Conformation of the synthetic DNA poly(amino2dA-dT) duplex in high-salt and aqueous alcohol solutions.

It has previously been demonstrated by other workers that the duplex of a synthetic DNA poly(amino2dA-dT) undergoes a salt-induced conformational isomerization. We show in the present work using circular dichroism that the same isomerization is induced in poly(amino2dA-dT) by various alcohols. The isomerization was originally identified as the B-to-Z and then B-to-A conformational transition of DNA but we demonstrate that the high-salt or alcohol conformation of poly (amino2dA-dT) is the non Z-DNA zig-zag double helix we have previously observed with poly(dA-dT) and called X-DNA. X-DNA is a cesium cation specific conformation of poly(dA-dT) while no similar cation specificity is observed with poly(amino2dA-dT). Thus it appears that the extra amino group attached to A and cesium cations make the same thing; they probably dehydrate the double helix minor groove and relieve its conformational variability. Poly(amino2dA-dT) is exceptionally stable in X-DNA and conditions inducing it are mild, which opens the door to assess its molecular structure.     

Molecular-dynamics simulations of [Met5]- and [D-Ala2,Met5]-enkephalins. Biological implication of monomeric folded and dimeric unfolded conformations.

To investigate the biologically active conformation of enkephalin, molecular-dynamics simulations were applied to [Met5]- and [D-Ala2,Met5]-enkephalins. The dynamic trajectory of monomeric extended [Met5]-enkephalin was analysed in terms of relative mobility between respective torsions of backbone chain. After 10 ps of the dynamics simulation, the conformational transition was converged into a stationary state among the beta-bend folded forms, where they are stabilized by several intramolecular hydrogen-bond formations. Similar conformational transition was also observed in the dynamics simulation of [D-Ala2,Met5]enkephalin, which is a more mu-receptor-specific peptide than [Met5]enkephalin. The geometrical correspondence between the monomeric enkephalin conformation in the stationary state and morphine molecule (a mu-specific rigid opiate) was surveyed by virtue of the triangular substructures generated by choosing three functional atoms in each molecule, and good resemblances were observed. On the other hand, the dynamics simulation of the antiparallel extended [Met5]enkephalin dimer showed a trajectory different from that of the monomeric one. Two intermolecular hydrogen bonds at Tyr1 (NH3+)...Met5(CO2-) end residues were held throughout the 100 ps simulation, the dimeric structure being consequently kept. The conformational transition of the backbone chains from the antiparallel extended form to the twisted one took place via an intermediate state. Many conformations revealed during the dynamics simulation showed that the relative orientations of each two Tyr1, Gly3, Phe4 and Met5 residues in the dimer are nearly related by a pseudo-C2-symmetry respectively, and both halves of the dimer structure could be further fitted to the monomeric folded enkephalin conformation. The monomeric and dimeric conformations of enkephalin at their stationary states are discussed in relation to the substrate-specificity for mu- and delta-opioid receptors.     

Loop-driven conformational transition between the alternative and collapsed form of prethrombin-2: targeted molecular dynamics study

Two distinct crystal structures of prethrombin-2, the alternative and collapsed forms, are elucidated by X-ray crystallogrphy. We analyzed the conformational transition from the alternative to the collapsed form employing targeted molecular dynamics (TMD) simulation. Despite small RMSD difference in the two X-ray crystal structures, some hydrophobic residues (W60d, W148, W215, and F227) show a significant difference between the two conformations. TMD simulation shows that the four hydrophobic residues undergo concerted movement from dimer to trimer transition via tetramer state in the conformational change from the alternative to the collapsed form. We reveal that the concerted movement of the four hydrophobic residues is controlled by movement of specific loop regions behind. In this paper, we propose a sequential scenario for the conformational transition from the alternative form to the collapsed form, which is partially supported by the mutant W148A simulation.     

Adsorption of polypeptides on a solid surface. IV. Adsorption and β-structure–coil transition

A theory of adsorption of a polypetide chain capable of undergoing the coil–β-structure transition on a solid planar surface has been developed. The mutual influence of two order–disorder phase transitions, a conformational and an adsorption transition, was investigated. Various types of adsorption transitions are possible, depending on the initial conformational state (partly or completely β-structured) and the selectivity of adsorption: (a) the second-order phase transition, in which the chain is partly structured, both in adsorbed and desorbed states; and (b) the first-order phase transition, in which the chain exhibits a regular β-structure, at least on one side of the adsorption transition boundary. The chain bonding to the surface alters the degree of β-structure, both in the case of selective and nonselective adsorption (similar to the adsorption of the chains with other types of secondary structure). We show that the slope of the adsorption curves for partly β-structural chains increases as a result of an increase in the degree of β-structuring, and this effect is even stronger than the analogous effect of β-structuring.     

Differential scanning calorimetry of alpha 2-macroglobulin and alpha 2-macroglobulin-proteinase complexes.

Differential scanning calorimetry is shown to detect substantial structural alterations occurring on the association of proteinases with the serum glycoprotein alpha 2-macroglobulin. At pH 7.5, the thermally induced unfolding of the macroglobulin occurs at approx. 60 degrees C with a transition enthalpy of 17 J/g. Association of active thermolysin, trypsin and papain shifts the transition temperature to 77 degrees C (transition enthalpy 5 J/g), indicating that a substantial conformational change accompanies the binding event. The stoicheiometry of the thermolysin--alpha 2-macroglobulin association producing this change appears to be unity, implying the presence of co-operative subunit interactions in the mechanism of association. The calorimetric method provides a novel approach for the evaluation of conformational variants induced on protein-protein association or pre-existing in the purified macroglobulin.     

Synthesis and physical characterization of DNA fragments containing N4-methylcytosine and 5-methylcytosine.

The synthesis of N4-methyl-2'-deoxycytidine and its fully protected mononucleotide, suitable for the oligonucleotide synthesis by phosphotriester method is described. A set of octanucleotides - d(CGCGCGCG), d(CG5mCGCGCG), d(CG4mCGCGCG) and dodecanucleotides - d(GGACCCGGGTCC), d(GGA5mCCCGGGTCC), d(GGA4mCCCGGGTCC) has been synthesized in a solution. Physical characterization of the oligonucleotide duplexes by means of UV and CD spectrometry provides the evidence that 4mC similarly to 5mC favours the B--greater than Z transition, although both of these methylated cytosines inhibit the B--greater than A conformational change. N4-Methylcytosine in contrast to 5-methylcytosine reduces the DNA double helix thermal stability.     

Conformational fluctuations of the Ca2+-ATPase in the native membrane environment. Effects of pH, temperature, catalytic substrates, and thapsigargin

Digestion with proteinase K or trypsin yields complementary information on conformational transitions of the Ca(2+)-ATPase (SERCA) in the native membrane environment. Distinct digestion patterns are obtained with proteinase K, revealing interconversion of E1 and E2 or E1 approximately P and E2-P states. The pH dependence of digestion patterns shows that, in the presence of Mg(2+), conversion of E2 to E1 pattern occurs (even when Ca(2+) is absent) as H(+) dissociates from acidic residues. Mutational analysis demonstrates that the Glu(309) and Glu(771) acidic residues (empty Ca(2+)-binding sites I and II) are required for stabilization of E2. Glu(309) ionization is most important to yield E1. However, a further transition produced by Ca(2+) binding to E1 (i.e. E1.2Ca(2+)) is still needed for catalytic activation. Following ATP utilization, H(+)/Ca(2+) exchange is involved in the transition from the E1 approximately P.2Ca(2+) to the E2-P pattern, whereby alkaline pH will limit this conformational transition. Complementary experiments on digestion with trypsin exhibit high temperature dependence, indicating that, in the E1 and E2 ground states, the ATPase conformation undergoes strong fluctuations related to internal protein dynamics. The fluctuations are tightly constrained by ATP binding and phosphoenzyme formation, and this constraint must be overcome by thermal activation and substrate-free energy to allow enzyme turnover. In fact, a substantial portion of ATP free energy is utilized for conformational work related to the E1 approximately P.2Ca(2+) to E2-P transition, thereby disrupting high affinity binding and allowing luminal diffusion of Ca(2+). The E2 state and luminal path closure follow removal of conformational constraint by phosphate.     

The effect of the L-azetidine-2-carboxylic acid residue on protein conformation. II. Homopolymers and copolymers

The alteration of polymer conformational properties caused by the replacement of L-proline by L-azetidine-2-carboxylic acid (Aze) has been studied by means of conformational energy computations. In addition to poly(Aze), two sequential copolymers, poly(Pro-Aze) and poly(Aze3-Pro3), have been investigated. All polymers containing Aze are more flexible than poly(Pro). This is a consequence of an increased number of permitted conformational states for the Aze residue, as compared to Pro, when they are incorporated into a polypeptide, as well as of a lessened cooperativity of the trans-cis transition. The results of the computation can be used to interpret the observed physical properties of poly(Aze) and of its copolymers.     

Right- and left-handed (Z) helical conformations of the hairpin d(C-G)5T4(C-G)5 monomer and dimer

The partial self-complementary 24-mer oligodeoxynucleotide d(C-G)5T4(C-G)5 forms a hairpin which can be enzymatically dimerized to a dumbbell structure. The blunt-ended nature of the hairpin is indicated by its ability to inhibit the T4 DNA ligase catalyzed joining of phi X174 HaeIII fragments. The hairpin monomer and dimer (dumbbell) undergo a reversible B to Z transition as shown by ultraviolet, circular dichroism, and 31P NMR spectroscopy. The Z form of the hairpin monomer and dimer is supported by monovalent ions (Na+), divalent ions (Mg2+ but not Mn2+), and dehydrating (ethanol) conditions. The conformational transition of d(C-G)5T4(C-G)5 monomer requires higher ionic or dehydrating conditions than those necessary for the corresponding linear oligomer d(C-G)5. The contribution of the loop (-T4-) of the hairpin to the apparent free energy change for the B to Z conformational transition at the midpoint was calculated to be 3.8 kJ mol-1.     

Mn2+ and other transition metals at low concentration induce the right-to-left helical transformation of poly[d(G-C)].

The effects of the first-row transition metal ions on the right(B)- to left(Z)-handed helical transition of poly[d(G-C)] have been determined. The Z conformation is induced by MnCl2 at submillimolar concentrations. The forward reaction has a very large activation energy (440 kJ/mol) so that a facile conversion occurs only at temperatures above 45 degrees C. However, the left-handed form remains stable upon cooling. The addition of ethanol (20% v/v) eliminates the requirement for elevated temperature. The transition is highly co-operative and is accompanied by spectral changes (absorption, circular dichroism) characteristic for the B----Z conformational transition. NiCl2 and CoCl2 also induce the B----Z transition in poly[d(G-C)] but the activation energies and thus the temperature requirements for the forward reaction are lower than those observed with MnCl2. The left-handed DNA formed in the presence of Mn2+ is similar to 'Z DNA' previously described in Mg2+-EtOH (van de Sande and Jovin , 1982): (a) it readily sediments out of solution at low speed as a consequence of intermolecular association which, however, is not accompanied by turbidity; and (b) it supports the binding of ethidium bromide although this drug interacts preferentially with the B form of DNA. With Ni2+, the B----Z isomerization step can be separated from the subsequent specific Z----Z* association. Mn2+, Ni2+, and Co2+ also promote the B----Z transition of poly[d(G-m5C)] at substoichiometric concentrations with respect to DNA nucleotide.     

Electron paramagnetic resonance of Cu2+:Mb single crystal. Conformational changes.

Copper introduced into met-myoglobin crystals occupies various sites as indicated by electron paramagnetic resonance parameters. Cu2+ (A) is probably liganded to histidine A10, lysine A14, and asparagine GH4 (Banaszak et al., 1965) and shows superhyperfine interaction with a single (imidazole) nitrogen. Cu2+ (B) and Cu2+ (C) correspond to other anisotropic sites described in less detail. Cu2+ (A) exhibits a transition to an isotropic form with a transition temperature of 40.5 degrees C. This transition indicates a conformational change in myoglobin and could correspond to a motion of A helix away from the GH section. The transition temperature is 7 degrees C higher than the one previously reported (Atanasov, 1971) for myoglobin in solution.     

Effect of methylamine and plasmin on the conformation of human alpha 2-macroglobulin as revealed by differential scanning calorimetric analysis.

Differential scanning calorimetric analysis was used as a probe of the conformational alteration in human alpha 2-macroglobulin (AM) upon its complex formation with methylamine and with the protease, human plasmin. The slow electrophoretic form of AM displayed a single thermal transition, characterized by a temperature midpoint (Tm) of 65.8 +/- 0.3 degrees, a calorimetric enthalpy (delta Hc) of 2,550 +/- 150 kcal/mol and a van't Hoff enthalpy (delta Hvh) of 140 kcal/mol. In the presence of sufficient methylamine to irreversibly disrupt the four thiol ester bonds in AM, a single thermal transition was obtained, characterized by a Tm of 62.8 +/- 0.3 degrees, a delta Hc of 1,700 +/- 100 kcal/mol, and a delta Hvh of 169 kcal/mol. These data suggest that a major conformational alteration is produced in AM upon complex formation with methylamine. When plasmin interacts with AM, the resulting thermogram displays Tm values for AM of 68-69 degrees and 77 degrees, also suggestive of a large conformational alteration in AM. However, this latter alteration appears dissimilar to the change induced by methylamine.     

BI-BII transitions in B-DNA.

Molecular modelling is used to study the conformational and energetic aspects of BI-BII transitions within the backbone of a B-DNA dodecamer d(CATGACGTCATG) whose fine structure has previously been determined by molecular modelling combined with NMR spectroscopy. It is shown that while the dodecamer under investigation does not contain any BII junctions, the central CpG step can most easily undergo the transition. More generally, it is also found that the base sequence and hence the backbone geometry of a DNA segment, strongly influences both the conformational impact of the transition, the associated energy barrier and the stability of the resulting BII state.     

Energetics of Z-DNA formation in poly d(A-T), poly d(G-C), and poly d(A-C) poly d(G-T).

The conformational change for the alternating purine-pyrimidine polydeoxyribonucleotides i.e. poly d(A-T), poly d(G-C), and poly d(A-C) poly d(G-T) from a right-handed conformation at room temperature to the left-handed Z-DNA like double helix at elevated temperatures has been studied by UV spectroscopy, Raman spectroscopy, and by adiabatic differential scanning microcalorimetry (DSC) in the presence of Na+ and Mg2+ or Ni2+ respectively as counterions. The differential UV spectra reveal through a hyperchromic shift at around 280nm and a hypochromic shift at 260nm that a conformational change to the left-handed conformation occurs. The Raman spectra clearly show characteristic changes, a drastic decrease of the band at 680cm-1 and the appearance of a new band at 628cm-1, due to the change of the purine bases to the syn conformation upon inversion of the helix-handedness. The course of the transition as function of temperature can be followed quantitatively by plotting the change in the excess heat capacity vs. temperature. The transition enthalpy delta H for the B- to Z-DNA transition per mole base pairs (mbp) amounts to 2.0 +/- 0.2kcal for poly d(G-C), to 4.0 +/- 0.4kcal for poly d(A-T), and to 3.1 +/- 0.3kcal for poly d(A-C) poly d(G-T). The enthalpy change due to the Z-DNA to coil transitions (per mole base pairs) amounts to 11kcal for poly d(G-C), 10.5kcal for poly d(A-T) and 11.3kcal for poly d(A-C) poly d(G-T).     

Interplay between structural rigidity and electrostatic interactions in the ligand binding domain of GluR2

Using molecular dynamics (MD) simulations, computational protein modifications, and a novel theoretical methodology that determines structural rigidity/flexibility (the FIRST algorithm), we investigate how molecular structure and dynamics of the glutamate receptor ligand binding domain (GluR2 S1S2) facilitate its conformational transition. S1S2 is a two-lobe protein, which undergoes a cleft closure conformational transition upon binding an agonist in the cleft between the two lobes; hence it is expected that the mechanism of this conformational transition can be characterized as a hinge-type. However, in the rigidity analysis one lobe of the protein is identified as a single rigid cluster while the other one is structurally flexible, inconsistent with a presumed mechanical hinge mechanism. Instead, we characterize the cleft-closing transition as a load and lock mechanism. We find that when two cross-cleft hydrogen bonds are disrupted the protein undergoes a rapid cleft opening transition. At the same time, the dynamical behavior of the cleft in the presence of the glutamate ligand is only weakly affected by the S652 peptide bond in its flipped conformation observed in the crystal structure. The residue E705 plays significant role in stabilization of the closed conformation via electrostatic interactions. The presence of the E705-K730 salt bridge seems to correlate strongly withthe cleft opening transition in the MD simulations.     

Multistep binding of transition metals to the H-N-H endonuclease toxin colicin E9

We report the first stopped-flow fluorescence analysis of transition metal binding (Co(2+), Ni(2+), Cu(2+), and Zn(2+)) to the H-N-H endonuclease motif within colicin E9 (the E9 DNase). The H-N-H consensus forms the active site core of a number of endonuclease groups but is also structurally homologous to the so-called treble-clef motif, a ubiquitous zinc-binding motif found in a wide variety of metalloproteins. We find that all the transition metal ions tested bind via multistep mechanisms. Binding was further dissected for Ni(2+) and Zn(2+) ions through the use of E9 DNase single tryptophan mutants, which demonstrated that most steps reflect conformational rearrangements that occur after the bimolecular collision, many common to the two metals, while one appears specific to zinc. The kinetically derived equilibrium dissociation constants (K(d)) for transition metal binding to the E9 DNase agree with previously determined equilibrium measurements and so confirm the validity of the derived kinetic mechanisms. Zn(2+) binds tightest to the enzyme (K(d) approximately 10(-)(9) M) but does not support endonuclease activity, whereas the other metals (K(d) approximately 10(-)(6) M) are active in endonuclease assays implying that the additional step seen for Zn(2+) traps the enzyme in an inactive but high affinity state. Metal-induced conformational changes are likely to be a conserved feature of H-N-H/treble clef motif proteins since similar Zn(2+)-induced, multistep binding was observed for other colicin DNases. Moreover, they appear to be independent both of the conformational heterogeneity that is naturally present within the E9 DNase at equilibrium, as well as the conformational changes that accompany the binding of its cognate inhibitor protein Im9.     

Correlation proton magnetic resonance studies at 250 MHz of bovine pancreatic ribonuclease. II. pH and inhibitor-induced conformational transitions affecting histidine-48 and one tyrosine residue of ribonuclease A.

The microenvironment of histidine-48 of bovine pancreatic ribonuclease A was investigated by proton magnetic resonance spectroscopy (1H NMR) using partially deuterated enzyme in which resolution of the C(2)-H resonance of histidine-48 was simplified. The NMR titration curves at 100 and 250 MHz of histidine-48 of ribonuclease A are discontinuous both for the enzyme alone in 0.3 M chloride and for its complex with cytidine 3'-phosphate. This suggests that titration of histidine-48 occurs only as the result of a slow conformational transition. The sum of the peaks corresponding to histidine-48 in the acid-stable and base-stable forms of the enzyme is less than one proton in the transition region, which indicates that there exists at least one intermediate conformational form of the enzyme. The transition from the acid-stable form to an intermediate form has a pHmid of 5.6, and the transition from an intermediate form to the base-stable form has a pHmid of 6.9. In ribonuclease S and in ribonuclease A in the presence of 0.3 M acetate, the titration curve of histidine-48 is continuous, and the area of the peak is uniform throughout the titration. Proton NMR difference spectra at 100 and 250 MHz reveal a pH-induced conformational change with a pHmid of 5.7 that affects the chemical shift of a single tyrosine residue. This conformational transition is absent in ribonuclease S and is altered in ribonuclease A by the presence of either acetate or cytidine 3'-monophosphate. It is postulated that the same conformational transition is responsible for both the tyrosine perturbation and the disappearance of the histidine-48 peak observed in the acid-stable form of the enzyme. It is proposed that the perturbed tyrosine is tyrosine-25. The transition with pHmid 5.6 is attributed to dissociation of aspartic acid-14, and the transition with pHmid 6.9 is assigned to dissociation of histidine-48. A peak in the aromatic region that moves upfield on addition of the competitive inhibitor cytidine 3'-monophosphate is assigned to a tyrosine, and evidence is presented that this tyrosine is tyrosine-25. Inhibitor binding appears to induce a conformational change in the histidine-48/tyrosine-25 region which is remote from the active site.     

ATP-induced conformational transition of denatured proteins.

Although the conformational change occurring in proteins upon ATP binding is important in many biological reactions, the mechanism by which ATP binding induces the conformational change is unknown. We found that ATP induces acid-unfolded (pH 2) ferricytochrome c or apomyoglobin to adopt a compact structure with a significant amount of alpha-helix and increased hydrophobicity. A very similar conformational transition was observed at neutral pH for an amphiphilic model polypeptide. The effectiveness of various adenine nucleotides in inducing the conformational transition was found to be proportional to their phosphate group contents, i.e., adenosine tetraphosphate greater than ATP greater than ADP greater than AMP. These results should be important when considering the mechanism of the ATP-induced conformational change in proteins during various biological reactions.     

Role of the N-terminal region for the conformational stability of esterase 2 from Alicyclobacillus acidocaldarius

In order to clarify the role played by the N-terminal region for the conformational stability of the thermophilic esterase 2 (EST2) from Alicyclobacillus acidocaldarius, two mutant forms have been investigated: a variant obtained by deleting the first 35 residues at the N-terminus (EST2-36del), and a variant obtained by mutating Lys102 to Gln (K102Q) to perturb the N-terminus by destroying the salt bridge E43-K102. The temperature- and denaturant-induced unfolding of EST2 and the two mutant forms have been studied by means of circular dichroism (CD), differential scanning calorimetry (DSC) and fluorescence measurements. In line with its thermophilic origin, the denaturation temperature of EST2 is high: T(d)=91 degrees C and 86 degrees C if detected by recording the CD signal at 222 nm and 290 nm, respectively. This difference suggests that the thermal denaturation process, even though reversible, is more complex than a two-state Nright arrow over left arrowD transition. The non-two-state behaviour is more pronounced in the case of the two mutant forms. The complex DSC profiles of EST2 and both mutant forms have been analysed by means of a deconvolution procedure. The thermodynamic parameters characterizing the two transitions obtained in the case of EST2 are: T(d,1)=81 degrees C, Delta(d)H(1)=440 kJ mol(-1), Delta(d)C(p,1)=7 kJ K(-1)mol(-1), T(d,2)=86 degrees C, Delta(d)H(2)=710 kJ mol(-1), and Delta(d)C(p,2)=9 kJ K(-1)mol(-1). The first transition occurs at lower temperatures in the two mutant forms, whereas the second transition is always centred at 86 degrees C. The results indicate that EST2 possesses two structural domains whose coupling is tight in the wild-type protein, but markedly weakens in the two mutant forms as a consequence of the perturbations in the N-terminal region.     

Lysines in the amino-terminal alpha-helix are important to the stability of Rhodobacter capsulatus cytochrome c2.

The protein stabilities of wild type and four site-directed mutants of Rhodobacter capsulatus cytochrome c2 have been characterized. The integrity of the cytochrome c2 iron-sulfur environment was ascertained by titration of the 696-nm absorbance band with alkali, and the conformational stability was determined by titration of the 220-nm circular dichroism signal with Gdn-HCl. Analysis of the alkaline transition pK value of K12D (lysine-12 substituted by aspartate) indicated that the K12D iron-sulfur environment was destabilized by 0.6 kcal/mol relative to the wild-type cytochrome c2 at low ionic strength. In contrast, the alkaline transition pK values of K14E (lysine-14 substituted by glutamate), K32E (lysine-32 substituted by glutamate), and K14E/K32E (lysines-14 and -32 substituted by glutamates) were indistinguishable from the wild type, indicating that these substitutions have no effect on the stability of the iron-sulfur environment. Gdn-HCl denaturation of K12D and K14E indicated that both these mutations decreased conformational stability by 1.3 kcal/mol. In contrast, mutant K32E exhibited a small stabilizing effect of 0.2 kcal/mol. Gdn-HCl denaturation of K14E/K32E indicated that this mutation decreased conformational stability by 1.3 kcal/mol, which is consistent with the additive effects of the single charge mutations at positions 14 and 32. The conformational instability of mutants possessing negative charges at position 12 or 14 is best explained by their positioning at the carboxy-terminal region of the amino-terminal alpha-helix of R. capsulatus cytochrome c2. Accordingly, introduction of negatively charged groups into this region appears to destabilize cytochrome c2 through energetically unfavorable interactions with the dipole of the amino-terminal helix.(ABSTRACT TRUNCATED AT 250 WORDS)