GCR1-dependent transcriptional activation of yeast retrotransposon Ty2-917

Differential activation mechanisms of two isoforms of Gcr1 transcription factor generated from spliced and un-spliced transcripts in Saccharomyces cerevisiae

Gcr1, an important transcription factor for glycolytic genes in Saccharomyces cerevisiae, was recently revealed to have two isoforms, Gcr1^U and Gcr1^S, produced from un-spliced and spliced transcripts, respectively. In this study, by generating strains expressing only Gcr1^U or Gcr1^S using the CRISPR/Cas9 system, we elucidate differential activation mechanisms of these two isoforms. The Gcr1^U monomer forms an active complex with its coactivator Gcr2 homodimer, whereas Gcr1^S acts as a homodimer without Gcr2. The USS domain, 55 residues at the N-terminus existing only in Gcr1^U, inhibits dimerization of Gcr1^U and even acts in trans to inhibit Gcr1^S dimerization. The Gcr1^S monomer inhibits the metabolic switch from fermentation to respiration by directly binding to the ALD4 promoter, which can be restored by overexpression of the ALD4 gene, encoding a mitochondrial aldehyde dehydrogenase required for ethanol utilization. Gcr1^U and Gcr1^S regulate almost the same target genes, but show unique activities depending on growth phase, suggesting that these isoforms play differential roles through separate activation mechanisms depending on environmental conditions.

An Autophagy-Independent Role for ATG41 in Sulfur Metabolism During Zinc Deficiency

The Zap1 transcription factor of Saccharomyces cerevisiae is a key regulator in the genomic responses to zinc deficiency. Among the genes regulated by Zap1 during zinc deficiency is the autophagy-related gene ATG41 Here, we report that Atg41 is required for growth in zinc-deficient conditions, but not when zinc is abundant or when other metals are limiting. Consistent with a role for Atg41 in macroautophagy, we show that nutritional zinc deficiency induces autophagy and that mutation of ATG41 diminishes that response. Several experiments indicated that the importance of ATG41 function to growth during zinc deficiency is not because of its role in macroautophagy, but rather is due to one or more autophagy-independent functions. For example, rapamycin treatment fully induced autophagy in zinc-deficient atg41Δ mutants but failed to improve growth. In addition, atg41Δ mutants showed a far more severe growth defect than any of several other autophagy mutants tested, and atg41Δ mutants showed increased Heat Shock Factor 1 activity, an indicator of protein homeostasis stress, while other autophagy mutants did not. An autophagy-independent function for ATG41 in sulfur metabolism during zinc deficiency was suggested by analyzing the transcriptome of atg41Δ mutants during the transition from zinc-replete to -deficient conditions. Analysis of sulfur metabolites confirmed that Atg41 is needed for the normal accumulation of methionine, homocysteine, and cysteine in zinc-deficient cells. Therefore, we conclude that Atg41 plays roles in both macroautophagy and sulfur metabolism during zinc deficiency.

The Ty1 LTR-retrotransposon of budding yeast, Saccharomyces cerevisiae

Long-terminal repeat (LTR)-retrotransposons generate a copy of their DNA (cDNA) by reverse transcription of their RNA genome in cytoplasmic nucleocapsids. They are widespread in the eukaryotic kingdom and are the evolutionary progenitors of retroviruses [1]. The Ty1 element of the budding yeast Saccharomyces cerevisiae was the first LTR-retrotransposon demonstrated to mobilize through an RNA intermediate, and not surprisingly, is the best studied. The depth of our knowledge of Ty1 biology stems not only from the predominance of active Ty1 elements in the S. cerevisiae genome but also the ease and breadth of genomic, biochemical and cell biology approaches available to study cellular processes in yeast. This review describes the basic structure of Ty1 and its gene products, the replication cycle, the rapidly expanding compendium of host co-factors known to influence retrotransposition and the nature of Ty1's elaborate symbiosis with its host. Our goal is to illuminate the value of Ty1 as a paradigm to explore the biology of LTR-retrotransposons in multicellular organisms, where the low frequency of retrotransposition events presents a formidable barrier to investigations of retrotransposon biology.

Remodeling yeast gene transcription by activating the Ty1 long terminal repeat retrotransposon under severe adenine deficiency

The Ty1 long terminal repeat (LTR) retrotransposon of Saccharomyces cerevisiae is a powerful model to understand the activation of transposable elements by stress and their impact on genome expression. We previously discovered that Ty1 transcription is activated under conditions of severe adenine starvation. The mechanism of activation is independent of the Bas1 transcriptional activator of the de novo AMP biosynthesis pathway and probably involves chromatin remodeling at the Ty1 promoter. Here, we show that the 5' LTR has a weak transcriptional activity and is sufficient for the activation by severe adenine starvation. Furthermore, we demonstrate that Ty1 insertions that bring Ty1 promoter sequences into the vicinity of a reporter gene confer adenine starvation regulation on it. We provide evidence that similar coactivation of genes adjacent to Ty1 sequences occurs naturally in the yeast genome, indicating that Ty1 insertions can mediate transcriptional control of yeast gene expression under conditions of severe adenine starvation. Finally, the transcription pattern of genes adjacent to Ty1 insertions suggests that severe adenine starvation facilitates the initiation of transcription at alternative sites, partly located in the 5' LTR. We propose that Ty1-driven transcription of coding and noncoding sequences could regulate yeast gene expression in response to stress.

Glucose signaling controls the transcription of retrotransposon Ty2-917 in Saccharomyces cerevisiae

We have analyzed the effects of glucose signaling on the transcription in the yeast retrotransposon Ty2-917. Growth of Saccharomyces cerevisiae in non-fermentable carbon sources such as glycerol, lactate, or ethanol resulted in a dramatic decrease in the transcription of Ty2-917. However, when the yeast cells were transferred to a fermentable growth medium, Ty2-917 transcription is activated by 13-fold. Nonetheless, it appears that the activation of Ty2 transcription requires high levels of glucose since low levels of glucose or 2-deoxyglucose were not sufficient for the activation of Ty2 transcription. In addition, we have shown that glucose induction of Ty2 transcription may require the transcription factor Gcr1p since the glucose induced transcription level of Ty2 is much lower in a gcr1 mutant yeast strain than the GCR1+ strain. These results demonstrate that glucose signaling activates the transcription in the retroviral-like element Ty2-917.

Molecular characterization of a new begomovirus infecting Sida cordifolia and its associated satellite DNA molecules

Two virus isolates Hn57 and Hn60 were obtained from Sida cordifolia showing mild upward leaf-curling symptoms in Hainan province of China. Comparison of partial sequences of DNA-A like molecule confirmed the existence of a single type of begomovirus. The complete nucleotide sequence of DNA-A of Hn57 was determined to be 2757 nucleotides, with a genomic organization typical of begomoviruses. Complete sequence comparison with other reported begomoviruses revealed that Hn57 DNA-A has the highest sequence identity (71.0%) with that of Tobacco leaf curl Yunnan virus. Consequently, Hn57 was considered to be a new begomovirus species, for which the name Sida leaf curl virus (SiLCV) is proposed. In addition to DNA-A molecule, two additional circular single-stranded satellite DNA molecules corresponding to DNAbeta and DNA1 were found to be associated with SiLCV isolates. Both DNAbeta and DNA1 were approximately half the size of their cognate genomic DNA. Sequence analysis shows that DNAbeta of Hn57 and Hn60 share 93.8% nucleotide sequence identity, and they have the highest sequence identity (58.5%) with DNAbeta associated with Ageratum leaf curl disease (AJ316027). The nucleotide sequence identity between DNA1 of Hn57 and that of Hn60 was 83.8%, they share 58.2-79.3% nucleotide sequence identities in comparison with other previously reported DNAl.

Yeast unfolded protein response pathway regulates expression of genes for anti-oxidative stress and for cell surface proteins

The unfolded protein response (UPR) is a cellular protective event against endoplasmic reticulum (ER) stress. In the yeast UPR signaling pathway, the ER-located transmembrane protein Ire1 promotes splicing of the HAC1 premRNA (HAC1(u)) to produce the translatable transcription factor mRNA (HAC1i). We generated a HAC1i gene-bearing strain, in which the UPR pathway was constitutively activated, and compared its gene expression profile with that of a Deltaire1 HAC1u strain using cDNA microarray technology. Comparison of the gene expression profile was also performed between non-stressed wild-type cells and those exposed to ER stress. Genes for which the expression level was significantly changed in both of these experiments were categorized as targets of the Ire1-HAC1 signaling pathway. This analysis revealed that in addition to the previously known UPR targets, some anti-oxidative stress genes were up-regulated by the Ire1-HAC1 pathway, possibly in order to reduce reactive oxygen species produced during the cellular response to ER stress. Moreover, we categorized 15 genes as those down-regulated by the UPR, most of which seem to encode cell surface or extracellular proteins. This UPR-mediated gene repression may alleviate the load of client proteins targeted to the ER.

Severe adenine starvation activates Ty1 transcription and retrotransposition in Saccharomyces cerevisiae

Ty1 retrotransposons of the yeast Saccharomyces cerevisiae are activated by different kinds of stress. Here we show that Ty1 transcription is stimulated under severe adenine starvation conditions. The Bas1 transcriptional activator, responsible for the induction of genes of the de novo AMP biosynthesis pathway (ADE) in the absence of adenine, is not involved in this response. Activation occurs mainly on Ty1 elements, whose expression is normally repressed by chromatin and is suppressed in a hta1-htb1Delta mutant that alters chromatin structure. Activation is also abolished in a snf2Delta mutant. Several regions of the Ty1 promoter are necessary to achieve full activation, suggesting that full integrity of the promoter sequences might be important for activation. Together, these observations are consistent with a model in which the activation mechanism involves chromatin remodeling at Ty1 promoters. The consequence of Ty1 transcriptional activation in response to adenine starvation is an increase in Ty1 cDNA levels and a relief of Ty1 dormancy. The retrotransposition of four native Ty1 elements increases in proportion to their increase in transcription. Implications for the regulation of Ty1 mobility by changes in Ty1 mRNA levels are discussed.

Influence of low glycolytic activities in gcr1 and gcr2 mutants on the expression of other metabolic pathway genes in Saccharomyces cerevisiae

A complex of the transcription factors Gcr1p and Gcr2p coordinately regulates the expression of glycolytic genes in Saccharomyces cerevisiae. To understand the effects of gcr mutations on other metabolic pathways, genome-wide gene expression profiles in gcr1 and gcr2 mutants were examined. The biggest effects of gcr1 and gcr2 mutations were observed on the glycolytic genes and the expressions of most of the glycolytic genes were substantially decreased compared to those in the wild-type strain in both glucose and glycerol+lactate growth conditions. On the other hand, the expressions of genes encoding the TCA cycle and respiration were increased in gcr mutants when the cells were grown in glucose. RT-PCR analyses revealed that the expression of SIP4 and HAP5, which are known to affect the expression of some of the gluconeogenic, TCA cycle and respiratory genes, were also increased under this condition. The growth of gcr mutants on glucose was impaired by adding respiration inhibitor antimycin A, whereas the growth of the wild-type strain was not. The conversion of glucose to biomass was higher and, to the contrary, ethanol yield was lower in the gcr2 mutant compared to those in the wild-type strain. These results suggest the possibility that the gcr mutants, in which glycolytic activities are low, changed their metabolic patterns under glucose growth condition to enhance the expression of TCA cycle and respiratory genes to produce more energy.

Local definition of Ty1 target preference by long terminal repeats and clustered tRNA genes

LTR-containing retrotransposons reverse transcribe their RNA genomes, and the resulting cDNAs are integrated into the genome by the element-encoded integrase protein. The yeast LTR retrotransposon Ty1 preferentially integrates into a target window upstream of tDNAs (tRNA genes) in the yeast genome. We investigated the nature of these insertions and the target window on a genomic scale by analyzing several hundred de novo insertions upstream of tDNAs in two different multicopy gene families. The pattern of insertion upstream of tDNAs was nonrandom and periodic, with peaks separated by approximately 80 bp. Insertions were not distributed equally throughout the genome, as certain tDNAs within a given family received higher frequencies of upstream Ty1 insertions than others. We showed that the presence and relative position of additional tDNAs and LTRs surrounding the target tDNA dramatically influenced the frequency of insertion events upstream of that target.

Mutations in GCR1 affect SUC2 gene expression in Saccharomyces cerevisiae

Transcription of SUC2, the gene that encodes the cytoplasmic and secreted forms of the enzyme invertase, is controlled by glucose repression and derepression mechanisms in Saccharomyces cerevisiae. Several regulatory factors such as the Mig1p-Tup1p-Ssn6p repressor complex and the Snf1p kinase complex have been identified previously as regulators of SUC2 expression. We show that, in addition to these factors, expression of SUC2 is affected by mutations in the gene GCR1 that encodes the glycolysis regulatory protein Gcr1p. Expression of Suc2-LacZ was not repressed by glucose in gcr1 mutant yeast cells exposed to glucose. Furthermore, secreted invertase activity was constitutively expressed under glucose-repressed and derepressed conditions in gcr1 mutants. DNA gel mobility shift assays and in-vitro DNase I protection experiments mapped a DNA binding site for Gcr1p in the transcriptional control region of the SUC2 gene, next to a previously mapped Mig1p binding site. However, the mechanism by which gcr1 mutations relieve glucose repression remains obscure.

The GCR2 gene is required for the transcriptional activation of retrotransposon Ty2-917 in Saccharomyces cerevisiae

Ty2 retrotransposons are the mobile genetic elements of the yeast Saccharomyces cerevisiae. Transcriptional regulation of Ty2-917 requires a complex set of cis acting elements which are located both upstream and downstream of the transcription initiation site. Previously, the glycolysis regulatory protein Gcr1p has been identified as the major transcriptional regulator of Ty2-917. Gcr1p is a DNA binding transcription factor that requires Gcr2p for its functions. In this study, the effect of Gcr2p on the transcriptional regulation of Ty2-917 was analyzed. The result of this study indicates that Ty2-917 transcription decreases 24-fold in gcr2 mutant yeast cells. In addition, Ty2 enhancer element dependent transcriptional activation of a heterolog promoter also decreases at a significant level. These results showed that Gcr2p is essential for the high level transcription of Ty2-917.

Differential effects of chromatin and Gcn4 on the 50-fold range of expression among individual yeast Ty1 retrotransposons

Approximately 30 copies of the Ty1 retrotransposon are present in the genome of Saccharomyces cerevisiae. Previous studies gave insights into the global regulation of Ty1 transcription but provided no information on the behavior of individual genomic elements. This work shows that the expression of 31 individual Ty1 elements in S288C varies over a 50-fold range. Their transcription is repressed by chromatin structures, which are antagonized by the Swi/Snf and SAGA chromatin-modifying complexes in highly expressed Ty1 elements. These elements carry five potential Gcn4 binding sites in their promoter regions that are mostly absent in weakly expressed Ty1 copies. Consistent with this observation, Gcn4 activates the transcription of highly expressed Ty1 elements only. One of the potential Gcn4 binding sites acts as an upstream activating sequence in vivo and interacts with Gcn4 in vitro. Since Gcn4 has been shown to interact with Swi/Snf and SAGA, we predict that Gcn4 activates Ty1 transcription by targeting these complexes to specific Ty1 promoters.

Phylogenetic footprinting reveals multiple regulatory elements involved in control of the meiotic recombination gene, REC102

REC102 is a meiosis-specific early exchange gene absolutely required for meiotic recombination in Saccharomyces cerevisiae. Sequence analysis of REC102 indicates that there are multiple potential regulatory elements in its promoter region, and a possible regulatory element in the coding region. This suggests that the regulation of REC102 may be complex and may include elements not yet reported in other meiotic genes. To identify potential cis-regulatory elements, phylogenetic footprinting analysis was used. REC102 homologues were cloned from other two Saccharomyces spp. and sequence comparison among the three species defined evolutionarily conserved elements. Deletion analysis demonstrated that the early meiotic gene regulatory element URS1 was necessary but not sufficient for proper regulation of REC102. Upstream elements, including the binding sites for Gcr1p, Yap1p, Rap1p and several novel conserved sequences, are also required for the normal regulation of REC102 as well as a Rap1p binding site located in the coding region. The data in this paper support the use of phylogenetic comparisions as a method for determining important sequences in complex promoters.

Bayesian analysis of gene expression levels: statistical quantification of relative mRNA level across multiple strains or treatments

BACKGROUND

Methods of microarray analysis that suit experimentalists using the technology are vital. Many methodologies discard the quantitative results inherent in cDNA microarray comparisons or cannot be flexibly applied to multifactorial experimental design. Here we present a flexible, quantitative Bayesian framework. This framework can be used to analyze normalized microarray data acquired by any replicated experimental design in which any number of treatments, genotypes, or developmental states are studied using a continuous chain of comparisons.

RESULTS

We apply this method to Saccharomyces cerevisiae microarray datasets on the transcriptional response to ethanol shock, to SNF2 and SWI1 deletion in rich and minimal media, and to wild-type and zap1 expression in media with high, medium, and low levels of zinc. The method is highly robust to missing data, and yields estimates of the magnitude of expression differences and experimental error variances on a per-gene basis. It reveals genes of interest that are differentially expressed at below the twofold level, genes with high 'fold-change' that are not statistically significantly different, and genes differentially regulated in quantitatively unanticipated ways.

CONCLUSIONS

Anyone with replicated normalized cDNA microarray ratio datasets can use the freely available MacOS and Windows software, which yields increased biological insight by taking advantage of replication to discern important changes in expression level both above and below a twofold threshold. Not only does the method have utility at the moment, but also, within the Bayesian framework, there will be considerable opportunity for future development.

The GCR1 gene function is essential for glycogen and trehalose metabolism in Saccharomyces cerevisiae

Trehalose (Tre) and glycogen (Glg) are synthesized in response to unfavorable growth conditions from glycolytic intermediates in Saccharomyces cerevisiae. Transcription of the glycolytic genes is activated by the Gcr1p complex, the DNA binding transcription factor that directly associates with the CT-box sequences on the promoter region of the glycolytic genes. gcr1 mutant yeast cells cannot utilize glucose effectively. Glg and Tre levels in stationary-phase gcr1 mutant yeast cells were 20-50% of those in the wild-type strain. Likewise, stress-induced accumulation of Tre and Glg in gcr1 mutant cells was significantly lower than in the wild type. In addition, both the synthesis and the degradation of Tre and Glg are very slow in the gcr1 mutant. It seems that Gcr1p function is essential for the coordinated regulation of glycolysis, Tre and Glg metabolism in S. cerevisiae.

Understanding the growth phenotype of the yeast gcr1 mutant in terms of global genomic expression patterns

The phenotype of an organism is the manifestation of its expressed genome. The gcr1 mutant of yeast grows at near wild-type rates on nonfermentable carbon sources but exhibits a severe growth defect when grown in the presence of glucose, even when nonfermentable carbon sources are available. Using DNA microarrays, the genomic expression patterns of wild-type and gcr1 mutant yeast growing on various media, with and without glucose, were compared. A total of 53 open reading frames (ORFs) were identified as GCR1 dependent based on the criterion that their expression was reduced twofold or greater in mutant versus wild-type cultures grown in permissive medium consisting of YP supplemented with glycerol and lactate. The GCR1-dependent genes, so defined, fell into three classes: (i) glycolytic enzyme genes, (ii) ORFs carried by Ty elements, and (iii) genes not previously known to be GCR1 dependent. In wild-type cultures, GCR1-dependent genes accounted for 27% of the total hybridization signal, whereas in mutant cultures, they accounted for 6% of the total. Glucose addition to the growth medium resulted in a reprogramming of gene expression in both wild-type and mutant yeasts. In both strains, glycolytic enzyme gene expression was induced by the addition of glucose, although the expression of these genes was still impaired in the mutant compared to the wild type. By contrast, glucose resulted in a strong induction of Ty-borne genes in the mutant background but did not greatly affect their already high expression in the wild-type background. Both strains responded to glucose by repressing the expression of genes involved in respiration and the metabolism of alternative carbon sources. Thus, the severe growth inhibition observed in gcr1 mutants in the presence of glucose is the result of normal signal transduction pathways and glucose repression mechanisms operating without sufficient glycolytic enzyme gene expression to support growth via glycolysis alone.

Transcription of the HXT4 gene is regulated by Gcr1p and Gcr2p in the yeast S. cerevisiae

Glucose transport and glycolysis are two sequential events which are regulated by both physiological and environmental signals in the yeast Saccharomyces cerevisiae. Transcription of the HXT4 gene was found to be regulated by Gcr1p and Gcr2p, transcription factors that are required for the regulated high level transcriptions of glycolytic genes. Transcription of HXT4 decreased about 35-fold in gcr1 mutant and two-fold in gcr2 mutant yeast cells. However, transcription of other HXT genes was not affected at a significant level by gcr1 or gcr2 mutations. Overproduction of Gcr1p from an inducible promoter resulted in a 15-64% increase in transcription of HXT4, depending on the growth conditions. Gel mobility shift assays performed with the purified DNA binding domain of Gcr1p and the UAS region of the HXT4 gene showed that Gcr1p interacts directly with multiple sites on the HXT4 UAS region. These results indicate that Gcr1p and Gcr2p coordinate the transcription of HXT4 and glycolytic genes.

Specific components of the SAGA complex are required for Gcn4- and Gcr1-mediated activation of the his4-912delta promoter in Saccharomyces cerevisiae

Mutations selected as suppressors of Ty or solo delta insertion mutations in Saccharomyces cerevisiae have identified several genes, SPT3, SPT7, SPT8, and SPT20, that encode components of the SAGA complex. However, the mechanism by which SAGA activates transcription of specific RNA polymerase II-dependent genes is unknown. We have conducted a fine-structure mutagenesis of one widely used SAGA-dependent promoter, the delta element of his4-912delta, to identify sequence elements important for its promoter activity. Our analysis has characterized three delta regions necessary for full promoter activity and accurate start site selection: an upstream activating sequence, a TATA region, and an initiator region. In addition, we have shown that factors present at the adjacent UASHIS4 (Gcn4, Bas1, and Pho2) also activate the delta promoter in his4-912delta. Our results suggest a model in which the delta promoter in his4-912delta is primarily activated by two factors: Gcr1 acting at the UASdelta and Gcn4 acting at the UASHIS4. Finally, we tested whether activation by either of these factors is dependent on components of the SAGA complex. Our results demonstrate that Spt3 and Spt20 are required for full delta promoter activity, but that Gcn5, another member of SAGA, is not required. Spt3 appears to be partially required for activation of his4-912delta by both Gcr1 and Gcn4. Thus, our work suggests that SAGA exerts a large effect on delta promoter activity through a combination of smaller effects on multiple factors.

The boundaries of the silenced HMR domain in Saccharomyces cerevisiae

The chromosomes of eukaryotes are organized into structurally and functionally discrete domains that provide a mechanism to compact the DNA as well as delineate independent units of gene activity. It is believed that insulator/boundary elements separate these domains. Here we report the identification and characterization of boundary elements that flank the transcriptionally repressed HMR locus in the yeast Saccharomyces cerevisiae. Deletion of these boundary elements led to the spread of silenced chromatin, whereas the ectopic insertion of these elements between a silencer and a promoter blocked the repressive effects of the silencer on that promoter at HMR and at telomeres. Sequence analysis indicated that the boundary element contained a TY1 LTR, and a tRNA gene and mutational analysis has implicated the Smc proteins, which encode structural components of chromosomes, in boundary element function.

Multiple domains of repressor activator protein 1 contribute to facilitated binding of glycolysis regulatory protein 1

The function of repressor activator protein 1 (Rap1p) at glycolytic enzyme gene upstream activating sequence (UAS) elements in Saccharomyces cerevisiae is to facilitate binding of glycolysis regulatory protein 1 (Gcr1p) at adjacent sites. Rap1p has a modular domain structure. In its amino terminus there is an asymmetric DNA-bending domain, which is distinct from its DNA-binding domain, which resides in the middle of the protein. In the carboxyl terminus of Rap1p lie its silencing and putative activation domains. We carried out a molecular dissection of Rap1p to identify domains contributing to its ability to facilitate binding of Gcr1p. We prepared full-length and three truncated versions of Rap1p and tested their ability to facilitate binding of Gcr1p by gel shift assay. The ability to detect ternary complexes containing Rap1p.DNA. Gcr1p depended on the presence of binding sites for both proteins in the probe DNA. The DNA-binding domain of Rap1p, although competent to bind DNA, was unable to facilitate binding of Gcr1p. Full-length Rap1p and the amino- and carboxyl-truncated versions of Rap1p were each able to facilitate binding of Gcr1p at an appropriately spaced binding site. Under these conditions, Gcr1p displayed an approximately 4-fold greater affinity for Rap1p-bound DNA than for otherwise identical free DNA. When spacing between Rap1p- and Gcr1p-binding sites was altered by insertion of five nucleotides, the ability to form ternary Rap1p.DNA.Gcr1p complexes was inhibited by all but the DNA-binding domain of Rap1p itself; however, the ability of each individual protein to bind the DNA probe was unaffected.