Platyhelminthes *Part 1

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Platyhelminthes –Part 1-Freeliving forms.
Background information
Flatworms, or Platyhelminthes, are bilaterally symmetrical metazoans with three tissue
layers. Unlike most triploblastic animals, they are compact and have no coelom (body cavity)
surrounding the viscera and no hemal system. The gut, if present, has a single opening to the
exterior. Osmoregulation and fluid regulation is accomplished with protonephridia. The end
product of nitrogen metabolism is ammonia, which is lost by diffusion across the body surface.
Gas exchange is by diffusion, which is facilitated by small body size and flattening. Nutrients
are delivered to tissues by diffusion from the gut, whereas oxygen diffuses across the body
surface. An anterior brain with associated concentration of sense organs is present, as expected
of bilaterians. Light-sensitive pigment-cup ocelli occur in various positions on the body.
Flatworms are complex animals with elaborate hermaphroditic reproductive systems.
Fertilization is internal with copulation. Most are hermaphroditic. They may be free-living or
parasitic.
Dugesia tigrina is one of several species of freshwater triclad flatworms collectively
known as "planarians".
Activities:
Four groups will conduct behavioral experiments while the rest of the class examines
internal and external anatomy. The groups running the behavioral experiments need to
be respectful of classmates and inform them when they are done, so the others have time
to conduct the behavioral studies.
1. Behavioral studies---Chemotaxis: Use brown or black freshwater planaria.. Living
worms can be picked up with a plastic pipette but they must be ejected quickly or they will
attach to its wall using their adhesive glands. They adhere tenaciously and are difficult to
remove when this happens.
We will use a training T maize or a habitat maze to investigate chemotaxis in planaria. This is
the first group to exhibit fairly complex sensory structures. In the laboratory, you will have
available liver and egg yolk and some commercial preparations. You can do a competitive
experiment or simply place one of the stimuli at the end of one of trails and see if the
planarians given a choice can detect the stimulus, presumably following the chemical
gradient caused by food dissolving in water and find either the egg yolk or liver. If you are
fortunate, you will see the worm protrude its pharynx and feed. The sight is impressive and the
length of the pharynx will may startle you. You may also want to investigate what other
classes have dubbed the “social influence”. They have placed two to three planarians in
one well, none in the other and found that other planarians are particularly “good” at
finding other planarians. Do your results substantiate their findings? Do the other
planarians have to be feeding or just hanging out?
Get approval of your experimental plan before proceeding.
If the class wishes they can try to “train” some planarians to always take one fork. One
group can determine their preferences and then turn their fast learners over to another group to
see if they can train them. Some specimens of planarians are surprisingly fast learners,
refusing after a few trials to try the other fork, even after the food has been removed and both
should be providing no stimulus. Alive in the literature (1998 article) is still the suggestion that
feeding such “smart” or trained worms to others results in them learning faster. It is claimed
that when trained planaria are sliced in half and allowed to regenerate, both the head- and tailderived worms demonstrate significant recall of their original training. They are the choice of
training models in some college psychology classes. They habituate to puffs of air and beams
of light (disliking intensely both stimuli). This is also the way they now are “trained” to go to
the left or right in training maize.
2. Living Specimens: anatomy and locomotion. Use very light brown, or white freshwater
planaria if available. If both are available each pair of students at a table should work
with a different species.
Place a living worm in a small pool of water on a small petri dish (Restrict movement by
restricting the water available or you will not be able to follow your worms). Living worms can
be picked up with a plastic pipette but they must be ejected quickly or they will attach to its
wall using their adhesive glands. They adhere tenaciously and are difficult to remove when this
happens.
a. Observe the worm with the dissecting microscope. Watch it as it moves across the slide.
Time the movement and divide the distanced moved by body length.
The major locomotory force is produced by the cilia of the ventral epidermis but muscular
activity also plays a role in locomotion, especially in making turning movements. Manipulate
the worm with a tiny needle to encourage it to change directions. Try to discover the
contributions of the musculature to this maneuver and think about which muscles would be
involved in making a turn. Freshwater specimens provided are poor, ineffective swimmers and
often just coil up and drop until they find a substrate upon which they can move.
b. Make a movie of a planarian moving. In your journal, describe planarian movement.
c. You should try to feed your worms. In light colored specimens this will make the digestive
tract obvious. Freshwater planaria will prefer fresh beefheart, liver or fish food flakes.
Photograph or make a movie of your planarian feeding.
d. Push the worm if it stops gently with the needle and look for evidence of adhesive
ability. Where do the adhesive cells seem to be located?
e. Observe the animal with transmitted light and look for the intestine and its cecae after
it is feed. You will have to add water to the dish to observe feeding. Take of a photograph
of an animal that has recently fed and label its digestive tract. If the animal does not feed,
try photographing the cilia. Transmitted light against a black background may also
enable you to see cilia better.
f. Your notebook should also contain a comparison (accompanied by photographs) of the
marine and freshwater species if available. Our marine species when available is a small
white flatworm that lives on horseshoe crabs. The Limulus flatworm (Bdelloura) is found
around the book gills and leg joints of crabs, especially on older females that have not shed for
a long time How is it's body modified for life attached to another organism.?
Bdelloura candida (Tricladida), ectocommensal on the king crab, Limulus. Complete digestive
and male systems are shown on the bottom half of the animal, female systems on top half.
HIGH MAGNIFICATION:
Working in pairs place a freshwater planarian on a slide and position a cover slip over the
worm. Place the slide on the compound or inverted microscope. The weight of the cover
slip will squeeze the worm thereby immobilizing it and making it thin enough to see some
internal structure. Do not use 400X on these slides.
Focus, with 100X, on the edge of the head, reduce the light, and look for evidence of
beating cilia. Most of the animal's cilia are ventral and thus difficult to see in a whole mount
but the head bears cilia associated with chemosensory receptors on the auricles and their
activity is obvious. The name "turbellaria" means "little disturbance" and is a reference to the
movement of water caused by the cilia of the auricles.
Increase the light so you can illuminate some of the interior. At 100X you may be
able to see gut diverticula, especially if the animal has eaten recently. The pharynx is the
conspicuous, long, pale area in the center of the body. If the animal is squeezed
sufficiently, you may see the pharynx clearly and you may even see the opening at its
posterior end. The pharynx will probably move about in the pharyngeal chamber and
may increase in length.
Use the diagram below to help you identify important structures. In most specimens you
will be able to see parts of the digestive tract, eyespots and pharynx. Other structures will
not generally be visible but they are included in the diagram so you can see their relationship to
the visible structure.
3. REGENERATION OF PLANARIA: Use only brown or black freshwater planaria
Freahwater planatians typically reproduce asexually by a type of fission in which the worm
divides into two fragments without prior differentiation of new parts. Transverse cleavage just
posterior to the pharynx divides the worm into an anterior, nearly normal, worm with head,
mouth, pharynx and most of the gut, and an incomplete, headless posterior mass of tissues,
which must replace its missing parts.
Following division, the anterior end behaves normally but the posterior end remains immobile
until regeneration is complete and the missing parts replaced. You are not likely to see fission
occurring but, if your laboratory maintains populations in aquaria, it is quite possible that you
will see these headless lumps stuck on the walls of the aquaria. In the experiment you have
done, if you cut the worm into two pieces at least, you were initiating a natural process,
although probably not at the scheduled desired by your worm
In spite of natural process, scientists were amazed to learn that a planarian often divided into 5
pieces or more, still retains the ability to regenerate a whole animal from most of the segments.
The regenerative abilities depend on neoblasts which are scattered throughout the planatian
body.
Neoblasts apparently remain in an unspecialized, stem cell state, which enables them to
differentiate into any cell type. Wherever planaria are cut, the neoblasts migrate to the site and
form a blastema by themselves.
As classic as this experiment appears, geneticists are again turning to planaria to provide
answers about development despite the fact that neoblasts are unique to this phylum. The new
approach is to slip genes into the neoblasts or mutate existing genes, and then add the cells
to worms whose own neoblasts have been destroyed with radiation. When such worms
regenerate, any new cells should derive from the genetically engineered neoblasts. The
object is to look at which genes are active in these organisms during regeneration and
even if the cells involved are different, similar genes may be involved in wound healing or
development in some way in other organisms.
a. Your task as a class is to design an experiment that will test whether gradients occur in
regenerative abilities. Note that the gradient can be head to tail, the reverse or actually
initiated from mid body with regeneration decreasing in efficiency as one moves from mid
body to head or tail. Some pairs need to divide the animal into threes. The class may wish to
discuss what other experimental manipulations will tell them about the gradient of regeneration.
Procedure: Prepare a divided Petri dish to receive your segments. Mark each section
with a different letter. As one partner places segments in the dish, another should keep
tract of which section of the dish, a particular segment of the dissected worm is placed.
Using a large bore pipette or butterfly forceps, remove a Planarian from the culture and
place it in the Petri dish and than on a damp piece of waxed paper.
Once it stretches out, place the waxed paper with the Planarian on an ice cube or dish
containing shaved ice. Make sure that you have several layers of waxed paper
between the planarian and the ice. Your goal is to use the ice to immobilize the
planarian without freezing the animal. Frozen or “dead” tissue does not regenerate.
Never keep your specimen on ice for very long. You goal should be to keep the
animal on ice only long enough to cut it into segments (one or two minutes at the
most).
With a scalpel or razor blade, quickly cut the Planarian. Place each segment in a separate
section of the petri dish.
We will keep the Petri dishes in a dark place at room temperature.
Each table should try to prepare three dishes.
We will try to examine the Planaria for a few minutes every two or three days and produce a
record of regeneration. Next week you will examine your specimens and discuss your results.
For next week:
As a class analyze your results. Each person writes their own report
Analysis: After examining the results of the Planaria regeneration experiments, did
you observe any pattern in the way that the regeneration occurred? If so, describe the
pattern. Does it indicate any gradient in regeneration efficiency? If you had to predict
where neoblasts are most found, where would that be and why?
Many of the sections of the Planaria will likely die before regeneration is complete. Why
might this have happened?
4. Acoel anatomy The acoels are small ciliated worms without a lumen to the gut. The
epidermis is a simple epithelium bearing the cilia and is underlaid by a grid-work of muscles.
The cilia provide gliding and swimming movement, and the muscles, both those of the body
wall and deeper-lying ones crossing through the body, steer the body with turning and twisting
motions as well as pull the body wall in movements that grab food and stuff it through the
mouth. The digestive tissue consists of a syncytium within which vacuoles form around food
that is ingested. The nervous system is largely in the form of a nerve net, but a centralized mass
surrounding the statocyst constitutes a brain from which stronger nerves extend as longitudinal
cords.The statocyst with a single highly refractile statolith is located anteriorly and can often
be seen in the dissecting microscope. In many species there are prominent glands that open
through an anteroterminal pore; these are the frontal glands. In mature animals, eggs are easily
detected as very large cells with a large nucleus. Discerning the testes usually requires higher
magnification. They are normally located anterolaterally to the ovaries, but there are exceptions.
There are many different types of male copulatory organs including a simple pore, a ciliated
antrum, a muscular penis or a sclerotized stylet. A female gonopore is present in most, but not
all species. Female accessory organs may be present in the form of a bursa for storage of
allosperm. In some species the bursa is equipped with a bursal nozzle, a narrow passage
through which allospermatozoa have to pass in order to fertilize the oocytes. Other features of
importance for identification of acoels are pigment patterns, presence of a pharynx (in a small
number of species), presence of symbiotic algae, and body shape and size.
Record locomotion in your specimen. Can you find the statocyst or see the cells of the
digestive tract through the pigmentation?
In your journal, compare the structure of an acoel with that of the ubellarians or more
complex flatworms. Confine your comments to structures you can see.
Below are diagrams to help you locate important structures.
Below
Parts of the digestive system=================Cilia/muscle tracks
Nervous system=============Male reproductive system====Female reproductive system
Ventral side showing position of mouth in some species
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