Margarita Mikhailova

Bcl-2 prevents Bax oligomerization in the mitochondrial outer membrane.

ATP depletion results in Bax translocation from cytosol to mitochondria and release of cytochrome c from mitochondria into cytosol in cultured kidney cells. Overexpression of Bcl-2 prevents cytochrome c release, without ameliorating ATP depletion or Bax translocation, with little or no association between Bcl-2 and Bax as demonstrated by immunoprecipitation (Saikumar, P., Dong, Z., Patel, Y., Hall, K., Hopfer, U., Weinberg, J. M., and Venkatachalam, M. A. (1998) Oncogene 17, 3401–3415). Now we show that translocated Bax forms homo-oligomeric structures, stabilized as chemical adducts by bifunctional cross-linkers in ATP-depleted wild type cells, but remains monomeric in Bcl-2-overexpressing cells. The protective effects of Bcl-2 did not require Bcl-2/Bax association, at least to a degree of proximity or affinity that was stable to conditions of immunoprecipitation or adduct formation by eight cross-linkers of diverse spacer lengths and chemical reactivities. On the other hand, nonionic detergents readily induced homodimers and heterodimers of Bax and Bcl-2. Moreover, associations between translocated Bax and the voltage-dependent anion channel protein or the adenine nucleotide translocator protein could not be demonstrated by immunoprecipitation of Bax, or by using bifunctional cross-linkers. Our data suggest that the in vivo actions of Bax are at least in part dependent on the formation of homo-oligomers without requiring associations with other molecules and that Bcl-2 cytoprotection involves mechanisms that prevent Bax oligomerization.

Association of Bax and Bak homo-oligomers in mitochondria. Bax requirement for Bak reorganization and cytochrome c release.

ATP depletion induced by hypoxia or mitochondrial inhibitors results in Bax translocation from cytosol to mitochondria and release of cytochrome c from mitochondria into cytosol in cultured rat proximal tubule cells. Translocated Bax undergoes further conformational changes to oligomerize into high molecular weight complexes (Mikhailov, V., Mikhailova, M., Pulkrabek, D. J., Dong, Z., Venkatachalam, M. A., and Saikumar, P. (2001) J. Biol. Chem. 276, 18361–18374). Here we report that following Bax translocation in ATP-depleted rat proximal tubule cells, Bak, a proapoptotic molecule that normally resides in mitochondria, also reorganizes to form homo-oligomers. Oligomerization of both Bax and Bak occurred independently of Bid cleavage and/or translocation. Western blots of chemically cross-linked membrane extracts showed nonoverlapping “ladders” of Bax and Bak complexes in multiples of ∼21 and ∼23 kDa, respectively, consistent with molecular homogeneity within each ladder. This indicated that Bax and Bak complexes were homo-oligomeric. Nevertheless, each oligomer could be co-immunoprecipitated with the other, suggesting a degree of affinity between Bax and Bak that permitted co-precipitation but not cross-linking. Furthermore, dissociation of cross-linked complexes by SDS and renaturation prior to immunoprecipitation did not prevent reassociation of the two oligomeric species. Notably, expression of Bcl-2 prevented not only the oligomerization of Bax and Bak, but also the association between these two proteins in energy-deprived cells. Using Bax-deficient HCT116 and BMK cells, we show that there is stringent Bax requirement for Bak homo-oligomerization and for cytochrome c release during energy deprivation. Using Bak-deficient BMK cells we further show that Bak deficiency is associated with delayed kinetics of Bax translocation but does not affect either the oligomerization of translocated Bax or the leakage of cytochrome c. These results suggest a degree of functional cooperation between Bax and Bak in this form of cell injury, but also demonstrate an absolute requirement of Bax for mitochondrial permeabilization.

Regulation of androgen receptor transcriptional activity by rapamycin in prostate cancer cell proliferation and survival

The mTOR (mammalian target of rapamycin) inhibitor rapamycin caused growth arrest in both androgen-dependent and androgen-independent prostate cancer cells; however, long-term treatment induced resistance to the drug. The aim of this study was to investigate methods that can overcome this resistance. Here, we show that rapamycin treatment stimulated androgen receptor (AR) transcriptional activity, whereas suppression of AR activity with the antiandrogen bicalutamide sensitized androgen-dependent, as well as AR-sensitive androgen-independent prostate cancer cells, to growth inhibition by rapamycin. Further, the combination of rapamycin and bicalutamide, but not the individual drugs, induced significant levels of apoptosis in prostate cancer cells. The net effect of rapamycin is determined by its individual effects on the mTOR complexes mTORC1 (mTOR/raptor/GβL) and mTORC2 (mTOR/rictor/sin1/GβL). Inhibition of both mTORC1 and mTORC2 by rapamycin-induced apoptosis, whereas rapamycin-stimulation of AR transcriptional activity resulted from the inhibition of mTORC1, but not mTORC2. The effect of rapamycin on AR transcriptional activity was mediated by the phosphorylation of the serine/threonine kinase Akt, which also partially mediated apoptosis induced by rapamycin and bicalutamide. These results indicate the presence of two parallel cell-survival pathways in prostate cancer cells: a strong Akt-independent, but rapamycin-sensitive pathway downstream of mTORC1, and an AR-dependent pathway downstream of mTORC2 and Akt, that is stimulated by mTORC1 inhibition. Thus, the combination of rapamycin and bicalutamide induce apoptosis in prostate cancer cells by simultaneously inhibiting both pathways and hence would be of therapeutic value in prostate cancer treatment.

A 90 kDa fragment of filamin A promotes Casodex-induced growth inhibition in Casodex-resistant androgen receptor positive C4-2 prostate cancer cells

Prostate tumors are initially dependent on androgens for growth, but the majority of patients treated with anti-androgen therapy progress to androgen-independence characterized by resistance to such treatment. This study investigates a novel role for filamin A (FlnA), a 280 kDa cytoskeletal protein (consisting of an actin-binding domain (ABD) followed by 24 sequential repeats), in androgen-independent (AI) growth. Full-length FlnA is cleaved to 170 kDa (ABD+FlnA1–15) and 110 kDa fragments (FlnA16–24); the latter is further cleaved to a 90 kDa fragment (repeats 16–23) capable of nuclear translocation and androgen receptor (AR) binding. Here, we demonstrate that in androgen-dependent LNCaP prostate cancer cells, the cleaved 90 kDa fragment is localized to the nucleus, whereas in its AI subline C4–2, FlnA failed to cleave and remained cytoplasmic. Transfection of FlnA16–24 cDNA in C4–2 cells restored expression and nuclear localization of 90 kDa FlnA. Unlike LNCaP, C4–2 cells proliferate in androgen-reduced medium and in the presence of the AR-antagonist Casodex. They also exhibit increased Akt phosphorylation compared to LNCaP, which may contribute to their AI phenotype. Nuclear expression of 90 kDa FlnA in C4–2 cells decreased Akt phosphorylation, prevented proliferation in androgen-reduced medium and restored Casodex sensitivity. This effect was inhibited by constitutive activation of Akt indicating that FlnA restored Casodex sensitivity in C4–2 cells by decreasing Akt phosphorylation. In addition, FlnA-specific siRNA which depleted FlnA levels, but not control siRNA, induced resistance to Casodex in LNCaP cells. Our results demonstrate that expression of nuclear FlnA is necessary for androgen dependence in these cells.

Dual EGFR/HER2 Inhibition Sensitizes Prostate Cancer Cells to Androgen Withdrawal by Suppressing ErbB3

Purpose: Patients with recurrent prostate cancer are commonly treated with androgen withdrawal therapy (AWT); however, almost all patients eventually progress to castration resistant prostate cancer (CRPC), indicating failure of AWT to eliminate androgen-sensitive prostate cancer. The overall goal of these studies is to determine whether dual inhibition of the receptor tyrosine kinases epidermal growth factor receptor (EGFR) and HER2 would prolong the effectiveness of this treatment in prostate cancer. Experimental Design: We used androgen-dependent LNCaP cells and its CRPC sublines LNCaP-AI and C4-2. Additional data were collected in pRNS-1-1 cells stably expressing a mutant androgen receptor (AR-T877A), and in nude mice harboring CWR22 tumors. Studies utilized EGFR inhibitors erlotinib and AG1478, and HER2 inhibitors trastuzumab and AG879. Results: Dual EGFR/HER2 inhibition induced apoptosis selectively in androgen-sensitive prostate cancer cells undergoing AWT, but not in the presence of androgens, or in CRPC cells. We show that AWT alone failed to induce significant apoptosis in androgen-dependent cells, due to AWT-induced increase in HER2 and ErbB3, which promoted survival by increasing Akt phosphorylation. AWT-induced ErbB3 stabilized the AR and stimulated PSA, while it was inactivated only by inhibition of both its dimerization partners EGFR and HER2 (prostate cancer cells do not express ErbB4); but not the inhibition of any one receptor alone, explaining the success of dual EGFR/HER2 inhibition in sensitizing androgen-dependent cells to AWT. The effectiveness of the inhibitors in suppressing growth correlated with its ability to prevent Akt phosphorylation. Conclusion: These studies indicate that dual EGFR/HER2 inhibition, administered together with AWT, sensitize prostate cancer cells to apoptosis during AWT. Clin Cancer Res; 17(19); 6218–28. ©2011 AACR.

Nuclear Magnetic Resonance Mapping and Functional Confirmation of the Collagen Binding Sites of Matrix Metalloproteinase-2 †

Interactions of matrix metalloproteinase-2 (MMP-2) with native and denatured forms of several types of collagen are mediated by the collagen binding domain (CBD). CBD positions substrates relative to the catalytic site and is essential for their cleavage. Our previous studies identified a CBD binding site on the alpha1(I) collagen chain. The corresponding synthetic collagen peptide P713 bound CBD with high affinity and was used in this study to identify specific collagen binding residues by NMR analysis of (15)N-labeled CBD complexed with P713. Results obtained showed that P713 caused chemical shift perturbations of several surface-exposed CBD backbone amide resonances in a concentration-dependent manner. The 10 residues that underwent the largest chemical shift perturbations (R(252) in module 1, R(296), F(297), Y(302), E(321), Y(323), and Y(329) in module 2, and R(368), W(374), and Y(381) in module 3) were investigated by site-specific substitution with alanine. The structural integrity of the CBD variants was also analyzed by one-dimensional (1)H NMR. Surface plasmon resonance and microwell protein binding assays of control and CBD variants showed that residues in all three CBD modules contributed to collagen binding. Single-residue substitutions altered the affinity for peptide P713, as well as native and denatured type I collagen, with the greatest effects observed for residues in modules 2 and 3. Additional alanine substitutions involving residues in two or three modules simultaneously further reduced the level of binding of CBD to native and denatured type I collagen and demonstrated that all three modules contribute to substrate binding. These results have localized and confirmed the key collagen binding site residues in the three fibronectin type II-like modules of MMP-2.

Regulation of caspase-9 activity by differential binding to the apoptosome complex

Proteolytic processing of procaspase-9 is required for its activation, but processing in itself appears to be insufficient for its activity. We studied caspase activation in a cell-free system and found that incubation of cytosol from rat kidney proximal tubule cells with Cytochrome c (Cyt c) and dATP results in rapid autocatalytic processing of procaspase-9 from ~50 kD to ~38 kD size fragment. Moreover, Cyt c concentration influences the production of alternatively processed forms of caspase-9. At lower Cyt c concentration (0.01-0.05 mg/ml), two fragments of caspase-9 of the size 38 and 40 kD are produced. In contrast, at higher concentrations of Cyt c (>0.1 mg/ml) only 38 kD fragment will prevail. However, our failure to capture processed caspase-9 by affinity labeling or co-elution with Apaf-1 suggested that caspase-9 undergoes a conformational change during its enzymatic action on effector caspases, resulting in its release from the apoptosome complex and inactivation. In support of this hypothesis, catalytic inhibitors of caspase-9 prevented its release from the apoptosome complex without affecting its auto-processing and allowed successful capture of active caspase-9 (38 kD) and its complex by affinity labeling. These observations suggest that complex allosteric interactions with the apoptosome complex influence caspase-9 activity and function by controlling not only the induction of its enzymatic activity, but also its rapid termination.

AKT regulates androgen receptor-dependent growth and PSA expression in prostate cancer.

Recurrent prostate cancer (PC) is usually treated with androgen deprivation therapy, which, despite initial success, eventually fails due to the development of androgen-independent PC. Androgen deprivation stimulates a significant increase in the phosphorylation (activation) of Akt, a serine/threonine kinase, which regulates cell growth and survival. Hence, we asked whether the increase in Akt phosphorylation contributes to the development of androgen independence. Akt regulates transcriptional activity of the androgen receptor (AR), and our data show that Akt-stimulated AR transcriptional activity is dependent on androgen-binding to the AR. PC proliferation has both androgen-sensitive and insensitive components. The androgen sensitive component is Akt-dependent, while the androgen-insensitive is not. However, Akt-induced cell survival is largely AR independent, suggesting that the cell stimulates Akt phosphorylation when subjected to androgen deprivation as an alternate pathway to maintain survival.

Fragmentation of fibronectin by inherent autolytic and matrix metalloproteinase activities.

Fibronectin (FN) purified by gelatin affinity chromatography is unstable and undergoes fragmentation. The cleavage has been ascribed to inherent autolytic protease activities as well as co-purified matrix metalloproteinases (MMP). Understanding the mechanism by which the proteolysis of FN occurs is important, because the FN fragments have biological activities that differ from those of intact FN. Having excluded contributions of other plasma-derived proteases, the present experiments demonstrated that cleavage of FN by MMP-2 to distinct fragments occurred in synergy with inherent FN activities. Limited heat treatment of FN at 56°C for 30 min inactivated the inherent protease activities sharply reducing autolysis of FN in a manner similar to that seen in the presence of serine proteinase inhibitors. Heat treatment did not alter cell attachment to FN, but significantly increased the susceptibility of FN to enzymatic cleavage by MMP-2. The carboxyl-terminal hemopexin-like domain (PEX) of MMP-2 was shown to possess critical exodomain properties required for the interactions of MMP-2 with FN, and FN was cleaved at a significantly reduced rate by an MMP-2 variant with deletion of PEX. Verifying the specificity of interactions, isolated PEX competed FN cleavage by MMP-2 in a concentration-dependent manner. These results have further elucidated the synergistic contributions of inherent autolytic serine protease-like activities and MMP-2 to fragmentation of FN and provide the rationale and basis for modified preparation and handling of FN used in biological research.

Identification of collagen binding domain residues that govern catalytic activities of matrix metalloproteinase-2 (MMP-2).

An innovative approach to enhance the selectivity of matrix metalloproteinase (MMP) inhibitors comprises targeting these inhibitors to catalytically required substrate binding sites (exosites) that are located outside the catalytic cleft. In MMP-2, positioning of collagen substrate molecules occurs via a unique fibronectin-like domain (CBD) that contains three distinct modular collagen binding sites. To characterize the contributions of these exosites to gelatinolysis by MMP-2, seven MMP-2 variants were generated with single, or concurrent double and triple alanine substitutions in the three fibronectin type II modules of the CBD. Circular dichroism spectroscopy verified that recombinant MMP-2 wild-type (WT) and variants had the same fold. Moreover, the MMP-2 WT and variants had the same activity on a short FRET peptide substrate that is hydrolyzed independently of CBD binding. Among single-point variants, substitution in the module 3 binding site had greatest impact on the affinity of MMP-2 for gelatin. Simultaneous substitutions in two or three CBD modules further reduced gelatin binding. The rates of gelatinolysis of MMP-2 variants were reduced by 20-40% following single-point substitutions, by 60-75% after double-point modifications, and by >90% for triple-point variants. Intriguingly, the three CBD modules contributed differentially to cleavage of dissociated α-1(I) and α-2(I) collagen chains. Importantly, kinetic analyses (k(cat)/K(m)) revealed that catalysis of a triple-helical FRET peptide substrate by MMP-2 relied primarily on the module 3 binding site. Thus, we have identified three collagen binding site residues that are essential for gelatinolysis and constitute promising targets for selective inhibition of MMP-2.