1. © 2012 Pearson Education, Inc. Lecture by Edward J. Zalisko PowerPoint Lectures for Campbell Biology: Concepts & Connections, Seventh Edition Reece, Taylor, Simon, and Dickey Chapter 30 How Animals Move

2. Introduction  Horses are well adapted for long-distance running with legs that are –long and –light. © 2012 Parson Education, Inc.

3. Figure 30.0_1 Chapter 30: Big Ideas Movement and Locomotion The Vertebrate Skeleton Muscle Contraction and Movement

4. Figure 30.0_2

5. MOVEMENT AND LOCOMOTION © 2012 Parson Education, Inc.

6.  Animal movement –is very diverse but –relies on the same cellular mechanisms, moving protein strands against one another using energy.  Locomotion –is active travel from place to place and –requires energy to overcome friction and gravity. 30.1 Locomotion requires energy to overcome friction and gravity © 2012 Parson Education, Inc.

7.  An animal swimming is –supported by water but –slowed by friction. 30.1 Locomotion requires energy to overcome friction and gravity © 2012 Parson Education, Inc.

8. Figure 30.1A

9.  An animal walking, hopping, or running –involves less overall friction between air and the animal, –must resist gravity, and –requires good balance. 30.1 Locomotion requires energy to overcome friction and gravity © 2012 Parson Education, Inc.

10. Figure 30.1B

11. Figure 30.1C

12.  An animal burrowing or crawling –must overcome great friction between the animal and the ground, –is more stable with respect to gravity, –may move by side-to-side undulations (such as snakes), or –may move by a form of peristalsis (such as worms). 30.1 Locomotion requires energy to overcome friction and gravity © 2012 Parson Education, Inc.

13. Figure 30.1D Longitudinal muscle relaxed (extended) Circular muscle contracted Circular muscle relaxed Longitudinal muscle contracted Head Bristles 1 2 3

14. Figure 30.1D_1 Longitudinal muscle relaxed (extended) Circular muscle contracted Circular muscle relaxed Longitudinal muscle contracted Head Bristles 1 2 3

15. Figure 30.1D_2

16.  An animal flying uses its wings as airfoils to generate lift.  Flying has evolved in very few groups of animals. Flying animals include –most insects, –reptiles, including birds, and –bats (mammals). 30.1 Locomotion requires energy to overcome friction and gravity © 2012 Parson Education, Inc.

17. Figure 30.1E Airfoil

18. Figure 30.1E_1

19.  Animal movement results from a collaboration between muscles and a skeletal system to overcome –friction and –gravity. 30.1 Locomotion requires energy to overcome friction and gravity © 2012 Parson Education, Inc.

20.  Skeletons provide –body support, –movement by working with muscles, and –protection of internal organs.  There are three main types of animal skeletons: –hydrostatic skeletons, –exoskeletons, and –endoskeletons. 30.2 Skeletons function in support, movement, and protection © 2012 Parson Education, Inc.

21. 1. Hydrostatic skeletons are –fluid held under pressure in a closed body compartment and –found in worms and cnidarians. –Hydrostatic skeletons –help protect other body parts by cushioning them from shocks, –give the body shape, and –provide support for muscle action. 30.2 Skeletons function in support, movement, and protection © 2012 Parson Education, Inc.

22. Figure 30.2A

23. 2. Exoskeletons are rigid external skeletons that consist of –chitin and protein in arthropods and –calcium carbonate shells in molluscs. –Exoskeletons must be shed to permit growth. 30.2 Skeletons function in support, movement, and protection © 2012 Parson Education, Inc.

24. Figure 30.2B

25. Figure 30.2C Shell (exoskeleton) Mantle

26. 3. Endoskeletons consist of hard or leathery supporting elements situated among the soft tissues of an animal. They may be made of –cartilage or cartilage and bone (vertebrates), –spicules (sponges), or –hard plates (echinoderms). 30.2 Skeletons function in support, movement, and protection © 2012 Parson Education, Inc.

27. Figure 30.2D

28. Figure 30.2E

29. Figure 30.2E_1

30. THE VERTEBRATE SKELETON © 2012 Parson Education, Inc.

31.  The vertebrate skeletal system provided –the structural support and –means of location –that enabled tetrapods to colonize land. 30.3 EVOLUTION CONNECTION: Vertebrate skeletons are variations on an ancient theme © 2012 Parson Education, Inc.

32.  The human skeleton consists of an –axial skeleton –that supports the axis or trunk of the body and –consists of the skull, vertebrae, and ribs and –appendicular skeleton –that includes the appendages and the bones that anchor the appendage and –consists of the arms, legs, shoulders, and pelvic girdles. 30.3 EVOLUTION CONNECTION: Vertebrate skeletons are variations on an ancient theme © 2012 Parson Education, Inc.

33. Figure 30.3A Skull Sternum Ribs Vertebra Clavicle Scapula Pectoral girdle Humerus Radius Ulna Pelvic girdle Carpals Phalanges Metacarpals Femur Patella Tibia Fibula Tarsals Metatarsals Phalanges

34. Figure 30.3A_1 Skull Sternum Ribs Vertebra Clavicle Scapula Pectoral girdle Humerus Radius Ulna Pelvic girdle Carpals Phalanges Metacarpals

35. Figure 30.3A_2 Femur Patella Tibia Fibula Tarsals Metatarsals Phalanges

36. Figure 30.3B Intervertebral discs 7 cervical vertebrae 12 thoracic vertebrae 5 lumbar vertebrae Hip bone Sacrum Coccyx

37.  Vertebrate bodies reveal variations of this basic skeletal arrangement.  Master control (homeotic) genes –are active during early development and –direct the arrangement of the skeleton. –Vertebrate evolution has included changes in these master control genes. 30.3 EVOLUTION CONNECTION: Vertebrate skeletons are variations on an ancient theme © 2012 Parson Education, Inc.

38. Figure 30.3C PythonChicken Cervical vertebrae Gene expression during development Hoxc6 Hoxc8 Hoxc6 and Hoxc8 Thoracic vertebrae Lumbar vertebrae T h o r a c i c v e r t e b r e a

39.  Cartilage at the ends of bones –cushions joints and –reduces friction of movements.  Fibrous connective tissue covering most of the outer surface of bone forms new bone in the event of a fracture. 30.4 Bones are complex living organs © 2012 Parson Education, Inc.

40.  Bone cells –live in a matrix of flexible protein fibers and hard calcium salts and –are kept alive by blood vessels, hormones, and nerves. 30.4 Bones are complex living organs © 2012 Parson Education, Inc.

41.  Long bones have –a central cavity storing fatty yellow bone marrow and –spongy bone located at the ends of bones containing red bone marrow, a specialized tissue that produces blood cells. 30.4 Bones are complex living organs © 2012 Parson Education, Inc.

42. Figure 30.4 Cartilage Spongy bone (contains red bone marrow) Compact bone Central cavity Yellow bone marrow Fibrous connective tissue Blood vessels Cartilage

43. Figure 30.4_1 Cartilage Spongy bone (contains red bone marrow) Compact bone Central cavity

44. Figure 30.4_2 Yellow bone marrow Fibrous connective tissue Blood vessels Cartilage

45.  Bone cells –repair bones and –reshape bones throughout life.  Broken bones –are realigned and immobilized and –bone cells build new bone, healing the break. 30.5 CONNECTION: Healthy bones resist stress and heal from injuries © 2012 Parson Education, Inc.

46. Figure 30.5A

47.  Osteoporosis is –a bone disease, –characterized by low bone mass and structural deterioration, and –less likely if a person –has high levels of calcium in the diet, –exercises regularly, and –does not smoke. 30.5 CONNECTION: Healthy bones resist stress and heal from injuries © 2012 Parson Education, Inc.

48. Figure 30.5B

49. 30.6 Joints permit different types of movement  Joints allow limited movement of bones.  Different joints permit various movements. –Ball-and-socket joints enable rotation in the arms and legs. –Hinge joints in the elbows and knees permit movement in a single plane. –Pivot joints enable the rotation of the forearm at the elbow. © 2012 Parson Education, Inc.

50. Figure 30.6 Head of humerus Humerus Scapula Ulna Ball-and-socket jointHinge joint Ulna Pivot joint Radius

51. Figure 30.6_1 Head of humerus Scapula Ball-and-socket joint

52. Figure 30.6_2 Humerus Ulna Hinge joint

53. Figure 30.6_3 Ulna Pivot joint Radius

54. MUSCLE CONTRACTION AND MOVEMENT © 2012 Parson Education, Inc.

55.  Muscles and bones interact to produce movement.  Muscles –are connected to bones by tendons and –can only contract, requiring an antagonistic muscle to –reverse the action and –relengthen muscles. 30.7 The skeleton and muscles interact in movement © 2012 Parson Education, Inc.

56. Figure 30.7A Biceps contracted, triceps relaxed (extended) Biceps Triceps Tendons Triceps Biceps Triceps contracted, biceps relaxed

57.  Muscle fibers are cells that consist of bundles of myofibrils. Skeletal muscle cells –are cylindrical, –have many nuclei, and –are oriented parallel to each other.  Myofibrils contain overlapping –thick filaments composed primarily of the protein myosin and –thin filaments composed primarily of the protein actin. 30.8 Each muscle cell has its own contractile apparatus © 2012 Parson Education, Inc.

58.  Sarcomeres are –repeating groups of overlapping thick and thin filaments and –the contractile unit—the fundamental unit of muscle action. 30.8 Each muscle cell has its own contractile apparatus © 2012 Parson Education, Inc.

59. Figure 30.8 Muscle Several muscle fibers Single muscle fiber (cell) Plasma membrane Nuclei Myofibril Light band Dark band Light band Z line Sarcomere Z line Thick filaments (myosin) Thin filaments (actin)

60. Figure 30.8_1 Muscle Several muscle fibers Single muscle fiber (cell)

61. Figure 30.8_2 Plasma membrane Nuclei Myofibril Light band Dark band Light band Z line Sarcomere Single muscle fiber (cell)

62. Figure 30.8_3 Sarcomere Z line Thick filaments (myosin) Thin filaments (actin) Light band Dark band Light band Z line Sarcomere

63. Figure 30.8_4

64.  According to the sliding-filament model of muscle contraction, a sarcomere contracts (shortens) when its thin filaments slide across its thick filaments. –Contraction shortens the sarcomere without changing the lengths of the thick and thin filaments. –When the muscle is fully contracted, the thin filaments overlap in the middle of the sarcomere. 30.9 A muscle contracts when thin filaments slide along thick filaments © 2012 Parson Education, Inc.

65. Figure 30.9A Relaxed muscle Contracting muscle Fully contracted muscle Dark band Sarcomere Contracted sarcomere ZZ

66.  Myosin heads of the thick filaments –bind ATP and –extend to high-energy states.  Myosin heads then –attach to binding sites on the actin molecules and –pull the thin filaments toward the center of the sarcomere. 30.9 A muscle contracts when thin filaments slide along thick filaments © 2012 Parson Education, Inc.

67. Figure 30.9B Thin filaments Thin filament Thick filament Thick filament Z line Actin Myosin head (low- energy configuration) Myosin head (high- energy configuration) Cross-bridge New position of Z line Thin filament moves toward center of sarcomere. 1 2 3 ATP ADP P P 4 P  5 Myosin head (pivoting to low-energy configuration) ATP Myosin head (low- energy configuration)

68. Figure 30.9B_s1 Thin filaments Thick filament Z line

69. Figure 30.9B_s2 Thin filaments Thick filament Z line Myosin head (low- energy configuration) Actin Thin filament Thick filament 1 ATP

70. Figure 30.9B_s3 Thin filaments Thick filament Z line Myosin head (low- energy configuration) Myosin head (high- energy configuration) Actin Thin filament Thick filament 1 2 ATP ADP P

71. Figure 30.9B_s4 Cross-bridge 3 ADP P

72. Figure 30.9B_s5 Myosin head (pivoting) 4 New position of Z line Thin filament moves toward center. ADPP  Cross-bridge 3 ADP P

73. Figure 30.9B_s6 Myosin head (low-energy) Myosin head (pivoting) ATP 5 4 New position of Z line Thin filament moves toward center. ADPP  Cross-bridge 3 ADP P

74.  A motor neuron –carries an action potential to a muscle cell, –releases the neurotransmitter acetylcholine from its synaptic terminal, and –initiates a muscle contraction. 30.10 Motor neurons stimulate muscle contraction © 2012 Parson Education, Inc.

75. Figure 30.10A Motor neuron axon Synaptic terminal T tubule Action potential Mitochondrion Endoplasmic reticulum (ER) Myofibril Plasma membrane Sarcomere Ca 2  released from ER

76.  An action potential in a muscle cell –passes along T tubules and –into the center of the muscle fiber.  Calcium ions –are released from the endoplasmic reticulum and –initiate muscle contraction by moving the regulatory protein tropomyosin away from the myosin-binding sites on actin. 30.10 Motor neurons stimulate muscle contraction © 2012 Parson Education, Inc.

77. Figure 30.10B Myosin-binding sites blocked Myosin-binding sites exposed Myosin-binding site Ca 2  floods the cytoplasmic fluid Actin Tropomyosin Ca 2  -binding sites Troponin complex

78.  A motor unit consists of –a neuron and –the set of muscle fibers it controls.  More forceful muscle contractions result when additional motor units are activated. 30.10 Motor neurons stimulate muscle contraction © 2012 Parson Education, Inc.

79. Figure 30.10C Spinal cord Motor neuron cell body Nerve Motor neuron axon Synaptic terminals Muscle Tendon Muscle fibers (cells) Nuclei Bone Motor unit 1 Motor unit 2

80.  Aerobic respiration –requires a constant supply of glucose and oxygen and –provides most of the ATP used to power muscle movement during exercise.  The anaerobic process of lactic acid fermentation –can provide ATP faster than aerobic respiration but –is less efficient. 30.11 CONNECTION: Aerobic respiration supplies most of the energy for exercise © 2012 Parson Education, Inc.

81. Figure 30.11

82. Table 30.11

83.  Depending on the pathway they use to generate ATP, muscle fibers can be classified as –slow, –intermediate, or –fast.  Most muscles have a combination of fiber types, which can be affected by exercise. 30.12 CONNECTION: Characteristics of muscle fiber affect athletic performance © 2012 Parson Education, Inc.

84. Table 30.12

85.  Muscles can adapt to exercise by increasing the –levels of myoglobin, –number of mitochondria, and/or –number of capillaries going to muscles. 30.12 CONNECTION: Characteristics of muscle fiber affect athletic performance © 2012 Parson Education, Inc.

86. Figure 30.12 Slow Intermediate Fast 100 80 60 40 20 0 World- class sprinter Average couch potato Average active person Middle- distance runner World- class marathon runner Extreme endurance athlete Percentage of total muscle

87. 1.Describe the diverse methods of locomotion found among animals and the forces each method must overcome. 2.Describe the three main types of skeletons, their advantages and disadvantages, and provide examples of each. 3.Describe the common features of terrestrial vertebrate skeletons, distinguishing between the axial and appendicular skeletons. You should now be able to © 2012 Parson Education, Inc.

88. 4.Describe the complex structure of bone, noting the major tissues and their relationship to blood- forming tissues. 5.Explain why bones break and how we can help them heal. 6.Describe three types of joints and provide examples of each. 7.Explain how muscles and the skeleton interact to produce movement. You should now be able to © 2012 Parson Education, Inc.

89. 8.Explain at the cellular level how a muscle cell contracts. 9.Explain how a motor neuron signals a muscle fiber to contract. 10.Describe the role of calcium in a muscle contraction. 11.Explain how motor units control muscle contraction. 12.Explain what causes muscle fatigue. You should now be able to © 2012 Parson Education, Inc.

90. 13.Distinguish between aerobic and anaerobic exercise, noting the advantages of each. 14.Compare the structure and functions of slow, intermediate, and fast muscle fibers. You should now be able to © 2012 Parson Education, Inc.

91. Figure 30.UN01

92. Figure 30.UN02 Sarcomere Myosin Actin

93. Figure 30.UN03 Animal movement must overcome forces of requires both gravity and friction (a)(b) types are move parts of usually in units of contraction are antagonistic pairs hydrostatic skeleton (c) (d) shorten as myosin pulls actin filaments called sliding-filament model endoskeleton made of (e)