Thermodynamics and kinetics of formation of the alkaline state of a Lys 79-->Ala/Lys 73-->His variant of iso-1-cytochrome c

The alkaline transition kinetics of a Lys 73-->His (H73) variant of iso-1-cytochrome c are triggered by three ionizable groups [Martinez, R. E., and Bowler, B. E. (2004) J. Am. Chem. Soc. 126, 6751-6758]. To eliminate ambiguities caused by overlapping phases due to formation of the Lys 79 alkaline conformer and proline isomerization associated with the His 73 alkaline conformer, we mutated Lys 79 to Ala in the H73 variant (A79H73). The stability and guanidineHCl m-values of the A79H73 and H73 variants at pH 7.5 are the same. The Ala 79 mutation causes formation of the alkaline conformer to depend on [NaCl]. The salt dependence saturates at 500 mM NaCl, and the thermodynamics of alkaline state formation for the A79H73 and H73 variants become identical. The salt dependence is consistent with loss of an electrostatic contact between Lys 79 and heme propionate D in the A79H73 variant. The kinetics of alkaline state formation for the A79H73 variant support the three trigger group model developed for the H73 variant, with the primary trigger, pK(HL), being ionization of His 73. The low pH ionization, pK(H1), is perturbed by the Ala 79 mutation indicating that this ionization is modulated by the buried hydrogen bond network involving heme propionate D. The A79H73 variant has a high spin heme above pH 9 suggesting that the high pH ionization, pK(H2), involves a high spin heme conformer. The proline isomerization phase is modulated by both pK(HL) and pK(H2) indicating that it is sensitive to protein conformation.     

Conformational dynamics and molecular recognition: backbone dynamics of the estrogen receptor DNA-binding domain.

We examined the internal mobility of the estrogen receptor DNA-binding domain (ER DBD) using NMR15N relaxation measurements and compared it to that of the glucocorticoid receptor DNA-binding domain (GR DBD). The studied protein fragments consist of residues Arg183-His267 of the human ER and residues Lys438-Gln520 of the rat GR. The15N longitudinal (R1) and transverse (R2) relaxation rates and steady state {1H}-15N nuclear Overhauser enhancements (NOEs) were measured at 30 degrees C at1H NMR frequencies of 500 and 600 MHz. The NOE versus sequence profile and calculated order parameters for ER DBD backbone motions indicate enhanced internal dynamics on pico- to nanosecond time-scales in two regions of the core DBD. These are the extended strand which links the DNA recognition helix to the second zinc domain and the larger loop region of the second zinc domain. The mobility of the corresponding regions of the GR DBD, in particular that of the second zinc domain, is more limited. In addition, we find large differences between the ER and GR DBDs in the extent of conformational exchange mobility on micro- to millisecond time-scales. Based on measurements of R2as a function of the15N refocusing (CPMG) delay and quantitative (Lipari-Szabo-type) analysis, we conclude that conformational exchange occurs in the loop of the first zinc domain and throughout most of the second zinc domain of the ER DBD. The conformational exchange dynamics in GR DBD is less extensive and localized to two sites in the second zinc domain. The different dynamical features seen in the two proteins is consistent with previous studies of the free state structures in which the second zinc domain in the ER DBD was concluded to be disordered whereas the corresponding region of the GR DBD adopts a stable fold. Moreover, the regions of the ER DBD that undergo conformational dynamics on the micro- to millisecond time-scales in the free state are involved in intermolecular protein-DNA and protein-protein interactions in the dimeric bound state. Based on the present data and the previously published dynamical and DNA binding properties of a GR DBD triple mutant which recognize an ER binding site on DNA, we argue that the free state dynamical properties of the nuclear receptor DBDs is an important element in molecular recognition upon DNA binding.     

T antigen origin-binding domain of simian virus 40: determinants of specific DNA binding

To better understand origin recognition and initiation of DNA replication, we have examined by NMR complexes formed between the origin-binding domain of SV40 T antigen (T-ag-obd), the initiator protein of the SV40 virus, and cognate and noncognate DNA oligomers. The results reveal two structural effects associated with "origin-specific" binding that are absent in nonspecific DNA binding. The first is the formation of a hydrogen bond (H-bond) involving His 203, a residue that genetic studies have previously identified as crucial to both specific and nonspecific DNA binding in full-length T antigen. In free T-ag-obd, the side chain of His 203 has a pK(a) value of approximately 5, titrating to the N(epsilon)(1)H tautomer at neutral pH (Sudmeier, J. L., et al. (1996) J. Magn. Reson., Ser. B 113, 236-247). In complexes with origin DNA, His 203 N(delta)(1) becomes protonated and remains nontitrating as the imidazolium cation at all pH values from 4 to 8. The H-bonded N(delta1)H resonates at 15.9 ppm, an unusually large N-H proton chemical shift, of a magnitude previously observed only in the catalytic triad of serine proteases at low pH. The formation of this H-bond requires the middle G/C base pair of the recognition pentanucleotide, GAGGC. The second structural effect is a selective distortion of the A/T base pair characterized by a large (0.6 ppm) upfield chemical-shift change of its Watson-Crick proton, while nearby H-bonded protons remain relatively unaffected. The results indicate that T antigen, like many other DNA-binding proteins, may employ "catalytic" or "transition-state-like" interactions in binding its cognate DNA (Jen-Jacobson, L. (1997) Biopolymers 44, 153-180), which may be the solution to the well-known paradox between the relatively modest DNA-binding specificity exhibited by initiator proteins and the high specificity of initiation.     

Identification of the catalytically important histidine of 3-hydroxy-3-methylglutaryl-coenzyme A reductase.

We identify His381 of Pseudomonas mevalonii 3-hydroxy-3-methylglutaryl-coenzyme A (HMG-CoA) reductase as the basic residue functional in catalysis. The catalytic domain of 20 HMG-CoA reductases contains a single conserved histidine (His381 of the P. mevalonii enzyme). Diethyl pyrocarbonate inactivated the P. mevalonii enzyme, and hydroxylamine partially restored activity. We changed His381 to alanine, lysine, asparagine, and glutamine. The mutant proteins were overexpressed, purified to homogeneity, and characterized. His381 mutant enzymes were not inactivated by diethyl pyrocarbonate. All four mutant enzymes exhibited wild-type crystal morphology and chromatographed on substrate affinity supports like wild-type enzyme. The mutant enzymes had low catalytic activity (Vmax 0.06-0.5% that of wild-type enzyme), but Km values approximated those for wild-type enzyme. For wild-type enzyme and mutant enzymes H381A, H381N, and H381Q, Km values at pH 8.1 were 0.45, 0.27, 3.7, and 0.71 mM [(R,S)-mevalonate]; 0.05, 0.03, 0.20, and 0.11 mM [coenzyme A]; 0.22, 0.14, 0.81, and 0.62 mM [NAD+]. Km values at pH 11 for wild-type enzyme and mutant enzyme H381K were 0.32 and 0.75 mM [(R,S)-mevalonate]; 0.24 and 0.50 mM [coenzyme A]; 0.15 and 1.23 mM [NAD+]. Both pK values for the enzyme-substrate complex increased relative to wild-type enzyme (by 1-2.5 pH units for pK1 and by 0.5-1.3 pH units for pK2). For mutant enzyme H381K, the pK1 of 10.2 is consistent with lysine acting as a general base at high pH. His381 of P. mevalonii HMG-CoA reductase, and consequently the histidine of the consensus Leu-Val-Lys-Ser-His-Met-Xaa-Xaa-Asn-Arg-Ser motif of the catalytic domain of eukaryotic HMG-CoA reductases, thus is the general base functional in catalysis.     

Nucleosome cores containing H2B,H3, H4 and HMG2 are reconstituted

Nucleosome cores mixed with the high mobility group proteins, HMG1 and HMG2, in 2 M NaCl, 5 M urea, 0.2 mM EDTA and 10 mM Tris pH 7.0, have been reconstituted by salt gradient dialysis. The reconstituted material, in 10 mM Tris pH 7.0, had a sedimentation peak at the same position as that of control nucleosome cores in sucrose density gradient ultracentrifugation. The SDS polyacrylamide gel electrophoresis of the reconstituted nucleosome cores demonstrated that they contain H2B, H3, H4 and HMG2 and are selectively deficient in H2A. The circular dichroism of DNA of the reconstituted cores was indistinguishable from that of control nucleosome cores. The results suggest that HMG2 replaces H2A as a component of the nucleosome histone core during reconstitution.     

Salt effects on ionization equilibria of histidines in myoglobin

The salt dependence of histidine pK(a) values in sperm whale and horse myoglobin and in histidine-containing peptides was measured by (1)H-NMR spectroscopy. Structure-based pK(a) calculations were performed with continuum methods to test their ability to capture the effects of solution conditions on pK(a) values. The measured pK(a) of most histidines, whether in the protein or in model compounds, increased by 0.3 pH units or more between 0.02 M and 1.5 M NaCl. In myoglobin two histidines (His(48) and His(36)) exhibited a shallower dependence than the average, and one (His(113)) showed a steeper dependence. The (1)H-NMR data suggested that the salt dependence of histidine pK(a) values in the protein was determined primarily by the preferential stabilization of the charged form of histidine with increasing salt concentrations rather than by screening of electrostatic interactions. The magnitude and salt dependence of interactions between ionizable groups were exaggerated in pK(a) calculations with the finite-difference Poisson-Boltzmann method applied to a static structure, even when the protein interior was treated with arbitrarily high dielectric constants. Improvements in continuum methods for calculating salt effects on pK(a) values will require explicit consideration of the salt dependence of model compound pK(a) values used for reference in the calculations.     

Role of electrophilic and general base catalysis in the mechanism of Escherichia coli uracil DNA glycosylase.

Escherichia coli uracil DNA glycosylase (UDG) catalyzes the hydrolysis of premutagenic uracil bases in DNA by flipping the deoxyuridine from the DNA helix [Stivers, J. T., et al. (1999) Biochemistry 38, 952]. A general acid-base mechanism has been proposed whereby His187 facilitates leaving group departure by protonating the O2 of uracil and Asp64 activates a water molecule for nucleophilic attack at C1' of the deoxyribose. Detailed kinetic studies on the H187Q, H187A, and D64N mutant enzymes indicate that Asp64 and His187 stabilize the chemical transition state by 5.3 and 4.8 kcal/mol, respectively, with little effect on substrate or product binding. The pH dependence of k(cat) for wild-type and H187Q UDG indicates that an unprotonated group in the enzyme-substrate complex (pK(a) = 6.2 +/- 0.2) is required for catalysis. This unprotonated group has a small DeltaH of ionization (-0.4 +/- 1.7 kcal/mol) and is absent in the pH profile for D64N UDG, suggesting that it corresponds to the general base Asp64. The pH dependence of k(cat) for wild-type, H187Q, and D64N UDG shows no evidence for an essential protonated group over the pH range of 5.5-10. Hence, the pK(a) of His187 must be outside this pH range if it serves as an electrophilic catalyst. These results support a mechanism in which Asp64 serves as the general base and His187 acts as a neutral electrophile, stabilizing a developing negative charge on uracil O2 in the transition state. In the following paper of this issue we establish by crystallography and heteronuclear NMR spectroscopy that the imidazole of His187 is neutral during the catalytic cycle of UDG.     

Delineation of the high-affinity single-stranded telomeric DNA-binding domain of Saccharomyces cerevisiae Cdc13

Cdc13 is an essential protein from Saccharomyces cerevisiae that caps telomeres by protecting the C-rich telomeric DNA strand from degradation and facilitates telomeric DNA replication by telomerase. In vitro, Cdc13 binds TG-rich single-stranded telomeric DNA with high affinity and specificity. A previously identified domain of Cdc13 encompassing amino acids 451–694 (the 451–694 DBD) retains the single-stranded DNA-binding properties of the full-length protein; however, this domain contains a large unfolded region identified in heteronuclear NMR experiments. Trypsin digestion and MALDI mass spectrometry were used to identify the minimal DNA-binding domain (the 497–694 DBD) necessary and sufficient for full DNA-binding activity. This domain was completely folded, and the N-terminal unfolded region removed was shown to be dispensable for function. Using affinity photocrosslinking to site-specifically modified telomeric single-stranded DNA, the 497–694 DBD was shown to contact the entire 11mer required for high-affinity binding. Intriguingly, both domains bound single-stranded telomeric DNA with much greater affinity than the full-length protein. The full-length protein exhibited the same rate of dissociation as both domains, however, indicating that the full-length protein contains a region that inhibits association with single-stranded telomeric DNA.     

The vnd/NK-2 homeodomain: thermodynamics of reversible unfolding and DNA binding for wild-type and with residue replacements H52R and H52R/T56W in helix III

The conformational stabilities of the vnd (ventral nervous system defective)/NK-2 homeodomain [HD(wt); residues 1-80 that encompass the 60-residue homeodomain] and those harboring mutations in helix III of the DNA recognition site [HD(H52R) and HD(H52R/T56W)] have been investigated by differential scanning calorimetry (DSC) and ellipticity changes at 222 nm. Thermal unfolding reactions at pH 7.4 are reversible and repeatable in the presence of 50-500 mM NaCl with DeltaC(p) = 0.52 +/- 0.04 kcal K(-1) mol(-1). A substantial stabilization of HD(wt) is produced by 50 mM phosphate or by the addition of 100-500 mM NaCl to 50 mM Hepes, pH 7.4, buffer (from T(m) = 35.5 degrees C to T(m) 43-51 degrees C; DeltaH(vH) congruent with 47 +/- 5 kcal mol(-1)). The order of stability is HD(H52R/T56W) > HD(H52R) > HD(wt), irrespective of the anions present. Progress curves for ellipticity changes at 222 nm as a function of increasing temperature are fitted well by a two-state unfolding model, and the cooperativity of secondary structure changes is greater for mutant homeodomains than for HD(wt) and also is increased by adding 100 mM NaCl to Hepes buffer. A 33% quench of the intrinsic tryptophanyl residue fluorescence of HD(wt) by phosphate binding (K(D)' = 2.6 +/- 0.3 mM phosphate) is reversed approximately 60% by DNA binding. Thermodynamic parameters for vnd/NK-2 homeodomain proteins binding sequence-specific 18 bp DNA have been determined by isothermal titration calorimetry (10-30 degrees C). Values of DeltaC(p) are +0.25, -0.17, and -0.10 +/- 0.04 kcal K(-1) mol(-1) for HD(wt), HD(H52R), and HD(H52R/T56W) binding duplex DNA, respectively. Interactions of homeodomains with DNA are enthalpically controlled at 298 K and pH 7.4 with corresponding DeltaH values of -6.6 +/- 0.5, -10.8 +/- 0.1, and -9.0 +/- 0.6 kcal mol(-1) and DeltaG' values of -11.0 +/- 0.1, -11.0 +/- 0.1, and -11.3 +/- 0.3 kcal mol(-1) with a binding stoichiometry of 1.0 +/- 0.1. Thermodynamic parameters for DNA binding are not predicted from homeodomain structural changes that occur upon complexing to DNA and must reflect also solvent and possibly DNA rearrangements.     

Binding of Escherichia coli ribosomal protein S8 to 16S rRNA: kinetic and thermodynamic characterization

A sensitive membrane filter assay has been used to examine the kinetic and equilibrium properties of the interactions between Escherichia coli ribosomal protein S8 and 16S rRNA. In standard conditions (0 degrees C, pH 7.5, 20 mM Mg2+, 0.35 M KCl) the apparent association constant is 5 +/- 0.5 X 10(-7) M-1. The interaction is highly specific, and the kinetics of the reaction are consistent with the apparent association constant. Nevertheless, the rate of association is somewhat slower than that expected for a diffusion-controlled reaction, suggesting some steric constraint. The association is only slightly affected by temperature (delta H = -1.8 kcal/mol). The entropy change [delta S = +29 cal/(mol K)] is clearly the main driving force for the reaction. The salt dependence of Ka reveals that five ions are released upon binding at pH 7.5 and in the presence of 10 mM magnesium. The substitution of various anions for Cl- has an appreciable effect on the magnitude of Ka, following the order CH3COO- greater than Cl- greater than Br-, thus indicating the existence of anion binding site(s) on S8. An equal number of ions were released when Cl- was replaced by CH3COO-, but the absence of anion release upon binding cannot be excluded. On the other hand, the free energy of binding appears not to be exclusively electrostatic in nature. The effect of pH on both temperature and ionic strength dependence of Ka has been examined. It appears that protonation of residue(s) (with pK congruent to 9) increases the affinity via a generalized charge effect. On the other hand, deprotonation of some residue(s) with a pK congruent to 5-6 seems to be required for binding. Furthermore, the unique cysteine present in S8 was shown to be essential for binding.     

Enhancement of oxidative DNA degradation by histidine: the role of stereochemical parameters.

The nicking of supercoiled DNA by H2O2 and ferrous iron has been studied in a variety of environmental conditions. The replicative form of phage fd DNA (fd RF DNA) was used for investigating the phenomenon. The rate of nicking was measured in 10 mM NaCl. The addition of 1 mM Tris-HCl buffer (pH 7.5) slowed down the rate of nicking, the addition of 0.1 mM histidine enhanced it. The simultaneous presence of 1 mM Tris-HCl buffer and of 0.1 mM histidine further enhanced the rate of nicking of fd RF DNA. Increasing the concentration of NaCl dramatically reduced the rate of the reaction. The degradation of fd RF DNA was determined as a function of the concentration of histidine (0-5 mM): the rate increases with concentration, reaches a maximum and then decreases. In the presence of histidine, increasing the concentration of Tris leads to a similar phenomenon. In the absence of histidine, Tris always quenches the degradation of DNA. Electron spin resonance measurements failed to detect an enhancement of the signal characteristic for the hydroxyl radical when histidine was added to the solution containing hydrogen peroxide and ferrous iron. When the nicking of DNA is achieved via the process of auto-oxidation of ferrous iron (i.e., in the absence of added H2O2), histidine only reduces the rate of reaction in a dose-dependent manner, in the explored range of concentrations. In the presence of H2O2 and ferrous iron, histidine enhances the rate of nicking of double-stranded DNA in its supercoiled as well as in its relaxed state, but fails to modify the rate of nicking of fd DNA when it is in its vegetative, single-stranded form.     

Energetics of the equilibrium between two nucleotide-free myosin subfragment 1 states using fluorine-19 nuclear magnetic resonance

A new fluorine-containing reagent has been synthesized and used to specifically label the reactive sulfhydryl [sulfhydryl-1 (SH1)] of myosin subfragment 1 (S-1). The labeled S-1 (S-1-CF3) demonstrates activated calcium and magnesium adenosinetriphosphatase (ATPase) activities relative to S-1 and a lower potassium ethylenediaminetetraacetate (EDTA) ATPase activity. Maximal effect is obtained with the modification of one thiol per S-1. The 19F NMR spectrum of S-1 CF3 contains only one resonance with a line width of 110 Hz, which implies a rotational correlation time of 2.3 X 10(-7) s. The chemical shift of this resonance is sensitive to temperature, PH, ionic strength, and nucleotides bound in the active site. The temperature dependence of the chemical shift clearly indicates two limiting states for the S-1-CF3 with a highly temperature-dependent equilibrium between 5 and 40 degrees C. The low-temperature state appears to be identical with the state resulting from the binding of Mg.ADP or Mg.AMPPNP at 25 degree C. The energetics of the conformational change have been studied under various conditions. At pH 7 in 25 mM cacodylate, 0.1 M KCl, and 1 mM EDTA, delta H degree = 30 kcal/mol and delta S degree = 105 cal deg-1 mol-1. A decrease in pH to 6.5 results in an increased population of the low-temperature state with delta H degree = 31 kcal/mol and delta S degree = 107 cal deg-1 mol-1. Similarly, the low-temperature state is favored by low ionic strength. In 5.8 mM piperazine-N,N'bis(2-ethanesulfonic acid) and 1 mM EDTA (pH 7), delta H degree = 8 kcal/mol and delta S degree = 27 cal deg-1 mol-1. We have also obtained 19F NMR spectra of S-1-CF3 in D2O solution with 30% ethylene glycol at pH 7.1. Increasing concentrations of ethylene glycol progressively stabilize the high-temperature states.     

Reversible modulation of human factor Xa activity with phosphonate esters: media effects

Enantiomers of 4-nitrophenyl 4-X-phenacyl methylphosphonate esters (X = H, PMN; CH3 and CH3O) inactivate human factor Xa with rate constants 8-86 M(-1)s(-1) at pH 6.75 in 0.025 M Hepes buffer, 0.15 M NaCl and 2 mM CaCl2 at 7.0+/-0.1 degrees C. The stereoselectivity of the inactivation of factor Xa is 2-10 and favors the levorotatory enantiomers. The pH-dependence of inactivation of factor Xa by (-)-PMN is sigmoidal and consistent with the participation of a catalytic residue with a pKa of 6.2+/-0.1. Factor Xa reactivates from its phosphonyl adducts through a self-catalyzed intramolecular reaction, which is much influenced by the presence of phospholipids. The rate of reactivation in the absence of phospholipids is not pH dependent at pH <9, but it increases very much at pH >9. In the presence of phospholipids, the pH dependence of the rate constant for reactivation is sigmoidal in the pH 6.5-10.3 range and levels off at pH >9 indicating that the enzyme catalyzes its reactivation. The kinetic pKa for the recovery of factor Xa from its adducts with the PMNs is in the range of 6.7-8.1 and is consistent with the participation of the catalytic His57 in the reactivation process.     

Tautomerism,acid-base equilibria,and H-bonding of the six histidines in subtilisin BPN' by NMR

We have determined by (15)N, (1)H, and (13)C NMR, the chemical behavior of the six histidines in subtilisin BPN' and their PMSF and peptide boronic acid complexes in aqueous solution as a function of pH in the range of from 5 to 11, and have assigned every (15)N, (1)H, C(epsilon 1), and C(delta2) resonance of all His side chains in resting enzyme. Four of the six histidine residues (17, 39, 67, and 226) are neutrally charged and do not titrate. One histidine (238), located on the protein surface, titrates with pK(a) = 7.30 +/- 0.03 at 25 degrees C, having rapid proton exchange, but restricted mobility. The active site histidine (64) in mutant N155A titrates with a pK(a) value of 7.9 +/- 0.3 and sluggish proton exchange behavior, as shown by two-site exchange computer lineshape simulation. His 64 in resting enzyme contains an extremely high C(epsilon 1)-H proton chemical shift of 9.30 parts per million (ppm) owing to a conserved C(epsilon 1)-H(.)O=C H-bond from the active site imidazole to a backbone carbonyl group, which is found in all known serine proteases representing all four superfamilies. Only His 226, and His 64 at high pH, exist as the rare N(delta1)-H tautomer, exhibiting (13)C(delta1) chemical shifts approximately 9 ppm higher than those for N(epsilon 2)-H tautomers. His 64 in the PMSF complex, unlike that in the resting enzyme, is highly mobile in its low pH form, as shown by (15)N-(1)H NOE effects, and titrates with rapid proton exchange kinetics linked to a pK(a) value of 7.47 +/- 0.02.     

Titration of the phase transition of phosphatidylserine bilayer membranes. Effects of pH, surface electrostatics, ion binding, and head-group hydration

The dependence of the gel-to-fluid phase transition temperature of dimyristoyl- and dipalmitoylphosphatidylserine bilayers on pH, NaCl concentration, and degree of hydration has been studied with differential scanning calorimetry and with spin-labels. On protonation of the carboxyl group (pK2app = 5.5), the transition temperature increases from 36 to 44 degrees C in the fully hydrated state of dimyristoylphosphatidylserine (from 54 to 62 degrees C for dipalmitoylphosphatidylserine), at ionic strength J = 0.1. In addition, at least two less hydrated states, differing progressively by 1 H2O/PS, are observed at low pH with transition temperatures of 48 and 52 degrees C for dimyristoyl- and 65 and 68.5 degrees C for dipalmitoylphosphatidylserine. On deprotonation of the amino group (pK3app = 11.55) the transition temperature decreases to approximately 15 degrees C for dimyristoyl- and 32 degrees C for dipalmitoylphosphatidylserine, and a pretransition is observed at approximately 6 degrees C (dimyristoylphosphatidylserine) and 21.5 degrees C (dipalmitoylphosphatidylserine), at J = 0.1. No titration of the transition is observed for the fully hydrated phosphate group down to pH less than or equal to 0.5, but it affinity for water binding decreases steeply at pH greater than or equal to 2.6. Increasing the NaCl concentration from 0.1 to 2.0 M increases the transition temperature of dimyristoyphosphatidylserine by approximately 8 degrees C at pH 7, by approximately 5 degrees at pH 13, and by approximately 0 degrees C at pH 1. These increases are attributed to the screening of the electrostatic titration-induced shifts in transition temperature. On a further increase of the NaCl concentration to 5.5 M, the transition temperature increases by an additional 9 degree C at pH 7, 13 degree C at pH 13, approximately 7 degree C in the fully hydrated state at pH 1, and approximately 4 and approximately 0 degree C in the two less hydrated states. These shifts are attributed to displacement of water of hydration by ion binding. From the salt dependence it is deduced that the transition temperature shift at the carboxyl titration can be accounted for completely by the surface charge and change in hydration of approximately 1 H2O/lipid, whereas that of the amino group titration arises mostly from other sources, probably hydrogen bonding. The shifts in pK (delta pK2 = 2.85, delta pK3 = 1.56) are consistent with a reduced polarity in the head-group region, corresponding to an effective dielectric constant epsilon approximately or equal to 30, together with surface potentials of psi congruent to -100 and -150 mV at the carboxyl and amino group pKs, respectively. The transition temperature of dimyristoylphosphatidylserine-water mixtures decreases by approximately 4 degree C each water/lipid molecule added, reaching a limiting value at a water content of approximately 9-10 H2O/lipid molecule.     

Identification of protein contact sites within the glucocorticoid/progestin response element

The glucocorticoid receptor (GR) and the progestin receptor (PR) bind specifically to a variety of DNA sequences, glucocorticoid/progestin response elements (GRE/PRE), located in the proximity of responsive gene promoters. Using the isolated recombinant GR DNA-binding domain (DBD), it has recently been shown that GR interacts with the GRE/PRE, a 15-basepair partially palindromic consensus sequence, as a dimer. In this study an investigation into the GR-GRE/PRE and PR-GRE/PRE interaction has been performed using missing base contact analysis with the tyrosine aminotransferase GREII (TATII) and recombinant GR DBD as well as a fusion protein consisting of the PR DBD fused to Staph. aureus protein-A. GR and PR had identical base contact points, localized within two consecutive major grooves, binding to the same face of the DNA. Ethylation interference was also performed on the GR DBD-TATII interaction. The contact points with the backbone phosphate groups flank the contacts within the major groove for each of the two half-sites. Knowledge of the contact points within the DNA sequence together with the three-dimensional structure of the protein enables modelling of the protein-DNA interaction.     

Complex formation between the adenovirus DNA-binding protein and single-stranded poly(rA). Cooperativity and salt dependence

The complex formed between adenovirus DNA-binding protein (AdDBP) and poly(rA) was investigated with circular dichroism spectroscopy. The binding process was studied at a variety of salt concentrations, and the titration curves were analyzed according to the contiguous cooperative binding model given by McGhee and von Hippel [McGhee, J.D., & von Hippel, P.H. (1974) J. Mol. Biol. 86, 469-489]. The cooperativity factor omega of the binding process is low (omega approximately 20-30) and independent of the salt concentration. This in contrast to the binding constant K for which a moderately strong salt dependence is observed: delta log (K omega)/delta log [NaCl] = -3.1. The size of the binding site was consistently calculated to be about 13. We also studied the C-terminal 39-kDa fragment which is sufficient for DNA replication in vitro. Complex formation between this fragment of AdDBP and poly(rA) appeared to be characterized by spectroscopic and binding properties similar to those of the intact protein. Only, the binding constant in 50 mM NaCl is a factor of 5 lower.     

Backbone dynamics of the glucocorticoid receptor DNA-binding domain.

The extent of rapid (picosecond) backbone motions within the glucocorticoid receptor DNA-binding domain (GR DBD) has been investigated using proton-detected heteronuclear NMR spectroscopy on uniformly 15N-labeled protein fragments containing the GR DBD. Sequence-specific 15N resonance assignments, based on two- and three-dimensional heteronuclear NMR spectra, are reported for 65 of 69 backbone amides within the segment C440-A509 of the rat GR in a protein fragment containing a total of 82 residues (MW = 9200). Individual backbone 15N spin-lattice relaxation times (T1), rotating-frame spin-lattice relaxation times (T1 rho), and steady-state (1H)-15N nuclear Overhauser effects (NOEs) have been measured at 11.74 T for a majority of the backbone amide nitrogens within the segment C440-N506. T1 relaxation times and NOEs are interpreted in terms of a generalized order parameter (S2) and an effective correlation time (tau e) characterizing internal motions in each backbone amide using an optimized value for the correlation time for isotropic rotational motions of the protein (tau R = 6.3 ns). Average S2 order parameters are found to be similar (approximately 0.86 +/- 0.07) for various functional domains of the DBD. Qualitative inspection as well as quantitative analysis of the relaxation and NOE data suggests that the picosecond flexibility of the DBD backbone is limited and uniform over the entire protein, with the possible exception of residues S448-H451 of the first zinc domain and a few residues for which relaxation and NOE parameters were not obtained. in particular, we find no evidence for extensive rapid backbone motions within the second zinc domain. Our results therefore suggest that the second zinc domain is not disordered in the uncomplexed state of DBD, although the possibility of slowly exchanging (ordered) conformational states cannot be excluded in the present analysis.     

Complement C4bC2 complex formation: an investigation by surface plasmon resonance

Complex formation between the human complement proteins C4b and C2 was investigated by surface plasmon resonance. C4b was immobilised and C2 was used in the fluid phase to measure interaction at different ionic strengths (30-830 mM NaCl) and in the absence and presence of MgCl2. Maximum binding was observed at 30 mM NaCl, and was negligible above 300 mM NaCl. Binding was not greatly influenced by variation in Mg(2+) in the range of 2.5-15 mM. C4bC2 affinity (Kd) was determined by steady-state analysis to be 7.2x10(-8) M in physiological conditions (10 mM Hepes, 2.5 mM MgCl2, 0.75 mM CaCl2 and 140 mM NaCl, pH 7.4). For C4(H2O)C2 complex formation, a Kd of 4.0x10(-8) M was calculated. As far as detected by the applied method, complex formation does not involve conformational changes of one of the binding partners. Consistent with previous reports, C4bC2 binding takes place as a multiple-site binding event in the presence of Mg2+. C4bC2 complex formation in 10 mM Hepes, 2.5 mM EDTA and 140 mM NaCl (pH 7.4) was also observed and the interaction showed characteristics of a single-site binding event. Kd was 1.5x10(-8) M. Complement factor B (FB) was also tested for its binding to immobilised C4b. Weak interaction was observed at FB concentrations in the physiological range (500-1000 nM). Kd was 1.2x10(-6) M, indicating possible cross-reactivity between classical and alternative pathways of the activation of the complement system.     

pK values of histidine residues in ribonuclease Sa: effect of salt and net charge

The primary goal of this study was to gain a better understanding of the effect of environment and ionic strength on the pK values of histidine residues in proteins. The salt-dependence of pK values for two histidine residues in ribonuclease Sa (RNase Sa) (pI=3.5) and a variant in which five acidic amino acids have been changed to lysine (5K) (pI=10.2) was measured and compared to pK values of model histidine-containing peptides. The pK of His53 is elevated by two pH units (pK=8.61) in RNase Sa and by nearly one pH unit (pK=7.39) in 5K at low salt relative to the pK of histidine in the model peptides (pK=6.6). The pK for His53 remains elevated in 1.5M NaCl (pK=7.89). The elevated pK for His53 is a result of screenable electrostatic interactions, particularly with Glu74, and a non-screenable hydrogen bond interaction with water. The pK of His85 in RNase Sa and 5K is slightly below the model pK at low salt and merges with this value at 1.5M NaCl. The pK of His85 reflects mainly effects of long-range Coulombic interactions that are screenable by salt. The tautomeric states of the neutral histidine residues are changed by charge reversal. The histidine pK values in RNase Sa are always higher than the pK values in the 5K variant. These results emphasize that the net charge of the protein influences the pK values of the histidine residues. Structure-based pK calculations capture the salt-dependence relatively well but are unable to predict absolute histidine pK values.