1. II. Skeletal Muscle Overview A. Skeletal Muscle Distinguishing Characteristics Striated Voluntary Multi-nucleated B. Functions Movement Maintain Posture Stabilize Joints Generate Heat

2. III. Skeletal Muscle Anatomy Macroscopic Anatomy Fascia surrounds each muscle. Deep layer called epimysium. Bundles of muscle cells (fascicles)are surrounded by perimysium Each muscle cell (fiber) surrounded by endomysium These connective tissues allow each structure to remain separate and move independently. Blood vessels and nerves pass through these tissues. Figure 8.1

3. III. Skeletal Muscle Anatomy A. Microscopic Anatomy Each muscle cell has: - membrane (sarcolemma) - cytoplasm (sarcoplasm) - many nuclei - mitochondria - many myofibrils made of thick (myosin) and thin (actin) protein filaments. Myofibrils are organized in repeating units called sarcomeres: these are the units that contract. Figure 8.1

4. III. Skeletal Muscle Anatomy B. Microscopic Anatomy Surrounding each myofibril is a network of channels called the sarcoplasmic reticulum and transverse tubules. Figure 8.4

5. III. Skeletal Muscle Anatomy C.Sarcomere Anatomy Sarcomeres consists of 2 overlapping myofilaments with a repeated pattern. Thin filament-actin Thick filament-myosin Figure 8.2

6. Muscle contraction video

7. II. Skeletal Muscle Anatomy C. Sarcomere Anatomy Figure 8.3

8. III. Skeletal Muscle Anatomy D. Anatomy of Filaments 1. Myosin Myosin molecules have long, rod-shaped tails with globular heads. The heads form cross bridges between myosin and actin.

9. III. Skeletal Muscle Anatomy D. Anatomy of Filaments 2. Actin 2 proteins, troponin and tropomyosin, help to control the myosin-actin interactions in muscle contraction. TroponinTropomyosin

10. III. Skeletal Muscle Anatomy D. Anatomy of Filaments

11. II. Skeletal Muscle Anatomy E. Summary Summary Animation MuscleFascicleMuscle Cell/FiberMyofibrilMyofilament(actin/myosin)

12. IIII. Skeletal Muscle Contraction A.Overview of the Sliding Filament Theory 1.When a muscle cell contracts, individual sarcomeres shorten. 2.Thin filaments slide past thick filaments, so that they overlap to a greater degree. 3.I bands shorten, H zones disappears, and A bands move closer together. Simplified Animation Figure 8.8

13. IIII. Skeletal Muscle Contraction B. ATP Background Information 1. ATP consists of an adenine nucleotide attached by high-energy bonds to three phosphate groups. 2. When the terminal phosphate group is off, energy is released. 3. ATP  ADP + Pi + energy 4. This energy is available to perform cellular work.

14. III. Skeletal Muscle Contraction C. Detailed Sequence of Events 1. Cross bridge attachment Myosin heads bind to actin 2. The working stroke Myosin head pivots, propelling the actin Figure 8.7

15. IIII. Skeletal Muscle Contraction C. Detailed Sequence of Events 3. Cross bridge detachment ATP binds to myosin head, allowing it to release actin 4. Cocking of myosin head Breakdown of ATP  ADP + Pi provides energy to cock myosin head Figure 8.7 Myosin Head Animation

16. IIII. Skeletal Muscle Contraction D. Role of Calcium in Muscle Contraction 1.A nervous impulse triggers the release of Ca 2+ from the sarcoplasmic reticulum. 2.Ca 2+ binds to troponin, altering the shape and position of troponin. 3.This causes movement of the attached tropomyosin molecules, exposing the myosin binding site. 4.When calcium levels drop, the tropomyosin blockade is reestablished and contraction ends. Cross Bridge/ATP Animation

17. III. Skeletal Muscle Contraction Summary Figure 8.7 Summary Animation