Diatom Microscopy. Группа авторов

Diatom Microscopy - Группа авторов


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chlorophyll is commonly used as a contrast agent for imaging cell structures and evaluating cell toxicity. Two photon-excited fluorescent lifetime imaging (FLIM) can be used to assess the toxic effects of Thalasiosira weissflogii quickly and easily based on a statistical analysis of chlorophyll fluorescence decay (i.e., fluorescence lifetime change). By studying the fluorescence quenching of chlorophyll induced by the infrared two-photon excitation laser, the assessment of cadmium (Cd) toxicity based on the quenching effects can be well quantified and monitored. The characteristics of chlorophyll fluorescence in the time-domain could potentially be used as biomarkers to detect Cd toxicity levels without harming algae cells [1.75].

Schematic illustration of (a) Asterionellopsis glacialis and (b) Proboscia alata captured using a confocal multiphoton microscope. Schematic illustration of (a) Average fluorescence lifetime images of T. weissflogii exposed to different concentrations of MeHg; (b) Histogram analysis of fluorescence lifetime distributions; (c) Box analysis of fluorescence lifetime.

      Diatoms have also proven highly effective in the production of petroleum substitutes and bioactive compounds. Researchers have developed an effective method referred to as intracellular spectral recompositioning (ISR) in which the absorption of blue light and intracellular emissions in the green spectral band enhance the utilization of light by the organisms. In Phaeodylum tricornutum diatoms, ISR can be chemogenically used with lipophilic fluorophores, or biogenically used to enhance the expression of green fluorescent protein (eGFP). In laboratory testing under simulated outdoor sunlight conditions, the biomass production of eGFP was 50% higher than that of the wild-type parental strain. Chlorophyll autofluorescence and eGFP fluorescence were detected via multiphoton excitation using a laser scanning microscope (FV1000, Olympus) [1.20].

      Due to the nature of light diffraction, the image resolution of confocal microscopy is limited to roughly 250 nm, which makes it difficult to visualize silica-embedded proteins (ranging from ten to several hundred nanometers) via live-cell imaging. Super-resolution optical microscopy based on photoswitchable fluorescent proteins makes it possible to determine with a high degree of precision the location of proteins at the single-molecule level. Fusion proteins with silaffin-3 (tpSil3) are embedded in biosilica and permanently entrapped inside the valve region during biosilica formation [1.50]. PALM super-resolution optical imaging involves the expression of fusion proteins with photoswitchable fluorescent proteins, which can prevent the problem of silica limiting antibody access to the protein(s) of interest in STORM. Genetic transformation facilitates live-cell imaging of proteins associated with the cell wall, thereby making it possible to use the expression of GFP fusion proteins in Thalassiosira pseudonana to localize distinct regions of biosilica. Gröger et al. [1.22] used the inherently high labeling density of PALM to study proteins in diatom biosilica.


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