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.     

The change of DNA structure by specific binding of the cAMP receptor protein from rotation diffusion and dichroism measurements.

The structure of complexes formed between cAMP receptor protein (CRP) and various restriction fragments from the promoter region of the lactose operon has been analysed by measurements of electrodichroism. Binding of CRP to a 62-bp fragment containing the major site leads to an increase of the rotation time constant from 0.33 to 0.43 microseconds; addition of cAMP to the complex induces a decrease to 0.25 microseconds. Similar data are obtained for a 80-bp fragment containing the operator site; however, in this case the decrease of the rotation time for the specific complex is only observed when the salt concentration is increased from 3 to 13 mM. A 203-bp fragment containing both sites showed a corresponding change after pre-incubation at 50 mM salt. The salt dependence of the rotation time for the specific complex formed with the 203-bp fragment also indicates that a compact structure is formed at 13 mM salt, whereas the structure is not as compact at 3 mM salt. A 98-bp fragment without specific CRP sites did not reveal changes corresponding to those observed for the specific fragments. The rotation time constants together with the dichroism amplitudes indicate that binding of CRP to specific sites in the presence of cAMP leads to the formation of compact structures, which are consistent with bending of DNA helices. The observed strong salt dependence of the structure is apparently due to electrostatic repulsion between adjoining helix segments.     

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.     

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.     

The gene encoding the periplasmic cyclophilin homologue, PPlase A, in Escherichia coli, is expressed from four promoters, three of which are activated by the cAMP–CRP complex and negatively regulated by the CytR repressor

The rot gene in Escherichia coli encodes PPlase A, a periplasmic peptldyl-prolyl cis-trans isomerase with homology to the cyclophilin family of proteins. Here it is demonstrated that rot is expressed in a complex manner from four overlapping promoters and that the rot regulatory region is unusually compact, containing a close array of sites for DNA-binding proteins. The three most upstream rot promoters are activated by the global gene regulatory cAMP–CRP complex and negatively regulated by the CytR repressor protein. Activation of these three promoters occurs by binding of cAMP–CRP to two sites separated by 53 bp. Moreover, one of the cAMP–CRP complexes is involved in the activation of both a Class I and a Class II promoter. Repression takes place by the formation of a CytR/cAMP–CRP/DNA nucleoprotein complex consisting of the two cAMP–CRP molecules and CytR bound in between. The two regulators bind co-operatively to the DNA overlapping the three upstream promoters, simultaneously quenching the cAMP–CRP activator function. These results expand the CytR regulon to include a gene whose product has no known function in ribo- and deoxyribonucleoside catabolism or transport.     

Isolation and characterization of the amino and carboxyl proximal fragments of the adenosine cyclic 3' ,5'-phosphate receptor protein of Escherichia coli

The cyclic AMP receptor protein (CRP) is a positive and negative regulatory protein for gene expression in Escherichia coli. The protein has been cleaved proteolytically to determine the relation between CRP structure and function. In the presence of sodium dodecyl sulfate (NaDodSO4), chymotrypsin dissects CRP into two stable fragments of molecular weight 9500 (9.5K) and 13 000 (13K). After removal of NaDodSO4, the two fragments are resolved by Bio-Rex 70 chromatography in 6 M urea. Analyses of the terminal amino acids released from each fragment and cyanogen bromide cleavage products indicate that the 9.5K fragment is amino proximal in CRP while the 13K fragment is carboxyl proximal. Notable features of amino acid composition are the relatively high amount of arginine and methionine in the 13K fragment and the retention in the 9.5K fragment of the two tryptophans present in the CRP subunit. Following isoelectric focusing in 8 M urea, the 9.5K fragment, 22.5K CRP, and 13K fragment migrate to pH 5.5, 8.3, and 10.3, respectively. While CRP is a cAMP-stimulated DNA binding protein, the 13K fragment binds to DNA in the presence and absence of cAMP. The 9.5K fragment associates to form dimers and decamers. These data are consonant with a model in which the DNA binding domain is present in the carboxyl proximal region of CRP while the amino proximal region contains the subunit-subunit interaction sites and much of the cAMP binding domain.     

DNA bending by photolyase in specific and non-specific complexes studied by atomic force microscopy.

Specific and non-specific complexes of DNA and photolyase are visualised by atomic force microscopy. As a substrate for photolyase a 1150 bp DNA restriction fragment was UV-irradiated to produce damaged sites at random positions. Comparison with a 735 bp undamaged DNA fragment made it possible to separate populations of specific and non-specific photolyase complexes on the 1150 bp fragment, relieving the need for highly defined substrates. Thus it was possible to compare DNA bending for specific and non-specific interactions. Non-specific complexes show no significant bending but increased rigidity compared to naked DNA, whereas specific complexes show DNA bending of on average 36 degrees and higher flexibility. A model obtained by docking shows that photolyase can accommodate a 36 degrees bent DNA in the vicinity of the active site.     

Position 127 amino acid substitutions affect the formation of CRP:cAMP:lacP complexes but not CRP:cAMP:RNA polymerase complexes at lacP.

The lacP DNA binding and activation characteristics of CRP having amino acid substitutions at position 127 were investigated. Wild-type (WT) and T127C CRP footprinted lacP DNA in the presence of DNase I in a cAMP-dependent manner. The T127G, T127I, and T127S forms of CRP failed to footprint lacP both in the absence and in the presence of cAMP. Consistent with these data, WT and T127C CRP:cAMP complexes exhibited high affinity for the lacP CRP site whereas T127G, T127I, or T127S CRP:cAMP complexes exhibited low affinity for the lacP CRP site. CRP:cAMP:RNA polymerase (RNAP) complexes formed at lacP in reactions that contained WT, T127C, T127G, T127I, or T127S CRP. These results demonstrate that allosteric changes important for cAMP-mediated CRP activation are differentially affected by amino acid substitution at position 127. Proper cAMP-mediated reorientation of the DNA binding helices required either threonine or cysteine at position 127. However, cAMP-dependent interaction of CRP with RNAP was accomplished regardless of the amino acid at position 127. RNAP:lacP complexes that supported high-level lac RNA synthesis formed rapidly in reactions that contained WT or T127C CRP whereas RNAP:lacP complexes that supported only low-level lac RNA synthesis formed at slower rates in reactions that contained T127I or T127S CRP. The T127G CRP:cAMP:RNAP:lacP complex failed to activate lacP. The results of this study lead us to conclude that threonine 127 plays an important role in transduction of the signal from the CRP cyclic nucleotide binding pocket that promotes proper orientation of the DNA binding helices and only a minor, if any, role in the functional exposure of the CRP RNAP interaction domain.     

Ligand-modulated binding of a gene regulatory protein to DNA. Quantitative analysis of cyclic-AMP induced binding of CRP from Escherichia coli to non-specific and specific DNA targets

This paper describes a generally applicable method for quantitative investigation of ligand-dependent binding of a regulatory protein to its target DNA at equilibrium. It is used here to analyse the coupled binding equilibria of cAMP receptor protein from Escherichia coli K12 (CRP) with DNA and the physiological effector cAMP. In principle, the DNA binding parameters of CRP dimers with either one or two ligands bound are determinable in such an approach. The change of protein fluorescence was used to measure CRP binding to its recognition sequence in the lac control region and to non-specific DNA. Furthermore, the binding of cAMP to preformed CRP-DNA complexes was independently studied by equilibrium dialysis. The data were analysed using a simple interactive model for two intrinsically identical sites and site-site interactions. The intrinsic binding constant K and the co-operativity factor alpha for binding of cAMP to free CRP depend only slightly on salt concentration between 0.01 M and 0.2 M. In contrast, the affinity of cAMP for CRP pre-bound to non-specific DNA increases with the salt concentration and the co-operativity changes from positive to negative. This results from cation rebinding to the DNA lattice upon forming the cAMP-CRP-DNA complex from cAMP and the pre-formed CRP-DNA complex. The CRP-cAMP1 complex shows almost the same affinity for specific and non-specific DNA as the CRP-cAMP2 complex, and both displace the same number of cations. It is concluded that the allosteric activation of CRP is induced upon binding of the first cAMP. These results are used to estimate the occupation of the CRP site in the lac control region in relation to the cAMP concentration in vivo. Under physiological conditions the lac promoter is activated by the CRP dimer complexed with only one cAMP. Furthermore, a model for the differential activation of various genes expressed under catabolite repression is presented and discussed.     

Solution structure of the HMG protein NHP6A and its interaction with DNA reveals the structural determinants for non-sequence-specific binding

NHP6A is a chromatin-associated protein from Saccharomyces cerevisiae belonging to the HMG1/2 family of non-specific DNA binding proteins. NHP6A has only one HMG DNA binding domain and forms relatively stable complexes with DNA. We have determined the solution structure of NHP6A and constructed an NMR-based model structure of the DNA complex. The free NHP6A folds into an L-shaped three alpha-helix structure, and contains an unstructured 17 amino acid basic tail N-terminal to the HMG box. Intermolecular NOEs assigned between NHP6A and a 15 bp 13C,15N-labeled DNA duplex containing the SRY recognition sequence have positioned the NHP6A HMG domain onto the minor groove of the DNA at a site that is shifted by 1 bp and in reverse orientation from that found in the SRY-DNA complex. In the model structure of the NHP6A-DNA complex, the N-terminal basic tail is wrapped around the major groove in a manner mimicking the C-terminal tail of LEF1. The DNA in the complex is severely distorted and contains two adjacent kinks where side chains of methionine and phenylalanine that are important for bending are inserted. The NHP6A-DNA model structure provides insight into how this class of architectural DNA binding proteins may select preferential binding sites.