DNA looping

DNA constraints on transcription activation in vitro

Activators of eukaryotic transcription often function over a range of distances. It is commonly hypothesized that the intervening DNA between the transcription start site and the activator binding sites forms a loop in order to allow the activators to interact with the basal transcription apparatus, either directly or through mediators. If this hypothesis is correct, activation should be sensitive to the presence of intrinsic bends in the intervening DNA. Similarly, the precise helical phasing of such DNA bends and of the activator binding sites relative to the basal promoter should affect the degree of transcription activation. To explore these considerations, we designed transcription templates based on the adenovirus E4 promoter supplemented with upstream Gal4 activator binding sites. Surprisingly, we found that neither insertion of intrinsically curved DNA sequences between the activator binding sites and the basal promoter, nor alteration of the relative helical alignment of the activator binding sites and the basal promoter significantly affected in vitro transcription activation in HeLa cell nuclear extract. In all cases, the degree of transcription activation was a simple inverse function of the length of intervening DNA. Possible implications of these unexpected results are discussed.

The McrBC endonuclease translocates DNA in a reaction dependent on GTP hydrolysis

McrBC specifically recognizes and cleaves methylated DNA in a reaction dependent on GTP hydrolysis. DNA cleavage requires at least two recognition sites that are optimally separated by 40-80 bp, but can be spaced as far as 3 kb apart. The nature of the communication between two recognition sites was analyzed on DNA substrates containing one or two recognition sites. DNA cleavage of circular DNA required only one methylated recognition site, whereas the linearized form of this substrate was not cleaved. However, the linearized substrate was cleaved if a Lac repressor was bound adjacent to the recognition site. These results suggest a model in which communication between two remote sites is accomplished by DNA translocation rather than looping. A mutant protein with defective GTPase activity cleaved substrates with closely spaced recognition sites, but not substrates where the sites were further apart. This indicates that McrBC translocates DNA in a reaction dependent on GTP hydrolysis. We suggest that DNA cleavage occurs by the encounter of two DNA-translocating McrBC complexes, or can be triggered by non-specific physical obstacles like the Lac repressor bound on the enzyme's path along DNA. Our results indicate that McrBC belongs to the general class of DNA "motor proteins", which use the free energy associated with nucleoside 5'-triphosphate hydrolysis to translocate along DNA.

The biology of eukaryotic promoter prediction--a review

Computational prediction of eukaryotic promoters from the nucleotide sequence is one of the most attractive problems in sequence analysis today, but it is also a very difficult one. Thus, current methods predict in the order of one promoter per kilobase in human DNA, while the average distance between functional promoters has been estimated to be in the range of 30-40 kilobases. Although it is conceivable that some of these predicted promoters correspond to cryptic initiation sites that are used in vivo, it is likely that most are false positives. This suggests that it is important to carefully reconsider the biological data that forms the basis of current algorithms, and we here present a review of data that may be useful in this regard. The review covers the following topics: (1) basal transcription and core promoters, (2) activated transcription and transcription factor binding sites, (3) CpG islands and DNA methylation, (4) chromosomal structure and nucleosome modification, and (5) chromosomal domains and domain boundaries. We discuss the possible lessons that may be learned, especially with respect to the wealth of information about epigenetic regulation of transcription that has been appearing in recent years.

Gene activation by the AraC protein can be inhibited by DNA looping between AraC and a LexA repressor that interacts with AraC: possible applications as a two-hybrid system

The Escherichia coli activator and repressor proteins AraC and LexA bind DNA as homodimers. Here we show that their heterodimerization through fused cognate dimerization domains results in repression of AraC-dependent gene activation by LexA. Repression also requires a LexA operator half-site located several helical turns downstream of the AraC operator. This requirement for a specific spatial organization of the operators suggests the formation of a DNA loop between operator-bound Ara/LexA heterodimers, and we propose that heterodimerization with the AraC hybrid provides co-operativity for operator binding and repression by the LexA hybrid. Consistent with a mechanism that involves DNA looping, repression increases when the E. coli DNA looping and transcriptional effector protein IHF binds between the AraC and LexA operators. Thus, we have combined the functions of three distinct transcriptional effector proteins to achieve a new mode of gene regulation by DNA looping, in which the activator protein is an essential part of the repressor complex. The flexibility of the DNA loop may facilitate this novel combinatorial arrangement of those proteins on the DNA. The requirement for protein interactions between the AraC and LexA hybrids for gene regulation suggests that this regulatory circuit may prove useful as an E. coli-based two-hybrid system.

The function of auxiliary operators

Gene regulation by control of transcription has been analysed in great detail both in prokaryotes and in eukaryotes. The frequency of transcription may be decreased by repressors or increased by activators. A repressor may work by decreasing the concentration of RNA polymerase at a promoter capable of forming an open complex. An activator may work by increasing the concentration of RNA polymerase at a promoter capable of forming an open complex. For this purpose, a strategy is used over and over again. It is called increase in local concentration. How Escherichia coli uses this strategy efficiently is discussed.

Cooperative binding properties of restriction endonuclease EcoRII with DNA recognition sites

EcoRII is a member of the expanding group of type IIe restriction endonucleases that share the distinguishing feature of requiring cooperativity between two recognition sites in their substrate DNA. To determine the stoichiometry of the active DNA-enzyme complex and the mode of cooperative interaction, we have investigated the dependence of EcoRII cleavage on the concentration of EcoRII dimers. Maximal restriction was observed at dimer/site ratios of 0.25 and 0. 5. The molecular weight of the DNA-enzyme complex eluted from a gel filtration column also corresponds to a dimeric enzyme structure bound to two substrate sites. We conclude that one EcoRII dimer is sufficient to interact cooperatively with two DNA recognition sites. A Lac repressor "barrier" bound between two normally reactive EcoRII sites did not inhibit restriction endonuclease activity, indicating that cooperativity between EcoRII sites is achieved by bending or looping of the intervening DNA stretch. Comparative cleavage of linear substrates with differently spaced interacting sites revealed an inverse correlation between cleavage rate and site distance. At the optimal distance of one helical turn, EcoRII cleavage is independent of the orientation of the recognition sequence in the DNA double strand.

Positive and negative transcriptional regulation of the Escherichia coli gluconate regulon gene gntT by GntR and the cyclic AMP (cAMP)-cAMP receptor protein complex

The gntT gene of Escherichia coli is specifically induced by gluconate and repressed via catabolite repression. Thus, gluconate is both an inducer and a repressor of gntT expression since gluconate is a catabolite-repressing sugar. In a gntR deletion mutant, the expression of a chromosomal gntT::lacZ fusion is both high and constitutive, confirming that GntR is the negative regulator of gntT. Indeed, GntR binds to two consensus gnt operator sites; one overlaps the -10 region of the gntT promoter, and the other is centered at +120 with respect to the transcriptional start site. The binding of GntR to these sites was proven in vitro by gel redardation assays and in vivo by site-directed mutagenesis of the binding sites. Binding of GntR to the operators is eliminated by gluconate and also by 6-phosphogluconate at a 10-fold-higher concentration. Interestingly, when gntR deletion strains are grown in the presence of gluconate, there is a twofold decrease in gntT expression which is independent of catabolite repression and binding of GntR to the operator sites. This novel response of gntR mutants to the inducer is termed ultrarepression. Transcription of gntT is activated by binding of the cyclic AMP (cAMP)-cAMP receptor protein (CRP) complex to a CRP binding site positioned at -71 upstream of the gntT transcription start site.

A protein-induced DNA bend increases the specificity of a prokaryotic enhancer-binding protein

Control of transcription in prokaryotes often involves direct contact of regulatory proteins with RNA polymerase from binding sites located adjacent to the target promoter. Alternatively, in the case of genes transcribed by Escherichia coli RNA polymerase holoenzyme containing the alternate sigma factor sigma54, regulatory proteins bound at more distally located enhancer sites can activate transcription via DNA looping by taking advantage of the increasing flexibility of DNA over longer distances. While this second mechanism offers a greater possible flexibility in the location of these binding sites, it is not clear how the specificity offered by the proximity of the regulatory protein and the polymerase intrinsic to the first mechanism is maintained. Here we demonstrate that integration host factor (IHF), a protein that induces a sharp bend in DNA, acts both to inhibit DNA-looping-dependent transcriptional activation by an inappropriate enhancer-binding protein and to facilitate similar activation by an appropriate enhancer-binding protein. These opposite effects have the consequence of increasing the specificity of activation of a promoter that is susceptible to regulation by proteins bound to a distal site.

Analysis of immunoglobulin Sgamma3 recombination breakpoints by PCR: implications for the mechanism of isotype switching

The molecular mechanism of immunoglobulin switch recombination is poorly understood. Switch recombination occurs between pairs of switch regions located upstream of the constant heavy chain genes. Previously we showed that switch recombination breakpoints cluster to a defined subregion in the Sgamma3, Sgamma1 and Sgamma2b tandem repeats. We have developed a strategy for direct amplification of Smu/Sgamma3 composite fragments as well as Smu and Sgamma3 regions by PCR. This assay has been used to analyze the organization of Smu, Sgamma3 and a series of Smu/Sgamma3 recombination breakpoints from hybridomas and normal mitogen-activated splenic B cells. DNA sequence analysis of the switch fragments showed direct joining of Smu and Sgamma3 without deletions or duplications. Mutations were found in two switch junctions on both sides of the crossover point, suggesting that template switching is the most likely model for the mechanism of switch recombination. Statistical analysis of the positions of the recombination breakpoints in the Sgamma3 tandem repeat indicates the presence of two sub-clusters, suggesting non-random usage of DNA substrate in the recombination reaction.

The cellular transcription factor SP1 and an unknown cellular protein are required to mediate Rep protein activation of the adeno-associated virus p19 promoter

Control of adeno-associated virus (AAV) transcription from the three AAV promoters (p5, p19, and p40) requires the adenovirus E1a protein and the AAV nonstructural (Rep) proteins. The Rep proteins have been shown to repress the AAV p5 promoter yet facilitate activation of the p19 and p40 promoters during a productive infection. To elucidate the mechanism of promoter regulation by the AAV Rep proteins, the cellular factors involved in mediating Rep activation of the p19 promoter were characterized. A series of protein-DNA binding experiments using extracts derived from uninfected HeLa cells was performed to identify cellular factors that bind to the p19 promoter. Electrophoretic mobility shift assays, DNase I protection analyses, and UV cross-linking experiments demonstrated specific interactions with the cellular factor SP1 (or an SP1-like protein) at positions -50 and -130 relative to the start of p19 transcription. Additionally, an unknown cellular protein (cellular AAV activating protein [cAAP]) with an approximate molecular mass of 34 kDa was found to interact with a CArG-like element at position -140. Mutational analysis of the p19 promoter suggested that the SP1 site at -50 and the cAAP site at -140 were necessary to mediate Rep activation of p19. Antibody precipitation experiments demonstrated that Rep-SP1 protein complexes can exist in vivo. Although Rep was demonstrated to interact with p19 DNA directly, the affinity of Rep binding was much lower than that seen for the Rep binding elements within the terminal repeat and the p5 promoter. Furthermore, the interaction of purified Rep68 with the p19 promoter in vitro was negligible unless purified SP1 was also added to the reaction. Thus, the ability of Rep to transactivate the p19 promoter is likely to involve SP1-Rep protein contacts that facilitate Rep interaction with p19 DNA.

Inducible gene expression and environmentally regulated genes in lactic acid bacteria

Relatively recently, a number of genes and operons have been identified in lactic acid bacteria that are inducible and respond to environmental factors. Some of these genes/operons had been isolated and analysed because of their importance in the fermentation industry and, consequently, their transcription was studied and found to be regulatable. Examples are the lactose operon, the operon for nisin production, and genes in the proteolytic pathway of Lactococcus lactis, as well as xylose metabolism in Lactobacillus pentosus. Some other operons were specifically targetted with the aim to compare their mode of regulation with known regulatory mechanisms in other well-studied bacteria. These studies, dealing with the biosynthesis of histidine, tryptophan, and of the branched chain amino acids in L. lactis, have given new insights in gene regulation and in the occurrence of auxotrophy in these bacteria. Also, nucleotide sequence analyses of a number of lactococcal bacteriophages was recently initiated to, among other things, specifically learn more about regulation of the phage life cycle. Yet another approach in the analysis of regulated genes is the 'random' selection of genetic elements that respond to environmental stimuli and the first of such sequences from lactic acid bacteria have been identified and characterized. The potential of these regulatory elements in fundamental research and practical (industrial) applications will be discussed.

The Spo0A protein of Bacillus subtilis inhibits transcription of the abrB gene without preventing binding of the polymerase to the promoter

Repression of transcription of the abrB gene is essential to expression of many of the postexponential genes in Bacillus. The repression is due to the activity of the response regulator protein Spo0A. We have used in vitro transcription and DNase I and hydroxyl radical footprinting to explore the mechanism of transcription inhibition. Spo0A binds to specific DNA sequences (0A boxes), and two such boxes are found downstream of the tandem promoters for the abrB gene. The data indicate that both RNA polymerase and Spo0A bind simultaneously to a DNA fragment containing the promoters and the 0A boxes. The Spo0A prevents the polymerase from inducing DNA strand denaturation at the promoter for the abrB gene.

Dimer-dimer interfaces of the lambda-repressor are different in liganded and free states

Lambda-repressor dimers associate in solution to form tetramers and higher order structures. Dimer-dimer contact is also crucial in cooperative binding to adjacent operators. Fluorescence quenching studies indicate that the tryptophan 230 environment is significantly different in unliganded and adjacent operator-bound tetramers. Acrylodan attached to Cys 235, in a mutant F235C repressor, is also in different environments in the unliganded and adjacent operator bound tetramers. Thermodynamics of protein association, measured by fluorescence anisotropy, indicate that, whereas free repressor dimer association is strongly enthalpy driven, the single-operator (OR1)-bound repressor dimer association is largely entrophy driven with little change in enthalpy. Single-operator-bound dimer association to the corresponding tetramer does not lead to any significant change in tryptophan 230 environment, as was seen in the case of the free repressor. Data are also presented to support the contention that, under the conditions of this study, the free repressor association is predominantly from dimer to tetramer and then to octamer, unlike the dimer to octamer transition observed under a different condition. The results presented here point toward the conclusion that the lambda-repressor dimer-dimer interface is significantly different in the free and operator-bound states and that operator binding plays a crucial role in changing the nature of the dimer-dimer interface.

Regulation of gene expression at a distance: the hypothetical role of regulatory protein-mediated topological changes of DNA

A theoretical model is presented that a regulatory protein may activate the transcription of a promoter by interacting with a single remote operator. In response to an inducer molecule the regulatory protein bound to the operator undergoes a conformational change, and might mediate a B to Z-DNA conversion of the operator. This transition would remove both helical turns and supercoils from the intervening region between the operator and the promoter, resulting in the correct spatial arrangement of the -10 and -35 hexamers of the promoter, which therefore can be efficiently transcribed.

Identification of Epstein-Barr virus nuclear antigen 1 protein domains that direct interactions at a distance between DNA-bound proteins

The EBNA1 protein of Epstein-Barr virus (EBV) binds to and activates DNA replication from the EBV latent origin of replication, oriP, via a direct interaction with the two noncontiguous subelements of oriP. The EBNA1 molecules bound to the oriP subelements interact efficiently with each other by a DNA looping mechanism. We have previously mapped a region of EBNA1 (termed the looping region) that is required to mediate the interaction of the EBNA1 molecules bound to the oriP subelements. We now demonstrate that two fragments of this region of EBNA1, which consist largely of an eight amino acid repeat, can mediate homotypic interactions when transferred to another DNA-binding protein. Protein interactions mediated by the EBNA1 looping region appear to be dependent on DNA binding since these interactions were detected between DNA-bound forms of the proteins only.

Circular structures in retroviral and cellular genomes

A computer program for predicting DNA bending from nucleotide sequence was used to identify circular structures in retroviral and cellular genomes. An 830-base pair circular structure was located in a control region near the center of the genome of the human immunodeficiency virus type I (HIV-I). This unusual structure displayed relatively smooth planar bending throughout its length. The structure is conserved in diverse isolates of HIV-I, HIV-II, and simian immunodeficiency viruses, which implies that it is under selective constraints. A search of all sequences in the GenBank data base was carried out in order to identify similar circular structures in cellular DNA. The results revealed that the structures are associated with a wide range of sequences that undergo recombination, including most known examples of DNA inversion and subtelomeric translocation systems. Circular structures were also associated with replication and transposition systems where DNA looping has been implicated in the generation of large protein-DNA complexes. Experimental evidence for the structures was provided by studies which demonstrated that two sequences detected as circular by computer preferentially formed covalently closed circles during ligation reactions in vitro when compared to nonbent fragments, bent fragments with noncircular shapes, and total genomic DNA. In addition, a single T-->C substitution in one of these sequences rendered it less planar as seen by computer analysis and significantly reduced its rate of ligase-catalyzed cyclization. These results permit us to speculate that intrinsically circular structures facilitate DNA looping during formation of the large protein-DNA complexes that are involved in site- and region-specific recombination and in other genomic processes.

Flexing and folding double helical DNA

DNA base sequence, once thought to be interesting only as a carrier of the genetic blueprint, is now recognized as playing a structural role in modulating the biological activity of genes. Primary sequences of nucleic acid bases describe real three-dimensional structures with properties reflecting those structures. Moreover, the structures are base sequence dependent with individual residues adopting characteristic spatial forms. As a consequence, the double helix can fold into tertiary arrangements, although the deformation is much more gradual and spread over a larger molecular scale than in proteins. As part of an effort to understand how local structural irregularities are translated at the macromolecular level in DNA and recognized by proteins, a series of calculations probing the structure and properties of the double helix have been performed. By combining several computational techniques, complementary information as well as a series of built-in checks and balances for assessing the significance of the findings are obtained. The known sequence dependent bending, twisting, and translation of simple dimeric fragments have been incorporated into computer models of long open DNAs of varying length and chemical composition as well as in closed double helical circles and loops. The extent to which the double helix can be forced to bend and twist is monitored with newly parameterized base sequence dependent elastic energy potentials based on the observed configurations of adjacent base pairs in the B-DNA crystallographic literature.

Interaction of the Neisseria gonorrhoeae PilA protein with the pilE promoter involves multiple sites on the DNA

PilA is the putative DNA-binding component of a two-component system that regulates transcription of the pilin expression locus (pilE) of Neisseria gonorrhoeae. Here we report the purification of the PilA protein and characterization of its DNA-binding activity. PilA was overproduced in Escherichia coli with an isopropyl-beta-D-thiogalactopyranoside (IPTG)-inducible expression vector. Cell extracts were prepared by sonication and fractionated by anion-exchange chromotography, followed by dye affinity chromatography with Cibacron Blue. Proteins were eluted by using a gradient of KCl, and PilA-containing fractions were identified by immunoblot analysis with a polyclonal anti-PilA antiserum. Purified PilA was judged to be > 90% pure, as determined by Coomassie blue staining and sodium dodecyl sulfate-polyacrylamide gel electrophoresis. PilA purified in this manner was used to develop a gel retardation assay with a 301-bp fragment containing the pilE promoter (PpilE) and upstream sequences as a probe. A fragment of similar size containing the E. coli aroH promoter was used as a negative control. Competition experiments using a 100- to 1,000-fold excess of unlabelled DNA fragments confirmed the specificity of PilA binding to the pilE promoter. To localize the PilA binding site within the 301-bp PpilE fragment, stepwise deletions were generated by PCR and the fragments were examined in the gel shift assay. The results of these experiments show that there are two regions upstream of PpilE that are required for binding by PilA. Taken together, these data indicate that while PilA binds specifically to the upstream region of the pilE gene, this interaction is complex and likely involves multiple regions of this DNA sequence.

Measurement of lactose repressor-mediated loop formation and breakdown in single DNA molecules

In gene regulatory systems in which proteins bind to multiple sites on a DNA molecule, the characterization of chemical mechanisms and single-step reaction rates is difficult because many chemical species may exist simultaneously in a molecular ensemble. This problem was circumvented by detecting DNA looping by the lactose repressor protein of Escherichia coli in single DNA molecules. The looping was detected by monitoring the nanometer-scale Brownian motion of microscopic particles linked to the ends of individual DNA molecules. This allowed the determination of the rates of formation and breakdown of a protein-mediated DNA loop in vitro. The measurements reveal that mechanical strain stored in the loop does not substantially accelerate loop breakdown, and the measurements also show that subunit dissociation of tetrameric repressor is not the predominant loop breakdown pathway.

DNA bending by asymmetric phosphate neutralization

DNA is often bent when complexed with proteins. Understanding the forces responsible for DNA bending would be of fundamental value in exploring the interplay of these macromolecules. A series of experiments was devised to test the hypothesis that proteins with cationic surfaces can induce substantial DNA bending by neutralizing phosphates on one DNA face. Repulsions between phosphates in the remaining anionic helix are predicted to result in an unbalanced compression force acting to deform the DNA toward the protein. This hypothesis is supported by the results of electrophoretic experiments in which DNA spontaneously bends when one helical face is partially modified by incorporation of neutral phosphate analogs. Phasing with respect to a site of intrinsic DNA curvature (hexadeoxyadenylate tract) permits estimation of the electrostatic bend angle, and demonstrates that such modified DNAs are deformed toward the neutralized surface, as predicted. Similar model systems may be useful in exploring the extent to which phosphate neutralization can account for DNA bending by particular proteins.

Promoters responsive to DNA bending: a common theme in prokaryotic gene expression

The early notion of DNA as a passive target for regulatory proteins has given way to the realization that higher-order DNA structures and DNA-protein complexes are at the basis of many molecular processes, including control of promoter activity. Protein binding may direct the bending of an otherwise linear DNA, exacerbate the angle of an intrinsic bend, or assist the directional flexibility of certain sequences within prokaryotic promoters. The important, sometimes essential role of intrinsic or protein-induced DNA bending in transcriptional regulation has become evident in virtually every system examined. As discussed throughout this article, not every function of DNA bends is understood, but their presence has been detected in a wide variety of bacterial promoters subjected to positive or negative control. Nonlinear DNA structures facilitate and even determine proximal and distal DNA-protein and protein-protein contacts involved in the various steps leading to transcription initiation.

A distant upstream site involved in the negative regulation of the Escherichia coli ompF gene

The two-component regulatory system, OmpR-EnvZ, of Escherichia coli K-12 regulates the expression of the major outer membrane porin protein, OmpF. OmpR is a DNA-binding protein which acts as both an activator and a repressor to control ompF transcription. In this article, we describe a new OmpR-binding site that is located between 384 to 351 bp upstream from the ompF start point of transcription. Inactivation of this site by insertion of a 22-bp fragment prevents the repression of ompF expression conferred by the dominant negative mutation, envZ473. On the basis of the location of this binding site, the presence of bent DNA in the ompF regulatory region (T. Mizuno, Gene 54:57-64, 1987), and the fact that mutations altering integration host factor result in constitutive ompF expression (P. Tsui, V. Helu, and M. Freundlich, J. Bacteriol. 170:4950-4953, 1988), we propose that the negative regulation of ompF involves a DNA loop structure.

Regulation of Escherichia coli purA by purine repressor, one component of a dual control mechanism

Escherichia coli purA encodes adenylosuccinate synthetase, one of two enzymes required for synthesis of AMP from IMP. purA is subject to two- to threefold regulation by purR and about twofold regulation by a purR-independent mechanism. The 5'-flanking region of purA confers purR-dependent transcriptional regulation of purA but not the purR-independent regulation. Two operator sites in the 5'-flanking region which bind purine repressor in vitro and are required for in vivo regulation were identified. The purR-independent regulation may be posttranscriptional. It is now established that all transcription units involved in de novo synthesis of purine nucleotides, nine pur operons, as well as purR itself and guaBA, are subject to purR control.

A common element involved in transcriptional regulation of two DNA alkylation repair genes (MAG and MGT1) of Saccharomyces cerevisiae

The Saccharomyces cerevisiae MAG gene encodes a 3-methyladenine DNA glycosylase that protects cells from killing by alkylating agents. MAG mRNA levels are induced not only by alkylating agents but also by DNA-damaging agents that do not produce alkylated DNA. We constructed a MAG-lacZ gene fusion to help identify the cis-acting promoter elements involved in regulating MAG expression. Deletion analysis defined the presence of one upstream activating sequence and one upstream repressing sequence (URS) and suggested the presence of a second URS. One of the MAG URS elements matches a decamer consensus sequence present in the promoters of 11 other S. cerevisiae DNA repair and metabolism genes, including the MGT1 gene, which encodes an O6-methylguanine DNA repair methyltransferase. Two proteins of 26 and 39 kDa bind specifically to the MAG and MGT1 URS elements. We suggest that the URS-binding proteins may play an important role in the coordinate regulation of these S. cerevisiae DNA repair genes.

A common element involved in transcriptional regulation of two DNA alkylation repair genes (MAG and MGT1) of Saccharomyces cerevisiae

The Saccharomyces cerevisiae MAG gene encodes a 3-methyladenine DNA glycosylase that protects cells from killing by alkylating agents. MAG mRNA levels are induced not only by alkylating agents but also by DNA-damaging agents that do not produce alkylated DNA. We constructed a MAG-lacZ gene fusion to help identify the cis-acting promoter elements involved in regulating MAG expression. Deletion analysis defined the presence of one upstream activating sequence and one upstream repressing sequence (URS) and suggested the presence of a second URS. One of the MAG URS elements matches a decamer consensus sequence present in the promoters of 11 other S. cerevisiae DNA repair and metabolism genes, including the MGT1 gene, which encodes an O6-methylguanine DNA repair methyltransferase. Two proteins of 26 and 39 kDa bind specifically to the MAG and MGT1 URS elements. We suggest that the URS-binding proteins may play an important role in the coordinate regulation of these S. cerevisiae DNA repair genes.

A novel antivirulence element in the temperate bacteriophage HK022

Lysogens of the temperate lambdoid phage HK022 are immune to superinfection by HK022. Superinfection immunity is conferred in part by the action of the HK022 CI repressor at the O.R operators. In this work, we have identified an additional regulatory element involved in immunity. This site, termed OFR (operator far right), is located just downstream of the cro gene, more than 250 nucleotides distant from OR. The behavior of phage containing a mutation in OFR suggests that the wild-type site functions as an antivirulence element. HK022 OFR- mutants were able to form turbid plaques indistinguishable from those of the wild type. However, they gave rise to virulent derivatives at a far higher frequency than the wild type (approximately 10(-5) for OFR- versus about 10(-9) for the wild type). This frequency was so high that cultures of HK022 OFR- lysogens were rapidly overgrown by virulent derivatives. Whereas virulent mutants arising from a wild-type OFR+ background contained mutations in both OR1 and OR2, virulent derivatives of the OFR- mutant phage contained a single mutation in either OR1 or OR2. We conclude that the wild-type OFR site functions to prevent single mutations in OR from conferring virulence. The mechanism by which OFR acts is not yet clear. Both CI and Cro bound to OFR and repressed a very weak rightward promoter (PFR). It is unlikely that repression of PFR by CI or Cro binding to OFR can account in full for the antivirulence phenotype conferred by this element, since PFR is such a weak promoter. Other models for the possible action of OFR are discussed.

Analysis of Streptococcus pyogenes promoters by using novel Tn916-based shuttle vectors for the construction of transcriptional fusions to chloramphenicol acetyltransferase

We have developed a series of shuttle vectors based on the conjugative transposon Tn916 that have been designed for the analysis of transcriptional regulation in Streptococcus pyogenes and other gram-positive bacteria. Designated the pVIT vectors (vectors for integration into Tn916), the vectors are small, stable plasmids in Escherichia coli to facilitate the fusion of promoters from cloned S. pyogenes genes to a promoterless gene which encodes chloramphenicol acetyltransferase. The vectors each contain one or more small regions of Tn916 to direct the integration of the transcriptional fusion into the transposon via homologous recombination following transformation of S. pyogenes or other suitable gram-positive hosts. Integration can be monitored by the inactivation or replacement of an antibiotic resistance determinant in modified derivatives of Tn916. Promoter activity can then be quantitated by the determination of chloramphenicol acetyltransferase-specific activity. In addition, since integration is into loci that do not disrupt the conjugative transpositional functions of Tn916, the vectors are useful for analysis of regulation in strains that are difficult or impossible to transform and can be introduced into these strains by conjugation following transformation of an intermediate host. The promoters for the genes which encode both the M protein and protein F of S. pyogenes were active in pVIT vectors, as was the region which controls transcription of mry, a trans-acting positive regulator of M protein expression. However, neither of the two characterized promoters for mry demonstrated activity when independently analyzed in pVIT-generated partial diploid strains, suggesting that regulation of mry is more complex than predicted by current models. The broad host range of Tn916 should make the pVIT vectors useful for analysis of regulation in numerous other bacterial species.

Cooperative binding of an Ultrabithorax homeodomain protein to nearby and distant DNA sites

Cooperativity in binding of regulatory proteins to multiple DNA sites can heighten the sensitivity and specificity of the transcriptional response. We report here the cooperative DNA-binding properties of a developmentally active regulatory protein encoded by the Drosophila homeotic gene Ultrabithorax (Ubx). We show that naturally occurring binding sites for the Ubx-encoded protein contain clusters of multiple individual binding site sequences. Such sites can form complexes containing a dozen or more Ubx-encoded protein molecules, with simultaneous cooperative interactions between adjacent and distant DNA sites. The distant mode of interaction involves a DNA looping mechanism; both modes appear to enhance transcriptional activation in a simple yeast assay system. We found that cooperative binding is dependent on sequences outside the homeodomain, and we have identified regions predicted to form coiled coils carboxy terminal to the homeodomains of the Ubx-encoded protein and several other homeotic proteins. On the basis of our findings, we propose a multisite integrative model of homeotic protein action in which functional regulatory elements can be built from a few high-affinity sites, from many lower-affinity sites, or from sites of some intermediate number and affinity. An important corollary of this model is that even small differences in binding of homeotic proteins to individual sites could be summed to yield large overall differences in binding to multiple sites. This model is consistent with reports that homeodomain protein targets contain multiple individual binding site sequences distributed throughout sizable DNA regions. Also consistent is a recent report that sequences carboxy terminal to the Ubx homeodomain can contribute to segmental specificity.

Cooperative binding of an Ultrabithorax homeodomain protein to nearby and distant DNA sites

Cooperativity in binding of regulatory proteins to multiple DNA sites can heighten the sensitivity and specificity of the transcriptional response. We report here the cooperative DNA-binding properties of a developmentally active regulatory protein encoded by the Drosophila homeotic gene Ultrabithorax (Ubx). We show that naturally occurring binding sites for the Ubx-encoded protein contain clusters of multiple individual binding site sequences. Such sites can form complexes containing a dozen or more Ubx-encoded protein molecules, with simultaneous cooperative interactions between adjacent and distant DNA sites. The distant mode of interaction involves a DNA looping mechanism; both modes appear to enhance transcriptional activation in a simple yeast assay system. We found that cooperative binding is dependent on sequences outside the homeodomain, and we have identified regions predicted to form coiled coils carboxy terminal to the homeodomains of the Ubx-encoded protein and several other homeotic proteins. On the basis of our findings, we propose a multisite integrative model of homeotic protein action in which functional regulatory elements can be built from a few high-affinity sites, from many lower-affinity sites, or from sites of some intermediate number and affinity. An important corollary of this model is that even small differences in binding of homeotic proteins to individual sites could be summed to yield large overall differences in binding to multiple sites. This model is consistent with reports that homeodomain protein targets contain multiple individual binding site sequences distributed throughout sizable DNA regions. Also consistent is a recent report that sequences carboxy terminal to the Ubx homeodomain can contribute to segmental specificity.

Enhancer-like activity of A1gR1-binding site in alginate gene activation: positional, orientational, and sequence specificity

Significant activation of promoters of alginate genes such as algD or algC occurs in mucoid Pseudomonas aeruginosa during its proliferation in the lungs of cystic fibrosis patients. These promoters have been shown to be responsive to environmental signals such as high osmolarity. The signaling is mediated by a so-called two-component signal transduction system, in which a soluble protein, AlgR2, undergoes autophosphorylation and transfers the phosphate to a DNA-binding response regulator protein, AlgR1. The phosphorylated form of AlgR1 has a high affinity for binding at upstream sequences of both the algC and algD promoters. Two AlgR1-binding sites (ABS) have been reported upstream of the algC gene. One of the two ABSs (algC-ABS1, located at -94 to -81) is critical for the algC activation process, while the second ABS (algC-ABS2, located at +161 to +174) is only weakly active. We now report the presence of a third ABS within the structural gene of algC, and this ABS (algC-ABS3) is also important for algC promoter activation. algC-ABS1 can be replaced functionally by algC-ABS2, algD-ABS1, or algD-ABS2 and somewhat weakly by algD-ABS3. Introduction of a half-integral turn in the DNA helix between the algC site of transcription initiation and algC-ABS1 allowed only slight reduction of promoter activity, suggesting that the binding site could be appreciably functional even when present in the opposite face of the helix. Activation of the algC promoter is independent of the relative location (upstream or downstream of the mRNA start site), the number of copies, or the orientation of algC-ABS1, suggesting that it behaves like a eukaryotic enhancer element in promoting transcription from the algC promoter.

Identification of EBNA1 amino acid sequences required for the interaction of the functional elements of the Epstein-Barr virus latent origin of DNA replication

Epstein-Barr nuclear antigen 1 (EBNA1) activates DNA replication from the Epstein-Barr virus latent origin, oriP. This activation involves the direct interaction of EBNA1 dimers with multiple sites within the two noncontiguous functional elements of the origin, the family of repeats (FR) element and the dyad symmetry (DS) element. The efficient interaction of EBNA1 dimers bound to these two elements in oriP results in the formation of DNA loops in which the FR and DS elements are bound together through EBNA1. In order to elucidate the mechanism by which EBNA1 induces oriP DNA looping, we have investigated the DNA sequences and EBNA1 amino acids required for EBNA1-mediated DNA looping. Using a series of truncation mutants of EBNA1 produced in baculovirus and purified to apparent homogeneity, we have demonstrated that the EBNA1 DNA binding and dimerization domain is not sufficient to mediate oriP DNA looping and that an additional region(s) located between amino acids 346 and 450 is required. Single EBNA1-binding sites, separated by 930 bp of plasmid DNA, were also shown to support EBNA1-mediated looping, indicating that the formation of large EBNA1 complexes, such as those observed on oriP FR and DS elements, is not a requirement for looping.

Protein-protein communication within the transcription apparatus

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Structure, function, and regulation of the kilB locus of promiscuous plasmid RK2

The kil-kor regulon of the self-transmissible, broad-host-range plasmid RK2 is a unique network with eight coregulated operons. Among the genes encoded by the kil-kor regulon are trfA, which encodes the replication initiator, and several kil loci (kilA, kilB, kilC, and kilE), each of which is lethal to the host cell in the absence of appropriate negative regulatory elements encoded by the korA, korB, korC, and korE determinants. We have proposed that the functions of the kil loci are related to RK2 maintenance or host range. Here, we report the nucleotide sequence of a 2.44-kb region that includes the lethal kilB determinant. We identified the first three genes of the kilB operon (designated klbA, klbB, and klbC), and we determined by deletion analysis that the host-lethal phenotype requires klbB. The predicted amino acid sequence of the 34,995-Da klbA product reveals a potential ATP-binding fold. The klbB product is predicted to be a membrane protein with a molecular mass of 15,012 Da with homology to the RK2 KlaC membrane protein encoded by the kilA operon. The amino acid sequence of the 12,085-Da klbC product contains a perfect match to the leucine zipper motif common to eukaryotic regulatory proteins. Primer extension analysis revealed unambiguously that transcription of the kilB operon begins 46 nucleotides upstream of klbA. No transcription was initiated from the sequence previously presumed by other investigators to be the kilB promoter. The abundance of kilB transcripts is reduced in the presence of KorB, consistent with the prediction that KorB acts at the level of transcription. A degenerate KorB-binding site that contains a perfect half-palindrome overlaps the kilB promoter, but this site is insufficient for regulation by KorB. The region containing a KorB-binding site located 183 bp upstream of the transcriptional start is required for regulation by KorB, indicating that KorB acts at a distance to regulate transcription of kilB. Our studies with the mutant plasmid pRP101, a transfer-defective derivative of the RK2-like plasmid RP4, demonstrated that the kilB operon includes the conjugal transfer and surface exclusion genes of the Tra2 region. Nucleotide sequence analysis revealed that the transposon Tn7 insertion in pRP101 is located in the klbC gene, and complementation analysis showed that this mutation has a strong polar effect on the expression of genes for conjugal transfer and surface exclusion located several kilobases downstream. A klbA mutant was constructed and found to be both transfer defective and complementable, thus, demonstrating a requirement was constructed and found to be both transfer defective and complementable, thus demonstrating a requirement for klbA product in plasmid transmissibility. These results have demonstrated a role for the kilB operon in conjugal transfer. The kil-kor regulon of RK2 is the only known example of plasmid-mediated coregulation of replication and transfer.

A sigma 54 promoter and downstream sequence elements ftr2 and ftr3 are required for regulated expression of divergent transcription units flaN and flbG in Caulobacter crescentus

In this study, we investigated the cis-acting sequences required for transcription of the divergent, cell cycle-regulated flaN and flbG operons of Caulobacter crescentus. Previous work showed that transcription of flbG in vivo depends on a sigma 54 promoter and a sequence element called ftr1 that is located about 100 bp upstream from the transcription start site (D. A. Mullin and A. Newton, J. Bacteriol. 171:3218-3227, 1989). We now show that regulation of flaN transcription in vivo depends on a sigma 54 promoter and two ftr elements located downstream of the transcription start site at +86 (ftr2) and +120 (ftr3). Mutations in or between the conserved elements at -24 and -12 in this sigma 54 promoter reduced or abolished flaN transcription, and one mutation that eliminated flaN expression led to an increased level of flbG transcript. Mutations in ftr2 resulted in greatly reduced levels of flaN transcript but had no noticeable effect on flbG transcript levels. All three mutations constructed in ftr3 resulted in elevated flaN and flbG transcript levels. We conclude that ftr2 is required for positive regulation of flaN, whereas ftr3 appears to play a negative regulatory role in flaN and flbG expression. To explain the coordinated positive activation and negative autoregulation of these two transcription units and the effect of mutations on gene expression, we propose a model in which the flaN and flbG promoters interact through alternative DNA looping to form structures that are transcriptionally active or inactive.

Use of gel retardation to analyze protein-nucleic acid interactions

Protein-nucleic acid interactions are crucial in the regulation of many fundamental cellular processes. The nature of these interactions is susceptible to analysis by a variety of methods, but the combination of high analytical power and technical simplicity offered by the gel retardation (band shift) technique has made this perhaps the most widely used such method over the last decade. This procedure is based on the observation that the formation of protein-nucleic complexes generally reduces the electrophoretic mobility of the nucleic acid component in the gel matrix. This review attempts to give a simplified account of the physical basis of the behavior of protein-nucleic acid complexes in gels and an overview of many of the applications in which the technique has proved especially useful. The factors which contribute most to the resolution of the complex from the naked nucleic acid are the gel pore size, the relative mass of protein compared with nucleic acid, and changes in nucleic acid conformation (bending) induced by binding. The consequences of induced bending on the mobility of double-strand DNA fragments are similar to those arising from sequence-directed bends, and the latter can be used to help characterize the angle and direction of protein-induced bends. Whether a complex formed in solution is actually detected as a retarded band on a gel depends not only on resolution but also on complex stability within the gel. This is strongly influenced by the composition and, particularly, the ionic strength of the gel buffer. We discuss the applications of the technique to analyzing complex formation and stability, including characterizing cooperative binding, defining binding sites on nucleic acids, analyzing DNA conformation in complexes, assessing binding to supercoiled DNA, defining protein complexes by using cell extracts, and analyzing biological processes such as transcription and splicing.

Control of gal transcription through DNA looping: inhibition of the initial transcribing complex

Involvement of DNA looping between two spatially separated gal operators, OE and OI, in repression of the gal operon has been demonstrated in vivo. An in vitro transcription assay using a minicircle DNA containing the gal promoter region with lac operators was employed to elucidate the molecular mechanism of repression. Wild-type lac repressors (LacI+ protein molecules), which are capable of associating into a tetramer and forming a DNA loop, repressed transcription from promoter sites P1 and P2, whereas a non-looping lac repressor mutant (LacI(adi)) failed to show normal repression of both of the gal promoters. Thus a DNA loop is also required for repression of transcription in vitro. Repression mediated by DNA looping resulted in the inhibition of the synthesis of complete as well as aborted transcripts, demonstrating that the repressive action was on the formation or activity of the initial transcribing complex. Under similar conditions, the gal repressor (GalR protein) did not repress the gal promoters effectively, apparently because it failed to loop DNA containing gal operators in the purified system. The component(s) or conditions that aid GalR in DNA looping remain to be identified.