Trimethylamine N-oxide suppresses the activity of the actomyosin motor

Background

During actomyosin interactions, the transduction of energy from ATP hydrolysis to motility seems to occur with the modulation of hydration. Trimethylamine N-oxide (TMAO) perturbs the surface of proteins by altering hydrogen bonding in a manner opposite to that of urea. Hence, we focus on the effects of TMAO on the motility and ATPase activation of actomyosin complexes.

Methods

Actin and heavy meromyosin (HMM) were prepared from rabbit skeletal muscle. Structural changes in HMM were detected using fluorescence and circular dichroism spectroscopy. The sliding velocity of rhodamine-phalloidin-bound actin filaments on HMM was measured using an in vitro motility assay. ATPase activity was measured using a malachite green method.

Results

Although TMAO, unlike urea, stabilized the HMM structure, both the sliding velocity and ATPase activity of acto-HMM were considerably decreased with increasing TMAO concentrations from 0–1.0 M. Whereas urea-induced decreases in the structural stability of HMM were recovered by TMAO, TMAO further decreased the urea-induced decrease in ATPase activation. Urea and TMAO were found to have counteractive effects on motility at concentrations of 0.6 M and 0.2 M, respectively.

Conclusions

The excessive stabilization of the HMM structure by TMAO may suppress its activities; however, the counteractive effects of urea and TMAO on actomyosin motor activity is distinct from their effects on HMM stability.

General significance

The present results provide insight into not only the water-related properties of proteins, but also the physiological significance of TMAO and urea osmolytes in the muscular proteins of water-stressed animals.     

Time-dependent effects of trimethylamine-N-oxide/urea on lactate dehydrogenase activity: an unexplored dimension of the adaptation paradigm.

Given that enzymes in urea-rich cells are believed to be just as sensitive to urea effects as enzymes in non-urea-rich cells, it is argued that time-dependent inactivation of enzymes by urea could become a factor of overriding importance in the biology of urea-rich cells. Time-independent parameters (e.g. Tm, k(cat), and Km) involving protein stability and enzyme function have generally been the focus of inquiries into the efficacy of naturally occurring osmolytes like trimethylamine-N-oxide (TMAO), to offset the deleterious effects of urea on the intracellular proteins in the urea-rich cells of elasmobranchs. However, using urea concentrations found in urea-rich cells of elasmobranches, we have found time-dependent effects on lactate dehydrogenase activity which indicate that TMAO plays the important biological role of slowing urea-induced dissociation of multimeric intracellular proteins. TMAO greatly diminishes the rate of lactate dehydrogenase dissociation and affords significant protection of the enzyme against urea-induced time-dependent inactivation. The effects of TMAO on enzyme inactivation by urea adds a temporal dimension that is an important part of the biology of the adaptation paradigm.     

Measuring the stability of partly folded proteins using TMAO

Standard methods for measuring free energy of protein unfolding by chemical denaturation require complete folding at low concentrations of denaturant so that a native baseline can be observed. Alternatively, proteins that are completely unfolded in the absence of denaturant can be folded by addition of the osmolyte trimethylamine N-oxide (TMAO), and the unfolding free energy can then be calculated through analysis of the refolding transition. However, neither chemical denaturation nor osmolyte-induced refolding alone is sufficient to yield accurate thermodynamic unfolding parameters for partly folded proteins, because neither method produces both native and denatured baselines in a single transition. Here we combine urea denaturation and TMAO stabilization as a means to bring about baseline-resolved structural transitions in partly folded proteins. For Barnase and the Notch ankyrin domain, which both show two-state equilibrium unfolding, we found that DeltaG degrees for unfolding depends linearly on TMAO concentration, and that the sensitivity of DeltaG degrees to urea (the m-value) is TMAO independent. This second observation confirms that urea and TMAO exert independent effects on stability over the range of cosolvent concentrations required to bring about baseline-resolved structural transitions. Thermodynamic parameters calculated using a global fit that assumes additive, linear dependence of DeltaG degrees on each cosolvent are similar to those obtained by standard urea-induced unfolding in the absence of TMAO. Finally, we demonstrate the applicability of this method to measurement of the free energy of unfolding of a partly folded protein, a fragment of the full-length Notch ankyrin domain.     

Activation of halophilic nucleoside diphosphate kinase by a non-ionic osmolyte,trimethylamine N-oxide

The folding and activity of halophilic enzymes are believed to require the presence of salts at high concentrations. When the inactivated nucleoside diphosphate kinase (NDK) from extremely halophilic archaea was incubated with low salt media, no activity was regained over the course of 8 days. When it was incubated with 2 M NaCl or 3 M KCl, however, it gradually regained activity. To our surprise, trimethylamine N-oxide (TMAO) also was able to induce activation at 4.0 M. The enzyme activity and secondary structure of refolded NDK in 4 M TMAO were comparable with those of the native NDK or the refolded NDK in 3.8 M NaCl. TMAO is not an electrolyte, meaning that the presence of concentrated salts is not an absolute requirement, and that charge shielding or ion binding is not a sole factor for the folding and activation of NDK. Although both NaCl and TMAO are effective in refolding NDK, the mechanism of their actions appears to be different: the effect of protein concentration and pH on refolding is qualitatively different between these two, and at pH 8.0 NDK could be refolded in the presence of 4 M TMAO only when low concentrations of NaCl are included.     

Hydrogen exchange kinetics of RNase A and the urea:TMAO paradigm

A key paradigm in the biology of adaptation holds that urea affects protein function by increasing the fluctuations of the native state, while trimethylamine N-oxide (TMAO) affects function in the opposite direction by decreasing the normal fluctuations of the native ensemble. Using urea and TMAO separately and together, hydrogen exchange (HX) studies on RNase A at pH* 6.35 were used to investigate the basic tenets of the urea:TMAO paradigm. TMAO (1 M) alone decreases HX rate constants of a select number of sites exchanging from the native ensemble, and low urea alone increases the rate constants of some of the same sites. Addition of TMAO to urea solutions containing RNase A also suppresses HX rate constants. The data show that urea and TMAO independently or in combination affect the dynamics of the native ensemble in opposing ways. The results provide evidence in support of the counteraction aspect of the urea:TMAO paradigm linking structural dynamics with protein function in urea-rich organs and organisms. RNase A is so resistant to urea denaturation at pH* 6.35 that even in the presence of 4.8 M urea, the native ensemble accounts for >99.5% of the protein. An essential test, devised to determine the HX mechanism of exchangeable protons, shows that over the 0-4.8 M urea concentration range nearly 80% of all observed sites convert from EX2 to EX1. The slow exchange sites are all EX1; they do not exhibit global exchange even at urea concentrations (5.8 M) well into the denaturation transition zone, and their energetically distinct activated complexes leading to exchange gives evidence of residual structure. Under these experimental conditions, the use of DeltaG(HX) as a basis for HX analysis of RNase A urea denaturation is invalid.     

Inhibition of cytokinin-induced plant growth by jasmonic acid and its methyl ester

Effects of jasmonic acid, methyl jasmonate and ABA on cytokinin-induced soybean ( Glycine max Merrill cv. Kingen No. 1) callus growth and radish ( Raphanus sativus L. cv. Comet) cotyledon growth were studied. Jasmonic acid and methyl jasmonate were powerful inhibitors of kinetin- or N-phenyl-N'-(2-chloro-4-pyridyl)urea-induced soybean callus growth, the former being more effective than the latter, especially at low concentrations (0.45 to 4.5 μ M ). These compounds could completely eliminate kinetin- or N-phenyl-N'-(2-chloro-4-pyridyl)urea-induced soybean callus growth at 45 μ M . At low concentrations ABA had no effect but at 450 μ M it completely eliminated callus growth induced by kinetin. Of the compounds tested ABA was the most powerful inhibitor of radish cotyledon growth in the presence or absence of kinetin. Jasmonic acid and methyl jasmonate were much less effective than ABA in this assay system.     

Counteracting osmolyte trimethylamine N-oxide destabilizes proteins at pH below its pKa. Measurements of thermodynamic parameters of proteins in the presence and absence of trimethylamine N-oxide

Earlier studies have reported that trimethylamine N-oxide (TMAO), a naturally occurring osmolyte, is a universal stabilizer of proteins because it folds unstructured proteins and counteracts the deleterious effects of urea and salts on the structure and function of proteins. This conclusion has been reached from the studies of the effect of TMAO on proteins in the pH range 6.0-8.0. In this pH range TMAO is almost neutral (zwitterionic form), for it has a pK(a) of 4.66 +/- 0.10. We have asked the question of whether the effect of TMAO on protein stability is pH-dependent. To answer this question we have carried out thermal denaturation studies of lysozyme, ribonuclease-A, and apo-alpha-lactalbumin in the presence of various TMAO concentrations at different pH values above and below the pK(a) of TMAO. The main conclusion of this study is that near room temperature TMAO destabilizes proteins at pH values below its pK(a), whereas it stabilizes proteins at pH values above its pK(a). This conclusion was reached by determining the T(m) (midpoint of denaturation), delta H(m) (denaturational enthalpy change at T(m)), delta C(p) (constant pressure heat capacity change), and delta G(D) degrees (denaturational Gibbs energy change at 25 degrees C) of proteins in the presence of different TMAO concentrations. Other conclusions of this study are that T(m) and delta G(D) degrees depend on TMAO concentration at each pH value and that delta H(m) and the delta C(p) are not significantly changed in presence of TMAO.     

Trimethylamine N-oxide counteracts the denaturing effects of urea or GdnHCl on protein denatured state

To understand trimethylamine N-oxide (TMAO) attenuation of the denaturating effects of urea or guanidine hydrochloride (GdnHCl), we have determined the apparent transfer free energies (DeltaG(tr)(')) of cyclic dipeptides (CDs) from water to TMAO, urea or GdnHCl, and also the blends of TMAO and denaturants (urea or GdnHCl) at a 1:2 ratio as well as various denaturant concentrations in the presence of 1M TMAO, through the solubility measurements, at 25 degrees C. The CDs investigated in the present study included cyclo(Gly-Gly), cyclo(Ala-Ala) and cyclo(Val-Val). The observed DeltaG(tr)(') values indicate that TMAO can stabilize the CDs while urea or GdnHCl can destabilize the CDs. Furthermore, the DeltaG(tr)(') values of the blends of TMAO with urea or GdnHCl revealed that TMAO strongly counteracted the denaturating effects of urea on CDs in all instances, however, TMAO partially counteracted the perturbing effects of GdnHCl on CDs. TMAO counteraction ability of the deleterious effects of denaturants depended on the denaturant-CDs pair. The experimental results were further used to estimate the transfer free energies (Deltag(tr)(')) of the various functional group contributions from water to TMAO, urea or GdnHCl individually and to the combinations of TMAO and the denaturants in various ratios.     

Salting-in effects offset MgCL(2)-induced refolding of nucleoside diphosphate kinase

Previously we reported that halobacterial nucleoside diphosphate kinase can be refolded in the presence of concentrated trimethylamine N-oxide (TMAO) as well as NaCl, indicating that enhancement of compact structure formation by TMAO is sufficient for folding. Here we showed that the refolding effect of MgCl(2) is maximal at 1 M and declines to zero at 2 M, indicating that charge shielding effect of MgCl(2) is offset by its salting-in effect.     

A natural osmolyte trimethylamine N-oxide promotes assembly and bundling of the bacterial cell division protein, FtsZ and counteracts the denaturing effects of urea

Assembly of FtsZ was completely inhibited by low concentrations of urea and its unfolding occurred in two steps in the presence of urea, with the formation of an intermediate [Santra MK & Panda D (2003) J Biol Chem278, 21336-21343]. In this study, using the fluorescence of 1-anilininonaphthalene-8-sulfonic acid and far-UV circular dichroism spectroscopy, we found that a natural osmolyte, trimethylamine N-oxide (TMAO), counteracted the denaturing effects of urea and guanidium chloride on FtsZ. TMAO also protected assembly and bundling of FtsZ protofilaments from the denaturing effects of urea and guanidium chloride. Furthermore, the standard free energy changes for unfolding of FtsZ were estimated to be 22.5 and 28.4 kJ.mol(-1) in the absence and presence of 0.6 M TMAO, respectively. The data are consistent with the view that osmolytes counteract denaturant-induced unfolding of proteins by destabilizing the unfolded states. Interestingly, TMAO was also found to affect the assembly properties of native FtsZ. TMAO increased the light-scattering signal of the FtsZ assembly, increased sedimentable polymer mass, enhanced bundling of FtsZ protofilaments and reduced the GTPase activity of FtsZ. Similar to TMAO, monosodium glutamate, a physiological osmolyte in bacteria, which induces assembly and bundling of FtsZ filaments in vitro[Beuria TK, Krishnakumar SS, Sahar S, Singh N, Gupta K, Meshram M & Panda D (2003) J Biol Chem278, 3735-3741], was also found to counteract the deleterious effects of urea on FtsZ. The results together suggested that physiological osmolytes may regulate assembly and bundling of FtsZ in bacteria and that they may protect the functionality of FtsZ under environmental stress conditions.     

Trimethylamine-N-oxide counteracts urea effects on rabbit muscle lactate dehydrogenase function: a test of the counteraction hypothesis.

Trimethylamine-N-oxide (TMAO) in the cells of sharks and rays is believed to counteract the deleterious effects of the high intracellular concentrations of urea in these animals. It has been hypothesized that TMAO has the generic ability to counteract the effects of urea on protein structure and function, regardless of whether that protein actually evolved in the presence of these two solutes. Rabbit muscle lactate dehydrogenase (LDH) did not evolve in the presence of either solute, and it is used here to test the validity of the counteraction hypothesis. With pyruvate as substrate, results show that its Km and the combined Km of pyruvate and NADH are increased by urea, decreased by TMAO, and in 1:1 and 2:1 mixtures of urea:TMAO the Km values are essentially equivalent to the Km values obtained in the absence of the two solutes. In contrast, values of k(cat) and the Km for NADH as a substrate are unperturbed by urea, TMAO, or urea:TMAO mixtures. All of these effects are consistent with TMAO counteraction of the effects of urea on LDH kinetic parameters, supporting the premise that counteraction is a property of the solvent system and is independent of the evolutionary history of the protein.     

Osmolyte trimethylamine-N-oxide does not affect the strength of hydrophobic interactions: origin of osmolyte compatibility

Osmolytes are small organic solutes accumulated at high concentrations by cells/tissues in response to osmotic stress. Osmolytes increase thermodynamic stability of folded proteins and provide protection against denaturing stresses. The mechanism of osmolyte compatibility and osmolyte-induced stability has, therefore, attracted considerable attention in recent years. However, to our knowledge, no quantitative study of osmolyte effects on the strength of hydrophobic interactions has been reported. Here, we present a detailed molecular dynamics simulation study of the effect of the osmolyte trimethylamine-N-oxide (TMAO) on hydrophobic phenomena at molecular and nanoscopic length scales. Specifically, we investigate the effects of TMAO on the thermodynamics of hydrophobic hydration and interactions of small solutes as well as on the folding-unfolding conformational equilibrium of a hydrophobic polymer in water. The major conclusion of our study is that TMAO has almost no effect either on the thermodynamics of hydration of small nonpolar solutes or on the hydrophobic interactions at the pair and many-body level. We propose that this neutrality of TMAO toward hydrophobic interactions-one of the primary driving forces in protein folding-is at least partially responsible for making TMAO a "compatible" osmolyte. That is, TMAO can be tolerated at high concentrations in organisms without affecting nonspecific hydrophobic effects. Our study implies that protein stabilization by TMAO occurs through other mechanisms, such as unfavorable water-mediated interaction of TMAO with the protein backbone, as suggested by recent experimental studies. We complement the above calculations with analysis of TMAO hydration and changes in water structure in the presence of TMAO molecules. TMAO is an amphiphilic molecule containing both hydrophobic and hydrophilic parts. The precise balance of the effects of hydrophobic and hydrophilic segments of the molecule appears to explain the virtual noneffect of TMAO on the strength of hydrophobic interactions.     

31P and 1H NMR studies of the effect of the counteracting osmolyte trimethylamine-N-oxide on interactions of urea with ribonuclease A

31P NMR spectroscopy has been used to show that the activity of RNase A, which is lowered in the presence of urea, can be recovered with trimethylamine-N-oxide (TMAO). A 1:1 ratio of TMAO:urea was sufficient to recover the enzyme activity. (1)H nuclear Overhauser effect spectroscopy NMR studies with RNase A have shown that even at relatively low effective concentrations of TMAO, some modification of the three-dimensional structure of the biomolecule is apparent.     

Nuclear magnetic resonance studies of blood plasma and urine from subjects with chronic renal failure: identification of trimethylamine-N-oxide

We have used ¹H-, ¹³C- and ¹⁴N-NMR spectroscopy to investigate the constituents of plasma and urine in 16 patients with chromic renal failure (CRF). Resonances not previously observed in spectra of plasma from healthy volunteers were seen in CRF plasma, including those for trimethylamine-N-oxide (TMAO) and dimethylamine (DMA). A possible analogy with the plasma of elasmobranch fishes, in which TMAO stabilizes proteins in the presence of very high urea concentrations, is noted. The intensity of the TMAO resonance for CRF subjects was correlated with the plasma concentration of urea (R = 0.55) and creatinine (R = 0.74), suggesting that the presence of TMAO is closely related to the degree of renal failure. When normal subjects ate a meal of TMAO-containing fish, TMAO appeared rapidly in the plasma and in the urine. Thus TMAO is efficiently cleared by the healthy kidney. Differences in the interaction of lactate with plasma proteins were detected by NMR, suggesting that uraemia impairs their transport roles.     

Osmolyte effect on the stability and folding of a hyperthermophilic protein

Proteins are known to be stabilized by naturally occurring osmolytes such as amino acids, sugars, and methylamines. Here, we examine the effect of trimethylamine-N-oxide (TMAO) on the conformational stability of ribonuclease HII from a hyperthermophile, Thermococcus kodakaraensis (Tk-RNase HII), which inherently possesses high conformational stability. Heat- and guanidine hydrochloride-induced unfolding experiments demonstrated that the conformational stability of Tk-RNase HII in the presence of 0.5M TMAO was higher than that in the absence of TMAO at all examined temperatures. TMAO affected the unfolding and refolding kinetics of Tk-RNase HII to a similar extent. These results indicate that proteins are universally stabilized by osmolytes, regardless of their robustness, and suggest a stabilization mechanism by osmolytes, caused by the unfavorable interaction of osmolytes with protein backbones in the denatured state. Our results also imply that the basic protein folding principle is not dependent on protein stability and evolution.     

Novel Use for the Osmolyte Trimethylamine N-oxide: Retaining the Psychrophilic Characters of Cold-Adapted Protease Deseasin MCP-01 and Simultaneously Improving its Thermostability

The low thermostability of cold-adapted enzymes is a main barrier for their application. A simple and reliable method to improve both the stability and the activity of cold-adapted enzymes is still rare. As a protein stabilizer, the effect of trimethylamine N-oxide (TMAO) on a cold-adapted enzyme or protein has not been reported. In this study, effects of TMAO on the structure, activity, and stability of a cold-adapted protease, deseasin MCP-01, were studied. Deseasin MCP-01 is a new type of subtilase from deep-sea psychrotolerant bacterium Pseudoalteromonas sp. SM9913. Fluorescence and CD spectra showed that TMAO did not perturb the structure of MCP-01 and therefore kept the conformational flexibility of MCP-01. One molar TMAO improved the activity of MCP-01 by 174% and its catalytic efficiency (k _cat /K _m) by 290% at 0°C. In the presence of 1 M TMAO, the thermostability (t _1/2) of MCP-01 increased by two- to fivefold at 60∼40°C. Structural analysis with CD showed that 1 M TMAO could keep the structural thermostability of MCP-01 close to that of its mesophilic counterpart subtilisin Carlsberg when incubated at 40°C for 1 h. Moreover, 1 M TMAO increased the melting temperature (T _m) of MCP-01 by 10.5°C. These results suggest that TMAO can be used as a perfect stabilizing agent to retain the psychrophilic characters of a cold-adapted enzyme and simultaneously improve its thermostability.     

Rescue of the neuroblastoma mutant of the human nucleoside diphosphate kinase A/nm23-H1 by the natural osmolyte trimethylamine-N-oxide

The point mutation S120G in human nucleoside diphosphate kinase A, identified in patients with neuroblastoma, causes a protein folding defect. The urea-unfolded protein cannot refold in vitro, and accumulates as a molten globule folding intermediate. We show here that the trimethylamine-N-oxide (TMAO) corrects the folding defect and stimulated subunit association. TMAO also substantially increased the stability to denaturation by urea of both wild-type and S120G mutant. A non-native folding intermediate accumulated in the presence of 4.5-7 M urea and of 2 M TMAO. It was inactive, monomeric, contained some secondary structure but no tertiary structure and displayed a remarkable stability to denaturation.     

Singular efficacy of trimethylamine N-oxide to counter protein destabilization in ice

This study reports the first quantitative estimate of the thermodynamic stability (Delta G degrees ) of a protein in low-temperature partly frozen aqueous solutions in the presence of the protective osmolytes trimethylamine N-oxide (TMAO), glycine betaine, and sarcosine. The method, based on guanidinium chloride denaturation of the azurin mutant C112S from Pseudomonas aeruginosa, distinguishes between the deleterious effects of subfreezing temperatures from those due specifically to the formation of a solid ice phase. The results point out that in the liquid state molar concentrations of these osmolytes stabilize significantly the native fold and that their effect is maintained on cooling to -15 degrees C. At this temperature, freezing of the solution in the absence of any additive causes a progressive destabilization of the protein, Delta G degrees decreasing up to 3-4 kcal/mol as the fraction of liquid water in equilibrium with ice ( V L) is reduced to less than 1%. The ability of the three osmolytes to prevent the decrease in protein stability at small V L varies significantly among them, ranging from the complete inertness of sarcosine to full protection by TMAO. The singular effectiveness of TMAO among the osmolytes tested until now is maintained high even at concentrations as low as 0.1 M when the additive stabilization of the protein in the liquid state is negligible. In all cases the reduction in Delta G degrees caused by the solidification of water correlates with the decrease in m-value entailing that protein-ice interactions generally conduct to partial unfolding of the native state. It is proposed that the remarkable effectiveness of TMAO to counter the ice perturbation is owed to binding of the osmolyte to ice, thereby inhibiting protein adsorption to the solid phase.     

Effect of osmolytes on protein dynamics in the lactate dehydrogenase-catalyzed reaction

Laser-induced temperature jump relaxation spectroscopy was used to probe the effect of osmolytes on the microscopic rate constants of the lactate dehydrogenase-catalyzed reaction. NADH fluorescence and absorption relaxation kinetics were measured for the lactate dehydrogenase (LDH) reaction system in the presence of varying amounts of trimethylamine N-oxide (TMAO), a protein-stabilizing osmolyte, or urea, a protein-destabilizing osmolyte. Trimethylamine N-oxide (TMAO) at a concentration of 1 M strongly increases the rate of hydride transfer, nearly nullifies its activation energy, and also slightly increases the enthalpy of hydride transfer. In 1 M urea, the hydride transfer enthalpy is almost nullified, but the activation energy of the step is not affected significantly. TMAO increases the preference of the closed conformation of the active site loop in the LDH·NAD(+)·lactate complex; urea decreases it. The loop opening rate in the LDH·NADH·pyruvate complex changes its temperature dependence to inverse Arrhenius with TMAO. In this complex, urea accelerates the loop motion, without changing the loop opening enthalpy. A strong, non-Arrhenius decrease in the pyruvate binding rate in the presence of TMAO offers a decrease in the fraction of the open loop, pyruvate binding competent form at higher temperatures. The pyruvate off rate is not affected by urea but decreases with TMAO. Thus, the osmolytes strongly affect the rates and thermodynamics of specific events along the LDH-catalyzed reaction: binding of substrates, loop closure, and the chemical event. Qualitatively, these results can be understood as an osmolyte-induced change in the energy landscape of the protein complexes, shifting the conformational nature of functional substates within the protein ensemble.     

Ligation alters the pathway of urea-induced denaturation of the catalytic trimer of Escherichia coli aspartate transcarbamylase.

We have examined the pathway and energetics of urea-induced dissociation and unfolding of the catalytic trimer (c3) of aspartate transcarbamylase from Escherichia coli at low temperature in the absence and presence of carbamyl phosphate (CP; a substrate), N-(phosphonacetyl)-L-Asp (PALA; a bisubstrate analog), and 2 anionic inhibitors, Cl- and ATP, by analytical gel chromatography supplemented by activity assays and ultraviolet difference spectroscopy. In the absence of active-site ligands and in the presence of ATP, c3 dissociates below 2 M urea into swollen c chains that then gradually unfold from 2 to 6 M urea with little apparent cooperativity. Linear extrapolation to 0 M urea of free energies determined in 3 independent types of experiments yields estimates for delta Gdissociation at 7.5 degrees C of about 7-10 kcal m-1 per interface. delta Gunfolding of dissociated chains when modeled as a 2-state process is estimated to be very small, on the order of -2 kcal m-1. The data are also consistent with the possibility that the unfolding of the dissociated monomer is a 1-state swelling process. In the presence of the ligands CP and PALA, and in the presence of Cl-, c3 dissociates at much higher urea concentrations, and trimer dissociation and unfolding occur simultaneously and apparently cooperatively, at urea concentrations that increase with the affinity of the ligand.