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An In Vivo Immunofluorescence Localization Method to Study Antibody Biodistribution

Published: January 31, 2024

Abstract

Source: Wischhusen, J. C., et al. In Vivo Immunofluorescence Localization for Assessment of Therapeutic and Diagnostic Antibody Biodistribution in Cancer Research. J. Vis. Exp. (2019).

This video demonstrates an in vivo immunofluorescence localization (IVIL) technique to study the biodistribution of tumor-targeting antibodies in a murine model of breast cancer. Upon the intravenous injection of a tumor-specific antibody in the mouse, the tumor is surgically isolated, and the localization of the antibody within the tumor tissue is confirmed via ex vivo immunostaining.

Protocol

All procedures involving animal models have been reviewed by the local institutional animal care committee and the JoVE veterinary review board.

1. Transgenic mouse model of breast cancer development

  1. Observe mice from the desired cancer model for the appropriate tumor growth via palpation or caliper measurement before proceeding.
    NOTE: Here, the transgenic murine model of breast cancer development (FVB/N-Tg(MMTV-PyMT)634Mul/J) (MMTV-PyMT) was used. These animals spontaneously develop invasive breast carcinomas between 6 and 12 weeks of age in each mammary gland. Normal mammary glands were used as controls from the transgene-negative, age-matched littermates.

2. Intravenous injection of specific and nonspecific antibody agents

  1. Purify rabbit anti-mouse B7-H3 and rabbit immunoglobulin G (IgG) isotype control antibodies on a desalting column (e.g., PD-10) to remove preservatives and storage buffers following manufacturer instructions.
    NOTE: Some antibodies may need further purification with Protein-A agarose beads-based protocol.
  2. Aliquot dosages of 33 µg of each antibody conjugate in individual microcentrifuge tubes.
    NOTE: The dosage of the administered agent may vary depending on the application and matches the dosages at which the antibody conjugate is routinely used. The concentration of the antibody solutions is required if the volume is more than 100 µL for animal safety.
  3. At the desired time point before the tissue collection, here 96 h, anesthetize the tumor-bearing animal with 2% isoflurane flowing in oxygen at 2 L/min, and place on a 37 °C heated stage. Do a toe pinch to make sure the proper level of anesthesia was reached prior to the procedure.
  4. To prepare for the tail vein inoculation of the antibody solutions, disinfect the tail of the animal by wiping it three times with an alcohol wipe. Dilate the tail veins by warming them with a heat pad for approximately 30 seconds. Avoid heating the entire animal. Wipe the tail once more with an alcohol wipe after removing the heat pad.
  5. Using a 27G tail vein catheter, insert the butterfly needle into one of the two lateral tail veins and carefully fix the tail with the inserted needle to the stage with a piece of surgical tape.
    NOTE: Visible blood backflow into the catheter indicates the proper location of the needle within the tail vein.
  6. Flush the catheter with 25 µL of sterile phosphate-buffered saline (PBS), then inject the antibody solution into the catheter using insulin syringes. Flush the catheter once again with 25 µL of sterile PBS.
  7. Remove the needle from the tail and apply pressure to stop any bleeding.
  8. Turn off anesthesia and observe the animal until fully awake for any signs of distress.

3. Collection and preparation of target tumor tissues

  1. At the desired time point, humanely euthanize the animal according to the acceptable institutional procedure, here, by gradual inhalation of 100% CO2 from a compressed gas tank with a chamber displacement flow rate of 10-30% volume/min.
    NOTE: Some applications of the IVIL technique require euthanasia by cardiac perfusion with PBS to remove freely circulating antibodies.
  2. After confirmation of humane euthanasia via cessation of respiratory and cardiac movement, lack of toe pinch response, and greying of mucous membranes, excise tumor tissues using surgical scissors and forceps as follows:
    1. Lay the mouse in the supine position and grasping only the outer layer of skin between the set of mammary glands closest to the tail (5th) with forceps, make a small incision with a pair of surgical scissors.
    2. Introduce the closed scissors into the cut and slowly open the tip to carefully separate the skin from the underlying abdominal wall membrane keeping it intact.
    3. Make a vertical incision up the abdomen, continuing to separate the skin from the inner membrane. Between the 3rd and 4th mammary glands, make a horizontal cut across the abdomen to allow retraction of the skin and visualization of the mammary glands.
      NOTE: Mammary tumors and glands are located superficially under the skin.
    4. Grasping each tumor or normal gland with forceps, carefully trim away the attached skin using surgical scissors.
  3. Place excised tissues into tissue disposable base molds, prelabeled and filled with optimal cutting temperature (OCT) embedding medium, and freeze the molds quickly by placement on dry ice. In order to study off-target delivery, excise other tissues or organs of interest (e.g., the liver or lungs).
    NOTE: To pause the protocol at this point, store frozen tissue blocks at -80 °C until ready to proceed.
  4. Using a cryostat, section frozen tissue blocks at 10 µm thickness and place adjacent sections onto prelabeled adhesion glass slides.
    NOTE: To pause the protocol at this point, store slides at -80 °C until ready to proceed.

4. Ex vivo staining protocol

NOTE: For the quantitative comparison between fluorescence microscopy images, all slides are stained at the same time with the same prepared solutions.

  1. Rinse frozen tissue slides with room temperature PBS for 5 min to remove OCT.
  2. Demarcate tissue sections with a hydrophobic barrier pen to reduce the volume of solutions needed during staining.
    NOTE: Be careful not to allow the pen to run over the tissue samples as it may either remove the tissue from the slide or prevent proper staining on the affected tissue portion. Do not allow the tissue sections to dehydrate at any point.
  3. Fix the tissue sections with 4% paraformaldehyde solution for 5 min.
  4. Rinse slides in PBS for 5 min.
  5. Permeabilize tissue sections with 0.5% Triton-X 100 in PBS for 15 min.
  6. Rinse slides in PBS for 5 min.
  7. Block the tissues with 3% w/v bovine serum albumin (BSA) and 5% v/v goat serum, both in PBS (blocking solution) for 1 h at room temperature.
    NOTE: Match the blocking solution serum to the secondary antibody host animal.
  8. Rinse slides in PBS for 5 min.
  9. Incubate sections with record-keeping primary antibodies as desired, possibly a common nuclear (e.g., DAPI), vascular (e.g., CD31), or cytoplasmic marker (e.g., actin). Here, rat anti-mouse CD31 (vascular marker) at a 1:100 dilution was used according to the manufacturer's instructions in the blocking solution overnight at 4 °C protected from dehydration on a slide tray.
    NOTE: Do not add additional primary antibody or antibody conjugate. The conjugate that was injected and allowed to accumulate in the tissues in vivo acts as the primary antibody.
  10. Rinse slides in PBS for 5 minutes three times, changing the PBS each time.
  11. Incubate slides with secondary antibodies to label primary antibodies. For this application, visualize anti-B7-H3 antibody using AlexaFluor-546 conjugated goat anti-rabbit antibody (1:200 dilution, optimized according to manufacturer's instructions) and CD31 with AlexaFluor-488 goat anti-rat secondary antibody (1:200 dilution, optimized according to manufacturer's instructions) in blocking solution, protected from light and dehydration on a slide tray, for 1 h at room temperature.
    NOTE: Secondary antibodies are from the same host animal but match the affinity of the secondary antibodies to the host species of the respective primary antibody. Slides are protected from light from this point onwards.
  12. Rinse slides in PBS for 5 minutes three times, changing the PBS each time.
  13. Apply one drop of the mounting medium into the center of the tissue slice and carefully place a coverslip avoiding entrapment of air bubbles.
  14. Seal the edges of the coverslip with clear nail polish and allow to dry.
    NOTE: To pause the protocol for up to a week at this point, store slides at -20 °C until ready to proceed.

5. Confocal microscopy imaging and quantitative image analysis

NOTE: Preparing the confocal microscope and imaging parameters will depend on the confocal system used. The microscope used here was purchased commercially (e.g., Zeiss LSM 510 Meta system) and the associated acquisition software was used (e.g., Zen 2009). However, many of these steps will apply to any confocal microscope and assume basic confocal microscopy knowledge.

  1. After the system has been turned on and warmed up, select the desired objective; here a 20x (numerical aperture = 0.8) objective was used.
  2. Load a positive control slide, coverslip down, to allow for setting the optimization for the brightest signal. Imaging in the red channel, focus the system on the sample in Live imaging mode.
  3. For each laser channel used, optimize the laser intensity, master gain, and pinhole size as follows:
    1. Switch to Continuous mode for imaging.
    2. Optimize the Laser Intensity (which controls the laser power) and Gain (Master) (which controls the voltage for the photomultiplier tube) slide bars while monitoring the Look Up Table (LUT) histogram. Adjust these two settings until the dynamic range of the histogram is filled without saturating pixels.
      NOTE: If the laser intensity is too high photobleaching will occur. If the Gain (Master) is too high, the image will become noisy. Ideally, the Gain (Master) will be in the middle of its range.
    3. Set the pinhole to 1 airy unit (AU), which gives the highest resolution and the thinnest z-slice.
    4. Slide the Digital Offset bar to minimize the noise floor on the LUT histogram for a true black background.
      NOTE: Once microscopy settings are optimized for each laser channel and objective, keep them constant throughout the imaging session and for imaging of all slides, to allow for the quantitative comparison between slides.
  4. Under the Acquisition Mode tab, under Averaging, select the desired Number and Bit Depth. Click the Optimal button to set the optimal pixel size.
  5. Use the Snap acquisition button to collect a high-quality image. Here, random fields of view were selected from within the tumor, but other areas of interest may apply for different applications (vessels, tumor margins, penetration depth, etc.)
  6. Save image files in the format used by the confocal software (here, ".lsm") for offline processing and quantification.
    NOTE: If not all slides are imaged during the same session, save the settings and reload them on subsequent visits, though reimaging the same slide is not recommended due to photobleaching.
  7. Perform the quantitative fluorescence intensity measurements. Open Fiji (Fiji Is Just ImageJ software) and load a .lsm image file by dragging it onto the status bar.
  8. Split the color channel data. Go to Image > Stacks > Split Channels.
  9. Preprocess the fluorescence images as needed, i.e., subtract the background signal (Process > Subtract Background) or reduce the noise via a filtering method.
  10. Segment the color channel corresponding to the reference protein (vascular, nuclear, cellular stain) by setting a threshold on the signal intensity (Image > Adjust > Threshold).
    NOTE: Manual thresholding introduces subjectivity into the image analysis, therefore, using an automated thresholding algorithm or referencing image histograms makes image analysis results less biased.
  11. Use this threshold to create a binary mask (Process > Binary > Convert to Mask).
  12. Measure and label ROIs within the mask (Analyze > Analyze Particles > Check Add to Manager > OK).
  13. Apply ROIs to the color channel corresponding to the antibody of interest (Click channel image, Analyze > Tools > ROI Manager > Measure). This will apply the mask ROIs to the antibody image and provide image measurements for label sections in the Results window. Save results window (File > Save).
  14. Calculate the desired statistic of interest, such as the mean fluorescence intensity as described here.
  15. Perform all processing steps identically to each image within a set of slides. Create a macro to automatically do this for large image batches.
  16. For image display only after quantitative measurements, apply qualitative image adjustments to optimize visualization of biodistribution patterns by adjusting minimum, maximum, brightness, and contrast to the same levels on all slides (Image > Adjust > Brightness/Contrast).
  17. Convert the image type (Image > Type > RGB Color) and save files in a lossless image type such as .tiff (File > Save As > Tiff…) for use in presentations and publications.

Disclosures

The authors have nothing to disclose.

Materials

Animal Model
FVB/N-Tg(MMTV-PyMT)634Mul/J The Jackson Laboratory 2374 Females, 4-6 weeks of age
Animal Handling Supplies
27G Catheter VisualSonics Please call to order Vevo MicroMarker Tail Vein Access Cannulation Kit
Alcohol Wipes Fisher Scientific 22-246073
Gauze Sponges (4" x 4" 16 Ply) Cardinal Health 2913
Heat Lamp Morganville Scientific HL0100
Isoflurane Henry Schein Animal Health 29404
Ophthalmic Ointment Fisher Scientific NC0490117
Surgical Tape 3M 1530-1
Tissue Collection
Disposable Base Molds Fisher Scientific 22-363-556
Optimal Cutting Temperature (OCT) Medium Fisher Scientific 23-730-571
Surgical London Forceps Fine Science Tools 11080-02
Surgical Scissors Fine Science Tools 14084-08
Antibodies
AlexaFluor-488 goat anti-rat IgG Life Technologies A-11006
AlexaFluor-546 goat anti-rabbit IgG Life Technologies A-11010
AlexaFluor-594 goat anti-human IgG Life Technologies A11014
Human IgG Isotype Control Novus Biologicals NBP1-97043
Humanized anti-netrin-1 antibody Netris Pharma contact@netrispharma.com
Rabbit anti-Mouse CD276 (B7-H3) Abcam ab134161 EPNCIR122 Clone
Rat anti-Mouse CD31 BD Biosciences 550274 MEC 13.3 Clone
Reagents
Bovine Serum Albumin (BSA) Sigma-Aldrich A2153-50G
Clear Nail Polish Any local drug store
Indocyanine Green – NHS Intrace Medical ICG-NHS ester
Mounting Medium ThermoFisher Scientific TA-006-FM
Normal Goat Serum Fisher Scientific ICN19135680
Paraformaldehyde (PFA) Fisher Scientific AAJ19943K2
Sterile Phosphate Buffered Saline (PBS) ThermoFisher Scientific 14190250
Triton-X 100 Sigma-Aldrich T8787
Supplies
Adhesion Glass Slides VWR 48311-703
Desalting Columns Fisher Scientific 45-000-148
Glass Cover Slips Fisher Scientific 12-544G
Hydrophobic Barrier Pen Ted Pella 22311
Microcentrifuge Tubes Fisher Scientific 05-402-25
Slide Staining Tray VWR 87000-136
Software
FIJI LOCI, UW-Madison. Version 4.0 https://fiji.sc/

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Cite This Article
An In Vivo Immunofluorescence Localization Method to Study Antibody Biodistribution. J. Vis. Exp. (Pending Publication), e21891, doi: (2024).

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