The zebrafish is now an established and powerful tool for modeling muscular dystrophies, congenital myopathies, and related neuromuscular diseases. Birefringence and touch-evoked escape behavior are two common noninvasive assays used to determine the degree of muscular disorganization and locomotive impairment of zebrafish embryos during early development.
Zebrafish (Danio rerio) have become a particularly effective tool for modeling human diseases affecting skeletal muscle, including muscular dystrophies1-3, congenital myopathies4,5, and disruptions in sarcomeric assembly6,7, due to high genomic and structural conservation with mammals8. Muscular disorganization and locomotive impairment can be quickly assessed in the zebrafish over the first few days post-fertilization. Two assays to help characterize skeletal muscle defects in zebrafish are birefringence (structural) and touch-evoked escape response (behavioral).
Birefringence is a physical property in which light is rotated as it passes through ordered matter, such as the pseudo-crystalline array of muscle sarcomeres9. It is a simple, noninvasive approach to assess muscle integrity in translucent zebrafish larvae early in development. Wild-type zebrafish with highly organized skeletal muscle appear very bright amidst a dark background when visualized between two polarized light filters, whereas muscle mutants have birefringence patterns specific to the primary muscular disorder they model. Zebrafish modeling muscular dystrophies, diseases characterized by myofiber degeneration followed by repeated rounds of regeneration, exhibit degenerative dark patches in skeletal muscle under polarized light. Nondystrophic myopathies are not associated with necrosis or regenerative changes, but result in disorganized myofibers and skeletal muscle weakness. Myopathic zebrafish typically show an overall reduction in birefringence, reflecting the disorganization of sarcomeres.
The touch-evoked escape assay involves observing an embryo's swimming behavior in response to tactile stimulation10-12. In comparison to wild-type larvae, mutant larvae frequently display a weak escape contraction, followed by slow swimming or other type of impaired motion that fails to propel the larvae more than a short distance12. The advantage of these assays is that disease progression in the same fish type can be monitored in vivo for several days, and that large numbers of fish can be analyzed in a short time relative to higher vertebrates.
1. In vivo Analysis of Skeletal Muscle Structure by Birefringence
2. Touch-evoked Escape Behavior Assay
Birefringence can be used as an efficient, noninvasive assay to shed light on the state of myofibrillar organization in living zebrafish embryos. Examples of wild-type zebrafish as well as zebrafish with decreased expression of genes critical to skeletal muscle development and function are presented. Wild-type zebrafish at 5 dpf display highly birefringent skeletal muscles under polarized light due to the ordered array of myofilaments (Figures 2A-B). In contrast, an age-matched embryo homozygous for a pathogenic mutation in the dystroglycan gene (dag1) displays patchy birefringence, indicative of areas of muscle degeneration (Figures 2C-D)2. This patch-like pattern and rapid progression of muscle degeneration throughout early development is consistent with other dystrophic fish models1,3. Quantifying the birefringence of 5 dpf dystrophic dag1 mutants identifies a significant reduction in brightness to 27.9%±5.3 of the maximal birefringence seen in their wild-type siblings. This reduction is more severe than the reduction to 52.4%±5.5 observed in 3 dpf myopathic mtm1 morphants (wild-type/dag1/mtm1: n = 3; Student's t-test, P < 0.001) (Figure 4). Myopathic fish models (Figures 3C-D) instead tend to show an overall reduction in birefringence compared to wild-type (Figures 3A-B), as there is often myofibrillar disorganization in the major axial skeletal muscles but no evidence of degenerative changes.
Touch-evoked escape behaviors can be used to demonstrate that zebrafish models of skeletal muscle disease display locomotive defects and swimming difficulties. The live swimming phenotypes of wild-type and dag1 fish were examined by video microscopy with a touch-evoked escape behavior assay (Videos 1 and 2)2. Videos were then analyzed frame by frame to confirm that dag1 mutants exhibit impaired movement compared to wild-type controls in response to tactile stimuli (Figure 5). The distances both types of embryos were able to move within a fixed time interval were averaged (wild-type: 6.2±0.4 cm/0.1 sec, n = 10; mutant: 0.75±0.08 cm/0.1 sec, n = 10; Student's t-test, P < 0.001) and indicate diminished motor function in dag1 mutants. However, reduced touch-evoke responses in neuromuscular mutants could also be attributed to defects in the central nervous system and/or the neuromuscular junction. Therefore, electrophysiological measurement of the voltage response in muscles evoked by tactile stimulation may help to distinguish whether touch-evoke impairments are due to a sensory deficit or to a primary defect in skeletal muscle13.
Figure 1. Diagram of a standard dissecting microscope fitted with a camera and polarized lenses (A). Sample set-up with polarized lenses and anesthetized zebrafish embryos is presented larger in (B). Click here to view larger image.
Figure 2. Wild-type fish show bright birefringence indicative of highly organized muscles at 5 dpf (B). Age-matched dag1 mutant fish appear grossly normal in normal light whereas extensive muscle degeneration in most somites is demonstrated by the loss of birefringence under polarized light and is consistent with a dystrophic phenotype (D). Brightfield images of the wild-type fish (A) and the dag1 mutant (C) are shown for reference. Click here to view larger image.
Figure 3. Morpholino-based knockdown of myotubularin (mtm1) in zebrafish results in defects in skeletal muscle at 3 dpf. An overall reduction in birefringence is observed in mtm1 morphant fish (D) in comparison to wild-type fish (B), consistent with a myopathic phenotype. Brightfield images of the wild-type fish (A) and the mtm1 morphant (C) are shown for reference. Click here to view larger image.
Figure 4. Zebrafish embryos with skeletal muscle defects show a highly significant reduction in birefringence compared to wild-type controls. Quantification data are calculated by dividing the mean intensity by the selected area of the fish (ImageJ), and normalizing the percentage values to wild-type. Data are presented as means±SEM and ** indicates P < 0.001 by Student's t-test. Click here to view larger image.
Figure 5. Dag1 mutant embryos exhibit reduced touch-evoked response at 5 dpf (E-K) while mechanosensory stimulation causes 5 dpf wild-type embryos to swim away rapidly and fully exit the field of view (A-D). Scale bar = 1 mm. Click here to view larger image.
Video 1. Touch-evoked escape behavior assay on wild-type zebrafish. Normal fry (5 dpf) swim away very rapidly in response to touch. Click here to watch video.
Video 2. Touch-evoked escape behavior assay on dag1 mutant zebrafish. Dag1 fry (5 dpf) show impaired response to touch and fail to exit the field of view. Click here to watch video
Primary neuromuscular disorders are traditionally classified as dystrophic or nondystrophic processes. Muscular dystrophies are characterized by myofiber degeneration followed by repeated rounds of regeneration, which ultimately leads to an end stage process typified by fibrosis and replacement by adipose tissue14. Nondystrophic myopathies, in contrast, are not associated with necrosis or regenerative changes, but do result in disorganized myofibers and overall skeletal muscle weakness.
Zebrafish models have emerged in recent years as a tremendously valuable resource for better understanding the molecular pathways and pathogenesis of different neuromuscular diseases. In addition to the general advantages of this model system, including rapid ex utero development, translucent embryos, high reproductive capacity, and a genome closely related to that of human, the zebrafish disease model often closely mimics the human disease. Although many zebrafish with skeletal muscle defects have morphological abnormalities, some mutant phenotypes are grossly normal and require finer characterizations. For these and all cases, the extent of muscle damage and weakness can quickly and easily be evaluated in zebrafish using noninvasive in vivo assays for birefringence and touch-evoked escape behavior. Birefringence is a sensitive indicator of muscle integrity in translucent zebrafish embryos that has been used to noninvasively identify skeletal muscle mutants since early in the establishment of the zebrafish model system15. The assay itself involves placing a zebrafish embryo between two polarizing filters and visualizing the fish in an otherwise dark background16. Wild-type fish with highly organized sarcomeric arrays appear bright, whereas muscle mutants usually present with dark patches or an overall reduction in birefringence, suggesting myofibrillar disorganization within the major axial skeletal muscles. As described above, birefringent images may be readily quantified using publically available ImageJ software.
Touch-evoked escape behaviors in zebrafish involve many steps, beginning with the sensing of tactile stimuli and culminating in the contraction of muscles. Zebrafish embryos swim in response to touch by 26 hpf, but the frequency of muscle contractions during swimming does not increase to a value comparable to that of adult zebrafish until 36 hpf12,18. The touch-evoked response is optimally captured between 2-7 dpf. The time at which the touch stimulus is applied to the tail is set as the experimental “start” point. Whereas both wild-type and mutant larvae begin stationary, video microscopy is able to capture that wild-type larvae respond to mechanosensory stimuli with rapid and vigorous swimming in a straight line. Muscular mutants instead tend to weakly flex, swim in circles, or otherwise move for only a short distance. It should be noted that while there is an inherent degree of variability in the timing and intensity of manual touch stimuli, quantitative measurements of touch-evoke behaviors and swimming episodes tend to be highly reproducible within wild-type and reliable fish models of skeletal muscle disease.
Both birefringence and touch-evoked escape assays provide a fast and noninvasive way to analyze defects in skeletal muscles, and are therefore appropriate for analyzing a large number of embryos when performing high-throughput mutagenesis or chemical screens.
The authors have nothing to disclose.
We thank Behzad Moghadaszadeh for his wonderful help with quantification of birefringence images. This work was funded by the Muscular Dystrophy Association USA (MDA201302) and the National Institute of Arthritis and Musculoskeletal and Skin Diseases (R01 AR044345), as well as generous support from A Foundation Building Strength, Cure CMD, and the AUism Charitable Foundation. VAG is supported by K01 AR062601 from the National Institute of Arthritis and Musculoskeletal and Skin Diseases, and LLS is supported by F31 NS081928 from the National Institute of Neurological Disorders and Stroke.
Tricaine | Sigma | A5040 |
Petri dishes | Fischer Scientific | 0875711Z |
Forceps | Fischer Scientific | 100189-588 |
Insect pin | Fischer Scientific | S67375 |
Polarized lenses | Ritz Camera | Quantaray Tristar Optics C-PL 72mm |
Incubator | Fischer Scientific | Isotemp Incubator Model 630D |
Microscope | Nikon Instruments Inc. | SMZ 1500 |
Camera | Diagnostic Instruments Inc. | SPOT RT3 |
Imaging software | Diagnostic Instruments Inc. | SPOT 5.1 Advanced |