©1995 by The American Society for Biochemistry and Molecular Biology, Inc.
Prevention of in Vitro Protein Thermal Aggregation by the Sulfolobus solfataricus Chaperonin
EVIDENCE FOR NONEQUIVALENT BINDING SURFACES ON THE CHAPERONIN MOLECULE (*)

(Received for publication, March 24, 1995)

Annamaria Guagliardi (1) (2) Laura Cerchia (1) Mosè Rossi (1)

From the  (1)Dipartimento di Chimica Organica e Biologica, Università di Napoli, Via Mezzocannone, 16, 80134 Napoli, Italy, and (2)Istituto di Biochimica delle Proteine ed Enzimologia, CNR, Via Marconi, 10, 80125 Napoli, Italy

ABSTRACT
INTRODUCTION
EXPERIMENTAL PROCEDURES
RESULTS
DISCUSSION
FOOTNOTES
REFERENCES

ABSTRACT

We have studied the effects of the Sulfolobus solfataricus chaperonin on the aggregation and inactivation upon heating of four model enzymes: chicken egg white lysozyme (one 14.4-kDa chain), yeast alpha-glucosidase (one 68.5-kDa chain), chicken liver malic enzyme (four 65-kDa subunits), and yeast alcohol dehydrogenase (four 37.5-kDa subunits). When the proteins were heated in the presence of an equimolar amount of chaperonin, 1) the aggregation was prevented in all solutions; 2) the inactivation profiles of the single-chain enzymes were comparable with those detected in the absence of the chaperonin, and enzyme activities were regained in the solutions heated in the presence of the chaperonin upon ATP hydrolysis (78 and 55% activity regains for lysozyme and alpha-glucosidase, respectively); 3) the inactivation of the tetrameric enzymes was completely prevented, whereas the activities decreased in the absence of the chaperonin. We demonstrate by gel filtration chromatography that the chaperonin interacted with the structures occurring during thermal denaturation of the model proteins and that the interaction with the single-chain proteins (but not that with the tetrameric proteins) was reversed upon ATP hydrolysis. The chaperonin had nonequivalent surfaces for the binding of the model proteins upon heating: the thermal denaturation intermediates of the single-chain proteins share Surfaces I, while the thermal denaturation intermediates of the tetrameric proteins share Surfaces II. ATP binding to the chaperonin induced a conformation that lacked Surfaces I and carried Surfaces II. These data support the concept that chaperonins protect native proteins against thermal aggregation by two mechanistically distinct strategies (an ATP-dependent strategy and an ATP-independent strategy), and provide the first evidence that a chaperonin molecule bears functionally specialized surfaces for the binding of the protein substrates.


INTRODUCTION

The term ``chaperonins'' denotes a family of ubiquitous, essential proteins endowed with ATPase activity that are involved in the folding, transport, and assembly of newly synthesized proteins (for reviews, see Ellis and van der Vies(1991), Hartl et al. (1992), and Horwich and Willison(1993)).

Eubacterial chaperonins are structurally and functionally closely related to eukaryotic-intraorganellar chaperonins. They have similar amino acid sequences and consist of two stacked homo-oligomeric rings of seven subunits of 60 kDa each that delimitate a central cavity; sequence-related co-chaperonins, consisting of a single homo-oligomeric ring of seven subunits of 10 kDa each, have been isolated together with these chaperonins. The crystal structure determination of GroEL (the Escherichia coli chaperonin) and a mutational analysis revealed three domains in each subunit. The apical domain faces the central cavity, and its flexible regions are involved in the binding of the polypeptide substrate and the co-chaperonin GroES. The equatorial domain provides most of the intratoroidal side-to-side contacts and all of the ring-to-ring contacts and contains the ATP-binding site; the domain intermediate between the other two probably allows allosteric domain movement (Braig et al., 1994; Fenton et al., 1994; Hartl et al., 1994). GroEL promotes correct folding by binding to nonnative structures that are folding intermediates, thus preventing the aggregation of hydrophobic surfaces, and coupling their release in a correctly folded form to the binding and/or hydrolysis of ATP; in some, but not all, cases the formation of native proteins requires the presence of GroES.

Trent et al.(1991) reported that the chaperonin of the thermophilic archaeon Sulfolobus shibatae shows no significant relationship to GroEL-like chaperonins but has a 40% sequence identity with the chaperonins of the eukaryotic cytosol (named CCTs), reflecting the evolutive lineage of their sources. Archaeal chaperonins and CCTs do not have co-chaperonin equivalents; they show the typical double-ring structure with an 8- or 9-fold symmetry and a homo- or hetero-oligomeric structure. CCTs have a domain arrangement similar to that of GroEL; analysis of sequence relatedness to GroEL revealed a high level of identity in the regions corresponding to the ATP binding site, but no significant identity in the region corresponding to the polypeptide binding site (Kim et al., 1994; Kubota et al., 1994). In a functional regard, CCTs promote correct protein folding by an ATP-dependent mechanism similar to that exerted by GroEL but without the requirement for a co-chaperonin component (Frydman et al., 1992; Gao et al., 1992; Melki and Cowan, 1994).

The chaperonin of the thermophilic archaeon S. solfataricus (Ssocpn), (^1)has a 9-fold symmetry (Knapp et al., 1994; Marco et al., 1994) and two subunit species that differ in size and N-terminal sequences (Knapp et al., 1994), or one subunit of 60 kDa (Guagliardi et al., 1994; Marco et al., 1994). Ssocpn displays a K-dependent ATPase activity and promotes correct refolding of several thermophilic and mesophilic proteins in an ATP hydrolysis-dependent manner (Guagliardi et al., 1994). In an effort to enlarge our knowledge about archaeal chaperonins, we investigated the effects of Ssocpn on the aggregation and inactivation upon heating of four model enzymes: chicken egg white lysozyme (a monomer of 14.4 kDa), yeast alpha-glucosidase (a monomer of 68.5 kDa), chicken liver malic enzyme (a homotetramer of 65 kDa subunits), and yeast alcohol dehydrogenase (a homotetramer of 37.5 kDa subunits). This study provides, for the first time, biochemical evidence that a chaperonin molecule possesses nonequivalent surfaces for the binding of the protein substrates.


EXPERIMENTAL PROCEDURES

Materials

ATP, NAD, NADP, ME from chicken liver (29 units/mg), ADH from yeast (200 units/mg), and lysozyme from chicken egg white (183 units/mg) were purchased from Sigma; alpha-glucosidase from yeast (133 units/mg) and p-nitrophenyl-alpha-D-maltoside were from Boehringer Mannheim. The other chemicals were of the highest grade available.

Miscellaneous

Protein concentration was determined by the assay of Bradford(1976) using bovine serum albumin as the standard. SDS-PAGE analysis was carried out according to Laemmli(1970); after the run, the proteins were revealed by Coomassie staining. Protein aggregation was monitored as turbidity at 450 nm; the maximal turbidity was taken as 100% aggregation. Molar concentrations were calculated on the basis of the following molecular mass values: 920 kDa for Ssocpn; 14.4 kDa for lysozyme; 68.5 kDa for alpha-glucosidase; 260 kDa for ME; 150 kDa for ADH.

Enzymatic Assays

The enzymes were assayed at 25 °C (lysozyme, ME, and ADH) or at 30 °C (alpha-glucosidase) by a Cary 1E Varian recording spectrophotometer equipped with a thermostated cell compartment. Absorbance variations were always linear within 2 min; each activity assay was performed in duplicate.

The assay mixture for chicken egg white lysozyme consisted of 1 ml of a fresh suspension 0.1 mg/ml of lyophilized E. coli cells in 50 mM Tris-HCl buffer, pH 7.4. After the addition of lysozyme, the time required for an absorbance decrease of A = 0.1 was measured; the specific activity of the enzyme was calculated by the formula time mg of protein according to Tsugita et al.(1968). Yeast alpha-glucosidase was assayed in 0.1 M sodium phosphate buffer, pH 7.0, 0.3 mMp-nitrophenyl-alpha-D-maltoside (1 ml final volume) according to Halvorson(1966); the continuous increase of absorbance at 400 nm was monitored, and an extinction coefficient for p-nitrophenol was 9.6 mM. Chicken liver ME was assayed in 20 mM Tris-HCl buffer, pH 7.5, 0.05 mM NADP, 1 mM MgCl(2), 1 mML-malate (1 ml final volume). Yeast ADH was assayed in 50 mM sodium phosphate buffer, pH 8.0, 2 mM NAD, 1 mM ethanol (1 ml final volume).

Purification of the Chaperonin

The chaperonin was purified from crude extracts of S. solfataricus strain MT-4 as described previously (Guagliardi et al., 1994). Briefly, the crude extract (20 mg) was dialyzed against 10 mM Tris-HCl buffer, pH 8.4 (Buffer A) and loaded onto a Superose 6 column (Pharmacia Biotech Inc., 2.6 times 60 cm) eluted with the same buffer supplemented with 0.1 M NaCl at a flow rate of 0.5 ml/min; the fractions containing the chaperonin were pooled, concentrated by a vacuum centrifuge, and dialyzed against Buffer A. The sample (1.4 mg) was loaded onto a Matrex Gel Red A affinity chromatography column (Amicon, 1 times 3.5 cm) equilibrated in Buffer A and eluted with a linear 0-0.4 M NaCl gradient in Buffer A at a flow rate of 15 ml/h; the fractions containing the chaperonin were pooled, dialyzed against Buffer A, and stored at 4 °C (1 mg). SDS-PAGE analysis revealed one band at 57 kDa, which showed the preparation was homogeneous.


RESULTS

Effects of Ssocpn on the Thermal Aggregations and Inactivations of Lysozyme and alpha-Glucosidase

Temperatures and protein concentrations were so chosen as to obtain the aggregation of chicken egg white lysozyme and yeast alpha-glucosidase. Light scattering measurements showed that aggregation occurred in solutions of 80 µg/ml lysozyme and 200 µg/ml alpha-glucosidase upon heating at 70 and 40 °C, respectively (Fig. 1). The addition of excess Ssocpn to the solutions after they had precipitated did not exert any effect. When identical solutions of lysozyme and alpha-glucosidase were heated in the presence of Ssocpn at an equimolar ratio between the chaperonin oligomer and the polypeptide chain, light scattering did not increase. The effect of Ssocpn in preventing thermal aggregation of lysozyme and alpha-glucosidase was specific; the presence of an excess of bovine serum albumin in the place of Ssocpn in the solutions did not prevent the occurrence of precipitates. Following the addition of ATP/Mg/K (0.5 mM ATP, 0.5 mM MgCl(2), 10 mM KCl), light scattering increased in the solutions of lysozyme and alpha-glucosidase heated in the presence of Ssocpn.


Figure 1: Thermal aggregation of chicken egg white lysozyme (upper panels) and yeast alpha-glucosidase (lowerpanels) in the absence (open symbols) and in the presence (closed symbols) of Ssocpn. Lysozyme (80 µg in 1 ml) was incubated at 70 °C in 10 mM Tris-HCl buffer, pH 8.0, in the absence () or in the presence () of Ssocpn at a molar ratio of 1:1 between the chaperonin oligomer and the lysozyme chain. alpha-Glucosidase (200 µg in 1 ml) was incubated at 40 °C in 50 mM sodium phosphate buffer, pH 8.0, in the absence (up triangle) or in the presence () of Ssocpn at a molar ratio of 1:1 between the chaperonin oligomer and the alpha-glucosidase chain.



In a reasonable interpretation of the results, Ssocpn did not rescue the protein aggregates, but rather it interacted with lysozyme or alpha-glucosidase before their precipitation and so maintained them in solution. The hydrophobic surfaces of Ssocpn contributed to the binding, as demonstrated by the finding that aggregation occurred as in the absence of Ssocpn if the solutions of lysozyme and alpha-glucosidase contained the chaperonin plus 0.1% Triton X-100. The addition of ATP/Mg/K discharged the proteins that proceeded to aggregate at the temperatures of the incubation. No aggregation was detected if ATP/Mg (0.5 mM ATP, 0.5 mM MgCl(2)) was added instead of ATP/Mg/K; that is, because Ssocpn displays a K-dependent ATPase activity (Guagliardi et al., 1994), ATP hydrolysis was required to disrupt the binding between Ssocpn and the protein chain. Lysozyme and alpha-glucosidase discharged from Ssocpn after ATP hydrolysis reaggregated, even though the test tube contained Ssocpn; in other words, under the experimental conditions described, Ssocpn was not viable for rebinding the denaturation intermediates. We are currently investigating the recycling of Ssocpn by studying the effects of ATP hydrolysis on its conformation, and the chaperonin affinity toward the target protein, potassium ions, and ATP during in vitro functioning.

We determined the time courses of inactivations of lysozyme and alpha-glucosidase at the designated temperatures in the absence and in the presence of Ssocpn oligomer at an equimolar ratio with the protein chain (Fig. 2). Ssocpn did not modify the kinetics of inactivation; that is, Ssocpn did not prevent the loss of activity of the two enzymes. Following the addition of ATP/Mg/K (but not of ATP/Mg), final activity regains of 78 and 55% were obtained in the solutions of lysozyme and alpha-glucosidase heated in the presence of Ssocpn. Lysozyme and alpha-glucosidase activities decreased when the incubations were continued after the addition of ATP/Mg/K (not reported in the figure), which is in accordance with the intrinsic heat lability of the native enzymes. These results show that the molecules remained in a folding-competent conformation while bound to the chaperonin and that correctly folded molecules were released in solution upon ATP hydrolysis.


Figure 2: Thermal inactivations of chicken egg white lysozyme (upper panels) and yeast alpha-glucosidase (lower panels) in the absence (open symbols) and in the presence (closed symbols) of Ssocpn. Lysozyme and alpha-glucosidase were heated exactly as described in the legend to Fig. 1. At the times defined, the enzyme activity was assayed as described under ``Experimental Procedures'' on aliquots drawn from each mixture; the activity regains were calculated as percentages with respect to the specific activities of the native enzymes. The scale of the x axis changed at the time indicated by the arrow.



The final percents of active lysozyme or alpha-glucosidase did not vary when the chaperonin was present in the solutions at a molar excess over the protein chain or when a molar ratio of 1:2 between Ssocpn and the protein chain was used. At a molar ratio of Ssocpn to protein chain of 1:10, lysozyme activity was restored by 37% and alpha-glucosidase activity by 20%.

Effects of Ssocpn on the Thermal Aggregations and Inactivations of Malic Enzyme and Alcohol Dehydrogenase

We chose conditions of temperature and concentrations of chicken liver ME or yeast ADH that ensured their precipitation. Solutions of 6 µg/ml ME and 6 µg/ml ADH promptly aggregated upon heating at 50 °C (Fig. 3). Ssocpn was without effect if added when the proteins had aggregated. Aggregation was completely suppressed when Ssocpn was present in the solutions from the beginning of the heating in a molar ratio of one chaperonin oligomer to one ME or ADH molecule. The presence of excess bovine serum albumin in place of Ssocpn did not prevent the increases in light scattering. The addition of ATP/Mg/K or ATP/Mg in the solutions of ME and ADH heated in the presence of Ssocpn did not exert any effect.


Figure 3: Thermal aggregations of chicken liver ME (upper panels) and yeast ADH (lower panels) in the absence (open symbols) and in the presence (closed symbols) of Ssocpn. ME (6 µg in 1 ml) was incubated at 50 °C in 10 mM Tris-HCl buffer, pH 8.0, in the absence (circle) or in the presence (bullet) of Ssocpn at a molar ratio of 1:1 between the chaperonin oligomer and ME oligomer. ADH (6 µg in 1 ml) was incubated at 50 °C in 10 mM Tris-HCl buffer, pH 8.0, in the absence (box) or in the presence () of Ssocpn at a molar ratio of 1:1 between the chaperonin oligomer and ADH oligomer.



These results suggest that Ssocpn interacted with ME and ADH and prevented their precipitation upon heating; the hydrophobic nature of the interaction was demonstrated by the fact that 0.1% Triton X-100 in the solutions of ME and ADH containing Ssocpn abolished the protection against aggregation. The bound molecules were not released upon ATP binding or hydrolysis.

During heating, ME and ADH very rapidly lost their activity in the absence of Ssocpn but retained total activity in the presence of the chaperonin; the addition of ATP/Mg/K did not exert any effect (Fig. 4). We verified that the addition of Ssocpn to native solutions of ME and ADH did not affect their specific activities. In conclusion, the binding of ME or ADH to Ssocpn during heating did not cause any perturbation of the enzyme active sites, and the active conformations of the two enzymes were preserved.


Figure 4: Thermal inactivations of chicken liver ME (upper panels) and yeast ADH (lower panels) in the absence (open symbols) and in the presence (closed symbols) of Ssocpn. ME and ADH were heated exactly as described in the legend to Fig. 3. Enzyme activities were assayed as described under ``Experimental Procedures'' on aliquots drawn from each mixture.



No inactivation at all was detected when Ssocpn was incubated with ME or ADH at a molar ratio of 1:10; when Ssocpn and ME or ADH were heated at a molar ratio of 1:20, residual ME and ADH activities of about 30% were calculated after 30 min.

Interaction of Ssocpn with the Model Proteins

Fig. 5A shows that the Ssocpn-mediated suppression of protein thermal aggregation involved the interaction of the chaperonin with the protein molecule (see legend for experimental details). The solutions were heated and then injected onto a Superose 6 column; only one peak eluted from the column with the void volume. SDS-PAGE analysis revealed the presence of two molecular species in the peak: Ssocpn and the protein used as substrate. A peak of activity was superimposable to that of absorption at 280 nm in the run that showed the interaction of Ssocpn with ME or ADH; no activity was found in the peak of the run that showed the interaction of Ssocpn with lysozyme or alpha-glucosidase.


Figure 5: A, solutions (0.3 ml) of lysozyme (10 µg), alpha-glucosidase (20 µg), ME (30 µg) and ADH (30 µg) containing Ssocpn at an equimolar ratio with each protein molecule were heated at the designated temperatures; after a 2-h incubation, each solution was chromatographed on a Superose 6 column (1 times 48 cm; flow rate of 12 ml/h at 4 °C; eluent 10 mM Tris-HCl, pH 8.4, 0.2 M NaCl). Left, the chromatographic profiles relative to the runs: the elution volumes (ml) are plotted against the absorption at 280 nm; the letters indicate the protein used: a, lysozyme; b, alpha-glucosidase; c, ME; d, ADH. Right, the SDS-PAGE analysis of the peaks from the column; the lanes were loaded with an aliquot from the peak of the corresponding run. B, solutions of lysozyme, alpha-glucosidase, ME, and ADH plus Ssocpn as in A were heated at the designated temperatures; after a 2-h incubation, ATP/Mg/K was added to the solutions; 5 min after the addition, each solution was chromatographed onto a Superose 6 column (conditions were as described above). Axes and letters on the plots are as in A; the peak of ATP was omitted. C, solutions of lysozyme, alpha-glucosidase, ME and ADH plus Ssocpn as in A were directly chromatographed onto a Superose 6 column (conditions were as above). Axes and letters on the plots are as in A.



Exploiting the same experimental tool, we demonstrate that 1) the interaction of Ssocpn with the single-chain proteins was reversed upon ATP hydrolysis, free lysozyme, or alpha-glucosidase being catalytically active and 2) the interaction of Ssocpn with the tetrameric proteins was unaffected by ATP hydrolysis (Fig. 5B).

We demonstrate that Ssocpn does not interact with the native conformations of the model proteins (Fig. 5C). The chromatography on Superose 6 of nonheated solutions separated the protein used (eluted in an active form in a position corresponding to its native molecular weight) from Ssocpn (eluted in the void volume); SDS-PAGE analysis of the first eluting peak showed only the band corresponding to the Ssocpn subunit (not shown). Therefore, Ssocpn prevents the thermal aggregation of the model proteins by coating with its hydrophobic surfaces the interactive hydrophobic patches exposed on the intermediates of the thermal denaturation process.

Binding Surfaces on Ssocpn for the Model Proteins

The results described above led to the discovery of two different strategies by which Ssocpn prevents the thermal aggregation of the model proteins: an ATP hydrolysis-dependent strategy common to the single-chain enzymes and an ATP-independent strategy common to the tetrameric enzymes. This prompted the question do the molecules that share the same strategy, share the same binding surfaces on the chaperonin?

To ascertain whether lysozyme and alpha-glucosidase have the same binding surfaces, we saturated Ssocpn with the denaturation intermediate of alpha-glucosidase and tested if this chaperonin could prevent the thermal aggregation of lysozyme. Ssocpn and alpha-glucosidase in a molar ratio of 1:50 were heated at 40 °C for 2 h; an ultracentrifugation at 50,000 rpm for 1 h pelletted visible aggregates. Gel filtration of the supernatant on Superose 6 column (1 times 48 cm; eluent 10 mM Tris-HCl, pH 8.4, 0.2 M NaCl; flow rate of 12 ml/h at 4 °C) yielded the Ssocpnbulletalpha-glucosidase complex (as judged by SDS-PAGE analysis) in the void volume. We verified that all Ssocpn molecules in the peak were saturated with alpha-glucosidase. In fact, the inclusion of a protein excess from the peak in a solution of alpha-glucosidase heated at 40 °C did not prevent the occurrence of aggregates (no aggregation was detected when only the aliquot from the peak was heated).

Ssocpn saturated with alpha-glucosidase (briefly Ssocpn/alpha-glucosidase) was included in a solution of lysozyme in a protein excess over the lysozyme molecule, and the light scattering was continuously monitored during heating at 70 °C, a light scattering increase similar to that obtained when lysozyme was incubated in the absence of the chaperonin was recorded (Ssocpn/alpha-glucosidase alone did not aggregate over the time of the heating under the same conditions). This result means that the thermal denaturation intermediate of lysozyme did not find surfaces available for the binding to Ssocpn/alpha-glucosidase. In a control experiment, we included in the solution of lysozyme to be heated an Ssocpnbulletalpha-glucosidase complex, which was prepared at a molar ratio of 1:0.5 between the chaperonin and the alpha-glucosidase chain and was subjected to the same experimental protocol: in this case, lysozyme aggregation was completely suppressed.

By the same strategy, we demonstrated that the denaturation intermediates of ME and ADH have the same binding surfaces on Ssocpn. We prepared a chaperonin saturated with the thermal denaturation intermediate of ME by heating at 50 °C for 1 h a solution in which the molar ratio between Ssocpn and the substrate molecule was 1:80. The aggregates were removed by ultracentrifugation, and the saturated form of Ssocpn (Ssocpn/ME unable to prevent the aggregation of free ME) was recovered in the peak eluting with the void volume from the Superose column loaded with the supernatant (see above for details). Ssocpn/ME was unable to prevent the aggregation at 50 °C of a solution of ADH; vice versa, an SsocpnbulletME complex, which was prepared at a molar ratio of 1:1 and was subjected to the same experimental protocol as that used to prepare Ssocpn/ME, suppressed ADH aggregation

Surprisingly, when Ssocpn/ME was included in solutions of lysozyme and alpha-glucosidase and the solutions were heated at the respective temperatures, no aggregations were detected; active molecules were regained upon the addition of ATP/Mg/K. When Ssocpn/alpha-glucosidase was included in solutions of ME and ADH and the solutions were heated at 50 °C, aggregations and inactivations were prevented. Since no artifact seemed responsible for these results, Ssocpn has surfaces specific for the binding of the denaturation intermediates of the single-chain proteins (Surfaces I), which are not saturable by the thermal denaturation intermediates of the tetrameric proteins; other surfaces specific for the binding of the denaturation intermediates of the tetrameric proteins (Surfaces II) are not saturable by the thermal denaturation intermediates of the single-chain proteins. Consequently, it appears that Ssocpn has nonequivalent surfaces for the binding of the model proteins during their heating.


DISCUSSION

Some native proteins form visible aggregates when subjected to heating, as a consequence of hydrophobic intermolecular interactions; protein thermal aggregation is responsible for an irreversible loss of biological activity. We studied the effects of the chaperonin from the archaeon S. solfataricus, Ssocpn, on the in vitro thermal aggregation of two single-chain enzymes of 14.4 and 68.5 kDa and two tetrameric enzymes of 260 and 150 kDa.

Like other chaperonins, Ssocpn does not rescue proteins once they aggregate and does not bind the native molecules. Ssocpn prevents protein aggregation by interacting with the hydrophobic surfaces of the thermal denaturation intermediates of the model proteins, thus suppressing the intermolecular interactions that lead to aggregation. Because the tetrameric proteins retain their enzymatic activity upon binding to Ssocpn, the structure of the intermediate bound by Ssocpn is probably very similar to that of the native molecule. Ssocpn does not prevent the thermal denaturation of the single-chain enzymes that leads to their loss of activity, rather these enzymes are kept in a form that is refoldable upon ATP hydrolysis. As demonstrated for GroEL (Jackson et al., 1993; Hartl, 1994; Todd et al., 1994; Weissman et al., 1994), the binding and hydrolysis of ATP could trigger cycles of release from and rebinding to Ssocpn of the molecules until they have reached a correctly folded form.

The binding of the model proteins to Ssocpn during heating is not casual in the sense that the chaperonin surfaces are not indifferently available for the binding of any molecule; thermal denaturation intermediates of the single-chain proteins share Surfaces I, while thermal denaturation intermediates of the tetrameric proteins share Surfaces II.

There is evidence that the binding of ATP to Ssocpn drives a conformational change in the overall structure of the chaperonin (Guagliardi et al., 1994; Knapp et al., 1994). To gain insight into the functional consequence of this change, we heated lysozyme, alpha-glucosidase, ME, and ADH in the presence of the ATP-induced form of Ssocpn and found that only the aggregations of the tetrameric enzymes were suppressed, not the aggregations of the single-chain enzymes, which proceeded as in the absence of the chaperonin (not shown). Therefore, the ATP-induced form of Ssocpn does not bind the thermal denaturation intermediates of the single-chain enzymes, but it is still able to bind the thermal denaturation intermediates of the tetrameric enzymes. This finding implies that ATP binding to Ssocpn leads to a disappearance or modification of Surfaces I such that the interaction with the proper molecules is prevented; Surfaces II are probably less (or not at all) affected by the structural rearrangement. It is noteworthy that the ATP-induced form of Ssocpn is unable to bind the refolding intermediates of several chemically denatured proteins (Guagliardi et al., 1994); we are currently investigating whether the flexible Surfaces I are implicated also in the binding of the interactive structures occurring during folding.

The domain organization of archaeal chaperonins is unknown. We suspect that Surfaces I could correspond to the flexible regions of the apical domain in GroEL involved in the binding of polypeptide substrate: these regions undergo a strong motion upon ATP-binding (Chen et al., 1994), and there is compelling evidence in the literature that the ATP-bound form of GroEL has a low affinity for unfolded protein substrates. It is unlikely that Surfaces II are located in the same region. The absence of any functional interference between the two Surfaces could imply that they are not in close vicinity on the chaperonin cylinder, and surfaces suited to bind molecules that exert catalytic activity could be surfaces exposed to the milieu; electron microscopy showed that the external envelope of GroEL binds the protein molecules (Azem et al., 1994). Our data show that Surfaces I and Surfaces II can bind more than one polypeptide chain during heating, which is consistent with the idea that chaperonins have multiple substrate binding sites. How many binding sites there are on Surfaces I and Surfaces II remains an open question, although it seems that the latter surfaces bind a higher number of substrate molecules than the former ones.

The activity of GroEL in preventing the thermal aggregation of native proteins has been poorly investigated in comparison with its activity in preventing the aggregation during refolding of unfolded proteins. Upon heating in the presence of GroEL, native alpha-glucosidase (Holl-Neugebauer et al., 1991), rhodanese (Mendoza et al., 1992), dihydrofolate reductase (Martin et al., 1992), and malate dehydrogenase (Hartman et al., 1993) are protected against aggregation but not against inactivation, and active molecules are released in solution upon ATP hydrolysis. In an ATP-independent manner, GroEL keeps RNA polymerase active (Ziemienowicz et al., 1993), interacts with a conformation of 6-hydroxy-D-nicotine oxidase close to the native state (Brandsch et al., 1992) and with a form of rhodanese that is active (Mendoza et al., 1992).

Taken together, the aforementioned results about GroEL and the results of this study strongly suggest that chaperonins protect the native proteins against aggregative damage by two mechanistically distinct strategies. The cellular concentration of free ATP, which is high under physiological conditions and dramatically decreases upon different kinds of stress, may reflect the biological significance of the in vitro ATP-dependent strategy by which chaperonins prevent aggregation; thermal aggregation of proteins increases in ATP-depleted cells (Nguyen and Bensaude, 1994). The proteins that interact with the chaperonins in an ATP-independent fashion and in a conformation close to the native state probably undergo their cellular turnovers while bound to the chaperonin; active Ssocpn-bound ME and ADH lose their activity following trypsin digestion, and the inactivation profiles are identical to those of the free native molecules at the same protein concentrations (data not shown). In this scenario, the chaperonin-bound protein has the life-span of the free protein, which devised a strategy to avoid a sticky situation. The role of ``hydrophobic support'' played by the chaperonins in the cell is well suited to proteins that are very abundant also under physiological conditions, and, in terms of cell utility, one molecule that plays different roles via nonequivalent surfaces seems very advantageous.

Finally, we would like to underline an aspect of the research on chaperones from thermophilic Archaea. The protein named Hsp70 in Eukarya and DnaK in Eubacteria plays a central role in the heat shock response of these cells as a molecular chaperone involved in protein folding and transport; in E. coli, DnaK and related proteins cooperate with GroEL in a common pathway to facilitate protein folding (Gragerov et al., 1992; Hartl et al., 1994). Thermophilic Archaea do not possess an equivalent to DnaK, and chaperonins are the main proteins expressed under conditions of heat shock (Conway de Macario and Macario, 1994). Investigating the activity of archaeal chaperonins might strengthen the hypothesis that in Archaea chaperonins fulfill the functions of 70 kDa-chaperones in Eubacteria and Eukarya.


FOOTNOTES

*
This work was supported by MURST 40%, by Progetto Finalizzato Biotecnologie e Biostrumentazione C.N.R., and by EEC Project Biotechnology of Extremophiles contract BIO2-CT93-0274. The costs of publication of this article were defrayed in part by the payment of page charges. This article must therefore by hereby marked ``advertisement'' in accordance with 18 U.S.C. Section 1734 solely to indicate this fact.

()
To whom correspondence should be addressed. Tel.: 39-81-7041236; Fax: 39-81-5521217.

(^1)
The abbreviations used are: Ssocpn, S. solfataricus chaperonin; ME, malic enzyme; ADH, alcohol dehydrogenase; PAGE, polyacrylamide gel electrophoresis.


REFERENCES

  1. Azem, A., Kessel, M., and Goloubinoff, P. (1994) Science 265, 653-656 [Medline] [Order article via Infotrieve]
  2. Bradford, M. M. (1976) Anal. Biochem. 72, 248-254 [CrossRef][Medline] [Order article via Infotrieve]
  3. Braig, K., Otwinowski, Z., Hegde, R., Boisvert, D. C., Joachimiak, A., Horwich, A. L., and Sigler, P. B. (1994) Nature 371, 578-586 [CrossRef][Medline] [Order article via Infotrieve]
  4. Brandsch, R., Bichler, V., Schmidt, M., and Buchner, J. (1992) J. Biol. Chem . 267, 20844-20849 [Abstract/Free Full Text]
  5. Chen, S., Roseman, A. M., Hunter, A. S., Woo, S. P., Burston, S. G., Ranson, N. A., Clarke, A. R., and Saibil, H. R. (1994) Nature 371, 261-264 [CrossRef][Medline] [Order article via Infotrieve]
  6. Conway de Macario, E., and Macario, A. J. L. (1994) Trends Biotech. 12, 512-518 [Medline] [Order article via Infotrieve]
  7. Ellis, R. J., and van der Vies, S. M. (1991) Annu. Rev. Biochem. 60, 321-347 [CrossRef][Medline] [Order article via Infotrieve]
  8. Fenton, W. A., Kashi, Y., Furtak, K., and Horwich, A. L. (1994) Nature 371, 614-619 [CrossRef][Medline] [Order article via Infotrieve]
  9. Frydman, J., Nimmesgern, E., Erdijument-Bromage, H., Wall, J. S., Tempst, P., and Hartl, F. U. (1992) EMBO J. 11, 4767-4778 [Abstract]
  10. Gao, Y., Thomas, J. O., Chow, R. L., Lee, G., and Cowan, N. J. (1992) Cell 69, 1043-1050 [Medline] [Order article via Infotrieve]
  11. Gragerov, A., Nudler, E., Komissarova, N., Gaitanaris, G. A., Gottesman, M. E., and Nikiforov, V. (1992) Proc. Natl. Acad. Sci. U. S. A. 89, 10341-10344 [Abstract]
  12. Guagliardi, A., Cerchia, L., Bartolucci, S., and Rossi, M. (1994) Protein Sci . 3, 1436-1443 [Abstract/Free Full Text]
  13. Halvorson, H. (1966) Methods Enzymol. 8, 559-562
  14. Hartl, F. U. (1994) Nature 371, 557-559 [Medline] [Order article via Infotrieve]
  15. Hartl, F. U., Martin, J., and Neupert, W. (1992) Annu. Rev. Biophys. Biomol. Struct. 21, 293-322 [CrossRef][Medline] [Order article via Infotrieve]
  16. Hartl, F. U., Hlodan, R., and Langer, T. (1994) Trends Biochem. Sci. 19, 20-25 [CrossRef][Medline] [Order article via Infotrieve]
  17. Hartman, D. J., Surin, B. P., Dixon, N. E., Hoogenraad, N. J., and Hoj, P. (1993) Proc. Natl. Acad. Sci. U. S. A. 90, 2276-2280 [Abstract]
  18. Holl-Neugebauer, B., Rudolph, R., Schmidt, M., and Buchner, J. (1991) Biochemistry 30, 11609-11614 [Medline] [Order article via Infotrieve]
  19. Horwich, A. L., and Willison, K. R. (1993) Phil. Trans. R. Soc. Lond. 339, 313-326 [Medline] [Order article via Infotrieve]
  20. Jackson, G. S., Staniforth, R. A., Halsall, D. J., Atkinson, T., Holbrook, J. J., Clarke, A. R., and Burston, S. G. (1993) Biochemistry 32, 2554-2563 [Medline] [Order article via Infotrieve]
  21. Kim, S., Willison, K. R., and Horwich, A. L. (1994) Trends Biochem. Sci. 19, 543-548 [CrossRef][Medline] [Order article via Infotrieve]
  22. Knapp, S., Schmidt-Krey, I., Hebert, H., Berman, T., Jornvall, H., and Ladenstein, R. (1994) J. Mol. Biol. 242, 397-407 [CrossRef][Medline] [Order article via Infotrieve]
  23. Kubota, H., Hynes, G., Carne, A., Ashworth, A., and Willison, K. (1994) Current Biol. 4, 89-99 [Medline] [Order article via Infotrieve]
  24. Laemmli, U. K. (1970) Nature 227, 680-685 [Medline] [Order article via Infotrieve]
  25. Marco, S., Urena, D., Carrascosa, J. L., Waldmann, T., Peters, J., Hegerl, R., Pfeifer, G., Sack-Konehl, H., and Baumeister, W. (1994) FEBS Lett. 341, 152-155 [CrossRef][Medline] [Order article via Infotrieve]
  26. Martin, J., Horwich, A. L., and Hartl, F. U. (1992) Science 258, 995-998 [Medline] [Order article via Infotrieve]
  27. Melki, R., and Cowan, N. J. (1994) Mol. Cell. Biol. 14, 2895-2904 [Abstract]
  28. Mendoza, J. A., Lorimer, G. H., and Horowitz, P. M. (1992) J. Biol. Chem. 267, 17631-17634 [Abstract/Free Full Text]
  29. Nguyen, V. T., and Bensaude, O. (1994) Eur. J. Biochem. 220, 239-246 [Abstract]
  30. Todd, M. J., Viitanen, P. V., and Lorimer, G. H. (1994) Science 265, 659-666 [Medline] [Order article via Infotrieve]
  31. Trent, J. D., Nimmesgern, E., Wall, J. S., Hartl, F. U., and Horwich, A. L. (1991) Nature 354, 490-493 [CrossRef][Medline] [Order article via Infotrieve]
  32. Tsugita, A., Inouye, M., Terzaghi, E., and Streisinger, G. (1968) J. Biol. Chem. 243, 391-397 [Abstract/Free Full Text]
  33. Weissman, J. S., Kashi, Y., Fenton, W. A., and Horwich, A. L. (1994) Cell 78, 693-702 [Medline] [Order article via Infotrieve]
  34. Ziemienowicz, A., Skowyra, D., Zeilstra-Ryalls, J., Fayet, O., Georgopoulos, C., and Zylicz, M. (1993) J. Biol. Chem. 268, 25425-25431 [Abstract/Free Full Text]

©1995 by The American Society for Biochemistry and Molecular Biology, Inc.