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In This Article

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

Summary

An easy and reliable technique for visualizing and quantifying airway cilia motility and cilia generated flow using mouse trachea is described. This technique can be modified to determine how a wide range of factors influence cilia motility, including pharmacological agents, genetic factors, environmental exposures, and/or mechanical factors such as mucus load.

Abstract

An ex vivo technique for imaging mouse airway epithelia for quantitative analysis of motile cilia function important for insight into mucociliary clearance function has been established. Freshly harvested mouse trachea is cut longitudinally through the trachealis muscle and mounted in a shallow walled chamber on a glass-bottomed dish. The trachea sample is positioned along its long axis to take advantage of the trachealis muscle to curl longitudinally. This allows imaging of ciliary motion in the profile view along the entire tracheal length. Videos at 200 frames/sec are obtained using differential interference contrast microscopy and a high speed digital camera to allow quantitative analysis of cilia beat frequency and ciliary waveform. With the addition of fluorescent beads during imaging, cilia generated fluid flow also can be determined. The protocol time spans approximately 30 min, with 5 min for chamber preparation, 5-10 min for sample mounting, and 10-15 min for videomicroscopy.

Introduction

Analysis of motile cilia function in the airway epithelia is experimentally important for elucidating the genetic and environmental factors that can affect mucociliary clearance and pulmonary health 1. The simple protocol developed for imaging the mouse airway epithelia provides an efficient method to interrogate airway cilia motility in mutant and knockout mouse models and require only basic skills in mouse tracheal tissue dissection and ex vivo imaging of airway cilia motility with high resolution videomicroscopy. This protocol was established and refined during a large-scale mouse mutagenesis screen to allow rapid evaluation of motile cilia function (cilia beat frequency, cilia beat shape, cilia generated flow) in mutants with congenital heart disease associated with heterotaxy 2-5.

Current techniques used to study airway cilia motility can be grouped into either the acute ex vivo type or longer term in vitro experimental approaches. Acute experiments include ex vivo visualization of human nasal/airway brush biopsies 6,7 and analysis of simple transverse airway sections 8. The in vitro approaches utilize various cell culture techniques to generate sheets of differentiated ciliated epithelia such as in air liquid interface cultures or airway suspension cultures9-11. However, these airway epithelia reciliation techniques require very significant investment in time and training before any useable ciliated epithelial cells are produced for experimentation (4-6 weeks 9,10). While acute ex vivo analysis of airway epithelial brush biopsies are commonly used for human clinical studies, this method is not usable in mouse studies due to exacerbated mechanical tissue injury 12.

The technique outlined in this protocol for analysis of mouse tracheal airway epithelia is not only simple to execute, but it requires no special dissection skills nor any specialized equipment besides those standard for imaging by videomicroscopy. There are many advantages to this simple protocol. First, as the mouse trachea tissue harvest is quick and easy to perform, it allows for rapid assessment of airway cilia function in a large number of mice. This can include acute analysis of the short term effects of different in vitro treatments. Second, being an ex vivo technique, the ciliated airway epithelium remains attached to it underlying supporting tissues and thus retain associated cell signaling pathways. Therefore in comparison to in vitro reciliated airway epithelia, this preparation is a better representation of the natural in vivo tissue environment. Third, this protocol allows the acquisition of a number of different quantitative parameters that can provide the objective assessment of motile cilia function. Finally, in contrast to other current methods for airway cilia visualization, this protocol allows for visualization of the cilia at right angles to the cilia beat direction, allowing profile view of the cilia that is optimal for high resolution imaging of cilia beat and metachronal wave generation.

This protocol can be modified in a number of ways to address a wide range of experimental needs such as the role of pharmacological agents, genetic factors, environmental exposures, and/or mechanical factors such as mucus load on airway cilia function and generation/maintenance of airway cilia beat and metachronal wave propagation.

Protocol

1. Reagents Setup

1.1 Dissection and Imaging Medium

Leibovitz's L-15 medium (L15) is supplemented with FBS (10%) and Penicillin-Streptomycin (100 units/ml of penicillin G sodium and 100 μg/ml of streptomycin sulfate) is used during both harvest and imaging of trachea samples.

2. Shallow Walled Culture Chamber Assembly

The chamber used to hold trachea tissue is shown in Figure 1. The floor of the chamber is the glass bottomed 35 mm culture dish. The top and side of the chamber is generated by placing a small piece of 0.3 mm thick silicone sheeting over the glass dish. The edge of the sheet is cut to fit the round bottom dish and the center is further trimmed to form a shallow central chamber (see steps 2.1-2.3). On top of this assembly, a 18 mm round glass cover slip is placed to generate an enclosed chamber suitable for imaging.

  1. Completely cover a 18 mm round glass cover slip with a square of 0.3 mm thick silicone sheeting.
  2. With standard sharp dissection scissors trim off the excess silicone sheeting from around the edge of the cover slip (resulting in a circular layer of silicone sheeting).
  3. With a sharp scalpel cut out and remove a central square of silicone sheeting (approximately 10 mm square) from the middle of the covered cover slip (thus forming the top and sides of the imaging chamber).

3. Trachea Harvest and Preparation

  1. Euthanize mice in accordance with local institutional animal care and use committee and/or governmental guidelines and remove trachea into a standard plastic 35 mm culture dish with enough L15 media to submerge tissue (authors have used mice just before birth at gestation day 16.5, through to newborn, neonatal, and adult animals 2).
  2. Remove non-trachea associated tissue attached to the outside of the trachea using blunt dissection.
  3. Remove the larynx with a transverse cut just below the cricoid cartilage using micro dissection scissors (Figure 2A, line 1).
  4. Remove the left and right primary bronchial branches with a transverse cut just above the carina using micro dissection scissors (Figure 2A, line 2).
  5. Gently hold the trachea with fine forceps and flush the lumen 2-3 times with ~1 ml of the bathing L15 medium with a P1000 Pipetman and P1000 tip to clear any mucus and blood.
  6. Cut out a 3-4 ring segment of trachea using a transverse cut with micro dissection scissors (Figure 2B, line 1).
  7. Cut longitudinally through the middle of the trachealis muscle of this short trachea segment using micro dissection scissors (Figure 2B, line 2).
  8. Cut longitudinally through the middle of the tracheal cartilage rings using micro dissection scissors (Figure 2C, line), leaving two sections of trachea tissue suitable for imaging (single section shown in Figure 2D).

4. Cilia Imaging

  1. Transfer trachea tissue segments, lumen side down, onto the middle of a 35 mm glass bottom culture dish with 100-200 μl of L-15 medium.
  2. To quantify cilia generated flow add a small amount of fluorescent 0.20 μm microspheres to the L-15 medium bathing the trachea tissue sample (~1 x 1011 particles/ml or 20 μl/ml of the Fluoresbrite 2.5% aqueous microsphere suspension).
  3. Place the imaging chamber prepared previously (See Procedure 1-3 above) on top of the trachea sample silicone sheet side down, with the trachea sample located in the middle of the shallow walled chamber formed by the window cut into the silicone sheeting (Figure 1).
  4. Gently push down on the coverslip to secure in place and remove any excess L-15 media from the edges using a P1000 tip and P1000 Pipetman.
  5. Mount the 35 mm glass bottom culture dish and trachea sample on a inverted microscope with 100X objective and DIC optics.
  6. Using a high-speed camera and movie acquisition software collect movies of cilia motility at 200+ frames per second along the ciliated tracheal epithelia of the curled up edge of the trachealis muscle (Figure 2D Outlined box, E: example still image from recorded movie)(Supplementary Movie 1).
  7. Using FITC epifluorescent imaging and a low light CCD camera (See equipment list above), collect movies of fluorescent microsphere movement across the surface of the ciliated tracheal epithelia to allow later quantification of cilia generated flow (Supplementary Movie 2).

5. Quantitation of Cilia Motility

  1. Load DIC imaged movies into the ImageJ software package and following the technique described by Iain Drummond 13 use the line tool to draw a raster line crossing the beating cilia. A "reslice" of this line generates a kymograph type image where cilia movement across the line generates a wave pattern. The number of pixels between each wave peak is them measured (one pixel = one movie frame) from which the number of beats per minute (i.e. Hz) can then be calculated.
  2. To measure cilia generated flow load fluorescent bead movies into the ImageJ software package, and use the MTrackJ plugin 14 to manually track fluorescent beads across the surface of the trachea epithelia and let the software generate bead velocity and directionality for each bead tracked.

Care should be taken when using fluorescent beads to quantify flow as the distance from the beating cilia can strongly influence measured flow magnitude. The bead movement in Supplemental Movie 2 is a good example of this. In this example bead movement is fast at the surface of the beating cilia and significantly drops off for beads further away in the bathing media. To control for this, bead tracings should only be collected at a fixed distance above the ciliated epithelia in all samples to allow correct comparisons to be made. Finally, to obtain representative data on fluid flow, beads should be tracked for as long as possible; we prefer to use bead tracks that cover 10+ ciliated cells for calculating fluid flow.

Results

Control airway cilia should be clearly visible and seen to beat in a coordinated manner (Supplemental Movie 1; movie playback is slowed to 15% real time), with noticeable flow in the direction of cilia beat (Supplemental Movie 2; movie playback is 100% real time). Quantitation of cilia movies should yield results similar to that seen in Figure 3. Collection of high-speed DIC movies makes possible the quantification of cilia beat frequency (Figure 3C) and...

Discussion

Measurement of cilia beat frequency (CBF) is relatively easy using high power microscope objectives and fast image acquisition hardware 13,15, and explains why CBF measurements form the basis of most studies investigating mucociliary clearance during health and disease. However, while CBF measurement is essential for understanding mucociliary clearance, measurement of CBF alone ignores the underlying importance of both ciliary generated flow and cilia beat waveform, both of which are more difficult to measure,...

Disclosures

Authors have nothing to disclose.

Acknowledgements

The project was supported by NIH grant U01HL098180 from the National Heart, Lung, and Blood Institute. The content is solely the responsibility of the authors and does not necessarily represent the official views of the National Heart, Lung, and Blood Institute or the National Institutes of Health.

Materials

NameCompanyCatalog NumberComments
Leibovitz’s L-15 Medium Invitrogen21083-027No phenol red
Fetal bovine serum HycloneSH30088.03
Penicillin-Streptomycin Invitrogen15140-122
2x fine forceps RobozRS-4976
Dissection scissors RobozRS-5676
Micro dissection scissors RobozRS-5620
Scalpel RobozRS-9801-15
P1000 pipetman Gilson, IncF123602
P1000 tips Molecular BioProducts2079E
18 mm round glass cover slips Fisher Scientific430588
Plastic 35 mm culture dishes Corning430588
Glass bottom 35 mm culture dishes Warner InstrumentsW3 64-0758
Silicone sheet 0.012" (0.3 mm) thick AAA Acme Rubber CoCASS-.012X36-63908
0.20 μm diameter Fluoresbrite YG Carboxylate Microspheres Polysciences09834-10
Inverted microscope, with 100x oil objective and DIC filters LeciaDMIRE2Brand is not critical.
100-watt mercury lamp, epifluorescent FITC excitation/emission filtersLeciaBrand is not critical.
Microscope stage IncubatorLecia11521749Not required if imaging cilia at room temperature
High-speed camera bright field Vision ResearchPhantom v4.2Brand is not critical. Must be faster than 125 fps
High-speed fluorescent camera HamamatsuC9100-12Brand is not critical. Must be faster than 10 fps
Movie analysis softwareNational Institutes of HealthImageJ with MtrackJ plugin

References

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  3. Aune, C. N., et al. Mouse model of heterotaxy with single ventricle spectrum of cardiac anomalies. Pediatric Research. 63, 9-14 (2008).
  4. Tan, S. Y., et al. Heterotaxy and complex structural heart defects in a mutant mouse model of primary ciliary dyskinesia. J. Clin. Invest. 117, 3742-3752 (2007).
  5. Zhang, Z., et al. Massively parallel sequencing identifies the gene Megf8 with ENU-induced mutation causing heterotaxy. Proc. Natl. Acad. Sci. U.S.A. 106, 3219-3224 (2009).
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  16. Schwabe, G. C., et al. Primary ciliary dyskinesia associated with normal axoneme ultrastructure is caused by DNAH11 mutations. Hum. Mutat. 29, 289-298 (2008).
  17. Shah, A. S., et al. Loss of Bardet-Biedl syndrome proteins alters the morphology and function of motile cilia in airway epithelia. Proc. Natl. Acad. Sci. U.S.A. 105, 3380-3385 (2008).
  18. Clary-Meinesz, C. F., Cosson, J., Huitorel, P., Blaive, B. Temperature effect on the ciliary beat frequency of human nasal and tracheal ciliated cells. Biology of the Cell / under the auspices of the European Cell Biology Organization. 76, 335-338 (1992).

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Keywords Ex VivoCilia MotilityRodent Airway EpitheliumMucociliary ClearanceTracheaDifferential Interference Contrast MicroscopyHigh speed VideomicroscopyCilia Beat FrequencyCiliary WaveformFluid Flow

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