A quantitative analysis of the effect of nucleotides and the M domain on the association equilibrium of ClpB

ClpB is a hexameric molecular chaperone that, together with the DnaK system, has the ability to disaggregate stress-denatured proteins. The hexamer is a highly dynamic complex, able to reshuffle subunits. To further characterize the biological implications of the ClpB oligomerization state, the association equilibrium of the wild-type (wt) protein and of two deletion mutants, which lack part or the whole M domain, was quantitatively analyzed under different experimental conditions, using several biophysical [analytical ultracentrifugation, composition-gradient (CG) static light scattering, and circular dichroism] and biochemical (ATPase and chaperone activity) methods. We have found that (i) ClpB self-associates from monomers to form hexamers and higher-order oligomers that have been tentatively assigned to dodecamers, (ii) oligomer dissociation is not accompanied by modifications of the protein secondary structure, (iii) the M domain is engaged in intersubunit interactions that stabilize the protein hexamer, and (iv) the nucleotide-induced rearrangement of ClpB affects the protein oligomeric core, in addition to the proposed radial extension of the M domain. The difference in the stability of the ATP- and ADP-bound states [ΔΔG(ATP-ADP) = -10 kJ/mol] might explain how nucleotide exchange promotes the conformational change of the protein particle that drives its functional cycle.     

The legumin precursor from white lupin seed. Identity of the subunits, assembly and proteolysis.

The precursors of the legumin-like storage protein from developing white lupin seeds (35 days after flowering) are trimers composed of protomers of M(r) 72,000 or 67,000. Some subunits of these oligomers contain processed precursor polypeptides, namely alpha polypeptides of either 52,000 or 44,000 linked through disulphide bonds to a beta polypeptide of 21,000, typical of the mature legumin. The prolegumin is glycosylated. Legumin oligomers purified from the same seeds are both trimers and hexamers; some of their subunits are still made of precursor polypeptides. The hexamer contains less precursor polypeptide than the trimer. A low level or absence of precursor appears to be a condition of hexamer assembly. The heterogenous prolegumin and legumin oligomers represent intermediates in the processing of the prolegumin to mature legumin. Hydrophobic-interaction chromatography on TSK-phenyl-5PW and titration with the hydrophobic probe 8-anilino-1-naphthalenesulphonate indicate that the legumin is less hydrophobic than the prolegumin. This is attributed to structural rearrangements at processing of the propolypeptide, made evident by the behaviour in CD and by the second-derivative ultraviolet spectra of the two proteins. The total protein extract of developing cotyledons at 40 days after flowering contains endopeptidases, similar to those existing in the resting seeds, which cause a limited cascade degradation of the prolegumin and legumin.     

Disulfide Bond Stabilization of the Hexameric Capsomer of Human Immunodeficiency Virus

The human immunodeficiency virus type 1 capsid is modeled as a fullerene cone that is composed of ∼ 250 hexamers and 12 pentamers of the viral CA protein. Structures of CA hexamers have been difficult to obtain because the hexamer-stabilizing interactions are inherently weak, and CA tends to spontaneously assemble into capsid-like particles. Here, we describe a two-step biochemical strategy to obtain soluble CA hexamers for crystallization. First, the hexamer was stabilized by engineering disulfide cross-links (either A14C/E45C or A42C/T54C) between the N-terminal domains of adjacent subunits. Second, the cross-linked hexamers were prevented from polymerizing further into hyperstable capsid-like structures by mutations (W184A and M185A) that interfered with dimeric association between the C-terminal domains that link adjacent hexamers. The structures of two different cross-linked CA hexamers were nearly identical, and we combined the non-mutated portions of the structures to generate an atomic resolution model for the native hexamer. This hybrid approach for structure determination should be applicable to other viral capsomers and protein-protein complexes in general.     

Structural Insight into Proteorhodopsin Oligomers

Oligomerization has important functional implications for many membrane proteins. However, obtaining structural insight into oligomeric assemblies is challenging, as they are large and resist crystallization. We focus on proteorhodopsin (PR), a protein with seven transmembrane α-helices that was found to assemble to hexamers in densely packed lipid membrane, or detergent-solubilized environments. Yet, the structural organization and the subunit interface of these PR oligomers were unknown. We used site-directed spin-labeling together with electron spin-resonance lineshape and Overhauser dynamic nuclear polarization analysis to construct a model for the specific orientation of PR subunits within the hexameric complex. We found intersubunit distances to average 16 Å between neighboring 55 residues and that residues 177 are >20 Å apart from each other. These distance constraints show that PR has a defined and radial orientation within a hexamer, with the 55-site of the A-B loop facing the hexamer core and the 177-site of the E-F loop facing the hexamer exterior. Dynamic nuclear polarization measurements of the local solvent dynamics complement the electron spin-resonance-based distance analysis, by resolving whether protein surfaces at positions 55, 58, and 177 are exposed to solvent, or covered by protein-protein or protein-detergent contacts.     

Cobalt(III)-induced hexamerization of PEGylated insulin

Insulin conjugates in which the B1Phe residue has been chemically modified often exhibit a reduced tendency to associate into hexamers due to weakened interactions between subunits. The purpose of this study was to prepare a hexamer formulation for such insulin conjugates by using Co(III) as a coordinating metal ion. PEGylated insulin in which monomethoxypoly(ethylene glycol) (mPEG, M_r 5000 or 20,000) had been site-specifically attached to B1Phe was chosen as a model conjugate. Hexamerization of mPEG-insulin upon H₂O₂-mediated oxidation of Co(II) was kinetically and quantitatively analysed by visible spectrometry and size-exclusion HPLC. Co(III) mPEG-insulin hexamers thus obtained were extremely stable, existing mostly as a hexameric form even at nanomolar concentrations. A remarkable increase in hydrodynamic volumes was observed for Co(III) mPEG(20k)-insulin hexamers (1600 kDa), as well as Co(III) mPEG(5k)-insulin hexamers (300 kDa). Our results demonstrate the potential benefits of Co(III) hexamer formulation for weakly associating insulin conjugates in the treatment of diabetes.     

SV40 large T antigen hexamer structure: domain organization and DNA-induced conformational changes

Simian Virus 40 replication requires only one viral protein, the Large T antigen (T-ag), which acts as both an initiator of replication and as a replicative helicase (reviewed in ). We used electron microscopy to generate a three-dimensional reconstruction of the T-ag hexameric ring in the presence and absence of a synthetic replication fork to locate the T-ag domains, to examine structural changes in the T-ag hexamer associated with DNA binding, and to analyze the formation of double hexamers on and off DNA. We found that binding DNA to the T-ag hexamer induces large conformational changes in the N- and C-terminal domains of T-ag. Additionally, we observed a significant increase in density throughout the central channel of the hexameric ring upon DNA binding. We conclude that conformational changes in the T-ag hexamer are required to accommodate DNA and that the mode of DNA binding may be similar to that suggested for some other ring helicases. We also identified two conformations of T-ag double hexamers formed in the presence of forked DNA: with N-terminal hexamer-hexamer contacts, similar to those formed on origin DNA, or with C-terminal contacts, which are unlike any T-ag double hexamers reported previously.     

Physicochemical basis for the rapid time-action of LysB28ProB29-insulin: dissociation of a protein-ligand complex.

The rate-limiting step for the absorption of insulin solutions after subcutaneous injection is considered to be the dissociation of self-associated hexamers to monomers. To accelerate this absorption process, insulin analogues have been designed that possess full biological activity and yet have greatly diminished tendencies to self-associate. Sedimentation velocity and static light scattering results show that the presence of zinc and phenolic ligands (m-cresol and/or phenol) cause one such insulin analogue, LysB28ProB29-human insulin (LysPro), to associate into a hexameric complex. Most importantly, this ligand-bound hexamer retains its rapid-acting pharmacokinetics and pharmacodynamics. The dissociation of the stabilized hexameric analogue has been studied in vitro using static light scattering as well as in vivo using a female pig pharmacodynamic model. Retention of rapid time-action is hypothesized to be due to altered subunit packing within the hexamer. Evidence for modified monomer-monomer interactions has been observed in the X-ray crystal structure of a zinc LysPro hexamer (Ciszak E et al., 1995, Structure 3:615-622). The solution state behavior of LysPro, reported here, has been interpreted with respect to the crystal structure results. In addition, the phenolic ligand binding differences between LysPro and insulin have been compared using isothermal titrating calorimetry and visible absorption spectroscopy of cobalt-containing hexamers. These studies establish that rapid-acting insulin analogues of this type can be stabilized in solution via the formation of hexamer complexes with altered dissociation properties.     

Examination of the dynamic assembly equilibrium for E. coli ClpB

Escherichia coli ClpB is a heat shock protein that belongs to the AAA+ protein superfamily. Studies have shown that ClpB and its homologue in yeast, Hsp104, can disrupt protein aggregates in vivo. It is thought that ClpB requires binding of nucleoside triphosphate to assemble into hexameric rings with protein binding activity. In addition, it is widely assumed that ClpB is uniformly hexameric in the presence of nucleotides. Here we report, in the absence of nucleotide, that increasing ClpB concentration leads to ClpB hexamer formation, decreasing NaCl concentration stabilizes ClpB hexamers, and the ClpB assembly reaction is best described by a monomer, dimer, tetramer, hexamer equilibrium under the three salt concentrations examined. Further, we found that ClpB oligomers exhibit relatively fast dissociation on the time scale of sedimentation. We anticipate our studies on ClpB assembly to be a starting point to understand how ClpB assembly is linked to the binding and disaggregation of denatured proteins. Proteins 2015; 83:2008–2024. © 2015 Wiley Periodicals, Inc.     

Hexamer to monomer equilibrium of E. coli Hfq in solution and its impact on RNA annealing

The bacterial Sm-like protein Hfq forms a ring-shaped homo-hexamer that is necessary for Hfq to bind nucleic acids and to act in small noncoding RNA regulation. Using semi-native gels and fluorescence anisotropy, we show that Hfq undergoes a cooperative conformational change from monomer to hexamer around 1 μM protein, which is comparable to the in vivo concentration of Hfq and above the dissociation constant of the Hfq hexamer from many RNA substrates. Above 2 μM protein, Hfq hexamers associate in high-molecular-weight complexes. Mutations that impair RNA binding to the proximal face strongly destabilize the hexamer, while the mutation R16A near the outer rim prevents hexamer association. Stopped-flow fluorescence resonance energy transfer experiments showed that Hfq subunits interact within a few seconds, suggesting that Hfq monomers, hexamers and multi-hexamer complexes are in dynamic equilibrium. Finally, we show that Hfq is most active in RNA annealing when the hexamer is present. These results suggest that RNA binding is coupled to hexamer assembly and that the biochemical activity of Hfq reflects the equilibrium between different quaternary structures.     

Design of in Vitro Symmetric Complexes and Analysis by Hybrid Methods Reveal Mechanisms of HIV Capsid Assembly

Unlike the capsids of icosahedral viruses, retroviral capsids are pleomorphic, with variably curved, closed fullerene shells composed of ∼ 250 hexamers and exactly 12 pentamers of the viral CA protein. Structures of CA oligomers have been difficult to obtain because the subunit-subunit interactions are inherently weak, and CA tends to spontaneously assemble into capsid-like particles. Guided by a cryoEM-based model of the hexagonal lattice of HIV-1 CA, we used a two-step biochemical strategy to obtain soluble CA hexamers and pentamers for crystallization. First, each oligomer was stabilized by engineering disulfide cross-links between the N-terminal domains of adjacent subunits. Second, the cross-linked oligomers were prevented from polymerizing into hyperstable, capsid-like structures by mutations that weakened the dimeric association between the C-terminal domains that link adjacent oligomers. The X-ray structures revealed that the oligomers are comprised of a fairly rigid, central symmetric ring of N-terminal domains encircled by mobile C-terminal domains. Assembly of the quasi-equivalent oligomers requires remarkably subtle rearrangements in inter-subunit quaternary bonding interactions, and appears to be controlled by an electrostatic switch that favors hexamers over pentamers. An atomic model of the complete HIV-1 capsid was then built using the fullerene cone as a template. Rigid-body rotations around two assembly interfaces are sufficient to generate the full range of continuously varying lattice curvature in the fullerene cone. The steps in determining this HIV-1 capsid atomic model exemplify the synergy of hybrid methods in structural biology, a powerful approach for exploring the structure of pleomorphic macromolecular complexes.     

Subunits of Panulirus japonicus hemocyanin. 2. Cooperativity of the homogeneous hexamers

Hexameric hemocyanin from a spiny lobster, Panulirus japonicus, comprises three major subunits (Ib, II and III) and one minor subunit (Ia), as reported in the preceding paper in this journal. It has previously been shown that the O2 equilibria of Panulirus hemocyanin can be described by a concerted model extended to three affinity states [Makino, N. (1986) Eur. J. Biochem. 154, 49-55]. In this study the equilibrium binding of O2 to the reassociated subunits (Ib, II and III) was examined at various pH in the presence or absence of Ca2+ in order to test the applicability of the three-state model to the homogeneous hexamers. The hexameric structure of the reassembled subunits was less stable than that of the native protein under the conditions examined. The model could be fitted to the O2-binding isotherms of the homohexamers composed of the subunits II or III, if the molecular dissociation of the protein was taken into account. It was postulated that the monomeric hemocyanin has the same ligand affinity as that of the hexamer in the intermediate-affinity state (S). The fitting of the model to the O2 binding of the subunit I was unsuccessful mainly because of the low cooperativity of the assembled subunits.     

Association Equilibrium of the HIV-1 Capsid Protein in a Crowded Medium Reveals that Hexamerization during Capsid Assembly Requires a Functional C-Domain Dimerization Interface

Polymerization of the intact capsid protein (CA) of HIV-1 into mature capsidlike particles at physiological ionic strength in vitro requires macromolecularly crowded conditions that approach those inside the virion, where the mature capsid is assembled in vivo. The capsid is organized as a hexameric lattice. CA subunits in each hexamer are connected through interfaces that involve the CA N-terminal domain (NTD); pairs of CA subunits belonging to different hexamers are connected through a different interface that involves the C-terminal domain (CTD). At physiological ionic strength in noncrowded conditions, CA subunits homodimerize through this CTD-CTD interface, but do not hexamerize through the other interfaces (those involving the NTD). Here we have investigated whether macromolecular crowding conditions are able to promote hexamerization of the isolated NTD and/or full-length CA (with an inactive CTD-CTD interface to prevent polymerization). The oligomerization state of the proteins was determined using analytical ultracentrifugation in the absence or presence of high concentrations of an inert macromolecular crowding agent. Under the same conditions that promoted efficient assembly of intact CA dimers, neither NTD nor CA with an inactive CTD-CTD interface showed any tendency to form hexamers or any other oligomer. This inability to hexamerize was observed even in macromolecularly crowded conditions. The results indicate that a functional CTD-CTD interface is strictly required for hexamerization of HIV-1 CA through the other interfaces. Together with previous results, these observations suggest that establishment of NTD-CTD interactions involved in CA hexamerization during mature HIV-1 capsid assembly requires a homodimerization-dependent conformational switching of CTD.