This protocol describes an approach for in toto labeling and multidimensional imaging of zebrafish early eye development. We describe labeling, embedding, and four dimensional (4D) imaging using laser scanning confocal microscopy, and considerations for optimizing acquisition of datasets for dissecting mechanisms of optic cup morphogenesis.
Visual system function requires the establishment of precise tissue and organ structures. In the vertebrate eye, structural defects are a common cause of visual impairment, yet mechanisms of eye morphogenesis are still poorly understood. The basic organization of the embryonic eye is conserved throughout vertebrates, thus live imaging of zebrafish embryos has become a powerful approach to directly observe eye development at real time under normal and pathological conditions. Dynamic cell processes including movements, morphologies, interactions, division, and death can be visualized in the embryo. We have developed methods for uniform labeling of subcellular structures and timelapse confocal microscopy of early eye development in zebrafish. This protocol outlines the method of generating capped mRNA for injection into the 1-cell zebrafish embryo, mounting embryos at optic vesicle stage (~12 hours post fertilization, hpf), and performing multi-dimensional timelapse imaging of optic cup morphogenesis on a laser scanning confocal microscope, such that multiple datasets are acquired sequentially in the same imaging session. Such an approach yields data that can be used for a variety of purposes, including cell tracking, volume measurements, three-dimensional (3D) rendering, and visualization. Our approaches allow us to pinpoint the cellular and molecular mechanisms driving optic cup development, in both wild type and genetic mutant conditions. These methods can be employed directly by other groups or adapted to visualize many additional aspects of zebrafish eye development.
Vertebrate eye development begins with the emergence, or evagination, of the optic vesicles from the prospective brain neuroepithelium. The optic vesicles then undergo a series of tissue shape changes, elongating and then invaginating to generate the optic cup. In the optic cup, the neural retina and retinal pigment epithelium, both derived from the neuroepithelium, enwrap the nascent lens, which is derived from the surface ectoderm. The entire process requires a complex series of cell and tissue movements and molecular signaling, coordinated between neuroepithelium, ectoderm, and mesenchymal cell populations. These initial events establish the basic structure of the eye, and later steps of eye development, including iris and cornea formation, are elaborations on early organization. Disruptions to early eye development and morphogenesis underlie numerous visual impairment conditions in humans, including anophthalmia, microphthalmia, and coloboma. Unlocking the cellular and molecular mechanisms governing optic cup morphogenesis is crucial for further understanding visual system development and the pathological conditions that result when these processes go awry.
Our understanding of vertebrate eye development and morphogenesis emerged from a tremendous amount of work spanning classic histological studies to embryological and genetic approaches in a variety of model organisms including mouse, chick, frog, and fish1,2,3,4,5. While this body of work established molecular mechanisms that regulate early eye development, historically there exists a poor understanding of the morphogenesis of the eye: the emergence of its 3D structure. The bulk of these findings have come from imaging sectioned embryos at discrete time points. While this is sufficient to provide a view of tissue morphology in 2 dimensions, morphogenesis is a dynamic, 3D process. In order to determine how the shape of the tissue changes in 3 dimensions over time, how single cells behave, and how those behaviors contribute to changes in 3D tissue shape, different approaches are necessary.
One solution to address this significant gap in knowledge is live imaging, which enables dynamic observation of cells and tissues in real time as the organ takes shape. Unfortunately, this is not readily feasible in many model organisms due to the constraints of embryonic development. For example, mouse and chick embryos (developing in utero or within an eggshell) are not easily accessed, and many live embryos are not optically transparent, causing significant light scatter and limiting the depth to which images can be acquired. Zebrafish, with external development and transparent embryos, provide a unique opportunity to carry out live imaging of eye morphogenesis6,7,8,9,10,11,12,13,14,15,16,17,18,19. Ample transgenic and mutant lines are also available, as well as tools to generate new transgenics and mutants20,21,22,23,24. Further, optic cup morphogenesis occurs rapidly in zebrafish, over a 12 h timeframe (12-24 hours post fertilization, hpf), making imaging of the entire process feasible.
Live imaging efforts have been accelerated by expansion and optimization of the family of fluorescent proteins, which allow genetically encoded vital labeling of subcellular structures, as well as improvements and innovations to microscopy methods. The protocol described here uses laser scanning confocal microscopy, rather than other current approaches to imaging zebrafish embryogenesis, including spinning disk confocal microscopy, selective plane illumination microscopy (SPIM and its variants), and other more specialized microscopy methods. For the developing zebrafish eye, we found that spinning disk confocal microscopy was not sufficient for imaging deeper in the tissue. Although SPIM boasts an extremely fast imaging time and is becoming more widely used, handling the large datasets for visualization and analysis remains a challenge. In contrast, laser scanning confocal microscopy is easily accessible, especially for individuals lacking expertise in assembling optical hardware. We hope that the wide availability of laser scanning confocal microscopy will make our protocol useful for many labs.
Here, we describe our method for capturing 4D datasets of optic cup morphogenesis, using in toto labeling of the embryo for membranes and chromatin, and a laser scanning confocal microscope for image acquisition (schematized in Figure 1). The fluorescent proteins used here (EGFP-CAAX and H2A.F/Z-mCherry) were chosen to provide tissue labeling with single cell resolution. We use datasets generated with this protocol for a variety of image analysis and visualization functions. This protocol can be easily adapted if other subcellular structures are desired. Plasma membrane labeling was selected for visualization of cell shape: we use EGFP-CAAX, in which the last 21 amino acids of H-ras, serving as a prenylation signal sequence, are fused to the C-terminus of EGFP13. Other plasma membrane targeted fluorescent proteins (e.g., transmembrane fusion or myristoylated) are likely to work just as well. To mark nuclei, we selected H2A.F/Z-mCherry, in which mCherry is fused to a histone protein13. This ensures that cell division, including mitotic spindle orientation, is easily visualized.
With any live imaging approach, one must consider trade-offs between increasing imaging speed while maximizing signal-to-noise ratio, axial resolution, and sample preservation. We have optimized our methods to maximize image quality and number of embryos that can be imaged in a single run. Often, the goal is to image optic cup morphogenesis in a homozygous mutant embryo, which may be phenotypically indistinguishable from wild type at the onset of optic cup morphogenesis and the offspring of a heterozygous incross (25% of the embryos are the desired genotype). By optimizing, and then multiplexing image acquisition, there is an increased likelihood of capturing a dataset of a homozygous mutant embryo.
Temporal resolution, or how frequently volume data (Z-stacks) are acquired, is a key aspect of timelapse imaging. Depending on the purpose for such datasets, there are different requirements for speed. Initially this protocol was developed for manual 4D cell tracking. Tracking of individual cells within a uniformly labeled tissue requires high enough temporal resolution to provide confidence that any one cell is being continuously tracked over time. We found that Z-stacks of zebrafish optic cup morphogenesis must be acquired at least every 3.1 min over 12 h; here, we have optimized our acquisition on a laser scanning confocal microscope such that we can acquire Z-stacks of 4-5 embryos every 2.5 min.
Establishing Z-step size was a crucial step in protocol optimization: for 3D rendering and visualization, isotropic data are ideal, in which the Z-step size is equal to XY pixel dimension. In reality, it is extremely difficult to acquire such timelapse data with live samples, given constraints with imaging time and photobleaching. Therefore, determining the adequate Z-step size is important for the rendering and visualization needs of the experiment, and specifically, what X:Y:Z voxel ratio is needed to maximize axial information while maintaining speed and preventing photobleaching. For this protocol, the voxel ratio established was 1:1:3.5 (0.6 µm x 0.6 µm x 2.1 µm Z-step size using a 40x long working distance water immersion objective). When acquiring a Z-depth of 130-140 µm, this yields volume data with suitable temporal resolution and little photobleaching.
As discussed above, this protocol is specific for 4D imaging of zebrafish optic cup morphogenesis, using embryos in toto labeled for plasma membrane and chromatin, and a laser scanning confocal microscope. The protocol below can be easily adapted for a variety of experiments and needs. First, with respect to subcellular structures, any structure for which a live cell marker exists can be imaged. Next, although the focus here is exclusively on optic cup morphogenesis, timelapse imaging can be adapted for other stages of eye development, for example, neurogenesis25,26,27,28,29,30,31,32,33. For imaging later development, one may need to consider embryo immobilization (as spontaneous muscle activity begins around 24 hpf), pigmentation (which begins to emerge around 24 hpf), tissue size (the eye grows significantly in volume during neurogenesis), and imaging speed (which should be adjusted depending on the speed of the process of interest). All of these considerations can be readily managed. The protocol is quite flexible; in addition to the details of the specific protocol here, there are general principles that will aid those interested in live imaging other aspects of eye development.
All methods described here using zebrafish are covered under Dr. Kristen Kwan's animal protocol, "Cellular and Molecular Mechanisms of Visual System Development in Zebrafish", and approved by the Institutional Animal Care and Use Committee (IACUC) of the University of Utah.
1. Capped RNA Synthesis
2. Microinjection of 1-cell zebrafish embryos
NOTE: Inject 200-300 pg per RNA to obtain ubiquitous expression of chromatin and cell membranes throughout optic cup morphogenesis. Prepare 5-10 µL of the RNA dilution, and load 2.5-5 µL/needle; plan for extra in the event the needle breaks.
3. Mounting optic vesicle stage zebrafish embryos for timelapse imaging
4. Multiple position confocal timelapse with a laser scanning confocal microscope
NOTE: This timelapse imaging protocol was designed to be used with a laser scanning confocal microscope equipped with manufacturer's software (see Table of Materials). This system is equipped with a piezo Z-stage device that allows rapid acquisition of Z-stacks. The laser lines used in this protocol are a 488 nm Argon ion laser and a DPSS 561 nm laser. The 561 nm laser is well-suited for imaging the mCherry fluorophore: it is close enough to the peak of mCherry excitation (587 nm) and well-powered.
Injection of fluorescent RNAs enables subcellular labeling
RNAs that label the cell's plasma membrane and histones are injected in order to capture the individual cell morphologies and movements that underlie optic cup morphogenesis. Figure 2 demonstrates each step of the process of microinjecting zebrafish embryos at the 1-cell stage. Briefly, zebrafish are mated (Figure 2E), and embryos are collected and loaded into the injection mold (Figure 2J). A microinjection needle is backfilled (Figure 2H), and embryos are injected directly into the single cell (Figure 2K–M), which is necessary to obtain uniform labeling (Figure 2M, Figure 4I–I''', Movie 1). In addition to uniform labeling, robust fluorescence is observed and development proceeds unperturbed (Figure 3B–B'').
Effective mounting is essential for timelapse imaging OCM from 12–24 hpf
To image optic cup morphogenesis, which occurs over an extended period of time, it is critical to both select ideal embryos and properly position each sample while embedding. Figure 3 shows a detailed account for successful mounting of 11 hpf embryos. Injected embryos are first screened for sufficient fluorescence (Figure 3B',B'',F'',F'''). Individual embryos are immersed in agarose (Figure 3C,C') and mounted dorsally in an individual drop of agarose (Figure 3D,D'). All samples are mounted in a collective disc of agarose (Figure 3E–F'). When embryos are staged correctly, sufficiently fluorescent, and adequately mounted (Figure 3G), the samples will stay in the imaging frame during the timelapse allowing for the entire organ to be imaged (Figure 4G–G'', I–I''', Movie 1). Failure to accomplish any of these steps will result in a mounted embryo that is not an optimal sample for timelapse imaging. The slightest variation in the degree of rotation will have a dramatic effect on the direction of embryo growth during the timelapse. Sub-optimal rotations are shown in Figure 3, including an embryo that is over-rotated (Figure 3I), which will result in a more posterior timelapse, and an embryo that is under-rotated (Figure 3J) in which only the most anterior tissue can be observed. In addition to proper rotation during mounting, samples that are mounted with respect to the orientation of the frame are more likely to yield a successful timelapse (Figure 4G–G'', I–I''', Movie 1). Optimal samples are those that are oriented vertically on the dish, with the anterior-posterior axis in line with 12 and 6 o'clock on a clock face (Figure 3G). Sub-optimal samples are those that are not oriented on this axis, such as those that are horizontal or diagonal (Figure 3H). These samples will grow out of the imaging frame as the timelapse proceeds and cannot be used for further analysis (Figure 4H–H'', J–J''').
Acquiring a timelapse dataset that is suitable for future analysis
Embryos that are accurately injected, raised, and mounted will make for successful confocal imaged samples. Figure 4 shows an optimal sample for timelapse: there is even fluorescence, and the sample is 12 hpf. The z-stack for imaging is assigned such that the first slice is just dorsal to the optic vesicle, while the last slice leaves several slices beyond the ventral boundary of the 12 hpf optic vesicle (Figure 4G–G''). This bias toward the ventral side provides excess space for tissue growth in the ventral direction. These factors, when met, result in an optimal timelapse (Figure 4I–I''', Movie 1). A sub-optimal sample has mosaic or dim fluorescence, has already developed past 12 hpf (when optic cup morphogenesis is under way), or is positioned poorly in the Z-stack or the XY frame (Figure 4H–H''). When these criteria are not met, the timelapse will no longer capture the entire 3D volume of the tissue as it develops and cannot be used for further analysis (Figure 4J–J''').
Figure 1: Workflow of 4D timelapse imaging of zebrafish optic cup morphogenesis. (A) To fluorescently label subcellular structures of interest, synthesize the appropriate capped mRNAs. (B) Microinject mRNA(s) into zebrafish embryos at the 1-cell stage. (C) Embryos are mounted dorsally, or head-down for an inverted confocal microscope, at the optic vesicle stage, ~11 h post fertilization or 3 somite-stage. (D) Multiple embryos can be sequentially imaged during a single timelapse imaging session. Please click here to view a larger version of this figure.
Figure 2: A visual guide for microinjecting 1-cell zebrafish embryos. (A) Items to include in an injection kit (clockwise): medium sized box that can hold the entire kit with disposable nitrile gloves; a dish containing microinjection needles; forceps; an aliquot of mineral oil and cut up squares of parafilm; microloading tips; diluted RNA on ice; agarose injection mold; marker; roller/transfer pipette; and P10 pipette. (B) Microinjection set-up: a dissecting microscope next to a pico-injector that is connected to an external compressed gas source. A foot pedal and micromanipulator are attached to the pico-injector. The micromanipulator is equipped with a needle holder and positioned in place above the microscope stage. (C) An agarose injection mold containing six rows of grooves with a 90-degree angle on one side and a 45-degree angle on the other side. (D) The pico-injector front panel. The pressure display reads 7.8 PSI; this can be adjusted with the knob labeled Pinject. Beneath, there are pushbuttons to manually trigger pressure to inject, to change the injection time, or to clear, fill, or hold the liquid in the needle. The inject time is set to 08 (equivalent to 8 x 10 msec). An output hose is connected to Pout and is attached to the injection needle. The pressure meter source switch is set to Pinject while setting the injection pressure, and it can be switched to Pbalance to adjust the basal pressure applied to the needle when injections are not being made. The Pbalance regulator is next to the Pinject regulator. The power button is lit to indicate the machine is turned on. (E) Adult zebrafish are mated in small breeding tanks that contain a nested tank with a mesh bottom that separates adult fish from fertilized eggs and allows easy collection. Water level is lowered to mimic shallow water conditions and tank dividers are removed to initiate mating behavior. (F) The micropipette (needle) puller front panel: contains a display which shows the specific conditions used to pull needles. The pressure setting is P = 500, followed by the last date and time the program was edited, the program number, HEAT = 546, PULL = 130, VEL = 70, and TIME = 90. (G) One glass capillary is inserted into the micropipette (needle) puller and secured into place. Each programmed pull run results in two long tapered needles (red arrowheads). (H) The RNA dilution is backloaded into a needle; the phenol red dye allows easy visualization of the solution. (I) After breaking the tip of the needle, the bolus of RNA is measured using an eyepiece reticle on the dissecting scope. For this stereomicroscope, at 30x total magnification 6 hash marks is equal to 1 nL volume. (J) Fertilized eggs are loaded into the agarose injection mold and distributed along the troughs of the mold using a roller pipette. (K) The injection mold containing one-cell stage embryos is positioned under the microscope and embryos are injected sequentially. (L) The injection needle is inserted into each embryo targeting the single cell. (M) Once in the cell, the foot pedal is used to trigger a regulated amount of pressure and the release of 1 nL of RNA into the cell of the embryo (as visualized by phenol red). Scale bars: I = 0.1 mm; L, M = 0.5 mm. Please click here to view a larger version of this figure.
Figure 3: A visual guide for mounting embryos for imaging. (A) Mounting set up (from left to right): a heat block programmed to 42 °C, heating tubes of low-melt agarose; a roller pipette; a pair of forceps; an agarose coated dish containing dechorionated embryos; and a dissecting stereomicroscope connected to a metal halide fluorescent lamp. (B,B',B'') An 11 hpf embryo injected with EGFP-CAAX mRNA and mCherry-H2A mRNA, shown under brightfield, GFP fluorescence and mCherry fluorescence, respectively. (C,C') A glass pasteur pipette containing agarose and an embryo sitting in the tip; C' is a magnified view. (D,D') One embryo mounted in a droplet of low-melt agarose on a glass bottomed dish, seen both from the stage of the microscope and through the microscope eyepieces. (E,E') 12 embryos mounted in individual droplets of low-melt agarose on a glass bottomed dish, seen both from the stage of the microscope and through the microscope eyepieces. (F,F',F'',F''') All mounted embryos are overlaid with a complete layer of agarose to fill the bottom of the dish, seen both from the stage of the microscope and from the microscope eyepieces shown in bright field; F'' GFP fluorescence; and F''' mCherry fluorescence. (G) An optimal sample at 12 hpf is mounted dorsally and oriented vertically in line with 12 and 6 o'clock with both optic vesicles in the same plane. (H) A sub-optimal sample: although mounted dorsally and optic vesicles are in plane with each other, this sample is oriented on a diagonal axis and will grow out of the frame size as development proceeds. (I) A sub-optimal sample: this sample is over-rotated and not a dorsal mount, as a result, the anterior portion of the optic vesicle will not be captured in the timelapse. (J) A sub-optimal sample: this sample is under-rotated and not a dorsal mount, as a result the posterior portion of the optic vesicle will not be captured in the timelapse. Dotted lines indicate each optic vesicle. Scale bars: B = 0.1 mm; D' = 1.5 mm; E', F' = 2.5 mm; G = 0.1 mm. Please click here to view a larger version of this figure.
Figure 4: Setting up a multiple position timelapse and potential results. (A) Laser scanning confocal microscope. (B) Piezo Z-stage insert. (C) The bottom of a glass bottom dish containing embryos embedded in agarose is coated in immersion medium matching the refractive index of water. (D) A droplet of immersion medium is placed on the 40x W objective (long working distance). (E) The dish is held into place with the stage insert, E3 is added on top of the agarose layer, and the lid is secured with modeling clay. (F) Acquisition software settings: The desired laser lines are turned on from the drop-down menu. For embryos injected with EGFP-CAAX RNA and H2A-mCherry RNA, the Argon and DPSS 561-10 lasers are turned on. The red highlight indicates that the Argon laser is warming up. To locate the sample over the objective, the transmitted light is turned on through the microscope control panel. Both EGFP and mCherry are assigned to Track 1 (for simultaneous imaging) and the range of each detector is set. Here, the EGFP range is set to 494-545 nm, and the mCherry range is set to 598-679 nm. Under the Channels menu, laser power can be set. After the lasers have warmed up, the power can be increased up to 5.0, and gain (master) can be adjusted. The pinhole is set at 60.2, which is equal to 1.63 Airy Units or 1.6 µm section. Under the Acquisition menu, the frame size is set to 512 x 384, scan speed is 9.0, averaging is bidirectional, and zoom is set to 0.7. Under the Z-Stack menu, the first and last position in the Z-axis are set while the confocal is scanning. The interval (step size) is set to 2.1 µm. While choosing first and last Z-position, a standard number of 63 slices is generally maintained; this accommodates the overall growth of the eye. The "use piezo" option is selected. Under the Positions menu, each selected position is listed including an assigned number and X, Y, and Z position. There are additional buttons to control the number of embryos (separate positions) to image, including add, update, or remove. Under the Time Series menu, the cycle is set to 300 (the number of Z-stacks that will be acquired) and interval (time step) is set to 2.5 min. Once the settings are finalized, timelapse acquisition is initiated by pressing start. The software will show the slice of the Z-stack, the cycle, and the position that is currently scanning. When the timelapse is complete, the file is saved by clicking on the floppy disk icon in the Images and Documents panel. (G–J) Cell membranes (green) are labeled with EGFP-CAAX and cell nuclei (chromatin, magenta) are labeled with H2A-mCherry RNAs. (G,G',G'') An example of setting the first and last Z-slice for an optimally mounted sample. The first Z-slice (at the dorsal side) comes at the expense of dorsal ectoderm, while the last Z-slice (at the ventral side) is well below the optic vesicle, to accommodate its growth in the ventral direction. (H,H',H'') An example of setting the first and last Z-slice of a sub-optimal sample. The sample has weak mCherry fluorescence and it is mounted diagonally, such that the developing optic cup is unlikely to stay in frame for the duration of the timelapse. (I,I',I'',I''') An example of a timelapse from an optimal sample. Single slice images from the middle of the Z-stack are taken from the entire 63 slice volume at 4 time points (T value). Br, brain; NR, neural retina; RPE, retinal pigmented epithelium; Le, lens. (J,J',J'',J''') An example of a timelapse from a suboptimal sample. In this case, the sample moved out of the Z-plane and only an oblique portion of the anterior optic cup was captured. Scale bars: G, I = 50 µm. Please click here to view a larger version of this figure.
Movie 1: Timelapse of optic cup morphogenesis in an optimal wild type embryo. A dorsal view of a wild type embryo that is labeled with EGFP-CAAX (plasma membranes, green) and H2A.F/Z-mCherry (chromatin, magenta). The timelapse is from ~12-24 hpf and contains a single confocal section from an entire 4D dataset. Time interval is 2.5 min between z-stacks and is shown at 22.5 frames per second. Please click here to download this movie.
Here, we describe a protocol for in toto labeling and 4D timelapse imaging of optic cup morphogenesis. We step through the process of generating capped RNA encoding fluorescent proteins to mark different subcellular compartments; injecting zebrafish 1-cell embryos; embedding 11 hpf embryos in agarose for multiplexed imaging; and acquiring 4D datasets of multiple embryos for the duration of optic cup morphogenesis (12–24 hpf).
A myriad of questions can be answered with these information-dense datasets. 4D data can be visualized and quantitatively analyzed in a variety of ways. Although outside of the scope of this protocol, we include here some of our goals and standard applications as an example of the types of things that can be accomplished. Of course, quantitative image analysis methods are constantly being developed, and both commercially available and custom-built tools can be used. If one has not used such methods before, one should be prepared to work through some optimization to ensure that the acquired datasets are adequate for the quantitative analysis approach of choice.
Visualizing and quantitatively evaluating the 4D datasets can be challenging, due to the size of the files. The acquisition software can be used to separate the datasets into individual embryos, and ImageJ/Fiji can be used to convert confocal files from commercial formats to more standard tif stacks, in which each timepoint is saved as a separate file. This will decrease the file sizes and standardize the file formats. Individual optical sections from each timepoint can be assembled as a 2D (XY) timelapse using ImageJ/Fiji, enabling rapid 2D visualization and evaluation of the data. Movie 1 is an example of precisely this: a single optical section over time assembled as a timelapse of the optimal sample shown in Figure 4I–I’’’. From there, for 3D and 4D visualization, we commonly use FluoRender35,36, which is freely available but has specific graphics card requirements. Using FluoRender, one can rotate 3D-rendered data in any axis, visualize the dataset in 4D over time, generate cutaways in any plane, and save the rotations and visualizations as a movie or series of tif images.
In terms of quantitative analysis, there are numerous questions to be answered. We have developed software in-house to aid our own specific goals of understanding the cell behaviors underlying optic cup morphogenesis. Our program, LongTracker, uses the nuclear signal as a proxy for position to track cells13. With these data, we can determine when, where, and how cells move; how fast and how far cells move; and how frequently cells divide. In addition to our own software, there are multiple commercially available and custom-built options for 4D cell tracking. We have also developed the program LongAxis to carry out cell segmentation and quantify cell shape and organization within the neural retina37. The datasets input into LongAxis, however, are single Z-stacks, taken at a high resolution. A persistent challenge has been generating timelapse datasets with high enough resolution that cells can be segmented with confidence and their morphology extrapolated. One alternative is mosaic (sparse) labeling using a photoconvertible fluorophore such as Kaede for direct visualization of cell shape, as we and others have carried out in the developing eye8,11,13. This simplifies the cell segmentation problem, and cell shape and size can be readily quantified through 3D rendering in FluoRender.
Each step of this protocol was optimized specifically for our purposes. The specificity of this protocol results in several limitations: the protocol, as written, is not optimized for imaging other aspects of zebrafish eye development (such as retinal neurogenesis), other eye structures, other developmental stages, or other subcellular compartments. The orientation of embedding, the speed of imaging, and the labels are all designed to allow us to answer our biological questions. In order to image retinal neurogenesis, for example, the dorsal orientation of the embryo as described here may not allow for visualization of specific features of interest, and the speed of imaging may not be appropriate. Many aspects of the protocol can be adapted and modified for a variety of needs, depending on one’s specific interests and goals. First, using RNA injections makes the labeling process very flexible. Fluorescent protein fusion constructs can be used to label subcellular structures of interest, and RNA injection amount can be varied to optimize labeling. Based on our work with the photoconvertible fluorophore Kaede, RNA injections appear to support a burst of translation that is over by 12 hpf11,13. High levels of fluorescent protein expression from RNA injection could combat photobleaching, but such an approach does not support sustained expression of the fluorescent label of interest. If sustained expression is necessary, such as when imaging embryos at later stages, transgenic lines are an option, and constructing new lines in zebrafish is straightforward24.
Next, the protocol can be adapted for later stages of development. Because pigment may impede imaging at later stages, embryos can be treated with phenylthiourea (PTU) to inhibit pigment formation, or genetic mutants for pigment synthesis can be used. To prevent embryo twitching, tricaine can be added to the agarose and embryo media overlay solutions, and the percent agarose can be adjusted as necessary. As the eye grows, it may be necessary to change the mounting orientation; here, we mount embryos dorsally, but at later stages, it may make more sense to mount laterally or anteriorly, depending on the structure of interest. Because different processes occur over different spatial and temporal scales, one can also optimize the Z-step and time step of image acquisition. These features can really only be determined empirically for each lab’s needs.
Finally, this protocol was developed specifically for a laser scanning confocal microscope, with embryos embedded in a relatively high percentage of agarose at an early stage of eye development. If one is imaging at different times or different locations during eye development, this protocol will need to be adapted for the process of interest. Many different imaging approaches are currently possible, with more being developed by optical engineers. Each approach brings its own set of challenges, from different ways to embed and mount embryos for imaging, to different file sizes and formats. We outline considerations in the introduction to guide the optimization process, in which maximal spatial and temporal resolution are balanced with photobleaching, phototoxicity, and immense file sizes. We hope that these general principles, in addition to the practical information described above, will aid others in establishing timelapse imaging approaches to study the many open questions in eye development.
The authors have nothing to disclose.
We are grateful to past and present members of the Kwan Lab for work on timelapse approaches and discussions of this protocol. This work was supported by the NIH (R01 EY025378 and R01 EY025780 to KMK; F31 EY030758 to SL; and T32 GM007464 to MAC).
Delta TPG Dish 0.17mm clear | Bioptechs | 0420041500C | coverglass bottom for optical compatibility |
Disposable Pasteur Pipettes | VWR | 14672-608 | overall length 14.6 cm (53/4") |
Dumont #5, #55, or #5SF Forceps | Fine Science Tools | 11254-20 | For style #5: straight tip, 0.05 x 0.01 mm tip, inox, 11 cm long |
Flaming/Brown Micropipette Puller | Sutter | P-97 | |
Immersol W | Carl Zeiss Microscopy | 4449690000000 | immersion fluid for water-emission objectives, halogen-free, low fluorescence |
Microinjection Mold | Adaptive Science Tools | TU-1 | Six ramps, one 90 degree and one 45 degree beveled side. |
Microloader Tips | Eppendorf | 930001007 | Microloader, tip for filling glass microcapillaries, 0.5 – 20 µL |
mMessage mMachine SP6 Transcription Kit | Invitrogen | AM1340 | contains SP6 Enzyme Mix, 10X Reaction Buffer, 2XNTP⁄CAP Solution, GTP Solution, pTRI-Xef, TURBO DNase, Ammonium Acetate Stop Solution, Lithium Chloride Precipitation Solution, and Gel Loading Buffer and are all stored at –20°C. Nuclease-free Water may be stored at any temperature. |
Nikon SMZ645 Stereo Microscope | Nikon | SMZ645 | used for injecting embryos (see Fig. 2B) |
NotI-HF enzyme | NEB | R3189S | comes with Gel Loading Dye, Purple (6X) |
NuSieve GTG Agarose | Lonza | 50081 | fine resolution, low melt agarose |
Objective LD "C-Apochromat" 40x/1.1 W Korr M27 | Carl Zeiss Microscopy | 421867-9970-000 | |
Olympus SZX16 Stereo Microscope | Olympus | SZX2-ZB16 | used for screening, embedding embryos (see Fig. 3A) |
Phenol red solution | Sigma-Aldrich | P0290 | 0.5% in DPBS, sterile filtered, endotoxin tested, cell culture tested |
Pico-liter Microinjector | Harvard Apparatus | PLI-100 | Femtoliter to microliter injections; digital readouts for injection count, time, and pressure; contains 5 pressures including inject, balance, clear, fill, and hold |
Pipette Pump Pipettor | SP Bel-Art | F37898 | fits a disposable pasteur pipette, contains thumbwheel on side for aspirating or dispensing and plunger for quick emptying |
Premium Thin Wall Borosilicate Glass Capillaries | Warner Instruments | G100T-4 | 1.0 x 0.78 mm |
QIAquick PCR Purification Kit | Qiagen | 28106 | contains QIAquick Spin Columns, Buffers, Collection Tubes (2 ml) |
RNase-free H2O | Invitrogen | AM9906 | DNase-Free, Molecular Biology Grade, RNase-Free |
RNeasy Mini Kit | Qiagen | 74104 | contains RNeasy Mini Spin Columns, Collection Tubes (1.5 ml and 2 ml), RNase-free Reagents and Buffers |
Stage Attachment Z PIEZO WSB 500 | Carl Zeiss Microscopy | 432339-9000-000 | |
Stage Insert Z PIEZO WSB Universal | Carl Zeiss Microscopy | 432339-9030-000 | |
Zeiss LSM 880 with Airyscan | Carl Zeiss Microscopy | N/A | inverted Axio Observer microscope |
Zen Black 2.3 SP1 software | Carl Zeiss Microscopy | N/A | Zeiss Efficient Navigation (ZEN) controls all light microscope systems from Zeiss |