Your search keyword '"Samuel E. Sherman"' showing total 13 results

1. Encapsulation of hydrophobic components in dendrimersomes and decoration of their surface with proteins and nucleic acids

Author

Virgil Percec, Samuel E. Sherman, Khosrow Rahimi, Irene Buzzacchera, Michael L. Klein, Christopher J. Wilson, Nina Yu. Kostina, Martin Möller, Qi Xiao, Matthew C. Good, Paola Torre, and Cesar Rodriguez-Emmenegger

Subjects

Nitrilotriacetic Acid, biological membrane mimic, Dendrimers, Surface Properties, Green Fluorescent Proteins, Phospholipid, 02 engineering and technology, Conjugated system, Ligands, 010402 general chemistry, 01 natural sciences, chemistry.chemical_compound, Nucleic Acids, Dendrimer, Amphiphile, Janus, Multidisciplinary, Vesicle, Proteins, Biological membrane, Cell Biology, Biological Sciences, onion-like vesicles, 021001 nanoscience & nanotechnology, nucleic acid, 0104 chemical sciences, Chemistry, PNAS Plus, chemistry, Physical Sciences, Liposomes, Nucleic acid, Biophysics, ddc:500, folded protein, 0210 nano-technology, Janus dendrimer vesicles, Hydrophobic and Hydrophilic Interactions

Abstract

Significance Lipid vesicles are globular assemblies that compartmentalize, encapsulate, transport, and provide signal transmission and communication between cells. In living systems, these vesicles perform critical functions to sustain life. Biomimetic lipid vesicles, such as liposomes, have been developed as mimics of biological cell membranes and for applications in biotechnology, but they do have specific limitations. Dendrimersomes are vesicles self-assembled from amphiphilic Janus dendrimers. They offer improved stability and versatility over liposomes. These dendrimersomes are extremely efficient at loading hydrophobic small molecules and natural macromolecules including folded proteins, at a level higher than comparable liposomes. Additionally, they can be readily functionalized to enable modular recruitment of proteins and nucleic acids on their periphery., Reconstructing the functions of living cells using nonnatural components is one of the great challenges of natural sciences. Compartmentalization, encapsulation, and surface decoration of globular assemblies, known as vesicles, represent key early steps in the reconstitution of synthetic cells. Here we report that vesicles self-assembled from amphiphilic Janus dendrimers, called dendrimersomes, encapsulate high concentrations of hydrophobic components and do so more efficiently than commercially available stealth liposomes assembled from phospholipid components. Multilayer onion-like dendrimersomes demonstrate a particularly high capacity for loading low-molecular weight compounds and even folded proteins. Coassembly of amphiphilic Janus dendrimers with metal-chelating ligands conjugated to amphiphilic Janus dendrimers generates dendrimersomes that selectively display folded proteins on their periphery in an oriented manner. A modular strategy for tethering nucleic acids to the surface of dendrimersomes is also demonstrated. These findings augment the functional capabilities of dendrimersomes to serve as versatile biological membrane mimics.

Published

2019

2. Bioactive cell-like hybrids from dendrimersomes with a human cell membrane and its components

Author

William D. Hasley, Michael L. Klein, Qi Xiao, Mark Goulian, Virgil Percec, Samuel E. Sherman, and Srujana S. Yadavalli

Subjects

Protocell, Dendrimers, Green Fluorescent Proteins, Cell, 02 engineering and technology, 010402 general chemistry, Biochemistry, 01 natural sciences, mammalian cell, Amphiphile, coassembly, bacterial adhesin, Escherichia coli, medicine, Humans, hybrid vesicles, Multidisciplinary, Chemistry, Escherichia coli Proteins, Vesicle, Cell Membrane, Cytoplasmic Vesicles, Biological membrane, Biological Sciences, 021001 nanoscience & nanotechnology, In vitro, 0104 chemical sciences, HEK293 Cells, medicine.anatomical_structure, Membrane, PNAS Plus, Physical Sciences, Biophysics, bacterial membrane, Artificial Cells, 0210 nano-technology, Bacterial outer membrane, HeLa Cells

Abstract

Significance Gram-negative bacterial cells such as Escherichia coli contain a relatively rigid outer membrane, and cross-linked peptidoglycan in their periplasm, giving them the rigidity and stability to survive independently in harsh environments. To dismantle these strong bacterial cell envelopes, enzymatic processes need to be used. In contrast, human cell membranes are much more fragile, making it possible to dismantle them more easily by relatively mild mechanical disruption. Once these membranes are dismantled, they can be coassembled with synthetic phospholipid mimics, named Janus dendrimers, into cell-like hybrids. This method stabilizes the delicate human cell membranes, introducing the potential for the study of human cell membranes and of their constituents in vitro in a more robust environment., Cell-like hybrids from natural and synthetic amphiphiles provide a platform to engineer functions of synthetic cells and protocells. Cell membranes and vesicles prepared from human cell membranes are relatively unstable in vitro and therefore are difficult to study. The thicknesses of biological membranes and vesicles self-assembled from amphiphilic Janus dendrimers, known as dendrimersomes, are comparable. This feature facilitated the coassembly of functional cell-like hybrid vesicles from giant dendrimersomes and bacterial membrane vesicles generated from the very stable bacterial Escherichia coli cell after enzymatic degradation of its outer membrane. Human cells are fragile and require only mild centrifugation to be dismantled and subsequently reconstituted into vesicles. Here we report the coassembly of human membrane vesicles with dendrimersomes. The resulting giant hybrid vesicles containing human cell membranes, their components, and Janus dendrimers are stable for at least 1 y. To demonstrate the utility of cell-like hybrid vesicles, hybrids from dendrimersomes and bacterial membrane vesicles containing YadA, a bacterial adhesin protein, were prepared. The latter cell-like hybrids were recognized by human cells, allowing for adhesion and entry of the hybrid bacterial vesicles into human cells in vitro.

Published

2018

3. Dendrimersomes Exhibit Lamellar-to-Sponge Phase Transitions

Author

Qi Xiao, Samuel E. Sherman, Tobias Baumgart, Samantha E. Wilner, Zachary T. Graber, and Virgil Percec

Subjects

Dendrimers, Phase transition, Materials science, 02 engineering and technology, 010402 general chemistry, Models, Biological, 01 natural sciences, Article, Phase Transition, Drug Delivery Systems, Phase (matter), Amphiphile, Electrochemistry, General Materials Science, Lamellar structure, Spectroscopy, Bilayer, Cell Membrane, Lipid bilayer fusion, Biological membrane, Surfaces and Interfaces, 021001 nanoscience & nanotechnology, Condensed Matter Physics, 0104 chemical sciences, Membrane, Chemical physics, 0210 nano-technology

Abstract

Lamellar to nonlamellar membrane shape transitions play essential roles in key cellular processes, such as membrane fusion and fission, and occur in response to external stimuli, including drug treatment and heat. A subset of these transitions can be modeled by means of thermally inducible amphiphile assemblies. We previously reported on mixtures of hydrogenated, fluorinated, and hybrid Janus dendrimers (JDs) that self-assemble into complex dendrimersomes (DMSs), including dumbbells, and serve as promising models for understanding the complexity of biological membranes. Here we show, by means of a variety of complementary techniques, that DMSs formed by single JDs or by mixtures of JDs undergo a thermally induced lamellar-to-sponge transition. Consistent with the formation of a three- dimensional bilayer network, we show that DMSs become more permeable to water-soluble fluorophores after transitioning to the sponge phase. These DMSs may be useful not only in modeling isotropic membrane rearrangements of biological systems but also in drug delivery since nonlamellar delivery vehicles can promote endosomal disruption and cargo release.

Published

2018

4. Mimicking Complex Biological Membranes and Their Programmable Glycan Ligands with Dendrimersomes and Glycodendrimersomes

Author

Samuel E. Sherman, Virgil Percec, and Qi Xiao

Subjects

Dendrimers, Liposome, Chemistry, Vesicle, Cell Membrane, Dispersity, Carbohydrates, Membranes, Artificial, Nanotechnology, Biological membrane, 02 engineering and technology, General Chemistry, Ligands, 010402 general chemistry, 021001 nanoscience & nanotechnology, 01 natural sciences, 0104 chemical sciences, Dendrimer, Amphiphile, Polymersome, Copolymer, Animals, Humans, 0210 nano-technology, Hydrophobic and Hydrophilic Interactions

Abstract

Synthetic vesicles have been assembled and coassembled from phospholipids, their modified versions, and other single amphiphiles into liposomes, and from block copolymers into polymersomes. Their time-consuming synthesis and preparation as stable, monodisperse, and biocompatible liposomes and polymersomes called for the elaboration of new synthetic methodologies. Amphiphilic Janus dendrimers (JDs) and glycodendrimers (JGDs) represent the most recent self-assembling amphiphiles capable of forming monodisperse, stable, and multifunctional unilamellar and multilamellar onion-like vesicles denoted dendrimersomes (DSs) and glycodendrimersomes (GDSs), dendrimercubosomes (DCs), glycodendrimercubosomes (GDCs), and other complex architectures. Amphiphilic JDs consist of hydrophobic dendrons connected to hydrophilic dendrons and can be thought of as monodisperse oligomers of a single amphiphile. They can be functionalized with a variety of molecules such as dyes, and, in the case of JGDs, with carbohydrates. Their iterative modular synthesis provides efficient access to sequence control at the molecular level, resulting in topologies with specific epitope sequence and density. DSs, GDSs, and other architectures from JDs and JGDs serve as powerful tools for mimicking biological membranes and for biomedical applications such as targeted drug and gene delivery and theranostics. This Review covers all aspects of the synthesis of JDs and JGDs and their biological activity and applications after assembly in aqueous media.

Published

2017

5. Precise and Accelerated Polymer Synthesis via Mixed-Ligand and Mixed-RAFT Agents

Author

Michael J. Monteiro, Samuel E. Sherman, and Virgil Percec

Subjects

chemistry.chemical_classification, General Chemical Engineering, Biochemistry (medical), Radical polymerization, 02 engineering and technology, General Chemistry, Polymer, Mixed ligand, Raft, 010402 general chemistry, 021001 nanoscience & nanotechnology, 01 natural sciences, Biochemistry, Combinatorial chemistry, 0104 chemical sciences, chemistry, Chain (algebraic topology), Polymerization, Materials Chemistry, Environmental Chemistry, Molar mass distribution, 0210 nano-technology, Macromolecule

Abstract

Increasing the rate of polymerization while decreasing the molecular weight distribution and maintaining well-defined chain ends remains one of the most challenging problems of macromolecular synthesis. In this issue of Chem, the Anastasaki laboratory demonstrates that mixed-RAFT agents provide a living radical polymerization that makes a very important step toward this goal.

Published

2020

6. Why Do Membranes of Some Unhealthy Cells Adopt a Cubic Architecture?

Author

Samuel E. Sherman, Mihai Peterca, Qi Xiao, Paul A. Heiney, Steven R. King, Dewight Williams, David M. Markovitz, Sabine André, Daniel A. Hammer, Shaodong Zhang, Hans-Joachim Gabius, Zhichun Wang, Michael L. Klein, Pawaret Leowanawat, and Virgil Percec

Subjects

0301 basic medicine, biology, Chemistry, General Chemical Engineering, Vesicle, General Chemistry, 010402 general chemistry, 01 natural sciences, Viral infection, 0104 chemical sciences, lcsh:Chemistry, 03 medical and health sciences, Agglutination (biology), 030104 developmental biology, Membrane, lcsh:QD1-999, Biochemistry, Electron tomography, Concanavalin A, Biophysics, biology.protein, Lamellar structure, Research Article

Abstract

Nonlamellar lipid arrangements, including cubosomes, appear in unhealthy cells, e.g., when they are subject to stress, starvation, or viral infection. The bioactivity of cubosomes—nanoscale particles exhibiting bicontinuous cubic structures—versus more common vesicles is an unexplored area due to lack of suitable model systems. Here, glycodendrimercubosomes (GDCs)—sugar-presenting cubosomes assembled from Janus glycodendrimers by simple injection into buffer—are proposed as mimics of biological cubic membranes. The bicontinuous cubic GDC architecture has been demonstrated by electron tomography. The stability of these GDCs in buffer enabled studies on lectin-dependent agglutination, revealing significant differences compared with the vesicular glycodendrimersome (GDS) counterpart. In particular, GDCs showed an increased activity toward concanavalin A, as well as an increased sensitivity and selectivity toward two variants of banana lectins, a wild-type and a genetically modified variant, which is not exhibited by GDSs. These results suggest that cells may adapt under unhealthy conditions by undergoing a transformation from lamellar to cubic membranes as a method of defense., A sugar-presenting cubosome is proposed as a biomimetic model for cubic membranes found in some diseased cells and provides, via agglutination with sugar receptors, clues to the biological rationale for the transition from lamellar to cubic membranes.

Published

2016

7. Encoding biological recognition in a bicomponent cell-membrane mimic

Author

Michael L. Klein, Samuel E. Sherman, Nina Yu. Kostina, Qi Xiao, Khosrow Rahimi, Cesar Rodriguez-Emmenegger, Christopher J. Wilson, Martin Möller, Matthew C. Good, Shangda Li, Benjamin E. Partridge, Meir Kerzner, Tobias Baumgart, Aracelee M. Reveron Perez, Mark Goulian, Virgil Percec, Ishita Malhotra, Dipankar Sahoo, Hong Han, and Irene Buzzacchera

Subjects

Dendrimers, Supramolecular chemistry, 010402 general chemistry, 01 natural sciences, Cell membrane, Surface-Active Agents, Janus glycodendrimers, Biomimetic Materials, Biomimetics, Dendrimer, medicine, Lamellar structure, Soft matter, lipid rafts, atomic force microscopy, galectin, Multidisciplinary, 010405 organic chemistry, Chemistry, Vesicle, Cell Membrane, nanosegregation, Cell Biology, Biological Sciences, Lipids, 0104 chemical sciences, Nanomedicine, medicine.anatomical_structure, PNAS Plus, Physical Sciences, Biophysics, ddc:500, Glycolipids, Sugars, Chirality (chemistry)

Abstract

Significance The seminal fluid mosaic model of the cell membranes suggests a lipid bilayer sea, in which cholesterol, proteins, glycoconjugates, and other components are swimming. Complementing this view, a microsegregated rafts model predicts clusters of components that function as relay stations for intracellular signaling and trafficking. However, elucidating the arrangement of glycoconjugates responsible for communication and recognition between cells, and cells with proteins remains a challenge. Herein, designed dendritic macromolecules are shown to self-assemble into vesicles that function as biological-membrane mimics with controlled density of sugar moieties on their periphery. Surprisingly, lowering sugar density elicits higher bioactivity to sugar-binding proteins. This finding informs a design principle for active complex soft matter with potential for applications in cellular biology and nanomedicine., Self-assembling dendrimers have facilitated the discovery of periodic and quasiperiodic arrays of supramolecular architectures and the diverse functions derived from them. Examples are liquid quasicrystals and their approximants plus helical columns and spheres, including some that disregard chirality. The same periodic and quasiperiodic arrays were subsequently found in block copolymers, surfactants, lipids, glycolipids, and other complex molecules. Here we report the discovery of lamellar and hexagonal periodic arrays on the surface of vesicles generated from sequence-defined bicomponent monodisperse oligomers containing lipid and glycolipid mimics. These vesicles, known as glycodendrimersomes, act as cell-membrane mimics with hierarchical morphologies resembling bicomponent rafts. These nanosegregated morphologies diminish sugar–sugar interactions enabling stronger binding to sugar-binding proteins than densely packed arrangements of sugars. Importantly, this provides a mechanism to encode the reactivity of sugars via their interaction with sugar-binding proteins. The observed sugar phase-separated hierarchical arrays with lamellar and hexagonal morphologies that encode biological recognition are among the most complex architectures yet discovered in soft matter. The enhanced reactivity of the sugar displays likely has applications in material science and nanomedicine, with potential to evolve into related technologies.

Published

2019

8. Exploring functional pairing between surface glycoconjugates and human galectins using programmable glycodendrimersomes

Author

Herbert Kaltner, Christopher J. Wilson, Qi Xiao, Ellen H. Reed, Cecilia Romanò, Martin Möller, Daniel A. Hammer, Hans-Joachim Gabius, Virgil Percec, Sabine Vértesy, Michael L. Klein, Irene Buzzacchera, Samuel E. Sherman, Stefan Oscarson, Anna-Kristin Ludwig, and M. Vetro

Subjects

0301 basic medicine, glycolipids, Glycan, Galectin 1, Physiology, Galectins, Carbohydrates, glycodendrimers, 010402 general chemistry, 01 natural sciences, Epitope, Glycomics, 03 medical and health sciences, Glycolipid, Galectin, Multidisciplinary, biology, Chemistry, aggregation, Lectin, Biological membrane, Protein engineering, Biological Sciences, 0104 chemical sciences, 030104 developmental biology, PNAS Plus, Physical Sciences, biology.protein, Biophysics, Sugars, Protein Binding

Abstract

Significance Cells are decorated with charged and uncharged carbohydrate ligands known as glycans, which are responsible for several key functions, including their interactions with proteins known as lectins. Here, a platform consisting of synthetic nanoscale vesicles, known as glycodendrimersomes, which can be programmed with cell surface-like structural and topological complexity, is employed to dissect design aspects of glycan presentation, with specificity for lectin-mediated bridging. Aggregation assays reveal the extent of cross-linking of these biomimetic nanoscale vesicles—presenting both anionic and neutral ligands in a bioactive manner—with disease-related human and other galectins, thus offering the possibility of unraveling the nature of these fundamental interactions., Precise translation of glycan-encoded information into cellular activity depends critically on highly specific functional pairing between glycans and their human lectin counter receptors. Sulfoglycolipids, such as sulfatides, are important glycolipid components of the biological membranes found in the nervous and immune systems. The optimal molecular and spatial design aspects of sulfated and nonsulfated glycans with high specificity for lectin-mediated bridging are unknown. To elucidate how different molecular and spatial aspects combine to ensure the high specificity of lectin-mediated bridging, a bottom-up toolbox is devised. To this end, negatively surface-charged glycodendrimersomes (GDSs), of different nanoscale dimensions, containing sulfo-lactose groups are self-assembled in buffer from a synthetic sulfatide mimic: Janus glycodendrimer (JGD) containing a 3′-O-sulfo-lactose headgroup. Also prepared for comparative analysis are GDSs with nonsulfated lactose, a common epitope of human membranes. These self-assembled GDSs are employed in aggregation assays with 15 galectins, comprising disease-related human galectins, and other natural and engineered variants from four families, having homodimeric, heterodimeric, and chimera architectures. There are pronounced differences in aggregation capacity between human homodimeric and heterodimeric galectins, and also with respect to their responsiveness to the charge of carbohydrate-derived ligand. Assays reveal strong differential impact of ligand surface charge and density, as well as lectin concentration and structure, on the extent of surface cross-linking. These findings demonstrate how synthetic JGD-headgroup tailoring teamed with protein engineering and network assays can help explain how molecular matchmaking operates in the cellular context of glycan and lectin complexity.

Published

2018

9. Janus dendrimersomes coassembled from fluorinated, hydrogenated, and hybrid Janus dendrimers as models for cell fusion and fission

Author

Samuel E. Sherman, Daniel A. Hammer, Michael L. Klein, Tobias Baumgart, Virgil Percec, Qi Xiao, Samantha E. Wilner, Cody Dazen, Xuhao Zhou, Ellen H. Reed, and Wataru Shinoda

Subjects

Dendrimers, Multidisciplinary, Materials science, Molecular Structure, Vesicle, Supramolecular chemistry, Janus particles, Nanotechnology, 02 engineering and technology, 010402 general chemistry, 021001 nanoscience & nanotechnology, 01 natural sciences, Models, Biological, 0104 chemical sciences, Cell Fusion, Chemical engineering, PNAS Plus, Transmission electron microscopy, Dendrimer, Fluorescence microscope, Molecule, Janus, 0210 nano-technology, Hydrogen

Abstract

A three-component system of Janus dendrimers (JDs) including hydrogenated, fluorinated, and hybrid hydrogenated–fluorinated JDs are reported to coassemble by film hydration at specific ratios into an unprecedented class of supramolecular Janus particles (JPs) denoted Janus dendrimersomes (JDSs). They consist of a dumbbell-shaped structure composed of an onion-like hydrogenated vesicle and an onion-like fluorinated vesicle tethered together. The synthesis of dye-tagged analogs of each JD component enabled characterization of JDS architectures with confocal fluorescence microscopy. Additionally, a simple injection method was used to prepare submicron JDSs, which were imaged with cryogenic transmission electron microscopy (cryo-TEM). As reported previously, different ratios of the same three-component system yielded a variety of structures including homogenous onion-like vesicles, core-shell structures, and completely self-sorted hydrogenated and fluorinated vesicles. Taken together with the JDSs reported herein, a self-sorting pathway is revealed as a function of the relative concentration of the hybrid JD, which may serve to stabilize the interface between hydrogenated and fluorinated bilayers. The fission-like pathway suggests the possibility of fusion and fission processes in biological systems that do not require the assistance of proteins but instead may result from alterations in the ratios of membrane composition.

Published

2017

10. Ultrafast SET-LRP with Peptoid Cytostatic Drugs as Monofunctional and Bifunctional Initiators

Author

Samuel E. Sherman, Rauan B. Smail, Virgil Percec, Mojtaba Enayati, Gerard Lligadas, Silvia Grama, Polimers Sostenibles, Departament de Química Analítica i Química Orgànica, and Universitat Rovira i Virgili

Subjects

Biologia, Polymers and Plastics, Radical polymerization, Free radical reactions, Bioengineering, 02 engineering and technology, 010402 general chemistry, 01 natural sciences, Radicals lliures (Química), Reaccions químiques, Biomaterials, chemistry.chemical_compound, Peptoids, Morpholine, Materials Chemistry, Organic chemistry, Bifunctional, 1525-7797, chemistry.chemical_classification, Aqueous solution, biology, Peptoid, Polymer, Química, 021001 nanoscience & nanotechnology, Cytostatic Agents, 0104 chemical sciences, Piperazine, Chemistry, chemistry, Cytostatic drugs, 0210 nano-technology

Abstract

DOI: 10.1021/acs.biomac.7b00722 URL: https://pubs-acs-org.sabidi.urv.cat/doi/abs/10.1021/acs.biomac.7b00722 Filiació URV: SI To continue expanding the use of Single Electron Transfer-Living Radical Polymerization (SET-LRP) in applications at the interface between macromolecular science, biomacromolecules, biology and medicine, it is essential to develop novel initiators that do not compromise the structural stability of synthesized polymers in biological environments. Here, we report that stable 2-bromopropionyl peptoid-type initiators such as 1,4-bis(2-bromopropionyl)piperazine and 4-(2-bromopropionyl)morpholine are an alternative that meets the standards reached by the well-known secondary and tertiary ¿-haloester-type initiators in terms of excellent control over molecular weight evolution and distribution as well as polymer chain ends. SET-LRP methodologies in organic, aqueous, and biphasic organic-aqueous media were evaluated for this purpose.

Published

2017

11. Reaction of a programmable glycan presentation of glycodendrimersomes and cells with engineered human lectins to show the sugar functionality of the cell surface

Author

Michael L. Klein, Sabine Vértesy, Samuel E. Sherman, Virgil Percec, Qi Xiao, Cody Dazen, Xuhao Zhou, Jürgen Kopitz, Malwina Michalak, Anna-Kristin Ludwig, Antonio A. Romero, Hans-Joachim Gabius, Herbert Kaltner, and National Science Foundation (US)

Subjects

0301 basic medicine, Glycan, Agglutination, Glycosylation, Cell, 01 natural sciences, Catalysis, 03 medical and health sciences, chemistry.chemical_compound, Polysaccharides, Lectins, Gangliosides, medicine, Humans, Tumors, Ganglioside, biology, 010405 organic chemistry, Chemistry, Cell Membrane, Lectin, General Medicine, General Chemistry, Adhesion, Self-assembly, Ligand (biochemistry), 0104 chemical sciences, 030104 developmental biology, medicine.anatomical_structure, Biochemistry, biology.protein, Biophysics, Sugars, Linker

Abstract

10 p.-6 fig.-22 p. inf. supl. Kopitz, Jürgen et al., Chemical and biological tools are harnessed to investigate the impact of spatial factors for functional pairing of human lectins with counterreceptors. The homodimeric adhesion/growth-regulatory galectin-1 and a set of covalently linked homo-oligomers from di- to tetramers serve as proof-of-principle test cases. Glycodendrimersomes provide a versatile and sensitive diagnostic platform to reveal thresholds for ligand density and protein concentration in aggregation assays (trans-activity), irrespective of linker length between lectin domains. Monitoring the affinity of cell binding and ensuing tumor growth inhibition reveal the linker length to be a bidirectional switch for cis-activity. The discovery that two aspects of lectin functionality (trans- versus cis-activity) respond non-uniformly to a structural change underscores the power of combining synthetic and biological tools to advance understanding of the sugar functionality of the cell surface., Financial support from the National Science Foundation (grants DMR-1066116 and DMR-1120901), the P. Roy Vagelos Chair at the University of Pennsylvania (all to V.P.), and the National Science Foundation (grant DMR-1120901 to M.L.K.) are gratefully acknowledged

Published

2017

12. Onion-like glycodendrimersomes from sequence-defined Janus glycodendrimers and influence of architecture on reactivity to a lectin

Author

Sabine André, Mihai Peterca, Sabine Vértesy, Hans-Joachim Gabius, Qi Xiao, Dewight Williams, Ralph-Olivier Moussodia, Daniel A. Hammer, Samuel E. Sherman, Virgil Percec, Adam Muncan, Michael L. Klein, Zhichun Wang, and Shaodong Zhang

Subjects

Glycan, Dendrimers, Multidisciplinary, biology, 010405 organic chemistry, Stereochemistry, Chemistry, Vesicle, Carbohydrates, Lectin, Transporter, Sequence (biology), 010402 general chemistry, 01 natural sciences, 0104 chemical sciences, Agglutinin, Microscopy, Electron, Transmission, Lectins, Amphiphile, Physical Sciences, biology.protein, Biophysics, Janus

Abstract

A library of eight amphiphilic Janus glycodendrimers (GDs) with d-mannose (Man) headgroups, a known routing signal for lectin-mediated transport processes, was constructed via an iterative modular methodology. Sequence-defined variations of the Janus GD modulate the surface density and sequence of Man after self-assembly into multilamellar glycodendrimersomes (GDSs). The spatial mode of Man presentation is decisive for formation of either unilamellar or onion-like GDS vesicles. Man presentation and Janus GD concentration determine GDS size and number of bilayers. Beyond vesicle architecture, Man topological display affects kinetics and plateau level of GDS aggregation by a tetravalent model lectin: the leguminous agglutinin Con A, which is structurally related to endogenous cargo transporters. The agglutination process was rapid, efficient, and readily reversible for onion-like GDSs, demonstrating their value as versatile tools to explore the nature of physiologically relevant glycan/lectin pairing.

Published

2016

13. Bioactive cell-like hybrids coassembled from (glyco)dendrimersomes with bacterial membranes

Author

Louise da Silva, Virgil Percec, Srujana S. Yadavalli, Daniel A. Hammer, Michael L. Klein, Daniela A. Wilson, Shaodong Zhang, Mark Goulian, Samuel E. Sherman, Qi Xiao, Sabine André, Hans-Joachim Gabius, and Elodie Fiorin

Subjects

chemistry.chemical_classification, Dendrimers, Multidisciplinary, 010405 organic chemistry, Vesicle, Biological membrane, Biology, 010402 general chemistry, 01 natural sciences, Bio-Organic Chemistry, Transmembrane protein, 0104 chemical sciences, Green fluorescent protein, Membrane, Membrane protein, chemistry, Biochemistry, PNAS Plus, Cell Wall, Fluorescence microscope, Escherichia coli, Glycoprotein

Abstract

A library of amphiphilic Janus dendrimers including two that are fluorescent and one glycodendrimer presenting lactose were used to construct giant dendrimersomes and glycodendrimersomes. Coassembly with the components of bacterial membrane vesicles by a dehydration-rehydration process generated giant cell-like hybrid vesicles, whereas the injection of their ethanol solution into PBS produced monodisperse nanometer size assemblies. These hybrid vesicles contain transmembrane proteins including a small membrane protein, MgrB, tagged with a red fluorescent protein, lipopolysaccharides, and glycoproteins from the bacterium Escherichia coli. Incorporation of two colored fluorescent probes in each of the components allowed fluorescence microscopy to visualize and demonstrate coassembly and the incorporation of functional membrane channels. Importantly, the hybrid vesicles bind a human galectin, consistent with the display of sugar moieties from lipopolysaccharides or possibly glycosylated membrane proteins. The present coassembly method is likely to create cell-like hybrids from any biological membrane including human cells and thus may enable practical application in nanomedicine.

Published

2016