1. Chapter 39 Sections 1 and 2 ONLY
Concept 39.1: The physical interaction of protein filaments is required for muscle function

2. Muscle Bundle of muscle fibers Nuclei Single muscle fiber (cell)
Figure 39.2
Muscle
Bundle of
muscle fibers
Nuclei
Single muscle fiber
(cell)
Plasma
membrane
Myofibril
Z lines
Sarcomere
Figure 39.2 The structure of skeletal muscle
TEM
Thick filaments
(myosin)
M line
0.5 m
Thin filaments
(actin)
Z line
Z line
Sarcomere 2

3. Muscle Bundle of muscle fibers Nuclei Single muscle fiber (cell)
Figure 39.2a
Muscle
Bundle of
muscle fibers
Nuclei
Single muscle fiber
(cell)
Plasma
membrane
Myofibril
Figure 39.2a The structure of skeletal muscle (part 1: muscle fibers)
Z lines
Sarcomere 3

4. Thick and Thin Filaments
Copyright © McGraw-Hill Companies Permission required for reproduction or display

5. http://highered. mcgraw-hill

6. energy configuration) 5 2
Figure 39.4
Thin
filaments 1
Thick filament
Thin filament
Myosin head (low
energy configuration)
ATP 5
ATP 2
Thick
filament
Myosin-
binding sites
Thin filament moves
toward center of sarcomere.
Actin
Myosin head (low
energy configuration)
ADP
Myosin head (high
energy configuration) P i
Figure 39.4 Myosin-actin interactions underlying muscle fiber contraction
ADP 3
ADP P i P i
Cross-bridge 4 6

7. Figure 39.3
Sarcomere
Relaxed muscle Z M Z Z M Z
Contracting muscle
0.5 m
Fully contracted muscle
Figure 39.3 The sliding-filament model of muscle contraction
Contracted
sarcomere 7

8. http://highered. mcgraw-hill

9. Synaptic terminal Axon of motor neuron T tubule Sarcoplasmic
Figure 39.6a
Synaptic terminal
Axon of
motor neuron
T tubule
Sarcoplasmic
reticulum (SR)
Mitochondrion
Myofibril
Plasma membrane
of muscle fiber
Figure 39.6a Exploring the regulation of skeletal muscle contraction (part 1: detail of synaptic terminal)
Ca2 released
from SR
Sarcomere 9

10. Synaptic terminal of motor neuron Plasma membrane Synaptic cleft
Figure 39.6b 1
Synaptic terminal of motor neuron
Plasma
membrane
Synaptic cleft
T tubule
Sarcoplasmic
reticulum (SR) 2
ACh
Ca2 pump 3
Ca2
ATP 4
CYTOSOL 7
Figure 39.6b Exploring the regulation of skeletal muscle contraction (part 2: steps of process)
Ca2 6 5 10

11. Nervous Control of Muscle Tension
Contraction of a whole muscle is GRADED, which means that the extent and strength of its contraction can be VOLUNTARILY altered
There are two basic mechanisms by which the nervous system produces graded contractions
Varying the number of fibers that contract
Varying the rate at which fibers are stimulated 11

12. Spinal cord Motor unit 1 Motor unit 2 Synaptic terminals Nerve
Figure 39.7
Spinal cord
Motor
unit 1
Motor
unit 2
Synaptic terminals
Nerve
Motor neuron
cell body
Motor neuron
axon
Figure 3.7 Motor units in a vertebrate skeletal muscle
Muscle
Muscle fibers
Tendon 12

13. Tetanus Summation of two twitches Tension Single twitch Time Action
Figure 39.8
Tetanus
Summation of
two twitches
Tension
Single
twitch
Figure 39.8 Summation of twitches
Time
Action
potential
Pair of
action
potentials
Series of action
potentials at
high frequency 13

14. Table 39.1
Table 39.1 Types of skeletal muscle fibers 14

15. Types of Muscle Fibers
Skeletal muscle fibers can be divided on the basis of their contraction speed.
Type I - Slow twitch fibers
Contract more slowlysustain LONGER contractions
OXIDATIVE
Type II - Fast twitch fibers
Contract more rapidly  sustain SHORTER contractions
GYLCOLYTIC or OXIDATIVE

16. Comparing Cardiac & Smooth Muscles
Cardiac Muscle is composed of shorter, branched cells that interconnect with one another at intercalated discs. No neural input needed.
Smooth Muscle surrounds walls of hollow internal organs (digestive tract, bladder, etc.). Contractions are slower-can be initiated by the muscles themselves or by neurons of the autonomic nervous system

17. Concept 39.2: Skeletal systems transform muscle contraction into locomotion
Skeletal muscles are attached in ANTAGONISTIC pairs…nervous system coordinates its actions!
Purpose of the skeleton? 17

18. Human forearm (internal skeleton) Grasshopper tibia
Figure 39.10
Human forearm
(internal skeleton)
Grasshopper tibia
(external skeleton)
Extensor
muscle
Biceps
Flexion
Flexor
muscle
Triceps
Biceps
Extensor
muscle
Figure The interaction of muscles and skeletons in movement
Extension
Flexor
muscle
Triceps
Key
Contracting muscle
Relaxing muscle 18

19. Types of Skeletal Systems
The three main types of skeletons are
__________________ skeletons (lack hard parts)
__________________ (external hard parts)
__________________ (internal hard parts) 19

20. Longitudinal muscle relaxed (extended) Circular muscle contracted
Figure 39.11
Longitudinal
muscle relaxed
(extended)
Circular muscle
contracted
Circular muscle
relaxed
Longitudinal
muscle
contracted
Bristles
Head end 1
Head end
Figure Crawling by peristalsis 2
Head end 3 20

21. Types of joints Skull Ball-and-socket Clavicle joint Shoulder girdle
Figure 39.12
Types
of joints
Skull
Clavicle
Ball-and-socket
joint
Shoulder girdle
Scapula
Sternum
Rib
Humerus
Hinge joint
Vertebra
Pivot joint
Radius
Ulna
Pelvic girdle
Carpals
Phalanges
Metacarpals
Figure Bones and joints of the human skeleton
Femur
Patella
Tibia
Fibula
Tarsals
Metatarsals
Phalanges 21

22. Ball-and-socket joint Head of humerus
Figure 39.13
Ball-and-socket joint
Head of
humerus
Scapula
Hinge joint
Humerus
Ulna
Figure Types of joints
Pivot joint
Ulna
Radius 22

23. Types of Locomotion
Most animals are capable of locomotion, or active travel from place to place
In locomotion, energy is expended to overcome friction and gravity
Flying
Locomotion on Land
Swimming 23