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In Vitro Evaluation of Bacterial Killing by Neonatal Mouse Splenic Phagocytes

作者：

简介：

Overview

This article describes a method for isolating and analyzing neutrophils and inflammatory monocytes from neonatal mouse spleens. The protocol includes steps for cell dissociation, magnetic bead sorting, and bacterial internalization assays.

Key Study Components

Area of Science

Immunology
Cell Biology
Microbiology

Background

Neutrophils and monocytes play crucial roles in the immune response.
Understanding their function in bacterial clearance is essential for immunological research.
Isolation techniques are vital for studying these cells in vitro.
Phagocytosis is a key mechanism by which these cells eliminate pathogens.

Purpose of Study

To develop a reliable method for isolating neutrophils and inflammatory monocytes from mouse spleens.
To assess the ability of these cells to internalize and kill bacteria.
To provide a detailed protocol for researchers in the field.

Methods Used

Mechanical dissociation of spleens to create a single-cell suspension.
Use of lysis buffer to remove erythrocytes from the suspension.
Magnetic bead sorting to isolate specific cell types.
In vitro assays to measure bacterial internalization and killing.

Main Results

Successful isolation of Ly6 B2 positive cells from spleen tissue.
Demonstrated phagocytosis of luminescent bacteria by neutrophils and monocytes.
Quantitative assessment of bacterial killing through luminescence measurements.
Validated the effectiveness of the isolation and assay methods.

Conclusions

The described methods provide a robust approach for studying immune cell functions.
Insights gained can enhance understanding of host-pathogen interactions.
This protocol can be adapted for various experimental setups in immunology.

Frequently Asked Questions

What is the significance of isolating neutrophils and monocytes?

Isolating these cells allows researchers to study their specific roles in the immune response and their mechanisms of action against pathogens.

How does the magnetic bead sorting work?

Magnetic bead sorting utilizes antibodies attached to beads that bind to specific cell surface markers, allowing for the separation of target cells from a mixture.

What are the key steps in the bacterial killing assay?

The key steps include incubating immune cells with bacteria, replacing media to eliminate non-internalized bacteria, and measuring luminescence to assess bacterial killing.

Can this method be applied to other cell types?

Yes, the protocol can be adapted for isolating and studying other immune cell types with appropriate modifications.

What are the limitations of this study?

Limitations may include the specificity of the antibodies used for sorting and the in vitro nature of the assays, which may not fully replicate in vivo conditions.

How can the results be quantified?

Results can be quantified using a plate reader to measure luminescence, which correlates with the level of bacterial internalization and killing.

Begin by mechanically dissociating neonatal mouse spleens to generate a single-cell suspension.

Transfer the suspension to a tube, centrifuge, and remove the supernatant.

Resuspend the pellet in lysis buffer to eliminate erythrocytes.

Add buffer, centrifuge again, and remove the supernatant.

Resuspend the cells in buffer and incubate with antibody-coated magnetic microbeads targeting a receptor expressed on neutrophils and inflammatory monocytes.

Centrifuge and remove the unbound beads. Add buffer, then pass the suspension through a ferromagnetic column and apply a magnetic field to retain the bead-bound cells.

Remove the magnetic field, elute the cells with buffer, and seed them into a multi-well plate.

Add increasing concentrations of luminescent bacteria to selected wells.

Incubate to allow neutrophils and monocytes to internalize the bacteria by phagocytosis.

Replace the media with antibiotic-containing media to eliminate non-internalized bacteria.

Record luminescence at regular intervals to assess bacterial internalization and subsequent killing induced by phagocytosis.

To perform an in vitro bacterial killing assay, place the uninfected spleen into a 40-micrometer nylon strainer within a sterile 60-millimeter Petri dish containing 5 milliliters of PBS supplemented with 10% fetal bovine serum, and use a sterile 3 milliliter syringe plunger to disaggregate the tissue into a single cell suspension. Transfer the cells to a 15 milliliter centrifuge tube and collect them by centrifugation. Resuspend the pellet in 1 milliliter of red blood cell lysis buffer per 3 to 4 spleens.

After 5 minutes at room temperature, wash the spleens in PBS and resuspend the pellet in 250 microliters of PBS supplemented with bovine serum albumin and 2 millimolar EDTA for counting. Next, isolate the Ly6 B2 positive cells with the appropriate immunomagnetic beads according to manufacturer's protocol and seed the enriched Ly6 B2 positive cells at a 1 times 10 to the 5 cells per 100 microliters of complete medium per well density in a black or white 96-well plate. Prepare the bacterial inoculum at the desired multiplicity of infection in a final volume of 100 microliters per well and add 100 microliters of bacterial inoculum or medium alone to each well, for a 1 hour incubation in the cell culture incubator.

At the end of the incubation, replace the medium with 200 microliters of fresh complete medium supplemented with 100 micrograms per milliliter of gentamicin to remove any remaining extracellular bacteria and return the cells to the cell culture incubator for an additional 2 hours. At the end of the incubation and at each experimental time point thereafter, use a plate reader to measure the luminescence in each well of the lidded culture plate before returning the plate to the cell culture incubator until the next reading.

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