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Overview of Muscle Tissue Types of Muscle Tissue

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Overview of Muscle Tissue Types of Muscle Tissue OVERVIEW OF MUSCLE TISSUE TYPES OF MUSCLE TISSUE Both skeletal and cardiac muscle cells have striations, giving both cell types a striped appearance. Figure 10.1 Three types of muscle tissue. © 2016 Pearson Education, Inc. STRIATED MUSCLE TISSUE • Functions: support, movement (limbs, blood, lymph, urine, air, food, fluids, sperm), maintenance of body temperature (involuntary shivering), regulate organ volumes (sphincters) • Organs/tissues: ▪ Skeletal muscle o Striated o Voluntary o Attached to bone, skin or fascia ▪ Cardiac muscle o Striated o Involuntary o Autorhythmic (built in pacemaker) ▪ Smooth muscle o Nonstriated o Involuntary o Hair follicles in skin, walls of hollow organs STRUCTURE • Myocytes, or muscle cells ▪ sarcoplasm is the myocyte’s cytoplasm OF MUSCLE ▪ sarcolemma is the myocyte’s plasma CELLS membrane ▪ sarcoplasmic reticulum (SR) is modified endoplasmic reticulum: gives rise to myofibrils © 2016 Pearson Education, Inc. MUSCLE PROPERTY • Excitability ▪ Response to chemicals released from nerve cells • Conductivity ▪ Propagate electrical signals over membrane • Contractility ▪ Shorten and generate force • Extensibility ▪ Stretch without damaging the tissue • Elasticity ▪ Return to original shape after being stretched STRUCTURE OF THE SKELETAL MUSCLE FIBER Figure 10.4 Structure of a skeletal muscle fiber. © 2016 Pearson Education, Inc. STRUCTURE OF THE SKELETAL MUSCLE FIBER Skeletal muscle fibers - many embryonic myoblasts • The sarcoplasmic reticulum (SR) surrounds the myofibrils and stores and releases calcium ions • T-tubules form a tunnel-like network within the muscle fiber, continuous with the exterior of the cell, and are therefore filled with extracellular fluid STRUCTURE OF THE MYOFIBRIL • Thick filaments are composed of bundles of the contractile protein myosin ▪ Each myosin has globular heads at each end linked by intertwining tails ▪ Myosin heads are connected to the tails by a hinge-like neck ▪ Each myosin head has an active site that binds with actin • Thin filaments are composed of the proteins actin, tropomyosin, and troponin • Elastic filaments are composed of a single massive, spring-like structural protein called titin that stabilizes the myofibril structure and resists excessive stretching force STRUCTURE OF THE MYOFIBRIL Figure 10.5 Structure of myofilaments. © 2016 Pearson Education, Inc. SARCOMERE • From Z to Z is a functional unit: the sarcomere STRUCTURE OF THICK AND THIN FILAMENTS • Thin: Actin ▪ Polymer of G-actin ▪ Tropomyosin ▪ Troponin • Thick: Myosin ▪ Globular heads ▪ ATP binding site ▪ Actin binding site • Multiple actin subunits string together like beads on a necklace to form the two intertwining strands in the functional thin filament • Tropomyosin is a long, rope-like regulatory protein that twists around actin covering up its active sites MYOFILAMENT ARRANGEMENT AND THE SARCOMERE Dark and light areas of striations: • The I band = thin filaments • The Z disc is found in the middle of the I band and is composed of structural proteins • A band contains the zone of overlap, the region where we find both thick and thin filament • A band where only thick filaments exist is the H zone • The M line is a dark line in the middle of the A band made up of structural proteins that hold the thick filaments MYOFILAMENT ARRANGEMENT AND THE SARCOMERE Figure 10.8 Three-dimensional structure of the sarcomere. © 2016 Pearson Education, Inc. THE SLIDING-FILAMENT MECHANISM OF CONTRACTION Remember – none of the filaments themselves actually shorten; the thin filaments simply move toward the M line Figure 10.9 The sliding filament mechanism; changes in the bands of the sarcomere. © 2016 Pearson Education, Inc. THE SLIDING-FILAMENT MECHANISM OF CONTRACTION • The sarcomere extends from one Z-disc • The sliding filament mechanism explains how tension is generated during muscle contraction ▪ During a contraction, ▪ I band - decreases ▪ H zone - decreases ▪ A band - unchanged ▪ Z-discs - decreases shortening the sarcomere ▪ Sarcomeres are arranged end to end within each myofibril and when simultaneously contracted, shorten the whole muscle fiber CONTRACTION CYCLE: INTERACTION OF FILAMENTS MUSCLE LAB • *Complete Physio-ex Worksheet - complete Activity 1 , Activity 5, Activity 6 http://www.physioex.com/login.html and use the Login Name RCBIOL22 and the Password Spring2017 • *Sketch and label all three muscle fibers (Skeletal, Smooth, and Cardiac) • *Complete discussions • *(All due before you leave).
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