Point mutations 5' to the tRNA selenocysteine TATA box alter RNA polymerase III transcription by affecting the binding of TBP

Human Disorders Affecting the Selenocysteine Incorporation Pathway Cause Systemic Selenoprotein Deficiency

Significance: Generalized selenoprotein deficiency has been associated with mutations in SECISBP2, SEPSECS, and TRU-TCA1-1, 3 factors that are crucial for incorporation of the amino acid selenocysteine (Sec) into at least 25 human selenoproteins. SECISBP2 and TRU-TCA1-1 defects are characterized by a multisystem phenotype due to deficiencies of antioxidant and tissue-specific selenoproteins, together with abnormal thyroid hormone levels reflecting impaired hormone metabolism by deiodinase selenoenzymes. SEPSECS mutations are associated with a predominantly neurological phenotype with progressive cerebello-cerebral atrophy. Recent Advances: The recent identification of individuals with defects in genes encoding components of the selenocysteine insertion pathway has delineated complex and multisystem disorders, reflecting a lack of selenoproteins in specific tissues, oxidative damage due to lack of oxidoreductase-active selenoproteins and other pathways whose nature is unclear. Critical Issues: Abnormal thyroid hormone metabolism in patients can be corrected by triiodothyronine (T3) treatment. No specific therapies for other phenotypes (muscular dystrophy, male infertility, hearing loss, neurodegeneration) exist as yet, but their severity often requires supportive medical intervention. Future Directions: These disorders provide unique insights into the role of selenoproteins in humans. The long-term consequences of reduced cellular antioxidant capacity remain unknown, and future surveillance of patients may reveal time-dependent phenotypes (e.g., neoplasia, aging) or consequences of deficiency of selenoproteins whose function remains to be elucidated. The role of antioxidant therapies requires evaluation. Antioxid. Redox Signal. 33, 481-497.

Contributions of in vitro transcription to the understanding of human RNA polymerase III transcription

Human RNA polymerase III transcribes small untranslated RNAs that contribute to the regulation of essential cellular processes, including transcription, RNA processing and translation. Analysis of this transcription system by in vitro transcription techniques has largely contributed to the discovery of its transcription factors and to the understanding of the regulation of human RNA polymerase III transcription. Here we review some of the key steps that led to the identification of transcription factors and to the definition of minimal promoter sequences for human RNA polymerase III transcription.

Isolation and Molecular Evolution of the Selenocysteine tRNA (Cf TRSP) and RNase P RNA (Cf RPPH1) Genes in the Dog Family, Canidae

In an effort to identify rapidly evolving nuclear sequences useful for phylogenetic analyses of closely related species, we isolated two genes transcribed by RNA polymerase III (pol III), the selenocysteine tRNA gene (TRSP) and an RNase P RNA (RPPH1) gene from the domestic dog (Canis familiaris). We focus on genes transcribed by pol III because their coding regions are small (generally 100-300 base pairs [bp]) and their essential promoter elements are located within a couple of hundred bps upstream of the coding region. Therefore, we predicted that regions flanking the coding region and outside of the promoter elements would be free of constraint and would evolve rapidly. We amplified TRSP from 23 canids and RPPH1 from 12 canids and analyzed the molecular evolution of these genes and their utility as phylogenetic markers for resolving relationships among species in Canidae. We compared the rate of evolution of the gene-flanking regions to other noncoding regions of nuclear DNA (introns) and to the mitochondrial encoded COII gene. Alignment of TRSP from 23 canids revealed that regions directly adjacent to the coding region display high sequence variability. We discuss this pattern in terms of functional mechanisms of transcription. Although the flanking regions evolve no faster than introns, both genes were found to be useful phylogenetic markers, in part, because of the synapomorphic indels found in the flanking regions. Gene trees generated from the TRSP and RPPH1 loci were generally in agreement with the published mtDNA phylogeny and are the first phylogeny of Canidae based on nuclear sequences.

Chlamydomonas reinhardtii selenocysteine tRNA[Ser]Sec

Eukaryotic selenocysteine (Sec) protein insertion machinery was thought to be restricted to animals, but the occurrence of both Sec-containing proteins and the Sec insertion system was recently found in Chlamydomonas reinhardtii, a member of the plant kingdom. Herein, we used RT-PCR to determine the sequence of C. reinhardtii Sec tRNA[Ser]Sec, the first non-animal eukaryotic Sec tRNA[Ser]Sec sequence. Like its animal counterpart, it is 90 nucleotides in length, is aminoacylated with serine by seryl-tRNA synthetase, and decodes specifically UGA. Evolutionary analyses of known Sec tRNAs identify the C. reinhardtii form as the most diverged eukaryotic Sec tRNA[Ser]Sec and reveal a common origin for this tRNA in bacteria, archaea, and eukaryotes.

TFIIIC-independent in vitro transcription of yeast tRNA genes

The most peculiar transcriptional property of eukaryotic tRNA genes, as well as of other genes served by RNA polymerase III, is their complete dependence on the intragenic interaction platform provided by transcription factor IIIC (TFIIIC) for the productive assembly of the TBP-containing initiation factor TFIIIB. The sole exception, in yeast, is the U6 RNA gene, which is able to exploit a TATAAATA element, 30 bp upstream of the transcription start site, for the TFIIIC-independent assembly of TFIIIB. To find out whether this extragenic core promoter organization and autonomous TFIIIB assembly capacity are unique features of the U6 gene or also apply to other genes transcribed by RNA polymerase III, we scanned the 5'-flanking regions (up to position -100) of the entire tRNA gene set of Saccharomyces cerevisiae searching for U6-like TATA motifs. Four tRNA genes harboring such a sequence motif around position -30 were identified and found to be transcribed in vitro by a minimal system only composed of TFIIIB and RNA polymerase III. In this system, start site selection is not at all affected by the absence of TFIIIC, which, when added, significantly stimulates transcription by determining an increase in the number, rather than in the efficiency of utilization, of productive initiation complexes. A specific TBP-TATA element interaction is absolutely required for TFIIIC-independent transcription, but the nearby sequence context also contributes to the efficiency of autonomous TFIIIB assembly. The existence of a TFIIIB assembly pathway leading to the faithful transcription of natural eukaryotic tRNA genes in the absence of TFIIIC provides novel insights into the functional flexibility of the eukaryotic tRNA gene transcription machinery and on its evolution from an ancestral RNA polymerase III system relying on upstream, TATA- centered control elements.

Molecular cloning and characterization of the murine staf cDNA encoding a transcription activating factor for the selenocysteine tRNA gene in mouse mammary gland

We have isolated and characterized a cDNA encoding a transcription activating factor for the mouse selenocysteine tRNA (tRNAsec) gene from mouse mammary gland. The full-length cDNA, designated m-Staf, has a 1878-base pair open reading frame encoding 626 amino acids. The predicted amino acid sequence of m-Staf is highly homologous to that of Staf, another selenocysteine tRNA gene transcription activating factor of Xenopus laevis. Like Staf, m-Staf contains seven tandemly repeated zinc fingers and four repeated motifs. Gel shift assays indicated that the recombinant m-Staf specifically bound to the activator element region in the mouse tRNAsec gene. Transient co-transfection experiments in Drosophila Schneider cells, which lack endogenous Staf-like binding activity, showed that m-Staf increased the mouse tRNAsec gene transcription about 15-fold, whereas it stimulated Pol II-dependent thymidine kinase promoter only 2-fold. Northern blot analysis detected the presence of a 3.4-kilobase pair m-Staf transcript, which was widely but differentially expressed in various murine tissues. The binding activity of m-Staf in mouse mammary gland was undetectable during virgin and postlactating periods but increased markedly in parallel with the increase of tRNAsec transcript during the periods of pregnancy and lactation, when the gland undergoes growth and development. These results indicate that m-Staf is a transcriptional activator of the mouse tRNAsec gene and that its binding activity in the mammary gland undergoes developmental alterations.

Differential mode of TBP utilization in transcription of the tRNA[Ser]Sec gene and TATA-less class III genes

The Xenopus laevis selenocysteine tRNA[Ser]Sec gene utilizes the TATA box binding protein (TBP) for its transcription in a manner more like TATA-dependent class II genes than TATA-less class III tRNA genes, even though this gene is transcribed by RNA polymerase III (Pol III). Addition of TBP increased in vitro transcription of the tRNA[Ser]Sec gene and a RNA polymerase II-(Pol II-) dependent template, while it decreased TATA-independent tRNA(Met) gene transcription, in a dose-dependent manner. Addition of wild-type TBP, truncated TBP containing the highly conserved COOH-terminal domain or a mutant TBP defective in TATA-independent Pol III transcription to TBP-depleted extracts restored tRNA[Ser]Sec transcription, while addition of a mutant TBP defective in Pol II transcription did not. These studies provide evidence that common surfaces of TBP may be used in transcription from TATA-dependent promoters of the tRNA[Ser]Sec gene and class II genes. Further, we show that distinct chromatographic fractions of TBP complexes are required for tRNA[Ser]Sec gene transcription and TATA-less class III gene transcription.

Effect of warmup protocol and sampling time on convergence of molecular dynamics simulations of a DNA dodecamer using AMBER 4.1 and particle-mesh Ewald method

This report describes one 3000 ps and two 1500 ps molecular dynamic simulations on a TATA box containing dodecamer DNA duplex in a periodic box of TIP3P water molecules, using the AMBER 4.1 implementation of the particle-mesh Ewald method. We compare the effect of warmup protocol and simulation time length on the root-mean square deviation (RMSD) parameter. For the longer simulation, the RMSD computed for the 500-1000 ps time interval is representative of longer time intervals, including 500-3000 ps. The various warmup protocols do not appear to have a significant effect on the simulation results. Based on the present results, DNA sequence-dependent differences in RMSD, or related properties, should exceed two standard deviations before being attributed to non-simulation factors, such as warmup protocol and sampling time effects; we recommend a minimum criterion of at least a three standard deviation difference with a sampling period of at least 500-1000 ps. In addition, while end effects appear negligible there is a consistent dependence of RMSD on DNA helix length.

Staf, a promiscuous activator for enhanced transcription by RNA polymerases II and III

Staf is a zinc finger protein that we recently identified as the transcriptional activator of the RNA polymerase III-transcribed selenocysteine tRNA gene. In this work we demonstrate that enhanced transcription of the majority of vertebrate snRNA and snRNA-type genes, transcribed by RNA polymerases II and III, also requires Staf. DNA binding assays and microinjection of mutant genes into Xenopus oocytes showed the presence of Staf-responsive elements in the genes for human U4C, U6, Y4 and 7SK, Xenopus U1b1, U2, U5 and MRP and mouse U6 RNAs. Using recombinant Staf, we established that it mediates the activating properties of Staf-responsive elements on RNA polymerase II and III snRNA promoters in vivo. Lastly a 19 bp consensus sequence for the Staf binding site, YY(A/T)CCC(A/G)N(A/C)AT(G/C)C(A/C)YY-RCR, was derived by binding site selection. It enabled us to identify 23 other snRNA and snRNA-type genes carrying potential Staf binding sites. Altogether, our results emphasize the prime importance of Staf as a novel activator for enhanced transcription of snRNA and snRNA-type genes.

Lack of gene- and strand-specific DNA repair in RNA polymerase III-transcribed human tRNA genes

UV light induces DNA lesions which are removed by nucleotide excision repair. Genes transcribed by RNA polymerase II are repaired faster than the flanking chromatin, and the transcribed strand is repaired faster than the coding strand. Transcription-coupled repair is not seen in RNA polymerase I-transcribed human rRNA genes. Since repair of genes transcribed by RNA polymerase III has not been analyzed before, we investigated DNA repair of tRNA genes after irradiation of human fibroblasts with UVC. We studied the repair of UV-induced cyclobutane pyrimidine dimers at nucleotide resolution by ligation-mediated PCR. A single-copy gene encoding selenocysteine tRNA, a tRNA valine gene, and their flanking sequences were analyzed. Protein-DNA footprinting showed that both genes were occupied by regulatory factors in vivo, and Northern blotting and nuclear run-on analysis of the tRNA indicated that these genes were actively transcribed. We found that both genes were repaired slower than RNA polymerase II-transcribed genes. No major difference between repair of the transcribed and the coding DNA strands was detected. Transcribed sequences of the tRNA genes were not repaired faster than flanking sequences. Indeed, several sequence positions in the 5' flanking region of the tRNA(Val) gene were repaired more efficiently than the gene itself. These results indicate that unlike RNA polymerase II, RNA polymerase III has no stimulatory effect on DNA repair. Since tRNA genes are covered by the regulatory factor TFIIIC and RNA polymerase III, these proteins may actually inhibit the DNA's accessibility to repair enzymes.

DNA binding by TATA-box binding protein (TBP): a molecular dynamics computational study

TATA-box binding protein (TBP) in a monomeric form and the complexes it forms with DNA have been elucidated with molecular dynamics simulations. Large TBP domain motions (bend and twist) are detected in the monomer as well as in the DNA complexes; these motions can be important for TBP binding of DNA. TBP interacts with guanine bases flanking the TATA element in the simulations of the complex; these interactions may explain the preference for guanine observed at these DNA positions. Side chains of some TBP residues at the binding interface display significant dynamic flexibility that results in 'flip-flop' contacts involving multiple base pairs of the DNA. We discuss the possible functional significance of these observations.

RNAs mediating cotranslational insertion of selenocysteine in eukaryotic selenoproteins

Selenocysteine, a selenium-containing analog of cysteine, is found in the prokaryotic and eukaryotic kingdoms in active sites of enzymes involved in oxidation-reduction reactions. Its biosynthesis and cotranslational insertion into selenoproteins is performed by an outstanding mechanism, implying the participation of several gene products. The tRNA(Sec) is one of these. In eukaryotes, its transcription mode by RNA polymerase III differs from that of classical tRNA genes, both at the level of the promoter elements and transcription factors involved. In addition, enhanced transcription is afforded by a newly characterized zinc finger activator. Not only transcription of the gene, but also the tRNA(Sec) itself is atypical since its 2D and 3D structures exhibit features which set it apart from classical tRNAs. Decoding of eukaryotic selenocysteine UGA codons requires a stem-loop structure in the 3'UTR of mRNAs, the selenocysteine insertion sequence (SECIS) element. Structure probing and sequence comparisons led us to propose a 2D structure model for the SECIS element, containing a novel RNA motif composed of four consecutive non-Watson-Crick base-pairs. A 3D model, rationalizing the accessibility data, was elaborated by computer modeling. It yields indicative or suggestive evidence for the role that could play some conserved residues and/or structural features in SECIS function. These might act as signals for interaction with SBP, the SECIS binding protein that we have characterized.

Mammalian mitochondrial DNA topoisomerase I preferentially relaxes supercoils in plasmids containing specific mitochondrial DNA sequences

Selected regions of mammalian mitochondrial DNA (mtDNA) were inserted into pGEM plasmid vectors and used as substrates in a kinetic analysis of the highly purified bovine mitochondrial type I topoisomerase. Recombinant plasmids containing the bovine mtDNA heavy and light strand origins of replication (pZT-Hori and pZT-Lori, respectively), a major transcription termination region (pZT-Term) and a portion of cytochrome b gene (pZT-Cytb) were prepared. Southern hybridization using probes specific for either control or mtDNA-containing plasmid indicated a relative preference by the mitochondrial topoisomerase I to relax supercoils in pZT-Hori and pZT-Term. Quantitative determination of kinetic parameters derived from double-reciprocal Lineweaver-Burk plots showed that recombinant plasmids containing the heavy and light strand origins and the transcription termination region were preferentially relaxed by the mitochondrial enzyme with Km values 2.3- to 3.3-fold lower than controls. The Km values for pZT-Hori, pZT-Lori and pZT-Term were 21.0 +/- 0.9 microM, 25.2 +/- 1.0 microM and 17.0 +/- 0.8 microM, respectively, while those for control plasmids were 57.5 +/- 2.1 microM and 56.3 +/- 2.3 microM. pZT-Cytb was not preferentially relaxed compared to the control plasmid (Km = 53.4 +/- 2.0 microM vs. 56.3 +/- 2.3 microM, respectively) indicating that mitochondrial topoisomerase I preferentially interacts with certain mtDNA sequences but not others. Identical experiments with the purified nuclear enzyme did not differentiate between control or mtDNA containing plasmids.

Base modification pattern at the wobble position of Xenopus selenocysteine tRNA(Sec)

We examined the base modification pattern of Xenopus tRNA(Sec) using microinjection into Xenopus oocytes, with particular focus on the wobble base U34 at the first position of the anticodon. We found that U34 becomes modified to mcm5U34 (5-methylcarboxymethyluridine) in the oocyte cytoplasm in a rather complex manner. When the tRNA(Sec) gene is injected into Xenopus oocyte nuclei, psi 55 and m1A58 are readily obtained, but not mcm5U34. This will appear only upon cytoplasmic injection of the gene product arising from the first nuclear injection. In contrast, tRNA(Sec) produced by in vitro transcription with T7 RNA polymerase readily acquires i6A37, psi 55, m1A58, and mcm5U34. The latter is obtained after direct nuclear or cytoplasmic injections. It has been reported by others that mcm5Um, a 2'-O-methylated derivative of mcm5U34, also exists in rat and bovine tRNA(Sec). With both the gene product and the in vitro transcript, and using the sensitive RNase T2 assay, we were unable to detect under our conditions the presence of a dinucleotide carrying mcm5Um and that would be therefore refractory to hydrolysis. We showed that the unusual mcm5U acquisition pathway does not result from impairment of nucleocytoplasmic transport. Rather, these data can be interpreted to mean that the modification is performed by a tRNA(Sec) specific enzyme, limiting in the oocyte cytoplasm.

Transcription factors required for the expression of Xenopus laevis selenocysteine tRNA in vitro

It has previously been reported that transcription in vivo of the tRNA(Sec) gene requires three promoter elements, a PSE and a TATA-box upstream of the coding region which are functionally interchangeable with the U6 snRNA gene counterparts and an internal B-block, resembling that of classical tRNA genes (1). We have established an in vitro transcription system from HeLa cells in which three factors, which are either essential for or stimulate transcription were identified. Apart from the TATA-binding protein TBP, the PSE-binding protein PBP was found to be essentially required for expression of the gene. Depletion of PBP from cell extracts by PSE-oligonucleotides abolished tRNA(Sec) transcription, which could be reconstituted by readdition of partially purified PBP. Addition of increasing amounts of recombinant human TBP to an S100 extract stimulated transcription of the tRNA(Sec), the mouse U6 snRNA and the human Y3 genes, an effect which was not observed in the case of a TATA-less tRNA gene. Purified human TFIIA strongly stimulated tRNA(Sec) transcription in a fashion depending on the concentration of TBP. Surprisingly, partially purified TFIIIC was shown to be dispensable for transcription in vitro and unable to bind the B-block of this gene in vitro, although its sequence matches the consensus for this element. Collectively, these data suggest that the mechanism by which transcription complexes are formed on the tRNA(Sec) gene is dramatically different from that observed for classical tRNA genes and much more resembles that observed for externally controlled pol III genes.