Isolation and characterization of the positive regulatory gene ADR1 from Saccharomyces cerevisiae

Transcription factors and ABC transporters: from pleiotropic drug resistance to cellular signaling in yeast

Budding yeast Saccharomyces cerevisiae survives in microenvironments utilizing networks of regulators and ATP-binding cassette (ABC) transporters to circumvent toxins and a variety of drugs. Our understanding of transcriptional regulation of ABC transporters in yeast is mainly derived from the study of multidrug resistance protein networks. Over the past two decades, this research has not only expanded the role of transcriptional regulators in pleiotropic drug resistance (PDR) but evolved to include the role that regulators play in cellular signaling and environmental adaptation. Inspection of the gene networks of the transcriptional regulators and characterization of the ABC transporters has clarified that they also contribute to environmental adaptation by controlling plasma membrane composition, toxic-metal sequestration, and oxidative stress adaptation. Additionally, ABC transporters and their regulators appear to be involved in cellular signaling for adaptation of S. cerevisiae populations to nutrient availability. In this review, we summarize the current understanding of the S. cerevisiae transcriptional regulatory networks and highlight recent work in other notable fungal organisms, underlining the expansion of the study of these gene networks across the kingdom fungi.

Quantitative Trait Nucleotides Impacting the Technological Performances of Industrial Saccharomyces cerevisiae Strains

The budding yeast Saccharomyces cerevisiae is certainly the prime industrial microorganism and is related to many biotechnological applications including food fermentations, biofuel production, green chemistry, and drug production. A noteworthy characteristic of this species is the existence of subgroups well adapted to specific processes with some individuals showing optimal technological traits. In the last 20 years, many studies have established a link between quantitative traits and single-nucleotide polymorphisms found in hundreds of genes. These natural variations constitute a pool of QTNs (quantitative trait nucleotides) that modulate yeast traits of economic interest for industry. By selecting a subset of genes functionally validated, a total of 284 QTNs were inventoried. Their distribution across pan and core genome and their frequency within the 1,011 Saccharomyces cerevisiae genomes were analyzed. We found that 150 of the 284 QTNs have a frequency lower than 5%, meaning that these variants would be undetectable by genome-wide association studies (GWAS). This analysis also suggests that most of the functional variants are private to a subpopulation, possibly due to their adaptive role to specific industrial environment. In this review, we provide a literature survey of their phenotypic impact and discuss the opportunities and the limits of their use for industrial strain selection.

MIG1 as a positive regulator for the histidine biosynthesis pathway and as a global regulator in thermotolerant yeast Kluyveromyces marxianus

Kmmig1 as a disrupted mutant of MIG1 encoding a regulator for glucose repression in Kluyveromyces marxianus exhibits a histidine-auxotrophic phenotype. Genome-wide expression analysis revealed that only HIS4 in seven HIS genes for histidine biosynthesis was down-regulated in Kmmig1. Consistently, introduction of HIS4 into Kmmig1 suppressed the requirement of histidine. Considering the fact that His4 catalyzes four of ten steps in histidine biosynthesis, K. marxianus has evolved a novel and effective regulation mechanism via Mig1 for the control of histidine biosynthesis. Moreover, RNA-Seq analysis revealed that there were more than 1,000 differentially expressed genes in Kmmig1, suggesting that Mig1 is directly or indirectly involved in the regulation of their expression as a global regulator.

Dynamic motif occupancy (DynaMO) analysis identifies transcription factors and their binding sites driving dynamic biological processes

Biological processes are usually associated with genome-wide remodeling of transcription driven by transcription factors (TFs). Identifying key TFs and their spatiotemporal binding patterns are indispensable to understanding how dynamic processes are programmed. However, most methods are designed to predict TF binding sites only. We present a computational method, dynamic motif occupancy analysis (DynaMO), to infer important TFs and their spatiotemporal binding activities in dynamic biological processes using chromatin profiling data from multiple biological conditions such as time-course histone modification ChIP-seq data. In the first step, DynaMO predicts TF binding sites with a random forests approach. Next and uniquely, DynaMO infers dynamic TF binding activities at predicted binding sites using their local chromatin profiles from multiple biological conditions. Another landmark of DynaMO is to identify key TFs in a dynamic process using a clustering and enrichment analysis of dynamic TF binding patterns. Application of DynaMO to the yeast ultradian cycle, mouse circadian clock and human neural differentiation exhibits its accuracy and versatility. We anticipate DynaMO will be generally useful for elucidating transcriptional programs in dynamic processes.

Genomic and transcriptomic analysis of Saccharomyces cerevisiae isolates with focus in succinic acid production

Succinic acid is a platform chemical that plays an important role as precursor for the synthesis of many valuable bio-based chemicals. Its microbial production from renewable resources has seen great developments, specially exploring the use of yeasts to overcome the limitations of using bacteria. The objective of the present work was to screen for succinate-producing isolates, using a yeast collection with different origins and characteristics. Four strains were chosen, two as promising succinic acid producers, in comparison with two low producers. Genome of these isolates was analysed, and differences were found mainly in genes SDH1, SDH3, MDH1 and the transcription factor HAP4, regarding the number of single nucleotide polymorphisms and the gene copy-number profile. Real-time PCR was used to study gene expression of 10 selected genes involved in the metabolic pathway of succinic acid production. Results show that for the non-producing strain, higher expression of genes SDH1, SDH2, ADH1, ADH3, IDH1 and HAP4 was detected, together with lower expression of ADR1 transcription factor, in comparison with the best producer strain. This is the first study showing the capacity of natural yeast isolates to produce high amounts of succinic acid, together with the understanding of the key factors associated, giving clues for strain improvement.

Characterization of the transcription factor encoding gene, KlADR1: metabolic role in Kluyveromyces lactis and expression in Saccharomyces cerevisiae

In Saccharomyces cerevisiae, Adr1 is a zinc-finger transcription factor involved in the transcriptional activation of ADH2. Deletion of KlADR1, its putative ortholog in Kluyveromyces lactis, led to reduced growth in glycerol, oleate and yeast extract-peptone medium suggesting, as in S. cerevisiae, its requirement for glycerol, fatty acid and nitrogen utilization. Moreover, growth comparison on yeast extract and peptone plates showed in K. lactis a KlAdr1-dependent growth trait not present in S. cerevisiae, indicating different metabolic roles of the two factors in their environmental niches. KlADR1 is required for growth under respiratory and fermentative conditions like KlADH, alcohol dehydrogenase genes necessary for metabolic adaptation during the growth transition. Using in-gel native alcohol dehydrogenase assay, we showed that this factor affected the Adh pattern by altering the balance between these activities. Since the activity most affected by KlAdr1 is KlAdh3, a deletion analysis of the KlADH3 promoter allowed the isolation of a DNA fragment through which KlAdr1 modulated its expression. The expression of the KlADR1-GFP gene allowed the intracellular localization of the factor in K. lactis and S. cerevisiae, suggesting in the two yeasts a common mechanism of KlAdr1 translocation under fermentative and respiratory conditions. Finally, the chimeric Kl/ScADR1 gene encoding the zinc-finger domains of KlAdr1 fused to the transactivating domains of the S. cerevisiae factor activated in Scadr1Δ the transcription of ADH2 in a ScAdr1-dependent fashion.

Investigation of protein secretion and secretion stress in Ashbya gossypii

Background

Ashbya gossypii is a filamentous Saccharomycete used for the industrial production of riboflavin that has been recently explored as a host system for recombinant protein production. To gain insight into the protein secretory pathway of this biotechnologically relevant fungus, we undertook genome-wide analyses to explore its secretome and its transcriptional responses to protein secretion stress.

Results

A computational pipeline was used to predict the inventory of proteins putatively secreted by A. gossypii via the general secretory pathway. The proteins actually secreted by this fungus into the supernatants of submerged cultures in minimal and rich medium were mapped by two-dimensional gel electrophoresis, revealing that most of the A. gossypii secreted proteins have an isoelectric point between 4 and 6, and a molecular mass above 25 kDa. These analyses together indicated that 1-4% of A. gossypii proteins are likely to be secreted, of which less than 33% are putative hydrolases. Furthermore, transcriptomic analyses carried out in A. gossypii cells under recombinant protein secretion conditions and dithiothreitol-induced secretion stress unexpectedly revealed that a conventional unfolded protein response (UPR) was not activated in any of the conditions, as the expression levels of several well-known UPR target genes (e.g. IRE1, KAR2, HAC1 and PDI1 homologs) remained unaffected. However, several other genes involved in protein unfolding, endoplasmatic reticulum-associated degradation, proteolysis, vesicle trafficking, vacuolar protein sorting, secretion and mRNA degradation were up-regulated by dithiothreitol-induced secretion stress. Conversely, the transcription of several genes encoding secretory proteins, such as components of the glycosylation pathway, was severely repressed by dithiothreitol

Conclusions

This study provides the first insights into the secretion stress response of A. gossypii, as well as a basic understanding of its protein secretion potential, which is more similar to that of yeast than to that of other filamentous fungi. Contrary to what has been widely described for yeast and fungi, a conventional UPR was not observed in A. gossypii, but alternative protein quality control mechanisms enabled it to cope with secretion stress. These data will help provide strategies for improving heterologous protein secretion in A. gossypii.

Electronic supplementary material

The online version of this article (doi:10.1186/1471-2164-15-1137) contains supplementary material, which is available to authorized users.

Phosphoproteomic analysis identifies proteins involved in transcription-coupled mRNA decay as targets of Snf1 signaling

Stresses, such as glucose depletion, activate Snf1, the Saccharomyces cerevisiae ortholog of adenosine monophosphate-activated protein kinase (AMPK), enabling adaptive cellular responses. In addition to affecting transcription, Snf1 may also promote mRNA stability in a gene-specific manner. To understand Snf1-mediated signaling, we used quantitative mass spectrometry to identify proteins that were phosphorylated in a Snf1-dependent manner. We identified 210 Snf1-dependent phosphopeptides in 145 proteins. Thirteen of these proteins are involved in mRNA metabolism. Of these, we found that Ccr4 (the major cytoplasmic deadenylase), Dhh1 (an RNA helicase), and Xrn1 (an exoribonuclease) were required for the glucose-induced decay of Snf1-dependent mRNAs that were activated by glucose depletion. Unexpectedly, deletion of XRN1 reduced the accumulation of Snf1-dependent transcripts that were synthesized during glucose depletion. Deletion of SNF1 rescued the synthetic lethality of simultaneous deletion of XRN1 and REG1, which encodes a regulatory subunit of a phosphatase that inhibits Snf1. Mutation of three Snf1-dependent phosphorylation sites in Xrn1 reduced glucose-induced mRNA decay. Thus, Xrn1 is required for Snf1-dependent mRNA homeostasis in response to nutrient availability.

Accelerated alcoholic fermentation caused by defective gene expression related to glucose derepression in Saccharomyces cerevisiae

Sake yeast strains maintain high fermentation rates, even after the stationary growth phase begins. To determine the molecular mechanisms underlying this advantageous brewing property, we compared the gene expression profiles of sake and laboratory yeast strains of Saccharomyces cerevisiae during the stationary growth phase. DNA microarray analysis revealed that the sake yeast strain examined had defects in expression of the genes related to glucose derepression mediated by transcription factors Adr1p and Cat8p. Furthermore, deletion of the ADR1 and CAT8 genes slightly but statistically significantly improved the fermentation rate of a laboratory yeast strain. We also identified two loss-of-function mutations in the ADR1 gene of existing sake yeast strains. Taken together, these results indicate that the gene expression program associated with glucose derepression for yeast acts as an impediment to effective alcoholic fermentation under glucose-rich fermentative conditions.

The effect of scale on gene expression: commercial versus laboratory wine fermentations

Molecular and cellular processes that are responsible for industrially relevant phenotypes of fermenting microorganisms are a central focus of biotechnological research. Such research intends to generate insights and solutions for fermentation-based industries with regards to issues such as improving product yield or the quality of the final fermentation product. For logistical reasons, and to ensure data reproducibility, such research is mostly carried out in defined or synthetic media and in small-scale fermentation vessels. Two questions are frequently raised regarding the applicability of this approach to solve problems experienced in industrial fermentations: (1) Is synthetic medium a sufficiently accurate approximation of the generally more complex natural (and frequently highly variable) substrates that are employed in most fermentation-based industries, and (2) can results obtained in small-scale laboratory fermentations be extrapolated to large-scale industrial environments? Here, we address the second question through a comparative transcriptomic approach by assessing the response of an industrial wine yeast strain fermenting a natural grape juice in small-scale laboratory and large-scale industrial conditions. In yeast, transcriptome analysis is arguably the best available tool to holistically assess the physiological state of a population and its response to changing environmental conditions. The data suggest that scale does indeed impact on some environmental parameters such as oxygen availability. However, the data show that small-scale fermentations nevertheless accurately reflect general molecular processes and adaptations during large-scale fermentation and that extrapolation of laboratory datasets to real industrial processes can be justified.

Effect of rad50 mutation on illegitimate recombination in Saccharomyces cerevisiae

Genes in the RAD52 epistasis group are involved in repairing DNA double-stranded breaks via homologous recombination. We have previously shown that RAD50 is involved in mitotic nonhomologous integration but not in homologous integration. However, the role of Rad50 in nonhomologous integration has not previously been examined. In the current work, we report that the rad50∆ mutation caused a tenfold decrease in the frequency of nonhomologous integration with the majority of nonhomologous integrants showing an unstable Ura(+) phenotype. Sequencing analysis of the integration target sites showed that integration events of both ends of the integrating vector in the rad50∆ mutant occurred at different chromosomal locations, resulting in large deletions or translocations on the genomic insertion sites. Interestingly, 47% of events in the rad50∆ mutant were integrated into repetitive sequences including rDNA locus, telomeres and Ty elements and 27% of events were integrated into non-repetitive sequences as compared to 11% of events integrated into rDNA and 70% into non-repetitive sequences in the wild-type cells. These results showed that deletion of RAD50 significantly changes the distribution of different classes of integration events, suggesting that Rad50 is required for nonhomologous integration at non-repetitive sequences more so than at repetitive ones. Furthermore, Southern analysis indicated that half of the events contained deletions at one or at both ends of the integrating DNA fragment, suggesting that Rad50 might have a role in protecting free ends of double-strand breaks. In contrast to the rad50∆ mutant, the rad50S mutant (separation of function allele) slightly increases the frequency of nonhomologous integration but the distribution of integration events is similar to that of wild-type cells with the majority of events integrated into a chromosomal locus. Our results suggest that deletion of RAD50 may block the major pathway of nonhomologous integration into a non-repetitive chromosomal locus and Rad50 may be involved in tethering two ends of the integrating DNA into close proximity that facilitates nonhomologous integration of both ends into a single chromosomal locus.

Molecular genetics of 6-phosphofructokinase in Pichia pastoris

Previously, studies on glucose-induced microautophagy in the methylotrophic yeast Pichia pastoris provided evidence that the glucose-induced selective autophagy-1-protein is the alpha-subunit of 6-phosphofructokinase (Pfk), a key enzyme in the glycolytic pathway. In our work, we could clearly demonstrate that two types of subunits of Pfk exist in P. pastoris. Investigating the yeast cell-free extract by Western blot analysis, two distinct signals of Pfk were obtained. In addition, we isolated a DNA sequence containing the complete ORF of PpPFK2 encoding the beta-subunit of Pfk from P. pastoris with a deduced molecular mass of 103.7 kDa. On the basis of these results, a hetero-oligomeric structure of Pfk in P. pastoris became obvious. Because the molecular and kinetic properties of a homo-oligomeric yeast Pfk appear to be more similar to those of mammalian Pfk, as described in the literature, our results are of interest for the growing number of studies on P. pastoris as a heterologous production system. Furthermore, the 3'- and 5'-non-coding regions of PpPFK2 were isolated and several putative binding sites for regulatory factors could be identified in the promoter region.

In vivo changes of nucleosome positioning in the pretranscription state

The involvement of chromatin structure and organization in transcriptional regulatory pathways has become evident. One unsolved question concerns the molecular mechanisms of chromatin remodeling during in vivo promoter activation. By using a high resolution in vivo analysis we show that when yeast cells are exposed to a regulatory signal the positions of specific nucleosomes change. The system analyzed consists of the basic elements of the Saccharomyces cerevisiae ADH2 promoter, two nucleosomes of which are shown to change the distribution of their positions by few nucleotides in the direction of transcription when the glucose content of the medium is lowered. Such repositioning does not occur in the absence of the ADH2 transcriptional activator Adr1 or in the presence of its DNA-binding domain alone. A construct consisting of the DNA-binding domain plus a 43-amino acid peptide containing the Adr1 activation domain is sufficient to induce the same effect of the full-length protein. Nucleosome repositioning occurs even when the catalytic activity of the RNA polymerase II is impaired, suggesting that the Adr1 activation domain mediates the recruitment of some factor to correctly preset the relevant sequences for the subsequent transcription steps.

A mutation in the yeast mitochondrial ribosomal protein Rml2p is associated with a defect in catalase gene expression

Yeast strains containing a new temperature-sensitive allele of the RML2 gene, encoding a component of the large subunit of the mitochondrial ribosome, display normal growth on acetate, slowed growth on glycerol and an inability to grow on oleic acid. These cells, denoted rml2(fat21), have an apparent inability to induce peroxisomal function, as evidenced by a deficiency in oleic acid induction of beta-oxidation. However, the oleic acid regulation of genes encoding core enzymes of peroxisomal beta-oxidation is normal. In contrast, up-regulation of CTA1 (catalase) mRNA expression and enzyme activity is interrupted. Upon comparison of the induction requirements of catalase and the genes of beta-oxidation, we hypothesized that the rml2(fat21) mutation alters the activity of the transcription factor Adr1p. In support of this hypothesis, over-expression of ADR1 in rml2(fat21) cells restores CTA1 induction. Several assays of mitochondria from rml2(fat21) strains suggest normal mitochondrial function. Thus, the modulation of Adr1p-associated gene regulation is not due to overt mitochondrial dysfunction.

A novel hemiacetal dehydrogenase activity involved in ethyl acetate synthesis in Candida utilis

Acetate ester synthesis was studied in vitro with the ethyl acetate-producing yeast Candida utilis. The level of enzyme activity observed for the NAD+-dependent hemiacetal dehydrogenase acting on hemiacetal, which was produced non-enzymatically from an alcohol and an aldehyde, was much greater than that for the other enzyme involved in ester synthesis, alcohol acetyltransferase. The level of ethyl acetate synthesis in vivo approximately paralleled the hemiacetal dehydrogenase (HADH) activity. The results suggest that the main pathway for ethyl acetate synthesis in C. utilis involves a novel hemiacetal dehydrogenase activity.

Factors affecting Saccharomyces cerevisiae ADH2 chromatin remodeling and transcription

The chromatin structure of the Saccharomyces cerevisiae ADH2 gene is modified during the switch from repressing (high glucose) to derepressing (low glucose) conditions of growth. Loss of protection toward micrococcal nuclease cleavage for the nucleosomes covering the TATA box and the RNA initiation sites (-1 and +1, respectively) is the major modification taking place and is strictly dependent on the presence of the transcriptional activator ADR1. To identify separate functions involved in the transition from a repressed to a transcribing promoter, we have analyzed the ADH2 chromatin organization in various genetic backgrounds. Deletion of the CCR4 gene coding for a general transcription factor impaired ADH2 expression without affecting chromatin remodeling. Growing yeast at 37 degrees C also resulted in chromatin remodeling at the ADH2 locus even under glucose repressing conditions. However, although this temperature-induced remodeling was dependent on the ADR1 protein, no ADH2 mRNA was observed. In addition, inactivating RNA polymerase II (and therefore, elongation) was found to have no effect on the ability to reconfigure nucleosomes. Taken together, these data indicate that chromatin remodeling by itself is insufficient to induce transcription at the ADH2 promoter.

NMR chemical shift perturbation mapping of DNA binding by a zinc-finger domain from the yeast transcription factor ADR1

Mutagenesis studies have revealed that the minimal DNA-binding domain of the yeast transcription factor ADR1 consists of two Cys2-His2 zinc fingers plus an additional 20 residues proximal and N-terminal to the fingers. We have assigned NMR 1H, 15N, and 13C chemical shifts for the entire minimal DNA-binding domain of ADR1 both free and bound to specific DNA. 1H chemical shift values suggest little structural difference between the zinc fingers in this construct and in single-finger constructs, and 13C alpha chemical shift index analysis indicates little change in finger structure upon DNA binding. 1H chemical shift perturbations upon DNA binding are observed, however, and these are mapped to define the protein-DNA interface. The two zinc fingers appear to bind DNA with different orientations, as the entire helix of finger 1 is perturbed, while only the extreme N-terminus of the finger 2 helix is affected. Furthermore, residues N-terminal to the first finger undergo large chemical shift changes upon DNA binding suggesting a role at the protein-DNA interface. A striking correspondence is observed between the protein-DNA interface mapped by chemical shift changes and that previously mapped by mutagenesis.

ADR1 activation domains contact the histone acetyltransferase GCN5 and the core transcriptional factor TFIIB

The yeast transcriptional activator ADR1, which is required for ADH2 and peroxisomal gene expression, contains four separable and partially redundant activation domains (TADs). Mutations in ADA2 or GCN5, encoding components of the ADA coactivator complex involved in histone acetylation, severely reduced LexA-ADR1-TAD activation of a LexA-lacZ reporter gene. Similarly, the ability of the wild-type ADR1 gene to activate an ADH2-driven promoter was compromised in strains deleted for ADA2 or GCN5. In contrast, defects in other general transcription cofactors such as CCR4, CAF1/POP2, and SNF/SWI displayed much less or no effect on LexA-ADR1-TAD activation. Using an in vitro protein binding assay, ADA2 and GCN5 were found to specifically contact individual ADR1 TADs. ADA2 could bind TAD II, and GCN5 physically interacted with all four TADs. Both TADs I and IV were also shown to make specific contacts to the C-terminal segment of TFIIB. In contrast, no significant binding to TBP was observed. TAD IV deletion analysis indicated that its ability to bind GCN5 and TFIIB was directly correlated with its ability to activate transcription in vivo. ADR1 TADs appear to make several contacts, which may help explain both their partial redundancy and their varying requirements at different promoters. The contact to and dependence on GCN5, a histone acetyltransferase, suggests that rearrangement of nucleosomes may be one important means by which ADR1 activates transcription.

Respiration and low cAMP-dependent protein kinase activity are required for high-level expression of the peroxisomal thiolase gene in Saccharomyces cerevisiae

Transcription of genes for peroxisomal proteins is repressed by glucose and induced by oleate. At least for the peroxisomal thiolase gene (POT1) there is a third regulatory mechanism, mediated by the transcription factor Adr1p, which is responsible for the high-level expression of the gene in stationary phase. Here we show that a region in the POT1 promoter that extends from positions -238 to -152 mediates this mechanism, and we suggest that Adr1p acts indirectly on POT1. We have also analyzed the role of the cAMP-dependent protein kinase (PKA) in the transcriptional regulation of POT1. PKA exerts a negative control: the high, unregulated PKA activity in a bcy1 mutant maintains POT1 transcription at the repressed level. In a ras2 mutant, which has low PKA activity, glucose repression is not alleviated but in non-repressing conditions POT1 regulation is perturbed and expression prematurely increases during exponential phase. This suggests that the PKA signalling pathway controls the regulation of POT1 in stationary phase. Finally, we have found that Adr1p-dependent expression in stationary phase and induction by oleate are both abolished when respiration is blocked. Utilization of fatty acids as carbon source requires respiration. Our result points to the existence of mechanisms that co-ordinate the level of expression of thiolase and the functional state of the mitochondria.

Conserved regulation of the Hansenula polymorpha MOX promoter in Saccharomyces cerevisiae reveals insights in the transcriptional activation by Adr1p

The Hansenula polymorpha MOX gene encodes a peroxisomal enzyme that catalyzes the first step of the highly specialized methanol metabolism. MOX is strongly transcribed in cells growing in methanol and completely repressed in glucose. We show here that the MOX promoter confers a glucose-repressible expression upon a lacZ reporter gene in Saccharomyces cerevisiae, an unrelated yeast species that lacks the methanol metabolism. Repression was mediated by a 200-bp region of the MOX promoter, termed MOX-B, and was counteracted by Adr1p, a transcription factor involved in the derepression of S. cerevisiae genes encoding peroxisomal proteins, the class to which MOX belongs. Binding of Adr1p to MOX-B was demonstrated by gel retardation and DNaseI-footprinting, and Adr1p was shown to interact with a DNA region containing only a half of the putative Adr1p consensus binding site. Our findings suggest that Adr1p is a conserved regulator for genes encoding peroxisomal proteins at least in other yeast species, and that its interaction with the DNA is dependent on the promoter context.

Expression of genes encoding peroxisomal proteins in Saccharomyces cerevisiae is regulated by different circuits of transcriptional control

In Saccharomyces cerevisiae induction of the FOX3 gene, encoding peroxisomal 3-oxoacyl-CoA thiolase, by growth on oleate as sole carbon source, is exerted via the cis-acting DNA element designated oleate response element (ORE) (Einerhand et al. (1991) Eur. J. Biochem. 200, 113-122). The transcription factor(s) binding to this upstream activation site (UAS) are still unknown, however. Induction of another peroxisomal enzyme, citrate synthase (CIT2) is dependent on the products of two genes called RTG1 and RTG2 (Liao and Butow (1993) Cell 72, 61-71). In the present study we have investigated whether RTG1 controls other genes coding for peroxisomal proteins, and whether such control takes place via the ORE. A number of genes coding for a variety of peroxisomal proteins such as: thiolase and catalase (peroxisomal matrix proteins), PAS3p (a peroxisomal membrane protein) and PAS10p (a protein involved in the import of peroxisomal proteins) were studied in their response to RTG1. Although the RTG1 and 2 products proved to be required for the increase in number and volume of peroxisomes upon induction by oleate, the single promoter output of the chosen set of genes remained practically unchanged in a rtg1 mutant strain. In addition gel retardation experiments indicated that RTG1 does not bind to the ORE. The behavior of genes coding for the various proteins also varied during repression, derepression and induction, indicating that probably a number of proteins are involved in tuning the output of each gene to cellular demand.

Expression of the FOX1 gene of Saccharomyces cerevisiae is regulated by carbon source, but not by the known glucose repression genes

We have investigated the regulation of expression of the FOX1 gene of Saccharomyces cerevisiae which encodes acyl-CoA oxidase, the first enzyme in the peroxisomal beta oxidation of fatty acids. We have found that the FOX1 steady state mRNA level is repressed by glucose, partially induced by ethanol (but not by raffinose) and fully induced by oleic acid as a carbon source. Glucose repression was observed even if cultures were grown to stationary phase; however, if the glucose supply was limited initially then partial induction of FOX1 mRNA occurred upon growth to high cell density. A variety of mutants are known to affect the glucose repression of many genes, including the FOX3 gene which encodes the thiolase activity in peroxisomal beta oxidation. However, upon examination none of these mutants showed de-repression of FOX1 expression. Similarly we investigated the role of two inducers of genes encoding peroxisomal enzymes (namely SNF1 and ADR1). No evidence was found to suggest that either of these plays a significant role in the induction of FOX1 mRNA levels. These observations indicate that the regulation of FOX1 is under the control of as yet unidentified genes involved in catabolite repression and suggest that the regulatory circuit influencing acyl CoA oxidase activity, and hence beta oxidation and peroxisome function, is significantly different than that which might have been assumed from other studies.

Designing zinc-finger ADR1 mutants with altered specificity of DNA binding to T in UAS1 sequences

Yeast ADR1 contains two Cys2,His2 zinc fingers needed for DNA binding to the upstream activation sequence UAS1, with bases T5T6G7-G8A9G10 in the ADH2 promoter. Potential DNA-contacting amino acid residues at -1, +3, and +6 in the alpha-helical domains of ADR1's fingers one and two include RHR-RLR; however, the latter finger two residues Leu146 and Arg149 had not proved to be crucial for ADR1 binding, even though Leu146-T6 and Arg149-T5 interactions with UAS1 DNA were predicted. We altered Leu146 or Arg149 by PCR cassette mutagenesis, to study ADR1 mutant binding to 16 UAS1 variants of thymine bases T5 and T6. Mutation of Leu146 to His, making finger two (RLR) like finger one (RHR), decreased binding to wild type UAS1 having T6, but enhanced its binding strength to sequences having purines G6 or A6, similar to binding seen between finger one's His118 and base A9 of UAS1. Mutating Leu146 to Lys caused this finger two RKR mutant to bind strongly to both G6 and T6, possibly by lysine's amine H-bonding to the carbonyl of guanine or thymine. Specificity of ADR1 for UAS1 with T6 may thus be due to hydrophobic interaction between Leu146 and the T6 methyl group. ADR1 mutants with either His or Lys in the central +3 residue (146) of zinc finger two, which have Arg149 in the +6 alpha-helical position, bind with UAS1 mutant sequences having G5 very strongly, T5 strongly, A5 intermediately, and C5 weakly.(ABSTRACT TRUNCATED AT 250 WORDS)

Use of the yeast two-hybrid system for identifying the cascade of protein interactions resulting in apoptotic cell death

Use of the yeast two-hybrid system allows rapid identification of interacting protein or proteins for a specific target protein. The technique is readily applied and allows immediate isolation of a cDNA encoding the interacting protein. One consideration might be to outline criteria for continued study of the interactors once they are identified. Our criterion for further study of an interactor is its presence in the mammary gland at a developmental time when the target protein is also present. Further characterization of interactors may involve immunoprecipitation, enzyme assays, or other techniques applicable to the specific protein.

The positive and negative cis-acting elements for methanol regulation in the Pichia pastoris AOX2 gene

The methylotrophic yeast Pichia pastoris has two alcohol oxidase genes, AOX1 and AOX2. The AOX2 gene is transcribed at a much lower level than the AOX1 gene. Apart from this difference in expression levels, the two genes are regulated similarly. To study the role of cis-acting elements in the promoter region of the AOX2 gene, we constructed expression plasmids in which the human serum albumin (HSA) gene was placed under the control of various deleted or mutated AOX2 promoter derivatives. By analyzing the expression of HSA in P. pastoris transformants, we have identified three cis-acting regulatory elements in the AOX2 promoter. The positive cis-acting element AOX2-UAS, located between positions -337 and -313 (relative to the transcription initiation codon), is required for response to transcriptional induction by methanol in an orientation-independent manner, and artificial amplification of the AOX2-UAS resulted in an increase in the transcriptional activity of the promoter. A sequence homologous to AOX2-UAS was also found in the AOX1 promoter, and in methanol-regulated promoters in other methylotrophic yeast. Two negative cis-acting elements, AOX2-URS1 and AOX2-URS2 play a role in repressing transcription from the AOX2 promoter. The function of AOX2-UAS is completely repressed by this unique repression system when both the AOX2-URS1 and AOX2-URS2 are functional.

Structure of a histidine-X4-histidine zinc finger domain: insights into ADR1-UAS1 protein-DNA recognition

The solution structure for a mutant zinc finger peptide based on the sequence of the C-terminal ADR1 finger has been determined by two-dimensional NMR spectroscopy. The mutant peptide, called PAPA, has both proline residues from the wild-type sequence replaced with alanines. A nonessential cysteine was also replaced with alanine. The behavior of PAPA in solution implicates the prolines in the conformational heterogeneity reported earlier for the wild-type peptide [Xu, R. X., Horvath, S. J., & Klevit, R. E. (1991) Biochemistry 30, 3365-3371]. The solution structure of PAPA reveals several interesting features of the zinc finger motif. The residue immediately following the second cysteine ligand adopts a positive phi angle, which we propose is a common feature of this class of zinc fingers, regardless of whether this residue is a glycine. The NMR spectrum and resulting solution structure of PAPA suggest that a side-chain to side-chain hydrogen bond involving an arginine and an aspartic acid analogous to one observed in the Zif268 protein-DNA cocrystal structure exists in solution in the absence of DNA [Pavletich, N. P., & Pabo, C. O. (1991) Science 252, 809-817]. A model for the interaction between the two ADR1 zinc fingers and their DNA binding sites was built by superpositioning the refined solution structures of PAPA and ADR1b onto the Zif268 structure. This model offers structural explanations for a variety of mutations to the ADR1 zinc finger domains that have been shown to affect DNA-binding affinity or specificity.

Identification of sequences responsible for transcriptional regulation of the strongly expressed methanol oxidase-encoding gene in Hansenula polymorpha

The methylotrophic yeasts have been the subject of intensive studies, because of their highly regulated methanol metabolism and the biogenesis of peroxisomes. We investigated the 5' regulatory region of the MOX gene from the yeast, Hansenula polymorpha, encoding the peroxisomal methanol oxidase, the key enzyme of methanol metabolism. This tightly regulated yeast promoter of approximately 1.5 kb is unusually large, and also of remarkable strength under inducing conditions, belonging to the strongest yeast promoters yet described. Deletion analyses revealed a complex promoter structure composed of several sequence elements with positive and negative regulatory effects on reporter gene expression and a pronounced cooperation between the elements. Specific binding of several factors was detected in vitro by gel retardation and DNase I footprinting experiments. On the basis of deletion data, two binding sites could be identified as upstream activation sequences (UAS1 and UAS2) and one binding site as an upstream repressing sequence (URS1).

Structures of DNA-binding mutant zinc finger domains: implications for DNA binding

Studies of Cys2-His2 zinc finger domains have revealed that the structures of individual finger domains in solution determined by NMR spectroscopy are strikingly similar to the structure of fingers bound to DNA determined by X-ray diffraction. Therefore, detailed structural analyses of single finger domains that contain amino acid substitutions known to affect DNA binding in the whole protein can yield information concerning the structural ramifications of such mutations. We have used this approach to study two mutants in the N-terminal finger domain of ADR1, a yeast transcription factor that contains two Cys2-His2 zinc finger sequences spanning residues 102-159. Two point mutants at position 118 in the N-terminal zinc finger (ADR1b: 102-130) that adversely affect the DNA-binding activity of ADR1 have previously been identified: H118A and H118Y. The structures of wild-type ADR1b and the two mutant zinc finger domains were determined using two-dimensional nuclear magnetic resonance spectroscopy and distance geometry and were refined using a complete relaxation matrix method approach (REPENT) to improve agreement between the models and the nuclear Overhauser effect spectroscopy data from which they were generated. The molecular architecture of the refined wild-type ADR1b domain is presented in detail. Comparisons of wild-type ADR1b and the two mutants revealed that neither mutation causes a significant structural perturbation. The structures indicate that the DNA binding properties of the His 118 mutants are dependent on the identity of the side chain at position 118, which has been postulated to make a direct DNA contact in the wild-type ADR1 protein. The results suggest that the identity of the side chain at the middle DNA contact position in Cys2-His2 zinc fingers may be changed with impunity regarding the domain structure and can affect the affinity of the protein-DNA interaction.

Phenotypic identification of amplifications of the ADH4 and CUP1 genes of Saccharomyces cerevisiae

Primary gene amplification, i.e., mutation from one gene copy to multiple gene copies per genome, is important in genomic evolution, as a means of producing anti-cancer drug resistance, and is associated with the progression of tumor malignancy. Primary amplification has not been studied in normal eukaryotic cells because amplifications are extremely rare in these cells. A system has been developed to phenotypically identify co-amplifications of the ADH4 and CUP1 genes of Saccharomyces cerevisiae and 21 independent spontaneous amplifications have been isolated.

Identification of three genes required for the glucose-dependent transcription of the yeast transcriptional activator ADR1

Glucose repression of the ADH2 gene from Saccharomyces cerevisiae is mediated by the synthesis and activity of the transcriptional activator ADR1. In this study, we isolated mutations in three new genes (SAF1, SAF2 and SAF3) that suppressed the glucose-insensitive expression of ADH2 caused by the ADR1-5c allele. The mechanism by which the SAF genes maintain ADR1-5c function was investigated. Each of the mutated SAF genes was found to suppress ADR1-5c activity by lowering ADR1-5c steady state mRNA levels 5- to 8-fold under glucose growth conditions. ADR1 mRNA levels were similarly affected by the saf mutations. In contrast, mutations in the SAF genes had little or no effect on ADR1-5c or ADR1 mRNA levels under ethanol growth conditions. The stability of ADR1-5c mRNA was unaffected by mutations in each of the SAF genes, implying that the SAF genes are required for the transcription of ADR1 mRNA under glucose growth conditions. The possible function of the three SAF genes in ADR1 expression is discussed.

The CCR4 protein from Saccharomyces cerevisiae contains a leucine-rich repeat region which is required for its control of ADH2 gene expression

The CCR4 gene from Saccharomyces cerevisiae is required for the transcription of the glucose-repressible alcohol dehydrogenase (ADH2). Mutations in CCR4 also suppress the transcription at the ADH2 and his4-912delta loci caused by defects in the SPT10 (CRE1) and SPT6 (CRE2) genes. The CCR4 gene was mapped to the left arm of chromosome I and cloned by complementation of function using previously isolated segments of chromosome I. DNA sequence analysis of the cloned gene defined CCR4 as a 2511 bp open reading frame that would encode a polypeptide of 837 amino acids. The CCR4 mRNA was found to be 2.8 kb in size and Western analysis identified CCR4 as a 95,000 D protein. Disruption of the CCR4 gene resulted in reduced levels of ADH2 expression under both glucose and ethanol growth conditions and in temperature sensitive growth on nonfermentative medium, phenotypes essentially indistinguishable from previously identified mutations in CCR4. The amino terminus of the CCR4 protein was found to be rich in glutamine residues similar to a number of genes which are required for transcription. More importantly, CCR4 showed similarity to a diverse set of proteins sharing a leucine-rich tandem repeat motif, the presence of which has been implicated in mediating protein-protein interactions. Deletions of several of the five leucine-rich repeats in CCR4 were shown to produce nonfunctional proteins indicating the importance of the repeats to CCR4 activity. This leucine-rich repeat region may mediate the contact CCR4 makes with another factor.

Identification and characterization of three genes that affect expression of ADH2 in Saccharomyces cerevisiae

Using a new selection protocol we have identified and preliminarily characterized three new loci (ADR7, ADR8 and ADR9) which affect ADH2 (alcohol dehydrogenase isozyme II) expression. Mutants were selected which activate ADH2 expression in the presence of an over-expressed, normally inactive ADR1 allele. The mutants had very similar phenotypes with the exception that one was temperature sensitive for growth. In the absence of any ADR1 allele, the mutants allowed ADH2 to partially escape glucose repression. However, unlike wildtype strains deleted for ADR1, the mutants were able to efficiently derepress ADH2. The mutations allowed a small escape from glucose repression for secreted invertase, but had no effect on the glucose repression of isocitrate lyase or malate dehydrogenase. The mutations were shown to be nonallelic to a wide variety of previously characterized mutations, including mutations that affect other glucose-repressed enzymes.

Peroxisome biogenesis in Saccharomyces cerevisiae

The observation that peroxisomes of Saccharomyces cerevisiae can be induced by oleic acid has opened the possibility to investigate the biogenesis of these organelles in a biochemically and genetically well characterized organism. Only few enzymes have been identified as peroxisomal proteins in Saccharomyces cerevisiae so far; the three enzymes involved in beta-oxidation of fatty acids, enzymes of the glyoxylate cycle, catalase A and the PAS3 gene product have been unequivocally assigned to the peroxisomal compartment. However, more proteins are expected to be constituents of the peroxisomes in Saccharomyces cerevisiae. Mutagenesis of Saccharomyces cerevisiae cells gave rise to mutants unable to use oleic acid as sole carbon source. These mutants could be divided in two groups: those with defects in structural genes of beta-oxidation enzymes (fox-mutants) and those with defects in peroxisomal assembly (pas-mutants). All fox-mutants possess morphologically normal peroxisomes and can be assigned to one of three complementation groups (FOX1, 2, 3). All three FOX genes have been cloned and characterized. The pas-mutants isolated are distributed among 13 complementation groups and represent 3 different classes: peroxisomes are either morphologically not detectable (type I) or present but non-proliferating (type II). Mislocalization concerns all peroxisomal proteins in cells of these two classes. The third class of mutants contains peroxisomes normal in size and number, however, distinct peroxisomal matrix proteins are mislocalized (type III). Five additional complementation groups were found in the laboratory of H.F. Tabak. Not all PAS genes have been cloned and characterized so far, and only for few of them the function could be deduced from sequence comparisons. Proliferation of microbodies is repressed by glucose, derepressed by non-fermentable carbon sources and fully induced by oleic acid. The regulation of four genes encoding peroxisomal proteins (PAS1, CTA1, FOX2, FOX3) occurs on the transcriptional level and reflects the morphological observations: repression by glucose and induction by oleic acid. Moreover, trans-acting factors like ADR1, SNF1 and SNF4, all involved in derepression of various cellular processes, have been demonstrated to affect transcriptional regulation of genes encoding peroxisomal proteins. The peroxisomal import machinery seems to be conserved between different organisms as indicated by import of heterologous proteins into microbodies of different host cells. In addition, many peroxisomal proteins contain C-terminal targeting signals. However, more than one import route into peroxisomes does exist.(ABSTRACT TRUNCATED AT 400 WORDS)

The POT1 gene for yeast peroxisomal thiolase is subject to three different mechanisms of regulation

The Saccharomyces cerevisiae POT1 gene is, as are other yeast peroxisomal protein genes, inducible by fatty acids and repressible by glucose. We have now found that it is also induced during the stationary phase of the culture. To investigate these three regulatory circuits, we have studied the mRNA levels of regulatory mutants as well as the changes in chromatin structure upon gene activation. We conclude that the regulation of transcriptional activity in glucose repression, oleate induction, and stationary phase induction follow different molecular mechanisms. We suggest that this multiplicity of regulatory mechanisms may represent a general rule for the yeast peroxisomal protein genes.

Evolution of the alcohol dehydrogenase (ADH) genes in yeast: characterization of a fourth ADH in Kluyveromyces lactis

Three alcohol dehydrogenase (ADH) genes have recently been characterized in the yeast Kluyveromyces lactis. We report on a fourth ADH in K. lactis (KADH II: KADH2* gene) which is highly similar to other ADHs in K. lactis and Saccharomyces cerevisiae. KADH II appears to be a cytoplasmic enzyme, and after expression of KADH2 in S. cerevisiae enzyme activity comigrated with a K. lactis ADH present in cells grown in glucose or in ethanol. KADH I was also expressed in S. cerevisiae and it comigrated with a major ADH species expressed under glucose growth conditions in K. lactis. The substrate specificities for KADH I and KADH II were shown to be more similar to that of SADH II than to SADH I. SADH I cannot efficiently utilize long chain alcohols, in contrast to other cytoplasmic yeast ADHs, presumably because of the presence of a methionine (residue 271) in its substrate binding cleft. A comparison of the DNA sequences of ADHs among K. lactis, S. cerevisiae and Schizosaccharomyces pombe suggests that the ancestral yeast species contained one cytoplasmic ADH. After divergence from S. pombe, the ADH in the ancestor to K. lactis and S. cerevisiae was duplicated, and one ADH became localized to the mitochondrion, presumably for the oxidative use of ethanol. Following the speciation of S. cerevisiae and K. lactis, the gene encoding the cytoplasmic ADH in S. cerevisiae duplicated, which resulted in the development of the SADH II protein as the primary oxidative enzyme in place of SADH III. In contrast, the K. lactis mitochondrial ADH duplicated to give rise to the highly expressed KADH3 and KADH4 genes, both of which may still play primary roles in oxidative metabolism. These data suggest that K. lactis and S. cerevisiae use different compartments for their metabolism of ethanol. Our results also indicate that the complex regulatory circuits controlling the glucose-repressible SADH2 in S. cerevisiae are a recent acquisition from regulatory networks used for the control of genes other than SADH2.

Mitotic hyperploidy for chromosomes VIII and III in Saccharomyces cerevisiae

The arg4-8 and cup1s markers comprise a copy-number-dependent signal device in the yeast Saccharomyces cerevisiae. These alleles permit reliable discrimination between euploid and disomic haploids as well as between euploid and trisomic diploids. To investigate and compare inherent inter-chromosomal differences as regards propensity for hyperploidy, we transplaced arg4-8 and cup1s by deleting them from chromosome VIII and then re-introducing them at the leu2 locus on chromosome III. The rate of chromosome gain was significantly greater for the chromosome III construct compared to the native chromosome VIII, in both diploid and haploid strains. In addition, more coincident aneuploidy for other chromosomes was found among chromosome VIII hyperploids compared to chromosome III hyperploids.

Physical map of the Saccharomyces cerevisiae genome at 110-kilobase resolution

A physical map of the Saccharomyces cerevisiae genome is presented. It was derived by mapping the sites for two restriction endonucleases, SfiI and NotI, each of which recognizes an 8-bp sequence. DNA-DNA hybridization probes for genetically mapped genes and probes that span particular SfiI and NotI sites were used to construct a map that contains 131 physical landmarks--32 chromosome ends, 61 SfiI sites and 38 NotI sites. These landmarks are distributed throughout the non-rDNA component of the yeast genome, which comprises 12.5 Mbp of DNA. The physical map suggests that those genes that can be detected and mapped by standard genetic methods are distributed rather uniformly over the full physical extent of the yeast genome. The map has immediate applications to the mapping of genes for which single-copy DNA-DNA hybridization probes are available.

The alcohol dehydrogenase system in the yeast, Kluyveromyces lactis

We have studied the alcohol dehydrogenase (ADH) system in the yeast Kluyveromyces lactis. Southern hybridization to the Saccharomyces cerevisiae ADH2 gene indicates four probable structural ADH genes in K. lactis. Two of these genes have been isolated from a genomic bank by hybridization to ADH2. The nucleotide sequence of one of these genes shows 80% and 50% sequence identity to the ADH genes of S. cerevisiae and Schizosaccharomyces pombe respectively. One K. lactis ADH gene is preferentially expressed in glucose-grown cells and, in analogy to S. cerevisiae, was named K1ADH1. The other gene, homologous to K1ADH1 in sequence, shows an amino-terminal extension which displays all of the characteristics of a mitochondrial targeting presequence. We named this gene K1ADH3. The two genes have been localized on different chromosomes by Southern hybridization to an orthogonal-field-alternation gel electrophoresis-resolved K. lactis genome. ADH activities resolved by gel electrophoresis revealed several ADH isozymes which are differently expressed in K. lactis cells depending on the carbon source.

The CCR4 gene from Saccharomyces cerevisiae is required for both nonfermentative and spt-mediated gene expression

Mutations in the yeast CCR4 gene inhibit expression of the glucose-repressible alcohol dehydrogenase (ADH2), as well as other nonfermentative genes, and suppress increased ADH2 expression caused by the cre1 and cre2 alleles. Both the cre1 and ccr4 alleles were shown to affect ADH II enzyme activity by altering the levels of ADH2 mRNA. Mutations in either CRE1 or CRE2 bypassed the inhibition of ADH2 expression caused by delta insertions at the ADH2 promoter which displace the ADH2 activation sequences 336 bp upstream of the TATA element. These cre1 and cre2 effects were suppressible by the ccr4 allele. The cre1 and ccr4 mutations also affected ADH2 expression when all the ADH2 regulatory sequences upstream of the TATA element were deleted. The relationship of the CRE genes to the SPT genes, which when mutated are capable of bypassing the inhibition of HIS4 expression caused by a delta promoter insertion (his4-912 delta allele), was examined. Both the cre1 and cre2 mutations allowed his4-912 delta expression. ccr4 mutations were able to suppress the ability of the cre alleles to increase his4-912 delta expression. CRE2 was shown to be allelic to the SPT6 gene, and CRE1 was found to be allelic to SPT10. We suggest that the CRE genes comprise a general transcriptional control system in yeast that requires the function of the CCR4 gene.

Regulation of sugar and ethanol metabolism in Saccharomyces cerevisiae

This review briefly surveys the literature on the nature, regulation, genetics, and molecular biology of the major energy-yielding pathways in yeasts, with emphasis on Saccharomyces cerevisiae. While sugar metabolism has received the lion's share of attention from workers in this field because of its bearing on the production of ethanol and other metabolites, more attention is now being paid to ethanol metabolism and the regulation of aerobic metabolism by fermentable and nonfermentable substrates. The utility of yeast as a highly manipulable organism and the discovery that yeast metabolic pathways are subject to the same types of control as those of higher cells open up many opportunities in such diverse areas as molecular evolution and cancer research.

Characterization of the adr1-1 nonsense mutation identifies the translational start of the yeast transcriptional activator ADR1

We have characterized a nonsense mutation in the ADR1 gene that identifies the translational start of the ADR1 protein. The ADR1 gene of Saccharomyces cerevisiae is required for synthesis of the glucose-repressible alcohol dehydrogenase (ADH2). The adr1-1 mutation, which inhibits ADH2 expression, was identified as a C to G transversion at base pair +32. This alteration would result in a UGA nonsense codon in place of a serine codon that would lead to termination of the ADR1 polypeptide after the 10th amino acid. The effect of the adr1-1 mutation was partially reversed by UGA-tRNA suppressors, indicating that the adr1-1 mutation affects ADR1 expression at the translational level. These observations establish that the first available AUG in the ADR1 sequence is used as the translational start site of ADR1. Tyrosine or leucine UGA-tRNA-suppressors resulted in levels of adr1-1 activity similar to that found for a serine UGA-tRNA-suppressor, suggesting that serine residue-11 is not essential to ADR1 function. Northern analyses showed that the 5.1 kb ADR1 mRNA was two- to three-fold more abundant when isolated from a strain carrying the ADR1 allele than from an isogenic strain containing the adr1-1 allele. These data confirm that the 5.1 kb mRNA is the ADR1 mRNA and suggest that inhibition of adr1-1 mRNA translation results in more rapid degradation of the adr1-1 mRNA.