Transcription by RNA polymerase II induces changes of DNA topology in yeast

Does genome surveillance explain the global discrepancy between binding and effect of chromatin factors?

Knocking out a chromatin factor often does not alter the transcription of its binding targets. What explains the observed disconnect between binding and effect? We hypothesize that this discrepancy could be associated with the role of chromatin factors in maintaining genetic and epigenetic integrity at promoters, and not necessarily with transcription. Through re-analysis of published datasets, we present several lines of evidence that support our hypothesis and deflate the popular assumptions. We also tested the hypothesis through mutation accumulation assays on yeast knockouts of chromatin factors. Altogether, the proposed hypothesis presents a simple explanation for the global discord between chromatin factor binding and effect. Future work in this direction might fortify the hypothesis and elucidate the underlying mechanisms.

Activation domains for controlling plant gene expression using designed transcription factors

Targeted gene regulation via designed transcription factors has great potential for precise phenotypic modification and acceleration of novel crop trait development. To this end, designed transcriptional activators have been constructed by fusing transcriptional activation domains to DNA-binding proteins. In this study, a transcriptional activator from the herpes simplex virus, VP16, was used to identify plant regulatory proteins. Transcriptional activation domains were identified from each protein and fused with zinc finger DNA-binding proteins (ZFPs) to generate designed transcriptional activators. In addition, specific sequences within each transcriptional activation domain were modified to mimic the VP16 contact motif that interacts directly with RNA polymerase II core transcription factors. To evaluate these designed transcriptional activators, test systems were built in yeast and tobacco comprising reporter genes driven by promoters containing ZFP-binding sites upstream of the transcriptional start site. In yeast, transcriptional domains from the plant proteins ERF2 and PTI4 activated MEL1 reporter gene expression to levels similar to VP16 and the modified sequences displayed even greater levels of activation. Following stable transformation of the tobacco reporter system with transcriptional activators derived from ERF2, GUS reporter gene transcript accumulation was equal to or greater than those derived from VP16. Moreover, a modified ERF2 domain displayed significantly enhanced transcriptional activation compared with VP16 and with the unmodified ERF2 sequence. These results demonstrate that plant sequences capable of facilitating transcriptional activation can be found and, when fused to DNA-binding proteins, can enhance gene expression.

Topological constraints impair RNA polymerase II transcription and causes instability of plasmid-borne convergent genes

Despite the theoretical bases for the association of topoisomerases and supercoiling changes with transcription and replication, our knowledge of the impact of topological constraints on transcription and replication is incomplete. Although mutation of topoisomerases affects expression and stability of the rDNA region it is not clear whether the same is the case for RNAPII transcription and genome integrity in other regions. We developed new assays in which two convergent RNAPII-driven genes are transcribed simultaneously. Plasmid-based systems were constructed with and without a transcription terminator between the two convergent transcription units, so that the impact of transcription interference could also be evaluated. Using these assays we show that Topos I and II play roles in RNAPII transcription in vivo and reduce the stability of RNAPII-transcribed genes in Saccharomyces cerevisiae. Supercoiling accumulation in convergent transcription units impairs RNAPII transcription in top1Δ strains, but Topo II is also required for efficient transcription independent of Topo I and of detectable supercoiling accumulation. Our work shows that topological constraints negatively affect RNAPII transcription and genetic integrity, and provides an assay to study gene regulation by transcription interference.

H3 k36 methylation helps determine the timing of cdc45 association with replication origins

BACKGROUND

Replication origins fire at different times during S-phase. Such timing is determined by the chromosomal context, which includes the activity of nearby genes, telomeric position effects and chromatin structure, such as the acetylation state of the surrounding chromatin. Activation of replication origins involves the conversion of a pre-replicative complex to a replicative complex. A pivotal step during this conversion is the binding of the replication factor Cdc45, which associates with replication origins at approximately their time of activation in a manner partially controlled by histone acetylation.

METHODOLOGY/PRINCIPAL FINDINGS

Here we identify histone H3 K36 methylation (H3 K36me) by Set2 as a novel regulator of the time of Cdc45 association with replication origins. Deletion of SET2 abolishes all forms of H3 K36 methylation. This causes a delay in Cdc45 binding to origins and renders the dynamics of this interaction insensitive to the state of histone acetylation of the surrounding chromosomal region. Furthermore, a decrease in H3 K36me3 and a concomitant increase in H3 K36me1 around the time of Cdc45 binding to replication origins suggests opposing functions for these two methylation states. Indeed, we find K36me3 depleted from early firing origins when compared to late origins genomewide, supporting a delaying effect of this histone modification for the association of replication factors with origins.

CONCLUSIONS/SIGNIFICANCE

We propose a model in which K36me1 together with histone acetylation advance, while K36me3 and histone deacetylation delay, the time of Cdc45 association with replication origins. The involvement of the transcriptionally induced H3 K36 methylation mark in regulating the timing of Cdc45 binding to replication origins provides a novel means of how gene expression may affect origin dynamics during S-phase.

Fuzzy association rules for biological data analysis: a case study on yeast

Background

Last years' mapping of diverse genomes has generated huge amounts of biological data which are currently dispersed through many databases. Integration of the information available in the various databases is required to unveil possible associations relating already known data. Biological data are often imprecise and noisy. Fuzzy set theory is specially suitable to model imprecise data while association rules are very appropriate to integrate heterogeneous data.

Results

In this work we propose a novel fuzzy methodology based on a fuzzy association rule mining method for biological knowledge extraction. We apply this methodology over a yeast genome dataset containing heterogeneous information regarding structural and functional genome features. A number of association rules have been found, many of them agreeing with previous research in the area. In addition, a comparison between crisp and fuzzy results proves the fuzzy associations to be more reliable than crisp ones.

Conclusion

An integrative approach as the one carried out in this work can unveil significant knowledge which is currently hidden and dispersed through the existing biological databases. It is shown that fuzzy association rules can model this knowledge in an intuitive way by using linguistic labels and few easy-understandable parameters.

The effects of camptothecin on RNA polymerase II transcription: Roles of DNA topoisomerase I

Eukaryotic DNA topoisomerase I is active in transcribed chromatin domains to modulate transcription-generated DNA torsional tension. Camptothecin and other agents targeting DNA topoisomerase I are used in the treatment of human solid cancers with significant clinical efficacy. Major progress has been achieved in recent years in the understanding of enzyme structures and basic cellular functions of DNA topoisomerase I. Nevertheless, the precise enzyme functions and mechanisms during transcription-related processes remain unclear. The current understanding of the molecular action of camptothecin emphasizes the drug action against the enzyme and the production of irreversible breaks in the cellular DNA. However, the high drug potency is hardly fully explained by the DNA damage outcome only. In the recent past, several unexpected findings have been reported in relation to the role of eukaryotic topoisomerase I during transcription. In particular, the function of DNA topoisomerase I and the molecular effects of its inhibition on transcription-coupled processes constitute a very active research area. Here, we will briefly review relevant investigations on topoisomerase I involvement in different stages of transcription, discussing both enzyme functions and drug effects on molecular processes.

Competitive processivity-clamp usage by DNA polymerases during DNA replication and repair

Protein clamps are ubiquitous and essential components of DNA metabolic machineries, where they serve as mobile platforms that interact with a large variety of proteins. In this report we identify residues that are required for binding of the beta-clamp to DNA polymerase III of Escherichia coli, a polymerase of the Pol C family. We show that the alpha polymerase subunit of DNA polymerase III interacts with the beta-clamp via its extreme seven C-terminal residues, some of which are conserved. Moreover, interaction of Pol III with the clamp takes place at the same site as that of the delta-subunit of the clamp loader, providing the basis for a switch between the clamp loading machinery and the polymerase itself. Escherichia coli DNA polymerases I, II, IV and V (UmuC) interact with beta at the same site. Given the limited amounts of clamps in the cell, these results suggest that clamp binding may be competitive and regulated, and that the different polymerases may use the same clamp sequentially during replication and repair.

Relationship between G+C content, ORF-length and mRNA concentration in Saccharomyces cerevisiae

RNA biogenesis is a tightly-regulated process. The levels and timing of expression of a gene depends on its particular function. However, gene expression levels may also depend on structural features. Here we describe the analysis of gene expression of 4977 ORFs using DNA microarrays covering the whole genome of three different S. cerevisiae strains, wild-type and tho2 and thp1 mutants with a general effect on mRNA biogenesis. We show that transcripts from G+C-rich ORFs accumulate at higher concentrations than those from G+C-poor ones, in different ORF-length categories in all strains tested. In addition, we found a negative correlation between ORF length and G+C content. Our results indicate that length and G+C content of a gene have a clear effect on its levels of expression. We discuss the biological relevance of these results, as well as different ways that these structural features could modulate mRNA biogenesis.

Role of transcription in plasmid maintenance in the hpr1Delta mutant of Saccharomyces cerevisiae

The Saccharomyces cerevisiae hyperrecombination mutation hpr1Delta results in instability of sequences between direct repeats that is dependent on transcription of the repeat. Here it is shown that the HPR1 gene also functions in plasmid stability in the presence of destabilizing transcription elongation. In the hpr1Delta mutant, plasmid instability results from unchecked transcription elongation, which can be suppressed by a strong transcription terminator. The plasmid system has been used to examine in vivo aspects of transcription in the absence of Hpr1p. Nuclear run-on studies suggest that there is an increased RNA polymerase II density in the hpr1Delta mutant strain, but this is not accompanied by an increase in accumulation of cytoplasmic mRNA. Suppression of plasmid instability in hpr1Delta can also be achieved by high-copy expression of the RNA splicing factor SUB2, which has recently been proposed to function in mRNA export, in addition to its role in pre-mRNA splicing. High-copy-number SUB2 expression is accompanied by an increase in message accumulation from the plasmid, suggesting that the mechanism of suppression by Sub2p involves the formation of mature mRNA. Models for the role of Hpr1p in mature mRNA formation and the cause of plasmid instability in the absence of the Hpr1 protein are discussed.

The poly(A) signal, without the assistance of any downstream element, directs RNA polymerase II to pause in vivo and then to release stochastically from the template

Genes encoding polyadenylated mRNAs depend on their poly(A) signals for termination of transcription. Typically, transcription downstream of the poly(A) signal gradually declines to zero, but often there is a transient increase in polymerase density immediately preceding the decline. Special elements called pause sites are traditionally invoked to account for this increase. Using run-on transcription from the nuclei of transfected cells, we show that both the pause and the gradual decline that follow a poly(A) site are generated entirely by the poly(A) signal itself in a series of model constructs. We found no other elements to be involved and argue that the elements called pause sites do not function through pausing. Both the poly(A)-dependent pause and the subsequent decline occurred earlier for a stronger poly(A) signal than for a weaker one. Because the gradual decline resembles the abortive elongation that occurs downstream of many promoters, one model has proposed that the poly(A) signal flips the polymerase from the elongation mode to the abortive mode like a binary switch. We compared abortive elongators with poly(A) terminators and found a 4-fold difference in processivity. We conclude that poly(A) terminating polymerases do not merely revert to their prior state of low processivity but rather convert to a new termination-prone condition.

Activation and silencing of leu-500 promoter by transcription-induced DNA supercoiling in the Salmonella chromosome

The notion that transcription can generate supercoils in the DNA template largely stems from work with small circular plasmids. In the present work, we tested this model in the bacterial chromosome using a supercoiling-sensitive promoter as a functional sensor of superhelicity changes. The leu-500 promoter of Salmonella typhimurium is a mutant and inactive variant of the leucine operon promoter that regains activity if negative DNA supercoiling rises above normal levels, typically as a result of mutations affecting DNA topoisomerase I (topA mutants). Activation of the leu-500 promoter was analysed in topA mutant cells harbouring transcriptionally inducible tet or cat gene cassettes inserted in the region upstream from the leu operon. Some insertions inhibited leu-500 promoter activation in the absence of inducer. This effect is dramatic in the interval between 1.7 kb and 0.6 kb from the leu operon, suggesting that the insertions physically interfere with the mechanism responsible for activation. Superimposed on these effects, transcription of the inserted gene stimulated or inhibited leu-500 promoter activity depending on whether this gene was oriented divergently from the leu operon or in the same direction respectively. Interestingly, transcription-mediated inhibition of leu-500 promoter was observed with inserts as far as 5 kb from the leu operon, and it could be relieved by the introduction of a strong gyrase site between the inserted element and the leu-500 promoter. These results are consistent with the idea that transcriptionally generated positive and negative supercoils can diffuse along chromosomal DNA and, depending on their topological sign, elicit opposite responses from the leu-500 promoter.

CAMP is involved in transcriptional regulation of delta9-desaturase during Histoplasma capsulatum morphogenesis

We have characterized the promoter region of the delta9-desaturase gene from two different strains of the dimorphic fungus Histoplasma capsulatum. Desaturase transcription is regulated in the two phases of growth: it is transcribed in the yeast phase at 37 degrees C, while it is inactive in the mycelial phase at 25 degrees C. Phase transition can be induced by shifting the temperature from 25 to 37 degrees C or by adding cAMP to the growth medium. We have identified a stress-responsive cis element (STRE) responsive to cyclic AMP (cAMP)-signaling pathway and demonstrated that this element acts in H. capsulatum. We have also identified an element, hereafter called DRE (Desaturase Regulatory Element), present in the promoters of the H. capsulatum and S. cerevisiae delta9-desaturase gene. We show that this element is necessary but not sufficient to regulate transcription of the H. capsulatum delta9-desaturase gene.

The nuclear actin-related protein of Saccharomyces cerevisiae, Act3p/Arp4, interacts with core histones

Act3p/Arp4, an essential actin-related protein of Saccharomyces cerevisiae located within the nucleus, is, according to genetic data, involved in transcriptional regulation. In addition to the basal core structure of the actin family members, which is responsible for ATPase activity, Act3p possesses two insertions, insertions I and II, the latter of which is predicted to form a loop-like structure protruding from beyond the surface of the molecule. Because Act3p is a constituent of chromatin but itself does not bind to DNA, we hypothesized that insertion II might be responsible for an Act3p-specific function through its interaction with some other chromatin protein. Far Western blot and two-hybrid analyses revealed the ability of insertion II to bind to each of the core histones, although with somewhat different affinities. Together with our finding of coimmunoprecipitation of Act3p with histone H2A, this suggests the in vivo existence of a protein complex required for correct expression of particular genes. We also show that a conditional act3 mutation affects chromatin structure of an episomal DNA molecule, indicating that the putative Act3p complex may be involved in the establishment, remodeling, or maintenance of chromatin structures.

Nascent transcription from the nmt1 and nmt2 genes of Schizosaccharomyces pombe overlaps neighbouring genes

We have determined the extent of the primary transcription unit for the two highly expressed genes nmt1 and nmt2 of Schizosaccharomyces pombe. Transcription run-on analysis in permeabilized yeast cells was employed to map polymerase density across the 3'-flanking region of these two genes. Surprisingly, polymerases were detected 4.3 kb beyond the nmt1 polyadenylation [poly(A)] site and 2.4 kb beyond the nmt2 poly(A) site, which in each case have transcribed through an entire convergent downstream transcription unit. However, the steady-state levels of both downstream genes were unaffected by the high level of nmt1 or nmt2 nascent transcription. Analysis of nmt1 and nmt2 RNA 3' end formation signals indicates that efficient termination of transcription requires not only a poly(A) signal but also additional pause elements. The absence of such pause elements close to the poly(A) sites of these genes may account for their extended nascent transcripts.

DNA in transcriptionally silent chromatin assumes a distinct topology that is sensitive to cell cycle progression

Transcriptionally silent regions of the Saccharomyces cerevisiae genome, the silent mating type loci and telomeres, represent the yeast equivalent of metazoan heterochromatin. To gain insight into the nature of silenced chromatin structure, we have examined the topology of DNA spanning the HML silent mating type locus by determining the superhelical density of mini-circles excised from HML (HML circles) by site-specific recombination. We observed that HML circles excised in a wild-type (SIR+) strain were more negatively supercoiled upon deproteinization than were the same circles excised in a sir- strain, in which silencing was abolished, even when HML alleles in which neither circle was transcriptionally competent were used. cis-acting sites flanking HML, called silencers, are required in the chromosome for establishment and inheritance of silencing. HML circles excised without silencers from cells arrested at any point in the cell cycle retained SIR-dependent differences in superhelical density. However, progression through the cell cycle converted SIR+ HML circles to a form resembling that of circles from sir- cells. This decay was not observed with circles carrying a silencer. These results establish that (i) DNA in transcriptionally silenced chromatin assumes a distinct topology reflecting a distinct organization of silenced versus active chromatin; (ii) the altered chromatin structure in silenced regions likely results from changes in packaging of individual nucleosomes, rather than changes in nucleosome density; and (iii) cell cycle progression disrupts the silenced chromatin structure, a process that is counteracted by silencers.

Template topology and transcription: chromatin templates relaxed by localized linearization are transcriptionally active in yeast

To address the role of transient torsional stress in transcription, we have utilized the regulated expression of HO endonuclease in yeast to create double-strand breaks in DNA templates in vivo at preselected sites. Linearization of circular minichromosomes, either 2 kb upstream or immediately downstream of a lacZ reporter gene controlled by the yeast metallothionein gene (CUP1) promoter, did not alter the copper induction profile of lacZ RNA transcripts compared to that of nonlinearized controls. Constructs site-specifically integrated into yeast chromosome II gave similar results. In vivo cross-linking with psoralen as a probe for negative DNA supercoiling demonstrated that template linearization efficiently dissipated DNA supercoiling induced by transcription. Therefore, the efficient transcription of linearized, relaxed templates found here demonstrates that transient torsional tension is not required for transcription of chromatin templates in yeast.

Inverted repeats, stem-loops, and cruciforms: significance for initiation of DNA replication

Inverted repeats occur nonrandomly in the DNA of most organisms. Stem-loops and cruciforms can form from inverted repeats. Such structures have been detected in pro- and eukaryotes. They may affect the supercoiling degree of the DNA, the positioning of nucleosomes, the formation of other secondary structures of DNA, or directly interact with proteins. Inverted repeats, stem-loops, and cruciforms are present at the replication origins of phage, plasmids, mitochondria, eukaryotic viruses, and mammalian cells. Experiments with anti-cruciform antibodies suggest that formation and stabilization of cruciforms at particular mammalian origins may be associated with initiation of DNA replication. Many proteins have been shown to interact with cruciforms, recognizing features like DNA crossovers, four-way junctions, and curved/bent DNA of specific angles. A human cruciform binding protein (CBP) displays a novel type of interaction with cruciforms and may be linked to initiation of DNA replication.

Enhancement of transcription by short alternating C.G tracts incorporated within a Rous sarcoma virus-based chimeric promoter: in vivo studies

In view of the wide chromosomal distribution of short alternating purine-pyrimidine sequences capable of adopting a number of superhelical stress-dependent structural configurations (left-handed helices and cruciforms), the question has been posed whether such sequences exert any functional effects in vivo. A series of eukaryotic expression vectors were constructed which contained C.G tracts of various lengths in the promoter region. It was shown that insertion of C.G tracts of 12-16 bp significantly increased the level of expression of the chloramphenicol acetyltransferase reporter gene. It was also demonstrated that the formation of additional activation complexes and the use of a preferred "face" or side of the DNA molecule is not responsible for the increased transcription which was observed upon insertion of the C.G tracts. Comparative assays of chromatin structure at the chimeric promoters indicate that the alternating C.G tracts adopt a structure which is incapable of binding histone proteins. These results strongly suggest that control of access to chromatin is involved in regulating the transcriptional activity of the chimeric promoters. Possible molecular bases for this phenomena are discussed.

Hyper-negative template DNA supercoiling during transcription of the tetracycline-resistance gene in topA mutants is largely constrained in vivo

The excess linking deficit of plasmid DNA from topoisomerase I-defective bacteria (topA mutants) results mainly from transcription and is commonly ascribed to unbalanced relaxation of transcription-induced twin-supercoiled domains. This defect is aggravated in genes for membrane-binding proteins (such as the tet gene) where anchoring of the transcription complex to the bacterial membrane is thought to enhance twin-domain partitioning. Thus, it is often assumed that the 'hyper-negative' linking difference of plasmid DNA from topA mutants reflects unconstrained, hyper-negative DNA supercoiling inside the cell. We tested the validity of this assumption in the present study. A DNA sequence that undergoes a gradual B to Z transition under increasing negative superhelical tension was used as a sensor of unconstrained negative supercoiling. Z-DNA formation was probed at a site upstream from the inducible pTac promoter fused either to the tet gene or to the gene for cytosolic chloramphenicol acetyl transferase (cat). Although plasmid DNA linking deficit increased more extensively in topA mutants following tet activation than following cat activation, no significant differences were observed in the extents to which the B to Z DNA transition is stimulated in the two cases. We infer that the excess linking deficit of the tet-containing plasmid DNA reflects constrained negative DNA supercoiling inside the cell.

Signals sufficient for 3'-end formation of yeast mRNA

The following three elements were previously shown to be required for 3'-end formation of mRNA in the yeast Saccharomyces cerevisiae: (i) the efficiency element TATATA or related sequences, which function by enhancing the efficiency of downstream positioning elements; (ii) the positioning element AATAAA or related sequences, which position the poly(A) site; and (iii) the actual poly(A) site, which is usually Py(A)n. In this study, we synthesized a 39-pb poly(A) signal that contained the optimum sequences of these three elements. By inserting the synthetic 3'-end-forming signal into various positions of a CYC1-lacZ fusion gene, we showed that truncated transcripts of the expected sizes were generated. Furthermore, the poly(A) sites of the truncated transcripts were mapped to the expected poly(A) site within the synthetic signal. Our findings establish that the three elements are not only necessary but also sufficient for mRNA 3'-end formation in S. cerevisiae.

A novel histone H4 mutant defective in nuclear division and mitotic chromosome transmission

The histone proteins are essential for the assembly and function of th e eukaryotic chromosome. Here we report the first isolation of a temperature-sensitive lethal histone H4 mutant defective in mitotic chromosome transmission Saccharomyces cerevisiae. The mutant requires two amino acid substitutions in histone H4: a lethal Thr-to-Ile change at position 82, which lies within one of the DNA-binding surfaces of the protein, and a substitution of Ala to Val at position 89 that is an intragenic suppressor. Genetic and biochemical evidence shows that the mutant histone H4 is temperature sensitive for function but not for synthesis, deposition, or stability. The chromatin structure of 2 micrometer circle minichromosomes is temperature sensitive in vivo, consistent with a defect in H4-DNA interactions. The mutant also has defects in transcription, displaying weak Spt- phenotypes. At the restrictive temperature, mutant cells arrest in the cell cycle at nuclear division, with a large bud, a single nucleus with 2C DNA content, and a short bipolar spindle. At semipermissive temperatures, the frequency of chromosome loss is elevated 60-fold in the mutant while DNA recombination frequencies are unaffected. High-copy CSE4, encoding an H3 variant related to the mammalian CENP-A kinetochore antigen, was found to suppress the temperature sensitivity of the mutant without suppressing the Spt- transcription defect. These genetic, biochemical, and phenotypic results indicate that this novel histone H4 mutant defines one or more chromatin-dependent steps in chromosome segregation.

3'-end-forming signals of yeast mRNA

It was previously shown that three distinct but interdependent elements are required for 3' end formation of mRNA in the yeast Saccharomyces cerevisiae: (i) the efficiency element TATATA and related sequences, which function by enhancing the efficiency of positioning elements; (ii) positioning elements, such as TTAAGAAC and AAGAA, which position the poly(A) site; and (iii) the actual site of polyadenylation. In this study, we have shown that several A-rich sequences, including the vertebrate poly(A) signal AATAAA, are also positioning elements. Saturated mutagenesis revealed that optimum sequences of the positioning element were AATAAA and AAAAAA and that this element can tolerate various extents of replacements. However, the GATAAA sequence was completely ineffective. The major cleavage sites determined in vitro corresponded to the major poly(A) sites observed in vivo. Our findings support the assumption that some components of the basic polyadenylation machinery could have been conserved among yeasts, plants, and mammals, although 3' end formation in yeasts is clearly distinct from that of higher eukaryotes.

Presence of negative torsional tension in the promoter region of the transcriptionally poised dihydrofolate reductase gene in vivo

DNA topology has been suggested to play an important role in the process of transcription. Negative torsional tension has been shown to stimulate both pre-initiation complex formation and promoter clearance on plasmid DNA in vitro. We recently showed that genomic DNA in human cells contains localized torsional tension. In the present study we have further characterized and mapped torsional tension in the dihydrofolate reductase (DHFR) gene in Chinese hamster ovary (CHO) cells and investigated the effects of differential rates of transcription on the magnitude and location of this tension. Using psoralen photo-cross-linking in conjunction with X-irradiation, we found that relaxable psoralen hypersensitivity was specifically localized to the promoter region of the serum-regulated DHFR gene in serum-stimulated, but not in serum-starved, cells. Moreover, this hypersensitivity did not appear to be caused by transcription elongation, since it persisted in cells in which transcription of the DHFR gene had been reduced by the transcription inhibitor 5,6-dichloro-1-beta-D-ribofurano-sylbenzimidazole (DRB). We suggest that the generation of negative torsional tension in DNA may play an important role in gene regulation by poising genes for transcription.

Saccharomyces cerevisiae mRNA 3' end forming signals are also involved in transcription termination

Previously, a 38-base-pair (bp) region in the 3' untranslated portion of the Saccharomyces cerevisiae iso-1-cytochrome c gene, was shown to be required for both normal CYC1 mRNA 3' end formation (Zaret and Sherman, 1982), and efficient transcription termination (Russo and Sherman, 1989). In another study, specific sequences such as TATATA, TACATA, and TAGTAGTA were shown to be involved in mRNA 3' end formation in S. cerevisiae (Russo et al., 1991). In this report, an in vivo plasmid stability assay has been utilized to show that these and related sequences are also involved in transcription termination, at varying efficiencies, and in an orientation-dependent manner. For example: the sequence TATATA appeared to terminate transcription almost as efficiently as the original wild type 38-bp region; whereas, the sequences TAGATATATGTAA and TACATA were less efficient, and TTTTTTTATA had little, if any, transcription termination function. In contrast, none of these sequences appeared to terminate transcription in the reverse orientation. Therefore, it appears that certain sequence signals capable of promoting mRNA 3' end formation in yeast, are also directly involved in transcription termination.

Alternating purine-pyrimidine tract activates transcription from the Rouse sarcoma virus LTR lacking promoter and enhancer elements

The transcriptional control region of the Rouse sarcoma virus long terminal repeats (LTR) was shown to contain enhancer and promoter elements located within 200 base pairs upstream from the transcription initiation site [Cullen et al. (1985) Mol. Cell. Biol. 5, 438-447]. Deletion of these elements results in significant loss of LTR transcriptional activity. In the present paper it is shown that a short alternating purine-pyrimidine sequence can restore the constitutive activity of the Rouse sarcoma virus LTR in the absence of upstream elements when inserted in close proximity to the transcription initiator site. The possible molecular bases of this phenomena are discussed.

Production and cleavage of Drosophila hsp70 transcripts extending beyond the polyadenylation site

Transcription downstream of the polyadenylation site was studied in the Drosophila hsp70 gene, whose high level of transcription in response to temperature elevation facilitates detection of rare and possibly short-lived transcripts. Transcription downstream of the polyadenylation site was detected both in cultured cells and in intact animals. Even shortly after temperature elevation the extended nonpolyadenylated RNAs were rare relative to mature message, and their level continued to increase following temperature elevation even after the amount of mature message stopped increasing. The extended transcripts therefore are unlikely to be message precursors. Although continuous transcripts were detected extending as far as 2 kb downstream of the normal polyadenylation site, the predominant extended transcript was 0.45 kb long, apparently produced by cleavage of longer transcripts. Its amount relative to mature message increased with the duration and severity of heat-shock. As is the case in nonpolyadenylated histone mRNA, there is a potential stem-loop structure just upstream of the cleavage site. These data and other lines of evidence suggest that this extended transcript results from an alternative mode of stable 3'-end formation.

The relative contributions of transcription and translation to plasmid DNA supercoiling in Salmonella typhimurium

Mutations affecting DNA topoisomerase I (topA) in Salmonella typhimurium were isolated and graded on the basis of their ability to reverse the effects of gyrB mutations on his operon expression. Different topA and gyrB alleles (in otherwise isogenic strains) were used to gather insights into the transcription-dependent variability of plasmid DNA-linking deficit in growing bacteria. This study showed that modulation of DNA supercoiling by transcription results from the action of two components: one is highly dependent on the coupling of translation to RNA-chain elongation; and the other is unrelated to protein synthesis and entirely dependent on promoter determinants. The former greatly predominates in DNA topoisomerase I mutants (topA and topA gyrB) while the latter is the sole contributor to plasmid DNA-linking deficit in wild-type cells. Altogether, these data suggest that whereas translation acts by enhancing the formation of twin supercoiled domains during elongation, the promoter-dependent effects bear no relation to the twin-supercoiled-domain model and are better explained by a mechanism which responds to the binding/unwinding of template DNA by RNA polymerase.

DNA topoisomerase I controls the kinetics of promoter activation and DNA topology in Saccharomyces cerevisiae

Inactivation of the nonessential TOP1 gene, which codes for Saccharomyces cerevisiae DNA topoisomerase I, affects the rate of transcription starting at the ADH2 promoter. For both the chromosomal gene and the plasmid-borne promoter, mRNA accumulation is kinetically favored in the mutant relative to a wild-type isogenic strain. The addition of ethanol causes in wild-type yeast strains a substantial increase in linking number both on the ADH2-containing plasmid and on the resident 2 microns DNA. Evidence has been obtained that such an in vivo increase in linking number depends on (i) the activity of DNA topoisomerase I and of no other enzyme and (ii) ethanol addition, not on the release from glucose repression. A direct cause-effect relationship between the change in supercoiling and alteration of transcription cannot be defined. However, the hypothesis that a metabolism-induced modification of DNA topology in a eukaryotic cell plays a role in regulating gene expression is discussed.

DNA topoisomerase I controls the kinetics of promoter activation and DNA topology in Saccharomyces cerevisiae

Inactivation of the nonessential TOP1 gene, which codes for Saccharomyces cerevisiae DNA topoisomerase I, affects the rate of transcription starting at the ADH2 promoter. For both the chromosomal gene and the plasmid-borne promoter, mRNA accumulation is kinetically favored in the mutant relative to a wild-type isogenic strain. The addition of ethanol causes in wild-type yeast strains a substantial increase in linking number both on the ADH2-containing plasmid and on the resident 2 microns DNA. Evidence has been obtained that such an in vivo increase in linking number depends on (i) the activity of DNA topoisomerase I and of no other enzyme and (ii) ethanol addition, not on the release from glucose repression. A direct cause-effect relationship between the change in supercoiling and alteration of transcription cannot be defined. However, the hypothesis that a metabolism-induced modification of DNA topology in a eukaryotic cell plays a role in regulating gene expression is discussed.

Termination and pausing of RNA polymerase II downstream of yeast polyadenylation sites

Little is known about the transcriptional events which occur downstream of polyadenylation sites. Although the polyadenylation site of a gene can be easily identified, it has been difficult to determine the site of transcription termination in vivo because of the rapid processing of pre-mRNAs. Using an in vitro approach, we have shown that sequences from the 3' ends of two different Saccharomyces cerevisiae genes, ADH2 and GAL7, direct transcription termination and/or polymerase pausing in yeast nuclear extracts. In the case of the ADH2 sequence, the RNA synthesized in vitro ends approximately 50 to 150 nucleotides downstream of the poly(A) site. This RNA is not polyadenylated and may represent the primary transcript. A similarly sized nonpolyadenylated [poly(A)-] transcript can be detected in vivo from the same transcriptional template. A GAL7 template also directs the in vitro synthesis of an RNA which extends a short distance past the poly(A) site. However, a significant amount of the GAL7 RNA is polyadenylated at or close to the in vivo poly(A) site. Mutations of GAL7 or ADH2 poly(A) signals prevent polyadenylation but do not affect the in vitro synthesis of the extended poly(A)- transcript. Since transcription of the mutant template continues through this region in vivo, it is likely that a strong RNA polymerase II pause site lies within the 3'-end sequences. Our data support the hypothesis that the coupling of this pause site to a functional polyadenylation signal results in transcription termination.

Termination and pausing of RNA polymerase II downstream of yeast polyadenylation sites

Little is known about the transcriptional events which occur downstream of polyadenylation sites. Although the polyadenylation site of a gene can be easily identified, it has been difficult to determine the site of transcription termination in vivo because of the rapid processing of pre-mRNAs. Using an in vitro approach, we have shown that sequences from the 3' ends of two different Saccharomyces cerevisiae genes, ADH2 and GAL7, direct transcription termination and/or polymerase pausing in yeast nuclear extracts. In the case of the ADH2 sequence, the RNA synthesized in vitro ends approximately 50 to 150 nucleotides downstream of the poly(A) site. This RNA is not polyadenylated and may represent the primary transcript. A similarly sized nonpolyadenylated [poly(A)-] transcript can be detected in vivo from the same transcriptional template. A GAL7 template also directs the in vitro synthesis of an RNA which extends a short distance past the poly(A) site. However, a significant amount of the GAL7 RNA is polyadenylated at or close to the in vivo poly(A) site. Mutations of GAL7 or ADH2 poly(A) signals prevent polyadenylation but do not affect the in vitro synthesis of the extended poly(A)- transcript. Since transcription of the mutant template continues through this region in vivo, it is likely that a strong RNA polymerase II pause site lies within the 3'-end sequences. Our data support the hypothesis that the coupling of this pause site to a functional polyadenylation signal results in transcription termination.

Positive supercoiling of DNA greatly diminishes mRNA synthesis in yeast

In Saccharomyces cerevisiae cells harboring a GAL1 promoter-linked beta-galactosidase gene, the simultaneous expression of Escherichia coli DNA topoisomerase I and inactivation of yeast DNA topoisomerases I and II reduces the cellular level of beta-galactosidase to an undetectable level. Analysis of intracellular mRNA level and the density of RNA polymerase along DNA indicates that this reduction is due to the suppression of transcription and that both plasmid-borne and chromosomally located genes are affected. These results are interpreted in terms of inhibition of transcription in vivo due to positive supercoiling of the DNA template: preferential removal of transcription-generated negative supercoils by E. coli DNA topoisomerase I in the absence of both yeast DNA topoisomerases I and II results in the accumulation of positive supercoils in intracellular DNA. In normal prokaryotic or eukaryotic cells, accumulation of positive supercoils is presumably avoided through the balanced actions of DNA topoisomerases.

Involvement of the SIN4 global transcriptional regulator in the chromatin structure of Saccharomyces cerevisiae

We have cloned and sequenced the SIN4 gene and determined that SIN4 is identical to TSF3, identified as a negative regulator of GAL1 gene transcription (S. Chen, R.W. West, Jr., S.L. Johnson, H. Gans, and J. Ma, submitted for publication). Yeast strains bearing a sin4 delta null mutation have been constructed and are temperature sensitive for growth and display defects in both negative and positive regulation of transcription. Transcription of the CTS1 gene is reduced in sin4 delta mutants, suggesting that Sin4 functions as a positive transcriptional regulator. Additionally, a Sin4-LexA fusion protein activates transcription from test promoters containing LexA binding sites. The sin4 delta mutant also shows phenotypes common to histone and spt mutants, including suppression of delta insertion mutations in the HIS4 and LYS2 promoters, expression of promoters lacking upstream activation sequence elements, and decreased superhelical density of circular DNA molecules. These results suggest that the sin4 delta mutation may alter the structure of chromatin, and these changes in chromatin structure may affect transcriptional regulation.

Involvement of the SIN4 global transcriptional regulator in the chromatin structure of Saccharomyces cerevisiae

We have cloned and sequenced the SIN4 gene and determined that SIN4 is identical to TSF3, identified as a negative regulator of GAL1 gene transcription (S. Chen, R.W. West, Jr., S.L. Johnson, H. Gans, and J. Ma, submitted for publication). Yeast strains bearing a sin4 delta null mutation have been constructed and are temperature sensitive for growth and display defects in both negative and positive regulation of transcription. Transcription of the CTS1 gene is reduced in sin4 delta mutants, suggesting that Sin4 functions as a positive transcriptional regulator. Additionally, a Sin4-LexA fusion protein activates transcription from test promoters containing LexA binding sites. The sin4 delta mutant also shows phenotypes common to histone and spt mutants, including suppression of delta insertion mutations in the HIS4 and LYS2 promoters, expression of promoters lacking upstream activation sequence elements, and decreased superhelical density of circular DNA molecules. These results suggest that the sin4 delta mutation may alter the structure of chromatin, and these changes in chromatin structure may affect transcriptional regulation.

The yeast actin intron contains a cryptic promoter that can be switched on by preventing transcriptional interference

We show that the single intron of the actin gene of the yeast Saccharomyces cerevisiae contains a cryptic promoter for transcription of the second exon. This promoter is inactive in the normal actin gene, but can be activated when the actin gene promoter is deleted. An identical activation was induced by placing efficient transcriptional terminators at position 61 of the 309 bp intron. In all cases transcripts with identical 5' ends close to the boundary of the intron and the second exon were produced. These results indicate that the cryptic promoter in the actin intron is occluded in the normal actin gene by transcriptional interference with the actin gene promoter. Transcription initiation near the intron/exon 2 boundary is enabled by protection from traversing polymerases, that initiated transcription at the upstream located actin gene promoter. A partial promoter protection using leaky terminators resulted in small amounts of transcripts initiated from the cryptic promoter. Although we do not know any function of the cryptic promoter in actin gene expression, it is tentative to speculate that the cryptic intron promoter might be a relict of a promoter that was functional earlier in evolution.

Identification of pre-mRNA polyadenylation sites in Saccharomyces cerevisiae

In contrast to higher eukaryotes, little is known about the nature of the sequences which direct 3'-end formation of pre-mRNAs in the yeast Saccharomyces cerevisiae. The hexanucleotide AAUAAA, which is highly conserved and crucial in mammals, does not seem to have any functional importance for 3'-end formation in yeast cells. Instead, other elements have been proposed to serve as signal sequences. We performed a detailed investigation of the yeast ACT1, ADH1, CYC1, and YPT1 cDNAs, which showed that the polyadenylation sites used in vivo can be scattered over a region spanning up to 200 nucleotides. It therefore seems very unlikely that a single signal sequence is responsible for the selection of all these polyadenylation sites. Our study also showed that in the large majority of mRNAs, polyadenylation starts directly before or after an adenosine residue and that 3'-end formation of ADH1 transcripts occurs preferentially at the sequence PyAAA. Site-directed mutagenesis of these sites in the ADH1 gene suggested that this PyAAA sequence is essential for polyadenylation site selection both in vitro and in vivo. Furthermore, the 3'-terminal regions of the yeast genes investigated here are characterized by their capacity to act as signals for 3'-end formation in vivo in either orientation.

Identification of pre-mRNA polyadenylation sites in Saccharomyces cerevisiae

In contrast to higher eukaryotes, little is known about the nature of the sequences which direct 3'-end formation of pre-mRNAs in the yeast Saccharomyces cerevisiae. The hexanucleotide AAUAAA, which is highly conserved and crucial in mammals, does not seem to have any functional importance for 3'-end formation in yeast cells. Instead, other elements have been proposed to serve as signal sequences. We performed a detailed investigation of the yeast ACT1, ADH1, CYC1, and YPT1 cDNAs, which showed that the polyadenylation sites used in vivo can be scattered over a region spanning up to 200 nucleotides. It therefore seems very unlikely that a single signal sequence is responsible for the selection of all these polyadenylation sites. Our study also showed that in the large majority of mRNAs, polyadenylation starts directly before or after an adenosine residue and that 3'-end formation of ADH1 transcripts occurs preferentially at the sequence PyAAA. Site-directed mutagenesis of these sites in the ADH1 gene suggested that this PyAAA sequence is essential for polyadenylation site selection both in vitro and in vivo. Furthermore, the 3'-terminal regions of the yeast genes investigated here are characterized by their capacity to act as signals for 3'-end formation in vivo in either orientation.

Genetic isolation of ADA2: a potential transcriptional adaptor required for function of certain acidic activation domains

We have devised a genetic strategy to isolate the target of acidic activation domains of transcriptional activators based on toxicity in yeast cells of the chimeric activator, GAL4-VP16. Toxicity required the integrity of both the VP16 acidic activation domain and the GAL4 DNA-binding domain, suggesting that inhibition resulted from trapping of general transcription factors at genomic sites. Mutations that break the interaction between GAL4-VP16 and general factors would alleviate toxicity and identify transcriptional adaptors, if adaptors bridged the interaction between activators and general factors. We thus identified ADA1, ADA2, and ADA3. Mutations in ADA2 reduced the activity of GAL4-VP16 and GCN4 in vivo. ada2 mutant extracts exhibited normal basal transcription, but were defective in responding to GAL4-VP16, GCN4, or the dA:dT activator. Strikingly, the mutant extract responded like wild type to GAL4-HAP4. We conclude that ADA2 potentiates the activity of one class of acidic activation domain but not a second class.

Localized torsional tension in the DNA of human cells

Torsional tension in DNA may be both a prerequisite for the efficient initiation of transcription and a consequence of the transcription process itself with the generation of positive torsional tension in front of the RNA polymerase and negative torsional tension behind it. To examine torsional tension in specific regions of genomic DNA in vivo, we developed an assay using photoactivated psoralen as a probe for unconstrained DNA superhelicity and x-rays as a means to relax DNA. Psoralen intercalates more readily into DNA underwound by negative torsional tension than into relaxed. DNA, and it can form interstrand DNA cross-links upon UVA irradiation. By comparing the amount of psoralen-induced DNA cross-links in cells irradiated with x-rays either before or after the psoralen treatment, we examined the topological state of the DNA in specific regions of the genome in cultured human 6A3 cells. We found that although no net torsional tension was detected in the bulk of the genome, localized tension was prominent in the DNA of two active genes. Negative torsional tension was found in the 5' end of the amplified dihydrofolate reductase gene and in a region near the 5' end of the 45S rRNA transcription unit, whereas a low level of positive torsional tension was found in a region near the 3' end of the dihydrofolate reductase gene. These results document an intragenomic heterogeneity of DNA torsional tension and lend support to the twin supercoiled domain model for transcription in the genome of intact human cells.

The end of the message: 3'-end processing leading to polyadenylated messenger RNA

Almost all messenger RNAs carry a polyadenylate tail that is added in a post-transcriptional reaction. In the nuclei of animal cells, the 3'-end of the RNA is formed by endonucleolytic cleavage of the primary transcript at the site of poly(A) addition, followed by the polymerisation of the tail. The reaction depends on specific RNA sequences upstream as well as downstream of the polyadenylation site. Cleavage and polyadenylation can be uncoupled in vitro. Polyadenylation is carried out by poly(A) polymerase with the aid of a specificity factor that binds the polyadenylation signal AAUAAA. Several additional factors are required for the initial cleavage. A newly discovered poly(A)-binding protein stimulates poly(A) tail synthesis and may be involved in the control of tail length. Polyadenylation reactions different from this scheme, either in other organisms or under special physiological circumstances, are discussed.

Direct evidence for the effect of transcription on local DNA supercoiling in vivo

The B-to-Z structural transition of varying lengths (74 to 14 base-pairs) of (CG) tracts has been used as a superhelicity probe to examine the local topological changes induced by transcription at defined genetic loci in vivo. The local-topology reporter sequences indicate that under steady-state transcription the region upstream from the promoter experiences an increase in negative supercoiling whereas the region downstream from the terminator displays a decrease in negative superhelicity. This result provides direct in vivo evidence for the notion that the translocation of an RNA polymerase elongation complex along the double-helical DNA generates positive supercoils in front of it and negative supercoils behind it. Also, this twin-supercoiled domain model was tested inside a transcribed region where a high degree of negative supercoiling generated by the passage of each individual RNA polymerase was detected. Hence, these data indicate that the induced supercoils are confined to the vicinity of each RNA polymerase complex in a multipolymerase system.

Evidence for torsional stress in transcriptionally activated chromatin

The existence of torsional stress in eukaryotic chromatin has been controversial. To determine whether it could be detected, we probed the structure of an alternating AT tract. These sequences adopt cruciform geometry when the DNA helix is torsionally strained by negative supercoiling. The single-strand-specific nuclease P1 was used to determine the structure of an alternating AT sequence upstream of the Xenopus beta-globin gene when assembled into chromatin in microinjected Xenopus oocytes. The pattern of cleavage by P1 nuclease strongly suggests that the DNA in this chromatin template is under torsional stress. The cruciform was detected specifically in the most fully reconstituted templates at later stages of chromatin assembly, suggesting that negative supercoiling is associated with chromatin maturation. Furthermore, the number of torsionally strained templates increased dramatically at the time when transcription of assembled chromatin templates began. Transcription itself has been shown to induce supercoiling, but the requisite negative supercoiling for cruciform extrusion by (AT)n in oocytes was not generated in this way since the characteristic P1 cutting pattern was retained even when RNA polymerase elongation was blocked with alpha-amanitin. Thus, torsional stress is associated with transcriptional activation of chromatin templates in the absence of ongoing transcription.

Relationship of histone acetylation to DNA topology and transcription

An autonomously replicating plasmid constructed from bovine papiloma virus (BPV) and pBR322 was stably maintained as a nuclear episome in a mouse cell culture. Addition to a cell culture of sodium butyrate (5 mM) induced an increase in plasmid DNA supercoiling of 3-5 turns, an increase in acetylation of cellular histones, and a decrease in plasmid transcription by 2- to 4-fold. After withdrawal of butyrate, DNA supercoiling began to fluctuate in a wave-like manner with an amplitude of up to 3 turns and a period of 3-4 h. These waves gradually faded by 24 h. The transcription of the plasmid and acetylation of cellular histones also oscillated with the same period. The wave-like alterations were not correlated with the cell cycle, for there was no resumption of DNA replication after butyrate withdrawal for at least 24 h. In vitro chemical acetylation of histones with acetyl adenylate also led to an increase in the superhelical density of plasmid DNA. The parallel changes in transcription, histone acetylation, and DNA supercoiling in vivo may indicate a functional innerconnection. Also, the observed in vivo variation in the level of DNA supercoiling directly indicates the possibility of its natural regulation in eukaryotic cells.

Evidence for torsional stress in transcriptionally activated chromatin

The existence of torsional stress in eukaryotic chromatin has been controversial. To determine whether it could be detected, we probed the structure of an alternating AT tract. These sequences adopt cruciform geometry when the DNA helix is torsionally strained by negative supercoiling. The single-strand-specific nuclease P1 was used to determine the structure of an alternating AT sequence upstream of the Xenopus beta-globin gene when assembled into chromatin in microinjected Xenopus oocytes. The pattern of cleavage by P1 nuclease strongly suggests that the DNA in this chromatin template is under torsional stress. The cruciform was detected specifically in the most fully reconstituted templates at later stages of chromatin assembly, suggesting that negative supercoiling is associated with chromatin maturation. Furthermore, the number of torsionally strained templates increased dramatically at the time when transcription of assembled chromatin templates began. Transcription itself has been shown to induce supercoiling, but the requisite negative supercoiling for cruciform extrusion by (AT)n in oocytes was not generated in this way since the characteristic P1 cutting pattern was retained even when RNA polymerase elongation was blocked with alpha-amanitin. Thus, torsional stress is associated with transcriptional activation of chromatin templates in the absence of ongoing transcription.

Histone hyperacetylation is accompanied by changes in DNA topology in vivo

The effect of histone acetylation on the topology of plasmids transfected into COS7 cells was examined. Parallel determinations of histone profiles and DNA topology showed that with increasing levels of acetylation the minichromosomal DNA is gradually relaxed. This effect could not be attributed to the increased transcriptional activity accompanying butyrate treatment since plasmids with different promoter strengths exhibited similar superhelical densities. Considering that the number of nucleosomes/minichromosome were constant under these conditions, the data suggest that in vivo histone hyperacetylation reduces the linking number change/nucleosome.

Aromatic amino acid biosynthesis in the yeast Saccharomyces cerevisiae: a model system for the regulation of a eukaryotic biosynthetic pathway

This review focuses on the gene-enzyme relationships and the regulation of different levels of the aromatic amino acid biosynthetic pathway in a simple eukaryotic system, the unicellular yeast Saccharomyces cerevisiae. Most reactions of this branched pathway are common to all organisms which are able to synthesize tryptophan, phenylalanine, and tyrosine. The current knowledge about the two main control mechanisms of the yeast aromatic amino acid biosynthesis is reviewed. (i) At the transcriptional level, most structural genes are regulated by the transcriptional activator GCN4, the regulator of the general amino acid control network, which couples transcriptional derepression to amino acid starvation of numerous structural genes in multiple amino acid biosynthetic pathways. (ii) At the enzyme level, the carbon flow is controlled mainly by modulating the enzyme activities at the first step of the pathway and at the branch points by feedback action of the three aromatic amino acid end products. Implications of these findings for the relationship of S. cerevisiae to prokaryotic as well as to higher eukaryotic organisms and for general regulatory mechanisms occurring in a living cell such as initiation of transcription, enzyme regulation, and the regulation of a metabolic branch point are discussed.

Expression of lacZ gene fusions affects downstream transcription in yeast

Chimeric genes containing Escherichia coli lacZ sequences are often used to characterize gene expression in yeast cells. By Northern analysis, we found that such genes produce multiple transcripts due to inefficient 3'-end formation. The same transcript pattern was found for two related chimeric genes when these genes were cloned separately into the commonly used vector, YIp5, and integrated into the yeast genome at two different locations. Each chimeric gene was composed of promoter and N-terminal coding regions from the yeast SSA1 or SSA2 genes fused in-frame to the lac operon. Transcripts were shown to initiate within the yeast promoter fragment, but transcript size indicated that 3' ends were localized to three different regions: within the lac operon near the 3' end of the lacZ gene; near a terminator region previously identified upstream of the URA3 gene in YIp5; and at the URA3 terminator region. Readthrough transcription of the URA3 promoter from upstream lac sequences decreased the basal activity of the URA3 promoter, although induced URA3 transcription levels were unaffected. This readthrough transcription also resulted in a novel, longer URA3 transcript.