Targeting Bcl-2-IP3 receptor interaction to reverse Bcl-2's inhibition of apoptotic calcium signals - PubMed (original) (raw)

. 2008 Jul 25;31(2):255-65.

doi: 10.1016/j.molcel.2008.06.014.

Ademuyiwa S Aromolaran, Geert Bultynck, Fei Zhong, Xiang Li, Karen McColl, Shigemi Matsuyama, Stephan Herlitze, H Llewelyn Roderick, Martin D Bootman, Gregory A Mignery, Jan B Parys, Humbert De Smedt, Clark W Distelhorst

Affiliations

Targeting Bcl-2-IP3 receptor interaction to reverse Bcl-2's inhibition of apoptotic calcium signals

Yi-Ping Rong et al. Mol Cell. 2008.

Abstract

The antiapoptotic protein Bcl-2 inhibits Ca2+ release from the endoplasmic reticulum (ER). One proposed mechanism involves an interaction of Bcl-2 with the inositol 1,4,5-trisphosphate receptor (IP3R) Ca2+ channel localized with Bcl-2 on the ER. Here we document Bcl-2-IP3R interaction within cells by FRET and identify a Bcl-2 interacting region in the regulatory and coupling domain of the IP3R. A peptide based on this IP3R sequence displaced Bcl-2 from the IP3R and reversed Bcl-2-mediated inhibition of IP3R channel activity in vitro, IP3-induced ER Ca2+ release in permeabilized cells, and cell-permeable IP3 ester-induced Ca2+ elevation in intact cells. This peptide also reversed Bcl-2's inhibition of T cell receptor-induced Ca2+ elevation and apoptosis. Thus, the interaction of Bcl-2 with IP3Rs contributes to the regulation of proapoptotic Ca2+ signals by Bcl-2, suggesting the Bcl-2-IP3R interaction as a potential therapeutic target in diseases associated with Bcl-2's inhibition of cell death.

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Figures

Figure 1

Figure 1. FRET Detection of Bcl-2-IP3R Interaction

FRET was detected by the increase of CFP fluorescence following YFP bleaching in COS-7 cells expressing CFP-Bcl-2 + YFP-IP3R and CFP-YFP cameleon, but not control combinations of fluorescently tagged proteins. (A) Representative images of CFP fluorescence intensity before and after YFP photobleaching (left and middle columns). Gray value images (right column) were obtained by pixel-by-pixel subtraction of CFP prebleach images from postbleach images, with relative intensity differences represented by the gray scale. Scale bar, 5 μm. (B) Diagram of C-terminal location of CFP and YFP on Bcl-2 and IP3R, respectively. (C) Multiple regions of interest (>60 for each pair of samples) were randomly selected from the CFP and YFP colocalization regions in three individual experiments. FRET efficiency was calculated according to the increase in CFP emission by Volocity software. Symbols represent mean ± SEM. *p < 0.01.

Figure 2

Figure 2. Endogenous Bcl-2 Inhibits Anti-CD3-Induced Ca2+ Elevation in Jurkat Cells

(A) Bcl-2 levels in wild-type WEHI7.2, Jurkat, and Bcl-2(+) WEHI7.2 cells by immunoblotting. (B) Coimmunoprecipitation of Bcl-2 with IP3R in Jurkat extracts; immunoblot analysis using anti-Bcl-2 antibody. (C) Immunoblot of Bcl-2 in Jurkat extracts 24 and 48 hr after transfection with nontargeting control siRNA (siNT) or Bcl-2 siRNA (siBcl-2). (D) Digital imaging traces (average 160 cells per sample) monitoring Ca2+ elevation induced by 20 μg/ml anti-CD3 in the presence of extracellular Ca2+. (E) Peak Ca2+ elevation induced by 20 μg/ml anti-CD3 in presence of extracellular Ca2+ (mean ± SEM, three experiments). (F) Peak Ca2+ elevation induced by 100 nM thapsigargin, measured fluorometrically in the absence of extracellular Ca2+ (mean ± SEM, three experiments). (G) Area under the cytosolic Ca2+ 340 nM/380 nM ratio curve in (F) (mean ± SEM, three experiments).

Figure 3

Figure 3. Bcl-2-IP3R Interaction Mapping

(A) Diagram of type 1 IP3R domains. (B and C) GST-IP3R fragment pull-downs employing cytosolic extracts from Bcl-2(+) WEHI7.2 or Jurkat cells as Bcl-2 source. (Upper panel) Coomassie blue-stained gel showing input GST-IP3R fragments; (bottom panel) Bcl-2 detected by immunoblotting. Findings representative of five experiments using Bcl-2(+) WEHI7.2 extract and two experiments using Jurkat extract indicate that Bcl-2 mainly interacts with domain 3. (D) Cell extracts from Bcl-2(+) WEHI7.2 cells were prepared in three different buffers, which differ mainly by detergent type and concentration. The same buffers were used during GST-IP3R pull-down and wash steps, except that in buffers 2 and 3 1% BSA was added and the NaCl concentration was increased to 300 mM in the binding steps to increase binding specificity. Also, wash steps were repeated three times with buffer 1, but seven to eight times with buffers 2 and 3. (Upper panel) Coomassie blue staining of GST-IP3R fragments, repeated twice with the same result. (E) GST pull-down, performed as in (B), using GSTIP3R subdomain fragments 3a, 3b, 3a1, and 3a2. (Upper panel) Anti-GST immunoblot documenting input levels of IP3R fragments. (Lower panel) Anti-Bcl-2 immunoblot documenting that subdomain 3a1 is the major binding region of Bcl-2 on the IP3R. This experiment was repeated twice with the same result. (F) Silver-stain gel indicating the purity of His-tagged Bcl-2. (G) GST pull-down with purified His-tagged Bcl-2. (Upper panel) Input GST-IP3R fragments resolved by SDS-PAGE and stained with Coomassie blue. (Bottom panel) Immunoblot for Bcl-2 showing that purified 30 kDa His-Bcl-2 directly interacted with GST-IP3R domain 3, repeated three times with the same result.

Figure 4

Figure 4. An IP3R Peptide Inhibits Bcl-2-IP3R Interaction but Not Bim-Bcl-2 Interaction

(A) Sequences of peptides 1 and 2, corresponding to regions within IP3R subdomain 3a1, and control peptide representing a scrambled sequence of peptide 2. (B) Peptide 2 inhibits the interaction between Bcl-2 and GST-IP3R domain 3 in GST pull-down assays. Bcl-2(+) WEHI7.2 cell extracts were preincubated with 200 μM or 1 mM peptides for 20 min before adding the glutathione sepharose resin with GST-IP3R domain 3 fragment attached. (C and E) IP3R was immunoprecipitated from extracts of Bcl-2(+) WEHI7.2 cells (C) or Jurkat cells (E) in the presence of 400 μM peptides. Peptide 2, but not peptide 1 or control peptide, inhibited the Bcl-2-IP3R coimmunoprecipitation. (D) Summary of Bcl-2 immunoblot signal intensities in three GST pull-down experiments identical to (C) (mean ± SEM). (F) Bcl-2 was immunoprecipitated from Bcl-2(+) WEHI7.2 cell extracts in the presence of 400 μM peptides, and coimmunoprecipitation of Bim was detected by anti-Bim immunoblotting. Neither control peptide nor peptide 2 interfered with the Bcl-2-Bim interaction. (G) Summary of Bim immunoblot signal intensities in three experiments identical to (F) (mean ± SEM).

Figure 5

Figure 5. Peptide 2 Reverses Bcl-2’s Inhibition of IP3R Channel Opening In Vitro

(A) IP3R type 1 single channel recordings at 0 mV in planar lipid bilayers with 250 nM Ca2+ and 2 μM IP3 in the cis (cytosolic) compartment (zero-current level marked). Current traces at the expanded time scale are shown in the bottom panel. Purified Bcl-2 (0.1 μM), added to the cis compartment, blocked channel activity. Subsequent addition of peptide 2 (10 μM) reversed Bcl-2’s inhibition of channel activity. (B) Shown is a single channel recording documenting that significant reduction of channel activity is detected within less than 3 min after Bcl-2 addition. (C) Summary of multiple experiments (mean ± SEM) measuring effects of Bcl-2 and peptides on IP3R channel open probability. n = number of individual channels examined. Symbols represent mean ± SEM. *p < 0.05.

Figure 6

Figure 6. Peptide 2 Reverses Bcl-2’s Inhibition of Anti-CD3-Induced Ca2+ Elevation

(A) Representative Ca2+ traces (each the mean of −65 cells) recording anti-CD3 (arrow, time of addition)- induced Ca2+ elevation in Bcl-2(+) WEHI7.2 cells. Peptide (60 μM) uptake was facilitated by Chariot reagent. (B) Peak anti-CD3 induced Ca2+ elevation in Bcl-2(−) and Bcl-2(+) WEHI7.2 cells treated with peptides as in (A) [mean ± SEM, five experiments for Bcl-2(−) and seven experiments for Bcl-2(+) cells, with mean 68 cells per sample per experiment]. (C) Representative Ca2+ traces in Jurkat cells (mean 85 cells each). Treatment conditions are the same as in (A), except that a control involving addition of peptide 2 without Chariot reagent has been added. (D) Peak anti-CD3-induced Ca2+ elevation in Jurkat cells treated with peptides as in (C) (mean ± SEM, seven experiments, mean 81 cells per sample per experiment).

Figure 7

Figure 7. Peptide 2 Enhances Anti-CD3-Induced Apoptosis in Bcl-2-Positive Cells

(A) Typical apoptotic nuclear morphology (arrow, Hoechst 33342 stain) 24 hr after 5 μg/ml anti-CD3 treatment of Jurkat cells. Scale bars, 10 μm. (B) Bcl-2(−) and Bcl-2(+) WEHI7.2 cells were preincubated ± 60 μM peptides plus Chariot reagent and then incubated with 20 μg/ml anti-CD3 for 24 hr. Symbols represent the percentage of cells (mean ± SEM) with apoptotic nuclei in three experiments for Bcl-2(−) and five experiments for Bcl-2(+) cells (200 cells counted per coverslip). (C) Jurkat cells were preincubated ± 60 μM peptides ± Chariot reagent and then incubated with 5 μg/ml anti-CD3 for 24 hr. Symbols represent the percentage of cells (mean ± SEM) with apoptotic nuclei in five experiments (240 cells counted per coverslip).

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