A novel flow cytometric assay for measurement of In Vivo pulmonary neutrophil phagocytosis

A novel method based on the intracellular conjugation of the fluorescent probe 5 (and 6-)-carboxyfluorescein succinimidyl ester (cFSE) was developed to determine the intracellular pH of bacteria. cFSE can be taken up by bacteria in the form of its diacetate ester, 5 (and 6-)-carboxyfluorescein diacetate succinimidyl ester, which is subsequently hydrolyzed by esterases to cFSE in the cytoplasm. When Lactococcus lactis cells were permeabilized with ethanol, a significant proportion of cFSE was retained in the cells, which indicated that cFSE was bound intracellularly. Unbound probe could be conveniently extruded by a short incubation of the cells in the presence of a fermentable sugar, most likely by exploiting an active transport system. Such a transport system for cFSE was identified in L. lactis, Listeria innocua, and Bacillus subtilis. The intracellular pH in bacteria can be determined from the ratio of the fluorescence signal at the pH-sensitive wavelength (490 nm) and the fluorescence signal at the pH-insensitive wavelength (440 nm). This cFSE ratio method significantly reduced problems due to the efflux of fluorescent probe from the cells during the measurement. Moreover, the method described was successfully used to determine the intracellular pH in bacteria under stress conditions, such as elevated temperatures and the presence of detergents.

This paper reviews a variety of methods available for quantifying phagocytosis and bacterial killing by neutrophils. We outline the advantages and disadvantages of each technique, with the selection of a technique for research or analytical purposes being dependent on the information required and the resources available. A detailed protocol is provided for a comprehensive microbiological technique that measures both phagocytosis and killing in a single assay, along with a kinetic analysis for measuring and calculating separate rate constants for the two events. The kinetic analysis can be easily adapted to other methods to give the same quantitative information.

One of the challenges of phagocytosis research is to differentiate bacteria adherent to a host cell from bacteria which the cell has internalized. To address this question, various techniques such as fluorescence microscopy, electron microscopy, and flow cytometry have been used. We have adapted a flow cytometric method (Fattorossi et al., 1989) to use fluorescence microscopy for studying phagocytosis of fluorescein-labeled Listeria by inflammatory mouse peritoneal macrophages. In this assay, ethidium bromide is used as a quenching agent and is added to cells after they have phagocytosed labeled bacteria. Ethidium bromide causes extracellular FITC-labeled Listeria to fluoresce red-orange, whereas intracellular bacteria are not exposed to the dye and remain green. This process allows distinction between intracellular and extracellular bacteria by simultaneous visualization of both populations.