Function depends on structure

Slides:

Advertisements

Similar presentations

Excitation Contraction Coupling

Advertisements

Skeletal Muscle Activity: Contraction

Muscle Specialized for: Types:.

Muscle Physiology Chapter 1.

Muscle Function.

Muscles and Muscle Tissue

Skeletal Muscle Contraction

The Muscular System. Muscles are responsible for all types of body movement BECAUSE ……….! They contract – get shorter Three basic muscle types are found.

Fig 12.1 P. 327 Each somatic neuron together with all the muscle fibers it innervates. Each muscle fiber receives a single axon terminal from a somatic.

Chapter 24 …. a little anatomy and physiology. Levels of organization in the vertebrate body.

Muscles n Skeletal muscle organization and how it contracts.

Structure and action of skeletal muscle Mechanisms of contraction

The Muscular System. Muscular System Functions MOVEMENT MOVEMENT Maintain Posture Maintain Posture Stabilize Joints Stabilize Joints Generate HEAT Generate.

Muscular system SKELETAL MUSCLE Skeletal muscle is made up of hundreds of muscle fibers –Fibers consists of threadlike myofibrils –Myofibrils composed.

Anatomy and Physiology I

Sliding Filament Mechanism

Histology of Muscle.

The Muscular System.

Functions of the Muscular System 1.Produce body movements 2.Stabilize body positions 3.Regulate organ volume 4.Move substances within the body 5.Produce.

Myofilaments: Banding Pattern

1 Skeletal muscle structure fig 9-1a striated long multinucleate cells extend from tendon to tendon formed by fusion of myoblasts innervated by somatic.

The Muscular System What do skeletal muscles do? How do muscles work?

Muscle Contraction. Muscle Movement Muscle fiber must be stimulated: – By an electrical signal called muscle action potential (AP) – Delivered by motor.

Muscle Cells & Muscle Fiber Contractions

The Muscular System Skeletal muscle consists of numerous muscle cells called Muscle fibers. Muscle fiber terminology and characteristics Sarcolemma = plasma.

Muscle Physiology Chapter 7.

Cardiac Muscle Involuntary –heart only Contracts & relaxes continuously throughout life –Contracts without nervous stimulation! –A piece of cardiac muscle.

Lecture # 17: Muscular Tissue

CHAPTER EIGHT MUSCULAR SYSTEM.

1 Structure of Skeletal Muscle We will begin our look at the structure of muscle starting with the largest structures and working our way down to the smallest.

Muscle physiology. homeostasis skeletal muscles contribute to homeostasis by playing a major role in the procurement of food, breathing,heat generation.

Everything you didn’t know you wanted to know.. Microscopic Anatomy of Skeletal Muscle Sarcolema: Plalsma membrane of cell (fiber) Myofibril: Organelle.

Hair cells, actin bundles, and unconventional myosins.

Muscles. Smooth muscle Found in the walls of hollow organs and the blood vessels Lack striations Contain less myosin Cannot generate as much tension as.

Muscular System. Muscle Video Characteristics of Muscles Skeletal and smooth muscle cells are elongated (muscle cell = muscle fiber) Contraction of muscles.

Chapter 11 Physiology of the Muscular System. Introduction Muscular system is responsible for moving the framework of the body In addition to movement,

Dr.Mohammed Alotaibi MRes, PhD (Liverpool, England) Department of Physiology College of Medicine King Saud University.

Kate Phelan Eleni Angelopoulos Anastasia Matkovski

Skeletal Skeletal – striated, multinucleate, voluntary, Smooth Smooth - found in walls of hollow visceral organs; ex. stomach, bladder, respiratory passages;

Warm-Up Based on what you know about Latin root words, what do you think these terms refer to? Sarcomere Sarcoplasm Myofibril Epimysium Perimysium Endomysium.

Sensory and Motor Mechanisms – chpt 49-. I. Anatomy & physiology of Muscular system n A. 3 types of muscle tissue –1. skeletal muscle aka striated muscle–

Ch : Contraction and Metabolism of Skeletal Muscle

Interaction of thick & thin filaments __________________ –_____________________________________ _____________________________________ –_____________________________________.

Sliding Filament.

Filaments Resting state Electrical impulse (Action Potential) reaches axon terminal.

Synapse – The site of connection between a neuron and a cell. Neurotransmitter – A chemical released at the neuron’s synapse that communicates with the.

The Sliding Filament Theory

Outline I. Types of Muscle II. Anatomy of Skeletal Muscle III. Sliding Filament Theory IV. Role of Ca+ in regulating muscle contraction.

Lecture #21 Date ____ n Chapter 49 ~ Sensory and Motor Mechanisms.

MUSCULAR SYSTEM Structure and Function. Skeletal Muscle Properties 1. Excitability = ability to receive and respond to a stimulus  Also called irritability.

Muscle voluntary, striated involuntary, striated auto-rhythmic involuntary, non-striated evolved first multi-nucleated digestive system arteries, veins.

The Muscular System What do skeletal muscles do? How do muscles work?

Muscle Contraction Chapter 9 Part B. How does the anatomical structure function physiologically? What is the importance of the membranes? Why is it important.

Section Sarcolemma- plasma membrane of a muscle fiber 2. Sarcoplasm- cytoplasm 3. Sarcoplasmic reticulum- smooth ER that stores Ca Myofibrils-

The Muscular System What do skeletal muscles do? How do muscles work?

Muscle Physiology ..

Initially Sarcolemma is in the Resting Membrane state

9 Muscles and Muscle Tissue: Part B-Muscle Contraction and Signal Transmission.

The Structure of Skeletal Muscle

The Muscular System What do skeletal muscles do? How do muscles work?

Introductory Skeletal Muscle – Histology Flash Cards

Introduction The Muscular System.

Neuromuscular Function

LECTURE 14 CHAPTER 12 MECHANISMS OF CONTRACTION AND NEURAL CONTROL

NOTES: The Muscular System (Ch 8, part 2)

NOTES: The Muscular System (Ch 8, part 3)

Sliding Filament Theory

Presentation transcript:

Function depends on structure

Muscle classification Striated muscle Skeletal Muscle - voluntary muscles that allow for movement Cardiac Muscle - heart - specialized, involuntary Non-striated muscle Smooth Muscle such as blood vessels, digestive tract, internal organs, involuntary

Muscle functions Muscle perform four import functions: Produce movement Maintaining posture Stabilizing joints Generating heat

Functional characteristics of muscles Excitability (irritability): the ability to receive and respond to a stimulus Contractility: the ability to shorten forcibly when adequately stimulated Extensibility: the ability to be stretched or extended Elasticity: the ability of a muscle fiber to resume its resting length after being stretched.

Sarcomere: the contractile unit of a myofibril contains actin thin filament and myosin thick filament

I band A band Cross bridge Thick filament Thin filament Fig. 8-4, p.317

Contraction of sarcomeres-sliding-filament theory muscle contraction- sarcomeres shorten, actin and myosin move past each other and increase overlap between actin and myosin. muscle stretched- Sarcomeres elongate. Reduce overlap between actin and myosin. Note: Length of thick (myosin) and thin (actin) filaments remains constant.

Length-tension relation Total tension is proportional to the total number of cross-bridges (overlap) between actin and myosin filaments Ideal resting length: generate maximum force. Overlap to small: few cross-bridges can attach. No overlap: no cross-bridges can attach to actin.

3 pairs of molecules: myosin heavy chains essential light chains regulatory light chains

Actin - thin filaments 1. comprised of protein dimers linked in "chains" 2. each actin monomer has a myosin binding site 3. thin filaments are anchored at one end to "Z-line" proteins 4. thin filaments are free at other end 5. "sarcomere" is the name for unit between "Z-lines" G-actin polymerize F-actin (filamentous)

Troponin is a complex of 3 protein subunits: Troponin C binds Ca 2+ Troponin T binds tropomyosin Troponin I binds both actin & tropomyosin

Troponin C binds Ca 2+ Troponin T binds tropomyosin Troponin I binds both actin & tropomyosin

Cross-bridge chemistry Attachable Revisable Transduction of chemical to mechanical energy in muscle causes the filaments to slide: Partial rotation of the actin-bound myosin head.

neuromuscular junctions Each muscle cell is directly innervated by the terminal branch of a motor neuron. The contact between nerve and muscle occurs at a small specialized spot termed the neuromuscular junction (NMJ).

Transverse tube (T tube not Z disk): transmit excitation into muscle fibers Crab Frog

Sarcoplasmic reticulum (SR): Ca2+ is stored and released as free Ca2+ during excitation-contraction

Calsequestirin: Ca2+ binding protein in SR Ca2+/Ma2+ pump (ATPase): proteins in SR actively transport Ca2+ ions (requires ATP).

Ca++ regulation a. neural activation >> muscle is electrically excited >> AP AP ionic currents reach SR, open voltage sensitive Ca++ channels Ca++ rushes out of SR, binds to troponin C, actin-myosin permitted to interact >> contraction b. AP stops, voltage sensitive Ca++ channels close, Ca++ rapidly pumped into SR, tropomyosin returns, actin-myosin interactions blocked >> relaxation c. Ca++ is sequestered (pumped and stored) in Sarcoplasmic Reticulum (SR) - SR is the endoplasmic reticulum of muscle cells - SR is intracellular Ca++ store d. Ca++ is actively pumped into SR from muscle cytoplasm

Ryanodine receptor: located on SR membrane Dihydropyridine receptor: located on T tubule membrane, no or little Ca2+ passes through in skeletal muscle. Releasing Ca2+ from SR into the myoplasm depends interaction of activated dihydropyridine receptor and ryanodine receptor-plunger model Calcium-induced calcium release

Mechanisms of Contraction AP travels down the motor neuron to bouton. VG Ca++ channels open, Ca++ diffuses into the bouton. Ca++ binds to vesicles of NT. ACh released into neuromuscular junction. ACh binds onto receptor. Chemical gated channel for Na+ and K+open.

Mechanisms of Contraction Na+ diffuses into and K+ out of the membrane. End-plate potential occurs (depolarization). + ions are attracted to negative membrane. If depolarization sufficient, threshold occurs, producing AP.

Mechanisms of Contraction AP travels down sarcolema and T tubules. Terminal cisternae release Ca++.

Mechanisms of Contraction Ca++binds to troponin. Troponin-tropomyosin complex moves. Active binding site on actin disclosed.

Sliding Filament Theory Sliding of filaments is produced by the actions of cross bridges. Cross bridges are part of the myosin proteins that form arms that terminate in heads. Each myosin head contains an ATP-binding site. The myosin head functions as a myosin ATPase.

Contraction Myosin binding site splits ATP to ADP and Pi. ADP and Pi remain bound to myosin until myosin heads attach to actin. Pi is released, causing the power stroke to occur.

Contraction Power stroke pulls actin toward the center of the A band. ADP is released, when myosin binds to a fresh ATP at the end of the power stroke. Release of ADP upon binding to another ATP, causes the cross bridge bond to break. Cross bridges detach, ready to bind again.

Contraction ACh-esterase degrades ACh. Ca++ pumped back into SR. Choline recycled to make more ACh. Only about 50% if cross bridges are attached at any given time. Asynchronous action.

Contraction A bands: I band: Move closer together. Do not shorten. I band: Distance between A bands of successive sarcomeres. Decrease in length. Occurs because of sliding of thin filaments over and between thick filaments. H band shortens. Contains only thick filaments.

Regulation of Contraction Regulation of cross-bridge attachment to actin due to: Tropomyosin. Troponin.

Role of Ca++ Relaxation: [Ca++ ] in sarcoplasm low when tropomyosin block attachment. Ca++ is pumped back into the SR in the terminal cisternae. Muscle relaxes.

Role of Ca++ in Muscle Contraction Stimulated: Ca++ is released from SR. Ca++ attaches to troponin Tropomyosin-troponin configuration change

Two major processes require ATP in muscle contraction: Hydrolysis ATP by myosin (70-80%) Pumping of Ca2+ back into SR (20-30%)