Progress in the Correlative Atomic Force Microscopy and Optical Microscopy

Zhou, Lulu; Cai, Mingjun; Tong, Ti

doi:10.3390/s17040938

Cited by 46 publications

(37 citation statements)

References 74 publications

(101 reference statements)

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“…20,24,27 While not attaining the resolution of AFM, fluorescence microscopy provides high detection selectivity enabled by fluorescence tagging. 28 Correlative AFM and fluorescence microscopy can localize NPs in relation to other fluorescently tagged biomolecules with very high spatial resolution and detection selectivity. The correlative approach has been used to characterize phase segregation in SLBs 29,30 and membrane restructuring due to the addition of ceramide, 31,32 as well as to study the impact of 2,4-dichlorophenoxyacetic acid on bacterial, fungal, and human cells 33 and localize labeled fusion proteins within mammalian cells.…”

Section: Introductionmentioning

confidence: 99%

Preferential interactions of primary amine-terminated quantum dots with membrane domain boundaries and lipid rafts revealed with nanometer resolution

Mensch

Melby

Laudadio

et al. 2020

Environ. Sci.: Nano

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The initial interactions of engineered nanoparticles (NPs) with living cells are governed by physicochemical properties of the NP and the molecular composition and structure of the cell membrane. Eukaryotic cell membranes contain lipid raftsliquid-ordered nanodomains involved in membrane trafficking and molecular signaling. However, the impact of these membrane structures on cellular interactions of NPs remains unclear.Here we investigate the role of membrane domains in the interactions of primary amine-terminated quantum dots (Qdots) with liquid-ordered domains or lipid rafts in model membranes and intact cells, respectively.Using correlative atomic force and fluorescence microscopy, we found that the Qdots preferentially localized to boundaries between liquid-ordered and liquid-disordered phases in supported bilayers. The Qdots also induced holes at these phase boundaries. Using super resolution fluorescence microscopy (STORM), we found that the Qdots preferentially co-localized with lipid rafts in the membrane of intact trout gill epithelial cellsa model cell type for environmental exposures. Our observations uncovered preferential interactions of amineterminated Qdots with liquid-ordered domains and their boundaries, possibly due to membrane curvature at phase boundaries creating energetically favorable sites for NP interactions. The preferential interaction of the Qdots with lipid rafts supports their potential internalization via lipid raft-mediated endocytosis and interactions with raft-resident signaling molecules.The initial interactions of engineered nanoparticles (NPs) at the cell membrane govern NP internalization and impact on cellular functions. These interactions depend on physicochemical properties of the NP and the molecular structure of the cell membrane. Liquid-ordered domains, or lipid rafts, are key structures in eukaryotic cell membranes but their role in NP interactions is unclear. We focus on quantum dots (Qdots)technologically relevant NPs with broad applications and concerns over their environmental release. We show that primary amine-terminated Qdots preferentially interact with liquidordered domain boundaries in bilayers and with lipid rafts in intact cells. These findings shed new light on mechanisms underlying NP-cell interactions and ultimately contribute to predictive evaluations of environmental health and safety for the use of NPs.

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Section: Introductionmentioning

confidence: 99%

Preferential interactions of primary amine-terminated quantum dots with membrane domain boundaries and lipid rafts revealed with nanometer resolution

Mensch

Melby

Laudadio

et al. 2020

Environ. Sci.: Nano

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“…Current research mainly is focused on the understanding of biological processes at the nanoscale, as recognition of molecules and their properties with no labeling and the interaction among them [22][23][24]. This mini review revealed that only few papers deals with inner cell structure in situ.…”

Section: Discussionmentioning

confidence: 99%

Visualization of Cell Structure by Atomic Force Microscopy

García¹

2017

MOJAP

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Cell structure has been extensively studied by light and electron microscopy. However, there are relatively few papers on the study of internal cell structure with the atomic force microscope. In this mini review, efforts to visualize and analyze inner cell structure with the atomic force microscope are here presented, using the technique for sample preparation derived from the standard transmission electron microscopy. Semithin sections of epon embedded samples mounted on glass slides are scanned with a microscope working on contact or intermittent modes. The surface of sections revealed internal cell structure. Animal and plant cells show structures as nuclei, nucleoli, chromatin, cell wall, mitochondria. These works opens up the perspective to analyze these organelles and structures at a nanoscale under liquid physiological conditions.

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“…Sample preparation procedures for exvivo microscopy differ substantially across the technologies and even within a modality; AFM images alone, for example, can be acquired under various conditions (vacuum, atmosphere, and liquid). Correlative imaging usually requires modality-specific preparation and setup trade-offs, such as between preservation of fluorescence and subcellular architecture for CLEM, between the AFM laser and excitation spectra of the used fluorophores to avoid bleaching for correlative AFM [78], or between preservation of fluorescence and X-ray contrast for correlative CT. Dependent on the used technology, the sample preparation needs to be adapted.…”

Section: Novel CMI Pipelinesmentioning

confidence: 99%