Abstract
Bacterial toxin or viral entry into the cell often requires cell surface binding and endocytosis. The endosomal acidification induces a limited unfolding/refolding and membrane insertion reaction of the soluble toxins or viral proteins into their translocation competent or membrane inserted states. At the molecular level, the specific orientation and immobilization of the pre-transitioned toxin on the cell surface is often an important prerequisite prior to cell entry. We propose that structures of some toxin membrane insertion complexes may be observed through procedures where one rationally immobilizes the soluble toxin so that potential unfolding ↔ refolding transitions that occur prior to membrane insertion orientate away from the immobilization surface in the presence of lipid micelle pre-nanodisc structures. As a specific example, the immobilized prepore form of the anthrax toxin pore translocon or protective antigen can be transitioned, inserted into a model lipid membrane (nanodiscs), and released from the immobilized support in its membrane solubilized form. This particular strategy, although unconventional, is a useful procedure for generating pure membrane-inserted toxins in nanodiscs for electron microscopy structural analysis. In addition, generating a similar immobilized platform on label-free biosensor surfaces allows one to observe the kinetics of these acid-induced membrane insertion transitions. These platforms can facilitate the rational design of inhibitors that specifically target the toxin membrane insertion transitions that occur during endosomal acidification. This approach may lead to a new class of direct anti-toxin inhibitors.
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References
Akkaladevi N, Hinton-Chollet L, Katayama H, Mitchell J, Szerszen L, Mukherjee S, Gogol EP, Pentelute BL, Collier RJ, Fisher MT (2013) Assembly of anthrax toxin pore: lethal-factor complexes into lipid nanodiscs. Protein Sci 22:492–501
Bayburt TH, Sligar SG (2010) Membrane protein assembly into nanodiscs. FEBS Lett 584(9):1721–1727
Coyle JE, Jaeger J, Gross M, Robinson CV, Radford SE (1997) Structural and mechanistic consequences of polypeptide binding by GroEL. Fold Des 2(6):R93–R104
Deaton J, Sun J, Holzenburg A, Struck DK, Berry J, Young R (2004a) Functional bacteriorhodopsin is efficiently solubilized and delivered to membranes by the chaperonin GroEL. Proc Natl Acad Sci USA 101(8):2281–2286
Deaton J, Savva CG, Sun J, Holzenburg A, Berry J, Young R (2004b) Solubilization and delivery by GroEL of megadalton complexes of the lambda holing. Protein Sci 13(7):1778–1786
Efremov RG, Leitner A, Aebersold R, Raunser S (2014) Architecture and conformational switch mechanism of the ryanodine receptor. Nature. doi: 10.1038/nature13916.
Elad N, Farr GW, Clare DK, Orlova EV, Horwich AL, Saibil HR (2007) Topologies of a substrate protein bound to the chaperonin GroEL. Mol Cell 26(3):415–426
Esko JD, Sharon N (2009) Microbial lectins: hemagglutinins, adhesins and toxins. In: Varki A, Cummings RD, Esko JD (eds) Essentials of glycobiology, 2nd edn. Cold Spring Harbor Laboratory Press, Cold Spring Harbor
Falke S, Tama F, Brooks CL 3rd, Gogol EP, Fisher MT (2004) The 13 angstroms structure of a chaperonin GroEL–protein substrate complex by cryo-electron microscopy. J Mol Biol 348(1):219–230
Feld GK, Brown MJ, Krantz BA (2012) Ratcheting up protein translocation with anthrax toxin. Protein Sci 21(5):606–624 Review
Frauenfeld J, Gumbart J, Sluis EO, Funes S, Gartmann M, Beatrix B, Mielke T, Berninghausen O, Becker T, Schulten K, Beckmann R (2011) Cryo-EM structure of the ribosome–SecYE complex in the membrane environment. Nat Struct Mol Biol 18:614–621
Gogol EP, Akkaladevi N, Szerszen L, Mukherjee S, Chollet-Hinton L, Katayama H, Pentelute BL, Collier RJ, Fisher MT (2013) Three dimensional structure of the anthrax toxin translocon-lethal factor complex by cryo-electron microscopy. Protein Sci 22:586–594
Hernández-Rocamora VM, García-Montañés C, Rivas G, Llorca O (2012) Reconstitution of the Escherichia coli cell division ZipA–FtsZ complexes in nanodiscs as revealed by electron microscopy. J Struct Biol 180(3):531–538
Janowiak BE, Finkelstein A, Collier RJ (2009) An approach to characterizing single-subunit mutations in multimeric prepores and pores of anthrax protective antigen. Protein Sci 18:348–358
Janowiak BE, Jennings-Antipov LD, Collier RJ (2011) Cys–Cys cross-linking shows contact between the N-terminus of lethal factor and Phe427 of the anthrax toxin pore. Biochemistry 50(17):3512–3516
Katayama H, Janowiak BE, Brzozowski M, Jurcyk J, Falke S, Gogol EP, Collier RJ, Fisher MT (2008) GroEL as a molecular scaffold for structural analysis of the anthrax toxin pore. Nat Struct Mol Biol 15:754–760
Katayama H, Wang J, Tama F, Chollet L, Gogol EP, Collier RJ, Fisher MT (2010) Three-dimensional structure of the anthrax toxin pore inserted into lipid nanodiscs and lipid vesicles. Proc Natl Acad Sci USA 107:3453–3457
Kühlbrandt W (2014) The resolution revolution. Science 343:1443–1444
Kyrychenko A, Rodnin MV, Posokhov YO, Holt A, Pucci B, Killian JA, Ladokhin AS (2012) Thermodynamic measurements of bilayer insertion of a single transmembrane helix chaperoned by fluorinated surfactants. J Mol Biol 416(3):328–334
Laine E, Martínez L, Ladant D, Malliavin T, Blondel A (2012) Molecular motions as a drug target: mechanistic simulations of anthrax toxin edema factor function led to the discovery of novel allosteric inhibitors. Toxins (Basel). 4(8):580–604
Liao H-S, Liu H-L, Chen W-H, Ho Y (2014) Structure-based pharmacophore modeling and virtual screening to identify novel inhibitors for anthrax lethal factor. Med Chem Res 23:3725–3732
Liu S, Crown D, Miller-Randolph S, Moayeri M, Wang H et al (2009) Capillary morphogenesis protein-2 is the major receptor mediating lethality of anthrax toxin in vivo. Proc Natl Acad Sci USA 106:12424–12429
Nagayama K, Danev R (2010) Phase contrast enhancement with phase plates in biological electron microscopy. Microsc Today 18(4):10–13
Naglich JG, Metherall JE, Russell DW, Eidels L (1992) Expression cloning of a diphtheria toxin receptor: identity with a heparin-binding EGF-like growth factor precursor. Cell 69:1051–1061
Naik S, Brock S, Akkaladevi N, Tally J, Gao P, Zhang N, Pentelute BL, Collier RJ, Fisher MT (2013) Monitoring the kinetics of the pH driven transition of the anthrax toxin prepore to the pore by biolayer inferferometry and surface plasmon resonance. Biochemistry 52:6335–6347
Naik S, Kumru OS, Cullom M, Telikepalli SN, Lindboe E, Roop TL, Joshi SB, Amin D, Gao P, Middaugh CR, Volkin DB, Fisher MT (2014) Probing structurally altered and aggregated states of therapeutically relevant proteins using GroEL coupled to bio-layer interferometry. Protein Sci 23(10):1461–1478
Palazzo G, Lopez F, Mallardi A (2010) Effect of detergent concentration on the thermal stability of a membrane protein: the case study of bacterial reaction center solubilized by N,N-dimethyldodecylamine-N-oxide. Biochim Biophys Acta 804(1):137–146
Parker MW, Buckley JT, Postma JP, Tucker AD, Leonard K, Pattus F, Tsernoglou D (1994) Structure of the Aeromonas toxin proaerolysin in its water-soluble and membrane-channel states. Nature 367:292–295
Reviakine I, Stoylova S, Holzenburg A (1996) Surfactosomes: a novel approach to the reconstitution and 2-D crystallisation of membrane proteins. FEBS Lett 380(3):296–300
Ritchie TK, Grinkova YV, Bayburt TH, Denisov IG, Zolnerciks JK, Atkins WM, Sligar SG (2009) Chapter 11—reconstitution of membrane proteins in phospholipid bilayer nanodiscs. Methods Enzymol 464:211–231
Rodnin MV, Posokhov YO, Contino-Pépin C, Brettmann J, Kyrychenko A, Palchevskyy SS, Pucci B, Ladokhin AS (2008) Interactions of fluorinated surfactants with diphtheria toxin T-domain: testing new media for studies of membrane proteins. Biophys J 94(11):4348–4357
Roseman AM, Ranson NA, Gowen B, Fuller SD, Saibil HR (2001) Structures of unliganded and ATP-bound states of the Escherichia coli chaperonin GroEL by cryoelectron microscopy. J Struct Biol 135(2):115–125
Song L, Hobaugh MR, Shustak C, Cheley S, Bayley H, Gouaux JE (1996) Structure of staphylococcal alpha-hemolysin, a heptameric transmembrane pore. Science 274:1859–1866
Sun J, Savva CG, Deaton J, Kaback HR, Svrakic M, Young R, Holzenburg A (2005) Asymmetric binding of membrane proteins to GroEL. Arch Biochem Biophys 434(2):352–357
Unno H, Goda S, Hatakeyama T (2014) Hemolytic lectin CEL-III heptamerizes via a large structural transition from α-helices to a β-barrel during the transmembrane pore formation process. J Biol Chem 289(18):12805–12812
Vernier G, Wang J, Jennings LD, Sun J, Fischer A, Song L, Collier RJ (2009) Solubilization and characterization of the anthrax toxin pore in detergent micelles. Protein Sci 18(9):1882–1895
Wadsäter M, Simonsen JB, Lauridsen T, Tveten EG, Naur P, Bjørnholm T, Wacklin H, Mortensen K, Arleth L, Feidenhans’l R, Cárdenas M (2011) Aligning nanodiscs at the air–water interface, a neutron reflectivity study. Langmuir 27(24):15065–15073
Wynia-Smith SL, Brown MJ, Chirichella G, Kemalyan G, Krantz BA (2012) Electrostatic ratchet in the protective antigen channel promotes anthrax toxin translocation. J Biol Chem 287(52):43753–43764
Xu XP, Zhai D, Kim E, Swift M, Reed JC, Volkmann N, Hanein D (2013) Three-dimensional structure of Bax-mediated pores in membrane bilayers. Cell Death Dis 4:e683
Yang Z, Wang C, Zhou Q, An J, Hildebrandt E, Aleksandrov LA, Kappes JC, DeLucas LJ, Riordan JR, Urbatsch IL, Hunt JF, Brouillette CG (2014) Membrane protein stability can be compromised by detergent interactions with the extramembranous soluble domains. Protein Sci 23(6):769–789
Ye F, Hu G, Taylor D, Ratnikov B, Bobkov AA, McLean MA, Sligar SG, Taylor KA, Ginsberg MH (2010) Recreation of the terminal events in physiological integrin activation. J Cell Biol 188(1):157–173
Zhu PJ, Hobson JP, Southall N, Qiu C, Thomas CJ, Lu J, Inglese J, Zheng W, Leppla SH, Bugge TH, Austin CP, Liu S (2009) Quantitative high-throughput screening identifies inhibitors of anthrax-induced cell death. Bioorg Med Chem 17(14):5139–5145
Acknowledgments
This work was supported grant funds from National Institutes of Health (NIH) R56 R56AI090085 (MTF), NIH R01AI090085 (MTF), and NIH SR37AI022021 (RJC). Some initial cryo-EM results presented in Figs. 3 and 4 were collected at the National Center for Imaging Macromolecules, supported by NIH Grant NIGMS P41 GM103832 (Wah Chiu). Additionally, some of the recombinant proteins used in the study were prepared in the Biomolecule Production Core of the New England Regional Center of Excellence (NERCE), supported by NIH Grant Number AI057159.
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Akkaladevi, N., Mukherjee, S., Katayama, H. et al. Following Natures Lead: On the Construction of Membrane-Inserted Toxins in Lipid Bilayer Nanodiscs. J Membrane Biol 248, 595–607 (2015). https://doi.org/10.1007/s00232-014-9768-3
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DOI: https://doi.org/10.1007/s00232-014-9768-3