Kinetics of reconstitution of porcein muscle lactic dehydrogenase after reversible high pressure dissociation

Pressure tolerance of deep-sea enzymes can be evolved through increasing volume changes in protein transitions: a study with lactate dehydrogenases from abyssal and hadal fishes

We explore the principles of pressure tolerance in enzymes of deep-sea fishes using lactate dehydrogenases (LDH) as a case study. We compared the effects of pressure on the activities of LDH from hadal snailfishes Notoliparis kermadecensis and Pseudoliparis swirei with those from a shallow-adapted Liparis florae and an abyssal grenadier Coryphaenoides armatus. We then quantified the LDH content in muscle homogenates using mass-spectrometric determination of the LDH-specific conserved peptide LNLVQR. Existing theory suggests that adaptation to high pressure requires a decrease in volume changes in enzymatic catalysis. Accordingly, evolved pressure tolerance must be accompanied with an important reduction in the volume change associated with pressure-promoted alteration of enzymatic activity ( Δ V PP ∘ ). Our results suggest an important revision to this paradigm. Here, we describe an opposite effect of pressure adaptation-a substantial increase in the absolute value of Δ V PP ∘ in deep-living species compared to shallow-water counterparts. With this change, the enzyme activities in abyssal and hadal species do not substantially decrease their activity with pressure increasing up to 1-2 kbar, well beyond full-ocean depth pressures. In contrast, the activity of the enzyme from the tidepool snailfish, L. florae, decreases nearly linearly from 1 to 2500 bar. The increased tolerance of LDH activity to pressure comes at the expense of decreased catalytic efficiency, which is compensated with increased enzyme contents in high-pressure-adapted species. The newly discovered strategy is presumably used when the enzyme mechanism involves the formation of potentially unstable excited transient states associated with substantial changes in enzyme-solvent interactions.

Effect of high-pressure processing on activity and structure of alkaline phosphatase and lactate dehydrogenase in buffer and milk

Changes in the activity and structure of alkaline phosphatase (ALP) and L-lactate dehydrogenase (LDH) were investigated after high pressure processing (HPP). HPP treatments (206-620 MPa for 6 and 12 min) were applied to ALP and LDH prepared in buffer, fat-free milk, and 2% fat milk. Enzyme activities were measured using enzymatic assays, and changes in structure were investigated using far-ultraviolet circular dichroism (CD) spectroscopy and dynamic light scattetering (DLS). Kinetic data indicated that the activity of ALP was not affected after 6 min of pressure treatments (206-620 MPa), regardless of the medium in which the enzyme was prepared. Increasing the processing time to 12 min did significantly reduce the activity of ALP at 620 MPa (P < 0.001). However, even the lowest HPP treatment of 206 MPa induced a reduction in LDH activity, and the course of reduction increased with HPP treatment until complete inactivation at 482, 515, and 620 MPa. CD data demonstrated a partial change in the secondary structure of ALP at 620 MPa, whereas the structure of LDH showed gradual denaturation after exposure at 206 MPa for 6 min, leading to a random coil structure at both 515 and 620 MPa. DLS results indicated aggregation of ALP only at HPP treatment of 206 MPa and not above and enzyme precipitation as well as aggregation at 345, 415, 482, and 515 MPa. The loss of LDH activity with increasing pressure and time treatment was due to the combined effects of denaturation and aggregation.

Subunit dissociation and inactivation of pyruvate kinase by hydrostatic pressure oxidation of sulfhydryl groups and ligand effects on enzyme stability

The effect of hydrostatic pressure on the stability of tetrameric rabbit muscle pyruvate kinase was investigated by enzyme activity measurements, size-exclusion chromatography, circular dichroism and fluorescence spectroscopies. Under nonreducing conditions, enzyme activity was irreversibly inhibited by increasing pressure and was completely abolished at 350 MPa. Inhibition was dependent on the concentration of pyruvate kinase, indicating that it was related to pressure-induced subunit dissociation. Size-exclusion chromatography of pressurized samples confirmed a decrease in the proportion of tetramers and an increase in monomers relative to native samples. Addition of dithiothreitol immediately following pressure release led to full recovery of both enzyme activity and of native tetramers. Furthermore, no irreversible inhibition of pyruvate kinase was observed if pressure treatment was carried out in the presence of dithiothreitol. These data suggest that pressure-dissociated monomers undergo conformational changes leading to oxidation of sulfhydryl groups, which prevents correct refolding of native tetramers on decompression. These conformational changes are relatively subtle, as indicated by the lack of significant changes in far-UV circular dichroism and intrinsic fluorescence emission spectra of previously pressurized samples. The effects of various physiological ligands on the pressure stability of pyruvate kinase were also investigated. A slight protection against inhibition was observed in the simultaneous presence of K+, Mg2+ and ADP. Both phosphoenolpyruvate and the allosteric inhibitor, phenylalanine, caused marked stabilization against pressure, suggesting significant energy coupling between binding of these ligands and stabilization of the tetramer.

The statistical-thermodynamic basis for computation of binding affinities: a critical review

Although the statistical thermodynamics of noncovalent binding has been considered in a number of theoretical papers, few methods of computing binding affinities are derived explicitly from this underlying theory. This has contributed to uncertainty and controversy in certain areas. This article therefore reviews and extends the connections of some important computational methods with the underlying statistical thermodynamics. A derivation of the standard free energy of binding forms the basis of this review. This derivation should be useful in formulating novel computational methods for predicting binding affinities. It also permits several important points to be established. For example, it is found that the double-annihilation method of computing binding energy does not yield the standard free energy of binding, but can be modified to yield this quantity. The derivation also makes it possible to define clearly the changes in translational, rotational, configurational, and solvent entropy upon binding. It is argued that molecular mass has a negligible effect upon the standard free energy of binding for biomolecular systems, and that the cratic entropy defined by Gurney is not a useful concept. In addition, the use of continuum models of the solvent in binding calculations is reviewed, and a formalism is presented for incorporating a limited number of solvent molecules explicitly.

Proteins under pressure. The influence of high hydrostatic pressure on structure, function and assembly of proteins and protein complexes

Oceans not only cover the major part of the earth's surface but also reach into depths exceeding the height of the Mt Everest. They are populated down to the deepest levels (approximately 11,800 m), which means that a significant proportion of the global biosphere is exposed to pressures of up to 120 MPa. Although this fact has been known for more than a century, the ecology of the 'abyss' is still in its infancy. Only recently, barophilic adaptation, i.e. the requirement of elevated pressure for viability, has been firmly established. In non-adapted organisms, increased pressure leads to morphological anomalies or growth inhibition, and ultimately to cell death. The detailed molecular mechanism of the underlying 'metabolic dislocation' is unresolved. Effects of pressure as a variable in microbiology, biochemistry and biotechnology allow the structure/function relationship of proteins conjugates to be analyzed. In this context, stabilization by cofactors or accessory proteins has been observed. High-pressure equipment available today allows the comprehensive characterization of the behaviour of proteins under pressure. Single-chain proteins undergo pressure-induced denaturation in the 100-MPa range, which, in the case of oligomeric proteins or protein assemblies, is preceded by dissociation at lower pressure. The effects may be ascribed to the positive reaction volumes connected with the formation of hydrophobic and ionic interactions. In addition, the possibility of conformational effects exerted by moderate, non-denaturing pressures, and related to the intrinsic compressibility of proteins, is discussed. Crystallization may serve as a model reaction of protein self-organization. Kinetic aspects of its pressure-induced inhibition can be described by a model based on the Oosawa theory of molecular association. Barosensitivity is known to be correlated with the pressure-induced inhibition of protein biosynthesis. Attempts to track down the ultimate cause in the dissociation of ribosomes have revealed remarkable stabilization of functional complexes under pseudo-physiological conditions, with the post-translational complex as the most pressure-sensitive species. Apart from the key issue of barosensitivity and barophilic adaptation, high-pressure biochemistry may provide means to develop new approaches to nonthermic industrial processes, especially in the field of food technology.

myo-inositol oxygenase from rat kidneys. Substrate-dependent oligomerization

myo-Inositol from rat kidneys, an oligomeric protein with apparent molecular mass of about 270 kDa can be dissociated under mild conditions to structured 16.8-kDa monomers. This dissociation can be reversed at high protein concentrations at room temperature. The corresponding apparent dimerization constant K2app = 1.38 x 10(5) M-1, the corresponding rate constant k2 = 350 s-1.M-1, and the apparent constant for the association of dimers, K4app = 2.7 x 10(6) M-1. Reassociation is significantly enhanced in the presence of the substrate and iron(II) (K2app = 9.8 x 10(5) M-1; K4app = 3.75 x 10(6) M-1, k2 = 1750 s-1.M-1, at 20 mM myo-inositol and 0.5 mM FeSO4). Under these conditions almost 100% of the original enzymatic activity was reconstituted. Monomers, with or without bound ligands, lack catalytic activity, whereas the dimer is likely to be the elementary active enzyme-building unit. The effects of myo-inositol on the dimerization lead to the conclusion that this step is both mediated and facilitated by the substrate.

A reactor permitting injection and sampling for steady state studies of enzymatic reactions at high pressure: tests with aspartate transcarbamylase

A high pressure reactor for steady state studies of enzymes is described. It allows injection, stirring, and sampling without release of the pressure (up to at least 400 MPa). Thus, either substrate or enzyme can be injected to initiate an enzyme-catalyzed reaction whose progress can then be followed by measurements on samples taken from the reactor. The dead time of sampling is 10-15 s, which allows reactions with pseudo-first-order rate constants smaller than about 1 min-1 to be monitored. It can be used for any enzymatic reaction; unlike previously described high pressure apparatus, it is not limited to the study of enzymes whose activity can be directly followed by spectrophotometry. The use and reliability of this reactor is demonstrated by tests with aspartate transcarbamylase. The activity of this enzyme is enhanced by pressures of the order of 120 MPa.

Kinetics of pressure-induced inactivation of bovine liver glutamate dehydrogenase

Kinetics of pressure-induced denaturation of bovine liver glutamate dehydrogenase (EC 1.4.1.3) were investigated in the pressure range 1.8-2.8 kbar by observing the residual activity after the pressure-release and the scattered light intensity during the incubation at high pressure. The residual activity decreased exponentially with the incubation time, whereas the scattered light intensity showed a bimodal profile indicating parallel aggregation and dissociation reactions. The latter suggested that two kinds of aggregates were formed during the incubation under pressure. The observed first-order rate constant for the inactivation, k obs, showed a minimum around 30 degrees C. These experimental results were interpreted in terms of the following reaction scheme; (formula; see text) where N represents the enzyme entity with native structure, D1 the partially denatured intermediate, D2 the irreversibly denatured state, and A1 and A2 the two kinds of aggregates, one of which (A1) is reversibly formed at an early stage of the incubation under high pressure. The apparent activation volume for the inactivation reaction was estimated to be delta V*app = -113 +/- 5 cm3 X mol-1 from the pressure dependence of k obs. The effect of coenzyme, NAD+, on the pressure-induced inactivation was also studied. The inactivation was retarded by the presence of the coenzyme, whereas the apparent activation volume for the holoenzyme (delta V*app = -104 +/- 2 cm3 X mol-1) did not differ significantly from that for the apoenzyme.

High pressure dissociation of lactate dehydrogenase from Bacillus stearothermophilus and reconstitution of the enzyme after denaturation in 6 M guanidine hydrochloride

Tetrameric lactate dehydrogenase from Bacillus stearothermophilus exhibits unusual stability towards high hydrostatic pressure: In contrast to the mesophilic enzyme, incubation at pressures up to 2.8 kbar does not cause irreversible denaturation. Hybridization under these conditions suggests partial dissociation to the dimer, indicating that reassociation occurs within the dead-time after pressure release (less than 20 s at less than or equal to 40 micrograms/ml, 20 degrees C). Incubation at P less than 2.8 kbar affects neither the native quaternary structure nor the catalytic function of the enzyme. Reconstitution of the unfolded and dissociated subunits after denaturation, e.g., in 6 M guanidine . HC1, is characterized by fast association favouring the native assembled structure. Evidence from spectroscopic measurements shows that reconstitution starts with a fast refolding reaction generating a native-like conformation. The subsequent rate-determining transconformation of the "structured monomers" governs the kinetics of reactivation and reassociation as one single first-order process. Chemical crosslinking with glutaraldehyde proves that the "structured monomers" undergo fast association to form the tetrameric final state of reconstitution, with significant amounts of dimeric intermediates being detectable. The renatured enzyme is indistinguishable from the native enzyme regarding its physicochemical and enzymological properties (e.g., activation by fructose-1,6-bisphosphate, and susceptibility towards proteolytic digestion).

High-pressure dissociation of the beta 2-dimer of tryptophan synthase from Escherichia coli monitored by sucrose gradient centrifugation

The isolated beta 2-dimer of Escherichia coli tryptophan synthase exhibits reversible high-pressure deactivation and hybridization with an equilibrium transition at 690 and 870 bar for the apoenzyme and holoenzyme, respectively. To investigate the hypothetical dissociation mechanism ultracentrifugal analysis has been applied. In a conventional swing-out rotor (r(max) = 16 cm, fill-height 9 cm) a pressure gradient of 1 less than p less than 1840 bar is formed at maximum speed (40 000 rpm). Using a sucrose gradient to stabilize the particle distribution, pressure-dependent alterations of the state of association of oligomeric systems may be determined. In the present experiments ovalbumin (with a molecular mass close to the beta-monomer) has been used as a reference. The radial sedimentation velocity of the beta 2-dimer (in 5-20% sucrose, 10 degrees C) is found to decrease significantly at p approximately equal to 850 bar. From the slopes in an r-r(degrees) vs t plot the limiting values for the particle weight at the meniscus and the bottom of the tube are found to be the beta 2-dimer (M(r) = 85 800) and the beta-monomer (M(r) = 42 900), thus proving pressure-dependent dissociation. Since sucrose stabilizes the native quaternary structure, the beta 2 leads to 2 beta transition is shifted towards higher pressures compared to the dissociation in standard buffer. Conventional quench experiments in high-pressure cells in the presence of 13% (w/v) sucrose confirm the result of the sucrose gradient centrifugation with respect to the critical pressure where deactivation (and dissociation) occur.

The effect of high pressure upon proteins and other biomolecules

We shall not attempt here to enumerate the results or review in a systematic way the significant literature dealing with the use of high pressure in studies of proteins and other molecules of biological interest. Two recent reviews on this subject, one by MOrild (1981) and another by Heremans (1982), and a further article by Jaenicke (1981) on enzymes under extreme environmental conditions contain expositions and references that would render redundatn such a task. Rather we concentrate here on the examination of othe conceptual framework employed in the interpretation of high pressure experiments and in the critical discussion of our knowledge of selected areas of present interest and likely future significance.

Thermodynamics and mechanism of high-pressure deactivation and dissociation of porcine lactic dehydrogenase

Lactic dehydrogenase (LDH) from pig heart and pig skeletal muscle can be reversibly dissociated into monomers at high hydrostatic pressure. The reaction can be quantitatively fitted by a reversible consecutive dissociation-unfolding mechanism according to N in equilibrium 4M in equilibrium 4M (where N is the native tetramer, and M and M two different conformations of the monomer) (K. Müller, et al., Biophys. Chem. 14 (1981) 101.). At p less than or equal to 1 kbar, the pressure deactivation of both isoenzymes (H4 and M4) is described by the two-state equilibrium N in equilibrium 4M. From the respective equilibrium constant and the temperature and pressure dependence of the change in free energy, the thermodynamic parameters of the dissociation/deactivation may be determined, e.g., for LDH-M4: delta GDiss = 110 kJ/mol, delta SDiss =-860 J/K per mol, delta HDiss= -124 kJ/mol (enzyme concentration 10 microgram/ml, in Tris-HCl buffer, pH 7.6, I = 0.16 M, 293 K, 0.8 kbar); the dissociation volume is found to be delta VDiss =-420 ml/mol (0.7 less than p less than 0.9 kbar). Measurements using 8-anilino-1-naphthalenesulfonic acid (ANS) as extrinsic fluorophore demonstrate that the occurrence of hydrophobic surface area upon dissociation parallels the decrease in reactivation yield after pressurization beyond 1 kbar. Within the range of reversible deactivation (p less than 1 kbar) no increase in ANS fluorescence is detectable, thus indicating compensatory effects in the process of subunit dissociation. 2H2O is found to stabilize the enzyme towards pressure dissociation, in accordance with the involvement of hydrophobic interactions in the subunit contact of both isoenzymes of LDH.

Reconstitution of the isolated beta2-subunit of tryptophan synthase from Escherichia coli after dissociation induced by high hydrostatic pressure. Equilibrium and kinetic studies

The isolated beta2-subunit of Escherichia coli tryptophan synthase can be reversibly dissociated into enzymically inactive monomers under high hydrostatic pressure. Deactivation at 1.5 kbar which shows a half-time of 11 min (rate constant k=10 (-3) s (-1) is paralleled by dissociation with a small lag phase of about 5 min. Pressure release leads to 95 +/- 5% recovery of specific activity and complete restoration of the hydrodynamic and spectral properties which specify the native dimer. Over the concentration range 1-100 micrograms/ml (0.02-2.3 micrograms M) the kinetics of reactivation can be fitted by one apparent first-order rate constant (k=6.5 +/- 0.6 X 10 (-4) s (-1), half-time = 17.5 min). The reconstitution of catalytic activity is paralleled by alterations in tryptophan fluorescence at 327 nm, thus presenting direct evidence for conformational changes in the direct vicinity of the active center (k1 = 1.9 X 10 (-3) s(-1), k2 = 6.5 +/- 0.6 X 10(-4) s (-1) ). On the other hand, a definite mechanism of reactivation requires the association of the refolding monomers to be included. The kinetics of dimerization have been followed via hybridization between native and chemically modified beta-chains, yielding an apparent first-order rate constant of 6.3 +/- 0.6 X 10 (-4) s (-1). As a consequence, we propose a sequential uni-uni-bimolecular mechanism, which is characterized by a minimum of two conformational changes in substantially structured monomers followed by a fast dimerization reaction to yield the active beta2-subunit.

Pressure-induced structural changes of pig heart lactic dehydrogenase

Lactic dehydrogenase from pig heart can be reversibly dissociated at hydrostatic pressures above 1000 bar. The breakdown of the native quaternary structure occurs at lower pressures compared to the isoenzyme from pig skeletal muscle. As shown by hybridization experiments of the two isoenzymes the final product of dissociation is the homogeneous monomer. Fluorescence emission spectra of the monomeric enzyme at elevated pressure are characterized by a decrease in fluorescence intensity without any red shift, indicating that no significant unfolding occurs upon high-pressure dissociation. The spectral changes are comparable to those observed after acid dissociation. The amount and rate of deactivation depend on pressure and on the conditions of the solvent. The presence of various anions (C1-, SO2-/4, HPO2-/4) has no effect on the stability of the enzyme towards pressure. High-pressure denaturation (as monitored by intrinsic protein fluorescence), and deactivation (measured immediately after decompression) run parallel; the pressure dependence of their first-order rate constants is characterized by an activation volume delta V not equal to De = - 140 +/- 10 cm3/mol. As taken from the yield of reconstitution, dissociation, denaturation and deactivation are found to be fully reversible provided the pressure does not exceed a limiting value (p = 1000 bar in Tris, pH 7.6; 24 h incubation at 20 degrees C). After extended incubation beyond the limiting pressure of 1000 bar, "irreversible high-pressure denaturation" occurs which is accompanied by partial aggregation after decompression. The coenzyme, NAD+, stabilizes the native tetramer shifting the dissociation equilibrium to higher pressures. The overall dissociation-association reaction can be quantitatively described by a consecutive dissociation/unfolding mechanism N in equilibrium 4 M' in equilibrium 4 M* (where N is the native tetramer, and M' and M* two different conformations of the monomer). The reaction volume of the dissociation reaction N in equilibrium 4 M' is found to be delta V Diss = - 360 +/- 30 cm3/mol; as indicated by the pressure dependence of the yield of reconstitution, the reaction volume of the equilibrium M' in equilibrium M* is also negative.