIIIB, a TATA-binding protein (TBP)-containing factor. Although many studies have shown that p53 binds to TBP, the significance of this interaction has remained elusive. Here we demonstrate that the TBP-p53 interaction is of functional importance for regulating RNA pol III-transcribed genes. Unlike RNA pol II-dependent promoter repression, overexpressing TBP can reverse inhibition of tRNA gene transcription by p53. p53 does not disrupt the direct interaction between the TFIIIB subunits TBP and Brf1, but prevents the association of Brf1 complexes with TFIIIC2 and RNA pol III. Using chromatin immunoprecipitation assays, we found that TFIIIB occupancy on tRNA genes markedly decreases following p53 induction, whereas binding of TFIIIC2 to these genes is unaffected. Together our results support the idea that p53 represses RNA pol III transcription through direct interactions with TBP, preventing promoter occupancy by TFIIIB.

The mitogen-activated protein (MAP) kinase ERK induces tRNA synthesis by phosphorylating TFIIIB

RNA polymerase (pol) III transcription increases within minutes of serum addition to growth-arrested fibroblasts. We show that ERK mitogen-activated protein kinases regulate pol III output by directly binding and phosphorylating the BRF1 subunit of transcription factor TFIIIB. Blocking the ERK signalling cascade inhibits TFIIIB binding to pol III and to transcription factor TFIIIC2. Chromatin immunoprecipitation shows that the association of BRF1 and pol III with tRNA(Leu) genes in cells decreases when ERK is inactivated. Furthermore, mutation of an ERK docking domain or phosphoacceptor site in BRF1 prevents serum induction of pol III transcription. These data identify a novel target for ERK, and suggest that its ability to stimulate biosynthetic capacity and growth involves direct transcriptional activation of tRNA and 5S rRNA genes.

Direct regulation of RNA polymerase III transcription by RB, p53 and c-Myc

The synthesis of tRNA and 5S rRNA by RNA polymerase (pol) III is cell cycle regulated in higher organisms. Overexpression of pol III products is a general feature of transformed cells. These observations may be explained by the fact that a pol III-specific transcription factor, TFIIIB, is strongly regulated by the tumor suppressors RB and p53, as well as the proto-oncogene product c-Myc. RB and p53 repress TFIIIB, but this restraint can be lost in tumors through a variety of mechanisms. In contrast, c-Myc binds and activates TFIIIB, causing potent induction of pol III transcription. Using chromatin immunoprecipitation and RNA interference, we show that c-Myc interacts with tRNA and 5S rRNA genes in transformed cervical cells, stimulating their expression. Availability of pol III products may be an important determinant of a cell's capacity to grow. The ability to regulate pol III output may therefore be integral to the growth control functions of RB, p53 and c-Myc.

Myotonic dystrophy and paediatric anaesthesia

Myotonic dystrophy is a neuromuscular condition inherited in an autosomal dominant fashion, and is most commonly diagnosed in the neonatal period. With improving levels of care, these patients are now presenting more commonly for anaesthesia. We review the clinical features of the condition, and then discuss the steps in the anaesthetic process, outlining the anaesthetic implications of myotonic dystrophy at each stage.

Direct activation of RNA polymerase III transcription by c-Myc

The proto-oncogene product c-Myc has a direct role in both metazoan cell growth and division. RNA polymerase III (pol III) is involved in the generation of transfer RNA and 5S ribosomal RNA, and these molecules must be produced in bulk to meet the need for protein synthesis in growing cells. We demonstrate here that c-Myc binds to TFIIIB, a pol III-specific general transcription factor, and directly activates pol III transcription. Chromatin immunoprecipitation reveals that endogenous c-Myc is present at tRNA and 5S rRNA genes in cultured mammalian cells. These results suggest that activation of pol III may have a role in the ability of c-Myc to stimulate cell growth.

Issues of exploration: human health and wellbeing during a mission to Mars

Today, the tools are in our hands to enable us to travel away from our home planet and become citizens of the solar system. Even now, we are seriously beginning to develop the robust infrastructure that will make the 21st century the Century of Space Travel. But this bold step must be taken with due concern for the health, safety and wellbeing of future space explorers. Our long experience with space biomedical research convinces us that, if we are to deal effectively with the medical and biomedical issues of exploration, then dramatic and bold steps are also necessary in this field. We can no longer treat the human body as if it were composed of muscles, bones, heart and brain acting independently. Instead, we must lead the effort to develop a fully integrated view of the body, with all parts connected and fully interacting in a realistic way. This paper will present the status of current (2000) plans by the National Space Biomedical Research Institute to initiate research in this area of integrative physiology and medicine. Specifically, three example projects are discussed as potential stepping stones towards the ultimate goal of producing a digital human. These projects relate to developing a functional model of the human musculoskeletal system and the heart.

Multiple mechanisms contribute to the activation of RNA polymerase III transcription in cells transformed by papovaviruses

RNA polymerase (pol) III transcription is abnormally active in fibroblasts transformed by polyomavirus (Py) or simian virus 40 (SV40). Several distinct mechanisms contribute to this effect. In untransformed fibroblasts, the basal pol III transcription factor (TF) IIIB is repressed through association with the retinoblastoma protein RB; this restraint is overcome by large T antigens of Py and SV40. Furthermore, cells transformed by these papovaviruses overexpress the BDP1 subunit of TFIIIB, at both the protein and mRNA levels. Despite the overexpression of BDP1, the abundance of the other TFIIIB components is unperturbed following papovavirus transformation. In contrast, mRNAs encoding all five subunits of the basal factor TFIIIC2 are found at elevated levels in fibroblasts transformed by Py or SV40. Thus, both papovaviruses stimulate pol III transcription by boosting production of selected components of the basal machinery. Py differs from SV40 in encoding a highly oncogenic middle T antigen that localizes outside the nucleus and activates several signal transduction pathways. Middle T can serve as a potent activator of a pol III reporter in transfected cells. Several distinct mechanisms therefore contribute to the high levels of pol III transcription that accompany transformation by Py and SV40.

Direct and indirect regulation of derrière, a Xenopus mesoderm-inducing factor, by VegT

One candidate for an endogenous mesoderm-inducing factor in Xenopus is derrière, a member of the TGFβ family closely related to Vg1. In this paper we first show that derrière is able to exert long-range effects in the early Xenopus embryo, reinforcing the view that it functions as a secreted factor required for proper formation of posterior structures. Analysis of the derrière promoter shows that expression of the gene is controlled through a complex inductive network involving VegT and TGFβ-related molecules and also, perhaps, FGF family members. The work confirms that derrière plays an important role in mesoderm formation and it illustrates the complex regulation to which inducing factors are subject.

Several regions of p53 are involved in repression of RNA polymerase III transcription

The tumour suppressor p53 has been shown to regulate RNA polymerase (pol) III transcription both in vitro and in vivo. We have characterized the regions of p53 that contribute to this effect. Repression of pol III transcription in vivo does not require residues 13-19 near the N-terminus of p53 that are highly conserved through evolution. However, amino acids 22 and 23 in the adjacent transactivation domain do contribute to the inhibition of pol III activity. Deletions within the central DNA-binding core domain (residues 102-292) of p53 can entirely abolish the repression function in these assays, despite the fact that pol III templates contain no recognized p53 binding site. Deletion or substitution within the C-terminal domain of p53 can also compromise its ability to repress pol III activity in vitro and in transfected cells. These observations reveal that repression of pol III transcription is a complex function involving multiple regions of p53 extending throughout much of the protein.