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In This Article

  • Summary
  • Abstract
  • Introduction
  • Protocol
  • Results
  • Discussion
  • Disclosures
  • Acknowledgements
  • Materials
  • References
  • Reprints and Permissions

Summary

Here we present a mouse brain vascular permeability assay using intraperitoneal injection of fluorescent tracers followed by perfusion that is applicable to animal models of blood-brain barrier dysfunction. One hemi-brain is used for assessing permeability quantitatively and the other for tracer visualization/immunostaining. The procedure takes 5 - 6 h for 10 mice.

Abstract

Blood-brain barrier (BBB) is a specialized barrier that protects the brain microenvironment from toxins and pathogens in the circulation and maintains brain homeostasis. The principal sites of the barrier are endothelial cells of the brain capillaries whose barrier function results from tight intercellular junctions and efflux transporters expressed on the plasma membrane. This function is regulated by pericytes and astrocytes that together form the neurovascular unit (NVU). Several neurological diseases such as stroke, Alzheimer's disease (AD), brain tumors are associated with an impaired BBB function. Assessment of the BBB permeability is therefore crucial in evaluating the severity of the neurological disease and the success of the treatment strategies employed.

We present here a simple yet robust permeability assay that have been successfully applied to several mouse models both, genetic and experimental. The method is highly quantitative and objective in comparison to the tracer fluorescence analysis by microscopy that is commonly applied. In this method, mice are injected intraperitoneally with a mix of aqueous inert fluorescent tracers followed by anesthetizing the mice. Cardiac perfusion of the animals is performed prior to harvesting brain, kidneys or other organs. Organs are homogenized and centrifuged followed by fluorescence measurement from the supernatant. Blood drawn from the cardiac puncture just before perfusion serves for normalization purpose to the vascular compartment. The tissue fluorescence is normalized to the wet weight and serum fluorescence to obtain a quantitative tracer permeability index. For additional confirmation, the contralateral hemi-brain preserved for immunohistochemistry can be utilized for tracer fluorescence visualization purposes.

Introduction

The blood-brain barrier (BBB) consists of the microvascular endothelial cells (ECs) supported by closely associated pericytes (PCs), which are ensheathed in the basal lamina, and astrocytes (ACs) that envelop the basement membrane with their end-feet1,2. ECs interact with several cell types that support and regulate the barrier function, primarily ACs and PCs, and also neurons and microglia, all of which together form the neurovascular unit (NVU). The NVU is critical for the function of the BBB, which limits the transport of blood-borne toxins and pathogens from entering the brain. This function is a result of tight-junction molecules such as claudin-5, occludin, zonula occludens-1, which are present between ECs and also due to the action of transporters such as p-glycoprotein (P-gp) that efflux molecules that enter the endothelium back into the vessel lumen1,2,3. The BBB however allows for the transport of essential molecules such as nutrients (glucose, iron, amino acids) by specific transporters expressed on the EC plasma membranes1,2,3. The EC layer is highly polarized with respect to the distribution of the various transporters between the luminal (blood-facing) and abluminal (brain-facing membranes) to allow for the specific and vectorial transport function4,5. While the BBB is protective with respect to tightly regulating the CNS milieu, it is a major challenge for CNS drug delivery in diseases such as Parkinson's with a functional BBB. Even in neurological diseases with BBB dysfunction, it cannot be assumed that the brain drug delivery is increased particularly as the barrier dysfunction could include damage to the specific transporter targets for example as in Alzheimer's disease (AD). In AD, several amyloid beta transporters such as LRP1, RAGE, P-gp are known to be dysregulated and hence targeting these transporters might be futile6,7,8. The BBB is impaired in several neurological diseases such as stroke, AD, meningitis, multiple-sclerosis, and in brain tumors9,10,11. Restoring the barrier function is a crucial part of the therapeutic strategy and thus its assessment is critical.

In this work, we have described an objective and quantitative protocol for permeability assay in rodents that we successfully applied to several mouse lines both transgenic and experimental disease models10,12,13,14. The method is based on a simple intraperitoneal injection of fluorescent tracers followed by perfusion of the mice to remove the tracers from the vascular compartment. Brain and other organs are collected post perfusion and permeability assessed by an objective and absolute permeability index based on fluorescence measurements of tissue homogenates in a plate reader. All raw fluorescence values are corrected for the background using tissue homogenates or serum from sham animals that do not receive any tracer. Ample normalizations are included for serum volume, serum fluorescence, and the weight of the tissues, thus yielding permeability index that is absolute and comparable between experiments and tissue types. For ease of comparison between groups, the absolute permeability index values can be readily transformed to ratios as we had performed previously12. Concurrently, stored hemi-brains and kidney could be utilized for tracer visualization by fluorescence microscopy10. The classic fluorescence microscopy could be valuable in obtaining regional difference in permeability albeit cumbersome due to subjective selection of tissue sections and images for a semi-quantitative analysis. The detailed steps are presented in the protocol and notes are added where appropriate. This provides the necessary information for successfully performing the in vivo permeability assay in mice that can be scaled to other small animals. The assay can be applied to many kinds of tracers allowing for the charge and the size based permeability assessment by a combination of tracers with distinct fluorescence spectra.

Protocol

All animals were handled with utmost care minimizing pain or discomfort during the procedure. This procedure follows the animal care guidelines of our institution and has been approved by the local committee (Regierungspraesidium Darmstadt, approval number FK/1044).

A schematic of the work steps for in vivo permeability assay in mice is shown in Figure 1. The details of each step are described below.

1. Animal Handling

  1. Preparation and administration of tracers and anesthetics
    1. Prepare labeled tubes and molds for tissue embedding at least a day before the permeability assay. Maintain sterile conditions throughout the protocol by working under clean fume hood and using tools cleaned with 80 % ethanol. Use male or female wild-type (WT) or angiopoietin-2 (Ang-2) gain-of-function (GOF) CD1 mice in the mature adult age group of 3-6 months for the current protocol. Perform genotyping of the mice as described previously 10
      Note: 80% alcohol will not result in sterile instruments but will minimize contamination of the samples prepared.
    2. Dilute all the tracers in sterile PBS into 2 mM stocks and store the aliquots protected from light at -20 °C.
    3. Choose tracers such as (Tetramethyl Rhodamine) TMR and (fluorescein isothiocyanate) FITC with distinct excitation/emission spectra and that are lysine fixable resulting in minimal interference between the dyes both by fluorescence microscopy (using the TMR or FITC filter respectively) and by fluorometry in a plate reader for the permeability assay.
      NOTE: TMR dextran 3 kD and FITC dextran 3 kD used in the study are both lysine fixable and hence could be also used for immunohistochemical analysis post-fixation with aldehydes in order to investigate regional differences.
    4. Handle all animals with utmost care following the institutional care guidelines. Inject intraperitoneally each mouse with 100 µL tracer solution that can be increased up to 200 µL when an additional tracer is combined using 100 µL of each tracer in a 1:1 mix10,13. Inject at least one animal with PBS alone instead of the tracers to serve as sham control for autofluorescence background subtraction.
    5. 5 min after tracer injection, anesthetize the animal with an i.p injection of Ketamine and Xylazine (100 mg and 5-10 mg in 0.9 % Saline per kg body weight respectively, 150 µL of the cocktail per 25 g mouse).
      NOTE: Vet ointment was not applied on eyes during the procedure as the period between animal anesthesia and perfusion/sacrifice was brief (10 minutes) where any drying of the eyes was not observed.
  2. Blood collection and cardiac perfusion
    1. Prepare the animals for cardiac perfusion 10 min after anesthetic administration. Check the absence of paw twitch response in order to ensure that the animal reached a surgical plane of anesthesia.
    2. Lay the animals on their back and apply 80 % ethanol on the skin of abdominal area. Using small scissors, open up the abdominal wall with a small incision (2 cm) just beneath the rib cage. Separate liver from the diaphragm and then slowly cut through the diaphragm exposing the pleural cavity 15.
    3. Cut the rib cage bilaterally and fix the cut sternum in order to expose the left ventricle. Insert a 21-gauge butterfly needle connected to a peristaltic perfusion system in the posterior of the left ventricle.
    4. Puncture the right atrium and quickly (within 10 s) collect 200-300 µL of blood released into the chest cavity using 1 mL pipette tips (with end cut-off) in serum collection tubes and store it on ice. 
      Note: This perfusion procedure is non-survival.
    5. As soon as the blood is collected, switch on the perfusion system (10-12 rpm, 5 mL/min) and perfuse the animal for 3 min with warm (RT) 1x PBS (free of Ca2+/Mg2+ ions).
      NOTE: PBS containing Ca2+/Mg2+ ions can be utilized for better heart activity during the perfusion. The total amount of PBS used for perfusion is in the range of 15-20 mL.
    6. Assess perfusion quality by noting the color of liver, kidneys, which appear white/pale after perfusion.
      NOTE: Kidney or liver perfusion do not necessarily indicate brain perfusion as the arteries (carotid/vertebral) reaching the brain from aorta might get ruptured during the preparation in step 3 particularly during the atrial puncture.

2. Tissue Processing

  1. Organ collection and storage
    1. At the end of the perfusion, confirm death of the animal by cervical dislocation and harvest brain and kidneys. Verify brain perfusion by the color of the brains (no visible blood in vessels of the meninges), so as to exclude the animals from permeability analysis when perfusion quality is not good. Separate the brain into 2 hemibrains using a scalpel (Figure 1).
    2. Dissect with a scalpel one hemibrain free of olfactory lobes and cerebellum and transfer the hemicerebrum to a 2-mL tube. Store hemi-cerebellum in an additional tube if required for cerebellar permeability assessment.
    3. Transfer a single kidney to another 2-mL tube. Store the samples immediately on dry ice.
    4. Embed natively the remaining kidney and hemi-brain (comprising the cerebellum and olfactory lobes) in tissue-tek optimal cutting temperature (O.C.T) compound on dry ice.
    5. In the end, centrifuge the blood samples stored on ice in serum collection tubes at 10, 000 g, 10 min at 4 °C. Transfer serum supernatants to 1.5 mL tubes and place them in the dry ice container.
    6. Transfer all the samples collected on dry-ice to -80 °C freezer until further processing.
      NOTE: It is important to freeze the samples before proceeding to the homogenization steps as homogenization efficiency increases after as freeze thawing.
  2. Homogenization and centrifugation
    1. Thaw on ice the hemi-cerebrum and kidney samples frozen down at -80 °C and weigh the tubes containing the organs. From these weights, subtract the mean value of several empty tubes (about 20) to get the tissue weight. Add 300 µL and 200 µL of cold 1X PBS to the tubes containing kidney and hemi-cerebrum, respectively.
      NOTE: For lower amounts of tissue (like hemi-cerebellum, below 100 mg) weighing the individual tubes is recommended.
    2. Homogenize each sample in the original eppendorf tube with a polytetrafluoroethylene (PTFE) pestle attached to an electric overhead stirrer (1, 000 rpm) by performing about 15 strokes (1 stroke = 1 up and 1 down). Rinse the pestle with PBS in between samples and wipe dry before proceeding to the next sample.
      NOTE: The use of detergents during homogenization was avoided due to potential interference with fluorometry. However, intracellular tracer is also detected in this protocol as the tissue is thoroughly homogenized, which is more efficient after one round of freeze thawing.
    3. Store the homogenized samples on ice protected from light and centrifuge all together in the end at 15,000 g, 20 min, 4 °C in a tabletop centrifuge. Transfer supernatants to a new 1.5 mL tubes on ice for immediate fluorometry or at -80 °C to be analyzed later.
  3. Fluorescence measurement and quantification
    1. If frozen at the end of the previous step, thaw on ice the tissue supernatant and serum samples stored at -80 ˚C protecting them from light with the foil.
    2. Pipette 50 µL of diluted serum (30 µL 1x PBS + 20 µL serum) or tissue supernatants (as is) into a 384-well black plate. Include at least one sample from sham animal for serum and tissue supernatants to ensure proper background subtraction, as this tissue homogenate background is normally higher than that of PBS used as the diluent.
      NOTE: An average of 3 sham animals can be used for autofluorescence although a very little variability in sham autofluorescence values (data not shown) was observed. The amount of serum used can be reduced by diluting it with PBS, which can also increase the signal to noise ratio for samples with low fluorescence such as the brain samples. Upto 10 µL serum was tested diluting it with 40 µL PBS. Make sure that no bubbles are present in the wells.
    3. Insert the 384-well black plate into the plate reader and open a new script selecting fluorescence measurement.
    4. Set the gain to optimal and use excitation/emission (nm) values of 550/580 or 490/520 for TMR or FITC dyee respectively and start the measurement to obtain the raw fluorescence units (RFUs).
    5. Use the raw fluorescence units (RFUs) from the plate reader to calculate the permeability index (PI) after subtracting the corresponding sham values.
      1. *Permeability Index (mL/g) =(Tissue RFUs/g tissue weight)/(Serum RFUs/mL serum)
    6. Example calculation for brain permeability index (PI) of the animal GOF1 (Table 1):
      1. GOF1 brain RFUs - SHAM brain RFUs = 154 - 22.5 = 131.5
      2. GOF1 serum RFUs - SHAM serum RFUs = 38305 - 27 = 38278
      3. Brain weight (g) = 0.195
      4. Serum volume (ml) = 0.02
      5. Brain Permeability Index (10-3 mL/g) = (131.5/0.195)/(38278/0.02) = 0.352
        NOTE: The permeability index calculations yield values that are absolute and comparable between experiments and tissue types. These however can be presented as ratios for ease of comparison between 2 groups 12. This can be achieved by dividing the PI of each animal in both groups with the mean PI of control group, driving the control group mean through 1 yet keeping the inter animal variation in the control group. This transformation provides values for experimental group (or groups) relative to control group set to 1.
  4. Immunofluorescence visualization of tracer
    1. Cut the kidney/hemi-brain blocks embedded natively in tissue-tek compound (O.C.T) (step 2.1) into 10 µm sections on a cryostat set to -20 °C and transfer the sections to slides placed at room temperature. Once the sections are dried (about 30 min), transfer slides to -80 °C freezer until use.
    2. On the day of staining, thaw the slides at 37 °C for 10 min, and then fix the sections with 4% paraformaladehyde (PFA) for 10 min at room temperature followed by quick washing in PBS.
    3. Incubate the sections in permeabilization/blocking buffer made of sterile PBS containing 1 % BSA and 0.5 % Triton X-100 pH 7.5 for 1 h at room temperature.
    4. Incubate slides for 1.5 h at room temperature with CD31 primary antibody (0.5 mg/ml, clone MEC 13.3), diluted in 1:100 in buffer containing sterile PBS, 0.5 % BSA, 0.25 % Triton X-100 (pH 7.2) followed by three 5 min washes in PBS.
    5. Perform secondary antibody incubation in the above buffer for 1 h at room temperature with species-specific fluorescently labeled antibodies diluted 1:500 (2 mg/mL). For CD31, goat anti-rat Alexa 568 or Alexa 488 can be used at a dilution of 1:500. Include DAPI (300 µM) in the secondary antibody mix (1:1,000 dilution from the stock) to stain for the nuclei.
    6. Mount the stained sections with aqua polymount and leave it overnight for polymerization at room temperature in dark.
    7. Acquire images using a spectral imaging confocal laser scanning microscope system. Analyze images by NIS elements software (version 4.3). Software such as Photoshop can be used for generation of montage figures.

Results

We have recently shown that angiopoietin-2 (Ang-2) gain-of-function (GOF) mice have higher brain vascular permeability than control mice in healthy conditions10. In stroke-induced mice, it was also shows that the GOF mice had bigger infarct sizes and greater permeability than the control littermates. These results show a critical role of Ang-2 in permeability at the BBB. The protocol therefore utilized the GOF mice and compared them to control littermates to descri...

Discussion

Blood-brain barrier dysfunction is associated with a number of neurological disorders, including primary and secondary brain tumors or stroke. BBB breakdown is often associated with life-threatening CNS edema. The elucidation of the molecular mechanisms that trigger the opening or closure of the BBB is therefore of therapeutic significance in neurological disorders and commonly investigated by researchers. However, methods to investigate BBB permeability in vivo reported in the literature, are often associated w...

Disclosures

The authors declare that they have no competing financial interests.

Acknowledgements

The authors would like to acknowledge Sphingonet consortium funded by the Leduq foundation for supporting this work. This work was also supported by the Collaborative Research Center "Vascular differentiation and remodeling" (CRC/ Transregio23, Project C1) and by the 7. FP, COFUND, Goethe International Postdoc Programme GO-IN, No. 291776 funding. We further acknowledge Kathleen Sommer for her technical assistance with mice handling and genotyping.

Materials

NameCompanyCatalog NumberComments
Tetramethyl Rhodamine (TMR) dextran 3kDThermosfisherD3308
Fluorescein isothiocyanate (FITC) dextran 3kDThermosfisherD3306
Ketamine (Ketavet)Zoetis
Xylazine (Rompun)Bayer
0.9% SalineFresenius Kabi Deutschland GmbH
1X PBSGibco10010-015
Tissue-tek O.C.T compoundSakura Finetek4583
37% Formaldhehyde solutionSigma252549-1Lprepare a 4% solution
Bovine Serum Albumin, fraction VRoth8076.3
Triton X-100SigmaT8787
rat anti CD31 antibody, clone MEC 13.3BD Pharmingen553370
goat anti rat alexa 568Molecular ProbesA-11077
goat anti rat alexa 488Molecular ProbesA-11006
DAPIMolecular ProbesD1306
Aqua polymountPolyscience Inc18606
21-gauge butterfly needleBD387455
serum collection tubeSarstedt41.1500.005
2mL eppendorf tubesSarstedt72.695.500
Kimtech precision wipes tissue wipersKimberley-Clark Professional05511
384-well black plateGreiner781086
slides superfrost plusThermoscientificJ1800AMNZ
PTFE pestleWheaton358029
electric overhead stirrerVWRVWR VOS 14
plate readerTecanInfinite M200
CryostatMicrom GmbHHM 550
Nikon C1 Spectral Imaging confocal Laser Scanning Microscope SystemNikon
peristaltic perfusion systemBVK Ismatec
microcentrifugeeppendorf5415R

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