Most microorganisms possess a negative surface charge under physiological conditions due to the presence
of anionic carboxyl and phosphate groups. Cell surface charge plays an important role in controlling cell
adhesion and aggregation phenomena, as well as antigen−antibody, cell−virus, cell−drug, and cell−ions
interactions. We have used atomic force microscopy (AFM) with chemically functionalized probes to
investigate the surface charges of yeast cells. Force−distance curves and adhesion maps recorded with
probes terminated with ionizable carboxyl groups were strongly influenced by pH: while no adhesion was
measured at neutral/alkaline pH, multiple adhesion forces were recorded at pH ≤ 5. Three pieces of
evidence indicated that these changes were related to differences in the ionization state of the cell surface
functional groups. First, the adhesion force vs pH curve was correlated with microelectrophoresis data,
the pH of the largest adhesion force corresponding to the cell isoelectric point, i.e., pH 4. Second, treating
the cells with Cu(II) ions caused a reversal of the cell surface charge at neutral pH and promoted the
adhesion toward the negatively charged probe. Third, control experiments using nonionizable hydroxyl-terminated probes indicated that the changes in adhesion forces were not simply due to the titration of
the probe surface charges. This study shows that AFM with chemically modified probes is a valuable
approach in microbiology and biophysics for probing the local electrostatic properties of microbial cell
surfaces.
Notch signaling is repeatedly used during animal development to specify cell fates. Using atomic force microscopy on live cells, chemical inhibitors, and conventional analyses, we show that the rate of Notch signaling is linked to the adhesion force between cells expressing Notch receptors and Delta ligand. Both the Notch extracellular and intracellular domains are required for the high adhesion force with Delta. This high adhesion force is lost within minutes, primarily due to the action of Presenilin on Notch. Reduced turnover or Delta pulling accelerate this loss. These data suggest that strong adhesion between Notch and Delta might serve as a booster for initiating Notch signaling at a high rate.
The concentrations of elements or functions ratioed to total carbon can be modeled on the basis of the known composition of model biochemical compounds, which leads to an evaluation of the surface composition expressed in wt% of these classes of compounds. Thereby, it was shown that surface accumulation, as compared to the bulk, increases in the order proteins < NL < PL. Moreover, the surface enrichment of PL compared to triglycerides was found to be increased after baking.
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