Promotion of the in vitro renaturation of dodecameric glutamine synthetase from Escherichia coli in the presence of GroEL (chaperonin-60) and ATP

Model peptide studies demonstrate that amphipathic secondary structures can be recognized by the chaperonin GroEL (cpn60)

The molecular chaperone cpn60 binds many unfolded proteins and facilitates their proper folding. Synthetic peptides have been used to probe the question of how cpn60 might recognize such a diverse set of unfolded proteins. Three hybrid peptides were synthesized encompassing portions of the bee venom peptide, apamin, and the sequence KWLAESVRAGK from an amphipathic helix in the NH2-terminal region of bovine rhodanese. Two disulfides connecting cysteine residues hold the peptides in stable helical conformations with unobstructed faces oriented away from the disulfides. Peptides were designed to present either a hydrophobic or hydrophilic face of the amphipathic helix that is similar to the one near the amino terminus of rhodanese. Aggregation of these peptides was detected by measuring 1,1'-bis(4-anilino)napthalene-5,5'-disulfonic acid (bisANS) fluorescence at increasing peptide concentrations, and aggregation was not apparent below 2 microM. Thus, all experiments with the peptides were performed at a concentration of 1 microM. Reducing agents cause these helical peptides to form random coils. Fluorescence anisotropy measurements of fluorescein-labeled peptide with the exposed hydrophobic face yielded a Kd = approximately 106 microM for binding to cpn60, whereas there was no detectable binding of the reduced form. The peptide with the exposed hydrophilic face did not bind to cpn60 in either the oxidized or reduced states. Fluorescence experiments utilizing bisANS as a probe showed that binding of the helical hydrophobic peptide could induce the exposure of hydrophobic surfaces on cpn60, whereas the same peptide in its random coil form had no effect. Thus, binding to cpn60 is favored by a secondary structure that organizes and exposes a hydrophobic surface, a feature found in amphipathic helices. Further, the binding of a hydrophobic surface to cpn60 can induce further exposure of complementary surfaces on cpn60 complexes, thus amplifying interactions available for target proteins.

Intrinsic fluorescence studies of the chaperonin GroEL containing single Tyr --> Trp replacements reveal ligand-induced conformational changes

Two mutants of GroEL containing the single tyrosine to tryptophan replacement of either residue 203 or 360 in the apical domain have been purified, characterized, and used for fluorescence studies. Both mutants can facilitate the in vitro refolding of rhodanese in an ATP- and GroES-dependent manner, producing yields of recoverable activity comparable to the wild-type chaperonin. Y203W shows some increased hydrophobic exposure and easier urea-induced disassembly compared with wild-type or Y360W, although the unfolding of all the species was similar at high concentrations of urea. Intrinsic fluorescence studies of the two mutants reveal that nucleotide binding (ADP or AMP-PNP (adenosine 5'-(beta,gamma-imino)triphosphate)) induces conformational changes in the tetradecamer that are independent of the presence of the co-chaperonin, GroES. The K1/2 for this transition is approximately 5 microM for both mutants. Energy transfer experiments show that the tryptophan fluorescence of the Y360W mutant is partially quenched ( approximately 50%) upon binding of the fluorescent, hydrophobic probe 4,4'-bis(1-anilino-8-naphthalenesulfonic acid), while the fluorescence of the Y203W mutant is significantly quenched ( approximately 75%). These results are discussed in relation to the molecular mechanism for GroEL function.

GroEL reversibly binds to, and causes rapid inactivation of, human carbonic anhydrase II at high temperatures

The initial yield of reactivation of GuHCl denatured human carbonic anhydrase II does not change with temperature between 3 and 35 degrees C. At temperatures above 35 degrees C, the enzymatic activity is not stable, but decreases over time. If the bacterial chaperonin GroEL is present during reactivation, the initial yield is lower compared to the spontaneous reaction at temperatures of 35-50 degrees C. However, unlike the spontaneous reactivation, the enzymatic activity with time in the presence of GroEL. In the presence of GroEL, native HCA II incubated at elevated temperatures will rapidly loose enzymatic activity to the same value as during reactivation at that particular temperature; most of the activity will recover if the temperature is lowered when GroEL is present. It is evident that there is an equilibrium between an inactive intermediate of HCA II, probably bound to GroEL, and active enzyme. Furthermore, proline isomerization is part of the rate-limiting step of refolding even in the presence of GroEL, and it is very noteworthy that prolyl isomerase will influence the refolding of HCA II in the presence of GroEL.

Nucleotides reveal polynucleotide phosphorylase activity from conventionally purified GroEL

GroEL, as conventionally purified, can be incubated with nucleotides to produce high molecular weight material with an absorption maximum at 260 nm. This material is most clearly demonstrated when samples are subjected to gel filtration under conditions where GroEL is monomeric. There is a time-dependent increase in the high molecular weight material that occurs on incubation with ADP or, more slowly, with ATP. This material is generated during incubation, and none is present in the initial samples. Experiments with nucleases, proteases, radiolabeled nucleotides, and chemical cleavage reagents demonstrate that the high molecular weight material is polyadenylic acid whose formation is inhibited by phosphate. These results are consistent with the GroEL samples containing polynucleotide phosphorylase activity. Nondenaturing gels stained with acridine orange, after incubation in ADP, reveal that the activity producing the poly(A) coelectrophoreses with authentic polynucleotide phosphorylase. Conditions that remove the tryptophan-like fluorescence from preparations of GroEL also remove the PNPase activity. Thus, this activity is not associated with GroEL itself. The results are consistent with reports that GroEL can associate with RNase E and with other studies showing that RNase E and PNPase can form complexes. Thus, the present experiments support suggestions that GroEL can participate in multiprotein complexes that are involved in mRNA processing and degradation.

In vivo and in vitro folding of a recombinant metalloenzyme, phosphomannose isomerase

Phosphomannose isomerase (PMI) catalyses the interconversion of mannose 6-phosphate and fructose 6-phosphate in prokaryotic and eukaryotic cells. The enzyme is a metalloenzyme which contains 1 mol of zinc per mol of enzyme. Heterologous expression of the cDNA coding for the Candida albicans enzyme in the prokaryotic host Escherichia coli results in an expression level of up to 30% of total E. coli protein. Ten percent of recombinant PMI is expressed in the soluble fraction and 90% in inclusion bodies. Inclusion of a high level of zinc in the fermentation medium resulted in a fourfold increase in soluble protein. Co-expression of the bacterial chaperones, GroES and GroEL, resulted in a proportional twofold increase in soluble PMI while causing an overall decrease in the PMI expression level. Folding denatured PMI in vitro required reductant and zinc ions. The yield of renatured protein was increased by folding in the presence of GroEL and DnaK in an ATP-independent manner. The refolding yield of denatured soluble enzyme from a guanidine solution was threefold higher than that of folding monomerized inclusion body protein solubilized in guanidine hydrochloride. This suggests that a proportion of recombinant protein expressed in E.coli inclusion bodies may be irreversibly denatured.

Ligand-induced conformational changes of GroEL are dependent on the bound substrate polypeptide

Ligand-induced conformational changes of GroEL alone and with bound rhodanese, citrate synthase, or dihydrofolate reductase were studied by limited proteolysis. Similar digestion patterns of GroEL, with or without bound substrate polypeptide, were obtained in the absence and presence of the chaperonin ligands, K+, Mg2+, or ATP. The rates of formation and degradation of the six produced proteolytic fragments were significantly different, however. Strikingly, only with Mg2+/ATP or K+/Mg2+/ATP an additional fragment of approximately 25 kDa was generated during digestion of GroEL alone or with bound rhodanese or dihydrofolate reductase, but not with bound citrate synthase. Most of the trypsin-sensitive sites in GroEL were localized in the flexible apical domain, which contains the putative polypeptide-binding region. Our data indicate that subtle structural changes in the trypsin-sensitive regions of GroEL occur as a result of the binding of the chaperonin ligands. However, these structural changes are influenced by the GroEL substrate polypeptides.

Ligand-induced conformational changes in the apical domain of the chaperonin GroEL

Although the role of nucleotides in the catalytic cycle of the GroESL chaperonin system has been extensively studied, the molecular effects of nucleotides in modulating exposure of sites on GroEL has not been thoroughly investigated. We report here that nucleotides (ATP, ADP, or adenosine 5'-(beta, gamma-imino)triphosphate) in the presence of Mg2+ make the oligomer selectively sensitive to trypsin proteolysis in a fashion suggesting conformational changes in the monomers of one heptameric ring. The site of proteolysis in the monomer that is exposed upon nucleotide binding by the oligomer is in the apical domain (Arg-268). Further, complexes of GroEL with GroES or rhodanese display the same sensitivity to proteolysis, unlike the GroEL-GroES-rhodanese complex, which is protected from proteolysis. The influence of various cations on trypsin proteolysis is investigated to elucidate the differential effects that monovalent and divalent cations have on the oligomeric structure of the chaperonin. These results are discussed in relation to the molecular basis for the chaperonin activity.

The chaperonin GroEL is destabilized by binding of ADP

The urea-induced dissociation and subsequent conformational transitions of the nucleotide-bound form of GroEL were studied by light scattering, 4,4'-bis(1-anilino-8- naphthalenesulfonic acid) binding, and intrinsic tyrosine fluorescence. Magnesium ion alone (10 mM) stabilizes GroEL and leads to coordination of the structural transitions monitored by the different parameters. The midpoint of the light-scattering transition that monitored dissociation of the 14-mer with bound magnesium was raised to approximately 3 M, which is considerably higher than the ligand-free form of the protein, which exhibits a transition with a midpoint at approximately 2 M urea. Binding of ADP results in destabilization of the GroEL oligomeric structure, and complete dissociation of the 14-mer in the presence of 5 mM ADP occurs at about 2 M urea with the midpoint of the transition at approximately 1 M urea. The same destabilization by ADP and stabilization by Mg2+ were seen when the conformation was followed by the intrinsic fluorescence. Complexation with the nonhydrolyzable ATP analog, 5'-adenylimidodiphosphate gave an apparent stability of the quaternary structure that was between that observed with Mg2+ and that with ADP. The ADP-bound form of the protein demonstrated increased hydrophobic exposure at lower urea concentrations than the uncomplexed GroEL. In addition, the GroEL-ADP complex is more accessible for proteolytic digestion by chymotrypsin than the uncomplexed protein, consistent with a more open, flexible form of the protein. The implication of the conformational changes to the mechanism of the GroEL function is discussed.

Inactive GroEL monomers can be isolated and reassembled to functional tetradecamers that contain few bound peptides

For the first time, it has been shown that GroEL can be converted from tetradecamers (14-mers) to monomers under conditions commonly used for the preparation of this chaperonin. The essential requirements are the simultaneous presence of nucleotides such as MgATP or MgADP and a solid-phase anion-exchange medium. The monomers that are formed are metastable in that they only reassemble to a small degree in the absence of additives. These results are in keeping with previous studies on high pressure dissociation that showed the separated monomers display conformational plasticity and can undergo conformational relaxation when relieved of the constraints of the quaternary structure in the oligomer (Gorovits, B., Raman, C. S., and Horowitz, P. M. (1995) J. Biol. Chem. 270, 2061-2066). The monomers display greatly enhanced hydrophobic exposure to the probe 1,1'-bis(4-anilino)naphthalene-5,5'-disulfonic acid, although they are not active in folding functions, and they are unable to form complexes with partially folded rhodanese. The monomers can be completely reassembled to 14-mers by incubation in 1 M ammonium sulfate. There is no evidence of intermediates in the reassembly process. Compared with the original oligomers, the reassembled 14-mers have (a) very low levels of polypeptide contaminants and tryptophan-like fluorescence, two problems that previously hampered spectroscopic studies of GroEL structure and function; (b) functional properties that are very similar to the original material; (c) considerably decreased hydrophobic exposure in the native state; and (d) a similar triggered exposure of hydrophobic surfaces after treatment with urea or spermidine. This study demonstrates that the quaternary structure of GroEL is more labile than previously thought. These results are consistent with suggestions that nucleotides can loosen subunit interactions and show that changes in quaternary structure can operate under conditions where GroEL function has been demonstrated.

Rapid refolding studies on the chaperone-like alpha-crystallin. Effect of alpha-crystallin on refolding of beta- and gamma-crystallins

alpha-Crystallin, a multimeric protein present in the eye lens, is shown to have chaperone-like activity in preventing thermally induced aggregation of enzymes and other crystallins. We have studied the rapid refolding of alpha-crystallin, and compared it with other calf eye lens proteins, namely beta- and gamma-crystallins. alpha-Crystallin forms a clear solution upon rapid refolding from 8 M urea. The refolded alpha-crystallin has native-like secondary, tertiary, and quaternary structures as revealed by circular dichroism and fluorescence characteristics as well as gel filtration and sedimentation velocity measurements. On rapid refolding, beta- and gamma-crystallins aggregate and form turbid solutions. The presence of alpha-crystallin in the refolding buffer marginally increases the recovery of beta- and gamma-crystallins in the soluble form. However, unfolding of these crystallins together with alpha-crystallin using 8 M urea and subsequent refolding significantly increases the recovery of these proteins in the soluble form. These results indicate that an intermediate of alpha-crystallin formed during refolding is more effective in preventing the aggregation of beta- and gamma-crystallins. This supports our earlier hypothesis (Raman, B., and Rao, C. M. (1994) J. Biol. Chem. 269, 27264-27268) that the chaperone-like activity of alpha-crystallin is more pronounced in its structurally perturbed state.

Functional characterization of the higher plant chloroplast chaperonins

The higher plant chloroplast chaperonins (ch-cpn60 and ch-cpn10) have been purified and their structural/functional properties examined. In all plants surveyed, both proteins were constitutively expressed, and only modest increases in their levels were detected upon heat shock. Like GroEL and GroES of Escherichia coli, the chloroplast chaperonins can physically interact with each other. The asymmetric complexes that form in the presence of ADP are "bullet-shaped" particles that likely consist of 1 mol each of ch-cpn60 and ch-cpn10. The purified ch-cpn60 is a functional molecular chaperone. Under "nonpermissive" conditions, where spontaneous folding was not observed, it was able to assist in the refolding of two different target proteins. In both cases, successful partitioning to the native state also required ATP hydrolysis and chaperonin 10. Surprisingly, however, the "double-domain" ch-cpn10, comprised of unique 21-kDa subunits, was not an obligatory co-chaperonin. Both GroES and a mammalian mitochondrial homolog were equally compatible with the ch-cpn60. Finally, the assisted-folding reaction mediated by the chloroplast chaperonins does not require K+ ions. Thus, the K(+)-dependent ATPase activity that is observed with other known groEL homologs is not a universal property of all chaperonin 60s.

Tetradecameric chaperonin 60 can be assembled in vitro from monomers in a process that is ATP independent

The present work shows that monomers of cpn60 (groEL) formed at 2.5 M urea could be assembled to tetradecamers in a process that was independent of ATP. Reassembled cpn60 was able to assist the folding of urea unfolded rhodanese. When cpn60 was incubated at urea concentrations higher than 2.75 M, assembly of tetradecameric cpn60 did not occur after dialysis, and the presence of ATP did not stimulate the assembly process. The cpn60 used here did not display the previously reported ATP-dependent self-assembly of cpn60 monomers that required a higher urea concentration (4 M) for formation (Lissen et al. (1990) Nature 348, 339-342). Assembly and disassembly of cpn60 tetradecamers were followed as a function of the urea concentration by ultracentrifugation and gel electrophoresis in the presence of urea. The electrophoresis results demonstrate that there is rapid assembly of tetradecamers following preincubation and rapid removal of urea at concentrations lower than 2.5 M. Thus, previous methods monitored irreversible dissociation of cpn60, and the present results indicate that the cpn60 assembly requirements for ATP are dependent on pretreatment conditions.

Solution X-ray scattering study on the chaperonin GroEL from Escherichia coli

The molecular architecture of native GroEL has been studied by solution X-ray scattering. The radius of gyration for the native molecule was estimated to be 66.0 A in 50 mM Tris-HCl, 100 mM KCl at pH 7.5 and 25 degrees C. The maximum dimension was estimated to be 170 A, based on the pair distance distribution function. A cylindrical structure or two heptameric rings was found to be the best for native GroEL among structures examined by using a multi-sphere model analysis in which the radius of constituent sphere was 6 A. The results of the model analysis show that the radius of GroEL is 68.0 A and the height is 150.7 A. Unexpectedly, the central penetrating hole through GroEL was not confirmed in the best-fit structure.

Homologous proteins with different affinities for groEL. The refolding of the aspartate aminotransferase isozymes at varying temperatures

The homologous cytosolic and mitochondrial isozymes of aspartate aminotransferase (c- and mAspAT, respectively) seem to follow very different folding pathways after synthesis in rabbit reticulocyte lysate, suggesting that the nascent proteins interact differently with molecular chaperones (Mattingly, J. R., Jr., Iriarte, A., and Martinez-Carrion, M. (1993) J. Biol. Chem. 268, 26320-26327). In an attempt to discern the structural basis for this phenomenon, we have begun to study the effect of temperature on the refolding of the guanidine hydrochloride-denatured, purified proteins and their interaction with the groEL/groES molecular chaperone system from Escherichia coli. In the absence of chaperones, temperature has a critical effect on the refolding of the two isozymes, with mAspAT being more susceptible than cAspAT to diminishing refolding yields at increasing temperatures. No refolding is observed for mAspAT at physiological temperatures. The molecular chaperones groEL and groES can extend the temperature range over which the AspAT isozymes successfully refold; however, cAspAT can still refold at higher temperatures than mAspAT. In the absence of groES and MgATP, the two isozymes interact differently with groEL, groEL arrests the refolding of mAspAT throughout the temperature range of 0-45 degrees C. Adding only MgATP releases very little mAspAT from groEL; both groES and MgATP are required for significant refolding of mAspAT in the presence of groEL. On the other hand, the extent to which groEL inhibits the refolding of cAspAT depends upon the temperature of the refolding reaction, only slowing the reaction at 0 degrees C but arresting it completely at 30 degrees C. MgATP alone is sufficient to effect the release of cAspAT from groEL at any temperature examined; inclusion of groES along with MgATP has no effect on the refolding yield but does increase the refolding rate at temperatures greater than 15 degrees C. These results demonstrate that groEL can have significantly different affinities for proteins with highly homologous final tertiary and quarternary structures and suggest that dissimilarities in the primary sequence of the protein substrates may control the structure of the folding intermediates captured by groEL and/or the composition of the surfaces through which the folding proteins interact with groEL.

The guanidine-induced conformational changes of the chaperonin GroEL from Escherichia coli. Evidence for the existence of an unfolding intermediate state

Equilibrium unfolding experiments of the E. coli chaperonin GroEL were performed in guanidine hydrochloride. A reversible unfolding intermediate was observed in very low concentrations of denaturant (< 0.5 M guanidine hydrochloride). This intermediate was characterized by a decreased light scattering intensity and an increased binding of the fluorescent probe 1-anilino-8-naphthalene sulfonate. No significant changes in circular dichroism spectra were observed for this unfolding intermediate. A second decrease in fluorescence intensity and light scattering was observed in higher concentrations of guanidine hydrochloride, with a transitional midpoint of 1.15 M. This transition was accompanied by the complete loss of secondary structure, as monitored by circular dichroism spectroscopy. This second transition agreed well with the results previously reported in this journal (Price et al. (1993) Biochim. Biophys. Acta 1161, 52-58).

Refolding and release of tubulins by a functional immobilized groEL column

Denatured tubulins form stable complexes with groEL upon dilution into refolding buffer. These complexes are retained on an immunoaffinity column which contains chemically immobilized antibodies to groEL. Tubulin remains bound to the immobilized groEL column after extensive washing and is released upon incubation with groES and ATP. Similar results were obtained with glutamine synthetase. These data suggest that groEL can function while it is attached to a solid support system.

The chaperonin from the archaeon Sulfolobus solfataricus promotes correct refolding and prevents thermal denaturation in vitro

We have isolated a chaperonin from the hyperthermophilic archaeon Sulfolobus solfataricus based on its ability to inhibit the spontaneous refolding at 50 degrees C of dimeric S. solfataricus malic enzyme. The chaperonin, a 920-kDa oligomer of 57-kDa subunits, displays a potassium-dependent ATPase activity with an optimum temperature at 80 degrees C. S. solfataricus chaperonin promotes correct refoldings of several guanidine hydrochloride-denatured enzymes from thermophilic and mesophilic sources. At a molar ratio of chaperonin oligomer to single polypeptide chain of 1:1, S. solfataricus chaperonin completely inhibits spontaneous refoldings and suppresses aggregation upon dilution of the denaturant; refoldings resume upon ATP hydrolysis, with yields of active molecules and rates of folding notably higher than in spontaneous processes. S. solfataricus chaperonin prevents the irreversible inactivations at 90 degrees C of several thermophilic enzymes by the binding of the denaturation intermediate; the time-courses of inactivations are unaffected and most activity is regained upon hydrolysis of ATP. S. solfataricus chaperonin completely prevents the formation of aggregates during thermal inactivation of chicken egg white lysozyme at 70 degrees C, without affecting the rate of activity loss; ATP hydrolysis results in the recovery of most lytic activity. Tryptophan fluorescence measurements provide evidence that S. solfataricus chaperonin undergoes a dramatic conformational rearrangement in the presence of ATP/Mg, and that the hydrolysis of ATP is not required for the conformational change. The ATP/Mg-induced conformation of the chaperonin is fully unable to bind the protein substrates, probably due to disappearance or modification of the substrate binding sites. This is the first archaeal chaperonin whose involvement in protein folding has been demonstrated.

The chaperonin GroEL does not recognize apo-alpha-lactalbumin in the molten globule state

We investigate here the interaction between GroEL and two kinds of non-native alpha-lactalbumin. alpha-Lactalbumin is a Ca(2+)-binding protein which assumes a molten globule state in the absence of Ca2+ (apo-alpha-lactalbumin) at neutral pH. Our results, obtained by molecular-sieve chromatography and hydrogen-exchange measurements, show that apo-alpha-lactalbumin in this molten globule state is not bound to GroEL either in the absence or in the presence of KCl. On the other hand, we show by molecular-sieve chromatography that alpha-lactalbumin, in which the four disulphide bonds are fully reduced, is bound to GroEL when 50 mM KCl is present. The results demonstrate that the protein state recognized by GroEL is more unfolded and expanded than the typical molten globule state of alpha-lactalbumin.

Affinity of chaperonin-60 for a protein substrate and its modulation by nucleotides and chaperonin-10

The refolding of lactate dehydrogenase fully unfolded in 4 M guanidinium chloride was initiated by dilution into assay buffer, and the emergence of active enzyme was recorded. This was performed in the presence of the following chaperonin complexes in the refolding medium: chaperonin-60 (cpn60), cpn60-MgATP, cpn60-Mgp[NH]ppA, cpn60-MgADP in both the presence and absence of chaperonin-10 (cpn10). For each nucleotide-chaperonin complex studied, the effect of nucleotide concentration was measured. Dissociation constants (Kd) for unfolded LDH bound to the various chaperonin complexes were derived directly from the ability of the complexes to retard the folding of the enzyme. Dissociation constants for the different complexes were found to be in the order: cpn60 < cpn60-MgADP-cpn10 (formed at low [MgADP]) < cpn60-MgADP < cpn60-MgADP-cpn10 < cpn60-Mgp[NH]ppA < cpn60-Mgp[NH]ppA-cpn10 < cpn60-MgATP < cpn60-MgATP-cpn10; i.e. the tightest complex is with cpn60 and the weakest with cpn60-MgATP-cpn10. Only when MgATP is the nucleotide do we see the yield of native enzyme increased on the time scale of 1 h. The results provide estimates of the change in binding energy between the chaperonin and a substrate protein through the cycle of MgATP binding, hydrolysis and dissociation.

The chaperonin cycle and protein folding

The process of protein folding in the cell is now known to depend on the action of other proteins. These proteins include molecular chaperones, which interact non-covalently with proteins as they fold and improve the final yields of active protein in the cell. The precise mechanism by which molecular chaperones act is obscure. Experiments reported recently show that for one molecular chaperone (Cpn60, typified by the E. coli protein GroEL), the folding reaction is driven by cycles of binding and release of the co-chaperone Cpn10 (known as GroES in E. coli). These alternate with binding and release of the unfolded protein substrate. These cycles come about because of the opposite effects of Cpn10 and unfolded protein on the Cpn60 complex: the former stabilises the ADP-bound state of Cpn60, whereas the latter stimulates ADP-ATP exchange. This model proposes that the substrate protein goes through multiple cycles of binding and release, and is released into the cavity of the Cpn60 complex where it can undergo folding without interacting with other nearby folding intermediates. This is consistent with the ability of Cpn60 proteins to enhance folding by blocking pathways to aggregation.

Heat-shock-increased survival to far-UV radiation in Escherichia coli is wavelength dependent

Heat-shock-induced resistance to far-UV (FUV) radiation was studied in Escherichia coli. The induction of FUV resistance was shown to be dependent on the products of the genes uvrA and polA in bacteria irradiated at 254 nm. Heat shock increased the resistance to 280 nm radiation in a uvrA6 recA13 mutant. Heat shock lowered the mutation frequency (reversion to tryptophan proficiency) in wild-type or uvrA strains irradiated at 254 nm. When these strains were irradiated at 280 nm, heat shock did not interfere with the mutation frequency in the wild-type strain, but greatly enhanced mutations in the uvrA mutant. After heat-shock treatment, the wild-type strain irradiated at 254 nm showed increased DNA degradation, indicating enhanced repair activity. However, heat shock did not stimulate SOS repair triggered by FUV. An increased survival of bacteriophages irradiated with FUV and inoculated into heat-shock-treated bacteria was not detected. The possibility that heat shock enhances excision repair activity in a wavelength-dependent manner is discussed.

The chaperonin assisted and unassisted refolding of rhodanese can be modulated by its N-terminal peptide

The in vitro refolding of the monomeric, mitochondrial enzyme rhodanese (thiosulfate: cyanide sulfurtransferase, EC 2.8.1.1), which is assisted by the E. coli chaperonins, is modulated by the 23 amino acid peptide (VHQVLYRALVSTKWLAESVRAGK) corresponding to the amino terminal sequence (1-23) of rhodanese. In the absence of the peptide, a maximum recovery of active enzyme of about 65% is achieved after 90 min of initiation of the chaperonin assisted folding reaction. In contrast, this process is substantially inhibited in the presence of the peptide. The maximum recovery of active enzyme is peptide concentration-dependent. The peptide, however, does not prevent the interaction of rhodanese with the chaperonin 60 (cpn60), which leads to the formation of the cpn60-rhodanese complex. In addition, the peptide does not affect the rate of recovery of active enzyme, although it does affect the extent of recovery. Further, the unassisted refolding of rhodanese is also inhibited by the peptide. Thus, the peptide interferes with the folding of rhodanese in either the chaperonin assisted or the unassisted refolding of the enzyme. A 13 amino acid peptide (STKWLAESVRAGK) corresponding to the amino terminal sequence (11-23) of rhodanese does not show any significant effect on the chaperonin assisted or unassisted refolding of the enzyme. The results suggest that other sequences of rhodanese, in addition to the N-terminus, may be required for the binding of cpn60, in accord with a model in which cpn60 interacts with polypeptides through multiple binding sites.

Stable expression plasmid for high-level production of GroE molecular chaperones in large-scale cultures

A stable expression plasmid has been developed to overproduce the Escherichia coli GroES and GroEL molecular chaperones in large-scale cultures. This was achieved by cloning the groE operon under the transcriptional control of a bacteriophage T7 promoter to achieve regulated expression. Isopropyl-beta-D-thiogalactopyranoside (IPTG) induction of a lacUV5 regulated chromosomal copy of T7 gene 1, encoding viral RNA polymerase, resulted in high-level expression of the groE operon from a multicopy plasmid. Induced cells harboring the pT7groE expression plasmid accumulated GroEL to levels of 30% total cell protein, and GroES to 4-5%. Both overproduced proteins were recovered primarily from the soluble fraction of lysed cells. The T7 expression plasmid was significantly more stable than other groE expression plasmids tested during scale-up experiments, and could be used successfully for large-volume cultures of up to 200 l. Strain stability was greatly improved, compared to rich media, when cells were grown in a supplemented minimal medium.

GroE-mediated folding of bacterial luciferases in vivo

In this study we present evidence indicating that GroE chaperonins mediate de novo protein folding of heterodimeric and monomeric luciferases under heat shock or sub-heat shock conditions in vivo. The effects of additional groESL and groEL genes on the bioluminescence of Escherichia coli cells expressing different bacterial luciferase genes at various temperatures were directly studied in cells growing in liquid culture. Data indicate that at 42 degrees C GroESL chaperonins are required for the folding of the beta subunit polypeptide of the heterodimeric alpha beta luciferase from the mesophilic bacterium Vibrio harveyi MAV (B392). In contrast, the small number of amino acid substitutions present in the luciferase beta subunit polypeptide from the thermotolerant V. harveyi CTP5 suppresses this requirement for GroE chaperonins, and greatly reduces interaction between the beta subunit polypeptide and GroEL chaperonin. In addition, GroESL are required for the de novo folding at 37 degrees C of a MAV alpha beta luciferase fusion polypeptide that is functional as a monomer. No such requirement for luciferase activity is observed at that temperature with a fusion of the CTP5 alpha and beta subunit polypeptides, although GroE chaperonins can still mediate folding of the CTP5 fusion luciferase. Bacterial luciferases provide a unique system for direct observation of the effects of GroE chaperonins on protein folding and enzyme assembly in living cells. Furthermore, they offer a sensitive and simple assay system for the identification of polypeptide domains required for GroEL protein binding.

Escherichia coli chaperonins cpn60 (groEL) and cpn10 (groES) do not catalyse the refolding of mitochondrial malate dehydrogenase

In vitro refolding of pig mitochondrial malate dehydrogenase is investigated in the presence and absence of Escherichia coli chaperonins cpn60 (groEL) and cpn10 (groES). The refolded yields of active malate dehydrogenase are increased almost 3-fold in the presence of groEL, groES, Mg2+/ATP and K+ ions. Chaperonin-assisted refolding of malate dehydrogenase does not have an absolute requirement for K+ ions but Mg2+/ATP is obligatory. When ATP is replaced by other nucleoside triphosphates, or by non-hydrolysable ATP analogues, assisted refolding is prevented. Optimal chaperonin-assisted refolding requires both groEL and groES homo-oligomers in molar excess over malate dehydrogenase. Kinetic analysis shows that the chaperonins do not catalyse the refolding of malate dehydrogenase but increase the flux of unfolded enzyme through the productive refolding pathway without altering and/or accelerating that pathway. Although not acting as refolding catalysts, the chaperonins are able to assist at least six consecutive cycles of malate dehydrogenase refolding.

Chaperonins and protein folding: unity and disunity of mechanisms

Chaperonin-facilitated folding of proteins involves two partial reactions. The first partial reaction, the formation of stable binary complexes between chaperonin-60 and non-native states of the target protein, is common to the chaperonin-facilitated folding of all target proteins investigated to date. The structural basis for this interaction is not presently understood. The second partial reaction, the dissociation of the target protein in a form committed to the native state, appears to proceed by a variety of mechanisms, dependent upon the nature of the target protein in question. Those target proteins (e.g. rubisco, rhodanese, citrate synthase) which require the presence of chaperonin-10, also appear to require the hydrolysis of ATP to bring about the dissociation of the target protein from chaperonin-60. With one exception (pre-beta-lactamase) those target proteins which do not require the presence of chaperonin-10 to be released from chaperonin-60, also do not require the hydrolysis of ATP, since non-hydrolysable analogues of ATP support the release of the target protein in a state committed to the native state. The question of whether or not chaperonin-facilitated folding constitutes a catalysed event is addressed.