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1. Simultaneous mapping of nanoscale topography and surface potential of charged surfaces by scanning ion conductance microscopy

   https://doi.org/10.1039/D0NR04555A  

   Chen, Feng; Panday, Namuna; Li, Xiaoshuang; Ma, Tao; Guo, Jing; Wang, Xuewen; Kos, Lidia; Hu, Ke; Gu, Ning; He, Jin (October 2020, Nanoscale)

   null (Ed.)

   Scanning ion conductance microscopy (SICM) offers the ability to obtain nanoscale resolution images of the membranes of living cells. Here, we show that a dual-barrel nanopipette probe based potentiometric SICM (P-SICM) can simultaneously map the topography and surface potential of soft, rough and heterogeneously charged surfaces under physiological conditions. This technique was validated and tested by systematic studies on model samples, and the finite element method (FEM) based simulations confirmed its surface potential sensing capability. Using the P-SICM method, we compared both the topography and extracellular potential distributions of the membranes of normal (Mela-A) and cancerous (B16) skin cells. We further monitored the structural and electrical changes of the membranes of both types of cells after exposing them to the elevated potassium ion concentration in extracellular solution, known to depolarize and damage the cell. From surface potential imaging, we revealed the dynamic appearance of heterogeneity of the surface potential of the individual cell membrane. This P-SICM method provides new opportunities to study the structural and electrical properties of cell membrane at the nanoscale. 

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2. Engineered molecular sensors for quantifying cell surface crowding

   https://doi.org/10.1073/pnas.2219778120  

   Takatori, Sho C.; Son, Sungmin; Lee, Daniel S.; Fletcher, Daniel A. (May 2023, Proceedings of the National Academy of Sciences)

   Cells mediate interactions with the extracellular environment through a crowded assembly of transmembrane proteins, glycoproteins and glycolipids on their plasma membrane. The extent to which surface crowding modulates the biophysical interactions of ligands, receptors, and other macromolecules is poorly understood due to the lack of methods to quantify surface crowding on native cell membranes. In this work, we demonstrate that physical crowding on reconstituted membranes and live cell surfaces attenuates the effective binding affinity of macromolecules such as IgG antibodies in a surface crowding-dependent manner. We combine experiment and simulation to design a crowding sensor based on this principle that provides a quantitative readout of cell surface crowding. Our measurements reveal that surface crowding decreases IgG antibody binding by 2 to 20 fold in live cells compared to a bare membrane surface. Our sensors show that sialic acid, a negatively charged monosaccharide, contributes disproportionately to red blood cell surface crowding via electrostatic repulsion, despite occupying only ~1% of the total cell membrane by mass. We also observe significant differences in surface crowding for different cell types and find that expression of single oncogenes can both increase and decrease crowding, suggesting that surface crowding may be an indicator of both cell type and state. Our high-throughput, single-cell measurement of cell surface crowding may be combined with functional assays to enable further biophysical dissection of the cell surfaceome. 

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3. Engineering Functional Membrane–Membrane Interfaces by InterSpy

   https://doi.org/10.1002/smll.202202104  

   Moghimianavval, Hossein; Patel, Chintan; Mohapatra, Sonisilpa; Hwang, Sung‐Won; Kayikcioglu, Tunc; Bashirzadeh, Yashar; Liu, Allen P.; Ha, Taekjip (May 2022, Small)

   Abstract Engineering synthetic interfaces between membranes has potential applications in designing non‐native cellular communication pathways and creating synthetic tissues. Here, InterSpy is introduced as a synthetic biology tool consisting of a heterodimeric protein engineered to form and maintain membrane–membrane interfaces between apposing synthetic as well as cell membranes through the SpyTag/SpyCatcher interaction. The inclusion of split fluorescent protein fragments in InterSpy allows tracking of the formation of a membrane–membrane interface and reconstitution of functional fluorescent protein in the space between apposing membranes. First, InterSpy is demonstrated by testing split protein designs using a mammalian cell‐free expression (CFE) system. By utilizing co‐translational helix insertion, cell‐free synthesized InterSpy fragments are incorporated into the membrane of liposomes and supported lipid bilayers with the desired topology. Functional reconstitution of split fluorescent protein between the membranes is strictly dependent on SpyTag/SpyCatcher. Finally, InterSpy is demonstrated in mammalian cells by detecting fluorescence reconstitution of split protein at the membrane–membrane interface between two cells each expressing a component of InterSpy. InterSpy demonstrates the power of CFE systems in the functional reconstitution of synthetic membrane interfaces via proximity‐inducing proteins. This technology may also prove useful where cell‐cell contacts and communication are recreated in a controlled manner using minimal components. 

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4. Multicolor polymeric carbon dots: synthesis, separation and polyamide-supported molecular fluorescence

   https://doi.org/10.1039/D0SC05743F  

   Haynes, Christy; Frank, Benjamin; Kappel, Elaine; Nishimoto, Yoshio; Hamers, Robert; Niehaus, Thomas A; Trerayapiwat, Kasidet; Duchimaza-Heredia, Jaun; Fairbrother, Howard; Deng, Jiahua; et al (January 2021, Chemical Science)

   null (Ed.)

   Multicolor carbon dots (CDs) have been developed recently and demonstrate great potential in bio-imaging, sensing, and LEDs. However, the fluorescence mechanism of their tunable colors is still under debate, and efficient separation methods are still challenging. Herein, we synthesized multicolor polymeric CDs through solvothermal treatment of citric acid and urea in formamide. Automated reversed-phase column separation was used to achieve fractions with distinct colors, including blue, cyan, green, yellow, orange and red. This work explores the physicochemical properties and fluorescence origins of the red, green, and blue fractions in depth with combined experimental and computational methods. Three dominant fluorescence mechanism hypotheses were evaluated by comparing time-dependent density functional theory and molecular dynamics calculation results to measured characteristics. We find that blue fluorescence likely comes from embedded small molecules trapped in carbonaceous cages, while pyrene analogs are the most likely origin for emission at other wavelengths, especially in the red. Also important, upon interaction with live cells, different CD color fractions are trafficked to different sub-cellular locations. Super-resolution imaging shows that the blue CDs were found in a variety of organelles, such as mitochondria and lysosomes, while the red CDs were primarily localized in lysosomes. These findings significantly advance our understanding of the photoluminescence mechanism of multicolor CDs and help to guide future design and applications of these promising nanomaterials. 

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5. Label-free imaging of fibroblast membrane interfaces and protein signatures with vibrational infrared photothermal and phase signals

   https://doi.org/10.1364/BOE.411888  

   Samolis, Panagis_D; Langley, Daniel; O’Reilly, Breanna_M; Oo, Zay; Hilzenrat, Geva; Erramilli, Shyamsunder; Sgro, Allyson_E; McArthur, Sally; Sander, Michelle_Y (December 2020, Biomedical Optics Express)

   Label-free vibrational imaging of biological samples has attracted significant interest due to its integration of structural and chemical information. Vibrational infrared photothermal amplitude and phase signal (VIPPS) imaging provide label-free chemical identification by targeting the characteristic resonances of biological compounds that are present in the mid-infrared fingerprint region (3 µm - 12 µm). High contrast imaging of subcellular features and chemical identification of protein secondary structures in unlabeled and labeled fibroblast cells embedded in a collagen-rich extracellular matrix is demonstrated by combining contrast from absorption signatures (amplitude signals) with sensitive detection of different heat properties (lock-in phase signals). We present that the detectability of nano-sized cell membranes is enhanced to well below the optical diffraction limit since the membranes are found to act as thermal barriers. VIPPS offers a novel combination of chemical imaging and thermal diffusion characterization that paves the way towards label-free imaging of cell models and tissues as well as the study of intracellular heat dynamics. 

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