Summary

FACS-Isolation and Culture of Fibro-Adipogenic Progenitors and Muscle Stem Cells from Unperturbed and Injured Mouse Skeletal Muscle

Published: June 08, 2022
doi:

Summary

The precise identification of fibro-adipogenic progenitor cells (FAPs) and muscle stem cells (MuSCs) is critical to studying their biological function in physiological and pathological conditions. This protocol provides guidelines for the isolation, purification, and culture of FAPs and MuSCs from adult mouse muscles.

Abstract

Fibro-adipogenic progenitor cells (FAPs) are a population of skeletal muscle-resident mesenchymal stromal cells (MSCs) capable of differentiating along fibrogenic, adipogenic, osteogenic, or chondrogenic lineage. Together with muscle stem cells (MuSCs), FAPs play a critical role in muscle homeostasis, repair, and regeneration, while actively maintaining and remodeling the extracellular matrix (ECM). In pathological conditions, such as chronic damage and muscular dystrophies, FAPs undergo aberrant activation and differentiate into collagen-producing fibroblasts and adipocytes, leading to fibrosis and intramuscular fatty infiltration. Thus, FAPs play a dual role in muscle regeneration, either by sustaining MuSC turnover and promoting tissue repair or contributing to fibrotic scar formation and ectopic fat infiltrates, which compromise the integrity and function of the skeletal muscle tissue. A proper purification of FAPs and MuSCs is a prerequisite for understanding the biological role of these cells in physiological as well as in pathological conditions. Here, we describe a standardized method for the simultaneous isolation of FAPs and MuSCs from limb muscles of adult mice using fluorescence-activated cell sorting (FACS). The protocol describes in detail the mechanical and enzymatic dissociation of mononucleated cells from whole limb muscles and injured tibialis anterior (TA) muscles. FAPs and MuSCs are subsequently isolated using a semi-automated cell sorter to obtain pure cell populations. We additionally describe an optimized method for culturing quiescent and activated FAPs and MuSCs, either alone or in coculture conditions.

Introduction

The skeletal muscle is the largest tissue in the body, accounting for ~40% of adult human weight, and is responsible for maintaining posture, generating movement, regulating basal energy metabolism, and body temperature1. Skeletal muscle is a highly dynamic tissue and possesses a remarkable ability to adapt to a variety of stimuli, such as mechanical stress, metabolic alterations, and daily environmental factors. In addition, skeletal muscle regenerates in response to acute injury, leading to complete restoration of its morphology and functions2. Skeletal muscle plasticity mainly relies upon a population of resident muscle stem cells (MuSCs), also termed satellite cells, which are located between the myofiber plasma membrane and the basal lamina2,3. Under normal conditions, MuSCs reside in the muscle niche in a quiescent state, with only a few divisions to compensate for cellular turnover and to replenish the stem cell pool4. In response to injury, MuSCs enter the cell cycle, proliferate, and either contribute to the formation of new muscle fibers or return to the niche in a self-renewal process2,3. In addition to MuSCs, homeostatic maintenance and regeneration of the skeletal muscle rely upon the support of a population of muscle resident cells named fibro-adipogenic progenitors (FAPs)5,6,7. FAPs are mesenchymal stromal cells embedded in the muscle connective tissue and capable of differentiating along fibrogenic, adipogenic, osteogenic, or chondrogenic lineage5,8,9,10. FAPs provide structural support for MuSCs as they are a source of extracellular matrix proteins in the muscle stem cell niche. FAPs also promote long-term maintenance of the skeletal muscle by secreting cytokines and growth factors that provide trophic support for myogenesis and muscle growth6,11. Upon acute muscle injury, FAPs rapidly proliferate to produce a transient niche that supports the structural integrity of the regenerating muscle and provides a favorable environment to sustain MuSCs proliferation and differentiation in a paracrine manner5. As regeneration proceeds, FAPs are cleared from the regenerative muscle by apoptosis, and their numbers gradually return to basal level12. However, in conditions favoring chronic muscle injury, FAPs override pro-apoptotic signaling and accumulate in the muscle niche, where they differentiate into collagen-producing fibroblasts and adipocytes, leading to ectopic fat infiltrates and fibrotic scar formation12,13.

Due to their multipotency and their regenerative abilities, FAPs and MuSCs have been identified as prospective targets in regenerative medicine for the treatment of skeletal muscle disorders. Therefore, to investigate their function and therapeutic potential, it is important to establish efficient and reproducible protocols for the isolation and culture of FAPs and MuSCs.

Fluorescence-activated cell sorting (FACS) can identify different cell populations based on morphological characteristics such as size and granularity, and permits cell-specific isolation based on the use of antibodies directed against cell surface markers. In adult mice, MuSCs express the vascular cell adhesion molecule 1 (VCAM-1, also known as CD106)14,15 and α7-Integrin15, while FAPs express the platelet-derived growth factor receptor α (PDGFRα) and the stem cell antigen 1 (Sca1 or Ly6A/E)5,6,9,12,16,17. In the protocol described here, MuSCs were identified as CD31-/CD45-/Sca1-/VCAM-1+/α7-Integrin+, while FAPs were identified as CD31-/CD45-/Sca1+/VCAM-1-/α7-Integrin-. Alternatively, PDGFRαEGFP mice were employed to isolate FAPs as CD31-/CD45-/PDGFRα+/VCAM-1-/α7-Integrin- events18,19. Furthermore, we compared the overlapping between the fluorescent signal of PDGFRα-GFP+ cells to cells identified by the surface marker Sca1. Our analysis showed that all GFP-expressing cells were also positive for Sca1, indicating that either approach can be employed for the identification and isolation of FAPs. Finally, staining with specific marker antibodies confirmed the purity of each cell population.

Protocol

All animal experiments performed were conducted in compliance with institutional guidelines approved by the Animal Care and Use Committee (ACUC) of the National Institute of Arthritis, Musculoskeletal, and Skin Diseases (NIAMS). Investigators performing this protocol must adhere to their local animal ethics guidelines.

NOTE: This protocol describes in detail how to isolate FAPs and MuSCs from hind limb and injured tibialis anterior (TA) muscles of adult male and female mice (3-6 months) and provides guidelines for coculturing FAPs and MuSCs. An overview of the experimental procedure is shown in Figure 1. All steps of this protocol should be performed in sterile conditions and at room temperature (RT) unless otherwise specified.

1. Reagent setup

  1. Wash Medium (WM): Prepare this solution by adding 10% (vol/vol) horse serum and 1x penicillin/streptomycin to Ham's F-10 Nutrient Mix cell media. WM can be prepared in advance and stored at 4 °C.
  2. Muscle Dissociation Buffer (MDB): Prepare this buffer by dissolving Collagenase II in WM. If collecting whole hind limb muscles, dissolve 1000 U/mL Collagenase II in 10 mL of WM for each mouse (to be prepared into a 50 mL conical tube). If collecting TA muscles, dissolve 800 U/mL Collagenase II in 7 mL of WM for each mouse (to be prepared into a 15 mL conical tube). For TA muscles, this will help to better visualize cell pellets and obtain a higher yield of FAPs and MuSCs. Prepare MDB fresh before collecting the muscles and keep it on ice until needed.
  3. Collagenase II solution stock: Prepare this solution by dissolving Collagenase II in sterile 1x phosphate-buffered saline (PBS) to a final concentration of 1000 U/mL. Filter the solution through a 0.45 μm syringe filter and aliquot into 1 mL stocks. Store the solution at -20 °C.
  4. Dispase solution stock: prepare this solution by dissolving Dispase in sterile 1x PBS to a final concentration of 11 U/mL. Filter the solution through a 0.45 μm syringe filter and aliquot into 1 mL stocks. Store the solution at -20 °C.
  5. Prepare FAP's culture medium by supplementing DMEM with 10% (vol/vol) fetal bovine serum, 1x penicillin/streptomycin, and 2.5 ng/mL FGF. Store the medium at 4 °C.
  6. Prepare MuSC's culture medium supplementing F10 with 10% (vol/vol) horse serum, 1x penicillin/streptomycin, and 2.5 ng/mL FGF. Store the medium at 4 °C.
  7. Prepare the coculture medium by supplementing DMEM with 10% (vol/vol) fetal bovine serum, 10% (vol/vol) horse serum, 1x penicillin/streptomycin, and 2.5 ng/mL FGF. Store the medium at 4 °C.

2. Hind limb muscle harvesting

  1. Add 2-3 mL of WM in a 6 cm dish (one dish per mouse) and place it on ice.
  2. Perform euthanasia by asphyxiation: place the mouse in a CO2 chamber and introduce 100% CO2. Use cervical dislocation to confirm death.
  3. Place the mouse supine on a dissection pad and spray it with 70% (vol/vol) ethanol to avoid contamination.
  4. Use forceps to pinch the center of the mouse belly skin and cut a ~1 cm opening horizontally. Grasp the wound edges and deskin the mouse by pulling the opening in opposite directions to uncover the muscles underneath. Expose one side of the mouse's hind limb at the time.
  5. Before collecting muscles, remove intermuscular fat between the hamstrings and the proximal end of the quadriceps. This will improve the isolation of FAPs and MuSCs.
  6. Without damaging the tissue, use sharp forceps to break and peel off the fascia to expose the underneath TA and extensor digitorum longus (EDL) muscles. Run the sharp tip of the forceps underneath the TA/EDL muscles to detach the muscles from the tibia.
  7. Cut off the tendons attaching the TA/EDL to the ankle and, while holding it with forceps, trim the muscles with scissors along the longitudinal line of the TA/EDL. Cut the tendons around the knee to detach the whole TA/EDL muscles. Place the muscles in a 6 cm dish kept on ice.
  8. Proceed to isolate the gastrocnemius and soleus muscles by cutting all tendons at the ankle and detaching the muscles from the tibia and fibula. Cut around the knee and transfer the muscles to the 6 cm dish.
  9. Peel off the fascia around the quadriceps and separate it from the femur by running the sharp tip of the forceps between the muscle and the bone. Cut the tendons around the knee and, while holding the quadriceps with forceps at the distal end, trim the rest of the muscle by cutting along the femur. Place the muscles in the 6 cm dish.
  10. Detach the hamstrings and remaining muscles around the femur and transfer those to the 6 cm dish. Collect the hind limb muscles in a 6 cm dish kept on ice.
    NOTE: Avoid damaging blood vessels, when possible, to prevent formation of blood clumps that could interfere with the downstream isolation. If bleeding occurs, blot the excised vessel immediately with a sterile gauze to absorb the blood.
  11. Collect TA, EDL, gastrocnemius, soleus, quadricep, and hamstring muscles from the contralateral limb.
    ​NOTE: When isolating the whole hind limb muscles, do not pool two or more mice. If isolating TA muscles, up to three TA muscles can be pooled.

3. Mechanical and enzymatic muscle digestion

  1. Aspirate WM from the 6 cm dish and add 1-2 mL of MDB to keep the muscles moist.
  2. Mince the muscles thoroughly until obtaining a slurry paste of well-minced tissue. To do so, use forceps to hold one end of a piece of muscle, then use a scalpel to tear and slice the muscle until less tight.
  3. Using scissors, keep cutting the muscle into small pieces for 1-2 min. Repeat this step for each group of muscles until obtaining a well-minced muscle sludge.
    NOTE: This is a very critical step to maximize the yield of FAPs and MuSCs. It is recommended to spend 8-10 min (4-5 min if isolating TA muscles only) in this step to ensure a proper muscle mincing.
  4. Transfer the minced muscles from each mouse to the conical tube containing MDB.
  5. Seal the tubes with laboratory film and incubate in a 37 °C water bath with agitation (75 rpm) for 1 h. Place the tubes horizontally along the shaking path and use weights to keep the tubes submerged in water.
  6. Thaw 1 mL of Collagenase II stock and 1 mL of dispase stock per mouse. Before use, spin the dispase stock in a swinging bucket rotor at 10,000 x g for 1 min at 4 °C. Use only the supernatant.
  7. If whole hind limb muscles were collected, proceed as follows:
    1. After 1 h, remove the tube from the shaker and fill it to 50 mL with WM. Gently invert a couple of times to ensure mixing.
    2. Centrifuge the cells in a swinging bucket rotor at 250 x g for 5 min at 4 °C. Transfer 42 mL of supernatant into two new tubes (~21 mL in each tube) and leave ~8 mL in the original tube.
      1. Fill the new tubes containing 21 mL of the supernatant up to 50 mL with WM. Centrifuge the cells again in a swinging bucket rotor at 350 x g for 8 min at 4 °C. Aspirate all the supernatant and keep the pellets on ice.
    3. Add 1 mL of collagenase II stock and 1 mL of dispase stock in the original tube containing ~8 mL of MDB.
    4. Using a 5 mL serological pipette, resuspend the pellet 10 times without clogging. Eject the solution toward the wall of the tube, avoiding the formation of bubbles. If clogging occurs during resuspension, push the tip of the pipette against the bottom of the tube to mechanically disrupt the muscle chunks. Proceed to step 3.9.
  8. If TA muscles were collected, proceed as follows:
    1. After 1 h, remove the tube from the shaker and fill them to 15 mL with WM. Gently invert a couple of times to ensure mixing.
    2. Centrifuge the cells in a swinging bucket rotor at 250 x g for 5 min at 4 °C. Transfer 13 mL of supernatant into one new 15 mL tube and leave ~2 mL in the original tube.
      1. Fill the new tube containing 13 mL of the supernatant up to 15 mL with WM. Centrifuge the cells again in a swinging bucket rotor at 350 x g for 8 min at 4 °C. Aspirate all the supernatant and keep the pellet on ice.
    3. Using a 1000 µL pipette tip, resuspend the pellet in the original tube up and down without clogging.
    4. Add 1 mL of Collagenase II stock and 1 mL of dispase stock in the original tube containing 2 mL of MDB and fill up to 10 mL with WM. Proceed to step 3.9.
  9. Seal the tubes with laboratory film and incubate in a 37 °C water bath with agitation (75 rpm) for 30 min. Place the tubes as in step 3.5.

4. Generation of mononucleated cells

NOTE: If working with TA muscles collected in a 15 mL conical tube, transfer the suspension into a 50 mL conical tube before proceeding with step 4.1.

  1. After 30 min, remove the tube from the shaker. Aspirate and eject the muscle suspension through a 10 mL syringe with a 20 G needle successfully 10 times.
    NOTE: Eject muscle suspension toward the wall of the tube to avoid bubbles and foaming. Small pieces of undigested tendons or cartilages might clog the needle during the first rounds of aspiration. If clogging occurs, use sterile forceps to remove the clog from the tip of the needle.
  2. Fill each tube up to 50 mL with WM and gently invert a couple of times to ensure mixing.
  3. Centrifuge the cells in a swinging bucket rotor at 250 x g for 5 min at 4 °C. Transfer supernatant into a new tube (~42 mL) and leave ~8 mL in the original tube.
    1. Fill the new tube containing 42 mL of the supernatant up to 50 mL with WM. Centrifuge the cells again in a swinging bucket rotor at 350 x g for 8 min at 4 °C. Aspirate all the supernatant and keep the pellet on ice.
  4. Place a 40 μm nylon cell strainer in the original 50 mL conical tube containing 8 mL of WM and pre-wet the cell strainer with 1-2 mL of WM.
  5. While holding the 40 μm nylon cell strainer, use a 10 mL pipette to gently resuspend the pellet 5-10 times. Filter the pellets through the cell strainer back into the same tube to minimize cell loss.
  6. At this step, ensure that there are additional tubes with cell pellets on ice. Filter those pellets back into the original tube by adding 4-5 mL of WM to each tube to resuspend the pellets and transfer the solution to the cell strainer positioned in the original tube. Allow filtering by gravity.
  7. After collecting all the pellets into the original 50 mL conical tube, rinse the cell strainer with another 4-5 mL of WM. Use a 1000 μL pipette to collect all the liquid from the underside of the cell strainer.
  8. Fill each tube with WM up to 50 mL and gently invert a couple of times to ensure mixing.
  9. Centrifuge the cells in a swinging bucket rotor at 250 x g for 5 min at 4 °C. Immediately aspirate all the supernatant after centrifugation without disturbing the pellet.
  10. Resuspend the pellet in 600 μL of WM and transfer it to a 2 mL microcentrifuge tube.

5. Antibody staining for flow cytometry

NOTE: For each experiment, set up the following controls: i) unstained control, ii) viability control to select for the live cell population, iii) single stained compensation controls to correct for fluorochrome emission spillover, and iv) fluorescence minus one (FMO) controls to set gating boundaries by accounting for spillover spread. Refer to Table 1 for a full list of staining controls.

  1. To prepare unstained control, transfer 10 μL of the cell suspension into a 2 mL microcentrifuge tube containing 190 μL of WM. Resuspend the cell suspension and filter through a 5 mL polystyrene round-bottom tube with a 35 μm cell-strainer cap. Allow the suspension to filter by gravity.
  2. Use a 200 μL pipette to collect all the liquid from the underside of the cell strainer. Seal with a cap and leave it on ice, protected from light.
  3. Prepare viability, FMO, and single stained controls: label 10 2 mL microcentrifuge tubes and add 190 μL of WM into each tube and 10 μL of cell suspension. Refer to Table 1 for a full list of controls. Add antibodies to the appropriate tube depending on the experimental control. Refer to Table 1 for information regarding antibody combination and concentration.
  4. Transfer the rest of the cell suspension (500 μL) into a 2 mL microcentrifuge tube (experimental tube) and add the following antibodies: CD31-APC, CD45-APC, Sca1-Pacific Blue, VCAM-1-biotin, and α7-Integrin-PE. Refer to Table 1 for information regarding antibody combination and concentration.
  5. Gently mix well each tube to ensure uniform distribution and incubate the cells in a rotating shaker at 4 °C for 45 min protected from light.
  6. After 45 min, fill all microcentrifuge tubes up to 2 mL with WM. Gently invert the tubes a couple of times to ensure complete mixing. Centrifuge the tubes in a refrigerated centrifuge with a fixed angle rotor at 250 x g for 5 min at 4 °C. Aspirate the supernatant without disturbing the pellet.
  7. Resuspend the cells in all microcentrifuge tubes in 300 μL of WM.
  8. Add streptavidin antibody into appropriate tubes. Refer to Table 1 for information regarding antibody combination and concentration. Gently mix well each tube to ensure uniform distribution and incubate the cells in a rotating shaker at 4 °C for 20 min protected from light. Leave the remaining tubes on ice, protected from the light.
  9. After 20 min, fill microcentrifuge tubes containing streptavidin antibody to 2 mL with WM. Gently invert the tubes a few times to ensure complete mixing. Centrifuge the tubes in a refrigerated centrifuge with a fixed angle rotor at 250 x g for 5 min at 4 °C. Aspirate the supernatant completely and resuspend cells in 300 μL of WM. 
  10. Pre-wet the 35 μm cell strainer cap of 10 5 mL polystyrene round-bottom tubes with 200 μL of WM. Filter cells from control tubes through the appropriate 5 mL polystyrene round-bottom tubes. Use a 200 μL pipette to collect all the liquid from the underside of the cell strainer. Seal with caps, leave the tubes on ice, and protect them from light.
  11. Resuspend the cells in the experimental tube with an additional 200 μL of WM for a total of 500 μL of WM. Pre-wet a cell strainer cap of a 5 mL polystyrene round-bottom tube with 200 μL of WM. Transfer the cell suspension from the experimental tube into the 5 mL polystyrene round-bottom tube and allow it to filter by gravity.
  12. Rinse the 2 mL microcentrifuge tube containing the experimental sample suspension with 300 μL of WM and pass it through the same strainer cap.Use a 200 μL pipette to collect all the liquid from the underside of the cell strainer. Seal with a cap, leave tubes on ice, and protect them from light.
    NOTE: If clogging of the 35 μm cell-strainer cap occurs, gently tap the tube on the bench to facilitate flow-through.
  13. Prepare and label the collection tubes for FAPs and MuSCs. If isolating cells from whole hind limb muscles, sort the cells in 5 mL polypropylene round-bottom tubes with up to 1 mL of either FAPs or MuSCs culture medium supplemented with 2x serum. If isolating cells from TA muscles, sort FAPs and MuSCs in 2 mL microcentrifuge tubes containing up to 400 μL of culture medium supplemented with 2x serum.

6. Fluorescence-activated cell sorting (FACS)

NOTE: This protocol employs a compact benchtop research flow cytometer equipped with a 100 μm nozzle and featuring a three-laser configuration (488 nm, 640 nm, 405 nm) with the capability to analyze up to nine different fluorochromes (11 parameters including the forward and side scatter). The fluorochromes used in this protocol and their associated detector bandpass filters are as follows: PE 586/42; PE-Cy7 783/56; APC 660/10; Pacific Blue 448/45; 7-Aminoactinomycin D (7-AAD) 700/54, GFP 527/32. Cells are sorted at 4 °C and remain on ice following the sort. Before operating this instrument, ensure that the user is properly trained by a technical applications specialist.

  1. Set up and performance check the cell sorter according to the manufacturer's specifications.
  2. Set up a hierarchical gating strategy to identify FAPs and MuSCs (Figure 2).
    1. Isolate FAPs based on the following scheme: i) forward cell scatter area vs side cell scatter area (FSC-A vs. SSC-A) to separate cells versus debris, ii) side cell scatter height vs side cell scatter width (SSC-H vs. SSC-W) to discriminate singlets from doublets in the SSC range, iii) forward cell scatter height vs forward cell scatter width (FSC-H vs. FSC-W) to discriminate singlets from doublets in the FSC range, and iv) 7-AAD area vs SSC-A to distinguish live versus dead cells.
      1. If isolating FAPs through the antibody-based method, use the following scheme: v) APC-CD45/CD31 area vs Pacific Blue-Ly-6A/E (Sca1) area to exclude CD31+ and CD45+ cells from further analysis, and vi) PE-Cy7-VCAM-1 area vs PE-α7-Integrin area from the CD31-/CD45-/Sca1+ population to distinguish FAPs. FAPs are identified as CD31-/CD45-/Sca1+/VCAM-1-/α7-Integrin- events.
      2. If isolating FAPs through endogenous GFP reporter method, use the following scheme: v) APC-CD45/CD31 area vs GFP-PDGFRα area to exclude CD31+ and CD45+ cells from further analysis and isolate GFP+ cells. FAPs are identified as CD31-/CD45-/PDGFRα+/VCAM-1-/α7-Integrin- events.
    2. Isolate MuSCs based on the following scheme: i) forward cell scatter area vs side cell scatter area (FSC-A vs. SSC-A) to separate cells versus debris, ii) side cell scatter height vs side cell scatter width (SSC-H vs. SSC-W) to discriminate singlets from doublets in the SSC range, iii) forward cell scatter height vs forward cell scatter width (FSC-H vs. FSC-W) to discriminate singlets from doublets in the FSC range, iv) 7-AAD area vs SSC-A to distinguish live vs dead cells, v) APC-CD45/CD31 area vs Pacific Blue-Ly-6A/E (Sca1) area to exclude CD31+ and CD45+ cells from further analysis, and vi) PE-Cy7-VCAM-1 area vs PE-α7-Integrin area from the CD31-/CD45-/Sca1- population to distinguish MuSCs. MuSCs are identified as CD31-/CD45-/Sca1-/VCAM-1+/α7-Integrin+ events.
  3. Run the unstained control and viability control to ensure that the cell population is properly positioned in the SSC-A vs FSC-A plot and to properly gate on live single cells.
  4. Acquire all single stained controls and generate the spillover compensation matrix.
  5. Run all FMO controls and determine the cut-off point between background fluorescence spread and the positively stained population.
  6. Approximately 5-10 min before acquisition of the experimental sample, add 7-AAD viability dye and mix gently.
  7. Once all controls have been processed, set the sort gates in accordance with the FMO controls; acquire and sort the experimental samples.
  8. After all samples have been processed, clean the cytometer according to the manufacturer's specification. Export all .fcs data for analysis.

7. Culture of FAPs and MuSCs

NOTE: Sorted cells should be cultured immediately after sorting, in an appropriate medium on collagen I coated plates.

  1. Centrifuge the collection tubes in a fixed angle rotor at 250 x g for 5 min at 4 °C.
  2. Aspirate the supernatant without disturbing the cell pellet.
  3. For MuSC's culture, resuspend the cells in an appropriate volume of MuSC culture medium and incubate them in standard conditions at 37 °C and 5% CO2.
    1. Plate freshly isolated MuSCs at a density of 20,000 cells/cm2 and activated MuSCs at a density of 15,000 cells/cm2.
    2. After plating, cells appear small, spherical, and translucent. Within 36 h, MuSCs adhere to the surface of the plate and slowly increase their size for the first 48 h.
    3. Replace the medium every 2 days.
      NOTE: MuSCs are very sensitive to cell density. To keep MuSCs in their proliferating state, grow them until they are 60%-70% confluent. Passage the cells into new collagen I coated dishes or plates and add new fresh medium every 2 days. If MuSCs are kept in the same dish or plate for longer than 3-4 days, they will acquire an elongated form and will align with neighboring cells until fusing together.
  4. For FAP's culture, resuspend the cells in an appropriate volume of MuSC culture medium and incubate them in standard conditions at 37 °C and 5% CO2.
    1. Plate the FAPs isolated from unperturbed muscle at a density of 15,000 cells/cm2 and FAPs isolated from injured muscle at 9,000 cells/cm2.
      NOTE: After plating, FAPs completely adhere to the surface of the plate within 48 h, while activated FAPs attach to the plate within a few hours. Once they are attached, FAPs acquire their characteristic shape, with a small cell body and elongated cell processes, and they rapidly proliferate.
    2. Replace the medium every 2 days.
      NOTE: FAPs are very sensitive to cell density. Seeding FAPs at low densities can lead to poor cell growth and cell death. On the contrary, plating FAPs at high seeding density will boost cell survival and improve their expansion. FAPs deriving from damaged muscle usually require lower cell density than undamaged muscle, as they are already activated. It is recommended to adjust FAP plating density based on one's experimental conditions and on the source of the samples.
  5. For coculture, resuspend FAPs and MuSCs in the coculture medium at a ratio of 1:1 and incubate those in standard conditions at 37 °C and 5% CO2. Allow the cells to attach for 48 h and replace the medium every 2 days.

8. Immunofluorescence analysis of cultured FAPs and MuSCs

  1. Aspirate the cell medium and perform two or three washes with 1x PBS.
  2. Fix the cells with 2% paraformaldehyde (PFA) in 1x PBS for 15 min at RT.
  3. Aspirate 2% PFA and quickly wash the cells two or three times with 1x PBS.
  4. Perform cell permeabilization and blocking:
    1. For immunostaining of freshly isolated FAPs, perform cell permeabilization and blocking by incubating cells with 1x PBS + 0.1% Triton X-100 (PBST) + 1% bovine serum albumin (BSA) + 5% Normal Donkey Serum (NDS) for 30 min at RT.
    2. For immunostaining of freshly isolated MuSCs, perform cell permeabilization and blocking by incubating cells with PBST + 1% BSA + 5% Normal Goat Serum (NGS) for 30 min at RT.
  5. Apply primary antibodies:
    1. For immunostaining of freshly isolated FAPs, apply goat anti PDGFRα primary antibody (1:300) diluted in PBST + 1% BSA + 5% NDS overnight at 4 °C.
    2. For immunostaining of freshly isolated MuSCs, apply mouse anti Pax7 primary antibody (1:10) diluted in PBST + 1% BSA + 5% NGS for 45 min at RT.
  6. Wash the cells two or three times with 1x PBS to remove the primary antibody solution.
  7. Apply secondary antibodies:
    1. For immunostaining of freshly isolated FAPs, apply donkey anti-goat IgG (H+L) Alexa Fluor 488 secondary antibody (1:500) diluted in PBST + 1% BSA for 1 h at RT.
    2. For immunostaining of freshly isolated MuSCs, apply goat anti-mouse IgG1 Alexa Fluor 555 secondary antibody (1:500) diluted in PBST + 1% BSA for 45 min at RT.
  8. Wash the cells two or three times with 1x PBS to remove the primary antibody solution.
  9. Perform nuclear counter-staining by incubating cells with DAPI in PBST (1:1000) for 5 min at RT.
  10. Wash the cells three times with 1x PBS to remove the DAPI solution.
    CAUTION: DAPI is toxic and hazardous; handle it with care and dispose it in the hazardous waste bottle.
  11. Store the cells at 4 °C protected from the light.

Representative Results

This protocol allows the isolation of approximately one million FAPs and up to 350,000 MuSCs from uninjured hind limbs of wild-type adult mice (3-6 months), corresponding to a yield of 8% for FAPs and 3% for MuSCs of total events. When sorting cells from damaged TA 7 days post-injury, two to three TA muscles are pooled to obtain up to 300,000 FAPs and 120,000 MuSCs, which correspond to a yield of 11% and 4%, respectively. Post-sort purity values are usually above 95% for FAPs and MuSCs.

The gating strategy adopted to isolate FAPs and MuSCs is illustrated in Figure 2. First, cell populations of interest are identified by creating a forward scatter (FSC) versus side scatter (SSC) density plot, which allows for some degree of cellular identification based on cell morphological properties. This gating strategy is also used to exclude small cellular debris, which is usually located at the bottom left corner of the FSC vs SSC plot. Cells are further gated to exclude doublets based on FSC and SSC height and width signals, and the resulting singlet cells are then stained with 7-AAD to evaluate their viability. Living cells are further assessed for Sca1 and CD31/CD45 expression to exclude Lineage positive cells from further analysis. Lineage negative Sca1 negative singlets are then stained for VCAM-1 and α7-Integrin to distinguish FAPs and MuSCs. FAPs are identified as CD31-/CD45-/Sca1+/VCAM-1-/α7-Integrin- cells and MuSCs are identified as CD31-/CD45-/Sca1-/VCAM-1+/α7-Integrin+ cells. Alternatively, living cells are also gated for CD31/CD45 and GFP-PDGFRα to distinguish FAPs. FAPs are identified as CD31-/CD45-/PDGFRα+/VCAM-1-/α7-Integrin- cells.

This protocol presents two gating strategies to isolate the FAP population: either by using an endogenous PDGFRα-EGFP reporter or by performing cell staining with a Sca1 antibody. The PDGFRα-EGFP knock-in reporter mice (B6.129S4-Pdgfratm11(EGFP)Sor/J)18 express the H2B-eGFP fusion gene from the endogenous PDGFRα locus, allowing efficient and specific labeling of the PDGFRα lineage (Figure 3A). This mouse line was previously used to isolate Pdgfrα+ FAPs and is indeed very helpful for the isolation of FAPs, as the GFP reporter provides a highly visible and specific signal19. Alternatively, this protocol describes a Sca1-based isolation method for the identification of FAPs. Sca1 (Ly-6A/E) is commonly used to identify and isolate FAPs in muscle preparation13,16,17. Sca1 is an 18-kDa glycosylphosphatidylinositol (GPI)-linked protein member of the Ly-6 family20. However, besides being expressed on the cell surface of mesenchymal progenitor muscle cells, Sca1 expression is also observed in hematopoietic stem cells (HSCs) as well as mature leukocytes and T cells. In this protocol, we confirmed the suitability of Sca1 as FAPs' marker by performing FACS-based lineage tracing studies. Specifically, PDGFRα-EGFP mice were employed to isolate Sca1+/GFP-expressing FAPs among populations of mononucleated cells. We found that all GFP-expressing cells were also positive for Sca1 and negative for CD31, CD45, VCAM-1, and α7-Integrin (Figure 4). This analysis confirmed the use of Sca1 antibody as a marker for FAPs in both quiescent and activated FAPs and provides means for the indistinct use of either strategy to isolate FAPs.

In this protocol, FAPs and MuSCs were also isolated from adult mice injured with intramuscular injections of Notexin, 7 days post-injury (Figure 5). Following injury, MuSCs and FAPs activate and proliferate in vivo, reaching the peak of proliferation between day 3 and 42,3. These changes in proliferation are reflected by an increase in the percentage of Sca1/PDFGRα as well as VCAM-1/α7-Integrin positive cells. Figure 6 represents the quantification of FAPs and MuSCs in uninjured and 7 days post-injury TAs; although the peak in proliferation is observed between days 2 and 3 after injury, a low rate of proliferating cells is still appreciable 7 days after injury. As MuSCs are activated, there is a marked increase in their cellular size21,22. Therefore, while isolating these cells by FACS, it is of critical importance to adjust FSC-A and SSC-A parameters and expand the gate to include those cells in the center (Figure 5A).

The purity of the isolated cell populations was confirmed by immunostaining of cocultured GFP+ FAPs and MuSCs with Pax7 antibodies. Freshly isolated GFP+ FAPs and MuSCs were cocultured for 48 h at a ratio of 1:1 (Figure 3B). GFP+ FAPs did not express Pax7 marker, while MuSCs reacted with this antibody. Thus, Lin-/Sca-1+/VCAM-1-/α7-Integrin- and Lin-/Sca-1-/VCAM-1+/α7-Integrin+ gating strategy is effective in isolating pure populations of FAPs and MuSCs, respectively.

Figure 1
Figure 1: Graphical overview of FAP and MuSC isolation. Graphical overview showing FAP and MuSC isolation from hind limb muscles. The protocol also applies to cells isolated from TA muscles. First, muscles are collected and mechanically minced before undergoing enzymatic digestion. The muscle mixture is then processed through a 20 G needle and filtered to obtain a suspension of mononucleated cells. Cells are then incubated with a cocktail of fluorophore-conjugated antibodies and ultimately run through a cell sorter to isolate a pure population of FAPs and MuSCs. Pure cell populations are then processed for downstream application. Please click here to view a larger version of this figure.

Figure 2
Figure 2: Representative FACS profile of quiescent FAPs and MuSCs. (AH) Gating strategy for the isolation of FAPs and MuSCs. (A) First, samples are gated to exclude cellular debris and (B,C) doublets based on SSC and FSC properties. (D) The resulting single cells are then stained with 7-AAD to evaluate their viability. (E) 7-AAD negative single cells are then assessed for APC-CD31/CD45 and Pacific Blue-Sca1 to exclude Lineage positive cells from further analysis. (F,G) Lineage negative singlets are then stained for PE-Cy7-VCAM-1 and PE-α7-Integrin. (F) FAPs are identified as CD31-/CD45-/Sca1+/VCAM-1-/α7-Integrin- cells and (G) MuSCs are identified as CD31-/CD45-/Sca1-/VCAM-1+/α7-Integrin+ cells. (H) FAPs isolation in PDGFRα-EGFP mice using a GFP reporter. (IM) FACS profile for Fluorescence Minus One (FMO) controls to demonstrate proper compensation and gating. Please click here to view a larger version of this figure.

Figure 3
Figure 3: Validation of FAP and MuSC cell culture. (A) Freshly isolated FAPs expressing GFP were plated and co-stained with a PDGFRα antibody. Nuclei were stained with DAPI. Merged images of GFP (green), PDGFRα (red), and DAPI (blue) staining are displayed. Scale bars, 25 μm. (B) Freshly isolated FAPs (green) and MuSCs were cocultured for 48h and stained with Pax7 (red). Nuclei were stained with DAPI. GFP-expressing FAPs do not express Pax7, while MuSCs exclusively express Pax7 and are not positive for GFP, confirming the purity of both sorted populations. Scale bars, 75 μm. Please click here to view a larger version of this figure.

Figure 4
Figure 4: PDGFRα-EGFP mice and Sca1 expression specifically label FAPs in adult mice. FAPs are isolated as GFP+/Sca1+ cells. 7-AAD negative single cells are assessed for APC-CD31/CD45 and GFP-PDGFRα to exclude Lineage positive cells and distinguish FAPs. Lineage negative/Sca1 positive cells are stained for PE-Cy7-VCAM-1 and PE-α7-Integrin to exclude MuSCs. FAPs are identified as CD31-/CD45-/PDGFRα+/Sca1+/VCAM-1-/α7-Integrin- cells. Please click here to view a larger version of this figure.

Figure 5
Figure 5: Representative FACS profile of activated FAPs and MuSCs. (AH) Gating strategy for the isolation of activated FAPs and MuSCs. (A) Samples are gated to exclude cellular debris by creating FSC-A vs SSC-A density plot. Note the enlarged gate to accommodate the population of interest. (B,C) Samples are further gated to eliminate doublets based on SSC and FSC properties. (D) The resulting single cells are then stained with 7-AAD to evaluate their viability. (E) 7-AAD negative single cells are then assessed for APC-CD31/CD45 and Pacific Blue-Sca1 to exclude Lineage positive cells from further analysis. (F,G) Lineage negative singlets are then stained for PE-Cy7-VCAM-1 and PE-α7-integrin. (F) FAPs are identified as CD31-/CD45-/Sca1+/VCAM-1-/α7-integrin- cells and (G) MuSCs are identified as CD31-/CD45-/Sca1-/VCAM-1+/α7-integrin+ cells. (H) FAPs isolation in PDGFRα-EGFP mice using a GFP reporter. (IM) FACS profile for Fluorescence Minus One (FMO) controls to demonstrate proper compensation and gating. Please click here to view a larger version of this figure.

Figure 6
Figure 6: Quantification of FAPs and MuSCs in unperturbed and injured TAs. Quantification of FAPs and MuSCs in uninjured and 7 days post-injury TA muscles. Cell counting was performed by dividing the number of cells sorted per mgs of muscle collected. ** P < 0.01 between uninjured vs injured. Please click here to view a larger version of this figure.

7-AAD
(µg/mL)
CD31/CD45-APC
(µg/mL) 
Sca1-Pacific Blue
(µg/mL)
α 7-Integrin-PE
(µg/mL)
VCAM-1-Biotin
(µg/mL)
PE-Cy7 Streptavidin
(µg/mL)
Unstained Control
Single Stained Controls
7-AAD (Viability Control) 1
CD31/CD45 2
Sca1 5
α7-Integrin 1
VCAM-1 5 2
FMO Controls
FMO 7 AAD 2 5 1 5 2
FMO CD31/CD45 1 5 1 5 2
FMO Sca1 1 2 1 5 2
FMO α7-Integrin 1 2 5 5 2
FMO VCAM-1 1 2 5 1
Experimental sample
Full stain 1 2 5 1 5 2

Table 1: Antibody staining matrix. List of antibody concentrations used for staining the experimental and control samples. If isolating FAPs by GFP, Sca1 staining can be omitted. Instead, run GFP single stained control and GFP FMO.

Discussion

Establishing efficient and reproducible protocols for the identification and isolation of pure adult stem cell populations is the first and most critical step toward understanding their function. Isolated FAPs and MuSCs can be used to conduct multiomics analysis in transplantation experiments as a potential treatment for muscular diseases or can be genetically modified for disease modeling in stem cell therapy.

The protocol described here provides standardized guidelines for the identification, isolation, and culture of FAPs and MuSCs obtained from hind limb muscles of adult mice. Pure populations of FAPs and MuSCs were isolated using a FACS-based technique, and their purity was subsequently assessed by immunostaining cells with specific cell surface markers and genetic means.

The protocol consists of three main sections that highly impact the yield of FAPs and MuSCs: the mechanical and enzymatic muscle digestion, the generation of a mononucleated cell suspension through the 20 G needle, and the final isolation of single cells through FACS.

Performing proper muscle mincing is of critical importance to release single cells. Emphasis should be placed on this step, as reaching the optimal size of the muscle pieces after mincing allows the enzymes used for digestion to work best and prevents clogging the needle used in step 4.1. On the other hand, over-mincing the muscle may result in poor cell yield and reduced cell viability, as MuSCs are rapidly released during the first digestion and may be aspirated in step 3.7.2 or 3.8.214. Additionally, the efficiency of the enzymes used for the digestion of the muscle preparation also impacts the quality of the enzymatic dissociation, as there may be variability among different enzyme lots or a decrease in enzymes’ activity with time23. Therefore, it is advised to test each batch of enzymes to optimize the digestion timing and concentration. Furthermore, the concentration and amount of time required for digesting the muscle may also be affected by pathological conditions that affect muscle stiffness. These particular conditions will require individual optimization.

The final generation of mononucleated cells happens by running the suspension through a 10 mL syringe with a 20 G needle. Specific care should be taken when performing this step to minimize the number of bubbles formed as their bursting causes additional cell damage24.

The cell suspension is then stained with an antibody cocktail and acquired with a cell sorter. Setting the proper gates is another critical step. When performing these experiments, it is strongly recommended to run the listed single stained controls and FMO controls to properly compensate for emission spillover and account for the background signal due to spillover spread. This is especially important when dealing with bright fluorescent proteins like GFP and indirect stains like the VCAM-1-biotin/Stretpavidin-PE-Cy7 complex.

Moreover, before executing this experiment for the first time, it is good practice to perform a titration of the antibodies used to detect populations of interest. Determining the optimal concentration of the antibodies is a critical step to ensuring the brightest signal of the positive population and avoiding the increase in background staining.

Once the sorting is completed, it is important to perform a post-sort analysis on the sorted cells to determine their purity and viability. The yield and viability of the sorted cells are highly influenced by the amount of time required to process the sample and should be taken into consideration when planning to process multiple mice. Furthermore, keeping the sorted cells on ice in 2x serum-enrich media can help cell recovery and improve their viability.

In this protocol, FAPs and MuSCs were isolated from the tibialis anterior muscles of uninjured mice as well as 7 days after Notexin injection. Following an acute injury, different FAP and MuSC sub-populations have been reported to be transiently expressed in the regenerating muscle tissue. Malecova and colleagues have reported the presence of a sub-population of VCAM-1 expressing FAPs that is absent in undamaged muscle, peaked between days 2 and 3 post-injury in acute inflammation, and persisted in murine dystrophic mice13. Similarly, Kafadar and colleagues have reported a transient increase in the expression of Sca1 on a small subset of myogenic progenitors 2 days post injury25. However, Sca1+ myogenic cells were greatly decreased 3 days after injury25. The presence of these subpopulations should be acknowledged and considered when using this protocol to isolate FAPs and MuSCs at earlier stages.

In summary, this protocol describes a method for the isolation and culture of a pure population of FAPs and MuSCs isolated from either healthy or injured adult mouse muscles. The high purity and viability of the cells make this protocol suitable for further downstream applications.

Disclosures

The authors have nothing to disclose.

Acknowledgements

We would like to thank Tom Cheung (The Hong Kong University of Science & Technology) for advice on MuSC isolation. This work was funded by the NIAMS-IRP through NIH grants AR041126 and AR041164.

Materials

5 mL Polypropylene Round-Bottom Tube Falcon 352063
5 mL Polystyrene Round-Bottom Tube with Cell-Strainer Cap Falcon 352235
20 G BD Needle 1 in. single use, sterile BD Biosciences  305175
anti-Alpha 7 Integrin PE (clone:R2F2) (RatIgG2b) The University of British Columbia 53-0010-01
APC anti-mouse CD31 Antibody BioLegend 102510
APC anti-mouse CD45 Antibody BioLegend 103112
BD FACSMelody Cell Sorter BD Biosciences 
BD Luer-Lok tip control syringe, 10-mL BD Biosciences  309604
Biotin anti-mouse CD106 Antibody BioLegend 105703
C57BL/6J  mouse (Female and Male) The Jackson Laboratory 000664
B6.129S4-Pdgfratm11(EGFP)Sor/J mouse The Jackson Laboratory 007669
Corning BioCoat Collagen I 6-well Clear Flat Bottom TC-treated Multiwell Plate Corning 356400
Corning BioCoat Collagen I 12-well Clear Flat Bottom TC-treated Multiwell Plate Corning 356500
Corning BioCoat Collagen I 24-well Clear Flat Bottom TC-treated Multiwell Plate Corning 356408
DAPI Solution (1 mg/mL) ThermoFisher Scientific 62248
Disposable Aspirating Pipets, Polystyrene, Sterile VWR 414004-265
Donkey anti-Goat IgG (H+L) Highly Cross-Adsorbed Secondary Antibody, Alexa Fluor 488 ThermoFisher Scientific A-11055
Falcon 40 µm Cell Strainer, Blue, Sterile Corning 352340
Falcon 60 mm TC-treated Cell Culture Dish, Sterile Corning 353002
Falcon Centrifuge Tubes, Polypropylene, Sterile, Corning, 15-mL VWR 352196
Falcon Centrifuge Tubes, Polypropylene, Sterile, Corning, 50-mL Corning 352070
Falcon Round-Bottom Tubes, Polypropylene, Corning VWR 60819-728
Falcon Round-Bottom Tubes, Polystyrene, with 35um Cell Strainer Cap Corning VWR 21008-948
Fibroblast Growth Factor, Basic, Human, Recombinant (rhFGF, Basic) Promega G5071
FlowJo 10.8.1
Gibco Collagenase, Type II, powder ThermoFisher Scientific 17101015
Gibco Dispase, powder ThermoFisher Scientific 17105041
Gibco DMEM, high glucose, HEPES ThermoFisher Scientific 12430054
Gibco Fetal Bovine Serum, certified, United States ThermoFisher Scientific 16000044
Gibco Ham's F-10 Nutrient Mix ThermoFisher Scientific 11550043
Gibco Horse Serum, New Zealand origin ThermoFisher Scientific 16050122
Gibco PBS, pH 7.4 ThermoFisher Scientific 10010023
Gibco PBS (10x), pH 7.4 ThermoFisher Scientific 70011044
Gibco Penicillin-Streptomycin-Glutamine (100x) ThermoFisher Scientific 10378016
Goat anti-Mouse IgG1 cross-absorbed secondary antibody, Alexa Fluor 555 ThermoFisher Scientific A-21127
Hardened Fine Scissors Fine Science Tools Inc 14090-09
Invitrogen 7-AAD (7-Aminoactinomycin D) ThermoFisher Scientific A1310
Mouse PDGF R alpha Antibody R&D Systems AF1062
Normal Donkey Serum Fisher Scientific NC9624464
Normal Goat Serum ThermoFisher Scientific 31872
Pacific Blue anti-mouse Ly-6A/E (Sca 1) Antibody BioLegend 108120
Paraformaldehyde, 16% Fisher Scientific NCC0528893
Pax7 mono-clonal mouse antibody (IgG1) (supernatant) Developmental Study Hybridoma Bank N/A
PE/Cyanine7 Streptavidin BioLegend 405206
Student Vannas Spring Scissors Fine Science Tools Inc 91500-09
Student Dumont #5 Forceps Fine Science Tools Inc 91150-20
Triton X-100 Sigma-Aldrich T8787

References

  1. Baskin, K. K., Winders, B. R., Olson, E. N. Muscle as a "mediator" of systemic metabolism. Cell Metabolism. 21 (2), 237-248 (2015).
  2. Dumont, N. A., Bentzinger, C. F., Sincennes, M. C., Rudnicki, M. A. Satellite cells and skeletal muscle regeneration. Comprehensive Physiology. 5 (3), 1027-1059 (2015).
  3. Relaix, F., et al. Perspectives on skeletal muscle stem cells. Nature Communications. 12 (1), 692 (2021).
  4. Pawlikowski, B., Pulliam, C. J., Betta, N. D., Kardon, G., Olwin, B. B. Pervasive satellite cell contribution to uninjured adult muscle fibers. Skeletal Muscle. 5, 42 (2015).
  5. Joe, A. W. B., et al. Muscle injury activates resident fibro/adipogenic progenitors that facilitate myogenesis. Nature Cell Biology. 12 (2), 153-163 (2010).
  6. Wosczyna, M. N., et al. Mesenchymal stromal cells are required for regeneration and homeostatic maintenance of skeletal muscle. Cell Reports. 27 (7), 2029-2035 (2019).
  7. Theret, M., Rossi, F. M. V., Contreras, O. Evolving roles of muscle-resident fibro-adipogenic progenitors in health, regeneration, neuromuscular disorders, and aging. Frontiers in Physiology. 12, 673404 (2021).
  8. Uezumi, A., Fukada, S. I., Yamamoto, N., Takeda, S., Tsuchida, K. Mesenchymal progenitors distinct from satellite cells contribute to ectopic fat cell formation in skeletal muscle. Nature Cell Biology. 12 (2), 143-152 (2010).
  9. Wosczyna, M. N., Biswas, A. A., Cogswell, C. A., Goldhamer, D. J. Multipotent progenitors resident in the skeletal muscle interstitium exhibit robust BMP-dependent osteogenic activity and mediate heterotopic ossification. Journal of Bone and Mineral Research. 27 (5), 1004-1017 (2012).
  10. Eisner, C., et al. Murine tissue-resident PDGFRα+ fibro-adipogenic progenitors spontaneously acquire osteogenic phenotype in an altered inflammatory environment. Journal of Bone and Mineral Research. 35 (8), 1525-1534 (2020).
  11. Biferali, B., Proietti, D., Mozzetta, C., Madaro, L. Fibro-adipogenic progenitors cross-talk in skeletal muscle: The social network. Frontiers in Physiology. 10, 1074 (2019).
  12. Lemos, D. R., et al. Nilotinib reduces muscle fibrosis in chronic muscle injury by promoting TNF-mediated apoptosis of fibro/adipogenic progenitors. Nature Medicine. 21 (7), 786-794 (2015).
  13. Malecova, B., et al. Dynamics of cellular states of fibro-adipogenic progenitors during myogenesis and muscular dystrophy. Nature Communications. 9, 3670 (2018).
  14. Liu, L., Cheung, T. H., Charville, G. W., Rando, T. A. Isolation of skeletal muscle stem cells by fluorescence-activated cell sorting. Nature Protocols. 10 (10), 1612-1624 (2015).
  15. Maesner, C. C., Almada, A. E., Wagers, A. J. Established cell surface markers efficiently isolate highly overlapping populations of skeletal muscle satellite cells by fluorescence-activated cell sorting. Skeletal Muscle. 8, 6-35 (2016).
  16. Low, M., Eisner, C., Rossi, F. M. V. Fibro/adipogenic progenitors (FAPs): Isolation by FACS and culture. Methods and Protocols. 1556, 179-189 (2017).
  17. Judson, R. N., Low, M., Eisner, C., Rossi, F. M. V. Isolation, culture, and differentiation of fibro/adipogenic progenitors (FAPs) from skeletal muscle. Methods in Molecular Biology. 1668, 93-103 (2017).
  18. Hamilton, T. G., Klinghoffer, R. A., Corrin, P. D., Soriano, P. Evolutionary divergence of platelet-derived growth factor alpha receptor signaling mechanisms. Molecular and Cellular Biology. 23 (11), 4013-4025 (2003).
  19. Contreras, O., et al. Cross-talk between TGF-β and PDGFRα signaling pathways regulates the fate of stromal fibro-adipogenic progenitors. Journal of Cell Science. 132 (19), (2019).
  20. Holmes, C., Stanford, W. L. Concise review: Stem cell antigen-1: Expression, function, and enigma. Stem Cells. 25 (6), 1339-1347 (2007).
  21. Rodgers, J. T., Schroeder, M. D., Chanthia, M., Rando, T. A. HGFA Is an injury-regulated systemic factor that induces the transition of stem cells into GAlert. Cell Reports. 19 (3), 479-486 (2017).
  22. García-Prat, L., et al. FoxO maintains a genuine muscle stem-cell quiescent state until geriatric age. Nature Cell Biology. 22 (11), 1307-1318 (2020).
  23. Yamamoto, T., et al. Deterioration and variability of highly purified collagenase blends used in clinical islet isolation. Transplantation. 84 (8), 997-1002 (2007).
  24. Walls, P. L. L., et al. Quantifying the potential for bursting bubbles to damage suspended cells. Scientific Reports. 7 (1), 1-9 (2017).
  25. Kafadar, K. A., et al. Sca-1 expression is required for efficient remodeling of the extracellular matrix during skeletal muscle regeneration. Developmental Biology. 326 (1), 47-59 (2009).

Play Video

Cite This Article
Riparini, G., Simone, J. M., Sartorelli, V. FACS-Isolation and Culture of Fibro-Adipogenic Progenitors and Muscle Stem Cells from Unperturbed and Injured Mouse Skeletal Muscle. J. Vis. Exp. (184), e63983, doi:10.3791/63983 (2022).

View Video