Plasmid permutation vectors to monitor DNA bending

The telomere resolvase, TelA, utilizes an underwound pre-cleavage intermediate to promote hairpin telomere formation

The telomere resolvase, TelA, forms the hairpin telomeres of the linear chromosome of Agrobacterium tumefaciens in a process referred to as telomere resolution. Telomere resolution is a unique DNA cleavage and rejoining reaction that resolves replicated telomere junctions into a pair of hairpin telomeres. Telomere resolvases utilize a reaction mechanism with similarities to that of topoisomerase-IB enzymes and tyrosine recombinases. The reaction proceeds without the need for high-energy cofactors due to the use of a covalent, enzyme-cleaved DNA intermediate that stores the bond energy of the cleaved bonds in 3'-phosphotyrosyl linkages. The cleaved DNA strands are then refolded into a hairpin conformation and the 5'-OH ends of the refolded strands attack the 3'-phosphotyrosine linkages in order to rejoin the DNA strands into hairpin telomeres. Because this kind of reaction mechanism is, in principle, reversible it is unclear how TelA controls the direction of the reaction and propels the reaction to completion. We present evidence that TelA forms and/or stabilizes a pre-cleavage intermediate that features breakage of the four central basepairs between the scissile phosphates prior to DNA cleavage to help propel the reaction forwards, thus preventing abortive cleavage and rejoining cycles that regenerate the substrate DNA. We identify eight TelA sidechains, located in the hairpin-binding module and catalytic domains of TelA, implicated in this process. These mutants were deficient for telomere resolution on parental replicated telomere junctions but were rescued by introduction of substrate modifications that mimic unwinding of the DNA between the scissile phosphates.

DNA Sequence Determinants Controlling Affinity, Stability and Shape of DNA Complexes Bound by the Nucleoid Protein Fis

The abundant Fis nucleoid protein selectively binds poorly related DNA sequences with high affinities to regulate diverse DNA reactions. Fis binds DNA primarily through DNA backbone contacts and selects target sites by reading conformational properties of DNA sequences, most prominently intrinsic minor groove widths. High-affinity binding requires Fis-stabilized DNA conformational changes that vary depending on DNA sequence. In order to better understand the molecular basis for high affinity site recognition, we analyzed the effects of DNA sequence within and flanking the core Fis binding site on binding affinity and DNA structure. X-ray crystal structures of Fis-DNA complexes containing variable sequences in the noncontacted center of the binding site or variations within the major groove interfaces show that the DNA can adapt to the Fis dimer surface asymmetrically. We show that the presence and position of pyrimidine-purine base steps within the major groove interfaces affect both local DNA bending and minor groove compression to modulate affinities and lifetimes of Fis-DNA complexes. Sequences flanking the core binding site also modulate complex affinities, lifetimes, and the degree of local and global Fis-induced DNA bending. In particular, a G immediately upstream of the 15 bp core sequence inhibits binding and bending, and A-tracts within the flanking base pairs increase both complex lifetimes and global DNA curvatures. Taken together, our observations support a revised DNA motif specifying high-affinity Fis binding and highlight the range of conformations that Fis-bound DNA can adopt. The affinities and DNA conformations of individual Fis-DNA complexes are likely to be tailored to their context-specific biological functions.

Interaction of Escherichia coli RNA polymerase with artificial promoters, containing nonnucleotide spacers

To study the functional role of the spacer region between two consensus -10 and -35 elements of promoters, recognized by E. coli RNA polymerase, the model promoter-like DNA duplexes containing nonnucleotide inserts (mimicking 17-mer spacer) either in one or both strands, were constructed. The modified duplexes can form the heparin-resistant binary complexes with RNA polymerase. The DNA duplex with nonnucleotide insert in the template strand can specifically direct the synthesis of mRNA in the in vitro run-off transcription assays.

Coordinated regulation by AgrA, SarA, and SarR to control agr expression in Staphylococcus aureus

The agr locus of Staphylococcus aureus is composed of two divergent transcripts (RNAII and RNAIII) driven by the P2 and P3 promoters. The P2-P3 intergenic region comprises the SarA/SarR binding sites and the four AgrA boxes to which AgrA binds. We reported here the role of AgrA, SarA, and SarR on agr P2 and P3 transcription. Using real-time reverse transcription (RT)-PCR and promoter fusion studies with selected single, double, triple, and complemented mutants, we showed that AgrA is indispensable to agr P2 and P3 transcription, whereas SarA activates and SarR represses P2 transcription. In vitro runoff transcription assays revealed that AgrA alone promoted transcription from the agr P2 promoter, with SarA enhancing it and SarR inhibiting agr P2 transcription in the presence of AgrA or with SarA and AgrA. Electrophoretic mobility shift assay (EMSA) analysis disclosed that SarR binds more avidly to the agr promoter than SarA and displaces SarA from the agr promoter. Additionally, SarA and AgrA bend the agr P2 promoter, whereas SarR does not. Collectively, these data indicated that AgrA activates agr P2 and P3 promoters while SarA activates the P2 promoter, presumably via bending of promoter DNA to bring together AgrA dimers to facilitate engagement of RNA polymerase (RNAP) to initiate transcription.

Functional characterization of the Escherichia coli Fis-DNA binding sequence

The Escherichia coli protein Fis is remarkable for its ability to interact specifically with DNA sites of highly variable sequences. The mechanism of this sequence-flexible DNA recognition is not well understood. In a previous study, we examined the contributions of Fis residues to high-affinity binding at different DNA sequences using alanine-scanning mutagenesis and identified several key residues for Fis-DNA recognition. In this work, we investigated the contributions of the 15-bp core Fis binding sequence and its flanking regions to Fis-DNA interactions. Systematic base-pair replacements made in both half sites of a palindromic Fis binding sequence were examined for their effects on the relative Fis binding affinity. Missing contact assays were also used to examine the effects of base removal within the core binding site and its flanking regions on the Fis-DNA binding affinity. The results revealed that: (1) the -7G and +3Y bases in both DNA strands (relative to the central position of the core binding site) are major determinants for high-affinity binding; (2) the C(5) methyl group of thymine, when present at the +4 position, strongly hinders Fis binding; and (3) AT-rich sequences in the central and flanking DNA regions facilitate Fis-DNA interactions by altering the DNA structure and by increasing the local DNA flexibility. We infer that the degeneracy of specific Fis binding sites results from the numerous base-pair combinations that are possible at noncritical DNA positions (from -6 to -4, from -2 to +2, and from +4 to +6), with only moderate penalties on the binding affinity, the roughly similar contributions of -3A or G and +3T or C to the binding affinity, and the minimal requirement of three of the four critical base pairs to achieve considerably high binding affinities.

The promoter and transcribed regions of the Leishmania tarentolae spliced leader RNA gene array are devoid of nucleosomes

BACKGROUND

The spliced leader (SL) RNA provides the 5' m7G cap and first 39 nt for all nuclear mRNAs in kinetoplastids. This small nuclear RNA is transcribed by RNA polymerase II from individual promoters. In Leishmania tarentolae the SL RNA genes reside in two multi-copy tandem arrays designated MINA and MINB. The transcript accumulation from the SL promoter on the drug-selected, episomal SL RNA gene cassette pX-tSL is ~10% that of the genomic array in uncloned L. tarentolae transfectants. This disparity is neither sequence- nor copy-number related, and thus may be due to interference of SL promoter function by epigenetic factors. To explore these possibilities we examined the nucleoplasmic localization of the SL RNA genes as well as their nucleosomal architecture.

RESULTS

The genomic SL RNA genes and the episome did not co-localize within the nucleus. Each genomic repeat contains one nucleosome regularly positioned within the non-transcribed intergenic region. The 363-bp MINA array was resistant to micrococcal nuclease digestion between the -258 and -72 positions relative to the transcription start point due to nucleosome association, leaving the promoter elements and the entire transcribed region exposed for protein interactions. A pattern of ~164-bp protected segments was observed, corresponding to the amount of DNA typically bound by a nucleosome. By contrast, nucleosomes on the pX-tSL episome were randomly distributed over the episomal SL cassette, reducing transcription factor access to the episomal promoter by approximately 74%. Cloning of the episome transfectants revealed a range of transcriptional activities, implicating a mechanism of epigenetic heredity.

CONCLUSION

The disorganized nucleosomes on the pX episome are in a permissive conformation for transcription of the SL RNA cassette approximately 25% of the time within a given parasite. Nucleosome interference is likely the major factor in the apparent transcriptional repression of the SL RNA gene cassette. Coupled with the requirement for run-around transcription that drives expression of the selectable drug marker, transcription of the episomal SL may be reduced even further due to sub-optimal nucleoplasmic localization and initiation complex disruption.

Common and variable contributions of Fis residues to high-affinity binding at different DNA sequences

Fis is a nucleoid-associated protein that interacts with poorly related DNA sequences with a high degree of specificity. A difference of more than 3 orders of magnitude in apparent Kd values was observed between specific (Kd, approximately 1 to 4 nM) and nonspecific (Kd, approximately 4 microM) DNA binding. To examine the contributions of Fis residues to the high-affinity binding at different DNA sequences, 13 alanine substitutions were generated in or near the Fis helix-turn-helix DNA binding motif, and the resulting proteins were purified. In vitro binding assays at three different Fis sites (fis P II, hin distal, and lambda attR) revealed that R85, T87, R89, K90, and K91 played major roles in high-affinity DNA binding and that R85, T87, and K90 were consistently vital for binding to all three sites. Other residues made variable contributions to binding, depending on the binding site. N84 was required only for binding to the lambda attR Fis site, and the role of R89 was dramatically altered by the lambda attR DNA flanking sequence. The effects of Fis mutations on fis P II or hin distal site binding in vitro generally correlated with their abilities to mediate fis P repression or DNA inversion in vivo, demonstrating that the in vitro DNA-binding effects are relevant in vivo. The results suggest that while Fis is able to recognize a minimal common set of DNA sequence determinants at different binding sites, it is also equipped with a number of residues that contribute to the binding strength, some of which play variable roles.

Analysis of chromosomal insertion sites for Bacteroides Tn4555 and the role of TnpA

Tn4555, a mobilizable transposon carrying cefoxitin resistance, is directed to a preferred target site in the Bacteroides fragilis chromosome by a transposon-encoded targeting protein TnpA. In an effort to characterize target site selection for Tn4555, the existence of preferred target sites in other species of Bacteroides and in Escherichia coli was examined. For these analyses a Tn4555 mini element, pFD660, was transferred from E. coli donors to Bacteroides thetaiotaomicron or Bacteroides ovatus recipients and the resulting sites of insertion analyzed. A similar construct, pFD794 was used to determine insertion sites in E. coli, and preferred sites were found in all bacteria tested. Also the ability of TnpA to bind to various targets was examined in mobility shift assays. Although TnpA bound to all tested sequences, it displayed higher affinity for the target sites. The binding characteristics of TnpA and the lack of significant base sequence homology between targets suggested that secondary structure of the sites was important for TnpA binding. Circular permutation tests supported the idea that TnpA targets bent DNA.

Effects of sequence and structure in the separation of nucleic acids using ion pair reverse phase liquid chromatography

Ion pair reverse phase high performance liquid chromatography on non-porous alkylated poly(styrene-divinylbenzene) particles enables the high resolution separation of double stranded DNA fragments. To further understand the separation mechanisms involved in ion pair reverse phase liquid chromatography we have analysed the effects of curved or "bent" DNA fragments with respect to their separation using both gel electrophoresis and ion pair reverse phase liquid chromatography. Size dependent separations of curved DNA fragments that migrate anomalously during gel electrophoresis were observed using ion pair reverse phase liquid chromatography. To further study the sequence effect and resulting changes in hydrophobicity of the duplex DNA, PCR fragments were generated that contain uracil in place of thymine. The resulting fragments were shown to elute with shorter retention times, demonstrating that sequence-specific effects can alter the retention of duplex DNA. The study was extended to the investigation of non-canonical B-DNA structures (Holliday junctions) under various chromatographic conditions, demonstrating that the coaxial stacking of the helices in such structures, in the presence of magnesium causes a change in retention.

Two distinct curved DNAs upstream of the light-responsive psbA gene in a cyanobacterium

A functional intrinsic DNA curvature, CIT, and potential DNA-binding factors for the basal transcription of psbA2 have been reported in a cyanobacterium, Microcystis aeruginosa K-81 (Asayama et al., Nucleic Acids Res., 30, 4658-4666 (2002)). In this article, we found another novel curved DNA, which was induced by RNA polymerases binding to the promoter region. Circular permutation analyses showed that the curved center of RNA polymerase-induced DNA bending (RIB) lies at approximately the +10 site, referring to the transcription start point as +1, in the RNA polymerase-DNA complex. Regions containing the curved center of RIB and CIT contributed to the basal transcription in vivo and in vitro. These results indicate that the region upstream of K-81 psbA2 has two distinct curved DNAs, CIT (sequence-directed type) and RIB (protein-induced type).

Target DNA bending is an important specificity determinant in target site selection in Tn10 transposition

The bacterial transposon Tn10 inserts preferentially into specific DNA sequences. DNA footprinting and interference studies have revealed that the Tn10-encoded transposase protein contacts a large stretch of target DNA ( approximately 24 bp) and that the target DNA structure is deformed upon incorporation into the transpososome. Target DNA deformation might contribute significantly to target site selection and thus it is of interest to further define the nature of this deformation. Circular permutation analysis was used to demonstrate that the target DNA is bent upon its incorporation into the transpososome. Two lines of evidence are presented that target DNA bending is an important event in target site selection. First, we demonstrate a correlation between increased target site usage and an increased level of target DNA bending. Second, transposase mutants with relaxed target specificity are shown to cause increased target DNA bending relative to wild-type transposase. This latter observation provides new insight into how relaxed specificity may be achieved. We also show that Ca(2+) facilitates target capture by stabilizing transposase interactions with sequences immediately flanking the insertion site. Ca(2+) could, in theory, exert this effect by stabilizing bends in the target DNA.

The DNA architectural protein HMGB1 displays two distinct modes of action that promote enhanceosome assembly

HMGB1 (also called HMG-1) is a DNA-bending protein that augments the affinity of diverse regulatory proteins for their DNA sites. Previous studies have argued for a specific interaction between HMGB1 and target proteins, which leads to cooperative binding of the complex to DNA. Here we propose a different model that emerged from studying how HMGB1 stimulates enhanceosome formation by the Epstein-Barr viral activator Rta on a target gene, BHLF-1. HMGB1 stimulates binding of individual Rta dimers to multiple sites in the enhancer. DNase I and hydroxyl radical footprinting, electrophoretic mobility shift assays, and immobilized template assays failed to reveal stable binding of HMGB1 within the complex. Furthermore, mutational analysis failed to identify a specific HMGB1 target sequence. The effect of HMGB1 on Rta could be reproduced by individual HMG domains, yeast HMO1, or bacterial HU. These results, combined with the effects of single-amino-acid substitutions within the DNA-binding surface of HMGB1 domain A, argue for a mechanism whereby DNA-binding and bending by HMGB1 stimulate Rta-DNA complex formation in the absence of direct interaction with Rta or a specific HMGB1 target sequence. The data contrast with our analysis of HMGB1 action on another BHLF-1 regulatory protein called ZEBRA. We discuss the two distinct modes of HMGB1 action on a single regulatory region and propose how HMGB1 can function in diverse contexts.

Subunit exchange and the role of dimer flexibility in DNA binding by the Fis protein

Fis is an abundant bacterial DNA binding protein that functions in many different reactions. We show here that Fis subunits rapidly exchange between dimers in solution by disulfide cross-linking mixtures of Fis mutants with different electrophoretic mobilities and by monitoring energy transfer between fluorescently labeled Fis subunits upon heterodimer formation. The effects of detergents and salt concentrations on subunit exchange imply that the dimer is predominantly stabilized by hydrophobic forces, consistent with the X-ray crystal structures. Specific and nonspecific DNA strongly inhibit Fis subunit exchange. In all crystal forms of Fis, the separation between the DNA recognition helices within the Fis dimer is too short to insert into adjacent major grooves on canonical B-DNA, implying that conformational changes within the Fis dimer and/or the DNA must occur upon binding. We therefore investigated the functional importance of dimer interface flexibility for Fis-DNA binding by studying the DNA binding properties of Fis mutants that were cross-linked at different positions in the dimer. Flexibility within the core dimer interface does not appear to be required for efficient DNA binding, Fis-DNA complex dissociation, or Fis-induced DNA bending. Moreover, FRET-based experiments provided no evidence for a change in the spatial relationship between the two helix-turn-helix motifs in the Fis dimer upon DNA binding. These results support a model in which the unusually short distance between DNA recognition helices on Fis is accommodated primarily through bending of the DNA.

Rice TATA binding protein interacts functionally with transcription factor IIB and the RF2a bZIP transcriptional activator in an enhanced plant in vitro transcription system

TATA binding protein (TBP) and transcription factor IIB (TFIIB) are key factors for the assembly of eukaryotic transcription initiation complexes. We used a rice whole-cell extract in vitro transcription system to characterize the functional interactions of recombinant plant TBP and TFIIB. Bacterially expressed rice TBP (OsTBP2) bound to the TATA box of the rice pal gene encoding phenylalanine ammonia-lyase, caused DNA bending, and enhanced basal transcription from the pal promoter in a TATA box-dependent manner. Recombinant rice TFIIB (OsTFIIB) stimulated the DNA binding and bending activities of OsTBP2 and synergistically enhanced OsTBP2-mediated transcription from the pal promoter and the promoter of Rice tungro bacilliform virus but not from the barley pr1 promoter. We also demonstrate a physical interaction between OsTBP2 and RF2a, a rice bZIP transcription factor that bound to the box II cis element of the promoter of Rice tungro bacilliform virus, resulting in enhanced transcription from the viral promoter. Enhancement of rice whole-cell extracts with recombinant transcription factors thus provides a powerful tool for the in vitro determination of plant gene regulation mechanisms. We conclude that OsTBP2 undergoes promoter-specific functional interactions with both the basal transcription factor OsTFIIB and the accessory transcription factor RF2a.

Transcriptional activation by LR1 at the Emu enhancer and switch region sites

LR1 is a B cell-specific, sequence-specific duplex DNA binding activity which is induced in B cells carrying out class switch recombination. Here we identify several properties of LR1 which enable it to function in transcriptional regulation. We show that LR1 contributes to transcriptional activation by the Emu immunoglobulin heavy chain intron enhancer by binding to a site within the enhancer core. We further show that LR1 bends DNA upon binding. In addition, we show that LR1 is itself a bona fide transcriptional activator, as multimerized LR1 sites produce an element which can enhance transcription from a minimal promoter. In order for class switch recombination to occur, an activating signal must be transmitted via the Emu core, and both S regions targeted for recombination must be actively transcribed. The properties of LR1 that we have identified suggest distinct potential functions of LR1 duplex DNA binding activity in class switch recombination. First, LR1 may contribute to recombinational activation by the Emu core. Second, there are multiple potential LR1 duplex binding sites in each of the G-rich switch regions, and LR1 bound at contiguous sites may enhance recombination by stimulating transcription of the S regions.

Site-specific DNA binding and bending by the Borrelia burgdorferi Hbb protein

The Borrelia burgdorferi Hbb protein shows sequence similarity to members of the Escherichia coli HU/integration host factor (IHF) family of DNA accessory factors. We have overexpressed the hbb gene product in E. coli and purified the protein to near homogeneity. Biochemical analyses have revealed that Hbb has unique properties and is neither a strict HU nor IHF analogue. Hbb was found to bind specifically to a site in the putative origin of DNA replication between dnaA and dnaN. DNA footprinting studies have shown that this site is unrelated to the consensus sequence recognized by IHF proteins. Hbb induces a dramatic bend (> 126 degrees ) at this site and was also shown to restrain negative supercoils efficiently upon DNA binding. These features of the protein suggest that Hbb may act as a DNA accessory factor that facilitates the assembly of higher order protein-DNA complexes, such as those involved in DNA replication, transcription, recombination, packaging and perhaps other DNA metabolic processes unique to Borrelia.

Localization of amino acids required for Fis to function as a class II transcriptional activator at the RpoS-dependent proP P2 promoter

ProP is an integral membrane transporter of proline, glycine betaine, and several other osmoprotecting compounds. Fis plus RpoS collaborate to promote a burst of proP transcription in late exponential growth phase. This brief period of ProP synthesis enables stationary phase cells to cope with a potential hyperosmotic shock. Fis activates the RpoS (sigma(38))-dependent proP P2 promoter by binding to a site within the promoter region centered at -41 and thus functions as a class II activator. We show here that activation by Fis at this promoter is completely dependent upon the alpha-CTD of RNA polymerase and that the activation domain on Fis is localized to a four amino acid ridge on the surface of Fis adjacent to the helix-turn-helix DNA binding domain in only one subunit of the homodimer. Fis mutants containing amino acid substitutions within this region are defective in cooperative binding interactions with the sigma(38)-form of RNA polymerase. Some of these substitutions also alter interactions with DNA sequences flanking the core binding site, but we show that changes in Fis-mediated curvature do not affect promoter activity. We conclude that the same amino acids are used by Fis to activate transcription from a class I (-71, rrnB P1) and class II (-41, proP P2) location, but this region is distinct from that required to regulate the Hin site-specific DNA inversion reaction.

Molecular characterization of the gene encoding the DNA gyrase A subunit of Streptococcus pneumoniae

The gene encoding the DNA gyrase A subunit of Streptococcus pneumoniae was cloned and sequenced. The gyrA gene codes for a protein of 822 amino acids homologous to the gyrase A subunit of eubacteria. Translation of the gene in an Escherichia coli expression system revealed a 92-kDa polypeptide. A sequence-directed DNA curvature was identified in the promoter region of gyrA. The bend center was mapped and located between the -35 and -10 regions of the promoter. Primer extension analysis showed that gyrA transcription initiates 6 bp downstream of an extended -10 promoter. The possible implications of the bent DNA region as a regulatory element in the transcription of gyrA are discussed.

Location, degree, and direction of DNA bending associated with the Hin recombinational enhancer sequence and Fis-enhancer complex

The Fis protein of Escherichia coli and Salmonella typhimurium stimulates several site-specific DNA recombination reactions, as well as transcription of a number of genes. Fis binds to a 15-bp core recognition sequence and induces DNA bending. Mutations in Fis which alter its ability to bend DNA have been shown to reduce the stimulatory activity of Fis in both site-specific recombination and transcription systems. To examine the role of DNA bending in the activity of the Fis-recombinational enhancer complex in Hin-mediated site-specific DNA inversion, we have determined the locations, degrees, and directions of DNA bends associated with the recombinational enhancer and the Fis-enhancer complex. Circular-permutation assays demonstrated that a sequence-directed DNA bend is associated with the Fis binding sites in the proximal and distal domains of the recombinational enhancer. Binding of Fis to its core recognition sequence significantly increases the degree of DNA bending associated with the proximal and distal domains. The degree of DNA bending induced by Fis binding depended on the DNA sequences flanking the core Fis binding site, with angles ranging from 42 to 69 degrees. Phasing analyses indicate that both the sequence-directed and the Fis-induced DNA bends associated with the proximal and distal domains face the minor groove of the DNA helix at the center of the Fis binding site. The positions and directions of DNA bends associated with the Fis-recombinational complex support a direct role for Fis-induced DNA bending in assembly of the active invertasome.

DNA binding and DNA bending by the MelR transcription activator protein from Escherichia coli

The Escherichia coli melR gene encodes MelR protein which is a member of the AraC/XylS family of bacterial transcription activators. The function of MelR was investigated by making a targeted deletion in the melR gene of the Escherichia coli chromosome. MelR is a transcription activator essential for melibiose- dependent expression of the melAB operon which is needed for bacterial growth with melibiose as a carbon source. To investigate the interactions of MelR at the melAB promoter, both full length MelR and a shortened derivative, MelR173, containing the C-terminal DNA-binding domain, were purified as fusions to glutathione- S -transferase. Circular permutation studies show that both full-length MelR and MelR173 induce an apparent bend upon binding to target sites at the melAB promoter. Bound full-length MelR, but not MelR173, can oligomerise to form larger complexes that are likely to be involved in transcription activation.

Yeast HMG proteins NHP6A/B potentiate promoter-specific transcriptional activation in vivo and assembly of preinitiation complexes in vitro

Nonhistone proteins 6A and 6B (NHP6A/B) are nonsequence-specific DNA-binding proteins from Saccharomyces cerevisiae that are related structurally and functionally to the mammalian high mobility group proteins 1 and 2. These DNA architectural proteins distort DNA structure severely and have been shown to promote assembly of specialized recombination complexes. Here we show that the yeast NHP6A/B proteins are required for the induction of a subset of genes transcribed by RNA polymerase II (pol II). Activation of the CUP1, CYC1, GAL1, and DDR2 genes was decreased or abolished completely in the delta nhp6A/B strain. No significant change in basal expression was observed for any of the 10 genes examined. Analysis of chimeric gene constructs localized the regions dependent on NHP6A/B to be primarily at the core promoters, although the GAL1 UAS also requires NHP6A/B for activity. In vitro, NHP6A stimulated transcription by pol II at the GAL1 promoter three- to fivefold above the level of activation by GAL4-VP16 alone. Gel mobility shift assays showed that NHP6A promotes the formation of a complex with TBP and TFIIA at the TATA box that has enhanced affinity for TFIIB.

Identification of new Fis binding sites by DNA scission with Fis-1,10-phenanthroline-copper(I) chimeras

The chimeric nuclease Fis-OP has been used to identify novel Fis binding sites. Tethering the chemical nuclease OP-Cu+ to position 73 of the protein with a newly developed longer acetyl-beta-alanylamino spacer has facilitated the localization of two high-affinity Fis binding sequences in a 3 kb pUC19 plasmid. The shorter acetamido linker has allowed the chimeric nuclease to locate two strong Fis binding sites in the 50 kb phage lambda genome. All four sites reside in biologically interesting loci and have been confirmed by gel-retardation and DNase I footprint analyses. A newly discovered site resides in the lac operon of Escherichia coli. The binding of Fis to this site may antagonize repression by the LacI repressor. These studies demonstrate the feasibility of applying chimeric chemical nucleases to the task of identifying functional protein binding sites of biological interest within genomes without any assumption about their sequence preference.

DNA-binding properties of the yeast transcriptional activator, Gcr1p

In Saccharomyces cerevisiae the GCRI gene product is required for high-level expression of genes encoding glycolytic enzymes. In this communication, we extend our analysis of the DNA binding properties of Gcr1p. The DNA-binding domain of Gcr1p binds DNA with high affinity. The apparent dissociation constant of the Gcr1p DNA-binding domain for one of its specific binding sites (TTTCAGCTTCCTCTAT) is 2.9 x 10(-10) M. However, competition experiments showed that Gcr1p binds this site in vitro with a low degree of specificity. We measured a 33-fold difference between the ability of specific competitor and DNA of random sequence to inhibit the formation of nucleoprotein complexes between Gcr1p and a radiolabeled DNA probe containing its binding site. DNA band-shift experiments, utilizing probes of constant length in which the positions of Gcr1p-binding sites are varied relative to the ends, indicated that Gcr1p-DNA nucleoprotein complexes contain bent DNA. The implications of these findings in terms of the combinatorial interactions that occur at the upstream activating sequence elements of genes encoding glycolytic enzymes are discussed.

A DNA-bending protein interacts with an essential upstream regulatory element of the human embryonic beta-like globin gene

The mammalian beta-like globin gene family has served as an important model system for analysis of tissue- and developmental state-specific gene regulation. Although the activities of a number of regulatory proteins have been implicated in the erythroid cell-specific transcription of globin genes, the mechanisms that restrict their expression to discrete stages of development are less well understood. We have previously identified a novel regulatory element (PRE II) upstream from the human embryonic beta-like globin gene (epsilon) that synergizes with other sequences to confer tissue- and stage-specific expression on a minimal epsilon-globin gene promoter in cultured embryonic erythroid cells. Binding of an erythroid nuclear protein (PRE II-binding factor [PRE-IIBF]) to the PRE II control element is required for promoter activation. Here we report on some of the biochemical properties of PREIIBF, including the characterization of its specificity and affinity for DNA. The embryonic and adult forms of PREIIBF recognize their cognate sequences with identical specificities, supporting our earlier conclusion that they are very similar proteins. PREIIBF binds DNA as a single polypeptide with an Mr of approximately 80,000 to 85,000 and introduces a bend into the target DNA molecule. These results suggest a mechanism by which PREIIBF may contribute to the regulation of the embryonic beta-like globin gene within the context of a complex locus.

Mutational analysis of Rox1, a DNA-bending repressor of hypoxic genes in Saccharomyces cerevisiae

Rox1 is a repressor of the hypoxic genes of Saccharomyces cerevisiae. It binds to a specific hypoxic consensus sequence in the upstream region of these genes and represses transcription in conjunction with the general repression complex Tup1-Ssn6. In this study, we demonstrated that the first 100 amino acids comprising the HMG domain of Rox1 were responsible for DNA binding and that when bound, Rox1 bent DNA at an angle of 90 degrees. A mutational analysis resulted in the isolation of seven missense mutations, all located within the HMG domain, that caused loss of DNA binding. The effect of these mutations on the structure of Rox1 was evaluated on the basis of the homology between Rox1 and the human male sex-determining protein SRY, for which a structural model is available. The failure to isolate missense mutations in the carboxy-terminal three-quarters of the protein prompted a deletion analysis of this region. The results suggested that this region was responsible for the repression function of Rox1 and that the repression information was redundant. This hypothesis was confirmed by using a set of fusions between sequences encoding the GAL4 DNA-binding domain and portions of ROX1. Those fusions containing either the entire carboxy-terminal region or either half of it were capable of repression. Repression by selected fusions was demonstrated to be dependent on Ssn6.

Activation of the HIV-1 enhancer by the LEF-1 HMG protein on nucleosome-assembled DNA in vitro

Lymphoid enhancer-binding factor 1 (LEF-1) is a regulatory high mobility group (HMG) protein that activates the T cell receptor alpha (TCR alpha) enhancer in a context-restricted manner in T cells. In this paper we demonstrate that the distal region of the human immunodeficiency virus-1 (HIV-1) enhancer, which contains DNA-binding sites for LEF-1 and Ets-1, also provides a functional context for activation by LEF-1. First, we show that mutations in the LEF-1-binding site inhibit the activity of multimerized copies of the HIV-1 enhancer in Jurkat T cells, and that LEF-1/GAL4 can activate a GAL4-substituted HIV-1 enhancer 80- to 100-fold in vivo. Second, recombinant LEF-1 is shown to activate HIV-1 transcription on chromatin-assembled DNA in vitro. By using a nucleosome-assembly system derived from Drosophila embryos, we find that the packaging of DNA into chromatin in vitro strongly represses HIV-1 transcription and that repression can be counteracted efficiently by preincubation of the DNA with LEF-1 (or LEF-1 and Ets-1) supplemented with fractions containing the promoter-binding protein, Sp1. Addition of TFE-3, which binds to an E-box motif upstream of the LEF-1 and Ets-1 sites, further augments transcription in this system. Individually or collectively, none of the three enhancer-binding proteins (LEF-1, Ets-1, and TFE-3) could activate transcription in the absence of Sp1. A truncation mutant of LEF-1 (HMG-88), which contains the HMG box but lacks the trans-activation domain, did not activate transcription from nucleosomal DNA, indicating that bending of DNA by the HMG domain is not sufficient to activate transcription in vitro. We conclude that transcription activation by LEF-1 in vitro is a chromatin-dependent process that requires a functional trans-activation domain in addition to the HMG domain.

Tn916 target DNA sequences bind the C-terminal domain of integrase protein with different affinities that correlate with transposon insertion frequency

The conjugative transposon Tn916 inserts with widely different frequencies into a variety of target sites with related nucleotide sequences. The binding of chimeric proteins, consisting of maltose-binding protein fused to Tn916 integrase, to three different target sequences for Tn916 was examined by DNase I protection experiments. The C-terminal DNA binding domain of the Tn916 integrase protein was shown to protect approximately 40 bp, spanning target sites in the orfA and cat genes of the plasmid pIP501 and in the cylA gene of the plasmid pAD1. Competition binding assays showed that the affinities of the three target sites for Tn916 integrase varied over a greater than 3- but less than 10-fold range and that the cat target site bound integrase at a lower affinity than did the other two target sites. A PCR-based assay for transposition in Escherichia coli was developed to assess the frequency with which a defective minitransposon inserted into each target site. In these experiments, integrase provided in trans from a plasmid was the sole transposon-encoded protein present. This assay detected transposition into the orfA and cylA target sites but not into the cat target site. Therefore, the frequency of transposon insertion into a particular target site correlated with the affinity of the target for the integrase protein. Sequences within the target fragments similar to known Tn916 insertion sites were not protected by integrase protein. Analysis ot he electrophoretic behavior of circularly permuted sets of DNA fragments showed that all three target sites contained structural features consistent with the presence of a static bend, suggesting that these structural features in addition to the primary nucleotide sequence are necessary for integrase binding and, thus, target site activity.

Intrinsically bent DNA in a eukaryotic transcription factor recognition sequence potentiates transcription activation

Many eukaryotic transcription factors induce DNA bending on binding to their recognition sequences. DNA bending could play a structural role by altering contacts between the protein and DNA. Alternatively, DNA bending could play a more direct role in transcription activation. To distinguish between these possibilities, we inserted two to eight copies of the intrinsic bending sequence, AAAAAACGTG, into a minimal promoter containing only a TATA box. The intrinsic DNA bending sequence was a potent activator of transcription in both in vivo transfection experiments and in a cell-free transcription system. A protein binds to the intrinsic bending sequence with high specificity in gel mobility shift assays and was required for its transcription in cell-free extracts. The intercalator, distamycin, which eliminates the ability of the sequence to bend, specifically reduced its transcription by about 60%. Mutations in the sequence which abolished DNA bending reduced transcription by approximately 70% in vivo. Competition gel mobility shift assays showed that the transcription factor bound equally well to mutants in which DNA bending was abolished and to the intrinsic bending sequence. These data indicate that DNA bending can play a direct role in the activation of eukaryotic transcription.

RAP1 stimulates single- to double-strand association of yeast telomeric DNA: implications for telomere-telomere interactions

Repressor Activator Protein 1 (RAP1) of Saccharomyces cerevisiae is an abundant nuclear protein implicated in telomere length maintenance, transactivation, and in the establishment of silent chromatin domains. The RAP1 binding site 5' of the yeast HIS4 gene is also a region of hyperrecombination in meiosis. We report here that as RAP1 binds its recognition consensus, it appears to untwist double-stranded DNA, which we detect as the introduction of a negative supercoil in circularization assays. Coincident with the RAP1-dependent untwisting, we observe stimulation of the association of a single-stranded yeast telomeric sequence with its homologous double-stranded sequence in a supercoiled plasmid. This unusual distortion of the DNA double helix by RAP1 may contribute to the RAP1-dependent enhancement of recombination rates and promote non-duplex strand interactions at telomeres.

Localization of the intrinsically bent DNA region upstream of the E.coli rrnB P1 promoter

DNA sequences upstream of the rrnB P1 core promoter (-10, -35 region) increase transcription more than 300-fold in vivo and in vitro. This stimulation results from a cis-acting DNA sequence, the UP element, which interacts directly with the alpha subunit of RNA polymerase, increasing transcription about 30-fold, and from a positively acting transcription factor, FIS, which increases expression another 10-fold. A DNA region exhibiting a high degree of intrinsic curvature has been observed upstream of the rrnB P1 core promoter and has thus been often cited as an example of the effect of bending on transcription. However, the precise position of the curvature has not been determined. We address here whether this bend is in fact related to activation of rRNA transcription. Electrophoretic analyses were used to localize the major bend in the rrnB P1 upstream region to position approximately -100 with respect to the transcription initiation site. Since most of the effect of upstream sequences on transcription results from DNA between the -35 hexamer and position -88, i.e. downstream of the bend center, these studies indicate that the curvature leading to the unusual electrophoretic behavior of the upstream region does not play a major role in activation of rRNA transcription. Minor deviations from normal electrophoretic behavior were associated with the region just upstream of the -35 hexamer and could conceivably influence interactions between the UP element and the alpha subunit of RNA polymerase.

Stoichiometry of binding of CysB to the cysJIH, cysK, and cysP promoter regions of Salmonella typhimurium

CysB is a member of the LysR family of transcriptional activators and regulates genes of the cysteine regulon in Salmonella typhimurium and Escherichia coli. CysB binds to specific sites just upstream of the -35 regions of the cysJIH, cysK, and cysP promoters, where, in the presence of N-acetyl-L-serine, it stimulates transcription initiation. The cysK and cysP promoters contain additional binding sites, and we have proposed that CysB bends these promoters by binding to adjacent sites. N-Acetyl-L-serine is thought to decrease the magnitude of such bending. Since stoichiometric data bearing on this model have been lacking, we analyzed complexes in gel mobility shift experiments with 35S-labeled CysB and 32P-labeled promoter fragments. CysB was found to bind as a tetramer, and N-acetyl-L-serine increased the electrophoretic mobilities of one-protein complexes of the multibinding site cysK and cysP promoters without changing their stoichiometry, indicating that a single CysB tetramer can bend these promoters and that N-acetyl-L-serine diminishes such bending. Bend angles for both promoters were calculated to be 100 and 50 degrees in the absence and presence of N-acetyl-L-serine. N-Acetyl-L-serine affected neither the stoichiometry nor the electrophoretic mobility of cysJIH promoter complexes, which are not known to contain bent DNA. DNA bending may be a mechanism for sequestering CysB at certain promoter sites by increasing their affinity for this protein in the absence of N-acetyl-L-serine.

The bovine papillomavirus type 1 genome contains multiple loci of static DNA bending, but bends are absent from the functional origin of replication

Twenty-four overlapping restriction fragments spanning the entire bovine papillomavirus type 1 (BPV-1) genome were analyzed by electrophoresis to determine the extent of static DNA bending in the BPV-1 genome. Thirteen of 24 fragments contained static bends. Based on known locations of previously mapped bend loci and the overlapping pattern of these 13 fragments, we estimate that there are 8-11 distinct static bend loci in the BPV-1 genome. The bend loci were not uniformly distributed on the genome and with one exception, were clustered from nucleotides 5816 to 2621 on the BPV-1 map. This portion of the BPV-1 genome contains most of the transcriptional regulatory sequences as well as the origin of replication. The concordance between the genomic distribution of DNA bends and cis-active elements is consistent with the possibility that bent sequences may contribute to the function of at least some of these elements. However, unlike SV40, there was no static bend at that functional origin of replication for BPV-1. The nearest bends to the origin were approximately 120 bp to the 5' side and 300 bp to the 3' side. As both of these bends were outside of the sequences required for origin function, it is unlikely that static bending plays a critical role in BPV-1 replication.

Structural features of the 5' region of the human erbB-2 gene

The human erbB-2 gene encodes a receptor protein tyrosine kinase which has strong growth-promoting properties. Overexpression of erbB-2 is directly associated with tumor cell growth in vivo and in vitro. To investigate structural features which may contribute to expression, we isolated and sequenced a 3.65-kb 5' promoter fragment of the human erbB-2 gene. This 5' fragment contains an exceptionally high density of four Alu sequences. Other structural features include an A + T-rich region that causes DNA bending, as measured by anomalously slow migration in polyacrylamide gels. These structural features of the 5' region of erbB-2 may contribute to expression of the gene in different growth states.

Possible implications of Sp1-induced bending of DNA on synergistic activation of transcription

We examined DNA bending using an electrophoretic mobility shift assay to determine whether Sp1 induces structural changes in DNA. The results indicated that Sp1 bends DNA upon binding to its recognition sequence. We discuss the possibility that DNA bending is involved in synergistic activation of transcription.

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.

Analysis of DNA curvature using circular permutation of 5' end labelled fragments

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Analysis of promoter-specific repression by triple-helical DNA complexes in a eukaryotic cell-free transcription system

A site-specific triple-helical DNA complex has previously been shown to inhibit DNA binding by eukaryotic transcription factor Sp1. To examine the functional consequences of such inhibition, homopurine target sequences for oligonucleotide-directed triple-helix formation were inserted in various configurations relative to Sp1 transcription activator binding sites, upstream of the TATA element of recombinant eukaryotic promoters. The resulting promoters were tested for activity in the presence or absence of recombinant human Sp1 in a Drosophila in vitro transcription system lacking endogenous Sp1. When triple-helical complexes were assembled on the promoters by incubation with specific oligodeoxyribonucleotides, promoter-specific repression of basal transcription was observed in the absence of Sp1. Transcriptional repression required the preassembly of triple-helical complexes before addition of nuclear extract. The degree of basal repression was a function of the number and proximity of triple-helical complexes relative to the basal promoter complex. Repression did not result from triple-helix-induced template degradation. Addition of recombinant Sp1 did not cause derepression. These results suggest that triple-helical complexes can repress transcription primarily by blocking promoter DNA assembly into initiation complexes rather than by occluding Sp1 binding. One of several plausible mechanisms for triple-helix-induced repression involves changes in DNA flexibility. Evidence in favor of this model is provided by a permutation-dependent gel mobility assay in which formation of site-specific triple-helical complexes is shown to stiffen double-helical DNA.

DNA-bending properties of TF1

Transcription factor 1 (TF1) is the Bacillus subtilis phage SPO1-encoded member of the family of DNA-binding proteins that includes Escherichia coli HU and integration host factor, IHF. A gel electrophoretic retardation method has been used to show that a TF1 dimer binding to one of its preferred sites in (5-hydroxymethyl)uracil (hmUra)-containing DNA sharply bends the latter. In fact, the DNA-bending properties of TF1 and E. coli IHF are indistinguishable. Substitutions at amino acid 61 in the DNA-binding "arm" of TF1 are known to affect DNA-binding affinity and site selectivity. Experiments described here show that these substitutions also affect DNA bending. The selectivity of TF1 binding is very greatly diminished and the affinity is reduced when hmUra is replaced in DNA by thymine (T). An extension of the gel retardation method that permits an analysis of DNA bending by non-specifically bound TF1 is proposed. Under the assumptions of this analysis, the reduced affinity of TF1 for T-containing DNA is shown to be associated with bending that is still sharp. The analysis of the TF1-DNA interaction has also been extended by hydroxyl radical (.OH) and methylation interference footprinting at two DNA sites. At each of these sites, and on each strand, TF1 strongly protects three segments of DNA from attack by OH. Patches of protected DNA are centered approximately ten base-pairs apart and fall on one side of the B-helix. Methylation in either the major or minor groove in the central ten base-pairs of the two TF1 binding sites quantitatively diminishes, but does not abolish, TF1 binding. We propose that multiple protein contacts allow DNA to wrap around the relatively small TF1 dimer, considerably deforming the DNA B-helix in the process.

TFIIIA induced DNA bending: effect of low ionic strength electrophoresis buffer conditions

We have used a circular permutation gel shift assay to show that the 5S gene transcription factor, TFIIIA, induces a bend at the internal promoter of the Xenopus oocyte-type 5S gene. The degree of bending is comparable to what we have previously observed for TFIIIA induced bending of the Xenopus somatic-type gene [Schroth, G.P. et al. (1989) Nature 340, 487-488]. In addition, we show that TFIIIA induced DNA bending is dramatically affected by the ionic conditions used during gel electrophoresis. By modifying the conditions of the electrophoresis, we can detect two distinct conformations for the TFIIIA/DNA complex. In very low ionic strength buffers, the degree of DNA bending in the complex is estimated to be about 25 to 30 degrees, whereas in higher ionic strength buffers it is about 60 to 65 degrees. These data explain the apparent discrepancy between our results and the results of another study in which it was claimed that TFIIIA did not 'substantially' bend DNA [Zweib, C. and Brown, R.S. (1990) Nucleic Acid Res. 18, 583-587]. These results also demonstrate that the TFIIIA/DNA complex has a large degree of conformational flexibility. Both DNA bending and conformational flexibility are structural features which may provide a key insight into the function of TFIIIA as a positive transcription factor.

The DNA-binding domain of HPV-16 E2 protein interaction with the viral enhancer: protein-induced DNA bending and role of the nonconserved core sequence in binding site affinity

We expressed the carboxy-terminal portion of the E2 open reading frame (ORF)-encoded protein of human papillomavirus type 16 (HPV-16) and purified it to near homogeneity. Using DNase I footprinting techniques, we show that like the homologous protein from bovine papillomavirus type 1 (BPV-1), HPV-18, HPV-11, it binds DNA at the enhancer consensus motif ACCN6GGT. Base and phosphate backbone contact points were determined using methylation protection and interference and ethylation interference assays. This HPV-16 E2 DNA-binding domain protein contacts the site at the outermost conserved GG residues which is similar to the interaction of the BPV-1 E2 system. However, there are many fewer phosphate backbone contacts. Using gel retardation assays, the HPV-16 E2 protein interaction with the consensus motif was characterized further based on the specific sequence of the noncontacted, nonconserved internal bases. Affinity of this E2 protein for the consensus site increased dramatically with an A.T-rich core sequence. Like the homologous BPV-1 protein, HPV-16 E2 protein induces DNA bending at its binding site. Furthermore, examination of the DNA region containing a single consensus motif far upstream from the major promoter, P97, revealed naturally bent DNA that was further bent upon interaction with the HPV-16 E2 protein.

Bending of DNA by gene-regulatory proteins: construction and use of a DNA bending vector

The binding of a protein to its specific sequence, borne on a DNA fragment, retards the mobility of the fragment in a characteristic way during gel electrophoresis. If the protein induces bending in the DNA, the contortion can also be monitored by gel electrophoresis, because the amount of retardation of the mobility of the DNA-protein complex is dependent upon the position and the degree of the bend induced in the DNA fragment [Wu and Crothers, Nature 308 (1984) 509-513]. We have constructed a plasmid, pBend2, which can generate a large number of DNA fragments of identical length in which the protein-binding nucleotide sequence is located in circular permutations. The vector contains two identical DNA segments containing 17 restriction sites in a direct repeat spanning a central region containing cloning sites. The protein-binding sequence is inserted at one of these cloning sites. To investigate the functional significance of bending, we have compared, using pBend2, the cAMP.cAMP-receptor protein (CPR)-induced bending of CRP-binding sites found in five different genes of Escherichia coli. We have also shown that the bacteriophage lambda 0R1 operator DNA is bent when complexed with the CI or Cro repressor of the phage.

Transcription factor IIIA induced bending of the Xenopus somatic 5S gene promoter

Transcription factor IIIA (TFIIIA), the canonical zinc-finger protein, is a protein of relative molecular mass 39,000 (39K) that is required for transcription of 5S-ribosomal subunit genes in Xenopus. It binds in a sequence-specific manner to the internal control region of the 5S gene (see Fig. 1) and facilitates transcription of the gene by RNA polymerase III. It also binds to the 5S gene product to form a 7S ribonucleoprotein particle. In oocytes the 7S particle acts as a storage form of the RNA to be utilized later in development. TFIIIA binds to DNA through its 30 K N-terminal domain, which contains nine zinc-fingers. TFIIIA was the first protein described to have this type of DNA binding motif, but numerous other proteins have now been shown to have zinc-finger domains. A structure for a single zinc-finger from the yeast protein ADR1, was recently proposed based on two-dimensional NMR data (ref. 8), and a similar structure was proposed based on comparison with crystal structures of other metalloproteins. Although models for the interaction of TFIIIA with the 5S-ribosomal gene DNA have been proposed, based on nuclease digestion and methylation interference data, little precise structural information is available for TFIIIA and the physical basis for the interaction of zinc-fingers with DNA is not understood. Using both circular permutation and circularization assays we provide convincing biochemical evidence that TFIIIA bends the DNA at the internal promoter of the 5S gene.