Here, we present an organotypic culturing protocol to grow embryonic chicken organs in vitro. Using this method, the development of embryonic chicken tissue can be studied, while maintaining a high degree of control over the culture environment.
The embryonic chicken is commonly used as a reliable model organism for vertebrate development. Its accessibility and short incubation period makes it ideal for experimentation. Currently, the study of these developmental pathways in the chicken embryo is conducted by applying inhibitors and drugs at localized sites and at low concentrations using a variety of methods. In vitro tissue culturing is a technique that enables the study of tissues separated from the host organism, while simultaneously bypassing many of the physical limitations present when working with whole embryos, such as the susceptibility of embryos to high doses of potentially lethal chemicals. Here, we present an organotypic culturing protocol for culturing the embryonic chicken half head in vitro, which presents new opportunities for the examination of developmental processes beyond the currently established methods.
The embryonic chicken (Gallus gallus) is an excellent model organism commonly used in the field of biology. Its incubation period is roughly 21 days and many eggs can be incubated simultaneously, making experimentation quick and efficient. Perhaps most importantly, the embryo is also easily manipulated, enabling the extensive study of key developmental processes and of the genes and proteins that drive these processes.
The embryonic chicken eye is a complex organ that develops via the interaction of a number of different tissues similar to many other body systems. This method enables the study of the development of these tissues, particularly at advanced stages of development. For example, the multi-layered retina may be of particular interest to those studying the development of the nervous system. Alternative methods that enable the study of other eye tissues such as the cornea, the vitreal body, the lens, the sclera, and the eyelids are of benefit to researchers. The chicken embryonic eye also contains a series of flat bones, the scleral ossicles, which can be used as a model for the study of intramembranous bone induction and ossification in vertebrates1.
Currently, there are a number of methods used to study embryonic development. Microinjections of inhibitory antibodies or other inhibitory molecules2,3, surgically implanted microbeads soaked in inhibitor4, and electroporation5 are all methods that can be used to downregulate genes or proteins of interest in an embryo. Similar methods are used to upregulate proteins. These methods are not without their limitations. For example, when using chemicals to alter the embryonic development, the lethal effects on the embryo must be evaluated, and this limits the use of the aforementioned methods to localized sites of application at doses low enough to ensure the survivability of the embryo.
In vitro tissue culturing has been used in a wide range of organisms to study development and can be used to bypass some of the aforementioned limitations. For example, the femora6, feather buds7,8, and limbs9 of the chicken have all been studied using tissue culturing methods, as have the testes of the mouse10 and the roots and stems of plants11. These methods grant scientists a high degree of control over the tissue development, such as the ability to fluctuate the temperature and alter the nutrient availability. The isolation of the tissue from the whole embryo also makes it far less susceptible to the lethal effects of chemicals, thus enabling manipulation studies on a global scale at higher concentrations. Another notable advantage of in vitro culturing is the preservation of the tissue's cellular environment; the arrangement of tissues remains relatively unchanged, making it possible to study the interactions between different tissue types9. Thus, in vitro culturing opens doors to additional experimental approaches not available in in vivo or in ovo models.
Currently, studying the development of the embryonic chicken eye using chemicals is particularly challenging. A number of extraembryonic membranes cover the embryo, making it difficult to apply microbeads or chemicals; the embryo is also very active within the egg as it gets older, further complicating an already difficult method. This protocol enables easy access to the eye and its surrounding tissues, eliminating these barriers, while also providing new opportunities to examine the developmental processes within the eye. This protocol was established to study the induction of the scleral ossicles within the embryonic eye.
NOTE: For embryo stages, utilize the Hamburger and Hamilton12 (HH) staging table.
1. Embryo Incubation
2. Preparation and Sterilization of the Materials
3. Embryo Preparation
NOTE: From this point onwards, wear a protective dust face mask to avoid contaminating the cultures. A bacterial or fungal infection will ruin the culture and there is a risk of it spreading quickly to all cultures in the incubator.
4. Culture Setup
5. Culture Maintenance
6. Fixation
Using this method, an embryonic chicken eye can be cultured from day 8 of its development (HH34) in vitro for 4 days. Four days of in ovo development corresponds to HH38.
This culturing method supports the development of feather buds surrounding the eye and on the eyelids (Figure 1B). These feather buds are not present in ovo at HH34 prior to the culturing (Figure 1A), indicating that feather bud development is initiated during the culturing period, as it is in ovo13 (Figure 1C). The eyelids and nictitating membrane grow to cover the eye during the culturing (Figure 1B). The eyelids appear more mature after the in vitro culturing than at the start of the culturing at HH34 (Figure 1A) but are less developed than at HH38 (Figure 1C). This data shows that the key aspects of embryonic development are supported, albeit with some small delay.
After culturing, we dissected the anterior portion of the eye to show the conjunctival papillae (a transient ring of 13 – 14 epithelial protrusions), which act as yet another landmark indicating that the developmental events are supported in culture. Typically, these papillae are fully formed by HH34 (Figure 1D), and degenerate over time as they induce skeletogenic condensations in the underlying mesenchyme; they disappear by HH381 (Figure 1F). Our data shows that this degeneration occurs in vitro (Figure 1E) and is preceded by a flattening of the papillae following the in ovo pattern of development. Unstained condensations, however, are not visible in the in vitro samples, unlike at HH38 (Figure 1F). We used alkaline phosphatase staining, which detects early osteoblast activity to further assess the induction of these condensations14; this process occurs alongside the degeneration of the conjunctival papillae in ovo. The induction of the skeletogenic condensations, which begins at HH34 (Figure 1G), does proceed in vitro as evidenced by the alkaline phosphatase staining (Figure 1H). These condensations, however, are not as large as they are at HH3814 (Figure 1I), again indicating that there is a small delay in the development. We estimate that the 4 days of culturing represent approximately 2 days of embryonic development; hence a delay of about 50%. Collectively, these results show that the induction and development of the intramembranous bones, the scleral condensations, is supported in vitro and that the developmental processes such as eyelid growth and feather bud formation proceed in vitro.
Figure 1. Morphological characteristics of in vitro cultured eyes, HH34 eyes, and HH38 eyes. A – F are unstained and G – I are stained for the alkaline phosphatase (AP) enzyme to distinguish active osteoblasts within the scleral condensations. A, D, and G show eyes at the start of the culturing period at HH34. B, E, and H show eyes after 4 days of in vitro culturing. C, F, and I show eyes after 4 days of in ovo culturing, at HH38. All eyes are viewed laterally. (A) The conjunctival papillae are visible in a ring surrounding the cornea. An asterisk indicates papilla #12, the first one to form. The arrow indicates the edge of the eyelid in the nasal region of the eye. (B) The conjunctival papillae have flattened and begun to degenerate. The arrow indicates a growing feather bud. (C) The conjunctival papillae have completely degenerated and are covered by eyelids and the nictitating membrane. The open arrow indicates the edge of the eyelid in the nasal region of the eye. The solid arrow indicates a growing feather bud. (D) A dissected anterior portion of the HH34 eye. The asterisk indicates papilla #12. (E) A dissected anterior portion of an HH34+4 in vitro eye showing flattened papillae. The papillae in the temporal region (solid arrow) have begun to degenerate; these are the oldest papillae in the ring. (F) A dissected anterior portion of an HH38 eye with the eyelids and nictitating membranes removed, showing that all papillae have degenerated. The dashed lines outline the position of two adjacent unstained condensations. (G) A HH34 eye stained for AP showing very small skeletogenic condensations indicative of the start of induction. (H) A HH34+4 eye stained for AP showing enlarged, growing skeletogenic condensations. (I) A HH38 eye stained for AP showing large skeletogenic condensations. All scale bars are 1 mm. Please click here to view a larger version of this figure.
This protocol makes use of established tissue culturing techniques to achieve the growth of a chicken eye from embryonic day 8 (HH34) in vitro for 4 days. This grid-culturing method was originally described by Trowell15. We optimized a protocol from Pinto and Hall's 1991 study16 utilizing a semi-porous membrane with the grid to study inductive signals between separated tissue layers of the embryonic chicken eye15. Using this method, Roach cultured 14-day old chicken femur6. This method has also proven effective in culturing mouse tissues6,17. The use of the filter paper is critical to the success of the protocol as it helps the tissue to take up nutrients from the medium effectively without saturating or submersing the tissue.
Nutrient medium at a proper pH is critical for optimal growth. The medium should be at or near the physiological pH, and the use of phenol red in the medium as an indicator provides an advantage in that pH changes can be easily detected. Serum-free media can be used, and changing the media daily is not necessary and does not affect the results. The protocol was developed using a commercially available medium (see Table of Materials), which contains high levels of amino acids and glucose; no further supplementation of the media is needed. Most occurrences of poor tissue growth using this protocol occurred when the nutrient media was either at an improper pH or contaminated.
The eye can survive and grow for up to 4 days in vitro, starting at embryonic day 8, when the protocol is performed under optimal conditions. One limitation of this protocol is that the survivability is impacted beyond 4 days of culturing. Thus, the developmental processes that span a longer timeframe will require modifications to the protocol. Another limitation of the protocol is the absence of an active blood flow and vascularization. Blood vessels are important for many developmental processes, not just for the delivery of nutrients to the tissue9, which is achieved in vitro via capillary action through the filter paper on which the tissue rests.
This protocol can be used to study the development of entire organs or large pieces of tissue in vitro. Vertebrate organs are highly complex, and their development is regulated by many distinct spatiotemporal patterns. The study of these developmental pathways relies on the ability to manipulate the signals that regulate them. Current methods limit this manipulation to relatively small, localized areas, and to low enough concentrations to avoid embryonic lethality. For example, the ex ovo method of culturing the entire chicken embryo in culture18 or the method to window eggs19 to conduct manipulations are limited in that either the entire embryo must be treated, which can cause lethality, or only a small localized area is treated. The advantage of the protocol presented here is that the effect of these signals can be studied on entire organs or large amounts of tissue, without affecting the embryonic viability. This protocol does not require any supplementation with carbon dioxide as in earlier protocols15. The delay in development that we observed is an advantage in that rapid developmental processes can be studied.
The authors have nothing to disclose.
The authors would like to thank Gregory Haller (Mount Saint Vincent University) for his preliminary work in the development of the protocol. The authors would also like to thank Nicholas Jones (Mount Saint Vincent University) for his technical expertise and assistance with the filming and production of the audio/visual portion of the manuscript. Daniel Andrews was supported by funding from MSVU and the Natural Sciences and Engineering Research Council of Canada (NSERC) via an Undergraduate Student Research Award. Tamara A. Franz-Odendaal is supported by an NSERC Discovery Grant.
35 mm cell culture petri dishes | Corning | 353001 | easy grip tissue culture dish, polystyrene, non-pyrogenic |
100 mm cell culture petri dishes | Corning | 353003 | tissue culture dish, polystyrene, non-pyrogenic |
paper tissue | Kimtech | 34155 | Kimtech Science Brand Task Wipers, 280 per carton |
wire mesh | n/a | n/a | stainless steel wire mesh (grid size 0.7 mm) |
disposable glass pipettes | VWR | 14673-010 | Borosilicate glass disposable 5 3/4" |
nutrient medium | Gibco | 12591-038 | Fitton-Jackson Modification, [+] L-glutamine with phenol red (BGJB) |
penicillin-streptomycin | Sigma-Aldrich | P4458 | 10000 units/mL penicillin streptomycin solution stabilised |
filter paper | Whatman | 1454 090 | semi-porous filter paper 90mm |
fertilized chicken eggs | Dalhousie University Agricultural College | n/a | can be obtained from local farms |
sodium chloride (NaCl) | EMD | SX0420-3 | sodium chloride crystals, reagent grade |
1 L glass bottle | VWR | 89000-240 | 1 L pyrex autoclavable glass bottle |
ethanol | Fisher Scientific | BP82011 | 70% molecular biology grade |
tupperware containers | n/a | n/a | store-bought and sterilized with EtOH |
disposable razor blades | VWR | 55411-050 | single edge industrial razor blades (surgical carbon steel) |
plastic spoons | n/a | n/a | store-bought and sterilized with EtOH |
dust mask | 3M | n/a | 3M 8500 Comfort Mask |
paraformaldehyde | Sigma-Aldrich | P6148 | paraformaldehyde, reagent grade, crystalline |
neutral-buffered formalin | Fisher Scientific | 72210 | 10% neutral buffered formalin |
phosphate buffered saline (PBS) | n/a | n/a | 10X phosphate buffered saline pH 7.4 (137mM NaCl, 2.5mM KCl, 4.3mM Na2HPO4, 1.4mM KH2PO4) |
15 ml falcon tubes | VWR | 21008-216 | presterilized centrifuge tubes |
forceps | FST | n/a | fine forceps |
chick saline | n/a | n/a | 0.85% NaCl |
tinfoil | n/a | n/a | store-bought |
paper towel | n/a | n/a | store-bought |