To understand the cellular processes for synthesis of ATP. To compare and contrast aerobic and anaerobic processes in the muscle cell. To examine the differences in ATP synthesis among different types of muscle cells
Structure of Adenosine Triphosphate (ATP) Note: ATP has three phosphate groups. The structure of a phosphate group (Pi) is: • The bond between the last two phosphate groups is high energy
(1) (2) (3) Regeneration of ATP 1.direct phosphorylation of CP 2.anaerobic glycolysis 3.Oxidative phosphorylation of glycogen, glucose, fat (1) (2) (3)
Metabolism of Skeletal Muscles Phosphcreatine: Rapid source of renewal of ATP. ADP combines with creatine phosphate. Phosphocreatine concentration (20-40 mM) is 4-8 times concentration of ATP (5mM).
Sources of Glucose • Two sources of glucose to muscles: 1. Blood glucose. 2. Breakdown of glycogen into glucose within the muscle cell
Anaerobic Pathway: Lactic Acid glucose glycogen glucose lactic acid pyruvic acid 2 Anaerobic Pathway: Lactic Acid
Aerobic Pathway O2 O2 CO2 H2O glucose glycogen glucose 2 myoglobin 36 pyruvic acid acetyl CoA 2 myoglobin 36 O2 CO2 H2O
Regeneration of ATP 1.direct phosphorylation of CP: 1ATP produced per CP 2.anaerobic glycolysis: 2 ATP per glucose 3.Oxidative phosphorylation of glycogen, glucose, fat; ?? ATP per glucose
glucose pyruvic acid lactic acid acetyl CoA myoglobin O2 H2O CO2 glycogen pyruvic acid lactic acid acetyl CoA myoglobin O2 H2O CO2 creatine
White muscle fiber Red muscle fiber
Features of White Muscle Fibers Characteristics of white muscle fibers: Large in diameter Light in color due to reduced or absent myoglobin Surrounded by only a few capillaries Have relatively few mitochondria Have a high glycogen content 6. Synthesize ATP mainly by glycolysis
Features of Red Muscle Fibers Characteristics of red muscle fibers: Half the diameter of white muscle fibers Dark red in color due to a large quantity of myoglobin Surrounded by many capillaries Have many mitochondria Have a low glycogen content 6. Synthesize ATP mainly by the Krebs cycle and oxidative phosphorylation
Factors Affecting Muscle Tension Three factors which affect muscle tension in a whole muscle: 1. Frequency of stimulation 2. Number of motor units recruited 3. Degree of muscle stretch
Contraction of Motor Units To examine the components of a motor unit. To understand the relationship between motor unit size and precision of muscle movement. To explore the relationship of motor units to muscle tone.
Types of Muscle Contractions Relaxation Latent period Contraction phase Twitch: Muscle is stimulated with a single electrical shock (above threshold). Quickly contracts and then relaxes. Increasing stimulus increases the strength of the twitch (up to maximum).
Relation between force and shortening velocity Velocity of contraction is maximal when load is zero Velocity decreases when load increases Power is maximal at intermediate velocity
Temporal Summation of Two Stimuli Effect of Time Interval on Second Contraction
Types of Muscle Contractions Summation: If second electrical shock is administered before complete relaxation of muscle.
Types of Muscle Contractions Incomplete tetanus: Stimulator delivers an increasing frequency of electrical shocks. Relaxation period shortens between twitches. Strength of contraction increases. Complete tetanus: Fusion frequency of stimulation. No visible relaxation between twitches. Smooth sustained contraction.
Second & Third Factor Affecting Muscle Tension Three factors which affect the development of muscle tension: 1. Frequency of Stimulation 2. Number of Motor Units Recruited 3. Degree of Muscle Stretch
Length-Tension Relationship
Slow- and Fast-Twitch Fibers Slow-twitch (type I fibers): High oxidative capacity: Resistant to fatigue. Have rich capillary supply. Numerous mitochondria and aerobic enzymes. Use ATP slowly Red muscle (dark-colored meat of fish and fowl)
Classification of fiber types 1. Tonic fibers: contract slowly, do not produce twitches and AP, postural muscle and extraocular muscles 2.Three types of twitch (or phasic) fibers a. slow twitch (or type I) fibers b. fast twitch oxidative (or type IIa) fibers c. fast-twitch glycolytic (or type IIb) fibers
Slow- and Fast-Twitch Fibers Fast-twitch (type IIa fibers): Adapted to respire aerobically. Specialized for repetitive movement Relatively resistant to fatigue. Numerous mitochondria and aerobic enzymes Flight muscles of migratory birds
Slow- and Fast-Twitch Fibers Fast-twitch (type IIB fibers): Adapted to respire anaerobically. Have large stores of glycogen. Have few capillaries. Have few mitochondria. White breast muscle of domestic fowl.
Ration for different fiber types Fast-twitch fibers: rapid movement of its limb or fins, use large amount of ATP. Slow muscles: move slowly, use less amount of energy Trade-off
Cardiac Muscle Contain actin and myosin arranged in sarcomeres. Contract via sliding-filament mechanism.. Adjacent myocardial cells joined by gap junctions. AP spread through cardiac muscle through gap junctions. Behaves as one unit. All cells contribute to contraction.
Cardiac muscle A small, elongated cell, single nucleus, connected together by gap junction, myogenic (contraction initiated in the muscle fibers themselves). Contains contractile fibers and conducting fibers (peacemaker fibers) Initiation and sustain of contraction depend on a signal from pacemaker fibers and spreads as APs through the heart by gap junctions.
Skeletal muscle: short AP with a few milliseconds Cardiac muscle: Long AP and long refractory period with several hundred milliseconds
Features of smooth muscle Lack of sarcomeres & T-tubules (non-striated) Thick and thin filaments are anchored on dense bodies Walls of hollow organs Support visceral functions (not for locomotion and other behavior) Very slow contraction & prolonged contracted activity Low energy requirement Myogenic (single-unit) and neurogenic (multi-unit) Stretch more than skeletal muscle Synthesis and secrete proteins (collagen & elastin)
Small spindle-shaped cells, one central located nucleus, diameter 2-10 mm, length 100-500 mm
Smooth Muscle Contraction Depends on rise in free intracellular Ca++ . Ca++ binds with calmodulin. Ca++ calmodulin complex joins with and activates myosin light chain kinase. Myosin heads are phosphorylated. Myosin head binds with actin. Relaxation occurs when Ca++ concentration decreases.
Inactive myosin kinase Active myosin kinase Ca 2+ Calmodulin Ca 2+ -calmodulin Inactive myosin kinase Active myosin kinase ATP P i ADP Inactive myosin Phosphor ylated myosin (can bind with actin) Fig. 8-30, p.351
Caldesmon inhibits myosin-actin binding in smooth muscle. Remove caldesmon by Ca 2+-Calmodulin or phosphorylation
Binding Ca 2+ to myosin light chain Phyosphorylation of myosin light chain by Ca2+-calmodulin or PKC