Structural analysis of the Sulfolobus solfataricus TF55ß chaperonin by cryo-electron microscopy.

Chaperonins are biomolecular complexes that assist in protein folding. Thermophilic factor 55 (TF55) is a group II chaperonin found in the archaeal genus Sulfolobus that has α, ß and γ subunits. Using cryo-electron microscopy, structures of the ß-only complex of S. solfataricus TF55 (TF55ß) were determined to 3.6-4.2 Šresolution. The structures of the TF55ß complexes formed in the presence of ADP or ATP highlighted an open state in which nucleotide exchange can occur before progressing in the refolding cycle.

Atomic modeling of cryo-electron microscopy reconstructions--joint refinement of model and imaging parameters.

When refining the fit of component atomic structures into electron microscopic reconstructions, use of a resolution-dependent atomic density function makes it possible to jointly optimize the atomic model and imaging parameters of the microscope. Atomic density is calculated by one-dimensional Fourier transform of atomic form factors convoluted with a microscope envelope correction and a low-pass filter, allowing refinement of imaging parameters such as resolution, by optimizing the agreement of calculated and experimental maps. A similar approach allows refinement of atomic displacement parameters, providing indications of molecular flexibility even at low resolution. A modest improvement in atomic coordinates is possible following optimization of these additional parameters. Methods have been implemented in a Python program that can be used in stand-alone mode for rigid-group refinement, or embedded in other optimizers for flexible refinement with stereochemical restraints. The approach is demonstrated with refinements of virus and chaperonin structures at resolutions of 9 through 4.5 Å, representing regimes where rigid-group and fully flexible parameterizations are appropriate. Through comparisons to known crystal structures, flexible fitting by RSRef is shown to be an improvement relative to other methods and to generate models with all-atom rms accuracies of 1.5-2.5 Å at resolutions of 4.5-6 Å.

A single amino acid residue is responsible for species-specific incompatibility between CCT and alpha-actin.

Actin is dependent on the type-II chaperonin CCT (chaperonin containing TCP-1) to reach its native state. In vitro, yeast CCT folds yeast and also mammalian cytoplasmic (beta/gamma) actins but is now found to be incapable of folding mammalian skeletal muscle alpha-actin. Arrest of alpha-actin on yeast CCT at a folding cycle intermediate has been observed by electron microscopy. This discovery explains previous observations in vivo that yeast mutants expressing only the muscle actin gene are non-viable. Mutational analysis identified a single specific alpha-actin residue, Asn-297, that confers this species/isoform folding specificity. The implications of this incompatibility for chaperonin mechanism and actin-CCT co-evolution are discussed.

GroEL assisted folding of large polypeptide substrates in Escherichia coli: Present scenario and assignments for the future.

Escherichia coli chaperonins GroEL and GroES are indispensable for survival and growth of the cell since they provide essential assistance to the folding of many newly translated proteins in the cell. Recent studies indicate that a substantial portion of the proteins involved in the host pathways are completely dependent on GroEL-GroES for their folding and hence providing some explanation for why GroEL is essential for cell growth. Many proteins either small-single domain or large multidomains require assistance from GroEL-ES during their lifetime. Proteins of size up to approximately 70kDa can fold via the cis mechanism during GroEL-ES assisted pathway, but other proteins (>70kDa) that cannot be pushed inside the cavity of GroEL-ATP complex upon binding of GroES fold by an evolved mechanism called trans. In recent years, much work has been done on revealing facts about the cis mechanism involving the GroEL assisted folding of small proteins whereas the trans mechanism with larger polypeptide substrates still remains under cover. In order to disentangle the role of chaperonin GroEL-GroES in the folding of large E. coli proteins, this review discusses a number of issues like the range of large polypeptide substrates acted on by GroEL. Do all these substrates need the complete chaperonin system along with ATP for their folding? Does GroEL act as foldase or holdase during the process? We conclude with a discussion of the various queries that need to be resolved in the future for an extensive understanding of the mechanism of GroEL mediated folding of large substrate proteins in E. coli cytosol.

Mechanism of lid closure in the eukaryotic chaperonin TRiC/CCT.

All chaperonins mediate ATP-dependent polypeptide folding by confining substrates within a central chamber. Intriguingly, the eukaryotic chaperonin TRiC (also called CCT) uses a built-in lid to close the chamber, whereas prokaryotic chaperonins use a detachable lid. Here we determine the mechanism of lid closure in TRiC using single-particle cryo-EM and comparative protein modeling. Comparison of TRiC in its open, nucleotide-free, and closed, nucleotide-induced states reveals that the interdomain motions leading to lid closure in TRiC are radically different from those of prokaryotic chaperonins, despite their overall structural similarity. We propose that domain movements in TRiC are coordinated through unique interdomain contacts within each subunit and, further, these contacts are absent in prokaryotic chaperonins. Our findings show how different mechanical switches can evolve from a common structural framework through modification of allosteric networks.

Multiple states of a nucleotide-bound group 2 chaperonin.

Chaperonin action is controlled by cycles of nucleotide binding and hydrolysis. Here, we examine the effects of nucleotide binding on an archaeal group 2 chaperonin. In contrast to the ordered apo state of the group 1 chaperonin GroEL, the unliganded form of the homo-16-mer Methanococcus maripaludis group 2 chaperonin is very open and flexible, with intersubunit contacts only in the central double belt of equatorial domains. The intermediate and apical domains are free of contacts and deviate significantly from the overall 8-fold symmetry. Nucleotide binding results in three distinct, ordered 8-fold symmetric conformations--open, partially closed, and fully closed. The partially closed ring encloses a 40% larger volume than does the GroEL-GroES folding chamber, enabling it to encapsulate proteins up to 80 kDa, in contrast to the fully closed form, whose cavities are 20% smaller than those of the GroEL-GroES chamber.

Identification of a critical chaperoning region on an archaeal recombinant thermosome.

Chaperone function in water-miscible organic co-solvents is useful for biocatalytic applications requiring enzyme stability in semi-aqueous media and for understanding chaperone behavior in hydrophobic environments. Previously, we have shown that a recombinant single subunit thermosome (rTHS) from Methanocaldococcus jannaschii functions in multiple co-solvents to hydrolyze ATP, prevent protein aggregation, and refold enzymes following solvent denaturation. For the present study, a truncated analog to the thermosome in which 70 N-terminal amino acids are removed is used to identify important regions within the thermosome for its chaperoning functions in organic co-solvents. Data presented herein indicate that the N-terminal region of rTHS is essential for the chaperone to restore the native state of the enzyme citrate synthase, but it is not a critical region for either binding of unfolded proteins or ATP hydrolysis. This is the first demonstration that direct refolding by a Group II chaperonin requires the N-terminal region of the protein.

The inter-ring arrangement of the cytosolic chaperonin CCT.

The eukaryotic cytosolic chaperonin CCT (chaperonin containing TCP-1) is the most complex of all chaperonins-an oligomeric structure built from two identical rings, each composed of single copies of eight different subunits. The arrangement of the eight subunits within each ring has been characterised for some time, but the phasing between the two rings remains unknown. Here, three-dimensional reconstructions generated by cryoelectron microscopy of complexes between CCT and either of two different monoclonal antibodies that react specifically with the CCTepsilon and CCTdelta subunits have been used to determine the phasing between the two chaperonin rings. The inter-ring arrangement is such that up/down inter-ring communication always involves two different CCT subunits in all eight positions, and the group of subunits concerned with the initiation and completion of the folding cycle cluster together both in the intra- and inter-ring arrangement. This supports a sequential mechanism of conformational changes between the two interacting rings.

Sequential ATP-induced allosteric transitions of the cytoplasmic chaperonin containing TCP-1 revealed by EM analysis.

The eukaryotic cytoplasmic chaperonin containing TCP-1 (CCT) is a hetero-oligomeric complex that assists the folding of actins, tubulins and other proteins in an ATP-dependent manner. To understand the allosteric transitions that occur during the functional cycle of CCT, we imaged the chaperonin complex in the presence of different ATP concentrations. Labeling by monoclonal antibodies that bind specifically to the CCTalpha and CCTdelta subunits enabled alignment of all the CCT subunits of a given type in different particles. The analysis shows that the apo state of CCT has considerable apparent conformational heterogeneity that decreases with increasing ATP concentration. In contrast with the concerted allosteric switch of GroEL, ATP-induced conformational changes in CCT are found to spread around the ring in a sequential fashion that may facilitate domain-by-domain substrate folding. The approach described here can be used to unravel the allosteric mechanisms of other ring-shaped molecular machines.

Structure of the complex between the cytosolic chaperonin CCT and phosducin-like protein.

The three-dimensional structure of the complex formed between the cytosolic chaperonin CCT (chaperonin containing TCP-1) and phosducin (Pdc)-like protein (PhLP), a regulator of CCT activity, has been solved by cryoelectron microscopy. Binding of PhLP to CCT occurs through only one of the chaperonin rings, and the protein does not occupy the central folding cavity but rather sits above it through interactions with two regions on opposite sides of the ring. This causes the apical domains of the CCT subunits to close in, thus excluding access to the folding cavity. The atomic model of PhLP generated from several atomic structures of the homologous Pdc fits very well with the mass of the complex attributable to PhLP and predicts the involvement of several sequences of PhLP in CCT binding. Binding experiments performed with PhLP/Pdc chimeric proteins, taking advantage of the fact that Pdc does not interact with CCT, confirm that both the N- and C-terminal domains of PhLP are involved in CCT binding and that several regions suggested by the docking experiment are indeed critical in the interaction with the cytosolic chaperonin.

Archaeal group II chaperonin mediates protein folding in the cis-cavity without a detachable GroES-like co-chaperonin.

Group II chaperonins of archaea and eukaryotes are distinct from group I chaperonins of bacteria. Whereas group I chaperonins require the co-chaperonin Cpn-10 or GroES for protein folding, no co-chaperonin has been known for group II. The protein folding mechanism of group II chaperonins is not yet clear. To understand this mechanism, we examined protein refolding by the recombinant alpha or beta-subunit chaperonin homo-oligomer (alpha16mer and beta16mer) from a hyperthermoplilic archaeum, Thermococcus strain KS-1, using a model substrate, green fluorescent protein (GFP). The alpha16mer and beta16mer captured the non-native GFP and promoted its refolding without any co-chaperonin in an ATP dependent manner. A non-hydrolyzable ATP analog, AMP-PNP, induced the GFP refolding mediated by beta16mer but not by the alpha16mer. A mutant alpha-subunit chaperonin homo-oligomer (trap-alpha) could capture the non-native protein but lacked the ability to refold it. Although trap-alpha suppressed ATP-dependent refolding of GFP mediated by alpha16mer or beta16mer, it did not affect the AMP-PNP-dependent refolding. This indicated that the GFP refolding mediated by beta16mer with AMP-PNP was not accessible to the trap-alpha. Gel filtration chromatography and a protease protection experiment revealed that this refolded GFP, in the presence of AMP-PNP, was associated with beta16mer. After the completion of GFP refolding mediated by beta16mer with AMP-PNP, addition of ATP induced an additional refolding of GFP. Furthermore, the beta16mer preincubated with AMP-PNP showed the ability to capture the non-native GFP. These suggest that AMP-PNP induced one of two chaperonin rings (cis-ring) to close and induced protein refolding in this ring, and that the other ring (trans-ring) could capture the unfolded GFP which was refolded by adding ATP. The present data indicate that, in the group II chaperonin of Thermococcus strain KS-1, the protein folding proceeds in its cis-ring in an ATP-dependent fashion without any co-chaperonin.

Structural comparison of prokaryotic and eukaryotic chaperonins.

Chaperonins are key components of the cell machinery and are involved in the productive folding of proteins. Most chaperonins share a common general morphology based in a cylinder composed of two rings of 7-9 subunits, with a conspicuous cavity inside the particle. Chaperonins have been classified into two groups according to their sequence homologies: type I, whose better known member is GroEL, and type II comprising the eukaryotic cytosolic CCT and the archaebacterial thermosome, among others. Although the basic structure of both chaperonin types is rather similar, there are a number of basic differences among them. Whereas GroEL is rather non-specific regarding its substrate, CCT is more specialized, and plays a fundamental role in the folding of cytoskeletal proteins. Another important difference is that GroEL is an homopolymer, while CCT is an heteromeric complex built up of eight different polypeptides. Furthermore, GroEL requires a cofactor (GroES) that is not present in the type II chaperonins. Recent studies of the structure of CCT have allowed a deeper insight into its function. Electron microscopic analyses have revealed a different behavior of this chaperonin after binding to nucleotides, respect to GroEL. The atomic structure of the thermosome fits into the electron microscopy reconstructed volume of the CCT. This fitting gives clues to compare the structural transitions of GroEL and CCT during the folding cycle. The different changes undergone by the two chaperonins suggest the existence of differences in the way they bind substrates and enlarge the internal cavity, as well as a different type of signaling between the two rings of the types I and II chaperonins.

Eukaryotic chaperonin CCT stabilizes actin and tubulin folding intermediates in open quasi-native conformations.

Three-dimensional reconstruction from cryoelectron micrographs of the eukaryotic cytosolic chaperonin CCT complexed to tubulin shows that CCT interacts with tubulin (both the alpha and beta isoforms) using five specific CCT subunits. The CCT-tubulin interaction has a different geometry to the CCT-actin interaction, and a mixture of shared and unique CCT subunits is used in binding the two substrates. Docking of the atomic structures of both actin and tubulin to their CCT-bound conformation suggests a common mode of chaperonin-substrate interaction. CCT stabilizes quasi-native structures in both proteins that are open through their domain-connecting hinge regions, suggesting a novel mechanism and function of CCT in assisted protein folding.

The thermosome from Methanopyrus kandleri possesses an NH4+-dependent ATPase activity.

The ATPase activity of the thermosome from a methanogen, Methanopyrus kandleri, was characterized in detail. In contrast to all other known chaperonins, enzymatic ATP hydrolysis was found to be strictly dependent on high levels of ammonium salts in vitro. The ths gene encoding the thermosome subunit from the hyperthermophilic M. kandleri was functionally expressed in Escherichia coli and the overproduced polypeptide was assembled into intact thermosome complexes in the mesophilic host. The recombinant particles could be purified by a simple two-step procedure including only one chromatographic step. Structural and biochemical properties of the recombinant protein were closely similar to those of the natural complex. Western blot analysis with an antiserum against the M. kandleri thermosome indicated the presence of at least two subfamilies of archaeal chaperonins.

Chaperonin filaments: their formation and an evaluation of methods for studying them.

Chaperonins are multisubunit protein complexes that can be isolated from cells as high-molecular-weight structures that appear as double rings in the electron microscope. We recently discovered that chaperonin double rings isolated from the hyperthermophilic archaeon Sulfolobus shibatae, when incubated at physiological temperatures in the presence of ATP and Mg2+, stacked into filaments; we hypothesized that these filaments are related to filaments seen inside S. shibatae cells and that chaperonins exist as filaments in vivo (J. D. Trent et al., 1997, Proc. Natl. Acad. Sci. USA 94, 5383-5388). This paper elucidates the conditions under which we have observed S. shibatae chaperonins to form filaments and evaluates native polyacrylamide gel electrophoresis (PAGE), TEM, spectrophotometry, and centrifugation as methods for studying these filaments. We observed that in the presence of Mg2+ combined with ATP, ADP, ATPgammaS, or GTP, native PAGE indicated that chaperonin subunits assembled into double rings and that the conformation of these double rings was effected by nucleotide binding, but we saw no indication of chaperonin filament formation. Under these same conditions, however, TEM, spectroscopy, and centrifugation methods indicated that chaperonin subunits and double rings had assembled into filaments. We determined that this discrepancy in the representation of the chaperonin structure was due to the native PAGE method itself. When we exposed chaperonin filaments to the electrophoretic field used in native PAGE, the filaments dissociated into double rings. This suggests that TEM, spectrophotometry, and centrifugation are the preferred methods for studying the higher-order structures of chaperonins, which are likely to be of biological significance.

Recombinant homo- and hetero-oligomers of an ultrastable chaperonin from the archaeon Pyrodictium occultum show chaperone activity in vitro.

The archaeon Pyrodictium occultum is one of the most thermophilic organisms presently known. Previous experiments provided support for the significant contribution of a high-molecular-mass protein complex to the extreme thermotolerance of P. occultum. This protein complex, the 'thermosome', is composed of two subunits, alpha and beta, which form a hexadecameric double ring complex. In order to obtain the thermosome in amounts sufficient for structural and functional investigations, we produced the two subunits jointly and separately in Escherichia coli BL21(DE3). In all three cases, we isolated soluble, high-molecular-mass double-ring complexes from E. coli BL21(DE3). On electron micrographs, the recombinant complexes were indistinguishable from each other and from the natural thermosome. To characterize the quaternary structure of the recombinant particles, we used native gel electrophoresis, analytical gel filtration, and analytical ultracentrifugation. Spectral analysis, using absorption, fluorescence emission and far-UV circular dichroism spectroscopy were applied to compare the three recombinant protein complexes with the natural thermosome from P. occultum. All three recombinant complex species exhibit ATPase activity. Furthermore, we could demonstrate that the recombinant complexes slow down the aggregation of citrate synthase, alcohol dehydrogenase, and insulin. Thus, we conclude that the recombinant protein complexes exhibit a chaperone-like activity, interacting with non-native proteins; they do so at temperatures far below the lower physiological limit of growth.

Structural and functional characterization of homo-oligomeric complexes of alpha and beta chaperonin subunits from the hyperthermophilic archaeum Thermococcus strain KS-1.

To elucidate the function of group II chaperonin, the gene for the chaperonin from the hyperthermophilic archaeum Thermococcus strain KS-1 was cloned and sequenced. Two distinct genes coding for chaperonin subunits, designated alpha and beta, were obtained, and their deduced amino acid sequences are highly homologous to those of group II chaperonins from other sources. The alpha and beta subunits were individually expressed in Escherichia coli. Both of the recombinant subunits assemble to constitute the homo-oligomeric double-ring complexes, which are prone to form large aggregates. The alpha aggregate is dissociated into the typical chaperonin ring complex by incubation in buffer containing 15% (v/v) methanol, while the beta aggregate cannot be dissociated. At high temperature, both of the recombinant complexes have weak ATPase activities. They are able to arrest refolding of a chemically denatured thermophilic enzyme in the absence of ATP, and refolding is resumed when ATP is supplemented. These results suggest that homo-oligomeric complexes of the archaeal chaperonin have activity.

Cytoplasmic chaperonin containing TCP-1: structural and functional characterization.

Actin and tubulin polypeptide chains acquire their native conformation in the presence of the cytoplasmic chaperonin containing TCP-1 (CCT, also called TRiC) and, in the case of alpha- and beta-tubulin, additional protein cofactors. It has been previously demonstrated that nucleotide exchange and ATP hydrolysis act to switch CCT between conformations that interact either strongly or weakly with unfolded substrates [Melki, R., & Cowan, N.J. (1994) Mol. Cell. Biol. 14, 2895-2904]. The present study further documents the conformational changes and function of CCT. It is first shown, by the use of a range of labeled denatured substrate proteins and a radiolabeled total soluble HeLa cell extract, that CCT in the absence of nucleotides can bind any of a large number of proteins in vitro with high affinity. Second, by the use of denatured labeled beta-actin and beta-tubulin as model substrates for binding to CCT, we demonstrate that the CCT particle can contain two substrate protein chains simultaneously. Third, by electron microscopy, sedimentation velocity, and intrinsic fluorescence measurements, we document the conformational difference between CCT in its ATP- and ADP-bound forms, as well as the change that results from binding of substrate protein. A model summarizes substrate association with CCT and the role of the nucleotide in regulating the affinity of CCT for target proteins.

Chaperonin filaments: the archaeal cytoskeleton?

Chaperonins are high molecular mass double-ring structures composed of 60-kDa protein subunits. In the hyperthermophilic archaeon Sulfolobus shibatae the two chaperonin proteins represent approximately 4% of its total protein and have a combined intracellular concentration of >30 mg/ml. At concentrations >/= 0.5 mg/ml purified chaperonins form filaments in the presence of Mg2+ and nucleotides. Filament formation requires nucleotide binding (not hydrolysis), and occurs at physiological temperatures in biologically relevant buffers, including a buffer made from cell extracts. These observations suggest that chaperonin filaments may exist in vivo and the estimated 4600 chaperonins per cell suggest that such filaments could form an extensive cytostructure. We observed filamentous structures in unfixed, uranyl-acetate-stained S. shibatae cells, which resemble the chaperonin filaments in size and appearance. ImmunoGold (Janssen) labeling using chaperonin antibodies indicated that many chaperonins are associated with insoluble cellular structures and these structures appear to be filamentous in some areas, although they could not be uranyl-acetate-stained. The existence of chaperonin filaments in vivo suggests a mechanism whereby their protein-folding activities can be regulated. More generally, the filaments themselves may play a cytoskeletal role in Archaea.

Development of pilus organelle subassemblies in vitro depends on chaperone uncapping of a beta zipper.

The major subassemblies of virulence-associated P pili, the pilus rod (comprised of PapA) and tip fibrillum (comprised of PapE), were reconstituted from purified chaperone-subunit complexes in vitro. Subunits are held in assembly-competent conformations in chaperone-subunit complexes prior to their assembly into mature pili. The PapD chaperone binds, in part, to a conserved motif present at the C terminus of the subunits via a beta zippering interaction. Amino acid residues in this conserved motif were also found to be essential for subunit-subunit interactions necessary for the formation of pili, thus revealing a molecular mechanism whereby the PapD chaperone may prevent premature subunit-subunit interactions in the periplasm. Uncapping of the chaperone-protected C terminus of PapA and PapE was mimicked in vitro by freeze-thaw techniques and resulted in the formation of pilus rods and tip fibrillae, respectively. A mutation in the leading edge of the beta zipper of PapA produces pilus rods with an altered helical symmetry and azimuthal disorder. This change in the number of subunits per turn of the helix most likely reflects involvement of the leading edge of the beta zipper in forming a right-handed helical cylinder. Organelle development is a fundamental process in all living cells, and these studies shed new light on how immunoglobulin-like chaperones govern the formation of virulence-associated organelles in pathogenic bacteria.