Design of Asymmetric Peptide Bilayer Membranes.

Energetic insights emerging from the structural characterization of peptide cross-β assemblies have enabled the design and construction of robust asymmetric bilayer peptide membranes. Two peptides differing only in their N-terminal residue, phosphotyrosine vs lysine, coassemble as stacks of antiparallel β-sheets with precisely patterned charged lattices stabilizing the bilayer leaflet interface. Either homogeneous or mixed leaflet composition is possible, and both create nanotubes with dense negative external and positive internal solvent exposed surfaces. Cross-seeding peptide solutions with a preassembled peptide nanotube seed leads to domains of different leaflet architecture within single nanotubes. Architectural control over these cross-β assemblies, both across the bilayer membrane and along the nanotube length, provides access to highly ordered asymmetric membranes for the further construction of functional mesoscale assemblies.

[1]  Allisandra K. Mowles,et al.  Defining the Dynamic Conformational Networks of Cross-β Peptide Assembly , 2015 .

[2]  D. Das,et al.  Cross-β Amyloid Nanohybrids Loaded With Cytochrome C Exhibit Superactivity in Organic Solvents. , 2015, Angewandte Chemie.

[3]  Jun Hu,et al.  Tunable assembly of amyloid-forming peptides into nanosheets as a retrovirus carrier , 2015, Proceedings of the National Academy of Sciences.

[4]  Rong Ni,et al.  Structural mimics of viruses through peptide/DNA co-assembly. , 2014, Journal of the American Chemical Society.

[5]  A. Mehta,et al.  Kinetic intermediates in amyloid assembly. , 2014, Journal of the American Chemical Society.

[6]  Anthony J. Bisignano,et al.  Neurofibrillar tangle surrogates: histone H1 binding to patterned phosphotyrosine peptide nanotubes. , 2014, Biochemistry.

[7]  G. Nicolson,et al.  The Fluid-Mosaic Model of Membrane Structure: still relevant to understanding the structure, function and dynamics of biological membranes after more than 40 years. , 2014, Biochimica et biophysica acta.

[8]  Neil R. Anthony,et al.  Mapping amyloid-β(16-22) nucleation pathways using fluorescence lifetime imaging microscopy. , 2014, Soft matter.

[9]  M. Zanni,et al.  How to Get Insight into Amyloid Structure and Formation from Infrared Spectroscopy , 2014, The journal of physical chemistry letters.

[10]  Martha A. Grover,et al.  Shape Selection and Multi-stability in Helical Ribbons , 2013, 1312.3571.

[11]  Alexander K. Buell,et al.  Electrostatic effects in filamentous protein aggregation. , 2013, Biophysical journal.

[12]  Kyle L. Morris,et al.  The Structure of Cross‐β Tapes and Tubes Formed by an Octapeptide, αSβ1† , 2013, Angewandte Chemie.

[13]  A. Ávila,et al.  Direct observation of the spatial distribution of charges on a polypropylene fiber via Electrostatic Force Microscopy , 2012, Journal of microscopy.

[14]  D. Yoon,et al.  Mapping the surface charge distribution of amyloid fibril , 2012 .

[15]  A. Mehta,et al.  Remodeling cross-β nanotube surfaces with peptide/lipid chimeras. , 2012, Angewandte Chemie.

[16]  Neil R. Anthony,et al.  Phase networks of cross-β peptide assemblies. , 2012, Langmuir : the ACS journal of surfaces and colloids.

[17]  D. Middleton,et al.  Fibrils and nanotubes assembled from a modified amyloid-β peptide fragment differ in the packing of the same β-sheet building blocks. , 2012, Chemical communications.

[18]  A. Mitraki,et al.  Electrostatic force microscopy of self-assembled peptide structures. , 2011, Scanning.

[19]  Christopher M Dobson,et al.  Perturbation of the stability of amyloid fibrils through alteration of electrostatic interactions. , 2011, Biophysical journal.

[20]  J. Trewhella,et al.  Effect of temperature during assembly on the structure and mechanical properties of peptide-based materials. , 2010, Biomacromolecules.

[21]  A. Mehta,et al.  Peptides organized as bilayer membranes. , 2010, Angewandte Chemie.

[22]  A. Ávila,et al.  Surface charge estimation on hemispherical dielectric samples from EFM force gradient measurements , 2010 .

[23]  R. Zhuo,et al.  Coassembly of oppositely charged short peptides into well-defined supramolecular hydrogels. , 2010, The journal of physical chemistry. B.

[24]  A. Mehta,et al.  Templating molecular arrays in amyloid's cross-beta grooves. , 2009, Journal of the American Chemical Society.

[25]  J. Snyder,et al.  Facial symmetry in protein self-assembly. , 2008, Journal of the American Chemical Society.

[26]  V. Conticello,et al.  Macroscale assembly of peptide nanotubes. , 2007, Chemical communications.

[27]  Ilpo Vattulainen,et al.  Lipid transmembrane asymmetry and intrinsic membrane potential: two sides of the same coin. , 2007, Journal of the American Chemical Society.

[28]  H. Stanley,et al.  Role of electrostatic interactions in amyloid beta-protein (A beta) oligomer formation: a discrete molecular dynamics study. , 2007, Biophysical journal.

[29]  Y. Tseng,et al.  Electrostatically controlled hydrogelation of oligopeptides and protein entrapment , 2005 .

[30]  D Thirumalai,et al.  Probing the initial stage of aggregation of the Abeta(10-35)-protein: assessing the propensity for peptide dimerization. , 2005, Journal of molecular biology.

[31]  S. Stupp,et al.  Coassembly of amphiphiles with opposite peptide polarities into nanofibers. , 2005, Journal of the American Chemical Society.

[32]  T. Ban,et al.  Critical balance of electrostatic and hydrophobic interactions is required for beta 2-microglobulin amyloid fibril growth and stability. , 2005, Biochemistry.

[33]  Krista L. Niece,et al.  Self-assembly combining two bioactive peptide-amphiphile molecules into nanofibers by electrostatic attraction. , 2003, Journal of the American Chemical Society.

[34]  V. Conticello,et al.  Exploiting amyloid fibril lamination for nanotube self-assembly. , 2003, Journal of the American Chemical Society.

[35]  T. Konno Amyloid-induced aggregation and precipitation of soluble proteins: an electrostatic contribution of the Alzheimer's beta(25-35) amyloid fibril. , 2001, Biochemistry.

[36]  R. Leapman,et al.  Amyloid Fibril Formation by Aβ16-22, a Seven-Residue Fragment of the Alzheimer's β-Amyloid Peptide, and Structural Characterization by Solid State NMR† , 2000 .

[37]  C. Blake,et al.  From the globular to the fibrous state: protein structure and structural conversion in amyloid formation , 1998, Quarterly Reviews of Biophysics.

[38]  J. Schaefer,et al.  REDOR dephasing by multiple spins in the presence of molecular motion. , 1997, Journal of magnetic resonance.

[39]  J. Schaefer,et al.  Solid-state NMR determination of intra- and intermolecular 31P-13C distances for shikimate 3-phosphate and [1-13C]glyphosate bound to enolpyruvylshikimate-3-phosphate synthase. , 1993, Biochemistry.

[40]  P E Fraser,et al.  Structure of beta-crystallite assemblies formed by Alzheimer beta-amyloid protein analogues: analysis by x-ray diffraction. , 1993, Biophysical journal.

[41]  H. Butt,et al.  Measuring electrostatic, van der Waals, and hydration forces in electrolyte solutions with an atomic force microscope. , 1991, Biophysical journal.

[42]  F. Richards,et al.  Relationship between nuclear magnetic resonance chemical shift and protein secondary structure. , 1991, Journal of molecular biology.

[43]  T. Gullion,et al.  New, compensated Carr-Purcell sequences , 1990 .

[44]  N. Nevskaya,et al.  Infrared spectra and resonance interaction of amide‐I vibration of the antiparallel‐chain pleated sheet , 1976, Biopolymers.

[45]  G. Glenner,et al.  X-RAY DIFFRACTION STUDIES ON AMYLOID FILAMENTS , 1968, The journal of histochemistry and cytochemistry : official journal of the Histochemistry Society.

[46]  E. Atkins,et al.  “Cross-β” conformation in proteins☆ , 1968 .

[47]  T. Miyazawa Perturbation Treatment of the Characteristic Vibrations of Polypeptide Chains in Various Configurations , 1960 .

[48]  K. M. Rudall,et al.  The Silk of the Egg-Stalk of the Green Lace-Wing Fly: Structure of the Silk of Chrysopa Egg-stalks , 1957, Nature.

[49]  K. Bailey,et al.  The X-ray interpretation of denaturation and the structure of the seed globulins. , 1935, The Biochemical journal.

[50]  B. Fung,et al.  An improved broadband decoupling sequence for liquid crystals and solids. , 2000, Journal of magnetic resonance.

[51]  K. Mueller,et al.  Simultaneous Multiple Distance Measurements in Peptides via Solid-State NMR , 1996 .

[52]  T. Gullion,et al.  Detection of Weak Heteronuclear Dipolar Coupling by Rotational-Echo Double-Resonance Nuclear Magnetic Resonance , 1989 .

[53]  T. Gullion,et al.  Rotational-Echo, Double-Resonance NMR , 1989 .

[54]  J. Bandekar,et al.  Vibrational spectroscopy and conformation of peptides, polypeptides, and proteins. , 1986, Advances in protein chemistry.