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NOVA scienceNOW: Aging
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Viewing Ideas
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Before Watching
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Graph the age demographics of your town or city. Assign
student groups different towns or cities in your area, and have
each group find the age demographics by decades (e.g., 0-10;
11-20, etc.) for their assigned location. (For some towns, this
information is on the Internet; for others, the information can
be obtained from the town or city census office.) Then ask
groups to display the information in a bar graph. Have them
label the x-axis "Age by Decade" and the y-axis "Percent of
Population." Ask students to display their graphs. Is the
number of centenarians greater than, less than, or equal to
1/10,000 (0.01 percent) as is stated in the program? Have
students consider factors that may have contributed to higher or
lower percentages (ratios) than 1/10,000 (assisted-living
centers for seniors, extremely harsh climate, or lack of medical
care). Extend the activity and have students research and graph
the age demographics of cities and towns in areas of the country
known to have high populations of senior citizens, such as San
Francisco, CA; Boynton Beach, FL; Philadelphia, PA; New York,
NY; Lynchburg, VA; and Muncie, IN. Ask how graphs that are made
using age demographics from these areas compare to their graphs
based on local age demographics.
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Design a survey. Have students design an anonymous survey
to find how many people there are in the extended school
community (including family members and other caregivers) over
the age of 90. (Do families that include members older than 90
and 100 years old have, or did they once have, more than one
member in that age group? Ask students to include a question in
the survey about this.) Is the number of people over 100 years
of age greater than, less than, or equal to the ratio of
1/10,000? Ask what happens when you take a small sample and try
to extend the results to represent a larger population. If there
are people in their 90s or centenarians in the extended school
community, invite one or more individuals to your classroom and
have the class interview them. Before their visit(s), have
students prepare interview questions.
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Brainstorm genetic, environmental, and lifestyle factors that
relate to life span.
Review the definition of the term life span. (The average length of time, often expressed in a range, that
a species in a particular environment can be expected to
survive.)
Have student pairs brainstorm and list factors that may play a
role in determining whether individuals reach their expected
life span. Then have them group the factors as mostly genetic
(inherited), mostly environmental (pollution and other external
factors), and mostly lifestyle (smoking, amount and kind of
exercise, drug use, dietary choices). Make a three-column chart
on the board, and label one column genetic factors, one
environmental factors, and one lifestyle choices.
Have teams share the factors they came up with and list them on
the board. Review the list with students and discuss the ways
genes, the environment, and lifestyle can affect how long a
person lives.
After Watching
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Research organisms used for laboratory research. Have
students recall the laboratory organisms discussed in the
program that are used to study genes related to aging and
longevity (yeast; C. elegans, a common roundworm; mice; and, briefly mentioned, Drosophila, a fruit fly). Divide the class into four
groups, and assign each group a different organism to research
(see Howard Hughes Medical Institute site in
Links & Books). Groups should find out why their organism is so widely used
and important for genetic studies. Have each group prepare and
present a poster about their organism. Posters should include
the information listed below.
- organism's classification
- length of time required for the organism to reproduce
- organism's habitat and availability
- how and where the animals are kept in the laboratory
- how long the organism generally lives
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reasons why the organism is frequently used for genetic
research (for example, the functions of many of the organism's
genes are already known)
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Consider why DNA needs repair genes. The scientists in
the program report that sirtuin genes in yeast are active when
an organism is stressed, such as when food intake is low; a
different scientific study showed that damage to the Daph 2 gene
in the roundworm C. elegans caused a decrease in the
worm's insulin level. The researchers postulate that both
sirtuin and low insulin may trigger "survival genes" to become
active or expressed. The scientists state that "survival genes"
probably include DNA repair genes. Ask students why DNA might
need its own set of repair genes. (DNA can be changed during replication or damaged by UV light
and environmental toxins such as cigarette smoke or other
inhaled or ingested toxins. Therefore, it is important that
genes exist that can repair the damage to this basic building
block of life.)
As an extension for advanced biology students, use a DNA model
and have students locate the sugar-phosphate backbone, the
individual nucleotide bases, and the nucleotide base pairs. Ask
students to brainstorm different break points that could occur
in DNA that would need repair. Tell students that a number of
DNA repair genes are involved in the following: base excision
and replacement, mismatch repair, and rejoining broken strands.
Have students use the model to show the three types of repair.
What might happen to the cell if a DNA repair mechanism didn't
exist? (Cells and organs could die. Cells might make too little or
too much of a protein. If the damage were to affect a gene
that controls cell division, the cell could continue to
divide, resulting in a tumor or in cancer.)
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Research plant chemicals that have health benefits.
Scientists researching longevity found that resveratrol, in high
doses, caused yeast, roundworms (C. elegans), and mice to
live longer than their expected life span. Resveratrol is made
by plants to protect them from fungal growth. It is found in
different amounts in grapes (mainly in the skin), raspberries,
peanuts, cranberries, and other plants. Many plant chemicals
have a beneficial effect on health. Divide the class into groups
and have each group research resveratrol or one of the following
groups of plant chemicals—the flavonoid anthocyanin (found
in blueberries, blackberries, cherries, and some vegetables such
as red cabbage); or the flavonoid quercitin (found in yellow
onions). Have students report on the function their chemical
plays in the plant, and the potential health benefits of the
chemical for people. Note: Explain that information about health
benefits should be obtained from encyclopedias or scientific
research sites, because health claims can be false or
unsubstantiated.
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Plant Chemical
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Found In
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Plant Function
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Potential Benefit for Humans
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resveratrol
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grapes (mainly on the skin), raspberries, peanuts,
cranberries, and other plants
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protects plant from fungal infections
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possibly anti-inflammatory and antiviral effects
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anthocyanin
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blueberries, blackberries, cherries, and some vegetables such
as red cabbage
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gives blueberries their color; provides color to flower and
fruit
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acts as antioxidant and may also help prevent some types of
memory loss and disease
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quercitin
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yellow onions
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provides color to plant; gives visual cues to pollinators
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may help protect against some types of heart disease
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As an extension, ask students to keep a record of the fruits and
vegetables they eat for two days. Have them research and group any
foods that contain the plant chemicals in the chart.
Links
HHMI Online Companion
www.hhmi.org/resources/science_now/aging.html
The Howard Hughes Medical Institute offers an extensive
collection of aging research resources in its online companion to
this episode of NOVA scienceNOW.
More on HHMI and its partnership with NOVA
Healthy Aging for Older Adults
www.cdc.gov/aging
The Centers for Disease Control and Prevention provides this
extensive Web site on aging for older adults. Find information on
healthy living, view medical statistics, and browse other online
resources.
National Institute on Aging
www.nia.nih.gov/ResearchInformation/
This Web site from the National Institutes of Health offers
information on current research into the biology of aging,
behavioral and social aspects of old age, and more.
The Aging Research Center
www.arclab.org/
On this Web site, learn about upcoming conferences on
geriatrics research, read up on federally and privately supported
clinical research, and find a list of online aging resources.
Infoaging
www.infoaging.org
This Web site from the American Federation for Aging Research
has information on the biology of aging, age-related diseases, and
links to current research.
Genes and Longevity
www.dnafiles.org/resources/res12.html
This companion Web site to the National Public Radio series
"The DNA Files" provides a number of links and other online
resources related to longevity and aging.
Books
Epigenetics
by C. David Allis. Cold Spring Harbor Laboratory Press, 2006.
Ageless Quest: One Scientist's Search for Genes That Prolong
Youth
by Lenny Guarente. Cold Spring Harbor Laboratory Press, 2002.
Aging at the Molecular Level: Biology of Aging and its
Modulation
edited by T. von Zglinicki. Springer Books, 2003.
Articles
"A Conversation With Nir Barzilai; It's Not the Yogurt: Looking for
Longevity Genes"
by Claudia Dreifus. The New York Times, February 24, 2004.
"The Quest For a Way Around Aging"
by Nicholas Wade. The New York Times, November 8, 2006.
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