The adjacent yeast genes ARO4 and HIS7 carry no intergenic region

A genomic study of the inter-ORF distances in Saccharomyces cerevisiae

The genome of eukaryotic microbes is usually quite compacted. The yeast Saccharomyces cerevisiae is one of the best-known examples. Open reading frames (ORFs) occupy about 75% of the total DNA sequence. The existence of other, non-protein coding genes and other genetic elements leaves very little space for gene promoters and terminators. We have performed an in silico study of inter-ORF distances that shows that there is a minimum distance between two adjacent ORFs that depends on the relative orientation between them. Our analyses suggest that different kinds of promoters and terminators exist with regard to their length and ability to overlap each other. The experimental testing of some putative exceptions to the minimum length model in tandemly orientated ORF pairs suggests that, in those cases, defects in promoter or terminator functionality exist that provoke transcription of polycistronic mRNAs.

Causes and effects of nuclear genome reduction

Eukaryotic nuclear genomes are generally considered to be large and gene-sparse, but extreme reduction has taken place several times, resulting in small genomes with a high gene-density. This process involves losing genes, compacting those that remain, or often both. Recently sequenced nuclear genomes include several that have converged to similar gene-densities by many means: variation in numbers and lengths of genes, intergenic regions and introns all contribute, but not equally in any given genome. Genomes of microsporidia and nucleomorphs have taken compaction much further, and in these hyper-compacted genomes there is evidence that some basic processes such as gene expression might be affected by genome form. In these genomes, normally weak forces might become more significant drivers of genome evolution.

A high frequency of overlapping gene expression in compacted eukaryotic genomes

The gene density of eukaryotic nuclear genomes is generally low relative to prokaryotes, but several eukaryotic lineages (many parasites or endosymbionts) have independently evolved highly compacted, gene-dense genomes. The best studied of these are the microsporidia, highly adapted fungal parasites, and the nucleomorphs, relict nuclei of endosymbiotic algae found in cryptomonads and chlorarachniophytes. These systems are now models for the effects of compaction on the form and dynamics of the nuclear genome. Here we report a large-scale investigation of gene expression from compacted eukaryotic genomes. We have conducted EST surveys of the microsporidian Antonospora locustae and nucleomorphs of the cryptomonad Guillardia theta and the chlorarachniophyte Bigelowiella natans. In all three systems we find a high frequency of mRNA molecules that encode sequence from more than one gene. There is no bias for these genes to be on the same strand, so it is unlikely that these mRNAs represent operons. Instead, compaction appears to have reduced the intergenic regions to such an extent that control elements like promoters and terminators have been forced into or beyond adjacent genes, resulting in long untranslated regions that encode other genes. Normally, transcriptional overlap can interfere with expression of a gene, but these genomes cope with high frequencies of overlap and with termination signals within expressed genes. These findings also point to serious practical difficulties in studying expression in compacted genomes, because many techniques, such as arrays or serial analysis of gene expression will be misleading.

Transcriptional collision between convergent genes in budding yeast

Transcriptional interference between genes and the regulatory elements of simple eukaryotes such as Saccharomyces cerevisiae is an unavoidable consequence of their compressed genetic arrangement. We have shown previously that with the tandem arranged genes GAL10 and GAL7, inefficient transcriptional termination of the upstream gene inhibits initiation of transcription on the downstream gene. We now show that transcriptional interference can occur also with S. cerevisiae RNA polymerase II genes arranged convergently. We demonstrate that when the GAL10 and GAL7 genes are rearranged in a convergent orientation, transcriptional initiation occurs at full levels. However, as soon as the two transcripts begin to overlap, elongation is restricted, resulting in a severe reduction in steady-state mRNA accumulation. This effect is observed only in cis arrangement, arguing against RNA-interference effects acting on the potential generation of antisense transcripts. These data reinforce the necessity of separating adjacent RNA polymerase II transcription units by efficient termination signals.

Multiple factors prevent transcriptional interference at the yeast ARO4-HIS7 locus

Increased transcriptional activity may cause transcriptional interference in organisms with compact genomes such as the yeast Saccharomyces cerevisiae. Replacement of the yeast ARO4 promoter by the stronger ACT1 promoter increases ARO4 transcription and simultaneously reduces the basal transcription of the downstream HIS7 gene. The open reading frames of ARO4 and HIS7 are tandemly transcribed and are separated by 416 bp. In wild-type cells, a nuclease-resistant site suggests that the two genes are separated by a single positioned nucleosome. Transcriptional interference correlates with Micrococcus nuclease accessibility of this otherwise nuclease-resistant site. Deletion analyses of the region between the two open reading frames revealed that transcriptional interference increases upon removal of either parts of the ARO4 3' end or HIS7 promoter sequences. The abolishment of the Abf1p-binding site within the HIS7 promoter significantly enhances transcriptional interference, resulting in a histidine auxotrophic strain. Our data suggest that the yeast cell prevents transcriptional interference by the combined action of efficient ARO4 transcription termination, the positioning of a fixed nucleosome, and transcription factor binding to the HIS7 promoter.

Probabilistic prediction of Saccharomyces cerevisiae mRNA 3'-processing sites

We present a tool for the prediction of mRNA 3'-processing (cleavage and polyadenylation) sites in the yeast Saccharomyces cerevisiae, based on a discrete state-space model or hidden Markov model. Comparison of predicted sites with experimentally verified 3'-processing sites indicates good agreement. All predicted or known yeast genes were analyzed to find probable 3'-processing sites. Known alternative 3'-processing sites, both within the 3'-untranslated region and within the protein coding sequence were successfully identified, leading to the possibility of prediction of previously unknown alternative sites. The lack of an apparent 3'-processing site calls into question the validity of some predicted genes. This is specifically investigated for predicted genes with overlapping coding sequences.

Selection and orientation of adjacent genes influences DAM-mediated male sterility in transformed maize

Anther-targeted expression of E. coli DNA (Adenosine-N6-)-Methyltransferase (DAM) in maize was tested as a means to produce male-sterile plants. A high frequency of male-sterile plants with reduced anther size was observed when DAM was regulated by the maize anther-specific promoter 5126 (5126:DAM) and placed upstream of the herbicide resistance gene, pat, regulated by the cauliflower mosaic virus (CaMV) 35S promoter (35S:PAT). In contrast, placement of 5126:DAM upstream of a pat gene regulated by either the maize ubiquitin (UBI:PAT) or rice actin (rACTIN:PAT) promoters resulted in male-fertile plants. Based on these observed differences, DAM-mediated sterility was used as a phenotypic marker to assess the contribution of factors affecting gene expression such as orientation of the transcription units, choice of regulatory sequences mediating expression of adjacent genes, and effects of varying the anther-specific promoter regulating DAM. Constructs that place a portion of the CaMV 35S promoter, including the native AS-1 sequences, between 5126:DAM and UBI:PAT yielded a high frequency of male-sterile plants with reduced anther size. Significant differences in the frequency of male-sterile events and the associated anther size were also observed when the position of 35S:PAT was changed relative to 5126:DAM. These data provide evidence that gene expression in transformed maize plants can be impacted by simply altering the order, orientation or regulatory sequences of adjacent genes.

Characterization of the biotin biosynthesis pathway in Saccharomyces cerevisiae and evidence for a cluster containing BIO5, a novel gene involved in vitamer uptake

An engineered mutant of Saccharomyces cerevisiae affected in biotin biosynthesis has been isolated. This mutant allowed the characterization of a bio cluster (BIO3-4-5). We demonstrate that BIO3 (YNR058w) and BIO4 (YNR057c) encode, respectively, a 7, 8-diaminopelargonic acid aminotransferase and a dethiobiotin synthase, involved in the biotin biosynthesis pathway. A novel gene, BIO5 (YNR056c), is present immediately downstream from BIO4. This gene encodes Bio5p, a protein with 11 putative transmembrane regions. Uptake experiments performed with labeled 7-keto 8-aminopelargonic acid indicate that Bio5p is responsible for transport into the cell of 7-keto 8-aminopelargonic acid.

A mutation in GRS1, a glycyl-tRNA synthetase, affects 3'-end formation in Saccharomyces cerevisiae

3'-end formation is a complex and incompletely understood process involving both cis-acting and trans-acting factors. As part of an effort to examine the mechanisms of transcription termination by RNA polymerase II, a mutant hunt for strains defective in 3'-end formation was conducted. Following random mutagenesis, a temperature-sensitive strain exhibiting several phenotypes consistent with a role in transcription termination was isolated. First, readthrough of a terminator increases significantly in the mutant strain. Accordingly, RNA analysis indicates a decrease in the level of terminated transcripts, both in vivo and in vitro. Moreover, a plasmid stability assay in which high levels of readthrough lead to high levels of plasmid loss and transcription run-on analysis also demonstrate defective termination of transcription. Examination of polyadenylation and cleavage by the mutant strain indicates these processes are not affected. These results represent the first example of a transcription termination factor in Saccharomyces cerevisiae that affects transcription termination independent of 3'-end processing of mRNA. Complementation studies identified GRS1, an aminoacyl-tRNA synthetase, as the complementing gene. Sequence analysis of grs1-1 in the mutant strain revealed that nucleotides 1656 and 1657 were both C to T transitions, resulting in a single amino acid change of proline to phenylalanine. Further studies revealed GRS1 is essential, and the grs1-1 allele confers the temperature-sensitive growth defect associated with the mutant strain. Finally, we observed structures with some similarity to tRNA molecules within the 3'-end of various yeast genes. On the basis of our results, we suggest Grs1p is a transcription termination factor that may interact with the 3'-end of pre-mRNA to promote 3'-end formation.

The yeast FBP1 poly(A) signal functions in both orientations and overlaps with a gene promoter

This report provides an analysis of a region of chromosome XII in which the FBP1 and YLR376c genes transcribe in the same direction. Our investigation indicates that the Saccharomyces cerevisiae FBP1 gene contains strong signals for polyadenylation and transcription termination in both orientations in vivo . A (TA)14 element plays a major role in directing polyadenylation in both orientations. While this region has four nonoverlapping copies of a TATATA hexanucleotide, which is a very potent polyadenylation efficiency element in yeast, it alone is not sufficient for full activation in the reverse orientation of a cluster of downstream poly(A) sites, and an additional upstream sequence is required. The putative RNA hairpin formed from the (TA)14 element is not involved in 3'-end formation. Surprisingly, deletion of the entire (TA)14 stretch affects transcription termination in the reverse orientation, in contrast to our previous results with the forward orientation, indicating that the transcription termination element operating in the reverse orientation has very different sequence requirements. Promoter elements for the YLR376c gene overlap with the signal for FBP1 3'-end formation. To our knowledge, this is the first time that overlapping of both types of regulatory signals has been found in two adjacent yeast genes.

Poly(A) signals control both transcriptional termination and initiation between the tandem GAL10 and GAL7 genes of Saccharomyces cerevisiae

We have investigated transcriptional interactions between the GAL10 and GAL7 genes of Saccharomyces cerevisiae. Both genes are part of the galactose (GAL) gene cluster which is transcriptionally activated to high levels in the presence of galactose. Since GAL7 is positioned downstream of GAL10 and both genes are expressed co-ordinately at high levels, the possibility that GAL10 transcription influences GAL7 was analysed. Using transcriptional run-on assays, we show that high levels of polymerase are found in the 600 bp GAL10-7 intergenic region that accumulate over the GAL7 promoter. Furthermore, GAL7 transcription is enhanced when the GAL10 upstream activating sequence (UASG) is deleted, indicating that interference between GAL10 and GAL7 is likely to occur in the chromosomal locus. Deletions in the GAL10 poly(A) signal result in complete inactivation of the GAL7 promoter and cause a dramatic increase in bi-cistronic GAL10-7 mRNA, predominantly utilizing the downstream, GAL7 poly(A) site. These data demonstrate a pivotal role for the GAL10 poly(A) site in allowing the simultaneous expression of GAL10 and GAL7. In effect, this RNA processing signal has a direct influence on both transcriptional termination and initiation.