BIM and tBID are not mechanistically equivalent when assisting BAX to permeabilize bilayer membranes

BIM and tBID are two BCL-2 homology 3 (BH3)-only proteins with a particularly strong capacity to trigger BAX-driven mitochondrial outer membrane permeabilization, a crucial event in mammalian apoptosis. However, the means whereby BIM and tBID fulfill this task is controversial. Here, we used a reconstituted liposomal system bearing physiological relevance to explore systematically how the BAX-permeabilizing function is influenced by interactions of BIM/BID-derived proteins and BH3 motifs with multidomain BCL-2 family members and with membrane lipids. We found that nanomolar dosing of BIM proteins sufficed to reverse completely the inhibition of BAX permeabilizing activity exerted by all antiapoptotic proteins tested (BCL-2, BCL-X(L), BCL-W, MCL-1, and A1). This effect was reproducible by a peptide representing the BH3 motif of BIM, whereas an equivalent BID BH3 peptide was less potent and more selective, reversing antiapoptotic inhibition. On the other hand, in the absence of BCL-2-type proteins, BIM proteins and the BIM BH3 peptide were inefficient, directly triggering the BAX-permeabilizing function. In contrast, tBID alone potently assisted BAX to permeabilize membranes at least in part by producing a structural distortion in the lipid bilayer via BH3-independent interaction of tBID with cardiolipin. Together, these results support the notion that BIM and tBID follow different strategies to trigger BAX-driven mitochondrial outer membrane permeabilization with strong potency.     

Pro-apoptotic cascade activates BID, which oligomerizes BAK or BAX into pores that result in the release of cytochrome c

We review data supporting a model in which activated tBID results in an allosteric activation of BAK, inducing its intramembranous oligomerization into a proposed pore for cytochrome c efflux. The BH3 domain of tBID is not required for targeting but remains on the mitochondrial surface where it is required to trigger BAK to release cytochrome c. tBID functions not as a pore-forming protein but as a membrane targeted and concentrated death ligand. tBID induces oligomerization of BAK, and both Bid and Bak knockout mice indicate the importance of this event in the release of cytochrome c. In parallel, the full pro-apoptotic member BAX, which is highly homologous to BAK, rapidly forms pores in liposomes that release intravesicular FITC-cytochrome c approximately 20A. A definable pore progressed from approximately 11A consisting of two BAX molecules to a approximately 22A pore comprised of four BAX molecules, which transported cytochrome c. Thus, an activation cascade of pro-apoptotic proteins from BID to BAK or BAX integrates the pathway from surface death receptors to the irreversible efflux of cytochrome c. Cell Death and Differentiation (2000) 7, 1166 - 1173     

A stapled BID BH3 helix directly binds and activates BAX

BAX is a multidomain proapoptotic BCL-2 family protein that resides in the cytosol until activated by an incompletely understood trigger mechanism, which facilitates BAX translocation to mitochondria and downstream death events. Whether BAX is activated by direct contact with select BH3-only members of the BCL-2 family is highly debated. Here we detect and quantify a direct binding interaction between BAX and a hydrocarbon-stapled BID BH3 domain, which triggers the functional activation of BAX at nanomolar doses in vitro. Chemical reinforcement of BID BH3 alpha helicity was required to reveal the direct BID BH3-BAX association. We confirm the specificity of this BH3 interaction by characterizing a stapled BAD BH3 peptide that interacts with antiapoptotic BCL-X(L) but does not bind or activate BAX. We further demonstrate that membrane targeting of stapled BID BH3 optimizes its ability to activate BAX, supporting a model in which BID directly engages BAX to trigger mitochondrial apoptosis.     

Lipidic pore formation by the concerted action of proapoptotic BAX and tBID

BCL-2 homology 3 (BH3)-only proteins of the BCL-2 family such as tBID and BIM(EL) assist BAX-type proteins to breach the permeability barrier of the outer mitochondrial membrane, thereby allowing cytoplasmic release of cytochrome c and other active inducers of cell death normally confined to the mitochondrial inter-membrane space. However, the exact mechanism by which tBID and BIM(EL) aid BAX and its close homologues in this mitochondrial protein release remains enigmatic. Here, using pure lipid vesicles, we provide evidence that tBID acts in concert with BAX to 1) form large membrane openings through both BH3-dependent and BH3-independent mechanisms, 2) cause lipid transbilayer movement concomitant with membrane permeabilization, and 3) disrupt the lipid bilayer structure of the membrane by promoting positive monolayer curvature stress. None of these effects were observed with BAX when BIM(EL) was substituted for tBID. Based on these data, we propose a novel model in which tBID assists BAX not only via protein-protein but also via protein-lipid interactions to form lipidic pore-type non-bilayer structures in the outer mitochondrial membrane through which intermembrane prodeath molecules exit mitochondria during apoptosis.     

BID regulates AIF-mediated caspase-independent necroptosis by promoting BAX activation

Alkylating DNA-damage agents such as N-methyl-N'-nitro-N'-nitrosoguanidine (MNNG) trigger necroptosis, a newly defined form of programmed cell death (PCD) managed by receptor interacting protein kinases. This caspase-independent mode of cell death involves the sequential activation of poly(ADP-ribose) polymerase-1 (PARP-1), calpains, BAX and AIF, which redistributes from mitochondria to the nucleus to promote chromatinolysis. We have previously demonstrated that the BAX-mediated mitochondrial release of AIF is a critical step in MNNG-mediated necroptosis. However, the mechanism regulating BAX activation in this PCD is poorly understood. Employing mouse embryonic knockout cells, we reveal that BID controls BAX activation in AIF-mediated necroptosis. Indeed, BID is a link between calpains and BAX in this mode of cell death. Therefore, even if PARP-1 and calpains are activated after MNNG treatment, BID genetic ablation abolishes both BAX activation and necroptosis. These PCD defects are reversed by reintroducing the BID-wt cDNA into the BID(-/-) cells. We also demonstrate that, after MNNG treatment, BID is directly processed into tBID by calpains. In this way, calpain non-cleavable BID proteins (BID-G70A or BID-Δ68-71) are unable to promote BAX activation and necroptosis. Once processed, tBID localizes in the mitochondria of MNNG-treated cells, where it can facilitate BAX activation and PCD. Altogether, our data reveal that, as in caspase-dependent apoptosis, BH3-only proteins are key regulators of caspase-independent necroptosis.     

tBID Homooligomerizes in the mitochondrial membrane to induce apoptosis.

Activation of the tumor necrosis factor R1/Fas receptor results in the cleavage of cytosolic BID to truncated tBID. tBID translocates to the mitochondria to induce the oligomerization of BAX or BAK, resulting in the release of cytochrome c (Cyt c). Here we demonstrate that in tumor necrosis factor alpha-activated FL5.12 cells, tBID becomes part of a 45-kDa cross-linkable mitochondrial complex that does not include BAX or BAK. Using fluorescence resonance energy transfer analysis and co-immunoprecipitation, we demonstrate that tBID-tBID interactions occur in the mitochondria of living cells. Cross-linking experiments using a tBID-GST chimera indicated that tBID forms homotrimers in the mitochondrial membrane. To test the functional consequence of tBID oligomerization, we expressed a chimeric FKBP-tBID molecule. Enforced dimerization of FKBP-tBID by the bivalent ligand FK1012 resulted in Cyt c release, caspase activation, and apoptosis. Surprisingly, enforced dimerization of tBID did not result in the dimerization of either BAX or BAK. Moreover, a tBID BH3 mutant (G94E), which does not interact with or induce the dimerization of either BAX or BAK, formed the 45-kDa complex and induced both Cyt c release and apoptosis. Thus, tBID oligomerization may represent an alternative mechanism for inducing mitochondrial dysfunction and apoptosis.     

Amphipathic tail-anchoring peptide and Bcl-2 homology domain-3 (BH3) peptides from Bcl-2 family proteins induce apoptosis through different mechanisms

Bcl-2 homology domain-3 (BH3) peptides are potent cancer therapeutic reagents that target regulators of apoptotic cell death in cancer cells. However, their cytotoxic effects are affected by different expression levels of Bcl-2 family proteins. We recently found that the amphipathic tail-anchoring peptide (ATAP) from Bfl-1, a bifunctional Bcl-2 family member, produced strong pro-apoptotic activity by permeabilizing the mitochondrial outer membrane. Here, we test whether the activity of ATAP requires other cellular factors and whether ATAP has an advantage over the BH3 peptides in targeting cancer cells. Confocal microscopic imaging illustrates specific targeting of ATAP to mitochondria, whereas BH3 peptides show diffuse patterns of cytosolic distribution. Although the pro-apoptotic activities of BH3 peptides are largely inhibited by either overexpression of anti-apoptotic Bcl-2 or Bcl-xL or nullification of pro-apoptotic Bax and Bak in cells, the pro-apoptotic function of ATAP is not affected by these cellular factors. Reconstitution of synthetic ATAP into liposomal membranes results in release of fluorescent molecules of the size of cytochrome c from the liposomes, suggesting that the membrane permeabilizing activity of ATAP does not require additional protein factors. Because ATAP can target to the mitochondrial membrane and its pro-apoptotic activity does not depend on the content of Bcl-2 family proteins, it represents a promising candidate for anti-cancer drugs that can potentially overcome the intrinsic apoptosis-resistant nature of cancer cells.     

The Bcl-2-associated death promoter (BAD) lowers the threshold at which the Bcl-2-interacting domain death agonist (BID) triggers mitochondria disintegration

The Bcl-2-associated death promoter (BAD) protein, like many other BH3-only proteins, is known to promote apoptosis through the intrinsic mitochondrial pathway. Unlike the BH3-interacting domain death agonist (BID) protein, BAD cannot directly trigger apoptosis but, instead, lowers the threshold at which apoptosis is induced. In many mathematical models of apoptosis, BAD is neglected or abstracted. The work presented here considers the incorporation of BAD and its various modifications in a model of the tBID-induction of BAK (Bcl-2 homologous antagonist killer) or the tBID-induction of BAX (Bcl-2-associated X protein). Steady state equations are used to develop an explicit formula describing the total concentration level of tBID, guaranteed to trigger apoptosis, as a bilinear function of the total BAD concentration level and the total anti-apoptotic protein concentration level (usually Bcl-2 or Bcl-x_L). In particular, the formula explains how the pro-apoptotic protein BAD lowers the threshold at which tBID induces BAK/BAX activation—reducing the level of total Bcl-2/Bcl-x_L available to inhibit tBID signaling in the mitochondria. Attention is then turned to the experimental data surrounding BAD phosphorylation, a process known to inhibit the pro-apoptotic effects of BAD. To address this data, the phosphorylation process is modeled following two separate kinetics in which either free unbound BAD is the assumed substrate or Bcl-x_L/Bcl-2-bound BAD is the assumed substrate. Bifurcation analysis and further analysis of the bilinear equation validate experiments, which suggest that BAD phosphorylation prevents irreversible BAK/BAX-mediated apoptosis, even when phosphorylation-induced dissociation of Bcl-x_L/Bcl-2-bound BAD is blocked. It is also shown that a cooperative, even synergistic, removal of mitochondrial BAD is seen when both types of phosphorylation are assumed possible. The presented work, however, reveals that the balance between BAD phosphorylation and dephosphorylation modulates the degree to which BAD influences the signaling from tBID to BAK/BAX. Our model shows that both the mode(s) of phosphorylation and the BAD dephosphorylation rate become important factors in determining whether BAD influences the activation of the BAK/BAX signal or not. Such potential variations in the pro-apoptotic effects of BAD are used to explain some of the inconsistent experimental data surrounding BAD phosphorylation. Nonetheless, our model serves to evaluate BAD and its sensitizing effects on the tBID-induction of BAK/BAX and thus aid in predicting when the incorporation of BAD in an apoptosis signaling model is important and when it is not.     

BCL-2 selectively interacts with the BID-induced open conformer of BAK,inhibiting BAK auto-oligomerization

Caspase-8 cleaves BID to tBID, which targets mitochondria and induces oligomerization of BAX and BAK within the outer membrane, resulting in release of cytochrome c from the organelle. Here, we have initiated these steps in isolated mitochondria derived from control and BCL-2-overexpressing cells using synthetic BH3 peptides and subsequently analyzed the BCL members by chemical cross-linking. The results show that the BH3 domain of BID interacts with and induces an "open" conformation of BAK, exposing the BAK N terminus. This open (activated) conformer of BAK potently induces oligomerization of non-activated ("closed") conformers, causing a cascade of BAK auto-oligomerization. Induction of the open conformation of BAK occurs even in the presence of excess BCL-2, but BCL-2 selectively interacts with this open conformer and blocks BAK oligomerization and cytochrome c release, dependent on the ratio of BID BH3 and BCL-2. This mechanism of inhibition by BCL-2 also occurs in intact cells stimulated with Fas or expressing tBID. Although BID BH3 interacts with both BCL-2 and BAK, the results indicate that when BCL-2 is in excess it can sequester the BID BH3-induced activated conformer of BAK, effectively blocking downstream events. This model suggests that the primary mechanism for BCL-2 blockade targets activated BAK rather than sequestering tBID.     

A unified model of mammalian BCL-2 protein family interactions at the mitochondria

During apoptosis, the BCL-2 protein family controls mitochondrial outer membrane permeabilization (MOMP), but the dynamics of this regulation remain controversial. We employed chimeric proteins composed of exogenous BH3 domains inserted into a tBID backbone that can activate the proapoptotic effectors BAX and BAK to permeabilize membranes without being universally sequestered by all antiapoptotic BCL-2 proteins. We thus identified two "modes" whereby prosurvival BCL-2 proteins can block MOMP, by sequestering direct-activator BH3-only proteins ("MODE 1") or by binding active BAX?and BAK ("MODE 2"). Notably, we found that MODE 1 sequestration is less efficient and more easily derepressed to promote MOMP than MODE 2. Further, MODE 2 sequestration prevents mitochondrial fusion. We provide a unified model of BCL-2 family function that helps to explain otherwise paradoxical observations relating to MOMP, apoptosis, and mitochondrial dynamics.     

Activation of calcium-independent phospholipase A (iPLA) in brain mitochondria and release of apoptogenic factors by BAX and truncated BID

Cleaved or truncated BID (tBID) is known to oligomerize both BAK and BAX. Previously, BAK and BAX lacing the C-terminal fragment (BAXDeltaC) were shown to induce modest cytochrome c (Cyt c) release from rat brain mitochondria when activated by tBID. We now show that tBID plus monomeric full-length BAX induce extensive release of Cyt c, Smac/DIABLO, and Omi/HtrA2 (but not endonuclease G and the apoptosis inducing factor) comparable to the release induced by alamethicin. This occurs independently of the permeability transition without overt changes in mitochondrial morphology. The mechanism of the release may involve formation of reactive oxygen species (ROS) and activation of calcium-independent phospholipase A(2) (iPLA(2)). Indeed, increased ROS production and activated iPLA(2) were observed prior to massive Cyt c release. Furthermore, the extent of inhibition of Cyt c release correlated with the degree of suppression of iPLA(2) by the inhibitors propranolol, dibucaine, 4-bromophenacyl bromide, and bromenol lactone. Consistent with a requirement for iPLA(2) in Cyt c release from brain mitochondria, synthetic liposomes composed of lipids mimicking the outer mitochondrial membrane (OMM) but lacing iPLA(2) failed to release 10 kDa fluorescent dextran (FD-10) in response to tBID plus BAX. We propose that tBID plus BAX activate ROS generation, which subsequently augments iPLA(2) activity leading to changes in the OMM that allow translocation of certain mitochondrial proteins from the intermembrane space.     

MCL-1 inhibits BAX in the absence of MCL-1/BAX Interaction

The BCL-2 family of proteins plays a major role in the control of apoptosis as the primary regulator of mitochondrial permeability. The pro-apoptotic BCL-2 homologues BAX and BAK are activated following the induction of apoptosis and induce cytochrome c release from mitochondria. A second class of BCL-2 homologues, the BH3-only proteins, is required for the activation of BAX and BAK. The activity of both BAX/BAK and BH3-only proteins is opposed by anti-apoptotic BCL-2 homologues such as BCL-2 and MCL-1. Here we show that anti-apoptotic MCL-1 inhibits the function of BAX downstream of its initial activation and translocation to mitochondria. Although MCL-1 interacted with BAK and inhibited its activation, the activity of MCL-1 against BAX was independent of an interaction between the two proteins. However, the anti-apoptotic function of MCL-1 required the presence of BAX. These results suggest that the pro-survival activity of MCL-1 proceeds via inhibition of BAX function at mitochondria, downstream of its activation and translocation to this organelle.     

Mitochondrial carrier homolog 2 is a target of tBID in cells signaled to die by tumor necrosis factor alpha

BID, a proapoptotic BCL-2 family member, plays an essential role in the tumor necrosis factor alpha (TNF-alpha)/Fas death receptor pathway in vivo. Activation of the TNF-R1 receptor results in the cleavage of BID into truncated BID (tBID), which translocates to the mitochondria and induces the activation of BAX or BAK. In TNF-alpha-activated FL5.12 cells, tBID becomes part of a 45-kDa cross-linkable mitochondrial complex. Here we describe the biochemical purification of this complex and the identification of mitochondrial carrier homolog 2 (Mtch2) as part of this complex. Mtch2 is a conserved protein that is similar to members of the mitochondrial carrier protein family. Our studies with mouse liver mitochondria indicate that Mtch2 is an integral membrane protein exposed on the surface of mitochondria. Using blue-native gel electrophoresis we revealed that in viable FL5.12 cells Mtch2 resides in a protein complex of ca. 185 kDa and that the addition of TNF-alpha to these cells leads to the recruitment of tBID and BAX to this complex. Importantly, this recruitment was partially inhibited in FL5.12 cells stably expressing BCL-X(L). These results implicate Mtch2 as a mitochondrial target of tBID and raise the possibility that the Mtch2-resident complex participates in the mitochondrial apoptotic program.     

Synthetic Antibodies Inhibit Bcl-2-associated X Protein (BAX) through Blockade of the N-terminal Activation Site

The BCL-2 protein family plays a critical role in regulating cellular commitment to mitochondrial apoptosis. Pro-apoptotic Bcl-2-associated X protein (BAX) is an executioner protein of the BCL-2 family that represents the gateway to mitochondrial apoptosis. Following cellular stresses that induce apoptosis, cytosolic BAX is activated and translocates to the mitochondria, where it inserts into the mitochondrial outer membrane to form a toxic pore. How the BAX activation pathway proceeds and how this may be inhibited is not yet completely understood. Here we describe synthetic antibody fragments (Fabs) as structural and biochemical probes to investigate the potential mechanisms of BAX regulation. These synthetic Fabs bind with high affinity to BAX and inhibit its activation by the BH3-only protein tBID (truncated Bcl2 interacting protein) in assays using liposomal membranes. Inhibition of BAX by a representative Fab, 3G11, prevented mitochondrial translocation of BAX and BAX-mediated cytochrome c release. Using NMR and hydrogen-deuterium exchange mass spectrometry, we showed that 3G11 forms a stoichiometric and stable complex without inducing a significant conformational change on monomeric and inactive BAX. We identified that the Fab-binding site on BAX involves residues of helices α1/α6 and the α1-α2 loop. Therefore, the inhibitory binding surface of 3G11 overlaps with the N-terminal activation site of BAX, suggesting a novel mechanism of BAX inhibition through direct binding to the BAX N-terminal activation site. The synthetic Fabs reported here reveal, as probes, novel mechanistic insights into BAX inhibition and provide a blueprint for developing inhibitors of BAX activation.     

Caspase-2 cleavage of BID is a critical apoptotic signal downstream of endoplasmic reticulum stress

The accumulation of misfolded proteins stresses the endoplasmic reticulum (ER) and triggers cell death through activation of the multidomain proapoptotic BCL-2 proteins BAX and BAK at the outer mitochondrial membrane. The signaling events that connect ER stress with the mitochondrial apoptotic machinery remain unclear, despite evidence that deregulation of this pathway contributes to cell loss in many human degenerative diseases. In order to "trap" and identify the apoptotic signals upstream of mitochondrial permeabilization, we challenged Bax-/- Bak-/- mouse embryonic fibroblasts with pharmacological inducers of ER stress. We found that ER stress induces proteolytic activation of the BH3-only protein BID as a critical apoptotic switch. Moreover, we identified caspase-2 as the premitochondrial protease that cleaves BID in response to ER stress and showed that resistance to ER stress-induced apoptosis can be conferred by inhibiting caspase-2 activity. Our work defines a novel signaling pathway that couples the ER and mitochondria and establishes a principal apoptotic effector downstream of ER stress.     

Effects of phospholipids on the functional regulation of tBID in membranes

The functional interplay between tBID and phospholipids was investigated in this study. The binding of tBID to model membranes was increased by an incorporation of phosphatidylserine (PS) into the liposomes. Using limited proteolysis and mass spectrometry, two peptide regions, which correspond to Ser(100)-Arg(114) and His(89)-Arg(114) in BID, revealed the specific PS-binding site. tBID also decreased the light scattering values of PS-containing liposomes and increased the leakage of fluorescent dye encapsulated in vesicles, which suggest that tBID reduces membrane integrity by fragmentation. The membrane fragmentation by tBID was also observed using confocal and transmission electron microscopy. The activity of tBID paralleled results that were obtained with cardiolipin (CL)-containing membranes. However, other anionic phospholipids had little effect. CL- and PS-induced conformational changes of tBID were observed by circular dichroism and intrinsic fluorescence. CL and PS also stimulated the insertion of BID into lipid monolayers. tBID stimulated the leakage of Ca(2+) from purified microsomes and mitochondria in a protein concentration-dependent manner. In contrast, BID showed significantly reduced effects when compared to tBID in all of the experiments performed. These results suggest that tBID specifically interacts with PS as well as CL and decreases membrane integrity without the aid of other pro-apoptotic proteins.     

Solution structure of human BCL-w: modulation of ligand binding by the C-terminal helix

The structure of human BCL-w, an anti-apoptotic member of the BCL-2 family, was determined by triple-resonance NMR spectroscopy and molecular modeling. Introduction of a single amino acid substitution (P117V) significantly improved the quality of the NMR spectra obtained. The cytosolic domain of BCL-w consists of 8 alpha-helices, which adopt a fold similar to that of BCL-xL, BCL-2, and BAX proteins. Pairwise root meant square deviation values were less than 3 A for backbone atoms of structurally equivalent regions. Interestingly, the C-terminal helix alpha8 of BCL-w folds into the BH3-binding hydrophobic cleft of the protein, in a fashion similar to the C-terminal transmembrane helix of BAX. A peptide corresponding to the BH3 region of the pro-apoptotic protein, BID, could displace helix alpha8 from the BCL-w cleft, resulting in helix unfolding. Deletion of helix alpha8 increased binding affinities of BCL-w for BAK and BID BH3-peptides, indicating that this helix competes for peptide binding to the hydrophobic cleft. These results suggest that although the cytosolic domain of BCL-w exhibits an overall structure similar to that of BCL-xL and BCL-2, the unique organization of its C-terminal helix may modulate BCL-w interactions with pro-apoptotic binding partners.     

VDAC2 is required for truncated BID‐induced mitochondrial apoptosis by recruiting BAK to the mitochondria

Truncated BID (tBID), a proapoptotic BCL2 family protein, induces BAK/BAX‐dependent release of cytochrome c and other mitochondrial intermembrane proteins to the cytosol to induce apoptosis. The voltage‐dependent anion channels (VDACs) are the primary gates for solutes across the outer mitochondrial membrane (OMM); however, their role in apoptotic OMM permeabilization remains controversial. Here, we report that VDAC2^?/? (V2^?/?) mouse embryonic fibroblasts (MEFs) are virtually insensitive to tBID‐induced OMM permeabilization and apoptosis, whereas VDAC1^?/?, VDAC3^?/? and VDAC1^?/?/VDAC3^?/? MEFs respond normally to tBID. V2^?/? MEFs regain tBID sensitivity after VDAC2 expression. Furthermore, V2^?/? MEFs are deficient in mitochondrial BAK despite normal tBID–mitochondrial binding and BAX/BAK expression. tBID sensitivity of BAK^?/? MEFs is also reduced, although not to the same extent as V2^?/? MEFs, which might result from their strong overexpression of BAX. Indeed, addition of recombinant BAX also sensitized V2^?/? MEFs to tBID. Thus, VDAC2 acts as a crucial component in mitochondrial apoptosis by allowing the mitochondrial recruitment of BAK, thereby controlling tBID‐induced OMM permeabilization and cell death.     

Two pathways for tBID-induced cytochrome c release from rat brain mitochondria: BAK- versus BAX-dependence

The mechanisms of truncated BID (tBID)-induced Cyt c release from non-synaptosomal brain mitochondria were examined. Addition of tBID to mitochondria induced partial Cyt c release which was inhibited by anti-BAK antibodies, implicating BAK. Immunoblotting showed the presence of BAK, but not BAX, in brain mitochondria. tBID did not release Cyt c from rat liver mitochondria, which lacked both BAX and BAK. This indicated that tBID did not act independently of BAX and BAK. tBID plus monomeric BAX produced twice as much Cyt c release as did tBID or oligomeric BAX alone. Neither tBID alone nor in combination with BAX induced mitochondrial swelling. In both cases Cyt c release was insensitive to cyclosporin A plus ADP, inhibitors of the mitochondrial permeability transition (mPT). Recombinant Bcl-xL inhibited Cyt c release induced by tBID alone or in combination with monomeric BAX. Koenig's polyanion, an inhibitor of VDAC, suppressed tBID-induced Cyt c release from brain mitochondria mediated by BAK but not by BAX. Thus, tBID can induce mPT-independent Cyt c release from brain mitochondria by interacting with exogenous BAX and/or with endogenous BAK that may involve VDAC. In contrast, neither adenylate kinase nor Smac/DIABLO was released from isolated rat brain mitochondria via BAK or BAX.     

The MUC1-C oncoprotein binds to the BH3 domain of the pro-apoptotic BAX protein and blocks BAX function

The pro-apoptotic BAX protein contains a BH3 domain that is necessary for its dimerization and for activation of the intrinsic apoptotic pathway. The MUC1 (mucin 1) heterodimeric protein is overexpressed in diverse human carcinomas and blocks apoptosis in the response to stress. In this study, we demonstrate that the oncogenic MUC1-C subunit associates with BAX in human cancer cells. MUC1-C·BAX complexes are detectable in the cytoplasm and mitochondria and are induced by genotoxic and oxidative stress. The association between MUC1-C and BAX is supported by the demonstration that the MUC1-C cytoplasmic domain is sufficient for the interaction with BAX. The results further show that the MUC1-C cytoplasmic domain CQC motif binds directly to the BAX BH3 domain at Cys-62. Consistent with binding to the BAX BH3 domain, MUC1-C blocked BAX dimerization in response to (i) truncated BID in vitro and (ii) treatment of cancer cells with DNA-damaging agents. In concert with these results, MUC1-C attenuated localization of BAX to mitochondria and the release of cytochrome c. These findings indicate that the MUC1-C oncoprotein binds directly to the BAX BH3 domain and thereby blocks BAX function in activating the mitochondrial death pathway.