A Partially Folded State of Ovalbumin at Low pH Tends to Aggregate

At pH 2, ovalbumin retains native-like secondary structure as seen by far-UV CD and FTIR, but lacks well-defined tertiary structure as seen by the fluorescence and near-UV CD spectra. Addition of 20 mM Trifluoroacetic acid (TFA) or 30 mM Trichloroacetic acid (TCA) on acid-induced state results in protein aggregation. This aggregated state possesses extensive β-sheet structure as revealed by far-UV CD and FTIR spectroscopy. Furthermore, the aggregates exhibit decreased ANS fluorescence and increased thioflavin T fluorescence. The presence of aggregates was confirmed by size exclusion chromatography. Such a formation of β-sheet structure is found in the amyloid of a number of neurological diseases such as Alzheimer’s and scrapie. Ovalbumin at low pH, in the presence of K₂SO₄, exists in partially folded state characterized by native-like secondary structure and tertiary folds.     

Stability and folding of the protein complexes of barnase.

Native-like complexes of proteins, formed by the association of two complementary fragments comprising the entire sequence of the protein, can be used to gain insight into the stability and folding of the intact protein. We have studied the structural, thermodynamic and kinetic properties of four barnase complexes, with the cleavage site at different positions of the amino-acid chain (CB36, at position 36; CB56, at position 56; CB68, at position 68; and CB79, at position 79). The four barnase complexes have native-like structure as shown by fluorescence, far-and near-UV CD, size-exclusion chromatography and NMR. The NMR characterization indicated that the structural changes were mainly located in regions close to the cleavage site. The main core of the protein was fully formed and the overall structure was similar to that of intact barnase. The thermal and chemical denaturation showed that all complexes were substantially destabilized. CB56 displayed two denaturation transitions, probably because of the presence of partially folded conformations around the cleavage site. The rate constant for the association/folding of fragments decreased with the decreasing length of the C-terminal fragment. Thus, the larger the fragment (and, consequently, the larger the amount of residual native-like structure), the faster the association. These findings are consistent with the proposed model of barnase folding.     

Structural properties of semenogelin I

The zinc-binding protein semenogelin I is the major structural component of the gelatinous coagulum that is formed in freshly ejaculated semen. Semenogelin I is a rapidly evolving protein with a primary structure that consists of six repetitive units, each comprising approximately 60 amino acid residues. We studied the secondary and tertiary structure of semenogelin I by circular dichroism (CD) spectroscopy and Trp fluorescence emission spectroscopy. Fitting to the far-UV CD data indicated that the molecule comprises 5-10% alpha-helix and 20-30% beta-sheet formations. The far-UV spectrum of semenogelin I is clearly temperature dependent in the studied range 5-90 degrees C, and the signal at 222 nm increased with increasing temperature. The presence of Zn(2+) did not change the secondary structure revealed by the far-UV CD spectrum, whereas it did alter the near-UV CD spectrum, which implies that rearrangements occurred on the tertiary structure level. The conformational change induced in semenogelin I by the binding of Zn(2+) may contribute to the ability of this protein to form a gel.     

Structural intermediates of acid unfolded Con-A in different co-solvents: fluoroalcohols and polyethylene glycols

A molten globule-like intermediate of Con-A was obtained when subjected to acid unfolding. At pH 2 the intermediate was found to have native-like secondary structure, somewhat denatured tertiary structure and maximum ANS binding. Further the stability of this intermediate was studied in presence of fluoroalcohols (TFE and HFIP) and polyethylene glycols (PEG-400, 4000 and 20,000). Secondary structural changes were monitored by far-UV CD while alterations in the tertiary structure of the acid unfolded intermediate were probed by near-UV CD. To study the environment and position of the tryptophan residues present intrinsic fluorescence studies were performed. ANS binding studies were also made to know the extent of exposure of the hydrophobic patches. Using the above-mentioned techniques it was found that in presence of fluoroalcohols the pH 2 intermediate was transformed to a state with predominant alpha-helical secondary and denatured tertiary structures. In the pathway of these transformations MG-like intermediates were formed at 10% TFE and 6% HFIP. The folding intermediate of Con-A obtained at pH 2 underwent a series of conformational changes when exposed to different molecular weight PEGs. Secondary structure was induced by low molecular weight PEG-400 and low concentrations of PEG-4000 and PEG-20,000 while at higher concentrations transition in structure was observed. Tertiary structure was stabilized only at low concentrations of PEG-400. PEG-4000 and PEG-20,000 in the whole concentration range resulted in the loss of tertiary structure.     

Multiple-probe analysis of folding and unfolding pathways of human serum albumin. Evidence for a framework mechanism of folding.

The changes in the far-UV CD signal, intrinsic tryptophan fluorescence and bilirubin absorbance showed that the guanidine hydrochloride (GdnHCl)-induced unfolding of a multidomain protein, human serum albumin (HSA), followed a two-state process. However, using environment sensitive Nile red fluorescence, the unfolding and folding pathways of HSA were found to follow a three-state process and an intermediate was detected in the range 0.25-1.5 m GdnHCl. The intermediate state displayed 45% higher fluorescence intensity than that of the native state. The increase in the Nile red fluorescence was found to be due to an increase in the quantum yield of the HSA-bound Nile red. Low concentrations of GdnHCl neither altered the binding affinity of Nile red to HSA nor induced the aggregation of HSA. In addition, the secondary structure of HSA was not perturbed during the first unfolding transition (<1.5 m GdnHCl); however, the secondary structure was completely lost during the second transition. The data together showed that the half maximal loss of the tertiary structure occurred at a lower GdnHCl concentration than the loss of the secondary structure. Further kinetic studies of the refolding process of HSA using multiple spectroscopic techniques showed that the folding occurred in two phases, a burst phase followed by a slow phase. An intermediate with native-like secondary structure but only a partial tertiary structure was found to form in the burst phase of refolding. Then, the intermediate slowly folded into the native state. An analysis of the refolding data suggested that the folding of HSA could be best explained by the framework model.     

Partially folded states of the cytolytic protein sticholysin II

Sticholysin II (Stn II) is a cytolytic protein produced by the sea anemone Stichodactyla helianthus, its effect being related to pore formation. The conformation of the protein and its temperature-induced transitions, in the 1.5-12.0 pH range and in the 0-0.5 M NaCl concentration interval, have been studied by circular dichroism and fluorescence spectroscopy. At temperature < 35 degrees C, the protein maintains the same, high beta-structure content, folded conformation in the 1.5-11.0 pH range and ionic strength up to 0.5 M. In the 1.5-3.5 pH range and ionic strength > or = 0.1 M, Stn II shows a thermal transition, resulting in a partially folded state characterized by: (i) a native-like content of regular secondary structure, as detected by far-UV CD; (ii) a largely disordered tertiary structure, as detected by near-UV CD, with partially exposed tryptophan residues according to their fluorescence emission; and (iii) ability to bind the hydrophobic probe 2-anilinonaphthalene-6-sulfonic acid. In the pH range 4.0-10.5, thermally-induced protein aggregation occurs. The obtained results demonstrate the existence of partially folded state of Stn II, which may contribute to the pore formation ability of this cytolysin.     

Foldability of barnase mutants obtained by permutation of modules or secondary structure units

Modules, defined as stable, compact structure units in a globular protein, are good candidates for the construction of novel foldable proteins by permutation. Here we decomposed barnase into six modules (M1-M6) and constructed 23 barnase mutants containing permutations of the internal four (M2-M5) out of six modules. Globular proteins can also be subdivided into secondary structure units based on the extended structures that control the mutual relationships of the modules. We also decomposed barnase into six secondary structure units (S1-S6) and constructed 21 barnase mutants containing permutations of the internal four (S2-S5) out of six secondary structure units. Foldability of these two types of mutants was assessed by means of circular dichroism, fluorescence, and 1H-NMR measurements. A total of 15 of 23 module mutants and 15 of 21 secondary structure unit mutants formed definite secondary structures, such as alpha-helix and beta-sheet, at 20 microM owing to intermolecular interactions, but most of them converted to random coil structures at a lower concentration (1 microM). Of the 44 mutants, only two, M3245 and S2543, gave distinct near-UV CD spectra. S2543 especially showed definite signal dispersion in the amide and methyl regions of the 1H-NMR spectrum, though M3245 did not. Furthermore, urea-induced unfolding of S2543 monitored by far-UV CD and fluorescence measurements showed a distinct cooperative transition. These results strongly suggest that S2543 takes partially folded conformations in aqueous solution. Our results also suggest that building blocks such as secondary structure units capable of taking different stable conformations by adapting themselves to the surrounding environment, rather than building blocks such as modules having a specified stable conformation, are required for the formation of foldable proteins. Therefore, the use of secondary structure units for the construction of novel globular proteins is likely to be an effective approach.     

Guanidine hydrochloride induced equilibrium unfolding studies of colicin B and its channel-forming fragment

The conformational stabilities of full-length colicin B and its isolated C-terminal domain were studied by guanidine hydrochloride induced unfolding. The unfolding/refolding was monitored by far-UV CD and intrinsic tryptophan fluorescence spectroscopies. At pH 7.4, the disruption of the secondary structure of full-length colicin B is monophasic, while changes in tertiary structure occur in two separate transitions. The intermediate species, which is well-populated around 2.2 M guanidine hydrochloride, exhibits secondary and tertiary structures distinct from both native and unfolded states. Whereas the domain structure of native full-length colicin B is reflected in its DSC profile, the folding intermediate of the same protein exhibits a single unresolved peak. These observations have led us to propose an unfolding model for full-length colicin B where the first transition between 0 and 2.5 M GuHCl with an associated free energy of 3 kcal/mol correlates with the partial unfolding of the R/T domain. The stability of full-length colicin B is weakened due to the presence of the R/T domain in both the native [Ortega, A., Lambotte, S., and Bechinger, B. (2001) J. Biol. Chem. 276 (17), 13563-13572] and the intermediate states. The second transition between 2.5 and 5 M GuHCl involves unfolding of the C-terminal domain (Delta = 7 kcal/mol). The isolated colicin B C-terminal domain consists of two subdomains, and the two parts of this protein fragment unfold sequentially through the formation of at least one intermediate. The significance of these results for membrane insertion of colicin B is discussed.     

Conformational states of beta-lactamase: molten-globule states at acidic and alkaline pH with high salt

We present evidence that beta-lactamase is close to fully unfolded (i.e., random coil conformation) at low ionic strength at the extremes of pH and that the presence of salt causes a cooperative transition to a conformation with the properties of a molten globule, namely, a compact state with native-like secondary structure but disordered side chains (tertiary structure). The conformation of beta-lactamase I from Bacillus cereus was examined over the pH 1.5-12.5 region by circular dichroism (CD), tryptophan fluorescence, dynamic light scattering, and 1-anilino-8-naphthalenesulfonate (ANS) binding. Under conditions of low ionic strength (I = 0.05) beta-lactamase was unfolded below pH 2.5 and above pH 11.5, on the basis of the far-UV and near-UV CD and tryptophan fluorescence. However, at high ionic strength and low pH an intermediate conformation (state A) was observed, with a secondary structure content similar to that of the native protein but a largely disordered tertiary structure. The transition from the unfolded state (U) to state A induced by KCl was cooperative and had a midpoint at 0.12 M KCl (I = 0.17 M) at pH 1.6. A similar conformation (state B) was observed at high pH and high ionic strength. The transition from the alkaline U state to state B induced by KCl at pH 12.2 was cooperative and had a midpoint at 0.6 M KCl (I = 0.65 M). Light scattering measurements showed that state B was compact although somewhat expanded compared to the N state. The compactness of state A could not be determined due to its strong propensity to aggregate.(ABSTRACT TRUNCATED AT 250 WORDS)     

Autonomous folding of a C-terminal inhibitory fragment of Escherichia coli isoleucine-tRNA synthetase.

We previously reported that C-terminal fragments of Escherichia coli Ile-tRNA synthetase, a monomeric enzyme of 939 amino acids, act as dominant negative inhibitors of the wild-type enzyme in vivo and in vitro. Our experiments suggested that it is possible to block the functional assembly of a monomeric protein by interfering with the folding pathway. We postulated that the inhibitory C-terminal fragments fold autonomously, and in the presence of full-length Ile-tRNA synthetase, trap the N-terminal portion of polypeptide in an unproductive complex. Here, we report the results of experiments aimed at understanding the mechanism of dominant negative inhibition. We have carried out biophysical experiments on fragment 585-939 of Ile-tRNA synthetase, which we previously determined to be the minimal inhibitory unit. Circular dichroism and fluorescence spectroscopy indicate that this fragment forms a compact and stable structure in solution. The secondary structure of this fragment is predominantly alpha-helical, consistent with the crystal structure of Ile-tRNA synthetase from another organism. The C-terminal fragment is capable of forming native-like secondary and tertiary structure after refolding from guanidine HCl. Taken together, the results are consistent with the hypothesis that the inhibitory fragment of Ile-tRNA synthetase forms an independent folding unit.     

Interactions between subdomains in the partially folded state of staphylococcal nuclease

Staphylococcal nuclease can be roughly divided into a beta-subdomain in N-terminal and an alpha-subdomain in C-terminal. They fold sequentially under certain conditions, causing a partially folded intermediate state in which the native-like beta-barrel persists while alpha-helix regions largely disorder. To investigate the possible long-range interactions between the two subdomains in the intermediate, N-terminal fragments have been used as intermediate analogues, with polypeptide ending at positions 102, 110, 121 and 135 and with a tryptophan substitution at position 66 or 88 to facilitate the observation of the beta-barrel. Segment-resolved interactions between beta-barrel and residues 103-135 were identified by comparing their spectroscopic properties of fluorescence, circular dichroism and NMR and by their stability. Except for unstable V66W102, the guanidine and thermal denaturation of fragments are cooperative and well approximated by the two-state transition. Minimal stable structure units of both tryptophan-containing fragments comprise residues 1-110. With the main interaction in segment 103-135, residues 103-110 contribute approximate 2 kcal/mol to the stability. Elongation of C-terminal from 110 residue neither increases the stability nor alters the structure core of the G88W fragments. However, residues 111-121 influence the tertiary structure of the V66W fragments suggesting its minor interactions with beta-barrel.     

Secondary structure formation precedes tertiary structure in the refolding of ribonuclease A.

The kinetics of refolding of ribonuclease A were monitored by circular dichroism (CD), tyrosine fluorescence and absorbance in the -40 to -10 degrees C range using a methanol cryosolvent. The native-like far-ultraviolet CD signal returned in the dead-time of the mixing, whereas the native absorbance and fluorescence signals returned in a multiphasic process at rates several orders of magnitude more slowly. Thus the secondary structure was formed much more rapidly than the tertiary structure. In addition, the absorbance signal showed evidence of an early intermediate in which one, or more, tyrosine residues was in a transiently more polar environment. A total of four kinetic phases were observed by absorbance in refolding, the slowest two of which had energies of activation consistent with proline isomerization. A refolding scheme involving initial hydrophobic collapse, concurrent with secondary structure formation, followed by much slower rearrangement to the native tertiary structure is proposed.     

Cloning, overexpression, purification, and spectroscopic characterization of human S100P.

The calcium-binding protein S100P has been found to be associated with human prostate cancer. We have overexpressed S100P in Escherichia coli using a T7 expression system. A rapid two-step procedure for the isolation of overexpressed S100P leads to a preparation of >95% pure protein with a yield of approximately 150 mg per liter of culture. The structural integrity of recombinant S100P was analyzed using CD and fluorescence spectroscopic techniques. The far-UV CD shows that secondary structure of recombinant S100P consists predominantly of a-helical structure. Both near-UV CD and tyrosine fluorescence spectra show that aromatic residues are involved in the formation of a specific, well packed structure, indicating that the recombinant S100P protein adopts a compact folded conformation. Ca2+ has a profound effect on S100P structure. Near-UV CD and fluorescence intensity of both internal (tyrosine) and external (ANS) probes suggest significant structural rearrangements in the tertiary structure of the molecule. The similarity of far-UV CD spectrum of S100P in the presence and in the absence of Ca2+ suggests that Ca2+ binding has only minor effects on secondary structure.     

The acid-induced state of glucose oxidase exists as a compact folded intermediate

A systematic investigation of the acid-induced unfolding of glucose oxidase (beta-D-glucose: oxygen 1-oxidoreductase) (GOD) from Aspergillus niger was made using steady-state tryptophan fluorescence, circular dichroism (CD), and ANS (1-anilino 8-naphthalene sulfonic acid) binding. Intrinsic tryptophan fluorescence studies showed a maximally unfolded state at pH 2.6 and the presence of a non-native intermediate in the vicinity of pH 1.4. Flavin adenine dinucleotide (FAD) fluorescence measurements indicate that the bound cofactors are released at low pH. In the pH range studied, near- and far-UV CD spectra show maximal loss of tertiary as well as secondary structure (40%) at pH 2.6 although glucose oxidase at this pH is relatively less denatured as compared to the conformation in 6M GdnHCl. Interestingly, in the vicinity of pH 1.4, glucose oxidase shows a refolded conformation (A-state) with approximately 90% of native secondary structure and native-like near-UV CD spectral features. ANS fluorescence studies, however, show maximal binding of the dye to the protein at pH 1.4, indicating a "molten-globule"-like conformation with enhanced exposure of hydrophobic surface area. Acrylamide quenching data exhibit reduced accessibility of quencher to tryptophan, suggesting a more compact conformation at low pH. Thermal stability of this state was assessed by ellipticity changes at 222 nm relative to native protein. While native glucose oxidase showed a completely reversible thermal denaturation profile, the state at pH 1.4 showed approximately 50% structural loss and the denatured state appeared to be in a different conformation exhibiting prominent beta-sheet structure (around 85 degrees C) that was not reversible. To summarize; the A-state of GOD exists as a compact folded intermediate with "molten-globule"-like characteristics, viz., native-like secondary structure but with non-native cofactor environment, enhanced hydrophobic surface area and non-cooperative thermal unfolding. That the A-state also possesses significant tertiary structure is an interesting observation made in this study.     

The histidine-phosphocarrier protein of Streptomyces coelicolor folds by a partially folded species at low pH.

The folding of a 93-residue protein, the histidine-phosphocarrier protein of Streptomyces coelicolor, HPr, has been studied using several biophysical techniques, namely fluorescence, 8-anilinonaphthalene-1-sulfate binding, circular dichroism, Fourier transform infrared spectroscopy, gel filtration chromatography and differential scanning calorimetry. The chemical-denaturation behaviour of HPr, followed by fluorescence, CD and gel filtration, at pH 7.5 and 25 degrees C, is described as a two-state process, which does not involve the accumulation of thermodynamically stable intermediates. Its conformational stability under those conditions is deltaG = 4.0 +/- 0.2 kcal x mol-1 (1 kcal = 4.18 kJ), which makes the HPr from S. coelicolor the most unstable member of the HPr family described so far. The stability of the protein does not change significantly from pH 7-9, as concluded from the differential scanning calorimetry and thermal CD experiments. Conformational studies at low pH (pH 2.5-4) suggest that, in the absence of cosmotropic agents, HPr does not unfold completely; rather, it accumulates partially folded species. The transition from those species to other states with native-like secondary and tertiary structure, occurs with a pKa = 3.3 +/- 0.3, as measured by the averaged measurements obtained by CD and fluorescence. However, this transition does not agree either with: (a) that measured by burial of hydrophobic patches (8-anilinonaphthalene-1-sulfate binding experiments); or (b) that measured by acquisition of native-like compactness (gel-filtration studies). It seems that acquisition of native-like features occurs in a wide pH range and it cannot be ascribed to a unique side-chain titration. These series of intermediates have not been reported previously in any member of the HPr family.     

Effect of Heat and pH Denaturation on the Structure and Conformation of Recombinant Human Hepatic Stimulator Substance

Hepatic stimulator substance (HSS) is a novel liver-specific growth-promoting factor. Although HSS has been successfully crystallized, several properties of this protein have yet to be determined. This study shows that recombinant human HSS (rhHSS) is a dimer with a molecular mass of 31 kDa, The protein is weakly acidic and has an isoelectric point (pI) of 4.50. rhHSS was able to protect hepatoma cells from H₂O₂-induced apoptosis and to stimulate cell growth. The recombinant protein was thermostable up to 80°C and resistant to changes in pH, as determined by synchronous fluorescence and far-UV circular dichroism (CD). Within the range of pH 4.0–10.0, rhHSS assumed a folded conformation identical to the secondary structure of the original, native protein and a native-like far-UV CD spectrum. Denatured rhHSS could be partly reconstituted with respect to its structure, but not its activity. Thus, rhHSS is a structurally stable protein insensitive to thermal and acid–alkaline denaturation.     

Folding stability and cooperativity of the three forms of 1-110 residues fragment of staphylococcal nuclease

Folding stability and cooperativity of the three forms of 1-110 residues fragment of staphylococcal nuclease (SNase110) have been studied by various biophysical and NMR methods. Samples of G-88W- and V-66W-mutant SNase110, namely G-88W110 and V-66W110, in aqueous solution and SNase110 in 2.0 M TMAO are adopted in this study. The unfolding transitions and folded conformations of the three SNase fragments were detected by far- and near-ultraviolet circular dichroism and intrinsic tryptophan fluorescence measurements. The tertiary structures and internal motions of the fragments were determined by NMR spectroscopy. Both G-88W and V-66W single mutations as well as a small organic osmolyte (Trimethylamine N-oxide, TMAO) can fold the fragment into a native-like conformation. However, the tertiary structures of the three fragments exhibit different degrees of folding stability and compactness. G-88W110 adopts a relatively rigid structure representing a most stable native-like beta-subdomain conformation of the three fragments. V-66W110- and TMAO-stabilized SNase110 produce less compact structures having a less stable "beta-barrel" structural region. The different folding status accounts for the different backbone dynamic and urea-unfolding transition features of the three fragments. The G-20I/G-29I-mutant variants of the three fragments have provided the evidence that the folding status is correlated closely to the packing of the beta-strands in the beta-barrel of the fragments. The native-like beta-barrel structural region acts as a nonlocal nucleus for folding the fragment. The tertiary folding of the three fragments is initiated by formation of the local nucleation sites at two beta-turn regions, I-18-D-21 and Y-27-Q-30, and developed by the formation of a nonlocal nucleation site at the beta-barrel region. The formation of beta-barrel and overall structure is concerted, but the level of cooperativity is different for the three 1-110 residues SNase fragments.     

Native-like partially folded conformations and folding process revealed in the N-terminal large fragments of staphylococcal nuclease: a study by NMR spectroscopy

The N-terminal large fragments of staphylococcal nuclease (SNase), SNase110 (1-110 residues), SNase121 (1-121 residues), and SNase135 (1-135 residues), and the fragment mutants G88W110, G88W121, V66W110 and V66W121 were studied by heteronuclear multidimensional NMR spectroscopy. Ensembles of co-existent native-like partially folded and unfolded states were observed for fragments. The persistent native-like tertiary interaction drives fragments to be in partially folded states, which reveal native-like beta-barrel conformations. G88W and V66W mutations modulate the extent of inherent native-like tertiary interaction in fragment molecules, and in consequence, fragment mutants fold into native-like beta-subdomain conformations. In cooperation with the inherent tertiary interaction, 2 M TMAO (trimethylamine N-oxide) can promote the folding reaction of fragments through the changes of unfolding free energy, and a native-like beta-subdomain conformation is observed when the chain length contains 135 residues. Heterogeneous partially folded conformations of 1-121 and 1-135 fragments due to cis and trans X-prolyl bond of Lys116-Pro117 make a non-unique folding pathway of fragments. The folding reaction of fragments can be characterized as a hierarchical process.     

A natively unfolded toxin domain uses its receptor as a folding template

Natively unfolded proteins range from molten globules to disordered coils. They are abundant in eukaryotic genomes and commonly involved in molecular interactions. The essential N-terminal translocation domains of colicin toxins from Escherichia coli are disordered bacterial proteins that bind at least one protein of the Tol or Ton family. The colicin N translocation domain (ColN-(1-90)), which binds to the C-terminal domain of TolA (TolA-(296-421)), shows a disordered far-UV CD spectrum, no near-UV CD signal, and non-cooperative thermal unfolding. As expected, TolA-(296-421) displays both secondary structure in far-UV CD and tertiary structure in near-UV CD. Furthermore it shows a cooperative unfolding transition at 65 degrees C. CD spectra of the 1:1 complex show both increased secondary structure and colicin N-specific near-UV CD signals. A new cooperative thermal transition at 35 degrees C is followed by the unchanged unfolding behavior of TolA-(296-421). Fluorescence and surface plasmon resonance confirm that the new unfolding transition accompanies dissociation of ColN-(1-90). Hence upon binding the disordered structure of ColN-(1-90) converts to a cooperatively folded domain without altering the TolA-(296-421) structure.     

Anion-induced refolding of human serum albumin under low pH conditions

We studied the effect of various anions (of acids and salts) on the acid denatured state of HSA by near-UV circular dichroism (CD), far-UV CD, 1-anilinonaphthalene-8-sulfonate (ANS) binding, tryptophan fluorescence and thermal transition. Addition of different acids and salts caused an induction of alpha-helical structure as evident from the increase in the mean residue ellipticity (MRE) value at 222 nm and loss of ANS binding sites exhibited by the decrease in the ANS fluorescence intensity at 480 nm. However, the concentration range of acids/salts required to bring about the transition varied greatly among different acids and salts. Among various acids/salts tested, K(3)Fe(CN)(6) was found to be most effective whereas HCl and KCl were least effective in inducing the properties close to native structure. Further, they followed the electroselectivity series. The near-UV CD spectra showed an increase in MRE towards the native state, whereas the tryptophan fluorescence emission spectra produced a red shift of about 6 nm on addition of KClO(4). The temperature-induced transition in the presence of 40 mM KClO(4) monitored by ellipticity measurements at 222 nm was characterized by the presence of an intermediate state in the temperature range 30-50 degrees C having abundant secondary structure. These results suggest that human serum albumin at low pH and in the presence of acids or salts exists in a partially folded state characterized by native-like secondary structure and tertiary folds.