Poly(L–lysine)–DNA interactions in NaCl solutions: B → C and B → ψ Transitions

Thermal denaturation and circular dichroism (CD) properties of poly(L -lysine)–DNA complexes vary greatly when these complexes are prepared differently, that is, whether by NaCl-gradient dialysis starting from 2.0 M NaCl or by direct mixing at low salt. These differing properties were investigated in more detail by examining complexes, made by direct mixing in the presence of various concentrations of NaCl, both before and after the NaCl was dialyzed out of the complex solution. The precipitation curves of DNA due to polylysine binding indicate that such binding is noncooperative at zero salt; from 0.1 up to 1.0 M NaCl they exhibit varying degrees of cooperatively. Starting from zero salt, as the NaCl concentration used for complex formation is increased, both the CD and the melting properties of the complexes are shifted from those of directly mixed at zero salt to those of reconstitution: in the CD spectra there is a gradual shift from a B → C transition to a B → ψ transition; thermal denaturation results show a gradual increase in the melting temperatures of both free DNA (t_m) and polylysine-bound DNA (t′_m). The progressive shift from B → C to B → ψ suggests a close relationship between these two transitions. Large aggregates of the complexes do not warrant the appearance of ψ-type CD spectra: ψ-spectra have been obtained in the supernatants of polylysine–DNA complexes made and measured at 1.0 M NaCl while slightly perturbed CD spectra in B → C transition have been observed in turbid solutions of fully covered complexes made at very low salt. If the complexes are made at intermediate salts and dialyzed to a very low salt, although up to 60% of the DNA is still bound by polylysine, the CD spectra of the complexes are shifted back to the B-type CD characteristic of pure DNA.     

Interaction between poly(L-lysine48, L-histidine52) and DNA.

Poly(Lys⁴⁸, His⁵²), a random copolypeptide of L -lysine (48%) and L -histidine (52%), was used as a model protein for investigating the effects of protonation on the imidazole group of histidines on protein binding to DNA. The complexes formed between poly(Lys⁴⁸, His⁵²) and DNA were examined using absorbance, circular dichroism (CD), and thermal denaturation. Although increasing pH reduces the charges on histidine side chains in the model protein, the protein still binds the DNA with approximately one positive charge per negative charge in protein-bound regions. Nevertheless, CD and melting properties of poly(Lys⁴⁸, His⁵²)-DNA complexes still depend upon the solution pH which determines the protonation state of imidazole group of histidine side chains. At pH 7.0, the complexes show two characteristic melting bands with a t_m (46–51°C) for free base pairs and a t′_m (94°C) for protein-bound base pairs. The t′_m of the complexes is reduced to 90°C at pH 9.2, although at this pH there is still one lysine per phosphate in protein-bound regions. Presumably, the presence of deprotonated histidine residues destabilizes the native structure of protein-bound DNA. The binding of this model protein to DNA causes a red shift of the crossover point and both a red shift and a reduction of the positive CD band of DNA near 275 nm. This phenomenon is similar to that caused by polylysine binding. These effects, however, are greatly diminished when histidine side chains in the model protein are deprotonated. The structure of already formed poly(Lys⁴⁸, His⁵²)·DNA complexes can be perturbed by changing the solution pH. However, the results suggest a readjustment of the complex to accommodate charge interactions rather than a full dissociation of the complex followed by reassociation between the model protein and DNA.     

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 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.     

Regulation of the synthesis of adenylate cyclase in Escherichia coli by the cAMP -- cAMP receptor protein complex

Summary The synthesis of the adenylate cyclase [ATP pyrophosphatelyase-(cyclizing), E.C. 4.6.1.1.] of Escherichia coli, appears to be regulated negatively by the cAMP receptor protein CRP. This conclusion is based on a comparison of adenylate cyclase activities measured in vitro with the rates of cAMP synthesis by intact bacteria. The activity of adenylate cyclase, depending on conditions of growth, is also regulated by CRP; this effect, however, is indirect insofar as it is mediated by a protein or proteins under CRP control.     

Interaction of the trp repressor with trp operator DNA fragments

The interaction of the trp repressor with several trp operator DNA fragments has been examined by DNA gel retardation assays and by circular dichroism, in the absence and presence of the corepressor l-tryptophan. The holorepressor binds stoichiometrically to both the trpO and aroH operators, forming 1:1 complexes. In the presence of excess protein, additional complexes are formed with these operator fragments. The relative electrophoretic mobilities of the 1:1 complexes differ significantly for trp and aroH operators, indicating that they differ substantially in gross structure. A mutant trp operator, trpO ^c, has low affinity for the holorepressor, and forms only complexes with stoichiometries of 2:1 (repressor: DNA) or higher, which have a very low electrophoretic mobility. Specific binding is also accompanied by a large increase in the intensity of the near ultraviolet circular dichroism, with only a small blue shift, which is consistent with significant changes in the conformation of the DNA. Large changes in the chemical shifts of three resonances in the ³¹P NMR spectrum of both the trp operator and the aroH operator occur on adding repressor only in the presence of L-tryptophan, consistent with localised changes in the backbone conformation of the DNA.Abbreviations CD circular dichroism - trpO, trpR aroH trp operator fragments - trpO ^c trpMH mutant trp operator fragments     

The Sequential Mechanism of Guanidine Hydrochloride-Induced Denaturation of cAMP Receptor Protein from Escherichia coli. A Fluorescent Study Using 8-Anilino-1-Naphthalenesulfonic Acid

cAMP receptor protein (CRP) regulates expression of a number of genes in Escherichia coli. The protein is a homodimer and each monomer is folded into two structural domains. The biological activation of CRP upon cAMP binding may involve the subunit realignment as well as reorientation between the domains within each subunit. In order to study the interactions between the subunits or domains, we performed stopped-flow measurements of the guanidine hydrochloride (GuHCl)-induced denaturation of CRP. The changes in CRP structure induced by GuHCl were monitored using both intrinsic Trp fluorescence as well as the fluorescence of an extrinsic probe, 8-anilino-1-Naphthalenesulfonic acid (ANS). Results of CRP denaturation using Trp fluorescence detection are consistent with a two-step model [Malecki, and Wasylewski, (1997), Eur. J. Biochem. 243, 660], where the dissociation of dimer into subunits is followed by the monomer unfolding. The denaturation of CRP monitored by ANS fluorescence reveals the existence of two additional processes. One occurs before the dissociation of CRP into subunits, whereas the second takes place after the dissociation, but prior to proper subunit unfolding. These additional processes suggest that CRP denaturation is described by a more complicated mechanism than a simple three-state equilibrium and may involve additional changes in both inter- and intrasubunit interactions. We also report the effect of cAMP on the kinetics of CRP subunit unfolding and refolding.     

Studies on poly(L-lysine50, L-tyrosine50)-DNA interaction

Interaction between poly(Lys⁵⁰, Tyr⁵⁰) and DNA has been studied by absorption, circular dichroism (CD), and fluorescence spectroscopy and thermal denaturation in 0.001M Tris, pH 6.8. The binding of this copolypeptide to DNA results in an absorbance enhancement and fluorescence quenching on tyrosine. There is also an increase in the tyrosine CD at 230 nm. The CD of DNA above 250 nm is slightly shifted to the longer wavelength which is qualitatively similar to, but quantitatively much smaller than, that induced by polylysine binding. At physiological pH the poly(Lys⁵⁰, Tyr⁵⁰)–DNA complex is soluble until there is one lysine and one tyrosine per nucleotide in the complex. The same ratio of amino acid residues to nucleotide has also been observed in copolypeptide-bound regions of the complex. The addition of more poly(Lys⁵⁰, Tyr⁵⁰) to DNA yields a constant melting temperature, T_m′, for bound base pairs at 90°C which is close to that of polylysine-bound DNA under the same condition. The melting temperature, T_m, of free base pairs at about 60°C on the other hand, is increased by 10°C as more copolypeptide is bound to DNA. As the temperature is raised, both absorption and CD spectra of the complexes with high coverage are changed, suggesting structural alteration, perhaps deprotonation, on bound tyrosine. The results in this report also suggest that intercalation of tyrosine in DNA is unlikely to be the mode of binding.     

Escherichia coli cAMP receptor protein: evidence for three protein conformational states with different promoter binding affinities

Cyclic AMP receptor protein (CRP) from Escherichia coli is assumed to exist in two states, namely, those represented by the free protein and that of the ligand-protein complex. To establish a quantitative structure-function relation between cAMP binding and the cAMP-induced conformational changes in the receptor, protein conformational change was quantitated as a function of cAMP concentration up to 10 mM. The protein conformation was monitored by four different methods at pH 7.8 and 23 degrees C, namely, rate of proteolytic digestion by subtilisin, rate of chemical modification of Cys-178, tryptophan fluorescence, and fluorescence of the extrinsic fluorescence probe 8-anilino-1-naphthalenesulfonic acid (ANS). Each of these techniques reveals a biphasic dependence of protein conformation on cAMP concentration. At low cAMP concentrations ranging from 0 to 200 microM, the rates of proteolytic digestion and that of Cys-178 modification increase, whereas the fluorescence intensity of the ANS-protein complex is quenched, and there is no change in the fluorescence intensity of the tryptophan residues in the protein. At higher cAMP concentrations, the rates of proteolytic and chemical modification of the protein decrease, while the fluorescence intensity of the ANS-protein complex is further quenched but there is an increase in the intensity of tryptophan fluorescence. These results show unequivocally that there are at least three conformational states of the protein. The association constants for the formation of CRP-cAMP and CRP-(cAMP)2 complexes derived from conformational studies are in good agreement with those determined by equilibrium dialysis, nonequilibrium dialysis, and ultrafiltration. Therefore, the simplest explanation would be that the protein exhibits three conformational states, free CRP and two cAMP-dependent states, which correspond to the CRP-cAMP and CRP-(cAMP)2 complexes. The binding properties of CRP-cAMP and CRP-(cAMP)2 to the lac promoter were studied by using the gel retardation technique. At a high concentration of cAMP which favors the formation of the CRP-(cAMP)2 complex, binding of the protein to DNA is decreased. This, together with conformational data, strongly suggests that only the CRP-cAMP complex is active in specific DNA binding whereas CRP and CRP-(cAMP)2 are not.     

Circular dichroism of films of polynucleotides

The CD spectra of films of the lithium salt of E. coli and calf thymus DNA, and alternating d-AT : AT were measured as a function of relative humidity. Films of the ammonium acetate salt of DNA were also measured. The ammonium films yield the previously reported A-form CD spectra. A possible explanation for the small magnitude of the 260-nm band of the A-form film spectra compared to double-stranded RNA spectra is that the film DNA is in a different conformation than RNA within the A family of conformations. At relative humidities of 92% or lower, a negative nonconservative CD spectrum with negative minima near 270 and 210 nm is observed with the lithium films. The magnitude of the minima varies from film to film. In films of DNA the magnitude ranges from a delta epsilon of ?5 to ?35; d-AT : AT films show magnitudes to ?300. CD spectra of this type are designated Ψ spectra. Similar spectra have been reported from reconstituted complexes of DNA and polylysine or f-1 histone. If the origins of the film and protein–DNA complex spectra are similar, the complex spectra are not the result of specific secondary structural changes induced in the DNA by the protein fraction. Theoretical analysis suggests that Ψ spectra are not the result of changes in the secondary or tertiary structure of DNA. Instead, the previously proposed explanation based on liquid crystals is favored. The DNA could form asymmetric structures with long-range periodicity. It is likely that the observed CD spectra of f-1 complexes are artifacts of DNA aggregation. The possibility that some other previously published spectra of protein–DNA complexes also reflect artifacts is suggested.     

Assembly of the CD8α/p56 protein complex in stably expressing rat epithelial cells

We have previously characterized the biogenesis of the human CD8α protein expressed in rat epithelial cells. We now describe the biosynthesis, post-translational maturation and hetero-oligomeric assembly of the human CD8α/p56^lck protein complex in stable transfectants obtained from the same cell line. There were no differences in the myristilation of p56^lck, or in the dimerization, O-glycosylation and transport to the plasma membrane of CD8α, between cells expressing either one or both proteins. In the doubly expressing cells, dimeric forms of CD8α established hetero-oligomeric complexes with p56^lck, as revealed by co-immunoprecipitation assays performed with anti-CD8α antibody. Moreover, p56^lck bound in these hetero-oligomeric complexes was endowed with auto- and hetero-phosphorylating activity. The present study shows that: (1) the newly synthesized p56^lck binds rapidly to CD8α and most of the p56^lck is bound to CD8α at steady state; (2) CD8α/p56^lck protein complexes are formed at internal membranes as well as at the plasma membrane; and (3) about 50% of complexed p56^lck reaches the cell surface.     

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.     

Effect of temperature and guanidine hydrochloride on ferrocytochrome<Emphasis Type="Italic"> c</Emphasis> at neutral pH

Thermally denatured horse heart ferrocytochrome c (ferrocyt c) has been characterized using absorption spectroscopy, differential scanning calorimetry (DSC) and viscometry at pH 7.0. DSC experiments have yielded the transition temperature of denaturant-free ferrocyt c unfolding as 100.6±0.3 °C, indicating an extremely high stability of the protein. The presence of guanidine hydrochloride (GdnHCl) facilitated estimation of the structural features of thermally unfolded ferrocyt c. The stability of the protein, expressed by G _D at 25 °C, is 59±5 kJ mol^–1 (DSC) and 65±6 kJ mol^–1 (absorption spectroscopy). An absorption spectrum of ferrocyt c demonstrates that the heme occurs in the high-spin state at extreme denaturing conditions (94 °C, 6.6 M GdnHCl). Absorption spectroscopy, using heme as a probe, shows that thermal denaturation of ferrocyt c occurs as a transition from a native low-spin (Met80/His18) to a high-spin disordered state with involvement of non-native, low-spin (bis-His) species.Abbreviations CD circular dichroism - cyt c cytochrome c - DSC differential scanning calorimetry - ferricyt c ferricytochrome c - ferrocyt c ferrocytochrome c - GdnHCl guanidine hydrochloride - NHE normal hydrogen electrode