The catabolite activator protein stabilizes its binding site in the E. coli lactose promoter.

The effect of catabolite activator protein, CAP, on the thermal stability of DNA was examined. Site specific binding was studied with a 62 bp DNA restriction fragment containing the primary CAP site of the E. coli lactose (lac) promoter. A 144 bp DNA containing the lac promoter region and a 234 bp DNA from the pBR322 plasmid provided other DNA sites. Thermal denaturation of protein-DNA complexes was carried out in a low ionic strength solvent with 40% dimethyl sulfoxide, DMSO. In this solvent free DNA denatured below the denaturation temperature of CAP. The temperature stability of CAP for site specific binding was monitored using an acrylamide gel electrophoresis assay. Results show that both specific and non-specific CAP binding stabilize duplex DNA. Site specific binding to the 62 bp DNA produced a 13.3 degrees C increase in the transition under conditions where non-specific binding stabilized this DNA by 2-3 degrees C.     

Specific DNA binding of the cAMP receptor protein within the lac operon stabilizes double-stranded DNA in the presence of cAMP

The effects of varying amounts of cAMP receptor protein (CRP) in the presence and absence of cAMP on the melting and differential melting curves of a 301-bp fragment containing the lac control region in 5 mM Na+ have been investigated. The native 301-bp fragment consists of three cooperatively melting thermalites. At 5 mM Na+, thermalite I (155 bp) has a Tm of 66.4 degrees C and the melting transitions of thermalites II (81 bp) and III (65 bp) are superimposed with a Tm of 61.9 degrees C. The specific DNA target site for CRP and the lac promotor are located within thermalite II. CRP alone exerts no specific effects on the melting of the 301-bp fragment, non-specific DNA binding of CRP resulting in a progressive stabilization of the double-stranded DNA by increasing the number of base pairs melting at a higher Tm in a non-cooperative transition. The cAMP-CRP complex, however, exerts a specific effect with a region of approximately 36 bp, comprising the specific CRP binding site and a neighbouring region of DNA, being stabilized. The appearance of this new cooperatively melting region, known as thermalite IV, is associated with a corresponding decrease in the area of thermalites II/III. The Tm of thermalite IV is 64.4 degrees C, 2.5 degrees C higher than that of thermalites II/III. With two or more cAMP-CRP complexes bound per 301-bp fragment, the stabilization also affects the remaining 110 bp now making up thermalites II/III whose Tm is increased by 1 degrees C to 62.9 degrees C. The implications of these findings for various models of the mode of action of the cAMP-CRP complex are discussed.     

Turn of promotor DNA by cAMP receptor protein characterized by bead model simulation of rotational diffusion

The rotation diffusion of DNA double helices and their complexes with the cAMP receptor protein (CRP) has been simulated by bead models, in order to derive information on their structure in solution by comparison with results obtained from dichroism decay measurements. Straight DNA double helices are simulated by linear, rigid strings of overlapping beads. The radius of the beads and the length of the string are increased simultaneously by the same increments from initial outer dimensions derived from crystallographic data to final values, which are fitted to experimental rotation time constants observed for short DNA fragments (less than 100 bp). The final values reflect the solvated structure with the same 'solvation layer' added in all three dimensions. The protein is simulated by overlapping beads, which are assembled to a structure very similar to that found by x-ray crystallography. Complexes of the protein with DNA are formed with the centres of palindromic DNA sites at the centre of the two helix-turn-helix-motifs of the protein with some overlap of the two components. Simulation of the experimental data obtained for CRP complexes with specific DNA in the presence of cAMP requires strong bending of the double helices. According to our simulation the DNA is almost completely wrapped around the protein both in the complexes with a 62 bp fragment containing the standard CRP site and with a 80 bp fragment containing the second binding site of the lac operon. Simulations of the data obtained for a 203 bp fragment with both binding sites suggest that the two bound CRP proteins are in contact with each other and that the DNA is wrapped around the two protein dimers. A stereochemical model is suggested with a tetrahedral arrangement of the four protein subunits, which provides the advantage that two binding sites of the protein formed by two subunits each are located favorable for tight contacts to two binding sites on bent DNA, provided that the DNA sites are separated by an integer number of helix turns. In summary, the simulations demonstrate strong bending, which can be reflected by an arc radius in the range around 50 A. According to these data the overall bending angle of our longest DNA fragment is approximately 180 degrees, and thus the protruding ends are sufficiently close to each other such that RNA polymerase, for example, could contact both helical segments.     

Turn of Promotor DNA by cAMP Receptor Protein Characterized by Bead Model Simulation of Rotational Diffusion

Abstract

The rotation diffusion of DNA double helices and their complexes with the cAMP receptor protein (CRP) has been simulated by bead models, in order to derive information on their structure in solution by comparison with results obtained from dichroism decay measurements. Straight DNA double helices are simulated by linear, rigid strings of overlapping beads. The radius of the beads and the length of the string are increased simultaneously by the same increments from initial outer dimensions derived from crystallographic data to final values, which are fitted to experimental rotation time constants observed for short DNA fragments (< 100 bp). The final values reflect the solvated structure with the same ‘solvation layer’ added in all three dimensions. The protein is simulated by overlapping beads, which are assembled to a structure very similar to that found by x-ray crystallography. Complexes of the protein with DNA are formed with the centres of palindromic DNA sites at the centre of the two helix- turn-helix-motifs of the protein with some overlap of the two components. Simulation of the experimental data obtained for CRP complexes with specific DNA in the presence of cAMP requires strong bending of the double helices. According to our simulation the DNA is almost completely wrapped around the protein both in the complexes with a 62 bp fragment containing the standard CRP site and with a 80 bp fragment containing the second binding site of the lac operon. Simulations of the data obtained for a 203 bp fragment with both binding sites suggest that the two bound CRP proteins are in contact with each other and that the DNA is wrapped around the two protein dimers. A stereochemical model is suggested with a tetrahedral arrangement of the four protein subunits, which provides the advantage that two binding sites of the protein formed by two subunits each are located favorable for tight contacts to two binding sites on bent DNA provided that the DNA sites are separated by an integer number of helix turns. In summary, the simulations demonstrate strong bending, which can be reflected by an arc radius in the range around 50 Å. According to these data the overall bending angle of our longest DNA fragment is approximately 180°, and thus the protruding ends are sufficiently close to each other such that RNA polymerase, for example, could contact both helical segments.     

CAP binding to B and Z forms of DNA.

We have examined the interaction between the cyclic AMP receptor protein (CAP) and a small DNA fragment containing its specific recognition sequence by circular dichroism spectroscopy. The binding of CAP to this fragment induces a B to "C-like" change in the CD spectrum, which is different from that observed for non-specific binding. A one-to-one (CAP dimer to DNA) binding stoichiometry was deduced from spectroscopic titration data, as was a non-specific binding site size of 17 bp/dimer. In addition, we have compared the non-specific binding affinity of CAP for the B and Z forms of synthetic DNA copolymers. A slight preference for the B form was found. These results do not support the recent specific suggestion that CAP binds to a left-handed form of DNA (1), but indicate more generally that an optically detectable conformational change takes place in DNA on binding CAP.     

TET repressor.tet operator complex formation induces conformational changes in the tet operator DNA.

The structural changes of the tet operator DNA upon binding of the TET repressor protein are examined by circular dichroism. For this purpose a 70 bp DNA fragment was prepared which contains both tet operators. About 67% of the base pairs of this DNA are involved in specific interaction with the TET repressor. A rather large change in the CD of the DNA is induced by binding of the TET repressor. The shape of the CD difference spectrum is similar to the respective difference found for the lac operator DNA upon complex formation with the lac repressor. However, the effect induced by the TET repressor on tet operator DNA seems to comprise both the specific and non-specific effect of the lac repressor on the structure of DNA [Culard, F. and Maurizot, J.C. (1981) Nucl. Acids Res. 9, 5157-5184]. Specificity of binding is confirmed by the lack of any effect of the TET repressor on the CD of a 95 bp lac operator containing DNA fragment, by the reduced mobility of TET repressor.tet operator complexes on polyacrylamide gels under CD conditions, and by a titration experiment of tet operator DNA with TET repressor employing the CD change. The latter experiment reveals a stoichiometry of four TET repressors per tet operon control region.     

Structures during binding of cAMP receptor to promoter DNA: promoter search slowed by non-specific sites

The kinetics of cAMP receptor (CAP) binding to promoter DNA has been studied by stopped-flow electric-dichroism at a reduced salt concentration, where the coupling of non-specific and specific binding can be observed directly. Amplitudes, rise and decay times of dichroism transients provide detailed information about the reaction and the structure of intermediates over more than six orders of magnitude on the time scale. CAP binding during the first milliseconds after mixing is indicated by an increase of both rise- and decay-time constants. A particularly large increase of rise times reflects initial formation of non-symmetric complexes by protein binding to non-specific sites at DNA ends. The increase of the hydrodynamic dimensions continues up to ~1 s, before a decrease of time constants reflects transition to compact states with bent DNA up to the time range of ~10³ s. The slow approach to CAP-induced DNA bending is due to non-specific complexes, which are formed initially and are converted slowly to the specific complex. At the salt concentration of 13.5 mM, conversion to specific complexes with bent DNA is completed after ~40 s at pH 8 compared to >10³ s at pH 7, resulting from a higher affinity of CAP to non-specific sites at pH 7 than 8 by a factor of ~100. Thus, under the given conditions non-specific sites delay rather than facilitate formation of the specific complex with bent DNA. Experimental data obtained for a non-specific DNA clearly indicate the impact of pseudo-sites. The different electro-optical parameters have been combined in global fits.     

Molecular enzymology of the EcoRV DNA-(Adenine-N (6))-methyltransferase: kinetics of DNA binding and bending, kinetic mechanism and linear diffusion of the enzyme on DNA

The EcoRV DNA-(adenine-N(6))-methyltransferase recognizes GATATC sequences and modifies the first adenine residue within this site. We show here, that the enzyme binds to the DNA and the cofactor S-adenosylmethionine (AdoMet) in an ordered bi-bi fashion, with AdoMet being bound first. M.EcoRV binds DNA in a non-specific manner and the enzyme searches for its recognition site by linear diffusion with a range of approximately 1800 bp. During linear diffusion the enzyme continuously scans the DNA for the presence of recognition sites. Upon specific M.EcoRV-DNA complex formation a strong increase in the fluorescence of an oligonucleotide containing a 2-aminopurine base analogue at the GAT-2AP-TC position is observed which, most likely, is correlated with DNA bending. In contrast to the GAT-2AP-TC substrate, a G-2AP-TATC substrate in which the target base is replaced by 2-aminopurine does not show an increase in fluorescence upon M.EcoRV binding, demonstrating that 2-aminopurine is not a general tool to detect base flipping. Stopped-flow experiments show that DNA bending is a fast process with rate constants >10 s(-1). In the presence of cofactor, the specific complex adopts a second conformation, in which the target sequence is more tightly contacted by the enzyme. M.EcoRV exists in an open and in a closed state that are in slow equilibrium. Closing the open state is a slow process (rate constant approximately 0.7 min(-1)) that limits the rate of DNA methylation under single turnover conditions. Product release requires opening of the closed complex which is very slow (rate constant approximately 0.05-0.1 min(-1)) and limits the rate of DNA methylation under multiple turnover conditions. M.EcoRV methylates DNA sequences containing more than one recognition sites in a distributive manner. Since the dissociation rate from non-specific DNA does not depend on the length of the DNA fragment, DNA dissociation does not preferentially occur at the ends of the DNA.     

Differential binding of RNA polymerase to the pRM and pR promoters of bacteriophage lambda

Escherichia coli RNA polymerase binding to the promoters pR and pRM of bacteriophage lambda was visualized and quantitated by electron microscopy. Although the two promoters are located close together in the phage genome, their proximity to the end of an 889-bp HaeIII DNA fragment made it possible to position binary complexes within 18 bp (2%) intervals. Thus, polymerase binding to pR and pRM could be distinguished by comparing the locations of binary complexes formed with wild-type and mutant (prm-) DNA at 37 degrees and 15 degrees C. We found that at 37 degrees C, RNA polymerase bound primarily to pR, while at 15 degrees C the efficiency of binding was the same at pRM as at pR. In addition, at 15 degrees C the overall efficiency of binding was significantly reduced relative to that at 37 degrees C. When the enzyme was incubated with prm- DNA, binding to pRM was reduced at both temperatures, as expected. Reduced binding to pRM was accompanied by an increase in binding to pR, apparently as a consequence of the low enzyme-to-DNA ratios used in these experiments.     

Binding, bending and cleavage of DNA substrates by the homing endonuclease Pl-SceI.

To characterize the interaction between the homing endonuclease PI-SceI and DNA, we prepared different DNA substrates containing the natural recognition sequence or parts thereof. Depending on the nature of the substrates, efficient cleavage is observed with a DNA containing approximatel 30 bp of the natural recognition sequence using supercoiled plasmids, approximately 40-50 bp using linearized plasmids and > 50 bp using synthetic double-stranded oligodeoxynucleotides. Cleavage of supercoiled plasmids occurs without accumulation of the nicked intermediate. In the presence of Mn2+, DNA cleavage by PI-SceI is more efficient than with Mg2+ and already occurs with substrates containing a shorter part of the recognition sequence. The requirements for strong binding are less stringent: a 35 bp oligodeoxynucleotide which is not cleaved is bound as firmly as other longer oligodeoxynucleotides. PI-SceI binds with high affinity to one of its cleavage products, a finding which may explain why PI-SceI hardly shows enzymatic turnover in vitro. Upon binding, two complexes are formed, which differ in the degree of bending (45 degrees versus 75 degrees). According to a phasing analysis bending is directed into the major groove. Strong binding, not, however, cleavage is also observed with the genetically engineered enzymatically inactive variant comprising amino acids 1-277. Models for binding and cleavage of DNA by PI-SceI are discussed based on these results.     

Flexibility of DNA in complex with proteins deduced from the distribution of bending angles observed by scanning force microscopy

Flexibility and dynamics of DNA are important for DNA-binding and recognition by proteins. Here the flexibility of DNA is calculated from the distribution of DNA-bending angles of single DNA molecules as observed by scanning force microscopy by applying an equation that links the force constant of DNA-bending (f) to the variance of the distribution of bending angles (sigma): f=RT/sigma(2). Using published data, f is calculated to be 3-5 J/degree(2) for free DNA. Thus, bending DNA by 20 degrees requires approx. 0.5-1 kJ/mol. This result shows that DNA is very flexible and readily can be bent by thermal motion. DNA-flexibility is not altered in some protein-DNA complexes (HhaI methyltransferase, EcoRV restriction endonuclease). In contrast, DNA-binding by EcoRI endonuclease increases DNA-flexibility and binding by EcoRI methyltransferase restricts the flexibility of DNA. During the transition of the RNA polymerase-sigma(54)-DNA complex from the closed to the open form and of cro repressor from a non-specific to a specific binding mode the flexibility of the DNA is strongly reduced.     

Escherichia coli RNA polymerase binding to a DNA terminus prevents formation of a closed promoter complex

A 302 bp DNA fragment and a 113 bp subfragment of the former, both containing the fd gene VIII promoter (P VIII), were found to exhibit temperature-dependent differential behaviour in RNA chain initiation from P VIII. At 37 degrees C no significant differences were observed, while at 17 degrees C chain initiation was strongly suppressed only with the 113 bp fragment. This phenomenon depended on the presence of the (blunt) DNA terminus upstream from P VIII (position -70). Footprinting revealed that at 17 degrees C RNA polymerase was bound to this DNA fragment in a different mode. Contacts were observed only upstream from position -25. On the contrary, at 37 degrees C only the promoter complex footprint was visible. These results indicate that at 17 degrees C formation of the non-initiating complex is more favourable than formation of the promoter complex (which is closed at 17 degrees C; Hofer, B., Müller, D. and K?ster, H. (1985) Nucleic Acids Res. 13, 5995-6013) and that formation of both complexes is mutually exclusive. No footprints of RNA polymerase were observed at other DNA termini. This indicates a sequence-specificity for the interaction at the terminus of the 113 bp fragment. The footprint pattern, together with features of the DNA sequence, suggests that the contacts involved in this interaction are similar to those promoter contacts formed upstream from position -20 and that DNA without a -10 region can be specifically recognized by RNA polymerase.     

DNA bending induced by high mobility group proteins studied by fluorescence resonance energy transfer.

The HMG domains of the chromosomal high mobility group proteins homologous to the vertebrate HMG1 and HMG2 proteins preferentially recognize distorted DNA structures. DNA binding also induces a substantial bend. Using fluorescence resonance energy transfer (FRET), we have determined the changes in the end-to-end distance consequent on the binding of selected insect counterparts of HMG1 to two DNA fragments, one of 18 bp containing a single dA(2) bulge and a second of 27 bp with two dA(2) bulges. The observed changes are consistent with overall bend angles for the complex of the single HMG domain with one bulge and of two domains with two bulges of approximately 90-100 degrees and approximately 180-200 degrees, respectively. The former value contrasts with an inferred value of 150 degrees reported by Heyduk et al. (1) for the bend induced by a single domain. We also observe that the induced bend angle is unaffected by the presence of the C-terminal acidic region. The DNA bend of approximately 95 degrees observed in the HMG domain complexes is similar in magnitude to that induced by the TATA-binding protein (80 degrees), each monomeric unit of the integration host factor (80 degrees), and the LEF-1 HMG domain (107 degrees). We suggest this value may represent a steric limitation on the extent of DNA bending induced by a single DNA-binding motif.     

In the presence of subunit A inhibitors DNA gyrase cleaves DNA fragments as short as 20 bp at specific sites.

A key step in the supercoiling reaction is the DNA gyrase-mediated cleavage and religation step of double-stranded DNA. Footprinting studies suggest that the DNA gyrase binding site is 100-150 bp long and that the DNA is wrapped around the enzyme with the cleavage site located near the center of the fragment. Subunit A inhibitors interrupt this cleavage and resealing cycle and result in cleavage occurring at preferred sites. We have been able to show that even a 30 bp DNA fragment containing a 20 bp preferred cleavage sequence from the pBR322 plasmid was a substrate for the DNA gyrase-mediated cleavage reaction in the presence of inhibitors. This DNA fragment was cleaved, although with reduced efficiency, at the same sites as a 122 bp DNA fragment. A 20 bp DNA fragment was cleaved with low efficiency at one of these sites and a 10 bp DNA fragment was no longer a substrate. We therefore propose that subunit A inhibitors interact with DNA at inhibitor-specific positions, thus determining cleavage sites by forming ternary complexes between DNA, inhibitors and DNA gyrase.     

The interaction of E. coli integration host factor and lambda cos DNA: multiple complex formation and protein-induced bending.

The interaction of E. coli's integration Host Factor (IHF) with fragments of lambda DNA containing the cos site has been studied by gel-mobility retardation and electron microscopy. The cos fragment used in the mobility assays is 398 bp and spans a region from 48,298 to 194 on the lambda chromosome. Several different complexes of IHF with this fragment can be distinguished by their differential mobility on polyacrylamide gels. Relative band intensities indicate that the formation of a complex between IHF and this DNA fragment has an equilibrium binding constant of the same magnitude as DNA fragments containing lambda's attP site. Gel-mobility retardation and electron microscopy have been employed to show that IHF sharply bends DNA near cos and to map the bending site. The protein-induced bend is near an intrinsic bend due to DNA sequence. The position of the bend suggests that IHF's role in lambda DNA packaging may be the enhancement of terminase binding/cos cutting by manipulating DNA structure.     

Binding of the estrogen receptor DNA-binding domain to the estrogen response element induces DNA bending.

We have used circular permutation analysis to determine whether binding of purified Xenopus laevis estrogen receptor DNA-binding domain (DBD) to a DNA fragment containing an estrogen response element (ERE) causes the DNA to bend. Gel mobility shift assays showed that DBD-DNA complexes formed with fragments containing more centrally located EREs migrated more slowly than complexes formed with fragments containing EREs near the ends of the DNA. DNA bending standards were used to determine that the degree of bending induced by binding of the DBD to an ERE was approximately 34 degrees. A 1.55-fold increase in the degree of bending was observed when two EREs were present in the DNA fragment. These in vitro studies suggest that interaction of nuclear receptors with their hormone response elements in vivo may result in an altered DNA conformation.     

Preferential uptake of restriction fragments from a gonococcal cryptic plasmid by competent Neisseria gonorrhoeae

Factors involved in the specificity of DNA uptake by competent Neisseria gonorrhoeae were examined. Host-controlled modification did not affect uptake. Certain restriction fragments of the 4.2 kb gonococcal cryptic plasmid pFA1 and of the replicative form of the bacteriophage M13 were taken up in preference to others, independent of differences in fragment size. A 600 bp fragment from the 4.2 kb plasmid was cloned into pLES2, a gonococcal-Escherichia coli shuttle vector; the 600 bp fragment was taken up into a DNAase-I-resistant state in preference to the vector fragment. A second 370 bp fragment in pFA1 was also taken up preferentially. The 600 bp and 370 bp fragments share a 10 bp sequence, which is found in pFA1 only on fragments that were taken up readily. However, a fragment from M13 which was efficiently taken up did not contain this 10 bp sequence. In addition, this sequence was not sufficient to direct preferential DNA uptake by gonococci, since a recombinant plasmid containing this 10 bp sequence was not taken up appreciably better than the vector plasmid or another recombinant plasmid containing an unrelated 10 bp sequence. Sequence comparisons of the three restriction fragments which were preferentially taken up did not yield any consensus sequences greater than 7 bp. Although it is likely that efficient uptake of DNA by gonococci is determined by DNA structure, a single short sequence could not be found that accounted for specific uptake.