Promoter TATA Research Articles

The fission yeast TFIIB-related factor limits RNA polymerase III to a TATA-dependent pathway of TBP recruitment.

The RNA polymerase (pol) III-transcribed (e.g. tRNA and 5S rRNA) genes of traditionally studied organisms rely on gene-internal promoters that precisely position the initiation factor, TFIIIB, on the upstream promoter-less DNA. This is accomplished by the ability of the TFIIIB subunit, TFIIB-related factor (Brf1), to make stable protein-protein interactions with TATA-binding protein (TBP) and place it on the promoter-less upstream DNA. Unlike traditional model organisms, Schizosaccharomyces pombe tRNA and 5S rRNA genes contain upstream TATA promoters that are required to program functional pol III initiation complexes. In this study we demonstrate that S.pombe (Sp)Brf does not form stable interactions with TBP in the absence of DNA using approaches that do reveal stable association of TBP and S.cerevisiae (Sc)Brf1. Gel mobility analyses demonstrate that a TBP-TATA DNA complex can recruit SpBrf to a Pol III promoter. Consistent with this, overproduction of SpBrf in S.pombe increases the expression of a TATA-dependent, but not a TATA-less, suppressor tRNA gene. Since previous whole genome analysis also revealed TATA elements upstream of tRNA genes in Arabidopsis, this pathway may be more widespread than appreciated previously.

Vertebrate TBP-like protein (TLP/TRF2/TLF) stimulates TATA-less terminal deoxynucleotidyl transferase promoters in a transient reporter assay, and TFIIA-binding capacity of TLP is required for this function.

The TBP-like protein (TLP/TRF2/TLF), which belongs to the TBP family of proteins, is present in all metazoan organisms. Although the human TLP has been reported to interfere with transcription from TATA-containing promoters, the transcription activation potential of TLP in higher animals is obscure. We previously demonstrated that artificially promoter-recruited TLP behaves like an unconventional transcriptional activator. In this study, we investigated the effects of TLP on TATA-less promoters of mouse and human terminal deoxynucleotidyl transferase (TdT) genes by transient reporter assays. As expected, TLP repressed both basal and activator-augmented transcription from the TATA-containing adenovirus major late promoter (MLP) and E1B promoter. On the other hand, however, TLP significantly stimulated both basal and activated transcription from TdT promoters. We investigated the strength of the promoters in chicken DT40 cells that lack the TLP gene. The MLP showed higher activity but the TdT promoter showed lower activity in TLP-null cells than in the wild-type cells. Moreover, ectopic expression of mouse TLP in the TLP-null cells considerably stimulated the TdT promoter. Insertion of a TATA element upstream from the TdT core promoter resulted in a loss of TLP-mediated activation. The mouse TLP was demonstrated to bind specifically to TFIIA with greater strength than TBP. We constructed mutated TLPs having amino acid substitutions that impair TFIIA binding. A representative TLP mutant lacking TFIIA-binding ability could not stimulate transcription from the TdT promoter, whereas that mutation suppressed TLP-mediated transcription repression of TATA promoters. The results of the present study suggest that the vertebrate TLP potentiates exogenous TATA-less promoters and that TFIIA plays an important role in the TLP function.

PlantProm: a database of plant promoter sequences.

PlantProm DB, a plant promoter database, is an annotated, non-redundant collection of proximal promoter sequences for RNA polymerase II with experimentally determined transcription start site(s), TSS, from various plant species. The first release (2002.01) of PlantProm DB contains 305 entries including 71, 220 and 14 promoters from monocot, dicot and other plants, respectively. It provides DNA sequence of the promoter regions (-200 : +51) with TSS on the fixed position +201, taxonomic/promoter type classification of promoters and Nucleotide Frequency Matrices (NFM) for promoter elements: TATA-box, CCAAT-box and TSS-motif (Inr). Analysis of TSS-motifs revealed that their composition is different in dicots and monocots, as well as for TATA and TATA-less promoters. The database serves as learning set in developing plant promoter prediction programs. One such program (TSSP) based on discriminant analysis has been created by Softberry Inc. and the application of a support ftp: vector machine approach for promoter identification is under development. PlantProm DB is available at http://mendel.cs.rhul.ac.uk/ and http://www.softberry.com/.

Osteoclast Inhibitory Lectin, a Family of New Osteoclast Inhibitors

We have identified two novel type II membrane-bound C-lectins, designated mOCILrP1 and mOCILrP2, of 218 and 217 amino acids, respectively, that share substantial identity with the murine osteoclast inhibitory lectin (OCIL). The extracellular domains of mOCILrP1 and mOCILrP2 share 83 and 75% identity, respectively, with the extracellular domain of mOCIL. When the extracellular domains were expressed as recombinant proteins, each inhibited osteoclast formation in murine bone marrow cultures treated with M-CSF and RANKL with similar potencies to mOCIL (IC(50) of 0.2 ng/ml). Distinct but highly related genes encoded the three OCIL family members, with mOCIL and mOCILrP2 controlled by an inverted TATA promoter, and mOCILrP1 by a TTAAAA promoter. However only mOCIL was robustly regulated by calciotropic agents, while mOCILrP1 was not expressed, and mOCILrP2 was constitutively expressed in osteoblasts. Immunohistochemistry using antipeptide antibodies to the intracellular domain of mOCILrP1/mOCILrP2 and to mOCIL demonstrated that mOCIL and mOCILrP1/mOCILrP2 were concordantly expressed in osteoblasts, chondrocytes, and in extraskeletal tissues. Further, their cellular distribution was identical to that of RANKL. The identification of three distinct genes that were functionally related implies redundancy for OCIL, and their concordant expression with that of RANKL suggests that the RANKL:OPG axis may be further influenced by OCIL family members.

Characterization of the 5′-flanking fragment of the human GM3-synthase gene

To investigate the transcriptional regulation of human GM3-synthase, a 5′-flanking fragment of 1379 bp was cloned by a PCR-based procedure. Analysis of the human genomic sequence showed that the gene consists of seven exons, locates at chromosome 2, and spans over 62 kb. There are a number of potential consensus binding sites in the cloned promoter region, but TATA and CCAAT boxes were not found in the promoter. Primer extension analysis identified two transcription start sites approximately 11 and 57 bp upstream of the exon 1. The transcription activity of the promoter was assessed in human HeLa cells by transient transfection. Of the fragments assayed, the proximal 409 bp fragment exhibits the highest transcription activity. Transcription factors that bound to the 409 bp fragment were pulled down by DNA-coupled magnetic beads. Identities of the pull-down proteins were determined by array analysis. Eight transcription factors were identified, which might either bind to the proximal region or be recruited as co-activators of the transcription factor complexes.

Characterization of the rat RALDH1 promoter: A functional CCAAT and octamer motif are critical for basal promoter activity

Retinal dehydrogenase type 1 (RALDH1) catalyzes the oxidation of retinal to retinoic acid (RA), a metabolite of vitamin A important for embryogenesis and tissue differentiation. Rat RALDH1 is expressed to high levels in developing kidney, and in stomach, intestine epithelia. To understand the mechanisms of the transcriptional regulation of rat RALDH1, we cloned a 1360-base pair (bp) 5′-flanking region of RALDH1 gene. Using luciferase reporter constructs transfected into HEK 293 and LLCPK (kidney-derived) cells, basal promoter activity was associated with sequences between −80 and +43. In this minimal promoter region, TATA and CCAAT cis-acting elements as well as SP1, AP1 and octamer (Oct)-binding sites were present. The CCAAT box and Oct-binding site, located between positions −72 and −68 and −56 and −49, respectively, were shown by deletion analysis and site-directed mutation to be critical for promoter activity. Nuclear extracts from kidney cells contain proteins specifically binding the Oct and CCAAT sequences, resulting in the formation of six complexes, while different patterns of complexes were observed with non-kidney cell extracts. Gel shift assays using either single or double mutations of the Oct and CCAAT sequences as well as super shift assays demonstrated single and double occupancy of these two sites by Oct-1 and CBF-A. In addition, unidentified proteins also bound the Oct motif specifically in the absence of CBF-A binding. These results demonstrate specific involvement of Oct and CCAAT-binding proteins in the regulation of RALDH1 gene.

RGS12TS-S localizes at nuclear matrix-associated subnuclear structures and represses transcription: structural requirements for subnuclear targeting and transcriptional repression.

RGS12TS-S, an 1,157-amino-acid RGS protein (regulator of G protein signaling), is a nuclear protein that exhibits a unique pattern of subnuclear organization into nuclear foci or dots when expressed endogenously or ectopically. We now report that RGS12TS-S is a nuclear matrix protein and identify structural determinants that target this protein to the nuclear matrix and to discrete subnuclear sites. We also determine the relationship between RGS12TS-S-decorated nuclear dots and known subnuclear domains involved in control of gene expression and provide the first evidence that RGS12TS-S is functionally involved in the regulation of transcription and cell cycle events. A novel nuclear matrix-targeting sequence was identified that is distinct from a second novel motif needed for targeting RGS12TS-S to nuclear dots. RGS12TS-S nuclear dots were distinct from Cajal bodies, SC-35 domains, promyelocytic leukemia protein nuclear bodies, Polycomb group domains, and DNA replication sites. However, RGS12TS-S inhibited S-phase DNA synthesis in various tumor cell lines independently of Rb and p53 proteins, and its prolonged expression promoted formation of multinucleated cells. Expression of RGS12TS-S dramatically reduced bromo-UTP incorporation into sites of transcription. RGS12TS-S, when tethered to a Gal4 DNA binding domain, dramatically inhibited basal transcription from a Gal4-E1b TATA promoter in a histone deacetylase-independent manner. Structural analysis revealed a role for the unique N-terminal domain of RGS12TS-S in its transcriptional repressor and cell cycle-regulating activities and showed that the RGS domain was dispensable for these functions. These results provide novel insights into the structure and function of RGS12TS-S in the nucleus and demonstrate that RGS12TS-S possesses biological activities distinct from those of other members of the RGS protein family.

Enhancer-promoter specificity mediated by DPE or TATA core promoter motifs.

To investigate the basis for enhancer-promoter specificity, we compared the ability of enhancers to activate transcription in vivo from core promoters containing either downstream promoter element (DPE) or TATA box motifs. To eliminate position effects, we generated and analyzed pairs of sister Drosophila lines that contain a DPE- or TATA-dependent reporter gene at precisely the same genomic position relative to each enhancer. These studies revealed transcriptional enhancers that are specific for promoters that contain either DPE or TATA box elements. Thus, the core promoter not only mediates the initiation of transcription, but also functions as a regulatory element.

Widespread use of TATA elements in the core promoters for RNA polymerases III, II, and I in fission yeast.

In addition to directing transcription initiation, core promoters integrate input from distal regulatory elements. Except for rare exceptions, it has been generally found that eukaryotic tRNA and rRNA genes do not contain TATA promoter elements and instead use protein-protein interactions to bring the TATA-binding protein (TBP), to the core promoter. Genomewide analysis revealed TATA elements in the core promoters of tRNA and 5S rRNA (Pol III), U1 to U5 snRNA (Pol II), and 37S rRNA (Pol I) genes in Schizosaccharomyces pombe. Using tRNA-dependent suppression and other in vivo assays, as well as in vitro transcription, we demonstrated an obligatory requirement for upstream TATA elements for tRNA and 5S rRNA expression in S. pombe. The Pol III initiation factor Brf is found in complexes with TFIIIC and Pol III in S. pombe, while TBP is not, consistent with independent recruitment of TBP by TATA. Template commitment assays are consistent with this and confirm that the mechanisms of transcription complex assembly and initiation by Pol III in S. pombe differ substantially from those in other model organisms. The results were extended to large-rRNA synthesis, as mutation of the TATA element in the Pol I promoter also abolishes rRNA expression in fission yeast. A survey of other organisms' genomes reveals that a substantial number of eukaryotes may use widespread TATAs for transcription. These results indicate the presence of TATA-unified transcription systems in contemporary eukaryotes and provide insight into the residual need for TBP by all three Pols in other eukaryotes despite a lack of TATA elements in their promoters.

Use of a combined enzymatic digestion/ESI mass spectrometry assay to study the effect of TATA-binding protein on photoproduct formation in a TATA box.

Recently, it was reported that TATA-binding protein (TBP) enhances (6-4) photoproduct formation in a TATA box under UVC irradiation [Aboussekhra and Thoma (1999) EMBO J. 18, 433-443]. The conclusions of that study were based on an indirect enzymatic assay that was not specific for (6-4) photoproducts. Herein we report the use of a recently developed coupled enzymatic digestion/mass spectrometry assay [Wang et al. (1999) Chem. Res. Toxicol. 12, 1077-1082] to identify unambiguously and quantify the photoproducts formed in a TATA box-containing dodecamer duplex sequence in the presence or absence of TBP binding. Exposure of the adenovirus major late promoter TATA box to a high dose of UVC irradiation in the absence of the C-terminal domain of yeast TBP leads to predominant formation of the cis-syn dimer within the T(4) tract, whereas exposure in the presence of TBP leads to almost exclusive formation of the (6-4) photoproduct. In contrast, the (6-4) product is not detected at high doses of UVB irradiation in the absence of TBP but is detected in the presence of TBP, although the cis-syn product predominates. When the products of UVB irradiation were subsequently exposed to a high dose of UVC irradiation in the presence of TBP, the (6-4) photoproduct again becomes nearly the exclusive photoproduct, indicating that the cis-syn dimer is being reversed to TT by UVC light. Both cis-syn and (6-4) photoproducts are formed in approximately equal amounts upon irradiation with small doses of UVC in the presence of TBP, but the fraction of (6-4) photoproduct increases with dose. Through the use of a TATA box containing a site-specifically deuterated thymine, it was found that (6-4) photoproducts formed most selectively at the second and third positions of the T(4) tract upon either UVB or UVC irradiation in the presence of TBP. By using the same substrate, it was found that UVC-induced TA formation was inhibited by TBP binding and that TA formation was greatest at the 5' end of the TATA sequence.

Characterization of tilapia FSHβ gene and analysis of its 5′ flanking region

The objective of the current study was to unveil molecular mechanisms underlying transcriptional regulation of the FSHβ gene expression in the pituitary of tilapia (Oreochromis mossambicus). The full-length sequence of tilapia FSHβ (tFSHβ) gene was determined. Its transcriptional unit (2.7 kb) exhibits the conserved genomic organization, i.e. three exons and two introns. Primer extension and RT-PCR analysis revealed heterogeneity of the tFSHβ transcripts, due to alternate mRNA splicing and multiple initiation sites for transcription. Examination of the 5′ flanking region (5′FR) of the tFSHβ gene identified potential CAAT and TATA promoter proximal elements as well as several sequences of cis-acting motifs known to dictate inducible and tissue-specific transcriptional regulation in other gonadotropin genes. Chimeric constructs containing 1.7 kb of the tFSHβ 5′FR fused to a luciferase (LUC) reporter gene were transiently transfected into primary culture of tilapia pituitary cells. The tFSHβ-LUC construct was efficiently expressed under basal conditions and was rapidly induced by GnRH stimulation. Our data indicate that the 5′FR contains a functional promoter, which is responsive to GnRH treatment. In addition, 5′ deletion analysis showed that the 1.7 kb, DNA sequence of the FSHβ 5′FR encompasses both positive and negative regulatory elements.

Influence of Bulky Polynuclear Carcinogen Lesions in a TATA Promoter Sequence on TATA Binding Protein−DNA Complex Formation

The TATA binding protein (TBP) is an essential component of the transcription initiation complex that recognizes and binds to the minor groove of the TATA DNA duplex consensus sequences. The objective of this study was to determine the effect of a carcinogen-modified adenine residue, positioned site-specifically within a regulatory TATA DNA sequence, on the binding of TBP. Two 25-mer oligonucleotides with stereoisomeric 10S (+)-trans-anti- or 10R (-)-trans-anti-BPDE-N(6)-dA residues at A(1) or A(2) within the TATA sequence element (5'-...TA(1)TAAA...-3')-(5'-...TTTA(2)TA...) were synthesized (anti-BPDE-N(6)-dA denotes an adduct formed from the reaction of r7,t8-dihydroxy-t9,10-epoxy-7,8,9,10-tetrahydobenzo[a]pyrene). The formation of complexes with TBP of these two sequences in the double-stranded forms (1 nM) were studied employing electrophoretic mobility shift assays (EMSA) at different TBP concentrations (0-70 nM). The overall affinity of TBP for the BPDE-modified target DNA sequences was weakly enhanced in the case of the (+)-trans or (-)-trans lesions positioned at site A(1) with K(d) approximately 8 and 6 nM, respectively (K(d) approximately 9 nM for the unmodified TATA DNA). Higher-order TBP-DNA complexes were observed at TBP concentrations in excess of approximately 15 nM. However, the stabilities of the biologically significant monomeric TBP-DNA complexes was dramatically increased or decreased, depending on the position of the lesion (A(1) or A(2)), or on its stereochemical and conformational characteristics. A molecular docking modeling approach was employed to insert the stereoisomeric BPDE residues into the known TATA box-TBP structure [Nikolov, D. B., et al. (1996) Proc. Natl. Acad. Sci. U.S.A. 4862-4867] to rationalize these observations. Native gel electrophoresis experiments with the same duplexes without TBP indicate that none of the modified sequences exhibit unusual bending induced by the lesions, nor that they differ from one another in this respect. These results suggest that the hydrophobic, bulky BPDE residues influence the binding of TBP by mechanisms other than prebending. The efficiency of RNA transcription of TBP-controlled promoters could be strongly influenced by the presence of such bulky lesions that could adversely affect the levels of gene expression.

Activation of PTHrP gene expression in squamous carcinoma cell lines by mutant isoforms of the tumor suppressor p53.

We have evaluated the status of p53 expression in three squamous carcinoma cell lines that express high levels of PTHrP mRNA and protein and also cause hypercalcemia when grown in nude mice. All three of these lines possess a single p53 allele, each of which harbors a missense point mutation that gives rise to it mutant p53 protein with a denatured conformation. Using site-directed mutagenesis, we created a p53 expression construct bearing a missense mutation at codon 158, identical to that expressed by one of the cell lines. This construct and p53 constructs expressing representative denatured conformation mutants were then used to develop stably transfected lines, which expressed increased levels of PTHrP mRNA. Promoter-specific RNase protection indicated that this increase was due primarily to transcripts originating from the two TATA promoters, and not the GC-rich initiator element within the PTHrP gene. Cotransfection of mutant p53 expression vectors with a series of reporter constructs under the control of the human PTHrP promoter region showed that mutant p53 isoforms activated constructs containing multiple promoter elements and flanking sequences, but failed to activate constructs with individual promoters in isolation. These findings suggest that the activation of PTHrP gene expression by mutant p53 isoforms displaying a denatured conformation is dependent on interactions with sequences in the PTHrP gene regulatory region beyond the basal TATA promoters.

Negative regulation of bcl-2 expression by p53 in hematopoietic cells.

The p53 protein activates promoters containing p53 binding sites, and it represses other promoters. We examined the effect of p53 on bcl-2 expression in both the DHL-4 B cell line and the K562 erythroleukemia line. Transient transfection analyses revealed that wild-type p53 repressed the bcl-2 full-length promoter. The region of the bcl-2 promoter that was responsive to p53 was mapped to the bcl-2 P2 minimal promoter region, and we showed that p53 and the TATA binding protein bound to the bcl-2 TATA sequence. The TATA binding protein, p53, histone deacetylase-1 and mSin3a could be co-immunoprecipitated from K562 cell nuclear extract. The TATA binding protein and mSin3a could be recovered in a complex at the bcl-2 promoter TATA sequence, however, the formation of this complex was not dependent on the presence of p53. Treatment of K562 cells with the histone deacetylase inhibitor, trichostatin A, resulted in an increase in bcl-2 promoter activity whether p53 was present or not. Therefore, we demonstrated that p53 and the histone deacetylases repress the bcl-2 promoter independently. Similar results were obtained when endogenous bcl-2 mRNA or protein levels were measured in response to either p53 or trichostatin A, and p53 expression resulted in enhanced apoptosis. RNase protection assays demonstrated that transcription from the endogenous 3' bcl-2 promoter was decreased by p53. The regions of p53 that were required for repression of the bcl-2 promoter were defined. We conclude that the TATA sequence in the bcl-2 P2 minimal promoter is the target for repression by p53, and that the interaction between p53 and TBP is most likely responsible for the repression. Mutation of p53 may play a role in the up-regulation of bcl-2 expression in some B cell lymphomas.

A basal transcription factor that activates or represses transcription.

We have identified an activity that is required for transcription of downstream promoter element (DPE)-containing core promoters in vitro. The purified factor was found to be the Drosophila homolog of the transcriptional repressor known as NC2 or Dr1-Drap1. Purified recombinant dNC2 activates DPE-driven promoters and represses TATA-driven promoters. A mutant version of dNC2 can activate DPE promoters but is unable to repress TATA promoters. Thus, the activation and repression functions are distinct. These studies reveal that NC2 (Dr1-Drap1) is a bifunctional basal transcription factor that differentially regulates gene transcription through DPE or TATA box motifs.

Molecular characterization of the Abp1 5'-flanking region in maize and the teosintes.

Auxin-binding protein 1 subsp. mays (ABP1) has been suggested as a receptor mediating auxin-induced cell expansion and differentiation. In maize (Zea mays), ABP1 is encoded by a single gene, Abp1. The TATA and CAAT promoter elements as well as the transcriptional start site were previously identified and all were found to be located within a transposable element (TE), Tourist-Zm11. In this study we report the cloning and characterization of the Abp1 5'-flanking region in maize and its wild relatives, the teosintes. We provide evidence for insertion polymorphism corresponding to Tourist-Zm11 and two novel TEs, Batuta and Pilgrim. Despite this polymorphic structure, the Abp1 core promoter in maize and the teosintes is conserved, is located downstream of the TE insertions in the 5'-flanking region, and is TATA-less. We discuss the potential evolutionary impact of these TEs on the regulation of Abp1 gene expression.

Virtually unidirectional binding of TBP to the AdMLP TATA box within the quaternary complex with TFIIA and TFIIB

Background: The TATA box binding protein (TBP) is required by all three RNA polymerases for the promoter-specific initiation of transcription. All eukaryotic TBP–DNA complexes observed in crystal structures show the conserved C-terminal domain of TBP (TBP c) bound to the TATA box in a single orientation that is consistent with assembly of a preinitiation complex (PIC) possessing a unique polarity. The binding of TBP to the TATA box is believed to orient the PIC correctly on the promoter and can function as the rate-limiting step in PIC assembly. Previous work performed with TBP from Saccharomyces cerevisiae (yTBP) showed that, despite the oriented binding of eukaryotic TBP observed in crystal structures, yTBP in solution does not orient itself uniquely on the adenovirus major late promoter (AdMLP) TATA box. Instead, yTBP binds the AdMLP as a mixture of two orientational isomers that are related by a 180 degree rotation about the pseudo-dyad axis of the complex. In addition, these orientational isomers are not restricted to the 8 bp TATA box, but rather bind a distribution of sites that partially overlap the TATA box. Two members of the PIC, general transcription factor (TF) IIB and TFIIA individually enhance the orientational and axial specificity of yTBP binding to the TATA box, but fail to fix yTBP in a single orientation or a unique position on the promoter. Results: We used an affinity cleavage assay to explore the combined effects of TFIIA and TFIIB on the axial and orientational specificity of yTBP. Our results show that the combination of TFIIA and TFIIB affixes yTBP in virtually a single orientation as well as a unique location on the AdMLP TATA box. Ninety-five percent of the quaternary TBP–TFIIA–TFIIB–TATA complex contained yTBP bound in the orientation expected on the basis of crystallographic and genetic experiments, and more than 70% is restricted axially to the 8 bp sequence TATAAAAG. Conclusions: Although yTBP itself binds to the TATA box without a high level of orientational or axial specificity, our data show that a small subset of general TFs are capable of uniquely orienting the PIC on the AdMLP. Our results, in combination with recent data concerning the pathway of PIC formation in yeast, suggest that transcription could be regulated during both early and late stages of PIC assembly by general factors (and the proteins to which they bind) that influence the position and orientation of TBP on the promoter.

Molecular cloning, characterization, and differential expression of a glucoamylase gene from the basidiomycetous fungus Lentinula edodes.

The complete nucleotide sequence of putative glucoamylase gene gla1 from the basidiomycetous fungus Lentinula edodes strain L54 is reported. The coding region of the genomic glucoamylase sequence, which is preceded by eukaryotic promoter elements CAAT and TATA, spans 2,076 bp. The gla1 gene sequence codes for a putative polypeptide of 571 amino acids and is interrupted by seven introns. The open reading frame sequence of the gla1 gene shows strong homology with those of other fungal glucoamylase genes and encodes a protein with an N-terminal catalytic domain and a C-terminal starch-binding domain. The similarity between the Gla1 protein and other fungal glucoamylases is from 45 to 61%, with the region of highest conservation found in catalytic domains and starch-binding domains. We compared the kinetics of glucoamylase activity and levels of gene expression in L. edodes strain L54 grown on different carbon sources (glucose, starch, cellulose, and potato extract) and in various developmental stages (mycelium growth, primordium appearance, and fruiting body formation). Quantitative reverse transcription PCR utilizing pairs of primers specific for gla1 gene expression shows that expression of gla1 was induced by starch and increased during the process of fruiting body formation, which indicates that glucoamylases may play an important role in the morphogenesis of the basidiomycetous fungus.

The NC2 repressor is dispensable in yeast mutated for the Sin4p component of the holoenzyme and plays roles similar to Mot1p in vivo

NC2 (Dr1/DRAP1) and Mot1p are global repressors of transcription that have been isolated in both Saccharomyces cerevisiae and humans. NC2 is a dimeric histone-fold complex that represses RNA polymerase II transcription through binding to TBP and inhibition of TFIIA and TFIIB. Mot1p is an ATPase that removes DNA-bound TBP upon ATP hydrolysis. In this work, we studied the core promoter specificity of NC2 in vivo using a strain that carries mutated NC2beta activity. We show that NC2, like Mot1p, is required for transcription of the HIS3 and HIS4 TATA-less core promoters. Furthermore, whereas neither Mot1p nor NC2 appear to function as repressors of the HIS3 gene in cells growing exponentially in glucose, we find that both are required for repression of the HIS3 TATA promoter when cells go through the diauxic shift. Thus, the activity of these factors is similarly regulated depending upon the physiological conditions, and it appears that core promoters activated or repressed by them in vivo might be distinguishable by whether or not they contain a canonical TATA sequence. Finally, although NC2 is an essential factor for yeast viability, we isolated a mutation in a non-essential component of the holoenzyme, Sin4p, that bypasses the requirement for NC2.

A single point mutation in TFIIA suppresses NC2 requirement in vivo

Negative cofactor 2 (NC2) is a dimeric histone-fold complex that represses RNA polymerase II transcription through binding to TATA-box-binding protein (TBP) and inhibition of the general transcription factors TFIIA and TFIIB. Here we study molecular mechanisms of repression by human NC2 in vivo in yeast. Yeast NC2 genes are essential and can be exchanged with human NC2. The physiologically relevant regions of NC2 have been determined and shown to match the histone-fold dimerization motif. A suppressor screen based upon limiting concentrations of NC2beta yielded a cold-sensitive mutant in the yeast TFIIA subunit Toa1. The single point mutation in Toa1 alleviates the requirement for both subunits of NC2. Biochemical characterization indicated that mutant (mt)-Toa1 dimerizes well with Toa2; it supports specific recognition of the TATA box by TBP but forms less stable TBP-TFIIA-DNA complexes. Wild-type but not the mt-Toa1 can relieve NC2 effects in purified transcription systems. These data provide evidence for a dimeric NC2 complex that is in an equilibrium with TFIIA after the initial binding of TBP to promoter TATA boxes.