Highly Efficient Transfection of Primary Macrophages with In Vitro Transcribed mRNA

Podsumowanie

Macrophages, especially primary macrophages, are challenging to transfect as they specialize in detecting molecules of non-self origin. We describe a protocol that allows highly efficient transfection of primary macrophages with mRNA generated from DNA templates such as plasmids.

Streszczenie

Macrophages are phagocytic cells specialized in detecting molecules of non-self origin. To this end, they are equipped with a large array of pattern recognition receptors (PRRs). Unfortunately, this also makes macrophages particularly challenging to transfect as the transfection reagent and the transfected nucleic acids are often recognized by the PRRs as non-self. Therefore, transfection often results in macrophage activation and degradation of the transfected nucleic acids or even in suicide of the macrophages. Here, we describe a protocol that allows highly efficient transfection of murine primary macrophages such as peritoneal macrophages (PM) and bone marrow-derived macrophages (BMDM) with mRNA in vitro transcribed from DNA templates such as plasmids. With this simple protocol, transfection rates of about 50-65% for PM and about 85% for BMDM are achieved without cytotoxicity or immunogenicity observed. We describe in detail the generation of mRNA for transfection from DNA constructs such as plasmids and the transfection procedure.

Wprowadzenie

Macrophages are phagocytic cells that specialize in detecting, ingesting and degrading microbes, apoptotic cells and cellular debris. Moreover, they help to orchestrate immune responses by secreting cytokines and chemokines and by presenting antigens to T cells and B cells. Macrophages also play important roles in numerous other processes, such as wound healing, atherosclerosis, tumorigenesis and obesity.

To be able to detect non-self molecules such as pathogen-associated molecular patterns (PAMPs) and out-of-place molecules such as damage-associated molecular patterns (DAMPs), macrophages are equipped with a large array of pattern recognition receptors (PRR)¹. Unfortunately, this also makes macrophages particularly challenging to transfect² as the transfection reagent³ and the transfected nucleic acids^4,5,6,7 often are recognized by the PRRs as non-self. For this reason, transfection of macrophages using chemical or physical methods⁸ usually results in macrophage activation and degradation of the transfected nucleic acids or even in macrophage suicide via pyroptosis, a form of programmed lytic cell death triggered after recognition of cytosolic PAMPs/DAMPs such as DNA or foreign RNA⁹. Biological transfection of macrophages using viruses such as adenoviruses or lentiviruses as vectors is often more efficient, yet construction of such viral vectors is time-consuming and requires biosafety level 2 equipment^10,11.

Thus, although macrophages are the subject of intensive research, analysis of their functions on the molecular level is hampered because one of the most important tools of molecular biology, the transfection of nucleic acid constructs for exogenous expression of proteins, is hardly applicable. This often forces researchers to use macrophage-like cell lines rather than bona fide macrophages. Applications for nucleic acid construct transfection include expression of mutated or tagged protein versions, overexpression of a specific protein, protein re-expression in a respective knockout background and expression of proteins from other species (e.g., Cre recombinase or guide RNA and Cas9 for targeted gene knockout).

Here, we describe a protocol that allows highly efficient transfection of (usually hard to transfect) primary macrophages, that is murine peritoneal macrophages (PM) and bone marrow-derived macrophages (BMDM) with mRNA generated from DNA templates such as plasmids. Importantly, the in vitro transcribed mRNA generated using this protocol contains the naturally occurring modified nucleosides 5-methyl-CTP and pseudo-UTP that reduce immunogenicity and enhance stability^4,6,7,12,13. Moreover, the 5'-ends of the in vitro transcribed mRNA are dephosphorylated by Antarctic phosphatase to prevent recognition by the RIG-I complex^14,15. This minimizes innate immune recognition of the in vitro transcribed mRNA. With our easy to perform protocol, transfection rates between 50-65% (peritoneal macrophages (PM)) and 85% (BMDM) are reached while, importantly, there is no cytotoxicity or immunogenicity observed. We describe in detail (i) how the immunologically silenced mRNA for transfection can be generated from DNA constructs such as plasmids and (ii) the transfection procedure itself.

Protokół

Macrophage isolation from mice was performed in accordance with the Animal Protection Law of Germany in compliance with the Ethics Committee at the University of Cologne.

NOTE: Carry out all steps wearing gloves. Carry out all transfection steps under a laminar flow hood to prevent contamination of the cells. Before working with mRNA, clean all instruments such as pipettes and every surface with 70% ethanol and/or a RNAse-degrading surfactant (Table of Materials). Ensure that all reaction tubes are RNAse-free and sterile. Use only sterile, RNAase-free water for dilutions. Exclusively use pipette tips with filters. Change pipette tips after every pipetting step.

1. Generation of the DNA Template

NOTE: The DNA template for in vitro mRNA transcription using this protocol must contain a T7 promotor sequence to allow docking of the RNA polymerase. If the plasmid containing the DNA sequence of the protein of interest already contains a correctly orientated T7 promotor sequence directly upstream of the sequence of interest, linearization of the plasmid (see step 1.1.) needs to be performed. Otherwise, attach a T7 promotor to the sequence of interest by polymerase chain reaction (PCR, see step 1.2.).

1. Linearization of T7 promotor-containing plasmids
   1. Linearize plasmids already containing a correctly orientated T7 promotor sequence by digestion with a restriction enzyme cutting downstream of the stop codon of the sequence of interest. Otherwise, transcription will not end properly after the sequence of interest.
      NOTE: It is best to use restriction enzymes leaving blunt ends or 5' overhangs.
   2. Confirm complete linearization of the plasmid by agarose gel electrophoresis of undigested versus digested plasmid DNA.
   3. Purify linearized plasmid DNA prior to use as DNA template for in vitro mRNA transcription using a DNA purification kit (Table of Materials).
2. Attachment of the T7 promotor by PCR
   1. Use a forward primer containing the following components (in the indicated order from 5' to 3'): about 5 random bp upstream of the promotor (e.g., GAAAT); the T7 promotor sequence (TAATACGACTCACTATAG); two extra Gs for increased transcription efficiency (GG); the target sequence-specific part that is homologous to the plasmid sequence surrounding the start codon.
      NOTE: It should be composed of: 3-6 bp upstream of the KOZAK sequence and start codon, the KOZAK sequence and start codon (usually GCCACC ATG G), 12-18 bp downstream of the start codon. If the sequence of interest does not already contain a KOZAK sequence or start codon, these can be attached in this step by simply including them in the primer sequence.
   2. Calculate the t_m of the forward primer only by taking into account the part homologous to the target sequence.
   3. To assess dimers/hairpin formation use the whole primer sequence, which easily can exceed 50 bp.
   4. Use a reverse primer located somewhere downstream of the stop codon.
      NOTE: If the sequence of interest doesn't already contain a stop codon, it can be attached in this step by simply including it in the primer sequence.
   5. Use the forward and reverse primers to perform a PCR using a high-fidelity polymerase with proofreading (Table of Materials).
   6. Confirm generation of a single product and amplicon size by agarose gel electrophoresis (e.g., use a 1% agarose gel and 100 V constant current).
   7. Purify the PCR product prior to use as DNA template for in vitro mRNA transcription using a DNA purification kit.

2. mRNA Generation

1. Thaw all components of the in vitro mRNA transcription kit (see the Table of Materials). Vortex for 5 s and spin down for 2 s at 2,000 x g. Keep on ice until use.
2. Prepare the reaction mix for in vitro mRNA transcription in a 0.5 mL microcentrifuge tube in the following order (total volume of 40 µL): 20 µL of 10x ARCA/NTP mix (included in the in vitro mRNA transcription kit); 0.25 µL of 5-methyl-CTP (final concentration (f.c.) is 1.25 mM; 50% of total CTP); 0.25 µL of pseudo-UTP (f.c. is 1.25 mM; 50% of total UTP); X µL of DNA template; 2 µL of T7 RNA polymerase mix (included in the in vitro mRNA transcription kit); Y µL of RNAse-free H₂O.
   NOTE: X is a volume containing at least 1 µg of DNA. For example, 1.6 µL from a 625 ng/µL stock solution. Y is the spare volume to the total volume of 40 µL.
3. Vortex for 5 s and spin down for 2 s at 2,000 x g. Incubate at 37 °C for 30 min at 400 rpm on a thermal mixer for in vitro transcription.
4. Then, add 2 µL of DNase I directly into the reaction mix for removal of the template DNA. Vortex for 5 s and spin down for 2 s at 2,000 x g.
5. Incubate at 37 °C for 15 min at 400 rpm on a thermal mixer. Take an aliquot of 2 µL for the control gel (step 3.3) and store at -80 °C.
6. For poly(A) tailing, add the following components directly into the previous reaction mix (to a final volume of 50 µL): 5 µL of 10x poly(A) polymerase reaction buffer and 5 µL of poly(A) polymerase (both included in the in vitro mRNA transcription kit). Vortex for 5 s and spin down for 2 s at 2,000 x g.
7. Incubate the mix at 37 °C for 30 min at 400 rpm on a thermomixer. Take an aliquot of 2 µL for the control gel (step 3.3) and store at -80 °C.
8. For dephosphorylation of the 5´-ends of the mRNA, add the following components directly into the previous reaction mix (to a final volume of 60 µL): 3 µL of RNAse-free H₂O; 6 µL of 10x Antarctic phosphatase reaction buffer; 3 µL of Antarctic phosphatase (15 units for 60 µL reaction volume). Vortex for 5 s and spin down for 2 s at 2,000 x g.
9. Incubate the mix at 37 °C for 30 min at 400 rpm on a thermal mixer.
10. Heat-inactivate Antarctic phosphatase by incubation at 80 °C for 2 min.
    NOTE: Ideally, use a separate thermal mixer, do not wait until the first mixer reaches the desired temperature.

3. mRNA Purification

1. Purify the in vitro transcribed mRNA using a dedicated RNA purification kit (Table of Materials).
   1. Add X µL of elution solution to the mRNA reaction mix from step 2.10. Mix by inverting 5 times. Add 300 µL of binding solution concentrate. Mix by gentle pipetting 5 times.
      NOTE: X is the spare volume to a total volume of 100 µL. For example, add 40 µL elution solution to 60 µL mRNA reaction mix.
   2. Add 100 µL of RNAase-free ethanol. Mix by gentle pipetting 5 times.
   3. Place a filter column in one of the supplied collection tubes. Transfer the mRNA reaction mix gently onto the center of the filter without touching the filter. Centrifuge at 15,000 x g for 1 min at room temperature (RT).
   4. Carefully lift the filter column and discard the flow-through in the collection tube. Place the filter column back into the same collection tube.
   5. Add 500 µL of wash solution (do not forget to add 20 mL of RNAase-free ethanol before using the wash solution for the first time).
   6. Centrifuge at 15,000 x g for 1 min at RT. Repeat steps 3.1.4-3.1.6 to wash one more time.
   7. Centrifuge at full speed (17,900 x g) for 1 min at RT to remove any residual fluid from the filter column. Carefully take the filter column from the collection tube. Place the filter column in a new collection tube.
   8. Add 50 µL of elution buffer onto the center of the filter without touching the filter. Incubate at 65 °C for 10 min on a thermal mixer.
   9. Centrifuge at 15,000 x g for 1 min at RT. Remove the filter column and discard it.
2. Measure the concentration and purity of the eluted mRNA, for example, by using a microvolume spectrophotometer to measure absorbance at 260 and 280 nm.
   NOTE: An A260/A280 ratio of 1.8-2.1 is indicative of highly purified mRNA.
3. Verify presence of a single product, correct transcript length and poly(A) tailing by analyzing the aliquots from steps 2.5 and 2.7 by agarose gel electrophoresis under denaturing conditions (for example, use a 1.2% agarose gel containing 20 mM 3-(N-morpholino)propanesulfonic acid [MOPS], 5 mM sodium acetate, 1 mM EDTA and 20% formaldehyde and run in 20 mM MOPS, 5 mM sodium acetate, 1 mM EDTA and 0.74 % formaldehyde at 100 V constant current).
4. Store the purified mRNA in the elution tube at -80 °C until transfection. If using only low amounts of the mRNA for transfection then aliquot the mRNA to avoid repeated freeze-thaw cycles.
   NOTE: mRNA can be stored at -80 °C for about 1 year.

4. Macrophage Preparation

1. Euthanize C57/BL6 mice (use mice of the same sex and of 6-24 weeks of age) by cervical dislocation.
   NOTE: The same mice can be used for isolation of PM (step 4.2) and generation of BMDM (steps 4.3 and 4.4). For isolation of PM use at least two mice. If only BMDM are to be generated one mouse usually is enough.
2. Immunomagnetic enrichment of peritoneal macrophages.
   1. Fill a 10 mL syringe with a 0.9 x 40 mm cannula with 8 mL of ice-cold phosphate-buffered saline (PBS) and 2 mL of air. Flush the peritoneal cavity with PBS. The air will form a bubble that minimizes leakage of the PBS.
   2. Quickly collect peritoneal lavage with the same syringe and transfer into a 50 mL conical centrifugation tube. Combine peritoneal cells of multiple mice if required. Keep cell suspension on ice.
   3. Centrifuge cell suspension at 650 x g for 5 min at 4 °C. Discard the supernatant and resuspend the cell pellet in 5 mL of 0.2 % NaCl for 30 s to lyse red blood cells.
   4. Add 5 mL of 1.6% NaCl to a total volume of 10 mL to reconstitute isotonic conditions. Centrifuge at 650 x g for 5 min at 4 °C.
   5. Discard the supernatant and resuspend the cell pellet in 97.5 µL of magnetic cell sorting (MCS) buffer (2 mM ethylenediaminetetraacetic acid [EDTA], 0.5% bovine serum albumin [BSA] in PBS) per 1 peritoneal lavage (e.g., if three mice were flushed, resuspend in 292.5 µL).
   6. Add 2.5 µL of paramagnetic beads conjugated to an CD11b-specific antibody per 97.5 µL of cell suspension (e.g., add 7.5 µL to 292.5 µL).
   7. Incubate on ice for 15 min at 150 rpm on an orbital shaker.
   8. Centrifuge cell suspension at 650 x g for 5 min at 4 °C, discard the supernatant and resuspend the cell pellet in 1 mL of MCS buffer.
   9. Add 4 mL of MCS buffer to a total volume of 5 mL and wash the cells by gently pipetting up and down three times.
   10. Repeat steps 4.2.8 and 4.2.9 two more times for a total of three wash steps.
   11. During the wash steps place an LS column in a magnetic cell separator (see Table of Materials). Rinse the column with 3 mL of MCS buffer.
       NOTE: Avoid any bubbles as these may clog the column.
   12. Resuspend the cell pellet in 1 mL of MCS buffer. Add 3 mL of MCS buffer to a total volume of 4 mL, mix by pipetting up and down three times.
   13. Transfer the 4 mL of cell suspension onto the rinsed LS column.
       NOTE: Again, avoid any bubbles as these may clog the column.
   14. Wait until the reservoir of the column is completely empty. Do not add additional fluid until the column stops dripping.
   15. Add 3 mL of MCS buffer onto the column. Then, wait until the reservoir of the column is completely empty. Repeat step 4.2.15 two more times.
   16. Place the LS column in a 15 mL conical centrifugation tube. Apply 5 mL of MCS buffer onto the column. Wait until 2 mL of fluid has passed through the column, then use the plunger to gently push the remaining fraction into the tube.
   17. Centrifuge cell suspension at 650 x g for 5 min at 4 °C and discard the supernatant.
   18. Resuspend the cell pellet in 1 mL of DMEM supplemented with 10% heat-inactivated fetal calf serum (FCS) (DMEM+FCS).
   19. Determine the number of viable cells by counting in trypan blue solution in a Neubauer counting chamber and seed cells in DMEM+FCS into culture plates.
       NOTE: Seed PM at a density of 100,000 cells/well in a flat bottom microtiter plate. Do not use tissue culture-treated plates as PM cannot be detached from these. Use non-treated plates instead.
3. Generation of BMDM
   1. Remove skin and muscles from the hind legs using a pair of scissors. Wash each leg by short submersion in 70% ethanol.
   2. Detach legs and open both ends of the femur and the tibia by cutting with scissors.
   3. Fill a 5 mL syringe filled with a 0.6 mm x 30 mm cannula with 5 mL of very low endotoxin (VLE) RPMI 1640 and flush the bone marrow out of the opened bones into a culture dish.
   4. Combine bone marrow of multiple mice if required by repeating steps 4.3.1-4.3.3. Transfer the bone marrow into a 50 mL conical centrifugation tube.
   5. Centrifuge the bone marrow suspension at 650 x g for 5 min at 4 °C and discard the supernatant.
   6. Resuspend the cell pellet in 5 mL of red blood cell lysis buffer (8.3% NH₄Cl, 0.1 M Tris) and incubate for 5 min at RT to lyse the red blood cells.
   7. Centrifuge the cell suspension at 650 x g at 4° C for 5 min and discard the supernatant.
   8. Resuspend the cell pellet in 1 mL of VLE RPMI 1640 medium supplemented with 10% FCS, 1% penicillin/streptomycin, 1% HEPES, 1% sodium pyruvate and 10 ng/mL recombinant macrophage colony-stimulating factor (M-CSF) (RPMI⁺⁺⁺⁺⁺).
   9. Add 4 mL of RPMI⁺⁺⁺⁺⁺ to a total volume of 5 mL.
   10. Prepare 5 92 mm x 16 mm untreated Petri dishes with cams (see the Table of Materials) per mouse by pipetting 7 mL of RPMI⁺⁺⁺⁺⁺ medium into each dish.
   11. Transfer the 1 mL of cell solution to the 5 prepared culture dishes and incubate at 37 °C and 5% CO₂.
   12. After 4 days, feed the cells by adding 4 mL of RPMI⁺⁺⁺⁺⁺. After 6-7 days, the bone marrow cells are fully differentiated into BMDM.
4. Harvesting of BMDM
   1. Completely remove the medium from culture dishes. Add 5 mL of warm 0.2 mM EDTA in PBS to each dish.
   2. Gently scrape the whole plate with a cell scraper to detach the BMDM. Combine the cell suspensions in a 50 mL conical centrifugation tube.
   3. Flush all 5 dishes again. Use the same volume of 5 mL of warm 0.2 mM EDTA in PBS for all 5 dishes. Combine this cell suspension with the one from the previous step.
   4. Centrifuge the cell suspension at 650 x g for 5 min at 4° C and discard the supernatant.
   5. Resuspend the cell pellet in 1 mL of VLE RPMI 1640 medium supplemented with 10% FCS, 1% HEPES, 1% sodium pyruvate and 10 ng/mL recombinant M-CSF but no antibiotics (RPMI⁺⁺⁺⁺).
   6. Determine the number of viable cells by counting in trypan blue solution in a Neubauer counting chamber and seed cells in RPMI⁺⁺⁺⁺ into culture plates.
      NOTE: Seed BMDM at a density of 50,000 cells/well maximum in a flat bottom microtiter plate. Do not use tissue culture-treated plates as BMDM can hardly be detached from these. Use non-treated plates instead.

5. Transfection of Macrophages with mRNA

1. Calculate the required volume of mRNA transfection buffer.
   NOTE: The volume of mRNA transfection buffer required depends on well size: use 200 µL for transfection in a 6-well plate, 100 µL in a 12-well plate and so on. Always add a little spare volume because of pipetting loss (but not too much, to prevent undue dilution of mRNA). For example, use 450 µL instead of 4 x 100 µL = 400 µL to transfect in 4 wells of a 12-well plate.
2. Calculate the required volume of mRNA transfection reagent. The mRNA transfection reagent is added at a ratio of 1:50. For example, 9 µL of mRNA transfection reagent is required for a final volume of 450 µL.
3. Calculate the total amount of mRNA required. At least 100 ng per 100,000 macrophages are required for efficient transfection, 200 ng works even better (e.g., 800 ng mRNA to transfect 400,000 macrophages).
   1. Multiply the calculated amount of mRNA required with the total number of wells that have to be transfected (e.g., 4 wells with 400,000 macrophages each: 4 x 800 ng = 3,200 ng mRNA is required in total for all wells). For example, if your mRNA stock is 426.8 ng/µL, 7.49 µL are needed for optimal transfection of 4 wells with 400,000 macrophages each.
4. Add the calculated volume of mRNA transfection buffer (step 5.1.) minus the volumes for mRNA transfection reagent (step 5.2) and the mRNA (step 5.3) to a reaction tube. For example, 450 µL - 9 µL - 7.49 µL = 433.51 µL.
5. Thaw the mRNA stock and mix it by gentle flipping of the elution tube. Add the calculated volume of mRNA (step 5.3) to the reaction tube with mRNA reaction buffer (in the example presented above: 7.49 µL in 433.51 µL).
6. Vortex for 5 s and spin down for 2 s at 2,000 x g.
7. Vortex the mRNA transfection reagent for 5 s and spin down for 2 s at 2,000 x g.
8. Add the calculated volume of mRNA transfection reagent (step 5.2) to the reaction tube containing the mRNA transfection buffer and the mRNA (in the example presented above: 9 µL of mRNA transfection reagent).
9. Vortex the transfection mix for 5 s and spin down for 2 s at 2,000 x g.
10. Incubate for 15 min at RT.
11. Meanwhile, replace the culture medium of the macrophages with fresh, warm culture medium (see steps 4.2.18. and 4.4.5).
12. After the incubation step 5.10, add the transfection mix to the wells containing the macrophages in a volume appropriate for the size of the well (see step 5.1). Add the transfection mix dropwise in a circle from the outside to the middle of the well.
13. Gently rock the plate, first in a vertical and then in a horizontal direction to ensure uniform distribution of the transfection mix in the well. Then, incubate at 37 °C and 5 % CO₂. Synthesis of the protein encoded by the transfected mRNA will begin shortly after transfection. For best results, incubate for at least 6 h.
14. After the incubation, analyze transfection efficiency by (immuno)fluorescence microscopy, flow cytometry or immunoblot¹⁶, or use the transfected macrophages for the experiment of choice.

Wyniki

We have successfully used this protocol to generate mRNA encoding for FLAG-tagged NEMO and IKKβ variants for transfection of primary macrophages¹⁶. The plasmids encoding for FLAG-tagged wild-type (NEMO^WT) and C54/347A mutant NEMO (NEMO^C54/374A) (see the Table of Materials) already contain a T7 promotor in the correct orientation (Figure 1A). Thus, we only had to linearize the...

Dyskusje

Here we present a protocol for highly efficient transfection of usually hard-to-transfect primary macrophages with in vitro transcribed mRNA. Importantly, transfection of the macrophages using this protocol does not induce cell death or activate proinflammatory signaling indicating that neither the transfection reagent nor the transfected mRNA are recognized as non-self.

The quality of the mRNA is of key importance for successful transfection of macrophages using this protocol. Thus, great car...

Materiały

Name	Company	Catalog Number	Comments
5-methyl-CTP (100 mM)	Jena Biosience	NU-1138S	stored at -20 °C
Antarctic phosphatase	New England BioLabs	M0289	stored at -20 °C
Antarctic phosphatase reaction buffer (10x)	New England BioLabs	B0289	stored at -20 °C
anti-NEMO/IKKγ antibody	Invitrogen	MA1-41046	stored at -20 °C
anti-β-actin antibody	Sigma-Aldrich	A2228	stored at -20 °C
Petri dishes 92,16 mm with cams	Sarstedt	821,473	stored at RT
CD11b Microbeads mouse and human	Miltenyi Biotec	130-049-601	stored at 4 °C
Cre recombinase + T7-Promotor forward primer	Sigma-Aldrich		5′-GAAATTAATACGACTCACTATA GGGGCAGCCGCCACCATGTCC AATTTACTGACCGTAC-3´, stored at -20 °C
Cre recombinase + T7-Promotor reverse primer	Sigma-Aldrich		5′-CTAATCGCCATCTTCCAGCAGG C-3′, stored at -20 °C
DNA purification kit: QIAquick PCR purification Kit	Qiagen	28104	stored at RT
eGFP + T7-Promotor forward primer	Sigma-Aldrich		5´-GAAATTAATACGACTCACTATA GGGATCCATCGCCACCATGGTG AGCAAGG-3´, stored at -20 °C
eGFP + T7-Promotor reverse primer	Sigma-Aldrich		5´-TGGTATGGCTGATTA TGATCTAGAGTCG-3´, stored at -20 °C
Fast Digest buffer (10x)	Thermo Scientific	B64	stored at -20 °C
FastDigest XbaI	Thermo Scientific	FD0684	stored at -20 °C
High-fidelity polymerase with proofreading: Q5 High-Fidelity DNA-Polymerase	New England Biolabs Inc	M0491S	stored at -20 °C
IKKβ + T7-Promotor forward primer	Sigma-Aldrich		5′-GAAATTAATACGACTCACTATA GGGTTGATCTACCATGGACTACA AAGACG-3′, stored at -20 °C
IKKβ + T7-Promotor reverse primer	Sigma-Aldrich		5′-GAGGAAGCGAGAGCT-CCATCTG-3′, stored at -20 °C
In vitro mRNA transcription kit: HiScribe T7 ARCA mRNA kit (with polyA tailing)	New England BioLabs	E2060	stored at -20 °C
LS Columns	Miltenyi Biotec	130-042-401	stored at RT
MACS MultiStand	Miltenyi Biotec	130-042-303	stored at RT
mRNA transfection buffer and reagent: jetMESSENGER	Polyplus transfection	409-0001DE	stored at 4 °C
Mutant IKKβ IKK-2S177/181E plasmid	Addgene	11105	stored at -20 °C
Mutant NEMOC54/347A plasmid	Addgene	27268	stored at -20 °C
pEGFP-N3 plasmid	Addgene	62043	stored at -20 °C
poly(I:C)	Calbiochem	528906	stored at -20 °C
pPGK-Cre plasmid			F.T. Wunderlich, H. Wildner, K. Rajewsky, F. Edenhofer, New variants of inducible Cre recombinase: A novel mutant of Cre-PR fusion protein exhibits enhanced sensitivity and an expanded range of inducibility. Nucleic Acids Res. 29, 47e (2001). stored at -20 °C
pseudo-UTP (100 mM)	Jena Biosience	NU-1139S	stored at -20 °C
QuadroMACS Separator	Miltenyi Biotec	130-090-976	stored at RT
Rat-anti-mouse CD11b antibody, APC-conjugated	BioLegend	101212	stored at 4 °C
Rat-anti-mouse F4/80 antibody, PE-conjugated	eBioscience	12-4801-82	stored at 4 °C
Recombinant M-CSF	Peprotech	315-02	stored at -20 °C
RNA purification kit: MEGAclear transcription clean-up kit	ThermoFisher Scientific	AM1908	stored at 4 °C
RNAse-degrading surfactant: RnaseZAP	Sigma-Aldrich	R2020	stored at RT
Ultrapure LPS from E.coli O111:B4	Invivogen		stored at -20 °C
Wild type IKKβ plasmid	Addgene	11103	stored at -20 °C
Wild type NEMO plasmid	Addgene	27268	stored at -20 °C