SCIENCE 9 TEXTBOOK (1).pdf

Full Transcript

U N I T

Biological
Diversity
How would you feel if the grizzly bear pictured here were the last one left on
Earth? Would it matter? Never before, since life appeared on this planet
3.5 billion years ago, have so many different species lived on the planet at the
same time. From the simplest of cells to today’s plants and animals, life has
flourished and continues to express itself in amazing ways. E.O. Wilson, a
famous U.S. biologist, has said that future generations may be able to
forgive us for such disasters as using up Earth’s stored energy
supplies or destroying the economy. As terrible as these
disasters would be, the environment could repair itself. Our
one unforgivable act would be to contribute to the loss of
Earth’s biological diversity. This incredible variety of life that
inhabits the world with us took millions of years to develop.
Any losses could be permanent.
Biologists estimate the number of different plants, animals,
and micro-organisms at about 15 million, but the number could
be as high as 100 million. However, many species are at risk and the
rate of extinction is increasing. What has caused this rate to increase? What
can science teach us about the causes of extinctions and the importance of
biological diversity?
In this unit you will:
•

Learn about the diversity of life on Earth.

•

Discover how living things pass on their traits to future generations.

•

Investigate the impacts of human activities on biological diversity, and
understand issues and decisions associated with future activities.

2

Unit Contents
TOPIC

1

Biological
Diversity and
Survival
TOPIC

2

Habitat and
Lifestyle
TOPIC

58

7

The Sixth
Extinction?
TOPIC

46

6

The Best
Selection
TOPIC

37

5

When Plans
Change
TOPIC

26

4

Wearing Your
Genes
TOPIC

16

3

Passing It On
TOPIC

6

66

8

Pains and Gains

73

U N I T

1

• What does biological
diversity look like?
• How do organisms pass
on their traits?
• How can we prevent
the loss of biological
diversity on Earth?

What could a single-celled amoeba and a
towering Douglas fir tree possibly have in
common? You’ll find some answers to this
question in Topic 1 as you explore life’s diversity.
You will see what makes life forms similar and
what makes them different. You will also
investigate the special features that allow some
organisms to succeed and survive, while others
do not. What role do organisms play in their
habitats? What are their relationships with other
organisms? Read Topic 2 to find out.

Have you ever thought about why some members of a family share certain physical
traits, while others don’t? Topics 3, 4, and 5 will explore the ways in which traits are
passed on from one generation to another. You will get down to basics as you learn
about the continuation of life in a variety of forms through DNA, life’s building plans.
Biotechnology—should we or shouldn’t we? Topic 5 explores this new field of study
and its implications.

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How does your lifestyle affect biological
diversity? Topics 6, 7, and 8 provide an
opportunity to examine changes in
organisms and our influences on these
changes. What do we need to know
about other organisms in order to make
decisions that will positively affect them?

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Unit 1 Preview • MHR

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TOPIC

1

Biological Diversity
and Survival

Figure 1.1 People, like all other life forms, display a wide variety of similarities and differences.
What is it that makes us the same? What is it that makes us different?

No two people are alike. Look around your classroom. You recognize
your friends because they have distinctive characteristics or features
that make them different from everyone else. These differences or
variations are a normal part of our lives. Variations are found not only
in humans, but in all populations or groups of similar living things.
The number and variety of organisms is called biological diversity.
Why, and in what ways, might biological diversity be important?
You will often see the
words “biological
diversity” shortened to
“biodiversity.” This
word is known as a
portmanteau word,
which means it is formed
by merging the meaning
of two different words.
Where did the term
“portmanteau word”
come from? Look up
“portmanteau” in the
dictionary and write an
explanation in your notebook. Write down two
other examples of
portmanteau words that
you know.
Figure 1.2 Can you see the variation among the individuals in the photograph above?

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A Wealth of Diversity
Imagine a world without mosquitoes. That would be a good thing,
wouldn’t it – or would it? Besides the advantage of never suffering from
another itchy mosquito bite, what other effects might there be? What
would you need to know about mosquitoes in order to decide whether
or not to try to eliminate them? How does the decision to eliminate
one type of organism affect us and other species in both positive and
negative ways? While people benefit from a wealth of biological diversity,
so do entire ecosystems. What would happen to the food web if there
were no more mosquitoes? Is there any way to predict the outcome?
As well, a great deal of our medicines come from biological sources.
The Pacific yew tree, for example, is the source of a cancer-fighting
chemical called Taxol. Before the discovery of Taxol, many people considered the Pacific yew a useless "trash" tree. Each time Earth loses a
plant or animal species, are we also losing an important medicine?
Figure 1.3 The Pacific yew tree
was once burned as trash. Now,
the tree is highly valued for its
life-giving properties. Should we
burn trees that cannot be used for
building materials or other
products? What would be the
overall result of this action?

Scientists still have a lot to learn about how the different
members in natural communities affect one another. Some
studies suggest that when several different types of plants
grow in an area, the interactions among them promote their
growth. This research supports the belief of many scientists
that biological diversity is important for the health and survival of natural communities.

For tips on societal decision making turn to Skill Focus 8.

Make a note in your
Science Log describing
what might happen if a
mosquito-eating bird
were introduced to
Alberta from another
part of the world.

Conserving venomous
animals may be good for
our health! How?
Venoms are complex
mixtures of compounds,
with various effects. For
instance, some snake
venoms and secretions
from frogs have antibacterial action. Such venoms could be the source
of new antibiotics.

In the 1700s Swedish biologist Carolus
Linnaeus developed the system of naming
species that we use today. His published
lists of all species known to science included the names of over 4000 plants and
7000 animals. Since that time his list has
expanded to include the names of over
1.75 million species. This listing is still
incomplete! Some scientists believe we
may have identified only 1–2% of the total
number of species alive today. How will we
maintain this diversity of life without even
knowing some species exist? Write your
thoughts in your Science Log. To review
classification systems, turn to Appendix A.

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Variation Within Species
Organisms are often
grouped together as a
species if:
1. They interbreed in nature.
2. Their offspring are able
to breed.
Tigers and lions are
separate species. They
are not known to breed
together in the wild. Tigers
and lions have been bred
together in zoos, but their
offspring are infertile.

The word “flora” refers
to all of the plant life in a
region. What do you think
“fauna” means? Check the
dictionary to see if you
are correct.

Take a look at the photographs on the first page of this unit. Each
organism is an example of a different species, or one type of plant
or animal. In general, organisms of the same species are similar in
appearance. However, there is always variation within a species.
To many of us all dandelions look the same. If you were to take a
closer look, you would see differences between individual dandelion
plants. In some cases
biologists can have
difficulty deciding if
two similar groups of
organisms belong to
the same species. On
the other hand, there
can sometimes be a
great deal of variation
within a species.

Figure 1.4 How many
different species of dandelion
are in this field?

Exploring Variation
All domestic cats belong to one species,
Felis catus. However, these cats show
many variations.

Find Out
What Did You Find Out?

Analyzing and Interpreting

1. What are the major characteristics for each
group of cats in the photographs?

Materials
photographs of farm,
house, or stray cats

2. How do purebreds
differ from other
domestic cats?

Procedure
1. Along with your
classmates, find
a photograph of
a domestic cat.
You can look in
magazines or newspapers, or you can use
a photograph of your own pet.
2. Post the photographs (or photocopies) on
a bulletin board in your class. Group the
photographs of similar looking cats together.

8 MHR • Biological Diversity

3. Thinking Critically
Explain how the
different types
of cats might be
suited to different
environments.
4. Thinking Critically Which cats
are most likely to be rat-hunters?
Which cats are most likely to
hunt mice?

A Classroom of Differences
Your school provides an excellent place to
investigate variations or differences within a
group of similar living things. In this case, the
population consists of the students in your
class and the variations are physical characteristics that you can easily measure.

Find Out
3. Measure, or have your partner measure,
the distance around your left wrist to the
nearest millimetre at the point where the
wrist bone sticks up. Record your results on
the chalkboard.

Materials
tape measure
chalkboard
Procedure

chalk and pencils
flipchart paper
Performing and Recording
Communication and Teamwork

1. Working in pairs,
measure each student’s height to the
nearest centimetre
and record each
measurement on the
chalkboard.
2. Stretch out your
hand. Measure the
distance (to the
nearest millimetre)
from the tip of the
thumb to the tip of
the little finger of your outstretched hand.
Again record all results on the chalkboard.

4. Write all of the class results in your notebook and record the class results for each
set of measurements on the chalkboard or
separate pieces of flipchart paper. Show
each measurement and the number of
students that share it. Put the measurements
into groups. For example, put the number
of students that have heights between
176–180 cm into one group.
5. Prepare a histogram for each of your
three measurements. You may use a
computer to record and sort the data
and draw the graphs.
What Did You Find Out?

Analyzing and Interpreting

1. Are there any similarities between the
graphs?
2. Can you explain the shapes of the graphs?
3. Is there any reason why a graph for right
wrist measurements might be different
from left wrist measurements?

For tips on how to prepare graphs, turn to Skill Focus 10.

4. What are some of the factors that might
cause variations between you and your
classmates?

Biological Diversity and Survival • MHR

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Variation Among Species
Taxonomists classify things, such as living
organisms. Sometimes taxonomists have
lengthy discussions about whether or not
two organisms belong to the same species.
For example, Bullock’s and Baltimore
orioles were once considered separate
species. Later, the birds were re-classified
as a single species, the northern oriole.
Recently, scientists split the
grouping once again.
Why might it be
important to
know whether
or not two
types of
organisms
belonged to the
same species?

Figure 1.5 The cougar (A), lynx (B), and bobcat (C)
are classified in the same family of animals. However,
each cat is a different species.

Many organisms show similar characteristics: insects
have six legs, birds have feathers, and mammals nurse
their young. Even so, there are many species of each
of these creatures. How did so much variety come
about? To answer this question scientists have looked
to areas of the world that are rich in various species of
plants and animals. Great biological diversity often
occurs on islands, or other places where animals and
plants have been isolated for a long time.
Many studies on similar species, such as wild cats
like the lynx, bobcat, and cougar, indicate that all
came from a common ancestor. Over time, one type
of cat evolved into a variety of similar yet separate
species. This process is called speciation. Much of
Earth’s biological diversity is due to speciation.

B

A

C

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Initiating and Planning
Performing and Recording

1-A

Analyzing and Interpreting
Communication and Teamwork

The Galápagos Finches
Think About It
The Galápagos Islands are located on the Equator in the Pacific Ocean about
1000 km from the coast of Ecuador, South America. The 13 main islands and
several smaller islands are volcanic in origin and contain a number of ecosystems. At lower elevations the islands are dry,
and bushes, trees, and cacti make up the vegetation.
Humid forests grow on the larger islands at
sharp-beaked
higher elevations. On his stop at the
ground finch
large
cactus finch
cactus finch
Galápagos, biologist Charles Darwin gathered specimens of birds from some of the
cocos
Pinta
islands. He noticed that there were a
Marchena
island finch
large
large number of closely related finches,
Pacific Ocean
ground finch
each of which was a distinctive species.
Santiago BartoloméGenovesa
Fernandina
Darwin counted 13 species of finch
N. Seymour
warbler finch
from the Galápagos, and one from
Baltra
Rábida
medium
Cocos Island, located 830 km north
Santa Cruz
ground finch
of the Galápagos. In this investigaIsabela
Santa Fé
Pinzón
woodpecker
tion you will examine Darwin’s
San Cristóbal
finch
Floreana
N
finches and how the islands gave rise
small
to the variety of different species.
Española
ground finch

What To Do
Study the diagram of the
vegetarian
different finches. What is the
tree finch
major anatomical difference between
the species illustrated? Form a hypothesis
that might explain the difference between,
for example, the woodpecker finch and the
cactus finch.
Ground finches that depend primarily on
seeds as a source of food live primarily on
solidified lava beds. What kinds of habitats
might be suitable for some other species of
finches? If information is available, match
these habitats to particular islands.
Research the different areas on the
Galápagos Islands. What are the conditions
like in each of these places?

mangrove finch

small
tree finch

large
tree finch

medium
tree finch

Analyze
1. Did your research findings support
your hypothesis?
2. What problems might you encounter when
developing a hypothesis from an artist's
drawing of an organism?

Biological Diversity and Survival • MHR

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Geckos are small lizards with some strange habits! They
can walk upside down across the bottom of a leaf without
falling off. As they walk, their feet uncurl, flattening tiny projections called
setae. Intermolecular forces of attraction bond the setae to the leaf’s surface.

Variations for Survival

www.mcgrawhill.ca/links/
sciencefocus9
Madagascar is an island that lies off the coast of Africa.
The unique species on Madagascar attract biologists from
around the world. Unfortunately, many of these species are
endangered. Choose one species from Madagascar and find out
what makes it one of a kind. What effect would the loss of this
species have on other species in Madagascar? Create a poster
by hand or on a computer that shows this plant or animal’s special features. To begin your research, go to
the web site above, and click on Web Links
to find out where to go next.

The rufous hummingbird
migrates farther than any
bird its size. Each year
rufous hummingbirds
migrate from Mexico or
the southern United States
to summer homes in the
northwestern states and
western Canada, including
southwestern Alberta. If
a rufous hummingbird
travels 1800 km, it will
travel a distance 2 x 107
times the length of its
body. How big is the
rufous hummingbird?
Give your answer in
centimetres.

As you may remember, every organism has
adaptations that enable it to survive in its
environment. There are many ways to solve a
problem, such as obtaining food. As a result,
a great variety of adaptations can be seen in
living things. Examine the photographs
shown below. Most plants obtain nutrients
through their roots. The pitcher plant has an
unusual way of obtaining the nutrient nitrogen. This plant obtains nitrogen from insects
that it traps in its pitcher shaped leaf. This
physical feature is a structural adaptation.
Behavioural adaptations include the owl
hunting at night and the migration of birds
from the tropics to their nesting sites in the
Far North. Variation in animal behaviours is
not only interesting, but as you will learn in
Topic 2, different behavioural adaptations
allow each species to have its own place in
an ecosystem.

Figure 1.6 The pitcher plant may be found in
boggy areas of northeastern Alberta and near
Edson, typically in nitrogen-poor soils. Insects
that are attracted to the plant slip down the
smooth lip of the leaf into a liquid at the base.
There they drown and are digested by the plant.

12 MHR • Biological Diversity

Figure 1.7 Most owls are nocturnal. This
behavioural adaptation goes along with
certain structural adaptations. What might
some of these structural adaptations be?
How do nocturnal owls differ from birds
such as magpies that feed during the day?

The Value of Variation
Western forests are under attack. The mountain pine beetle
is a pest of the lodgepole pine, a very common tree in the
Rocky Mountains. A mountain pine beetle infestation can
destroy a forest that is made up mainly of lodgepole pine.
In contrast, areas with greater biological diversity are often
more able to tolerate changes in the environment. A forest
with many tree species has a good chance of staying healthy
in spite of disease. If a disease destroys only one species of
tree, the other trees will remain unharmed.
The lodgepole pine is an important source of timber
in Canada. Finding a lasting solution to the mountain
pine beetle problem could have economic benefits.
Mature lodgepole pine are less resistant to infection, so
one solution is to burn areas with older trees. What
information would help you decide if burning these trees
would be the best action to take?

Figure 1.8 This forest has been hit by a mountain
pine beetle infestation. The beetle bores into the
bark, carrying the spores of the bluestain fungus
with it. Fungal infection and damage caused by
the beetles eventually kill the trees.

Measuring Biological Diversity
To determine the biological diversity of an area, biologists use a measurement called the diversity index. This measurement compares the diversity
of species in an area with the total number of organisms in the same area.
It is normal for some places to have a higher diversity index than others.
The diversity index can be used to check the health of an ecosystem.
For example, a river with many different kinds of organisms living in it
would have a high diversity index. The river would also likely be
healthier than a river that supports only a few types of organisms. Why
would this be true? In fact, the large number of different species in a
healthy river prevents the population of any one type of organism from
becoming too great. A polluted river may have large numbers of the
same organism. However, this river would support only the few species
that are able to live in polluted conditions. You may remember that
when rivers become polluted with sewage, algae can grow out of control,
killing off other species. Such a river would have a low diversity index.

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Why is there a new flu virus every year? It turns out that
the flu virus is a master at variation! To learn more about the flu
virus, visit the above web site. Go to the web site above, and click on
Web Links to find out where to go next. Write a paragraph that
explains why the human body has trouble recognizing the flu virus.
Build a model of the flu virus using modelling clay or create a
computer model using modelling software to help
illustrate your answer.

Lo

www.mcgrawhill.ca/links/sciencefocus9

The influenza outbreak of
1918–1919 killed 50 000
people in Canada alone.
In just one year, the
pandemic (a global outbreak) killed 25 million
people worldwide. Yet
18 months after the
disease was reported, it
disappeared. It now
seems that the virus ran
out of susceptible people.
Whether or not someone
is likely to catch a disease
can depend on the
person’s age, genetics, or
general health. The fact
that some people get
diseases and others do
not is another example
of variation. Even today,
scientists are only
beginning to understand
why some people get
sick and others do not.

hea

Remember to keep planning for
your Unit 1 Issue Analysis. Think
about the forum as you work
through each Topic in this unit.

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Initiating and Planning
Performing and Recording

1-B

Analyzing and Interpreting
Communication and Teamwork

Using the Diversity Index
In this investigation you will begin to explore the
biodiversity of an area by focussing on one small piece
of it. You will focus in even further by studying tree
diversity only and developing a tree diversity index.

A

A

A

B

C

D

Question
How can the diversity index be used to measure diversity in different areas?

Hypothesis
State a hypothesis about the diversity of trees in natural areas compared to areas of human
activity. Predict which of the areas in your study will have a higher tree diversity index.
Apparatus
notebook
ball of string

pen
metre sticks

Procedure
Working in a group, decide upon two different
study areas. One should be an area of human
activity (such as a school yard or street) and the
other a natural area (such as a community park).
Using a string line 25 m in length, measure a
path in the area you have chosen to study.
Imagine a carpet that extends out one metre
on either side of your string line. Beginning at
one end of the string line, start to count all of
the trees with a trunk that is inside or at least
touches your two metre-wide carpet. (You
might want to use your metre stick to measure
in a case where you’re unsure whether a tree is
inside or outside the area.)
Record the first tree in the area as "A." If the
next tree is the same as the first, record it as
another "A." If the second tree is different
from the first, record it as "B." Every time
you come across a tree that is different from
the last one, record a new letter (C, D, etc.). It
is the change from one kind of tree to another
that indicates diversity. Each change starts a
new “run” of data. (See the example above.)
Determine the number of runs in your trial
by counting how many different letters you
have recorded. There were four runs in total
in the example provided (AAABCD).
14 MHR • Biological Diversity

Count the total number of specimens (trees)
in your trial. In the example trial there were
six specimens.
Copy the data table below in your notebook.
Complete the table.
Data Table
Number of Runs 
Number of Specimens 
Number of Runs
Diversity Index   
Number of Specimens

Repeat steps 2–5 for the second study area.

Analyze
1. Which area has a higher tree diversity index?
2. How did your results compare with those
of other groups in the class?

Conclude and Apply
3. The closer the diversity index is to one, the
more diversity there is within an ecosystem.
The smaller the diversity index, the less
diversity there is in an area. Which of your
two sites had more tree diversity?
4. Did your observations support your
hypothesis? How could you design an
investigation to test for variables that might
affect tree diversity in different areas?

The Nature of the Job
Imagine spending your working day walking along quiet woodland trails. Interpretive naturalists
do just this! They lead nature walks and explain the natural environment to others, from young
children to adults. Most naturalists work at conservation areas, wildlife reserves, government
parks, or for conservation groups. Through nature walks, they help visitors experience nature
first-hand. Naturalists also give talks, prepare displays, and sometimes write informational
leaflets. They may even take care of animals or help maintain the habitats of local wildlife.
In this job, a love of both the outdoors and working with people is
essential. Most interpretive naturalists are good communicators
and have a post-secondary science degree. This may be either a
Bachelor of Science degree from a university, or a college degree
in outdoor education, wildlife studies, ecology, wildlife biology, or
a related subject.
Can you picture yourself as an interpretive naturalist? Make two
lists: one listing the parts of this job that appeal to you, and the
other listing the parts that do not. Then complete the statement
below using as many points as possible that apply to you. Your
points can be as simple as “will not have to wear business
clothes” or “can travel.” Choose five points that you feel will be
the most important to you when choosing a career.
I am interested in a career in which I . . .

TOPIC 1

Review

1. Write your own definition for biological diversity.
2. Think about a time you have seen a flock of Canada geese (Branta
canadensis) flying overhead. If you could examine the geese closely,
would they look identical? Explain your answer.
3. Apply Name a situation in which it would be useful to determine the
diversity index of an area.
4. Thinking Critically Invent an animal that is perfectly adapted for living
inside the school gym.

Biologists can use
diversity indexes to
monitor the health of
Alberta ecosystems. What
types of human activities
could lower the diversity
index of grasslands?
How would you decide if
these activities should be
continued? Write your
ideas in your Science Log

5. One variation seen in birds is the placement of the eyes. Shown
here is the American woodcock, which feeds on worms in the
ground. Its eyes are located virtually on the top of the head.
Explain how this variation may be a useful adaptation.
6. The bubonic plague, or Black Death, kills people every year.
However, it was devastating when it swept through Europe in
the sixth, fourteenth, and seventeenth centuries. It killed 90%
of the people exposed to the germ and resulted in the deaths of
approximately 137 million people. Why was everyone not killed
by the Black Death?
Biological Diversity and Survival • MHR

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