Transcription by RNA polymerase III

Deletion mapping of tumor promotion-susceptibility gene pro1 implicates an RNA polymerase III transcription unit

The murine gene pro1 has been cloned from JB6 epidermal cell lines that are sensitive to neoplastic transformation by tumor promoters. Insensitive JB6 variants acquire susceptibility to neoplastic transformation by tumor promoters when transfected with pro1. The repetitive nature of pro1 was indicated by sequence and Southern analysis. In contrast, northern analysis of RNA from promotion-sensitive cells revealed the presence of a small pro1-hybridizing transcript. Strand-specific RNA probes implicated an RNA polymerase III (RNAPIII) coding domain in pro1 as the source of this hybridization signal. Ribonuclease protection of gel-purified pro1 RNA from JB6 variant cell lines identified a 130-nucleotide transcript. The size of this transcript is compatible with in vitro RNAPIII transcription of pro1. Deletion mapping of pro1 by exonuclease III demonstrated that the biologically active domain included the RNAPIII transcription unit. RNA probes map pro1 RNA within the activity domain. These results delineate an activity domain of 597 nucleotides and suggest that a small RNA is the product of promotion-sensitivity gene pro1.

Induction of short interspersed nuclear repeat-containing transcripts in epithelial cells upon infection with a chicken adenovirus

Chicken embryo lethal orphan adenovirus (CELO) is used as a vector for expression of exogenous genes in mammalian cells. Here, we analyzed transcriptional alterations in mouse epithelial host cells following infection with CELO using cDNA microarray analysis. Sequence data characterization revealed that a major portion of CELO-induced genes contained short interspersed nuclear elements of the B2 subclass (B2 SINEs). In fact, we could identify SINEs and other repetitive sequences as contributing significantly to the cDNAs used for microarray construction. Moreover, we found that the CELO protein Gam1 was able to mediate transcriptional activation of these B2 SINE-containing RNAs. We hypothesize that upregulation of B2-SINE-containing RNAs could be a novel contribution of Gam1 to CELO host cell infection.

Suppression of a nuclear frameshift mutation by a mitochondrial tRNA in the yeast Kluyveromyces lactis

A fragment of mitochondrial DNA containing the Kluyveromyces lactis gene for valine-tRNA (tRNAVAL) was isolated as a multicopy suppressor of a respiratory-deficient mutant of this yeast. The mutant produced a truncated Cox14p because of a +1 frameshift mutation in COX14, a nuclear gene encoding a protein imported into mitochondria which is necessary for respiration (Fiori et al. 2000 Yeast 16: 307-314). We report here that the mitochondrial tRNAVAL gene, when transformed into K. lactis cells, is transcribed outside mitochondria and suppresses the frameshift mutation in COX14 restoring the correct reading frame during translation of its mRNA. In fact, using histidine tagging, the existence of a suppressed Cox14p of normal length was demonstrated in mutants expressing the mt-tRNAVAL from the nucleus. Suppression could occur through a non-canonical four base pairing between the tRNAVAL and the mutated mRNA or through slippage of ribosomes during translation. This is a new case of informational suppression in that the suppression of a chromosomal mutation is not caused by a second mutation but to a mislocalization/expression of a mt-tRNA.

The third zinc finger of TFIIIA stabilizes a hairpin structure of the non-coding strand in the internal control region of 5S RNA gene

The structures of non-coding and coding strands in box C of the internal control region (ICR) of Xenopus laevis somatic 5S RNA gene have been examined by circular dichroism (CD) and Raman spectroscopy in the absence and presence of the third zinc finger of transcription factor IIIA (TFIIIA), which binds to the ICR. The non-coding strand exhibits CD signals assignable to a hairpin and an unfolded structure. The presence of the hairpin structure is supported by Raman spectra, gel electrophoresis, and nucleotide deletion experiments. Binding of the zinc finger to the non-coding strand increases the CD signal of hairpin structure, indicating stabilization of the hairpin structure by the zinc finger. In contrast, the corresponding coding strand remains unfolded even in the presence of the zinc finger. The TFIIIA-ICR complex is not only required for initiation of transcription but also lasts during many rounds of transcription of the 5S RNA gene including the ICR (Bogenhagen et al., Cell 28 (1982) 413). TFIIIA may play a role in promoting the transcription by maintaining the unwound non-coding strand in the hairpin structure and leaving the coding strand available for transcription by RNA polymerase.

Adenylation of small RNAs in human cells. Development of a cell-free system for accurate adenylation on the 3'-end of human signal recognition particle RNA

The 3'-end sequences of several human small RNAs were determined, and the results show that a fraction of human cytoplasmic 7SL, ribosomal 5S, and nuclear U2, U6, and 7SK small RNAs contain a post-transcriptionally added adenylic acid residue on their 3'-ends. Incubation of HeLa cell extract in vitro in the presence of [alpha-32P]ATP resulted in labeling of several small RNAs including ribosomal 5S and cytoplasmic 7SL as well as U2 and U6 small nuclear RNAs. Analysis of 7SL RNA labeled in this in vitro adenylation system showed that a single adenylic acid residue is added to the 3'-end. These results show that the adenylation observed in the in vitro system reflects the post-transcriptional adenylation occurring in vivo.

Genes for murine Y1 and Y3 Ro RNAs have class 3 RNA polymerase III promoter structures and are unlinked on mouse chromosome 6

Murine YRNAs, which are components of the conserved Ro ribonucleoprotein (RNP) complex, have been identified by enzymatic RNA sequencing. Mouse Y1 (mY1) and Y3 (mY3; originally named mY2) RNAs share 97 and 95% identity to the human Y1 and Y3 RNAs, respectively. TATA-like sequences, Proximal Sequence Elements, and octamer sequences, which are upstream promoter element motifs indicative of Class 3 RNA Polymerase III (RNAPIII) transcribed genes, are found upstream of both the putative mY1 and mY3 coding regions. Further, these elements are strikingly conserved both in sequence and position relative to known Class 3 genes and to human YRNA genes. Inhibition of transcription in vitro by 200 micrograms/ml but not 1 microgram/ml of alpha-amanitin indicates transcription of the mouse YRNA genes by RNAPIII. Southern blot of C57BL/6J and Mus spretus murine genomic DNA with mY1 and mY3 gene-specific probes suggests that these genes are single copy in the mouse genome. Finally, gene mapping with a (C57BL/6J x SPRET/Ei)F1 x SPRET/Ei mouse interspecific backcross DNA panel localizes the mY1 gene to the distal end of mouse chromosome 6, close to the motheaten (me) autoimmunity locus. The mY3 gene maps to the proximal end of mouse chromosome 6 very close to the T cell receptor beta locus, in a region homologous to human chromosome 7 where the human YRNA genes have been mapped.

BC1 RNA: transcriptional analysis of a neural cell-specific RNA polymerase III transcript

Rodent BC1 RNA represents the first example of a neural cell-specific RNA polymerase III (Pol III) transcription product. By developing a rat brain in vitro system capable of supporting Pol III-directed transcription, we showed that the rat BC1 RNA intragenic promoter elements, comprising an A box element and a variant B box element, as well as its upstream region, containing octamer-binding consensus sequences and functional TATA and proximal sequence element sites, are necessary for transcription. The BC1 B box, lacking the invariant A residue found in the consensus B boxes of tRNAs, represents a functionally related and possibly distinct promoter element. The transcriptional activity of the BC1 B box element is greatly increased, in both a BC1 RNA and a chimeric tRNA(Leu) gene construct, when the BC1 5' flanking region is present and is appropriately spaced. Moreover, a tRNA consensus B-box sequence can efficiently replace the BC1 B box only if the BC1 upstream region is removed. These interactions, identified only in a homologous in vitro system, between upstream Pol II and intragenic Pol III promoters suggest a mechanism by which the tissue-specific BC1 RNA gene and possibly other Pol III-transcribed genes can be regulated.

A nuclear tRNA gene cluster in the protozoan Leishmania tarentolae and differential distribution of nuclear-encoded tRNAs between the cytosol and mitochondria

All mitochondrial tRNAs in the protozoan Leishmania are believed to be encoded in the nuclear genome and imported selectively into the mitochondria by an as yet unknown mechanism. Previously, we reported that two tRNAs whose genes are tightly linked were imported by mitochondria. In contrast, a tRNA encoded by a lone tRNA gene was not detectable in mitochondria. The lone tRNA gene had flanking sequences that were different from the linked genes. These studies implied a possible correlation between tRNA gene organization and gene flanking sequence, and selective tRNA import into mitochondria. Here, we report the identification of a cluster of 10 tRNA genes and show the distribution of the corresponding tRNAs in cytosolic and mitochondrial fractions. tRNA(leu)(CAG) and tRNA2(arg)(TCG) are abundant in the cytosol, but relatively scarce in mitochondria. Conversely, tRNA(ile)(TAT) and tRNA1(lys)(TTT) are abundant in mitochondria, but relatively scarce in the cytosol. tRNA(val)(TAC) and tRNA2(thr)(TGT) are barely detectable in either cellular compartment, while tRNA(gln)(TTG), tRNA1(arg)(ACG), tRNA(gly)(TCC), and tRNA(trp)(CCA) are detected in approximately equal levels in both compartments. Sequencing of the 2600 bp that comprise the tRNA gene cluster also encoding the genes for 5S RNA and URNAB RNA indicates that nucleotide composition, length, and location of genes within the cluster do not clearly correlate with import characteristics. The unexpected presence of the tRNA(trp)(CCA)-gene transcript in mitochondria is also reported. Evidence suggests that this tRNA may have unidentified base modifications at the anticodon triplet.

In vivo expression and mitochondrial import of normal and mutated tRNA(thr) in Leishmania

Evidence suggests that mitochondria of protozoans and plants contain nuclear-encoded tRNAs. In trypanosomatids, the entire set of tRNAs in the mitochondria are presumably imported from the nucleus, but the mechanism of tRNA import is not presently understood. In this study, we have employed a plasmid-encoded nuclear tRNA gene as a means of investigating tRNA expression and mitochondrial import in vivo in Leishmania tarentolae. Using a Leishmania plasmid, we cloned a 1-kb or 250-bp restriction fragment carrying the nuclear tRNA(thr) gene and three in vitro mutagenized derivatives: Tac6 (an insertion of 6 nucleotides at the anticodon loop), Td4 (a 4-nt insert at the D-loop) and Tv4 (a 4-nt insert at the variable arm). Leishmania cells stably transfected with these plasmids were then examined for tRNA expression and import by Northern analysis. The results show that the plasmid-encoded wild type tRNA(thr) gene produced a significantly elevated level of expression in the cytosol. Similarly, the Tac6-transfected cells exhibited a large abundance of the mutant RNA relative to the normal tRNA (chromosome-encoded gene transcripts) in the cytosol. Furthermore, the mutant Tac6 RNA was found imported into mitochondria, although the proportion of the mutant vs. normal tRNA in mitochondria was greatly reduced as compared to that in the cytosol. We suggest that the mitochondrial import machinery is capable of discriminating against the mutant RNA in favor of the normal tRNA for import. In another example, we found that the Tv4 gene showed expression, albeit somewhat reduced, but its import into mitochondria was completely blocked. Unexpectedly, the 4-base addition mutation (Td4) at the D-loop showed neither expression nor import. While these results clearly signify the importance of various segments within the tRNA gene for in vivo expression, our data underscore the significance of the variable loop for mitochondrial import. It is our belief that this plasmid-encoded tRNA gene expression system in Leishmania may be useful in gaining further insights on tRNA import.

Selective import of nuclear-encoded tRNAs into mitochondria of the protozoan Leishmania tarentolae

The trypanosomatid mitochondrial genome does not encode tRNA genes at all and experimental evidence obtained with Leishmania tarentolae shows that tRNAs in mitochondria represent a selected set of imported nuclear-encoded tRNAs. In this paper we present the data showing that tRNAs derived from the clustered genomic tRNA genes are invariably imported into mitochondria, while tRNA from the solitary gene is not. By sequencing a cosmid DNA clone of L. tarentolae genomic DNA, we have identified a 1.5-kb subclone encoding a duplicate set of the closely linked tRNA(Tyr) (GTA) and tRNA(Thr) (AGT) genes. Northern analysis shows that these tRNAs are imported into mitochondria. In contrast, when the tRNA gene [tRNA(Gln) (CUG)] located alone in a 40-kb DNA fragment was examined, the corresponding tRNA was not detected in the mitochondrion. This "loner" tRNA gene is highly unusual since the 3'-flanking putative RNA polymerase III transcription termination signal sequence is characterized by a long string of 8 Ts followed by an A and a stretch of 7 Cs, while all other trypanosomatid tRNA genes whose tRNA transcripts are imported are terminated by a possible transcription termination signal of only 4-6 Ts. Whether the correlation found between the gene organization and tRNA-import characteristics is of general significance needs to be investigated further. A simple computer analysis presented in this paper rules out the possibility that tRNAs found in the trypanosomatid mitochondrion are the products of the U-addition type 'RNA editing' of maxicircle DNA.

In vitro binding to the leucine tRNA gene identifies a novel yeast homeobox gene

In a search for gene products of Saccharomyces cerevisiae interacting with the internal promoter of yeast tRNA genes two genes encoding a homeodomain protein of the Drosophila Antennapedia type were isolated. One of them codes for Pho2, and the second codes for a previously unknown protein (Yox1). The corresponding gene, termed YOX1, maps to chromosome 16. The amino acid sequence of Yox1 shows a remarkable similarity within the homeobox domain to many proteins from a wide variety of sources. Fusion proteins that contain sequences encoded by these genes demonstrate that the genes encode DNA-binding proteins that are capable of binding to the DNA of the leucine tRNA gene in vitro. However, deletion of YOX1 gene activity does not give rise to a scorable mutant phenotype. This result leaves open whether Yox1 binding to the leucine tRNA gene is necessary for the in vivo regulation of the gene and its suggests that the YOX1 gene codes for a non-essential product.

Endonucleolytic cleavage of a long 3'-trailer sequence in a nuclear yeast suppressor tRNA

Transcripts of Saccharomyces cerevisiae nuclear tRNA genes are normally terminated within a few nucleotides of the tRNA coding region, in contrast to mitochondrially encoded tRNAs, which are contained within polycistronic transcripts and thus require 3'-processing by mitochondrial endonucleases. We show that 3'-processing activities capable of removing artificially extended 3'-trailer sequences from some tRNA substrates are also present in the yeast nucleus. Correct 3'-processing in vivo resulted in the formation of functional suppressor tRNA. The 3'-processing activities were also identified in vitro through analysis of transcription-processing products in cell-free yeast S-100 extracts. Comparison of several pre-tRNA substrates showed that the tRNA structure played a major role in determining the processability of a substrate but that the nature of the 3'-trailer sequence also modulated the rate of 3'-processing. Pre-tRNA containing mitochondrial tRNA(Val) sequence was a good substrate for in vitro processing, independent of its 3'-trailer. A 200-nt-long pre-tRNA, encoding the nuclear SUP4 tRNA gene and a mitochondrial 3'-trailer, was processed in yeast S-100 extract in a multistep pathway into mature-sized tRNA(Tyr). Part of the 3'-processing was due to an endonuclease which cleaved near or precisely at the 3'-end of the coding region of the tRNA. A short sequence around this endonucleolytic 3'-cleavage site was crucial for the formation of active suppressor tRNA in vivo. A 9-nt-long sequence motif derived from the mitochondrial 3'-trailer allowed processing, while sequences derived from lacZ or pBR322 DNA were processed neither in vitro nor in vivo.

The herpes simplex virus immediate-early protein ICP27 stimulates the transcription of cellular Alu repeated sequences by increasing the activity of transcription factor TFIIIC

Infection with herpes simplex virus (HSV) results in an increase in the transcription of the endogenous Alu repeated sequence by RNA polymerase III. This effect is also observed in uninfected cells stably transformed with a plasmid expressing the HSV immediate-early protein ICP27 or in cells transfected with the gene encoding this protein. Both uninfected cells expressing ICP27 and cells infected with virus producing functional ICP27 display increased activity of the cellular transcription factor TFIIIC when compared with untreated cells. This increase is not observed, however, in cells infected with a mutant strain of virus which does not produce ICP27. Hence ICP27 induces elevated Alu transcription by activating transcription factor TFIIIC, which is the limiting factor for such transcription. This is the first report of increased activity of a cellular transcription factor during HSV infection, when most cellular gene activity is inhibited.

Characterization of transcription and processing from plasmids that use polIII and a yeast tRNA gene as promoter to transcribe promoter-deficient downstream DNA

Transfer RNA (tRNA) with mutations affecting the internal promoters and thereby causing them to be nontranscribable by polIII (exemplified, e.g., by nematode tDNAPro with large insertions between the two internal promoters) could be transcribed by polIII both in vitro (yeast) and in vivo (oocytes) when cloned behind a yeast tRNAArg gene. PolIII initiated RNA synthesis could also proceed into a downstream structural gene normally read by polIII. the resultant yeast-nematode dimeric tRNA linked in front of mRNA sequences was recognized by processing enzymes to give mature tRNA. Thus, a yeast tRNA gene preceded by its 5' flank can function as a promoter for polIII transcription of any DNA, also of DNA coding for genes that otherwise could not have been expressed either in vitro or in vivo.

Regulation of transcription by translational components in coupled translation-transcription cell-free system

A coupled translation-transcription cell-free system was established from eukaryotic cells. The biosynthetic activity of this coupled system closely resembles the synthetic behavior of cells in vivo, and exhibits regulatory phenomena similar to that of intact cells. The translational system consists of rabbit reticulocyte lysate, or its components fractionated by centrifugation. The transcriptional portion consists of cockerel liver nuclei. Incorporation of amino acids into protein by the coupled system is linear for hours. Similarly, transcription in the coupled system is continuous for hours and is proportional with time. More than 90% of the transcriptional products are secreted into the incubation medium. The components of the translational system influence and regulate transcriptional activities. In the presence of ribosomes the nuclei transcribe mostly poly(A)+ RNA with alpha-amanitin sensitivity consistent with activation of RNA polymerase II. Hybrid selection experiments demonstrate authentic preproalbumin mRNA among the transcriptional products. The putative mRNA secreted into the medium in the coupled system is found on polysomes, indicating translation of de novo synthesized message. Addition of excess reticulocyte mRNP to the medium of the coupled system results in transcription of primarily ribosomal RNA, 5S RNA, and tRNA, the products of RNA polymerases I and III. These activities closely imitate the behavior of liver in vivo under conditions of nutritional shifts or hormonal influences. The coupled system transcribes, processes, and transports substantial quantities of RNA, about 1.6 micrograms/10(6) nuclei/h. Thus, a coupled system has been established that lends itself to the exploration of regulatory interactions of cell components as it appears to closely resemble the in vivo situation.

Trypanosoma cruzi 5S rRNA genes: molecular cloning, structure and chromosomal organization

To further study the ribosomal RNA genetic system in Trypanosoma cruzi, the 5S rRNA gene family was characterized. We found that this gene family is reiterated about 1600 times per diploid nuclei and is mostly organized as a tandem repeat of 481 base pairs. These gene clusters were assigned to two chromosomes of about 1500 and 1400 kilobase pairs. We found that the 5S rRNA-coding region is comprised of 120 nucleotides, and contains the well-known internal control regions of eukaryotic RNA polymerase III. The two gene-spacer regions analysed exhibit a putative signal for transcription termination and six sites homologous to the consensus sequence for the binding of transcription factor Sp1.

A role for the TATA-box-binding protein component of the transcription factor IID complex as a general RNA polymerase III transcription factor

The major class of vertebrate genes transcribed by RNA polymerase (EC 2.7.7.6) III, which includes 5S rRNA genes, tRNA genes, and the adenovirus VA genes, is characterized by split internal promoters and no absolute dependence upon specific upstream sequences. Fractionation experiments have shown that transcription of such genes requires two general RNA polymerase III-specific factors, TFIIIB and TFIIIC. We now demonstrate that a third general factor is also employed by these genes. This is the TATA-box-binding protein originally identified as being a component of the general RNA polymerase II transcription factor TFIID. This protein is involved in the transcription by RNA polymerase III of every template tested, even though the promoters of VA and most vertebrate tRNA and 5S rRNA genes do not contain recognizable TATA elements.

The assembly of functional preinitiation complexes and transcription of 5S RNA-encoding genes containing point mutations

The transcription of several Syrian hamster 5S RNA-encoding genes (5S genes) containing single and multiple point mutations in and around the intragenic control region has been analyzed in a HeLa cell-free system. Although most genes with point mutations displayed normal levels of transcription, several exhibited a three- to fivefold reduction in transcription. These mutations interfere with the interaction between the 5S genes and the soluble factors. The above studies help to establish the importance of specific nucleotides within the 5S gene for productive interactions of individual transcription factors in vitro.

Nuclear factors which bind to Dictyostelium discoideum transfer RNA genes

RNA Polymerase III transcription factors from the cellular slime mold Dictyostelium discoideum were characterized, based on their stable binding to isolated tRNA genes. Different protein complexes are sequestered on DNA fragments containing tRNA genes depending on the conditions by which the nuclei were extracted. Binding specificity was determined through competition assays using competitor tRNA genes from the same gene family, from different gene families and from truncated tRNA genes. The complex with the highest multiformity of interdependent proteins is able to assemble with low affinity on a B-block-free tDNA template, whereas most lower molecular weight complexes require the presence of an intact B-block promoter element in order to assemble.

Sequence and organization of 5S RNA genes from the eukaryotic protist Acanthamoeba castellanii

A 5S RNA genomic clone has been isolated from Acanthamoeba castellanii and the sequence of the coding region plus flanking DNA was determined. This clone encodes an RNA whose sequence matches that of 5S RNA from this organism. There is sequence similarity in the 5'-flanking region to other eukaryotic 5S RNA genes which require or are greatly affected by upstream regions for transcriptional activity. The immediate 3'-flanking region has a termination sequence similar to that found in all genes that are transcribed by RNA polymerase III. The 5S RNA genes of A. castellanii are dispersed, which is highly unusual, since the majority of eukaryotic organisms contain 5S genes clustered in tandem repeats. There may be up to 480 genes encoding 5S RNA in each A. castellanii cell.

Genetic and molecular analysis of eight tRNA(Trp) amber suppressors in Caenorhabditis elegans

Over 100 revertants of five different amber mutants were analyzed by Southern blot hybridization using synthetic oligomers as probes to detect a single base change at the anticodon, CCA to CTA (amber), of tRNA(Trp) genes of Caenohrabditis elegans. Of the 12 members of the tRNA(Trp) gene family, a total of eight were converted to amber suppressor alleles. All eight encode identical tRNAs; three of these are new tRNA(Trp) suppressors, sup-21, sup-33 and sup-34. Previous results had suggested that individual suppressor tRNA genes were expressed differentially in a cell-type- or developmental stage-specific manner. To extend these observations to the new genes and to test the specificity of expression against additional genes, cross suppression tests of these eight amber suppressors were carried out against amber mutations in several different genes including genes likely to be expressed in the same cell-type: three nervous system-affecting genes, two muscle structure-affecting genes and two genes presumed to be expressed in hypodermis. Seven out of eight suppressors could be distinguished one from another by the spectrum of their suppression efficiencies. These results also provide further evidence of cell-type-specific patterns of expression in the nervous system, muscle and hypodermis. The suppression pattern of the suppressor against the two muscle-affecting genes, unc-15 and unc-52, suggested that either the suppressors are expressed in a developmental stage-specific manner or that the unc-52 products are expressed in cell-types other than muscle, possibly hypodermis.

ret1-1, a yeast mutant affecting transcription termination by RNA polymerase III

In eukaryotes, extended tracts of T residues are known to signal the termination of RNA polymerase III transcription. However, it is not understood how the transcription complex interacts with this signal. We have developed a selection system in yeast that uses ochre suppressors weakened by altered transcription termination signals to identify mutations in the proteins involved in termination of transcription by RNA polymerase III. Over 7600 suppression-plus yeast mutants were selected and screened, leading to the identification of one whose effect is mediated transcriptionally. The ret1-1 mutation arose in conjunction with multiple rare events, including uninduced sporulation, gene amplification, and mutation. In vitro transcription extracts from ret1-1 cells terminate less efficiently at weak transcription termination signals than those from RET1 cells, using a variety of tRNA templates. In vivo this reduced termination efficiency can lead to either an increase or a further decrease in suppressor strength, depending on the location of the altered termination signal present in the suppressor tRNA gene. Fractionation of in vitro transcription extracts and purification of RNA polymerase III has shown that the mutant effect is mediated by highly purified polymerase in a reconstituted system.

Sarkosyl defines three intermediate steps in transcription initiation by RNA polymerase III: application to stimulation of transcription by E1A

We used Sarkosyl to analyze steps along the pathway of transcription initiation by RNA polymerase III. Sarkosyl (0.015%) inhibited transcription when present prior to incubation of RNA polymerase III, TFIIIB, and TFIIIC with the VAI gene, whereas it had no detectable effect on initiation or reinitiation of transcription when added subsequently. The formation of the corresponding 0.015% Sarkosyl-resistant complex required the presence of TFIIIC, TFIIIB, and RNA polymerase III but not nucleoside triphosphates. The addition of 0.05% Sarkosyl after this early step selectively inhibited a later step in the preinitiation pathway, allowing a single round of transcription after nucleoside triphosphate addition but blocking subsequent rounds of initiation. This step occurred prior to initiation because nucleoside triphosphates were not required for the formation of the corresponding 0.05% Sarkosyl-resistant complex. These observations provided a means to distinguish effects of regulatory factors on different steps in promoter activation and function. Using 0.05% Sarkosyl to limit reinitiation, we determined that the E1A-mediated stimulation of transcription by RNA polymerase III resulted from an increase in the number of active transcription complexes.

Sequence and factor requirements for faithful in vitro transcription of human 7SL DNA

We have analysed the transcription of a functional human 7SL gene by RNA polymerase III (RNAPIII) in S100 extracts in vitro. Accurate and efficient synthesis of 7S L RNA depends on the presence of (i) an upstream sequence and (ii) an internal promoter element located within the first 22 bp of the gene. These findings were substantiated by DNase I footprinting. Mutations of the internal promoter identified the doublet CG [nucleotide (nt) +15/+16] outside the A-box homologue (nt +5 to +14) as being essential for both proper promoter function in the in vitro transcription assay and competition in the template-exclusion assay. Fractionation of S100 extracts identified two fractions required in addition to RNAPIII for faithful transcription of the gene. Each of these two fractions gave rise to one of two footprints observed in DNase I protection experiments, indicating that at least two DNA-binding factors are involved.

HSV infection induces increased transcription of Alu repeated sequences by RNA polymerase III

The Alu family of repeated sequences is transcribed by both RNA polymerase II and RNA polymerase III. In cells infected with HSV, transcription by polymerase III increases while transcription by polymerase II decreases. By using virus strains carrying mutations in the genes encoding individual regulatory proteins, we have shown that this effect is dependent upon the immediate-early protein ICP27 and occurs by a process distinct from those which regulate viral gene expression. This is the first example of increased transcription of endogenous cellular sequences by RNA polymerase III during infection with a DNA virus.

The most abundant small cytoplasmic RNA of Saccharomyces cerevisiae has an important function required for normal cell growth

The most abundant RNA visible between 5.8S and 18S rRNA on an ethidium bromide-stained gel of total Saccharomyces cerevisiae RNA has an apparent size of about 600 nucleotides. By purifying the band and using it as a probe to screen a genomic library, we isolated and sequenced the unique gene for this RNA. The transcribed sequence, determined to be 519 nucleotides long, contains elements typical of RNA polymerase III transcription. The RNA is predominantly cytoplasmic, so we called it small cytoplasmic RNA 1 (scR1). ScR1 is neither 3'-polyadenylated nor 5'-trimethylguanosine capped. We constructed a null mutation of the gene by deleting 252 base pairs from the transcribed region. Haploid strains carrying the scr1-delta lesion grew very slowly, segregated cytoplasmic petites [( rho-]) at high frequency, and showed signs of aberrant cell division. A secondary structure model for scR1 shows some of the conserved features of the signal recognition particle 7SL RNAs.

A DNA-binding domain of human transcription factor IIIC2

Transcription factor IIIC2 is required for in vitro transcription of the adenovirus 2 VA1 gene and binds with high affinity to its B-box promoter element which is an 18 bp perfect inverted repeat. Partial proteolysis of TFIIIC2 with chymotrypsin and Staphylococcus aureus V8 protease yielded a species which produced a discrete band in a gel shift assay with about twice the mobility of the undigested complex. Chymotrypsin-digested TFIIIC2 produced a DNase I footprint virtually identical to that of the undigested protein, but the stability of the protein-VA1 DNA complex was drastically reduced and the in vitro transcriptional activity was eliminated. These results indicate that a chymotrypsin-resistant domain of TFIIIC2 binds to the B-box sequence. We speculate that stable binding requires protease sensitive cooperative interactions between TFIIIC2 DNA-binding domains.

Transcription factor IIIB generates extended DNA interactions in RNA polymerase III transcription complexes on tRNA genes

Transcription complexes that assemble on tRNA genes in a crude Saccharomyces cerevisiae cell extract extend over the entire transcription unit and approximately 40 base pairs of contiguous 5'-flanking DNA. We show here that the interaction with 5'-flanking DNA is due to a protein that copurifies with transcription factor TFIIIB through several steps of purification and shares characteristic properties that are normally ascribed to TFIIIB: dependence on prior binding of TFIIIC and great stability once the TFIIIC-TFIIIB-DNA complex is formed. SUP4 gene (tRNATyr) DNA that was cut within the 5'-flanking sequence (either 31 or 28 base pairs upstream of the transcriptional start site) was no longer able to stably incorporate TFIIIB into a transcription complex. The TFIIIB-dependent 5'-flanking DNA protein interaction was predominantly not sequence specific. The extension of the transcription complex into this DNA segment does suggest two possible explanations for highly diverse effects of flanking-sequence substitutions on tRNA gene transcription: either (i) proteins that are capable of binding to these upstream DNA segments are also potentially capable of stimulating or interfering with the incorporation of TFIIIB into transcription complexes or (ii) 5'-flanking sequence influences the rate of assembly of TFIIIB into stable transcription complexes.

The most abundant small cytoplasmic RNA of Saccharomyces cerevisiae has an important function required for normal cell growth

The most abundant RNA visible between 5.8S and 18S rRNA on an ethidium bromide-stained gel of total Saccharomyces cerevisiae RNA has an apparent size of about 600 nucleotides. By purifying the band and using it as a probe to screen a genomic library, we isolated and sequenced the unique gene for this RNA. The transcribed sequence, determined to be 519 nucleotides long, contains elements typical of RNA polymerase III transcription. The RNA is predominantly cytoplasmic, so we called it small cytoplasmic RNA 1 (scR1). ScR1 is neither 3'-polyadenylated nor 5'-trimethylguanosine capped. We constructed a null mutation of the gene by deleting 252 base pairs from the transcribed region. Haploid strains carrying the scr1-delta lesion grew very slowly, segregated cytoplasmic petites [( rho-]) at high frequency, and showed signs of aberrant cell division. A secondary structure model for scR1 shows some of the conserved features of the signal recognition particle 7SL RNAs.

Transcription factor IIIB generates extended DNA interactions in RNA polymerase III transcription complexes on tRNA genes

Transcription complexes that assemble on tRNA genes in a crude Saccharomyces cerevisiae cell extract extend over the entire transcription unit and approximately 40 base pairs of contiguous 5'-flanking DNA. We show here that the interaction with 5'-flanking DNA is due to a protein that copurifies with transcription factor TFIIIB through several steps of purification and shares characteristic properties that are normally ascribed to TFIIIB: dependence on prior binding of TFIIIC and great stability once the TFIIIC-TFIIIB-DNA complex is formed. SUP4 gene (tRNATyr) DNA that was cut within the 5'-flanking sequence (either 31 or 28 base pairs upstream of the transcriptional start site) was no longer able to stably incorporate TFIIIB into a transcription complex. The TFIIIB-dependent 5'-flanking DNA protein interaction was predominantly not sequence specific. The extension of the transcription complex into this DNA segment does suggest two possible explanations for highly diverse effects of flanking-sequence substitutions on tRNA gene transcription: either (i) proteins that are capable of binding to these upstream DNA segments are also potentially capable of stimulating or interfering with the incorporation of TFIIIB into transcription complexes or (ii) 5'-flanking sequence influences the rate of assembly of TFIIIB into stable transcription complexes.

Ordering promoter binding of class III transcription factors TFIIIC1 and TFIIIC2

The separation of the mammalian class III transcription factor TFIIIC into two functional components, termed TFIIIC1 and TFIIIC2, enabled an analysis of their functions in transcription initiation. Template competition assays were used to define the order with which these factors interact in vitro to form stable preinitiation complexes on the adenovirus VAI and Drosophila melanogaster tRNA(Arg) genes. The interaction between these genes and TFIIIC2, the factor that binds with high affinity to the B block, was both necessary and sufficient for template commitment. When either the VAI or tRNA(Arg) gene was preincubated with TFIIIC2 alone, transcription of a second gene added subsequently was excluded, indicating that TFIIIC2 bound stably to the first template. Furthermore, the interaction between TFIIIC2 and these genes must occur prior to that of TFIIIC1 or TFIIIB. Once TFIIIC2 was bound, TFIIIC1 could bind to the tRNA(Arg) and VAI genes, although its interaction with the VAI gene was less stable than that with the tRNA(Arg) gene. TFIIIB activity bound stably to the complex of both genes with TFIIIC2. These results demonstrate that TFIIIC2 is the first transcription factor to bind to these genes and that TFIIIB and TFIIIC1 can then interact in either order to form a preinitiation complex.

Gene structure, organization, and expression in archaebacteria

Major advances have recently been made in understanding the molecular biology of the archaebacteria. In this review, we compare the structure of protein and stable RNA-encoding genes cloned and sequenced from each of the major classes of archaebacteria: the methanogens, extreme halophiles, and acid thermophiles. Protein-encoding genes, including some encoding proteins directly involved in methanogenesis and photoautotrophy, are analyzed on the basis of gene organization and structure, transcriptional control signals, codon usage, and evolutionary conservation. Stable RNA-encoding genes are compared for gene organization and structure, transcriptional signals, and processing events involved in RNA maturation, including intron removal. Comparisons of archaebacterial structures and regulatory systems are made with their eubacterial and eukaryotic homologs.

Small B2 RNAs in mouse oocytes, embryos, and somatic tissues

RNAs of full-grown mouse oocytes, ovulated eggs, embryos, and somatic tissues have been analyzed on Northern blots for the presence of small transcripts homologous to the B2 element, a repetitive 180-nucleotide (N) sequence in the genome, using a single stranded RNA probe. In addition to the heterogeneous 200- to 600-N polyadenylated group reported by others, cytoplasmic RNA contains discrete nonadenylated species of B2-related RNA, approximately 100, 120, 155, and 180 N in length. During meiotic maturation of oocytes, the 200- to 600-N group declines and the 155-N species becomes more prominent. Upon hybridization to oligo(dT) and cleavage with RNase H to remove poly(A) regions, the 200- to 600-N group is removed, the 180-N species increased greatly, and the 155-N species increased slightly. Essentially all of the 200- to 600-N species bind to poly(U) sepharose. We conclude that polyadenylation rather than run-on transcription of B2 elements accounts for most of the heterogeneity of the 200- to 600-N group and that some deadenylation and cleavage take place during maturation. Small B2 RNAs make up 0.04% of total RNA in oocytes and eggs, 6- to 9-fold more than in brain. For comparison, a known small RNA, 4.5 S RNA, is relatively sparse in oocytes and almost absent in eggs. The 100-N B2-related species has been tentatively identified as 4.5 SI RNA; relative to total RNA, it remains approximately constant in oocytes and somatic tissues. During development to the blastocyst stage, small B2 RNAs per embryo increase severalfold, but decline as a fraction of total RNA. In postimplantation development, they continue to decline toward the level found in brain. Expression of B2 transcripts in hnRNA rises around 10 days of development to the level found in brain. The time course of expression of small B2 RNAs suggests an important role in development.

Molecular hypotheses for position-effect variegation: anti-sense transcription and promoter occlusion

There is currently no comprehensive molecular hypothesis to account for position-effect variegation, the mosaic expression of a gene lying near a breakpoint of a chromosomal rearrangement. Here it is proposed that position-effect variegation arises from either anti-sense transcription or from promoter occlusion (transcription readthrough), the former mechanism operating for breakpoints on the 3' side of the affected gene and the latter for breakpoints on the 5' side. Anti-sense transcription will occur in rearrangements that place the anti-sense strand of genes next to a promoter. This anti-sense RNA hybridizes to, and thereby inactivates, sense mRNA transcripts (as anti-sense RNA is known to do). Promoter occlusion may occur in rearrangements that place the affected gene near an open upstream promoter. This promoter drives readthrough transcription that inhibits most normal transcripts. Occasional normal transcripts lead to phenotypic variegation. These hypotheses have three strengths: (i) they predict the major observed features of position-effect variegation including variegated phenotype, stable inheritance, the involvement of rearrangements, only some rearrangements causing variegation, the occurrence of both dominant and recessive variegation, the spreading effect of variegation to several loci, and the conditions required for expression of variegation; (ii) they can plausibly account for features of position-effect variegation that they do not specifically predict; (iii) they lead to a series of novel and testable predictions, including the presence of altered transcripts in rearrangements including position-effect variegation, the location of breakpoints required to cause variegation, and a correlation between the extent of the spreading effect and the length of the novel transcript. These mechanisms can account for several other cases of variegation in addition to classic position-effect variegation. Actual or putative examples of phenotypic variegation due to these mechanisms are known.

Evidence that mouse promotion-sensitivity gene pro1 is transcribed by RNA polymerase III

The murine gene pro1 confers susceptibility to tumor promoters upon transfection into an insensitive host cell. Nucleotide analysis over a minimally active domain of 1049 bp reveals signals expected for a gene transcribed by RNA polymerase II (RNAPII). Similar analysis of the complementary strand shows intragenic signals characteristic of genes transcribed by RNA polymerase III (RNAPIII). We have previously characterized a small, pro1-homologous transcript that is constitutively expressed at lower levels in promotion-insensitive JB6 epidermal cells as compared to promotion-sensitive and transformed clonal variants. To identify whether the pro1 RNAPII or RNAPIII transcription unit encodes the pro1-homologous RNA, RNA probes specific for each of the predicted transcripts were generated. The RNA probe specific for the pro1 RNAPIII transcription unit was found to detect the pro1-hybridizing RNA. Ligating the pro1 RNAPII 5'-flanking region to an interferon gamma reporter sequence failed to induce synthesis of the reporter protein. In addition, pro1 transcripts generated from the predicted RNAPII and RNAPIII transcription units were untranslatable in rabbit reticulocyte lysates. These data are consistent with pro1 associated tumor promotion occurring not through an RNAPII intermediate, but through an RNAPIII intermediate.

Ordering promoter binding of class III transcription factors TFIIIC1 and TFIIIC2

The separation of the mammalian class III transcription factor TFIIIC into two functional components, termed TFIIIC1 and TFIIIC2, enabled an analysis of their functions in transcription initiation. Template competition assays were used to define the order with which these factors interact in vitro to form stable preinitiation complexes on the adenovirus VAI and Drosophila melanogaster tRNA(Arg) genes. The interaction between these genes and TFIIIC2, the factor that binds with high affinity to the B block, was both necessary and sufficient for template commitment. When either the VAI or tRNA(Arg) gene was preincubated with TFIIIC2 alone, transcription of a second gene added subsequently was excluded, indicating that TFIIIC2 bound stably to the first template. Furthermore, the interaction between TFIIIC2 and these genes must occur prior to that of TFIIIC1 or TFIIIB. Once TFIIIC2 was bound, TFIIIC1 could bind to the tRNA(Arg) and VAI genes, although its interaction with the VAI gene was less stable than that with the tRNA(Arg) gene. TFIIIB activity bound stably to the complex of both genes with TFIIIC2. These results demonstrate that TFIIIC2 is the first transcription factor to bind to these genes and that TFIIIB and TFIIIC1 can then interact in either order to form a preinitiation complex.

Activation of transcription factor IIIC by the adenovirus E1A protein

The factor(s) responsible for the adenovirus E1A-stimulated transcription of RNA polymerase III genes was localized previously in a chromatographic fraction containing transcription factor IIIC (TFIIIC). In further studies, two distinct forms of TFIIIC, which were chromatographically separable, generated VA gene-protein complexes that were distinguished by gel shift assays. The form of TFIIIC that generated the more slowly migrating promoter complex had greater transcriptional activity in vitro, associated more rapidly with the promoter, and formed a more salt-resistant complex. Greater amounts of this more active form of TFIIIC resulted from either E1A expression during infection or growth of the cells in a higher concentration of serum, whereas template commitment assays indicated that overall TFIIIC concentrations remained unchanged during viral infection. The in vitro interconversion of the two forms of TFIIIC by phosphatase treatment suggests that transcriptional activation of RNA polymerase III genes can be mediated by phosphorylation of TFIIIC.

Organization of multiple regulatory elements in the control region of the adenovirus type 2-specific VARNA1 gene: fine mapping with linker-scanning mutants

The adenovirus type 2-specific virus-associated RNA 1 (VARNA1) gene is transcribed by eucaryotic RNA polymerase III. Previous studies using deletion mutants for transcription have shown that the VARNA1 gene has a large control region which is composed of several regulatory elements. Twenty-five exact linker-scanning mutations in the control region, from -33 to +77, of this gene were used for definition of the number and boundaries of these elements. The effects of these mutations on transcription and competition for transcription factors in human KB cell extracts revealed five positive regulatory elements. The essential element, which coincided with the B block, was absolutely required for both transcription and formation of stable complexes. A second element, which included the A block, was also required for both transcription and formation of stable complexes. Although this element is not as essential as the B-block element, together with the B-block element it may be necessary for formation of the most basal form of transcription machinery. Therefore, these two elements are the promoter elements in this gene. In addition, one possible element in the interblock region and two elements in the 5' flanking region were also required for efficient transcription, but they were moderately required for formation of stable complexes. Transcription of these mutants and the wild-type gene using an extract of 293 cells was stimulated at least threefold over that with the KB cell extract, as expected. Similar regulatory elements of this gene were revealed, however, when the 293 cell extract was used for transcription of these mutants, suggesting that the E1A-mediated specific transcription factors act on the transcription machinery in a sequence-nonspecific manner.

Effects of single-base substitutions within the Acanthamoeba castellanii rRNA promoter on transcription and on binding of transcription initiation factor and RNA polymerase I

Single-point mutations were introduced into the promoter region of the Acanthamoeba castellanii rRNA gene by chemical mutagen treatment of a single-stranded clone in vitro, followed by reverse transcription and cloning of the altered fragment. The promoter mutants were tested for transcription initiation factor (TIF) binding by a template commitment assay plus DNase I footprinting and for transcription by an in vitro runoff assay. Point mutations within the previously identified TIF interaction region (between -20 and -47, motifs A and B) indicated that TIF interacts most strongly with a sequence centered at -29 and less tightly with sequences upstream and downstream. Some alterations of the base sequence closer to the transcription start site (and outside the TIF-protected site) also significantly decreased specific RNA synthesis in vitro. These were within the region which is protected from DNase I digestion by polymerase I, but these mutations did not detectably affect the binding of polymerase to the promoter.

Genes for tRNA(Asp), tRNA (Pro), tRNA (Tyr) and two tRNAs (Ser) in wheat mitochondrial DNA

We have begun a systematic search for potential tRNA genes in wheat mtDNA, and present here the sequences of regions of the wheat mitochondrial genome that encode genes for tRNA(Asp) (anticodon GUC), tRNA(Pro) (UGG), tRNA(Tyr) (GUA), and two tRNAs(Ser) (UGA and GCU). These genes are all solitary, not immediately adjacent to other tRNA or known protein coding genes. Each of the encoded tRNAs can assume a secondary structure that conforms to the standard cloverleaf model, and that displays none of the structural aberrations peculiar to some of the corresponding mitochondrial tRNAs from other eukaryotes. The wheat mitochondrial tRNA sequences are, on average, substantially more similar to their eubacterial and chloroplast counterparts than to their homologues in fungal and animal mitochondria. However, an analysis of regions ∼ 150 nucleotides upstream and ∼ 100 nucleotides downstream of the tRNA coding regions has revealed no obvious conserved sequences that resemble the promoter and terminator motifs that regulate the expression of eubacterial and some chloroplast tRNA genes. When restriction digests of wheat mtDNA are probed with (32)P-labelled wheat mitochondrial tRNAs, <20 hybridizing bands are detected, whether enzymes with 4 bp or 6 bp recognition sites are used. This suggests that the wheat mitochondrial genome, despite its large size, may carry a relatively small number of tRNA genes.

Inhibition of host cell RNA polymerase III-mediated transcription by poliovirus: inactivation of specific transcription factors

The inhibition of transcription by RNA polymerase III in poliovirus-infected cells was studied. Experiments utilizing two different cell lines showed that the initiation step of transcription by RNA polymerase III was impaired by infection of these cells with the virus. The observed inhibition of transcription was not due to shut-off of host cell protein synthesis by poliovirus. Among four distinct components required for accurate transcription in vitro from cloned DNA templates, activities of RNA polymerase III and transcription factor TFIIIA were not significantly affected by virus infection. The activity of transcription factor TFIIIC, the limiting component required for transcription of RNA polymerase III genes, was severely inhibited in infected cells, whereas that of transcription factor TFIIIB was inhibited to a lesser extent. The sequence-specific DNA-binding of TFIIIC to the adenovirus VA1 gene internal promoter, however, was not altered by infection of cells with the virus. We conclude that (i) at least two transcription factors, TFIIIB and TFIIIC, are inhibited by infection of cells with poliovirus, (ii) inactivation of TFIIIC does not involve destruction of its DNA-binding domain, and (iii) sequence-specific DNA binding by TFIIIC may be necessary but is not sufficient for the formation of productive transcription complexes.