LexA Operator Research Articles

Yeast telomeric sequences function as chromosomal anchorage points invivo

Site-specific recombination in Saccharomyces cerevisiae was used to generate non-replicative DNA rings containing yeast telomeric sequences. In topoisomerase mutants expressing Escherichia coli topoisomerase I, the rings adopted a novel DNA topology consistent with the ability of yeast telomeric DNA to block or retard the axial rotation of DNA. DNA fragments bearing portions of the terminal repeat sequence C1-3 A/TG1-3 were both necessary and sufficient to create a barrier to DNA rotation. Synthetic oligonucleotide sequences containing Rap1p binding sites, a well represented motif in naturally occurring C1-3A arrays, also conferred immobilization; mutant Rap1p binding sites and telomeric sequences from other organisms were not sufficient. DNA anchoring was diminished by addition of competing telomeric sequences, implicating a role for an as yet unidentified limiting trans-acting factor. Though Rap1p is a likely protein constituent of the DNA anchor, deletion of the non-essential C-terminal domain did not affect the topology of telomeric DNA rings. Similarly, disruption of SIR2, SIR3 and SIR4, genes which influence a variety of telomere functions in yeast, also had no effect. We propose that telomeric DNA supports the formation of a SIR-independent macromolecular protein-DNA assembly that hinders the motion of DNA because of its linkage to an insoluble nuclear structure. Potential roles for DNA anchoring in telomere biology are discussed.

Complementation of a yeast Δ pkc1 mutant by the Arabidopsis protein ANT

The Saccharomyces cerevisiae protein kinase C homologue, PKC1, is involved in maintenance of cell integrity during polarized growth. We have used a mutant complementation approach to investigate related signal transduction pathways in higher plants. Here we report the isolation of a cDNA from Arabidopsis thaliana which partially suppresses the lytic defect of a Δ pkc1 yeast strain. The encoded protein, ANT, belongs to the AP2-related gene family and is essential for ovule development. Expression in yeast of a LexA-ANT fusion protein activates transcription of a reporter gene from promoters containing lexA operators. Our results support the idea that ANT acts as transcriptional activator in planta.

Activating transcription from single stranded DNA.

Sequence specific regulators of eukaryotic gene expression, axiomatically, act through double stranded DNA targets. Proteins that recognize DNA cis-elements as single strands but for which compelling evidence has been lacking to indicate in vivo involvement in transcription are orphaned in this scheme. We sought to determine whether sequence specific single strand binding proteins can find their cognate elements and modify transcription in vivo by studying heterogeneous nuclear ribonucleoprotein K (hnRNP K), which binds the single stranded sequence (CCCTCCCCA; CT-element) of the human c-myc gene in vitro. To monitor its DNA binding in vivo, the ability of hnRNP K to activate a reporter gene was amplified by fusion with the VP16 transactivation domain. This chimeric protein was found to transactivate circular but not linear CT-element driven reporters, suggesting that hnRNP K recognizes a single strand region generated by negative supercoiling in circular plasmid. When CT-elements were engineered to overlap with lexA operators, addition of lexA protein, either in vivo or in vitro, abrogated hnRNP K binding most likely by preventing single strand formation. These results not only reveal hnRNP K to be a single strand DNA binding protein in vivo, but demonstrate how a segment of DNA may modify the transcriptional activity of an adjacent gene through the interconversion of duplex and single strands.

Interactions between the amino‐terminal domain of p56lck and cytoplasmic domains of CD4 and CD8α in yeast

The interactions between CD4 or CD8 and p56lck were tested using the two-hybrid protein interaction system in yeast. Plasmid constructs were created which fuse the cytoplasmic domains of either CD4 or CD8 alpha to the DNA-binding protein LexA, and the unique amino-terminal domain of p56lck fused to a transcriptional activation domain. These constructs were transfected into yeast bearing lacZ and LEU2 reporter genes controlled by upstream LexA operator sequences. Yeast transfectants bearing either CD4 or CD8 alpha hybrid proteins in combination with the amino terminal p56lck hybrid protein exhibited increased beta-galactosidase activity and growth on leucine-deficient medium, indicating interactions between these protein domains. Quantitation of reporter activation indicated that the interaction of p56lck with CD8 alpha is at least 18-fold weaker than the interaction with CD4 in this assay. This reduced interactive capacity is apparently not due to competition by CD8 alpha interacting with itself, since homotypic or heterotypic interactions between CD8 alpha and/or CD4 could not be detected. Truncation and point mutants demonstrated that the interactions of p56lck with CD4 or CD8 alpha were dependent on the integrity of a pair of cysteines on each protein. The results indicate that these interactions do not require any additional proteins. Additionally, expression of the entire p56lck molecule as a hybrid with LexA resulted in dramatic reduction in the growth of yeast. Though the two-hybrid system is a powerful tool for examining protein interactions, this result indicates potential limitations in studying full-length src family tyrosine kinases in yeast.

Connecting a promoter-bound protein to TBP bypasses the need for a transcriptional activation domain.

Biochemical analyses have suggested potential targets for transcriptional activation domains, which include several components of the RNA polymerase II machinery, as well as the chromatin template. Here we examine the mechanism of transcriptional activation in yeast cells by connecting a heterologous DNA-binding domain (LexA) to the TATA-binding protein (TBP). LexA-TBP efficiently activates transcription from a promoter containing a LexA operator upstream of a TATA element. Activation is promoter-specific and is sensitive to mutations on the DNA-binding surface of TBP; hence it is not due to a fortuitous activation domain on TBP. Thus a promoter-bound protein lacking an activation domain can stimulate transcription if it is directly connected to TBP. This suggests that recruitment of TBP to the promoter can be a rate-limiting step for transcription in vivo, and that interactions between activation domains and factors that function after TBP recruitment can be bypassed for activation.

Targeting of promoters for trans activation by a carboxy-terminal domain of the NS-1 protein of the parvovirus minute virus of mice

The NS-1 gene of the parvovirus minute virus of mice (MVM) (prototype strain, MVMp) was fused in phase with the sequence coding for the DNA-binding domain of the bacterial LexA repressor. The resulting chimeric protein, LexNS-1, was tested for its transcriptional activity by using various target promoters in which multiple LexA operator sequences had been introduced. Under these conditions, NS-1 was shown to stimulate gene expression driven by the modified long terminal repeat promoters (from the retroviruses mouse mammary tumor virus and Rous sarcoma virus) and P38 promoter (from MVMp), indicating that the NS-1 protein is a potent transcriptional activator. It is noteworthy that in the absence of LexA operator-mediated targeting, the genuine mouse mammary tumor virus and Rous sarcoma virus promoters were inhibited by NS-1. Together these data strongly suggest that NS-1 contains an activating region able to induce promoters with which this protein interacts but also to repress transcription from nonrecognized promoters by a squelching mechanism similar to that described for other activators. Deletion mutant analysis led to the identification of an NS-1 domain that exhibited an activating potential comparable to that of the whole polypeptide when fused to the DNA-binding region of LexA. This domain is localized in the carboxy-terminal part of NS-1 and corresponds to one of the two regions previously found to be responsible for toxicity. These results argue for the involvement of the regulatory functions of NS-1 in the cytopathic effect of this parvovirus product.

The 90-kDa heat shock protein is essential for Ah receptor signaling in a yeast expression system.

In an effort to provide a more powerful system to study the Ah receptor (AHR) signaling pathway, we expressed the AHR, its dimerization partner ARNT, and a beta-galactosidase (lacZ) reporter gene, driven by two dioxin-responsive enhancers, in the yeast Saccharomyces cerevisiae. In this system, the agonists beta-naphthoflavone and alpha-naphthoflavone induced transcription of the lacZ gene, with EC50 values of 7.9 x 10(-8) and 3.0 x 10(-7) M, respectively, while the nonagonist dexamethasone was without effect. As a first application of this system, we examined the relationship between the 90-kDa heat shock protein (hsp90) and AHR function. To accomplish this in a manner that was independent of the ARNT protein, we constructed a chimeric receptor in which the DNA binding and primary dimerization domains of the AHR were swapped with analogous domains from the LexA protein. Coexpression of this AHR-LexA chimera and a lacZ reporter gene driven by eight LexA operator sites in a yeast strain with regulatable levels of hsp90, yielded pharmacology that closely mirrored that of the AHR/ARNT/dioxin-responsive enhancer system described above, but only when hsp90 levels were held near their wild type levels. When hsp90 levels were reduced to approximately 5% of normal, AHR signaling in response to agonist was completely blocked despite normal cell growth. These results provide the first genetic evidence for the role of hsp90 in AHR signaling and provide the basis for a powerful new system in which to study this pathway.

Repression of the genes for lysine biosynthesis in Saccharomyces cerevisiae is caused by limitation of Lys14-dependent transcriptional activation.

The product of the LYS14 gene of Saccharomyces cerevisiae activates the transcription of at least four genes involved in lysine biosynthesis. Physiological and genetic studies indicate that this activation is dependent on the inducer alpha-aminoadipate semialdehyde, an intermediate of the pathway. The gene LYS14 was sequenced and, from its nucleotide sequence, predicted to encode a 790-amino-acid protein carrying a cysteine-rich DNA-binding motif of the Zn(II)2Cys6 type in its N-terminal portion. Deletion of this N-terminal portion including the cysteine-rich domain resulted in the loss of LYS14 function. To test the function of Lys14 as a transcriptional activator, this protein without its DNA-binding motif was fused to the DNA-binding domain of the Escherichia coli LexA protein. The resulting LexA-Lys14 hybrid protein was capable of activating transcription from a promoter containing a lexA operator, thus confirming the transcriptional activation function of Lys14. Furthermore, evidence that this function, which is dependent on the presence of alpha-aminoadipate semialdehyde, is antagonized by lysine was obtained. Such findings suggest that activation by alpha-aminoadipate semialdehyde and the apparent repression by lysine are related mechanisms. Lysine possibly acts by limiting the supply of the coinducer, alpha-aminoadipate semialdehyde.

The protein HU can displace the LexA repressor from its DNA-binding sites.

The major bacterial histone-like protein HU is a small, basic, dimeric protein composed of two closely related subunits. HU is involved in several processes in the bacterial cell such as the initiation of replication, transposition, gene inversion and cell division. It has been suggested that HU could introduce structural changes to the DNA which would facilitate or inhibit the binding of regulatory proteins to their specific sites. In this study we investigated the effect of HU on the binding of LexA protein, the regulator of SOS functions, to three of its specific binding sites. We show that HU can displace LexA from its binding sites on the operators of the lexA, recA and sfiA genes. The lexA operator was the most sensitive while the higher affinity sfiA operator was the least sensitive. Since HU, like its homologue IHF, probably binds DNA in the minor groove we tested the effect of distamycin, a drug which binds to the minor groove, on LexA binding. Like HU, this drug disrupted LexA-operator complexes. These results suggest that distortion of the minor groove of the lexA operators excludes the binding of the repressor to the major groove.

Identification of High Affinity Binding Sites for LexA which Define New DNA Damage-inducible Genes in Escherichia coli

A multi-step screening procedure was devised to identify new operators for the LexA repressor in the sequenced portions of the genomes of Escherichia coli and its plasmids and bacteriophages. Sequence analysis methods were employed initially to distinguish true LexA operators from "operator-like" sequences stored within the GenBank and EMBL databases. The affinity of purified LexA protein for cloned DNA fragments containing several of the prospective new sites was then assessed using quantitative electrophoretic mobility shift assays and site-directed mutagenesis. Calculated binding affinities were compared directly with values determined for known and mutant LexA operators in concurrent experiments. Three E. coli chromosomal segments (near pyrC, hsdS and ntrla) and two bacteriophage sequences (near the P1 cre and λ oop genes) bound LexA protein specifically. These sites and most others identified in the screening are located immediately upstream of known genes and/or large open reading frames. These results and additional transcription data demonstrate that several of the sequences define new DNA damage-inducible ( din) genes and include the previously uncharacterized dinD locus. Furthermore, the search identified an SOS gene within the genome of P1 which encodes a protein that is homologous to UmuD′, the RecA-promoted cleavage product of the umuD gene. The success of the combinatorial approach described here suggests that analogous searches for new regulatory sequences within the E. coli genome and the genomes of other organisms will also yield favorable results.

Functional domains of the AraC protein.

The AraC protein, which regulates the L-arabinose operons in Escherichia coli, was dissected into two domains that function in chimeric proteins. One provides a dimerization capability and binds the ligand arabinose, and the other provides a site-specific DNA-binding capability and activates transcription. In vivo and in vitro experiments showed that a fusion protein consisting of the N-terminal half of the AraC protein and the DNA-binding domain of the LexA repressor dimerizes, binds well to a LexA operator, and represses expression of a LexA operator-beta-galactosidase fusion gene in an arabinose-responsive manner. In vivo and in vitro experiments also showed that a fusion protein consisting of the C-terminal half of the AraC protein and the leucine zipper dimerization domain from the C/EBP transcriptional activator binds to araI and activates transcription from a PBAD promoter-beta-galactosidase fusion gene. Dimerization was necessary for occupancy and activation of the wild-type AraC binding site.

Transcriptional repression in Saccharomyces cerevisiae by a SIN3-LexA fusion protein.

The yeast SIN3 gene (also known as SDI1, UME4, RPD1, and GAM2) has been identified as a transcriptional regulator. Previous work has led to the suggestion that SIN3 regulates transcription via interactions with DNA-binding proteins. Although the SIN3 protein is located in the nucleus, it does not bind directly to DNA in vitro. We have expressed a LexA-SIN3 fusion protein in Saccharomyces cerevisiae and show that this fusion protein represses transcription from heterologous promoters that contain lexA operators. The predicted amino acid sequence of the SIN3 protein contains four copies of a paired amphipathic helix (PAH) motif, similar to motifs found in HLH (helix-loop-helix) and TPR (tetratricopeptide repeat) proteins, and these motifs are proposed to be involved in protein-protein interactions. We have conducted a deletion analysis of the SIN3 gene and show that the PAH motifs are required for SIN3 activity. Additionally, the C-terminal region of the SIN3 protein is sufficient for repression activity in a LexA-SIN3 fusion, and deletion of a PAH motif in this region inactivates this repression activity. A model is presented in which SIN3 recognizes specific DNA-binding proteins in vivo in order to repress transcription.

Transcriptional repression in Saccharomyces cerevisiae by a SIN3-LexA fusion protein.

The yeast SIN3 gene (also known as SDI1, UME4, RPD1, and GAM2) has been identified as a transcriptional regulator. Previous work has led to the suggestion that SIN3 regulates transcription via interactions with DNA-binding proteins. Although the SIN3 protein is located in the nucleus, it does not bind directly to DNA in vitro. We have expressed a LexA-SIN3 fusion protein in Saccharomyces cerevisiae and show that this fusion protein represses transcription from heterologous promoters that contain lexA operators. The predicted amino acid sequence of the SIN3 protein contains four copies of a paired amphipathic helix (PAH) motif, similar to motifs found in HLH (helix-loop-helix) and TPR (tetratricopeptide repeat) proteins, and these motifs are proposed to be involved in protein-protein interactions. We have conducted a deletion analysis of the SIN3 gene and show that the PAH motifs are required for SIN3 activity. Additionally, the C-terminal region of the SIN3 protein is sufficient for repression activity in a LexA-SIN3 fusion, and deletion of a PAH motif in this region inactivates this repression activity. A model is presented in which SIN3 recognizes specific DNA-binding proteins in vivo in order to repress transcription.

Yeast SNF2/SWI2, SNF5, and SNF6 proteins function coordinately with the gene-specific transcriptional activators GAL4 and Bicoid.

The SNF2 (SWI2), SNF5, and SNF6 genes are required for transcription of many diversely regulated genes in Saccharomyces cerevisiae. Previously, we showed that SNF2, SNF5, and SNF6 function interdependently in transcriptional activation, possibly forming a heteromeric complex. Here, we present evidence that SNF6 has a more direct role in stimulating transcription than SNF2 and SNF5. The global effects of mutations in SNF2, SNF5, and SNF6 suggested that these SNF proteins may function coordinately with many gene-specific activators. We show that LexA-GAL4 and LexA-Bicoid fusion proteins are both dependent on SNF2, SNF5, and SNF6 for activation of target genes containing one or multiple lexA operators. The stringency of the requirement for the SNF proteins varies with the activator, the number of binding sites for the activator, and the target promoter. Thus, these SNF proteins appear to represent a class of intermediary proteins that facilitate transcriptional activation by gene-specific regulatory proteins.

Interaction of LexA repressor with the asymmetric dinG operator and complete nucleotide sequence of the gene.

The dinG gene was originally isolated during a search for Escherichia coli promoters which are components of the SOS regulon. The regulatory region of this gene contains a potential binding site for LexA repressor which is quite different from other known sites. All previously described chromosomal LexA operators are imperfect palindromes containing the sequence CTG(N10)CAG. The noncanonical dinG sequence breaks the symmetry and takes the form TTG(N10)CAG. In the present study, a search for mutations within dinGop::galK fusion plasmids which render transcription independent of intracellular levels of LexA has yielded mutations only within this 16-bp sequence. Electrophoretic mobility shift assays performed with purified mutant and wild-type operator fragments revealed that the affinity of LexA for each of the mutant sites is greatly reduced compared with that of the wild type. One of the mutants contained an alteration in the putative promoter of dinG which increased the similarity of the -35 region to the consensus sequence (TTGGCT----TTGACT); the apparent promoter activity of this construct was subsequently found to be approximately eight times higher than that of the wild type in vivo. Additional experiments have established the complete nucleotide sequence of the dinG gene. A long open reading frame located immediately downstream of the asymmetric operator segment which could potentially encode a 72.9-kDa DinG protein was identified.

MAT alpha 1 can mediate gene activation by a-mating factor.

In the yeast Saccharomyces cerevisiae, expression of alpha-specific genes is governed by the MAT alpha 1 and MCM1 gene products. MAT alpha 1 and MCM1 bind cooperatively to PQ elements upstream of alpha-specific genes. The PQ element not only directs alpha-specific expression but can also direct gene induction in response to treatment with a-mating pheromone. We have used gene fusions to investigate whether induction conferred by the PQ box is mediated through either MAT alpha 1 or MCM1, or a combination of both. When MCM1 is fused to the DNA-binding domain of the bacterial repressor LexA, this fusion protein is capable of trans-activating a lacZ reporter gene driven by a LexA operator. However, the transcriptional activity of the MCM1-LexA fusion is not further enhanced by treatment of cells with a-factor. A MAT alpha 1-LexA fusion protein is also capable of trans-activation through a LexA operator. Moreover, the activity of the MAT alpha 1-LexA fusion protein can be further induced by treatment with a-factor. When progressive deletions are made from the amino terminus of MAT alpha 1 in the fusion protein, the basal level of trans-activation progressively decreases, but the inducibility of the fusion protein increases. MAT alpha 1-LexA fusion proteins, which have greater than or equal to 57 amino acids deleted from the amino terminus of MAT alpha 1 are not capable of trans-activation. In addition, the activity of the MAT alpha 1-LexA fusion protein is dependent on the functions of the STE7, STE11, and STE12 genes that encode components of the pheromone response pathway.

Assessment of the transcriptional activation potential of the HMG chromosomal proteins.

Chromosomal proteins HMG-14, HMG-17, and HMG-1 are among the most abundant, ubiquitous, and evolutionarily conserved nonhistone proteins. Analysis of their structure reveals features which are similar to those of certain transcription factors. The distribution of charged amino acid residues along the polypeptide chains is asymmetric: positive charges are clustered toward the N-terminal region, while negative charges are clustered toward the C-terminal region. The residues in the C-terminal region have the potential to form alpha helices with negatively charged surfaces. The abilities of HMG-14, -17, and -1 to function as transcriptional activators were studied in Saccharomyces cerevisiae cells expressing LexA-HMG fusion proteins (human HMG-14 and -17 and rat HMG-1) which bind to reporter molecules containing the beta-galactosidase gene downstream from a lexA operator. Fusion constructs expressing deletion mutants of HMG-14, -17, and -1 were also tested. Analysis of binding to the lexA operator with in vitro-synthesized fusion proteins shows that there are more sites for HMG-14, -17, and -1 binding than for LexA binding and that only the fusion constructs which contain the C-terminal, acidic domains of HMG-17 bind the lexA operator specifically. None of the LexA-HMG fusion protein constructs elevate the level of beta-galactosidase activity in transfected yeast cells. Thus, although HMG-14, -17, and -1 are structurally similar to acidic transcriptional activators, these chromosomal proteins do not function as activators in this test system.

Assessment of the Transcriptional Activation Potential of the HMG Chromosomal Proteins

Chromosomal proteins HMG-14, HMG-17, and HMG-1 are among the most abundant, ubiquitous, and evolutionarily conserved nonhistone proteins. Analysis of their structure reveals features which are similar to those of certain transcription factors. The distribution of charged amino acid residues along the polypeptide chains is asymmetric: positive charges are clustered toward the N-terminal region, while negative charges are clustered toward the C-terminal region. The residues in the C-terminal region have the potential to form alpha helices with negatively charged surfaces. The abilities of HMG-14, -17, and -1 to function as transcriptional activators were studied in Saccharomyces cerevisiae cells expressing LexA-HMG fusion proteins (human HMG-14 and -17 and rat HMG-1) which bind to reporter molecules containing the beta-galactosidase gene downstream from a lexA operator. Fusion constructs expressing deletion mutants of HMG-14, -17, and -1 were also tested. Analysis of binding to the lexA operator with in vitro-synthesized fusion proteins shows that there are more sites for HMG-14, -17, and -1 binding than for LexA binding and that only the fusion constructs which contain the C-terminal, acidic domains of HMG-17 bind the lexA operator specifically. None of the LexA-HMG fusion protein constructs elevate the level of beta-galactosidase activity in transfected yeast cells. Thus, although HMG-14, -17, and -1 are structurally similar to acidic transcriptional activators, these chromosomal proteins do not function as activators in this test system.

The SNF5 Protein of Saccharomyces cerevisiae Is a Glutamine- and Proline-Rich Transcriptional Activator That Affects Expression of a Broad Spectrum of Genes

The Saccharomyces cerevisiae SNF5 gene affects expression of both glucose- and phosphate-regulated genes and appears to function in transcription. We report the nucleotide sequence, which predicts that SNF5 encodes a 102,536-dalton protein. The N-terminal third of the protein is extremely rich in glutamine and proline. Mutants carrying a deletion of the coding sequence were viable but grew slowly, indicating that the SNF5 gene is important but not essential. Evidence that SNF5 affects expression of the cell type-specific genes MF alpha 1 and BAR1 at the RNA level extends the known range of SNF5 function. SNF5 is apparently required for expression of a wide variety of differently regulated genes. A bifunctional SNF5-beta-galactosidase fusion protein was localized in the nucleus by immunofluorescence. No DNA-binding activity was detected for SNF5. A LexA-SNF5 fusion protein, when bound to a lexA operator, functioned as a transcriptional activator.

The SNF5 protein of Saccharomyces cerevisiae is a glutamine- and proline-rich transcriptional activator that affects expression of a broad spectrum of genes.

The Saccharomyces cerevisiae SNF5 gene affects expression of both glucose- and phosphate-regulated genes and appears to function in transcription. We report the nucleotide sequence, which predicts that SNF5 encodes a 102,536-dalton protein. The N-terminal third of the protein is extremely rich in glutamine and proline. Mutants carrying a deletion of the coding sequence were viable but grew slowly, indicating that the SNF5 gene is important but not essential. Evidence that SNF5 affects expression of the cell type-specific genes MF alpha 1 and BAR1 at the RNA level extends the known range of SNF5 function. SNF5 is apparently required for expression of a wide variety of differently regulated genes. A bifunctional SNF5-beta-galactosidase fusion protein was localized in the nucleus by immunofluorescence. No DNA-binding activity was detected for SNF5. A LexA-SNF5 fusion protein, when bound to a lexA operator, functioned as a transcriptional activator.