Jamia Millia Islamia
BIOLOGY INVESTIGATORY PROJECT
Thigmotropism In Tendrils
EHAB SHAHID XII Sci.B
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CERTIFICATE
It is hereby certified that Ehab Shahid of class XII has satisfactorily completed
the Investigatory Project in the subject of Biology on the topic“Thigmotropism
in Tendrils”in the school laboratory.
The work carried out to investigate about the subject matter and the related
data collection is original and genuine and has been completed solely and
satisfactorily by the student.
SIGNATURE of TEACHER
SIGNATURE of PRINCIPAL
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ACKNOWLEDGEMENT
I would like to express my gratitude to my teacher Mrs.YASMEEN QURESHI as
well as the principal of my institution Mr. ATIQUR RAHMAN who gave me the
golden opportunity to carry out this wonderful project on the topic
‘Thigmotropism in Tendrils’ through which I learnt many things. I am very
thankful to them.
Secondly, I would also like to thank our Lab assistants who provided me with
the facilities and conductive conditions required for on-time completion of this
Project. I also would like to thank my parents and friends who helped me a lot
in finalizing and completing this project within the limited time frame. The
errors and inconsistencies, if any, remain my own.
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INTRODUCTION
Thigmotropism is the directional response of a plant organ to touch or physical contact
with solid object. This directional response is generally caused by induction of some
pattern of differential growth. This phenomenon is clearly illustrated by the climbing
tendrils of some plants, such as the sweet pea. The tendrils actually “feel” the solid
object, which results in the coiling response.
So plants actually have a sense of touch?
Yes. In fact, some plants are actually much more sensitive to touch than human beings!
For example, human skin can minimally detect a thread weighing 0.002mg being drawn
across it. However, a feeding tentacle of the insectivorous sundew plant responds to a
thread of 0.0008 mg, and a climbing tendril of Sicyos actually responds to a thread
weighing just 0.00025mg! Therefore, some plants have a sense of touch which is nearly
10 times as sensitive as human skin!
What Parts of the Plant Can Respond to Touch?
The clearest example of thigmotropism is the coiling that occurs in some tendrils.
However, roots also depend on touch sensitivity to navigate their way through the soil.
The general touch response in roots is negative. That is, when a root "feels" an object,
the root grows away from the object. In comparison, most tendrils grow toward the
touch stimulus, allowing for the tendril to wrap around the object which it is in contact
with.
Therefore, roots are said to be "negatively thigmotropic". This allows the roots to follow
the line of least resistance through the soil. In addition to thigmotropic responses, roots
(as well as other organs) are known to grow in response to gravity. This "gravitopism"
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allows the roots to grow in the direction of gravity, which is down into the earth.
Interestingly, thigmotropism seems capable of overriding the strong graviptropic
responses of even primary roots. Gravitropism overrides thigmotropism in horizontally
oriented roots. This interaction, or "cross-talk" between thigmotropism and gravitropism
likely regulates the path finding of roots, but significant studies on the nature of this
interaction have yet to be performed.
How Do Tendrils Actually Curve?
In general, tendrils are able to curve by employing a process known as "differential growth".
This process involves the stimulation of growth in particular regions of the tendril. In
positive thigmotropism, for example, the side of the tendril which is opposite to the side of
contact will grow at a faster rate than the contact side. In some cases, the cells on the
contact side will actually compress, which enhances the curving response. Therefore, the
non-contact side begins to elongate faster than the rest of the tendril, while the contact side
actually compresses. This causes the tendril to curve toward the site of contact.
In addition to differential growth, some tendrils exhibit a type of coiling response which is
referred to as "rapid contact-coiling". This type of response is, as the name suggests, very
rapid. It is caused by changes in cell turgor which alter the shape of the tendril, causing it to
curve. The cells on the non-contact side of the tendril expand, while the cells on the contact
side contract, similar to the differential growth patterns in the animation above. Therefore,
the rapid contact-coiling response is a rapid initial response, while differential growth is a
somewhat slower, but more "permanent" response.
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AIM OF THE PROJECT
The objective of this plant biology project is to investigate the response of a plant's tendrils
to touch.
APPARATUS REQUIRED
• Seeds
• Small pots
• Potting soil
• Permanent marker
• Masking tape
• Pencils for smaller plants
• Stopwatch
• Lab notebook
PROCEDURE
1. Plant two morning glory seeds in a small pot. First put about 3 inches of potting soil into
the pot. Form a hole and place the seeds in the hole. Then cover them with about 1–2 more
inches of potting soil.
2. Water the seeds regularly and keep the pots in a warm area, out of the direct sunlight.
3. Record the date, the time, the common and scientific name of the plant.
4. It will take up to three weeks for the plant to grow and form tendrils.
Observing Tendril Response to a Solid Support
1. When the plants have produced several tendrils, insert a pencil into the soil near one of the
tendrils.
a. Place the pencil in the pot so that it is touching the tendril.
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b. Arrange the tendril and support so that the middle of the tendril is in direct contact with the
support.
c. Gently secure the stem of the plant to the pencil with a little piece of tape so that the
tendrils are in contact with the pencil.
2. Repeat step 1 for two more tendrils.
3. Observe the tendrils for the next 24 hours, as each first touches the pencil, and then as it
curls around the pencil.
a. Keep a record of your observations, including times, in the lab notebook.
OBSERVATIONS
Experimenting with Stimuli
Now that we have healthy plant with tendrils, experiment with the stimuli that result in the
tendrils starting to curl. Specifically, investigate how the frequency of physical contact
affects curling. To stimulate curling in the tendrils, first mark a region on tendrils with a
permanent marker. Then touch them at different times, with a pencil, and record their
response to touch.
1. Mark one spot on few tendrils with a permanent marker, as follows.
a. Mark each tendril in approximately the same region; for example, near the
middle of the tendril.
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b. The mark should be about 1 cm long.
2. Keep track of each of the tendrils.
3. Pick three tendrils that will not be marked with the permanent marker. These tendrils will
be the negative controls. These tendrils should not touch the pencil or any other solid
object.
4. Touch (always with the pencil and always timing with the stopwatch) tendrils 1– 12 at
different times of the day, as follows:
a. Tendrils 1, 2, and 3: One time per day for 30 seconds in the morning.
b. Tendrils 4, 5, and 6: Three times per day, for 30 seconds each time, in the morning,
afternoon, and at night.
c. Tendrils 7, 8, and 9: Six times per day for 30 seconds. Six times over the course of the day.
d. Tendrils 10, 11, 12: These tendrils should be in constant contact with a support, such as a
pencil, as they were in the previous section.
e. Tendrils 13, 14, and 15: These tendrils receive no stimulus.
5. Record the time it takes for the tendrils to start curling.
6. Record the degree of curl—such as 90 degrees, one full rotation, two full rotations, etc.—
in the lab notebook.
OBSERVATION
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RESULT
Thigmotropism is very complex! However, consider that the initial signal must be generated
by an action potential. This action potential leads to the establishment of an ionic gradient,
which results in increased turgidity in the non-contact side cells, and decreased turgidity in
the contact-side cells. This process allows for the initial, rapid bending of the tendril. This
rapid bending is then followed by a slower process of differential growth. Jasmonate
production may then be increased, which would promote growth in the non-contact side
cells. In addition, up regulation of the TCH genes may act in concert with the jasmonates to
induce cell growth. Although there are "missing links" in this mechanism which we have not
yet uncovered, further research may elucidate the entire mechanism. Studies which focus
on the regulation of the TCH genes may prove invaluable in determining how certain areas
of the tendril grow at a faster rate than others in response to touch.
REFERENCES
Books
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NCERT Biology Class 12
Thigmotropism – Lee Pennington
Web
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• http://biology.kenyon.edu/edwards/project/steffan/b45sv.htm
• http://plantsinaction.science.uq.edu.au/edition1/?q=content/8-2-2-thigmotropism
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