Cloning of yeast HAP5: a novel subunit of a heterotrimeric complex required for CCAAT binding

Identifying cooperative transcriptional regulations using protein-protein interactions

Cooperative transcriptional activations among multiple transcription factors (TFs) are important to understand the mechanisms of complex transcriptional regulations in eukaryotes. Previous studies have attempted to find cooperative TFs based on gene expression data with gene expression profiles as a measure of similarity of gene regulations. In this paper, we use protein-protein interaction data to infer synergistic binding of cooperative TFs. Our fundamental idea is based on the assumption that genes contributing to a similar biological process are regulated under the same control mechanism. First, the protein-protein interaction networks are used to calculate the similarity of biological processes among genes. Second, we integrate this similarity and the chromatin immuno-precipitation data to identify cooperative TFs. Our computational experiments in yeast show that predictions made by our method have successfully identified eight pairs of cooperative TFs that have literature evidences but could not be identified by the previous method. Further, 12 new possible pairs have been inferred and we have examined the biological relevances for them. However, since a typical problem using protein-protein interaction data is that many false-positive data are contained, we propose a method combining various biological data to increase the prediction accuracy.

Subunits of the heterotrimeric transcription factor NF-Y are imported into the nucleus by distinct pathways involving importin beta and importin 13

The transcriptional activator NF-Y is a heterotrimeric complex composed of NF-YA, NF-YB, and NF-YC, which specifically binds the CCAAT consensus present in about 30% of eukaryotic promoters. All three subunits contain evolutionarily conserved core regions, which comprise a histone fold motif (HFM) in the case of NF-YB and NF-YC. Our results of in vitro binding studies and nuclear import assays reveal two different transport mechanisms for NF-Y subunits. While NF-YA is imported by an importin beta-mediated pathway, the NF-YB/NF-YC heterodimer is translocated into the nucleus in an importin 13-dependent manner. We define a nonclassical nuclear localization signal (ncNLS) in NF-YA, and mutational analysis indicates that positively charged amino acid residues in the ncNLS are required for nuclear targeting of NF-YA. Importin beta binding is restricted to the monomeric, uncomplexed NF-YA subunit. In contrast, the nuclear import of NF-YB and NF-YC requires dimer formation. Only the NF-YB/NF-YC dimer, but not the monomeric components, are recognized by importin 13 and are imported into the nucleus. Importin 13 competes with NF-YA for binding to the NF-YB/NF-YC dimer. Our data suggest that a distinct binding platform derived from the HFM of both subunits, NF-YB/NF-YC, mediates those interactions.

Motifs, themes and thematic maps of an integrated Saccharomyces cerevisiae interaction network

BACKGROUND

Large-scale studies have revealed networks of various biological interaction types, such as protein-protein interaction, genetic interaction, transcriptional regulation, sequence homology, and expression correlation. Recurring patterns of interconnection, or 'network motifs', have revealed biological insights for networks containing either one or two types of interaction.

RESULTS

To study more complex relationships involving multiple biological interaction types, we assembled an integrated Saccharomyces cerevisiae network in which nodes represent genes (or their protein products) and differently colored links represent the aforementioned five biological interaction types. We examined three- and four-node interconnection patterns containing multiple interaction types and found many enriched multi-color network motifs. Furthermore, we showed that most of the motifs form 'network themes' -- classes of higher-order recurring interconnection patterns that encompass multiple occurrences of network motifs. Network themes can be tied to specific biological phenomena and may represent more fundamental network design principles. Examples of network themes include a pair of protein complexes with many inter-complex genetic interactions -- the 'compensatory complexes' theme. Thematic maps -- networks rendered in terms of such themes -- can simplify an otherwise confusing tangle of biological relationships. We show this by mapping the S. cerevisiae network in terms of two specific network themes.

CONCLUSION

Significantly enriched motifs in an integrated S. cerevisiae interaction network are often signatures of network themes, higher-order network structures that correspond to biological phenomena. Representing networks in terms of network themes provides a useful simplification of complex biological relationships.

Transcriptional regulation of plant cell wall degradation by filamentous fungi

Plant cell wall consists mainly of the large biopolymers cellulose, hemicellulose, lignin and pectin. These biopolymers are degraded by many microorganisms, in particular filamentous fungi, with the aid of extracellular enzymes. Filamentous fungi have a key role in degradation of the most abundant biopolymers found in nature, cellulose and hemicelluloses, and therefore are essential for the maintenance of the global carbon cycle. The production of plant cell wall degrading enzymes, cellulases, hemicellulases, ligninases and pectinases, is regulated mainly at the transcriptional level in filamentous fungi. The genes are induced in the presence of the polymers or molecules derived from the polymers and repressed under growth conditions where the production of these enzymes is not necessary, such as on glucose. The expression of the genes encoding the enzymes is regulated by various environmental and cellular factors, some of which are common while others are more unique to either a certain fungus or a class of enzymes. This review summarises our current knowledge on the transcriptional regulation, focusing on the recently characterized transcription factors that regulate genes coding for enzymes involved in the breakdown of plant cell wall biopolymers.

A new Hansenula polymorpha HAP4 homologue which contains only the N-terminal conserved domain of the protein is fully functional in Saccharomyces cerevisiae

In Saccharomyces cerevisiae, the HAP transcriptional complex is involved in the fermentation-respiration shift. This complex is composed of four subunits. Three subunits are necessary for DNA-binding, whereas the Hap4p subunit, glucose-repressed, contains the transcriptional activation domain. Hap4p is the key regulator of the complex activity in response to carbon sources in S. cerevisiae. To date, no HAP4 homologue has been identified, except in Kluyveromyces lactis. Examination of these two HAP4 sequences led to the identification of two very short conserved peptides also identified in other yeasts. In the yeast Hansenula polymorpha, two possible HAP4 homologues have been found. Their deduced amino acid sequences are similar to the ScHap4p and KlHap4p proteins only in the N-terminal 16-amino-acid basic motif. Since molecular genetic tools exist and complete genome sequence is known for this yeast, we expressed one of these putative HpHap4 proteins in S. cerevisiae and showed that this protein is able to restore the growth defect of the S. cerevisiae hap4-deleted strain. A set of experiments was performed to confirm the functional homology of this new gene with ScHAP4. The discovery of a Hap4-regulatory protein in H. polymorpha with only the N-terminal conserved domain of the S. cerevisiae protein indicates that this domain may play a crucial role during evolution.

Identification, mutational analysis, and coactivator requirements of two distinct transcriptional activation domains of the Saccharomyces cerevisiae Hap4 protein

The Hap4 protein of the budding yeast Saccharomyces cerevisiae activates the transcription of genes that are required for growth on nonfermentable carbon sources. Previous reports suggested the presence of a transcriptional activation domain within the carboxyl-terminal half of Hap4 that can function in the absence of Gcn5, a transcriptional coactivator protein and histone acetyltransferase. The boundaries of this activation domain were further defined to a region encompassing amino acids 359 to 476. Within this region, several clusters of hydrophobic amino acids are critical for transcriptional activity. This activity does not require GCN5 or two other components of the SAGA coactivator complex, SPT3 and SPT8, but it does require SPT7 and SPT20. Contrary to previous reports, a Hap4 fragment comprising amino acids 1 to 330 can support the growth of yeast on lactate medium, and when tethered to lexA, can activate a reporter gene with upstream lexA binding sites, demonstrating the presence of a second transcriptional activation domain. In contrast to the C-terminal activation domain, the transcriptional activity of this N-terminal region depends on GCN5. We conclude that the yeast Hap4 protein has at least two transcriptional activation domains with strikingly different levels of dependence on specific transcriptional coactivator proteins.

A Single Subunit of a Heterotrimeric CCAAT-binding Complex Carries a Nuclear Localization Signal: Piggy Back Transport of the Pre-assembled Complex to the Nucleus

An unresolved question concerns the nuclear localization of the heterotrimeric CCAAT-binding complex, which is evolutionarily conserved in eukaryotic organisms including fungi, plants and mammals. All three subunits are necessary for DNA binding. In the filamentous fungus Aspergillus nidulans the corresponding complex was designated AnCF (A.nidulans CCAAT-binding factor). AnCF consists of the HapB, HapC and HapE subunits. Here, by using various green fluorescent protein constructs, a nuclear localization signal sequence (NLS) of the HapB protein was identified, outside of the evolutionarily conserved domain. HapB-EGFP was transported into the nucleus in both DeltahapC and DeltahapE strains, indicating that its NLS interacts with the import machinery independently of the other Hap subunits. In contrast, HapC-EGFP did not enter the nucleus in the absence of HapE or HapB. A similar finding was made for HapE-EGFP, which did not localize to the nucleus in the absence of HapC or HapB. Addition of the HapB-NLS to either HapC or HapE led to nuclear localization of the respective protein fusions, indicating that both HapC and HapE lack a functional NLS. Furthermore, these data strongly suggest that HapC and HapE have first to form a heterodimer and can be transported only as a heterodimer via the HapB protein into the nucleus. Therefore, the HapB subunit is the primary cargo for the import machinery, while HapC and HapE are transported to the nucleus only as a heterodimer and in complex with HapB via a piggy back mechanism. This enables the cell to provide equimolar concentrations of all subunits to the nucleus.

Human p32, interacts with B subunit of the CCAAT-binding factor, CBF/NF-Y, and inhibits CBF-mediated transcription activation in vitro

To understand the role of the CCAAT-binding factor, CBF, in transcription, we developed a strategy to purify the heterotrimeric CBF complex from HeLa cell extracts using two successive immunoaffinity chromatography steps. Here we show that the p32 protein, previously identified as the ASF/SF2 splicing factor-associated protein, copurified with the CBF complex. Studies of protein-protein interaction demonstrated that p32 interacts specifically with CBF-B subunit and also associates with CBF-DNA complex. Cellular localization by immunofluorescence staining revealed that p32 is present in the cell throughout the cytosol and nucleus, whereas CBF is present primarily in the nucleus. A portion of the p32 colocalizes with CBF-B in the nucleus. Interestingly, reconstitution of p32 in an in vitro transcription reaction demonstrated that p32 specifically inhibits CBF-mediated transcription activation. Altogether, our study identified p32 as a novel and specific corepressor of CBF-mediated transcription activation in vitro.

NFY interacts with the promoter region of two genes involved in the rat peroxisomal fatty acid beta-oxidation: the multifunctional protein type 1 and the 3-ketoacyl-CoA B thiolase

BACKGROUND

Beta-oxidation of long and very long chain fatty acyl-CoA derivatives occurs in peroxisomes, which are ubiquitous subcellular organelles of eukaryotic cells. This pathway releases acetyl-CoA as precursor for several key molecules such as cholesterol. Numerous enzymes participating to cholesterol and fatty acids biosynthesis pathways are co-localized in peroxisomes and some of their encoding genes are known as targets of the NFY transcriptional regulator. However, until now no interaction between NFY transcription factor and genes encoding peroxisomal beta-oxidation has been reported.

RESULTS

This work studied the interactions between NFY factor with the rat gene promoters of two enzymes of the fatty acid beta-oxidation, MFP-1 (multifunctional protein type 1) and ThB (thiolase B) and their involvement in the cholesterol dependent-gene regulation. Binding of this nuclear factor to the ATTGG motif of the MFP-1 and of the ThB promoters was demonstrated by EMSA (Electrophoretic Mobility Shift Assay) and super shift assay. In contrast, in spite of the presence of putative Sp1 binding sites in these promoters, competitive EMSA did not reveal any binding. The promoter-dependent luciferase gene expression was downregulated by cholesterol in MFP-1 and ThB promoters harbouring constructs.

CONCLUSIONS

This work describes for the first time a NFY interaction with promoter sequences of the peroxisomal beta-oxidation encoding genes. It suggests that cholesterol would negatively regulate the expression of genes involved in beta-oxidation, which generates the initial precursor for its own biosynthesis, via at least the NFY transcription factor.

Discovery of an inhibitor of a transcription factor using small molecule microarrays and diversity-oriented synthesis

Small molecule microarrays were screened to identify a small molecule ligand for Hap3p, a subunit of the yeast Hap2/3/4/5p transcription factor complex. The compound, named haptamide A, was determined to have a KD of 5.03 muM for binding to Hap3p using surface plasmon resonance analysis. Haptamide A also inhibited activation of a GDH1-lacZ reporter gene in a dose-dependent fashion. To explore structure-activity relationships, 11 derivatives of haptamide A were prepared using the same synthetic route that was developed for the original library synthesis. Analysis of dissociation constants and IC50 values for the reporter gene assay revealed a more potent inhibitor, haptamide B, with a KD of 330 nM. Whole-genome transcriptional profiling was used to compare effects of haptamide B with a hap3Delta yeast strain. Treatment with haptamide B, like the deletion mutant, reduced lactate-induced transcription of several genes from wild-type levels. Profiling the genetic "knockout" and the chemical genetic "knockdown" led to the identification of several genes that are regulated by Hap3p under nonfermentative conditions. These results demonstrate that a small molecule discovered using the small molecule microarray binding assay can permeate yeast cells and reach its target transcription factor protein in cells.

Transcriptional control of nonfermentative metabolism in the yeast Saccharomyces cerevisiae

Although sugars are clearly the preferred carbon sources of the yeast Saccharomyces cerevisiae, nonfermentable substrates such as ethanol, glycerol, lactate, acetate or oleate can also be used for the generation of energy and cellular biomass. Several regulatory networks of glucose repression (carbon catabolite repression) are involved in the coordinate biosynthesis of enzymes required for the utilization of nonfermentable substrates. Positively and negatively acting complexes of pleiotropic regulatory proteins have been characterized. The Snf1 (Cat1) protein kinase complex, together with its regulatory subunit Snf4 (Cat3) and alternative beta-subunits Sip1, Sip2 or Gal83, plays an outstanding role for the derepression of structural genes which are repressed in the presence of a high glucose concentration. One molecular function of the Snf1 complex is deactivation by phosphorylation of the general glucose repressor Mig1. In addition to regulation of alternative sugar fermentation, Mig1 also influences activators of respiration and gluconeogenesis, although to a lesser extent. Snf1 is also required for conversion of specific regulatory factors into transcriptional activators. This review summarizes regulatory cis-acting elements of structural genes of the nonfermentative metabolism, together with the corresponding DNA-binding proteins (Hap2-5, Rtg1-3, Cat8, Sip4, Adr1, Oaf1, Pip2), and describes the molecular interactions among general regulators and pathway-specific factors. In addition to the influence of the carbon source at the transcriptional level, mechanisms of post-transcriptional control such as glucose-regulated stability of mRNA are also discussed briefly.

Transcriptional regulation of yeast peroxiredoxin gene TSA2 through Hap1p, Rox1p, and Hap2/3/5p

In Saccharomyces cerevisiae, the transcription of peroxiredoxin gene TSA2 is responsive to various reactive oxygen and nitrogen species. Redox-regulated transcriptional activators Yap1p, Skn7p, Msn2p/Msn4p have been shown to play a role in regulating TSA2 expression. In this study we show that the transcription of TSA2 is under complex control involving additional transcription factors Hap1p, Rox1p, and Hap2/3/5p. Deletion of HAP1 led to a 50% reduction of TSA2 transcriptional activity. As an intracellular oxygen sensor, heme stimulated TSA2 transcription by activating Hap1p. The induction of TSA2 by H(2)O(2) is also mediated in part through Hap1p. Countering the effects of Hap1p was a transcriptional repressor Rox1p. Deletion of ROX1 or mutation of Rox1p-binding site significantly activated TSA2 transcription. In addition, TSA2 activity was diminished in hap2Delta, hap3Delta, hap4Delta, and hap5Delta strains, but was stimulated upon overexpression of Hap4p. Hap2/3/5p may cooperate with Msn2/4p to activate TSA2 after diauxic shift. Finally, we demonstrated a role for kinases Ras1/2p and Hog1p in Msn2/4p-dependent activation of TSA2. In particular, Hog1p mediated the response of TSA2 to osmotic and oxidative stress. Taken together, our findings suggest that the expression of TSA2 is regulated by a group of transcription factors responsive differentially to stress conditions.

The NF-YB/NF-YC structure gives insight into DNA binding and transcription regulation by CCAAT factor NF-Y

The heterotrimeric transcription factor NF-Y recognizes with high specificity and affinity the CCAAT regulatory element that is widely represented in promoters and enhancer regions. The CCAAT box acts in concert with neighboring elements, and its bending by NF-Y is thought to be a major mechanism required for transcription activation. We have solved the structure of the NF-YC/NF-YB subcomplex of NF-Y, which shows that the core domains of both proteins interact through histone fold motifs. This histone-like pair is closely related to the H2A/H2B and NC2alpha/NC2beta families, with features that are both common to this class of proteins and unique to NF-Y. The structure together with the modeling of the nonspecific interaction of NF-YC/NF-YB with DNA and the full NF-Y/CCAAT box complex highlight important structural features that account for different and possibly similar biological functions of the transcriptional regulators NF-Y and NC2. In particular, it emphasizes the role of the newly described alphaC helix of NF-YC, which is both important for NF-Y trimerization and a target for regulatory proteins, such as MYC and p53.

Characterization of an α-ketoglutarate-resistant sake yeast mutant with high organic acid productivity

A yeast with high organic acid productivity was isolated from alpha-ketoglutarate-resistant mutants obtained by mutagenizing a sake yeast, Kyokai no. 701 (K-701). The new strain, 20G-R39, produces about twice as much malate and succinate as the parental strain. DNA microarray analyses revealed that the transcriptional levels of genes involved in the TCA cycle, oxidative phosphorylation, and respiration were higher in strain 20G-R39 than in strain K-701. Expression of these genes is regulated by the Hap2/3/4/5p complex, and especially by expression of the HAP4 gene. In a Northern blot analysis, the transcriptional level of the HAP4 gene was higher in strain 20G-R39 than in strain K-701. We constructed a plasmid that expresses the HAP4 gene constitutively and introduced it into strain K-701. The HAP4-overexpression-strain produced more malate and succinate than strain K-701 both in YPD medium and in a sake brewing test. These results indicate that strain 20G-R39 produces more organic acids than strain K-701 because strain 20G-R39 has a higher level of expression of the HAP4 gene than strain K-701.

Novel basic-region helix-loop-helix transcription factor (AnBH1) of Aspergillus nidulans counteracts the CCAAT-binding complex AnCF in the promoter of a penicillin biosynthesis gene

Cis-acting CCAAT elements are found frequently in eukaryotic promoter regions. Many of the genes containing such elements in their promoters are regulated by a conserved multimeric CCAAT-binding complex. In the fungus Emericella (Aspergillus) nidulans, this complex was designated AnCF (A.nidulans CCAAT-binding factor). AnCF regulates several genes, including the penicillin biosynthesis genes ipnA and aatA. Since it is estimated that the CCAAT-binding complex regulates more than 200 genes, an important question concerns the regulation mechanism that allows so many genes to be regulated by a single complex in a gene-specific manner. One of the answers to this question appears to lie in the interaction of AnCF with other transcription factors. Here, a novel transcription factor designated AnBH1 was isolated. The corresponding anbH1 gene was cloned and found to be located on chromosome IV. The deduced AnBH1 protein belongs to the family of basic-region helix-loop-helix (bHLH) transcription factors. AnBH1 binds in vitro as a homodimer to an, not previously described, asymmetric E-box within the aatA promoter that overlaps with the AnCF-binding site. This is the first report demonstrating that the CCAAT-binding complex and a bHLH transcription factor bind to overlapping sites. Since deletion of anbH1 appears to be lethal, the anbH1 gene was replaced by a regulatable alcAp-anbH1 gene fusion. The analysis of aatAp-lacZ expression in such a strain indicated that AnBH1 acts as a repressor of aatA gene expression and therefore counteracts the positive action of AnCF.

Spatially specific expression of Hoxb4 is dependent on the ubiquitous transcription factor NFY

Understanding how boundaries and domains of Hox gene expression are determined is critical to elucidating the means by which the embryo is patterned along the anteroposterior axis. We have performed a detailed analysis of the mouse Hoxb4 intron enhancer to identify upstream transcriptional regulators. In the context of an heterologous promoter, this enhancer can establish the appropriate anterior boundary of mesodermal expression but is unable to maintain it, showing that a specific interaction with its own promoter is important for maintenance. Enhancer function depends on a motif that contains overlapping binding sites for the transcription factors NFY and YY1. Specific mutations that either abolish or reduce NFY binding show that it is crucial for enhancer activity. The NFY/YY1 motif is reiterated in the Hoxb4 promoter and is known to be required for its activity. As these two factors are able to mediate opposing transcriptional effects by reorganizing the local chromatin environment, the relative levels of NFY and YY1 binding could represent a mechanism for balancing activation and repression of Hoxb4 through the same site.

Inhibition of major histocompatibility complex class II gene transcription by nitric oxide and antioxidants

Interferon (IFN)-gamma facilitates cellular immune response, in part, by inducing the expression of major histocompatibility complex class II (MHC-II) molecules. We demonstrate that IFN-gamma induces the expression of HLA-DRA in vascular endothelial cells via mechanisms involving reactive oxygen species. IFN-gamma-induced HLA-DRA expression was inhibited by nitric oxide (NO) and antioxidants such as superoxide dismutase, catalase, pyrrolidine dithiocarbamate, and N-acetylcysteine. Nuclear run-on assays demonstrated that NO and antioxidants inhibited IFN-gamma-induced HLA-DRA gene transcription. Transient transfection studies using a fully functional HLA-DRA promoter construct ([-300]DR alpha.CAT) showed that inhibition of endogenous NO synthase activity by N(omega)-monomethyl-l-arginine or addition of exogenous hydrogen peroxide (H(2)O(2)) augmented basal and IFN-gamma-stimulated [-300]DR alpha.CAT activity. However, H(2)O(2) and N(omega)-monomethyl-l-arginine could induce HLA-DRA expression suggesting that H(2)O(2) is a necessary but not a sufficient mediator of IFN-gamma-induced HLA-DRA expression. Electrophoretic mobility shift assay and Western blotting demonstrated that NO and antioxidants had little or no effect on IFN-gamma-induced IRF-1 activation or MHC-II transactivator (CIITA) expression but did inhibit IFN-gamma-induced activation of STAT1 alpha (p91) and Y box transcription factors, NF-Y(A) and NF-Y(B). These results indicate that NO and antioxidants may attenuate vascular inflammation by antagonizing the effects of intracellular reactive oxygen species generation by IFN-gamma, which is necessary for MHC-II gene transcription.

Isolation of genes encoding novel transcription factors which interact with the Hap complex from Aspergillus species

The Saccharomyces cerevisiae CCAAT-binding factor is composed of four subunits Hap2p, Hap3p, Hap4p and Hap5p. Three subunits, Hap2/3/5p, are required for DNA-binding and Hap4p is involved in transcriptional activation. Although homologues of Hap2/3/5p (in the case of Aspergillus nidulans; HapB/C/E, respectively) were found in many eukaryotes, no Hap4p homologues have been found except for the other yeast, Kluyveromyces lactis. With the lexA-hap2, -hapB, -hapC, or -hapE fusion gene, we evaluated the ability of interaction between Aspergillus Hap subunits and S. cerevisiae Hap4p subunit in S. cerevisiae. Using the system with lexA-hapB, a gene encoding a novel transcriptional activator, which interacted with the Hap complex, was isolated from A. nidulans and designated hapX.

Differential role of the proline-rich domain of nuclear factor 1-C splice variants in DNA binding and transactivation

We have addressed the functional significance of the existence of several natural splice variants of NF1-C* differing in their COOH-terminal proline-rich transactivation domain (PRD) by studying their specific DNA binding and transactivation in the yeast Saccharomyces cerevisiae. These parameters yielded the intrinsic transactivation potential (ITP), defined as the activation observed with equal amounts of DNA bound protein. Exchange of 83 amino acids at the COOH-terminal end of the PRD by 16 unrelated amino acids, as found in NF1-C2, and splicing out the central region of the PRD, as found in NF1-C7, enhanced DNA binding in vivo and in vitro. However, the ITP of the splice variants NF1-C2 and NF1-C7 was found to be similar to that of the intact NF1-C1. Additional mutations showed that the ITP of NF1-C requires the synergistic action of the PRD and a novel domain encoded in exons 5 and 6. Intriguingly the carboxyl-terminal domain-like motif encoded in exons 9/10 is not essential for transactivation of a reporter with a single NF1 site but is required for activation of a reporter with six NF1 sites in tandem. Our results imply that differential splicing is used to regulate transcription by generating variants with different DNA binding affinities but similar ITPs.

Accurate chromatin organization of the mouse mammary tumor virus promoter determines the nature of the synergism between transcription factors

The mechanism underlying the synergism between transcription factors in eukaryotic gene expression is not fully understood. In minichromosomes assembled in vitro the synergism between steroid hormone receptors (SHRs) and nuclear factor 1 (NF1) on the mouse mammary tumor virus (MMTV) promoter does not require the proline-rich transactivation domain (PRD) of NF1. Here we show that similar results are obtained in yeast. In contrast, replacing the native hormone-responsive elements (HREs) by a single HRE results in a more accessible chromatin and makes the synergism with SHR dependent on the PRD of NF1. Following hormone induction, in addition to glucocorticoid receptor, the DNA binding domain of NF1 is needed and sufficient for establishing an open chromatin conformation on the wild type MMTV promoter. Thus, NF1 acts as a classical transcription factor in a relaxed chromatin context, whereas in the context of the wild type chromatin DNA binding of NF1 is sufficient to cooperate with SHRs by stabilizing an open chromatin conformation.

The Gal4 activation domain binds Sug2 protein, a proteasome component, in vivo and in vitro

An in vivo protein interaction assay was used to search a yeast cDNA library for proteins that bind to the acidic activation domain (AD) of the yeast Gal4 protein. Sug2 protein, a component of the 19 S regulatory particle of the 26 S proteasome, was one of seven proteins identified in this screen. In vitro binding assays confirm a direct interaction between these proteins. SUG2 and SUG1, another 19 S component, were originally discovered as a mutation able to suppress the phenotype of a Gal4 truncation mutant (Gal4(D)p) lacking much of its AD. Sug1p has previously been shown to bind the Gal4 AD in vitro. Taken together, these genetic and biochemical data suggest a biologically significant interaction between the Gal4 protein and the 19 S regulatory particle of the proteasome. Indeed, it is demonstrated here that the Gal4 AD interacts specifically with immunopurified 19 S complex. The proteasome regulatory particle has been shown recently to play a direct role in RNA polymerase II transcription and the activator-19 S interaction could be important in recruiting this large complex to transcriptionally active GAL genes.

HSP-CBF is an NF-Y-dependent coactivator of the heat shock promoters CCAAT boxes

The cellular response to toxic stimuli is elicited through the expression of heat shock proteins, a transcriptional process that relies upon conserved DNA elements in the promoters: the Heat Shock Elements, activated by the heat shock factors, and the CCAAT boxes. The identity of the CCAAT activator(s) is unclear because two distinct entities, NF-Y and HSP-CBF, have been implicated in the HSP70 system. The former is a conserved ubiquitous trimer containing histone-like subunits, the latter a 110-kDa protein with an acidic N-terminal. We analyzed two CCAAT-containing promoters, HSP70 and HSP40, with recombinant NF-Y and HSP-CBF using electrophoretic mobility shift assay, protein-protein interactions, transfections and chromatin immunoprecipitation assays (ChIP) assays. Both recognize a common DNA-binding protein in nuclear extracts, identified in vitro and in vivo as NF-Y. Both CCAAT boxes show high affinity for recombinant NF-Y but not for HSP-CBF. However, HSP-CBF does activate HSP70 and HSP40 transcription under basal and heat shocked conditions; for doing so, it requires an intact NF-Y trimer as judged by cotransfections with a diagnostic NF-YA dominant negative vector. HSP-CBF interacts in solution and on DNA with the NF-Y trimer through an evolutionary conserved region. In yeast two-hybrid assays HSP-CBF interacts with NF-YB. These data implicate HSP-CBF as a non-DNA binding coactivator of heat shock genes that act on a DNA-bound NF-Y.

A repressor with similarities to prokaryotic and eukaryotic DNA helicases controls the assembly of the CAAT box binding complex at a photosynthesis gene promoter

A single nucleotide exchange in a promoter region located immediately upstream of the CAAT box of the spinach photosynthesis gene AtpC (gene product is subunit gamma of the chloroplast ATP synthase) prevents the formation of a secondary structure and causes an unregulated, constitutive high level of expression (Kusnetsov, V., Landsberger, M., Oelmüller, R. (1999) J. Biol. Chem. 274, 36009-36014). We have isolated cDNAs for ATPC-2, a new polypeptide with homologies to pro- and eukaryotic helicases, which specifically binds to this promoter region. Binding of ATPC-2 competes strongly with that of a CAAT box binding factor (CBF), consistent with the idea that both complexes cannot be formed simultaneously because of sterical reasons. In gel mobility shift assays, high binding activities of ATPC-2 and low binding activities of CBF were observed with nuclear extracts from tissue with low AtpC expression levels, and the opposite was observed with extracts from tissues with high AtpC expression levels. Binding of ATPC-2 to the mutant sequence, which directs a constitutively high level expression in vivo and prevents the formation of a secondary structure in vitro, is significantly weaker than binding to the wild-type sequence. Again, the opposite results were obtained for the CBF. Thus, we conclude that the assembly of the CBF.DNA complex stimulates transcription of AtpC and that CBF binding is prevented if ATPC-2 is bound to the promoter region. The novel mechanism of gene regulation and the role of the helicase-like protein ATPC-2 as a potential transcriptional repressor is discussed in relation to its modular structure.

Isolation and sequence of the MIG1 homologue from the yeast Candida utilis

The Mig1p repressor from the food yeast Candida utilis has been isolated using a homologous PCR hybridization probe. This probe was amplified with two sets of degenerate primers designed on the basis of highly conserved motifs in the DNA-binding region (zinc-finger domain) from yeast Mig1p and fungi CreA repressors. The cloned gene was sequenced and found to encode a polypeptide of 345 amino acids which shows significant identity with other yeast and fungus repressors in the DNA-binding domain and also with the yeast Mig1 proteins in the C-terminal region (effector domain). The MIG1 repressor gene from C. utilis was able to complement functionally the mig1 mutation of S. cerevisiae. The sequence presented here has been deposited in the EMBL data library under Accession No. AJ277830.

RNA polymerase II and TBP occupy the repressed CYC1 promoter

Saccharomyces cerevisiae CYC1 gene expression has been studied in great detail with regard to the response to oxygen availability and carbon source. In the absence of oxygen and the presence of glucose, the CYC1 gene is completely repressed. Chromatin structure is thought to play an important role in CYC1 gene regulation, as nucleosome depletion results in 94-fold derepression. In addition, the CYC1 core promoter has been used extensively in hybrid constructs to study activation by heterologous transcription factors. Therefore, we set out to map the chromatin structure of the CYC1 promoter and determine its role in CYC1 gene regulation. We report here that the repressed CYC1 promoter contains no positioned nucleosomes over the core promoter. However, we did find TFIID and RNA polymerase II bound in a complex on the repressed promoter. These results indicate that recruitment of TFIID and RNA polymerase II are not rate-limiting steps in CYC1 activation.

The Aspergillus nidulans multimeric CCAAT binding complex AnCF is negatively autoregulated via its hapB subunit gene

Cis-acting CCAAT elements are frequently found in eukaryotic promoter regions. Many of them are bound by conserved multimeric complexes. In the fungus Aspergillus nidulans the respective complex was designated AnCF (A. nidulans CCAAT binding factor). AnCF is composed of at least three subunits designated HapB, HapC and HapE. Here, we show that the promoter regions of the hapB genes in both A. nidulans and Aspergillus oryzae contain two inversely oriented, conserved CCAAT boxes (box alpha and box beta). Electrophoretic mobility shift assays (EMSAs) using both nuclear extracts and the purified, reconstituted AnCF complex indicated that AnCF binding in vitro to these boxes occurs in a non-mutually exclusive manner. Western and Northern blot analyses showed that steady-state levels of HapB protein as well as hapB mRNA were elevated in hapC and hapE deletion mutants, suggesting a repressing effect of AnCF on hapB expression. Consistently, in a hapB deletion background the hapB-lacZ expression level was elevated compared with the expression in the wild-type. This was further supported by overexpression of hapB using an inducible alcA-hapB construct. Induction of alcA-hapB expression strongly repressed the expression of a hapB-lacZ gene fusion. However, mutagenesis of box beta led to a fivefold reduced expression of a hapB-lacZ gene fusion compared with the expression derived from a wild-type hapB-lacZ fusion. These results indicate that (i) box beta is an important positive cis-acting element in hapB regulation, (ii) AnCF does not represent the corresponding positive trans-acting factor and (iii) that AnCF is involved in repression of hapB.

Transcriptional regulators of the Schizosaccharomyces pombe fbp1 gene include two redundant Tup1p-like corepressors and the CCAAT binding factor activation complex

The Schizosaccharomyces pombe fbp1 gene, which encodes fructose-1,6-bis-phosphatase, is transcriptionally repressed by glucose through the activation of the cAMP-dependent protein kinase A (PKA) and transcriptionally activated by glucose starvation through the activation of a mitogen-activated protein kinase (MAPK). To identify transcriptional regulators acting downstream from or in parallel to PKA, we screened an adh-driven cDNA plasmid library for genes that increase fbp1 transcription in a strain with elevated PKA activity. Two such clones express amino-terminally truncated forms of the S. pombe tup12 protein that resembles the Saccharomyces cerevisiae Tup1p global corepressor. These clones appear to act as dominant negative alleles. Deletion of both tup12 and the closely related tup11 gene causes a 100-fold increase in fbp1-lacZ expression, indicating that tup11 and tup12 are redundant negative regulators of fbp1 transcription. In strains lacking tup11 and tup12, the atf1-pcr1 transcriptional activator continues to play a central role in fbp1-lacZ expression; however, spc1 MAPK phosphorylation of atf1 is no longer essential for its activation. We discuss possible models for the role of tup11- and tup12-mediated repression with respect to signaling from the MAPK and PKA pathways. A third clone identified in our screen expresses the php5 protein subunit of the CCAAT-binding factor (CBF). Deletion of php5 reduces fbp1 expression under both repressed and derepressed conditions. The CBF appears to act in parallel to atf1-pcr1, although it is unclear whether or not CBF activity is regulated by PKA.

NF-Y mediates the transcriptional inhibition of the cyclin B1, cyclin B2, and cdc25C promoters upon induced G2 arrest

During normal cell cycles, the function of mitotic cyclin-cdk1 complexes, as well as of cdc25C phosphatase, is required for G2 phase progression. Accordingly, the G2 arrest induced by DNA damage is associated with a down-regulation of mitotic cyclins, cdk1, and cdc25C phosphatase expression. We found that the promoter activity of these genes is repressed in the G2 arrest induced by DNA damage. We asked whether the CCAAT-binding NF-Y modulates mitotic cyclins, cdk1, and cdc25C gene transcription during this type of G2 arrest. In our experimental conditions, the integrity of the CCAAT boxes of cyclin B1, cyclin B2, and cdc25C promoters, as well as the presence of a functional NF-Y complex, is strictly required for the transcriptional inhibition of these promoters. Furthermore, a dominant-negative p53 protein, impairing doxorubicin-induced G2 arrest, prevents transcriptional down-regulation of the mitotic cyclins, cdk1, and cdc25C genes. We conclude that, as already demonstrated for cdk1, NF-Y mediates the transcriptional inhibition of the mitotic cyclins and the cdc25C genes during p53-dependent G2 arrest induced by DNA damage. These data suggest a transcriptional regulatory role of NF-Y in the G2 checkpoint after DNA damage.

Interorganellar communication. Altered nuclear gene expression profiles in a yeast mitochondrial dna mutant

Communication between mitochondria and the nucleus is important for a variety of cellular processes such as carbohydrate and nitrogen metabolism, mating and sporulation, and cell growth and morphogenesis. It has long been known that the functional state of mitochondria can influence nuclear gene expression. For example, in yeast cells lacking the mitochondrial genome, the expression of several nuclear genes, such as CIT2 (citrate synthase), MRP13 (mitochondrial ribosomal protein), and DLD3 (d-lactate dehydrogenase) has been reported to be altered. Here we show by microarray analysis of the genome-wide transcription profile of Saccharomyces cerevisiae that yeast petite mutants lacking mitochondrial DNA induce genes coding for mitochondrial proteins, enzymes of the glycolytic pathway and of the citric acid cycle, cell wall components, membrane transporters, and genes normally induced by nutrient deprivation and a variety of stresses. Consistent with the observed induction of genes related to cell stress and those encoding membrane transporters, yeast petite cells showed increased resistance to severe heat shock and exhibited a pleiotropic drug resistance phenotype. The observed changes in nuclear gene expression in cells lacking mitochondrial DNA may have implications for the role of mitochondria in processes such as carcinogenesis and aging.

Regulation of the amylolytic and (hemi-)cellulolytic genes in aspergilli

Filamentous fungi produce high levels of polysaccharide-degrading enzymes and are frequently used for the production of industrial enzymes. Because of the high secretory capacity for enzymes, filamentous fungi are effective hosts for the production of foreign proteins. Genetic studies with Aspergillus nidulans have shown pathway-specific regulatory systems that control a set of genes that must be expressed to catabolize particular substrates. Besides the pathway-specific regulation, wide domain regulatory systems exist that affect a great many individual genes in different pathways. A molecular analysis of various regulated systems has confirmed the formal models derived from purely genetic data. In general, many genes are subject to more than one regulatory system. In this article, we describe two transcriptional activators, AmyR and XlnR, and an enhancer, Hap complex, in view of their regulatory roles in the expression of the amylolytic and (hemi-)cellulolytic genes mainly in aspergilli. The amyR gene has been isolated as a transcriptional activator involved in the expression of amylolytic genes from A. oryzae, A. niger, and A. nidulans, and the xlnR gene, which has been isolated from A. niger and A. oryzae, activates the expression of xylanolytic genes as well as some cellulolytic genes in aspergilli. Both AmyR and XlnR have a typical zinc binuclear cluster DNA-binding domain at their N-terminal regions. Hap complex, a CCAAT-binding complex, enhances the overall promoter activity and increases the expression levels of many fungal genes, including the Taka-amylase A gene. Hap complex comprises three subunits, HapB, HapC, and HapE, in A. nidulans and A. oryzae as well as higher eukaryotes, whereas HAP complex in Saccharomyces cerevisiae and Kluyveromyces lactis has the additional subunit, Hap4p, which is responsible for the transcriptional activation. Hap complex is suggested to enhance transcription by remodeling the chromatin structure. The regulation of gene expression in filamentous fungi of industrial interest could follow basically the same general principles as those discovered in A. nidulans. The knowledge of regulation of gene expression in combination with traditional genetic techniques is expected to be increasingly utilized for strain breeding. Furthermore, this knowledge provides a basis for the rational application of transcriptional regulators for biotechnological processes in filamentous fungi.

Cat8 and Sip4 mediate regulated transcriptional activation of the yeast malate dehydrogenase gene MDH2 by three carbon source-responsive promoter elements

Malate dehydrogenase isoenzymes are localized in different cellular compartments and fulfil important functions in intermediary metabolism. In the yeast Saccharomyces cerevisiae, three malate dehydrogenase genes, MDH1, MDH2 and MDH3, encoding mitochondrial, cytosolic and peroxisomal variants, have been identified. We demonstrate the importance of transcriptional activators Hap4, Cat8 and Pip2 for the carbon source-dependent regulation of MDH1, MDH2 and MDH3, respectively. The control region of the MDH2 gene required for gluconeogenic growth with C(2) substrates contains three sequence elements similar to the previously identified carbon source-responsive element (CSRE). In a synthetic test system, each of these sequences turned out to be a weak UAS element showing a strong synergism when present in multiple copies. Cumulative mutagenesis of the natural MDH2 promoter confirmed the contribution of all three elements to transcriptional derepression under non-fermentative growth conditions. The DNA-binding domains of zinc cluster proteins Cat8 and Sip4 synthesized in Escherichia coli could interact in vitro with CSRE motifs of MDH2. This result was confirmed by binding assays using protein extracts from yeast. Deregulated variants of Cat8 and Sip4 modified by heterologous transcriptional activation domains were able to alleviate glucose repression of MDH2 substantially. Although Sip4 turned out as the less effective activator, our findings demonstrate the general significance of both proteins for expression of gluconeogenic structural genes.

Mechanism of metabolic control. Target of rapamycin signaling links nitrogen quality to the activity of the Rtg1 and Rtg3 transcription factors

De novo biosynthesis of amino acids uses intermediates provided by the TCA cycle that must be replenished by anaplerotic reactions to maintain the respiratory competency of the cell. Genome-wide expression analyses in Saccharomyces cerevisiae reveal that many of the genes involved in these reactions are repressed in the presence of the preferred nitrogen sources glutamine or glutamate. Expression of these genes in media containing urea or ammonia as a sole nitrogen source requires the heterodimeric bZip transcription factors Rtg1 and Rtg3 and correlates with a redistribution of the Rtg1p/Rtg3 complex from a predominantly cytoplasmic to a predominantly nuclear location. Nuclear import of the complex requires the cytoplasmic protein Rtg2, a previously identified upstream regulator of Rtg1 and Rtg3, whereas export requires the importin-beta-family member Msn5. Remarkably, nuclear accumulation of Rtg1/Rtg3, as well as expression of their target genes, is induced by addition of rapamycin, a specific inhibitor of the target of rapamycin (TOR) kinases. We demonstrate further that Rtg3 is a phosphoprotein and that its phosphorylation state changes after rapamycin treatment. Taken together, these results demonstrate that target of rapamycin signaling regulates specific anaplerotic reactions by coupling nitrogen quality to the activity and subcellular localization of distinct transcription factors.

Regulatory networks revealed by transcriptional profiling of damaged Saccharomyces cerevisiae cells: Rpn4 links base excision repair with proteasomes

Exposure to carcinogenic alkylating agents, oxidizing agents, and ionizing radiation modulates transcript levels for over one third of Saccharomyces cerevisiae's 6,200 genes. Computational analysis delineates groups of coregulated genes whose upstream regions bear known and novel regulatory sequence motifs. One group of coregulated genes contain a number of DNA excision repair genes (including the MAG1 3-methyladenine DNA glycosylase gene) and a large selection of protein degradation genes. Moreover, transcription of these genes is modulated by the proteasome-associated protein Rpn4, most likely via its binding to MAG1 upstream repressor sequence 2-like elements, that turn out to be almost identical to the recently identified proteasome-associated control element (G. Mannhaupt, R. Schnall, V. Karpov, I. Vetter, and H. Feldmann, FEBS Lett. 450:27-34, 1999). We have identified a large number of genes whose transcription is influenced by Rpn4p.

Regulation of the CYB2 gene expression: transcriptional co-ordination by the Hap1p, Hap2/3/4/5p and Adr1p transcription factors

Expression of the Saccharomyces cerevisiae nuclear gene CYB2 encoding the mitochondrial enzyme L-(+)-lactate-cytochrome c oxidoreductase (EC 1.2.2.3) is subject to several strict metabolic controls at the transcriptional level: repression due to glucose fermentation, derepression by ethanol, induction by lactate and inhibition under anaerobic conditions or in response to deficiency of haem biosynthesis. In this respect, the data obtained from the transcriptional analysis of the CYB2 gene contribute to a better understanding of the control of mitochondrial biogenesis. In this study, we show that Hap1p is the main transcriptional activator involved in the control of CYB2 transcription. We found that Hap1p activity, known to be oxygen dependent, is effected by DNA-protein interaction with two binding sites present in the CYB2 promoter. Control is moreover dependent on carbon sources. This regulation by the carbon substrates is subordinate to the activity of the complex Hap2/3/4/5p, which counteracts the negative effect of the URS1 element. Finally, our results suggest that the Adr1p transcriptional activator is also required in CYB2 transcription control. This work provides new data which allows a better understanding of the molecular mechanisms implicated in the co-regulation at the transcriptional level of the genes encoding proteins involved in various aspects of oxidative metabolism.

Respirofermentative metabolism in Kluyveromyces lactis: Insights and perspectives

Yeasts do not form a homogeneous group as far as energy-yielding metabolism is concerned and the fate of pyruvate, a glycolytic intermediate, determines the type of energy metabolism. Kluyveromyces lactis has become an alternative to the traditional yeast Saccharomyces cerevisiae owing to its industrial applications as well as to studies on mitochondrial respiration. In this review we summarize the current knowdeledge about the K. lactis respirofermentative metabolism, taking into account the respiratory capacity of this yeast and the molecular mechanisms controlling its regulation, giving an up-to-date picture.

Stable expression of a dominant negative mutant of CCAAT binding factor/NF-Y in mouse fibroblast cells resulting in retardation of cell growth and inhibition of transcription of various cellular genes

The heterotrimeric CCAAT-binding factor CBF specifically interacts with the CCAAT motif present in the proximal promoters of numerous mammalian genes. To understand the in vivo function of CBF, a dominant negative mutant of CBF-B subunit that inhibits DNA binding of wild type CBF was stably expressed in mouse fibroblast cells under control of tetracycline-responsive promoter. Expression of the mutant CBF-B but not the wild-type CBF-B resulted in retardation of fibroblast cell growth. The analysis of cell growth using bromodeoxyuridine labeling showed that expression of the mutant CBF-B decreased the number of cells entering into S phase, and also delayed induction of S phase in the quiescent cells after serum stimulation, thus indicating that the inhibition of CBF binding prolonged the progression of S phase in fibroblasts. These results provide direct evidence for the first time that CBF is an important regulator of fibroblast growth. The inhibition of CBF binding reduced expression of various cellular genes including the alpha2(1) collagen, E2F1, and topoisomerase IIalpha genes which promoters contain the CBF-binding site. This result implied that expression of many other genes which promoters contain CBF-binding site was also decreased by the inhibition of CBF binding, and that the decreased expression of multiple cellular genes possibly caused the retardation of fibroblast cell growth.

A simple and rapid method for the preparation of a cell-free extract with CCAAT-binding activity from filamentous fungi

A simple and rapid method for the preparation of a cell-free extract with the CCAAT-binding activity was established with Aspergillus nidulans as a model fungus. Proteins were extracted with 6 M guanidine hydrochloride directly from mycelia and renatured by dialysis. This method was found applicable to other filamentous fungi such as Aspergillus oryzae and Trichoderma viride.

The role of ammonia metabolism in nitrogen catabolite repression in Saccharomyces cerevisiae

Saccharomyces cerevisiae is able to use a wide variety of nitrogen sources for growth. Not all nitrogen sources support growth equally well. In order to select the best out of a large diversity of available nitrogen sources, the yeast has developed molecular mechanisms. These mechanisms consist of a sensing mechanism and a regulatory mechanism which includes induction of needed systems, and repression of systems that are not beneficial. The first step in use of most nitrogen sources is its uptake via more or less specific permeases. Hence the first level of regulation is encountered at this level. The next step is the degradation of the nitrogen source to useful building blocks via the nitrogen metabolic pathways. These pathways can be divided into routes that lead to the degradation of the nitrogen source to ammonia and glutamate, and routes that lead to the synthesis of nitrogen containing compounds in which glutamate and glutamine are used as nitrogen donor. Glutamine is synthesized out of ammonia and glutamate. The expression of the specific degradation routes is also regulated depending on the availability of a particular nitrogen source. Ammonia plays a central role as intermediate between degradative and biosynthetic pathways. It not only functions as a metabolite in metabolic reactions but is also involved in regulation of metabolic pathways at several levels. This review describes the central role of ammonia in nitrogen metabolism. This role is illustrated at the level of enzyme activity, translation and transcription.

The assembly of the CAAT-box binding complex at a photosynthesis gene promoter is regulated by light, cytokinin, and the stage of the plastids

A functionally important region in the promoter of the spinach photosynthesis gene AtpC, which encodes the subunit gamma of the chloroplast ATP synthase, is located immediately upstream of the CAAT-box. A single nucleotide exchange in this region (AAAATTCAAT --> AAGATCAAT) uncouples the expression of an AtpC promoter::uidA gene fusion from the regulation by light, cytokinin, and functional plastids and results in a high constitutive expression of the reporter gene. By screening an Arabidopsis thaliana expression library with a double-stranded wild-type oligonucleotide from this promoter region, we have isolated cDNAs from Arabidopsis libraries that code for plant homologs of the CAAT-box binding factor (CBF)-C. Binding occurs only in the presence of nuclear extracts, consistent with reports from metazoa CBFs that the subunits A and B in addition to C are required for the formation of the CBF-DNA complex. At least eight genes with homologies to CBF-C are present in the Arabidopsis genome; one of them exhibits striking similarities to the gene for the human global transcriptional repressor Drap1. In gel mobility shift assays, low binding activity of CBF to the wild-type AtpC promoter sequence was observed with nuclear extracts from tissue with low AtpC expression levels, i.e. extracts from etiolated and photobleached seedlings, whereas high binding activity was detectable with extracts from tissues with high AtpC expression levels, i.e. extracts from light-grown seedlings and etiolated seedlings treated with cytokinin. Binding to the mutant sequence, which directs constitutive high level uidA expression in vivo, is significantly stronger than to the wild-type sequence. The data are consistent with the idea that the assembly of CBF at the AtpC promoter is regulated in response to light and cytokinin and that the low level of expression in etiolated and photobleached material is caused by an inhibitory effect. The structure/function relationships of the Arabidopsis CBFs are discussed in relation to their regulatory function in AtpC gene expression.

The molecular biology of the CCAAT-binding factor NF-Y

Protein coding genes are transcribed by Polymerase II, under the control of short discrete DNA elements in promoters and enhancers, recognized with high efficiency and specificity by trans-acting factors and by general transcription proteins (Tjian and Maniatis, 1994). The former regulate specific genes or set of genes, usually in a tissue-, developmental-, cell-cycle or stimuli-dependent way; the latter are involved in the activation of all promoters, as a whole multi-subunit holoenzyme (Parvis and Young, 1998). A limited set of elements, such as the GC and CCAAT-boxes, are present in a very high number of promoters. The whole process is further complicated by the need to operate in the context of higher order chromatin structures (Workman and Kingston, 1998). This review focuses on the CCAAT sequence and on the NF-Y protein, also known as CBF, which binds to it.

AnCF, the CCAAT binding complex of Aspergillus nidulans, is essential for the formation of a DNase I-hypersensitive site in the 5' region of the amdS gene

The CCAAT sequence in the amdS promoter of Aspergillus nidulans is recognized by AnCF, a complex consisting of the three evolutionary conserved subunits HapB, HapC, and HapE. In this study we have investigated the effect of AnCF on the chromatin structure of the amdS gene. The AnCF complex and the CCAAT sequence were found to be necessary for the formation of a nucleosome-free, DNase I-hypersensitive region in the 5' region of the amdS gene. Deletion of the hapE gene results in loss of the DNase I-hypersensitive site, and the positioning of nucleosomes over the transcriptional start point is lost. Likewise, a point mutation in the CCAAT motif, as well as a 530-bp deletion which removes the CCAAT box, results in the loss of the DNase I-hypersensitive region. The DNase I-hypersensitive region and the nucleosome positioning can be restored by insertion of a 35-bp oligonucleotide carrying the CCAAT motif. A DNase I-hypersensitive region has been found in the CCAAT-containing fmdS gene and was also hapE dependent. These data indicate a critical role for the AnCF complex in establishing an open chromatin structure in A. nidulans.

A transcriptional switch in the expression of yeast tricarboxylic acid cycle genes in response to a reduction or loss of respiratory function

The Hap2,3,4,5p transcription complex is required for expression of many mitochondrial proteins that function in electron transport and the tricarboxylic acid (TCA) cycle. We show that as the cells' respiratory function is reduced or eliminated, the expression of four TCA cycle genes, CIT1, ACO1, IDH1, and IDH2, switches from HAP control to control by three genes, RTG1, RTG2, and RTG3. The expression of four additional TCA cycle genes downstream of IDH1 and IDH2 is independent of the RTG genes. We have previously shown that the RTG genes control the retrograde pathway, defined as a change in the expression of a subset of nuclear genes, e.g., the glyoxylate cycle CIT2 gene, in response to changes in the functional state of mitochondria. We show that the cis-acting sequence controlling RTG-dependent expression of CIT1 includes an R box element, GTCAC, located 70 bp upstream of the Hap2,3,4,5p binding site in the CIT1 upstream activation sequence. The R box is a binding site for Rtg1p-Rtg3p, a heterodimeric, basic helix-loop-helix/leucine zipper transcription factor complex. We propose that in cells with compromised mitochondrial function, the RTG genes take control of the expression of genes leading to the synthesis of alpha-ketoglutarate to ensure that sufficient glutamate is available for biosynthetic processes and that increased flux of the glyoxylate cycle, via elevated CIT2 expression, provides a supply of metabolites entering the TCA cycle sufficient to support anabolic pathways. Glutamate is a potent repressor of RTG-dependent expression of genes encoding both mitochondrial and nonmitochondrial proteins, suggesting that it is a specific feedback regulator of the RTG system.

HAP-Like CCAAT-binding complexes in filamentous fungi: implications for biotechnology

Regulatory CCAAT boxes are found frequently in eukaryotic promoter regions. They are bound by different CCAAT-binding factors. Until now, a single CCAAT-binding complex has been reported in fungi. It is also found in higher eukaryotes and is highly conserved among eukaryotic organisms. This multimeric protein complex is designated HAP, AnCF, CBF, or NF-Y. The complex consists of at least three subunits. In fungi, only the HAP complex of Saccharomyces cerevisiae had been known for a long time. The recent cloning of genes encoding the components of the corresponding complex (AnCF/PENR1) of Aspergillus nidulans and characterization of CCAAT-regulated genes in A. nidulans, as well as other filamentous fungi, led to a deeper insight into the role of this transcription complex, in particular in aerobically growing fungi. An overview of the function of HAP-like complexes in gene regulation in filamentous fungi is presented. Some of the genes that have been found to be regulated by HAP-like complexes encode enzymes of biotechnological interest, like taka-amylase, xylanases, cellobiohydrolase, and penicillin biosynthesis enzymes. The importance of HAP-like complexes in controlling the expression of biotechnologically important genes is discussed.

Dissection of the NF-Y transcriptional activation potential

NF-Y is a trimeric CCAAT-binding factor with histone fold subunits (NF-YB/NF-YC) and bipartite activation domains located on NF-YA and NF-YC. We reconstituted the NF-Y activation potential in vivo with GAL4 DBD fusions. In the GAL4-YA configuration, activation requires co-expression of the three subunits; with GAL4-YB and GAL4-YC, transfections of the histone fold partners are sufficient, provided that the Q-rich domain of NF-YC is present. Combinations of mutants indicate that the Q-rich domains of NF-YA and NF-YC are redundant in the trimeric complex. Glutamines 101 and 102 of NF-YA are required for activity. We assayed NF-Y on different promoter targets, containing single or multiple GAL4 sites: whereas on a single site NF-Y is nearly as powerful as VP16, on multiple sites neither synergistic nor additive effects are observed. NF-Y activates TATA and Inr core elements and the overall potency is in the same range as other Q-rich and Pro-rich activation domains. These results represent the first in vivo evidence of subunit interactions studies and further support the hypothesis that NF-Y is a general promoter organizer rather than a brute activator.

Translation elongation factor 2 is encoded by a single essential gene in Candida albicans

Translation elongation factor 2 (eEF2) is a large protein of more than 800 amino acids which establishes complex interactions with the ribosome in order to catalyze the conformational changes needed for translation elongation. Unlike other yeasts, the pathogenic fungus Candida albicans was found to have a single gene encoding this factor per haploid genome, located on chromosome 2. Expression of this locus is essential for vegetative growth, as evidenced by placing it under the control of a repressible promoter. This C. albicans gene, named EFT2, was cloned and sequenced (EMBL accession number Y09664). Genomic and cDNA sequence analysis identified common transcription initiation and termination signals and an 842 amino acid open reading frame (ORF), which is interrupted by a single intron. Despite some genetic differences, CaEFT2 was capable of complementing a Saccharomyces cerevisiae Deltaeft1 Deltaeft2 null mutant, which lacks endogenous eEF2, indicating that CaEFT2 can be expressed from its own promoter and its intron can be correctly spliced in S. cerevisiae.

NF-Y histone fold alpha1 helices help impart CCAAT specificity

NF-Y is a conserved trimeric transcriptional activator with an extremely high specificity for CCAAT boxes. The NF-YB and NF-YC subunits have histone fold motifs with a high degree of homology to NC2alpha/beta, a TBP-binding repressor. The histone fold is composed of three alpha helices, alpha1, alpha2, alpha3, separated by short loops. Structural data on core histones showed that alpha1 are involved in DNA-binding. To understand the molecular basis of NF-Y sequence-specificity, we constructed deletion and swapping mutants, in which the alpha1 of NC2 and archeal HMfB, a bona fide histonic protein, was placed in NF-YB and NF-YC. Our analysis indicates that (i) subunit interactions are normal; (ii) NF-YB-NF-YC and NC2alpha/beta do not form heterodimers and NC2 cannot associate NF-YA. (iii) None of the NF-Y swaps can complex with TBP on a TATA box. (iv) Specific residues, R47 and K49 in NF-YC and N61 in NF-YB, are crucial for CCAAT-binding. We conclude that specificity of the NF-Y trimer is not due to NF-YA only, but stems in part from the contribution of the histone fold alpha1, particularly that of NF-YB.

HAP4, the glucose-repressed regulated subunit of the HAP transcriptional complex involved in the fermentation-respiration shift, has a functional homologue in the respiratory yeast Kluyveromyces lactis

In Saccharomyces cerevisiae, the heteromeric HAP transcription factor is necessary for optimal growth on respiratory carbon sources. One of its components, the Hap4p protein, is necessary for transcriptional activation. The same protein is also the regulatory part of the complex in response to carbon sources, as HAP4 is strongly induced during the shift from fermentative to respiratory metabolism in S. cerevisiae. We report here the characterization of a new gene from the respiratory yeast Kluyveromyces lactis, obtained by heterologous complementation of a delta hap4 S. cerevisiae mutant strain. The deduced sequence of the protein (643 amino acids) exhibits two small domains (11 and 16 amino acids respectively) highly homologous to corresponding domains of ScHap4p, while the overall similarity is rather weak. Additional experiments were performed to confirm the functional homology of this new gene with ScHAP4, which we named KIHAP4. The importance of the small highly conserved N-terminal sequence was confirmed by in vitro mutagenesis. All the mutations that interfere with the Hap4p-Hap2/3/5 interaction were localized in it. The discovery of the same regulatory protein in two metabolically distinct yeast species raises the question of its functional significance during evolution.

NF-Y binding to twin CCAAT boxes: role of Q-rich domains and histone fold helices

NF-Y (CBF) is a CCAAT-binding trimer that activates 25 % of eukaryotic promoters. It contains putative histone fold motifs (HFMs) and distorts DNA. By using electrophoretic mobility shift assays with the twin CCAAT boxes of the human gamma-globin promoter and several combinations of subunit mutants, we dissected some of the structural features of CCAAT-box binding. NF-YA and NF-YC Q-rich domains significantly influence bending angles quantitatively, but not qualitatively, since they do not modify DNA orientation. They are both required for co-operative interactions among NF-Y molecules: for this, a precise alignement of two CCAAT boxes, 32 bp, three turns of the helix, is essential. Unlike the wild-type (wt) protein, steric hindrance does not impede simultaneous binding of the mutant composed of the short homology domains to CCAAT boxes closer than 22 bp: the addition of 11 amino acid residues to NF-YB and 13 to NF-YC flanking the HFM, restores wt behaviour. These stretches are predicted to form H2B-like alphaC and H2A-like alphaN fourth helices. A further support to this hypothesis comes from off-rates analysis of mutant combinations: the half-life of NF-Y, which is dependent on the type of NF-YB used, is extremely shortened, when the putative alphaC is present, nearly as much as in the wt NF-YB. These data (i) provide further evidence that NF-YB-NF-YC belong to the H2B-H2A subclasses, (ii) uncover new features of Q-rich domains, and (iii) define rules for NF-Y synergy that are potentially important for the regulation of many eukaryotic promoters.