A yeast ARS-binding protein activates transcription synergistically in combination with other weak activating factors

Genome-wide off-rates reveal how DNA binding dynamics shape transcription factor function

Protein-DNA interactions are dynamic, and these dynamics are an important aspect of chromatin-associated processes such as transcription or replication. Due to a lack of methods to study on- and off-rates across entire genomes, protein-DNA interaction dynamics have not been studied extensively. Here, we determine in vivo off-rates for the Saccharomyces cerevisiae chromatin organizing factor Abf1, at 191 sites simultaneously across the yeast genome. Average Abf1 residence times span a wide range, varying between 4.2 and 33 min. Sites with different off-rates are associated with different functional characteristics. This includes their transcriptional dependency on Abf1, nucleosome positioning and the size of the nucleosome-free region, as well as the ability to roadblock RNA polymerase II for termination. The results show how off-rates contribute to transcription factor function and that DIVORSEQ (Determining In Vivo Off-Rates by SEQuencing) is a meaningful way of investigating protein-DNA binding dynamics genome-wide.

Promoter occupancy is a major determinant of chromatin remodeling enzyme requirements

Chromatin creates transcriptional barriers that are overcome by coactivator activities such as histone acetylation by Gcn5 and ATP-dependent chromatin remodeling by SWI/SNF. Factors defining the differential coactivator requirements in the transactivation of various promoters remain elusive. Induction of the Saccharomyces cerevisiae PHO5 promoter does not require Gcn5 or SWI/SNF under fully inducing conditions of no phosphate. We show that PHO5 activation is highly dependent on both coactivators at intermediate phosphate concentrations, conditions that reduce the nuclear concentration of the Pho4 transactivator and severely diminish its association with PHO5 in the absence of Gcn5 or SWI/SNF. Conversely, physiological increases in Pho4 nuclear concentration and binding at PHO5 suppress the need for both Gcn5 and SWI/SNF, suggesting that coactivator redundancy is established at high Pho4 binding site occupancy. Consistent with this, we demonstrate, using chromatin immunoprecipitation, that Gcn5 and SWI/SNF are directly recruited to PHO5 and other strongly transcribed promoters, including GAL1-10, RPL19B, RPS22B, PYK1, and EFT2, which do not require either coactivator for expression. These results show that activator concentration and binding site occupancy play crucial roles in defining the extent to which transcription requires individual chromatin remodeling enzymes. In addition, Gcn5 and SWI/SNF associate with many more genomic targets than previously appreciated.

Functional diversity of silencers in budding yeasts

We studied the silencing of the cryptic mating-type loci HMLa and HMRa in the budding yeast Kluyveromyces lactis. A 102-bp minimal silencer fragment was defined that was both necessary and sufficient for silencing of HMLalpha. Mutagenesis of the silencer revealed three distinct regions (A, B, and C) that were important for silencing. Recombinant K. lactis ribosomal DNA enhancer binding protein 1 (Reb1p) could bind the silencer in vitro, and point mutations in the B box abolished both Reb1p binding and silencer function. Furthermore, strains carrying temperature-sensitive alleles of the REBI gene derepressed the transcription of the HMLalpha1 gene at the nonpermissive temperature. A functional silencer element from the K. lactis cryptic HMRa locus was also identified, which contained both Reb1p binding sites and A boxes, strongly suggesting a general role for these sequences in K lactis silencing. Our data indicate that different proteins bind to Kluyveromyces silencers than to Saccharomyces silencers. We suggest that the evolution of silencers is rapid in budding yeasts and discuss the similarities and differences between silencers in Saccharomyces and Kluyveromyces.

Identification of a multifunctional domain in autonomously replicating sequence-binding factor 1 required for transcriptional activation, DNA replication, and gene silencing

Autonomously replicating sequence-binding factor 1 (ABF1) is a multifunctional, site-specific DNA binding protein that is essential for cell viability in Saccharomyces cerevisiae. ABF1 plays a direct role in transcriptional activation, stimulation of DNA replication, and gene silencing at the mating-type loci. Here we demonstrate that all three activities of ABF1 are conferred by the C terminus of the protein (amino acids [aa] 604 to 731). Furthermore, a detailed mutational analysis has revealed two important clusters of amino acid residues in the C terminus (C-terminal sequence 1 [CS1], aa 624 to 628; and CS2, aa 639 to 662). While both regions play a pivotal role in supporting cell viability, they make distinct contributions to ABF1 functions in various nuclear processes. CS1 specifically participates in transcriptional silencing and/or repression in a context-dependent manner, whereas CS2 is universally required for all three functions of ABF1. When tethered to specific regions of the genome, a 30-aa fragment that contains CS2 alone is sufficient for activation of transcription and chromosomal replication. In addition, CS2 is responsible for ABF1-mediated chromatin remodeling. Based on these results, we suggest that ABF1 may function as a chromatin-reorganizing factor to increase accessibility of the local chromatin structure, which in turn facilitates the action of additional factors to establish either an active or repressed chromatin state.

Different roles for abf1p and a T-rich promoter element in nucleosome organization of the yeast RPS28A gene

In vivo mutational analysis of the yeast RPS28A ribosomal protein (rp-)gene promoter demonstrated that both the Abf1p binding site and the adjacent T-rich element are essential for efficient transcription. In vivo Mnase and DNaseI digestion showed that the RPS28A promoter contains a 50-60 bp long nucleosome-free region directly downstream from the Abf1p binding site, followed by an ordered array of nucleosomes. Mutating either the Abf1p binding site or the T-rich element has dramatic, but different, effects on the local chromatin structure. Failure to bind Abf1p appears to cause nucleosome positioning to become disorganized as concluded from the complete disappearance of Mnase hypersensitive sites. On the other hand, mutation of the T-rich element causes the downstream nucleosomal array to shift by approximately 50 bp towards the Abf1p site, resulting in loss of the nucleosome-free region downstream of Abf1p. We conclude that Abf1p is a strong organizer of local chromatin structure that appears to act as a nucleosomal boundary factor requiring the downstream T-rich element to create a nucleosome-free region.

Yeast autonomously replicating sequence binding factor is involved in nucleotide excision repair

Nucleotide excision repair (NER) in yeast is effected by the concerted action of a large complex of proteins. Recently, we identified a stable subcomplex containing the yeast Rad7 and Rad16 proteins. Here, we report the identification of autonomously replicating sequence binding factor 1 (ABF1) as a component of the Rad7/Rad16 NER subcomplex. Yeast ABF1 protein is encoded by an essential gene required for DNA replication, transcriptional regulation, and gene silencing. We show that ABF1 plays a direct role in NER in vitro. Additionally, consistent with a role of ABF1 protein in NER in vivo, we show that certain temperature-sensitive abf1 mutant strains that are defective in DNA replication are specifically defective in the removal of photoproducts by NER and are sensitive to killing by ultraviolet (UV) radiation. These studies define a novel and unexpected role for ABF1 protein during NER in yeast.

Context-dependent modulation of replication activity of Saccharomyces cerevisiae autonomously replicating sequences by transcription factors

Evidence for transcription factor involvement in the initiation of DNA replication at certain replication origins in Saccharomyces cerevisiae mainly comes from an indirect assay which measures the mitotic stability of plasmids containing an autonomously replicating sequence (ARS), a selectable marker gene, and a centromere. In order to eliminate the effect of transcription factor binding to the selectable marker gene or centromere in such assays, we have adapted the DpnI assay to directly measure ARS replication activity in vivo by using ARS plasmids devoid of extraneous transcription elements. Using this assay, we found that the B3 element of ARS1, which serves as a binding site for the transcription factor Abf1p, does not stimulate ARS activity on plasmids lacking a centromere and a selectable marker gene. We also found with such plasmids that exogenous expression of the strong transcriptional activators Gal4 and Gal4-VP16 inhibited the replication activity of ARS1 when B3 was replaced by the Gal4 binding site, although these activators had previously been shown to stimulate replication activity in the stability assay. Moreover, a chromosomally inactive ARS, ARS301, which was active by itself on a plasmid, was inactivated by placing an Abf1p binding site in its vicinity. These results indicate that the sequences surrounding the ARS as well as properties of the ARS element itself determine its response to transcription factors.

Biochemical and genetic characterization of the dominant positive element driving transcription ofthe yeast TBP-encoding gene, SPT15

We previously demonstrated that a combination of both positive and negative cis -acting upstream elements control the transcription of the gene encoding TBP ( SPT15 ) in Saccharomyces cerevisiae . One of these elements found in that study, resident between 5' flanking sequences -147 and -128 , and termed PED (for positive element distal), was found to play an essential positive role in driving transcription of the gene encoding TBP. In this report, we map at nucleotide-level resolution, the critical residues which comprise PED, purify and sequence the protein that binds to it and determine that this PED binding factor is Abf1p, an abundant yeast protein previously broadly implicated in both gene regulation and DNA replication. In the case of the TBP-encoding gene, however, Abf1p works through the PED element which is a non-consensus binding site. Based upon the work of others, the PED-variant ABF1 site would be predicted to be a very poor binding site for this factor yet Abf1p binds PED and a consensus ABF1 site with comparable affinity. These results are discussed in light of the broader context of Abf1p-mediated gene regulation.

Regulation of cell size by glucose is exerted via repression of the CLN1 promoter

Yeast cells are keenly sensitive to the availability and quality of nutrients. Addition of glucose to cells growing on a poorer carbon source elicits a cell cycle delay during G1 phase and a concomitant increase in the cell size. The signal is transduced through the RAS-cyclic AMP pathway. Using synchronized populations of G1 cells, we show that the increase in cell size required for budding depends upon CLN1 but not other G1 cyclins. This delay in cell cycle initiation is associated specifically with transcriptional repression of CLN1. CLN2 is not repressed. Repression of CLN1 is not limited to the first cycle following glucose addition but occurs in each cell cycle during growth on glucose. A 106-bp fragment of the CLN1 promoter containing the three MluI cell cycle box (MCB) core elements responsible for the majority of CLN1-associated upstream activation sequence activity is sufficient to confer glucose-induced repression on a heterologous reporter. A mutant CLN2 promoter that is rendered dependent upon its three MCB core elements due to inactivation of its Swi4-dependent cell cycle box (SCB) elements is also repressed by glucose. The response to glucose is partially suppressed by inactivation of SWI4, but not MBP1, which is consistent with the dependence of MCB core elements upon the SCB-binding transcription factor (SBF). We suggest that differential regulation of CLN1 and CLN2 by glucose results from differences in the capacity of SBF to activate transcription driven by SCB and MCB core elements. Finally, we show that transcriptional repression is sufficient to explain the cell cycle delay that occurs in response to glucose.

Association of transcription factor IIA with TATA binding protein is required for transcriptional activation of a subset of promoters and cell cycle progression in Saccharomyces cerevisiae

The general transcription factor IIA (TFIIA) interacts with the TATA binding protein (TBP) and promoter DNA to mediate transcription activation in vitro. To determine if this interaction is generally required for activation of all class II genes in vivo, we have constructed substitution mutations in yeast TFIIA which compromise its ability to bind TBP. Substitution mutations in the small subunit of TFIIA (Toa2) at residue Y69 or W76 significantly impaired the ability of TFIIA to stimulate TBP-promoter binding in vitro. Gene replacement of wild-type TOA2 with a W76E or Y69A/W76A mutant was lethal in Saccharomyces cerevisiae, while the Y69F/W76F mutant exhibited extremely slow growth at 30 degrees C. Both the Y69A and W76A mutants were conditionally lethal at higher temperatures. Light microscopy indicated that viable toa2 mutant strains accumulate as equal-size dumbbells and multibudded clumps. Transcription of the cell cycle-regulatory genes CLB1, CLB2, CLN1, and CTS1 was significantly reduced in the toa2 mutant strains, while the noncycling genes PMA1 and ENO2 were only modestly affected, suggesting that these toa2 mutant alleles disrupt cell cycle progression. The differential effect of these toa2 mutants on gene transcription was examined for a number of other genes. toa2 mutant strains supported high levels of CUP1, PHO5, TRP3, and GAL1 gene activation, but the constitutive expression of DED1 was significantly reduced. Activator-induced start site expression for HIS3, GAL80, URA1, and URA3 promoters was defective in toa2 mutant strains, suggesting that the TFIIA-TBP complex is important for promoters which require an activator-dependent start site selection from constitutive to regulated expression. We present evidence to indicate that transcription defects in toa2 mutants can be both activator and promoter dependent. These results suggest that the association of TFIIA with TBP regulates activator-induced start site selection and cell cycle progression in S. cerevisiae.

Activation of chromosomal DNA replication in Saccharomyces cerevisiae by acidic transcriptional activation domains

A large body of evidence from viral systems has established that transcription factors play an important and direct role in activating viral DNA replication. Among the transcriptional activation domains that can stimulate viral DNA replication are acidic domains such as those derived from herpes simplex virus VP16 and the tumor suppressor p53. Here we show that acidic activation domains can also activate a cellular origin of replication in a chromosomal context. When tethered to the yeast ARS1 (autonomously replicating sequence 1) origin of replication, both VP16 and p53 activation domains can enhance origin function. In addition, the C-terminal acidic region of the yeast transcription factor ABF1, which normally activates the ARS1 origin, is sufficient for activating ARS1 function when tethered to the origin. Mutations at residues Trp-53 and Phe-54 of a 20-residue (41 to 60) activation region of p53 abolish the activation of both replication and transcription, suggesting that the same structural determinants may be employed to activate both processes in yeast. Furthermore, using a two-dimensional gel electrophoresis method, we demonstrate that the GAL4-p53 chimeric activator can activate initiation of chromosomal replication from an origin inserted at the native ARS1 locus. These findings strongly suggest functional conservation of the mechanisms used by the acidic activation domains to activate viral DNA replication in mammalian cells and chromosomal replication in yeast.

An Abf1p C-terminal region lacking transcriptional activation potential stimulates a yeast origin of replication

Although it has been demonstrated that eukaryotic cellular origins of DNA replication may harbor stimulatory elements that bind transcription factors, how these factors stimulate origin function is unknown. In Saccharomyces cerevisiae , the transcription factor Abf1p stimulates origin function of ARS121 and ARS1 . In the results presented here, an analysis of Abf1p function has been carried out utilizing LexA(BD)-Abf1p fusion proteins and an ARS 121 derivative harboring LexA DNA-binding sites. A minimal region which stimulates origin function mapped to 50 amino acids within the C-terminus of Abf1p. When tested for transcriptional activation of a LacZ reporter gene, the same LexA(BD)-Abf1p fusion protein had negligible transcriptional activation potential. Therefore, stimulation of ARS 121 may occur independently of a transcriptional activation domain. It has been previously observed that the Gal4p, Rap1p DNA-binding sites and the LexA-Gal4p fusion protein can replace the role of Abf1p in stimulating ARS 1 . Here we show that the stimulatory function of Abf1p at ARS 121 cannot be replaced by these alternative DNA-binding sites and the potent chimeric transcriptional activator LexA(BD)-Gal4(AD)p . Hence, these results strongly suggest that the Abf1p stimulation of replication may differ for ARS 121 and ARS 1 , and imply specificity in the Abf1p/ARS 121 relationship.

Functional equivalency and diversity of cis-acting elements among yeast replication origins

The DNA replication origins of the yeast Saccharomyces cerevisiae require several short functional elements, most of which are not conserved in sequence. To better characterize ARS305, a replicator from a chromosomal origin, we swapped functional DNA elements of ARS305 with defined elements of ARS1. ARS305 contains elements that are functionally exchangeable with ARS1 A and B1 elements, which are known to bind the origin recognition complex; however, the ARS1 A element differs in that it does not require a 3' box adjacent to the essential autonomously replicating sequence consensus. At the position corresponding to ARS1 B3, ARS305 has a novel element, B4, that can functionally substitute for every type of short element (B1, B2, and B3) in the B domain. Unexpectedly, the replacement of element B4 by ARS1 B3, which binds ABF1p and is known as a replication enhancer, inhibited ARS305 function. ARS305 has no short functional element at or near positions corresponding to the B2 elements in ARS1 and ARS307 but contains an easily unwound region whose functional importance was supported by a broad G+C-rich substitution mutation. Surprisingly, the easily unwound region can functionally substitute for the ARS1 B2 element, even though ARS1 B2 was found to possess a distinct DNA sequence requirement. The functionally conserved B2 element in ARS307 contains a known sequence requirement, and helical stability analysis of linker and minilinker mutations suggested that B2 also contains a DNA unwinding element (DUE). Our findings suggest that yeast replication origins employ a B2 element or a DUE to mediate a common function, DNA unwinding during initiation, although not necessarily through a common mechanism.

Regulation of gene expression during meiosis in Saccharomyces cerevisiae: SPR3 is controlled by both ABFI and a new sporulation control element

The SPR3 gene encodes a sporulation-specific homolog of the yeast Cdc3/10/11/12 family of bud neck filament proteins. It is expressed specifically during meiosis and sporulation in Saccharomyces cerevisiae. Analysis of the sporulation-specific regulation of SPR3 has shown that it is strongly activated under sporulating conditions but shows low levels of expression under nonsporulating conditions. A palindromic sequence located near the TATA box is essential to the developmental regulation of this gene and is the only element directly activating SPR3 at the right time during sporulation. Within the palindrome is a 9-bp sequence, gNCRCAAA(A/T) (midsporulation element [MSE]), found in the known control regions of three other sporulation genes. A previously identified ABFI element is also needed for activation. The MSE has been shown to activate a heterologous promoter (CYC1) in a sporulation-specific manner. Related sequences, including an association of MSE and ABFI elements, have been found upstream of other genes activated during the middle stage of S. cerevisiae sporulation. One group of these may be involved in spore coat formation or maturation.

Similar upstream regulatory elements of genes that encode the two largest subunits of RNA polymerase II in Saccharomyces cerevisiae

We have determined the location of cis-acting elements that are important for the expression of RPO21 and RPO22, genes that encode the two largest subunits of RNA polymerase II (RNAPII) in Saccharomyces cerevisiae. A series of 5'-end deletions and nucleotide substitutions in the upstream regions of RPO21 and RPO22 were tested for their effect on the expression of lacZ fusions of these genes. Deletion of sequences from -723 to -693 in RPO21, which disrupted two Reb1p-binding sites and an Abf1p-binding site, resulted in a 10-fold decrease in expression. A T-rich region downstream of these sites was also important for expression. Deletion of sequences from -437 to -392 in the RPO22-upstream, which resulted in a 30-fold decrease in expression, indicated that the Reb1p- and Abf1p-binding sites in this region were important for RPO22 expression, as was a T-rich sequence immediately downstream of these sites. The RPO21 and RPO22 upstream regions were capable of interacting in vitro (gel-mobility-shift assays) with Reb1p and Abf1p. The similarities in the type and organization of elements in the upstream regions of RPO21 and RPO22 suggest that expression of these genes may be regulated coordinately.

Combinatorial regulation of the Saccharomyces cerevisiae CAR1 (arginase) promoter in response to multiple environmental signals

CAR1 (arginase) gene expression responds to multiple environmental signals; expression is induced in response to the intracellular accumulation of arginine and repressed when readily transported and catabolized nitrogen sources are available in the environment. Up to 14 cis-acting sites and 9 trans-acting factors have been implicated in regulated CAR1 transcription. In all but one case, the sites are redundant. To test whether these sites actually participate in CAR1 expression, each class of sites was inactivated by substitution mutations that retained the native spacing of the CAR1 cis-acting elements. Three types of sites function independently of the nitrogen source: two clusters of Abflp- and Rap1p-binding sites, and a GC-rich sequence. Two different sets of nitrogen source-dependent sites are also required: the first consists of two GATAA-containing UASNTR sites that mediate nitrogen catabolite repression-sensitive transcription, and the second is arginine dependent and consists of three UAS1 elements that activate transcription only when arginine is present. A single URS1 site mediates repression of CAR1 arginine-independent upstream activator site (UAS) activity in the absence of arginine and the presence of a poor nitrogen source (a condition under which the inducer-independent Gln3p can function in association with the UASNTR sites). When arginine is present, the combined activity of the UAS elements overcomes the negative effects mediated by URS1. Mutation of the classes of sites either singly or in combination markedly alters CAR1 promoter operation and control, supporting the idea that they function synergistically to regulate expression of the gene.

Transcriptional terminators of RNA polymerase II are associated with yeast replication origins

The compact organization of the Saccharomyces cerevisiae genome necessitates that non-coding regulatory sequences reside in close proximity to one another. Here we show there is an intimate association between transcription terminators and DNA replication origins. Four replication origins were analyzed in a reporter gene assay that detects sequences that direct 3' end formation of mRNA transcripts. All four replication origins function as orientation-independent transcription terminators in this system, producing truncated polyadenylated mRNAs. Despite this close association, the cis-acting elements that confer replication origin function are genetically separable from those required for transcription termination. Several models are explored in an attempt to address how and why the signals specifying transcription termination and replication initiation overlap.

Activation mechanism of the multifunctional transcription factor repressor-activator protein 1 (Rap1p)

Transcriptional activation in eukaryotic organisms normally requires combinatorial interactions of multiple transcription factors. In most cases, the precise role played by each transcription factor is not known. The upstream activating sequence (UAS) elements of glycolytic enzyme genes in Saccharomyces cerevisiae are excellent model systems for the study of combinatorial interactions. The yeast protein known as Rap1p acts as both a transcriptional repressor and an activator, depending on sequence context. Rap1p-binding sites are found adjacent to Gcr1p-binding sites in the UAS elements of glycolytic enzyme genes. These UAS elements constitute some of the strongest activating sequences known in S. cerevisiae. In this study, we have investigated the relationship between Rap1p- and Gcr1p-binding sites and the proteins that bind them. In vivo DNA-binding studies with rap1ts mutant strains demonstrated that the inability of Rap1p to bind at its site resulted in the inability of Gcr1p to bind at adjacent binding sites. Synthetic oligonucleotides, modeled on the UAS element of PYK1, in which the relative positions of the Rap1p- and Gcr1p-binding sites were varied prepared and tested for their ability to function as UAS elements. The ability of the oligonucleotides to function as UAS elements was dependent not only on the presence of both binding sites but also on the relative distance between the binding sites. In vivo DNA-binding studies showed that the ability of Rap1p bind its site was independent of Gcr1p but that the ability of Gcr1p to bind its site was dependent on the presence of an appropriately spaced and bound Rap1p-binding site. In vitro binding studies showed Rap1p-enhanced binding of Gcr1p on oligonucleotides modeled after the native PYK1 UAS element but not when the Rap1p- and Gcr1p-binding sites were displaced by 5 nucleotides. This work demonstrates that the role of the Rap1p in the activation of glycolytic enzyme genes is to bind in their UAS elements and to facilitate the binding of Gcr1p at adjacent binding sites.

Mechanism of differential utilization of the his3 TR and TC TATA elements

The yeast his3 promoter region contains two TATA elements, TC and TR, that are differentially utilized in constitutive his3 transcription and Gcn4-activated his3 transcription. TR contains the canonical TATAAA sequence, whereas TC is an extended region that lacks a conventional TATA sequence and does not support transcription in vitro. Surprisingly, differential his3 TATA-element utilization does not depend on specific properties of activator proteins but, rather, is determined by the overall level of his3 transcription. At low levels of transcription, the upstream TC is preferentially utilized, even though it is inherently a much weaker TATA element than TR. The TATA elements are utilized equally at intermediate levels, whereas TR is strongly preferred at high levels of transcription. This characteristic behavior can be recreated by replacing TC with moderately functional derivatives of a conventional TATA element, suggesting that TC is a collection of weak TATA elements. Analysis of promoters containing two biochemically defined TATA elements indicates that differential utilization occurs when the upstream TATA element is weaker than the downstream element. In other situations, the upstream TATA element is preferentially utilized in a manner that is independent of the overall level of transcription. Thus, in promoters containing multiple TATA elements, relative utilization not only depends on the quality and arrangement of the TATA elements but can vary with the overall level of transcriptional stimulation. We suggest that differential TATA utilization results from the combination of an intrinsic preference for the upstream element and functional saturation of weak TATA elements at low levels of transcriptional stimulation.

Promoter elements of the PHR1 gene of Saccharomyces cerevisiae and their roles in the response to DNA damage

The PHR1 gene of Saccharomyces cerevisiae encodes the apoenzyme for the DNA repair enzyme photolyase. PHR1 transcription is induced in response to 254 nm radiation and a variety of chemical damaging agents. We report here the identification of promoter elements required for PHR1 expression. Transcription is regulated primarily through three sequence elements clustered within a 120 bp region immediately upstream of the translational start site. A 20 bp interrupted palindrome comprises UASPHR1 and is responsible for 80-90% of basal and induced expression. UASPHR1 alone can activate transcription of a CYC1 minimal promoter but does not confer damage responsiveness. In the intact PHR1 promoter UAS function is dependent upon an upstream essential sequence (UES). URSPHR1 contains a binding site for the damage-responsive repressor Prp; consistent with this role, deletion or specific mutations of the URS increase basal level expression and decrease the induction ratio. Deletion of URSPHR1 also eliminates the requirement for UESPHR1 for promoter activation, indicating that the UES attenuates Prp-mediated repression. Sequences within UASPHR1 are similar to regulatory sequences found upstream of both damage responsive and nonresponsive genes involved in DNA repair and metabolism.

Functional analysis of the ABF1-binding sites within the Ya regions of the MATa and HMRa loci of Saccharomyces cerevisiae

Cell type in the yeast Saccharomyces cerevisiae is determined by information present at the MAT locus. Cells can switch mating types when cell-type information located at a silent locus, HML or HMR, is transposed to the MAT locus. The HML and HMR loci are kept silent through the action of a number of proteins, one of which is the DNA-binding protein, ABF1. We have identified a binding site for ABF1 within the Ya region of MATa and HMRa. In order to examine the function of this ABF1-binding site, we have constructed strains that lack the site in the MATa or HMRa loci. Consistent with the idea that ABF1 plays a redundant role in silencing, it was found that a triple deletion of the ABF1-binding sites at HMRE, Ya and I did not permit the expression of HMRa. We have also shown that chromosomal deletion of the binding site at MATYa had no effect on the level of cutting by the HO endonuclease nor on the amount of mating-type switching observed. Similarly, chromosomal deletion of all three ABF1-binding sites at HMRa had no effect on the directionality of mating-type switching.

Transcription activation of yeast ribosomal protein genes requires additional elements apart from binding sites for Abf1p or Rap1p

All ribosomal protein (rp) gene promoters from Saccharomyces cerevisiae studied so far contain either (usually two) binding sites for the global gene regulator Rap1p or one binding site for another global factor, Abf1p. Previous analysis of the rpS33 and rpL45 gene promoters suggested that apart from the Abf1 binding site, additional cis-acting elements play a part in transcription activation of these genes. We designed a promoter reconstruction system based on the beta-glucuronidase reporter gene to examine the role of the Abf1 binding site and other putative cis-acting elements in promoting transcription. An isolated Abf1 binding site turned out to be a weak activating element. A T-rich sequence derived from the rpS33 proximal promoter was found to be stronger, but full transcription activation was only achieved by a combination of these elements. Both in the natural rpL45 promoter and in the reconstituted promoter, a Rap1 binding site could functionally replace the Abf1 binding site. Characteristic rp gene nutritional control of transcription, evoked by a carbon source upshift or by nitrogen re-feeding to nitrogen starved cells, could only be mediated by the combined Abf1 (or Rap1) binding site and T-rich element and not by the individual elements. These results demonstrate that Abf1p and Rap1p do not activate rp genes in a prototypical fashion, but rather may serve to potentiate transcription activation through the T-rich element.

Role of the Saccharomyces cerevisiae general regulatory factor CP1 in methionine biosynthetic gene transcription

Saccharomyces cerevisiae general regulatory factor CP1 (encoded by the gene CEP1) is required for optimal chromosome segregation and methionine prototrophy. MET16-CYC1-lacZ reporter constructs were used to show that MET16 5'-flanking DNA contains a CP1-dependent upstream activation sequence (UAS). Activity of the UAS required an intact CP1-binding site, and the effects of cis-acting mutations on CP1 binding and UAS activity correlated. In most respects, MET16-CYC1-lacZ reporter gene expression mirrored that of chromosomal MET16; however, the endogenous gene was found to be activated in response to amino acid starvation (general control). The latter mechanism was both GCN4 and CP1 dependent. MET25 was also found to be activated by GCN4, albeit weakly. More importantly, MET25 transcription was strongly CP1 dependent in gcn4 backgrounds. The modulation of MET gene expression by GCN4 can explain discrepancies in the literature regarding CP1 dependence of MET gene transcription. Lastly, micrococcal nuclease digestion and indirect end labeling were used to analyze the chromatin structure of the MET16 locus in wild-type and cep1 cells. The results indicated that CP1 plays no major role in configuring chromatin structure in this region, although localized CP1-specific differences in nuclease sensitivity were detected.

Cell cycle-dependent transcription of CLN2 is conferred by multiple distinct cis-acting regulatory elements

The budding yeast Saccharomyces cerevisiae CLN1, CLN2, and CLN3 genes encode functionally redundant G1 cyclins required for cell cycle initiation. CLN1 and CLN2 mRNAs accumulate periodically throughout the cell cycle, peaking in late G1. We show that cell cycle-dependent fluctuation in CLN2 mRNA is regulated at the level of transcriptional initiation. Mutational analysis of the CLN2 promoter revealed that the major cell cycle-dependent upstream activating sequence (UAS) resides within a 100-bp fragment. This UAS contains three putative SWI4-dependent cell cycle boxes (SCBs) and two putative MluI cell cycle boxes (MCBs). Mutational inactivation of these elements substantially decreased CLN2 promoter activity but failed to eliminate periodic transcription. Similarly, inactivation of SWI4 decreased CLN2 transcription without affecting its periodicity. We have identified a second UAS in the CLN2 upstream region that can promote cell cycle-dependent transcription with kinetics similar to that of the intact CLN2 promoter. Unlike the major CLN2 UAS, this newly identified UAS promotes transcription in cells arrested in G1 by inactivation of cdc28. This novel UAS is both necessary and sufficient for regulated transcription driven by a CLN2 promoter lacking functional SCBs and MCBs. Although this UAS itself contains no SCBs or MCBs, its activity is dependent upon SWI4 function. The characteristics of this novel UAS suggest that it might have a role in initiating CLN2 expression early in G1 to activate the positive feedback loop that drives maximal Cln accumulation.

RPK1, an essential yeast protein kinase involved in the regulation of the onset of mitosis, shows homology to mammalian dual-specificity kinases

We report here the sequence of RPK1 (for Regulatory cell Proliferation Kinase), a new Saccharomyces cerevisiae gene coding for a protein with sequence similarities to serine/threonine protein kinases. The protein sequence of 764 amino acids includes an amino-terminal domain (residues 1-410), which may be involved in regulation of the kinase domain (residues 411-764). The catalytic domain of Rpk1 is not closely related to other known yeast protein kinases but exhibits strong homology to a newly discovered group of mammalian kinases (PYT, TTK, esk) with serine/threonine/tyrosine kinase activity. Null alleles of RPK1 are lethal and thus this gene belongs to the small group of yeast protein kinase genes that are essential for cell growth. In addition, eliminating the expression of RPK1 gives rise to the accumulation of non-viable cells with less than a 1 N DNA content suggesting that cells proceed into mitosis without completion of DNA synthesis. Therefore, the Rpk1 kinase may function in a checkpoint control which couples DNA replication to mitosis. The level of the RPK1 transcript is extremely low and constant throughout the mitotic cycle. However it is regulated during cellular differentiation, being decreased in alpha-factor-treated a cells and increased late in meiosis in a/alpha diploids. Taken together, our results suggest that Rpk1 is involved in a pathway that coordinates cell proliferation and differentiation.

Functional analysis of mouse Hoxa-7 in Saccharomyces cerevisiae: sequences outside the homeodomain base contact zone influence binding and activation

The murine developmental control gene product, Hoxa-7, was shown to function as a DNA-binding transactivator in Saccharomyces cerevisiae. The importance of the ATTA core, the preference for antp class flanking nucleotides, the importance of Asn-51 of the homeodomain (HD), and the synergism of multiple binding sites all reflect properties that have previously been described for HOM or Hox proteins in tissue culture systems. A comparison of contact positions among genes of paralog groups and classes of mammalian HDs points to a lack of diversity in positions that make base contact, suggesting that besides the combination of HD amino acid-base pair contacts, another means of recognizing differences between targets must exist if Hox genes select different targets. The HD of antennapedia is identical to the Hoxa-7 HD. The interaction of Hoxa-7 with the exact sequence used in the nuclear magnetic resonance three-dimensional structural analysis on the antennapedia HD was studied. Hoxa-7 binding and transactivation was influenced by sequences outside of the known base contact zone of this site. We conclude that Hoxa-7 protein has a second means to interact with DNA or/and that the sequences flanking the base contact zone influence HD interactions by distorting DNA within the contact zone (base or backbone). This result is discussed in terms of DNA flexure and two modes of transcription used in S. cerevisiae.

Functional analysis of mouse Hoxa-7 in Saccharomyces cerevisiae: sequences outside the homeodomain base contact zone influence binding and activation

The murine developmental control gene product, Hoxa-7, was shown to function as a DNA-binding transactivator in Saccharomyces cerevisiae. The importance of the ATTA core, the preference for antp class flanking nucleotides, the importance of Asn-51 of the homeodomain (HD), and the synergism of multiple binding sites all reflect properties that have previously been described for HOM or Hox proteins in tissue culture systems. A comparison of contact positions among genes of paralog groups and classes of mammalian HDs points to a lack of diversity in positions that make base contact, suggesting that besides the combination of HD amino acid-base pair contacts, another means of recognizing differences between targets must exist if Hox genes select different targets. The HD of antennapedia is identical to the Hoxa-7 HD. The interaction of Hoxa-7 with the exact sequence used in the nuclear magnetic resonance three-dimensional structural analysis on the antennapedia HD was studied. Hoxa-7 binding and transactivation was influenced by sequences outside of the known base contact zone of this site. We conclude that Hoxa-7 protein has a second means to interact with DNA or/and that the sequences flanking the base contact zone influence HD interactions by distorting DNA within the contact zone (base or backbone). This result is discussed in terms of DNA flexure and two modes of transcription used in S. cerevisiae.

Saccharomyces cerevisiae BUF protein binds to sequences participating in DNA replication in addition to those mediating transcriptional repression (URS1) and activation

The heteromeric BUF protein was originally shown to bind to URS1 elements which are situated upstream of many genes in Saccharomyces cerevisiae and mediate negative control of their transcription. Among the genes regulated through the URS1 site and the proteins interacting with it are those participating in carbon, nitrogen, and inositol metabolism; electron transport; meiosis; sporulation; and mating-type switching. We show here that pure BUF protein, in addition to binding to the negatively acting URS1 site, also binds to CAR1 sequences supporting transcriptional activation (upstream activation sequences). To determine the BUF protein structure, we cloned and sequenced the BUF1 and BUF2 genes and found them to be identical to the RF-A (RP-A) gene whose products participate in yeast DNA replication as single-stranded DNA binding proteins. These data argue that BUF protein-binding sites serve multiple roles in transcription and replication.

Saccharomyces cerevisiae BUF protein binds to sequences participating in DNA replication in addition to those mediating transcriptional repression (URS1) and activation

The heteromeric BUF protein was originally shown to bind to URS1 elements which are situated upstream of many genes in Saccharomyces cerevisiae and mediate negative control of their transcription. Among the genes regulated through the URS1 site and the proteins interacting with it are those participating in carbon, nitrogen, and inositol metabolism; electron transport; meiosis; sporulation; and mating-type switching. We show here that pure BUF protein, in addition to binding to the negatively acting URS1 site, also binds to CAR1 sequences supporting transcriptional activation (upstream activation sequences). To determine the BUF protein structure, we cloned and sequenced the BUF1 and BUF2 genes and found them to be identical to the RF-A (RP-A) gene whose products participate in yeast DNA replication as single-stranded DNA binding proteins. These data argue that BUF protein-binding sites serve multiple roles in transcription and replication.

Mutational analysis of the Saccharomyces cerevisiae general regulatory factor CP1

The Saccharomyces cerevisiae general regulatory factor CP1, a helix-loop-helix protein that binds the centromere DNA element I (CDEI) of yeast centromeres, is required in yeast for optimal centromere function and for methionine prototrophy. Mutant alleles of CEP1, the gene encoding CP1, were generated by linker insertion, 5'- and 3'-deletion, and random mutagenesis and assayed for DNA binding activity and their ability to confer CP1 function when expressed in yeast. A heterologous CDEI-binding protein, TFEB, was also tested for CP1 function. The results suggested that DNA binding is required for both biological functions of CP1 but is not sufficient. A direct and quantitative correlation was observed between the chromosome loss and nutritional (i.e., Met) phenotypes of strains carrying loss of function alleles, but qualitatively the chromosome loss phenotype was more sensitive to decreased CP1 expression. The data are consistent with a model in which CP1 performs the same general chromatin-related function at centromeres and MET gene promoters and is normally present in functional excess.

Association of nucleosome-free regions and basal transcription factors with in vivo-assembled chromatin templates active in vitro

Using SV40 minichromosomes assembled in vivo, we have studied the relationship between a nucleosome-free promoter-region and initiation of transcription by RNA polymerase II on chromatin templates in vitro. Our data suggest that accessibility of DNA to transcription factors, programmed into the structure of the chromatin, is crucial for initiation of transcription. First, minichromosomes competent to be transcribed in vitro contained nucleosome-free promoter regions. Second, tsC219 minichromosomes, most of which contain the nucleosome-free promoter region, supported transcription more efficiently both in vivo and in vitro than wild-type minichromosomes, in which only a subset contain the nucleosome-free region. We have also identified basal transcription factors associated with the in vivo-assembled chromatin templates. A striking correlation was observed between minichromosomes associated with in vivo initiated RNA polymerases and those associated with the basal transcription factors TFIID and TFIIE/F, and to a lesser extent, TFIIB. Of these associated factors, only TFIID was poised for ready assembly into preinitiation complexes and therefore for subsequent initiation of transcription. However, an active chromatin template could also be maintained in the absence of the binding of TFIID. Finally, our data are consistent with the presence of TFIIF in elongating ternary complexes on the chromatin templates.

A complex regulatory element from the yeast gene ENO2 modulates GCR1-dependent transcriptional activation

The GCR1 gene product is required for maximal transcription of many yeast genes including genes encoding glycolytic enzymes. Transcription of the yeast enolase gene ENO2 is reduced 50-fold in strains carrying a gcr1 null mutation. cis-acting sequences that are sufficient for GCR1-dependent regulation of ENO2 expression were identified by using an enhancerless CYC1 promoter which is not normally dependent on GCR1 for expression. A 60-bp ENO2 sequence that was sufficient to provide high-level, GCR1-dependent transcriptional activation of the CYC1 promoter was identified. This 60-bp element could be subdivided into a 30-bp sequence containing a novel RAP1-binding site and a GCR1-binding site which did not activate CYC1 transcription and a 30-bp sequence containing a novel enhancer element that conferred moderate levels of GCR1-independent transcriptional activation. The 60-bp CGCR1-dependent upstream activator sequence is located immediately downstream from previously mapped overlapping binding sites for the regulatory proteins ABFI and RAP1. Evidence is presented that the overlapping ABFI- and RAP1-binding sites function together with sequences that bind GCR1 and RAP1 to stage transcriptional activation of ENO2 expression.

A complex regulatory element from the yeast gene ENO2 modulates GCR1-dependent transcriptional activation

The GCR1 gene product is required for maximal transcription of many yeast genes including genes encoding glycolytic enzymes. Transcription of the yeast enolase gene ENO2 is reduced 50-fold in strains carrying a gcr1 null mutation. cis-acting sequences that are sufficient for GCR1-dependent regulation of ENO2 expression were identified by using an enhancerless CYC1 promoter which is not normally dependent on GCR1 for expression. A 60-bp ENO2 sequence that was sufficient to provide high-level, GCR1-dependent transcriptional activation of the CYC1 promoter was identified. This 60-bp element could be subdivided into a 30-bp sequence containing a novel RAP1-binding site and a GCR1-binding site which did not activate CYC1 transcription and a 30-bp sequence containing a novel enhancer element that conferred moderate levels of GCR1-independent transcriptional activation. The 60-bp CGCR1-dependent upstream activator sequence is located immediately downstream from previously mapped overlapping binding sites for the regulatory proteins ABFI and RAP1. Evidence is presented that the overlapping ABFI- and RAP1-binding sites function together with sequences that bind GCR1 and RAP1 to stage transcriptional activation of ENO2 expression.

The rRNA enhancer regulates rRNA transcription in Saccharomyces cerevisiae

In Saccharomyces cerevisiae, the rRNA genes are organized as a tandem array of head-to-tail repeats. An enhancer of rRNA transcription is present just at the end of each transcription unit, 2 kb away from the next one. This enhancer is unusual for S. cerevisiae in that it acts both upstream and downstream of, and even across, genes. The role of the enhancer in the nutritional regulation of rRNA transcription was studied by introducing a centromere plasmid carrying two rRNA minigenes in tandem, flanking a single enhancer, into cells. Analysis of the transcripts from the two minigenes showed that the enhancer was absolutely required for the stimulation of transcription of rRNA that occurs when cells are shifted from a poor carbon source to a good carbon source. While full enhancer function is provided by a 45-bp region at the 3' end of the 190-bp enhancer, some activity was also conferred by other elements, including both a T-rich stretch and a region containing the binding sites for the proteins Reb1p and Abf1p. We conclude that the enhancer is composed of redundant elements and that it is a major element in the regulation of rRNA transcription.

The rRNA enhancer regulates rRNA transcription in Saccharomyces cerevisiae

In Saccharomyces cerevisiae, the rRNA genes are organized as a tandem array of head-to-tail repeats. An enhancer of rRNA transcription is present just at the end of each transcription unit, 2 kb away from the next one. This enhancer is unusual for S. cerevisiae in that it acts both upstream and downstream of, and even across, genes. The role of the enhancer in the nutritional regulation of rRNA transcription was studied by introducing a centromere plasmid carrying two rRNA minigenes in tandem, flanking a single enhancer, into cells. Analysis of the transcripts from the two minigenes showed that the enhancer was absolutely required for the stimulation of transcription of rRNA that occurs when cells are shifted from a poor carbon source to a good carbon source. While full enhancer function is provided by a 45-bp region at the 3' end of the 190-bp enhancer, some activity was also conferred by other elements, including both a T-rich stretch and a region containing the binding sites for the proteins Reb1p and Abf1p. We conclude that the enhancer is composed of redundant elements and that it is a major element in the regulation of rRNA transcription.

The REB1 site is an essential component of a terminator for RNA polymerase I in Saccharomyces cerevisiae

We have identified a terminator for transcription by RNA polymerase I in the genes coding for rRNA of the yeast Saccharomyces cerevisiae. The terminator is located 108 bp downstream of the 3' end of the mature 25S rRNA and shares several characteristics with previously studied polymerase I terminators in the vertebrates. For example, the yeast terminator is orientation dependent, is inhibited by its own sequence, and forms RNA 3' ends 17 +/- 2 bp upstream of an essential protein binding site. The recognition sequence for binding of the previously cloned REB1 protein (Q. Ju, B. E. Morrow, and J. R. Warner, Mol. Cell. Biol. 10:5226-5234, 1990) is an essential component of the terminator. In addition, the efficiency of termination depends upon sequence context extending at least 12 bp upstream of the REB1 site.

The REB1 site is an essential component of a terminator for RNA polymerase I in Saccharomyces cerevisiae

We have identified a terminator for transcription by RNA polymerase I in the genes coding for rRNA of the yeast Saccharomyces cerevisiae. The terminator is located 108 bp downstream of the 3' end of the mature 25S rRNA and shares several characteristics with previously studied polymerase I terminators in the vertebrates. For example, the yeast terminator is orientation dependent, is inhibited by its own sequence, and forms RNA 3' ends 17 +/- 2 bp upstream of an essential protein binding site. The recognition sequence for binding of the previously cloned REB1 protein (Q. Ju, B. E. Morrow, and J. R. Warner, Mol. Cell. Biol. 10:5226-5234, 1990) is an essential component of the terminator. In addition, the efficiency of termination depends upon sequence context extending at least 12 bp upstream of the REB1 site.

A REB1-binding site is required for GCN4-independent ILV1 basal level transcription and can be functionally replaced by an ABF1-binding site

The ILV1 gene of Saccharomyces cerevisiae encodes the first committed step in isoleucine biosynthesis and is regulated by general control of amino acid biosynthesis. Deletion analysis of the ILV1 promoter revealed a GC-rich element important for the basal level expression. This cis-acting element, called ILV1BAS, is functional independently of whether GCN4 protein is present. Furthermore, unlike the situation at HIS4, the magnitude of GCN4-mediated derepression is independent of ILV1BAS. The element has homology to the consensus REB1-binding sequence CGGGTARNNR. Gel retardation assays showed that REB1 binds specifically to this element. We show that REB1-binding sites normally situated in the SIN3 promoter and in the 35S rRNA promoter can substitute for the ILV1 REB1 site. Furthermore, a SIN3 REB1 site containing a point mutation that abolishes REB1 binding does not support ILV1 basal level expression, suggesting that binding of REB1 is important for the control of ILV1 basal level expression. Interestingly, an ABF1-binding site can also functionally replace the ILV1 REB1-binding site. A mutated ABF1 site that displays a very low affinity for ABF1 does not functionally replace the ILV1 REB1 site. This suggests that ABF1 and REB1 may have related functions within the cell. Although the REB1-binding site is required for the ILV1 basal level expression, the site on its own stimulates transcription only slightly when combined with the CYC1 downstream promoter elements, indicating that another ILV1 promoter element functions in combination with the REB1 site to control high basal level expression.

A REB1-binding site is required for GCN4-independent ILV1 basal level transcription and can be functionally replaced by an ABF1-binding site

The ILV1 gene of Saccharomyces cerevisiae encodes the first committed step in isoleucine biosynthesis and is regulated by general control of amino acid biosynthesis. Deletion analysis of the ILV1 promoter revealed a GC-rich element important for the basal level expression. This cis-acting element, called ILV1BAS, is functional independently of whether GCN4 protein is present. Furthermore, unlike the situation at HIS4, the magnitude of GCN4-mediated derepression is independent of ILV1BAS. The element has homology to the consensus REB1-binding sequence CGGGTARNNR. Gel retardation assays showed that REB1 binds specifically to this element. We show that REB1-binding sites normally situated in the SIN3 promoter and in the 35S rRNA promoter can substitute for the ILV1 REB1 site. Furthermore, a SIN3 REB1 site containing a point mutation that abolishes REB1 binding does not support ILV1 basal level expression, suggesting that binding of REB1 is important for the control of ILV1 basal level expression. Interestingly, an ABF1-binding site can also functionally replace the ILV1 REB1-binding site. A mutated ABF1 site that displays a very low affinity for ABF1 does not functionally replace the ILV1 REB1 site. This suggests that ABF1 and REB1 may have related functions within the cell. Although the REB1-binding site is required for the ILV1 basal level expression, the site on its own stimulates transcription only slightly when combined with the CYC1 downstream promoter elements, indicating that another ILV1 promoter element functions in combination with the REB1 site to control high basal level expression.

At least three distinct proteins are necessary for the reconstitution of a specific multiprotein complex at a eukaryotic chromosomal origin of replication

We have reconstituted in vitro a multistage assembly of a protein complex that specifically recognizes a yeast genomic origin of replication, the autonomously replicating sequence ARS121. The first step in the assembly was the interaction of the known origin-binding factor OBF1 and another factor, OBF2, with the ARS121 origin of replication to form the OBF1-OBF2-origin complex. This complex was the substrate for the ATP-dependent binding of a third DNA-binding activity, the core binding factor, CBF. Binding of CBF to the origin, identified by the retarded mobility of the origin DNA fragment in agarose gels, required, in addition to ATP and the OBF1-OBF2-origin complex, a functional essential core nucleotide sequence. ARS121 DNA containing mutations in the core, which inactivate the origin in vivo, did not sustain stable CBF binding, whereas ARS121 DNA mutated outside the boundaries of the essential core, which has normal origin function, bound CBF as wild type. This tight, direct correlation between the ability of the origin to bind CBF and its function as an origin of replication in vivo strongly suggest that the multiprotein complex reconstituted in vitro has a key role in the initiation of DNA replication.

Molecular cloning of the gene for the yeast homolog (ACB) of diazepam binding inhibitor/endozepine/acyl-CoA-binding protein

Diazepam binding inhibitor (DBI)/endozepine (EP)/acyl-CoA-binding protein (ACBP) is a small, highly conserved protein which has been independently isolated and characterized from different species using several different biological systems. To further investigate the structural and functional properties of this protein, we have cloned the homologous gene for DBI/EP/ACBP from the budding yeast Saccharomyces cerevisiae. The yeast gene contains no introns and encodes a polypeptide of 87 amino acids (including the initiating methionine), identical in length to the human gene product with 48% conservation of amino acid residues. The most highly conserved domain consists of 7 contiguous residues which are identical in all known protein species from yeast, birds, and mammals. This domain has previously been shown to constitute the hydrophobic binding site on DBI/EP/ACBP for acyl-CoA esters and is located within the second helical region of the molecule. Major and minor mRNA species of approximately 520 and 740 nucleotides, respectively, were detected in exponentially growing yeast. Sequences similar to those implicated in the regulation of fatty acid synthesis and beta-oxidation in yeast were detected in the promoter region of the gene. The presence of a highly conserved DBI/EP/ACBP gene in a primitive organism such as yeast provides support for the basic biological role of DBI/EP/ACBP as an acyl-CoA-binding protein and suggests that many of the biological functions attributed to it in higher organisms may result from its ability to interact with acyl-CoA. Hence, we have designated the yeast gene as ACB, for acyl-CoA-binding protein.

Silencers, silencing, and heritable transcriptional states

Three copies of the mating-type genes, which determine cell type, are found in the budding yeast Saccharomyces cerevisiae. The copy at the MAT locus is transcriptionally active, whereas identical copies of the mating-type genes at the HML and HMR loci are transcriptionally silent. Hence, HML and HMR, also known as the silent mating-type loci, are subject to a position effect. Regulatory sequences flank the silent mating-type loci and mediate repression of HML and HMR. These regulatory sequences are called silencers for their ability to repress the transcription of nearby genes in a distance- and orientation-independent fashion. In addition, a number of proteins, including the four SIR proteins, histone H4, and an alpha-acetyltransferase, are required for the complete repression of HML and HMR. Because alterations in the amino-terminal domain of histone H4 result in the derepression of the silent mating-type loci, the mechanism of repression may involve the assembly of a specific chromatin structure. A number of additional clues permit insight into the nature of repression at HML and HMR. First, an S phase event is required for the establishment of repression. Second, at least one gene appears to play a role in the establishment mechanism yet is not essential for the stable propagation of repression through many rounds of cell division. Third, certain aspects of repression are linked to aspects of replication. The silent mating-type loci share many similarities with heterochromatin. Furthermore, regions of S. cerevisiae chromosomes, such as telomeres, which are known to be heterochromatic in other organisms, require a subset of SIR proteins for repression. Further analysis of the transcriptional repression at the silent mating-type loci may lend insight into heritable repression in other eukaryotes.

ABF1 is a phosphoprotein and plays a role in carbon source control of COX6 transcription in Saccharomyces cerevisiae

Previously, we have shown that the Saccharomyces cerevisiae DNA-binding protein ABF1 exists in at least two different electrophoretic forms (K. S. Sweder, P. R. Rhode, and J. L. Campbell, J. Biol. Chem. 263: 17270-17277, 1988). In this report, we show that these forms represent different states of phosphorylation of ABF1 and that at least four different phosphorylation states can be resolved electrophoretically. The ratios of these states to one another differ according to growth conditions and carbon source. Phosphorylation of ABF1 is therefore a regulated process. In nitrogen-starved cells or in cells grown on nonfermentable carbon sources (e.g., lactate), phosphorylated forms predominate, while in cells grown on fermentable carbon sources (e.g., glucose), dephosphorylated forms are enriched. The phosphorylation pattern is affected by mutations in the SNF1-SSN6 pathway, which is involved in glucose repression-depression. Whereas a functional SNF1 gene, which encodes a protein kinase, is not required for the phosphorylation of ABF1, a functional SSN6 gene is required for itsd ephosphorylation. The phosphorylation patterns that we have observed correlate with the regulation of a specific target gene, COX6, which encodes subunit VI of cytochrome c oxidase. Transcription of COX6 is repressed by growth in medium containing a fermentable carbon source and is derepressed by growth in medium containing a nonfermentable carbon source. COX6 repression-derepression is under the control of the SNF1-SSN6 pathway. This carbon source regulation is exerted through domain 1, a region of the upstream activation sequence UAS6 that binds ABF1 (J. D. Trawick, N. Kraut, F. Simon, and R. O. Poyton, Mol. Cell Biol. 12:2302-2314, 1992). We show that the greater the phosphorylation of ABF1, the greater the transcription of COX6. Furthermore, the ABF1-containing protein-DNA complexes formed at domain 1 differ according to the phosphorylation state of ABF1 and the carbon source on which the cells were grown. From these findings, we propose that the phosphorylation of ABF1 is involved in glucose repression-derepression of COX6 transcription.

ABF1 is a phosphoprotein and plays a role in carbon source control of COX6 transcription in Saccharomyces cerevisiae

Previously, we have shown that the Saccharomyces cerevisiae DNA-binding protein ABF1 exists in at least two different electrophoretic forms (K. S. Sweder, P. R. Rhode, and J. L. Campbell, J. Biol. Chem. 263: 17270-17277, 1988). In this report, we show that these forms represent different states of phosphorylation of ABF1 and that at least four different phosphorylation states can be resolved electrophoretically. The ratios of these states to one another differ according to growth conditions and carbon source. Phosphorylation of ABF1 is therefore a regulated process. In nitrogen-starved cells or in cells grown on nonfermentable carbon sources (e.g., lactate), phosphorylated forms predominate, while in cells grown on fermentable carbon sources (e.g., glucose), dephosphorylated forms are enriched. The phosphorylation pattern is affected by mutations in the SNF1-SSN6 pathway, which is involved in glucose repression-depression. Whereas a functional SNF1 gene, which encodes a protein kinase, is not required for the phosphorylation of ABF1, a functional SSN6 gene is required for itsd ephosphorylation. The phosphorylation patterns that we have observed correlate with the regulation of a specific target gene, COX6, which encodes subunit VI of cytochrome c oxidase. Transcription of COX6 is repressed by growth in medium containing a fermentable carbon source and is derepressed by growth in medium containing a nonfermentable carbon source. COX6 repression-derepression is under the control of the SNF1-SSN6 pathway. This carbon source regulation is exerted through domain 1, a region of the upstream activation sequence UAS6 that binds ABF1 (J. D. Trawick, N. Kraut, F. Simon, and R. O. Poyton, Mol. Cell Biol. 12:2302-2314, 1992). We show that the greater the phosphorylation of ABF1, the greater the transcription of COX6. Furthermore, the ABF1-containing protein-DNA complexes formed at domain 1 differ according to the phosphorylation state of ABF1 and the carbon source on which the cells were grown. From these findings, we propose that the phosphorylation of ABF1 is involved in glucose repression-derepression of COX6 transcription.

A single-stranded DNA-binding protein from Crithidia fasciculata recognizes the nucleotide sequence at the origin of replication of kinetoplast DNA minicircles

A sequence-specific single-stranded DNA-binding protein from the trypanosomatid protozoan Crithidia fasciculata binds to a sequence of 12 nucleotides located at the origin of replication of kinetoplast DNA minicircles. This sequence, termed the universal minicircle sequence (UMS), is conserved in the kinetoplast DNA minicircles among species of the family Trypanosomatidae. The purified protein binds specifically to the heavy strand of the DNA at this site, which consists of the sequence 5'-GGGGTTGGTGTA-3'. Binding analyses using mutated UMS dodecamers have revealed the significant contribution of each of the individual residues at the binding site, with the exception of the 3'-terminal adenine residue, to the generation of specific protein-DNA complexes. The possible role of this sequence-specific single-stranded DNA-binding protein in replication of kinetoplast DNA minicircles and the relation of the UMS to chromosomal telomeric sequences are discussed.

Global regulators of chromosome function in yeast

In the yeast Saccharomyces cerevisiae, several abundant, sequence-specific DNA binding proteins are involved in multiple aspects of chromosome function. In addition to functioning as transcriptional activators of a large number of yeast genes, they are also involved in transcriptional silencing, the initiation of DNA replication, centromere function and regulation of telomere length. This review will consider each of these proteins, focusing on what is known about the mechanisms of their multiple functions.

Global regulation of mitochondrial biogenesis in Saccharomyces cerevisiae: ABF1 and CPF1 play opposite roles in regulating expression of the QCR8 gene, which encodes subunit VIII of the mitochondrial ubiquinol-cytochrome c oxidoreductase

The multifunctional DNA-binding proteins ABF1 and CPF1 bind in a mutually exclusive manner to the promoter region of the QCR8 gene, which encodes 11-kDa subunit VIII of the Saccharomyces cerevisiae mitochondrial ubiquinol-cytochrome c oxidoreductase (QCR). We investigated the roles that the two factors play in transcriptional regulation of this gene. To this end, the overlapping binding sites for ABF1 and CPF1 were mutated and placed in the chromosomal context of the QCR8 promoter. The effects on transcription of the QCR8 gene were analyzed both under steady-state conditions and during nutritional shifts. We found that ABF1 is required for repressed and derepressed transcription levels and for efficient induction of transcription upon escape from catabolite repression, independently of DNA replication. CPF1 acts as a negative regulator, modulating the overall induction response. Alleviation of repression through CPF1 requires passage through the S phase. Implications of these findings for the roles played by ABF1 and CPF1 in global regulation of mitochondrial biogenesis are discussed.

Global regulation of mitochondrial biogenesis in Saccharomyces cerevisiae: ABF1 and CPF1 play opposite roles in regulating expression of the QCR8 gene, which encodes subunit VIII of the mitochondrial ubiquinol-cytochrome c oxidoreductase

The multifunctional DNA-binding proteins ABF1 and CPF1 bind in a mutually exclusive manner to the promoter region of the QCR8 gene, which encodes 11-kDa subunit VIII of the Saccharomyces cerevisiae mitochondrial ubiquinol-cytochrome c oxidoreductase (QCR). We investigated the roles that the two factors play in transcriptional regulation of this gene. To this end, the overlapping binding sites for ABF1 and CPF1 were mutated and placed in the chromosomal context of the QCR8 promoter. The effects on transcription of the QCR8 gene were analyzed both under steady-state conditions and during nutritional shifts. We found that ABF1 is required for repressed and derepressed transcription levels and for efficient induction of transcription upon escape from catabolite repression, independently of DNA replication. CPF1 acts as a negative regulator, modulating the overall induction response. Alleviation of repression through CPF1 requires passage through the S phase. Implications of these findings for the roles played by ABF1 and CPF1 in global regulation of mitochondrial biogenesis are discussed.