Interactome disassembly during apoptosis occurs independent of caspase cleavage

Protein–protein interaction networks (interactomes) define the functionality of all biological systems. In apoptosis, proteolysis by caspases is thought to initiate disassembly of protein complexes and cell death. Here we used a quantitative proteomics approach, protein correlation profiling (PCP), to explore changes in cytoplasmic and mitochondrial interactomes in response to apoptosis initiation as a function of caspase activity. We measured the response to initiation of Fas‐mediated apoptosis in 17,991 interactions among 2,779 proteins, comprising the largest dynamic interactome to date. The majority of interactions were unaffected early in apoptosis, but multiple complexes containing known caspase targets were disassembled. Nonetheless, proteome‐wide analysis of proteolytic processing by terminal amine isotopic labeling of substrates (TAILS) revealed little correlation between proteolytic and interactome changes. Our findings show that, in apoptosis, significant interactome alterations occur before and independently of caspase activity. Thus, apoptosis initiation includes a tight program of interactome rearrangement, leading to disassembly of relatively few, select complexes. These early interactome alterations occur independently of cleavage of these protein by caspases.

[1]  Greg W. Clark,et al.  Panorama of ancient metazoan macromolecular complexes , 2015, Nature.

[2]  Edward L. Huttlin,et al.  The BioPlex Network: A Systematic Exploration of the Human Interactome , 2015, Cell.

[3]  M. Aebi,et al.  Protein degradation corrects for imbalanced subunit stoichiometry in OST complex assembly , 2015, Molecular biology of the cell.

[4]  U. Eckhard,et al.  Protein Termini and Their Modifications Revealed by Positional Proteomics. , 2015, ACS chemical biology.

[5]  Johannes E. Schindelin,et al.  The ImageJ ecosystem: An open platform for biomedical image analysis , 2015, Molecular reproduction and development.

[6]  Samantha G. Zeitlin,et al.  Engineered cellular gene-replacement platform for selective and inducible proteolytic profiling , 2015, Proceedings of the National Academy of Sciences.

[7]  A. Lamond,et al.  Multidimensional proteomics for cell biology , 2015, Nature Reviews Molecular Cell Biology.

[8]  Nichollas E. Scott,et al.  Development of a computational framework for the analysis of protein correlation profiling and spatial proteomics experiments. , 2015, Journal of proteomics.

[9]  G. Dewson,et al.  Mitochondria and apoptosis: emerging concepts , 2015, F1000prime reports.

[10]  István A. Kovács,et al.  Widespread Macromolecular Interaction Perturbations in Human Genetic Disorders , 2015, Cell.

[11]  Bridget E. Begg,et al.  A Proteome-Scale Map of the Human Interactome Network , 2014, Cell.

[12]  Sharon Yang,et al.  Proteome TopFIND 3.0 with TopFINDer and PathFINDer: database and analysis tools for the association of protein termini to pre- and post-translational events , 2014, Nucleic Acids Res..

[13]  Matthias Mann,et al.  Fractionation profiling: a fast and versatile approach for mapping vesicle proteomes and protein–protein interactions , 2014, Molecular biology of the cell.

[14]  B. Kuster,et al.  Mass-spectrometry-based draft of the human proteome , 2014, Nature.

[15]  Gary D Bader,et al.  A draft map of the human proteome , 2014, Nature.

[16]  M. Lei,et al.  Crystal structure of the TRBD domain of TERT and the CR4/5 of TR , 2014 .

[17]  Andrew R. Jones,et al.  ProteomeXchange provides globally co-ordinated proteomics data submission and dissemination , 2014, Nature Biotechnology.

[18]  Christian Kramer,et al.  Substrate-Driven Mapping of the Degradome by Comparison of Sequence Logos , 2013, PLoS Comput. Biol..

[19]  A. Burlingame,et al.  Global cellular response to chemotherapy-induced apoptosis , 2013, eLife.

[20]  Neil D. Rawlings,et al.  MEROPS: the database of proteolytic enzymes, their substrates and inhibitors , 2013, Nucleic Acids Res..

[21]  George M Church,et al.  pLogo: a probabilistic approach to visualizing sequence motifs , 2013, Nature Methods.

[22]  A. Lamond,et al.  Characterization of Native Protein Complexes and Protein Isoform Variation Using Size-fractionation-based Quantitative Proteomics* , 2013, Molecular & Cellular Proteomics.

[23]  L. Foster,et al.  High throughput strategies for probing the different organizational levels of protein interaction networks. , 2013, Molecular bioSystems.

[24]  David R McIlwain,et al.  Caspase functions in cell death and disease. , 2013, Cold Spring Harbor perspectives in biology.

[25]  M. Mann,et al.  Initial Quantitative Proteomic Map of 28 Mouse Tissues Using the SILAC Mouse* , 2013, Molecular & Cellular Proteomics.

[26]  C. Overall,et al.  Protein TAILS: when termini tell tales of proteolysis and function. , 2013, Current opinion in chemical biology.

[27]  Matthias Mann,et al.  A SILAC-based Approach Identifies Substrates of Caspase-dependent Cleavage upon TRAIL-induced Apoptosis* , 2013, Molecular & Cellular Proteomics.

[28]  Julia E. Seaman,et al.  The DegraBase: A Database of Proteolysis in Healthy and Apoptotic Human Cells* , 2012, Molecular & Cellular Proteomics.

[29]  A. Reichert,et al.  Complexome profiling identifies TMEM126B as a component of the mitochondrial complex I assembly complex. , 2012, Cell metabolism.

[30]  J. Enríquez,et al.  NDUFA4 is a subunit of complex IV of the mammalian electron transport chain. , 2012, Cell metabolism.

[31]  Franco J. Vizeacoumar,et al.  Interaction landscape of membrane-protein complexes in Saccharomyces cerevisiae , 2012, Nature.

[32]  Andrei L. Turinsky,et al.  A Census of Human Soluble Protein Complexes , 2012, Cell.

[33]  Julia E. Seaman,et al.  Conservation of caspase substrates across metazoans suggests hierarchical importance of signaling pathways over specific targets and cleavage site motifs in apoptosis , 2012, Cell Death and Differentiation.

[34]  L. Foster,et al.  A high-throughput approach for measuring temporal changes in the interactome , 2012, Nature Methods.

[35]  P. Vandenabeele,et al.  Degradomics Reveals That Cleavage Specificity Profiles of Caspase-2 and Effector Caspases Are Alike* , 2012, The Journal of Biological Chemistry.

[36]  Benjamin F. Cravatt,et al.  Functional Interplay between Caspase Cleavage and Phosphorylation Sculpts the Apoptotic Proteome , 2012, Cell.

[37]  Alma L. Burlingame,et al.  Quantitative profiling of caspase-cleaved substrates reveals different drug-induced and cell-type patterns in apoptosis , 2012, Proceedings of the National Academy of Sciences.

[38]  Natalie I. Tasman,et al.  A Cross-platform Toolkit for Mass Spectrometry and Proteomics , 2012, Nature Biotechnology.

[39]  Michael J. MacCoss,et al.  Platform-independent and Label-free Quantitation of Proteomic Data Using MS1 Extracted Ion Chromatograms in Skyline , 2012, Molecular & Cellular Proteomics.

[40]  W. Alkema,et al.  Molecular pathway profiling of T lymphocyte signal transduction pathways; Th1 and Th2 genomic fingerprints are defined by TCR and CD28-mediated signaling , 2012, BMC Immunology.

[41]  Matthias Mann,et al.  Analysis of High Accuracy, Quantitative Proteomics Data in the MaxQB Database , 2012, Molecular & Cellular Proteomics.

[42]  A. Burlingame,et al.  Global kinetic analysis of proteolysis via quantitative targeted proteomics , 2012, Proceedings of the National Academy of Sciences.

[43]  Julian Mintseris,et al.  A Protein Complex Network of Drosophila melanogaster , 2011, Cell.

[44]  A. Strasser,et al.  Fas death receptor signalling: roles of Bid and XIAP , 2011, Cell Death and Differentiation.

[45]  Christopher M Overall,et al.  Identifying and quantifying proteolytic events and the natural N terminome by terminal amine isotopic labeling of substrates , 2011, Nature Protocols.

[46]  Thomas M Green,et al.  A public genome-scale lentiviral expression library of human ORFs , 2011, Nature Methods.

[47]  E. Crawford,et al.  Caspase substrates and cellular remodeling. , 2011, Annual review of biochemistry.

[48]  Soak-Kuan Lai,et al.  Caspase-3-mediated degradation of condensin Cap-H regulates mitotic cell death , 2011, Cell Death and Differentiation.

[49]  D. Chan,et al.  Analysis of the Human Endogenous Coregulator Complexome , 2011, Cell.

[50]  Kenneth W Dunn,et al.  A practical guide to evaluating colocalization in biological microscopy. , 2011, American journal of physiology. Cell physiology.

[51]  A. Barabasi,et al.  Interactome Networks and Human Disease , 2011, Cell.

[52]  Andrea Califano,et al.  Rewiring makes the difference , 2011, Molecular systems biology.

[53]  Sourav Bandyopadhyay,et al.  Rewiring of Genetic Networks in Response to DNA Damage , 2010, Science.

[54]  K. Gevaert,et al.  Who gets cut during cell death? , 2010, Current opinion in cell biology.

[55]  D. Green,et al.  Mitochondria and cell death: outer membrane permeabilization and beyond , 2010, Nature Reviews Molecular Cell Biology.

[56]  Sami Mahrus,et al.  Activation of Specific Apoptotic Caspases with an Engineered Small-Molecule-Activated Protease , 2010, Cell.

[57]  F. Eisenhaber,et al.  The substrate specificity profile of human granzyme A , 2010, Biological chemistry.

[58]  F. Avilés,et al.  Complementary positional proteomics for screening substrates of endo- and exoproteases , 2010, Nature Methods.

[59]  L. Foster,et al.  An integrated global strategy for cell lysis, fractionation, enrichment and mass spectrometric analysis of phosphorylated peptides. , 2010, Molecular bioSystems.

[60]  L. Foster,et al.  Isotopic labeling of terminal amines in complex samples identifies protein N-termini and protease cleavage products , 2010, Nature Biotechnology.

[61]  Ryan D. Morin,et al.  The completion of the Mammalian Gene Collection (MGC). , 2009, Genome research.

[62]  S. Maurer-Stroh,et al.  Analysis of Protein Processing by N-terminal Proteomics Reveals Novel Species-specific Substrate Determinants of Granzyme B Orthologs *S , 2009, Molecular & Cellular Proteomics.

[63]  D. Lauffenburger,et al.  Modeling a Snap-Action, Variable-Delay Switch Controlling Extrinsic Cell Death , 2008, PLoS biology.

[64]  M. Mann,et al.  MaxQuant enables high peptide identification rates, individualized p.p.b.-range mass accuracies and proteome-wide protein quantification , 2008, Nature Biotechnology.

[65]  David T. Barkan,et al.  Global Sequencing of Proteolytic Cleavage Sites in Apoptosis by Specific Labeling of Protein N Termini , 2008, Cell.

[66]  Benjamin F. Cravatt,et al.  Global Mapping of the Topography and Magnitude of Proteolytic Events in Apoptosis , 2008, Cell.

[67]  Daniel O Daley,et al.  The assembly of membrane proteins into complexes. , 2008, Current opinion in structural biology.

[68]  S. High,et al.  Ribophorin I regulates substrate delivery to the oligosaccharyltransferase core , 2008, Proceedings of the National Academy of Sciences.

[69]  Hyeong Jun An,et al.  Estimating the size of the human interactome , 2008, Proceedings of the National Academy of Sciences.

[70]  L. Forney,et al.  The tragedy of the uncommon: understanding limitations in the analysis of microbial diversity , 2008, The ISME Journal.

[71]  D. Lauffenburger,et al.  Quantitative analysis of pathways controlling extrinsic apoptosis in single cells. , 2008, Molecular cell.

[72]  G. Heijne,et al.  GFP-based optimization scheme for the overexpression and purification of eukaryotic membrane proteins in Saccharomyces cerevisiae , 2008, Nature Protocols.

[73]  J. Lieberman,et al.  Death by a thousand cuts: granzyme pathways of programmed cell death. , 2008, Annual review of immunology.

[74]  H. Mewes,et al.  CORUM: the comprehensive resource of mammalian protein complexes—2009 , 2007, Nucleic Acids Res..

[75]  S. Elmore Apoptosis: A Review of Programmed Cell Death , 2007, Toxicologic pathology.

[76]  M. Peter,et al.  The CD95 Receptor: Apoptosis Revisited , 2007, Cell.

[77]  G. Salvesen,et al.  The apoptosome: signalling platform of cell death , 2007, Nature Reviews Molecular Cell Biology.

[78]  Christopher M Overall,et al.  Proteomics Discovery of Metalloproteinase Substrates in the Cellular Context by iTRAQ™ Labeling Reveals a Diverse MMP-2 Substrate Degradome*S , 2007, Molecular & Cellular Proteomics.

[79]  M. Moran,et al.  Large-scale mapping of human protein–protein interactions by mass spectrometry , 2007, Molecular systems biology.

[80]  L. Scorrano,et al.  Organelle isolation: functional mitochondria from mouse liver, muscle and cultured filroblasts , 2007, Nature Protocols.

[81]  M. Mann,et al.  In-gel digestion for mass spectrometric characterization of proteins and proteomes , 2006, Nature Protocols.

[82]  Arun K. Ramani,et al.  How complete are current yeast and human protein-interaction networks? , 2006, Genome Biology.

[83]  John E. Walker,et al.  Bovine Complex I Is a Complex of 45 Different Subunits* , 2006, Journal of Biological Chemistry.

[84]  P. Krammer,et al.  Caspase-2 is activated at the CD95 death-inducing signaling complex in the course of CD95-induced apoptosis. , 2006, Blood.

[85]  P. Bork,et al.  Proteome survey reveals modularity of the yeast cell machinery , 2006, Nature.

[86]  Tiago Braga,et al.  Serglycin-deficient Cytotoxic T Lymphocytes Display Defective Secretory Granule Maturation and Granzyme B Storage* , 2005, Journal of Biological Chemistry.

[87]  J. Trapani,et al.  Discordant Regulation of Granzyme H and Granzyme B Expression in Human Lymphocytes* , 2004, Journal of Biological Chemistry.

[88]  Mark H Ellisman,et al.  Disruption of Mitochondrial Function during Apoptosis Is Mediated by Caspase Cleavage of the p75 Subunit of Complex I of the Electron Transport Chain , 2004, Cell.

[89]  A. Barabasi,et al.  Network biology: understanding the cell's functional organization , 2004, Nature Reviews Genetics.

[90]  S. Shapiro,et al.  A New Member of the LIM Protein Family Binds to Filamin B and Localizes at Stress Fibers* , 2003, The Journal of Biological Chemistry.

[91]  M. Mann,et al.  Stop and go extraction tips for matrix-assisted laser desorption/ionization, nanoelectrospray, and LC/MS sample pretreatment in proteomics. , 2003, Analytical chemistry.

[92]  D. Green,et al.  Caspase-mediated loss of mitochondrial function and generation of reactive oxygen species during apoptosis , 2003, The Journal of cell biology.

[93]  N. Thornberry,et al.  Discovery of potent, selective human granzyme B inhibitors that inhibit CTL mediated apoptosis. , 2002, Bioorganic & medicinal chemistry letters.

[94]  H. Wajant,et al.  The Fas Signaling Pathway: More Than a Paradigm , 2002, Science.

[95]  M. Mann,et al.  Stable Isotope Labeling by Amino Acids in Cell Culture, SILAC, as a Simple and Accurate Approach to Expression Proteomics* , 2002, Molecular & Cellular Proteomics.

[96]  D. Tang,et al.  Apoptotic Release of Histones from Nucleosomes* , 2002, The Journal of Biological Chemistry.

[97]  Anton J. Enright,et al.  An efficient algorithm for large-scale detection of protein families. , 2002, Nucleic acids research.

[98]  P. Bork,et al.  Functional organization of the yeast proteome by systematic analysis of protein complexes , 2002, Nature.

[99]  Alicia Algeciras-Schimnich,et al.  Molecular Ordering of the Initial Signaling Events of CD95 , 2002, Molecular and Cellular Biology.

[100]  D. Andrews,et al.  Cytoplasmic O‐glycosylation prevents cell surface transport of E‐cadherin during apoptosis , 2001, The EMBO journal.

[101]  T. Rudel,et al.  Predominant Identification of RNA-binding Proteins in Fas-induced Apoptosis by Proteome Analysis* , 2001, The Journal of Biological Chemistry.

[102]  R. Takahashi,et al.  Ubiquitin-protein ligase activity of X-linked inhibitor of apoptosis protein promotes proteasomal degradation of caspase-3 and enhances its anti-apoptotic effect in Fas-induced cell death , 2001, Proceedings of the National Academy of Sciences of the United States of America.

[103]  R. Cerione,et al.  Cdc42 Is a Substrate for Caspases and Influences Fas-induced Apoptosis* , 2001, The Journal of Biological Chemistry.

[104]  Young Chul Park,et al.  Structural Basis of Caspase Inhibition by XIAP Differential Roles of the Linker versus the BIR Domain , 2001, Cell.

[105]  J. Hartwig,et al.  Filamins as integrators of cell mechanics and signalling , 2001, Nature Reviews Molecular Cell Biology.

[106]  R. Siegel,et al.  The multifaceted role of Fas signaling in immune cell homeostasis and autoimmunity , 2000, Nature Immunology.

[107]  V. L. Johnson,et al.  Effector caspases are dispensable for the early nuclear morphological changes during chemical-induced apoptosis. , 2000, Journal of cell science.

[108]  C. Bortner,et al.  Caspase Independent/Dependent Regulation of K+, Cell Shrinkage, and Mitochondrial Membrane Potential during Lymphocyte Apoptosis* , 1999, The Journal of Biological Chemistry.

[109]  E. Friedberg,et al.  The 19S regulatory complex of the proteasome functions independently of proteolysis in nucleotide excision repair. , 1999, Molecular cell.

[110]  N. Thornberry,et al.  Inhibition of Human Caspases by Peptide-based and Macromolecular Inhibitors* , 1998, The Journal of Biological Chemistry.

[111]  Junying Yuan,et al.  Cleavage of BID by Caspase 8 Mediates the Mitochondrial Damage in the Fas Pathway of Apoptosis , 1998, Cell.

[112]  M. Peter,et al.  Two CD95 (APO‐1/Fas) signaling pathways , 1998, The EMBO journal.

[113]  S. Nagata,et al.  Cleavage of CAD inhibitor in CAD activation and DNA degradation during apoptosis , 1998, Nature.

[114]  N. Thornberry,et al.  A Combinatorial Approach Defines Specificities of Members of the Caspase Family and Granzyme B , 1997, The Journal of Biological Chemistry.

[115]  G. Bloom,et al.  IQGAP1, a Rac- and Cdc42-binding Protein, Directly Binds and Cross-links Microfilaments , 1997, The Journal of cell biology.

[116]  G. Evan,et al.  Inhibition of Ced-3/ICE-related Proteases Does Not Prevent Cell Death Induced by Oncogenes, DNA Damage, or the Bcl-2 Homologue Bak , 1997, The Journal of cell biology.

[117]  J. Xiang,et al.  BAX-induced cell death may not require interleukin 1 beta-converting enzyme-like proteases. , 1996, Proceedings of the National Academy of Sciences of the United States of America.

[118]  E. Alnemri,et al.  Granzyme B/perforin-mediated apoptosis of Jurkat cells results in cleavage of poly(ADP-ribose) polymerase to the 89-kDa apoptotic fragment and less abundant 64-kDa fragment. , 1996, Biochemical and biophysical research communications.

[119]  D. Danley,et al.  D4-GDI, a Substrate of CPP32, Is Proteolyzed during Fas-induced Apoptosis (*) , 1996, Journal of Biological Chemistry.

[120]  M. Peter,et al.  Cytotoxicity‐dependent APO‐1 (Fas/CD95)‐associated proteins form a death‐inducing signaling complex (DISC) with the receptor. , 1995, The EMBO journal.

[121]  Seamus J. Martin,et al.  Protease activation during apoptosis: Death by a thousand cuts? , 1995, Cell.

[122]  S. Orrenius,et al.  Cellular events in Fas/APO-1-mediated apoptosis in JURKAT T lymphocytes. , 1995, Experimental cell research.

[123]  Patrick R. Griffin,et al.  Identification and inhibition of the ICE/CED-3 protease necessary for mammalian apoptosis , 1995, Nature.

[124]  A. Barabasi,et al.  Network medicine : a network-based approach to human disease , 2010 .

[125]  J. Vonck,et al.  Supramolecular organization of protein complexes in the mitochondrial inner membrane. , 2009, Biochimica et biophysica acta.

[126]  M. Mann,et al.  Protocol for micro-purification, enrichment, pre-fractionation and storage of peptides for proteomics using StageTips , 2007, Nature Protocols.

[127]  H. Schägger,et al.  Blue native PAGE , 2006, Nature Protocols.

[128]  Yuanjie Hu,et al.  A novel NF-kappaB binding site controls human granzyme B gene transcription. , 2006, Journal of immunology.

[129]  Sang Joon Kim,et al.  A Mathematical Theory of Communication , 2006 .

[130]  A. Barabasi,et al.  Emergence of Scaling in Random Networks , 1999 .