Evaluation of Injury-induced Senescence and In Vivo Reprogramming in the Skeletal Muscle

Podsumowanie

Here we present a detailed protocol to detect both senescent and pluripotent stem cells in the skeletal muscle upon injury while inducing in vivo reprogramming. This method is suitable for evaluating the role of cellular senescence during tissue regeneration and reprogramming in vivo.

Streszczenie

Cellular senescence is a stress response that is characterized by a stable cellular growth arrest, which is important for many physiological and pathological processes, such as cancer and ageing. Recently, senescence has also been implicated in tissue repair and regeneration. Therefore, it has become increasingly critical to identify senescent cells in vivo. Senescence-associated β-galactosidase (SA-β-Gal) assay is the most widely used assay to detect senescent cells both in culture and in vivo. This assay is based on the increased lysosomal contents in the senescent cells, which allows the histochemical detection of lysosomal β-galactosidase activity at suboptimum pH (6 or 5.5). In comparison with other assays, such as flow cytometry, this allows the identification of senescent cells in their resident environment, which offers valuable information such as the location relating to the tissue architecture, the morphology, and the possibility of coupling with other markers via immunohistochemistry (IHC). The major limitation of the SA-β-Gal assay is the requirement of fresh or frozen samples.

Here, we present a detailed protocol to understand how cellular senescence promotes cellular plasticity and tissue regeneration in vivo. We use SA-β-Gal to detect senescent cells in the skeletal muscle upon injury, which is a well-established system to study tissue regeneration. Moreover, we use IHC to detect Nanog, a marker of pluripotent stem cells, in a transgenic mouse model. This protocol enables us to examine and quantify cellular senescence in the context of induced cellular plasticity and in vivo reprogramming.

Wprowadzenie

Cellular senescence is a form of stress response characterized by a stable cell-cycle arrest. In the last decade, research has firmly established that senescence is associated with various biological and pathological processes including embryonic development, fibrosis, and organism ageing^1,2. Cellular senescence was first identified in human fibroblasts at the end of their replicative lifespan triggered by telomere shortening³. Besides replicative stress, there are many other stimuli that can induce senescence, including DNA damage, oxidative stress, oncogenic signals, and genomic/epigenomic alterations, any of which may eventually activate the p53/p21 and/or pRB pathways to establish and reinforce the permanent growth arrest¹. One of the important characteristics of senescent cells is that they remain metabolically active and robustly express a senescence-associated secretory phenotype (SASP): secretion of many inflammatory cytokines, growth factors, and extracellular matrix factors⁴. SASP factors have been proposed to play an important role in mediating and amplifying the senescence effect, due to their potent effects on attracting immune cells and altering local and systemic tissue milieus¹. Interestingly, senescence has been recently proposed to be important for tissue repair and regeneration^5,6. In addition, data from several labs, including ours, has suggested that tissue damage-induced senescence might enhance cellular plasticity, via SASPs, to promote regeneration^7-9. Therefore, all the emerging data highlight the importance of studying senescence in vivo.

In the post induced pluripotent stem cell (iPSC) era, cellular plasticity is the capacity of a cell to acquire a new identity and to adopt an alternative fate when exposed to different stimuli both in culture and in vivo¹⁰. It is known that full reprogramming can be achieved in vivo^11,12, where the expression of the the cassette containing four Yamanaka factors: Oct4, Sox2, Klf4, and c-Myc (OSKM) can be induced in vivo to promote teratomas formation in multiple organs. Therefore, a reprogrammable mouse model (i4F) can be used as a powerful system to identify critical regulators and pathways that are important for cellular plasticity¹¹.

A suitable and sensitive in vivo system is essential to understand how cellular senescence regulates cellular plasticity in the context of tissue regeneration. Here, we present a robust system and a detailed protocol to evaluate the link between senescence and cellular plasticity in the context of tissue regeneration. The combination of cardiotoxin (CTX) induced muscle damage in the Tibialis Anterior (TA) muscle group, a well-established system to study tissue regeneration, and the i4F mouse model, allows the detection of both cellular senescence and in vivo reprogramming during muscle regeneration.

To evaluate the link between cellular plasticity and senescence, i4F mice are injured with CTX to induce acute muscle damage and treated with doxycycline (0.2 mg/mL) over 7 days to induce in vivo reprogramming. While a CTX induced acute muscle damage and regeneration protocol has been recently published¹³, for ethical reasons, this procedure will be omitted in the current protocol. TA muscle samples will be collected at 10 days post injury¹³, when the peak of senescent cells have been previously observed¹⁴. Here, this detailed protocol describes all the steps required to evaluate the level of senescence (via SA-β-Gal) and reprogramming (via IHC staining of Nanog).

Senescence-associated beta-galactosidase (SA-β-Gal) assay is the most commonly used assay to detect senescent cells both in culture and in vivo¹⁵. Compared to other assays, the SA-β-Gal assay allows the identification of the senescent cells in their native environment with intact tissue architecture, which is particularly important for in vivo study. Moreover, it is possible to couple the SA-β-Gal assay with other markers using IHC. However, the SA-β-Gal assay does require fresh or frozen samples, which remains a major limitation. When fresh or frozen tissues are routinely available, such as frozen TA muscle samples, SA-β-Gal is obviously the most suitable assay to detect senescent cells. Nanog is the marker used to detect reprogramed cells for two reasons: 1) it is an essential marker for pluripotency; 2) more importantly, its expression is not driven by doxycycline (dox), therefore it detects induced pluripotency rather than the forced expression of the Yamanaka cassette.

It is important to note, the staining protocols presented in this study can be conducted separately to simplify the quantification procedure, but can also be done in a co-staining procedure to visualize both senescent and pluripotent stem cells on the same section.

Protokół

Animals were handled as per European Community guidelines and the ethics committee of the Institut Pasteur (CETEA) approved protocols.

1. Preparations of the Stock Solutions

1. Prepare the materials for muscle sample fixation.Dissolve 0.5 g of tragacanth gum with 20 mL water at RT to make the freezing-embedding medium for muscle fixation.
2. Prepare the solutions for SA-β-Gal staining.
   1. Prepare the stock solutions of K₃Fe(CN)₆ (100 mM), K₄Fe(CN)₆ (100 mM), MgCl₂ (1M) by dissolving the respective powders in distilled water.
   2. Prepare the stock solution of 0.2% C₂₀H₆Br₄Na₂O₅ (Eosin) by diluting it in water.
   3. Prepare the stock solution of C₁₄H₁₅BrClNO₆(X-gal) (50 mg/mL) by dissolving the X-gal powder in C₃H₇NO (dimethylformamide, DMF).
   4. Store K₃Fe(CN)₆ and K₄Fe(CN)₆ solutions at 4 °C, and MgCl₂ at RT.
      NOTE: X-gal can be stored in aliquot at -20 °C, up to 6 months. Eosin solution can be kept at RT and reused after filtering if necessary. K₃Fe(CN)₆ and K₄Fe(CN)₆ solutions are protectedfromthe light. X-gal solution is not stable in water and has to be protected from light.
3. Preparation of the solutions for Nanog staining: the permeabilization solution contains 0.1% Na₃C₆H₅O₇ (trisodium citrate), 0.1% C₁₄H₂₂O(C₂H₄O)_n(n = 9-10) (Triton X-100) in distilled water, which should be stored at 4 °C. Prepare the blocking solution containing 5% fetal bovine serum (FBS) in phosphate-buffered saline (PBS), which should be stored at RT.

2. SA-β-Gal Staining on Frozen TA Muscle Section

1. Prepare the fixation material for the TA muscle by placing a small amount of the tragacanth gum on a slice of cork.
2. Injured mice of both sexes (2 month old, C57/B6) were injured 10 days before with cardiotoxin (CDX) as described previously¹³. Use non-injured (PBS injection) TA from the same mouse as the negative control. If in vivo reprogramming is desired, treat each mouse with Dox (1 mg/mL) in the drinking water on the same day (protected from the light), right after CTX injury.
   NOTE: The Dox solution needs to be changed every 3 days for a total treatment duration of 7 days.
   1. Isolate both TA muscles (injured and control) from mice as described previously (Figure 1A)¹³. To ensure the transverse sections, insert the distal tendon of the TA muscle into the tragacanth gum and leave roughly ¾ part of the muscle outside (Figure 1B) and freeze directly in liquid nitrogen cooled isopentane for <1 min.
      NOTE: Make sure the TA muscle is in a perpendicular position and in the center of the cork. Samples can be stored at -80°C or directly cryosectioned in 10 µm sections.
3. Process the TA muscles as described in the Figure 1B.
   1. Distribute the 1^st-10^th sections in the correct order onto ten different slides at the upper left position of each slide. Place the 11^th section adjacent to the 1^st section on the first slide; the 12^th section will follow the same order to be placed right besides the 2^nd section on the second slide. Repeat this process till 10 sections/slide are obtained for ten slides (100 sections in total) to ensure minimum 1 mm distance between the first section and the last section.
4. Fix the sections for 4 min in PBS containing 1% paraformaldehyde and 0.2% glutaraldehyde. Wash with PBS, 2x 10 min. Next, incubate the sections in PBS (pH = 5.5) for 30 min. Perform all the steps at RT.
   NOTE: The fixation has to be mild to maintain enzymatic activity. Perform this step under the hood. The pH of the PBS is critical and the X-gal solution must be protected from light.
5. Incubate sections in the X-gal solution containing: 4 mM K3Fe(CN)₆, 4 mM K4Fe(CN)₆, 2 mM MgCl2, and 400 µg/mL X-Gal in PBS, pH = 5.5. Incubate in the dark at 37 °C for a minimum of 24 h. Wash the slides with PBS, 3x 10 min, at RT.
   NOTE: The incubation requires a minimum of 24 hours and can last for 48 hours to maximize the SA-β-Gal signal. The solution needs to be changed after 24 hours of incubation. The slides should be protected from light. If only SA-β-Gal staining is desired, continue with step 2.5. If co-staining with Nanog is desired, please skip forward to step 3.1.
6. Fix slides in 1% paraformaldehyde in PBS for 30 min. Wash slides with PBS, 3x 10 min. Counterstain with 0.2% eosin. Immerse the slides in the eosin solution for 1 min and rinse them with distilled water briefly. Finally, mount the slides with aqueous non-fluorescing mounting medium (see Table of Materials).
   NOTE: It is essential to perform the post-fixation. Perform this step under the hood. All steps are performed at RT.

3. Immunohistochemistry Using Anti-Nanog Antibody

1. Fix the slides with PBS containing 4% paraformaldehyde for 10 min. Wash with PBS, 2x 10 min. Add 200 µL of the permeabilization solution directly onto the slides and incubate for 5 min.
   1. Wash slides with PBS, 2x 5 min and in the last wash, use 200 µL PBS containing 0.25% BSA directly on the slides. Perform all these steps at RT.
      Caution: Perform the fixation step under the hood.
2. Incubate slides with the primary anti-Nanog antibody (final concentration: 1.25 ug/mL) overnight at 4 °C in PBS containing 5% FBS. Wash slides with PBS, 2x 10 min and in the last wash, use 200 µL PBS containing 0.25% BSA for 5 min. Perform all the washing steps at RT.
   NOTE: Incubate slides in a box with wet paper towel to prevent evaporation.
3. Incubate slides with 100 µL of rAb-HRP secondary antibody from a ready to use kit (see Table of Materials) for 45 min. Wash slides with PBS, 3x 5 min, to remove secondary antibody. Perform all the steps at RT with protection from light.
4. Visualization
   1. First, dilute the 3,3'-diaminobenzidine (C₁₂H₁₄N₄C₁₂H₁₈Cl₄N₄(₄HCl), DAB) in the substrate buffer provided by the ready to use kit (20 µL of DAB for 1 mL of substrate buffer solution). Add 100 µL of DAB solution directly onto each slide and incubate for a maximum of 10 min at RT.
      NOTE: The diluted DAB solution should be prepared freshly and can be stored for up to one week at 4 °C. The incubation time can be adjusted to minimize the background signal but must be kept the same for all slides.
   2. Remove the DAB solution by rinsing with water. Counterstain the slides with fast red solution (ready to use, see the Table of Materials) for 20 min. Wash the slides with water again briefly.
   3. Dehydrate them with 95% ethanol for 5 min followed by 100% ethanol, 2x 5 min. Finally, mount the slides with quick-hardening mounting medium (see Table of Materials).
   4. Observe the slides under the microscope in bright field at 20X to avoid background.
      NOTE: Fast red solution can be kept at RT and re-used after filtering.

4. Analysis and Quantification

1. SA-β-Gal quantification
   1. Scan the slides and choose the best sections on each slide based on the acquired images. Use at least 2 sections/TA for the quantification. Judge the section's quality based on tissue integrity, quality of the staining, and counterstaining. For the quantification, choose the two highest quality sections with the maximum possible distance in between samples, which allows better representation of SA-β-Gal quantification throughout the whole TA muscle.
   2. Quantification of SA-β-Gal positive cells (Figure 2).
      1. Determine the rank of the pixel size by manually selecting the smallest and the largest positive SA-β-Gal cells.
         1. Open the digital image of the scanned slide using ImageJ software.
         2. In the interface, click 'Analyze' > 'Tools' > 'ROI Manager' > 'Analyze' > 'set measurement' > 'select Area'. Use the selection tool and surround the smallest and biggest positive SA-β-Gal cell and add it to the ROI manager by clicking on 'Add'. Measure the sizes using the 'Measure' button and save the values for later use.
      2. Adjust the threshold parameter to ensure all the visible positive cells are selected.
         1. Convert the image to gray scale by clicking 'Image' > 'type' > '8-bit' (Figure 2A). Next, go to 'Image' > 'Adjust' > 'Threshold', move the second cursor until all the positive SA-β-Gal cells are covered in red (Figure 2B), then click 'Apply'.
         2. Analyze particles by clicking 'Analyze' > 'Analyze Particles' > 'Size (pixel^2)', and apply the value defined in step 4.1.2.1, enter 'Circularity': '0.00-1.00', click 'ok' ; a summary of all the counted particles is shown in the ROI manager (Figure 2D).
      3. Transfer all the selected particles to the original image. Adjust the selection manually to ensure accurate quantification. Add positive cells (green arrow, Figure 2E) and/or remove false positive cells (red arrow, Figure 2E). Finally, measure the area by outlining the section (Figure 2D) using the 'selection tool'. Click 'ROI manager' > 'Add' > 'Measure'.
      4. Importantly, normalize the number of positive cells by the area of the section.
2. Nanog quantification
   1. Count the Nanog positive cells under the microscope in the bright field manually at 20X magnification.
      NOTE: The fast red counterstaining allows good evaluation of the morphology of the TA muscle. However, the staining is very light and lacks a clear outline of the section. The scanner often fails to identify the boundary of the sections and cannot focus correctly. It is possible to use marker to circle the edges of the sections before scanning or use a more sensitive scanner to detect the section. For the current protocol, it is most efficient to count the Nanog positive cells manually.

Wyniki

Detecting muscle injury-induced cellular senescence

It has been recently demonstrated that muscle injury induces transient cellular senescence¹⁴. At 10 days post-injury (DPI), the majority of the damaged myofibers are undergoing regeneration with centrally located nuclei, a hallmark of regenerating myofibers, and the architecture of the muscle is re-established. The infiltrating inflammatory cells are dramat...

Dyskusje

Here, we present a method to detect both senescent and pluripotent stem cells in the skeletal muscle of reprogrammable mice. This method could be used to evaluate and quantify both senescence and induce cellular plasticity in vivo, and examine the role of senescence in tissue repair and regeneration.

In the current protocol, the senescence-associated β-galactosidase (SA-β-Gal) assay is used to detect in vivo senescent cells in the skeletal muscle. This assay detects...

Materiały

Name	Company	Catalog Number	Comments
K3Fe(CN)6	Sigma	13746-66-2	For SA-β Gal staining solution
K4Fe(CN)6	Sigma	14459-95-1	For SA-β Gal staining solution
MgCl2	Sigma	7786-30-3	For SA-β Gal staining solution
X-Gal	Sigma	B4252	For SA-β Gal staining solution
Doxycycline	Sigma	D3447	For inducing in vivo reprogramming
Cardiotoxin	Lotaxan Valence, France	L8102	For muscle injury
Glutaraldehyde	Sigma	111-30-8	For Fixation solution
Paraformaldehyde	Electron microscopy science	50-980-487	For Fixation solution
NaCitrate : Sodium Citrate monobasic bioxtra, anhydre	Sigma	18996-35-5	For permeabilization solution
Triton	Sigma	93443	For permeabilization solution
Bovine Serum Albumin	Sigma	A3608	Washing solution
Antibody anti- Nanog	Cell signalling	8822S	Rabbit monoclonal antibody
EnVision+ Kits (HRP. Rabbit. DAB+)	Dako	K4010	For Nanog revelation
Eosin 1%	Leica	380159EOF	Counterstainning
Fast red	Vector Laboratories	H-3403	Counterstainning
Thermo Scientific Shandon Immu-Mount	Fisher scientific	9990402	Mounting solution
Quick-hardening mounting medium for microscopy : Eukitt®	Sigma	25608-33-7	Mounting solution
Microscope Phase Contrast Brightfield CKX41: 10X-20X-40X objectives	Olympus	CKX41	Microscope for Nanog quantification
Mouse: i4F-A	Abad et al., 2013	N/A	Reprogrammable mouse model
Skeletal muscle, Tibialis Anterior
Slide Scanner	Zeiss	Axio Scan Z1	slides scanning