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Sub-20 nm Stable Micelles Based on a Mixture of Coiledcoils: A Platform for Controlled Ligand Presentation JooChuan Ang, Dan Ma, Benson Thomas Jung, Sinan Keten, and Ting Xu Biomacromolecules, Just Accepted Manuscript • DOI: 10.1021/acs.biomac.7b00917 • Publication Date (Web): 17 Aug 2017 Downloaded from http://pubs.acs.org on August 19, 2017
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Biomacromolecules
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Sub-20 nm Stable Micelles Based on a Mixture of Coiled-coils: A Platform for
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Controlled Ligand Presentation
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JooChuan Ang1, Dan Ma2, Benson T. Jung1, Sinan Keten2, Ting Xu*1,3,4
4 5
1
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California 94720, United States
7
2
8
Engineering, Northwestern University, Evanston, Illinois 60208, United States
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3
Department of Chemistry, University of California, Berkeley, California 94720, United States
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Material Science Division, Lawrence Berkeley National Laboratory, Berkeley, California 94720,
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United States
Department of Materials Science and Engineering, University of California, Berkeley,
Department of Civil and Environmental Engineering and Department of Mechanical
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Abstract
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Ligand-functionalized, multivalent nanoparticles have been extensively studied for
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biomedical applications from imaging agents to drug delivery vehicles. However, the ligand
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cluster size is usually heterogeneous and the local valency is ill-defined. Here, we present a
5
mixed micelle platform hierarchically self-assembled from a mixture of two amphiphilic 3-helix
6
and 4-helix peptide-PEG-lipid hybrid conjugates. We demonstrate that the local multivalent
7
ligand cluster size on the micelle surface can be controlled based on the coiled-coil oligomeric
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state. The oligomeric states of mixed peptide bundles were found to be in their individual native
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states. Similarly, mixed micelles indicate the orthogonal self-association of coiled-coil
10
amphiphiles. Using differential scanning calorimetry, fluorescence recovery spectroscopy, and
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coarse-grained molecular dynamics simulation, we studied the distribution of coiled-coil bundles
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within the mixed micelles and observed migration of coiled-coils into nanodomains within the
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sub-20 nm mixed micelle. This report provides important insights into the assembly and
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formation of nanophase-separated micelles with precise control over the local multivalent state
15
of ligands on the micelle surface.
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Biomacromolecules
Introduction
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Nanocarriers can exploit characteristics of tumor growth, such as leaky vasculature and
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poor lymphatic drainage, for passive targeting via the enhanced permeation and retention (EPR)
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effect1, 2. In addition to the EPR effect, nanocarriers can also be actively targeted to up-regulated
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cellular receptors or components present on tumor cells by incorporating surface grafted
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recognition moieties, such as sugar moieties3, epidermal growth factor4, folate5, 6, antibodies7 and
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peptides8, 9, to improve the efficacy of treatment and minimize side effects. Active targeting is of
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particular importance since many drug carriers encounter difficulties in accessing cancer cells
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deep in the tumor tissues and to interact with target cells after accumulation10. A wide variety of
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nanocarriers can be readily prepared, including liposomes11-13, dendrimers14, 15, micelles16, 17, and
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virus-like particles18, 19 and targeting ligands can be conjugated to the nanocarrier surface20.
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Moreover, multiple copies of ligands on the nanocarrier surface can be a viable route to improve
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the targeting efficiency of nanocarriers; biological multivalent inhibitors can increase binding
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avidity by 10–109 fold21-24. Experimentally, a 30 nm nanoparticle with four RGD peptides
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showed 25-fold enhancement in endothelial cell binding25. Three folate groups led to 2,500-fold
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enhancement in dendrimers binding to a surface26. There has been a concerted effort to develop
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peptide-based nanomaterials towards higher complexity and enhanced structural control27, 28.
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However, in contrast to well-regulated structural control seen in viruses21, there is limited
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structural control in existing nanocarriers over the spatial distribution of ligands and the
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orientation of ligand relative to the particle surface, which determines the availability of ligand
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binding sites. To this end, we have developed a new class of 3-helix micelle (3HM) nanocarrier
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based on amphiphilic coiled-coil peptide-polymer-lipid conjugates29-35 that has the potential to
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exert control over the local multivalency of presented ligand clusters.
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3HM has many desirable attributes as an effective drug delivery nanocarrier such as long
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circulation, deep tumor penetration, minimal cargo leakage in serum, and renal clearance30-32, 34.
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We have previously described the hierarchical self-assembly pathway of 3-helix bundle
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amphiphiles at the air-water interface36 as well as the kinetic pathway of 3HM formation in
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solution37. 3HM is based on a common coiled-coil protein tertiary structure that is routinely used
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to present ligand clusters on cell surfaces38-40. Coiled-coil self-assembly has high fidelity and
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orthogonal coiled-coil sequences41 have been conjugated and used to assemble higher ordered
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nanostructures such as protein-like nanoparticles42 and nanocages43, 44. Mixed micelles generated
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from two or more building blocks have been used to tune stability and drug loading capacity of
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conventional polymeric micelles for drug delivery45. This approach also allows for the
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incorporation of multiple functionalities, including ligand targeting, into our system. The use of
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mixed micelles based on coiled-coil peptides would allow the generation of ligand clusters with
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well-defined local multivalency determined by the oligomeric state of the coiled-coils within the
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mixed micelle. This approach also opens new possibilities to generate multi-compartment
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micelles with the two coiled-coil building blocks possessing different functionalities.
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The generation of micron-sized inorganic multi-compartment, Janus, or patchy particles
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has been well studied and optimized, whereas development of sub-100 nm patchy particles have
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been more challenging46. Patchy particles have been generated from linear dendritic polymers47,
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48
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roughness57, layer-by-layer deposition58, self-assembled monolayers59-61, host-guest binding62,
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metal coordination63, and polymer grafting64 to produce the patches. However, none of these
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approaches allow control over the precise ligand cluster size, or local multivalency on the surface
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of the nanoparticles. Ligand clustering with controlled cluster size observed in viruses is vital to
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improve binding selectivity and accuracy, and yet, has not been systematically investigated due
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to the lack of a platform that can regulate the clustering of ligands.
, di- and tri-block copolymers49-55, polymersomes56, and other systems that exploit surface
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In this contribution, we present a micellar platform that utilizes hierarchical self-assembly
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of amphiphilic coiled-coil peptide-PEG-lipid hybrid conjugates to control the local multivalency
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of ligands on the micelle surface based on the coiled-coil oligomeric state. A mixture of 3-helix
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and 4-helix peptide bundles was shown to retain their individual native oligomeric states. Mixed
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micelles with excellent stability in the presence of bovine serum albumin can be generated from
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mixtures of 3-helix and 4-helix amphiphilic peptide-PEG-lipid conjugates at various ratios. At
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various ratios, mixed micelles showed similar stability compared to the individual micelles. At a
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1:1 mixing ratio of 3HM:4HM, the thermal transition associated with alkyl chain packing within
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the hydrophobic core of the mixed micelle was found to re-distribute from a single homogeneous
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transition for an annealed sample to two distinct transitions indicating the formation of distinct
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domains as it was cooled down to room temperature. Fluorescence self-quenching and recovery
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experiments further affirmed the formation of nanodomains within the mixed micelles. Coarse-
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grained MD simulations illustrated the self-organization of separate phases consisting of helix
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peptide bundles with different oligomerization states. This study provides valuable insight into
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the self-assembly of orthogonal coiled-coil peptide-PEG-lipid conjugate amphiphiles into patchy
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micelles and guidance to develop biomaterials with controlled local multivalency for ligand
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cluster presentation.
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Experimental methods
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Synthesis of amphiphilic peptide-polymer conjugates and fluorescein-labeled peptide-polymer
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conjugates
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Synthesis of amphiphilic peptide-polymer conjugates using solid-phase peptide synthesis based
11
on standard Fmoc-chemistry has been previously described in detail29, 32, 33. Briefly, the two
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peptides
13
(EVEALEKKVAALECKVQALEKKVEALEHGW)
14
(GGGEIWKLHEEFLCKFEELLKLHEERLKKL). PAL-PEG-PS resin (0.17 mmol/g loading,
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ThermoFisher Scientific) was used to conduct solid-phase synthesis of the peptides on a Prelude
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peptide synthesizer (Protein Technologies). The N-termini of the peptides are modified with a
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short C6 alkyl linker, Fmoc-6-aminohexanoic acid, followed by a lysine residue. This allowed
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for conjugation of two palmitic acid molecules to the N-terminus. Both peptides contain a
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cysteine residue at position 14 to facilitate conjugation of a maleimide-PEG chain (MW 2000,
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Rapp Polymere) to the exterior of the coiled-coil bundles. Fluorescein was attached to the C-
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terminus of the 3-helix peptide by selective deprotection of alloc-protected lysine followed by
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coupling the amine with 5(6)-carboxy-fluorescein. Specifically, 0.2 eq. of Pd(PPh3)4 was used as
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a catalyst with 24 eq. of phenylsilane as an allyl trapper in dichloromethane. The reaction was
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carried out for 30 mins each, repeated 5 times.
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The conjugates were purified by RP-HPLC (Beckman Coulter) using a C-4 column (Vydac,
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Phenomenex). Separation of the conjugates was facilitated by using a linear AB gradient where
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solvent A is water plus 0.1% (v/v) TFA and solvent B is acetonitrile plus 0.1% (v/v) TFA.
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Elution of the conjugate was ~85% B. Purification of the FAM-labeled conjugate was achieved
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using solvent B as isopropanol plus 0.1% (v/v) TFA and the purified product eluted ~90% B.
studied
here
are
based
on
a
3-helix and
coiled-coil a
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4-helix
peptide coiled-coil
sequence65 peptide66
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The masses of the purified conjugates were verified by MALDI-TOF mass spectrometry (SI
2
Figure 1).
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Size-exclusion chromatography (SEC)
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The sizes of 3-helix peptide, 4-helix peptide, and a 1:1 mixture of the two peptides were studied
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using SEC (Agilent instruments) on a BioSep-SEC-S4000 column (Phenomenex) at a
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concentration of ~100 µM. Elution was carried out using a flowrate of 1 mL/min with phosphate
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buffer (pH 7.4, 25 mM) for 15 minutes. The elution profiles were monitored with a UV-Vis
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detector at wavelengths of 220 nm and 280 nm.
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UV-vis heme titration
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Titration experiments were performed with 1 mL of ~8 µM solutions of 4-helix peptide or 4HM
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dissolved in phosphate buffer (25 mM, pH 7.4) in the presence of excess 3-helix peptide or 3HM,
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respectively. Spectra from 250–600 nm were recorded on a Hewlett-Packard 8453
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spectrophotometer using a 1 cm pathlength quartz cuvette after addition of each 2 µL aliquot of a
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~800 µM stock hemin solution in DMSO.
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Fluorescence self-quenching and recovery
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Fluorescence spectroscopy was performed using a LS-55 fluorescence spectrometer (Perkin
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Elmer). Briefly, 200 µM of fluorescein-labeled 3HM (donor) and 400 µM of unlabeled 4HM
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(acceptor) were independently annealed at 70°C for 45 min then allowed to cool to room
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temperature before mixing for self-quenching experiments. Annealing conditions were selected
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based on previous studies36, 37. The two solutions were then mixed in a 2:1 (donor:acceptor)
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volume ratio at a total volume of 400 µL, giving a donor:acceptor molar ratio of 1:1. The sample
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was loaded into a 1 mm by 10 mm quartz cell (Starna Cells). Temporal evolution of fluorescence
23
intensity at 520 nm was recorded every 30 seconds using an excitation wavelength of 450 nm.
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Self-quenching and recovery experiments were conducted with the sample cell maintained at
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25°C for 22 hrs, increased to 70°C for 2 hrs, and finally decreased to 25°C for a further 20 hrs.
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The fluorescence intensity at various stages of heating and cooling were normalized to the initial
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fluorescence intensity at time zero.
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Forster Resonance Energy Transfer (FRET)
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A pair of lipophilic FRET pair, 3,3′-dioctadecyloxacarbocyanine perchlorate (DiO, donor) and
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1,1′-dioctadecyl-3,3,3′,3′-tetramethylindocarbocyanine perchlorate (DiI, acceptor), was dissolved
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in methanol (1 wt%) along with various 3HM:4HM ratios. The methanol was evaporated under
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vacuum at 60°C for 3 hrs to form a thin film in a glass vial. Phosphate buffer was added to
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rehydrate the film at a concentration of 1 mg/ml. The solutions were annealed at 70°C for 45
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mins then allowed to equilibrate over 16 hrs at room temperature and spin dialyzed using a 3K
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MWCO filter (Amicon Ultra-4, Millipore) to remove any un-encapsulated free dye in solution.
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The samples were incubated with BSA (20 mg/mL) at 37°C and time-resolved fluorescence
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emission intensity was monitored every 15 mins from 475–650 nm for 24 hrs using an excitation
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wavelength of 450 nm.
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Differential scanning calorimetry (DSC)
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DSC thermograms probing the alkyl core thermal transitions were obtained using a VP-Microcal
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calorimeter (GE). ~550 uL of sample and buffer solutions were degassed for 10 mins before
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being loaded into two hermetically sealed tantalum cells at a pressure of ~28 psi. The
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temperature was increased from 5°C to 60°C at a scanrate of 1 °C/min with 15-minute
16
equilibration at 5°C. Baseline correction and concentration normalization were performed using
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the Origin software provided by Microcal.
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Coarse-grained molecular dynamics (CGMD) simulation
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The molecular dynamics simulations presented in this work were coarse-grained (CG)
20
simulations based on the dissipative particle dynamics (DPD) technique. Considering that the
21
length and time-scale limitations of all-atomistic simulations prohibit comprehensive evaluation
22
of micelle formation, we chose to utilize a DPD67, 68 CG simulation methodology for micelle
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formation simulations. DPD is a Lagrangian thermostat technique that enables fast CG
24
simulations by employing hydrodynamics interactions to describe phase separation in materials.
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This method has been widely used in studying the behavior of lipid membranes, block
26
copolymers, and a broad range of complex fluids 69-71.
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The DPD model presented here adopted the lipid model developed by Groot and Rabone72, PEG
28
model developed by Ying71, and the peptides are modeled based on our previous publications35,
29
73
. This approach has been previously utilized to efficiently study 3HM self-assembly and
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35, 73
1
resulted in predictions that agree well with experimental data
. All CG simulations in this
2
work were performed using a variation of the DPD approach using the open source MD
3
simulation package LAMMPS74. A DPD thermostat procedure adopting an NVT ensemble with
4
a constant temperature 300 K was adopted for simulations, and periodic boundary conditions
5
were applied in three dimensions. Here the time scale is 𝜏 = 24.32 𝑝𝑠, length scale is 𝑅! =
6
0.8 𝑛𝑚. 69, 71 Each simulated system consists of 100 randomly distributed amphiphilic molecules
7
(with 3-helix and 4-helix components at a 1:1 ratio), and then solvated in explicit DPD water
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beads. All CG simulations were carried out for approximately 1.8 − 2.5 𝜇𝑠, and tend to reach
9
equilibrium before 800 ns. The equilibration of the simulations was assured by checking that the
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average micelle aggregation number was stable to ±3 in 200 ns. The last 150 ns of the
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equilibrated simulations were chosen for data analysis.
12 13
Results and discussion
14
A mixture of 3-helix and 4-helix peptides showed retention of their individual oligomeric
15
states as shown in Figure 1. Figure 1a shows that the SEC trace of a 1:1 mixture of 3-helix:4-
16
helix peptide (black) can be deconvoluted into two distinct peaks corresponding to the individual
17
3-helix and 4-helix peptides (blue and red, respectively). This is the first indication that mixture
18
of the peptides does not result in cross-oligomerization since they retain their original bundle
19
sizes. Next, Figure 1b shows the absorption at 412 nm due to binding of heme to the bis-histidyl
20
ligation pockets of the 4-helix peptide75-77. The ratio at which the slope of the data changes
21
corresponds to the number of heme molecules bound to each 4-helix bundle. 4-helix peptide in
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presence of 5% 3-helix peptide (red) indicates ~3.8 hemes bound per 4-helix bundle, close to the
23
native state (in the absence of 3-helix peptides, shown in black) binding capacity of 4 heme
24
molecules per 4-helix bundle. Retention of the heme-binding pocket of the 4-helix peptide
25
suggests minimal perturbation of the 4-helix bundle oligomeric state in the presence of 3-helix
26
peptides. Absence of an inflection point when there is no 4-helix peptide available for heme to
27
bind is shown in blue. Figure 1c shows the fluorescence intensity change as a function of
28
unlabeled 4-helix peptide mixed with FAM-labeled 3-helix peptide. Minimal increase in the
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fluorescence intensity of FAM-labeled 3-helix peptide when mixed with 4-helix peptide at
30
various mixing fractions (red trace) indicates that there is a lack of cross-oligomerization
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between the two coiled-coil peptides. Furthermore, the similar behavior of the mixtures even in
2
the presence of thermal annealing (black trace) does not promote cross-oligomerization. This
3
further suggests that the self-assembly of the two peptides are orthogonal and there is an absence
4
of cross-oligomerization when the two peptides are mixed.
5
6 7
Figure 1: Mixtures of 3-helix and 4-helix peptides. (a) SEC traces of 4-helix peptide (blue), 3-
8
helix peptide (red), and a 1:1 mixture of 3-helix and 4-helix peptides (black) measured at 280 nm.
9
(b) UV titration of heme bound to 4-helix peptide bundles in the absence of 4-helix peptide
10
(purple), 5% 4-helix peptide (red), and 100% 4-helix peptide (black). (c) Fluorescence recovery
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of various ratios of 3-helix to 4-helix mixtures. Freshly prepared mixtures and annealed samples
12
show no significant difference in fluorescence intensity.
13 14
We seek to understand the oligomeric state of the coiled-coil bundles upon conjugation of
15
alkyl tails and self-assembled into micelles. 3-helix peptide-polymer-lipid conjugate amphiphiles
16
have previously been observed to retain its native trimeric state at the air-water interface36.
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Varying ratios of 3-helix and 4-helix peptide amphiphiles were found to form 15-20 nm particles
2
in aqueous solution by DLS (SI Figure 2). Since amphiphiles of both 3-helix and 4-helix peptides
3
form micelles of similar sizes, SEC is not a viable method to study the individual oligomeric
4
states of the peptides within mixed micelles. However, cofactor binding of heme to the coiled-
5
coil bundle headgroup of 4-helix amphiphiles, as elucidated for the peptide mixtures in Figure 1b,
6
allows probing of the oligomeric state when mixed micelles are formed in the presence of 3-helix
7
amphiphiles. Figure 2a shows the UV-vis heme titration into an aqueous solution of ~8 µM 4HM.
8
Incorporation of heme into the hydrophobic pocket of the 4-helix peptide is evident from the
9
increase in the Soret peak at 412 nm and the poorly resolved Qα and Qβ bands at 560 and 529 nm,
10
respectively75, 78, 79. As more heme is added, the absorption maxima experienced a blue shift, due
11
to the absorbance of free heme in solution. Figure 2b plots the absorbance at 412 nm as a
12
function of heme per 4-helix amphiphile. In the absence of 3HM, the tertiary structure of 4-helix
13
bundle within 4HM (black) retained native-like heme binding capability75, indicating that there is
14
no substantial deleterious effects of di-alkyl conjugation to the N-terminus and PEGylation of the
15
coiled-coil exterior. More importantly, in the presence of excess 3-helix amphiphiles (red), the
16
number of heme molecules bound to the 4-helix amphiphiles was not compromised indicating
17
that the tertiary structure is likely to be preserved. Once again, no change in slope was observed
18
for a solution of 3HM in the absence of 4HM for heme binding (blue). The orthogonality and
19
peptide native oligomeric states were preserved when the peptides were conjugated with two
20
hexadecanoic acid tails at the peptide N-terminus and the resulting amphiphiles mixed.
21
22
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Figure 2: (a) UV-vis spectra of heme titrated into a ~8 µM solution of 4HM upon addition of 0,
2
0.4, 1.2, 2, 3, 4, 4.8, 6, 7.2, and 8 eq. of heme per 4-helix bundle. The vertical black line indicates
3
the peak at 412 nm which corresponds to the absorbance of heme within the hydrophobic interior
4
of the 4-helix bundle. (b) Absorbance at 412 nm monitored as a function of heme molecules per
5
4-helix bundle ratio for pure 4HM (black), pure 3HM (blue), and at 4HM:3HM ratio of 5:95
6
(red). The ratio at which the slope changes indicates the number of heme molecules bound to
7
each 4-helix bundle.
8 9
To assess if mixed micelles were created and to quantify their stability80-82, the change in
10
emission of an encapsulated FRET pair at various 3HM:4HM ratios was measured in the
11
presence of bovine serum albumin (BSA). When both FRET molecules are encapsulated within
12
the same micelle, appropriate excitation of the donor molecule can lead to energy transfer to the
13
acceptor molecule due to the close proximity between the two molecules. As a result, excitation
14
at 450 nm (donor excitation) leads to a strong emission at 565 nm (acceptor emission). If the
15
mixed micelles dissemble, the encapsulated FRET molecules are released and diffuse apart,
16
eliminating the energy transfer. As such, a shift from 565 to 505 nm would be observed. Figure
17
3a shows the change in normalized FRET ratio over a 24-hour period. All micelles created from
18
various 3HM:4HM ratios displayed good stability over the time period studied with FRET ratios
19
above 0.9. Two formulations in particular, 3HM:4HM ratios of 50:50 and 0:100, displayed
20
higher stability than the remaining of the micellar ratios with FRET ratios maintained ~ 0.99
21
over 24 hrs. The good stability presumably stems from the unique architecture of the coiled-coil
22
peptide-polymer headgroup that can direct polymer entropic repulsion between subunits of the
23
micelle29. To further illustrate the high kinetic stability of 3HM and 4HM, the FRET pair, DiO
24
and DiI, was independently encapsulated within each of 3HM and 4HM and mixed in equal
25
molar ratios at room temperature as shown in Figure 3b. The emission spectra over 16 hrs
26
essentially remained constant, indicating no cargo leakage and slow subunit kinetic exchange of
27
the two micellar populations. The high kinetic stability of micellar formulations at various
28
3HM:4HM ratios indicates that they do not undergo significant disassembly in the presence of
29
serum albumin. The stability of the mixed micelles demonstrated in the presence of BSA
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suggests that these mixed micelles may be compatible in vivo, which is critical for intravenous
2
drug delivery applications.
3 4
Figure 3: (a) Plot of normalized FRET ratio as a function of time for mixed micelles at various
5
ratios of 3HM:4HM. (b) Time-resolved fluorescence showing a 1:1 mixture of 3HM and 4HM,
6
each independently encapsulated with DiO and DiI, respectively.
7 8
Since the 50:50 ratio of 3HM:4HM showed higher stability than mixed micelles
9
composed of other ratios, it was further investigated. Initially, to probe the distribution of the two
10
coiled-coil amphiphiles within the mixed micelle, micelles composed of the individual
11
components – pristine 3HM and pristine 4HM were studied. Figure 4a shows DSC
12
measurements of the individual pristine micelles having very distinct phase transition
13
temperatures at 17°C and 40°C for 3HM and 4HM, respectively. Two separate micelle solutions
14
of 3HM and 4HM mixed in a 1:1 ratio displayed two prominent transitions at 17°C and 40°C,
15
indicative of discrete 3HM and 4HM populations in solution. However, a single homogeneous
16
transition ~ 21°C is apparent in Figure 4b upon thermal annealing of this mixture and subjected
17
to immediate DSC measurement (t = 0 hr). As the 1:1 mixture was allowed to equilibrate at room
18
temperature after thermal treatment, a separate transition at a higher temperature of ~33°C
19
appears and the enthalpy associated with the 33°C transition continued to increase from 1 hr to
20
16 hrs while the transition at 20°C decreased in enthalpy over the same time period. This
21
suggests that returning the thermally treated mixed micelles that are phase-mixed back to
22
ambient temperature led to the formation of distinct 3-helix and 4-helix domains within the
23
mixed micelles over the span of several to tens of hours.
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Figure 4: DSC measurements of (a) pristine 3HM, 4HM, and 1:1 mixture of separately prepared
3
3HM and 4HM, (b) time evolution of 1:1 ratio of 3HM:4HM mixed micelle at times 0, 1, 16, 26,
4
and 40 hrs after thermal annealing. Solid red lines are fits to the data while dotted red lines
5
indicate the deconvoluted peaks.
6 7
Table 1: Phase transition temperatures and enthalpy for the corresponding data in Figure 4. Sample
Tm (°C)
ΔH (kJ/mol)
Total ΔH (kJ/mol)
3HM
17
25.1 ± 0.1
25.1 ± 0.1
4HM
40
33.5 ± 0.2
33.5 ± 0.2
1:1 t = 0hr
21
11.5 ± 0.04
11.5 ± 0.04
20
7.84 ± 0.06
33
1.28 ± 0.05
17
1.85 ± 0.02
33
7.35 ± 0.02
20
1.56 ± 0.02
37
7.60 ± 0.02
1:1 t = 1hr
1:1 t = 16hr
1:1 t = 40hr 8
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9.12 ± 0.11
9.20 ± 0.04
9.11 ± 0.06
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1
To further examine the phase separation behavior of nanodomains within the 1:1 ratio of
2
3-helix and 4-helix mixed micelles, the formation process of mixed micelles from 3HM and
3
4HM was studied using fluorescence self-quenching and recovery. Figure 5a shows the
4
fluorescence spectra of unlabeled 4HM added to a solution of FAM-labeled 3HM in a 1:1
5
mixture as a function of time at three temperatures – 25°C (red), heated to 70°C (black), then
6
cooled down to 25°C (blue). Figure 5b plots the normalized fluorescence intensity as a function
7
of time and the data at the three temperatures are in the same color scheme as Figure 5a. The
8
mixture of two separate micellar populations of 3HM and 4HM at the initial temperature of 25°C
9
experienced a slight ~3% increase in fluorescence intensity over a period of 22 hrs. This modest
10
increase in fluorescence is due to the excellent kinetic stability of 3HM and 4HM with minimal
11
subunit exchange between the two micelle populations33. However, when the temperature of the
12
mixture was raised to 70°C, the fluorescence intensity greatly increased by 58% in 2 hrs. This
13
large increase in fluorescence intensity is due to subunit exchange as the FAM-labeled 3-helix
14
amphiphiles are desorbed from the self-quenched 3HM-FAM and inserted into non-labeled 4HM.
15
As the sample cell was cooled back down to 25°C, the fluorescence intensity decreased 10%
16
over ~10 hrs. The FAM-labeled 3-helix amphiphiles reorganized themselves closer to each other,
17
thereby self-quenching the fluorescence and resulting in a decrease in fluorescence intensity.
18
This sequence of results show that 3HM and 4HM are kinetically stable at room temperature and
19
minimal subunit exchange occurs in the presence of the other micellar species. Addition of
20
thermal energy promotes the rapid exchange of amphiphiles between 3HM and 4HM, blending
21
to form mixed micelles. However, cooling down to ambient temperature resulted in spatial
22
rearrangement of the 3-helix and 4-helix amphiphiles within the mixed micelles to form 3-helix
23
rich and 4-helix rich nanodomains within the same micelle.
24
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Figure 5: (a) Fluorescence spectra of 3HM-FAM mixed with 4HM at a 1:1 ratio as a function of
3
temperature. (b) Normalized fluorescence intensity at 520 nm plotted as a function of incubation
4
time at the different temperatures. Data points for 25°C, 70°C, and 25°C (post-heating) in red,
5
black, and blue, respectively.
6 7
To further augment our experimental results, CGMD simulations provided insight into the
8
arrangement of the peptides within the mixed micelles. Figure 6 maps the spatial distribution of
9
the 3-helix and 4-helix peptide headgroups and corresponding alkyl tails in spherical coordinates
10
in a single micelle. Clustering of 3-helix and 4-helix head groups is observed at equilibrium after
11
self-assembly. This supports our heme titration and SEC results (Figure 1), indicating an absence
12
of cross-oligomerization between the 3-helix and 4-helix amphiphiles upon assembly.
13
Additionally, simulation supports the experimental observation of intra-micellar nanophase
14
separation of 3-helix and 4 –helix amphiphiles from DSC and fluorescence recovery results.
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Figure 6: Coarse-grained molecular dynamics simulation of 3HM mixed with 4HM at a 1:1 ratio.
3
Packing plots of (a) headgroup and (b) alkyl chains in the mixed micelle. Schematic on the left
4
illustrates the spherical coordinates used.
5 6
The results shown here strongly suggest that the lack of cross-oligomerization between two
7
orthogonal 3-helix and 4-helix coiled-coil bundles, even when modified with di-alkyl chains and
8
PEG, can be an effective platform to specify the local multivalency of ligand clusters. Highly
9
stable sub-20 nm mixed micelles can be generated from a pair of orthogonal coiled-coil peptide-
10
PEG-lipid conjugates. Furthermore, the 3-helix and 4-helix amphiphiles were observed to phase
11
segregate within the mixed micelles, forming ‘patches’ of 3-helix and 4-helix rich domains.
12
Further work is needed to quantify the spatial distribution and domain size of 3-helix and 4-helix
13
regions within the mixed micelles. The phase separation is likely driven by incompatible
14
geometric packing of the coiled-coil headgroups in the micelle corona and alkyl tails in the
15
hydrophobic core. 4-helix amphiphiles have a higher density of alkyl chains attached to each
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1
bundle compared to 3-helix amphiphiles. The mismatch in alkyl chain length could cause phase
2
separation in mixed micelles. The domain size of nanodomains of lipids, also known as lipid
3
rafts, in membranes is directly correlated to the mismatch in degree of alkyl unsaturation and
4
subsequently bilayer thickness83,
5
minimization between 3-helix and 4-helix amphiphiles contributes to the phase separation
6
phenomenon described here. This study is an important first step to elucidate the properties of
7
these new hybrid self-assembled mixed micellar structures, and to allow their optimization
8
regarding different fields of application, in particular the design of drug delivery nanocarriers
9
with targeting capability using clustered ligands with well-defined oligomeric states using either
10
the 3-helix or 4-helix domain.
11
Conclusion
84
. We hypothesize a similar effect of interfacial energy
12
In this report, we show the retention of coiled-coil bundle oligomeric states and the
13
orthogonality of 3-helix and 4-helix peptide-PEG-lipid amphiphiles in mixed micelles with
14
potential utility for control over the local multivalency of ligands. Additionally, the mixed
15
micelles displayed high stability in serum albumin, which is crucial for intravenous drug delivery
16
applications. Temporal evolution of alkyl packing and tracking the relative distribution of FAM-
17
tagged 3-helix amphiphiles within mixed micelles indicated partitioning of 3-helix and 4-helix
18
rich domains to form self-assembled sub-20 nm patchy micelles. The proposed approach
19
described here for generating mixed micelles with well-defined ligand cluster sizes is extremely
20
versatile due to the ability to engineer a variety of coiled-coils with different oligomeric states.
21
Coiled-coil based peptide-PEG-lipid conjugates are a promising class of materials to specify the
22
oligomeric state of ligands on surfaces for a wide range of diagnostic and therapeutic
23
applications.
24 25
ASSOCIATED CONTENT
26
Supporting Information.
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1
MALDI-TOF, DLS, and time-resolved fluorescence spectroscopy of mixed micelles are
2
provided. This material is available free of charge via the Internet at http://pubs.acs.org.
3
AUTHOR INFORMATION
4
Corresponding Author
5
*
[email protected] 6
Author Contributions
7
The manuscript was written through contributions of all authors. All authors have given approval
8
to the final version of the manuscript.
9
Notes
Page 18 of 24
10
The authors declare no competing financial interest.
11
ACKNOWLEDGMENT
12
This study was supported by National Institutes of Health (Contract 5R21EB016947-02). Prof.
13
Xu is a core-principal investigator of Tsinghua-Berkeley Shenzhen Institute (TBSI). We
14
acknowledge the funding support of TBSI. B.T.J was supported by a NSF Graduate Fellowship
15
(DGE 1106400).
16
References
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Sub-20 nm Stable Micelles Based on a Mixture of Coiled-coils: A Platform for
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JooChuan Ang1, Dan Ma2, Benson T. Jung1, Sinan Keten2, Ting Xu*1,3,4
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California 94720, United States
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Engineering, Northwestern University, Evanston, Illinois 60208, United States
Department of Materials Science and Engineering, University of California, Berkeley,
Department of Civil and Environmental Engineering and Department of Mechanical
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Department of Chemistry, University of California, Berkeley, California 94720, United States
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Material Science Division, Lawrence Berkeley National Laboratory, Berkeley, California 94720,
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United States
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