Irreversible thermal denaturation of uridine phosphorylase from Escherichia coli K-12

Thermal denaturation of uridine phosphorylase from Escherichia coli K-12 has been studied by differential scanning calorimetry. The excess heat capacity vs. temperature profiles were obtained at temperature scanning rates of 0.25, 0.5, and 1 K/min. These profiles were analysed using three models of irreversible denaturation which are approximations to the whole Lumry-Eyring model, namely, the one-step model of irreversible denaturation, the Lumry-Eyring model with the fast equilibrating first step, and the model involving two consecutive irreversible steps. In terms of statistics the latter model describes the kinetics of thermal denaturation of uridine phosphorylase more satisfactorily than the two other models. The values of energy activation for the first and second steps calculated for the model involving two consecutive irreversible steps are the following: E_a,1 = 609.3 ± 1.8 kJ/mol and E_a,2 = 446.8 ± 3.2 kJ/mol.     

Comparison of the chemical and thermal denaturation of proteins by a two-state transition model

The conformational stabilities of eight proteins in terms of the free energy differences between the native "folded" state of the protein and its "unfolded" state were determined at 298 K by two methods: chemical denaturation at 298 K and extrapolation to 298 K of the thermal denaturation results at high temperature. The proteins were expressed in Escherichia coli from the Haemophilus influenzae and E. coli genes at different levels of expression, covered a molecular mass range from 13 to 37 kg mol(-1) per monomeric unit (some exhibiting unique structural features), and were oligomeric up to four subunits. The free energy differences were determined by application of a two-state transition model to the chemical and thermal denaturation results, ranged from 9.4 to 148 kJ mol(-1) at 298 K, and were found to be within the experimental uncertainties of both methods for all of the proteins. Any contributions from intermediate states detectable from chemical and thermal denaturation differences in the unfolding free energy differences in these proteins are within the experimental uncertainties of both methods.     

Fast scanning calorimetry of lysozyme unfolding at scanning rates from 5 K/min to 500,000 K/min

Background

Protein denaturation is often studied using differential scanning calorimetry (DSC). However, conventional instruments are limited in the temperature scanning rate available. Fast scanning calorimetry (FSC) provides an ability to study processes at much higher rates while using extremely small sample masses [ng]. This makes it a very interesting technique for protein investigation.

Kinetic study into the irreversible thermal denaturation of bacteriorhodopsin

We report on a differential scanning calorimetry study of native purple membranes under the following solvent conditions: 50 mM carbonate-bicarbonate, 100 mM NaCl, pH 9.5 and 190 mM phosphate, pH 7.5. The calorimetric transitions for bacteriorhodopsin denaturation are highly scanning-rate dependent, which indicates that the thermal denaturation is under kinetic control. This result is confirmed by a spectrophotometric study on the kinetics of the thermal denaturation of this protein. The calorimetric data at pH 9.5 conform to the two-state irreversible model. Comments are made regarding the information obtainable from differential scanning calorimetry studies on bacteriorhodopsin denaturation and the effect of irreversibility on the stability of membrane proteins. Correspondence to: J. M. Sanchez-Ruiz     

Structural analysis of denaturant-protein interactions: Comparison between the effects of bromoethanol and SDS on denaturation and renaturation of triclinic lysozyme

This paper summarizes our crystallographic studies of the interaction of denaturants with cross-linked triclinic lysozyme. Electron density maps of various bromoethanol-lysozyme complexes are analyzed and compared to those reported earlier for SDS-lysozyme complexes. Despite differences in the chemical nature and size of the two denaturants their mode of interaction with the protein is quite similar, suggesting the existence of a general mechanism for binding of hydrophobic-hydrophilic denaturants to proteins. Our results are consistent with the conclusion that lysozyme consists of two domains connected by a flexible segment and that this segment represents an internal degree of freedom of the protein.The work was carried out during the tenure of a fellowship from the European Molecular Biology OrganizationWe are grateful to Dr. Gerson Cohen for providing us with his data processing programs, to Drs. David Haas, Paul Sigler, Thomas Creighton and Micael James for helpful discussions, and to Mr. Samuel Getteno for his invaluable technical assistance.     

Refolding of partially and fully denatured lysozymes

Lysozyme refolding with high yields sometimes results from incomplete denaturation. Dithiothreitol (DTT) is a reductant commonly used to reduce and unfold disulfide-stabilized lysozymes. Through the use of fluorescence spectroscopy to access the extent of denaturation, we found that the rate and extent of denaturation highly depended on the concentration of DTT. Further, the denaturation exhibited a two-phase transition at a high DTT concentration with DTT at >100 mM and long denaturation time (>24 h) being needed for complete denaturation. A low DTT concentration and a short denaturation time resulted in fast refolding with high activity recovery, while a high DTT concentration and a long denaturation time resulted in slow refolding with low activity recovery. Hence, the renaturation of disulfide-containing lysozyme was highly affected by the extent of denaturation.     

Small heat shock protein Hsp27 protects myosin S1 from heat-induced aggregation, but not from thermal denaturation and ATPase inactivation

We applied different methods, such as turbidity measurements, dynamic light scattering, differential scanning calorimetry and co-sedimentation assay, to analyze the interaction of small heat shock protein Hsp27 with isolated myosin head (myosin subfragment 1, S1) under heat-stress conditions. Upon heating at 43 degrees C, Hsp27 effectively suppresses S1 aggregation, and this effect is enhanced by mutations mimicking Hsp27 phosphorylation. However, Hsp27 was unable to prevent thermal unfolding of myosin heads and to maintain their ATPase activity under heat-shock conditions.     

Heat-induced denaturation and aggregation of ovalbumin at neutral pH described by irreversible first-order kinetics

The heat-induced denaturation kinetics of two different sources of ovalbumin at pH 7 was studied by chromatography and differential scanning calorimetry. The kinetics was found to be independent of protein concentration and salt concentration, but was strongly dependent on temperature. For highly pure ovalbumin, the decrease in nondenatured native protein showed first-order dependence. The activation energy obtained with different techniques varied between 430 and 490 kJ*mole(-1). First-order behavior was studied in detail using differential scanning calorimetry. The calorimetric traces were irreversible and highly scan rate-dependent. The shape of the thermograms as well as the scan rate dependence can be explained by assuming that the thermal denaturation takes place according to a simplified kinetic process where N is the native state, D is denatured (or another final state) and k a first-order kinetic constant that changes with temperature, according to the Arrhenius equation. A kinetic model for the temperature-induced denaturation and aggregation of ovalbumin is presented. Commercially obtained ovalbumin was found to contain an intermediate-stable fraction (IS) of about 20% that was unable to form aggregates. The denaturation of this fraction did not satisfy first-order kinetics.     

kinetics of reactivation of rabbit muscle aldolase after denaturation and dissociation in various solvent media

The denaturation of aldolase from rabbit muscle in various solvents leads to significant qualitative and quantitative differences with respect to the structural disintegration of the enzyme. The differences refer to the quaternary structure and to the conformation which is changed only slightly in MgCl₂ while in guanidine · HCl or urea at pH 2 the molecule is close to the state of the random coil.Using the enzymic activity as a quantitative measure for the refolding process, the reaction order and the rate constants of the processes of structure formation ( _i N^*) are found to be identical.This observation suggests a common intermediate D in the process of renaturation after denaturation and dissociation in the different solvent media. D may be considered an intermediate state with a defined number of nucleation centers whose rapid formation is predetermined by the aminoacid sequence.As taken from the first order kinetics in the given range of enzyme concentration, transconformation reactions are rate limiting in the obligatory pathway of refolding. At low enzyme concentrations second order steps gain importance which indicates that the enzymic activity is significantly modified by the formation of the native quaternary structure.Dedicated to Professor J. M. Sturtevant     

The role of water in the reversibility of thermal denaturation of lysozyme in solid and liquid states

Although unfolding of protein in the liquid state is relatively well studied, its mechanisms in the solid state, are much less understood. We evaluated the reversibility of thermal unfolding of lysozyme with respect to the water content using a combination of thermodynamic and structural techniques such as differential scanning calorimetry, synchrotron small and wide-angle X-ray scattering (SWAXS) and Raman spectroscopy. Analysis of the endothermic thermal transition obtained by DSC scans showed three distinct unfolding behaviors at different water contents. Using SWAXS and Raman spectroscopy, we investigated reversibility of the unfolding for each hydration regime for various structural levels including overall molecular shape, secondary structure, hydrophobic and hydrogen bonding interactions. In the substantially dehydrated state below 37 wt% of water the unfolding is an irreversible process and can be described by a kinetic approach; above 60 wt% the process is reversible, and the thermodynamic equilibrium approach is applied. In the intermediate range of water contents between 37 wt% and 60 wt%, the system is phase separated and the thermal denaturation involves two processes: melting of protein crystals and unfolding of protein molecules. A phase diagram of thermal unfolding/denaturation in lysozyme - water system was constructed based on the experimental data.     

Dissociative mechanism of F-actin thermal denaturation

We have applied differential scanning calorimetry to investigate thermal unfolding of F-actin. It has been shown that the thermal stability of F-actin strongly depends on ADP concentration. The transition temperature, T(m), increases with increasing ADP concentration up to 1 mM. The T(m) value also depends on the concentration of F-actin: it increases by almost 3 degrees C as the F-actin concentration is increased from 0.5 to 2.0 mg/ml. Similar dependence of the T(m) value on protein concentration was demonstrated for F-actin stabilized by phalloidin, whereas it was much less pronounced in the presence of AlF4(-). However, T(m) was independent of protein concentration in the case of monomeric G-actin. The results suggest that at least two reversible stages precede irreversible thermal denaturation of F-actin; one of them is dissociation of ADP from actin subunits, and another is dissociation of subunits from the ends of actin filaments. The model explains why unfolding of F-actin depends on both ADP and protein concentration.     

Reduced ribosomal thermal denaturation in Listeria monocytogenes following osmotic and heat shocks

Abstract Increased thermotolerance of Listeria monocytogenes induced by exposure to a high NaCl concentration or a sublethal heat shock was concurrent with increased thermal stability of the 30S ribosomal subunit as measured by differential scanning calorimetry. It is proposed that protection of the 30S subunit is a critical mechanism for increased thermotolerance.     

No salting-in of lysozyme chloride observed at low ionic strength over a large range of pH.

Solubility of lysozyme chloride was determined in the absence of added salt and in the presence of 0.05-1.2 M NaCl, starting from isoionic lysozyme, which was then brought to pH values from 9 to 3 by addition of HCl. The main observation is the absence of a salting-in region whatever the pH studied. This is explained by a predominant electrostatic screening of the positively charged protein and/or by adsorption of chloride ions by the protein. The solubility increases with the protein net charge at low ionic strength, but the reverse is observed at high ionic strength. The solubility of lysozyme chloride seems to become independent of ionic strength at pH approximately 9.5, which is interpreted as a shift of the isoionic pH (10.8) to an isoelectric pH due to chloride binding. The crystallization at very low ionic strength, where lysozyme crystallizes at supersaturation values as low as 1.1, amplifies the effect of pH on protein solubility. Understanding the effect of the net charge and of ionic strength on protein-protein interactions is valuable not only for protein crystal growth but more generally also for the formation of protein-protein or protein-ligand complexes.     

Bovine lactoperoxidase - a versatile one- and two-electron catalyst of high structural and thermal stability

Lactoperoxidase (LPO), a member of the peroxidase-cyclooxygenase superfamily, is found in multiple human exocrine secretions and acts as a first line of defense against invading microorganisms by production of antimicrobial oxidants. Because of its ability to efficiently catalyze one- and two-electron oxidation reactions of inorganic and organic compounds, the heme peroxidase is widely used in food biotechnology, cosmetic industry, and diagnostic kits. In order to probe its structural integrity, conformational, and thermal stability, we have undertaken a comprehensive investigation by using complementary biophysical techniques including UV-Vis, circular dichroism and fluorescence spectroscopy as well as differential scanning calorimetry (DSC). The oxidoreductase exhibits a high chemical and thermal stability under oxidizing conditions but is significantly destabilized by addition of DTT. Due to its unique ester bonds between the prosthetic group and the protein as well as six intra-chain disulfides, unfolding of the central compact (-helical core occurs concomitantly with denaturation of the heme cavity. The corresponding enthalpic and entropic contributions to the free enthalpy of unfolding are presented. Together with spectroscopic data they will be discussed with respect to the known structure of bovine LPO and homologous myeloperoxidase as well as to its practical application.     

Differential scanning calorimetric and spectroscopic studies on the unfolding of Momordica charantia lectin. Similar modes of thermal and chemical denaturation

Thermal stability of Momordica charantia seed lectin (MCL) was investigated as a function of protein concentration, pH, scan rate, and at different ligand concentrations by using high-sensitivity differential scanning calorimetry (DSC). The DSC endotherm obtained at pH 7.4 consists of two entities with transition temperatures at ca. 333.7 K, and 338 K. The unfolding process is irreversible and could be described by a three-state model. For MCL tetramer ΔH_c/ΔH_v ratio is close to 4 for the first transition and ∼2 for the second transition, suggesting that four and two cooperative units are involved in the first and second transitions, respectively. In the presence of lactose both transitions shifted to higher temperatures, suggesting that ligand binds preferentially to the native conformation of MCL. Endotherms recorded as a function of pH indicate that MCL is more stable at lower pH. Chemical unfolding of MCL, induced by Gdn.HCl, was investigated by monitoring the intrinsic fluorescence properties of the protein. The results obtained indicate that chemical denaturation of MCL can also be described by a three-state process, involving an intermediate populated at ∼3–4 M Gdn.HCl. These observations suggest that the chemical and thermal unfolding processes are similar in that both of them proceed via an intermediate. The far UV and near UV CD spectra of MCL were nearly identical at different pH values and indicate that its secondary and tertiary structure do not change significantly with pH, suggesting that the structure of the protein is stable over a wide pH range.     

Use of critical point polyacrylamide sols in thermal denaturation experiments with chromatin at physiological ionic strength

Low percentage highly crosslinked polyacrylamide gels just above the critical point in the chemically polymerized sol to gel transition are used to generate polyacrylamide sols at critical point concentrations, 7.4 g liter-1, by mild heating. We find that chromatin samples mixed with these sols induce the sol to gel transition in a process of complex coacervation. In this state, salt insoluble chicken erythrocyte chromatin is stabilized against large scale aggregation and precipitation during thermal denaturation at physiological sodium ion concentrations. The hyperchromic melting behavior of DNA in polyacrylamide sols is reproducible and consistent throughout a wide range of sodium chloride concentrations. Empirical spectroscopic techniques are discussed which isolate temperature-dependent hyperchromic signals at 260 nm due to conformational changes of DNA in chromatin and local environmental changes which promote anomalous light scattering.     

Temperature stability of proteins: Analysis of irreversible denaturation using isothermal calorimetry

The structural stability of proteins has been traditionally studied under conditions in which the folding/unfolding reaction is reversible, since thermodynamic parameters can only be determined under these conditions. Achieving reversibility conditions in temperature stability experiments has often required performing the experiments at acidic pH or other nonphysiological solvent conditions. With the rapid development of protein drugs, the fastest growing segment in the pharmaceutical industry, the need to evaluate protein stability under formulation conditions has acquired renewed urgency. Under formulation conditions and the required high protein concentration (～100 mg/mL), protein denaturation is irreversible and frequently coupled to aggregation and precipitation. In this article, we examine the thermal denaturation of hen egg white lysozyme (HEWL) under irreversible conditions and concentrations up to 100 mg/mL using several techniques, especially isothermal calorimetry which has been used to measure the enthalpy and kinetics of the unfolding and aggregation/precipitation at 12°C below the transition temperature measured by DSC. At those temperatures the rate of irreversible protein denaturation and aggregation of HEWL is measured to be on the order of 1 day^?1. Isothermal calorimetry appears a suitable technique to identify buffer formulation conditions that maximize the long term stability of protein drugs.     

Slow aggregation of lysozyme in alkaline pH monitored in real time employing the fluorescence anisotropy of covalently labelled dansyl probe

The onset of hen egg white lysozyme aggregation on exposure to alkaline pH of 12.2 and subsequent slow growth of soluble lysozyme aggregates (at 298 K) was directly monitored by steady-state and time-resolved fluorescence anisotropy of covalently attached dansyl probe over a period of 24 h. The rotational correlation time accounting for tumbling of lysozyme in solution (40 microM) increased from approximately 3.6 ns (in pH 7) to approximately 40ns on exposure to pH 12.2 over a period of 6 h and remained stable thereafter. The growth of aggregates was strongly concentration dependent, irreversible after 60 min and inhibited by the presence of 0.9 M l-arginine in the medium. The day old aggregates were resistant to denaturation by 6 M guanidine.HCl. Our results reveal slow segmental motion of the dansyl probe in day old aggregates in the absence of L-arginine (0.9 M), but a much faster motion in its presence, when growth of aggregates is halted.     

Irreversible thermal denaturation of Torpedo californica acetylcholinesterase.

Thermal denaturation of Torpedo californica acetylcholinesterase, a disulfide-linked homodimer with 537 amino acids in each subunit, was studied by differential scanning calorimetry. It displays a single calorimetric peak that is completely irreversible, the shape and temperature maximum depending on the scan rate. Thus, thermal denaturation of acetylcholinesterase is an irreversible process, under kinetic control, which is described well by the two-state kinetic scheme N-->D, with activation energy 131 +/- 8 kcal/mol. Analysis of the kinetics of denaturation in the thermal transition temperature range, by monitoring loss of enzymic activity, yields activation energy of 121 +/- 20 kcal/mol, similar to the value obtained by differential scanning calorimetry. Thermally denatured acetylcholinesterase displays spectroscopic characteristics typical of a molten globule state, similar to those of partially unfolded enzyme obtained by modification with thiol-specific reagents. Evidence is presented that the partially unfolded states produced by the two different treatments are thermodynamically favored relative to the native state.