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ABSTRACT
We used the chicken, Gallus domesticus, to investigate limb development in
vertebrates. We observed unincubated eggs, the egg shell, and embryos that had been
incubated for 96, 72, 48, and 33 hours to identify important structures and understand the
timing of the appearance of these structures during normal development. We stained the
embryos and created whole mounts to preserve our embryos and identify additional
structures we were unable to see on the unstained embryo. We also attempted to
manipulate limb development by removing the AER and grafting beads of Fgf2 as well as
implanting Shh beads into the anterior marginal zone of intact embryos in an effort to
repeat Riddle’s 1993 experiment. The observations were valuable and we concluded that
the number of somites and size of limb buds increases with the longer incubation time.
We also concluded that the whole mount staining was an effective technique to visualize
additional structures in the embryo. The limb bud manipulation experiments were not as
successful since all of our embryos except one disintegrated in the KOH, but we were
able to conclude from that embryo that Fgf2 implantation does rescue the wildtype
phenotype as well as make important hypotheses about ways to improve the experiment
and be more successful.
INTRODUCTION
The chicken, Gallus domesticus, was used to study early development and limb
formation. The chick is an excellent model organism since it is easy to obtain and the
embryos are rather large compared to other model organisms. In addition, the chick is an
example of vertebrate development and can be readily compared to the development of
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other vertebrates. We investigated the chick to learn the methods of staging using the
Hamburger-Hamilton Staging Series, understand more about vertebrate anatomy, and
practice and perform various manipulations.
The chicken egg is similar to other birds and reptiles. The egg is an amniote egg
which contains its own supply of food and water which allows the animal to travel far
from a body of water to lay its eggs (Gilbert, 2006). There are four sacs within the
amniote egg: the yolk sac, the amnion, the allantois, and the chorion; these sacs store the
nutritional stores, contain the fluids surrounding the embryo, store the waste materials,
and interact with the outside environment respectively (Gilbert, 2006). The chicken egg
is considered a telolecithal egg because it has a large yolk mass that is located at one pole
(Houston, 2008).
The egg shell is a unique structure with dual functions; it is hard to protect the
delicate embryo from dehydration and other environmental stresses, yet it allows oxygen
to diffuse through its surface (Gilbert, 2006). The shell has three layers, the cuticular
membrane on the outside, spongy layer in the middle, and the mammilliary layer on the
inside (LM, Week 13). Just inside the shell is a thick white shell membrane whose
function is to provide support, prevent water loss, and inhibit microbial infection (LM,
Week 13).
Shell deposition occurs as the egg rotates through the oviduct (Houston, 2008).
During this rotation the yolk is shifted and the blastoderm slides off at a 45º angle; the
higher region of the blastoderm then becomes the posterior end of the embryo, where the
primitive streak begins (Gilbert, 2006). Another consequence of this rotation is the
placement of the lighter yolk cytoplasm under this posterior blastoderm; the lighter yolk
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is thought to contain maternal determinants (Houston, 2008). Thus, axis formation in the
chicken is determined by gravity during the egg’s rotation through the oviduct (Gilbert,
2006).
Chicken cleavage is discoidal and begins at the animal pole of the embryo; later
vertical and equatorial cleavages occur to further divide the blastoderm into a multi-
layered tissue (Gilbert, 2006). After egg laying, additional divisions of the blastoderm
occur to form the hypoblast and epiblast; only the epiblast forms the embryo while the
hypoblast functions in signaling to specify the epiblast cell migration (Gilbert, 2006).
Gastrulation begins when the epiblast cells ingress and enter the primitive streak; these
ingressing cells form the mesoderm and endoderm (Houston, 2008).
The streak progresses by a process called convergent extension where the
lengthening of the streak coincides with the reduction of its width (Gilbert, 2006). The
primitive streak is capped anteriorly by Hensen’s Node, analogous in function to the frog
Organizer (Gilbert, 2006). Once the node forms the streak regresses, and cells
differentiate based on their location in the streak (Houston, 2008). Tissues form
progressively from anterior-to-posterior along the streak and the notochord and somites
form anterior to the node (Houston, 2008). The nervous system is organized anterior-to-
posterior in the following order: prosencephalon, telencephalon + diencephalon,
mesencephalon, rhombencephalon, metencephalon + myelencyephalon, and spinal cord
(Houston, 2008).
We examined an unincubated egg to identify structures, particularly the yolk,
blastodisc, albumin (thin and thick), and chalazae. We also examined a piece of the shell
to identify its three layers. Every time we cracked the eggs—incubated or unincubated—
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we cracked them at the blunt end. This end has a pocket between the shell and shell
membrane called the air space; a crucial component to the chicken’s ability to hatch (LM,
Week 13). The chick first breaks the air space and inhales to fill its lungs; when it
exhales, the space fills with carbon dioxide and stimulates the chick to begin pipping, or
breaking the shell (LM, Week 13).
Once the chicken egg is laid it must be able to nourish the developing embryo
until hatching, which takes about 21 days (LM, Week 13). In order to ensure that our
embryos were oriented near the air space, eggs were incubated with their blunt side up;
the eggs can be incubated for varying lengths of time to observe embryos at different
time points (LM, Week 13). Egg viability decreases as incubation time increases, but
eggs can be incubated for less than 14 days at 80% humidity and 18.3ºC (LM, Week 13).
We observed embryos that had been incubated for 96, 72, 48, and 33 hours to identify
structures. Prior to our analysis we staged the embryos using the Hamburger-Hamilton
Staging Series. This formula defines parameters for the stages of the chick embryo based
on the size, presence, and location of characteristic structures.
We hypothesized that the 96 hour embryo would be more curled up than any of
the other time points, have larger limb buds and more distinguishable nervous system
features. In addition, we hypothesized that the curvature and limb bud size decrease with
less incubation time. Finally, we hypothesized that the number of somites would increase
with the longer incubation times, and that the whole mount staining would enable us to
identify additional structures that we could not see in the unstained embryo.
The chick is a popular organism to study for limb development and organogenesis
because their limbs can be identified and easily manipulated without damaging the rest of
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the embryo (LM, Week 14). The limb bud contains regions that have important signaling
functions, particularly the Apical Ectodermal Ridge (AER) and Zone of Polarizing
Activity (ZPA) (Houston, 2008). The AER runs along the anterior-posterior axis of the
distal edge of each limb bud, separates the dorsal and ventral surfaces, and is an
important requirement for the outgrowth of the limb buds (Gilbert, 2006). When the
AER is experimentally removed during limb development any undeveloped limb
structures fail to form; the AER promotes limb growth by maintaining underlying
mesenchymal cells in a continuously proliferative state (Gilbert, 2006).
The AER performs its function through the action of Fibroblast Growth Factors
(FGFs) which ultimately form a positive feedback loop between the underlying
mesenchyme and the AER; the underlying mesenchyme produces Fgf10 which induces
AER formation; the AER in turn secretes Fgf8 which stimulates the underlying
mesenchyme to go through mitosis and produce Fgf10 (Gilbert, 2006). We removed the
AER to examine its role in the developing limb bud. We hypothesized that embryos that
had their AERs removed would fail to produce distil limb structures. We also implanted
beads soaked with Fgf2 into the tip of limb buds after we removed the AER. We
hypothesized that the Fgf2 would rescue the limb development and those embryos with
the Fgf2 implant would have normal limb growth.
The Zone of Polarizing Activity (ZPA) is a region of mesoderm at the posterior
margin between the limb bud and body wall (Gilbert, 2006). When tissue from this
region was transplanted to the anterior margin of the limb bud digits formed in a mirror
image pattern (LM, Week 14). The ZPA’s activity is defined by the molecule sonic
hedgehog (Shh); Riddle et al transplanted Shh into the anterior margin of the chick limb
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bud and obtained the same mirror image phenotype as the ZPA transplantation
experiment (Gilbert, 2006). We repeated Riddle’s experiment and implanted a bead of
Shh into the anterior margin of the limb bud. We hypothesized that we would obtain the
same duplication of digits in a mirror image. In order to assess the phenotypes of the
implantation experiments we stained the embryos with Alcian blue, a cartilage stain.
MATERIALS AND METHODS
Observations
We obtained an unincubated egg and observed its features beginning with the
outside of the shell. We located the blunt end for future use and then cracked the egg into
a Petri dish to examine the internal structures. We noted these and then examined a piece
of the egg shell under the dissecting scope and noted the different layers we could
identify.
Next we obtained eggs that had been incubated for 96 hours and 72 hours. We
oriented the eggs with the blunt end facing up and cracked them using the blunt end of
our forceps. Once the eggs were cracked we removed the pieces to create a hole at the
top of each egg and peeled back the inner shell membranes to expose the embryos. We
observed the embryos under the dissecting scope and labeled the structures that were
visible.
We then obtained eggs that had been incubated for 48 and 33 hours. Since these
embryos were much smaller we injected India ink below them to create more contrast and
better view the structures. We obtained an insulin syringe of India ink in a 1:10 dilution
in Ringer’s and gently injected it into the egg by puncturing the vitelline membrane and
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injecting the ink just below the embryo. Once we could clearly see the embryo we
identified and labeled structures using the dissecting microscope.
Once we had finished looking at the embryos we collected them for whole mount
staining. We collected and stained two embryos at each time point (96, 72, 48, and 33
hours). For the 96 and 72 hour embryos we carefully removed them from the egg by
grabbing a blood vessel with the forceps and cutting away the extraembryonic
membranes. We slid the embryo spoon under the embryo and detached it from the
remaining extraembryonic membranes. We placed the embryos in a Petri dish of
Ringer’s solution and observed them again under the dissecting scope to identify
additional structures, and we staged them using the Hamburger-Hamilton staging series.
The 48 and 33 hour embryos were much smaller and had to be removed using a
different technique. We created a “lifesaver ring” by cutting a piece of filter paper into a
doughnut shape; then we carefully placed this ring onto the vitelline membrane of the
embryo inside the shell, the embryo was in the hole in the center of the ring. We used the
forceps to lift both the filter paper and underlying vitelline membrane and quickly cut the
extraembryonic membrane with scissors to remove the embryo. We placed these
embryos into a dish of Ringer’s, observed them to identify additional structures, and
staged them using the Hamburger-Hamilton staging series.
Fixing and Whole Mount Staining
The fixation was performed individually for each embryo. The embryo was
transferred to a fresh dish and a few drops of Carnoy’s Fix (3:1 100% ethanol: glacial
acetic acid) was placed on the embryo to flatten the extraembryonic membranes. After a
few minutes we added additional fixative to flood the tissue. A few minutes later we
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transferred the embryo to a small glass vial, filled it with fixative, and placed it on the
shaker for the remainder of the lab period. At the end of the lab period we replaced the
Carnoy’s with 70% ethanol and incubated it until the next lab period.
The next week we removed the 70% ethanol and replaced it with distilled water.
We let the embryos soak for 10 minutes and replaced the water with Mayer’s Carmalum
staining solution. We left the embryos in the Mayer’s Carmalum for 24 hours until the
embryos were a deep red. The stain was replaced with 70% ethanol and stored until the
following week. At that time we replaced the 70% ethanol with fresh 70% ethanol for 10
minutes. Next we washed the embryos twice in 95% ethanol for 10 minutes each, twice
in 100% ethanol for ten minutes each, and twice in Histoclear for 10 minutes each. We
made raised coverslip slides for all of our embryos by breaking coverslips and layering
them with clear nailpolish to build up a slide with a depression that was large enough to
hold the embryo. We transferred the embryos from the Histoclear onto the slides,
removed any remaining Histoclear, and covered them in Permount. We placed a
coverslip over the embryos and let them dry overnight before viewing them on the
dissecting microscope.
AER Removal and Implantation of Growth Factor Beads
Prior to any treatment we created growth factor beads by placing a drop of beads
into three Petri dishes and removing any remaining liquid. We then added PBS to one
dish, recombinant Fgf2 (dissolved in PBS at 100µg/ml) to another dish, and Shh
(dissolved in PBS 1mg/ml) to the third dish. The beads were incubated in the proteins for
30 minutes prior to implantation.
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While the beads were incubating we obtained an egg that had incubated for 72
hours and began practicing AER removal. For the removal procedures we made sure to
wash our tools and the egg shell with 70% ethanol before opening each egg to maintain a
sterile environment. We opened the eggs at the blunt end, removed the shell membrane
only, placed a drop of Ringer’s on the embryo to keep it hydrated, and staged the
embryos.
We located the limb buds—either the wing or leg bud depending on what was
easiest to locate—and used the tungsten needle to gently scrape off the AER of one limb.
We removed the AER of four embryos and these were used for the FGF treatments. We
implanted the Fgf2 beads into the end of the limb bud by making a slit in the tissue with
the tungsten needle and carefully inserting the bead with the forceps. We staged two
embryos at stage 17 and we implanted control beads soaked in PBS at the tip of the leg
buds. We staged one embryo at stage 18 and implanted an Fgf2 bead at the tip of the leg
bud and another embryo at stage 19 that we implanted an Fgf2 bead in the tip of the wing
bud.
We implanted the Shh beads at the anterior margin of the limb buds using the
same technique of creating a slit and inserting the bead using the forceps, but we left the
AER intact for these embryos. We staged two embryos, stage 18 and 19, and inserted
Shh beads into the anterior margin of the leg bud and wing bud respectively. We also
created a control by inserting a PBS bead into the anterior margin of the wing bud in an
embryo at stage 18. In addition to these treatments we created a control embryo which
was at stage 18 by not performing any treatment.
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We left all of the embryos in their shells for these treatments and added a few
drops of antibiotic following the manipulations. We covered the shells with parafilm and
incubated them at 38ºC for two days. After two days we removed the eggs from the
incubator, decapitated the embryos, and placed them into tubes with 95% ethanol until
the following lab period.
During the next lab period we replaced the 95% ethanol with Alcian blue, a
cartilage stain, [0.75mg/ml in acid alcohol (75% ethanol/25% acetic acid)] and incubated
the embryos overnight. The following day we washed them twice briefly in acid alcohol
and incubated them overnight in 100% ethanol. The next day we replaced the ethanol
with 0.5% KOH and kept the embryos in the KOH until they sunk. At that time we
added fresh KOH and incubated the embryos overnight. We returned the following day
to mount the embryos and view and analyze them. When we mounted the embryos it was
very difficult to clearly see the structures so we only mounted two and left the other six in
the tubes. We observed the embryos and identified the visible structures.
RESULTS
Observations
We identified several structures in the unincubated egg, Figure 1a. The blastodisc
was a light colored circle in the center of the mass of yolk, and the yolk that surrounded
the blastodisc was in a repeating pattern of light and dark regions. Immediately
surrounding the mass of yolk was a region of lightly colored thin albumin surrounded by
the darker thick albumin. The chalazae were visible as thin threads extending out of the
yolk.
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We examined the shell under the
dissecting microscope at 3X
magnification, Figure 1b. We could easily
identify the cuticular membrane, spongy
layer, and mammilliary layer. The spongy
layer was very bright white and did appear
to have a spongy texture. The other two
layers were slightly darker although they
were both shades of white. The shell
membrane was also white and visible
beneath these three layers.
We first viewed the embryo that was incubated for 96 hours inside the egg after
we had removed the shell at the blunt end, Figure 2a. The embryo was crescent-shaped
and had a web of red blood vessels extending from the ventricle to the yolk. The
ventricle, optic cup, and spinal cord were visible as dark structures while the rest of the
embryo was very lightly pigmented. The heart was visibly beating and we were able to
see the movement of blood through the vessels. From this orientation we were also able
to see a wing bud near the ventricle.
After removing the embryo from the shell it was much easier to identify
structures, Figure 2b, and once the embryo was in a Petri dish it was much more curved.
The embryo was viewed under the dissecting microscope at 1.5X magnification. The
somites were clearly visible along the dorsal surface and they extended from the base of
the head to the tail. Nervous system structures of the telencephalon, diencephalon,
b Figure 1. The unincubated egg viewed with the naked eye (a). The yolk is visible in the lower left region of the figure as a round structure with a repeating pattern of light and dark yolk. The blastodisc is the light circle in the center of the yolk. Surrounding the yolk is the thin albumin, which is then surrounded by the darker thick albumin. The chalazae are visible as thin threads extending from the side of the yolk. The shell (b) was viewed at 3X magnification on the dissecting scope and has three visible membranes: the cuticular membrane, spongy layer, and mammilliary layer. The spongy layer is much brighter white and has a spongy texture. Just below the three layers is the thin shell membrane.
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mesencephalon, and myelencephalon were visible in the head of the embryo beginning
near the eye and extending to the base of the head. The optic cup was easier to
distinguish as a ring and the lens was visible inside. Although the embryo was no longer
inside the egg, several blood vessels were still visible as well as the beating heart—it was
beating much slower now. The wing and leg buds were clearly visible and the leg buds
appeared to be slightly longer than the wing buds. Additionally, the allantois was visible
as a light grey sack-like structure extending from the ventral side of the embryo. Based
on the Hamburger-Hamilton Staging Series we determined this embryo was at Stage 23.
The 72 hour embryo was viewed in its shell at 0.7X magnification, Figure 2c. It
appeared to be quite smaller than the 96 hour embryo and was much more elongated with
just a slight bend near the anterior region. Inside the shell the ventricle and spinal cord
were clearly visible, and the tail bud was evident in this embryo. The heart was beating
very quickly and the blood vessels were visibly extending from the ventricle into the
yolk.
Once we removed the embryo from the egg some structures were much more
apparent, Figure 2d, and we viewed it at 1.5X magnification on the dissecting
microscope. The embryo was still more elongated than the 96 hour embryo, but there
was a slight curve at the posterior end and a larger bend at the anterior end. Somites were
visible in this embryo extending along the dorsal surface, but they did not extend as far
into the tail as the somites in the 96 hour embryo. Nervous system structures of the
diencephalon, mesencephalon, metencephalon, and myelencephalon were visible, but
they were not as distinct in this embryo as they were in the 96 hour embryo. Both wing
and leg buds were visible, however, they were much smaller and looked like small
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mounds of tissue at this point. The spinal cord was visible just ventral to the somites, and
the ventricle was visible and slowly beating. We could not see the lens or the optic cup at
this point. We staged this embryo at stage 19 based on the Hamburger-Hamilton Staging
Series.
The 48 hour embryo was much smaller and more difficult to see inside the egg,
Figure 2e. We used India Ink to better visualize the embryo and viewed it at 2.5X
magnification. The embryo was straight and elongated. There were two dark lines
extending from the anterior to the posterior end which defined the telencephalon,
diencephalon, mesencephalon, metencephalon, and optic cup boundaries. Surrounding
these dark lines was tissue of a very light pigmentation that defined the edges of the
embryo. At the posterior end was the open neural plate and primitive streak.
After removing the embryo from the shell we could see a more definite shape of
tissue, Figure 2f, and viewed it under the dissecting microscope at 2.5X magnification.
The same nervous system components were still visible, but we could also see somites at
the posterior end of the embryo, although there were fewer somites than either the 96 or
72 hour embryos. The head fold, lateral body fold, and lateral plate mesoderm were all
visible once the embryo was removed from the shell. This embryo was staged at stage 12
on the Hamburger-Hamilton Staging Series.
The 33 hour embryo was so small and lightly pigmented that we could not see it
in the egg to identify any structures, so we just identified structures once it was removed,
Figure 2g. The two lines that were visible in the 48 hour embryo were also visible,
although they were shorter and did not meet at the anterior end as they did in the older
embryo. This embryo was very small and we viewed it at 2.5X magnification under the
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Figure 2. The embryos were viewed under the dissecting scope. The 96 hour embryo was viewed at 0.7X inside the shell (a). The heart was beating and the optic cup, spinal cord, and ventricle were clearly visible along with limb buds. Once removed from the shell we viewed it at 1.5X, nervous system structures were visible as labeled, the embryo was more rounded, and somites were much more distinct (b). The limb buds were large and easy to see, and the allantois was distinct. The embryo was at stage 23. The 72 hour embryo was more elongated and smaller (c), and we viewed it at 0.7X inside the shell. The heart was beating and the ventricle and spinal cord were clear. Outside of the shell, at 1.5X, the embryo had visible somites and nervous system structures (d). The tail was slightly bent as was the anterior end. This embryo was at stage 19. The 48 hour embryo was much smaller and straight (e), viewed at 2.5X both inside and outside of the shell. In the shell, nervous system structures were apparent as defined by two thick dark lines extending from the anterior to the posterior end. Out of the shell, (f) the same nervous system structures were visible as well as somites in the posterior end. The head fold, lateral body fold, and lateral plate mesoderm were evident. This embryo was at stage 12. The 33 hour embryo was much smaller and could only be visualized outside of the shell (g). The anterior neuropore and open neural plate were distinguishing features, somites and nervous system structures were apparent. This embryo was at stage 9.
dissecting microscope. A couple of somites were barely visible, but the anterior
neuropore and the open neural plate were obvious. Visible nervous system structures
included the diencephalon, telencephalon, and mesencephalon. This embryo was staged
at stage 9 on the Hamburger-Hamilton Staging Series.
Whole Mount Staining
The whole mount staining made some structures of the embryo darker and easier to see.
We viewed the 96 hour embryo at 0.7X magnification on the dissecting scope, and it had
dark staining of the somites, ventricle, wing buds, and leg buds, Figure 3a. Also, the
amnion and allantois were clearly visible. The nervous system structures were easier to
distinguish; the mesencephalon was a round structure and the diencephalon and
a ba
c d e f g
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metencephalon were visible on either side of it. The optic cup was a dark circular
structure surrounding the lighter lens
The 72 hour embryo, Figure 3b, was viewed at 0.7X magnification on the
dissecting microscope. The telencephalon, mesencephalon, and metenchephalon were
clearly distinguishable as individual structures. The somites were not as easy to
distinguish and appeared as a dark line along the dorsal side of the embryo. The wing
buds and leg buds were darkly stained and easy to see. The optic cup was visible,
although smaller than the 96 hour embryo, and the lighter lens was visible inside. Both
the 96 and 72 hour embryos had several structures on their ventral surface that all
appeared to be on top of each other. Although the staining seemed to have made these
more apparent, it was difficult to distinguish them because it looked like they were piled
on each other. These structures included the atrium, pharyngeal pouch, and aortic arch.
The 48 hour embryo, Figure 3c, appears to have been damaged during the
processing as the head is slightly torn apart. This embryo was viewed at 2.5X
magnification on the dissecting scope. Several nervous system structures were more
easily distinguished with the staining including the telencephalon, diencephalon,
mesencephalon, metencephalon, and somites. Also, the infundibulum, and ventricle were
apparent after the staining. The somites were much clearer and easy to distinguish.
The 33 hour embryo also was damaged during processing, Figure 3d. We viewed
it at 2.5X magnification, but the tissue was folded over the embryo so the whole thing
was not visible in the whole mount. The somites and the dark lines that defined the
nervous system were slightly visible, but it was impossible to determine which nervous
system structures we could see.
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AER Removal and Growth Factor Implants
When we returned to analyze our limb bud experiments nearly all of the embryos
had disintegrated in the KOH and there was nothing to see. The only one we could see
was the embryo that was at Stage 17 when we performed the treatments and had Fgf2
implanted in the leg bud, Figure 4a. The embryo had definite blue staining of all the
structures of the spinal column and limbs. There appeared to be two fully formed legs
with blue staining through their length, both legs were symmetrical and identical. There
were also two fully formed wings with additional blue staining where the bones would
develop.
Figure 4 shows the expected outcomes of the limb bud experiment. The AER
removal was expected to result in the embryo’s failure to develop distal limb structures,
Figure 4d. The Fgf2 implantation was expected to result in the rescue of the wildtype
phenotype, Figure 4b. The Shh implantation was expected to give additional ectopic
digits in a mirror image to the normal digits, Figure 4c.
Figure 3. The whole mount staining embryos as viewed under the dissecting microscope. The 96 hour embryo was viewed at 0.7X and nervous system structures as well as the lens, ventricle, amnion, allantois, and limb buds were visible (a). The 72 hour embryo was also viewed at 0.7X magnification and the nervous system structures as well as the somites, lens, ventricle, limb buds and spinal cord were all visible (b), The 48 hour embryo, (c) was viewed at 2.5X magnification and seemed to have been damaged during processing as the head was torn apart, but the nervous system structures, somites, ventricle, and lateral plate mesoderm were all visible. The 33 hour embryo was very small (d) and also appeared to have been damaged as it looked like there was a fold of tissue covering the embryo. This embryo was also viewed at 2.5X magnification. It was difficult to distinguish any structures, but the somites and some nervous system tissue were visible.
a b c d
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DISCUSSION
Overall the chick experiments were helpful in visualizing development of a model
organism, especially concerning the development of the limbs. The observations were
valuable and the whole mount staining was successful. We hypothesized that the 96 hour
embryo would be more curled up than any of the other time points, and the limb buds
would be larger. Our observations support our hypothesis; the 96 hour embryo was much
more curled up than any of the other embryos, and the younger embryos are more
elongated than the older ones. The limb buds were visible and larger on the 96 hour
embryo than the 72 hour embryo, whose limb buds were small mounds of tissue. The
limb buds were not visible at all on the 48 or 33 hour embryos, supporting our
hypothesis.
Figure 4. Growth factor bead implants. The only limb bud experiment that could be analyzed was the Fgf2 implant into the leg bud (a). The phenotype was rescued as the embryo developed 2 legs with proximal and distal structures. The expected results for the Fgf2 grafting experiment (b) are to have the phenotype rescued (image modified from Dr. Houston’s Lecture notes, 4/28/08). The expected results for the Shh grafting experiment were a duplication of the digits in a mirror image (c) (image modified from Dr. Houston’s Lecture notes, 4/28/08). The expected results for the removal of the AER (d) were a failure to form distal limb structures (image modified from Dr. Houston’s Lecture notes, 4/28/08).
a b
c d
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We also hypothesized that the nervous system would be more distinguishable in
the 96 hour embryo. Our results offer some support of this hypothesis. The nervous
system structures were more apparent and much more developed in the 96 hour embryo
than in the 48 or 33 hour embryos, however, the 72 hour embryo also had a very
developed and defined nervous system, comparable to the 96 hour embryo. Although we
did not count an exact number, it was evident by observation that the number of somites
each embryo had did increase with age, supporting our hypothesis, and the whole mount
staining did, in fact, allow us to better visualize structures on the embryos.
One draw back to the whole mount staining was that we had some structures end
up overlapping others once the embryos were mounted. These were structures that we
were unable to see in the unstained embryo, so the staining was beneficial in that it
allowed us to see structures we would otherwise be unable to see. After mounting them,
however, we could not distinguish these structures, and the technique was pointless. In
the future it may be beneficial to visualize the stained embryos before and after mounting
to identify structures that could potentially get squished when the embryos are mounted.
Unfortunately, we were only able to analyze the phenotype of one of our limb bud
experiments as the rest of the embryos disintegrated in the KOH. The only embryo we
could analyze was the embryo with the Fgf2 implant in the leg bud. This embryo had 2
legs that were equal in length and developed structures, so we could support our
hypothesis that Fgf2 rescues the phenotype of the embryos allowing them to produce
distal limb structures after the removal of the AER. However, since our control had also
disintegrated, we cannot definitively state that the AER was effectively removed. If the
AER were not removed, the phenotype we observed would have been a result of the
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normal function of the AER, not the implanted Fgf2. We could not confirm or reject our
hypothesis that AER removal results in the embryo’s failure to form distal limb
structures, nor could we confirm or reject our hypothesis that Shh implants will result in
ectopic digits in a mirror image.
When we changed the KOH the embryos were visible and the blue dye had
clearly stained the cartilage of the developing embryos, however, when we returned after
allowing the embryos to incubate in the KOH overnight, all of the embryos had
disintegrated except one. The disintegration could have been due to the KOH. Although
we followed the lab manual, the KOH may have been too strong for the embryos, or 24
hours may have been too long to wait before analyzing the results. In retrospect we
should have visualized the embryos the same day we added the KOH so we could have
more data to analyze the limb bud phenotypes.
These experiments allowed us to understand some of the molecular mechanisms
involved in limb development in vertebrates. Although our results do not allow us to
address the validity of our hypotheses, past experiments suggest that our hypotheses are,
in fact, accurate. Riddle performed the Shh grafting experiment and was able to show
mirror image digit duplication (Gilbert, 2006). Also, Fallon performed a similar
experiment to our Fgf2 implants and was able to show that the implantation of the Fgf
beads rescued the wildtype phenotype (LM, Week 14).
Additional experiments could include repeating the limb bud experiments and
Alcian blue staining, but analyzing the results when the KOH is added instead of one day
later. Also, it would be interesting to implant the Fgf2 bead on the top or bottom of the
limb bud instead of at the tip and see if the phenotype differs since the protein is in a
20
different location. By learning the mechanism behind limb development in a vertebrate
model organism, we can make hypotheses about similar mechanisms in humans.
Understanding human mechanisms for limb growth could have some important medical
consequences; by familiarizing ourselves with the natural process of limb development,
we become closer to developing a process to regenerate human limbs after amputation.
REFERENCES Developmental Biology 002:135 Lab Manual, Spring 2008
Gilbert, S.F. 2006. Developmental Biology 8th Edition. Sinauer Associates Inc,
Sunderland, MD.
Hamburger V, Hamilton H. A series of normal stages in the development of the chick
embryo (1992). Developmental Dynamics 195:231-272.
Houston, D. Lecture Notes: April 15 and 22, 2008.
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