Gamma irradiation of intravenous immunoglobulin.

This paper describes gamma irradiation of a biotherapeutic product under conditions (the Clearant Process") that protect proteins and foster inactivation of viruses and other pathogens. The treated product was immunoglobulin paste from cold ethanol fractionation of human plasma, a process intermediate in the production of intravenous immunoglobulin (IGIV). The frozen paste was irradiated on dry ice to 45 kGy, conditions that inactivate > or = 4 log10 of non-enveloped viruses and > or = 6 log10 of enveloped viruses. When IGIV purified from the irradiated paste was characterized, no protein aggregation, fragmentation, oxidation or denaturation was detected and Fab functionality remained intact.

Structural stability and domain organization of colicin E1.

Thermodynamic properties, stability, and structure of the toxin-like molecule colicin E1 were analyzed by differential scanning calorimetry and circular dichroism to determine the number of structurally independent domains, and the interdomain interactions necessary for colicin import into the Escherichia coli cell. Analysis of denaturation profiles of the 522 residue colicin E1, together with fragments of 342 and 178 residues that contain subsets of the domains, showed three stable cooperative blocks that differ in thermal stability and correspond to three major functional domains of the colicin: (i) the COOH-terminal channel-forming (C) domain with the highest thermal stability; (ii) the BtuB receptor binding (R) domain; and (iii) the N-terminal translocation (T) domain that has the smallest stabilization enthalpy and thermal stability. Interdomain interactions were described in which T-R interactions stabilize R, and T-C and R-C interactions stabilize R and T, but destabilize C. The R and T domains behaved in a similar way as a function of pH and ionic strength. Interacting extended helices of the R domain, possibly a coiled-coil, were implied by: (i) the very high (>90%) alpha-helical content of the R domain, (ii) cooperative decreases in alpha-helical content near the T(tr) of thermal denaturation of the R domain; (iii) a large denaturation enthalpy, implying extensive H-bond and van der Waals interactions. The R domain was inferred, from the extended network of interacting helices, large DeltaH, and steep temperature dependence of its stabilization energy to have a dominant role in determining the conformation of other domains. It is proposed that cellular import starts with the R domain binding to the BtuB receptor, followed by unfolding of the R domain coiled-coil and thereby of the T domain, which then interacts with the TolC receptor-translocator.

Energetic basis of structural stability in the molten globule state: alpha-lactalbumin.

The denatured states of alpha-lactalbumin, which have features of a molten globule state, have been studied to elucidate the energetics of the molten globule state and its contribution to the stability of the native conformation. Analysis of calorimetric and CD data shows that the heat capacity increment of alpha-lactalbumin denaturation highly correlates with the degree of disorder of the residual structure of the state. As a result, the denaturational transition of alpha-lactalbumin from the native to a highly ordered compact denatured state, and from the native to the disordered unfolded state are described by different thermodynamic functions. The enthalpy and entropy of the denaturation of alpha-lactalbumin to compact denatured state are always greater than the enthalpy and entropy of its unfolding. This difference represents the unfolding of the molten globule state. Calorimetric measurements of the heat effect associated with the unfolding of the molten globule state reveal that it is negative in sign over the temperature range of molten globule stability. This observation demonstrates the energetic specificity of the molten globule state, which, in contrast to a protein with unique tertiary structure, is stabilized by the dominance of negative entropy and enthalpy of hydration over the positive conformational entropy and enthalpy of internal interactions. It is concluded that at physiological temperatures the entropy of dehydration is the dominant factor providing stability for the compact intermediate state on the folding pathway, while for the stability of the native state, the conformational enthalpy is the dominant factor.

A calorimetric study of the influence of calcium on the stability of bovine alpha-lactalbumin.

Bovine alpha-lactalbumin has been studied by differential scanning calorimetry with various concentrations of calcium to elucidate the effect of this ligand on its thermal properties. In the presence of excess calcium, alpha-lactalbumin unfolds upon heating with a single heat-absorption peak and a significant increase of heat capacity. Analysis of the observed heat effect shows that this temperature-induced process closely approximates a two-state transition. The transition temperature increases in proportion with the logarithm of the calcium concentration, which results in an increase in the transition enthalpy as expected from the observed heat capacity increment of denaturation. As the total concentration of free calcium in solution is decreased below that of the proteins, there are two temperature-induced heat absorption peaks whose relative area depends on the calcium concentration, such that further decrease of calcium concentration results in a increase of the low-temperature peak and a decrease of the high-temperature one. The high-temperature peak occurs at the same temperature as the unfolding of the holo-protein, while the low-temperature peak is within the temperature range associated with the unfolding of the apo-protein. Statistical thermodynamic modeling of this process shows that the bimodal character of the thermal denaturation of bovine alpha-lactalbumin at non-saturated calcium concentrations is due to a high affinity of Ca2+ for alpha-lactalbumin and a low rate of calcium exchange between the holo- and apo-forms of this protein. Using calorimetric data, the calcium-binding constant for alpha-lactalbumin has been determined to be 2.9 x 10(8) M-1.

Denaturation versus unfolding: energetic aspects of residual structure in denatured alpha-lactalbumin.

Denaturational changes in alpha-lactalbumin result in different degrees of disordering of the protein molecule. The thermally denatured states have been studied to elucidate the energetics of residual structure and its contributions to the stability of the native conformation. The value of the heat capacity increment of alpha-lactalbumin denaturation correlates closely with the amount of residual secondary structure in the denatured protein, therefore reflecting the degree of its disordering and accessibility to solvent. As a result of the observed correlation, the behavior of protein denaturation functions is influenced by the degree of disordering of protein conformation in the denatured state. Analysis of the calorimetric data shows that the denaturational transition of alpha-lactalbumin is described by different thermodynamic functions when it proceeds to an ordered compact denatured state and to the disordered unfolded state. This difference is related to unfolding of the compact denatured state known as a molten globule state, which is populated differently under different denaturing conditions. The enthalpy and entropy of the transition from the native to the compact denatured state are always higher in magnitude than the enthalpy and entropy of the complete unfolding reaction due to the large negative hydration effect upon molten globule unfolding. Since the hydration effect increases with decreasing temperature, the gap between the partial denaturing and complete unfolding thermodynamic parameters also increases, resulting in a large difference at physiological temperatures. The results clearly indicate that a degree of residual structure in the denatured state must be taken into account to yield a more accurate description of protein structural energetics.

Energetics of solvent and ligand-induced conformational changes in alpha-lactalbumin.

The energetics of structural changes in the holo and apo forms of a-lactalbumin and the transition between their native and denatured states induced by binding Ca2+ and Na+ have been studied by differential scanning and isothermal titration microcalorimetry and circular dichroism spectroscopy under various solvent conditions. Removal of Ca2+ from the protein enhances its sensitivity to pH and ionic conditions due to noncompensated negative charge-charge interactions at the cation binding site, which significantly reduces its overall stability. At neutral pH and low ionic strength, the native structure of apo-alpha-lactalbumin is stable below 14 C and undergoes a conformational change to a native-like molten globule intermediate at temperatures above 25 degrees C. The denaturation of either holo- or apo-alpha-lactalbumin is a highly cooperative process that is characterized by an enthalpy of similar magnitude when calculated at the same temperature. Measured by direct calorimetric titration, the enthalpy of Ca2+-binding to apo-LA at pH 7.5 is -7.1 kJ mol(-1) at 5.0 degrees C. which is essentially invariant to protonation effects. This small enthalpy effect infers that stabilization of alpha-lactalbumin by Ca2+ is primarily an entropy driven process, presumably arising from electrostatic interactions and the hydration effect. In contrast to the binding of calcium, the interaction of sodium with apo-LA does not produce a noticeable heat effect and is characterized by its ionic nature rather than specific binding to the metal-binding site. Characterization of the conformational stability and ligand binding energetics of alpha-lactalbumin as a function of solvent conditions furnishes significant insight regarding the molecular flexibility and regulatory mechanism mediated by this protein.

Energetics of Ca(2+)-EDTA interactions: calorimetric study.

The interaction between Ca(2+) and EDTA has been studied using isothermal titration calorimetry to elucidate the detailed mechanism of complex formation and to relate the apparent thermodynamic parameters of calcium binding to the intrinsic effects of ionization. It has been shown that Ca(2+) binding to EDTA is an exothermic process in the temperature range 5-48 degrees C and is highly dependent on the buffer in which the reaction occurs. Calorimetric measurements along with pH-titration of EDTA under different solvent conditions shows that the apparent enthalpy effect of the binding is predominantly from the protonation of buffer. Subtraction of the ionization effect of buffer from the total enthalpy shows that the enthalpy of binding Ca(2+) to EDTA is -0.56 kcal mol(-1) at pH 7.5. The DeltaH value strongly depends on solvent conditions as a result of the degree of ionization of the two amino groups in the EDTA molecule, but depends little on temperature, indicating that the heat capacity increment for metal binding is close to zero. At physiological pH values where the amino groups of EDTA with pK(a)=6.16 and pK(a)=10.26 are differently ionized, the coordination of the Ca(2+) ion into the complex leads to release of one proton due to deprotonation of the amino group having pK(a)=10.26. Increasing the pH up to 11.2, where little or no ionization occurs, leads to elimination of the enthalpy component due to ionization, while its decrease to pH 2 leads to its increase, due to protonation of the two amino groups. The heat effect of Ca(2+)/EDTA interactions, excluding the deprotonation enthalpy of the amino groups, i.e. that associated with the intrinsic enthalpy of binding, is higher in value (Delta(b)H(o)=-5.4 kcal mol(-1)) than the apparent enthalpy of binding. Thus, the large DeltaG value for Ca(2+) binding to EDTA arises not only from favorable entropic but also enthalpic changes, depending on the ionization state of the amino groups involved in coordination of the calcium. This explains the great variability in DeltaH obtained in previous studies. The ionization enthalpy is always unfavorable, and therefore dramatically decreases Ca(2+) affinity by reduction of the enthalpy term of the stability function. The origin of the enthalpy and entropy terms in the stability of the Ca(2+)-EDTA complex is discussed.

The unfolding thermodynamics of c-type lysozymes: a calorimetric study of the heat denaturation of equine lysozyme.

The energetics of the temperature-induced unfolding of equine lysozyme was studied calorimetrically and compared with that of two structurally homologous proteins: hen egg white lysozyme and alpha-lactalbumin. The structure of each of these proteins is characterized by the presence of a deep cleft that divides the molecule into two regions called the alpha and beta domains. In equine lysozyme and alpha-lactalbumin the latter domain specifically binds Ca2+. It is shown that, in contrast to hen egg white lysozyme in which the alpha and beta domains unfold as a single cooperative unit, in equine lysozyme the two domains unfold in two separate cooperative stages even in the presence of excess Ca2+. The calcium binding beta-domain unfolds at a lower temperature and with more extensive heat absorption than the alpha-domain. Binding of Ca2+ increases the stability of the beta-domain, but even in the holo form it is less stable than the alpha-domain. The thermodynamic characteristics of Ca2+ binding have been determined, and indicate that it is an entropically driven process. The unfolding of equine lysozyme largely resembles the unfolding of alpha-lactalbumin, which also unfolds in two stages, but in the latter case the second stage is much less cooperative and proceeds with a smaller and diffuse heat absorption. As a result, the total enthalpy of unfolding of equine lysozyme is significantly larger than that of alpha-lactalbumin, being almost of the same magnitude as the enthalpy of egg white lysozyme unfolding, which proceeds as a single two-state transition. Analyses of the unfolding enthalpy function of various lysozymes, which bind or do not bind Ca2+, and unfold in one or two stages, have led us to the conclusion that the main reason for the loss of interdomain cooperativity in equine lysozyme is not the cluster of negative charges forming the calcium binding site, but the difference in atomic packing in the interior and at the interface between the alpha and beta domains.

Structural energetics of barstar studied by differential scanning microcalorimetry.

The energetics of barstar denaturation have been studied by CD and scanning microcalorimetry in an extended range of pH and salt concentration. It was shown that, upon increasing temperature, barstar undergoes a transition to the denatured state that is well approximated by a two-state transition in solutions of high ionic strength. This transition is accompanied by significant heat absorption and an increase in heat capacity. The denaturational heat capacity increment at approximately 75 degrees C was found to be 5.6 +/- 0.3 kJ K-1 mol-1. In all cases, the value of the measured enthalpy of denaturation was notably lower than those observed for other small globular proteins. In order to explain this observation, the relative contributions of hydration and the disruption of internal interactions to the total enthalpy and entropy of unfolding were calculated. The enthalpy and entropy of hydration were found to be in good agreement with those calculated for other proteins, but the enthalpy and entropy of breaking internal interactions were found to be among the lowest for all globular proteins that have been studied. Additionally, the partial specific heat capacity of barstar in the native state was found to be 0.37 +/- 0.03 cal K-1 g-1, which is higher than what is observed for most globular proteins and suggests significant flexibility in the native state. It is known from structural data that barstar undergoes a conformational change upon binding to its natural substrate barnase.(ABSTRACT TRUNCATED AT 250 WORDS)

Purification and characterization of human pancreatic polypeptide expressed in E. coli.

The region of cDNA encoding human pancreatic polypeptide (hPP) was obtained by polymerase chain reaction (PCR) and subcloned into an expression vector. The pancreatic polypeptide gene was expressed in Escherichia coli in two versions: as a cleavable fusion protein with IgG-binding synthetic ZZ domains of protein A from Staphylococcus aureus or with the 1-48 fragment of lambda Cro repressor. Site-specific hydrolysis by hydroxylamine was used to cleave the fusion protein, releasing the human polypeptide. The structure of the obtained hPP has been studied by scanning microcalorimetry and circular dichroism spectrometry. It has been shown that hPP in solutions close to neutral has a compact and unique spatial structure with an extended hydrophobic core. This structure is stable at 20 degrees C and co-operatively breaks down upon heating from this temperature.

Residual structure in a staphylococcal nuclease fragment. Is it a molten globule and is its unfolding a first-order phase transition?

Temperature-induced unfolding of staphylococcal nuclease and its large fragment, which lacks 13 C-terminal amino acid residues, was studied calorimetrically, and by CD and fluorescence spectroscopy. It was shown that, in contrast to the full length protein which includes two domains and unfolds in two distinct stages under some conditions, the fragment unfolds in one stage. Unfolding of the fragment proceeds in the same temperature range in which the N-terminal beta-barrel domain unfolds in the full length staphylococcal nuclease. Therefore, the fragment is initially partly unfolded. It retains a stable N-terminal domain which unfolds co-operatively with significant heat absorption. Unfolding of the fragment can be regarded as a first-order phase transition, but its initial state certainly does not represent a molten globule, as it was believed.

Thermodynamics of barnase unfolding.

The thermodynamics of barnase denaturation has been studied calorimetrically over a broad range of temperature and pH. It is shown that in acidic solutions the heat denaturation of barnase is well approximated by a 2-state transition. The heat denaturation of barnase proceeds with a significant increase of heat capacity, which determines the temperature dependencies of the enthalpy and entropy of its denaturation. The partial specific heat capacity of denatured barnase is very close to that expected for the completely unfolded protein. The specific denaturation enthalpy value extrapolated to 130 degrees C is also close to the value expected for the full unfolding. Therefore, the calorimetrically determined thermodynamic characteristics of barnase denaturation can be considered as characteristics of its complete unfolding and can be correlated with structural features--the number of hydrogen bonds, extent of van der Waals contacts, and the surface areas of polar and nonpolar groups. Using this information and thermodynamic information on transfer of protein groups into water, the contribution of various factors to the stabilization of the native structure of barnase has been estimated. The main contributors to the stabilization of the native state of barnase appear to be intramolecular hydrogen bonds. The contributions of van der Waals interactions between nonpolar groups and those of hydration effects of these groups are not as large if considered separately, but the combination of these 2 factors, known as hydrophobic interactions, is of the same order of magnitude as the contribution of hydrogen bonding.

Energetics of the alpha-lactalbumin states: a calorimetric and statistical thermodynamic study.

The temperature dependence of the heat capacity function of holo and apo alpha-lactalbumin has been studied by high sensitivity differential scanning microcalorimetry. The heat capacities of the holo and apo forms in the native state were found to be close to, but somewhat higher than, that of lysozyme, which has a similar structure. At pH values higher than 5, the heat-denatured state and the unfolded state are indistinguishable. At lower pH values, the heat capacity of the state obtained by heat or acid denaturation is lower than what is expected for the completely unfolded polypeptide chain, but it approaches that value at higher temperatures. The heat capacity increment of the denatured state correlates well with the amount of residual structure measured by ellipticity (i.e., the lower the residual structure, the higher the heat capacity). The extent of residual structure in the denatured state, which is exceptionally high in alpha-lactalbumin, decreases upon increasing temperature and at approximately 110 degrees C becomes close to that observed in 6 M GdmCl. Above 110 degrees C, the denatured state of alpha-lactalbumin is practically indistinguishable in heat capacity and ellipticity from the fully unfolded state. The calorimetric data have been analyzed quantitatively using a statistically thermodynamic formalism. This analysis indicates that the long-range or global cooperativity of the protein is lost after heat denaturation of the native state, causing the remaining elements of residual structure to behave in a more or less independent fashion. At pH values close to neutral, heat denaturation occurs at high temperature and yields a totally unfolded polypeptide with no measurable population of partly folded intermediates. At lower pH values, denaturation occurs at lower temperatures and a progressively higher population of intermediates is observed. At pH 4.2, about 50% of the molecules is in compact intermediate states immediately after heat denaturation; however, at pH 3.5, this percentage is close to 80% and at pH 3.0 it reaches about 100% of the protein molecules. Upon heating, the unfolded state progressively becomes the predominant species. The analysis of the heat capacity data for alpha-lactalbumin indicates that the best model to account for the observed behavior is one in which the denatured state is represented as a distribution of substates with varying degrees of residual structure. At low temperatures, the distribution is centered around rather compact substates with significant residual structure. At higher temperatures, the distribution shifts toward states with less residual structure and eventually to the completely unfolded state.

Thermodynamic puzzle of apomyoglobin unfolding.

It has been shown that a compact, partly unfolded state of apomyoglobin, which is obtained in acidic solutions, had a heat capacity lower than that of the unfolded polypeptide chain. With increasing temperature, this intermediate state unfolds in a rather narrow temperature region. Its unfolding is accompanied by an increase of the heat capacity, which reaches the value specific for the fully unfolded polypeptide chain having all groups exposed to water. This unfolding, however, proceeds without the excess heat absorption expected for a temperature induced two-state transition. This eliminates the possibility of considering this process as a first order phase transition, as gross conformational transitions in proteins are usually considered. It appears that the process of unfolding of the intermediate state of apomyoglobin might represent a second order phase transition, which has been predicted on theoretical grounds for those compact proteins without unique structure, known as "molten globules".

The purification and characterization of an extremely thermostable alpha-amylase from the hyperthermophilic archaebacterium Pyrococcus furiosus.

The alpha-amylase from Pyrococcus furiosus, a hyperthermophilic archaebacterium, has been purified to homogeneity. The enzyme is a homodimer with a subunit molecular mass of 66 kDa. The isoelectric point is 4.3. The enzyme displays optimal activity, with substantial thermal stability, at 100 degrees C, with the onset of activity at approximately 40 degrees C. Unlike mesophilic alpha-amylases there is no dependence on Ca2+ for activity or thermostability. The enzyme displays a broad range of substrate specificity, with the capacity to hydrolyze carbohydrates as simple as maltotriose. No subtrate binding occurs below the temperature threshold of activity, and a decrease in Km accompanies an increase in temperature. Except for a decrease in Asp and an increase in Glu, the amino acid composition does not confirm previously defined trends in thermal adaption. Fourth derivative UV spectroscopy and intrinsic fluorescence measurements detected no temperature-dependent structural reorganization. Hydrogen exchange results indicate that the molecule is rigid, with only a slight increase in conformational flexibility at elevated temperature. Scanning microcalorimetry detected no considerable change in the heat capacity function, at the pH of optimal activity, within the temperature range in which activity is induced. The heat absorption peak due to denaturation, under these conditions, occurred within the temperature range of 90-120 degrees C. When the pH was increased, a change in the shape of the heat absorption peak was observed, which when analyzed thermodynamically shows that the process of heat denaturation is complex, and includes at least three stages, indicating that the protein structure consists of three domains. At temperatures below 90 degrees C no excess heat absorption or change in the CD spectra were observed which could be associated with the cooperative conformational transition of the protein. According to the thermodynamic characteristics of the heat denaturation, the cold denaturation of this protein can be expected only at -3 degrees C. Therefore, the observed inactivation of this enzyme is not caused by the cooperative change of its tertiary structure. It can be associated only with the gradual changes of protein domain interaction.

Domains in lambda Cro repressor. A calorimetric study.

Thermodynamic properties of a mutant lambda Cro repressor with Cys replacing Val55 were studied calorimetrically. Formation of the S-S cross-link between neighboring Cys55 residues in this dimeric molecule leads to stabilization of a structure formed by the C-terminal parts of the two polypeptide chains, which behave as a single cooperative domain upon protein denaturation by heating. This composite domain is very stable at neutral pH and disrupts at 110 degrees C. The S-S-cross-linked tryptic fragment (residues 22-66), which includes this C-terminal domain, has similar stability. The N-terminal parts of the polypeptide chains do not form any stable structure when isolated, but in S-S-cross-linked dimer, they form a single cooperative block which melts in an all-or-none way 9 degrees C higher than the un-cross-linked protein. The observed cooperation of the distant N-terminal parts in dimer raises questions regarding lambda Cro repressor structure in solution.

Calorimetric study of the heat and cold denaturation of beta-lactoglobulin.

Temperature-induced changes of the states of beta-lactoglobulin have been studied calorimetrically. In the presence of a high concentration of urea this protein shows not only heat but also cold denaturation. Its heat denaturation is approximated very closely by a two-state transition, while the cold denaturation deviates considerably from the two-state transition and this deviation increases as the temperature decreases. The heat effect of cold denaturation is opposite in sign to that of heat denaturation and is noticeably larger in magnitude. This difference in magnitude is caused by the temperature-dependent negative heat effect of additional binding of urea to the polypeptide chain of the protein upon its unfolding, which decreases the positive enthalpy of heat denaturation and increases the negative enthalpy of cold denaturation. The binding of urea considerably increases the partial heat capacity of the protein, especially in the denatured state. However, when corrected for the heat capacity effect of urea binding, the partial heat capacity of the denatured protein is close in magnitude to that expected for the unfolded polypeptide chain in aqueous solution without urea but only for temperatures below 10 degrees C. At higher temperatures, the heat capacity of the denatured protein is lower than that expected for the unfolded polypeptide chain. It appears that at temperatures above 10 degrees C not all the surface of the beta-lactoglobulin polypeptide chain is exposed to the solvent, even in the presence of 6 M urea; i.e., the denatured protein is not completely unfolded and unfolds only at temperatures lower than 10 degrees C.(ABSTRACT TRUNCATED AT 250 WORDS)

Thermodynamic study of the apomyoglobin structure.

Sperm whale apomyoglobin has been studied thermodynamically in solutions with different pH and temperature by scanning microcalorimetry, viscosimetry, nuclear magnetic resonance and circular dichroism spectrometry, and by electrometric and calorimetric titration. It has been shown that apomyoglobin in solutions with pH close to neutral has a compact and unique spatial structure with an extended hydrophobic core. This structure is maximally stable at about 30 degrees C and breaks down reversibly both upon heating or cooling from this temperature. The process of breakdown of this structure is highly co-operative and can be regarded as a transition between two macroscopic states of protein, the native and denatured states. In contrast to the native state, which is specified by definite values of compactness and ellipticity, the compactness and ellipticity of the denatured state of apomyoglobin depend strongly on pH; with a decrease of pH below 4.0, these parameters gradually approach the values of the random coil.

Cold denaturation of staphylococcal nuclease.

Denaturation of staphylococcal nuclease was studied in a temperature range from -7 to 70 degrees C by scanning microcalorimetry and spectropolarimetry. It was found that the native protein is maximally stable at about 20 degrees C and is denatured upon heating and cooling from this temperature. The heat and cold denaturation processes are approximated rather well by a two-state transition showing that the molecule is composed of a single cooperative system. The main difference between these two processes is in the sign of the enthalpy and entropy of denaturation: whereas the heat denaturation proceeds with increases in the enthalpy and entropy, the cold denaturation proceeds with decreases in both quantities. The inversion of the enthalpy sign occurs at about 15 degrees C in an acetate buffer, but this temperature can be raised by addition of urea to the solvent.