A critical motif for oligomerization and chaperone activity of bacterial alpha-heat shock proteins.

Oligomerization into multimeric complexes is a prerequisite for the chaperone function of almost all alpha-crystallin type heat shock proteins (alpha-Hsp), but the molecular details of complex assembly are poorly understood. The alpha-Hsp proteins from Bradyrhizobium japonicum are suitable bacterial models for structure-function studies of these ubiquitous stress proteins. They fall into two distinct classes, A and B, display chaperone activity in vitro and form oligomers of approximately 24 subunits. We constructed 19 derivatives containing truncations or point mutations within the N- and C-terminal regions and analyzed them by gel filtration, citrate synthase assay and coaffinity purification. Truncation of more than the initial few amino acids of the N-terminal region led to the formation of distinct dimeric to octameric structures devoid of chaperone activity. In the C-terminal extension, integrity of an isoleucine-X-isoleucine (I-X-I) motif was imperative for alpha-Hsp functionality. This I-X-I motif is one of the characteristic consensus motifs of the alpha-Hsp family, and here we provide experimental evidence of its structural and functional importance. alpha-Hsp proteins lacking the C-terminal extension were inactive, but still able to form dimers. Here, we demonstrate that the central alpha-crystallin domain alone is not sufficient for dimerization. Additional residues at the end of the N-terminal region were required for the assembly of two subunits.     

Mammalian SCAN domain dimer is a domain-swapped homolog of the HIV capsid C-terminal domain

Retroviral assembly is driven by multiple interactions mediated by the Gag polyprotein, the main structural component of the forming viral shell. Critical determinants of Gag oligomerization are contained within the C-terminal domain (CTD) of the capsid protein, which also harbors a conserved sequence motif, the major homology region (MHR), in the otherwise highly variable Gag. An unexpected clue about the MHR function in retroviral assembly emerges from the structure of the zinc finger-associated SCAN domain we describe here. The SCAN dimer adopts a fold almost identical to that of the retroviral capsid CTD but uses an entirely different dimerization interface caused by swapping the MHR-like element between the monomers. Mutations in retroviral capsid proteins and functional data suggest that a SCAN-like MHR-swapped CTD dimer forms during immature particle assembly. In the SCAN-like dimer, the MHR contributes the major part of the large intertwined dimer interface explaining its functional significance.     

The tetramerization domain of the Mnt repressor consists of two right-handed coiled coils.

The tetrameric Mnt repressor is involved in the genetic switch between the lysogenic and lytic growth of Salmonella bacteriophage P22. The solution structure of its C-terminal tetramerization domain, which holds together the two dimeric DNA-binding domains, has been determined by NMR spectroscopy. This structure reveals an assembly of four alpha-helical subunits, consisting of a dimer of two antiparallel coiled coils with a unique right-handed twist. The superhelical winding is considerably stronger and the interhelical separation closer than those found in the well-known left-handed coiled coils in fibrous proteins and leucine zippers. An unusual asymmetry arises between the two monomers that comprise one right-handed coiled coil. A difference in the packing to the adjacent monomer of the other coiled coil occurs with an offset of two helical turns. The two asymmetric monomers within each coiled coil interconvert on a time scale of seconds. Both with respect to symmetry and handedness of helical packing, the C2 symmetric four-helix bundle of Mnt differs from other oligomerization domains that assemble DNA-binding modules, such as that in the tumor suppressor p53 and the E. coli lac repressor.     

Hydrodynamic properties and quaternary structure of the 90 kDa heat-shock protein: effects of divalent cations

The 90 kDa heat-shock protein (Hsp90) is one of the major stress proteins whose overall structure remains unknown. In this study, we investigated the influence of divalent cations Mg(2+) and Ca(2+) on the hydrodynamic properties and quaternary structure of Hsp90. Using analytical ultracentrifugation, size-exclusion chromatography, and polyacrylamide gel electrophoresis, we showed that native Hsp90 was mostly dimeric. The Hsp90 dimer had a sedimentation coefficient, s(w,20) degrees, of 6.10 +/- 0.03 S, which slightly deviated from the hydrodynamics of a globular protein. Using chemical cross-linking and analytical ultracentrifugation, we showed that Mg(2+) and Ca(2+) induced a tertiary conformational change of Hsp90, leading to a self-association process. In the presence of divalent cations, Hsp90 existed as a mixture of monomers, dimers, and tetramers at equilibrium. Finally, to identify Hsp90 domains involved in this divalent cation-dependent self-association, we studied the oligomerization state of the N-terminal (positions 1-221) of Hsp90, the influence of an N-terminal specific ligand, geldanamycin (GA), and the effect of C-terminal truncation on the ability of Hsp90 to oligomerize in the presence of divalent cations. We previously showed that GA inhibits Hsp90 heat-induced oligomerization [Garnier, C., Protasevich, I., Gilli, R., Tsvetkov, P., Lobachov, V., Peyrot, V., Briand, C., and Makarov, A. (1998) Biochem. Biophys. Res. Commun. 249, 197-201], but now we observed that GA does not influence divalent cation-dependent oligomerization of Hsp90, suggesting another mechanism. This mechanism involved the C-terminal part of the protein since C-terminally truncated Hsp90 did not oligomerize in the presence of divalent cations.     

Structural evolution of C-terminal domains in the p53 family

The tetrameric state of p53, p63, and p73 has been considered one of the hallmarks of this protein family. While the DNA binding domain (DBD) is highly conserved among vertebrates and invertebrates, sequences C-terminal to the DBD are highly divergent. In particular, the oligomerization domain (OD) of the p53 forms of the model organisms Caenorhabditis elegans and Drosophila cannot be identified by sequence analysis. Here, we present the solution structures of their ODs and show that they both differ significantly from each other as well as from human p53. CEP-1 contains a composite domain of an OD and a sterile alpha motif (SAM) domain, and forms dimers instead of tetramers. The Dmp53 structure is characterized by an additional N-terminal beta-strand and a C-terminal helix. Truncation analysis in both domains reveals that the additional structural elements are necessary to stabilize the structure of the OD, suggesting a new function for the SAM domain. Furthermore, these structures show a potential path of evolution from an ancestral dimeric form over a tetrameric form, with additional stabilization elements, to the tetramerization domain of mammalian p53.     

Monomeric form of the molecular chaperone GroEL: structure, stability, and oligomerization]

The structure and stability in solution of the monomeric form of GroEL were studied by the methods of circular dichroism, binding of a hydrophobic probe, limited proteolysis, modification of thiol groups, sedimentation, and size-exclusion chromatography. The monomeric GroEL at 23 degrees C was shown to be a globular protein with a pronounced secondary and a rigid tertiary structure. It exhibited no marked tendency to oligomerization in the absence of adenine nucleotides. However, the free monomeric GroEL was substantially less stable to urea and heat than the corresponding subunit in the composition of native oligomeric particles. The monomeric form also bound the hydrophobic probe, 8-anilino-1-naphthalenesulfonic acid, by an order of magnitude better than the subunit in the oligomeric particles. The ATP-induced oligomerization process of both folded and unfolded GroEL monomers was studied. The oligomerization rate was found to be the same for both monomers, and, therefore, should be limited by the ATP-dependent "arrangement" of the sites in the folded monomers responsible for the oligomerization rather than by the spontaneous refolding of monomers.     

Regions Outside the α-Crystallin Domain of the Small Heat Shock Protein Hsp26 Are Required for Its Dimerization

Small heat shock proteins (sHsps) are a ubiquitous family of molecular chaperones. They form homo-oligomers, composed of mostly 24 subunits. The immunoglobulin-like α-crystallin domain, which is flanked by N- and C-terminal extensions, is the most conserved element in sHsps. It is assumed to be the dimeric building block from which the sHsp oligomers are assembled.Hsp26 from Saccharomyces cerevisiae is a well-characterized member of this family. With a view to study the structural stability and oligomerization properties of its α-crystallin domain, we produced a series of α-crystallin domain constructs. We show that a minimal α-crystallin domain can, against common belief, be monomeric and stably folded. Elongating either the N- or the C-terminus of this minimal α-crystallin domain with the authentic extensions leads to the formation of dimeric species. In the case of N-terminal extensions, their population is dependent on the presence of the complete so-called Hsp26 “middle domain”. For the C-terminal extensions, the presence of the conserved IXI motif of sHsps is necessary and sufficient to induce dimerization, which can be inhibited by increasing ionic strength. Dimerization does not induce major changes in secondary structure of the Hsp26 α-crystallin domain. A thermodynamic analysis of the monomeric and dimeric constructs revealed that dimers are not significantly stabilized against thermal and chemical denaturation in comparison to monomers, supporting our notion that dimerization is not a prerequisite for the formation of a well-folded Hsp26 α-crystallin domain.     

Crystal structure of the middle and C-terminal domains of the flagellar rotor protein FliG

The FliG protein is essential for assembly, rotation and clockwise/counter-clockwise (CW/CCW) switching of the bacterial flagellum. About 25 copies of FliG are present in a large rotor-mounted assembly termed the 'switch complex', which also contains the proteins FliM and FliN. Mutational studies have identified the segments of FliG most crucial for flagellar assembly, rotation and switching. The structure of the C-terminal domain, which functions specifically in rotation, was reported previously. Here, we describe the crystal structure of a larger fragment of the FliG protein from Thermotoga maritima, which encompasses the middle and C-terminal parts of the protein (termed FliG-MC). The FliG-MC molecule consists of two compact globular domains, linked by an alpha-helix and an extended segment that contains a well-conserved Gly-Gly motif. Mutational studies indicate that FliM binds to both of the globular domains, and given the flexibility of the linking segment, FliM is likely to determine the relative orientation of the domains in the flagellum. We propose a model for the organization of FliG-MC molecules in the flagellum, and suggest that CW/CCW switching might occur by movement of the C-terminal domain relative to other parts of FliG, under the control of FliM.     

Structural and functional studies of FkpA from Escherichia coli, a cis/trans peptidyl-prolyl isomerase with chaperone activity

The protein FkpA from the periplasm of Escherichia coli exhibits both cis/trans peptidyl-prolyl isomerase (PPIase) and chaperone activities. The crystal structure of the protein has been determined in three different forms: as the full-length native molecule, as a truncated form lacking the last 21 residues, and as the same truncated form in complex with the immunosuppressant ligand, FK506. FkpA is a dimeric molecule in which the 245-residue subunit is divided into two domains. The N-terminal domain includes three helices that are interlaced with those of the other subunit to provide all inter-subunit contacts maintaining the dimeric species. The C-terminal domain, which belongs to the FK506-binding protein (FKBP) family, binds the FK506 ligand. The overall form of the dimer is V-shaped, and the different crystal structures reveal a flexibility in the relative orientation of the two C-terminal domains located at the extremities of the V. The deletion mutant FkpNL, comprising the N-terminal domain only, exists in solution as a mixture of monomeric and dimeric species, and exhibits chaperone activity. By contrast, a deletion mutant comprising the C-terminal domain only is monomeric, and although it shows PPIase activity, it is devoid of chaperone function. These results suggest that the chaperone and catalytic activities reside in the N and C-terminal domains, respectively. Accordingly, the observed mobility of the C-terminal domains of the dimeric molecule could effectively adapt these two independent folding functions of FkpA to polypeptide substrates.     

The C5 domain of the collagen VI alpha3(VI) chain is critical for extracellular microfibril formation and is present in the extracellular matrix of cultured cells

Collagen VI, a microfibrillar protein found in virtually all connective tissues, is composed of three distinct subunits, alpha1(VI), alpha2(VI), and alpha3(VI), which associate intracellularly to form triple helical heterotrimeric monomers then dimers and tetramers. The secreted tetramers associate end-to-end to form beaded microfibrils. Although the basic steps in assembly and the structure of the tetramers and microfibrils are well defined, details of the interacting protein domains involved in assembly are still poorly understood. To explore the role of the C-terminal globular regions in assembly, alpha3(VI) cDNA expression constructs with C-terminal truncations were stably transfected into SaOS-2 cells. Control alpha3(VI) N6-C5 chains with an intact C-terminal globular region (subdomains C1-C5), and truncated alpha3(VI) N6-C1, N6-C2, N6-C3, and N6-C4 chains, all associated with endogenous alpha1(VI) and alpha2(VI) to form collagen VI monomers, dimers and tetramers, which were secreted. These data demonstrate that subdomains C2-C5 are not required for monomer, dimer or tetramer assembly, and suggest that the important chain selection interactions involve the C1 subdomains. In contrast to tetramers containing control alpha3(VI) N6-C5 chains, tetramers containing truncated alpha3(VI) chains were unable to associate efficiently end-to-end in the medium and did not form a significant extracellular matrix, demonstrating that the alpha3(VI) C5 domain plays a crucial role in collagen VI microfibril assembly. The alpha3(VI) C5 domain is present in the extracellular matrix of SaOS-2 N6-C5 expressing cells and fibroblasts demonstrating that processing of the C-terminal region of the alpha3(VI) chain is not essential for microfibril formation.     

The glycoprotein NOWA and minicollagens are part of a disulfide-linked polymer that forms the cnidarian nematocyst wall

The nematocyst is a unique extrusive organelle involved in the defense and capture of prey in cnidarians. Minicollagens and the glycoprotein NOWA are major components of the nematocyst capsule wall, which resists osmotic pressure of 15 MPa. Here we present the recombinant expression of NOWA, which spontaneously assembles to globular macromolecular particles that are sensitive to reduction as the native wall structure. Ultra-structural analysis showed that the Hydra nematocyst wall is composed of several layers of globular particles, which are interconnected via radiating rodlike protrusions. Evidence is presented that native wall particles contain NOWA and minicollagen, supposed to be linked via disulfide bonds between their homologous cysteine-rich domains. Our data suggest a continuous suprastructure of the nematocyst wall, assembled from wall proteins that share a common oligomerization motif.     

Crystal structure of FadA adhesin from Fusobacterium nucleatum reveals a novel oligomerization motif, the leucine chain

Many bacterial appendages have filamentous structures, often composed of repeating monomers assembled in a head-to-tail manner. The mechanisms of such linkages vary. We report here a novel protein oligomerization motif identified in the FadA adhesin from the Gram-negative bacterium Fusobacterium nucleatum. The 2.0 angstroms crystal structure of the secreted form of FadA (mFadA) reveals two antiparallel alpha-helices connected by an intervening 8-residue hairpin loop. Leucine-leucine contacts play a prominent dual intra- and intermolecular role in the structure and function of FadA. First, they comprise the main association between the two helical arms of the monomer; second, they mediate the head-to-tail association of monomers to form the elongated polymers. This leucine-mediated filamentous assembly of FadA molecules constitutes a novel structural motif termed the "leucine chain." The essential role of these residues in FadA is corroborated by mutagenesis of selected leucine residues, which leads to the abrogation of oligomerization, filament formation, and binding to host cells.     

细菌GntR家族转录调控因子的研究进展

GntR家族转录调控因子是细菌中分布最为广泛的一类螺旋-转角-螺旋(helix-turn-helix,HTH)转录调控因子,此家族转录调控因子包含两个功能域,分别是N端的DNA结合结构域和C端的效应物结合结构域/寡聚化作用结构域.DNA结合结构域的氨基酸序列是非常保守的,但效应物结合结构域/寡聚化作用结构域的氨基酸序列...     

Human uridine 5′-monophosphate synthase stores metabolic potential in inactive biomolecular condensates

Human uridine 5′-monophosphate synthase (HsUMPS) is a bifunctional enzyme that catalyzes the final two steps in de novo pyrimidine biosynthesis. The individual orotate phosphoribosyl transferase and orotidine monophosphate domains have been well characterized, but little is known about the overall structure of the protein and how the organization of domains impacts function. Using a combination of chromatography, electron microscopy, and complementary biophysical methods, we report herein that HsUMPS can be observed in two structurally distinct states, an enzymatically active dimeric form and a nonactive multimeric form. These two states readily interconvert to reach an equilibrium that is sensitive to perturbations of the active site and the presence of substrate. We determined that the smaller molecular weight form of HsUMPS is an S-shaped dimer that can self-assemble into relatively well-ordered globular condensates. Our analysis suggests that the transition between dimer and multimer is driven primarily by oligomerization of the orotate phosphoribosyl transferase domain. While the cellular distribution of HsUMPS is unaffected, quantification by mass spectrometry revealed that de novo pyrimidine biosynthesis is dysregulated when this protein is unable to assemble into inactive condensates. Taken together, our data suggest that HsUMPS self-assembles into biomolecular condensates as a means to store metabolic potential for the regulation of metabolic rates.     

The C-terminal domain of dimeric serine hydroxymethyltransferase plays a key role in stabilization of the quaternary structure and cooperative unfolding of protein: domain swapping studies with enzymes having high sequence identity

The serine hydroxymethyltransferase from Bacillus subtilis (bsSHMT) and B. stearothermophilus (bstSHMT) are both homodimers and share approximately 77% sequence identity; however, they show very different thermal stabilities and unfolding pathways. For investigating the role of N- and C-terminal domains in stability and unfolding of dimeric SHMTs, we have swapped the structural domains between bs- and bstSHMT and generated the two novel chimeric proteins bsbstc and bstbsc, respectively. The chimeras had secondary structure, tyrosine, and pyridoxal-5'-phosphate microenvironment similar to that of the wild-type proteins. The chimeras showed enzymatic activity slightly higher than that of the wild-type proteins. Interestingly, the guanidium chloride (GdmCl)-induced unfolding showed that unlike the wild-type bsSHMT, which undergoes dissociation of native dimer into monomers at low guanidium chloride (GdmCl) concentration, resulting in a non-cooperative unfolding of enzyme, its chimera bsbstc, having the C-terminal domain of bstSHMT was resistant to low GdmCl concentration and showed a GdmCl-induced cooperative unfolding from native dimer to unfolded monomer. In contrast, the wild-type dimeric bstSHMT was resistant to low GdmCl concentration and showed a GdmCl-induced cooperative unfolding, whereas its chimera bstbsc, having the C- terminal domain of bsSHMT, showed dissociation of native dimer into monomer at low GdmCl concentration and a GdmCl-induced non-cooperative unfolding. These results clearly demonstrate that the C-terminal domain of dimeric SHMT plays a vital role in stabilization of the oligomeric structure of the native enzyme hence modulating its unfolding pathway.     

Multiple distinct assemblies reveal conformational flexibility in the small heat shock protein Hsp26

Small heat shock proteins are a superfamily of molecular chaperones that suppress protein aggregation and provide protection from cell stress. A key issue for understanding their action is to define the interactions of subunit domains in these oligomeric assemblies. Cryo-electron microscopy of yeast Hsp26 reveals two distinct forms, each comprising 24 subunits arranged in a porous shell with tetrahedral symmetry. The subunits form elongated, asymmetric dimers that assemble via trimeric contacts. Modifications of both termini cause rearrangements that yield a further four assemblies. Each subunit contains an N-terminal region, a globular middle domain, the alpha-crystallin domain, and a C-terminal tail. Twelve of the C termini form 3-fold assembly contacts which are inserted into the interior of the shell, while the other 12 C termini form contacts on the surface. Hinge points between the domains allow a variety of assembly contacts, providing the flexibility required for formation of supercomplexes with non-native proteins.     

Crystal structure of the SMC head domain: an ABC ATPase with 900 residues antiparallel coiled-coil inserted

SMC (structural maintenance of chromosomes) proteins are large coiled-coil proteins involved in chromosome condensation, sister chromatid cohesion, and DNA double-strand break processing. They share a conserved five-domain architecture with three globular domains separated by two long coiled-coil segments. The coiled-coil segments are antiparallel, bringing the N and C-terminal globular domains together. We have expressed a fusion protein of the N and C-terminal globular domains of Thermotoga maritima SMC in Escherichia coli by replacing the approximately 900 residue coiled-coil and hinge segment with a short peptide linker. The SMC head domain (SMChd) binds and condenses DNA in an ATP-dependent manner. Using selenomethionine-substituted protein and multiple anomalous dispersion phasing, we have solved the crystal structure of the SMChd to 3.1 A resolution. In the monoclinic crystal form, six SMChd molecules form two turns of a helix. The fold of SMChd is closely related to the ATP-binding cassette (ABC) ATPase family of proteins and Rad50, a member of the SMC family involved in DNA double-strand break repair. In SMChd, the ABC ATPase fold is formed by the N and C-terminal domains with the 900 residue coiled-coil and hinge segment inserted in the middle of the fold. The crystal structure of an SMChd confirms that the coiled-coil segments in SMC proteins are anti-parallel and shows how the N and C-terminal domains come together to form an ABC ATPase. Comparison to the structure of the MukB N-terminal domain demonstrates the close relationship between MukB and SMC proteins, and indicates a helix to strand conversion when N and C-terminal parts come together.     

Subunit structure and assembly of the globular domain of basement-membrane collagen type IV

The globular domain of collagen IV was solubilized by collagenase digestion from a mouse tumor, human placenta and bovine aorta and was purified by chromatographic methods. The materials show a unique, mainly non-collagenous amino acid composition and contain small amounts of glucosamine and galactosamine. The globular structures with Mr = 170 000 appear as a hexameric assembly originating from two collagen IV molecules. Subunits of this assembly are two different dimers Da and Db (Mr about 56 000) and monomers (Mr = 28 000). Their N-terminal amino acid sequences start with short triple-helical sequences, which overlap with the C-terminal triple helix of the alpha 1(IV) and alpha 2(IV) chain, demonstrating that the globule originates from the C terminus of collagen IV. Dimers arise from monomers by disulfide cross-linking (form Db) and/or formation of non-reducible cross-links (form Da). Reduction under non-denaturing conditions causes partial dissociation of the globule and of collagen IV dimers, indicating that reducible cross-links are formed between monomers of two different collagen IV molecules. Dissociation of the hexamer into the subunits can be achieved with 8 M urea, sodium dodecyl sulfate or in the pH range 2.5-4. The latter indicates that carboxyl groups are essential for association. Mixtures of the subunits (monomers and dimers) or purified dimers reassemble in neutral buffer into hexamers as shown by ultracentrifugation and electron microscopy. Reconstituted hexamers, however, dissociate in a much broader pH range than the native globules. Circular dichroic spectra indicate that the structure is more completely refolded from acid-treated than from urea-treated material. These data suggest that globules originating from monomers (as existing in single collagen IV molecules) are stabilized by the adjacent triple helix. Covalent cross-link formation stabilizes the globular structure and allows reconstitution in stoichiometric proportions.