1H NMR studies on bovine cyclophilin: preliminary structural characterization of its complex with cyclosporin A

Cyclophilin (163 residues, Mr 17737), a peptidyl prolyl cis-trans isomerase, is a cytosolic protein that specifically binds the potent immunosuppressant cyclosporin A (CsA). The native form of the major bovine thymus isoform has been analyzed by 2D NMR methods, COSY, HOHAHA, and NOESY, in aqueous media. The 156 main-chain amides in CyP yield 126 observable NH/alpha CH couplings (81%, Gly pairs counted as 1). Following exhaustive D2O exchange, 44 amide resonances remain visible. Further analysis of the NH/NH, NH/alpha CH, and alpha CH/alpha CH regions of the COSY and NOESY data sets indicates that the residual amides in D2O form a coherent hydrophobic domain which yields 2D NMR features suggestive of a beta-sheet. Many (43/126) of the amide resonances have been classified according to amino acid type. In the aromatic region of the spectra, the assignment of the ring spin systems is nearly complete (12/15 Phe, 2/2 Tyr, 1/1 Trp, and 3/4 His). This has successfully lead to the complete assignment of all of their beta CH's, main-chain alpha CH resonances, and many of the backbone amide resonances (8/12 Phe, 2/2 Tyr, 1/1 Trp, and 2/3 His). In other regions of the spectrum, the side-chain and main-chain resonances for 10/23 Gly, 9/9 Ala, 5/11 Thr, 5/9 Val, and 1/6 Leu have been completely assigned. The drug-free cyclophilin and CsA-bound cyclophilin form two discrete protein structures that are in slow exchange on the NMR time scale. Comparison of the fingerprint regions from the COSY spectra obtained from the two forms of the protein reveals a minimum of 16 cross-peaks which are clearly shifted upon complexation. In fact, on the basis of chemical shift changes observed in assigned side-chain and main-chain resonances, only a relatively few of the amino acid residues identified to date are perturbed by complex formation. These include 3 Phe (8, 12, and 14) and the Trp in the aromatic region and 2 Ala (7 and 8) in the Ala/Thr region. In the upfield-shifted methyl region, an assigned Leu and Val spin system and a spin system labeled X10 (an Ile or Leu) are affected by complex formation. In addition, a new aliphatic spin system, labeled X11, which shows a close spatial relationship to the perturbed Phe12, is observed in this region of the spectrum. In summary, the regions of the protein altered by complex formation can be divided into two categories: a hydrophobic and a H2O-accessible domain.(ABSTRACT TRUNCATED AT 400 WORDS)     

1H, 13C and 15N backbone assignments of cyclophilin when bound to cyclosporin A (CsA) and preliminary structural characterization of the CsA binding site.

The backbone 1H, 13C and 15N chemical shifts of cyclophilin (CyP) when bound to cyclosporin A (CsA) have been assigned from heteronuclear two- and three-dimensional NMR experiments involving selectively 15N- and uniformly 15N- and 15N,13C-labeled cyclophilin. From an analysis of the 1H and 15N chemical shifts of CyP that change upon binding to CsA and from CyP/CsA NOEs, we have determined the regions of cyclophilin involved in binding to CsA.     

NMR studies of [U-13C]cyclosporin A bound to cyclophilin: bound conformation and portions of cyclosporin involved in binding

Cyclosporin A (CsA), a potent immunosuppressant, is known to bind with high specificity to cyclophilin (CyP), a 17.7 kDa protein with peptidyl-prolyl isomerase activity. In order to investigate the three-dimensional structure of the CsA/CyP complex, we have applied a variety of multidimensional NMR methods in the study of uniformly 13C-labeled CsA bound to cyclophilin. The 1H and 13C NMR signals of cyclosporin A in the bound state have been assigned, and from a quantitative interpretation of the 3D NOE data, the bound conformation of CsA has been determined. Three-dimensional structures of CsA calculated from the NOE data by using a distance geometry/simulated appealing protocol were found to be very different from previously determined crystalline and solution conformations of uncomplexed CsA. In addition, from CsA/CyP NOEs, the portions of CsA that interact with cyclophilin were identified. For the most part, those CsA residues with NOEs to cyclophilin were the same residues important for cyclophilin binding and immunosuppressive activity as determined from structure/activity relationships. The structural information derived in this study together with the known structure/activity relationships for CsA analogues may prove useful in the design of improved immunosuppressants. Moreover, the approach that is described for obtaining the structural information is widely applicable to the study of small molecule/large molecule interactions.     

NMR studies of [U-C]cyclosporin A bound to human cyclophilin B

NMR data (¹H and ¹³C chemical shifts, NOEs) on [[U-¹³C]cyclosporin A bound to cyclophilin B were compared to previously published data on the [U-¹³C]CsA/CyPA complex [Fesik et al., (1991) Biochemistry 30, 6574–6583]. Despite only 64% sequence identity between CyPA and CyPB, the conformation and active site environment of CsA when bound to CyPA and CyPB are nearly identical as judged by the similarity of the NMR data.     

Sequence-specific 1H NMR assignments and structural characterization of bovine seminal fluid protein PDC-109 domain b

Sequence-specific resonance assignments for the isolated second or b domain of the bovine seminal fluid protein PDC-109 have been obtained from analysis of two-dimensional 1H NMR experiments recorded at 500 MHz. These assignments include the identification of all aromatic and most aliphatic amino acid resonances. Stereospecific assignment of resonances stemming from the Val2 CH3 gamma,gamma' groups and from seven CH beta,beta' geminal pairs has been accomplished by analysis of 3J alpha beta coupling constants in conjunction with patterns of cross-peak intensities observed in two-dimensional nuclear Overhauser effect (NOESY) spectra. Analysis of NOESY and 3J alpha NH data reveals a small antiparallel beta-sheet involving stretches containing residues 25-28 and 39-42, a cis-proline residue (Pro4), antiparallel strands consisting of residues 1-3, 5-7, and 10-13, and an aromatic cluster composed of Tyr7, Trp26, and Tyr33. The results of distance geometry and restrained molecular dynamics calculations indicate that the global fold of the PDC-109 b domain, a type II module related to those found in fibronectin, is somewhat different from that predicted by modeling the structure on the basis of homology between type II and kringle units. A shallow depression in the molecular surface which presents a solvent-exposed hydrophobic area--a potential ligand-binding site-is identified in the NMR-based models.     

1H NMR relaxometric characterization of bovine lactoferrin

Lactoferrin (Lf) is a mammalian iron binding protein present in external secretions and in polymorphonuclear leukocytes. Its role in host defense mechanisms related to the non-immune defense system has been definitively established. Lf has two identical iron-binding sites, far from each other (44.3 A) and magnetically non-interacting. Fe(III) ions are six-coordinated, with four donor atoms provided by protein sidechains (two Tyr, one His, one Asp) and two oxygen atoms from a bridged HCO(3)(-). This set of ligands provides an ideal coordination scheme for stable and reversible iron binding. Nuclear magnetic relaxation dispersion (NMRD) profiles of Lf are consistent with a closest distance for a single water hydrogen atom of 3.1 A. By looking at the X-ray structure of Lf (PDB ID code: 1BLF) we can locate two water oxygens at 3.95 and 4.27 A from each Fe(III), respectively. Temperature dependence data suggest that an important contribution to the overall paramagnetic contribution to the solvent water relaxation rate arises from one or more second sphere water molecules in slow exchange with the bulk. A decreasing value of the exchange rate is obtained, ranging from 1.2 to 0.7 micros in the observed temperature range (25-65 degrees C), with an activation enthalpy of 7.3+/-0.8 kJ mol(-1). The low exchange rate obtained from NMRD data can be explained by the observation that both water molecules are bound to several polar groups of the protein backbone and side chains. By increasing the pH from 6.5 to 12 two distinct titrations are observed, consistent with sequential removal of both water molecules.     

Interaction of cyclosporin A and two cyclosporin analogs with cyclophilin: relationship between structure and binding

The immunosuppressant drug cyclosporin A exists as various conformers in water. Up to 1 h is needed to reach maximum complex formation after mixing the drug with its receptor, cyclophilin, or an antibody, indicating that only a fraction of the conformers in aqueous solution adopts a conformation suitable for binding. In the present study we compare the binding behavior of cyclosporin to that of two analogs, using a biosensor instrument (BIAcore, Pharmacia). The amount of complex formation was measured as a function of time after adding the peptides to cyclophilin. The equilibrium affinity constants of cyclophilin for these analogs have been measured. The slow binding of cyclosporin to cyclophilin compared to the instant binding of the cyclosporin analogs supports the hypothesis that cyclophilin recognizes a well defined conformation of cyclosporin that exists in water prior to binding.     

1H NMR studies of mastoparan binding by calmodulin

Association with the cytoactive tetradecapeptide mastoparan perturbs the downfield 1H NMR spectrum of the calmodulin-Ca42+ complex. Changes occur in the resonances assigned to His-107 and Tyr-138. Composite peaks assigned to Phe-16 and Phe-89 and to Phe-68 and Tyr-99 are also affected. Both the upfield and downfield 1H NMR spectra contain evidence for spectroscopically distinct intermediates in Ca2+ binding by the calmodulin-mastoparan complex.     

The NMR structure of cyclosporin A bound to cyclophilin in aqueous solution

Cyclosporin A bound to the presumed receptor protein cyclophilin was studied in aqueous solution at pH 6.0 by nuclear magnetic resonance spectroscopy using uniform 15N- or 13C-labeling of cyclosporin A and heteronuclear spectral editing techniques. Sequence-specific assignments were obtained for all but one of the cyclosporin A proton resonances. With an input of 108 intramolecular NOEs and four vicinal 3JHN alpha coupling constants, the three-dimensional structure of cyclosporin A bound to cyclophilin was calculated with the distance geometry program DISMAN, and the structures resulting from 181 converged calculations were energy refined with the program FANTOM. A group of 120 conformers was selected on the basis of the residual constraint violations and energy criteria to represent the solution structure. The average of the pairwise root-mean-square distances calculated for the backbone atoms of the 120 structures was 0.58 A. The structure represents a novel conformation of cyclosporin A, for which the backbone conformation is significantly different from the previously reported structures in single crystals and in chloroform solution. The structure has all peptide bonds in the trans form, contains no elements of regular secondary structure and no intramolecular hydrogen bonds, and exposes nearly all polar groups to its environment. The root-mean-square distance between the backbone atoms of the crystal structure of cyclosporin A and the mean of the 120 conformers representing the NMR structure of cyclosporin A bound to cyclophilin is 2.5 A.     

1H and 15N NMR resonance assignments and preliminary structural characterization of Escherichia coli apocytochrome b562

The 1H and 15N resonances of uniformly enriched apocytochrome b562 (106 residues) have been assigned. The assignment work began with the identification of the majority of HN-H alpha-H beta subspin systems in two-dimensional DQF-COSY and TOCSY spectra of unlabeled protein in D2O and in 95% H2O/5% D2O buffer. Intraresidue and interresidue NOE connectivities were then searched for in two-dimensional homonuclear NOESY spectra recorded on unlabeled protein and in the three-dimensional NOESY-HMQC spectrum recorded on uniformly 15N-enriched protein. Those data, combined with the main-chain-directed assignment strategy (MCD), led to the assignment of the main-chain and many side-chain resonances of 103 of the 106 residues. Qualitatively, the helical conformation is found to be the dominant secondary structure in apocytochrome b562 as it is in holocytochrome b562. The helical segments in apocytochrome b562 overlap extensively with the helical regions defined in the crystal structure of ferricytochrome b562. In addition, a number of tertiary NOEs have been identified which indicate that the global fold of the apoprotein at least partially resembles the four-helix bundle of the holoprotein. The results presented here, together with the evidence obtained with other methods [Feng and Sligar (1991) Biochemistry (submitted)], support the notion that the interior of the protein is fluid and may correspond to a molten globule state.     

Mapping of cyclosporin A binding sites in cyclophilin A by using synthetic peptides

In order to map cyclosporin A (CsA) binding sites of cyclophilin (CyP), we synthesized the complete set of overlapping 157 octapeptides corresponding to human CyP A using the multi-pin peptide synthesis system. The pin-coupled synthetic octapeptides were examined in terms of binding ability to CsA by a modification of the enzyme-linked immunosorbent assay. Significant binding of CsA was detected with 35 synthetic N alpha-acetylated octapeptides possessing the N-terminal amino acids corresponding to the residues in positions 24-26, 42-44, 69-73, 75, 76, 89-91, 102, 116, 124-131, 144-151 and 152 in human CyP A, respectively. Other eight octapeptides showed moderate CsA binding activity. The distinct binding of octapeptides covering the C-terminal region of the CyP A was particularly significant. These data are to be compared with the information provided by X-ray and NMR studies on the CsA binding sites and furnish thus a test of the reported method. The present study also gave added insight into the CsA interaction sites of CyP.     

Thermodynamic characterization of the interaction of human cyclophilin 18 with cyclosporin A

Isothermal titration calorimetry (ITC) was used to investigate thermodynamic parameters of the cyclosporin A (CsA)-cyclophilin 18 (hCyp18) association reaction. We have calculated the thermodynamic parameters (enthalpy, entropy, heat capacity, and free energy of binding) of the CsA/hCyp18 complexation. All but two methods described in the literature underestimate the affinity to hCyp18 of CsA. We found that the association constant (1.1·10⁸ M⁻¹ at 10 °C) of CsA to hCyp18 is in close agreement with the reciprocal of the reported inhibitory constant of the peptidylprolyl cis/trans isomerase activity of hCyp18. Interpretation of the thermodynamic parameters in buffered solution of water, 30% glycerol and D₂O leads to the conclusion that the highly specific binding of CsA to hCyp18 is mainly mediated through hydrogen bonding and to a lesser degree through hydrophobic interaction. Furthermore, the pH dependence of the association constant was determined and analyzed according to a single proton linkage model, resulting in a pK_a value of 5.7 in free hCyp18 and below 4.5 in the CsA complexed form. Titration experiments using different single component buffers possessing different heats of ionization allowed us to estimate that statistically half a proton is transferred upon CsA binding from the binding interface of hCyp18 to the buffer at pH 5.5. No proton transfer was detected at pH 7.5. The thermodynamic results are discussed in relation to the published X-ray and NMR structure of the free and CsA complexed hCyp18.     

1H NMR studies of tris(phenanthroline) metal complexes bound to oligonucleotides: characterization of binding modes

The binding of Ru(phen)3(2+), Rh(phen)3(3+), and Co(phen)3(3+) to the oligonucleotides d(GTGCAC)2 and 5'-pd(CGCGCG)2 has been examined by 1H NMR spectroscopy as a function of temperature, concentration, and chirality of the metal complex. The duplex oligonucleotides act as chiral shift reagents for the metal complexes; phenanthroline protons associated with each enantiomer are resolved upon binding to the oligomer. The spectral titrations, consistent with photophysical studies, indicate that the complexes bind to the oligomer through two modes: one assigned as intercalation favoring the delta-isomer, and the other assigned as the surface-bound interaction favoring the lambda-isomer. The ligand protons are perturbed in a manner that implies sensitivity of particular protons to binding mode; specifically, the H4,7 protons appear to be altered most for the lambda-enantiomer while the H5,6 protons are perturbed more for the delta-enantiomer. The NMR chemical shift variations appear particularly sensitive to this surface-bound interaction, which, on the basis of a comparison of binding and photophysical parameters for Ru(phen)3(2+), appears more prominant in binding to oligonucleotides than that to polynucleotides. With respect to oligonucleotide proton shifts, the adenine H2 proton, positioned in the minor groove of the helix, shows the largest upfield shifts with metal binding, and more dramatically with lambda-isomers. The major groove thymine methyl protons (TMe) shift downfield to a lesser extent, and more so for delta-isomers. The different binding modes also differ with respect to their dynamics of association; the longitudinal relaxation rates of delta- and lambda-4,7 phenanthroline protons of Rh(phen)3(3+) are 0.88 and 1.14 s, respectively, in the presence of d(GTGCAC)2.(ABSTRACT TRUNCATED AT 250 WORDS)     

Tryptophan microstate reshuffling upon the binding of cyclosporin A to human cyclophilin A.

Human cyclophilin A (hCypA) contains one tryptophan residue at position 121 (Trp121). The fluorescence intensity of this single tryptophan residue doubles upon binding the clinically important immunosuppressant cyclosporin A (CsA). Trp121 is in close contact to the bound CsA and is well-conserved in almost all immunophilins. The enhancement of the fluorescence intensity upon binding CsA is investigated by steady-state and time-resolved fluorescence measurements. The crystal structures of hCypA and the complex hCypA-CsA are compared. Only Glu120 is strongly influenced by the binding of CsA. The distance between the indole ring and the carboxylate group doubles during complexation. The influence of Glu120 on the fluorescence properties of Trp121 was investigated by pH-titration, and by substituting glutamate into an aspartate and an alanine residue. The fluorescence measurements on the glutamate mutants reveal that the carboxylate group influences the fluorescence properties of Trp121 to a limited extent. The major effect of CsA binding, however, consists in a reshuffling of the populations of microconformations of Trp121 leading to a selective increase of the 1.5 ns lifetime component. This selection is also accompanied by a decreased polarity of the environment and an increase in the radiative rate constant.     

DNA binding of tilorone: 1H NMR and calorimetric studies of the intercalation

The fluorene derivative tilorone has received great attention as a DNA intercalator and has been widely recognized as an inducer of interferon. The biological activity of tilorone is known to be related to its binding mode with DNA; however, few structural and thermodynamic studies have elaborated on this issue. This paper presents two-dimensional (2-D) NMR and isothermal titration calorimetry (ITC) for the tilorone/DNA complex, coupled with circular dichroism (CD) spectroscopy and viscosity measurements. NMR investigation suggests that tilorone binds to DNA through intercalation, showing greater affinity for insertion between AT base pairs than between CG pairs. CD spectral changes were observed for T/B (tilorone/DNA base pair molar ratio) ratios greater than the stoichiometric ratio generally expected for intercalators (i.e., T/B = 0.5, according to the neighbor-exclusion principle). However, there was a clear plateau in the CD intensity between T/B < 0.35 and T/B > 0.45. From comparison with NMR and other measurements, we postulate that CD changes below the plateau should be related to the intercalation and the latter to electrostatic interactions and nonspecific bindings. ITC data showed that DeltaH < -TDeltaS < 0, which indicated that tilorone/DNA binding is enthalpy controlled. The magnitude of Kb (the binding constant) was of the same order as that of ethidium bromide. The stoichiometric number, obtained from ITC, CD, and UV data, implied a relatively smaller value (0.28-0.35) than that of the neighbor-exclusion principle. This is because side chains located in the groove disrupt further intercalation to the adjacent sites.     

Sequence specific binding of chlamydial histone H1-like protein.

Chlamydia trachomatis is one of the few prokaryotic organisms known to contain proteins that bear homology to eukaryotic histone H1. Changes in macromolecular conformation of DNA mediated by the histone H1-like protein (Hc1) appear to regulate stage specific differentiation. We have developed a cross-linking immunoprecipitation protocol to examine in vivo protein-DNA interaction by immune precipitating chlamydial Hc1 cross linked to DNA. Our results strongly support the presence of sequence specific binding sites on the chlamydial plasmid and hc1 gene upstream of its open reading frame. The preferential binding sites were mapped to 520 bp BamHI-XhoI and 547 bp BamHI-DraI DNA fragments on the plasmid and hc1 respectively. Comparison of these two DNA sequences using Bestfit program has identified a 24 bp region with >75% identity that is unique to the chlamydial genome. Double-stranded DNA prepared by annealing complementary oligonucleotides corresponding to the conserved 24 bp region bind Hc1, in contrast to control sequences with similar A+T ratios. Further, Hc1 binds to DNA in a strand specific fashion, with preferential binding for only one strand. The site specific affinity to plasmid DNA was also demonstrated by atomic force microscopy data images. Binding was always followed by coiling, shrinking and aggregation of the affected DNA. Very low protein-DNA ratio was required if incubations were carried out in solution. However, if DNA was partially immobilized on mica substrate individual strands with dark foci were still visible even after the addition of excess Hc1.     

Solid-state NMR studies of the prion protein H1 fragment.

Conformational changes in the prion protein (PrP) seem to be responsible for prion diseases. We have used conformation-dependent chemical-shift measurements and rotational-resonance distance measurements to analyze the conformation of solid-state peptides lacking long-range order, corresponding to a region of PrP designated H1. This region is predicted to undergo a transformation of secondary structure in generating the infectious form of the protein. Solid-state NMR spectra of specifically 13C-enriched samples of H1, residues 109-122 (MKHMAGAAAAGAVV) of Syrian hamster PrP, have been acquired under cross-polarization and magic-angle spinning conditions. Samples lyophilized from 50% acetonitrile/50% water show chemical shifts characteristic of a beta-sheet conformation in the region corresponding to residues 112-121, whereas samples lyophilized from hexafluoroisopropanol display shifts indicative of alpha-helical secondary structure in the region corresponding to residues 113-117. Complete conversion to the helical conformation was not observed and conversion from alpha-helix back to beta-sheet, as inferred from the solid-state NMR spectra, occurred when samples were exposed to water. Rotational-resonance experiments were performed on seven doubly 13C-labeled H1 samples dried from water. Measured distances suggest that the peptide is in an extended, possibly beta-strand, conformation. These results are consistent with the experimental observation that PrP can exist in different conformational states and with structural predictions based on biological data and theoretical modeling that suggest that H1 may play a key role in the conformational transition involved in the development of prion diseases.     

1H NMR studies of aliphatic ligand binding to human plasminogen kringle 4

A detailed 1H NMR analysis of ligand binding to the human plasminogen kringle 4 domain has been carried out at 300 MHz. The ligands that were investigated are N alpha-acetyl-L-lysine, L-lysine methyl ester, N alpha-acetyl-L-lysine methyl ester, L-lysine hydroxamic acid, trans-(aminomethyl)cyclohexanecarboxylic acid (AMCHA), and 4-(aminomethyl)bicyclo[2.2.2]octane-1-carboxylic acid (AMBOC). Specific ligand-binding effects were detected via two-dimensional COSY experiments. The side chains that are the most perturbed by ligand presence are those from Trp62, Phe64, and Trp72. Ligand-kringle saturation transfer (Overhauser) experiments show that the aromatic rings from these three residues, especially Trp72, are in direct contact with the ligand. These results add support to a previously reported model of the kringle 4 lysine-binding site [Ramesh, V., Petros, A. M., Llinás, M., Tulinsky, A., & Park, C. H. (1987) J. Mol. Biol. 198, 481-498] by which these aromatic groups are assigned a key role in establishing hydrophobic interactions with the ligand molecule. Equilibrium association constants (Ka) and kinetic rate constants (kon, koff) were determined for the binding of the various linear and cyclic ligands to kringle 4. We find that those ligands whose carboxylate function is blocked bind significantly weaker (Ka approximately less than 2 mM-1) than the corresponding analogues where the anionic center is present (Ka approximately greater than 20 mM-1), which underscores the relevance of the polar group in stabilizing the interaction with the kringle 4 binding site.(ABSTRACT TRUNCATED AT 250 WORDS)     

A mitochondrial-targeted cyclosporin A with high binding affinity for cyclophilin D yields improved cytoprotection of cardiomyocytes

Mitochondrial CyP-D (cyclophilin-D) catalyses formation of the PT (permeability transition) pore, a key lesion in the pathogenesis of I/R (ischaemia/reperfusion) injury. There is evidence [Malouitre, Dube, Selwood and Crompton (2010) Biochem. J. 425, 137-148] that cytoprotection by the CyP inhibitor CsA (cyclosporin A) is improved by selective targeting to mitochondria. To investigate this further, we have developed an improved mtCsA (mitochondrial-targeted CsA) by modifying the spacer linking the CsA to the TPP+ (triphenylphosphonium) (mitochondrial-targeting) cation. The new mtCsA exhibits an 18-fold increase in binding affinity for CyP-D over the prototype and a 12-fold increase in potency of inhibition of the PT in isolated mitochondria, owing to a marked decrease in non-specific binding. The cytoprotective capacity was assessed in isolated rat cardiomyocytes subjected to transient glucose and oxygen deprivation (pseudo-I/R). The new mtCsA was maximally effective at lower concentrations than CsA (3-15 nM compared with 50-100 nM) and yielded improved cytoprotection for up to 3 h following the pseudo-ischaemic insult (near complete compared with 40%). These data indicate the potential value of selective CyP-D inhibition in cytoprotection.     

Comparative 1H NMR studies on the structural looseness of the aged (A) and non-aged (N) bovine mercaptalbumin in the alkaline region

Bovine serum albumin (BSA) and mercaptalbumin (BMA) exhibit the N-B transition in the alkaline region (pH 7.0-->9.0). BMA has 17 disulfide bonds and one SH group at Cys-34 which catalyzes the intramolecular SH, S-S exchange reaction at low ionic strength in the alkaline region (the N-A isomerization, where N and A indicate the non-aged and aged BMA, respectively). The N-A isomerization is a reversible first-order reaction of the type N<-->A. In the alkaline region, such as pH 8.6, (A)/(N) was approximately 1 in the absence of added salt and approximately 0 in 0.10 M NaCl, indicating the shift of the equilibrium from the A- to the N-forms. Using iodoacetamide-blocked BSA (IA-BSA) and aged BMA (IA-A-BMA), the 1H NMR cross-relaxation times (TIS), which reflect the structural looseness in proteins, were measured in the N-, B- (IA-BSA), N*- and B*-forms (IA-A-BMA), where the N*- and B*-forms indicate IA-A-BMA in the neutral (approximately pD 7) and alkaline regions (approximately pD 9), respectively. At pD 9.1-9.4 in the absence of added salt, the TIS values for the B- and B*-forms exhibited elongation, indicating the liberation of structural looseness resulting in (A)/(N) approximately 1. At pD 9.3 in 0.10 M NaCl, the TIS values for the B*-form exhibited elongation and those for the B-form did not, indicating the presence of structural looseness in only the B*-form resulting in (A)/(N) approximately 0.