Gene-environment Interaction Models to Unmask Susceptibility Mechanisms in Parkinson's Disease

Podsumowanie

Lipoxygenase (LOX) isozymes can generate products that may increase or decrease neuroinflammation and neurodegeneration. A gene-environment interaction study could identify LOX isozyme-specific effects. Using the 1-methyl-4-phenyl-1,2,3,6-tetrahydropyridine (MPTP) model of nigrostriatal damage in two LOX isozyme-deficient transgenic lines allows for comparison of the contribution of LOX isozymes on dopaminergic integrity and inflammation.

Streszczenie

Lipoxygenase (LOX) activity has been implicated in neurodegenerative disorders such as Alzheimer's disease, but its effects in Parkinson's disease (PD) pathogenesis are less understood. Gene-environment interaction models have utility in unmasking the impact of specific cellular pathways in toxicity that may not be observed using a solely genetic or toxicant disease model alone. To evaluate if distinct LOX isozymes selectively contribute to PD-related neurodegeneration, transgenic (i.e. 5-LOX and 12/15-LOX deficient) mice can be challenged with a toxin that mimics cell injury and death in the disorder. Here we describe the use of a neurotoxin, 1-methyl-4-phenyl-1,2,3,6-tetrahydropyridine (MPTP), which produces a nigrostriatal lesion to elucidate the distinct contributions of LOX isozymes to neurodegeneration related to PD. The use of MPTP in mouse, and nonhuman primate, is well-established to recapitulate the nigrostriatal damage in PD. The extent of MPTP-induced lesioning is measured by HPLC analysis of dopamine and its metabolites and semi-quantitative Western blot analysis of striatum for tyrosine hydroxylase (TH), the rate-limiting enzyme for the synthesis of dopamine. To assess inflammatory markers, which may demonstrate LOX isozyme-selective sensitivity, glial fibrillary acidic protein (GFAP) and Iba-1 immunohistochemistry are performed on brain sections containing substantia nigra, and GFAP Western blot analysis is performed on striatal homogenates. This experimental approach can provide novel insights into gene-environment interactions underlying nigrostriatal degeneration and PD.

Wprowadzenie

Use of gene-environment interaction models provides an approach to mimic risk factors that likely influence idiopathic Parkinson’s disease (PD) and affords an opportunity to discern mechanistic insights that are unlikely to be elucidated by use of a genetic or toxicant system alone^1,2. Here we illustrate this point and describe application of the 1-methyl-4-phenyl-1,2,3,6-tetrahydropyridine (MPTP) mouse model of nigrostriatal degeneration³ to better understand the selectivity of lipoxygenase (LOX) isozyme activity on neuroinflammation and toxicity⁴. While a role for LOX isozymes has been widely evaluated in peripheral disorders^5,6 as well as CNS disease including stroke⁷ and Alzheimer’s disease^8,9, the role of the family of isozymes in nigrostriatal function and degeneration related to PD is not well understood and warrants study. The MPTP neurotoxin demonstrates preferential degeneration of the nigrostriatal pathway and recapitulates the striatal dopamine depletion and nigral dopaminergic cell loss that underlie motoric impairments in PD patients¹⁰. While this model does not reproduce the full cadre of nonmotor and motor PD behaviors and frank α-synuclein-positive Lewy body pathology, it has been useful to elucidate novel mechanistic targets that contribute to nigrostriatal damage and for early-stage translational testing as it is the best characterized noninvasive model available to reliably produce nigral cell death accompanied by striatal dopamine loss^11-15. Wide use of the MPTP mouse, with paradigms ranging from acute, subacute to chronic^16-18, has allowed for standardization of dosing to result in mild to severe nigrostriatal damage^19,20 with activation of different mechanisms of toxicity depending on the treatment regimen^18,21,22. Consequently, this permits a ‘window of lesioning’ to be targeted that may result in enhanced or reduced nigrostriatal injury depending on the therapeutic agent or transgenic model utilized^23-25.

Also essential for translational and discovery biology studies are the techniques used to assess damage and the evidence such methods provide. For the MPTP mouse model, established metrics to evaluate lesioning are measurement of markers of striatal dopaminergic tone, including dopamine and its metabolites by HPLC, and Western blot analysis of tyrosine hydroxylase (TH), the rate-limiting enzyme in dopamine synthesis, and indicators of degenerative events such as glial activation using Western blot analysis and immunohistochemistry⁴. Although these are classical neurochemical, biochemical, and histological procedures, the techniques provide critical and reproducible readouts on the extent of damage within the nigrostriatal dopaminergic pathway, indicate mechanisms of toxicity, and have proven to be valuable tools in understanding degenerative events in PD.

Protokół

Note: All animal procedures and animal care methods should be approved by the institution’s Institutional Animal Care and Usage Committee (IACUC). Study described here was performed in accordance to the guidelines established by SRI International’s IACUC.

1. Acquisition and maintenance of LOX-deficient mice

1. Purchase 5-LOX-deficient or 12/15-LOX-deficient mice and respective strain and sex-matched controls at age 7-8 weeks and allow several days for acclimation to facility after arrival.
2. Maintain mice in group housing on a 12-h light-dark cycle and give food and drinking water ad libitum.

2. MPTP precautions, storage, preparation, decontamination and disposal

Note: MPTP intoxication from intravenous exposure in humans has been shown to cause parkinsonism¹⁰; MPTP is highly lipophilic and can readily cross the blood-brain barrier²⁶. Precautionary measures should be taken to ensure safe handling, detoxification and disposal. Its metabolism involves multiple steps including conversion to 1-methyl-4-phenyl-2,3-dihydropyridinium by the enzyme monoamine oxidase B (MAO-B)²⁷. MAO-B inhibitors may be utilized in case of accidental human intoxication.

1. Ensure that personnel have appropriate safety and handling training before utilizing MPTP as dictated by the institution’s Health and Safety Committee. Each institution may establish and implement its own standard operating procedures for use of MPTP, based on recommendations comprehensively outlined in the literature^17,22.
2. Prior to preparation, don appropriate personal protective equipment (PPE) including the following: disposable lab coat or full body suit, double nitrile gloves, surgical mask, hair cover, safety goggles, and disposable shoe covers. Proper PPE should be worn during preparation of MPTP, the injection paradigm and 72 h post-injection when handling animals and/or bedding.
3. Perform calculations prior to preparation. Institutional guidelines for dosing volumes should be followed; delivery of 100-150 µl is typically used for 25-30 g mice.
   1. To prepare a 3 mg/ml MPTP solution in saline, apply a correction factor (1.211 MPTP-HCl: 1.0 MPTP free base); the concentration of MPTP-HCl in saline vehicle is 3.633 mg/ml.
   2. Prepare all equipment, supplies and reagents needed for MPTP preparation and potential spill decontamination prior to handling the neurotoxin.
4. Remove MPTP-HCl source vial from proper storage location.
   Note: MPTP should be maintained at RT in a closed vial within a secondary container, and stored within a locked cabinet, labeled “MPTP.”
   1. Cover area surrounding scales with pads or paper towels dampened with 10% bleach solution to reduce the risk from spilled powder. Keep tissues and 10% bleach solution nearby as a precaution.
   2. Using an analytical balance located in a fume hood, weigh 50 mg of MPTP-HCl into glass vial with secondary containment containing 10% bleach-soaked tissue. Label the glass vial “MPTP” with concentration and date.
   3. Close source vial and wipe the outside with 10% bleach.
5. Slowly add 13.763-ml sterile saline to vial and close completely for mixing. (Solution is 3.633mg/ml MPTP-HCl.)
   1. In the hood, carefully sterilize MPTP solution by filtration using a 0.22 µm filter into labeled injection vial within a secondary container with 10% bleach-soaked tissue. Clean any spill with bleach-soaked tissue.
   2. Carefully dispose of sharps and vial in appropriately labeled biohazard container. Maintain MPTP solution in vial in the secondary container with bleach-soaked tissue for transport to animal procedure room.
      Note: do not autoclave MPTP solution for sterilization as its vaporization is an inhalation hazard.
6. Return MPTP source vial to its secondary container and place in storage location. Decontaminate spatula, analytical scale and hood surface for 10 min using 10% bleach.

3. MPTP administration

1. Prepare disposable cages with standard microisolator perforated lids containing polyester filtered liners marked “MPTP” (minus wire food grill), disposable cage liners, pre-wet food pellets and hydrogel as water source. Weigh all animals and record volume of 3 mg/ml MPTP in saline required for 15 mg/kg injection.
   Note: MPTP metabolites are detectable in excreta for 3 days following injection^28,29; however, mice excrete MPTP n-oxide, a non-toxic derivative that does not cross membranes because of its hydrophilicity³⁰.
   1. Wearing all PPE listed above and holding mice over a disposable absorption pad, inject saline vehicle or MPTP solution for 15 mg/kg dose into the intraperitoneal cavity (i.p.), daily for 4 days with a disposable 26-gauge tuberculin syringe.
   2. Do not recap syringe after use; dispose into a dedicated and labeled MPTP biohazardous sharps container. Maintain 10% bleach and tissues nearby to clean any accidental drips.
2. Place animals injected with MPTP in disposable cages, up to 5 mice per cage, and house on open racks. Do not use ventilated racks.
   1. Place MPTP use placards on rack containing mice and housing room door until 72 h after last injection.
      Note: ensure temperature of housing room is between 22.2 - 24.4^oC, as mice experience transient hypothermia up to 12h following MPTP intoxication.³¹
   2. Decontaminate work surface with bleach after each use (see step 2.8), dispose of leftover MPTP solution by addition of a volume equivalent of 10% bleach, and discard contents as biohazardous liquid waste.
   3. Discard all used PPE in dedicated disposal bin. If needed, spray with 10% bleach before disposal.
3. Check animals regularly and refresh food and water source daily during injection paradigm and 72 h after the last injection. Note: although no contamination is anticipated in the area immediately surrounding the outside of the cage, this region is treated with the bleach solution as a precaution (as described in Step 2.8).Care should be taken when handling all mice and equipment during this period.
   1. Three days after the last injection, dispose of all cages and liners in appropriately labeled biohazard bag. Resume use of regular PPE and normal housing for animals; remove door and shelf placards.

4. Tissue harvesting

1. Euthanize animals by cervical dislocation 7 days following the last MPTP injection. Immediately dissect brain on ice using pre-chilled brain mold with 1-mm slots in the coronal plane.
2. Dissect the striatum from a forebrain slice 2-mm thick at the level of the anterior commissure.
   1. Remove surrounding cortical and subcortical regions using a scalpel. Snap-freeze striatal tissue from each hemisphere in a separate 1.5-ml microcentrifuge tube for neurochemical or biochemical analysis.
3. Block midbrain/hindbrain in the coronal plane at the level of anterior hypothalamus and immersion-fix tissue in 4% formaldehyde aqueous solution.

5. Tissue processing

1. Process for biochemistry
   1. Homogenize striatal tissue from one hemisphere using an ultrasonic cell disruptor in 200-µL Tris-EDTA lysis buffer (25mM Tris base, 1mM EDTA, 1:100 protease and phosphatase inhibitor cocktails) for 10 pulses at 10-12 Hz and centrifuged for 10 min at 4^oC at 1000xg.
   2. Carefully aspirate the supernatant, and reconstitute the pellet in 150-µl lysis buffer. Fractions are used for biochemical analysis by SDS-PAGE and Western blotting.
      Note: use protease and phosphatase inhibitor-containing buffer within 1 h of preparation due to instability in aqueous solutions.
2. Process for neurochemistry
   1. Utilize striatum dissected from other hemisphere from each sample stored at -80°C for HPLC. Thaw striatal tissues in microfuge tubes on ice, add 500-μl 0.3N perchloric acid (PCA) and homogenize using sonicator.
      Note: To make 100 ml of 0.3N PCA, measure 90-ml ddH₂O, add to a 100-ml graduated cylinder, add 2.58 ml of 70% PCA, and bring to 100-ml mark. This sample buffer can be stored at 4°C for up to one month.
   2. Sonicate striatal tissue in 500-µl ice-cold 0.3N PCA, for 10 pulses at 10-12 Hz and place on ice. To ensure homogeneity, sonicate samples a second time for 10 sec, then centrifuge for 12 min at 4^oC at 16,100xg.
   3. Immediately decant supernatant to 1.5-ml microcentrifuge tubes and store at -80°C. Air-dry the pellet fraction in hood.
   4. Maintain the supernatant at -80°C until use for measurement of dopamine and its metabolites, 3,4-dihydroxyphenylacetic acid (DOPAC) and homovanillic acid (HVA) by HPLC with electrochemical detection.
   5. Once dry, reconstitute the pellet fraction in 0.5N NaOH (500 µL), and briefly sonicate. Store reconstituted pellet fraction at 4°C until use for determination of total protein using the Lowry method.
3. Process for immunohistochemistry
   1. Immersion-fix mid- and hind-brain blocks overnight in 4% formaldehyde aqueous solution and cryoprotect in graded sucrose solutions (10% in phosphate-buffered saline (0.01 M PBS; 0.138 M NaCl, 0.0027 M KCl, and ddH₂O, pH 7.4) for 24 h, then 30% in PBS until until the tissue sinks) at 4°C. Briefly blot cryoprotected blocks to remove excess sucrose solution, freeze on dry ice and store at -80°C until use.
   2. Microtome sectioning of brain blocks containing mid- and hind-brain in a cryostat.
      1. Remove tissues from -80°C, equilibrate at -16°C for 1 h in cryostat, and mount in tissue embedding media.
      2. Collect coronal sections at 40-µm thickness into cryoprotectant solution (0.01M PBS with 30% sucrose, 30% ethylene glycol, pH 7.4) at -16°C. Collect tissue serially into 6 1.5-ml microcentrifuge tubes at 240-um intervals and store at -20°C.

6. Immunoblotting

1. Determine protein concentration in striatal supernatant fraction (prepared as described in Section 5.1) by BCA assay.
2. Calculate dilution required for each sample to yield 10 µg per well delivered in 20 µl of volume.
3. Dilute supernatant protein with 4X Laemmli buffer and homogenization buffer to yield 10 µg protein in 1X Laemmli buffer solution. Example calculation:
   1. Determine final concentration of protein and volume required. In this case, 10 µg in 20 µl (0.5 mg/ml) is required.
   2. Determine the final volume of the protein solution needed. Although 20 µl is required for loading, extra volume should be prepared (30 µl).
   3. Since the final volume and concentration are known, and the concentration of the protein supernatant fraction is known (determined by the BCA assay), calculate the volume of the protein supernatant required using the equation:
      V_supernatant = (V_final x C_final)/C _supernatant
      Thus, for a supernatant protein concentration of 1.5 mg/ml,
      V_supernatant = (30 µl x 0.5 mg/ml)/1.5 mg/ml
      V_supernatant = 10 µl
   4. Calculate amount of 4X Laemmli buffer required to yield a 1x concentration in 30 µl of volume (30 µl / 4 = 7.5 µl). Note: 4X Laemmli buffer must be diluted to 1X strength in the sample preparation.
   5. Calculate amount of homogenization buffer required to bring volume to 30 µl (and obtain desired final protein concentration of 0.5 mg/ml):
   6. Prepare sample by vortexing then pipetting 10 µl of protein supernatant into 12.5 µl of homogenization buffer. Add 7.5 µl of 4X Laemmli buffer for a 30-µl sample working solution and 0.5 mg/ml concentration.
4. Prepare all samples using procedure described, vortex and boil for 5 min.
   Note: Use screw-top microcentrifuge tubes to prevent leakage and opening due to pressure during boiling.
5. After 5 min, immediately place on ice. Load 20 µl of sample working solution per gel well (10 µg of protein). Separate protein samples by SDS-PAGE on a 12% Tris-glycine gel.
   1. Use a pre-stained protein ladder for confirmation of molecular weights. Running buffer is 25 mM Tris-base, 192 mM glycine, 0.1% SDS, and ddH₂O, pH 8.3.
   2. Separate proteins by electrophoresis: run at 80 V to clear the wells (10 min) and 125 V (approximately 1 h; until protein ladder has fully separated) to resolve the proteins.
6. Perform protein-to-nitrocellulose transfer using 0.2 µm nitrocellulose membrane in Tris-glycine transfer buffer (25 mM Tris, 192 mM glycine, 0.04% SDS, 20% methanol and ddH₂O, pH 8.3) overnight for 40 V at 4°C.
7. Wash nitrocellulose blots in 1x Tris saline (TS; 25mM Tris, 0.9% NaCl in ddH₂O, pH 7.4) for 10 min at RT. lncubate in Ponceau S for 5 min then rinse in ddH₂O to provide a rough verification of equivalent protein loading. Scan image to retain record for notebook and destain using PBS.
   Note: Alternatively, wash blot in Milli-Q or ddH2O containing HCl (0.2%) for approximately 5 min. Scan for record. Remove Ponceau S stain from membrane by subsequent incubation step (i.e. place in the blocking buffer).
8. Block blots in 5% non-fat milk powder in TS for 1 h at RT and incubate 24h at 4ºC with rabbit anti-tyrosine hydroxylase (1:1000), anti-β-actin (1:200); anti-GFAP (1:1000) in 5% milk-TS.
9. Wash blots 3 x 5 min in TS with 0.05% Tween-20 and 1 x 5 min in TS, then incubate in HRP-conjugated secondary antibody (1:5000 in TS containing 5% milk), matched to the species of the primary, for 2 h at RT.
10. Prepare chemiluminescent substrate using equal volumes of luminol and peroxide solutions and apply for 1-3 min. In a darkroom, place blot in a plastic sleeve for film exposure and expose to film; film is then developed using an automatic processor.
11. Strip blots with commercially available stripping buffer at 37°C for 30 min, wash 3x 10 min in TS with 0.05% Tween-20, and 1x 10 min in TS and then reprobe for loading control or other protein of interest.
12. Quantify the signals by Image J software for optical density measurements and normalize to the internal loading control β–actin.

7. Neurochemistry

1. Tissue for analysis is prepared as described above in Section 5.2. Please refer to Table 1 for mobile phase recipe.
   Note: All reagents must be ≥99.0% pure and of HPLC grade. Ensure buffer integrity with clean, dedicated glassware and stir bars. Mobile phase buffer should be utilized within seven days of preparation.
   1. Weigh the dihydrogen phosphate and citric acid, add 1 L of ddH₂O and mix in a 2-L graduated cylinder. Filter the solution through a 0.22-µm GSTF membrane.
      Note: This maximizes the extraction of contaminants in the phosphate and citric acid, which helps to minimize background currents.
   2. Add the OSA followed by the acetonitrile and EDTA solution. Add HPLC grade ddH₂O to approximately 1900 ml prior to adjusting the pH to 3.0 with phosphoric acid.
   3. Add HPLC grade ddH₂O to the 2-L mark, and then pour into a 2-L flask. Add a dedicated stir bar, and degas the mobile phase by stirring it under vacuum for > 10 min.
2. Prepare the standards for dopamine, and DOPAC and HVA for standard curves. Stock solutions of standards are prepared at 1 mg/ml in 0.3 N PCA.
   1. Weigh 12.4 mg of dopamine-HCl, and add 10.0 ml of 0.3 N PCA to make 1 mg/ml dopamine.
   2. Weigh 10.0 mg of DOPAC, and add 10.0 ml of 0.3 N PCA to make 1 mg/ml DOPAC.
   3. Weigh 10.0 mg HVA, and add 10.0 ml of 0.3 N PCA to make 1 mg/ml HVA.
3. Prepare working standard solutions from the stock solutions. Five-point standards are used to generate a concentration curve.
   1. For measurement of striatal dopamine, prepare standard concentrations of 12.5 ng/ml, 25 ng/ml, 50 ng/ml, 100 ng/ml, and 200 ng/ml.
   2. For striatal DOPAC, prepare standard concentrations of 2.5 ng/ml, 5 ng/ml, 10 ng/ml, 20 ng/ml, and 40 ng/ml.
   3. For striatal HVA, prepare standard concentrations of 5 ng/ml, 10 ng/ml, 20 ng/ml, 40 ng/ml, and 80 ng/ml.
   4. Generate five-point standards: dilute 1 mg/ml dopamine stock solution to 5 µg/ml using 0.3N PCA. Dilute 1 mg/ml DOPAC stock solution to 1 µg/ml using 0.3N PCA, and dilute 1 mg/ml HVA stock solution to 2 µg/ml using 0.3N PCA.
   5. Transfer 1 ml of 5 µg/ml dopamine, 1 ml of 1 µg/ml DOPAC, and 1 ml of 2 µg/ml HVA into a 25-ml volumetric flask and bring volume to 25 ml mark with 0.3 N PCA.
      Note: The mixed standards in the volumetric flask contain the highest concentration of the five-point standards: 200 ng/ml of dopamine, 40 ng/ml of DOPAC, and 80 ng/ml of HVA.
   6. Transfer 1 ml of the mixed standards into clean 1.5-ml microcentrifuge tubes. Perform 1:1 serial dilution four times to generate the subsequent four-point standards.
      1. For example, to 250 μl of the mixed standards, add 250 μl of sample buffer and vortex thoroughly to produce mixed standards at 50% of original concentrations; repeat process until desired dilutions are achieved.
4. Prepare the HPLC system (pump, autosampler, reverse-phase column (C18, 150×3.2 mm, 3 µm)). Purge the pump with fresh mobile phase to replace all previous solution in the HPLC system and trapped air bubbles with fresh mobile phase. Chill the autosampler to 4°C. Warm the column to 35°C, which reduces the total pressure.
   1. Set the voltage at -150 mV and 220 mV for the first and second electrodes of the electrochemical detector, respectively. Equilibrate the system for at least 2 h, and ideally overnight, with the mobile phase at a flow rate of 0.2 ml/min.
      Note: During equilibration the cells should be on, and the baseline reading monitored. Stable reading indicates that the system is ready to use. For the two hours of the equilibration phase, allow the mobile phase to go into a waste container instead of recirculating it. After this period, the mobile phase can be recycled overnight for equilibration.
   2. Once equilibration is complete, adjust the mobile phase flow rate to 0.6 ml/min. Inject 20 µl of each of the five-point standards.
5. Thaw striatal samples on ice, and inject 2 x 20 µl of each sample into the HPLC system. Utilize standards at the beginning and randomly throughout each set of striatal samples.
6. Use the software to analyze the area under dopamine, DOPAC, and HVA peaks produced by the standards and samples. Identify analytes by retention time and measure by comparing the area under peak to that of 5-point curve for its corresponding standard.
7. Prepare pellet fraction as described in Section 5.2.3. Perform a Lowry protein assay on the striatal pellet. Note: This assay will measure the amount of protein present in the striatal samples in mg/ml; this information is used to determine the ng/mg concentration of analyte.

8. Immunohistochemistry

1. GFAP/TH dual immunofluorescence
   1. Remove tubes containing sectioned midbrain from -20°C freezer and bring to RT. Remove tissue sections containing substantia nigra from cryopreservative solution in a tray containing PBS.
   2. Place tissue sections in polystyrene inserts with polyester mesh bottoms for free-floating immunochemistry. Wash 3 x 5 min in PBS.
   3. Transfer sections to 96-well plate with 180-µl block solution (5% normal donkey serum, 1% PVP, 1% BSA and 0.3% Triton X-100 in PBS) in each well. Incubate 40 min at RT.
      Note: All wash and incubation steps are performed with light agitation on shaker.
   4. Transfer sections to wells containing the primary antibody solution (180 µl per well). Incubate in primary antibody cocktail, rabbit anti-GFAP (1:1000) and sheep anti-TH (1:400) diluted in PBS with 1% BSA and 0.3% TX-100, for 24 h at 4°C. IgG from the primary species serves as the negative immunostaining control.
   5. Incubate in secondary antibody cocktail (1:200 donkey anti-rabbit 568 and 1:200 FITC donkey anti-sheep in PBS with 0.1% TX-100). Use foil to protect solution from light during preparation and incubation; incubate at RT for 2 h.
      1. For a negative control, incubate sections in IgG from the primary species diluted to the same concentration as used for the primary antibodies.
      2. Wash 2 x PBS and 1 x TS for 5 min each at RT. Mount tissue sections on plus slides in mounting medium with Hoechst stain and coverslip.
   6. Incubate in secondary antibody cocktail (1:200 donkey anti-rabbit 568 and 1:200 FITC donkey anti-sheep in PBS with 0.1% TX-100). Use foil to protect solution from light during preparation and incubation; incubate at RT for 2 h.
   7. Wash 2 x PBS and 1 x TS for 5 min each at RT. Mount tissue sections on plus slides in mounting medium with Hoechst stain and coverslip.
   8. Protect slides from light and oxidation until imaging by storing in a slide box at 4°C.
   9. Analyze the negative control first to determine the background level of fluorescence, then evaluate for positive immunoreactivity using fluorescent microscopy.
2. Iba1 immunohistochemistry with chromagen precipitation
   1. Remove tubes containing sectioned midbrain from -20°C freezer and bring to RT. Remove tissue sections containing substantia nigra from cryopreservative solution in a tray containing PBS.
   2. Place tissue sections in polystyrene inserts for free-floating immunochemistry. Wash sections 3 x 5 min in PBS, and place sections directly into 12-well plate containing pre-heated 10 mM citric acid monohydrate, pH 9.0, 80°C for 30 min, for epitope retrieval.
   3. Cool plate 20 min at RT. Return sections to inserts and wash 3 x 5 min in PBS.
   4. Transfer sections to 96-well plate containing 180-µl blocking solution (10% normal goat serum, 1% BSA in PBS) per well, and incubate 40 min at RT.
   5. Transfer sections to wells containing 180-µl diluted primary antibody (1:1000 in 1% BSA-PBS). Incubate overnight at 4°C.
   6. Transfer sections to inserts. Wash 3 x 5 min PBS and apply biotinylated secondary antibody (1:200 in 1.5% normal serum-PBS) for 1 h at RT.
   7. Prepare ABC solution 30 min before use. Wash 3 x 5 min PBS and transfer to ABC solution for 1 h at RT.
   8. Prepare DAB solution in hood. Wash 2x 5 min in PBS and 1x 5 min in TS, and incubate sections in DAB.
      1. Develop for 3-4 min. Negative control should remain light in color.
         Note: perform this step in fume hood as DAB is a known carcinogen. A solution of 0.2M potassium permanganate in ddH₂O for decontamination should be maintained in proximity in case of accidental drips.
   9. Rinse sections briefly in ddH₂O, then in TS 3 x 5 min. Mount sections on plus slides and air-dry overnight in fume hood.
   10. Decontaminate DAB waste with an equal volume of 0.2M potassium permanganate in ddH₂O, vortex, and incubate in a fume hood overnight before storing in appropriately labeled DAB waste bin in fume hood.
       Note: Bleach solution does not eliminate the mutagenic properties of DAB.
       1. Decontaminate items to be reused (i.e. polystyrene inserts) and wash with detergent.
   11. Dehydrate/counterstain lightly with Cresyl violet (CV). All dehydration/wash steps are 3 min: ethanol 70%, 95%, 100%, 95%, ddH₂O, CV (30 seconds), ddH₂0 x 2, 95% ethanol + glacial acetic acid (0.1%) x 2, 100% ethanol, and xylene.
   12. Coverslip in distyrene-toluene-xylene mounting medium and dry in fume hood.
   13. Observe positive immunoreactivity by a light microscope. IgG from the primary species serves as the negative immunostaining control.

9. Statistics

1. Assess differences among means by one-way analysis of variance (ANOVA) to compare differences between genotype and by two-way ANOVA to compare differences between genotype and toxicant treatment. Utilize Tukey’s HSD post hoc analysis when differences are observed by ANOVA testing (p≤0.05).
   Note: experiments (with n = 6-9 mice/group) are performed a minimum of two times to ensure reproducibility.

Wyniki

This toxin exposure paradigm can produce a significant and detectable 20% striatal dopamine depletion in MPTP- vs. saline-injected animals. It is important to note that different lots of MPTP may yield slightly more or less lesioning; thus, for better precision, a preliminary experiment in wildtype mice is recommended prior to use in transgenics when a new lot of neurotoxin is utilized. The use of mild-to-moderate lesioning allows for impact of the transgene to be observed; a severe lesion may produce a 'floor e...

Dyskusje

The design of this gene-environment interaction study allowed us to gain new information regarding the dual nature of the 5-LOX isozyme in the nigrostriatal pathway. By performing HPLC to measure striatal monoamines after saline or MPTP treatment in transgenics lacking the 5-LOX isozyme and their wildtype littermates, we were able to note that its deficiency appears to be protective under toxic conditions (Figure 1), but under normal conditions, lack of the enzyme reduces striatal dopamine levels an...

Materiały

Name	Company	Catalog Number	Comments
1-Methyl-4-phenyl-1,2,3,6-tetra-hydropyridine hydrochloride (MPTP-HCL)	Sigma-Aldrich	M0896	for PD modeling
4% Formaldehyde (paraformaldehyde) solution, phosphate-buffered (PFA)	American MasterTech Scientific	BUP0157	for immersion fixation
Perchloric acid ACS reagent, 70% (PCA)	Sigma-Aldrich	244252	for HPLC acid extraction
Tris Base	Sigma-Aldrich	T1503	for tissue homogenization
Ethylenediaminotetraacetic acid disodium salt dihydrate (EDTA)	Sigma-Aldrich	E1644	for tissue homogenization
Protease inhibitor cocktail	Sigma-Aldrich	P8340	for tissue homogenization
Phosphatase inhibitor cocktail	Sigma-Aldrich	P5726	for tissue homogenization
Sodium Hydroxide (NaOH)	Sigma-Aldrich	S5881	for Lowry protein assay
Sucrose, molecular biology, ≥99.5% (GC)	Sigma-Aldrich	S0389	for cryoprotection
Phosphate buffered saline, powder, pH 7.4 (for 0.01 M PBS)	Sigma-Aldrich	P3813	for IHC
BCA Protein Assay Kit	Pierce/Thermo	23225	for protein determination
Novex 12% Tris-Glycine Mini Gels 1.0 mm, 12-well	Invitrogen/Life Technologies	EC60052BOX	for SDS-PAGE
NuPAGE LDS Sample Buffer (4x)	Invitrogen/Life Technologies	NP0007	for SDS-PAGE
Novex Sharp Prestained Protein Standard	Invitrogen/Life Technologies	LC5800	protein ladder
Glycine	Sigma-Aldrich	G7126	for SDS-PAGE
Sodium dodecyl sulfate, electrophoresis, 98.5% (SDS)	Sigma-Aldrich	L3771	for SDS-PAGE
Methyl Alcohol, Anhydrous, Reagent	American MasterTech Scientific	SPM1057C	methanol for transfer
Sodium chloride (NaCl), ACS reagent	Sigma-Aldrich	S9888	saline and buffers
Nonfat dry milk powder	Carnation	n/a	for immunoblotting
Ponceau S solution in 5% acetic acid	Sigma-Aldrich	P7170	for immunoblotting
Anti-Tyrosine Hydroxylase (TH), sheep polyclonal	Chemicon/Millipore	AB1542	for immunofluorescence
Anti-Tyrosine Hydroxylase (TH), rabbit polyclonal	Pel-Freez Biologicals	P40101-0	for immunoblotting
Anti-β Actin, rabbit	Sigma-Aldrich	A2066	for immunoblotting
Anti-Glial Fibrillary Acidic Protein (GFAP), rabbit polyclonal	Chemicon/Millipore	AB5804	for immunofluorescence
Anti-Glial Fibrillary Acidic Protein (GFAP), mouse monoclonal	Covance Inc.	SMI-22R	for immunoblotting
Tween-20	Sigma-Aldrich	P1379	for immunoblotting
Goat Anti-Rabbit IgG (H+L), Peroxidase Conjugated	Fisher Scientific	31462	for immunofluorescence
goat anti-sheep, peroxidase conjugated	Pierce/Thermo	31480	for immunofluorescence
goat anti-mouse, peroxidase conjugated	Pierce/Thermo	31430	for immunofluorescence
SuperSignal West Pico Chemiluminescent Substrate	Pierce/Thermo	34078	for immunoblotting
CL-XPosure Film 7 in x 9.5 in	Pierce/Thermo	34089	for immunoblotting
Restore Western Blot Stripping Buffer	Pierce/Thermo	21059	for immunoblotting
Citric acid monohydrate, ACS reagent, ≥99.0%	Sigma-Aldrich	C1909	for IHC
Normal Donkey Serum	Millipore	S30-100ML	for IHC
Polyvinylpyrrolidone (PVP)	Sigma-Aldrich	P5288	for IHC
Bovine Serum Albumin (BSA), lyophilized	Sigma-Aldrich	A3294	for IHC
Triton X-100	Fisher Scientific	BP151-01	for IHC
Donkey anti-Rabbit IgG, Alexa Fluor 568-labeled	Invitrogen/Life Technologies	A10042	for IHC
Donkey Anti-Sheep IgG (H+L), FITC	Jackson ImmunoResearch	713-095-147	for IHC
VECTASHIELD Hard-Set Mounting Medium with DAPI	Vector Laboratories	H-1500	for IHC
Normal Goat Serum	Millipore	S26-100ML	for IHC
VECTASTAIN ABC Kit (Rabbit IgG )	Vector Laboratories	PK-4001	for IHC; 10 µl each of solutions A and B per 1 ml PBS (per instructions )
DAB Peroxidase Substrate Kit, 3,3’-diaminobenzidine	Vector Laboratories	SK-4100	for IHC; per 5 ml cold ddH2O, add 2 drops buffer stock solution, 2 drops DAB, and 1 drop H2O2 (H2O2 is added immediately before use)
Hydrogen peroxide, 30%	Sigma-Aldrich	216763	for quench step in IHC
Rabbit anti-Iba1	Biocare Medicals	CP290A	for IHC
Cresyl Violet Solution, Regular Strength	FD Neurotechnologies	PS102-01	counterstain for Iba1 IHC
95% Ethanol, reagent alcohol	Sigma-Aldrich	R8382	dehydration for IHC
100% Absolute ethanol	Mallinckrodt	7019-10	dehydration for IHC
Acetic acid	Sigma-Aldrich	A6283	destaining for IHC
Xylene	Sigma-Aldrich	534056	clearing agent for IHC
DPX Mountant	Sigma-Aldrich	06522	mounting medium for DAB IHC
O.C.T. Compound - Frozen Section Embedding Medium	American MasterTech Scientific	EMOCTCS	embeddium medium for cryostat cutting
Potassium permanganate	Sigma-Aldrich	223468	to decontaminate DAB solution
Dopamine hydrochloride	Sigma-Aldrich	H8502	for HPLC
3,4-Dihydroxyphenylacetic acid (DOPAC)	Sigma-Aldrich	850217	for HPLC
Homovanillic acid (HVA)	Sigma-Aldrich	H1252	for HPLC
Perchloric acid (PCA) - 70%	Sigma-Aldrich	244252	for HPLC
Sodium dihydrogen phosphate monohydrate	Sigma-Aldrich	71504	for HPLC
Citric acid monohydrate	Sigma-Aldrich	C1909	for HPLC
1-Octanesulfonic acid sodium salt (OSA)	Sigma-Aldrich	O8380	for HPLC
EDTA	Sigma-Aldrich	E1644	for HPLC
Acetonitrile	EMD	AX0145-1	for HPLC
HPLC-grade distilled deionized water (ddH2O)	Millipore		for HPLC
0.22 µm GSTF membrane	Millipore		for filtration
Corning Netwells	Sigma-Aldrich	CLS3477	polystyrene insert with polyester mesh bottom, for IHC
Ultrasonic cell disrupter (Soniprep 150)	MSE	MSE.41371.274
Microcentrifuge	Eppendorf	5414R
ESA MD-150 reverse-phase column	ESA
HPLC Pump (Ultimate 3000)	Dionex	ISO-3100BM
HPLC Autosampler (Ultimate 3000)	Dionex	WPS-3000TSL
Electrochemical detector	ESA	Coulochem III
Guard Cell	ESA	5020
Analytical Cell	ESA	5011A
Chromeleon software	Dionex
Eclipse E400	Nikon	E400	light/fluorescent microscope
Disposable mouse cage	Ancare	N10HT
Microfilter top	Ancare	N10MBT
5-LOX- deficient mice	The Jackson Laboratory	004155
12/15-LOX-deficient mice	The Jackson Laboratory	002778