9781422284896

Animal Science

SCIENCE 24/7

A nimal S cience C ar S cience C omputer S cience E nvironmental S cience F ashion S cience F ood S cience H ealth S cience

M usic S cience P hoto S cience S ports S cience T ravel S cience

SCIENCE 24/7

animal Science

Jane P. Gardner

Science Consultant: Russ Lewin science and Math educator

Mason Crest

Mason Crest 450 Parkway Drive, Suite D Broomall, PA 19008 www.masoncrest.com

Copyright © 2016 by Mason Crest, an imprint of National Highlights, Inc.

All rights reserved. No part of this publication may be reproduced or transmitted in any form or by any means, electronic or mechanical, including photocopying, recording, taping, or any information storage and retrieval system, without per- mission from the publisher.

Printed and bound in the United States of America.

Series ISBN: 978-1-4222-3404-4 Hardback ISBN: 978-1-4222-3405-1 EBook ISBN: 978-1-4222-8489-6

First printing 1 3 5 7 9 8 6 4 2

Produced by Shoreline Publishing Group LLC Santa Barbara, California www.shorelinepublishing.com Cover photo: Dreamstime.com/Photobac

Library of Congress Cataloging-in-Publication Data Gardner, Jane P., author. Animal science / by Jane P. Gardner ; science consultant, Russ Lewin, science and math educator. pages cm. -- (Science 24/7) Audience: Grades 9-12 Includes bibliographical references and index. ISBN 978-1-4222-3405-1 (hardback) -- ISBN 978-1-4222-3404-4 (series) -- ISBN 978-1-4222-8489-6 (ebook) 1. Zo- ology--Miscellanea--Juvenile literature. 2. Ecology--Miscellanea--Juvenile literature. I. Title. QL49.G2485 2016 590--dc23 2015004962

IMPORTANT NOTICE The science experiments, activities, and information described in this publication are for educational use only. The publisher is not responsible for any direct, indirect, incidental or consequential damages as a result of the uses or misuses of the techniques and information within.

Contents

Introduction

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Chapter 1: Inheritance of Traits

Chapter 2: Flight

12 16 20 24 28 32

Chapter 3: Animal Behavior Chapter 4: Adaptations Chapter 5: Stay Warm Chapter 6: Conservation Chapter 7: Food Webs Chapter 8: Temperature

36 Chapter 9: Conclusion: Concept Review 40 Find Out More 44 Series Glossary of Key Terms 45 Picture Credits 46 About the Author and Consultant 47 Index 48

Key Icons to Look For

Words to Understand: These words with their easy-to-understand definitions will increase the reader’s understanding of the text, while building vocabulary skills.

Sidebars: This boxed material within the main text allows readers to build knowledge, gain in- sights, explore possibilities, and broaden their perspectives by weaving together additional in- formation to provide realistic and holistic perspectives. Series Glossary of Key Terms: This back-of-the-book glossary contains terminology used through- out this series. Words found here increase the reader’s ability to read and comprehend higher- level books and articles in this field.

Introduction S cience. Ugh! Is this the class you have to sit through in order to get to the cafeteria for lunch? Or, yeah! This is my favorite class! Whether you look forward to science or dread it, you can’t escape it. Science is all around us all the time. What do you think of when you think about science? People in lab coats peering anxiously through microscopes while scribbling notes? Giant telescopes scanning the universe for signs of life? Submersibles trolling the dark, cold, and lonely world of the deepest ocean? Yes, these are all science and things that scientists do to learn more about our planet, outer space, and the human body. But we are all scientists. Even you. Science is about asking questions. Why do I have to eat my vegetables? Why does the sun set in the west? Why do cats purr and dogs bark? Why am I warmer when I wear a black jacket than when I wear a white one? These are all great questions. And these questions can be the start of something big . . . the start of scientific discovery. 1. Observe: Ask questions. What do you see in the world around you that you don’t un- derstand? What do you wish you knew more about? Remember, there is always more than one solution to a problem. This is the starting point for scientists—and it can be the starting point for you, too! Enrique took a slice of bread out of the package and discovered there was mold on it. “Again?” he complained. “This is the second time this all-natural bread I bought turned moldy before I could finish it. I wonder why.” 2. Research: Find out what you can about the observation you have made. The more in- formation you learn about your observation, the better you will understand which ques- tions really need to be answered. Enrique researched the term “all-natural” as it applied to his bread. He discovered that it meant that no preservatives were used. Some breads contain preservatives, which are used to “maintain fresh- ness.” Enrique wondered if it was the lack of preservatives that was allowing his bread to grow mold. 3. Predict: Consider what might happen if you were to design an experiment based on your research. What do you think you would find? Enrique thought that maybe it was the lack of preservatives in his bread that was causing the mold. He predicted that bread containing preservatives would last longer than “all-natural” breads.

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4. Develop aHypothesis: A hypothesis is a possible answer or solution to a scientific prob- lem. Sometimes, they are written as an “if-then” statement. For example, “If I get a good night’s sleep, then I will do well on the test tomorrow.” This is not a fact; there is no guarantee that the hypothesis is correct. But it is a statement that can be tested with an experiment. And then, if necessary, revised once the experiment has been done. Enrique thinks that he knows what is going on. He figures that the preservatives in the bread are what keeps it from getting moldy. His working hypothesis is, “If bread contains preservatives, it will not grow mold.” He is now ready to test his hypothesis. 5. Design an Experiment: An experiment is designed to test a hypothesis. It is important when designing an experiment to look at all the variables. Variables are the factors that will change in the experiment. Some variables will be independent—these won’t change. Others are dependent and will change as the experiment progresses. A control is nec- essary, too. This is a constant throughout the experiment against which results can be compared. Enrique plans his experiment. He chooses two slices of his bread, and two slices of the bread with preservatives. He uses a small kitchen scale to ensure that the slices are approximately the same weight. He places a slice of each on the windowsill where they will receive the same amount of sunlight. He places the other two slices in a dark cupboard. He checks on his bread every day for a week. He finds that his bread gets mold in both places while the bread with preservatives starts to grow a little mold in the sunshine but none in the cupboard. 6. Revise the hypothesis: Sometimes the result of your experiment will show that the original hypothesis is incorrect. That is okay! Science is all about taking risks, making mistakes, and learning from them. Rewriting a hypothesis after examining the data is what this is all about. Enrique realized it may be more than the preservatives that prevents mold. Keeping the bread out of the sunlight and in a dark place will help preserve it, even without preservatives. He has decided to buy smaller quantities of bread now, and keep it in the cupboard. This book has activities for you to try at the end of each chapter. They are meant to be fun, and teach you a little bit at the same time. Sometimes, you’ll be asked to design your own ex- periment. Think back to Enrique’s experience when you start designing your own. And remem- ber—science is about being curious, being patient, and not being afraid of saying you made a mistake. There are always other experiments to be done!

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1 Inheritance of Traits

J esse and his friend, Gabriella, headed to their local pet store, which is called “All Pets, All the Time.” Jesse needed to buy crickets to feed his pet gecko and liked the owner, Mr. Wei. Mr. Wei is very nice and doesn’t mind if the kids browse in the store for a long time. The bell over the door chimed, announcing their arrival. An old golden retriever rose out of a dog bed next to the counter to meet them. A large blue bird swooped to a roost over the cash register. They heard a dog barking and crickets chirping in the background. And next to them was a large display of woven bracelets in front of a poster of elephants and rhinos. “Kittens!” exclaimed Gabriella. She rushed over to where a mother cat and her eight kittens were playing and lounging in a large enclosure. Jesse walked over to take a look at them as well. “Look at them,” he said. “They are so different. Tiger stripes, calico, and look at that solid

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black one. Why is there only one mother cat here?” Mr. Wei came up behind them and picked up the large cat with tiger stripes and an orange face. “This is the mother. She was found near a dumpster last week with all these babies.” Gabriella looked up. “How could one mother cat have kittens with so many different pat- terns?” Mr. Wei smiled at her. “Take a look at them. Are they really that different?” Then he went to help another customer who was ready to pay. Jesse and Gabriella turned back to the kittens. “Well, the mother is a tabby cat,” Jesse said. “Black, orange, and white spots with some brown blotches.” “Right, and some of the kittens have those same colors,” added Gabriella. They took a closer look at the kittens. “Actually, they all have small tufts of hair off their ears, just like their mother,” said Jesse. “You’re right, Jesse. And the ears are all rounded on top, not pointed like on my cat at home.” Jesse and Gabriella remembered what they had learned in science class. Organisms display traits . Traits include things like eye color in humans, the shape of ears or the color of fur in kit- tens, and seed shape or stem height in plants. Traits are determined by the genes of an individual organism. Individuals get their genes from their parents. Sometimes individuals display the same traits as their parents, sometimes they don’t. Genes are made of two parts called alleles [ul-LEELS]. Some alleles are dominant —this allele has the trait that will always appear if it is in the gene. Others are recessive —it is hiddenwhen there is a dominant allele around. Gabriella turned to her friend. “Jesse, what color are your eyes?” “Brown.”

alleles different forms of a gene; offspring inherit one allele from each parent dominant the allele that provides a trait that always appears in the organism genes information within the DNA of a cell that controls a specific trait recessive an allele that is masked by a dominant allele traits characteristics of an organism that are passed to the next generation Words to Understand

“What about your parents?” “Umm. My mom has brown eyes. And my dad has blue eyes.” “And I have brown eyes, as do both of my parents. Remem- ber what we learned? Brown eyes are dominant; the allele brown always shows through.” Jesse knew what she was talking about and piped in,

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“And blue is recessive.” He pulled a piece of a paper and pencil out of his backpack. “Punnett squares—remember these?” Drawing a box and splitting it in two, he continued. “My dad has blue eyes. The only way he can have blue eyes is if he has two recessive alleles. So that is lower case b and lower case b.” Gabriella continued. “And your mom has brown eyes. So she has at least a dominant gene—capital B. We don’t know for sure what the other allele is, do we?” Jesse thought for a moment. “Well, both my grandpar- ents have brown eyes, too.” “Okay,” said Gabriella. “Then let’s assume she has two dominant alleles—BB.” The kids completed the Punnett square using Jesse’s par- ents. They saw no “b-b” combinations. “Huh. Look at that. There is no way my brother or I could have had blue eyes.”

B BB B B B BB B b b b

This Punnett square shows how Jesse and Gabriella can’t have blue eyes. There would need to be a “b-b” pair for that to happen.

“Right, and it looks as if these kittens are in the same boat. Their mother had a dominant al- lele for tufted ears. All the kittens show it. So we can probably assume that the mother has two dominant alleles. It doesn’t even matter what the father’s ears looked like.”

Gregor Mendel Much of what we know today about how traits are passed from one generation to the next— the science of genetics—comes from the work of a European monk in the 1800s. His name was Gregor Mendel and he conducted thousands of experiments on pea plants. He looked at the height of their stems,

the arrangement of their flowers, and the shape of the pea pods and seeds. At the time, his experiments didn’t receive much attention. But the world would eventually know what his ideas about peas and genetics could mean for the understanding of the genetics of all living things!

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Try It Yourself

What did the kittens’ parents look like? Sometimes it is possible to trace the traits of the parents by looking at the off- spring. What if you could make your own “paper pet” and give it some unique and wacky traits. What would its parents have looked like?

Materials:

Construction paper Scissors Stickers of various shapes, sizes, and colors Markers, colored pencils

1. Decide on four unique traits you want your “pet” to have. Will it have long legs or short legs? Curly fur or long fur? Pointed ears or rounded ears? List the traits that you will highlight in your pet.

2. Indicate on the list whether or not the specific trait is dominant or recessive.

3. Create your pet using the materials available.

4. Draw Punnett squares for at least two of the traits your pet has—one recessive and one dominant. What traits did its parents have? What alleles made up those traits? Remember, traits come from the parents equally.

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Flight 2 G abriella let out a shriek as Rocco, the blue and gold macaw, swooped down over her head to land on a perch hanging from the ceiling. “Whoa! Did you see that thing fly?” Rocco took off again, swooping up and over tall shelves and down the aisles, soaring and flapping his big blue wings. “How does he do that?” Gabriella cried out. Tyrell, the manager of the bird collection at the store, came over with Rocco sitting on his shoulder. “It’s a matter of simple physics.”

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Jesse looked doubtful. “Is there really any such thing as simple physics?” Tyrell laughed. “Sure there is. Here, take Rocco and I’ll show you something.” Placing the big macaw on Jesse’s shoulder, Tyrell led the kids into the back room. Glancing uncertainly at the bird on his shoulder, Jesse followed Gabriella. Tyrell pulled a book out of a desk drawer. “I like to read during my lunch break.” Pulling out the strip of paper he used as a bookmark, he continued, “What do you think will happen if I blow across this paper?” Gabriella looked at the book and the strip of paper. “I bet it flaps in the wind you create with your breath.” “Let’s see.” As Tyrell gently blew across the top of the paper, the kids were surprised to see the paper rise. Tyrell blew even harder and the paper came to a horizontal position and flapped until he stopped blowing. Putting the book down, Tyrell said with a smile. “And that is why Rocco, other birds, and airplanes can fly.” lift the difference in pressure between the top of a bird, or airplane, wing and the bottom, enabling flight to occur Words to Understand

The horizontal arrows show air moving over the wing. When the pressure over the wing goes down, lift is created.

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“Huh?” Jesse said. “What does that have to do with Rocco flying?” “It’s a physical property called ‘lift.’

Rocco’s wings, like a wing of an airplane, are designed to produce an upward force, called lift . See how the wing is slanted a little? Air mov- ing over the top of the wing flows faster than the air moving along the bottom of the wing. This means the air flowing over the top of the wing exerts less pres- sure than the air moving along the bottom. This creates an upward motion.” “Oh! I get it. Just like when you blew on the paper. The air you were blowing was moving faster than the air on the underside of the paper. There was less pressure on the top, so it is almost like the air on the bottom side of the paper pushed it up.” “Right! And that is how our friend Rocco here flies too.” Tyrell clapped his hands and Rocco lifted up off of Jesse’s shoulder and flew to his outstretched hand.

Bernoulli’s Principle Why does the air flowing over the

top of the slanted wing move faster? And how does that result in a lower pressure? The answer to these questions can be found in Bernoulli’s Principle. This says that as the speed of a fluid in motion (in this case, the air) increases, then the pressure in that fluid decreases. Ber- noulli’s principle was first discovered in the 1700s by a scientist in Switzerland named Daniel Bernoulli, who found that fluids in motion behave differently than fluids at rest.

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