The role of cardiolipin in promoting the membrane pore-forming activity of BAX oligomers.

BCL-2-associated X (BAX) protein acts as a gatekeeper in regulating mitochondria-dependent apoptosis. Under cellular stress, BAX becomes activated and transforms into a lethal oligomer that causes mitochondrial outer membrane permeabilization (MOMP). Previous studies have identified several structural features of the membrane-associated BAX oligomer; they include the formation of the BH3-in-groove dimer, the collapse of the helical hairpin α5-α6, and the membrane insertion of α9 helix. However, it remains unclear as to the role of lipid environment in determining the conformation and the pore-forming activity of the BAX oligomers. Here we study molecular details of the membrane-associated BAX in various lipid environments using fluorescence and ESR techniques. We identify the inactive versus active forms of membrane-associated BAX, only the latter of which can induce stable and large membrane pores that are sufficient in size to pass apoptogenic factors. We reveal that the presence of CL is crucial to promoting the association between BAX dimers, hence the active oligomers. Without the presence of CL, BAX dimers assemble into an inactive oligomer that lacks the ability to form stable pores in the membrane. This study suggests an important role of CL in determining the formation of active BAX oligomers.

Oligomerization process of Bcl-2 associated X protein revealed from intermediate structures in solution.

Upon apoptotic stress, Bcl-2 associated X (BAX) protein undergoes conformational changes and oligomerizes, leading to the mitochondrial membrane permeabilization and cell death. While structures of the resultant oligomer have been extensively studied, little is known about the intermediates that describe the reaction pathway from the inactive monomers to activated oligomers. Here we characterize the intermediate structures of BAX using combined small-angle X-ray scattering (SAXS) with on-line gel-filtration and electron spin resonance (ESR). The intermediates, including monomers, dimers, and tetramers, are reconstructed via integrating the SAXS-envelopes and ESR-determined skeleton structures. The hence revealed structures suggest a linear oligomerization of BAX utilizing the extended dimers with the two flexible α6 chains protruded out as ditopic ligands. The results of molecular dynamics simulation also support the ditopic dimer conformation with mobile α6. The ditopic dimers could further wind into a helical rod structure with three dimers in one helical turn. Our results not only reveal the on-pathway intermediates, but also suggest a ditopic oligomerization mechanism that may bridge the observed intermediate structures in solution to the large BAX assemblies lately observed on mitochondria.

Evidence for an Induced-Fit Process Underlying the Activation of Apoptotic BAX by an Intrinsically Disordered BimBH3 Peptide.

Apoptotic BAX protein functions as a critical gateway to mitochondria-mediated apoptosis. A diversity of stimuli has been implicated in initiating BAX activation, but the triggering mechanism remains elusive. Here we study the interaction of BAX with an intrinsically disordered BH3 motif of Bim protein (BimBH3) using ESR techniques. Upon incubation with BAX, BimBH3 binds to BAX at helices 1/6 trigger site to initiate conformational changes of BAX, which in turn promotes the formation of BAX oligomers. The study strategy is twofold: while BAX oligomerization was monitored through spectral changes of spin-labeled BAX, the binding kinetics was studied by observing time-dependent changes of spin-labeled BimBH3. Meanwhile, conformational transition between the unstructured and structured BimBH3 was measured. We show that helical propensity of the BimBH3 is increased upon binding to BAX but is then reduced after being released from the activated BAX; the release is due to the BimBH3-induced conformational change of BAX that is a prerequisite for the oligomer assembling. Intermediate states are identified, offering a key snapshot of the coupled folding and binding process. Our results provide a quantitative mechanistic description of the BAX activation and reveal new insights into the mechanism underlying the interactions between BAX and BH3-mimetic peptide.

Solution Structure of Apoptotic BAX Oligomer: Oligomerization Likely Precedes Membrane Insertion.

Proapoptotic BAX protein is largely cytosolic in healthy cells, but it oligomerizes and translocates to mitochondria upon receiving apoptotic stimuli. A long-standing challenge has been the inability to capture any structural information beyond the onset of activation. Here, we present solution structures of an activated BAX oligomer by means of spectroscopic and scattering methods, providing details about the monomer-monomer interfaces in the oligomer and how the oligomer is assembled from homodimers. We show that this soluble oligomer undergoes a direct conversion into membrane-inserted oligomer, which has the ability of inducing apoptosis and structurally resembles a membrane-embedded oligomer formed from BAX monomers in lipid environment. Structural differences between the soluble and the membrane-inserted oligomers are manifested in the C-terminal helices. Our data suggest an alternative pathway of apoptosis in which BAX oligomer formation occurs prior to membrane insertion.

BAX-induced apoptosis can be initiated through a conformational selection mechanism.

BAX protein plays a key role in the mitochondria-mediated apoptosis. However, it remains unclear by what mechanism BAX is triggered to initiate apoptosis. Here, we reveal the mechanism using electron spin resonance (ESR) techniques. An inactive BAX monomer was found to exhibit conformational heterogeneity and exist at equilibrium in two conformations, one of which has never been reported. We show that upon apoptotic stimulus by BH3-only peptides, BAX can be induced to convert into either a ligand-bound monomer or an oligomer through a conformational selection mechanism. The kinetics of reaction is studied by means of time-resolved ESR, allowing a direct in situ observation for the transformation of BAX from the native to the bound states. In vitro mitochondrial assays provide further discrimination between the proposed BAX states, thereby revealing a population-shift allosteric mechanism in the process. BAX's apoptotic function is shown to critically depend on excursions between different structural conformations.

Kinetics study on the HIV-1 ectodomain protein quaternary structure formation reveals coupling of chain folding and self-assembly in the refolding cascade.

Entry of HIV-1 into the target cell is mediated by the envelope glycoprotein consisting of noncovalently associated surface subunit gp120 and transmembrane subunit gp41. To form a functional gp41 complex, the protein undergoes hairpin formation and self-assembly. The fusion event can be inhibited by gp41-derived peptides at nanomolar concentration and is highly dependent on the time of addition, implying a role of folding kinetics on the inhibitory action. Oligomerization of the gp41 ectodomain was demonstrated by light scattering measurements. Kinetic study by stopped-flow fluorescence and absorption measurements (i) revealed a multistate folding pathway and stable intermediates; (ii) showed a dissection of fast and slow components for early and late stages of folding, respectively, with 3 orders of magnitude difference in the time scale; (iii) showed the slow process was attributed to misfolding and unzipping of the hairpin; and (iv) showed retardation of the native hairpin formation is assumed to lead to coupling of the correctly registered hairpin and self-assembly. This coupling allows the deduction on the time scale of intrachain folding (0.1-1 s) for the protein. The folding reaction was illustrated by a free energy profile to explain the temporal dichotomy of fast and slow steps of folding as well as effective inhibition by gp41-derived peptide.

Identification of complex dynamic modes on prion protein peptides using multifrequency ESR with mesoporous materials.

Identifying protein dynamics is essential for studying protein function. However, the time-scale of dynamic modes varies over domains and segments of a protein. Here we describe an approach using multifrequency ESR with mesoporous materials for protein dynamics in confined nanospace that may mimic the crowded nature within a cell where proteins evolve to fold. While multifrequency ESR permits the separation of dynamic motions in different time-scales, we demonstrate its capability to capture dynamics can still be significantly enhanced by the encapsulation of nitroxide-labeled macromolecule into mesopores. Two mutants of a 26-residue prion protein peptide at temperatures from 2 to 27 °C are studied. The nanochannel provides the peptide with an ordered environment such that the global tumbling of peptide is slow, and 'frozen' on the ESR timescale. The local dynamic modes of the peptide in nanochannel are, therefore, distinctly reported on the spectra. The spectra of the peptide in ß-hairpin vs.α-helical forms differ markedly, demonstrating the significant improvement of ESR spectroscopic capability due to our methodology. Such distinctly different spectral patterns between the two secondary structures of the peptide cannot be obtained from ESR studies in viscous aqueous solution. The dynamic modes on the peptide are thus unambiguously identified in our multifrequency experiments at the X- and Q-bands. Additionally, the multifrequency spectra for each mutant and temperature are simultaneously fitted to the rigorous models, e.g. the slowly-relaxing-local-structure model, for slow-motion ESR. Marked correlations are revealed and characterized quantitatively for the backbone flexibility between the ß-hairpin and α-helical forms of the prion protein peptide. Confirmation of the slow collective dynamic modes extending across the ß-hairpin is also provided through the spectral simulations.