Characterization and Isolation of Mouse Primary Microglia by Density Gradient Centrifugation

Podsumowanie

A protocol for the isolation of primary microglia from murine brains is presented. This technique aids in furthering the current understanding of neurological conditions. Density gradient centrifugation and magnetic separation are combined to produce sufficient yield of a highly pure sample. Furthermore, we outline the steps for characterization of microglia.

Streszczenie

Microglia, the resident immune cells in the brain, are the first responders to inflammation or injury in the central nervous system. Recent research has revealed microglia to be dynamic, capable of assuming both pro-inflammatory and anti-inflammatory phenotypes. Both M1 (pro-inflammatory) and M2 (pro-reparative) phenotypes play an important role in neuroinflammatory conditions such as perinatal brain injury, and exhibit differing functions in response to certain environmental stimuli. The modulation of microglial activation has been noted to confer neuroprotection thus suggesting microglia may have therapeutic potential in brain injury. However, more research is required to better understand the role of microglia in disease, and this protocol facilitates that. The protocol described below combines a density gradient centrifugation process to reduce cellular debris, with magnetic separation, producing a highly pure sample of primary microglial cells that can be used for in vitro experimentation, without the need for 2-3 weeks culturing. Additionally, the characterization steps yield robust functional data about microglia, aiding studies to better our understanding of the polarization and priming of these cells, which has strong implications in the field of regenerative medicine.

Wprowadzenie

Damage acquired during the perinatal period from inflammation, hypoxic-ischaemia and haemorrhage can have an array of long term sequelae. The complex pathophysiology of perinatal brain injury is theorized to involve inflammation and ischemia with ensuing neuronal and axonal death¹. The innate immune response plays an important role in the cascade of events leading to injury².

Microglia, the resident immune cells within the central nervous system (CNS), are the first responders to injury³. Microglia are plastic cell types with the capacity to be both protective or toxic, dependent on the environment⁴. They are involved in chemotaxis, phagocytosis, antigen presentation and production of cytokines and reactive oxygen species^4,5. Senescent microglia constantly survey the environment and are activated by the presence of a foreign or harmful substance⁴. Activation leads to a pro-inflammatory response, critical in CNS protection⁴. These M1 "pro-inflammatory" phenotype microglia are primarily involved in antigen presentation and death of pathogens⁴. Despite the crucial role of the inflammatory response in neuroprotection, uncontrolled or prolonged inflammation can be harmful and lead to neuronal damage⁴. However, when exposed to certain environmental stimuli, microglia can exhibit an anti-inflammatory phenotype. These pro-reparative M2 microglia have a critical role in wound healing and repair⁶, releasing a range of cytokines and other soluble mediators that downregulate inflammation, increase phagocytosis and promote repair^4,7. The roles of microglia are diverse and include driving oligodendrocyte differentiation during re-myelination⁸, protecting neurons during oxygen and glucose depletion in stroke models⁹ and promoting neurite outgrowth in spinal cord injury models¹⁰.

The study of these glial cells represents an important aspect in understanding and manipulating the response to neuroinflammation. The described protocol allows for further investigation into the therapeutic potential of microglia modulation in neuroinflammatory disorders.

The modulation of microglial activation towards a neuroprotective role has been observed in a range of conditions^11,12,13. Thus, improving current understanding and further studying modulation of microglial activation is critical, requiring the use of various models including both in vitro and in vivo. In vitro studies represent an important tool due to their greater efficiency, lower cost and ability to investigate an isolated cell population.

There are a range of protocols described in the literature for the isolation of microglia from murine brains, the challenge to efficiently produce a high yield sample with good viability and high purity. Commonly used methods of isolation of primary microglia are by magnetic separation and prolonged shaking of mixed glial cultures. Through personal experience, it was found that there was a high degree of cellular debris which obstructed the magnetic column. Thus, the following protocol was utilized, which incorporates an initial density gradient centrifugation step followed by CD11b magnetic separation. The protocol described below has been optimized to produce a highly pure sample in sufficient quantity. It is advantageous due to its high purity and the short time period — one can perform assays within 2 days without having to culture for 2-3 weeks. This protocol can potentially be adapted for the isolation of primary murine astrocytes.

Protokół

The following procedures have been approved by the Animal Ethics Committee at the Monash University. Healthy untreated neonate C57Bl6/J P3-6 mice were used to generate the representative results.

1. Enzymatic Digestion

NOTE: It is important to consider sterility when isolating and culturing primary cells. Whilst ensuring the environment is as sterile as possible, the initial dissection and harvest of murine brains can be completed outside of a laminal flow hood, with all subsequent steps performed within a laminar flow hood.

1. Using sterile instruments, euthanize the mouse by cervical dislocation, decapitate the animal and rinse with 100% ethanol. Using small sterile scissors, make small incisions along the right and left sides of the head. At this age, the skin peels away easily. Using the tips of the curved forceps, gently slide the tissue towards the rostrum to expose the skull, including the Bregma.
2. Insert the tip of scissors in the opening of the spinal canal and make a lateral incision to the ear canal. Make an incision along the sagittal suture to the Bregma, gently pointing the tip of the scissors upwards to prevent damaging the brain. Insert tip of scissors at Bregma and make lateral incisions to the right and left sides of the head along the coronal suture.
3. Using forceps, gently peel away the skull to expose the brain. To do so, grasp the edges of skull exposed by the lateral incision, and gently pull the skull to the side. The skull should peel away easily. Using curved forceps, gently scoop under the brain to remove it.
4. Place the brain in a 5 mL sterile container, wash 2-3 times with ice-cold wash media (low glucose Dulbecco's Modified Eagle Medium (DMEM) supplemented with 1% penicillin-streptomycin), approximately 5 mL media per wash, to remove blood.
5. In a laminar airflow hood, place the contents of the 5 mL container in a small petri dish (35 mm), resting on ice. Using a sterile scalpel blade or sterile scissors, remove the cerebellum and olfactory bulb. Make a midline cut to separate the two hemispheres.
6. Carefully peel away the meningeal layer with fine forceps, taking care not to damage the cortices. Identify the meningeal layer as a very thin layer of cells with a red tinge on the surface of the brain, with visible blood vessels. Keeping the brain cold is essential for proper meninges removal. If the meningeal layer breaks, continue peeling away the torn fragments until it is completely removed.
7. Transfer the hemispheres to a new small petri dish (on ice) and fill with wash media. Chop the brain into small pieces with sterile scalpel blade/scissors.
   NOTE: These should be ~1 mm² in size, and care should be taken not to cut them into too small pieces as this may reduce yield.
8. Add 100 µL papain (17 U/mg stock) and 150 µL DNase I into the media and incubate for 30 min at 37 °C
9. Following digestion, triturate tissue using a P1000 pipette. If tissue pieces are too large to enter the pipette, consider using a pair or sterile scissors to widen the pipette tip. During this process, take care not to introduce bubbles into the media as this may reduce cell viability.

2. Myelin Debris Removal

1. Under a laminar flow hood use sterile equipment, prepare a 50-mL conical tube with a 100 µm cell strainer, for each brain. Pour contents of the petri dish, containing the digest medium and brain pieces onto a strainer. Push through the pieces of brain by using the plunger of a sterile 3 mL syringe in a grinding motion until there is no more tissue visible. Following digestion, the brain tissue should fall apart easily.
2. Continuously wash the filter with the wash media, by topping up the cell strainer throughout this process. This will wash through any cells trapped in the strainer.
   NOTE: This should be done until there is approximately ~15 mL in the tube. This is to ensure that the strainer is sufficiently washed through and to maximize the amount of cells collected.
3. Centrifuge the single cell suspension at 500 x g for 5 min at 4 °C. During this time, prepare the density gradient medium as described.
   1. Prepare the stock isotonic percoll (SIP), which is the density gradient medium used. Do this by adding 9:1 ratio of density gradient medium to 10x sterile Hanks balanced salt solution (HBSS).
   2. Prepare gradients as 30% SIP in DMEM and 70% SIP in 1x HBSS. For example, to prepare 10 mL of 30% SIP, add 3 mL of SIP to 7 mL DMEM.
4. Aspirate the supernatant from the conical tubes and resuspend the cell pellet with 8 mL of 30% SIP in DMEM. Transfer the full volume to a fresh 15 mL conical tube.
5. Underlay the 70 % SIP solution. To do so, fill a transfer pipette with 70% SIP and carefully push through the transfer pipette to the bottom of the conical tube. Once the tip is close to the bottom, gently push through the contents of the transfer pipette.
   NOTE: Do this slowly so as not to disrupt the 30/70 interface. There must be a clear line separating the two layers.
6. Centrifuge the SIP layers, including the cells, at 650 x g with brake 0 and acceleration 4, for 25 min at room temperature.
   NOTE: It is essential to complete the spin with brake OFF and to allow the centrifuge to slowly come to a halt, as application of brake will disrupt the interphase and dramatically reduce the cell collection between the SIP layers.
7. Aspirate the cellular debris at the top of the tube, and remove approximately 4 mL media from the top. This will ease the removal of the mononuclear cells in the following step. Using a P1000 pipette, carefully lower the pipette tip towards the interphase. Isolate the mononuclear cells from the 30/70 density gradient medium interface. Collect approximately 3 mL from the cloudy interface and transfer to a new 15 mL conical tube. Following this, dilute the mixture with 9 mL of HBSS to aid removal of the density gradient medium.
8. Centrifuge the diluted density gradient medium interphase, containing the mononuclear cells at 500 x g for 5 min. Aspirate supernatant and resuspend with 1 mL growth medium (DMEM supplemented with 10 % fetal bovine serum and 1% antibiotics). Following this, stain the resuspended cells with trypan blue and perform a cell count using a haemocytometer.

3. Magnetic Activated Cell Sorting

NOTE: These steps are modified from manufacturers' protocol.

1. Centrifuge the collected mononuclear cells at 300 x g for 10 min at 4 °C to remove the growth medium as this will interfere with the magnetic isolation. Using the same cell count obtained from Step 2.8, resuspend at 1 x 10⁸ nucleated cells/mL in PBS (Ca⁺⁺ and Mg⁺⁺ free) containing 2 % FBS and 1 mM EDTA, within a volume range of 0.1-2.5 mL.
2. Add the full volume of nucleated cells in PBS from the previous step to a fresh 5 mL (12 x 75 mm) polystyrene round bottom tube. Add 50 µL CD11b PE labelling reagent per 1 mL of sample. Incubate at room temperature for 15 min protected from light.
3. Add 70 µL of selection cocktail (a combination of monoclonal antibodies against CD11b in PBS) per 1 mL of sample. Incubate at room temperature for 15 min protected from light.
4. Mix magnetic particles by pipetting up and down more than 5 times. Add 50 µL/mL to the sample. Incubate at room temperature for 10 min protected from light.
   NOTE: These particles then form a tetrameric complex with the antibodies and will get attached to the magnetic column.
5. If the total volume of cell mixture is less than 2.5 mL, top up to this volume with PBS (Ca⁺⁺ and Mg⁺⁺ free) containing 2 % FBS and 1 mM EDTA, and mix by gently pipetting 2-3 times. Place the tube (without lid) into the magnet and incubate at room temperature for 5 min.
6. In one continuous motion, fully invert the magnet containing the tube for 2-3 s, pouring off the supernatant. Return the magnet to an upright position, and remove the tube from the magnet. Prepare to wash the remaining cells out from the column.
   NOTE: The supernatant contains unlabelled and unwanted cells, which are removed by inverting the tube while still in the magnet. The tube contains the attached Cd11b⁺ cells.
7. Wash the cells by repeating steps 3.5 and 3.6 twice more. If the sample is greater than 1 mL, a further repeat of steps 3.5 and 3.6 is recommended.
8. Resuspend the cells in a desired growth medium. Rinse the side of the collection vessel as well (e.g. a 15 mL tube) to collect cells from the sides of the tube and maximize yields.

4. Verification of Microglia Purity

NOTE: The primary microglia isolated from 3 L (n = 5 animals total) were verified via fluorescent activated cell sorting (FACS) to determine purity for the representative results.

1. Culture cells in a T-25 flask in the growth medium containing 10% FBS overnight, seeding at a density of 1 - 2 x 10⁶ cells per flask.
2. Wash the cells in the T-25 flasks with PBS 3x for 5 min to remove any remaining growth media which might interfere with the trypsinization.
3. Add 2 mL of 0.25% trypsin to detach the cells from the flasks. Ensure that the volume of trypsin is sufficient to cover the entire surface of the flask. Following gentle swirling of the flask to ensure uniform coverage of trypsin, incubate for 5 min at 37 °C.
4. Quench the trypsinization process by adding 2 mL of growth media containing 10% FBS into the flask.
5. Collect the supernatant containing the trypsinized cells and centrifuge at 500 x g for 5 min at 4 °C to collect cells.
6. Remove the supernatant containing the growth medium and trypsin and resuspend the pellet in 500 μL FACS buffer. Perform the cell count using trypan blue.
7. Centrifuge at 500 x g for 5 min at 4 °C. Perform Fc receptor block by adding 50 μL FACS buffer + 1 μL FcR blocker per 5 x 10⁶ cells. Incubate for 15 min at 4 °C.
   NOTE: The Fc receptor block is a critical step in the staining procedure to prevent non-specific binding of immunoglobulins to Fc receptors in immune cell populations. This blockade does not affect downstream binding of other antibodies.
8. Terminate the blocking process by diluting with 500 μL FACS buffer. Following this, centrifuge the mixture containing the cells at 500 x g for 5 min at 4 °C.
9. Resuspend in fresh 500 μL FACS buffer.
10. Place the majority of cells (e.g. if resuspending the cells in 500 μL of FACS buffer, use 400 μL) into a sample tube. Distribute the remaining cells amongst the control tubes and top up to 100 μL per control tube (e.g. for 6 control tubes, put 16.67 μL into each control tube and top up with 83.33 μL FACS buffer). Make the groups (control tubes in bold) as Unstained, single stained (CD45, CD11b), single live/dead stain, FMOs, and sample tubes.
11. Pellet the cells in all tubes by centrifuging at 500 x g for 5 min at 4 °C.
12. Stain the cells in the tube with 1 μL antibody per 100 μL FACS buffer per 5 x 10⁶ cells. Incubate for 20 min at 4 °C.
    NOTE: Use 50 μL antibody cocktail if less than 2 x 10⁶ cells are used.
13. Wash the cells with 500 μL FACS buffer. Centrifuge the cells at 500 x g for 5 min at 4 °C.
14. Resuspend the cells in 300 μL FACS buffer.
    NOTE: Use ~100 μl if cell count is less than 2 x 10⁶.
15. Using flow cytometry analysis, quantify the cells that are CD45^low and positive for CD11b staining. This percentage corresponds to the isolated primary microglia.

5. Immunohistochemical Staining of Primary Microglia

1. Plate the cells in a 96-well plate at a density of 1 x 10⁵ cells with the growth medium and incubate overnight.
2. Remove the supernatant and wash 3 times with PBS.
3. Fix the cells with 4% paraformaldehyde in PBS for 15 min. Remove the PFA with a P1000 pipette, then wash them 3 times with PBS + 0.1 % Triton-X.
4. Block for non-specific binding with 3% bovine serum albumin for 1 h at room temperature.
5. Incubate with rabbit Iba-1 (1:100) for 24 h at 4 °C. Following this, remove the primary antibody mixture and wash 3 times with PBS.
6. Incubate with secondary anti-rabbit GFP conjugate (1:200) for 1 h at room temperature. Following this, remove the secondary antibody mixture and wash 3 times with PBS.
7. Mount slides with a fluorescent mounting medium and capture images using a fluorescent microscope.

6. Quantification of Microglia Using the pHrodo Assay

NOTE: The pHrodo assay allows for identification of levels of phagocytosis in cultured cells. Upon uptake via endocytosis, internalization into the more acidic environment increases levels of fluorescence of the bioparticle conjugates. Fluorescence levels can then be quantified by FACS. The following steps are modified from manufacturers' protocol.

1. Culture the cells in a T-25 flask in the growth medium overnight, seeding at a density of 1 - 2 x 10⁶ cells per flask. Wash the cells in T-25 flasks with PBS 3 times for 5 min.
2. Detach the cells using 2 mL 0.25% trypsin. Incubate for 5 min at 37 °C.
3. Quench the trypsinisation process by adding 2 mL of growth media containing 10% FBS into the flask.
4. Centrifuge the cell suspension at 500 x g for 5 min at 4 °C to pellet cells.
5. Remove the supernatant and resuspend the pellet containing the primary microglia in culture medium at 10⁶ cells/mL.
   NOTE: Alternatively, plate cells in a 96-well plate at least a day before and aim for 1 x 10⁵ viable cells per well on the day the assay is to be performed.
6. Plate cells into 96-well plate at 1 x 10⁵ cells/well, 100 μL per well. Plate controls and experimental wells in triplicate, and leave one empty well per positive control for a no-cell control background subtraction.
7. Add 100 μL of growth media to the wells left empty for no-cell background subtraction.
   NOTE: Like any other in vitro assay, appropriate controls are vital for the accuracy of the readouts. Alongside the no-cell control (background reading), also include the negative control well (pHrodo conjugate added, but placed on ice).
8. Cover the plate and incubate for 1 h in an incubator with 5 % CO₂ at 37 °C.
9. Prepare experimental wells by adding stimulant and treatment. Add vehicle controls (growth media only) to untreated wells.
   NOTE: Lipopolysaccharide 1 µg/mL [stimulant] and human amnion epithelial cell (hAEC)-conditioned media [treatment] were used to generate the representative results.
10. Thaw a vial of conjugated dye, add 2 mL uptake buffer and briefly vortex. Transfer the tube contents into a clean glass tube and sonicate for 5 min, to ensure that particles are evenly dispersed.
11. Aspirate the culture medium from microplate wells and quickly replace with 100 μL of dye suspension. Cover and incubate at 37 °C for 1 h.
    NOTE: Remember to stain the control tubes as well.
12. Using flow cytometry analysis, quantify cells staining positive for the conjugated pHrodo beads and present as a percentage (of parent) of actively phagocytosing microglia.

7. Quantification of Microglia Apoptosis Following Inflammatory Insult

1. Repeat the steps 1-7 from "Verification of microglia purity" section.
2. Place the majority of cells (e.g. if you resuspended the cells in 500 μL of FACS buffer, use 400 μL) into a sample tube. Distribute the remaining cells amongst the control tubes and top up to 100 μL per control tube (e.g. for 6 control tubes, put 16.67 μL into each control tube and top up with 83.33 μL FACS buffer). Groups (control tubes in bold): Unstained, single stains (AnnexinV, Propidium iodide), single live/dead stain, FMOs, sample tubes.
3. Pellet the cells in all the tubes by centrifuging at 500 x g for 5 min.
4. Incubate with 1 μL antibody/100 μL FACS buffer/5 x 10⁶ cells for 20 min at 4 °C.
   NOTE: Use 50 μL if less than 2 x 10⁶ cells.
5. Wash the cells by adding 500 μL FACS buffer and centrifuge at 500 x g for 5 min.
6. Resuspend the cell pellet in 300 μL FACS buffer.
   NOTE: ~100 μL if cell count is less than 2 x 10⁶.
7. Quantify cells within each quadrant (Q1: necrotic, Q2: late apoptotic, Q3: viable, Q4: early apoptotic).

Wyniki

Using the methods outlined here, pure populations of microglia can be isolated and can be ready for characterization using in vitro and FACS analysis. To begin with, up to 18 animals can be used per cull, with an expected yield of approximately 450,000 - 600,000 microglial cells. It is crucial to first confirm the purity of the isolated cells, and to do so FACS analysis was performed by staining for the two markers CD45 and CD11b. Identification of microglia can prove troublesome...

Dyskusje

Microglia have the ability to be both pro- and anti-inflammatory, altered by environment stimuli. Previous studies have shown the modulation of microglia activation can confer neuroprotection. Their ability to provide protection to neurons and repair injury necessitates more research to further the current understanding of these complex cells. Thus, isolation of high purity primary microglia is an important and useful technique. This is a relatively quick method to obtaining highly pure primary microglia ready for in...

Materiały

Name	Company	Catalog Number	Comments
DMEM, low glucose, pyruvate	Gibco	11885084
Antibiotic-Antimycotic (100X)	Gibco	15240062
DNaseI grade II from bovine pancreas	Sigma-Aldrich	10104159001
Papain from papaya latex, buffered aqeuous solution	Sigma-Aldrich	P3125-100mg
Fetal Bovine Serum, qualified, heat inactivated	Gibco	16140071
Percoll	GE Healthcare	17-0891-01
Hank's Balanced Salt Solution (1X)	Gibco	14175-103
Hank's Balanced Salt Solution (10X)	Gibco	14185052
EasySep Mouse CD11b Positive Selection Kit	StemCell Technologies	18770	EasySep magnet variant
EasySep magnet	StemCell Technologies	18000
EasySep Buffer	StemCell Technologies	20144
Dulbecco's Phosphate buffered saline	Gibco	14040182
Trypsin (2.5%) (10X)	Gibco	15090-046
Purified Rat Anti-Mouse CD16/CD32 (Mouse BD Fc Block™)	BD Biosciences	553141
Falcon 5mL Round Bottom High Clarity PP Test Tube, with Snap Cap, Sterile	Corning	352063
175cm² Angled Neck Cell Culture Flask with Vent Cap	Corning	431080
Lipopolysaccharides from Escherichia coli O127:B8	Sigma-Aldrich	L5024
96 Well TC-Treated Microplates size 96 wells, clear, polystyrene, round bottom	Corning	CLS3799
Paraformaldehyde (powder, 95%)	Sigma-Aldrich	158127
Triton-X	Sigma-Aldrich	X100
Rabbit Anti-Iba1	Wako	01919741
Goat Anti-Rabbit IgG H&L (Alexa Fluor 488)	Abcam	ab150077
FACS Antibodies	Company	Catalog Number
V450,Rat,Anti-Mouse,CD45,30-F11,RUO	BD Biosciences	560501
PerCP-Cy5.5 CD11b	eBiosciences	45-0112-82
ZombieNIR	Biolegend	423105
pHrodo Red E. coli BioParticles Conjugate	Thermo Fisher Scientific	P35361
Annexin.V_FITC	Miltenyi Biotech	130-093-060
Propodium Iodide solution	Miltenyi Biotech	130-093-233