1. An Introduction to Muscle Tissue
A primary tissue type, divided into:
Skeletal muscle tissue
Cardiac muscle tissue
Smooth muscle tissue

2. 10-1 Functions of Skeletal Muscle Tissue
Skeletal Muscles
Are attached to the skeletal system
Allow us to move
The muscular system
Includes only skeletal muscles

3. 10-1 Functions of Skeletal Muscle Tissue
Six Functions of Skeletal Muscle Tissue
Produce skeletal movement
Maintain posture and body position
Support soft tissues
Guard entrances and exits
Maintain body temperature
Store nutrient reserves

4. 10-2 Organization of Muscle
Skeletal Muscle
Muscle tissue (muscle cells or fibers)
Connective tissues
Nerves
Blood vessels

5. 10-2 Organization of Muscle
Organization of Connective Tissues
Muscles have three layers of connective tissues
Epimysium
Perimysium
Endomysium

6. 10-2 Organization of Muscle
Epimysium
Exterior collagen layer
Connected to deep fascia
Separates muscle from surrounding tissues 6

7. Figure 10-1 The Organization of Skeletal Muscles
Skeletal Muscle (organ)
Epimysium
Perimysium
Endomysium
Nerve
Muscle fascicle
Muscle fibers
Blood vessels
Epimysium
Blood vessels and nerves
Tendon
Endomysium
Perimysium 7

8. 10-2 Organization of Muscle
Perimysium
Surrounds muscle fiber bundles (fascicles)
Contains blood vessel and nerve supply to fascicles

9. Figure 10-1 The Organization of Skeletal Muscles
Skeletal Muscle (organ)
Epimysium
Perimysium
Endomysium
Nerve
Muscle fascicle
Muscle fibers
Blood vessels
Epimysium
Blood vessels and nerves
Tendon
Endomysium
Perimysium 9

10. 10-2 Organization of Muscle
Endomysium
Surrounds individual muscle cells (muscle fibers)
Contains capillaries and nerve fibers contacting muscle cells
Contains myosatellite cells (stem cells) that repair damage

11. Figure 10-1 The Organization of Skeletal Muscles
Skeletal Muscle (organ)
Epimysium
Perimysium
Endomysium
Nerve
Muscle fascicle
Muscle fibers
Blood vessels
Epimysium
Blood vessels and nerves
Tendon
Endomysium
Perimysium 11

12. Figure 10-1 The Organization of Skeletal Muscles
Muscle Fascicle (bundle of fibers)
Perimysium
Muscle fiber
Epimysium
Blood vessels and nerves
Endomysium
Tendon
Endomysium
Perimysium 12

13. Figure 10-1 The Organization of Skeletal Muscles
Muscle Fiber (cell)
Capillary
Myofibril
Endomysium
Sarcoplasm
Epimysium
Blood vessels and nerves
Mitochondrion
Myosatellite cell
Sarcolemma
Nucleus
Tendon
Axon of neuron
Endomysium
Perimysium 13

14. 10-2 Organization of Muscle
Organization of Connective Tissues
Muscle Attachments
Endomysium, perimysium, and epimysium come together:
At ends of muscles
To form connective tissue attachment to bone matrix
I.e., tendon (bundle) or aponeurosis (sheet)

15. 10-2 Organization of Muscle
Blood Vessels and Nerves
Muscles have extensive vascular systems that:
Supply large amounts of oxygen
Supply nutrients
Carry away wastes
Skeletal muscles are voluntary muscles, controlled by nerves of the central nervous system (brain and spinal cord)

16. 10-3 Characteristics of Skeletal Muscle Fibers
Skeletal Muscle Cells
Are very long
Develop through fusion of mesodermal cells (myoblasts)
Become very large
Contain hundreds of nuclei

17. Figure 10-2 The Formation of a Multinucleate Skeletal Muscle Fiber
Muscle fibers develop through the fusion of mesodermal cells called myoblasts.
Myoblasts
A muscle fiber forms by the fusion of myoblasts.
Muscle fiber
LM  612
Nuclei
Sarcolemma
Myofibrils
Myosatellite cell
Nuclei
Mitochondria
Immature muscle fiber
A diagrammatic view and a micrograph of one muscle fiber.
Myosatellite cell
Up to 30 cm in length
Mature muscle fiber 17

18. Figure 10-2a The Formation of a Multinucleate Skeletal Muscle Fiber
Muscle fibers develop through the fusion of mesodermal cells called myoblasts.
Myoblasts
A muscle fiber forms by the fusion of myoblasts.
Myosatellite cell
Nuclei
Immature muscle fiber
Myosatellite cell
Up to 30 cm in length
Mature muscle fiber 18

19. Figure 10-2b The Formation of a Multinucleate Skeletal Muscle Fiber
Nuclei
Sarcolemma
Myofibrils
Mitochondria
A diagrammatic view and a micrograph of one muscle fiber. 19

20. 10-3 Characteristics of Skeletal Muscle Fibers
The Sarcolemma and Transverse Tubules
The sarcolemma
The cell membrane of a muscle fiber (cell)
Under the endomysium
Surrounds the sarcoplasm (cytoplasm of muscle fiber)
A change in transmembrane potential begins contractions

21. Figure 10-3 The Structure of a Skeletal Muscle Fiber
Myofibril
Sarcolemma
Nuclei
Sarcoplasm
MUSCLE FIBER
Mitochondria
Terminal cisterna
Sarcolemma
Sarcolemma
Sarcoplasm
Myofibril
Myofibrils
Thin filament
Thick filament
Triad
Sarcoplasmic reticulum
T tubules 21

22. 10-3 Characteristics of Skeletal Muscle Fibers
The Sarcolemma and Transverse Tubules
Transverse tubules (T tubules)
Transmit action potential through cell
Allow entire muscle fiber to contract simultaneously
Have same properties as sarcolemma

23. Figure 10-3 The Structure of a Skeletal Muscle Fiber
Myofibril
Sarcolemma
Nuclei
Sarcoplasm
MUSCLE FIBER
Mitochondria
Terminal cisterna
Sarcolemma
Sarcolemma
Sarcoplasm
Myofibril
Myofibrils
Thin filament
Thick filament
Triad
Sarcoplasmic reticulum
T tubules 23

24. 10-3 Characteristics of Skeletal Muscle Fibers
Myofibrils
Lengthwise subdivisions within muscle fiber
Made up of bundles of protein filaments (myofilaments)
Myofilaments are responsible for muscle contraction
Types of myofilaments:
Thin filaments
Made of the protein actin
Thick filaments
Made of the protein myosin

25. Figure 10-3 The Structure of a Skeletal Muscle Fiber
Mitochondria
Terminal cisterna
Sarcolemma
Sarcolemma
Sarcoplasm
Myofibril
Myofibrils
Thin filament
Thick filament
Triad
Sarcoplasmic reticulum
T tubules 25

26. 10-3 Characteristics of Skeletal Muscle Fibers
The Sarcoplasmic Reticulum (SR)
A membranous structure surrounding each myofibril
Helps transmit action potential to myofibril
Similar in structure to smooth endoplasmic reticulum
Forms chambers (terminal cisternae) attached to T tubules

27. Figure 10-3 The Structure of a Skeletal Muscle Fiber
Terminal cisterna
Sarcolemma
Sarcoplasm
Myofibrils
Triad
Sarcoplasmic reticulum
T tubules 27

28. 10-3 Characteristics of Skeletal Muscle Fibers
The Sarcoplasmic Reticulum (SR)
Triad
Is formed by one T tubule and two terminal cisternae
Cisternae
Concentrate Ca2+ (via ion pumps)
Release Ca2+ into sarcomeres to begin muscle contraction

29. Figure 10-3 The Structure of a Skeletal Muscle Fiber
Terminal cisterna
Sarcolemma
Sarcoplasm
Myofibrils
Triad
Sarcoplasmic reticulum
T tubules 29

30. Figure 10-1 The Organization of Skeletal Muscles
Skeletal Muscle (organ)
Epimysium
Perimysium
Endomysium
Nerve
Muscle fascicle
Muscle fibers
Blood vessels
Epimysium
Blood vessels and nerves
Tendon
Endomysium
Perimysium 30

31. Figure 10-1 The Organization of Skeletal Muscles
Muscle Fascicle (bundle of fibers)
Perimysium
Muscle fiber
Epimysium
Blood vessels and nerves
Endomysium
Tendon
Endomysium
Perimysium 31

32. Figure 10-1 The Organization of Skeletal Muscles
Muscle Fiber (cell)
Capillary
Myofibril
Endomysium
Sarcoplasm
Epimysium
Blood vessels and nerves
Mitochondrion
Myosatellite cell
Sarcolemma
Nucleus
Tendon
Axon of neuron
Endomysium
Perimysium 32

33. Figure 10-3 The Structure of a Skeletal Muscle Fiber
Myofibril
Sarcolemma
Nuclei
Sarcoplasm
MUSCLE FIBER
Mitochondria
Terminal cisterna
Sarcolemma
Sarcolemma
Sarcoplasm
Myofibril
Myofibrils
Thin filament
Thick filament
Triad
Sarcoplasmic reticulum
T tubules 33

34. Figure 10-3 The Structure of a Skeletal Muscle Fiber
Myofibril
Sarcolemma
Nuclei
Sarcoplasm
MUSCLE FIBER 34

35. Figure 10-3 The Structure of a Skeletal Muscle Fiber
Mitochondria
Terminal cisterna
Sarcolemma
Sarcolemma
Sarcoplasm
Myofibril
Myofibrils
Thin filament
Thick filament
Triad
Sarcoplasmic reticulum
T tubules 35

36. Figure 10-3 The Structure of a Skeletal Muscle Fiber
Mitochondria
Sarcolemma
Myofibril
Thin filament
Thick filament 36

37. Figure 10-3 The Structure of a Skeletal Muscle Fiber
Terminal cisterna
Sarcolemma
Sarcoplasm
Myofibrils
Triad
Sarcoplasmic reticulum
T tubules 37

38. Perimysium
Muscle
Epimysium
Muscle fiber
Endomysium
Muscle fascicle
Tendon

39. Figure 10-3 The Structure of a Skeletal Muscle Fiber
Myofibrils
Sarcoplasmic reticulum
Myofibril
T-tubules
Sarcomere
Triad
Sarcolemma 39

40. 10-3 Structural Components of a Sarcomere
Sarcomeres
The contractile units of muscle
Structural units of myofibrils
Form visible patterns within myofibrils
A striped or striated pattern within myofibrils
Alternating dark, thick filaments (A bands) and light, thin filaments (I bands)

41. Figure 10-4a Sarcomere Structure, Part I
I band
A band
H band
Z line
Titin
A longitudinal section of a sarcomere, showing bands
Zone of overlap
M line
Thin filament
Thick filament
Sarcomere 41

42. 10-3 Structural Components of a Sarcomere
Sarcomeres
The A Band
M line
At midline of sarcomere
The H Band
Has thick filaments but no thin filaments
Zone of overlap
The densest, darkest area on a light micrograph
Where thick and thin filaments overlap

43. Figure 10-4a Sarcomere Structure, Part I
I band
A band
H band
Z line
Titin
A longitudinal section of a sarcomere, showing bands
Zone of overlap
M line
Thin filament
Thick filament
Sarcomere 43

44. 10-3 Structural Components of a Sarcomere
Sarcomeres
The I Band
Z lines
At two ends of sarcomere
Titin
Stabilize the filaments

45. Figure 10-4a Sarcomere Structure, Part I
I band
A band
H band
Z line
Titin
A longitudinal section of a sarcomere, showing bands
Zone of overlap
M line
Thin filament
Thick filament
Sarcomere 45

46. Figure 10-4b Sarcomere Structure, Part I
I band
A band
H band
Z line
A corresponding view of a sarcomere in a myofibril from a muscle fiber in the gastrocnemius muscle of the calf
Myofibril
TEM  64,000
Z line
Zone of overlap
M line
Sarcomere 46

47. Figure 10-5 Sarcomere Structure, Part II
Myofibril
A superficial view of a sarcomere
Thin filament
Thick filament
Actinin filaments
Titin filament
Attachment of titin
Z line
I band
M line
H band
Zone of overlap
Cross-sectional views of different portions of a sarcomere 47

48. Figure 10-6 Levels of Functional Organization in a Skeletal Muscle
Myofibril
Surrounded by: Epimysium
Surrounded by: Sarcoplasmic reticulum
Epimysium
Contains: Muscle fascicles
Consists of: Sarcomeres (Z line to Z line)
Sarcomere
I band
A band
Muscle Fascicle
Contains: Thick filaments
Surrounded by: Perimysium
Thin filaments
Perimysium
Contains: Muscle fibers
Z line
M line
Titin
Z line
H band
Muscle Fiber
Surrounded by: Endomysium
Endomysium
Contains: Myofibrils 48

49. Figure 10-6 Levels of Functional Organization in a Skeletal Muscle
Surrounded by: Epimysium
Epimysium
Contains: Muscle fascicles 49

50. Figure 10-6 Levels of Functional Organization in a Skeletal Muscle
Muscle Fascicle
Surrounded by: Perimysium
Perimysium
Contains: Muscle fibers 50

51. Figure 10-6 Levels of Functional Organization in a Skeletal Muscle
Muscle Fiber
Surrounded by: Endomysium
Endomysium
Contains: Myofibrils 51

52. Figure 10-6 Levels of Functional Organization in a Skeletal Muscle
Myofibril
Surrounded by: Sarcoplasmic reticulum
Consists of: Sarcomeres (Z line to Z line) 52

53. Figure 10-6 Levels of Functional Organization in a Skeletal Muscle
Sarcomere
I band
A band
Contains: Thick filaments
Thin filaments
Z line
M line
Titin
Z line
H band 53

54. Figure 10-7b Thick and Thin Filaments
Troponin
Active site
Nebulin
Tropomyosin
G-actin molecules
F-actin strand
The organization of G-actin subunits in an F-actin strand, and the position of the troponin–tropomyosin complex 54

55. Figure 10-7cd Thick and Thin Filaments
Titin
The structure of thick filaments, showing the orientation of the myosin molecules
M line
Myosin head
Myosin tail
Hinge
The structure of a myosin molecule 55

56. 10-3 Structural Components of a Sarcomere
Thin Filament
Nebulin
The center of the thin filament
G-actin
The active sites on actin strands bind to myosin

57. 10-3 Structural Components of a Sarcomere
Thin Filaments
Tropomyosin
Prevents actin–myosin interaction
Troponin
Controlled by Ca2+

58. Figure 10-7ab Thick and Thin Filaments
Sarcomere
H band
Actinin
Z line
Titin
Myofibril
The gross structure of a thin filament, showing the attachment at the Z line
Troponin
Active site
Nebulin
Tropomyosin
G-actin molecules
Z line
M line
F-actin strand
The organization of G-actin subunits in an F-actin strand, and the position of the troponin–tropomyosin complex 58

59. Figure 10-7a Thick and Thin Filaments
Actinin
Z line
Titin
The gross structure of a thin filament, showing the attachment at the Z line 59

60. Figure 10-7b Thick and Thin Filaments
Troponin
Active site
Nebulin
Tropomyosin
G-actin molecules
F-actin strand
The organization of G-actin subunits in an F-actin strand, and the position of the troponin–tropomyosin complex 60

61. Figure 10-7b Thick and Thin Filaments
Troponin
Active site
Nebulin
Tropomyosin
G-actin molecules
F-actin strand
The organization of G-actin subunits in an F-actin strand, and the position of the troponin–tropomyosin complex 61

62. 10-3 Structural Components of a Sarcomere
Initiating Contraction
Ca2+ binds to receptor on troponin molecule
Troponin pulls tropomyosin away from f-actin
Exposes active site of F-actin

63. 10-3 Structural Components of a Sarcomere
Thick Filaments
Contain about 300 twisted myosin subunits
Contain titin strands that recoil after stretching
The mysosin molecule
Tail
Binds to other myosin molecules
Head
Made of two protein subunits
Reaches the nearest thin filament

64. Figure 10-7cd Thick and Thin Filaments
Titin
The structure of thick filaments, showing the orientation of the myosin molecules
M line
Myosin head
Myosin tail
Hinge
The structure of a myosin molecule 64

65. 10-3 Structural Components of a Sarcomere
Myosin Action
During contraction, myosin heads:
Interact with actin filaments, forming cross-bridges
Pivot, producing motion

66. 10-3 Structural Components of a Sarcomere
Sliding Filaments and Muscle Contraction
Sliding filament theory
Thin filaments of sarcomere slide toward M line, alongside thick filaments
The width of A zone stays the same
Z lines move closer together

67. Figure 10-8a Changes in the Appearance of a Sarcomere during the Contraction of a Skeletal Muscle Fiber
I band
A band
Z line
H band
Z line
A relaxed sarcomere showing location of the A band, Z lines, and I band. 67

68. Figure 10-8b Changes in the Appearance of a Sarcomere during the Contraction of a Skeletal Muscle Fiber
I band
A band
Z line
H band
Z line
During a contraction, the A band stays the same width, but the Z lines move closer together and the I band gets smaller. When the ends of a myofibril are free to move, the sarcomeres shorten simultaneously and the ends of the myofibril are pulled toward its center. 68

69. 10-3 Structural Components of a Sarcomere
Skeletal Muscle Contraction
The process of contraction
Neural stimulation of sarcolemma
Muscle fiber contraction
Tension production

70. Figure 10-9 An Overview of Skeletal Muscle Contraction
Neural control
Excitation–contraction coupling
Excitation
Calcium release
triggers
ATP
Thick-thin filament interaction
Muscle fiber contraction
leads to
Tension production 70

71. Figure 10-9 An Overview of Skeletal Muscle Contraction
Neural control 71

72. Figure 10-9 An Overview of Skeletal Muscle Contraction
Excitation
Calcium release
ATP
triggers
Thick-thin filament interaction 72

73. Figure 10-9 An Overview of Skeletal Muscle Contraction
Muscle fiber contraction
leads to
Tension production 73

74. 10-4 Components of the Neuromuscular Junction
The Control of Skeletal Muscle Activity
The neuromuscular junction (NMJ)
Between nervous system and skeletal muscle fiber
Stimulates release of calcium ions into sarcoplasm

75. Figure 10-11 Skeletal Muscle Innervation
Motor neuron
Path of electrical impulse (action potential)
Axon
Neuromuscular junction
Synaptic terminal
SEE BELOW
Sarcoplasmic reticulum
Motor end plate
Myofibril
Motor end plate 75

76. Figure 10-11 Skeletal Muscle Innervation
The cytoplasm of the synaptic terminal contains vesicles filled with molecules of acetylcholine, or ACh. Acetylcholine is a neurotransmitter, a chemical released by a neuron to change the permeability or other properties of another cell’s plasma membrane. The synaptic cleft and the motor end plate contain molecules of the enzyme acetylcholinesterase (AChE), which breaks down ACh.
Vesicles
ACh
The synaptic cleft, a narrow space, separates the synaptic terminal of the neuron from the opposing motor end plate.
Junctional fold of motor end plate
AChE 76

77. Figure 10-11 Skeletal Muscle Innervation
The stimulus for ACh release is the arrival of an electrical impulse, or action potential, at the synaptic terminal. An action potential is a sudden change in the transmembrane potential that travels along the length of the axon.
Arriving action potential 77

78. Figure 10-11 Skeletal Muscle Innervation
When the action potential reaches the neuron’s synaptic terminal, permeability changes in the membrane trigger the exocytosis of ACh into the synaptic cleft. Exocytosis occurs as vesicles fuse with the neuron’s plasma membrane.
Motor end plate 78

79. Figure 10-11 Skeletal Muscle Innervation
ACh molecules diffuse across the synatpic cleft and bind to ACh receptors on the surface of the motor end plate. ACh binding alters the membrane’s permeability to sodium ions. Because the extracellular fluid contains a high concentration of sodium ions, and sodium ion concentration inside the cell is very low, sodium ions rush into the sarcoplasm.
ACh receptor site 79

80. Figure 10-11 Skeletal Muscle Innervation
The sudden inrush of sodium ions results in the generation of an action potential in the sarcolemma. AChE quickly breaks down the ACh on the motor end plate and in the synaptic cleft, thus inactivating the ACh receptor sites.
Action potential
AChE 80

81. 10-4 Components of the Neuromuscular Junction
Excitation–Contraction Coupling
Action potential reaches a triad
Releasing Ca2+
Triggering contraction
Requires myosin heads to be in “cocked” position
Loaded by ATP energy

82. Figure 10-10 The Exposure of Active Sites
SARCOPLASMIC RETICULUM
Calcium channels open
Myosin tail (thick filament)
Tropomyosin strand
Troponin
G-actin (thin filament)
Active site
Nebulin
In a resting sarcomere, the tropomyosin strands cover the active sites on the thin filaments, preventing cross-bridge formation.
When calcium ions enter the sarcomere, they bind to troponin, which rotates and swings the tropomyosin away from the active sites.
Cross-bridge formation then occurs, and the contraction cycle begins. 82

83. 10-4 Skeletal Muscle Contraction
The Contraction Cycle
Contraction Cycle Begins
Active-Site Exposure
Cross-Bridge Formation
Myosin Head Pivoting
Cross-Bridge Detachment
Myosin Reactivation

84. Figure 10-12 The Contraction Cycle
Contraction Cycle Begins
The contraction cycle, which involves a series of interrelated steps, begins with the arrival of calcium ions within the zone of overlap.
Myosin head
Troponin
Tropomyosin
Actin 84

85. Figure 10-12 The Contraction Cycle
Active-Site Exposure
Calcium ions bind to troponin, weakening the bond between actin and the troponin– tropomyosin complex. The troponin molecule then changes position, rolling the tropomyosin molecule away from the active sites on actin and allowing interaction with the energized myosin heads.
Sarcoplasm
Active site 85

86. Figure 10-12 The Contraction Cycle
Cross-Bridge Formation
Once the active sites are exposed, the energized myosin heads bind to them, forming cross-bridges. 86

87. Figure 10-12 The Contraction Cycle
Myosin Head Pivoting
After cross-bridge formation, the energy that was stored in the resting state is released as the myosin head pivots toward the M line. This action is called the power stroke; when it occurs, the bound ADP and phosphate group are released. 87

88. Figure 10-12 The Contraction Cycle
Cross-Bridge Detachment
When another ATP binds to the myosin head, the link between the myosin head and the active site on the actin molecule is broken. The active site is now exposed and able to form another cross-bridge. 88

89. Figure 10-12 The Contraction Cycle
Myosin Reactivation
Myosin reactivation occurs when the free myosin head splits ATP into ADP and P. The energy released is used to recock the myosin head. 89