Co-reporter:Handan Acar, Ravand Samaeekia, Mathew R. Schnorenberg, Dibyendu K. Sasmal, Jun Huang, Matthew V. Tirrell, and James L. LaBelle
Bioconjugate Chemistry September 20, 2017 Volume 28(Issue 9) pp:2316-2316
Publication Date(Web):August 3, 2017
DOI:10.1021/acs.bioconjchem.7b00364
Peptides synthesized in the likeness of their native interaction domain(s) are natural choices to target protein–protein interactions (PPIs) due to their fidelity of orthostatic contact points between binding partners. Despite therapeutic promise, intracellular delivery of biofunctional peptides at concentrations necessary for efficacy remains a formidable challenge. Peptide amphiphiles (PAs) provide a facile method of intracellular delivery and stabilization of bioactive peptides. PAs consisting of biofunctional peptide headgroups linked to hydrophobic alkyl lipid-like tails prevent peptide hydrolysis and proteolysis in circulation, and PA monomers are internalized via endocytosis. However, endocytotic sequestration and steric hindrance from the lipid tail are two major mechanisms that limit PA efficacy to target intracellular PPIs. To address these problems, we have constructed a PA platform consisting of cathepsin-B cleavable PAs in which a selective p53-based inhibitory peptide is cleaved from its lipid tail within endosomes, allowing for intracellular peptide accumulation and extracellular recycling of the lipid moiety. We monitor for cleavage and follow individual PA components in real time using a Förster resonance energy transfer (FRET)-based tracking system. Using this platform, we provide a better understanding and quantification of cellular internalization, trafficking, and endosomal cleavage of PAs and of the ultimate fates of each component.
Co-reporter:Nicholas E. Jackson, Blair K. BrettmannVenkatram Vishwanath, Matthew Tirrell, Juan J. de Pablo
ACS Macro Letters February 21, 2017 Volume 6(Issue 2) pp:
Publication Date(Web):February 3, 2017
DOI:10.1021/acsmacrolett.6b00837
Coarse-grained molecular dynamics enhanced by free-energy sampling methods is used to examine the roles of solvophobicity and multivalent salts on polyelectrolyte brush collapse. Specifically, we demonstrate that while ostensibly similar, solvophobic collapsed brushes and multivalent-ion collapsed brushes exhibit distinct mechanistic and structural features. Notably, multivalent-induced heterogeneous brush collapse is observed under good solvent polymer backbone conditions, demonstrating that the mechanism of multivalent collapse is not contingent upon a solvophobic backbone. Umbrella sampling of the potential of mean-force (PMF) between two individual brush strands confirms this analysis, revealing starkly different PMFs under solvophobic and multivalent conditions, suggesting the role of multivalent “bridging” as the discriminating feature in trivalent collapse. Structurally, multivalent ions show a propensity for nucleating order within collapsed brushes, whereas poor-solvent collapsed brushes are more disordered; this difference is traced to the existence of a metastable PMF minimum for poor solvent conditions, and a global PMF minimum for trivalent systems, under experimentally relevant conditions.
Co-reporter:Blair BrettmannPhilip Pincus, Matthew Tirrell
Macromolecules February 14, 2017 Volume 50(Issue 3) pp:
Publication Date(Web):January 13, 2017
DOI:10.1021/acs.macromol.6b02563
We provide a theoretical model for the collapse of polyelectrolyte brushes in the presence of multivalent ions, focusing on the formation of lateral inhomogeneties in the collapsed state. Polyelectrolyte brushes are important in a variety of applications, including stabilizing colloidal particles and lubricating surfaces. Many uses rely on the extension of the densely grafted polymer chains from the surface in the extended brush morphology. In the presence of multivalent ions, brushes are significantly shorter than in monovalent ionic solutions, which greatly affects their properties. We base our theoretical analysis on an analogous collapse of polyelectrolyte brushes in a poor solvent, providing an energy balance representation for pinned micelles and cylindrical bundles. The equilibrium brush heights predicted for these structures are of a similar magnitude to those measured experimentally. The formation of lateral structures can open new avenues for stimuli-responsive applications that rely on nanoscale pattern formation on surfaces.
Co-reporter:John C. Barrett, Bret D. Ulery, Amanda Trent, Simon Liang, Natalie A. David, and Matthew V. Tirrell
ACS Biomaterials Science & Engineering 2017 Volume 3(Issue 2) pp:
Publication Date(Web):September 28, 2016
DOI:10.1021/acsbiomaterials.6b00422
Inducing a strong and specific immune response is the hallmark of a successful vaccine. Nanoparticles have emerged as promising vaccine delivery devices to discover and elicit immune responses. Fine-tuning a nanoparticle vaccine to create an immune response with specific antibody and other cellular responses is influenced by many factors such as shape, size, and composition. Peptide amphiphile micelles are a unique biomaterials platform that can function as a modular vaccine delivery system, enabling control over many of these important factors and delivering payloads more efficiently to draining lymph nodes. In this study, the modular properties of peptide amphiphile micelles are utilized to improve an immune response against a Group A Streptococcus B cell antigen (J8). The hydrophobic/hydrophilic interface of peptide amphiphile micelles enabled the precise entrapment of amphiphilic adjuvants which were found to not alter micelle formation or shape. These heterogeneous micelles significantly enhanced murine antibody responses when compared to animals vaccinated with nonadjuvanted micelles or soluble J8 peptide supplemented with a classical adjuvant. The heterogeneous micelle induced antibodies also showed cross-reactivity with wild-type Group A Streptococcus providing evidence that micelle-induced immune responses are capable of identifying their intended pathogenic targets.Keywords: biodistribution; Group A Streptococcus; J8 peptide; peptide amphiphile micelles; vaccine;
Co-reporter:Handan Acar;Jeffrey M. Ting;Samanvaya Srivastava;James L. LaBelle
Chemical Society Reviews 2017 vol. 46(Issue 21) pp:6553-6569
Publication Date(Web):2017/10/30
DOI:10.1039/C7CS00536A
Proteins and their interactions in and out of cells must be well-orchestrated for the healthy functioning and regulation of the body. Even the slightest disharmony can cause diseases. Therapeutic peptides are short amino acid sequences (generally considered <50 amino acids) that can naturally mimic the binding interfaces between proteins and thus, influence protein–protein interactions. Because of their fidelity of binding, peptides are a promising next generation of personalized medicines to reinstate biological harmony. Peptides as a group are highly selective, relatively safe, and biocompatible. However, they are also vulnerable to many in vivo pharmacologic barriers limiting their clinical translation. Current advances in molecular, chemical, and nanoparticle engineering are helping to overcome these previously insurmountable obstacles and improve the future of peptides as active and highly selective therapeutics. In this review, we focus on self-assembled vehicles as nanoparticles to carry and protect therapeutic peptides through this journey, and deliver them to the desired tissue.
Co-reporter:Jing Yu, Jun Mao, Guangcui Yuan, Sushil Satija, Wei Chen, Matthew Tirrell
Polymer 2016 Volume 98() pp:448-453
Publication Date(Web):19 August 2016
DOI:10.1016/j.polymer.2016.02.053
•ATRP.•Dense polystyrene sulfonate brushes.•Neutron reflectivity.•Multivalent effect.Surface tethered polyelectrolyte brushes are scientifically interesting and technologically relevant to many applications, ranging from colloidal stabilization to responsive and tunable materials to lubrication. Many applications operate in environments containing multi-valent ions, media in which our scientific understanding is not yet well-developed. We synthesized high-density polystyrene sulfonate (PSS) brushes via surface initiated atom-transfer radical polymerization, and performed neutron reflectivity (NR) measurements to investigate and compare the effects of mono-valent Rb+ and tri-valent Y3+ counterions to the structure of the densely tethered PSS brushes. Our NR results show that in mono-valent RbNO3 solution, the dense PSS brush retained its full thickness up to a salt concentration of 1 M, whereas it immediately collapsed upon adding 1.67 mM of tri-valent Y3+. Increasing the concentration of Y3+ beyond this level did not lead to any significant further structure change of the PSS brush. Our findings demonstrate that the presence of multi-valent counterions can significantly alter the structure of polyelectrolyte brushes, in a manner different from mono-valent ions, which has implications for the functionality of the brushes.
Co-reporter:Jing Yu, Jun Mao, Guangcui Yuan, Sushil Satija, Zhang Jiang, Wei Chen, and Matthew Tirrell
Macromolecules 2016 Volume 49(Issue 15) pp:5609-5617
Publication Date(Web):July 20, 2016
DOI:10.1021/acs.macromol.6b01064
Polyelectrolyte brushes are of great importance to a wide range of fields, ranging from colloidal stabilization to responsive and tunable materials to lubrication. We synthesized high-density polystyrenesulfonate (PSS) brushes using surface initiated atom transfer radical polymerization and performed neutron reflectivity (NR) and surface force measurements using a surface forces apparatus (SFA) to investigate the effect of monovalent Na+, divalent Ca2+, Mg2+, and Ba2+, and trivalent Y3+ counterions on the structure of the PSS brushes. NR and SFA results demonstrate that in monovalent salt solution the behavior of the PSS brushes agrees with scaling theory well, exhibiting two distinct regimes: the osmotic and salted brush regimes. Introducing trivalent Y3+ cations causes an abrupt shrinkage of the PSS brush due to the uptake of Y3+ counterions. The uptake of Y3+ counterions and shrinkage of the brush are reversible upon increasing the concentration of monovalent salt. Divalent cations, Mg2+, Ca2+, and Ba2+, while all significantly affecting the structure of PSS brushes, show strong ion specific effects that are related to the specific interactions between the divalent cations and the sulfonate groups. Our results demonstrate that the presence of multivalent counterions, even at relatively low concentrations, can strongly affect the structure of polyelectrolyte brushes. The results also highlight the importance of ion specificity to the structure of polyelectrolyte brushes in solution.
Co-reporter:Blair Kathryn Brettmann;Nicolas Laugel;Norman Hoffmann;Philip Pincus;Matthew Tirrell
Journal of Polymer Science Part A: Polymer Chemistry 2016 Volume 54( Issue 2) pp:284-291
Publication Date(Web):
DOI:10.1002/pola.27959
ABSTRACT
Polyelectrolyte brushes are essential in many aspects of surface functionality, particularly for colloidal stabilization and lubrication in biological and materials science applications. It has been shown experimentally that the brushes undergo an abrupt shrinkage in the presence of multivalent counter-ions. This transition is studied here using a phenomenological mean-field approach with a model that specifically includes bridging of the polyelectrolyte chains by the multiple charges on the multivalent counter-ions. Using an energy balance represented by the sum of electrostatic, polymeric and entropic mean-field terms, additional parameterized phenomenological terms are introduced for counter-ion condensation and for the attractive interaction between adjacent polyelectrolyte chains to account for the bridging effect. The free energy is minimized with respect to the counter-ion populations and the brush height. In agreement with experimental observations, increasing the concentration of multivalent ions leads to a sharp collapse of the polyelectrolyte brush height. © 2015 Wiley Periodicals, Inc. J. Polym. Sci., Part A: Polym. Chem. 2016, 54, 284–291
Co-reporter:Eun Ji Chung;Laurie B. Mlinar;Kathryn Nord;Matthew J. Sugimoto;Emily Wonder;Francis J. Alenghat;Yun Fang;Matthew Tirrell
Advanced Healthcare Materials 2015 Volume 4( Issue 3) pp:367-376
Publication Date(Web):
DOI:10.1002/adhm.201400336
Atherosclerosis is a multifactorial inflammatory disease that can progress silently for decades and result in myocardial infarction, stroke, and death. Diagnostic imaging technologies have made great strides to define the degree of atherosclerotic plaque burden through the severity of arterial stenosis. However, current technologies cannot differentiate more lethal “vulnerable plaques,” and are not sensitive enough for preventive medicine. Imaging early molecular markers and quantifying the extent of disease progression continues to be a major challenge in the field. To this end, monocyte-targeting, peptide amphiphile micelles (PAMs) are engineered through the incorporation of the chemokine receptor CCR2-binding motif of monocyte chemoattractant protein-1 (MCP-1) and MCP-1 PAMs are evaluated preclinically as diagnostic tools for atherosclerosis. Monocyte-targeting is desirable as the influx of monocytes is a marker of early lesions, accumulation of monocytes is linked to atherosclerosis progression, and rupture-prone plaques have higher numbers of monocytes. MCP-1 PAMs bind to monocytes in vitro, and MCP-1 PAMs detect and discriminate between early- and late-stage atherosclerotic aortas. Moreover, MCP-1 PAMs are found to be eliminated via renal clearance and the mononuclear phagocyte system (MPS) without adverse side effects. Thus, MCP-1 PAMs are a promising new class of diagnostic agents capable of monitoring the progression of atherosclerosis.
Co-reporter:Dr. Dimitrios Priftis;Dr. Lorraine Leon;Ziyuan Song;Dr. Sarah L. Perry;Khatcher O. Margossian;Anna Tropnikova; Jianjun Cheng; Matthew Tirrell
Angewandte Chemie 2015 Volume 127( Issue 38) pp:11280-11284
Publication Date(Web):
DOI:10.1002/ange.201504861
Abstract
Reported is the ability of α-helical polypeptides to self-assemble with oppositely-charged polypeptides to form liquid complexes while maintaining their α-helical secondary structure. Coupling the α-helical polypeptide to a neutral, hydrophilic polymer and subsequent complexation enables the formation of nanoscale coacervate-core micelles. While previous reports on polypeptide complexation demonstrated a critical dependence of the nature of the complex (liquid versus solid) on chirality, the α-helical structure of the positively charged polypeptide prevents the formation of β-sheets, which would otherwise drive the assembly into a solid state, thereby, enabling coacervate formation between two chiral components. The higher charge density of the assembly, a result of the folding of the α-helical polypeptide, provides enhanced resistance to salts known to inhibit polypeptide complexation. The unique combination of properties of these materials can enhance the known potential of fluid polypeptide complexes for delivery of biologically relevant molecules.
Co-reporter:Eun Ji Chung, Laurie B. Mlinar, Matthew J. Sugimoto, Kathryn Nord, Brian B. Roman, Matthew Tirrell
Nanomedicine: Nanotechnology, Biology and Medicine 2015 Volume 11(Issue 2) pp:479-487
Publication Date(Web):February 2015
DOI:10.1016/j.nano.2014.08.006
Co-reporter:Dr. Dimitrios Priftis;Dr. Lorraine Leon;Ziyuan Song;Dr. Sarah L. Perry;Khatcher O. Margossian;Anna Tropnikova; Jianjun Cheng; Matthew Tirrell
Angewandte Chemie International Edition 2015 Volume 54( Issue 38) pp:11128-11132
Publication Date(Web):
DOI:10.1002/anie.201504861
Abstract
Reported is the ability of α-helical polypeptides to self-assemble with oppositely-charged polypeptides to form liquid complexes while maintaining their α-helical secondary structure. Coupling the α-helical polypeptide to a neutral, hydrophilic polymer and subsequent complexation enables the formation of nanoscale coacervate-core micelles. While previous reports on polypeptide complexation demonstrated a critical dependence of the nature of the complex (liquid versus solid) on chirality, the α-helical structure of the positively charged polypeptide prevents the formation of β-sheets, which would otherwise drive the assembly into a solid state, thereby, enabling coacervate formation between two chiral components. The higher charge density of the assembly, a result of the folding of the α-helical polypeptide, provides enhanced resistance to salts known to inhibit polypeptide complexation. The unique combination of properties of these materials can enhance the known potential of fluid polypeptide complexes for delivery of biologically relevant molecules.
Co-reporter:Robert Farina
The Journal of Physical Chemistry C 2015 Volume 119(Issue 26) pp:14805-14814
Publication Date(Web):April 24, 2015
DOI:10.1021/acs.jpcc.5b02121
Applications of end-tethered polyelectrolyte “brushes” to modify solid surfaces have been developed and studied for their colloidal stabilization and high lubrication properties. Current efforts have expanded into biological realms and stimuli-responsive materials. Our work explores responsive and reversible aspects of polyelectrolyte brush behavior when polyelectrolyte chains interact with oppositely charged multivalent ions and complexes, which act as counterions. There is a significant void in the polyelectrolyte literature regarding interactions with multivalent species. This paper demonstrates that interactions between solid surfaces bearing negatively charged polyelectrolyte brushes are highly sensitive to the presence of trivalent lanthanum, La3+. Lanthanum cations have unique interactions with polyelectrolyte chains, in part due to their small size and hydration radius which results in a high local charge density. Using La3+ in conjunction with the surface forces apparatus (SFA), adhesion has been observed to reversibly appear and disappear upon the uptake and release, respectively, of these multivalent cations acting as counterions. In media of fixed ionic strength set by monovalent sodium salt, at I0 = 0.003 M and I0 = 0.3 M, the sign of the interaction forces between overlapping brushes changes from repulsive to attractive when La3+ concentrations reach 0.1 mol % of the total ion concentration. These results are also shown to be generally consistent with, but subtlety different from, previous polyelectrolyte brush experiments using trivalent ruthenium hexamine in the role of the multivalent counterion.
Co-reporter:Cheng-Hsiang Kuo, Lorraine Leon, Eun Ji Chung, Ru-Ting Huang, Timothy J. Sontag, Catherine A. Reardon, Godfrey S. Getz, Matthew Tirrell and Yun Fang
Journal of Materials Chemistry A 2014 vol. 2(Issue 46) pp:8142-8153
Publication Date(Web):05 Sep 2014
DOI:10.1039/C4TB00977K
Polyelectrolyte complex micelles have great potential as gene delivery vehicles because of their ability to encapsulate charged nucleic acids forming a core by neutralizing their charge, while simultaneously protecting the nucleic acids from non-specific interactions and enzymatic degradation. Furthermore, to enhance specificity and transfection efficiency, polyelectrolyte complex micelles can be modified to include targeting capabilities. Here, we describe the design of targeted polyelectrolyte complex micelles containing inhibitors against dys-regulated microRNAs (miRNAs) that promote atherosclerosis, a leading cause of human mortality and morbidity. Inhibition of dys-regulated miRNAs in diseased cells associated with atherosclerosis has resulted in therapeutic efficacy in animal models and has been proposed to treat human diseases. However, the non-specific targeting of microRNA inhibitors via systemic delivery has remained an issue that may cause unwanted side effects. For this reason, we incorporated two different peptide sequences to our miRNA inhibitor containing polyelectrolyte complex micelles. One of the peptides (Arginine-Glutamic Acid-Lysine-Alanine or REKA) was used in another micellar system that demonstrated lesion-specific targeting in a mouse model of atherosclerosis. The other peptide (Valine-Histidine-Proline-Lysine-Glutamine-Histidine-Arginine or VHPKQHR) was identified via phage display and targets vascular endothelial cells through the vascular cell adhesion molecule-1 (VCAM-1). In this study we have tested the in vitro efficacy and efficiency of lesion- and cell-specific delivery of microRNA inhibitors to the cells associated with atherosclerotic lesions via peptide-targeted polyelectrolyte complex micelles. Our results show that REKA-containing micelles (fibrin-targeting) and VHPKQHR-containing micelles (VCAM-1 targeting) can be used to carry and deliver microRNA inhibitors into macrophages and human endothelial cells, respectively. Additionally, the functionality of miRNA inhibitors in cells was demonstrated by analyzing miRNA expression as well as the expression or the biological function of its downstream target protein. Our study provides the first demonstration of targeting dys-regulated miRNAs in atherosclerosis using targeted polyelectrolyte complex micelles and holds promising potential for translational applications.
Co-reporter:Katie A. Black, Dimitrios Priftis, Sarah L. Perry, Jeremy Yip, William Y. Byun, and Matthew Tirrell
ACS Macro Letters 2014 Volume 3(Issue 10) pp:1088
Publication Date(Web):October 9, 2014
DOI:10.1021/mz500529v
Proteins have gained increasing success as therapeutic agents; however, challenges exist in effective and efficient delivery. In this work, we present a simple and versatile method for encapsulating proteins via complex coacervation with oppositely charged polypeptides, poly(l-lysine) (PLys) and poly(d/l-glutamic acid) (PGlu). A model protein system, bovine serum albumin (BSA), was incorporated efficiently into coacervate droplets via electrostatic interaction up to a maximum loading of one BSA per PLys/PGlu pair and could be released under conditions of decreasing pH. Additionally, encapsulation within complex coacervates did not alter the secondary structure of the protein. Lastly the complex coacervate system was shown to be biocompatible and interact well with cells in vitro. A simple, modular system for encapsulation such as the one presented here may be useful in a range of drug delivery applications.
Co-reporter:Laurie B. Mlinar, Eun Ji Chung, Emily A. Wonder, Matthew Tirrell
Biomaterials 2014 35(30) pp: 8678-8686
Publication Date(Web):
DOI:10.1016/j.biomaterials.2014.06.054
Co-reporter:Daniel V. Krogstad, Nathaniel A. Lynd, Daigo Miyajima, Jeffrey Gopez, Craig J. Hawker, Edward J. Kramer, and Matthew V. Tirrell
Macromolecules 2014 Volume 47(Issue 22) pp:8026-8032
Publication Date(Web):November 11, 2014
DOI:10.1021/ma5017852
The kinetics of formation and structural evolution of novel polyelectrolyte complex materials formed by the assembly of water-soluble di- and triblock copolymers, with one neutral block and one (or two) cationic or anionic blocks, have been investigated. Comparison was made between the assembly of ABA and AB′ copolymers in which A represents the ionic blocks and B and B′ are the neutral poly(ethylene oxide) blocks. The degree of polymerization of B was twice that of B′ and the ionic A blocks were of equal degrees of polymerization in all polymers. The mechanism and speed of the assembly process, and the organization of these domains, was probed using dynamic mechanical spectroscopy and small-angle X-ray scattering (SAXS). SAXS revealed that the equilibrium morphologies of both the diblock copolymer and the triblock copolymer materials were generally qualitatively the same with some apparent quantitative differences in phase boundaries, possibly attributable to lack of full equilibration. Slow kinetics and difficulties in reaching equilibrium phase structures, especially in triblock materials, is a principal message of this article. Detailed analysis of the SAXS data revealed that the triblock copolymer materials formed ordered phases via a nucleation and growth pathway and that the addition of small amounts (∼20%) of corresponding diblock copolymers increased the rate of structure formation and enhanced several key physical properties.
Co-reporter:Daniel V. Krogstad, Soo-Hyung Choi, Nathaniel A. Lynd, Debra J. Audus, Sarah L. Perry, Jeffrey D. Gopez, Craig J. Hawker, Edward J. Kramer, and Matthew V. Tirrell
The Journal of Physical Chemistry B 2014 Volume 118(Issue 45) pp:13011-13018
Publication Date(Web):October 22, 2014
DOI:10.1021/jp509175a
A complex coacervate is a fluid phase that results from the electrostatic interactions between two oppositely charged macromolecules. The nature of the coacervate core structure of hydrogels and micelles formed from complexation between pairs of diblock or triblock copolymers containing oppositely charged end-blocks as a function of polymer and salt concentration was investigated. Both ABA triblock copolymers of poly[(allyl glycidyl ether)-b-(ethylene oxide)-b-(allyl glycidyl ether)] and analogous poly[(allyl glycidyl ether)-b-(ethylene oxide)] diblock copolymers, which were synthesized to be nearly one-half of the symmetrical triblock copolymers, were studied. The poly(allyl glycidyl ether) blocks were functionalized with either guanidinium or sulfonate groups via postpolymerization modification. Mixing of oppositely charged block copolymers resulted in the formation of nanometer-scale coacervate domains. Small angle neutron scattering (SANS) experiments were used to investigate the size and spacing of the coacervate domains. The SANS patterns were fit using a previously vetted, detailed model consisting of polydisperse core–shell micelles with a randomly distributed sphere or body-centered cubic (BCC) structure factor. For increasing polymer concentration, the size of the coacervate domains remained constant while the spatial extent of the poly(ethylene oxide) (PEO) corona decreased. However, increasing salt concentration resulted in a decrease in both the coacervate domain size and the corona size due to a combination of the electrostatic interactions being screened and the shrinkage of the neutral PEO blocks. Additionally, for the triblock copolymers that formed BCC ordered domains, the water content in the coacervate domains was calculated to increase from approximately 16.8% to 27.5% as the polymer concentration decreased from 20 to 15 wt %.
Co-reporter:Robert Farina, Nicolas Laugel, Philip Pincus and Matthew Tirrell
Soft Matter 2013 vol. 9(Issue 44) pp:10458-10472
Publication Date(Web):08 Jul 2013
DOI:10.1039/C3SM51450A
This paper describes the structure and properties of end-tethered anionic polyelectrolyte brushes containing counterions of tri-valent ruthenium hexamine (Ru(NH3)63+) and mono-valent sodium (Na+). Detailed studies of these planar brushes composed of the strong polyelectrolyte, poly(sodium styrenesulfonate), were performed via electrochemical experiments using cyclic voltametry (CV) and surface force experiments using the Surface Forces Apparatus (SFA). A comparison between electrochemical and force measurements provided physical information regarding polyelectrolyte brush height and the population of tri-valent Ru(NH3)63+ counterions inside a brush. Polyelectrolyte brushes were observed to transform from extended brushes dominated by the presence of mono-valent counterions, to collapsed brushes saturated with tri-valent counterions. This transformation occurred as a result of Ru(NH3)63+ replacement of Na+ counterions in the polyelectrolyte brushes. This Ru(NH3)63+ uptake was seen to be limited by either the diffusion of tri-valent ions in low ionic strength solutions or the equilibrium between mono and tri-valent ions at higher fixed ionic strengths. The collapsed state, seen only with brushes dominated by multi-valent counterions, also corresponded to an observed adhesive state between brushes. Adhesion was never seen with exclusively mono-valent ions present in solution. Ru(NH3)63+ was observed to be released from saturated brushes when placed in a purely mono-valent salt solution of sufficiently high ionic strength. All SFA and CV experiments were performed in solutions of three separate fixed ionic strengths, with brush collapse/saturation occurring more sudden and producing higher adhesion at lower total ionic strength.
Co-reporter:Rachel Marullo;Mark Kastantin;Laurie B. Drews;Matthew Tirrell
Biopolymers 2013 Volume 99( Issue 9) pp:573-581
Publication Date(Web):
DOI:10.1002/bip.22217
This work advances bottom-up design of bioinspired materials built from peptide-amphiphiles, which are a class of bioconjugates in which a biofunctional peptide is covalently attached to a hydrophobic moiety that drives self-assembly in aqueous solution. Specifically, this work highlights the importance of peptide contour length in determining the equilibrium secondary structure of the peptide as well as the self-assembled (i.e., micelle) geometry. Peptides used here repeat a seven-amino acid sequence between one and four times to vary peptide contour length while maintaining similar peptide-peptide interactions. Without a hydrophobic tail, these peptides all exhibit a combination of random coil and α-helical structure. Upon self-assembly in the crowded environment of a micellar corona, however, short peptides are prone to β-sheet structure and cylindrical micelle geometry while longer peptides remain helical in spheroidal micelles. The transition to β-sheets in short peptides is rapid, whereby amphiphiles first self-assemble with α-helical peptide structure, then transition to their equilibrium β-sheet structure at a rate that depends on both temperature and ionic strength. These results identify peptide contour length as an important control over equilibrium peptide secondary structure and micelle geometry. Furthermore, the time-dependent nature of the helix-to-sheet transition opens the door for shape-changing bioinspired materials with tunable conversion rates. © 2013 Wiley Periodicals, Inc. Biopolymers 99: 573–581, 2013.
Co-reporter:Daniel V. Krogstad, Nathaniel A. Lynd, Soo-Hyung Choi, Jason M. Spruell, Craig J. Hawker, Edward J. Kramer, and Matthew V. Tirrell
Macromolecules 2013 Volume 46(Issue 4) pp:1512-1518
Publication Date(Web):February 6, 2013
DOI:10.1021/ma302299r
Structure–property relationships were established for complex coacervate hydrogels formed from binary aqueous solutions of oppositely charged ABA triblock copolymers. The charged triblock copolymers were synthesized by functionalizing poly[(allyl glycidyl ether)-b-(ethylene oxide)-b-(allyl glycidyl ether)] with either guanidinium or sulfonate functional groups. When aqueous solutions (ca. 5–40 wt %) of these oppositely charged polymers were mixed, the electrostatic interactions of the functionalized blocks led to the association of the oppositely charged end-blocks into phase-separated complex coacervate domains bridged by the uncharged, hydrophilic PEO midblock. The resulting structures were studied by small-angle X-ray scattering (SAXS) and dynamic mechanical spectroscopy. The organization of the coacervate domains was shown to affect substantially the viscoelastic properties of the hydrogels, with the storage modulus increasing significantly as the mixtures transformed from a disordered array of domains to an ordered BCC structure with increasing block copolymer concentration. As the polymer concentration was further increased to 30 wt %, a hexagonal structure appeared, which coincided with a 25% drop in the modulus. Further structural changes, resulting in variations in the viscoelastic response, were also induced through changes in salt concentration. The viscoelastic properties and the physical nature of the cross-links have important implications for the applicability of these gels as injectable drug delivery systems.
Co-reporter:Rungsima Chollakup, John B. Beck, Klaus Dirnberger, Matthew Tirrell, and Claus D. Eisenbach
Macromolecules 2013 Volume 46(Issue 6) pp:2376-2390
Publication Date(Web):March 13, 2013
DOI:10.1021/ma202172q
Phase separation of polyelectrolyte complexes (PECs) between the polyacid (sodium salt) and polybase (hydrochloride) of poly(acrylic acid) (PAA) and poly(allylamine) (PAH), respectively, has been investigated in aqueous solution. Chain length of the PAA was varied (25 < Pw < 700) holding Pw of the PAH constant at 765. The polyacid/polybase mixing ratio (10–90 wt %) and the ionic strength as salt concentration (0–3,000 mM) were systematically varied. Sample turbidity was utilized as an indicator of PEC formation, complemented by optical microscopy for discrimination between precipitate and coacervate. Salt-free systems always resulted in PEC precipitates; however, coacervates or polyelectrolyte solutions, respectively, were formed upon exceeding critical salt concentrations, the PEC formation also depending on the employed PAA/PAH ratio. The lower the PAA molecular weight, the lower were the critical salt concentrations required for both the precipitate/coacervate and coacervate/solution transitions. The experimental phase behavior established here is explained by molecular models of coacervate complexation, addressing effects of polyelectrolyte molecular weight and salt screening.
Co-reporter:Matthew Black;Ama Trent;Yulia Kostenko;Joseph Saeyong Lee;Colleen Olive;Matthew Tirrell
Advanced Materials 2012 Volume 24( Issue 28) pp:3845-3849
Publication Date(Web):
DOI:10.1002/adma.201200209
Co-reporter:Matthew Black;Ama Trent;Yulia Kostenko;Joseph Saeyong Lee;Colleen Olive;Matthew Tirrell
Advanced Materials 2012 Volume 24( Issue 28) pp:
Publication Date(Web):
DOI:10.1002/adma.201290170
Co-reporter:Brian F. Lin, Katie A. Megley, Nickesh Viswanathan, Daniel V. Krogstad, Laurie B. Drews, Matthew J. Kade, Yichun Qian and Matthew V. Tirrell
Journal of Materials Chemistry A 2012 vol. 22(Issue 37) pp:19447-19454
Publication Date(Web):21 May 2012
DOI:10.1039/C2JM31745A
Nanofibrous materials have become an important component in the field of regenerative medicine. Due to their resemblance with extracellular matrix proteins, nanofibrous materials are capable of eliciting natural cell behaviors. One class of self-assembling molecules that forms nanofibers is peptide amphiphiles (PAs). The modularity of self-assembly affords the ability to tailor PA assemblies for specific applications through molecular design and mixing of different components. Illustrated here is an extended-micelle-forming PA synthesized in a branched architecture composed of histidine and serine amino acids conjugated to a palmitoyl tail. Using histidine residues as molecular switches, PA solutions are capable of transitioning from viscoelastic liquids in mildly acidic conditions to self-supporting hydrogels above pH 6.5. By modulating the concentration of the PAs, biocompatible hydrogels of 0.2–10 kPa were achieved. This PA hydrogel system is a potential candidate as an injectable three-dimensional tissue scaffold.
Co-reporter:Dimitrios Priftis, Robert Farina, and Matthew Tirrell
Langmuir 2012 Volume 28(Issue 23) pp:8721-8729
Publication Date(Web):May 11, 2012
DOI:10.1021/la300769d
A systematic study of the interfacial energy (γ) of polypeptide complex coacervates in aqueous solution was performed using a surface forces apparatus (SFA). Poly(l-lysine hydrochloride) (PLys) and poly(l-glutamic acid sodium salt) (PGA) were investigated as a model pair of oppositely charged weak polyelectrolytes. These two synthetic polypeptides of natural amino acids have identical backbones and differ only in their charged side groups. All experiments were conducted using equal chain lengths of PLys and PGA in order to isolate and highlight effects of the interactions of the charged groups during complexation. Complex coacervates resulted from mixing very dilute aqueous salt solutions of PLys and PGA. Two phases in equilibrium evolved under the conditions used: a dense polymer-rich coacervate phase and a dilute polymer-deficient aqueous phase. Capillary adhesion, associated with a coacervate meniscus bridge between two mica surfaces, was measured upon the separation of the two surfaces. This adhesion enabled the determination of the γ at the aqueous/coacervate phase interface. Important experimental factors affecting these measurements were varied and are discussed, including the compression force (1.3–35.9 mN/m) and separation speed (2.4–33.2 nm/s). Physical parameters of the system, such as the salt concentration (100–600 mM) and polypeptide chain length (N = 30, 200, and 400) were also studied. The γ of these polypeptide coacervates was separately found to decrease with both increasing salt concentration and decreasing polypeptide chain length. In most of the above cases, γ measurements were found to be very low, <1 mJ/m2. Biocompatible complex coacervates with low γ have a strong potential for applications in surface coatings, adhesives, and the encapsulation of a wide range of materials.
Co-reporter:Handan Acar, Samanvaya Srivastava, Eun Ji Chung, Mathew R. Schnorenberg, ... Matthew Tirrell
Advanced Drug Delivery Reviews (February 2017) Volumes 110–111() pp:65-79
Publication Date(Web):1 February 2017
DOI:10.1016/j.addr.2016.08.006
Peptides and peptide-conjugates, comprising natural and synthetic building blocks, are an increasingly popular class of biomaterials. Self-assembled nanostructures based on peptides and peptide-conjugates offer advantages such as precise selectivity and multifunctionality that can address challenges and limitations in the clinic. In this review article, we discuss recent developments in the design and self-assembly of various nanomaterials based on peptides and peptide-conjugates for medical applications, and categorize them into two themes based on the driving forces of molecular self-assembly. First, we present the self-assembled nanostructures driven by the supramolecular interactions between the peptides, with or without the presence of conjugates. The studies where nanoassembly is driven by the interactions between the conjugates of peptide-conjugates are then presented. Particular emphasis is given to in vivo studies focusing on therapeutics, diagnostics, immune modulation and regenerative medicine. Finally, challenges and future perspectives are presented.Download high-res image (189KB)Download full-size image
Co-reporter:Brian F. Lin, Katie A. Megley, Nickesh Viswanathan, Daniel V. Krogstad, Laurie B. Drews, Matthew J. Kade, Yichun Qian and Matthew V. Tirrell
Journal of Materials Chemistry A 2012 - vol. 22(Issue 37) pp:NaN19454-19454
Publication Date(Web):2012/05/21
DOI:10.1039/C2JM31745A
Nanofibrous materials have become an important component in the field of regenerative medicine. Due to their resemblance with extracellular matrix proteins, nanofibrous materials are capable of eliciting natural cell behaviors. One class of self-assembling molecules that forms nanofibers is peptide amphiphiles (PAs). The modularity of self-assembly affords the ability to tailor PA assemblies for specific applications through molecular design and mixing of different components. Illustrated here is an extended-micelle-forming PA synthesized in a branched architecture composed of histidine and serine amino acids conjugated to a palmitoyl tail. Using histidine residues as molecular switches, PA solutions are capable of transitioning from viscoelastic liquids in mildly acidic conditions to self-supporting hydrogels above pH 6.5. By modulating the concentration of the PAs, biocompatible hydrogels of 0.2–10 kPa were achieved. This PA hydrogel system is a potential candidate as an injectable three-dimensional tissue scaffold.
Co-reporter:Cheng-Hsiang Kuo, Lorraine Leon, Eun Ji Chung, Ru-Ting Huang, Timothy J. Sontag, Catherine A. Reardon, Godfrey S. Getz, Matthew Tirrell and Yun Fang
Journal of Materials Chemistry A 2014 - vol. 2(Issue 46) pp:NaN8153-8153
Publication Date(Web):2014/09/05
DOI:10.1039/C4TB00977K
Polyelectrolyte complex micelles have great potential as gene delivery vehicles because of their ability to encapsulate charged nucleic acids forming a core by neutralizing their charge, while simultaneously protecting the nucleic acids from non-specific interactions and enzymatic degradation. Furthermore, to enhance specificity and transfection efficiency, polyelectrolyte complex micelles can be modified to include targeting capabilities. Here, we describe the design of targeted polyelectrolyte complex micelles containing inhibitors against dys-regulated microRNAs (miRNAs) that promote atherosclerosis, a leading cause of human mortality and morbidity. Inhibition of dys-regulated miRNAs in diseased cells associated with atherosclerosis has resulted in therapeutic efficacy in animal models and has been proposed to treat human diseases. However, the non-specific targeting of microRNA inhibitors via systemic delivery has remained an issue that may cause unwanted side effects. For this reason, we incorporated two different peptide sequences to our miRNA inhibitor containing polyelectrolyte complex micelles. One of the peptides (Arginine-Glutamic Acid-Lysine-Alanine or REKA) was used in another micellar system that demonstrated lesion-specific targeting in a mouse model of atherosclerosis. The other peptide (Valine-Histidine-Proline-Lysine-Glutamine-Histidine-Arginine or VHPKQHR) was identified via phage display and targets vascular endothelial cells through the vascular cell adhesion molecule-1 (VCAM-1). In this study we have tested the in vitro efficacy and efficiency of lesion- and cell-specific delivery of microRNA inhibitors to the cells associated with atherosclerotic lesions via peptide-targeted polyelectrolyte complex micelles. Our results show that REKA-containing micelles (fibrin-targeting) and VHPKQHR-containing micelles (VCAM-1 targeting) can be used to carry and deliver microRNA inhibitors into macrophages and human endothelial cells, respectively. Additionally, the functionality of miRNA inhibitors in cells was demonstrated by analyzing miRNA expression as well as the expression or the biological function of its downstream target protein. Our study provides the first demonstration of targeting dys-regulated miRNAs in atherosclerosis using targeted polyelectrolyte complex micelles and holds promising potential for translational applications.
