Sagana Thamboo scite author profile

Subcellular compartmentalization of cells, a defining characteristic of eukaryotes, is fundamental for the fine tuning of internal processes and the responding to external stimuli. Reproducing and controlling such compartmentalized hierarchical organization, responsiveness, and communication is important toward understanding biological systems and applying them to smart materials. Herein, a cellular signal transduction strategy (triggered release from subcompartments) is leveraged to develop responsive, purely artificial, polymeric multicompartment assemblies. Incorporation of responsive nanoparticles-loaded with enzymatic substrate or ion channels-as subcompartments inside micrometersized polymeric vesicles (polymersomes) allowed to conduct bioinspired signaling cascades. Response of these subcompartments to an externally added stimulus is achieved and studied by using confocal laser scanning micro scopy (CLSM) coupled with in situ fluorescence correlation spectroscopy (FCS). Signal triggered activity of an enzymatic reaction is demonstrated in multicompartments through recombination of compartmentalized substrate and enzyme. In parallel, a two-step signaling cascade is achieved by triggering the recruitment of ion channels from inner subcompartments to the vesicles' membrane, inducing ion permeability, mimicking endosome-mediated insertion of internally stored channels. This design shows remarkable versatility, robustness, and controllability, demonstrating that multicompartment polymer-based assemblies offer an ideal scaffold for the development of complex cell-inspired responsive systems for applications in biosensing, catalysis, and medicine.

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Biopores/membrane proteins in synthetic polymer membranes

Garni

Thamboo

Schoenenberger

et al. 2017

Biochimica et Biophysica Acta (BBA) - Biomembranes

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Multicompartment Polymer Vesicles with Artificial Organelles for Signal‐Triggered Cascade Reactions Including Cytoskeleton Formation

Belluati

Thamboo

Najer

et al. 2020

Adv Funct Materials

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Organelles, i.e., internal subcompartments of cells, are fundamental to spatially separate cellular processes, while controlled intercompartment communication is essential for signal transduction. Furthermore, dynamic remodeling of the cytoskeleton provides the mechanical basis for cell shape transformations and mobility. In a quest to develop cell‐like smart synthetic materials, exhibiting functional flexibility, a self‐assembled vesicular multicompartment system, comprised of a polymeric membrane (giant unilamellar vesicle, GUV) enveloping polymeric artificial organelles (vesicles, nanoparticles), is herein presented. Such multicompartment assemblies respond to an external stimulus that is transduced through a precise sequence. Stimuli‐triggered communication between two types of internal artificial organelles induces and localizes an enzymatic reaction and allows ion‐channel mediated release from storage vacuoles. Moreover, cytoskeleton formation in the GUVs' lumen can be triggered by addition of ionophores and ions. An additional level of control is achieved by signal‐triggered ionophore translocation from organelles to the outer membrane, triggering cytoskeleton formation. This system is further used to study the diffusion of various cytoskeletal drugs across the synthetic outer membrane, demonstrating potential applicability, e.g., anticancer drug screening. Such multicompartment assemblies represent a robust system harboring many different functionalities and are a considerable leap in the application of cell logics to reactive and smart synthetic materials.

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Antioxidant functionalized polymer capsules to prevent oxidative stress

et al. 2018

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Analysis of Molecular Parameters Determining the Antimalarial Activity of Polymer‐Based Nanomimics

Najer

Thamboo

Duskey

et al. 2015

Macromol. Rapid Commun.

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Malaria and other infectious diseases are major global public health problems, which need to be tackled using new technologies to cope with the lack of efficacious vaccines and emerging drug resistance. A recently developed anti-infectious concept based on nanomimics tested with Plasmodium falciparum is analyzed for the molecular parameters determining its applicability. Nanomimics-nanoscaled polymer-based mimics of host cell membranes-are designed with a reduced number of surface-exposed malaria parasite receptor molecules (heparin), resulting in less potent invasion inhibition as determined in antimalarial assays. In contrast, when shorter receptor molecules are used to form nanomimics, more molecules are needed to obtain nanomimic potency similar to nanomimics with longer receptor molecules. The interaction of heparin on nanomimics with the processed Plasmodium falciparum merozoite surface protein 1-42 (PfMSP1 ) have a high affinity, K = 12.1 ± 1.6 × 10 m, as measured by fluorescence cross-correlation spectroscopy (FCCS). This detailed characterization of nanomimics and their molecular variants are an important step towards defining and optimizing possible nanomimic therapies for infectious diseases.

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Sagana Thamboo

Mimicking Cellular Signaling Pathways within Synthetic Multicompartment Vesicles with Triggered Enzyme Activity and Induced Ion Channel Recruitment

Biopores/membrane proteins in synthetic polymer membranes

Multicompartment Polymer Vesicles with Artificial Organelles for Signal‐Triggered Cascade Reactions Including Cytoskeleton Formation

Antioxidant functionalized polymer capsules to prevent oxidative stress

Analysis of Molecular Parameters Determining the Antimalarial Activity of Polymer‐Based Nanomimics

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