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  • Podsumowanie
  • Streszczenie
  • Wprowadzenie
  • Protokół
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Podsumowanie

The pituitary gland is the key regulator of the body's endocrine system. This article describes the development of organoids from the mouse pituitary as a novel 3D in vitro model to study the gland's stem cell population of which the biology and function remain poorly understood.

Streszczenie

The pituitary is the master endocrine gland regulating key physiological processes, including body growth, metabolism, sexual maturation, reproduction, and stress response. More than a decade ago, stem cells were identified in the pituitary gland. However, despite the application of transgenic in vivo approaches, their phenotype, biology, and role remain unclear. To tackle this enigma, a new and innovative organoid in vitro model is developed to deeply unravel pituitary stem cell biology. Organoids represent 3D cell structures that, under defined culture conditions, self-develop from a tissue's (epithelial) stem cells and recapitulate multiple hallmarks of those stem cells and their tissue. It is shown here that mouse pituitary-derived organoids develop from the gland's stem cells and faithfully recapitulate their in vivo phenotypic and functional characteristics. Among others, they reproduce the activation state of the stem cells as in vivo occurring in response to transgenically inflicted local damage. The organoids are long-term expandable while robustly retaining their stemness phenotype. The new research model is highly valuable to decipher the stem cells' phenotype and behavior during key conditions of pituitary remodeling, ranging from neonatal maturation to aging-associated fading, and from healthy to diseased glands. Here, a detailed protocol is presented to establish mouse pituitary-derived organoids, which provide a powerful tool to dive into the yet enigmatic world of pituitary stem cells.

Wprowadzenie

The pituitary is a tiny endocrine gland located at the base of the brain, where it is connected to the hypothalamus. The gland integrates peripheral and central (hypothalamic) inputs to generate a tuned and coordinated hormone release, thereby regulating downstream target endocrine organs (such as adrenal glands and gonads) for producing appropriate hormones at the proper time. The pituitary is the key regulator of the endocrine system and is therefore rightfully termed the master gland1.

The mouse pituitary consists of three lobes (Figure 1), i.e., the anterior lobe (AL), the intermediate lobe (IL), and the posterior lobe (PL). The major endocrine AL contains five hormonal cell types, including somatotropes that produce growth hormone (GH); lactotropes generating prolactin (PRL); corticotropes that secrete adrenocorticotropic hormone (ACTH); thyrotropes responsible for thyroid-stimulating hormone (TSH) production; and gonadotropes that make luteinizing hormone (LH) and follicle-stimulating hormone (FSH). The PL consists of axonal projections from the hypothalamus in which the hormones oxytocin and vasopressin (antidiuretic hormone) are stored. The IL is located in-between the AL and PL and houses melanotropes that produce melanocyte-stimulating hormone (MSH). In the human pituitary, the IL regresses during development, and melanotropes are spread within the AL1. In addition to the endocrine cells, the pituitary gland also contains a pool of stem cells, essentially marked by the transcription factor SOX22,3,4,5,6. These SOX2+ cells are located in the marginal zone (MZ), the epithelial lining of the cleft (an embryonic remnant lumen between the AL and IL), or are spread as clusters throughout the parenchyma of the AL, thereby proposing two stem cell niches in the gland (Figure 1)2,3,4,5,6.

Given the indispensable nature of the pituitary, malfunctioning of the gland is associated with serious morbidity. Hyperpituitarism (characterized by over-secretion of one or more hormones) and hypopituitarism (defective or missing production of one or more hormones) can be caused by pituitary neuroendocrine tumors (PitNETs; e.g., ACTH-producing tumors leading to Cushing's disease) or by genetic defects (e.g., GH deficiency resulting in dwarfism)7. In addition, pituitary surgery (e.g., to remove tumors), infections (e.g., hypothalamic-pituitary tuberculosis, or infections following bacterial meningitis or encephalitis), Sheehan's syndrome (necrosis because of insufficient blood flow due to heavy blood loss at birth-giving), pituitary apoplexy and traumatic brain injury are other important causes of pituitary hypofunction8. It has been shown that the mouse pituitary possesses the regenerative capacity, being able to repair local damage introduced by transgenic ablation of endocrine cells9,10. The SOX2+ stem cells acutely react to the inflicted injury showing an activated phenotype, marked by enhanced proliferation (resulting in stem cell expansion) and increased expression of stemness-related factors and pathways (e.g., WNT/NOTCH). Moreover, the stem cells start to express the ablated hormone, finally resulting in substantial restoration of the depleted cell population over the following (5 to 6) months9,10. Also, during the neonatal maturation phase of the gland (the first 3 weeks after birth), the pituitary stem cells are thriving in an activated state6,11,12,13, whereas organismal aging is associated with declined in situ stem cell functionality, due to an increasing inflammatory (micro-) environment at aging (or 'inflammaging')10,14. In addition, tumorigenesis in the gland is also associated with stem cell activation7,15. Although stem cell activation has been detected in several situations of pituitary remodeling (reviewed in7,16), underlying mechanisms remain unclear. Since in vivo approaches (such as lineage tracing in transgenic mice) have not delivered a clear or comprehensive picture of pituitary stem cells, the development of reliable in vitro models to explore stem cell biology in normal and diseased pituitary is essential. Standard in vitro culture of primary pituitary stem cells remains inadequate because of very limited growth capacity and non-physiological (2D) conditions with rapid loss of phenotype (for a more detailed overview, see16). 3D sphere cultures (pituispheres) have been established from pituitary stem cells as identified by side population and SOX2+ phenotype2,3,4. The pituispheres clonally grow from the stem cells, express stemness markers and show differentiation capacity into the endocrine cell types. However, they do not considerably expand while showing only limited passageability (2-3 passages)3,4. Sphere-like structures were also obtained from non-dissociated pituitary stem cell clusters when cultured in 50% diluted Matrigel for 1 week, but expandability was not shown17. The pituisphere approach is mostly used as a read-out tool for stem cell numbers, but further applications are limited by inferior expansion capacity16.

To address and overcome these shortcomings, a new 3D model has recently been established, i.e., organoids, starting from the major endocrine AL of mice containing the MZ and parenchymal stem cells. It has been shown that the organoids are indeed derived from the pituitary's stem cells and faithfully recapitulate their phenotype18. Moreover, the organoids are long-term expandable, while robustly maintaining their stemness nature. Therefore, they provide a reliable method to expand primary pituitary stem cells for profound exploration. Such exploration is not achievable with the limited number of stem cells that can be isolated from a pituitary, which are also not expandable in 2D conditions16. It has been shown that the organoids are valuable and reliable tools to uncover new pituitary stem cell features (translatable to in vivo)14,18. Importantly, the organoid model faithfully mirrors the pituitary stem cell activation status as occurring during local tissue damage and neonatal maturation, showing enhanced formation efficiency and replicating upregulated molecular pathways14,18. Hence, the pituitary-derived organoid model is an innovative and powerful pituitary stem cell biology research model as well as a stem cell activation readout tool.

This protocol describes in detail the establishment of mouse pituitary-derived organoids. To this aim, the AL is isolated and dissociated into single cells, which are embedded in extracellular matrix-mimicking Matrigel (hereon referred to as ECM). The cell-ECM assembly is then cultured in a defined medium, essentially containing stem cell growth factors and pituitary embryonic regulators (further referred to as 'pituitary organoid medium' (PitOM)18; Table 1). Once the organoids are fully developed (after 10-14 days), they can be further expanded trough sequential passaging and subjected to extensive downstream exploration (e.g., immunofluorescence, RT-qPCR, and bulk or single-cell transcriptomics; Figure 1). In the longer run, it is expected that the pituitary stem cell organoids will pave the way to tissue repair approaches and regenerative medicine.

Protokół

Animal experiments for this study were approved by the KU Leuven Ethical Committee for Animal Experimentation (P153/2018). All mice were housed at the university's animal facility under standardized conditions (constant temperature of 23 ± 1.5 °C, relative humidity 40%-60%, and a day/night cycle of 12 h), with access to water and food ad libitum.

1. Mice

  1. Use commercially available mouse strains, such as C57BL/6J mice, of young-adult age (8-12 weeks old). In general, 2-3 mice provide a sufficient number of AL cells for the protocol.

2. Isolation and dissociation of mouse AL

NOTE: Medium A, B, and C are prepared in advance19,20. Compositions are shown in Table 2.

  1. Isolation of mouse AL
    1. Euthanize the mice by CO2 asphyxiation, followed by decapitation (Figure 2A). Wash mice heads with deionized water to remove the blood and spray them with 70% EtOH to generate a sterile environment.
    2. Using sterile surgical tools, remove the skin of the head between the ears (Figure 2B).
    3. Open the cranium and remove the brain.
      1. Break the 'nose bridge' (i.e., anterior part of the frontal bone; Figure 2B) with sterile scissors.
      2. Open the cranium further with scissors, starting from the broken nose bridge toward the ears, on both sides (Figure 2C).
      3. Remove the cranium and the brain with sterile tweezers, without touching the pituitary gland (Figure 2D).
    4. Remove the diaphragma sellae with blunt tweezers, without damaging the pituitary. Discard the PL and the IL from the AL under a stereomicroscope.
      NOTE: The PL and IL are linked and thus removed simultaneously. These parts appear as white tissue, as compared to the pink-colored AL (Figure 2D).
    5. Carefully isolate the AL with blunt tweezers and collect it in a 10 mL Erlenmeyer flask, filled with 3 mL of medium A (see Table 2). Place the flask on ice until further processing.
  2. Dissociation of mouse AL
    1. Remove the supernatant (SN) medium A from the Erlenmeyer flask containing the isolated AL. Add 2 mL of prewarmed (37 °C) 2.5% trypsin solution and incubate at 37 °C for 15 min.
    2. Without removing the trypsin solution, add 2 mL of prewarmed (37 °C) DNase solution (2 µg/mL in medium A; sterile-filtered through a 0.22 µm mesh), and swirl the Erlenmeyer flask 10 times. Let the pituitary sink to the bottom (~1 min) and remove the SN.
    3. Add 2 mL of prewarmed (37 °C) trypsin inhibitor solution (0.1 mg/mL in medium A; sterile-filtered through a 0.22 µm mesh) and incubate at 37 °C for 10 min. Let the pituitary sediment to the bottom and remove the SN.
    4. Add 2 mL of prewarmed (37 °C) medium B (see Table 2) and incubate at 37 °C for 5 min. Without removing the SN, add 2 mL of prewarmed (37 °C) medium C (see Table 2) and incubate at 37 °C for 15 min.
    5. Let the pituitary sink to the bottom and remove the SN. Rinse the pituitary three times with prewarmed (37 °C) medium C.
    6. Dissociate the pituitary into single cells.
      1. Add 2 mL of prewarmed (37 °C) medium C. Aspirate and expel the pituitary gland with a sterile, flame-polished Pasteur pipette multiple times, until fragments are not visible anymore.
      2. Transfer the suspension to a 15 mL tube with 4.5 mL of prewarmed (37 °C) DNase solution (2 µg/mL in medium A; sterile-filtered through a 0.22 µm mesh). Rinse the Erlenmeyer three times with 2 mL of prewarmed (37 °C) medium C and transfer the suspension to the 15 mL tube.
    7. Mix the collected cell suspension and filter it through a 40 µm cell strainer into a 30 mL tube. Rinse the 15 mL tube and the cell strainer three times with 2 mL of medium C and transfer the suspension to the 30 mL tube.
    8. Position the tip of a glass Pasteur pipette, filled with 2 mL of 3% bovine serum albumin (BSA) solution (in medium A; sterile-filtered through a 0.22 µm mesh), at the bottom of the tube and gently pipette out to form a visible density layer. Centrifuge at 190 x g for 10 min at 4 °C.
    9. Remove the SN by inverting the tube in one fluent movement and remove the remaining SN droplets with a P1000 tip. Resuspend the cell pellet in 1 mL of ice-cold Advanced DMEM/F12 (Adv DMEM/F12) and quantify the cells with a cell counter.

3. Establishment and culturing of AL-derived organoids

NOTE: Thaw ECM on ice in advance (2-3 h for 1 mL) and keep it on ice for the duration of the protocol.

  1. Organoid seeding and culturing
    1. Centrifuge the AL cell suspension at 190 x g for 10 min at 4 °C and remove the SN. Resuspend the cell pellet in Adv DMEM/F12 using the specific volume calculated to reach a cell density of 1.1 x 106 cells/mL.
      ​NOTE: For instance, if the cell suspension contains 500,000 cells/mL, one must resuspend the cell pellet in 454.54 µL of Adv DMEM/F12 to reach the desired density of 1.1 x 106 cells/mL.
    2. Take out the volume of cell suspension needed for plating (according to the desired number of wells to seed for organoid development) and add ECM in a 30:70 ratio (30% cell suspension (in Adv DMEM/F12 ) and 70% ECM). Mix well by pipetting up and down.
      NOTE: For instance, for one droplet of 30 µL (see step 3.1.3), one should (gently) mix 9 µL of cell suspension (containing ~10,000 cells when taken from the 1.1 x 106 cells/mL suspension) with 21 µL of ECM.
    3. Per well, deposit a 30 µL drop of the cell suspension/ECM mixture (see step 3.1.2) on a pre-warmed (37 °C) 48-well plate. Turn the plate upside down and let the ECM solidify at 37 °C for 20 min.
      NOTE: Pre-warm the culture plates for at least 24 h at 37 °C.
    4. Return the plate to its proper orientation and carefully add 250 µL of prewarmed (37 °C) PitOM (see Table 1) supplemented with 10 µM Rock Inhibitor (Y-27632).
    5. Continue to culture the organoids by changing the medium (devoid of Y-27632) every 2-3 days until the organoids are fully grown, which takes between 10-14 days (Figure 3A). Then, passage the organoids.
      NOTE: When aspirating the medium, make sure not to disrupt the ECM dome. Tilt the culture plate slightly and remove the medium from the bottom rim of the well. Fresh (prewarmed at 37 °C) medium should be added gently to the side of the well. If gel droplets de-attach, collect the organoids and resuspend and culture them again in a new ECM droplet.
  2. Organoid passaging
    1. Aspirate the medium gently and add 400 µL of ice-cold Adv DMEM/F12 to disintegrate the ECM and collect the organoids in a microcentrifuge tube. Wash once with 400 µL of ice-cold Adv DMEM/F12 EM. Centrifuge at 200 x g for 5 min at 4 °C.
    2. Remove the SN carefully and add 400 µL of prewarmed (37 °C) TrypLE Express Enzyme (1X). Mix by inverting the tube several times, and incubate at 37 °C for 5 min.
    3. Add 400 µL of ice-cold Adv DMEM/F12 and centrifuge at 200 x g for 5 min at 4 °C. Remove the SN.
    4. Resuspend the pellet with 100 µL of ice-cold Adv DMEM/F12 and subsequently break up the organoids by vigorously pipetting up and down with a narrowed P200 tip (i.e., push down the empty tip against the bottom of the microcentrifuge tube, to reduce its opening diameter) until organoid fragments (with a diameter around 50 µm) are obtained (Figure 3B).
      NOTE: The dissociation mixture should contain predominantly organoid fragments and only a few single cells. Harsh dissociation of the organoids into single cells negatively impacts the re-growth of the organoids.
    5. Add 800 µL of Adv DMEM/F12 and centrifuge at 190 x g for 10 min at 4 °C. Remove the SN.
    6. Passage the organoids in a 1:2 to 1:4 ratio. Resuspend the pellet in an adequate volume of Adv DMEM/F12 as needed for plating and add ECM in a 30:70 ratio (30% cell suspension and 70% ECM). Mix well by pipetting up and down.
    7. Seed and culture the organoids as described above in steps 3.1.3-3.1.5.
      ​NOTE: On average, 20 organoids develop per well from the 10,000 whole-AL cells seeded (0.2%). These passage 0 organoids can be split in a 1:2 ratio, resulting in >50 organoids developing per well (passage 1). Organoids can then be split in a 1:2 to 1:4 ratio during subsequent passages. Re-growth of the organoids slows down after ~10 passages (corresponding to 3 months of culture), concretized in gradually fewer and smaller organoids.

4. Cryopreservation of AL-derived organoids and thawing

  1. Cryopreservation of organoids
    1. Follow the passaging protocol from step 3.2.1 until step 3.2.5.
    2. Resuspend the organoid pellet (containing fragments and cells) with 1 mL of cryopreservation medium (Table 3). Transfer the suspension into a cryovial and place it on ice.
      ​NOTE: Organoids (i.e., resultant fragments and cells) from up to four wells of the 48-well plate can be combined in one cryovial.
    3. Place the cryovials in a freezing container and transfer them to -80 °C.
    4. After 24 h, transfer the samples to a cryobox and store them in liquid nitrogen (-196 °C) for long-term storage.
  2. Thawing of cryopreserved organoids
    1. Remove the cryovial from the liquid nitrogen tank and place it on ice. Immediately proceed with the thawing protocol.
    2. Thaw the solution with the cryopreserved organoid fragments and single cells at 37 °C (water bath).
      NOTE: Do not keep the solution for more than 2 min at 37 °C to avoid cell toxicity by DMSO.
    3. Transfer the content to a 15 mL tube containing 10 mL of ice-cold Adv DMEM/F12 with 30% fetal bovine serum (FBS). Rinse the cryovial with 1 mL of Adv DMEM/F12 with 30% FBS.
    4. Centrifuge at 190 x g for 10 min at 4 °C. Resuspend the pellet with 1 mL of ice-cold Adv DMEM/F12 and transfer the suspension to a microcentrifuge tube.
    5. Centrifuge at 190 x g for 10 min at 4 °C. Resuspend the pellet in an adequate volume of Adv DMEM/F12 as needed for plating and add ECM in a 30:70 ratio. Mix well by pipetting up and down.
    6. Seed and culture the organoids as described above in steps 3.1.3-3.1.5.

5. Validation of AL-derived organoids

  1. Collection and lysis of organoids for RNA isolation
    1. Collect and centrifuge the organoids as described above (step 3.2.1).
    2. Remove the SN and add 350 µL of lysis buffer with 1% 2-mercapto-ethanol. Vortex for 30 s and store at -80 °C or proceed immediately to RNA isolation.
      ​CAUTION: Beware that 2-mercapto-ethanol is a toxic compound. All work must be done in a chemical fume hood while wearing nitrile gloves, a dust mask, and safety glasses. 2-Mercapto-ethanol can cause irreversible damage to the eyes and skin.
  2. Fixation and embedding of organoids for immuno-histochemistry/-fluorescence staining
    1. Collect and centrifuge the organoids as described above (step 3.2.1).
    2. Remove the SN, add 1 mL of 4% paraformaldehyde (PFA) and incubate for 30 min at room temperature (RT) on an orbital shaker (100 rpm).
      CAUTION: PFA is a known human carcinogen that can cause irreversible damage to the cornea. All work must be done in a chemical fume hood. Nitrile gloves and safety glasses must always be worn.
    3. Centrifuge at 200 x g for 5 min and remove the SN. Add 1 mL of PBS, incubate 10 min at RT on an orbital shaker (100 rpm), and centrifuge at 90 x g for 3 min at 4 °C. Repeat the washing step twice. Store in PBS at 4 °C.
    4. For tissue processing and dehydration, remove the SN and add 150 µL of 2% agarose gel (in PBS) to the organoid pellet using a prewarmed widened p200 tip (made by cutting a small piece of the tip). Immediately pipet the entire volume up and eject in the lid of the microcentrifuge tube.
      NOTE: It is important to work swiftly, as the gel containing the organoids will quickly solidify.
    5. Let the gel firmly solidify for 30 min and move the gel disc to a histology cassette. Immerse and store in 50% EtOH, until dehydration in the tissue processor.
    6. For paraffin embedding, place the gel disc (using forceps) in an embedding mold and fill with warm paraffin (60 °C). Place the molds at 4 °C until the paraffin is solid (approximately 45 min). These samples can either be stored at 4 °C or can immediately be subjected to sectioning.
    7. Microtome the paraffin blocks containing organoids at 5 µm thickness and collect the samples on glass slides. Add one drop of deionized water underneath each section to allow proper stretching of the section and place the slides on a flat heating plate at 37 °C overnight. Store the slides with sections at 4 °C or directly continue with immunohistochemical or immunofluorescence staining.

Wyniki

After isolation and dissociation of the AL, the obtained single cells are seeded in ECM and grown in PitOM (Figure 1, Table 1). Figure 3A displays the cell culture and density at seeding (Day 0). Some small debris may be present (Figure 3A, white arrowheads), but will disappear at passaging. Fourteen days after seeding, the AL-derived organoids are fully developed (Figure 3A). The organ...

Dyskusje

The AL-derived organoids, as described here, represent a powerful research model to study pituitary stem cells in vitro. At present, this organoid approach is the only available tool to reliably and robustly grow and expand primary pituitary stem cells. A pituitary organoid model derived from embryonic stem cells (ESC) or induced pluripotent stem cells (iPSC) has been reported previously, which closely recapitulates pituitary embryonic organogenesis23; however, although highly useful to s...

Ujawnienia

The authors declare no competing financial interests.

Podziękowania

This work was supported by grants from the KU Leuven Research Fund and the Fund for Scientific Research (FWO) - Flanders. E.L. (11A3320N), and C.N. (1S14218N) are supported by a Ph.D. Fellowship from the FWO/FWO-SB.

Materiały

NameCompanyCatalog NumberComments
2-MercaptoethanolSigma-AldrichM6250
48-well plates, TC treated, individually wrappedCostar734-1607
A83-01Sigma-AldrichSML0788
Advanced DMEMGibco12491023
Albumin Bovine (cell culture grade)Serva47330
B-27 Supplement (50X), minus vitamin AGibco12587010
Base mouldsVWR720-1918
Buffer RLTQiagen79216
Cassettes, Q Path MicrotwinVWR720-2191
Cell strainer, 40 µm mesh, disposableFalcon352340
Cholera Toxin from Vibrio choleraeSigma-AldrichC8052
Deoxyribonuclease I from bovine pancreasSigma-AldrichD5025
D-glucoseMerck108342
Dimethylsulfoxide (DMSO)Sigma-AldrichD2650
DMEM, powder, high glucoseGibco52100039
Eppendorf Safe-Lock Tubes, 1.5 mLEppendorf30120086
Epredia SuperFrost Plus Adhesion slidesThermo Fisher ScientificJ1800AMNZ
Epredia HistoStar Embedding Workstation, 220 to 240VacThermo Fisher Scientific12587976
Ethanol Absolute 99.8+%Thermo Fisher Scientific10342652
Fetal bovine serum (FBS)Sigma-AldrichF7524
GlutaMAX SupplementGibco35050061
HEPESSigma-AldrichH4034
HEPES Buffer SolutionGibco15630056
InSolution Y-27632Sigma-Aldrich688001
L-Glutamine (200 mM)Gibco25030081
Matrigel Growth Factor Reduced (GFR) Basement Membrane Matrix, LDEV-FreeCorning15505739
Mr. Frosty Freezing ContainerThermo Fisher Scientific5100-0001
N-2 Supplement (100X)Thermo Fisher Scientific17502048
N-Acetyl-L-cysteineSigma-AldrichA7250
Nunc Biobanking and Cell Culture Cryogenic TubesThermo Fisher Scientific375353
Paraformaldehyde for synthesis (PFA)Merck818715
PBS, pH 7.4Gibco10010023
Penicillin G sodium saltSigma-AldrichP3032
Penicillin-Streptomycin (10,000 U/mL)Gibco15140122
Phenol redMerck107241
Potassium Chloride (KCl)Merck104936
Recombinant Human EGF Protein, CFR&D systems236-EG
Recombinant Human FGF basic/FGF2/bFGF (157 aa) ProteinR&D systems234-FSE
Recombinant Human FGF-10Peprotech100-26
Recombinant Human IGF-1Peprotech100-11
Recombinant Human IL-6Peprotech200-06
Recombinant Human NogginPeprotech120-10C
Recombinant Human R-Spondin-1Peprotech120-38
Recombinant Human/Murine FGF-8bPeprotech100-25
Recombinant Mouse Sonic Hedgehog/Shh (C25II) N-TerminusR&D systems464-SH
RNeasy micro kitQiagen74004
SB202190Sigma-AldrichS7067
SeaKem LE AgaroseLonza50004
Sodium Chloride (NaCl)BDH102415K
Sodium di-Hydrogen Phosphate 1-hydratePanReac-AppliChemA1047
Sodium Hydrogen Carbonate (NaHCO3)Merck106329
Sodium-Pyruvate (C3H3NaO3)Sigma-AldrichP5280
Stericup-GP, 0.22 µmMilliporeSCGPU02RE
Steriflip-GP Sterile Centrifuge Tube Top Filter Unit, 0.22 μmMilliporeSCGP00525
Sterile waterFreseniusB230531
Streptomycin sulfate saltSigma-AldrichS6501
Syringe, with BD Microlance needle with intradermal bevel, 26GBD PlastipakBDAM303176
Thermo Scientific Excelsior ES Tissue ProcessorThermo Scientific12505356
Titriplex IIIMerck108418
TrypL Express Enzyme (1X), phenol redThermo Fisher Scientific12605028
Trypsin inhibitor from Glycine max (soybean)Sigma-AldrichT9003
Trypsin solution 2.5 %Thermo Fisher Scientific15090046

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